diff --git a/sys/contrib/openzfs/cmd/zed/agents/zfs_mod.c b/sys/contrib/openzfs/cmd/zed/agents/zfs_mod.c index b2c008ad1d0e..9636c99fc85f 100644 --- a/sys/contrib/openzfs/cmd/zed/agents/zfs_mod.c +++ b/sys/contrib/openzfs/cmd/zed/agents/zfs_mod.c @@ -1,1347 +1,1366 @@ /* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or https://opensource.org/licenses/CDDL-1.0. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright (c) 2007, 2010, Oracle and/or its affiliates. All rights reserved. * Copyright (c) 2012 by Delphix. All rights reserved. * Copyright 2014 Nexenta Systems, Inc. All rights reserved. * Copyright (c) 2016, 2017, Intel Corporation. * Copyright (c) 2017 Open-E, Inc. All Rights Reserved. + * Copyright (c) 2023, Klara Inc. */ /* * ZFS syseventd module. * * file origin: openzfs/usr/src/cmd/syseventd/modules/zfs_mod/zfs_mod.c * * The purpose of this module is to identify when devices are added to the * system, and appropriately online or replace the affected vdevs. * * When a device is added to the system: * * 1. Search for any vdevs whose devid matches that of the newly added * device. * * 2. If no vdevs are found, then search for any vdevs whose udev path * matches that of the new device. * * 3. If no vdevs match by either method, then ignore the event. * * 4. Attempt to online the device with a flag to indicate that it should * be unspared when resilvering completes. If this succeeds, then the * same device was inserted and we should continue normally. * * 5. If the pool does not have the 'autoreplace' property set, attempt to * online the device again without the unspare flag, which will * generate a FMA fault. * * 6. If the pool has the 'autoreplace' property set, and the matching vdev * is a whole disk, then label the new disk and attempt a 'zpool * replace'. * * The module responds to EC_DEV_ADD events. The special ESC_ZFS_VDEV_CHECK * event indicates that a device failed to open during pool load, but the * autoreplace property was set. In this case, we deferred the associated * FMA fault until our module had a chance to process the autoreplace logic. * If the device could not be replaced, then the second online attempt will * trigger the FMA fault that we skipped earlier. * * On Linux udev provides a disk insert for both the disk and the partition. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "zfs_agents.h" #include "../zed_log.h" #define DEV_BYID_PATH "/dev/disk/by-id/" #define DEV_BYPATH_PATH "/dev/disk/by-path/" #define DEV_BYVDEV_PATH "/dev/disk/by-vdev/" typedef void (*zfs_process_func_t)(zpool_handle_t *, nvlist_t *, boolean_t); libzfs_handle_t *g_zfshdl; list_t g_pool_list; /* list of unavailable pools at initialization */ list_t g_device_list; /* list of disks with asynchronous label request */ tpool_t *g_tpool; boolean_t g_enumeration_done; pthread_t g_zfs_tid; /* zfs_enum_pools() thread */ typedef struct unavailpool { zpool_handle_t *uap_zhp; list_node_t uap_node; } unavailpool_t; typedef struct pendingdev { char pd_physpath[128]; list_node_t pd_node; } pendingdev_t; static int zfs_toplevel_state(zpool_handle_t *zhp) { nvlist_t *nvroot; vdev_stat_t *vs; unsigned int c; verify(nvlist_lookup_nvlist(zpool_get_config(zhp, NULL), ZPOOL_CONFIG_VDEV_TREE, &nvroot) == 0); verify(nvlist_lookup_uint64_array(nvroot, ZPOOL_CONFIG_VDEV_STATS, (uint64_t **)&vs, &c) == 0); return (vs->vs_state); } static int zfs_unavail_pool(zpool_handle_t *zhp, void *data) { zed_log_msg(LOG_INFO, "zfs_unavail_pool: examining '%s' (state %d)", zpool_get_name(zhp), (int)zfs_toplevel_state(zhp)); if (zfs_toplevel_state(zhp) < VDEV_STATE_DEGRADED) { unavailpool_t *uap; uap = malloc(sizeof (unavailpool_t)); if (uap == NULL) { perror("malloc"); exit(EXIT_FAILURE); } uap->uap_zhp = zhp; list_insert_tail((list_t *)data, uap); } else { zpool_close(zhp); } return (0); } /* * Write an array of strings to the zed log */ static void lines_to_zed_log_msg(char **lines, int lines_cnt) { int i; for (i = 0; i < lines_cnt; i++) { zed_log_msg(LOG_INFO, "%s", lines[i]); } } /* * Two stage replace on Linux * since we get disk notifications * we can wait for partitioned disk slice to show up! * * First stage tags the disk, initiates async partitioning, and returns * Second stage finds the tag and proceeds to ZFS labeling/replace * * disk-add --> label-disk + tag-disk --> partition-add --> zpool_vdev_attach * * 1. physical match with no fs, no partition * tag it top, partition disk * * 2. physical match again, see partition and tag * */ /* * The device associated with the given vdev (either by devid or physical path) * has been added to the system. If 'isdisk' is set, then we only attempt a * replacement if it's a whole disk. This also implies that we should label the * disk first. * * First, we attempt to online the device (making sure to undo any spare * operation when finished). If this succeeds, then we're done. If it fails, * and the new state is VDEV_CANT_OPEN, it indicates that the device was opened, * but that the label was not what we expected. If the 'autoreplace' property * is enabled, then we relabel the disk (if specified), and attempt a 'zpool * replace'. If the online is successful, but the new state is something else * (REMOVED or FAULTED), it indicates that we're out of sync or in some sort of * race, and we should avoid attempting to relabel the disk. * * Also can arrive here from a ESC_ZFS_VDEV_CHECK event */ static void zfs_process_add(zpool_handle_t *zhp, nvlist_t *vdev, boolean_t labeled) { const char *path; vdev_state_t newstate; nvlist_t *nvroot, *newvd; pendingdev_t *device; uint64_t wholedisk = 0ULL; uint64_t offline = 0ULL, faulted = 0ULL; uint64_t guid = 0ULL; uint64_t is_spare = 0; const char *physpath = NULL, *new_devid = NULL, *enc_sysfs_path = NULL; char rawpath[PATH_MAX], fullpath[PATH_MAX]; - char devpath[PATH_MAX]; + char pathbuf[PATH_MAX]; int ret; int online_flag = ZFS_ONLINE_CHECKREMOVE | ZFS_ONLINE_UNSPARE; boolean_t is_sd = B_FALSE; boolean_t is_mpath_wholedisk = B_FALSE; uint_t c; vdev_stat_t *vs; char **lines = NULL; int lines_cnt = 0; + /* + * Get the persistent path, typically under the '/dev/disk/by-id' or + * '/dev/disk/by-vdev' directories. Note that this path can change + * when a vdev is replaced with a new disk. + */ if (nvlist_lookup_string(vdev, ZPOOL_CONFIG_PATH, &path) != 0) return; /* Skip healthy disks */ verify(nvlist_lookup_uint64_array(vdev, ZPOOL_CONFIG_VDEV_STATS, (uint64_t **)&vs, &c) == 0); if (vs->vs_state == VDEV_STATE_HEALTHY) { zed_log_msg(LOG_INFO, "%s: %s is already healthy, skip it.", __func__, path); return; } (void) nvlist_lookup_string(vdev, ZPOOL_CONFIG_PHYS_PATH, &physpath); (void) nvlist_lookup_string(vdev, ZPOOL_CONFIG_VDEV_ENC_SYSFS_PATH, &enc_sysfs_path); (void) nvlist_lookup_uint64(vdev, ZPOOL_CONFIG_WHOLE_DISK, &wholedisk); (void) nvlist_lookup_uint64(vdev, ZPOOL_CONFIG_OFFLINE, &offline); (void) nvlist_lookup_uint64(vdev, ZPOOL_CONFIG_FAULTED, &faulted); (void) nvlist_lookup_uint64(vdev, ZPOOL_CONFIG_GUID, &guid); (void) nvlist_lookup_uint64(vdev, ZPOOL_CONFIG_IS_SPARE, &is_spare); /* * Special case: * * We've seen times where a disk won't have a ZPOOL_CONFIG_PHYS_PATH * entry in their config. For example, on this force-faulted disk: * * children[0]: * type: 'disk' * id: 0 * guid: 14309659774640089719 * path: '/dev/disk/by-vdev/L28' * whole_disk: 0 * DTL: 654 * create_txg: 4 * com.delphix:vdev_zap_leaf: 1161 * faulted: 1 * aux_state: 'external' * children[1]: * type: 'disk' * id: 1 * guid: 16002508084177980912 * path: '/dev/disk/by-vdev/L29' * devid: 'dm-uuid-mpath-35000c500a61d68a3' * phys_path: 'L29' * vdev_enc_sysfs_path: '/sys/class/enclosure/0:0:1:0/SLOT 30 32' * whole_disk: 0 * DTL: 1028 * create_txg: 4 * com.delphix:vdev_zap_leaf: 131 * * If the disk's path is a /dev/disk/by-vdev/ path, then we can infer * the ZPOOL_CONFIG_PHYS_PATH from the by-vdev disk name. */ if (physpath == NULL && path != NULL) { /* If path begins with "/dev/disk/by-vdev/" ... */ if (strncmp(path, DEV_BYVDEV_PATH, strlen(DEV_BYVDEV_PATH)) == 0) { /* Set physpath to the char after "/dev/disk/by-vdev" */ physpath = &path[strlen(DEV_BYVDEV_PATH)]; } } /* * We don't want to autoreplace offlined disks. However, we do want to * replace force-faulted disks (`zpool offline -f`). Force-faulted * disks have both offline=1 and faulted=1 in the nvlist. */ if (offline && !faulted) { zed_log_msg(LOG_INFO, "%s: %s is offline, skip autoreplace", __func__, path); return; } is_mpath_wholedisk = is_mpath_whole_disk(path); zed_log_msg(LOG_INFO, "zfs_process_add: pool '%s' vdev '%s', phys '%s'" " %s blank disk, %s mpath blank disk, %s labeled, enc sysfs '%s', " "(guid %llu)", zpool_get_name(zhp), path, physpath ? physpath : "NULL", wholedisk ? "is" : "not", is_mpath_wholedisk? "is" : "not", labeled ? "is" : "not", enc_sysfs_path, (long long unsigned int)guid); /* * The VDEV guid is preferred for identification (gets passed in path) */ if (guid != 0) { (void) snprintf(fullpath, sizeof (fullpath), "%llu", (long long unsigned int)guid); } else { /* * otherwise use path sans partition suffix for whole disks */ (void) strlcpy(fullpath, path, sizeof (fullpath)); if (wholedisk) { char *spath = zfs_strip_partition(fullpath); if (!spath) { zed_log_msg(LOG_INFO, "%s: Can't alloc", __func__); return; } (void) strlcpy(fullpath, spath, sizeof (fullpath)); free(spath); } } if (is_spare) online_flag |= ZFS_ONLINE_SPARE; /* * Attempt to online the device. */ if (zpool_vdev_online(zhp, fullpath, online_flag, &newstate) == 0 && (newstate == VDEV_STATE_HEALTHY || newstate == VDEV_STATE_DEGRADED)) { zed_log_msg(LOG_INFO, " zpool_vdev_online: vdev '%s' ('%s') is " "%s", fullpath, physpath, (newstate == VDEV_STATE_HEALTHY) ? "HEALTHY" : "DEGRADED"); return; } /* * vdev_id alias rule for using scsi_debug devices (FMA automated * testing) */ if (physpath != NULL && strcmp("scsidebug", physpath) == 0) is_sd = B_TRUE; /* * If the pool doesn't have the autoreplace property set, then use * vdev online to trigger a FMA fault by posting an ereport. */ if (!zpool_get_prop_int(zhp, ZPOOL_PROP_AUTOREPLACE, NULL) || !(wholedisk || is_mpath_wholedisk) || (physpath == NULL)) { (void) zpool_vdev_online(zhp, fullpath, ZFS_ONLINE_FORCEFAULT, &newstate); zed_log_msg(LOG_INFO, "Pool's autoreplace is not enabled or " "not a blank disk for '%s' ('%s')", fullpath, physpath); return; } /* * Convert physical path into its current device node. Rawpath * needs to be /dev/disk/by-vdev for a scsi_debug device since * /dev/disk/by-path will not be present. */ (void) snprintf(rawpath, sizeof (rawpath), "%s%s", is_sd ? DEV_BYVDEV_PATH : DEV_BYPATH_PATH, physpath); - if (realpath(rawpath, devpath) == NULL && !is_mpath_wholedisk) { + if (realpath(rawpath, pathbuf) == NULL && !is_mpath_wholedisk) { zed_log_msg(LOG_INFO, " realpath: %s failed (%s)", rawpath, strerror(errno)); - (void) zpool_vdev_online(zhp, fullpath, ZFS_ONLINE_FORCEFAULT, - &newstate); + int err = zpool_vdev_online(zhp, fullpath, + ZFS_ONLINE_FORCEFAULT, &newstate); - zed_log_msg(LOG_INFO, " zpool_vdev_online: %s FORCEFAULT (%s)", - fullpath, libzfs_error_description(g_zfshdl)); + zed_log_msg(LOG_INFO, " zpool_vdev_online: %s FORCEFAULT (%s) " + "err %d, new state %d", + fullpath, libzfs_error_description(g_zfshdl), err, + err ? (int)newstate : 0); return; } /* Only autoreplace bad disks */ if ((vs->vs_state != VDEV_STATE_DEGRADED) && (vs->vs_state != VDEV_STATE_FAULTED) && (vs->vs_state != VDEV_STATE_REMOVED) && (vs->vs_state != VDEV_STATE_CANT_OPEN)) { zed_log_msg(LOG_INFO, " not autoreplacing since disk isn't in " "a bad state (currently %llu)", vs->vs_state); return; } nvlist_lookup_string(vdev, "new_devid", &new_devid); if (is_mpath_wholedisk) { /* Don't label device mapper or multipath disks. */ zed_log_msg(LOG_INFO, " it's a multipath wholedisk, don't label"); if (zpool_prepare_disk(zhp, vdev, "autoreplace", &lines, &lines_cnt) != 0) { zed_log_msg(LOG_INFO, " zpool_prepare_disk: could not " "prepare '%s' (%s)", fullpath, libzfs_error_description(g_zfshdl)); if (lines_cnt > 0) { zed_log_msg(LOG_INFO, " zfs_prepare_disk output:"); lines_to_zed_log_msg(lines, lines_cnt); } libzfs_free_str_array(lines, lines_cnt); return; } } else if (!labeled) { /* * we're auto-replacing a raw disk, so label it first */ char *leafname; /* * If this is a request to label a whole disk, then attempt to * write out the label. Before we can label the disk, we need * to map the physical string that was matched on to the under * lying device node. * * If any part of this process fails, then do a force online * to trigger a ZFS fault for the device (and any hot spare * replacement). */ - leafname = strrchr(devpath, '/') + 1; + leafname = strrchr(pathbuf, '/') + 1; /* * If this is a request to label a whole disk, then attempt to * write out the label. */ if (zpool_prepare_and_label_disk(g_zfshdl, zhp, leafname, vdev, "autoreplace", &lines, &lines_cnt) != 0) { - zed_log_msg(LOG_INFO, + zed_log_msg(LOG_WARNING, " zpool_prepare_and_label_disk: could not " "label '%s' (%s)", leafname, libzfs_error_description(g_zfshdl)); if (lines_cnt > 0) { zed_log_msg(LOG_INFO, " zfs_prepare_disk output:"); lines_to_zed_log_msg(lines, lines_cnt); } libzfs_free_str_array(lines, lines_cnt); (void) zpool_vdev_online(zhp, fullpath, ZFS_ONLINE_FORCEFAULT, &newstate); return; } /* * The disk labeling is asynchronous on Linux. Just record * this label request and return as there will be another * disk add event for the partition after the labeling is * completed. */ device = malloc(sizeof (pendingdev_t)); if (device == NULL) { perror("malloc"); exit(EXIT_FAILURE); } (void) strlcpy(device->pd_physpath, physpath, sizeof (device->pd_physpath)); list_insert_tail(&g_device_list, device); - zed_log_msg(LOG_INFO, " zpool_label_disk: async '%s' (%llu)", + zed_log_msg(LOG_NOTICE, " zpool_label_disk: async '%s' (%llu)", leafname, (u_longlong_t)guid); return; /* resumes at EC_DEV_ADD.ESC_DISK for partition */ } else /* labeled */ { boolean_t found = B_FALSE; /* * match up with request above to label the disk */ for (device = list_head(&g_device_list); device != NULL; device = list_next(&g_device_list, device)) { if (strcmp(physpath, device->pd_physpath) == 0) { list_remove(&g_device_list, device); free(device); found = B_TRUE; break; } zed_log_msg(LOG_INFO, "zpool_label_disk: %s != %s", physpath, device->pd_physpath); } if (!found) { /* unexpected partition slice encountered */ - zed_log_msg(LOG_INFO, "labeled disk %s unexpected here", - fullpath); + zed_log_msg(LOG_WARNING, "labeled disk %s was " + "unexpected here", fullpath); (void) zpool_vdev_online(zhp, fullpath, ZFS_ONLINE_FORCEFAULT, &newstate); return; } zed_log_msg(LOG_INFO, " zpool_label_disk: resume '%s' (%llu)", physpath, (u_longlong_t)guid); - (void) snprintf(devpath, sizeof (devpath), "%s%s", - DEV_BYID_PATH, new_devid); + /* + * Paths that begin with '/dev/disk/by-id/' will change and so + * they must be updated before calling zpool_vdev_attach(). + */ + if (strncmp(path, DEV_BYID_PATH, strlen(DEV_BYID_PATH)) == 0) { + (void) snprintf(pathbuf, sizeof (pathbuf), "%s%s", + DEV_BYID_PATH, new_devid); + zed_log_msg(LOG_INFO, " zpool_label_disk: path '%s' " + "replaced by '%s'", path, pathbuf); + path = pathbuf; + } } libzfs_free_str_array(lines, lines_cnt); /* * Construct the root vdev to pass to zpool_vdev_attach(). While adding * the entire vdev structure is harmless, we construct a reduced set of * path/physpath/wholedisk to keep it simple. */ if (nvlist_alloc(&nvroot, NV_UNIQUE_NAME, 0) != 0) { zed_log_msg(LOG_WARNING, "zfs_mod: nvlist_alloc out of memory"); return; } if (nvlist_alloc(&newvd, NV_UNIQUE_NAME, 0) != 0) { zed_log_msg(LOG_WARNING, "zfs_mod: nvlist_alloc out of memory"); nvlist_free(nvroot); return; } if (nvlist_add_string(newvd, ZPOOL_CONFIG_TYPE, VDEV_TYPE_DISK) != 0 || nvlist_add_string(newvd, ZPOOL_CONFIG_PATH, path) != 0 || nvlist_add_string(newvd, ZPOOL_CONFIG_DEVID, new_devid) != 0 || (physpath != NULL && nvlist_add_string(newvd, ZPOOL_CONFIG_PHYS_PATH, physpath) != 0) || (enc_sysfs_path != NULL && nvlist_add_string(newvd, ZPOOL_CONFIG_VDEV_ENC_SYSFS_PATH, enc_sysfs_path) != 0) || nvlist_add_uint64(newvd, ZPOOL_CONFIG_WHOLE_DISK, wholedisk) != 0 || nvlist_add_string(nvroot, ZPOOL_CONFIG_TYPE, VDEV_TYPE_ROOT) != 0 || nvlist_add_nvlist_array(nvroot, ZPOOL_CONFIG_CHILDREN, (const nvlist_t **)&newvd, 1) != 0) { zed_log_msg(LOG_WARNING, "zfs_mod: unable to add nvlist pairs"); nvlist_free(newvd); nvlist_free(nvroot); return; } nvlist_free(newvd); /* * Wait for udev to verify the links exist, then auto-replace * the leaf disk at same physical location. */ - if (zpool_label_disk_wait(path, 3000) != 0) { - zed_log_msg(LOG_WARNING, "zfs_mod: expected replacement " - "disk %s is missing", path); + if (zpool_label_disk_wait(path, DISK_LABEL_WAIT) != 0) { + zed_log_msg(LOG_WARNING, "zfs_mod: pool '%s', after labeling " + "replacement disk, the expected disk partition link '%s' " + "is missing after waiting %u ms", + zpool_get_name(zhp), path, DISK_LABEL_WAIT); nvlist_free(nvroot); return; } /* * Prefer sequential resilvering when supported (mirrors and dRAID), * otherwise fallback to a traditional healing resilver. */ ret = zpool_vdev_attach(zhp, fullpath, path, nvroot, B_TRUE, B_TRUE); if (ret != 0) { ret = zpool_vdev_attach(zhp, fullpath, path, nvroot, B_TRUE, B_FALSE); } - zed_log_msg(LOG_INFO, " zpool_vdev_replace: %s with %s (%s)", + zed_log_msg(LOG_WARNING, " zpool_vdev_replace: %s with %s (%s)", fullpath, path, (ret == 0) ? "no errors" : libzfs_error_description(g_zfshdl)); nvlist_free(nvroot); } /* * Utility functions to find a vdev matching given criteria. */ typedef struct dev_data { const char *dd_compare; const char *dd_prop; zfs_process_func_t dd_func; boolean_t dd_found; boolean_t dd_islabeled; uint64_t dd_pool_guid; uint64_t dd_vdev_guid; uint64_t dd_new_vdev_guid; const char *dd_new_devid; uint64_t dd_num_spares; } dev_data_t; static void zfs_iter_vdev(zpool_handle_t *zhp, nvlist_t *nvl, void *data) { dev_data_t *dp = data; const char *path = NULL; uint_t c, children; nvlist_t **child; uint64_t guid = 0; uint64_t isspare = 0; /* * First iterate over any children. */ if (nvlist_lookup_nvlist_array(nvl, ZPOOL_CONFIG_CHILDREN, &child, &children) == 0) { for (c = 0; c < children; c++) zfs_iter_vdev(zhp, child[c], data); } /* * Iterate over any spares and cache devices */ if (nvlist_lookup_nvlist_array(nvl, ZPOOL_CONFIG_SPARES, &child, &children) == 0) { for (c = 0; c < children; c++) zfs_iter_vdev(zhp, child[c], data); } if (nvlist_lookup_nvlist_array(nvl, ZPOOL_CONFIG_L2CACHE, &child, &children) == 0) { for (c = 0; c < children; c++) zfs_iter_vdev(zhp, child[c], data); } /* once a vdev was matched and processed there is nothing left to do */ if (dp->dd_found && dp->dd_num_spares == 0) return; (void) nvlist_lookup_uint64(nvl, ZPOOL_CONFIG_GUID, &guid); /* * Match by GUID if available otherwise fallback to devid or physical */ if (dp->dd_vdev_guid != 0) { if (guid != dp->dd_vdev_guid) return; zed_log_msg(LOG_INFO, " zfs_iter_vdev: matched on %llu", guid); dp->dd_found = B_TRUE; } else if (dp->dd_compare != NULL) { /* * NOTE: On Linux there is an event for partition, so unlike * illumos, substring matching is not required to accommodate * the partition suffix. An exact match will be present in * the dp->dd_compare value. * If the attached disk already contains a vdev GUID, it means * the disk is not clean. In such a scenario, the physical path * would be a match that makes the disk faulted when trying to * online it. So, we would only want to proceed if either GUID * matches with the last attached disk or the disk is in clean * state. */ if (nvlist_lookup_string(nvl, dp->dd_prop, &path) != 0 || strcmp(dp->dd_compare, path) != 0) { return; } if (dp->dd_new_vdev_guid != 0 && dp->dd_new_vdev_guid != guid) { zed_log_msg(LOG_INFO, " %s: no match (GUID:%llu" " != vdev GUID:%llu)", __func__, dp->dd_new_vdev_guid, guid); return; } zed_log_msg(LOG_INFO, " zfs_iter_vdev: matched %s on %s", dp->dd_prop, path); dp->dd_found = B_TRUE; - /* pass the new devid for use by replacing code */ + /* pass the new devid for use by auto-replacing code */ if (dp->dd_new_devid != NULL) { (void) nvlist_add_string(nvl, "new_devid", dp->dd_new_devid); } } if (dp->dd_found == B_TRUE && nvlist_lookup_uint64(nvl, ZPOOL_CONFIG_IS_SPARE, &isspare) == 0 && isspare) dp->dd_num_spares++; (dp->dd_func)(zhp, nvl, dp->dd_islabeled); } static void zfs_enable_ds(void *arg) { unavailpool_t *pool = (unavailpool_t *)arg; (void) zpool_enable_datasets(pool->uap_zhp, NULL, 0); zpool_close(pool->uap_zhp); free(pool); } static int zfs_iter_pool(zpool_handle_t *zhp, void *data) { nvlist_t *config, *nvl; dev_data_t *dp = data; uint64_t pool_guid; unavailpool_t *pool; zed_log_msg(LOG_INFO, "zfs_iter_pool: evaluating vdevs on %s (by %s)", zpool_get_name(zhp), dp->dd_vdev_guid ? "GUID" : dp->dd_prop); /* * For each vdev in this pool, look for a match to apply dd_func */ if ((config = zpool_get_config(zhp, NULL)) != NULL) { if (dp->dd_pool_guid == 0 || (nvlist_lookup_uint64(config, ZPOOL_CONFIG_POOL_GUID, &pool_guid) == 0 && pool_guid == dp->dd_pool_guid)) { (void) nvlist_lookup_nvlist(config, ZPOOL_CONFIG_VDEV_TREE, &nvl); zfs_iter_vdev(zhp, nvl, data); } } else { zed_log_msg(LOG_INFO, "%s: no config\n", __func__); } /* * if this pool was originally unavailable, * then enable its datasets asynchronously */ if (g_enumeration_done) { for (pool = list_head(&g_pool_list); pool != NULL; pool = list_next(&g_pool_list, pool)) { if (strcmp(zpool_get_name(zhp), zpool_get_name(pool->uap_zhp))) continue; if (zfs_toplevel_state(zhp) >= VDEV_STATE_DEGRADED) { list_remove(&g_pool_list, pool); (void) tpool_dispatch(g_tpool, zfs_enable_ds, pool); break; } } } zpool_close(zhp); /* cease iteration after a match */ return (dp->dd_found && dp->dd_num_spares == 0); } /* * Given a physical device location, iterate over all * (pool, vdev) pairs which correspond to that location. */ static boolean_t devphys_iter(const char *physical, const char *devid, zfs_process_func_t func, boolean_t is_slice, uint64_t new_vdev_guid) { dev_data_t data = { 0 }; data.dd_compare = physical; data.dd_func = func; data.dd_prop = ZPOOL_CONFIG_PHYS_PATH; data.dd_found = B_FALSE; data.dd_islabeled = is_slice; data.dd_new_devid = devid; /* used by auto replace code */ data.dd_new_vdev_guid = new_vdev_guid; (void) zpool_iter(g_zfshdl, zfs_iter_pool, &data); return (data.dd_found); } /* * Given a device identifier, find any vdevs with a matching by-vdev * path. Normally we shouldn't need this as the comparison would be * made earlier in the devphys_iter(). For example, if we were replacing * /dev/disk/by-vdev/L28, normally devphys_iter() would match the * ZPOOL_CONFIG_PHYS_PATH of "L28" from the old disk config to "L28" * of the new disk config. However, we've seen cases where * ZPOOL_CONFIG_PHYS_PATH was not in the config for the old disk. Here's * an example of a real 2-disk mirror pool where one disk was force * faulted: * * com.delphix:vdev_zap_top: 129 * children[0]: * type: 'disk' * id: 0 * guid: 14309659774640089719 * path: '/dev/disk/by-vdev/L28' * whole_disk: 0 * DTL: 654 * create_txg: 4 * com.delphix:vdev_zap_leaf: 1161 * faulted: 1 * aux_state: 'external' * children[1]: * type: 'disk' * id: 1 * guid: 16002508084177980912 * path: '/dev/disk/by-vdev/L29' * devid: 'dm-uuid-mpath-35000c500a61d68a3' * phys_path: 'L29' * vdev_enc_sysfs_path: '/sys/class/enclosure/0:0:1:0/SLOT 30 32' * whole_disk: 0 * DTL: 1028 * create_txg: 4 * com.delphix:vdev_zap_leaf: 131 * * So in the case above, the only thing we could compare is the path. * * We can do this because we assume by-vdev paths are authoritative as physical * paths. We could not assume this for normal paths like /dev/sda since the * physical location /dev/sda points to could change over time. */ static boolean_t by_vdev_path_iter(const char *by_vdev_path, const char *devid, zfs_process_func_t func, boolean_t is_slice) { dev_data_t data = { 0 }; data.dd_compare = by_vdev_path; data.dd_func = func; data.dd_prop = ZPOOL_CONFIG_PATH; data.dd_found = B_FALSE; data.dd_islabeled = is_slice; data.dd_new_devid = devid; if (strncmp(by_vdev_path, DEV_BYVDEV_PATH, strlen(DEV_BYVDEV_PATH)) != 0) { /* by_vdev_path doesn't start with "/dev/disk/by-vdev/" */ return (B_FALSE); } (void) zpool_iter(g_zfshdl, zfs_iter_pool, &data); return (data.dd_found); } /* * Given a device identifier, find any vdevs with a matching devid. * On Linux we can match devid directly which is always a whole disk. */ static boolean_t devid_iter(const char *devid, zfs_process_func_t func, boolean_t is_slice) { dev_data_t data = { 0 }; data.dd_compare = devid; data.dd_func = func; data.dd_prop = ZPOOL_CONFIG_DEVID; data.dd_found = B_FALSE; data.dd_islabeled = is_slice; data.dd_new_devid = devid; (void) zpool_iter(g_zfshdl, zfs_iter_pool, &data); return (data.dd_found); } /* * Given a device guid, find any vdevs with a matching guid. */ static boolean_t guid_iter(uint64_t pool_guid, uint64_t vdev_guid, const char *devid, zfs_process_func_t func, boolean_t is_slice) { dev_data_t data = { 0 }; data.dd_func = func; data.dd_found = B_FALSE; data.dd_pool_guid = pool_guid; data.dd_vdev_guid = vdev_guid; data.dd_islabeled = is_slice; data.dd_new_devid = devid; (void) zpool_iter(g_zfshdl, zfs_iter_pool, &data); return (data.dd_found); } /* * Handle a EC_DEV_ADD.ESC_DISK event. * * illumos * Expects: DEV_PHYS_PATH string in schema * Matches: vdev's ZPOOL_CONFIG_PHYS_PATH or ZPOOL_CONFIG_DEVID * * path: '/dev/dsk/c0t1d0s0' (persistent) * devid: 'id1,sd@SATA_____Hitachi_HDS72101______JP2940HZ3H74MC/a' * phys_path: '/pci@0,0/pci103c,1609@11/disk@1,0:a' * * linux * provides: DEV_PHYS_PATH and DEV_IDENTIFIER strings in schema * Matches: vdev's ZPOOL_CONFIG_PHYS_PATH or ZPOOL_CONFIG_DEVID * * path: '/dev/sdc1' (not persistent) * devid: 'ata-SAMSUNG_HD204UI_S2HGJD2Z805891-part1' * phys_path: 'pci-0000:04:00.0-sas-0x4433221106000000-lun-0' */ static int zfs_deliver_add(nvlist_t *nvl) { const char *devpath = NULL, *devid = NULL; uint64_t pool_guid = 0, vdev_guid = 0; boolean_t is_slice; /* * Expecting a devid string and an optional physical location and guid */ if (nvlist_lookup_string(nvl, DEV_IDENTIFIER, &devid) != 0) { zed_log_msg(LOG_INFO, "%s: no dev identifier\n", __func__); return (-1); } (void) nvlist_lookup_string(nvl, DEV_PHYS_PATH, &devpath); (void) nvlist_lookup_uint64(nvl, ZFS_EV_POOL_GUID, &pool_guid); (void) nvlist_lookup_uint64(nvl, ZFS_EV_VDEV_GUID, &vdev_guid); is_slice = (nvlist_lookup_boolean(nvl, DEV_IS_PART) == 0); zed_log_msg(LOG_INFO, "zfs_deliver_add: adding %s (%s) (is_slice %d)", devid, devpath ? devpath : "NULL", is_slice); /* * Iterate over all vdevs looking for a match in the following order: * 1. ZPOOL_CONFIG_DEVID (identifies the unique disk) * 2. ZPOOL_CONFIG_PHYS_PATH (identifies disk physical location). * 3. ZPOOL_CONFIG_GUID (identifies unique vdev). * 4. ZPOOL_CONFIG_PATH for /dev/disk/by-vdev devices only (since * by-vdev paths represent physical paths). */ if (devid_iter(devid, zfs_process_add, is_slice)) return (0); if (devpath != NULL && devphys_iter(devpath, devid, zfs_process_add, is_slice, vdev_guid)) return (0); if (vdev_guid != 0) (void) guid_iter(pool_guid, vdev_guid, devid, zfs_process_add, is_slice); if (devpath != NULL) { /* Can we match a /dev/disk/by-vdev/ path? */ char by_vdev_path[MAXPATHLEN]; snprintf(by_vdev_path, sizeof (by_vdev_path), "/dev/disk/by-vdev/%s", devpath); if (by_vdev_path_iter(by_vdev_path, devid, zfs_process_add, is_slice)) return (0); } return (0); } /* * Called when we receive a VDEV_CHECK event, which indicates a device could not * be opened during initial pool open, but the autoreplace property was set on * the pool. In this case, we treat it as if it were an add event. */ static int zfs_deliver_check(nvlist_t *nvl) { dev_data_t data = { 0 }; if (nvlist_lookup_uint64(nvl, ZFS_EV_POOL_GUID, &data.dd_pool_guid) != 0 || nvlist_lookup_uint64(nvl, ZFS_EV_VDEV_GUID, &data.dd_vdev_guid) != 0 || data.dd_vdev_guid == 0) return (0); zed_log_msg(LOG_INFO, "zfs_deliver_check: pool '%llu', vdev %llu", data.dd_pool_guid, data.dd_vdev_guid); data.dd_func = zfs_process_add; (void) zpool_iter(g_zfshdl, zfs_iter_pool, &data); return (0); } /* * Given a path to a vdev, lookup the vdev's physical size from its * config nvlist. * * Returns the vdev's physical size in bytes on success, 0 on error. */ static uint64_t vdev_size_from_config(zpool_handle_t *zhp, const char *vdev_path) { nvlist_t *nvl = NULL; boolean_t avail_spare, l2cache, log; vdev_stat_t *vs = NULL; uint_t c; nvl = zpool_find_vdev(zhp, vdev_path, &avail_spare, &l2cache, &log); if (!nvl) return (0); verify(nvlist_lookup_uint64_array(nvl, ZPOOL_CONFIG_VDEV_STATS, (uint64_t **)&vs, &c) == 0); if (!vs) { zed_log_msg(LOG_INFO, "%s: no nvlist for '%s'", __func__, vdev_path); return (0); } return (vs->vs_pspace); } /* * Given a path to a vdev, lookup if the vdev is a "whole disk" in the * config nvlist. "whole disk" means that ZFS was passed a whole disk * at pool creation time, which it partitioned up and has full control over. * Thus a partition with wholedisk=1 set tells us that zfs created the * partition at creation time. A partition without whole disk set would have * been created by externally (like with fdisk) and passed to ZFS. * * Returns the whole disk value (either 0 or 1). */ static uint64_t vdev_whole_disk_from_config(zpool_handle_t *zhp, const char *vdev_path) { nvlist_t *nvl = NULL; boolean_t avail_spare, l2cache, log; uint64_t wholedisk = 0; nvl = zpool_find_vdev(zhp, vdev_path, &avail_spare, &l2cache, &log); if (!nvl) return (0); (void) nvlist_lookup_uint64(nvl, ZPOOL_CONFIG_WHOLE_DISK, &wholedisk); return (wholedisk); } /* * If the device size grew more than 1% then return true. */ #define DEVICE_GREW(oldsize, newsize) \ ((newsize > oldsize) && \ ((newsize / (newsize - oldsize)) <= 100)) static int zfsdle_vdev_online(zpool_handle_t *zhp, void *data) { boolean_t avail_spare, l2cache; nvlist_t *udev_nvl = data; nvlist_t *tgt; int error; const char *tmp_devname; char devname[MAXPATHLEN] = ""; uint64_t guid; if (nvlist_lookup_uint64(udev_nvl, ZFS_EV_VDEV_GUID, &guid) == 0) { sprintf(devname, "%llu", (u_longlong_t)guid); } else if (nvlist_lookup_string(udev_nvl, DEV_PHYS_PATH, &tmp_devname) == 0) { strlcpy(devname, tmp_devname, MAXPATHLEN); zfs_append_partition(devname, MAXPATHLEN); } else { zed_log_msg(LOG_INFO, "%s: no guid or physpath", __func__); } zed_log_msg(LOG_INFO, "zfsdle_vdev_online: searching for '%s' in '%s'", devname, zpool_get_name(zhp)); if ((tgt = zpool_find_vdev_by_physpath(zhp, devname, &avail_spare, &l2cache, NULL)) != NULL) { const char *path; char fullpath[MAXPATHLEN]; uint64_t wholedisk = 0; error = nvlist_lookup_string(tgt, ZPOOL_CONFIG_PATH, &path); if (error) { zpool_close(zhp); return (0); } (void) nvlist_lookup_uint64(tgt, ZPOOL_CONFIG_WHOLE_DISK, &wholedisk); if (wholedisk) { char *tmp; path = strrchr(path, '/'); if (path != NULL) { tmp = zfs_strip_partition(path + 1); if (tmp == NULL) { zpool_close(zhp); return (0); } } else { zpool_close(zhp); return (0); } (void) strlcpy(fullpath, tmp, sizeof (fullpath)); free(tmp); /* * We need to reopen the pool associated with this * device so that the kernel can update the size of * the expanded device. When expanding there is no * need to restart the scrub from the beginning. */ boolean_t scrub_restart = B_FALSE; (void) zpool_reopen_one(zhp, &scrub_restart); } else { (void) strlcpy(fullpath, path, sizeof (fullpath)); } if (zpool_get_prop_int(zhp, ZPOOL_PROP_AUTOEXPAND, NULL)) { vdev_state_t newstate; if (zpool_get_state(zhp) != POOL_STATE_UNAVAIL) { /* * If this disk size has not changed, then * there's no need to do an autoexpand. To * check we look at the disk's size in its * config, and compare it to the disk size * that udev is reporting. */ uint64_t udev_size = 0, conf_size = 0, wholedisk = 0, udev_parent_size = 0; /* * Get the size of our disk that udev is * reporting. */ if (nvlist_lookup_uint64(udev_nvl, DEV_SIZE, &udev_size) != 0) { udev_size = 0; } /* * Get the size of our disk's parent device * from udev (where sda1's parent is sda). */ if (nvlist_lookup_uint64(udev_nvl, DEV_PARENT_SIZE, &udev_parent_size) != 0) { udev_parent_size = 0; } conf_size = vdev_size_from_config(zhp, fullpath); wholedisk = vdev_whole_disk_from_config(zhp, fullpath); /* * Only attempt an autoexpand if the vdev size * changed. There are two different cases * to consider. * * 1. wholedisk=1 * If you do a 'zpool create' on a whole disk * (like /dev/sda), then zfs will create * partitions on the disk (like /dev/sda1). In * that case, wholedisk=1 will be set in the * partition's nvlist config. So zed will need * to see if your parent device (/dev/sda) * expanded in size, and if so, then attempt * the autoexpand. * * 2. wholedisk=0 * If you do a 'zpool create' on an existing * partition, or a device that doesn't allow * partitions, then wholedisk=0, and you will * simply need to check if the device itself * expanded in size. */ if (DEVICE_GREW(conf_size, udev_size) || (wholedisk && DEVICE_GREW(conf_size, udev_parent_size))) { error = zpool_vdev_online(zhp, fullpath, 0, &newstate); zed_log_msg(LOG_INFO, "%s: autoexpanding '%s' from %llu" " to %llu bytes in pool '%s': %d", __func__, fullpath, conf_size, MAX(udev_size, udev_parent_size), zpool_get_name(zhp), error); } } } zpool_close(zhp); return (1); } zpool_close(zhp); return (0); } /* * This function handles the ESC_DEV_DLE device change event. Use the * provided vdev guid when looking up a disk or partition, when the guid * is not present assume the entire disk is owned by ZFS and append the * expected -part1 partition information then lookup by physical path. */ static int zfs_deliver_dle(nvlist_t *nvl) { const char *devname; char name[MAXPATHLEN]; uint64_t guid; if (nvlist_lookup_uint64(nvl, ZFS_EV_VDEV_GUID, &guid) == 0) { sprintf(name, "%llu", (u_longlong_t)guid); } else if (nvlist_lookup_string(nvl, DEV_PHYS_PATH, &devname) == 0) { strlcpy(name, devname, MAXPATHLEN); zfs_append_partition(name, MAXPATHLEN); } else { sprintf(name, "unknown"); zed_log_msg(LOG_INFO, "zfs_deliver_dle: no guid or physpath"); } if (zpool_iter(g_zfshdl, zfsdle_vdev_online, nvl) != 1) { zed_log_msg(LOG_INFO, "zfs_deliver_dle: device '%s' not " "found", name); return (1); } return (0); } /* * syseventd daemon module event handler * * Handles syseventd daemon zfs device related events: * * EC_DEV_ADD.ESC_DISK * EC_DEV_STATUS.ESC_DEV_DLE * EC_ZFS.ESC_ZFS_VDEV_CHECK * * Note: assumes only one thread active at a time (not thread safe) */ static int zfs_slm_deliver_event(const char *class, const char *subclass, nvlist_t *nvl) { int ret; boolean_t is_check = B_FALSE, is_dle = B_FALSE; if (strcmp(class, EC_DEV_ADD) == 0) { /* * We're mainly interested in disk additions, but we also listen * for new loop devices, to allow for simplified testing. */ if (strcmp(subclass, ESC_DISK) != 0 && strcmp(subclass, ESC_LOFI) != 0) return (0); is_check = B_FALSE; } else if (strcmp(class, EC_ZFS) == 0 && strcmp(subclass, ESC_ZFS_VDEV_CHECK) == 0) { /* * This event signifies that a device failed to open * during pool load, but the 'autoreplace' property was * set, so we should pretend it's just been added. */ is_check = B_TRUE; } else if (strcmp(class, EC_DEV_STATUS) == 0 && strcmp(subclass, ESC_DEV_DLE) == 0) { is_dle = B_TRUE; } else { return (0); } if (is_dle) ret = zfs_deliver_dle(nvl); else if (is_check) ret = zfs_deliver_check(nvl); else ret = zfs_deliver_add(nvl); return (ret); } static void * zfs_enum_pools(void *arg) { (void) arg; (void) zpool_iter(g_zfshdl, zfs_unavail_pool, (void *)&g_pool_list); /* * Linux - instead of using a thread pool, each list entry * will spawn a thread when an unavailable pool transitions * to available. zfs_slm_fini will wait for these threads. */ g_enumeration_done = B_TRUE; return (NULL); } /* * called from zed daemon at startup * * sent messages from zevents or udev monitor * * For now, each agent has its own libzfs instance */ int zfs_slm_init(void) { if ((g_zfshdl = libzfs_init()) == NULL) return (-1); /* * collect a list of unavailable pools (asynchronously, * since this can take a while) */ list_create(&g_pool_list, sizeof (struct unavailpool), offsetof(struct unavailpool, uap_node)); if (pthread_create(&g_zfs_tid, NULL, zfs_enum_pools, NULL) != 0) { list_destroy(&g_pool_list); libzfs_fini(g_zfshdl); return (-1); } pthread_setname_np(g_zfs_tid, "enum-pools"); list_create(&g_device_list, sizeof (struct pendingdev), offsetof(struct pendingdev, pd_node)); return (0); } void zfs_slm_fini(void) { unavailpool_t *pool; pendingdev_t *device; /* wait for zfs_enum_pools thread to complete */ (void) pthread_join(g_zfs_tid, NULL); /* destroy the thread pool */ if (g_tpool != NULL) { tpool_wait(g_tpool); tpool_destroy(g_tpool); } while ((pool = list_remove_head(&g_pool_list)) != NULL) { zpool_close(pool->uap_zhp); free(pool); } list_destroy(&g_pool_list); while ((device = list_remove_head(&g_device_list)) != NULL) free(device); list_destroy(&g_device_list); libzfs_fini(g_zfshdl); } void zfs_slm_event(const char *class, const char *subclass, nvlist_t *nvl) { zed_log_msg(LOG_INFO, "zfs_slm_event: %s.%s", class, subclass); (void) zfs_slm_deliver_event(class, subclass, nvl); } diff --git a/sys/contrib/openzfs/include/libzutil.h b/sys/contrib/openzfs/include/libzutil.h index 237ff976ba62..053b1ed4b52a 100644 --- a/sys/contrib/openzfs/include/libzutil.h +++ b/sys/contrib/openzfs/include/libzutil.h @@ -1,215 +1,215 @@ /* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or https://opensource.org/licenses/CDDL-1.0. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright (c) 2005, 2010, Oracle and/or its affiliates. All rights reserved. * Copyright (c) 2018 by Delphix. All rights reserved. */ #ifndef _LIBZUTIL_H #define _LIBZUTIL_H extern __attribute__((visibility("default"))) #include #include #ifdef __cplusplus extern "C" { #endif /* - * Default wait time for a device name to be created. + * Default wait time in milliseconds for a device name to be created. */ #define DISK_LABEL_WAIT (30 * 1000) /* 30 seconds */ /* * Pool Config Operations * * These are specific to the library libzfs or libzpool instance. */ typedef nvlist_t *refresh_config_func_t(void *, nvlist_t *); typedef int pool_active_func_t(void *, const char *, uint64_t, boolean_t *); typedef const struct pool_config_ops { refresh_config_func_t *pco_refresh_config; pool_active_func_t *pco_pool_active; } pool_config_ops_t; /* * An instance of pool_config_ops_t is expected in the caller's binary. */ _LIBZUTIL_H pool_config_ops_t libzfs_config_ops; _LIBZUTIL_H pool_config_ops_t libzpool_config_ops; typedef enum lpc_error { LPC_SUCCESS = 0, /* no error -- success */ LPC_BADCACHE = 2000, /* out of memory */ LPC_BADPATH, /* must be an absolute path */ LPC_NOMEM, /* out of memory */ LPC_EACCESS, /* some devices require root privileges */ LPC_UNKNOWN } lpc_error_t; typedef struct importargs { char **path; /* a list of paths to search */ int paths; /* number of paths to search */ const char *poolname; /* name of a pool to find */ uint64_t guid; /* guid of a pool to find */ const char *cachefile; /* cachefile to use for import */ boolean_t can_be_active; /* can the pool be active? */ boolean_t scan; /* prefer scanning to libblkid cache */ nvlist_t *policy; /* load policy (max txg, rewind, etc.) */ } importargs_t; typedef struct libpc_handle { int lpc_error; boolean_t lpc_printerr; boolean_t lpc_open_access_error; boolean_t lpc_desc_active; char lpc_desc[1024]; pool_config_ops_t *lpc_ops; void *lpc_lib_handle; } libpc_handle_t; _LIBZUTIL_H const char *libpc_error_description(libpc_handle_t *); _LIBZUTIL_H nvlist_t *zpool_search_import(libpc_handle_t *, importargs_t *); _LIBZUTIL_H int zpool_find_config(libpc_handle_t *, const char *, nvlist_t **, importargs_t *); _LIBZUTIL_H const char * const * zpool_default_search_paths(size_t *count); _LIBZUTIL_H int zpool_read_label(int, nvlist_t **, int *); _LIBZUTIL_H int zpool_label_disk_wait(const char *, int); struct udev_device; _LIBZUTIL_H int zfs_device_get_devid(struct udev_device *, char *, size_t); _LIBZUTIL_H int zfs_device_get_physical(struct udev_device *, char *, size_t); _LIBZUTIL_H void update_vdev_config_dev_strs(nvlist_t *); /* * Default device paths */ #define DISK_ROOT "/dev" #define UDISK_ROOT "/dev/disk" #define ZVOL_ROOT "/dev/zvol" _LIBZUTIL_H int zfs_append_partition(char *path, size_t max_len); _LIBZUTIL_H int zfs_resolve_shortname(const char *name, char *path, size_t pathlen); _LIBZUTIL_H char *zfs_strip_partition(const char *); _LIBZUTIL_H const char *zfs_strip_path(const char *); _LIBZUTIL_H int zfs_strcmp_pathname(const char *, const char *, int); _LIBZUTIL_H boolean_t zfs_dev_is_dm(const char *); _LIBZUTIL_H boolean_t zfs_dev_is_whole_disk(const char *); _LIBZUTIL_H int zfs_dev_flush(int); _LIBZUTIL_H char *zfs_get_underlying_path(const char *); _LIBZUTIL_H char *zfs_get_enclosure_sysfs_path(const char *); _LIBZUTIL_H boolean_t is_mpath_whole_disk(const char *); _LIBZUTIL_H boolean_t zfs_isnumber(const char *); /* * Formats for iostat numbers. Examples: "12K", "30ms", "4B", "2321234", "-". * * ZFS_NICENUM_1024: Print kilo, mega, tera, peta, exa.. * ZFS_NICENUM_BYTES: Print single bytes ("13B"), kilo, mega, tera... * ZFS_NICENUM_TIME: Print nanosecs, microsecs, millisecs, seconds... * ZFS_NICENUM_RAW: Print the raw number without any formatting * ZFS_NICENUM_RAWTIME: Same as RAW, but print dashes ('-') for zero. */ enum zfs_nicenum_format { ZFS_NICENUM_1024 = 0, ZFS_NICENUM_BYTES = 1, ZFS_NICENUM_TIME = 2, ZFS_NICENUM_RAW = 3, ZFS_NICENUM_RAWTIME = 4 }; /* * Convert a number to a human-readable form. */ _LIBZUTIL_H void zfs_nicebytes(uint64_t, char *, size_t); _LIBZUTIL_H void zfs_nicenum(uint64_t, char *, size_t); _LIBZUTIL_H void zfs_nicenum_format(uint64_t, char *, size_t, enum zfs_nicenum_format); _LIBZUTIL_H void zfs_nicetime(uint64_t, char *, size_t); _LIBZUTIL_H void zfs_niceraw(uint64_t, char *, size_t); #define nicenum(num, buf, size) zfs_nicenum(num, buf, size) _LIBZUTIL_H void zpool_dump_ddt(const ddt_stat_t *, const ddt_histogram_t *); _LIBZUTIL_H int zpool_history_unpack(char *, uint64_t, uint64_t *, nvlist_t ***, uint_t *); struct zfs_cmd; /* * List of colors to use */ #define ANSI_BLACK "\033[0;30m" #define ANSI_RED "\033[0;31m" #define ANSI_GREEN "\033[0;32m" #define ANSI_YELLOW "\033[0;33m" #define ANSI_BLUE "\033[0;34m" #define ANSI_BOLD_BLUE "\033[1;34m" /* light blue */ #define ANSI_MAGENTA "\033[0;35m" #define ANSI_CYAN "\033[0;36m" #define ANSI_GRAY "\033[0;37m" #define ANSI_RESET "\033[0m" #define ANSI_BOLD "\033[1m" _LIBZUTIL_H int use_color(void); _LIBZUTIL_H void color_start(const char *color); _LIBZUTIL_H void color_end(void); _LIBZUTIL_H int printf_color(const char *color, const char *format, ...); _LIBZUTIL_H const char *zfs_basename(const char *path); _LIBZUTIL_H ssize_t zfs_dirnamelen(const char *path); #ifdef __linux__ extern char **environ; _LIBZUTIL_H void zfs_setproctitle_init(int argc, char *argv[], char *envp[]); _LIBZUTIL_H void zfs_setproctitle(const char *fmt, ...); #else #define zfs_setproctitle(fmt, ...) setproctitle(fmt, ##__VA_ARGS__) #define zfs_setproctitle_init(x, y, z) ((void)0) #endif /* * These functions are used by the ZFS libraries and cmd/zpool code, but are * not exported in the ABI. */ typedef int (*pool_vdev_iter_f)(void *, nvlist_t *, void *); int for_each_vdev_cb(void *zhp, nvlist_t *nv, pool_vdev_iter_f func, void *data); int for_each_vdev_in_nvlist(nvlist_t *nvroot, pool_vdev_iter_f func, void *data); void update_vdevs_config_dev_sysfs_path(nvlist_t *config); #ifdef __cplusplus } #endif #endif /* _LIBZUTIL_H */ diff --git a/sys/contrib/openzfs/include/os/freebsd/spl/sys/taskq.h b/sys/contrib/openzfs/include/os/freebsd/spl/sys/taskq.h index 30579b391711..b23a939b3aa7 100644 --- a/sys/contrib/openzfs/include/os/freebsd/spl/sys/taskq.h +++ b/sys/contrib/openzfs/include/os/freebsd/spl/sys/taskq.h @@ -1,124 +1,124 @@ /* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or https://opensource.org/licenses/CDDL-1.0. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2009 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #ifndef _SYS_TASKQ_H #define _SYS_TASKQ_H #ifdef _KERNEL #include #include +#include #include #include -#include #ifdef __cplusplus extern "C" { #endif #define TASKQ_NAMELEN 31 typedef struct taskq { struct taskqueue *tq_queue; } taskq_t; typedef uintptr_t taskqid_t; typedef void (task_func_t)(void *); typedef struct taskq_ent { - struct task tqent_task; - struct timeout_task tqent_timeout_task; + union { + struct task tqent_task; + struct timeout_task tqent_timeout_task; + }; task_func_t *tqent_func; void *tqent_arg; - taskqid_t tqent_id; - CK_LIST_ENTRY(taskq_ent) tqent_hash; - uint8_t tqent_type; - uint8_t tqent_registered; - uint8_t tqent_cancelled; - volatile uint32_t tqent_rc; + taskqid_t tqent_id; + LIST_ENTRY(taskq_ent) tqent_hash; + uint_t tqent_type; + volatile uint_t tqent_rc; } taskq_ent_t; /* * Public flags for taskq_create(): bit range 0-15 */ #define TASKQ_PREPOPULATE 0x0001 /* Prepopulate with threads and data */ #define TASKQ_CPR_SAFE 0x0002 /* Use CPR safe protocol */ #define TASKQ_DYNAMIC 0x0004 /* Use dynamic thread scheduling */ #define TASKQ_THREADS_CPU_PCT 0x0008 /* number of threads as % of ncpu */ #define TASKQ_DC_BATCH 0x0010 /* Taskq uses SDC in batch mode */ /* * Flags for taskq_dispatch. TQ_SLEEP/TQ_NOSLEEP should be same as * KM_SLEEP/KM_NOSLEEP. */ #define TQ_SLEEP 0x00 /* Can block for memory */ #define TQ_NOSLEEP 0x01 /* cannot block for memory; may fail */ #define TQ_NOQUEUE 0x02 /* Do not enqueue if can't dispatch */ #define TQ_NOALLOC 0x04 /* cannot allocate memory; may fail */ #define TQ_FRONT 0x08 /* Put task at the front of the queue */ #define TASKQID_INVALID ((taskqid_t)0) #define taskq_init_ent(x) extern taskq_t *system_taskq; /* Global dynamic task queue for long delay */ extern taskq_t *system_delay_taskq; extern taskqid_t taskq_dispatch(taskq_t *, task_func_t, void *, uint_t); extern taskqid_t taskq_dispatch_delay(taskq_t *, task_func_t, void *, uint_t, clock_t); extern void taskq_dispatch_ent(taskq_t *, task_func_t, void *, uint_t, taskq_ent_t *); extern int taskq_empty_ent(taskq_ent_t *); taskq_t *taskq_create(const char *, int, pri_t, int, int, uint_t); taskq_t *taskq_create_instance(const char *, int, int, pri_t, int, int, uint_t); taskq_t *taskq_create_proc(const char *, int, pri_t, int, int, struct proc *, uint_t); taskq_t *taskq_create_sysdc(const char *, int, int, int, struct proc *, uint_t, uint_t); void nulltask(void *); extern void taskq_destroy(taskq_t *); extern void taskq_wait_id(taskq_t *, taskqid_t); extern void taskq_wait_outstanding(taskq_t *, taskqid_t); extern void taskq_wait(taskq_t *); extern int taskq_cancel_id(taskq_t *, taskqid_t); extern int taskq_member(taskq_t *, kthread_t *); extern taskq_t *taskq_of_curthread(void); void taskq_suspend(taskq_t *); int taskq_suspended(taskq_t *); void taskq_resume(taskq_t *); #ifdef __cplusplus } #endif #endif /* _KERNEL */ #ifdef _STANDALONE typedef int taskq_ent_t; #define taskq_init_ent(x) #endif /* _STANDALONE */ #endif /* _SYS_TASKQ_H */ diff --git a/sys/contrib/openzfs/include/sys/txg_impl.h b/sys/contrib/openzfs/include/sys/txg_impl.h index 45fde2e1f351..8ab7969b25be 100644 --- a/sys/contrib/openzfs/include/sys/txg_impl.h +++ b/sys/contrib/openzfs/include/sys/txg_impl.h @@ -1,125 +1,124 @@ /* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or https://opensource.org/licenses/CDDL-1.0. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2009 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ /* * Copyright (c) 2013, 2017 by Delphix. All rights reserved. */ #ifndef _SYS_TXG_IMPL_H #define _SYS_TXG_IMPL_H #include #include #ifdef __cplusplus extern "C" { #endif /* * The tx_cpu structure is a per-cpu structure that is used to track * the number of active transaction holds (tc_count). As transactions * are assigned into a transaction group the appropriate tc_count is * incremented to indicate that there are pending changes that have yet * to quiesce. Consumers eventually call txg_rele_to_sync() to decrement * the tc_count. A transaction group is not considered quiesced until all * tx_cpu structures have reached a tc_count of zero. * * This structure is a per-cpu structure by design. Updates to this structure * are frequent and concurrent. Having a single structure would result in * heavy lock contention so a per-cpu design was implemented. With the fanned * out mutex design, consumers only need to lock the mutex associated with * thread's cpu. * * The tx_cpu contains two locks, the tc_lock and tc_open_lock. * The tc_lock is used to protect all members of the tx_cpu structure with * the exception of the tc_open_lock. This lock should only be held for a * short period of time, typically when updating the value of tc_count. * * The tc_open_lock protects the tx_open_txg member of the tx_state structure. * This lock is used to ensure that transactions are only assigned into * the current open transaction group. In order to move the current open * transaction group to the quiesce phase, the txg_quiesce thread must * grab all tc_open_locks, increment the tx_open_txg, and drop the locks. * The tc_open_lock is held until the transaction is assigned into the * transaction group. Typically, this is a short operation but if throttling * is occurring it may be held for longer periods of time. */ struct tx_cpu { kmutex_t tc_open_lock; /* protects tx_open_txg */ kmutex_t tc_lock; /* protects the rest of this struct */ kcondvar_t tc_cv[TXG_SIZE]; uint64_t tc_count[TXG_SIZE]; /* tx hold count on each txg */ list_t tc_callbacks[TXG_SIZE]; /* commit cb list */ - char tc_pad[8]; /* pad to fill 3 cache lines */ -}; +} ____cacheline_aligned; /* * The tx_state structure maintains the state information about the different * stages of the pool's transaction groups. A per pool tx_state structure * is used to track this information. The tx_state structure also points to * an array of tx_cpu structures (described above). Although the tx_sync_lock * is used to protect the members of this structure, it is not used to * protect the tx_open_txg. Instead a special lock in the tx_cpu structure * is used. Readers of tx_open_txg must grab the per-cpu tc_open_lock. * Any thread wishing to update tx_open_txg must grab the tc_open_lock on * every cpu (see txg_quiesce()). */ typedef struct tx_state { tx_cpu_t *tx_cpu; /* protects access to tx_open_txg */ kmutex_t tx_sync_lock; /* protects the rest of this struct */ uint64_t tx_open_txg; /* currently open txg id */ uint64_t tx_quiescing_txg; /* currently quiescing txg id */ uint64_t tx_quiesced_txg; /* quiesced txg waiting for sync */ uint64_t tx_syncing_txg; /* currently syncing txg id */ uint64_t tx_synced_txg; /* last synced txg id */ hrtime_t tx_open_time; /* start time of tx_open_txg */ uint64_t tx_sync_txg_waiting; /* txg we're waiting to sync */ uint64_t tx_quiesce_txg_waiting; /* txg we're waiting to open */ kcondvar_t tx_sync_more_cv; kcondvar_t tx_sync_done_cv; kcondvar_t tx_quiesce_more_cv; kcondvar_t tx_quiesce_done_cv; kcondvar_t tx_timeout_cv; kcondvar_t tx_exit_cv; /* wait for all threads to exit */ uint8_t tx_threads; /* number of threads */ uint8_t tx_exiting; /* set when we're exiting */ kthread_t *tx_sync_thread; kthread_t *tx_quiesce_thread; taskq_t *tx_commit_cb_taskq; /* commit callback taskq */ } tx_state_t; #ifdef __cplusplus } #endif #endif /* _SYS_TXG_IMPL_H */ diff --git a/sys/contrib/openzfs/lib/libzutil/os/linux/zutil_import_os.c b/sys/contrib/openzfs/lib/libzutil/os/linux/zutil_import_os.c index 8b64369dc29f..44ed697dd490 100644 --- a/sys/contrib/openzfs/lib/libzutil/os/linux/zutil_import_os.c +++ b/sys/contrib/openzfs/lib/libzutil/os/linux/zutil_import_os.c @@ -1,899 +1,898 @@ /* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or https://opensource.org/licenses/CDDL-1.0. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2015 Nexenta Systems, Inc. All rights reserved. * Copyright (c) 2005, 2010, Oracle and/or its affiliates. All rights reserved. * Copyright (c) 2012, 2018 by Delphix. All rights reserved. * Copyright 2015 RackTop Systems. * Copyright (c) 2016, Intel Corporation. */ /* * Pool import support functions. * * Used by zpool, ztest, zdb, and zhack to locate importable configs. Since * these commands are expected to run in the global zone, we can assume * that the devices are all readable when called. * * To import a pool, we rely on reading the configuration information from the * ZFS label of each device. If we successfully read the label, then we * organize the configuration information in the following hierarchy: * * pool guid -> toplevel vdev guid -> label txg * * Duplicate entries matching this same tuple will be discarded. Once we have * examined every device, we pick the best label txg config for each toplevel * vdev. We then arrange these toplevel vdevs into a complete pool config, and * update any paths that have changed. Finally, we attempt to import the pool * using our derived config, and record the results. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "zutil_import.h" #ifdef HAVE_LIBUDEV #include #include #endif #include #define DEV_BYID_PATH "/dev/disk/by-id/" /* * Skip devices with well known prefixes: * there can be side effects when opening devices which need to be avoided. * * hpet - High Precision Event Timer * watchdog[N] - Watchdog must be closed in a special way. */ static boolean_t should_skip_dev(const char *dev) { return ((strcmp(dev, "watchdog") == 0) || (strncmp(dev, "watchdog", 8) == 0 && isdigit(dev[8])) || (strcmp(dev, "hpet") == 0)); } int zfs_dev_flush(int fd) { return (ioctl(fd, BLKFLSBUF)); } void zpool_open_func(void *arg) { rdsk_node_t *rn = arg; libpc_handle_t *hdl = rn->rn_hdl; struct stat64 statbuf; nvlist_t *config; uint64_t vdev_guid = 0; int error; int num_labels = 0; int fd; if (should_skip_dev(zfs_basename(rn->rn_name))) return; /* * Ignore failed stats. We only want regular files and block devices. * Ignore files that are too small to hold a zpool. */ if (stat64(rn->rn_name, &statbuf) != 0 || (!S_ISREG(statbuf.st_mode) && !S_ISBLK(statbuf.st_mode)) || (S_ISREG(statbuf.st_mode) && statbuf.st_size < SPA_MINDEVSIZE)) return; /* * Preferentially open using O_DIRECT to bypass the block device * cache which may be stale for multipath devices. An EINVAL errno * indicates O_DIRECT is unsupported so fallback to just O_RDONLY. */ fd = open(rn->rn_name, O_RDONLY | O_DIRECT | O_CLOEXEC); if ((fd < 0) && (errno == EINVAL)) fd = open(rn->rn_name, O_RDONLY | O_CLOEXEC); if ((fd < 0) && (errno == EACCES)) hdl->lpc_open_access_error = B_TRUE; if (fd < 0) return; error = zpool_read_label(fd, &config, &num_labels); if (error != 0) { (void) close(fd); return; } if (num_labels == 0) { (void) close(fd); nvlist_free(config); return; } /* * Check that the vdev is for the expected guid. Additional entries * are speculatively added based on the paths stored in the labels. * Entries with valid paths but incorrect guids must be removed. */ error = nvlist_lookup_uint64(config, ZPOOL_CONFIG_GUID, &vdev_guid); if (error || (rn->rn_vdev_guid && rn->rn_vdev_guid != vdev_guid)) { (void) close(fd); nvlist_free(config); return; } (void) close(fd); rn->rn_config = config; rn->rn_num_labels = num_labels; /* * Add additional entries for paths described by this label. */ if (rn->rn_labelpaths) { const char *path = NULL; const char *devid = NULL; const char *env = NULL; rdsk_node_t *slice; avl_index_t where; int timeout; int error; if (label_paths(rn->rn_hdl, rn->rn_config, &path, &devid)) return; env = getenv("ZPOOL_IMPORT_UDEV_TIMEOUT_MS"); if ((env == NULL) || sscanf(env, "%d", &timeout) != 1 || timeout < 0) { timeout = DISK_LABEL_WAIT; } /* * Allow devlinks to stabilize so all paths are available. */ zpool_label_disk_wait(rn->rn_name, timeout); if (path != NULL) { slice = zutil_alloc(hdl, sizeof (rdsk_node_t)); slice->rn_name = zutil_strdup(hdl, path); slice->rn_vdev_guid = vdev_guid; slice->rn_avl = rn->rn_avl; slice->rn_hdl = hdl; slice->rn_order = IMPORT_ORDER_PREFERRED_1; slice->rn_labelpaths = B_FALSE; pthread_mutex_lock(rn->rn_lock); if (avl_find(rn->rn_avl, slice, &where)) { pthread_mutex_unlock(rn->rn_lock); free(slice->rn_name); free(slice); } else { avl_insert(rn->rn_avl, slice, where); pthread_mutex_unlock(rn->rn_lock); zpool_open_func(slice); } } if (devid != NULL) { slice = zutil_alloc(hdl, sizeof (rdsk_node_t)); error = asprintf(&slice->rn_name, "%s%s", DEV_BYID_PATH, devid); if (error == -1) { free(slice); return; } slice->rn_vdev_guid = vdev_guid; slice->rn_avl = rn->rn_avl; slice->rn_hdl = hdl; slice->rn_order = IMPORT_ORDER_PREFERRED_2; slice->rn_labelpaths = B_FALSE; pthread_mutex_lock(rn->rn_lock); if (avl_find(rn->rn_avl, slice, &where)) { pthread_mutex_unlock(rn->rn_lock); free(slice->rn_name); free(slice); } else { avl_insert(rn->rn_avl, slice, where); pthread_mutex_unlock(rn->rn_lock); zpool_open_func(slice); } } } } static const char * const zpool_default_import_path[] = { "/dev/disk/by-vdev", /* Custom rules, use first if they exist */ "/dev/mapper", /* Use multipath devices before components */ "/dev/disk/by-partlabel", /* Single unique entry set by user */ "/dev/disk/by-partuuid", /* Generated partition uuid */ "/dev/disk/by-label", /* Custom persistent labels */ "/dev/disk/by-uuid", /* Single unique entry and persistent */ "/dev/disk/by-id", /* May be multiple entries and persistent */ "/dev/disk/by-path", /* Encodes physical location and persistent */ "/dev" /* UNSAFE device names will change */ }; const char * const * zpool_default_search_paths(size_t *count) { *count = ARRAY_SIZE(zpool_default_import_path); return (zpool_default_import_path); } /* * Given a full path to a device determine if that device appears in the * import search path. If it does return the first match and store the * index in the passed 'order' variable, otherwise return an error. */ static int zfs_path_order(const char *name, int *order) { const char *env = getenv("ZPOOL_IMPORT_PATH"); if (env) { for (int i = 0; ; ++i) { env += strspn(env, ":"); size_t dirlen = strcspn(env, ":"); if (dirlen) { if (strncmp(name, env, dirlen) == 0) { *order = i; return (0); } env += dirlen; } else break; } } else { for (int i = 0; i < ARRAY_SIZE(zpool_default_import_path); ++i) { if (strncmp(name, zpool_default_import_path[i], strlen(zpool_default_import_path[i])) == 0) { *order = i; return (0); } } } return (ENOENT); } /* * Use libblkid to quickly enumerate all known zfs devices. */ int zpool_find_import_blkid(libpc_handle_t *hdl, pthread_mutex_t *lock, avl_tree_t **slice_cache) { rdsk_node_t *slice; blkid_cache cache; blkid_dev_iterate iter; blkid_dev dev; avl_index_t where; int error; *slice_cache = NULL; error = blkid_get_cache(&cache, NULL); if (error != 0) return (error); error = blkid_probe_all_new(cache); if (error != 0) { blkid_put_cache(cache); return (error); } iter = blkid_dev_iterate_begin(cache); if (iter == NULL) { blkid_put_cache(cache); return (EINVAL); } /* Only const char *s since 2.32 */ error = blkid_dev_set_search(iter, (char *)"TYPE", (char *)"zfs_member"); if (error != 0) { blkid_dev_iterate_end(iter); blkid_put_cache(cache); return (error); } *slice_cache = zutil_alloc(hdl, sizeof (avl_tree_t)); avl_create(*slice_cache, slice_cache_compare, sizeof (rdsk_node_t), offsetof(rdsk_node_t, rn_node)); while (blkid_dev_next(iter, &dev) == 0) { slice = zutil_alloc(hdl, sizeof (rdsk_node_t)); slice->rn_name = zutil_strdup(hdl, blkid_dev_devname(dev)); slice->rn_vdev_guid = 0; slice->rn_lock = lock; slice->rn_avl = *slice_cache; slice->rn_hdl = hdl; slice->rn_labelpaths = B_TRUE; error = zfs_path_order(slice->rn_name, &slice->rn_order); if (error == 0) slice->rn_order += IMPORT_ORDER_SCAN_OFFSET; else slice->rn_order = IMPORT_ORDER_DEFAULT; pthread_mutex_lock(lock); if (avl_find(*slice_cache, slice, &where)) { free(slice->rn_name); free(slice); } else { avl_insert(*slice_cache, slice, where); } pthread_mutex_unlock(lock); } blkid_dev_iterate_end(iter); blkid_put_cache(cache); return (0); } /* * Linux persistent device strings for vdev labels * * based on libudev for consistency with libudev disk add/remove events */ typedef struct vdev_dev_strs { char vds_devid[128]; char vds_devphys[128]; } vdev_dev_strs_t; #ifdef HAVE_LIBUDEV /* * Obtain the persistent device id string (describes what) * * used by ZED vdev matching for auto-{online,expand,replace} */ int zfs_device_get_devid(struct udev_device *dev, char *bufptr, size_t buflen) { struct udev_list_entry *entry; const char *bus; char devbyid[MAXPATHLEN]; /* The bus based by-id path is preferred */ bus = udev_device_get_property_value(dev, "ID_BUS"); if (bus == NULL) { const char *dm_uuid; /* * For multipath nodes use the persistent uuid based identifier * * Example: /dev/disk/by-id/dm-uuid-mpath-35000c5006304de3f */ dm_uuid = udev_device_get_property_value(dev, "DM_UUID"); if (dm_uuid != NULL) { (void) snprintf(bufptr, buflen, "dm-uuid-%s", dm_uuid); return (0); } /* * For volumes use the persistent /dev/zvol/dataset identifier */ entry = udev_device_get_devlinks_list_entry(dev); while (entry != NULL) { const char *name; name = udev_list_entry_get_name(entry); if (strncmp(name, ZVOL_ROOT, strlen(ZVOL_ROOT)) == 0) { (void) strlcpy(bufptr, name, buflen); return (0); } entry = udev_list_entry_get_next(entry); } /* * NVME 'by-id' symlinks are similar to bus case */ struct udev_device *parent; parent = udev_device_get_parent_with_subsystem_devtype(dev, "nvme", NULL); if (parent != NULL) bus = "nvme"; /* continue with bus symlink search */ else return (ENODATA); } /* * locate the bus specific by-id link */ (void) snprintf(devbyid, sizeof (devbyid), "%s%s-", DEV_BYID_PATH, bus); entry = udev_device_get_devlinks_list_entry(dev); while (entry != NULL) { const char *name; name = udev_list_entry_get_name(entry); if (strncmp(name, devbyid, strlen(devbyid)) == 0) { name += strlen(DEV_BYID_PATH); (void) strlcpy(bufptr, name, buflen); return (0); } entry = udev_list_entry_get_next(entry); } return (ENODATA); } /* * Obtain the persistent physical location string (describes where) * * used by ZED vdev matching for auto-{online,expand,replace} */ int zfs_device_get_physical(struct udev_device *dev, char *bufptr, size_t buflen) { const char *physpath = NULL; struct udev_list_entry *entry; /* * Normal disks use ID_PATH for their physical path. */ physpath = udev_device_get_property_value(dev, "ID_PATH"); if (physpath != NULL && strlen(physpath) > 0) { (void) strlcpy(bufptr, physpath, buflen); return (0); } /* * Device mapper devices are virtual and don't have a physical * path. For them we use ID_VDEV instead, which is setup via the * /etc/vdev_id.conf file. ID_VDEV provides a persistent path * to a virtual device. If you don't have vdev_id.conf setup, * you cannot use multipath autoreplace with device mapper. */ physpath = udev_device_get_property_value(dev, "ID_VDEV"); if (physpath != NULL && strlen(physpath) > 0) { (void) strlcpy(bufptr, physpath, buflen); return (0); } /* * For ZFS volumes use the persistent /dev/zvol/dataset identifier */ entry = udev_device_get_devlinks_list_entry(dev); while (entry != NULL) { physpath = udev_list_entry_get_name(entry); if (strncmp(physpath, ZVOL_ROOT, strlen(ZVOL_ROOT)) == 0) { (void) strlcpy(bufptr, physpath, buflen); return (0); } entry = udev_list_entry_get_next(entry); } /* * For all other devices fallback to using the by-uuid name. */ entry = udev_device_get_devlinks_list_entry(dev); while (entry != NULL) { physpath = udev_list_entry_get_name(entry); if (strncmp(physpath, "/dev/disk/by-uuid", 17) == 0) { (void) strlcpy(bufptr, physpath, buflen); return (0); } entry = udev_list_entry_get_next(entry); } return (ENODATA); } /* * A disk is considered a multipath whole disk when: * DEVNAME key value has "dm-" * DM_NAME key value has "mpath" prefix * DM_UUID key exists * ID_PART_TABLE_TYPE key does not exist or is not gpt */ static boolean_t udev_mpath_whole_disk(struct udev_device *dev) { const char *devname, *type, *uuid; devname = udev_device_get_property_value(dev, "DEVNAME"); type = udev_device_get_property_value(dev, "ID_PART_TABLE_TYPE"); uuid = udev_device_get_property_value(dev, "DM_UUID"); if ((devname != NULL && strncmp(devname, "/dev/dm-", 8) == 0) && ((type == NULL) || (strcmp(type, "gpt") != 0)) && (uuid != NULL)) { return (B_TRUE); } return (B_FALSE); } static int udev_device_is_ready(struct udev_device *dev) { #ifdef HAVE_LIBUDEV_UDEV_DEVICE_GET_IS_INITIALIZED return (udev_device_get_is_initialized(dev)); #else /* wait for DEVLINKS property to be initialized */ return (udev_device_get_property_value(dev, "DEVLINKS") != NULL); #endif } #else int zfs_device_get_devid(struct udev_device *dev, char *bufptr, size_t buflen) { (void) dev, (void) bufptr, (void) buflen; return (ENODATA); } int zfs_device_get_physical(struct udev_device *dev, char *bufptr, size_t buflen) { (void) dev, (void) bufptr, (void) buflen; return (ENODATA); } #endif /* HAVE_LIBUDEV */ /* * Wait up to timeout_ms for udev to set up the device node. The device is * considered ready when libudev determines it has been initialized, all of * the device links have been verified to exist, and it has been allowed to - * settle. At this point the device the device can be accessed reliably. - * Depending on the complexity of the udev rules this process could take - * several seconds. + * settle. At this point the device can be accessed reliably. Depending on + * the complexity of the udev rules this process could take several seconds. */ int zpool_label_disk_wait(const char *path, int timeout_ms) { #ifdef HAVE_LIBUDEV struct udev *udev; struct udev_device *dev = NULL; char nodepath[MAXPATHLEN]; char *sysname = NULL; int ret = ENODEV; int settle_ms = 50; long sleep_ms = 10; hrtime_t start, settle; if ((udev = udev_new()) == NULL) return (ENXIO); start = gethrtime(); settle = 0; do { if (sysname == NULL) { if (realpath(path, nodepath) != NULL) { sysname = strrchr(nodepath, '/') + 1; } else { (void) usleep(sleep_ms * MILLISEC); continue; } } dev = udev_device_new_from_subsystem_sysname(udev, "block", sysname); if ((dev != NULL) && udev_device_is_ready(dev)) { struct udev_list_entry *links, *link = NULL; ret = 0; links = udev_device_get_devlinks_list_entry(dev); udev_list_entry_foreach(link, links) { struct stat64 statbuf; const char *name; name = udev_list_entry_get_name(link); errno = 0; if (stat64(name, &statbuf) == 0 && errno == 0) continue; settle = 0; ret = ENODEV; break; } if (ret == 0) { if (settle == 0) { settle = gethrtime(); } else if (NSEC2MSEC(gethrtime() - settle) >= settle_ms) { udev_device_unref(dev); break; } } } udev_device_unref(dev); (void) usleep(sleep_ms * MILLISEC); } while (NSEC2MSEC(gethrtime() - start) < timeout_ms); udev_unref(udev); return (ret); #else int settle_ms = 50; long sleep_ms = 10; hrtime_t start, settle; struct stat64 statbuf; start = gethrtime(); settle = 0; do { errno = 0; if ((stat64(path, &statbuf) == 0) && (errno == 0)) { if (settle == 0) settle = gethrtime(); else if (NSEC2MSEC(gethrtime() - settle) >= settle_ms) return (0); } else if (errno != ENOENT) { return (errno); } usleep(sleep_ms * MILLISEC); } while (NSEC2MSEC(gethrtime() - start) < timeout_ms); return (ENODEV); #endif /* HAVE_LIBUDEV */ } /* * Encode the persistent devices strings * used for the vdev disk label */ static int encode_device_strings(const char *path, vdev_dev_strs_t *ds, boolean_t wholedisk) { #ifdef HAVE_LIBUDEV struct udev *udev; struct udev_device *dev = NULL; char nodepath[MAXPATHLEN]; char *sysname; int ret = ENODEV; hrtime_t start; if ((udev = udev_new()) == NULL) return (ENXIO); /* resolve path to a runtime device node instance */ if (realpath(path, nodepath) == NULL) goto no_dev; sysname = strrchr(nodepath, '/') + 1; /* * Wait up to 3 seconds for udev to set up the device node context */ start = gethrtime(); do { dev = udev_device_new_from_subsystem_sysname(udev, "block", sysname); if (dev == NULL) goto no_dev; if (udev_device_is_ready(dev)) break; /* udev ready */ udev_device_unref(dev); dev = NULL; if (NSEC2MSEC(gethrtime() - start) < 10) (void) sched_yield(); /* yield/busy wait up to 10ms */ else (void) usleep(10 * MILLISEC); } while (NSEC2MSEC(gethrtime() - start) < (3 * MILLISEC)); if (dev == NULL) goto no_dev; /* * Only whole disks require extra device strings */ if (!wholedisk && !udev_mpath_whole_disk(dev)) goto no_dev; ret = zfs_device_get_devid(dev, ds->vds_devid, sizeof (ds->vds_devid)); if (ret != 0) goto no_dev_ref; /* physical location string (optional) */ if (zfs_device_get_physical(dev, ds->vds_devphys, sizeof (ds->vds_devphys)) != 0) { ds->vds_devphys[0] = '\0'; /* empty string --> not available */ } no_dev_ref: udev_device_unref(dev); no_dev: udev_unref(udev); return (ret); #else (void) path; (void) ds; (void) wholedisk; return (ENOENT); #endif } /* * Rescan the enclosure sysfs path for turning on enclosure LEDs and store it * in the nvlist * (if applicable). Like: * vdev_enc_sysfs_path: '/sys/class/enclosure/11:0:1:0/SLOT 4' */ static void update_vdev_config_dev_sysfs_path(nvlist_t *nv, const char *path) { char *upath, *spath; /* Add enclosure sysfs path (if disk is in an enclosure). */ upath = zfs_get_underlying_path(path); spath = zfs_get_enclosure_sysfs_path(upath); if (spath) { nvlist_add_string(nv, ZPOOL_CONFIG_VDEV_ENC_SYSFS_PATH, spath); } else { nvlist_remove_all(nv, ZPOOL_CONFIG_VDEV_ENC_SYSFS_PATH); } free(upath); free(spath); } /* * This will get called for each leaf vdev. */ static int sysfs_path_pool_vdev_iter_f(void *hdl_data, nvlist_t *nv, void *data) { (void) hdl_data, (void) data; const char *path = NULL; if (nvlist_lookup_string(nv, ZPOOL_CONFIG_PATH, &path) != 0) return (1); /* Rescan our enclosure sysfs path for this vdev */ update_vdev_config_dev_sysfs_path(nv, path); return (0); } /* * Given an nvlist for our pool (with vdev tree), iterate over all the * leaf vdevs and update their ZPOOL_CONFIG_VDEV_ENC_SYSFS_PATH. */ void update_vdevs_config_dev_sysfs_path(nvlist_t *config) { nvlist_t *nvroot = NULL; verify(nvlist_lookup_nvlist(config, ZPOOL_CONFIG_VDEV_TREE, &nvroot) == 0); for_each_vdev_in_nvlist(nvroot, sysfs_path_pool_vdev_iter_f, NULL); } /* * Update a leaf vdev's persistent device strings * * - only applies for a dedicated leaf vdev (aka whole disk) * - updated during pool create|add|attach|import * - used for matching device matching during auto-{online,expand,replace} * - stored in a leaf disk config label (i.e. alongside 'path' NVP) * - these strings are currently not used in kernel (i.e. for vdev_disk_open) * * single device node example: * devid: 'scsi-MG03SCA300_350000494a8cb3d67-part1' * phys_path: 'pci-0000:04:00.0-sas-0x50000394a8cb3d67-lun-0' * * multipath device node example: * devid: 'dm-uuid-mpath-35000c5006304de3f' * * We also store the enclosure sysfs path for turning on enclosure LEDs * (if applicable): * vdev_enc_sysfs_path: '/sys/class/enclosure/11:0:1:0/SLOT 4' */ void update_vdev_config_dev_strs(nvlist_t *nv) { vdev_dev_strs_t vds; const char *env, *type, *path; uint64_t wholedisk = 0; /* * For the benefit of legacy ZFS implementations, allow * for opting out of devid strings in the vdev label. * * example use: * env ZFS_VDEV_DEVID_OPT_OUT=YES zpool import dozer * * explanation: * Older OpenZFS implementations had issues when attempting to * display pool config VDEV names if a "devid" NVP value is * present in the pool's config. * * For example, a pool that originated on illumos platform would * have a devid value in the config and "zpool status" would fail * when listing the config. * * A pool can be stripped of any "devid" values on import or * prevented from adding them on zpool create|add by setting * ZFS_VDEV_DEVID_OPT_OUT. */ env = getenv("ZFS_VDEV_DEVID_OPT_OUT"); if (env && (strtoul(env, NULL, 0) > 0 || !strncasecmp(env, "YES", 3) || !strncasecmp(env, "ON", 2))) { (void) nvlist_remove_all(nv, ZPOOL_CONFIG_DEVID); (void) nvlist_remove_all(nv, ZPOOL_CONFIG_PHYS_PATH); return; } if (nvlist_lookup_string(nv, ZPOOL_CONFIG_TYPE, &type) != 0 || strcmp(type, VDEV_TYPE_DISK) != 0) { return; } if (nvlist_lookup_string(nv, ZPOOL_CONFIG_PATH, &path) != 0) return; (void) nvlist_lookup_uint64(nv, ZPOOL_CONFIG_WHOLE_DISK, &wholedisk); /* * Update device string values in the config nvlist. */ if (encode_device_strings(path, &vds, (boolean_t)wholedisk) == 0) { (void) nvlist_add_string(nv, ZPOOL_CONFIG_DEVID, vds.vds_devid); if (vds.vds_devphys[0] != '\0') { (void) nvlist_add_string(nv, ZPOOL_CONFIG_PHYS_PATH, vds.vds_devphys); } update_vdev_config_dev_sysfs_path(nv, path); } else { /* Clear out any stale entries. */ (void) nvlist_remove_all(nv, ZPOOL_CONFIG_DEVID); (void) nvlist_remove_all(nv, ZPOOL_CONFIG_PHYS_PATH); (void) nvlist_remove_all(nv, ZPOOL_CONFIG_VDEV_ENC_SYSFS_PATH); } } diff --git a/sys/contrib/openzfs/man/man4/zfs.4 b/sys/contrib/openzfs/man/man4/zfs.4 index 71a3e67ee67e..5f89f6adf1e3 100644 --- a/sys/contrib/openzfs/man/man4/zfs.4 +++ b/sys/contrib/openzfs/man/man4/zfs.4 @@ -1,2541 +1,2541 @@ .\" .\" Copyright (c) 2013 by Turbo Fredriksson . All rights reserved. .\" Copyright (c) 2019, 2021 by Delphix. All rights reserved. .\" Copyright (c) 2019 Datto Inc. .\" The contents of this file are subject to the terms of the Common Development .\" and Distribution License (the "License"). You may not use this file except .\" in compliance with the License. You can obtain a copy of the license at .\" usr/src/OPENSOLARIS.LICENSE or https://opensource.org/licenses/CDDL-1.0. .\" .\" See the License for the specific language governing permissions and .\" limitations under the License. When distributing Covered Code, include this .\" CDDL HEADER in each file and include the License file at .\" usr/src/OPENSOLARIS.LICENSE. If applicable, add the following below this .\" CDDL HEADER, with the fields enclosed by brackets "[]" replaced with your .\" own identifying information: .\" Portions Copyright [yyyy] [name of copyright owner] .\" .Dd July 21, 2023 .Dt ZFS 4 .Os . .Sh NAME .Nm zfs .Nd tuning of the ZFS kernel module . .Sh DESCRIPTION The ZFS module supports these parameters: .Bl -tag -width Ds .It Sy dbuf_cache_max_bytes Ns = Ns Sy UINT64_MAX Ns B Pq u64 Maximum size in bytes of the dbuf cache. The target size is determined by the MIN versus .No 1/2^ Ns Sy dbuf_cache_shift Pq 1/32nd of the target ARC size. The behavior of the dbuf cache and its associated settings can be observed via the .Pa /proc/spl/kstat/zfs/dbufstats kstat. . .It Sy dbuf_metadata_cache_max_bytes Ns = Ns Sy UINT64_MAX Ns B Pq u64 Maximum size in bytes of the metadata dbuf cache. The target size is determined by the MIN versus .No 1/2^ Ns Sy dbuf_metadata_cache_shift Pq 1/64th of the target ARC size. The behavior of the metadata dbuf cache and its associated settings can be observed via the .Pa /proc/spl/kstat/zfs/dbufstats kstat. . .It Sy dbuf_cache_hiwater_pct Ns = Ns Sy 10 Ns % Pq uint The percentage over .Sy dbuf_cache_max_bytes when dbufs must be evicted directly. . .It Sy dbuf_cache_lowater_pct Ns = Ns Sy 10 Ns % Pq uint The percentage below .Sy dbuf_cache_max_bytes when the evict thread stops evicting dbufs. . .It Sy dbuf_cache_shift Ns = Ns Sy 5 Pq uint Set the size of the dbuf cache .Pq Sy dbuf_cache_max_bytes to a log2 fraction of the target ARC size. . .It Sy dbuf_metadata_cache_shift Ns = Ns Sy 6 Pq uint Set the size of the dbuf metadata cache .Pq Sy dbuf_metadata_cache_max_bytes to a log2 fraction of the target ARC size. . .It Sy dbuf_mutex_cache_shift Ns = Ns Sy 0 Pq uint Set the size of the mutex array for the dbuf cache. When set to .Sy 0 the array is dynamically sized based on total system memory. . .It Sy dmu_object_alloc_chunk_shift Ns = Ns Sy 7 Po 128 Pc Pq uint dnode slots allocated in a single operation as a power of 2. The default value minimizes lock contention for the bulk operation performed. . .It Sy dmu_prefetch_max Ns = Ns Sy 134217728 Ns B Po 128 MiB Pc Pq uint Limit the amount we can prefetch with one call to this amount in bytes. This helps to limit the amount of memory that can be used by prefetching. . .It Sy ignore_hole_birth Pq int Alias for .Sy send_holes_without_birth_time . . .It Sy l2arc_feed_again Ns = Ns Sy 1 Ns | Ns 0 Pq int Turbo L2ARC warm-up. When the L2ARC is cold the fill interval will be set as fast as possible. . .It Sy l2arc_feed_min_ms Ns = Ns Sy 200 Pq u64 Min feed interval in milliseconds. Requires .Sy l2arc_feed_again Ns = Ns Ar 1 and only applicable in related situations. . .It Sy l2arc_feed_secs Ns = Ns Sy 1 Pq u64 Seconds between L2ARC writing. . .It Sy l2arc_headroom Ns = Ns Sy 2 Pq u64 How far through the ARC lists to search for L2ARC cacheable content, expressed as a multiplier of .Sy l2arc_write_max . ARC persistence across reboots can be achieved with persistent L2ARC by setting this parameter to .Sy 0 , allowing the full length of ARC lists to be searched for cacheable content. . .It Sy l2arc_headroom_boost Ns = Ns Sy 200 Ns % Pq u64 Scales .Sy l2arc_headroom by this percentage when L2ARC contents are being successfully compressed before writing. A value of .Sy 100 disables this feature. . .It Sy l2arc_exclude_special Ns = Ns Sy 0 Ns | Ns 1 Pq int Controls whether buffers present on special vdevs are eligible for caching into L2ARC. If set to 1, exclude dbufs on special vdevs from being cached to L2ARC. . .It Sy l2arc_mfuonly Ns = Ns Sy 0 Ns | Ns 1 Pq int Controls whether only MFU metadata and data are cached from ARC into L2ARC. This may be desired to avoid wasting space on L2ARC when reading/writing large amounts of data that are not expected to be accessed more than once. .Pp The default is off, meaning both MRU and MFU data and metadata are cached. When turning off this feature, some MRU buffers will still be present in ARC and eventually cached on L2ARC. .No If Sy l2arc_noprefetch Ns = Ns Sy 0 , some prefetched buffers will be cached to L2ARC, and those might later transition to MRU, in which case the .Sy l2arc_mru_asize No arcstat will not be Sy 0 . .Pp Regardless of .Sy l2arc_noprefetch , some MFU buffers might be evicted from ARC, accessed later on as prefetches and transition to MRU as prefetches. If accessed again they are counted as MRU and the .Sy l2arc_mru_asize No arcstat will not be Sy 0 . .Pp The ARC status of L2ARC buffers when they were first cached in L2ARC can be seen in the .Sy l2arc_mru_asize , Sy l2arc_mfu_asize , No and Sy l2arc_prefetch_asize arcstats when importing the pool or onlining a cache device if persistent L2ARC is enabled. .Pp The .Sy evict_l2_eligible_mru arcstat does not take into account if this option is enabled as the information provided by the .Sy evict_l2_eligible_m[rf]u arcstats can be used to decide if toggling this option is appropriate for the current workload. . .It Sy l2arc_meta_percent Ns = Ns Sy 33 Ns % Pq uint Percent of ARC size allowed for L2ARC-only headers. Since L2ARC buffers are not evicted on memory pressure, too many headers on a system with an irrationally large L2ARC can render it slow or unusable. This parameter limits L2ARC writes and rebuilds to achieve the target. . .It Sy l2arc_trim_ahead Ns = Ns Sy 0 Ns % Pq u64 Trims ahead of the current write size .Pq Sy l2arc_write_max on L2ARC devices by this percentage of write size if we have filled the device. If set to .Sy 100 we TRIM twice the space required to accommodate upcoming writes. A minimum of .Sy 64 MiB will be trimmed. It also enables TRIM of the whole L2ARC device upon creation or addition to an existing pool or if the header of the device is invalid upon importing a pool or onlining a cache device. A value of .Sy 0 disables TRIM on L2ARC altogether and is the default as it can put significant stress on the underlying storage devices. This will vary depending of how well the specific device handles these commands. . .It Sy l2arc_noprefetch Ns = Ns Sy 1 Ns | Ns 0 Pq int Do not write buffers to L2ARC if they were prefetched but not used by applications. In case there are prefetched buffers in L2ARC and this option is later set, we do not read the prefetched buffers from L2ARC. Unsetting this option is useful for caching sequential reads from the disks to L2ARC and serve those reads from L2ARC later on. This may be beneficial in case the L2ARC device is significantly faster in sequential reads than the disks of the pool. .Pp Use .Sy 1 to disable and .Sy 0 to enable caching/reading prefetches to/from L2ARC. . .It Sy l2arc_norw Ns = Ns Sy 0 Ns | Ns 1 Pq int No reads during writes. . .It Sy l2arc_write_boost Ns = Ns Sy 8388608 Ns B Po 8 MiB Pc Pq u64 Cold L2ARC devices will have .Sy l2arc_write_max increased by this amount while they remain cold. . .It Sy l2arc_write_max Ns = Ns Sy 8388608 Ns B Po 8 MiB Pc Pq u64 Max write bytes per interval. . .It Sy l2arc_rebuild_enabled Ns = Ns Sy 1 Ns | Ns 0 Pq int Rebuild the L2ARC when importing a pool (persistent L2ARC). This can be disabled if there are problems importing a pool or attaching an L2ARC device (e.g. the L2ARC device is slow in reading stored log metadata, or the metadata has become somehow fragmented/unusable). . .It Sy l2arc_rebuild_blocks_min_l2size Ns = Ns Sy 1073741824 Ns B Po 1 GiB Pc Pq u64 Mininum size of an L2ARC device required in order to write log blocks in it. The log blocks are used upon importing the pool to rebuild the persistent L2ARC. .Pp For L2ARC devices less than 1 GiB, the amount of data .Fn l2arc_evict evicts is significant compared to the amount of restored L2ARC data. In this case, do not write log blocks in L2ARC in order not to waste space. . .It Sy metaslab_aliquot Ns = Ns Sy 1048576 Ns B Po 1 MiB Pc Pq u64 Metaslab granularity, in bytes. This is roughly similar to what would be referred to as the "stripe size" in traditional RAID arrays. In normal operation, ZFS will try to write this amount of data to each disk before moving on to the next top-level vdev. . .It Sy metaslab_bias_enabled Ns = Ns Sy 1 Ns | Ns 0 Pq int Enable metaslab group biasing based on their vdevs' over- or under-utilization relative to the pool. . .It Sy metaslab_force_ganging Ns = Ns Sy 16777217 Ns B Po 16 MiB + 1 B Pc Pq u64 Make some blocks above a certain size be gang blocks. This option is used by the test suite to facilitate testing. . .It Sy metaslab_force_ganging_pct Ns = Ns Sy 3 Ns % Pq uint For blocks that could be forced to be a gang block (due to .Sy metaslab_force_ganging ) , force this many of them to be gang blocks. . .It Sy zfs_ddt_zap_default_bs Ns = Ns Sy 15 Po 32 KiB Pc Pq int Default DDT ZAP data block size as a power of 2. Note that changing this after creating a DDT on the pool will not affect existing DDTs, only newly created ones. . .It Sy zfs_ddt_zap_default_ibs Ns = Ns Sy 15 Po 32 KiB Pc Pq int Default DDT ZAP indirect block size as a power of 2. Note that changing this after creating a DDT on the pool will not affect existing DDTs, only newly created ones. . .It Sy zfs_default_bs Ns = Ns Sy 9 Po 512 B Pc Pq int Default dnode block size as a power of 2. . .It Sy zfs_default_ibs Ns = Ns Sy 17 Po 128 KiB Pc Pq int Default dnode indirect block size as a power of 2. . .It Sy zfs_history_output_max Ns = Ns Sy 1048576 Ns B Po 1 MiB Pc Pq u64 When attempting to log an output nvlist of an ioctl in the on-disk history, the output will not be stored if it is larger than this size (in bytes). This must be less than .Sy DMU_MAX_ACCESS Pq 64 MiB . This applies primarily to .Fn zfs_ioc_channel_program Pq cf. Xr zfs-program 8 . . .It Sy zfs_keep_log_spacemaps_at_export Ns = Ns Sy 0 Ns | Ns 1 Pq int Prevent log spacemaps from being destroyed during pool exports and destroys. . .It Sy zfs_metaslab_segment_weight_enabled Ns = Ns Sy 1 Ns | Ns 0 Pq int Enable/disable segment-based metaslab selection. . .It Sy zfs_metaslab_switch_threshold Ns = Ns Sy 2 Pq int When using segment-based metaslab selection, continue allocating from the active metaslab until this option's worth of buckets have been exhausted. . .It Sy metaslab_debug_load Ns = Ns Sy 0 Ns | Ns 1 Pq int Load all metaslabs during pool import. . .It Sy metaslab_debug_unload Ns = Ns Sy 0 Ns | Ns 1 Pq int Prevent metaslabs from being unloaded. . .It Sy metaslab_fragmentation_factor_enabled Ns = Ns Sy 1 Ns | Ns 0 Pq int Enable use of the fragmentation metric in computing metaslab weights. . .It Sy metaslab_df_max_search Ns = Ns Sy 16777216 Ns B Po 16 MiB Pc Pq uint Maximum distance to search forward from the last offset. Without this limit, fragmented pools can see .Em >100`000 iterations and .Fn metaslab_block_picker becomes the performance limiting factor on high-performance storage. .Pp With the default setting of .Sy 16 MiB , we typically see less than .Em 500 iterations, even with very fragmented .Sy ashift Ns = Ns Sy 9 pools. The maximum number of iterations possible is .Sy metaslab_df_max_search / 2^(ashift+1) . With the default setting of .Sy 16 MiB this is .Em 16*1024 Pq with Sy ashift Ns = Ns Sy 9 or .Em 2*1024 Pq with Sy ashift Ns = Ns Sy 12 . . .It Sy metaslab_df_use_largest_segment Ns = Ns Sy 0 Ns | Ns 1 Pq int If not searching forward (due to .Sy metaslab_df_max_search , metaslab_df_free_pct , .No or Sy metaslab_df_alloc_threshold ) , this tunable controls which segment is used. If set, we will use the largest free segment. If unset, we will use a segment of at least the requested size. . .It Sy zfs_metaslab_max_size_cache_sec Ns = Ns Sy 3600 Ns s Po 1 hour Pc Pq u64 When we unload a metaslab, we cache the size of the largest free chunk. We use that cached size to determine whether or not to load a metaslab for a given allocation. As more frees accumulate in that metaslab while it's unloaded, the cached max size becomes less and less accurate. After a number of seconds controlled by this tunable, we stop considering the cached max size and start considering only the histogram instead. . .It Sy zfs_metaslab_mem_limit Ns = Ns Sy 25 Ns % Pq uint When we are loading a new metaslab, we check the amount of memory being used to store metaslab range trees. If it is over a threshold, we attempt to unload the least recently used metaslab to prevent the system from clogging all of its memory with range trees. This tunable sets the percentage of total system memory that is the threshold. . .It Sy zfs_metaslab_try_hard_before_gang Ns = Ns Sy 0 Ns | Ns 1 Pq int .Bl -item -compact .It If unset, we will first try normal allocation. .It If that fails then we will do a gang allocation. .It If that fails then we will do a "try hard" gang allocation. .It If that fails then we will have a multi-layer gang block. .El .Pp .Bl -item -compact .It If set, we will first try normal allocation. .It If that fails then we will do a "try hard" allocation. .It If that fails we will do a gang allocation. .It If that fails we will do a "try hard" gang allocation. .It If that fails then we will have a multi-layer gang block. .El . .It Sy zfs_metaslab_find_max_tries Ns = Ns Sy 100 Pq uint When not trying hard, we only consider this number of the best metaslabs. This improves performance, especially when there are many metaslabs per vdev and the allocation can't actually be satisfied (so we would otherwise iterate all metaslabs). . .It Sy zfs_vdev_default_ms_count Ns = Ns Sy 200 Pq uint When a vdev is added, target this number of metaslabs per top-level vdev. . .It Sy zfs_vdev_default_ms_shift Ns = Ns Sy 29 Po 512 MiB Pc Pq uint Default lower limit for metaslab size. . .It Sy zfs_vdev_max_ms_shift Ns = Ns Sy 34 Po 16 GiB Pc Pq uint Default upper limit for metaslab size. . .It Sy zfs_vdev_max_auto_ashift Ns = Ns Sy 14 Pq uint Maximum ashift used when optimizing for logical \[->] physical sector size on new top-level vdevs. May be increased up to .Sy ASHIFT_MAX Po 16 Pc , but this may negatively impact pool space efficiency. . .It Sy zfs_vdev_min_auto_ashift Ns = Ns Sy ASHIFT_MIN Po 9 Pc Pq uint Minimum ashift used when creating new top-level vdevs. . .It Sy zfs_vdev_min_ms_count Ns = Ns Sy 16 Pq uint Minimum number of metaslabs to create in a top-level vdev. . .It Sy vdev_validate_skip Ns = Ns Sy 0 Ns | Ns 1 Pq int Skip label validation steps during pool import. Changing is not recommended unless you know what you're doing and are recovering a damaged label. . .It Sy zfs_vdev_ms_count_limit Ns = Ns Sy 131072 Po 128k Pc Pq uint Practical upper limit of total metaslabs per top-level vdev. . .It Sy metaslab_preload_enabled Ns = Ns Sy 1 Ns | Ns 0 Pq int Enable metaslab group preloading. . .It Sy metaslab_preload_limit Ns = Ns Sy 10 Pq uint Maximum number of metaslabs per group to preload . .It Sy metaslab_preload_pct Ns = Ns Sy 50 Pq uint Percentage of CPUs to run a metaslab preload taskq . .It Sy metaslab_lba_weighting_enabled Ns = Ns Sy 1 Ns | Ns 0 Pq int Give more weight to metaslabs with lower LBAs, assuming they have greater bandwidth, as is typically the case on a modern constant angular velocity disk drive. . .It Sy metaslab_unload_delay Ns = Ns Sy 32 Pq uint After a metaslab is used, we keep it loaded for this many TXGs, to attempt to reduce unnecessary reloading. Note that both this many TXGs and .Sy metaslab_unload_delay_ms milliseconds must pass before unloading will occur. . .It Sy metaslab_unload_delay_ms Ns = Ns Sy 600000 Ns ms Po 10 min Pc Pq uint After a metaslab is used, we keep it loaded for this many milliseconds, to attempt to reduce unnecessary reloading. Note, that both this many milliseconds and .Sy metaslab_unload_delay TXGs must pass before unloading will occur. . .It Sy reference_history Ns = Ns Sy 3 Pq uint Maximum reference holders being tracked when reference_tracking_enable is active. . .It Sy reference_tracking_enable Ns = Ns Sy 0 Ns | Ns 1 Pq int Track reference holders to .Sy refcount_t objects (debug builds only). . .It Sy send_holes_without_birth_time Ns = Ns Sy 1 Ns | Ns 0 Pq int When set, the .Sy hole_birth optimization will not be used, and all holes will always be sent during a .Nm zfs Cm send . This is useful if you suspect your datasets are affected by a bug in .Sy hole_birth . . .It Sy spa_config_path Ns = Ns Pa /etc/zfs/zpool.cache Pq charp SPA config file. . .It Sy spa_asize_inflation Ns = Ns Sy 24 Pq uint Multiplication factor used to estimate actual disk consumption from the size of data being written. The default value is a worst case estimate, but lower values may be valid for a given pool depending on its configuration. Pool administrators who understand the factors involved may wish to specify a more realistic inflation factor, particularly if they operate close to quota or capacity limits. . .It Sy spa_load_print_vdev_tree Ns = Ns Sy 0 Ns | Ns 1 Pq int Whether to print the vdev tree in the debugging message buffer during pool import. . .It Sy spa_load_verify_data Ns = Ns Sy 1 Ns | Ns 0 Pq int Whether to traverse data blocks during an "extreme rewind" .Pq Fl X import. .Pp An extreme rewind import normally performs a full traversal of all blocks in the pool for verification. If this parameter is unset, the traversal skips non-metadata blocks. It can be toggled once the import has started to stop or start the traversal of non-metadata blocks. . .It Sy spa_load_verify_metadata Ns = Ns Sy 1 Ns | Ns 0 Pq int Whether to traverse blocks during an "extreme rewind" .Pq Fl X pool import. .Pp An extreme rewind import normally performs a full traversal of all blocks in the pool for verification. If this parameter is unset, the traversal is not performed. It can be toggled once the import has started to stop or start the traversal. . .It Sy spa_load_verify_shift Ns = Ns Sy 4 Po 1/16th Pc Pq uint Sets the maximum number of bytes to consume during pool import to the log2 fraction of the target ARC size. . .It Sy spa_slop_shift Ns = Ns Sy 5 Po 1/32nd Pc Pq int Normally, we don't allow the last .Sy 3.2% Pq Sy 1/2^spa_slop_shift of space in the pool to be consumed. This ensures that we don't run the pool completely out of space, due to unaccounted changes (e.g. to the MOS). It also limits the worst-case time to allocate space. If we have less than this amount of free space, most ZPL operations (e.g. write, create) will return .Sy ENOSPC . . .It Sy spa_upgrade_errlog_limit Ns = Ns Sy 0 Pq uint Limits the number of on-disk error log entries that will be converted to the new format when enabling the .Sy head_errlog feature. The default is to convert all log entries. . .It Sy vdev_removal_max_span Ns = Ns Sy 32768 Ns B Po 32 KiB Pc Pq uint During top-level vdev removal, chunks of data are copied from the vdev which may include free space in order to trade bandwidth for IOPS. This parameter determines the maximum span of free space, in bytes, which will be included as "unnecessary" data in a chunk of copied data. .Pp The default value here was chosen to align with .Sy zfs_vdev_read_gap_limit , which is a similar concept when doing regular reads (but there's no reason it has to be the same). . .It Sy vdev_file_logical_ashift Ns = Ns Sy 9 Po 512 B Pc Pq u64 Logical ashift for file-based devices. . .It Sy vdev_file_physical_ashift Ns = Ns Sy 9 Po 512 B Pc Pq u64 Physical ashift for file-based devices. . .It Sy zap_iterate_prefetch Ns = Ns Sy 1 Ns | Ns 0 Pq int If set, when we start iterating over a ZAP object, prefetch the entire object (all leaf blocks). However, this is limited by .Sy dmu_prefetch_max . . .It Sy zap_micro_max_size Ns = Ns Sy 131072 Ns B Po 128 KiB Pc Pq int Maximum micro ZAP size. A micro ZAP is upgraded to a fat ZAP, once it grows beyond the specified size. . .It Sy zfetch_min_distance Ns = Ns Sy 4194304 Ns B Po 4 MiB Pc Pq uint Min bytes to prefetch per stream. Prefetch distance starts from the demand access size and quickly grows to this value, doubling on each hit. After that it may grow further by 1/8 per hit, but only if some prefetch since last time haven't completed in time to satisfy demand request, i.e. prefetch depth didn't cover the read latency or the pool got saturated. . .It Sy zfetch_max_distance Ns = Ns Sy 67108864 Ns B Po 64 MiB Pc Pq uint Max bytes to prefetch per stream. . .It Sy zfetch_max_idistance Ns = Ns Sy 67108864 Ns B Po 64 MiB Pc Pq uint Max bytes to prefetch indirects for per stream. . .It Sy zfetch_max_streams Ns = Ns Sy 8 Pq uint Max number of streams per zfetch (prefetch streams per file). . .It Sy zfetch_min_sec_reap Ns = Ns Sy 1 Pq uint Min time before inactive prefetch stream can be reclaimed . .It Sy zfetch_max_sec_reap Ns = Ns Sy 2 Pq uint Max time before inactive prefetch stream can be deleted . .It Sy zfs_abd_scatter_enabled Ns = Ns Sy 1 Ns | Ns 0 Pq int Enables ARC from using scatter/gather lists and forces all allocations to be linear in kernel memory. Disabling can improve performance in some code paths at the expense of fragmented kernel memory. . .It Sy zfs_abd_scatter_max_order Ns = Ns Sy MAX_ORDER\-1 Pq uint Maximum number of consecutive memory pages allocated in a single block for scatter/gather lists. .Pp The value of .Sy MAX_ORDER depends on kernel configuration. . .It Sy zfs_abd_scatter_min_size Ns = Ns Sy 1536 Ns B Po 1.5 KiB Pc Pq uint This is the minimum allocation size that will use scatter (page-based) ABDs. Smaller allocations will use linear ABDs. . .It Sy zfs_arc_dnode_limit Ns = Ns Sy 0 Ns B Pq u64 When the number of bytes consumed by dnodes in the ARC exceeds this number of bytes, try to unpin some of it in response to demand for non-metadata. This value acts as a ceiling to the amount of dnode metadata, and defaults to .Sy 0 , which indicates that a percent which is based on .Sy zfs_arc_dnode_limit_percent of the ARC meta buffers that may be used for dnodes. .It Sy zfs_arc_dnode_limit_percent Ns = Ns Sy 10 Ns % Pq u64 Percentage that can be consumed by dnodes of ARC meta buffers. .Pp See also .Sy zfs_arc_dnode_limit , which serves a similar purpose but has a higher priority if nonzero. . .It Sy zfs_arc_dnode_reduce_percent Ns = Ns Sy 10 Ns % Pq u64 Percentage of ARC dnodes to try to scan in response to demand for non-metadata when the number of bytes consumed by dnodes exceeds .Sy zfs_arc_dnode_limit . . .It Sy zfs_arc_average_blocksize Ns = Ns Sy 8192 Ns B Po 8 KiB Pc Pq uint The ARC's buffer hash table is sized based on the assumption of an average block size of this value. This works out to roughly 1 MiB of hash table per 1 GiB of physical memory with 8-byte pointers. For configurations with a known larger average block size, this value can be increased to reduce the memory footprint. . .It Sy zfs_arc_eviction_pct Ns = Ns Sy 200 Ns % Pq uint When .Fn arc_is_overflowing , .Fn arc_get_data_impl waits for this percent of the requested amount of data to be evicted. For example, by default, for every .Em 2 KiB that's evicted, .Em 1 KiB of it may be "reused" by a new allocation. Since this is above .Sy 100 Ns % , it ensures that progress is made towards getting .Sy arc_size No under Sy arc_c . Since this is finite, it ensures that allocations can still happen, even during the potentially long time that .Sy arc_size No is more than Sy arc_c . . .It Sy zfs_arc_evict_batch_limit Ns = Ns Sy 10 Pq uint Number ARC headers to evict per sub-list before proceeding to another sub-list. This batch-style operation prevents entire sub-lists from being evicted at once but comes at a cost of additional unlocking and locking. . .It Sy zfs_arc_grow_retry Ns = Ns Sy 0 Ns s Pq uint If set to a non zero value, it will replace the .Sy arc_grow_retry value with this value. The .Sy arc_grow_retry .No value Pq default Sy 5 Ns s is the number of seconds the ARC will wait before trying to resume growth after a memory pressure event. . .It Sy zfs_arc_lotsfree_percent Ns = Ns Sy 10 Ns % Pq int Throttle I/O when free system memory drops below this percentage of total system memory. Setting this value to .Sy 0 will disable the throttle. . .It Sy zfs_arc_max Ns = Ns Sy 0 Ns B Pq u64 Max size of ARC in bytes. If .Sy 0 , then the max size of ARC is determined by the amount of system memory installed. Under Linux, half of system memory will be used as the limit. Under .Fx , the larger of .Sy all_system_memory No \- Sy 1 GiB and .Sy 5/8 No \(mu Sy all_system_memory will be used as the limit. This value must be at least .Sy 67108864 Ns B Pq 64 MiB . .Pp This value can be changed dynamically, with some caveats. It cannot be set back to .Sy 0 while running, and reducing it below the current ARC size will not cause the ARC to shrink without memory pressure to induce shrinking. . .It Sy zfs_arc_meta_balance Ns = Ns Sy 500 Pq uint Balance between metadata and data on ghost hits. Values above 100 increase metadata caching by proportionally reducing effect of ghost data hits on target data/metadata rate. . .It Sy zfs_arc_min Ns = Ns Sy 0 Ns B Pq u64 Min size of ARC in bytes. .No If set to Sy 0 , arc_c_min will default to consuming the larger of .Sy 32 MiB and .Sy all_system_memory No / Sy 32 . . .It Sy zfs_arc_min_prefetch_ms Ns = Ns Sy 0 Ns ms Ns Po Ns ≡ Ns 1s Pc Pq uint Minimum time prefetched blocks are locked in the ARC. . .It Sy zfs_arc_min_prescient_prefetch_ms Ns = Ns Sy 0 Ns ms Ns Po Ns ≡ Ns 6s Pc Pq uint Minimum time "prescient prefetched" blocks are locked in the ARC. These blocks are meant to be prefetched fairly aggressively ahead of the code that may use them. . .It Sy zfs_arc_prune_task_threads Ns = Ns Sy 1 Pq int Number of arc_prune threads. .Fx does not need more than one. Linux may theoretically use one per mount point up to number of CPUs, but that was not proven to be useful. . .It Sy zfs_max_missing_tvds Ns = Ns Sy 0 Pq int Number of missing top-level vdevs which will be allowed during pool import (only in read-only mode). . .It Sy zfs_max_nvlist_src_size Ns = Sy 0 Pq u64 Maximum size in bytes allowed to be passed as .Sy zc_nvlist_src_size for ioctls on .Pa /dev/zfs . This prevents a user from causing the kernel to allocate an excessive amount of memory. When the limit is exceeded, the ioctl fails with .Sy EINVAL and a description of the error is sent to the .Pa zfs-dbgmsg log. This parameter should not need to be touched under normal circumstances. If .Sy 0 , equivalent to a quarter of the user-wired memory limit under .Fx and to .Sy 134217728 Ns B Pq 128 MiB under Linux. . .It Sy zfs_multilist_num_sublists Ns = Ns Sy 0 Pq uint To allow more fine-grained locking, each ARC state contains a series of lists for both data and metadata objects. Locking is performed at the level of these "sub-lists". This parameters controls the number of sub-lists per ARC state, and also applies to other uses of the multilist data structure. .Pp If .Sy 0 , equivalent to the greater of the number of online CPUs and .Sy 4 . . .It Sy zfs_arc_overflow_shift Ns = Ns Sy 8 Pq int The ARC size is considered to be overflowing if it exceeds the current ARC target size .Pq Sy arc_c by thresholds determined by this parameter. Exceeding by .Sy ( arc_c No >> Sy zfs_arc_overflow_shift ) No / Sy 2 starts ARC reclamation process. If that appears insufficient, exceeding by .Sy ( arc_c No >> Sy zfs_arc_overflow_shift ) No \(mu Sy 1.5 blocks new buffer allocation until the reclaim thread catches up. Started reclamation process continues till ARC size returns below the target size. .Pp The default value of .Sy 8 causes the ARC to start reclamation if it exceeds the target size by .Em 0.2% of the target size, and block allocations by .Em 0.6% . . .It Sy zfs_arc_shrink_shift Ns = Ns Sy 0 Pq uint If nonzero, this will update .Sy arc_shrink_shift Pq default Sy 7 with the new value. . .It Sy zfs_arc_pc_percent Ns = Ns Sy 0 Ns % Po off Pc Pq uint Percent of pagecache to reclaim ARC to. .Pp This tunable allows the ZFS ARC to play more nicely with the kernel's LRU pagecache. It can guarantee that the ARC size won't collapse under scanning pressure on the pagecache, yet still allows the ARC to be reclaimed down to .Sy zfs_arc_min if necessary. This value is specified as percent of pagecache size (as measured by .Sy NR_FILE_PAGES ) , where that percent may exceed .Sy 100 . This only operates during memory pressure/reclaim. . .It Sy zfs_arc_shrinker_limit Ns = Ns Sy 10000 Pq int This is a limit on how many pages the ARC shrinker makes available for eviction in response to one page allocation attempt. Note that in practice, the kernel's shrinker can ask us to evict up to about four times this for one allocation attempt. .Pp The default limit of .Sy 10000 Pq in practice, Em 160 MiB No per allocation attempt with 4 KiB pages limits the amount of time spent attempting to reclaim ARC memory to less than 100 ms per allocation attempt, even with a small average compressed block size of ~8 KiB. .Pp The parameter can be set to 0 (zero) to disable the limit, and only applies on Linux. . .It Sy zfs_arc_sys_free Ns = Ns Sy 0 Ns B Pq u64 The target number of bytes the ARC should leave as free memory on the system. If zero, equivalent to the bigger of .Sy 512 KiB No and Sy all_system_memory/64 . . .It Sy zfs_autoimport_disable Ns = Ns Sy 1 Ns | Ns 0 Pq int Disable pool import at module load by ignoring the cache file .Pq Sy spa_config_path . . .It Sy zfs_checksum_events_per_second Ns = Ns Sy 20 Ns /s Pq uint Rate limit checksum events to this many per second. Note that this should not be set below the ZED thresholds (currently 10 checksums over 10 seconds) or else the daemon may not trigger any action. . .It Sy zfs_commit_timeout_pct Ns = Ns Sy 5 Ns % Pq uint This controls the amount of time that a ZIL block (lwb) will remain "open" when it isn't "full", and it has a thread waiting for it to be committed to stable storage. The timeout is scaled based on a percentage of the last lwb latency to avoid significantly impacting the latency of each individual transaction record (itx). . .It Sy zfs_condense_indirect_commit_entry_delay_ms Ns = Ns Sy 0 Ns ms Pq int Vdev indirection layer (used for device removal) sleeps for this many milliseconds during mapping generation. Intended for use with the test suite to throttle vdev removal speed. . .It Sy zfs_condense_indirect_obsolete_pct Ns = Ns Sy 25 Ns % Pq uint Minimum percent of obsolete bytes in vdev mapping required to attempt to condense .Pq see Sy zfs_condense_indirect_vdevs_enable . Intended for use with the test suite to facilitate triggering condensing as needed. . .It Sy zfs_condense_indirect_vdevs_enable Ns = Ns Sy 1 Ns | Ns 0 Pq int Enable condensing indirect vdev mappings. When set, attempt to condense indirect vdev mappings if the mapping uses more than .Sy zfs_condense_min_mapping_bytes bytes of memory and if the obsolete space map object uses more than .Sy zfs_condense_max_obsolete_bytes bytes on-disk. The condensing process is an attempt to save memory by removing obsolete mappings. . .It Sy zfs_condense_max_obsolete_bytes Ns = Ns Sy 1073741824 Ns B Po 1 GiB Pc Pq u64 Only attempt to condense indirect vdev mappings if the on-disk size of the obsolete space map object is greater than this number of bytes .Pq see Sy zfs_condense_indirect_vdevs_enable . . .It Sy zfs_condense_min_mapping_bytes Ns = Ns Sy 131072 Ns B Po 128 KiB Pc Pq u64 Minimum size vdev mapping to attempt to condense .Pq see Sy zfs_condense_indirect_vdevs_enable . . .It Sy zfs_dbgmsg_enable Ns = Ns Sy 1 Ns | Ns 0 Pq int Internally ZFS keeps a small log to facilitate debugging. The log is enabled by default, and can be disabled by unsetting this option. The contents of the log can be accessed by reading .Pa /proc/spl/kstat/zfs/dbgmsg . Writing .Sy 0 to the file clears the log. .Pp This setting does not influence debug prints due to .Sy zfs_flags . . .It Sy zfs_dbgmsg_maxsize Ns = Ns Sy 4194304 Ns B Po 4 MiB Pc Pq uint Maximum size of the internal ZFS debug log. . .It Sy zfs_dbuf_state_index Ns = Ns Sy 0 Pq int Historically used for controlling what reporting was available under .Pa /proc/spl/kstat/zfs . No effect. . .It Sy zfs_deadman_enabled Ns = Ns Sy 1 Ns | Ns 0 Pq int When a pool sync operation takes longer than .Sy zfs_deadman_synctime_ms , or when an individual I/O operation takes longer than .Sy zfs_deadman_ziotime_ms , then the operation is considered to be "hung". If .Sy zfs_deadman_enabled is set, then the deadman behavior is invoked as described by .Sy zfs_deadman_failmode . By default, the deadman is enabled and set to .Sy wait which results in "hung" I/O operations only being logged. The deadman is automatically disabled when a pool gets suspended. . .It Sy zfs_deadman_failmode Ns = Ns Sy wait Pq charp Controls the failure behavior when the deadman detects a "hung" I/O operation. Valid values are: .Bl -tag -compact -offset 4n -width "continue" .It Sy wait Wait for a "hung" operation to complete. For each "hung" operation a "deadman" event will be posted describing that operation. .It Sy continue Attempt to recover from a "hung" operation by re-dispatching it to the I/O pipeline if possible. .It Sy panic Panic the system. This can be used to facilitate automatic fail-over to a properly configured fail-over partner. .El . .It Sy zfs_deadman_checktime_ms Ns = Ns Sy 60000 Ns ms Po 1 min Pc Pq u64 Check time in milliseconds. This defines the frequency at which we check for hung I/O requests and potentially invoke the .Sy zfs_deadman_failmode behavior. . .It Sy zfs_deadman_synctime_ms Ns = Ns Sy 600000 Ns ms Po 10 min Pc Pq u64 Interval in milliseconds after which the deadman is triggered and also the interval after which a pool sync operation is considered to be "hung". Once this limit is exceeded the deadman will be invoked every .Sy zfs_deadman_checktime_ms milliseconds until the pool sync completes. . .It Sy zfs_deadman_ziotime_ms Ns = Ns Sy 300000 Ns ms Po 5 min Pc Pq u64 Interval in milliseconds after which the deadman is triggered and an individual I/O operation is considered to be "hung". As long as the operation remains "hung", the deadman will be invoked every .Sy zfs_deadman_checktime_ms milliseconds until the operation completes. . .It Sy zfs_dedup_prefetch Ns = Ns Sy 0 Ns | Ns 1 Pq int Enable prefetching dedup-ed blocks which are going to be freed. . .It Sy zfs_delay_min_dirty_percent Ns = Ns Sy 60 Ns % Pq uint Start to delay each transaction once there is this amount of dirty data, expressed as a percentage of .Sy zfs_dirty_data_max . This value should be at least .Sy zfs_vdev_async_write_active_max_dirty_percent . .No See Sx ZFS TRANSACTION DELAY . . .It Sy zfs_delay_scale Ns = Ns Sy 500000 Pq int This controls how quickly the transaction delay approaches infinity. Larger values cause longer delays for a given amount of dirty data. .Pp For the smoothest delay, this value should be about 1 billion divided by the maximum number of operations per second. This will smoothly handle between ten times and a tenth of this number. .No See Sx ZFS TRANSACTION DELAY . .Pp .Sy zfs_delay_scale No \(mu Sy zfs_dirty_data_max Em must No be smaller than Sy 2^64 . . .It Sy zfs_disable_ivset_guid_check Ns = Ns Sy 0 Ns | Ns 1 Pq int Disables requirement for IVset GUIDs to be present and match when doing a raw receive of encrypted datasets. Intended for users whose pools were created with OpenZFS pre-release versions and now have compatibility issues. . .It Sy zfs_key_max_salt_uses Ns = Ns Sy 400000000 Po 4*10^8 Pc Pq ulong Maximum number of uses of a single salt value before generating a new one for encrypted datasets. The default value is also the maximum. . .It Sy zfs_object_mutex_size Ns = Ns Sy 64 Pq uint Size of the znode hashtable used for holds. .Pp Due to the need to hold locks on objects that may not exist yet, kernel mutexes are not created per-object and instead a hashtable is used where collisions will result in objects waiting when there is not actually contention on the same object. . .It Sy zfs_slow_io_events_per_second Ns = Ns Sy 20 Ns /s Pq int Rate limit delay and deadman zevents (which report slow I/O operations) to this many per second. . .It Sy zfs_unflushed_max_mem_amt Ns = Ns Sy 1073741824 Ns B Po 1 GiB Pc Pq u64 Upper-bound limit for unflushed metadata changes to be held by the log spacemap in memory, in bytes. . .It Sy zfs_unflushed_max_mem_ppm Ns = Ns Sy 1000 Ns ppm Po 0.1% Pc Pq u64 Part of overall system memory that ZFS allows to be used for unflushed metadata changes by the log spacemap, in millionths. . .It Sy zfs_unflushed_log_block_max Ns = Ns Sy 131072 Po 128k Pc Pq u64 Describes the maximum number of log spacemap blocks allowed for each pool. The default value means that the space in all the log spacemaps can add up to no more than .Sy 131072 blocks (which means .Em 16 GiB of logical space before compression and ditto blocks, assuming that blocksize is .Em 128 KiB ) . .Pp This tunable is important because it involves a trade-off between import time after an unclean export and the frequency of flushing metaslabs. The higher this number is, the more log blocks we allow when the pool is active which means that we flush metaslabs less often and thus decrease the number of I/O operations for spacemap updates per TXG. At the same time though, that means that in the event of an unclean export, there will be more log spacemap blocks for us to read, inducing overhead in the import time of the pool. The lower the number, the amount of flushing increases, destroying log blocks quicker as they become obsolete faster, which leaves less blocks to be read during import time after a crash. .Pp Each log spacemap block existing during pool import leads to approximately one extra logical I/O issued. This is the reason why this tunable is exposed in terms of blocks rather than space used. . .It Sy zfs_unflushed_log_block_min Ns = Ns Sy 1000 Pq u64 If the number of metaslabs is small and our incoming rate is high, we could get into a situation that we are flushing all our metaslabs every TXG. Thus we always allow at least this many log blocks. . .It Sy zfs_unflushed_log_block_pct Ns = Ns Sy 400 Ns % Pq u64 Tunable used to determine the number of blocks that can be used for the spacemap log, expressed as a percentage of the total number of unflushed metaslabs in the pool. . .It Sy zfs_unflushed_log_txg_max Ns = Ns Sy 1000 Pq u64 Tunable limiting maximum time in TXGs any metaslab may remain unflushed. It effectively limits maximum number of unflushed per-TXG spacemap logs that need to be read after unclean pool export. . .It Sy zfs_unlink_suspend_progress Ns = Ns Sy 0 Ns | Ns 1 Pq uint When enabled, files will not be asynchronously removed from the list of pending unlinks and the space they consume will be leaked. Once this option has been disabled and the dataset is remounted, the pending unlinks will be processed and the freed space returned to the pool. This option is used by the test suite. . .It Sy zfs_delete_blocks Ns = Ns Sy 20480 Pq ulong This is the used to define a large file for the purposes of deletion. Files containing more than .Sy zfs_delete_blocks will be deleted asynchronously, while smaller files are deleted synchronously. Decreasing this value will reduce the time spent in an .Xr unlink 2 system call, at the expense of a longer delay before the freed space is available. This only applies on Linux. . .It Sy zfs_dirty_data_max Ns = Pq int Determines the dirty space limit in bytes. Once this limit is exceeded, new writes are halted until space frees up. This parameter takes precedence over .Sy zfs_dirty_data_max_percent . .No See Sx ZFS TRANSACTION DELAY . .Pp Defaults to .Sy physical_ram/10 , capped at .Sy zfs_dirty_data_max_max . . .It Sy zfs_dirty_data_max_max Ns = Pq int Maximum allowable value of .Sy zfs_dirty_data_max , expressed in bytes. This limit is only enforced at module load time, and will be ignored if .Sy zfs_dirty_data_max is later changed. This parameter takes precedence over .Sy zfs_dirty_data_max_max_percent . .No See Sx ZFS TRANSACTION DELAY . .Pp Defaults to .Sy min(physical_ram/4, 4GiB) , or .Sy min(physical_ram/4, 1GiB) for 32-bit systems. . .It Sy zfs_dirty_data_max_max_percent Ns = Ns Sy 25 Ns % Pq uint Maximum allowable value of .Sy zfs_dirty_data_max , expressed as a percentage of physical RAM. This limit is only enforced at module load time, and will be ignored if .Sy zfs_dirty_data_max is later changed. The parameter .Sy zfs_dirty_data_max_max takes precedence over this one. .No See Sx ZFS TRANSACTION DELAY . . .It Sy zfs_dirty_data_max_percent Ns = Ns Sy 10 Ns % Pq uint Determines the dirty space limit, expressed as a percentage of all memory. Once this limit is exceeded, new writes are halted until space frees up. The parameter .Sy zfs_dirty_data_max takes precedence over this one. .No See Sx ZFS TRANSACTION DELAY . .Pp Subject to .Sy zfs_dirty_data_max_max . . .It Sy zfs_dirty_data_sync_percent Ns = Ns Sy 20 Ns % Pq uint Start syncing out a transaction group if there's at least this much dirty data .Pq as a percentage of Sy zfs_dirty_data_max . This should be less than .Sy zfs_vdev_async_write_active_min_dirty_percent . . .It Sy zfs_wrlog_data_max Ns = Pq int The upper limit of write-transaction zil log data size in bytes. Write operations are throttled when approaching the limit until log data is cleared out after transaction group sync. Because of some overhead, it should be set at least 2 times the size of .Sy zfs_dirty_data_max .No to prevent harming normal write throughput . It also should be smaller than the size of the slog device if slog is present. .Pp Defaults to .Sy zfs_dirty_data_max*2 . .It Sy zfs_fallocate_reserve_percent Ns = Ns Sy 110 Ns % Pq uint Since ZFS is a copy-on-write filesystem with snapshots, blocks cannot be preallocated for a file in order to guarantee that later writes will not run out of space. Instead, .Xr fallocate 2 space preallocation only checks that sufficient space is currently available in the pool or the user's project quota allocation, and then creates a sparse file of the requested size. The requested space is multiplied by .Sy zfs_fallocate_reserve_percent to allow additional space for indirect blocks and other internal metadata. Setting this to .Sy 0 disables support for .Xr fallocate 2 and causes it to return .Sy EOPNOTSUPP . . .It Sy zfs_fletcher_4_impl Ns = Ns Sy fastest Pq string Select a fletcher 4 implementation. .Pp Supported selectors are: .Sy fastest , scalar , sse2 , ssse3 , avx2 , avx512f , avx512bw , .No and Sy aarch64_neon . All except .Sy fastest No and Sy scalar require instruction set extensions to be available, and will only appear if ZFS detects that they are present at runtime. If multiple implementations of fletcher 4 are available, the .Sy fastest will be chosen using a micro benchmark. Selecting .Sy scalar results in the original CPU-based calculation being used. Selecting any option other than .Sy fastest No or Sy scalar results in vector instructions from the respective CPU instruction set being used. . .It Sy zfs_blake3_impl Ns = Ns Sy fastest Pq string Select a BLAKE3 implementation. .Pp Supported selectors are: .Sy cycle , fastest , generic , sse2 , sse41 , avx2 , avx512 . All except .Sy cycle , fastest No and Sy generic require instruction set extensions to be available, and will only appear if ZFS detects that they are present at runtime. If multiple implementations of BLAKE3 are available, the .Sy fastest will be chosen using a micro benchmark. You can see the benchmark results by reading this kstat file: .Pa /proc/spl/kstat/zfs/chksum_bench . . .It Sy zfs_free_bpobj_enabled Ns = Ns Sy 1 Ns | Ns 0 Pq int Enable/disable the processing of the free_bpobj object. . .It Sy zfs_async_block_max_blocks Ns = Ns Sy UINT64_MAX Po unlimited Pc Pq u64 Maximum number of blocks freed in a single TXG. . .It Sy zfs_max_async_dedup_frees Ns = Ns Sy 100000 Po 10^5 Pc Pq u64 Maximum number of dedup blocks freed in a single TXG. . .It Sy zfs_vdev_async_read_max_active Ns = Ns Sy 3 Pq uint Maximum asynchronous read I/O operations active to each device. .No See Sx ZFS I/O SCHEDULER . . .It Sy zfs_vdev_async_read_min_active Ns = Ns Sy 1 Pq uint Minimum asynchronous read I/O operation active to each device. .No See Sx ZFS I/O SCHEDULER . . .It Sy zfs_vdev_async_write_active_max_dirty_percent Ns = Ns Sy 60 Ns % Pq uint When the pool has more than this much dirty data, use .Sy zfs_vdev_async_write_max_active to limit active async writes. If the dirty data is between the minimum and maximum, the active I/O limit is linearly interpolated. .No See Sx ZFS I/O SCHEDULER . . .It Sy zfs_vdev_async_write_active_min_dirty_percent Ns = Ns Sy 30 Ns % Pq uint When the pool has less than this much dirty data, use .Sy zfs_vdev_async_write_min_active to limit active async writes. If the dirty data is between the minimum and maximum, the active I/O limit is linearly interpolated. .No See Sx ZFS I/O SCHEDULER . . .It Sy zfs_vdev_async_write_max_active Ns = Ns Sy 10 Pq uint Maximum asynchronous write I/O operations active to each device. .No See Sx ZFS I/O SCHEDULER . . .It Sy zfs_vdev_async_write_min_active Ns = Ns Sy 2 Pq uint Minimum asynchronous write I/O operations active to each device. .No See Sx ZFS I/O SCHEDULER . .Pp Lower values are associated with better latency on rotational media but poorer resilver performance. The default value of .Sy 2 was chosen as a compromise. A value of .Sy 3 has been shown to improve resilver performance further at a cost of further increasing latency. . .It Sy zfs_vdev_initializing_max_active Ns = Ns Sy 1 Pq uint Maximum initializing I/O operations active to each device. .No See Sx ZFS I/O SCHEDULER . . .It Sy zfs_vdev_initializing_min_active Ns = Ns Sy 1 Pq uint Minimum initializing I/O operations active to each device. .No See Sx ZFS I/O SCHEDULER . . .It Sy zfs_vdev_max_active Ns = Ns Sy 1000 Pq uint The maximum number of I/O operations active to each device. Ideally, this will be at least the sum of each queue's .Sy max_active . .No See Sx ZFS I/O SCHEDULER . . .It Sy zfs_vdev_open_timeout_ms Ns = Ns Sy 1000 Pq uint Timeout value to wait before determining a device is missing during import. This is helpful for transient missing paths due to links being briefly removed and recreated in response to udev events. . .It Sy zfs_vdev_rebuild_max_active Ns = Ns Sy 3 Pq uint Maximum sequential resilver I/O operations active to each device. .No See Sx ZFS I/O SCHEDULER . . .It Sy zfs_vdev_rebuild_min_active Ns = Ns Sy 1 Pq uint Minimum sequential resilver I/O operations active to each device. .No See Sx ZFS I/O SCHEDULER . . .It Sy zfs_vdev_removal_max_active Ns = Ns Sy 2 Pq uint Maximum removal I/O operations active to each device. .No See Sx ZFS I/O SCHEDULER . . .It Sy zfs_vdev_removal_min_active Ns = Ns Sy 1 Pq uint Minimum removal I/O operations active to each device. .No See Sx ZFS I/O SCHEDULER . . .It Sy zfs_vdev_scrub_max_active Ns = Ns Sy 2 Pq uint Maximum scrub I/O operations active to each device. .No See Sx ZFS I/O SCHEDULER . . .It Sy zfs_vdev_scrub_min_active Ns = Ns Sy 1 Pq uint Minimum scrub I/O operations active to each device. .No See Sx ZFS I/O SCHEDULER . . .It Sy zfs_vdev_sync_read_max_active Ns = Ns Sy 10 Pq uint Maximum synchronous read I/O operations active to each device. .No See Sx ZFS I/O SCHEDULER . . .It Sy zfs_vdev_sync_read_min_active Ns = Ns Sy 10 Pq uint Minimum synchronous read I/O operations active to each device. .No See Sx ZFS I/O SCHEDULER . . .It Sy zfs_vdev_sync_write_max_active Ns = Ns Sy 10 Pq uint Maximum synchronous write I/O operations active to each device. .No See Sx ZFS I/O SCHEDULER . . .It Sy zfs_vdev_sync_write_min_active Ns = Ns Sy 10 Pq uint Minimum synchronous write I/O operations active to each device. .No See Sx ZFS I/O SCHEDULER . . .It Sy zfs_vdev_trim_max_active Ns = Ns Sy 2 Pq uint Maximum trim/discard I/O operations active to each device. .No See Sx ZFS I/O SCHEDULER . . .It Sy zfs_vdev_trim_min_active Ns = Ns Sy 1 Pq uint Minimum trim/discard I/O operations active to each device. .No See Sx ZFS I/O SCHEDULER . . .It Sy zfs_vdev_nia_delay Ns = Ns Sy 5 Pq uint For non-interactive I/O (scrub, resilver, removal, initialize and rebuild), the number of concurrently-active I/O operations is limited to .Sy zfs_*_min_active , unless the vdev is "idle". When there are no interactive I/O operations active (synchronous or otherwise), and .Sy zfs_vdev_nia_delay operations have completed since the last interactive operation, then the vdev is considered to be "idle", and the number of concurrently-active non-interactive operations is increased to .Sy zfs_*_max_active . .No See Sx ZFS I/O SCHEDULER . . .It Sy zfs_vdev_nia_credit Ns = Ns Sy 5 Pq uint Some HDDs tend to prioritize sequential I/O so strongly, that concurrent random I/O latency reaches several seconds. On some HDDs this happens even if sequential I/O operations are submitted one at a time, and so setting .Sy zfs_*_max_active Ns = Sy 1 does not help. To prevent non-interactive I/O, like scrub, from monopolizing the device, no more than .Sy zfs_vdev_nia_credit operations can be sent while there are outstanding incomplete interactive operations. This enforced wait ensures the HDD services the interactive I/O within a reasonable amount of time. .No See Sx ZFS I/O SCHEDULER . . .It Sy zfs_vdev_queue_depth_pct Ns = Ns Sy 1000 Ns % Pq uint Maximum number of queued allocations per top-level vdev expressed as a percentage of .Sy zfs_vdev_async_write_max_active , which allows the system to detect devices that are more capable of handling allocations and to allocate more blocks to those devices. This allows for dynamic allocation distribution when devices are imbalanced, as fuller devices will tend to be slower than empty devices. .Pp Also see .Sy zio_dva_throttle_enabled . . .It Sy zfs_vdev_def_queue_depth Ns = Ns Sy 32 Pq uint Default queue depth for each vdev IO allocator. Higher values allow for better coalescing of sequential writes before sending them to the disk, but can increase transaction commit times. . .It Sy zfs_vdev_failfast_mask Ns = Ns Sy 1 Pq uint Defines if the driver should retire on a given error type. The following options may be bitwise-ored together: .TS box; lbz r l l . Value Name Description _ 1 Device No driver retries on device errors 2 Transport No driver retries on transport errors. 4 Driver No driver retries on driver errors. .TE . .It Sy zfs_expire_snapshot Ns = Ns Sy 300 Ns s Pq int Time before expiring .Pa .zfs/snapshot . . .It Sy zfs_admin_snapshot Ns = Ns Sy 0 Ns | Ns 1 Pq int Allow the creation, removal, or renaming of entries in the .Sy .zfs/snapshot directory to cause the creation, destruction, or renaming of snapshots. When enabled, this functionality works both locally and over NFS exports which have the .Em no_root_squash option set. . .It Sy zfs_flags Ns = Ns Sy 0 Pq int Set additional debugging flags. The following flags may be bitwise-ored together: .TS box; lbz r l l . Value Name Description _ 1 ZFS_DEBUG_DPRINTF Enable dprintf entries in the debug log. * 2 ZFS_DEBUG_DBUF_VERIFY Enable extra dbuf verifications. * 4 ZFS_DEBUG_DNODE_VERIFY Enable extra dnode verifications. 8 ZFS_DEBUG_SNAPNAMES Enable snapshot name verification. * 16 ZFS_DEBUG_MODIFY Check for illegally modified ARC buffers. 64 ZFS_DEBUG_ZIO_FREE Enable verification of block frees. 128 ZFS_DEBUG_HISTOGRAM_VERIFY Enable extra spacemap histogram verifications. 256 ZFS_DEBUG_METASLAB_VERIFY Verify space accounting on disk matches in-memory \fBrange_trees\fP. 512 ZFS_DEBUG_SET_ERROR Enable \fBSET_ERROR\fP and dprintf entries in the debug log. 1024 ZFS_DEBUG_INDIRECT_REMAP Verify split blocks created by device removal. 2048 ZFS_DEBUG_TRIM Verify TRIM ranges are always within the allocatable range tree. 4096 ZFS_DEBUG_LOG_SPACEMAP Verify that the log summary is consistent with the spacemap log and enable \fBzfs_dbgmsgs\fP for metaslab loading and flushing. .TE .Sy \& * No Requires debug build . . .It Sy zfs_btree_verify_intensity Ns = Ns Sy 0 Pq uint Enables btree verification. The following settings are culminative: .TS box; lbz r l l . Value Description 1 Verify height. 2 Verify pointers from children to parent. 3 Verify element counts. 4 Verify element order. (expensive) * 5 Verify unused memory is poisoned. (expensive) .TE .Sy \& * No Requires debug build . . .It Sy zfs_free_leak_on_eio Ns = Ns Sy 0 Ns | Ns 1 Pq int If destroy encounters an .Sy EIO while reading metadata (e.g. indirect blocks), space referenced by the missing metadata can not be freed. Normally this causes the background destroy to become "stalled", as it is unable to make forward progress. While in this stalled state, all remaining space to free from the error-encountering filesystem is "temporarily leaked". Set this flag to cause it to ignore the .Sy EIO , permanently leak the space from indirect blocks that can not be read, and continue to free everything else that it can. .Pp The default "stalling" behavior is useful if the storage partially fails (i.e. some but not all I/O operations fail), and then later recovers. In this case, we will be able to continue pool operations while it is partially failed, and when it recovers, we can continue to free the space, with no leaks. Note, however, that this case is actually fairly rare. .Pp Typically pools either .Bl -enum -compact -offset 4n -width "1." .It fail completely (but perhaps temporarily, e.g. due to a top-level vdev going offline), or .It have localized, permanent errors (e.g. disk returns the wrong data due to bit flip or firmware bug). .El In the former case, this setting does not matter because the pool will be suspended and the sync thread will not be able to make forward progress regardless. In the latter, because the error is permanent, the best we can do is leak the minimum amount of space, which is what setting this flag will do. It is therefore reasonable for this flag to normally be set, but we chose the more conservative approach of not setting it, so that there is no possibility of leaking space in the "partial temporary" failure case. . .It Sy zfs_free_min_time_ms Ns = Ns Sy 1000 Ns ms Po 1s Pc Pq uint During a .Nm zfs Cm destroy operation using the .Sy async_destroy feature, a minimum of this much time will be spent working on freeing blocks per TXG. . .It Sy zfs_obsolete_min_time_ms Ns = Ns Sy 500 Ns ms Pq uint Similar to .Sy zfs_free_min_time_ms , but for cleanup of old indirection records for removed vdevs. . .It Sy zfs_immediate_write_sz Ns = Ns Sy 32768 Ns B Po 32 KiB Pc Pq s64 Largest data block to write to the ZIL. Larger blocks will be treated as if the dataset being written to had the .Sy logbias Ns = Ns Sy throughput property set. . .It Sy zfs_initialize_value Ns = Ns Sy 16045690984833335022 Po 0xDEADBEEFDEADBEEE Pc Pq u64 Pattern written to vdev free space by .Xr zpool-initialize 8 . . .It Sy zfs_initialize_chunk_size Ns = Ns Sy 1048576 Ns B Po 1 MiB Pc Pq u64 Size of writes used by .Xr zpool-initialize 8 . This option is used by the test suite. . .It Sy zfs_livelist_max_entries Ns = Ns Sy 500000 Po 5*10^5 Pc Pq u64 The threshold size (in block pointers) at which we create a new sub-livelist. Larger sublists are more costly from a memory perspective but the fewer sublists there are, the lower the cost of insertion. . .It Sy zfs_livelist_min_percent_shared Ns = Ns Sy 75 Ns % Pq int If the amount of shared space between a snapshot and its clone drops below this threshold, the clone turns off the livelist and reverts to the old deletion method. This is in place because livelists no long give us a benefit once a clone has been overwritten enough. . .It Sy zfs_livelist_condense_new_alloc Ns = Ns Sy 0 Pq int Incremented each time an extra ALLOC blkptr is added to a livelist entry while it is being condensed. This option is used by the test suite to track race conditions. . .It Sy zfs_livelist_condense_sync_cancel Ns = Ns Sy 0 Pq int Incremented each time livelist condensing is canceled while in .Fn spa_livelist_condense_sync . This option is used by the test suite to track race conditions. . .It Sy zfs_livelist_condense_sync_pause Ns = Ns Sy 0 Ns | Ns 1 Pq int When set, the livelist condense process pauses indefinitely before executing the synctask \(em .Fn spa_livelist_condense_sync . This option is used by the test suite to trigger race conditions. . .It Sy zfs_livelist_condense_zthr_cancel Ns = Ns Sy 0 Pq int Incremented each time livelist condensing is canceled while in .Fn spa_livelist_condense_cb . This option is used by the test suite to track race conditions. . .It Sy zfs_livelist_condense_zthr_pause Ns = Ns Sy 0 Ns | Ns 1 Pq int When set, the livelist condense process pauses indefinitely before executing the open context condensing work in .Fn spa_livelist_condense_cb . This option is used by the test suite to trigger race conditions. . .It Sy zfs_lua_max_instrlimit Ns = Ns Sy 100000000 Po 10^8 Pc Pq u64 The maximum execution time limit that can be set for a ZFS channel program, specified as a number of Lua instructions. . .It Sy zfs_lua_max_memlimit Ns = Ns Sy 104857600 Po 100 MiB Pc Pq u64 The maximum memory limit that can be set for a ZFS channel program, specified in bytes. . .It Sy zfs_max_dataset_nesting Ns = Ns Sy 50 Pq int The maximum depth of nested datasets. This value can be tuned temporarily to fix existing datasets that exceed the predefined limit. . .It Sy zfs_max_log_walking Ns = Ns Sy 5 Pq u64 The number of past TXGs that the flushing algorithm of the log spacemap feature uses to estimate incoming log blocks. . .It Sy zfs_max_logsm_summary_length Ns = Ns Sy 10 Pq u64 Maximum number of rows allowed in the summary of the spacemap log. . .It Sy zfs_max_recordsize Ns = Ns Sy 16777216 Po 16 MiB Pc Pq uint We currently support block sizes from .Em 512 Po 512 B Pc No to Em 16777216 Po 16 MiB Pc . The benefits of larger blocks, and thus larger I/O, need to be weighed against the cost of COWing a giant block to modify one byte. Additionally, very large blocks can have an impact on I/O latency, and also potentially on the memory allocator. Therefore, we formerly forbade creating blocks larger than 1M. Larger blocks could be created by changing it, and pools with larger blocks can always be imported and used, regardless of this setting. . .It Sy zfs_allow_redacted_dataset_mount Ns = Ns Sy 0 Ns | Ns 1 Pq int Allow datasets received with redacted send/receive to be mounted. Normally disabled because these datasets may be missing key data. . .It Sy zfs_min_metaslabs_to_flush Ns = Ns Sy 1 Pq u64 Minimum number of metaslabs to flush per dirty TXG. . .It Sy zfs_metaslab_fragmentation_threshold Ns = Ns Sy 70 Ns % Pq uint Allow metaslabs to keep their active state as long as their fragmentation percentage is no more than this value. An active metaslab that exceeds this threshold will no longer keep its active status allowing better metaslabs to be selected. . .It Sy zfs_mg_fragmentation_threshold Ns = Ns Sy 95 Ns % Pq uint Metaslab groups are considered eligible for allocations if their fragmentation metric (measured as a percentage) is less than or equal to this value. If a metaslab group exceeds this threshold then it will be skipped unless all metaslab groups within the metaslab class have also crossed this threshold. . .It Sy zfs_mg_noalloc_threshold Ns = Ns Sy 0 Ns % Pq uint Defines a threshold at which metaslab groups should be eligible for allocations. The value is expressed as a percentage of free space beyond which a metaslab group is always eligible for allocations. If a metaslab group's free space is less than or equal to the threshold, the allocator will avoid allocating to that group unless all groups in the pool have reached the threshold. Once all groups have reached the threshold, all groups are allowed to accept allocations. The default value of .Sy 0 disables the feature and causes all metaslab groups to be eligible for allocations. .Pp This parameter allows one to deal with pools having heavily imbalanced vdevs such as would be the case when a new vdev has been added. Setting the threshold to a non-zero percentage will stop allocations from being made to vdevs that aren't filled to the specified percentage and allow lesser filled vdevs to acquire more allocations than they otherwise would under the old .Sy zfs_mg_alloc_failures facility. . .It Sy zfs_ddt_data_is_special Ns = Ns Sy 1 Ns | Ns 0 Pq int If enabled, ZFS will place DDT data into the special allocation class. . .It Sy zfs_user_indirect_is_special Ns = Ns Sy 1 Ns | Ns 0 Pq int If enabled, ZFS will place user data indirect blocks into the special allocation class. . .It Sy zfs_multihost_history Ns = Ns Sy 0 Pq uint Historical statistics for this many latest multihost updates will be available in .Pa /proc/spl/kstat/zfs/ Ns Ao Ar pool Ac Ns Pa /multihost . . .It Sy zfs_multihost_interval Ns = Ns Sy 1000 Ns ms Po 1 s Pc Pq u64 Used to control the frequency of multihost writes which are performed when the .Sy multihost pool property is on. This is one of the factors used to determine the length of the activity check during import. .Pp The multihost write period is .Sy zfs_multihost_interval No / Sy leaf-vdevs . On average a multihost write will be issued for each leaf vdev every .Sy zfs_multihost_interval milliseconds. In practice, the observed period can vary with the I/O load and this observed value is the delay which is stored in the uberblock. . .It Sy zfs_multihost_import_intervals Ns = Ns Sy 20 Pq uint Used to control the duration of the activity test on import. Smaller values of .Sy zfs_multihost_import_intervals will reduce the import time but increase the risk of failing to detect an active pool. The total activity check time is never allowed to drop below one second. .Pp On import the activity check waits a minimum amount of time determined by .Sy zfs_multihost_interval No \(mu Sy zfs_multihost_import_intervals , or the same product computed on the host which last had the pool imported, whichever is greater. The activity check time may be further extended if the value of MMP delay found in the best uberblock indicates actual multihost updates happened at longer intervals than .Sy zfs_multihost_interval . A minimum of .Em 100 ms is enforced. .Pp .Sy 0 No is equivalent to Sy 1 . . .It Sy zfs_multihost_fail_intervals Ns = Ns Sy 10 Pq uint Controls the behavior of the pool when multihost write failures or delays are detected. .Pp When .Sy 0 , multihost write failures or delays are ignored. The failures will still be reported to the ZED which depending on its configuration may take action such as suspending the pool or offlining a device. .Pp Otherwise, the pool will be suspended if .Sy zfs_multihost_fail_intervals No \(mu Sy zfs_multihost_interval milliseconds pass without a successful MMP write. This guarantees the activity test will see MMP writes if the pool is imported. .Sy 1 No is equivalent to Sy 2 ; this is necessary to prevent the pool from being suspended due to normal, small I/O latency variations. . .It Sy zfs_no_scrub_io Ns = Ns Sy 0 Ns | Ns 1 Pq int Set to disable scrub I/O. This results in scrubs not actually scrubbing data and simply doing a metadata crawl of the pool instead. . .It Sy zfs_no_scrub_prefetch Ns = Ns Sy 0 Ns | Ns 1 Pq int Set to disable block prefetching for scrubs. . .It Sy zfs_nocacheflush Ns = Ns Sy 0 Ns | Ns 1 Pq int Disable cache flush operations on disks when writing. Setting this will cause pool corruption on power loss if a volatile out-of-order write cache is enabled. . .It Sy zfs_nopwrite_enabled Ns = Ns Sy 1 Ns | Ns 0 Pq int Allow no-operation writes. The occurrence of nopwrites will further depend on other pool properties .Pq i.a. the checksumming and compression algorithms . . .It Sy zfs_dmu_offset_next_sync Ns = Ns Sy 1 Ns | Ns 0 Pq int Enable forcing TXG sync to find holes. When enabled forces ZFS to sync data when .Sy SEEK_HOLE No or Sy SEEK_DATA flags are used allowing holes in a file to be accurately reported. When disabled holes will not be reported in recently dirtied files. . .It Sy zfs_pd_bytes_max Ns = Ns Sy 52428800 Ns B Po 50 MiB Pc Pq int The number of bytes which should be prefetched during a pool traversal, like .Nm zfs Cm send or other data crawling operations. . .It Sy zfs_traverse_indirect_prefetch_limit Ns = Ns Sy 32 Pq uint The number of blocks pointed by indirect (non-L0) block which should be prefetched during a pool traversal, like .Nm zfs Cm send or other data crawling operations. . .It Sy zfs_per_txg_dirty_frees_percent Ns = Ns Sy 30 Ns % Pq u64 Control percentage of dirtied indirect blocks from frees allowed into one TXG. After this threshold is crossed, additional frees will wait until the next TXG. .Sy 0 No disables this throttle . . .It Sy zfs_prefetch_disable Ns = Ns Sy 0 Ns | Ns 1 Pq int Disable predictive prefetch. Note that it leaves "prescient" prefetch .Pq for, e.g., Nm zfs Cm send intact. Unlike predictive prefetch, prescient prefetch never issues I/O that ends up not being needed, so it can't hurt performance. . .It Sy zfs_qat_checksum_disable Ns = Ns Sy 0 Ns | Ns 1 Pq int Disable QAT hardware acceleration for SHA256 checksums. May be unset after the ZFS modules have been loaded to initialize the QAT hardware as long as support is compiled in and the QAT driver is present. . .It Sy zfs_qat_compress_disable Ns = Ns Sy 0 Ns | Ns 1 Pq int Disable QAT hardware acceleration for gzip compression. May be unset after the ZFS modules have been loaded to initialize the QAT hardware as long as support is compiled in and the QAT driver is present. . .It Sy zfs_qat_encrypt_disable Ns = Ns Sy 0 Ns | Ns 1 Pq int Disable QAT hardware acceleration for AES-GCM encryption. May be unset after the ZFS modules have been loaded to initialize the QAT hardware as long as support is compiled in and the QAT driver is present. . .It Sy zfs_vnops_read_chunk_size Ns = Ns Sy 1048576 Ns B Po 1 MiB Pc Pq u64 Bytes to read per chunk. . .It Sy zfs_read_history Ns = Ns Sy 0 Pq uint Historical statistics for this many latest reads will be available in .Pa /proc/spl/kstat/zfs/ Ns Ao Ar pool Ac Ns Pa /reads . . .It Sy zfs_read_history_hits Ns = Ns Sy 0 Ns | Ns 1 Pq int Include cache hits in read history . .It Sy zfs_rebuild_max_segment Ns = Ns Sy 1048576 Ns B Po 1 MiB Pc Pq u64 Maximum read segment size to issue when sequentially resilvering a top-level vdev. . .It Sy zfs_rebuild_scrub_enabled Ns = Ns Sy 1 Ns | Ns 0 Pq int Automatically start a pool scrub when the last active sequential resilver completes in order to verify the checksums of all blocks which have been resilvered. This is enabled by default and strongly recommended. . .It Sy zfs_rebuild_vdev_limit Ns = Ns Sy 67108864 Ns B Po 64 MiB Pc Pq u64 Maximum amount of I/O that can be concurrently issued for a sequential resilver per leaf device, given in bytes. . .It Sy zfs_reconstruct_indirect_combinations_max Ns = Ns Sy 4096 Pq int If an indirect split block contains more than this many possible unique combinations when being reconstructed, consider it too computationally expensive to check them all. Instead, try at most this many randomly selected combinations each time the block is accessed. This allows all segment copies to participate fairly in the reconstruction when all combinations cannot be checked and prevents repeated use of one bad copy. . .It Sy zfs_recover Ns = Ns Sy 0 Ns | Ns 1 Pq int Set to attempt to recover from fatal errors. This should only be used as a last resort, as it typically results in leaked space, or worse. . .It Sy zfs_removal_ignore_errors Ns = Ns Sy 0 Ns | Ns 1 Pq int Ignore hard I/O errors during device removal. When set, if a device encounters a hard I/O error during the removal process the removal will not be cancelled. This can result in a normally recoverable block becoming permanently damaged and is hence not recommended. This should only be used as a last resort when the pool cannot be returned to a healthy state prior to removing the device. . .It Sy zfs_removal_suspend_progress Ns = Ns Sy 0 Ns | Ns 1 Pq uint This is used by the test suite so that it can ensure that certain actions happen while in the middle of a removal. . .It Sy zfs_remove_max_segment Ns = Ns Sy 16777216 Ns B Po 16 MiB Pc Pq uint The largest contiguous segment that we will attempt to allocate when removing a device. If there is a performance problem with attempting to allocate large blocks, consider decreasing this. The default value is also the maximum. . .It Sy zfs_resilver_disable_defer Ns = Ns Sy 0 Ns | Ns 1 Pq int Ignore the .Sy resilver_defer feature, causing an operation that would start a resilver to immediately restart the one in progress. . .It Sy zfs_resilver_min_time_ms Ns = Ns Sy 3000 Ns ms Po 3 s Pc Pq uint Resilvers are processed by the sync thread. While resilvering, it will spend at least this much time working on a resilver between TXG flushes. . .It Sy zfs_scan_ignore_errors Ns = Ns Sy 0 Ns | Ns 1 Pq int If set, remove the DTL (dirty time list) upon completion of a pool scan (scrub), even if there were unrepairable errors. Intended to be used during pool repair or recovery to stop resilvering when the pool is next imported. . .It Sy zfs_scrub_min_time_ms Ns = Ns Sy 1000 Ns ms Po 1 s Pc Pq uint Scrubs are processed by the sync thread. While scrubbing, it will spend at least this much time working on a scrub between TXG flushes. . .It Sy zfs_scrub_error_blocks_per_txg Ns = Ns Sy 4096 Pq uint Error blocks to be scrubbed in one txg. . .It Sy zfs_scan_checkpoint_intval Ns = Ns Sy 7200 Ns s Po 2 hour Pc Pq uint To preserve progress across reboots, the sequential scan algorithm periodically needs to stop metadata scanning and issue all the verification I/O to disk. The frequency of this flushing is determined by this tunable. . .It Sy zfs_scan_fill_weight Ns = Ns Sy 3 Pq uint This tunable affects how scrub and resilver I/O segments are ordered. A higher number indicates that we care more about how filled in a segment is, while a lower number indicates we care more about the size of the extent without considering the gaps within a segment. This value is only tunable upon module insertion. Changing the value afterwards will have no effect on scrub or resilver performance. . .It Sy zfs_scan_issue_strategy Ns = Ns Sy 0 Pq uint Determines the order that data will be verified while scrubbing or resilvering: .Bl -tag -compact -offset 4n -width "a" .It Sy 1 Data will be verified as sequentially as possible, given the amount of memory reserved for scrubbing .Pq see Sy zfs_scan_mem_lim_fact . This may improve scrub performance if the pool's data is very fragmented. .It Sy 2 The largest mostly-contiguous chunk of found data will be verified first. By deferring scrubbing of small segments, we may later find adjacent data to coalesce and increase the segment size. .It Sy 0 .No Use strategy Sy 1 No during normal verification .No and strategy Sy 2 No while taking a checkpoint . .El . .It Sy zfs_scan_legacy Ns = Ns Sy 0 Ns | Ns 1 Pq int If unset, indicates that scrubs and resilvers will gather metadata in memory before issuing sequential I/O. Otherwise indicates that the legacy algorithm will be used, where I/O is initiated as soon as it is discovered. Unsetting will not affect scrubs or resilvers that are already in progress. . .It Sy zfs_scan_max_ext_gap Ns = Ns Sy 2097152 Ns B Po 2 MiB Pc Pq int Sets the largest gap in bytes between scrub/resilver I/O operations that will still be considered sequential for sorting purposes. Changing this value will not affect scrubs or resilvers that are already in progress. . .It Sy zfs_scan_mem_lim_fact Ns = Ns Sy 20 Ns ^-1 Pq uint Maximum fraction of RAM used for I/O sorting by sequential scan algorithm. This tunable determines the hard limit for I/O sorting memory usage. When the hard limit is reached we stop scanning metadata and start issuing data verification I/O. This is done until we get below the soft limit. . .It Sy zfs_scan_mem_lim_soft_fact Ns = Ns Sy 20 Ns ^-1 Pq uint The fraction of the hard limit used to determined the soft limit for I/O sorting by the sequential scan algorithm. When we cross this limit from below no action is taken. When we cross this limit from above it is because we are issuing verification I/O. In this case (unless the metadata scan is done) we stop issuing verification I/O and start scanning metadata again until we get to the hard limit. . .It Sy zfs_scan_report_txgs Ns = Ns Sy 0 Ns | Ns 1 Pq uint When reporting resilver throughput and estimated completion time use the performance observed over roughly the last .Sy zfs_scan_report_txgs TXGs. When set to zero performance is calculated over the time between checkpoints. . .It Sy zfs_scan_strict_mem_lim Ns = Ns Sy 0 Ns | Ns 1 Pq int Enforce tight memory limits on pool scans when a sequential scan is in progress. When disabled, the memory limit may be exceeded by fast disks. . .It Sy zfs_scan_suspend_progress Ns = Ns Sy 0 Ns | Ns 1 Pq int Freezes a scrub/resilver in progress without actually pausing it. Intended for testing/debugging. . .It Sy zfs_scan_vdev_limit Ns = Ns Sy 16777216 Ns B Po 16 MiB Pc Pq int Maximum amount of data that can be concurrently issued at once for scrubs and resilvers per leaf device, given in bytes. . .It Sy zfs_send_corrupt_data Ns = Ns Sy 0 Ns | Ns 1 Pq int Allow sending of corrupt data (ignore read/checksum errors when sending). . .It Sy zfs_send_unmodified_spill_blocks Ns = Ns Sy 1 Ns | Ns 0 Pq int Include unmodified spill blocks in the send stream. Under certain circumstances, previous versions of ZFS could incorrectly remove the spill block from an existing object. Including unmodified copies of the spill blocks creates a backwards-compatible stream which will recreate a spill block if it was incorrectly removed. . .It Sy zfs_send_no_prefetch_queue_ff Ns = Ns Sy 20 Ns ^\-1 Pq uint The fill fraction of the .Nm zfs Cm send internal queues. The fill fraction controls the timing with which internal threads are woken up. . .It Sy zfs_send_no_prefetch_queue_length Ns = Ns Sy 1048576 Ns B Po 1 MiB Pc Pq uint The maximum number of bytes allowed in .Nm zfs Cm send Ns 's internal queues. . .It Sy zfs_send_queue_ff Ns = Ns Sy 20 Ns ^\-1 Pq uint The fill fraction of the .Nm zfs Cm send prefetch queue. The fill fraction controls the timing with which internal threads are woken up. . .It Sy zfs_send_queue_length Ns = Ns Sy 16777216 Ns B Po 16 MiB Pc Pq uint The maximum number of bytes allowed that will be prefetched by .Nm zfs Cm send . This value must be at least twice the maximum block size in use. . .It Sy zfs_recv_queue_ff Ns = Ns Sy 20 Ns ^\-1 Pq uint The fill fraction of the .Nm zfs Cm receive queue. The fill fraction controls the timing with which internal threads are woken up. . .It Sy zfs_recv_queue_length Ns = Ns Sy 16777216 Ns B Po 16 MiB Pc Pq uint The maximum number of bytes allowed in the .Nm zfs Cm receive queue. This value must be at least twice the maximum block size in use. . .It Sy zfs_recv_write_batch_size Ns = Ns Sy 1048576 Ns B Po 1 MiB Pc Pq uint The maximum amount of data, in bytes, that .Nm zfs Cm receive will write in one DMU transaction. This is the uncompressed size, even when receiving a compressed send stream. This setting will not reduce the write size below a single block. Capped at a maximum of .Sy 32 MiB . . .It Sy zfs_recv_best_effort_corrective Ns = Ns Sy 0 Pq int When this variable is set to non-zero a corrective receive: .Bl -enum -compact -offset 4n -width "1." .It Does not enforce the restriction of source & destination snapshot GUIDs matching. .It If there is an error during healing, the healing receive is not terminated instead it moves on to the next record. .El . .It Sy zfs_override_estimate_recordsize Ns = Ns Sy 0 Ns | Ns 1 Pq uint Setting this variable overrides the default logic for estimating block sizes when doing a .Nm zfs Cm send . The default heuristic is that the average block size will be the current recordsize. Override this value if most data in your dataset is not of that size and you require accurate zfs send size estimates. . .It Sy zfs_sync_pass_deferred_free Ns = Ns Sy 2 Pq uint Flushing of data to disk is done in passes. Defer frees starting in this pass. . .It Sy zfs_spa_discard_memory_limit Ns = Ns Sy 16777216 Ns B Po 16 MiB Pc Pq int Maximum memory used for prefetching a checkpoint's space map on each vdev while discarding the checkpoint. . .It Sy zfs_special_class_metadata_reserve_pct Ns = Ns Sy 25 Ns % Pq uint Only allow small data blocks to be allocated on the special and dedup vdev types when the available free space percentage on these vdevs exceeds this value. This ensures reserved space is available for pool metadata as the special vdevs approach capacity. . .It Sy zfs_sync_pass_dont_compress Ns = Ns Sy 8 Pq uint Starting in this sync pass, disable compression (including of metadata). With the default setting, in practice, we don't have this many sync passes, so this has no effect. .Pp The original intent was that disabling compression would help the sync passes to converge. However, in practice, disabling compression increases the average number of sync passes; because when we turn compression off, many blocks' size will change, and thus we have to re-allocate (not overwrite) them. It also increases the number of .Em 128 KiB allocations (e.g. for indirect blocks and spacemaps) because these will not be compressed. The .Em 128 KiB allocations are especially detrimental to performance on highly fragmented systems, which may have very few free segments of this size, and may need to load new metaslabs to satisfy these allocations. . .It Sy zfs_sync_pass_rewrite Ns = Ns Sy 2 Pq uint Rewrite new block pointers starting in this pass. . .It Sy zfs_sync_taskq_batch_pct Ns = Ns Sy 75 Ns % Pq int This controls the number of threads used by .Sy dp_sync_taskq . The default value of .Sy 75% will create a maximum of one thread per CPU. . .It Sy zfs_trim_extent_bytes_max Ns = Ns Sy 134217728 Ns B Po 128 MiB Pc Pq uint Maximum size of TRIM command. Larger ranges will be split into chunks no larger than this value before issuing. . .It Sy zfs_trim_extent_bytes_min Ns = Ns Sy 32768 Ns B Po 32 KiB Pc Pq uint Minimum size of TRIM commands. TRIM ranges smaller than this will be skipped, unless they're part of a larger range which was chunked. This is done because it's common for these small TRIMs to negatively impact overall performance. . .It Sy zfs_trim_metaslab_skip Ns = Ns Sy 0 Ns | Ns 1 Pq uint Skip uninitialized metaslabs during the TRIM process. This option is useful for pools constructed from large thinly-provisioned devices where TRIM operations are slow. As a pool ages, an increasing fraction of the pool's metaslabs will be initialized, progressively degrading the usefulness of this option. This setting is stored when starting a manual TRIM and will persist for the duration of the requested TRIM. . .It Sy zfs_trim_queue_limit Ns = Ns Sy 10 Pq uint Maximum number of queued TRIMs outstanding per leaf vdev. The number of concurrent TRIM commands issued to the device is controlled by .Sy zfs_vdev_trim_min_active No and Sy zfs_vdev_trim_max_active . . .It Sy zfs_trim_txg_batch Ns = Ns Sy 32 Pq uint The number of transaction groups' worth of frees which should be aggregated before TRIM operations are issued to the device. This setting represents a trade-off between issuing larger, more efficient TRIM operations and the delay before the recently trimmed space is available for use by the device. .Pp Increasing this value will allow frees to be aggregated for a longer time. This will result is larger TRIM operations and potentially increased memory usage. Decreasing this value will have the opposite effect. The default of .Sy 32 was determined to be a reasonable compromise. . .It Sy zfs_txg_history Ns = Ns Sy 0 Pq uint Historical statistics for this many latest TXGs will be available in .Pa /proc/spl/kstat/zfs/ Ns Ao Ar pool Ac Ns Pa /TXGs . . .It Sy zfs_txg_timeout Ns = Ns Sy 5 Ns s Pq uint Flush dirty data to disk at least every this many seconds (maximum TXG duration). . .It Sy zfs_vdev_aggregation_limit Ns = Ns Sy 1048576 Ns B Po 1 MiB Pc Pq uint Max vdev I/O aggregation size. . .It Sy zfs_vdev_aggregation_limit_non_rotating Ns = Ns Sy 131072 Ns B Po 128 KiB Pc Pq uint Max vdev I/O aggregation size for non-rotating media. . .It Sy zfs_vdev_mirror_rotating_inc Ns = Ns Sy 0 Pq int A number by which the balancing algorithm increments the load calculation for the purpose of selecting the least busy mirror member when an I/O operation immediately follows its predecessor on rotational vdevs for the purpose of making decisions based on load. . .It Sy zfs_vdev_mirror_rotating_seek_inc Ns = Ns Sy 5 Pq int A number by which the balancing algorithm increments the load calculation for the purpose of selecting the least busy mirror member when an I/O operation lacks locality as defined by .Sy zfs_vdev_mirror_rotating_seek_offset . Operations within this that are not immediately following the previous operation are incremented by half. . .It Sy zfs_vdev_mirror_rotating_seek_offset Ns = Ns Sy 1048576 Ns B Po 1 MiB Pc Pq int The maximum distance for the last queued I/O operation in which the balancing algorithm considers an operation to have locality. .No See Sx ZFS I/O SCHEDULER . . .It Sy zfs_vdev_mirror_non_rotating_inc Ns = Ns Sy 0 Pq int A number by which the balancing algorithm increments the load calculation for the purpose of selecting the least busy mirror member on non-rotational vdevs when I/O operations do not immediately follow one another. . .It Sy zfs_vdev_mirror_non_rotating_seek_inc Ns = Ns Sy 1 Pq int A number by which the balancing algorithm increments the load calculation for the purpose of selecting the least busy mirror member when an I/O operation lacks locality as defined by the .Sy zfs_vdev_mirror_rotating_seek_offset . Operations within this that are not immediately following the previous operation are incremented by half. . .It Sy zfs_vdev_read_gap_limit Ns = Ns Sy 32768 Ns B Po 32 KiB Pc Pq uint Aggregate read I/O operations if the on-disk gap between them is within this threshold. . .It Sy zfs_vdev_write_gap_limit Ns = Ns Sy 4096 Ns B Po 4 KiB Pc Pq uint Aggregate write I/O operations if the on-disk gap between them is within this threshold. . .It Sy zfs_vdev_raidz_impl Ns = Ns Sy fastest Pq string Select the raidz parity implementation to use. .Pp Variants that don't depend on CPU-specific features may be selected on module load, as they are supported on all systems. The remaining options may only be set after the module is loaded, as they are available only if the implementations are compiled in and supported on the running system. .Pp Once the module is loaded, .Pa /sys/module/zfs/parameters/zfs_vdev_raidz_impl will show the available options, with the currently selected one enclosed in square brackets. .Pp .TS lb l l . fastest selected by built-in benchmark original original implementation scalar scalar implementation sse2 SSE2 instruction set 64-bit x86 ssse3 SSSE3 instruction set 64-bit x86 avx2 AVX2 instruction set 64-bit x86 avx512f AVX512F instruction set 64-bit x86 avx512bw AVX512F & AVX512BW instruction sets 64-bit x86 aarch64_neon NEON Aarch64/64-bit ARMv8 aarch64_neonx2 NEON with more unrolling Aarch64/64-bit ARMv8 powerpc_altivec Altivec PowerPC .TE . .It Sy zfs_vdev_scheduler Pq charp .Sy DEPRECATED . Prints warning to kernel log for compatibility. . .It Sy zfs_zevent_len_max Ns = Ns Sy 512 Pq uint Max event queue length. Events in the queue can be viewed with .Xr zpool-events 8 . . .It Sy zfs_zevent_retain_max Ns = Ns Sy 2000 Pq int Maximum recent zevent records to retain for duplicate checking. Setting this to .Sy 0 disables duplicate detection. . .It Sy zfs_zevent_retain_expire_secs Ns = Ns Sy 900 Ns s Po 15 min Pc Pq int Lifespan for a recent ereport that was retained for duplicate checking. . .It Sy zfs_zil_clean_taskq_maxalloc Ns = Ns Sy 1048576 Pq int The maximum number of taskq entries that are allowed to be cached. When this limit is exceeded transaction records (itxs) will be cleaned synchronously. . .It Sy zfs_zil_clean_taskq_minalloc Ns = Ns Sy 1024 Pq int The number of taskq entries that are pre-populated when the taskq is first created and are immediately available for use. . .It Sy zfs_zil_clean_taskq_nthr_pct Ns = Ns Sy 100 Ns % Pq int This controls the number of threads used by .Sy dp_zil_clean_taskq . The default value of .Sy 100% will create a maximum of one thread per cpu. . .It Sy zil_maxblocksize Ns = Ns Sy 131072 Ns B Po 128 KiB Pc Pq uint This sets the maximum block size used by the ZIL. On very fragmented pools, lowering this .Pq typically to Sy 36 KiB can improve performance. . .It Sy zil_maxcopied Ns = Ns Sy 7680 Ns B Po 7.5 KiB Pc Pq uint This sets the maximum number of write bytes logged via WR_COPIED. It tunes a tradeoff between additional memory copy and possibly worse log space efficiency vs additional range lock/unlock. . .It Sy zil_min_commit_timeout Ns = Ns Sy 5000 Pq u64 This sets the minimum delay in nanoseconds ZIL care to delay block commit, waiting for more records. If ZIL writes are too fast, kernel may not be able sleep for so short interval, increasing log latency above allowed by .Sy zfs_commit_timeout_pct . . .It Sy zil_nocacheflush Ns = Ns Sy 0 Ns | Ns 1 Pq int Disable the cache flush commands that are normally sent to disk by the ZIL after an LWB write has completed. Setting this will cause ZIL corruption on power loss if a volatile out-of-order write cache is enabled. . .It Sy zil_replay_disable Ns = Ns Sy 0 Ns | Ns 1 Pq int Disable intent logging replay. Can be disabled for recovery from corrupted ZIL. . -.It Sy zil_slog_bulk Ns = Ns Sy 786432 Ns B Po 768 KiB Pc Pq u64 +.It Sy zil_slog_bulk Ns = Ns Sy 67108864 Ns B Po 64 MiB Pc Pq u64 Limit SLOG write size per commit executed with synchronous priority. Any writes above that will be executed with lower (asynchronous) priority to limit potential SLOG device abuse by single active ZIL writer. . .It Sy zfs_zil_saxattr Ns = Ns Sy 1 Ns | Ns 0 Pq int Setting this tunable to zero disables ZIL logging of new .Sy xattr Ns = Ns Sy sa records if the .Sy org.openzfs:zilsaxattr feature is enabled on the pool. This would only be necessary to work around bugs in the ZIL logging or replay code for this record type. The tunable has no effect if the feature is disabled. . .It Sy zfs_embedded_slog_min_ms Ns = Ns Sy 64 Pq uint Usually, one metaslab from each normal-class vdev is dedicated for use by the ZIL to log synchronous writes. However, if there are fewer than .Sy zfs_embedded_slog_min_ms metaslabs in the vdev, this functionality is disabled. This ensures that we don't set aside an unreasonable amount of space for the ZIL. . .It Sy zstd_earlyabort_pass Ns = Ns Sy 1 Pq uint Whether heuristic for detection of incompressible data with zstd levels >= 3 using LZ4 and zstd-1 passes is enabled. . .It Sy zstd_abort_size Ns = Ns Sy 131072 Pq uint Minimal uncompressed size (inclusive) of a record before the early abort heuristic will be attempted. . .It Sy zio_deadman_log_all Ns = Ns Sy 0 Ns | Ns 1 Pq int If non-zero, the zio deadman will produce debugging messages .Pq see Sy zfs_dbgmsg_enable for all zios, rather than only for leaf zios possessing a vdev. This is meant to be used by developers to gain diagnostic information for hang conditions which don't involve a mutex or other locking primitive: typically conditions in which a thread in the zio pipeline is looping indefinitely. . .It Sy zio_slow_io_ms Ns = Ns Sy 30000 Ns ms Po 30 s Pc Pq int When an I/O operation takes more than this much time to complete, it's marked as slow. Each slow operation causes a delay zevent. Slow I/O counters can be seen with .Nm zpool Cm status Fl s . . .It Sy zio_dva_throttle_enabled Ns = Ns Sy 1 Ns | Ns 0 Pq int Throttle block allocations in the I/O pipeline. This allows for dynamic allocation distribution when devices are imbalanced. When enabled, the maximum number of pending allocations per top-level vdev is limited by .Sy zfs_vdev_queue_depth_pct . . .It Sy zfs_xattr_compat Ns = Ns 0 Ns | Ns 1 Pq int Control the naming scheme used when setting new xattrs in the user namespace. If .Sy 0 .Pq the default on Linux , user namespace xattr names are prefixed with the namespace, to be backwards compatible with previous versions of ZFS on Linux. If .Sy 1 .Pq the default on Fx , user namespace xattr names are not prefixed, to be backwards compatible with previous versions of ZFS on illumos and .Fx . .Pp Either naming scheme can be read on this and future versions of ZFS, regardless of this tunable, but legacy ZFS on illumos or .Fx are unable to read user namespace xattrs written in the Linux format, and legacy versions of ZFS on Linux are unable to read user namespace xattrs written in the legacy ZFS format. .Pp An existing xattr with the alternate naming scheme is removed when overwriting the xattr so as to not accumulate duplicates. . .It Sy zio_requeue_io_start_cut_in_line Ns = Ns Sy 0 Ns | Ns 1 Pq int Prioritize requeued I/O. . .It Sy zio_taskq_batch_pct Ns = Ns Sy 80 Ns % Pq uint Percentage of online CPUs which will run a worker thread for I/O. These workers are responsible for I/O work such as compression and checksum calculations. Fractional number of CPUs will be rounded down. .Pp The default value of .Sy 80% was chosen to avoid using all CPUs which can result in latency issues and inconsistent application performance, especially when slower compression and/or checksumming is enabled. . .It Sy zio_taskq_batch_tpq Ns = Ns Sy 0 Pq uint Number of worker threads per taskq. Lower values improve I/O ordering and CPU utilization, while higher reduces lock contention. .Pp If .Sy 0 , generate a system-dependent value close to 6 threads per taskq. . .It Sy zvol_inhibit_dev Ns = Ns Sy 0 Ns | Ns 1 Pq uint Do not create zvol device nodes. This may slightly improve startup time on systems with a very large number of zvols. . .It Sy zvol_major Ns = Ns Sy 230 Pq uint Major number for zvol block devices. . .It Sy zvol_max_discard_blocks Ns = Ns Sy 16384 Pq long Discard (TRIM) operations done on zvols will be done in batches of this many blocks, where block size is determined by the .Sy volblocksize property of a zvol. . .It Sy zvol_prefetch_bytes Ns = Ns Sy 131072 Ns B Po 128 KiB Pc Pq uint When adding a zvol to the system, prefetch this many bytes from the start and end of the volume. Prefetching these regions of the volume is desirable, because they are likely to be accessed immediately by .Xr blkid 8 or the kernel partitioner. . .It Sy zvol_request_sync Ns = Ns Sy 0 Ns | Ns 1 Pq uint When processing I/O requests for a zvol, submit them synchronously. This effectively limits the queue depth to .Em 1 for each I/O submitter. When unset, requests are handled asynchronously by a thread pool. The number of requests which can be handled concurrently is controlled by .Sy zvol_threads . .Sy zvol_request_sync is ignored when running on a kernel that supports block multiqueue .Pq Li blk-mq . . .It Sy zvol_threads Ns = Ns Sy 0 Pq uint The number of system wide threads to use for processing zvol block IOs. If .Sy 0 (the default) then internally set .Sy zvol_threads to the number of CPUs present or 32 (whichever is greater). . .It Sy zvol_volmode Ns = Ns Sy 1 Pq uint Defines zvol block devices behaviour when .Sy volmode Ns = Ns Sy default : .Bl -tag -compact -offset 4n -width "a" .It Sy 1 .No equivalent to Sy full .It Sy 2 .No equivalent to Sy dev .It Sy 3 .No equivalent to Sy none .El . .It Sy zvol_enforce_quotas Ns = Ns Sy 0 Ns | Ns 1 Pq uint Enable strict ZVOL quota enforcement. The strict quota enforcement may have a performance impact. .El . .Sh ZFS I/O SCHEDULER ZFS issues I/O operations to leaf vdevs to satisfy and complete I/O operations. The scheduler determines when and in what order those operations are issued. The scheduler divides operations into five I/O classes, prioritized in the following order: sync read, sync write, async read, async write, and scrub/resilver. Each queue defines the minimum and maximum number of concurrent operations that may be issued to the device. In addition, the device has an aggregate maximum, .Sy zfs_vdev_max_active . Note that the sum of the per-queue minima must not exceed the aggregate maximum. If the sum of the per-queue maxima exceeds the aggregate maximum, then the number of active operations may reach .Sy zfs_vdev_max_active , in which case no further operations will be issued, regardless of whether all per-queue minima have been met. .Pp For many physical devices, throughput increases with the number of concurrent operations, but latency typically suffers. Furthermore, physical devices typically have a limit at which more concurrent operations have no effect on throughput or can actually cause it to decrease. .Pp The scheduler selects the next operation to issue by first looking for an I/O class whose minimum has not been satisfied. Once all are satisfied and the aggregate maximum has not been hit, the scheduler looks for classes whose maximum has not been satisfied. Iteration through the I/O classes is done in the order specified above. No further operations are issued if the aggregate maximum number of concurrent operations has been hit, or if there are no operations queued for an I/O class that has not hit its maximum. Every time an I/O operation is queued or an operation completes, the scheduler looks for new operations to issue. .Pp In general, smaller .Sy max_active Ns s will lead to lower latency of synchronous operations. Larger .Sy max_active Ns s may lead to higher overall throughput, depending on underlying storage. .Pp The ratio of the queues' .Sy max_active Ns s determines the balance of performance between reads, writes, and scrubs. For example, increasing .Sy zfs_vdev_scrub_max_active will cause the scrub or resilver to complete more quickly, but reads and writes to have higher latency and lower throughput. .Pp All I/O classes have a fixed maximum number of outstanding operations, except for the async write class. Asynchronous writes represent the data that is committed to stable storage during the syncing stage for transaction groups. Transaction groups enter the syncing state periodically, so the number of queued async writes will quickly burst up and then bleed down to zero. Rather than servicing them as quickly as possible, the I/O scheduler changes the maximum number of active async write operations according to the amount of dirty data in the pool. Since both throughput and latency typically increase with the number of concurrent operations issued to physical devices, reducing the burstiness in the number of simultaneous operations also stabilizes the response time of operations from other queues, in particular synchronous ones. In broad strokes, the I/O scheduler will issue more concurrent operations from the async write queue as there is more dirty data in the pool. . .Ss Async Writes The number of concurrent operations issued for the async write I/O class follows a piece-wise linear function defined by a few adjustable points: .Bd -literal | o---------| <-- \fBzfs_vdev_async_write_max_active\fP ^ | /^ | | | / | | active | / | | I/O | / | | count | / | | | / | | |-------o | | <-- \fBzfs_vdev_async_write_min_active\fP 0|_______^______|_________| 0% | | 100% of \fBzfs_dirty_data_max\fP | | | `-- \fBzfs_vdev_async_write_active_max_dirty_percent\fP `--------- \fBzfs_vdev_async_write_active_min_dirty_percent\fP .Ed .Pp Until the amount of dirty data exceeds a minimum percentage of the dirty data allowed in the pool, the I/O scheduler will limit the number of concurrent operations to the minimum. As that threshold is crossed, the number of concurrent operations issued increases linearly to the maximum at the specified maximum percentage of the dirty data allowed in the pool. .Pp Ideally, the amount of dirty data on a busy pool will stay in the sloped part of the function between .Sy zfs_vdev_async_write_active_min_dirty_percent and .Sy zfs_vdev_async_write_active_max_dirty_percent . If it exceeds the maximum percentage, this indicates that the rate of incoming data is greater than the rate that the backend storage can handle. In this case, we must further throttle incoming writes, as described in the next section. . .Sh ZFS TRANSACTION DELAY We delay transactions when we've determined that the backend storage isn't able to accommodate the rate of incoming writes. .Pp If there is already a transaction waiting, we delay relative to when that transaction will finish waiting. This way the calculated delay time is independent of the number of threads concurrently executing transactions. .Pp If we are the only waiter, wait relative to when the transaction started, rather than the current time. This credits the transaction for "time already served", e.g. reading indirect blocks. .Pp The minimum time for a transaction to take is calculated as .D1 min_time = min( Ns Sy zfs_delay_scale No \(mu Po Sy dirty No \- Sy min Pc / Po Sy max No \- Sy dirty Pc , 100ms) .Pp The delay has two degrees of freedom that can be adjusted via tunables. The percentage of dirty data at which we start to delay is defined by .Sy zfs_delay_min_dirty_percent . This should typically be at or above .Sy zfs_vdev_async_write_active_max_dirty_percent , so that we only start to delay after writing at full speed has failed to keep up with the incoming write rate. The scale of the curve is defined by .Sy zfs_delay_scale . Roughly speaking, this variable determines the amount of delay at the midpoint of the curve. .Bd -literal delay 10ms +-------------------------------------------------------------*+ | *| 9ms + *+ | *| 8ms + *+ | * | 7ms + * + | * | 6ms + * + | * | 5ms + * + | * | 4ms + * + | * | 3ms + * + | * | 2ms + (midpoint) * + | | ** | 1ms + v *** + | \fBzfs_delay_scale\fP ----------> ******** | 0 +-------------------------------------*********----------------+ 0% <- \fBzfs_dirty_data_max\fP -> 100% .Ed .Pp Note, that since the delay is added to the outstanding time remaining on the most recent transaction it's effectively the inverse of IOPS. Here, the midpoint of .Em 500 us translates to .Em 2000 IOPS . The shape of the curve was chosen such that small changes in the amount of accumulated dirty data in the first three quarters of the curve yield relatively small differences in the amount of delay. .Pp The effects can be easier to understand when the amount of delay is represented on a logarithmic scale: .Bd -literal delay 100ms +-------------------------------------------------------------++ + + | | + *+ 10ms + *+ + ** + | (midpoint) ** | + | ** + 1ms + v **** + + \fBzfs_delay_scale\fP ----------> ***** + | **** | + **** + 100us + ** + + * + | * | + * + 10us + * + + + | | + + +--------------------------------------------------------------+ 0% <- \fBzfs_dirty_data_max\fP -> 100% .Ed .Pp Note here that only as the amount of dirty data approaches its limit does the delay start to increase rapidly. The goal of a properly tuned system should be to keep the amount of dirty data out of that range by first ensuring that the appropriate limits are set for the I/O scheduler to reach optimal throughput on the back-end storage, and then by changing the value of .Sy zfs_delay_scale to increase the steepness of the curve. diff --git a/sys/contrib/openzfs/module/os/freebsd/spl/spl_taskq.c b/sys/contrib/openzfs/module/os/freebsd/spl/spl_taskq.c index b31810d57f59..3fba5ed3c228 100644 --- a/sys/contrib/openzfs/module/os/freebsd/spl/spl_taskq.c +++ b/sys/contrib/openzfs/module/os/freebsd/spl/spl_taskq.c @@ -1,449 +1,447 @@ /* * Copyright (c) 2009 Pawel Jakub Dawidek * All rights reserved. * * Copyright (c) 2012 Spectra Logic Corporation. All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHORS AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHORS OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ #include __FBSDID("$FreeBSD$"); #include -#include -#include #include #include #include #include #include #include #include #include #if defined(__i386__) || defined(__amd64__) || defined(__aarch64__) #include #endif #include #if __FreeBSD_version < 1201522 #define taskqueue_start_threads_in_proc(tqp, count, pri, proc, name, ...) \ taskqueue_start_threads(tqp, count, pri, name, __VA_ARGS__) #endif static uint_t taskq_tsd; static uma_zone_t taskq_zone; /* * Global system-wide dynamic task queue available for all consumers. This * taskq is not intended for long-running tasks; instead, a dedicated taskq * should be created. */ taskq_t *system_taskq = NULL; taskq_t *system_delay_taskq = NULL; taskq_t *dynamic_taskq = NULL; proc_t *system_proc; -extern int uma_align_cache; - static MALLOC_DEFINE(M_TASKQ, "taskq", "taskq structures"); -static CK_LIST_HEAD(tqenthashhead, taskq_ent) *tqenthashtbl; +static LIST_HEAD(tqenthashhead, taskq_ent) *tqenthashtbl; static unsigned long tqenthash; static unsigned long tqenthashlock; static struct sx *tqenthashtbl_lock; static taskqid_t tqidnext; #define TQIDHASH(tqid) (&tqenthashtbl[(tqid) & tqenthash]) #define TQIDHASHLOCK(tqid) (&tqenthashtbl_lock[((tqid) & tqenthashlock)]) +#define NORMAL_TASK 0 #define TIMEOUT_TASK 1 -#define NORMAL_TASK 2 static void system_taskq_init(void *arg) { int i; tsd_create(&taskq_tsd, NULL); tqenthashtbl = hashinit(mp_ncpus * 8, M_TASKQ, &tqenthash); tqenthashlock = (tqenthash + 1) / 8; if (tqenthashlock > 0) tqenthashlock--; tqenthashtbl_lock = malloc(sizeof (*tqenthashtbl_lock) * (tqenthashlock + 1), M_TASKQ, M_WAITOK | M_ZERO); for (i = 0; i < tqenthashlock + 1; i++) sx_init_flags(&tqenthashtbl_lock[i], "tqenthash", SX_DUPOK); taskq_zone = uma_zcreate("taskq_zone", sizeof (taskq_ent_t), NULL, NULL, NULL, NULL, UMA_ALIGN_CACHE, 0); system_taskq = taskq_create("system_taskq", mp_ncpus, minclsyspri, 0, 0, 0); system_delay_taskq = taskq_create("system_delay_taskq", mp_ncpus, minclsyspri, 0, 0, 0); } SYSINIT(system_taskq_init, SI_SUB_CONFIGURE, SI_ORDER_ANY, system_taskq_init, NULL); static void system_taskq_fini(void *arg) { int i; taskq_destroy(system_delay_taskq); taskq_destroy(system_taskq); uma_zdestroy(taskq_zone); tsd_destroy(&taskq_tsd); for (i = 0; i < tqenthashlock + 1; i++) sx_destroy(&tqenthashtbl_lock[i]); for (i = 0; i < tqenthash + 1; i++) - VERIFY(CK_LIST_EMPTY(&tqenthashtbl[i])); + VERIFY(LIST_EMPTY(&tqenthashtbl[i])); free(tqenthashtbl_lock, M_TASKQ); free(tqenthashtbl, M_TASKQ); } SYSUNINIT(system_taskq_fini, SI_SUB_CONFIGURE, SI_ORDER_ANY, system_taskq_fini, NULL); #ifdef __LP64__ static taskqid_t __taskq_genid(void) { taskqid_t tqid; /* * Assume a 64-bit counter will not wrap in practice. */ tqid = atomic_add_64_nv(&tqidnext, 1); VERIFY(tqid); return (tqid); } #else static taskqid_t __taskq_genid(void) { taskqid_t tqid; for (;;) { tqid = atomic_add_32_nv(&tqidnext, 1); if (__predict_true(tqid != 0)) break; } VERIFY(tqid); return (tqid); } #endif static taskq_ent_t * taskq_lookup(taskqid_t tqid) { taskq_ent_t *ent = NULL; - sx_xlock(TQIDHASHLOCK(tqid)); - CK_LIST_FOREACH(ent, TQIDHASH(tqid), tqent_hash) { + if (tqid == 0) + return (NULL); + sx_slock(TQIDHASHLOCK(tqid)); + LIST_FOREACH(ent, TQIDHASH(tqid), tqent_hash) { if (ent->tqent_id == tqid) break; } if (ent != NULL) refcount_acquire(&ent->tqent_rc); - sx_xunlock(TQIDHASHLOCK(tqid)); + sx_sunlock(TQIDHASHLOCK(tqid)); return (ent); } static taskqid_t taskq_insert(taskq_ent_t *ent) { - taskqid_t tqid; + taskqid_t tqid = __taskq_genid(); - tqid = __taskq_genid(); ent->tqent_id = tqid; - ent->tqent_registered = B_TRUE; sx_xlock(TQIDHASHLOCK(tqid)); - CK_LIST_INSERT_HEAD(TQIDHASH(tqid), ent, tqent_hash); + LIST_INSERT_HEAD(TQIDHASH(tqid), ent, tqent_hash); sx_xunlock(TQIDHASHLOCK(tqid)); return (tqid); } static void taskq_remove(taskq_ent_t *ent) { taskqid_t tqid = ent->tqent_id; - if (!ent->tqent_registered) + if (tqid == 0) return; - sx_xlock(TQIDHASHLOCK(tqid)); - CK_LIST_REMOVE(ent, tqent_hash); + if (ent->tqent_id != 0) { + LIST_REMOVE(ent, tqent_hash); + ent->tqent_id = 0; + } sx_xunlock(TQIDHASHLOCK(tqid)); - ent->tqent_registered = B_FALSE; } static void taskq_tsd_set(void *context) { taskq_t *tq = context; #if defined(__amd64__) || defined(__aarch64__) if (context != NULL && tsd_get(taskq_tsd) == NULL) fpu_kern_thread(FPU_KERN_NORMAL); #endif tsd_set(taskq_tsd, tq); } static taskq_t * taskq_create_impl(const char *name, int nthreads, pri_t pri, proc_t *proc __maybe_unused, uint_t flags) { taskq_t *tq; if ((flags & TASKQ_THREADS_CPU_PCT) != 0) nthreads = MAX((mp_ncpus * nthreads) / 100, 1); tq = kmem_alloc(sizeof (*tq), KM_SLEEP); tq->tq_queue = taskqueue_create(name, M_WAITOK, taskqueue_thread_enqueue, &tq->tq_queue); taskqueue_set_callback(tq->tq_queue, TASKQUEUE_CALLBACK_TYPE_INIT, taskq_tsd_set, tq); taskqueue_set_callback(tq->tq_queue, TASKQUEUE_CALLBACK_TYPE_SHUTDOWN, taskq_tsd_set, NULL); (void) taskqueue_start_threads_in_proc(&tq->tq_queue, nthreads, pri, proc, "%s", name); return ((taskq_t *)tq); } taskq_t * taskq_create(const char *name, int nthreads, pri_t pri, int minalloc __unused, int maxalloc __unused, uint_t flags) { return (taskq_create_impl(name, nthreads, pri, system_proc, flags)); } taskq_t * taskq_create_proc(const char *name, int nthreads, pri_t pri, int minalloc __unused, int maxalloc __unused, proc_t *proc, uint_t flags) { return (taskq_create_impl(name, nthreads, pri, proc, flags)); } void taskq_destroy(taskq_t *tq) { taskqueue_free(tq->tq_queue); kmem_free(tq, sizeof (*tq)); } int taskq_member(taskq_t *tq, kthread_t *thread) { return (taskqueue_member(tq->tq_queue, thread)); } taskq_t * taskq_of_curthread(void) { return (tsd_get(taskq_tsd)); } static void taskq_free(taskq_ent_t *task) { taskq_remove(task); if (refcount_release(&task->tqent_rc)) uma_zfree(taskq_zone, task); } int taskq_cancel_id(taskq_t *tq, taskqid_t tid) { uint32_t pend; int rc; taskq_ent_t *ent; - if (tid == 0) - return (0); - if ((ent = taskq_lookup(tid)) == NULL) return (0); - ent->tqent_cancelled = B_TRUE; - if (ent->tqent_type == TIMEOUT_TASK) { + if (ent->tqent_type == NORMAL_TASK) { + rc = taskqueue_cancel(tq->tq_queue, &ent->tqent_task, &pend); + if (rc == EBUSY) + taskqueue_drain(tq->tq_queue, &ent->tqent_task); + } else { rc = taskqueue_cancel_timeout(tq->tq_queue, &ent->tqent_timeout_task, &pend); - } else - rc = taskqueue_cancel(tq->tq_queue, &ent->tqent_task, &pend); - if (rc == EBUSY) { - taskqueue_drain(tq->tq_queue, &ent->tqent_task); - } else if (pend) { + if (rc == EBUSY) { + taskqueue_drain_timeout(tq->tq_queue, + &ent->tqent_timeout_task); + } + } + if (pend) { /* * Tasks normally free themselves when run, but here the task * was cancelled so it did not free itself. */ taskq_free(ent); } /* Free the extra reference we added with taskq_lookup. */ taskq_free(ent); return (rc); } static void -taskq_run(void *arg, int pending __unused) +taskq_run(void *arg, int pending) { taskq_ent_t *task = arg; - if (!task->tqent_cancelled) - task->tqent_func(task->tqent_arg); + if (pending == 0) + return; + task->tqent_func(task->tqent_arg); taskq_free(task); } taskqid_t taskq_dispatch_delay(taskq_t *tq, task_func_t func, void *arg, uint_t flags, clock_t expire_time) { taskq_ent_t *task; taskqid_t tqid; clock_t timo; int mflag; timo = expire_time - ddi_get_lbolt(); if (timo <= 0) return (taskq_dispatch(tq, func, arg, flags)); if ((flags & (TQ_SLEEP | TQ_NOQUEUE)) == TQ_SLEEP) mflag = M_WAITOK; else mflag = M_NOWAIT; task = uma_zalloc(taskq_zone, mflag); if (task == NULL) return (0); task->tqent_func = func; task->tqent_arg = arg; task->tqent_type = TIMEOUT_TASK; - task->tqent_cancelled = B_FALSE; refcount_init(&task->tqent_rc, 1); tqid = taskq_insert(task); TIMEOUT_TASK_INIT(tq->tq_queue, &task->tqent_timeout_task, 0, taskq_run, task); taskqueue_enqueue_timeout(tq->tq_queue, &task->tqent_timeout_task, timo); return (tqid); } taskqid_t taskq_dispatch(taskq_t *tq, task_func_t func, void *arg, uint_t flags) { taskq_ent_t *task; int mflag, prio; taskqid_t tqid; if ((flags & (TQ_SLEEP | TQ_NOQUEUE)) == TQ_SLEEP) mflag = M_WAITOK; else mflag = M_NOWAIT; /* * If TQ_FRONT is given, we want higher priority for this task, so it * can go at the front of the queue. */ prio = !!(flags & TQ_FRONT); task = uma_zalloc(taskq_zone, mflag); if (task == NULL) return (0); refcount_init(&task->tqent_rc, 1); task->tqent_func = func; task->tqent_arg = arg; - task->tqent_cancelled = B_FALSE; task->tqent_type = NORMAL_TASK; tqid = taskq_insert(task); TASK_INIT(&task->tqent_task, prio, taskq_run, task); taskqueue_enqueue(tq->tq_queue, &task->tqent_task); return (tqid); } static void -taskq_run_ent(void *arg, int pending __unused) +taskq_run_ent(void *arg, int pending) { taskq_ent_t *task = arg; + if (pending == 0) + return; task->tqent_func(task->tqent_arg); } void taskq_dispatch_ent(taskq_t *tq, task_func_t func, void *arg, uint32_t flags, taskq_ent_t *task) { int prio; /* * If TQ_FRONT is given, we want higher priority for this task, so it * can go at the front of the queue. */ prio = !!(flags & TQ_FRONT); - task->tqent_cancelled = B_FALSE; - task->tqent_registered = B_FALSE; task->tqent_id = 0; task->tqent_func = func; task->tqent_arg = arg; TASK_INIT(&task->tqent_task, prio, taskq_run_ent, task); taskqueue_enqueue(tq->tq_queue, &task->tqent_task); } void taskq_wait(taskq_t *tq) { taskqueue_quiesce(tq->tq_queue); } void taskq_wait_id(taskq_t *tq, taskqid_t tid) { taskq_ent_t *ent; - if (tid == 0) - return; if ((ent = taskq_lookup(tid)) == NULL) return; - taskqueue_drain(tq->tq_queue, &ent->tqent_task); + if (ent->tqent_type == NORMAL_TASK) + taskqueue_drain(tq->tq_queue, &ent->tqent_task); + else + taskqueue_drain_timeout(tq->tq_queue, &ent->tqent_timeout_task); taskq_free(ent); } void taskq_wait_outstanding(taskq_t *tq, taskqid_t id __unused) { taskqueue_drain_all(tq->tq_queue); } int taskq_empty_ent(taskq_ent_t *t) { return (t->tqent_task.ta_pending == 0); } diff --git a/sys/contrib/openzfs/module/zfs/arc.c b/sys/contrib/openzfs/module/zfs/arc.c index b5946e7604c0..5d4a52fa0693 100644 --- a/sys/contrib/openzfs/module/zfs/arc.c +++ b/sys/contrib/openzfs/module/zfs/arc.c @@ -1,10722 +1,10729 @@ /* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or https://opensource.org/licenses/CDDL-1.0. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright (c) 2005, 2010, Oracle and/or its affiliates. All rights reserved. * Copyright (c) 2018, Joyent, Inc. * Copyright (c) 2011, 2020, Delphix. All rights reserved. * Copyright (c) 2014, Saso Kiselkov. All rights reserved. * Copyright (c) 2017, Nexenta Systems, Inc. All rights reserved. * Copyright (c) 2019, loli10K . All rights reserved. * Copyright (c) 2020, George Amanakis. All rights reserved. * Copyright (c) 2019, Klara Inc. * Copyright (c) 2019, Allan Jude * Copyright (c) 2020, The FreeBSD Foundation [1] * * [1] Portions of this software were developed by Allan Jude * under sponsorship from the FreeBSD Foundation. */ /* * DVA-based Adjustable Replacement Cache * * While much of the theory of operation used here is * based on the self-tuning, low overhead replacement cache * presented by Megiddo and Modha at FAST 2003, there are some * significant differences: * * 1. The Megiddo and Modha model assumes any page is evictable. * Pages in its cache cannot be "locked" into memory. This makes * the eviction algorithm simple: evict the last page in the list. * This also make the performance characteristics easy to reason * about. Our cache is not so simple. At any given moment, some * subset of the blocks in the cache are un-evictable because we * have handed out a reference to them. Blocks are only evictable * when there are no external references active. This makes * eviction far more problematic: we choose to evict the evictable * blocks that are the "lowest" in the list. * * There are times when it is not possible to evict the requested * space. In these circumstances we are unable to adjust the cache * size. To prevent the cache growing unbounded at these times we * implement a "cache throttle" that slows the flow of new data * into the cache until we can make space available. * * 2. The Megiddo and Modha model assumes a fixed cache size. * Pages are evicted when the cache is full and there is a cache * miss. Our model has a variable sized cache. It grows with * high use, but also tries to react to memory pressure from the * operating system: decreasing its size when system memory is * tight. * * 3. The Megiddo and Modha model assumes a fixed page size. All * elements of the cache are therefore exactly the same size. So * when adjusting the cache size following a cache miss, its simply * a matter of choosing a single page to evict. In our model, we * have variable sized cache blocks (ranging from 512 bytes to * 128K bytes). We therefore choose a set of blocks to evict to make * space for a cache miss that approximates as closely as possible * the space used by the new block. * * See also: "ARC: A Self-Tuning, Low Overhead Replacement Cache" * by N. Megiddo & D. Modha, FAST 2003 */ /* * The locking model: * * A new reference to a cache buffer can be obtained in two * ways: 1) via a hash table lookup using the DVA as a key, * or 2) via one of the ARC lists. The arc_read() interface * uses method 1, while the internal ARC algorithms for * adjusting the cache use method 2. We therefore provide two * types of locks: 1) the hash table lock array, and 2) the * ARC list locks. * * Buffers do not have their own mutexes, rather they rely on the * hash table mutexes for the bulk of their protection (i.e. most * fields in the arc_buf_hdr_t are protected by these mutexes). * * buf_hash_find() returns the appropriate mutex (held) when it * locates the requested buffer in the hash table. It returns * NULL for the mutex if the buffer was not in the table. * * buf_hash_remove() expects the appropriate hash mutex to be * already held before it is invoked. * * Each ARC state also has a mutex which is used to protect the * buffer list associated with the state. When attempting to * obtain a hash table lock while holding an ARC list lock you * must use: mutex_tryenter() to avoid deadlock. Also note that * the active state mutex must be held before the ghost state mutex. * * It as also possible to register a callback which is run when the * metadata limit is reached and no buffers can be safely evicted. In * this case the arc user should drop a reference on some arc buffers so * they can be reclaimed. For example, when using the ZPL each dentry * holds a references on a znode. These dentries must be pruned before * the arc buffer holding the znode can be safely evicted. * * Note that the majority of the performance stats are manipulated * with atomic operations. * * The L2ARC uses the l2ad_mtx on each vdev for the following: * * - L2ARC buflist creation * - L2ARC buflist eviction * - L2ARC write completion, which walks L2ARC buflists * - ARC header destruction, as it removes from L2ARC buflists * - ARC header release, as it removes from L2ARC buflists */ /* * ARC operation: * * Every block that is in the ARC is tracked by an arc_buf_hdr_t structure. * This structure can point either to a block that is still in the cache or to * one that is only accessible in an L2 ARC device, or it can provide * information about a block that was recently evicted. If a block is * only accessible in the L2ARC, then the arc_buf_hdr_t only has enough * information to retrieve it from the L2ARC device. This information is * stored in the l2arc_buf_hdr_t sub-structure of the arc_buf_hdr_t. A block * that is in this state cannot access the data directly. * * Blocks that are actively being referenced or have not been evicted * are cached in the L1ARC. The L1ARC (l1arc_buf_hdr_t) is a structure within * the arc_buf_hdr_t that will point to the data block in memory. A block can * only be read by a consumer if it has an l1arc_buf_hdr_t. The L1ARC * caches data in two ways -- in a list of ARC buffers (arc_buf_t) and * also in the arc_buf_hdr_t's private physical data block pointer (b_pabd). * * The L1ARC's data pointer may or may not be uncompressed. The ARC has the * ability to store the physical data (b_pabd) associated with the DVA of the * arc_buf_hdr_t. Since the b_pabd is a copy of the on-disk physical block, * it will match its on-disk compression characteristics. This behavior can be * disabled by setting 'zfs_compressed_arc_enabled' to B_FALSE. When the * compressed ARC functionality is disabled, the b_pabd will point to an * uncompressed version of the on-disk data. * * Data in the L1ARC is not accessed by consumers of the ARC directly. Each * arc_buf_hdr_t can have multiple ARC buffers (arc_buf_t) which reference it. * Each ARC buffer (arc_buf_t) is being actively accessed by a specific ARC * consumer. The ARC will provide references to this data and will keep it * cached until it is no longer in use. The ARC caches only the L1ARC's physical * data block and will evict any arc_buf_t that is no longer referenced. The * amount of memory consumed by the arc_buf_ts' data buffers can be seen via the * "overhead_size" kstat. * * Depending on the consumer, an arc_buf_t can be requested in uncompressed or * compressed form. The typical case is that consumers will want uncompressed * data, and when that happens a new data buffer is allocated where the data is * decompressed for them to use. Currently the only consumer who wants * compressed arc_buf_t's is "zfs send", when it streams data exactly as it * exists on disk. When this happens, the arc_buf_t's data buffer is shared * with the arc_buf_hdr_t. * * Here is a diagram showing an arc_buf_hdr_t referenced by two arc_buf_t's. The * first one is owned by a compressed send consumer (and therefore references * the same compressed data buffer as the arc_buf_hdr_t) and the second could be * used by any other consumer (and has its own uncompressed copy of the data * buffer). * * arc_buf_hdr_t * +-----------+ * | fields | * | common to | * | L1- and | * | L2ARC | * +-----------+ * | l2arc_buf_hdr_t * | | * +-----------+ * | l1arc_buf_hdr_t * | | arc_buf_t * | b_buf +------------>+-----------+ arc_buf_t * | b_pabd +-+ |b_next +---->+-----------+ * +-----------+ | |-----------| |b_next +-->NULL * | |b_comp = T | +-----------+ * | |b_data +-+ |b_comp = F | * | +-----------+ | |b_data +-+ * +->+------+ | +-----------+ | * compressed | | | | * data | |<--------------+ | uncompressed * +------+ compressed, | data * shared +-->+------+ * data | | * | | * +------+ * * When a consumer reads a block, the ARC must first look to see if the * arc_buf_hdr_t is cached. If the hdr is cached then the ARC allocates a new * arc_buf_t and either copies uncompressed data into a new data buffer from an * existing uncompressed arc_buf_t, decompresses the hdr's b_pabd buffer into a * new data buffer, or shares the hdr's b_pabd buffer, depending on whether the * hdr is compressed and the desired compression characteristics of the * arc_buf_t consumer. If the arc_buf_t ends up sharing data with the * arc_buf_hdr_t and both of them are uncompressed then the arc_buf_t must be * the last buffer in the hdr's b_buf list, however a shared compressed buf can * be anywhere in the hdr's list. * * The diagram below shows an example of an uncompressed ARC hdr that is * sharing its data with an arc_buf_t (note that the shared uncompressed buf is * the last element in the buf list): * * arc_buf_hdr_t * +-----------+ * | | * | | * | | * +-----------+ * l2arc_buf_hdr_t| | * | | * +-----------+ * l1arc_buf_hdr_t| | * | | arc_buf_t (shared) * | b_buf +------------>+---------+ arc_buf_t * | | |b_next +---->+---------+ * | b_pabd +-+ |---------| |b_next +-->NULL * +-----------+ | | | +---------+ * | |b_data +-+ | | * | +---------+ | |b_data +-+ * +->+------+ | +---------+ | * | | | | * uncompressed | | | | * data +------+ | | * ^ +->+------+ | * | uncompressed | | | * | data | | | * | +------+ | * +---------------------------------+ * * Writing to the ARC requires that the ARC first discard the hdr's b_pabd * since the physical block is about to be rewritten. The new data contents * will be contained in the arc_buf_t. As the I/O pipeline performs the write, * it may compress the data before writing it to disk. The ARC will be called * with the transformed data and will memcpy the transformed on-disk block into * a newly allocated b_pabd. Writes are always done into buffers which have * either been loaned (and hence are new and don't have other readers) or * buffers which have been released (and hence have their own hdr, if there * were originally other readers of the buf's original hdr). This ensures that * the ARC only needs to update a single buf and its hdr after a write occurs. * * When the L2ARC is in use, it will also take advantage of the b_pabd. The * L2ARC will always write the contents of b_pabd to the L2ARC. This means * that when compressed ARC is enabled that the L2ARC blocks are identical * to the on-disk block in the main data pool. This provides a significant * advantage since the ARC can leverage the bp's checksum when reading from the * L2ARC to determine if the contents are valid. However, if the compressed * ARC is disabled, then the L2ARC's block must be transformed to look * like the physical block in the main data pool before comparing the * checksum and determining its validity. * * The L1ARC has a slightly different system for storing encrypted data. * Raw (encrypted + possibly compressed) data has a few subtle differences from * data that is just compressed. The biggest difference is that it is not * possible to decrypt encrypted data (or vice-versa) if the keys aren't loaded. * The other difference is that encryption cannot be treated as a suggestion. * If a caller would prefer compressed data, but they actually wind up with * uncompressed data the worst thing that could happen is there might be a * performance hit. If the caller requests encrypted data, however, we must be * sure they actually get it or else secret information could be leaked. Raw * data is stored in hdr->b_crypt_hdr.b_rabd. An encrypted header, therefore, * may have both an encrypted version and a decrypted version of its data at * once. When a caller needs a raw arc_buf_t, it is allocated and the data is * copied out of this header. To avoid complications with b_pabd, raw buffers * cannot be shared. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifndef _KERNEL /* set with ZFS_DEBUG=watch, to enable watchpoints on frozen buffers */ boolean_t arc_watch = B_FALSE; #endif /* * This thread's job is to keep enough free memory in the system, by * calling arc_kmem_reap_soon() plus arc_reduce_target_size(), which improves * arc_available_memory(). */ static zthr_t *arc_reap_zthr; /* * This thread's job is to keep arc_size under arc_c, by calling * arc_evict(), which improves arc_is_overflowing(). */ static zthr_t *arc_evict_zthr; static arc_buf_hdr_t **arc_state_evict_markers; static int arc_state_evict_marker_count; static kmutex_t arc_evict_lock; static boolean_t arc_evict_needed = B_FALSE; static clock_t arc_last_uncached_flush; /* * Count of bytes evicted since boot. */ static uint64_t arc_evict_count; /* * List of arc_evict_waiter_t's, representing threads waiting for the * arc_evict_count to reach specific values. */ static list_t arc_evict_waiters; /* * When arc_is_overflowing(), arc_get_data_impl() waits for this percent of * the requested amount of data to be evicted. For example, by default for * every 2KB that's evicted, 1KB of it may be "reused" by a new allocation. * Since this is above 100%, it ensures that progress is made towards getting * arc_size under arc_c. Since this is finite, it ensures that allocations * can still happen, even during the potentially long time that arc_size is * more than arc_c. */ static uint_t zfs_arc_eviction_pct = 200; /* * The number of headers to evict in arc_evict_state_impl() before * dropping the sublist lock and evicting from another sublist. A lower * value means we're more likely to evict the "correct" header (i.e. the * oldest header in the arc state), but comes with higher overhead * (i.e. more invocations of arc_evict_state_impl()). */ static uint_t zfs_arc_evict_batch_limit = 10; /* number of seconds before growing cache again */ uint_t arc_grow_retry = 5; /* * Minimum time between calls to arc_kmem_reap_soon(). */ static const int arc_kmem_cache_reap_retry_ms = 1000; /* shift of arc_c for calculating overflow limit in arc_get_data_impl */ static int zfs_arc_overflow_shift = 8; /* log2(fraction of arc to reclaim) */ uint_t arc_shrink_shift = 7; /* percent of pagecache to reclaim arc to */ #ifdef _KERNEL uint_t zfs_arc_pc_percent = 0; #endif /* * log2(fraction of ARC which must be free to allow growing). * I.e. If there is less than arc_c >> arc_no_grow_shift free memory, * when reading a new block into the ARC, we will evict an equal-sized block * from the ARC. * * This must be less than arc_shrink_shift, so that when we shrink the ARC, * we will still not allow it to grow. */ uint_t arc_no_grow_shift = 5; /* * minimum lifespan of a prefetch block in clock ticks * (initialized in arc_init()) */ static uint_t arc_min_prefetch_ms; static uint_t arc_min_prescient_prefetch_ms; /* * If this percent of memory is free, don't throttle. */ uint_t arc_lotsfree_percent = 10; /* * The arc has filled available memory and has now warmed up. */ boolean_t arc_warm; /* * These tunables are for performance analysis. */ uint64_t zfs_arc_max = 0; uint64_t zfs_arc_min = 0; static uint64_t zfs_arc_dnode_limit = 0; static uint_t zfs_arc_dnode_reduce_percent = 10; static uint_t zfs_arc_grow_retry = 0; static uint_t zfs_arc_shrink_shift = 0; uint_t zfs_arc_average_blocksize = 8 * 1024; /* 8KB */ /* * ARC dirty data constraints for arc_tempreserve_space() throttle: * * total dirty data limit * * anon block dirty limit * * each pool's anon allowance */ static const unsigned long zfs_arc_dirty_limit_percent = 50; static const unsigned long zfs_arc_anon_limit_percent = 25; static const unsigned long zfs_arc_pool_dirty_percent = 20; /* * Enable or disable compressed arc buffers. */ int zfs_compressed_arc_enabled = B_TRUE; /* * Balance between metadata and data on ghost hits. Values above 100 * increase metadata caching by proportionally reducing effect of ghost * data hits on target data/metadata rate. */ static uint_t zfs_arc_meta_balance = 500; /* * Percentage that can be consumed by dnodes of ARC meta buffers. */ static uint_t zfs_arc_dnode_limit_percent = 10; /* * These tunables are Linux-specific */ static uint64_t zfs_arc_sys_free = 0; static uint_t zfs_arc_min_prefetch_ms = 0; static uint_t zfs_arc_min_prescient_prefetch_ms = 0; static uint_t zfs_arc_lotsfree_percent = 10; /* * Number of arc_prune threads */ static int zfs_arc_prune_task_threads = 1; /* The 7 states: */ arc_state_t ARC_anon; arc_state_t ARC_mru; arc_state_t ARC_mru_ghost; arc_state_t ARC_mfu; arc_state_t ARC_mfu_ghost; arc_state_t ARC_l2c_only; arc_state_t ARC_uncached; arc_stats_t arc_stats = { { "hits", KSTAT_DATA_UINT64 }, { "iohits", KSTAT_DATA_UINT64 }, { "misses", KSTAT_DATA_UINT64 }, { "demand_data_hits", KSTAT_DATA_UINT64 }, { "demand_data_iohits", KSTAT_DATA_UINT64 }, { "demand_data_misses", KSTAT_DATA_UINT64 }, { "demand_metadata_hits", KSTAT_DATA_UINT64 }, { "demand_metadata_iohits", KSTAT_DATA_UINT64 }, { "demand_metadata_misses", KSTAT_DATA_UINT64 }, { "prefetch_data_hits", KSTAT_DATA_UINT64 }, { "prefetch_data_iohits", KSTAT_DATA_UINT64 }, { "prefetch_data_misses", KSTAT_DATA_UINT64 }, { "prefetch_metadata_hits", KSTAT_DATA_UINT64 }, { "prefetch_metadata_iohits", KSTAT_DATA_UINT64 }, { "prefetch_metadata_misses", KSTAT_DATA_UINT64 }, { "mru_hits", KSTAT_DATA_UINT64 }, { "mru_ghost_hits", KSTAT_DATA_UINT64 }, { "mfu_hits", KSTAT_DATA_UINT64 }, { "mfu_ghost_hits", KSTAT_DATA_UINT64 }, { "uncached_hits", KSTAT_DATA_UINT64 }, { "deleted", KSTAT_DATA_UINT64 }, { "mutex_miss", KSTAT_DATA_UINT64 }, { "access_skip", KSTAT_DATA_UINT64 }, { "evict_skip", KSTAT_DATA_UINT64 }, { "evict_not_enough", KSTAT_DATA_UINT64 }, { "evict_l2_cached", KSTAT_DATA_UINT64 }, { "evict_l2_eligible", KSTAT_DATA_UINT64 }, { "evict_l2_eligible_mfu", KSTAT_DATA_UINT64 }, { "evict_l2_eligible_mru", KSTAT_DATA_UINT64 }, { "evict_l2_ineligible", KSTAT_DATA_UINT64 }, { "evict_l2_skip", KSTAT_DATA_UINT64 }, { "hash_elements", KSTAT_DATA_UINT64 }, { "hash_elements_max", KSTAT_DATA_UINT64 }, { "hash_collisions", KSTAT_DATA_UINT64 }, { "hash_chains", KSTAT_DATA_UINT64 }, { "hash_chain_max", KSTAT_DATA_UINT64 }, { "meta", KSTAT_DATA_UINT64 }, { "pd", KSTAT_DATA_UINT64 }, { "pm", KSTAT_DATA_UINT64 }, { "c", KSTAT_DATA_UINT64 }, { "c_min", KSTAT_DATA_UINT64 }, { "c_max", KSTAT_DATA_UINT64 }, { "size", KSTAT_DATA_UINT64 }, { "compressed_size", KSTAT_DATA_UINT64 }, { "uncompressed_size", KSTAT_DATA_UINT64 }, { "overhead_size", KSTAT_DATA_UINT64 }, { "hdr_size", KSTAT_DATA_UINT64 }, { "data_size", KSTAT_DATA_UINT64 }, { "metadata_size", KSTAT_DATA_UINT64 }, { "dbuf_size", KSTAT_DATA_UINT64 }, { "dnode_size", KSTAT_DATA_UINT64 }, { "bonus_size", KSTAT_DATA_UINT64 }, #if defined(COMPAT_FREEBSD11) { "other_size", KSTAT_DATA_UINT64 }, #endif { "anon_size", KSTAT_DATA_UINT64 }, { "anon_data", KSTAT_DATA_UINT64 }, { "anon_metadata", KSTAT_DATA_UINT64 }, { "anon_evictable_data", KSTAT_DATA_UINT64 }, { "anon_evictable_metadata", KSTAT_DATA_UINT64 }, { "mru_size", KSTAT_DATA_UINT64 }, { "mru_data", KSTAT_DATA_UINT64 }, { "mru_metadata", KSTAT_DATA_UINT64 }, { "mru_evictable_data", KSTAT_DATA_UINT64 }, { "mru_evictable_metadata", KSTAT_DATA_UINT64 }, { "mru_ghost_size", KSTAT_DATA_UINT64 }, { "mru_ghost_data", KSTAT_DATA_UINT64 }, { "mru_ghost_metadata", KSTAT_DATA_UINT64 }, { "mru_ghost_evictable_data", KSTAT_DATA_UINT64 }, { "mru_ghost_evictable_metadata", KSTAT_DATA_UINT64 }, { "mfu_size", KSTAT_DATA_UINT64 }, { "mfu_data", KSTAT_DATA_UINT64 }, { "mfu_metadata", KSTAT_DATA_UINT64 }, { "mfu_evictable_data", KSTAT_DATA_UINT64 }, { "mfu_evictable_metadata", KSTAT_DATA_UINT64 }, { "mfu_ghost_size", KSTAT_DATA_UINT64 }, { "mfu_ghost_data", KSTAT_DATA_UINT64 }, { "mfu_ghost_metadata", KSTAT_DATA_UINT64 }, { "mfu_ghost_evictable_data", KSTAT_DATA_UINT64 }, { "mfu_ghost_evictable_metadata", KSTAT_DATA_UINT64 }, { "uncached_size", KSTAT_DATA_UINT64 }, { "uncached_data", KSTAT_DATA_UINT64 }, { "uncached_metadata", KSTAT_DATA_UINT64 }, { "uncached_evictable_data", KSTAT_DATA_UINT64 }, { "uncached_evictable_metadata", KSTAT_DATA_UINT64 }, { "l2_hits", KSTAT_DATA_UINT64 }, { "l2_misses", KSTAT_DATA_UINT64 }, { "l2_prefetch_asize", KSTAT_DATA_UINT64 }, { "l2_mru_asize", KSTAT_DATA_UINT64 }, { "l2_mfu_asize", KSTAT_DATA_UINT64 }, { "l2_bufc_data_asize", KSTAT_DATA_UINT64 }, { "l2_bufc_metadata_asize", KSTAT_DATA_UINT64 }, { "l2_feeds", KSTAT_DATA_UINT64 }, { "l2_rw_clash", KSTAT_DATA_UINT64 }, { "l2_read_bytes", KSTAT_DATA_UINT64 }, { "l2_write_bytes", KSTAT_DATA_UINT64 }, { "l2_writes_sent", KSTAT_DATA_UINT64 }, { "l2_writes_done", KSTAT_DATA_UINT64 }, { "l2_writes_error", KSTAT_DATA_UINT64 }, { "l2_writes_lock_retry", KSTAT_DATA_UINT64 }, { "l2_evict_lock_retry", KSTAT_DATA_UINT64 }, { "l2_evict_reading", KSTAT_DATA_UINT64 }, { "l2_evict_l1cached", KSTAT_DATA_UINT64 }, { "l2_free_on_write", KSTAT_DATA_UINT64 }, { "l2_abort_lowmem", KSTAT_DATA_UINT64 }, { "l2_cksum_bad", KSTAT_DATA_UINT64 }, { "l2_io_error", KSTAT_DATA_UINT64 }, { "l2_size", KSTAT_DATA_UINT64 }, { "l2_asize", KSTAT_DATA_UINT64 }, { "l2_hdr_size", KSTAT_DATA_UINT64 }, { "l2_log_blk_writes", KSTAT_DATA_UINT64 }, { "l2_log_blk_avg_asize", KSTAT_DATA_UINT64 }, { "l2_log_blk_asize", KSTAT_DATA_UINT64 }, { "l2_log_blk_count", KSTAT_DATA_UINT64 }, { "l2_data_to_meta_ratio", KSTAT_DATA_UINT64 }, { "l2_rebuild_success", KSTAT_DATA_UINT64 }, { "l2_rebuild_unsupported", KSTAT_DATA_UINT64 }, { "l2_rebuild_io_errors", KSTAT_DATA_UINT64 }, { "l2_rebuild_dh_errors", KSTAT_DATA_UINT64 }, { "l2_rebuild_cksum_lb_errors", KSTAT_DATA_UINT64 }, { "l2_rebuild_lowmem", KSTAT_DATA_UINT64 }, { "l2_rebuild_size", KSTAT_DATA_UINT64 }, { "l2_rebuild_asize", KSTAT_DATA_UINT64 }, { "l2_rebuild_bufs", KSTAT_DATA_UINT64 }, { "l2_rebuild_bufs_precached", KSTAT_DATA_UINT64 }, { "l2_rebuild_log_blks", KSTAT_DATA_UINT64 }, { "memory_throttle_count", KSTAT_DATA_UINT64 }, { "memory_direct_count", KSTAT_DATA_UINT64 }, { "memory_indirect_count", KSTAT_DATA_UINT64 }, { "memory_all_bytes", KSTAT_DATA_UINT64 }, { "memory_free_bytes", KSTAT_DATA_UINT64 }, { "memory_available_bytes", KSTAT_DATA_INT64 }, { "arc_no_grow", KSTAT_DATA_UINT64 }, { "arc_tempreserve", KSTAT_DATA_UINT64 }, { "arc_loaned_bytes", KSTAT_DATA_UINT64 }, { "arc_prune", KSTAT_DATA_UINT64 }, { "arc_meta_used", KSTAT_DATA_UINT64 }, { "arc_dnode_limit", KSTAT_DATA_UINT64 }, { "async_upgrade_sync", KSTAT_DATA_UINT64 }, { "predictive_prefetch", KSTAT_DATA_UINT64 }, { "demand_hit_predictive_prefetch", KSTAT_DATA_UINT64 }, { "demand_iohit_predictive_prefetch", KSTAT_DATA_UINT64 }, { "prescient_prefetch", KSTAT_DATA_UINT64 }, { "demand_hit_prescient_prefetch", KSTAT_DATA_UINT64 }, { "demand_iohit_prescient_prefetch", KSTAT_DATA_UINT64 }, { "arc_need_free", KSTAT_DATA_UINT64 }, { "arc_sys_free", KSTAT_DATA_UINT64 }, { "arc_raw_size", KSTAT_DATA_UINT64 }, { "cached_only_in_progress", KSTAT_DATA_UINT64 }, { "abd_chunk_waste_size", KSTAT_DATA_UINT64 }, }; arc_sums_t arc_sums; #define ARCSTAT_MAX(stat, val) { \ uint64_t m; \ while ((val) > (m = arc_stats.stat.value.ui64) && \ (m != atomic_cas_64(&arc_stats.stat.value.ui64, m, (val)))) \ continue; \ } /* * We define a macro to allow ARC hits/misses to be easily broken down by * two separate conditions, giving a total of four different subtypes for * each of hits and misses (so eight statistics total). */ #define ARCSTAT_CONDSTAT(cond1, stat1, notstat1, cond2, stat2, notstat2, stat) \ if (cond1) { \ if (cond2) { \ ARCSTAT_BUMP(arcstat_##stat1##_##stat2##_##stat); \ } else { \ ARCSTAT_BUMP(arcstat_##stat1##_##notstat2##_##stat); \ } \ } else { \ if (cond2) { \ ARCSTAT_BUMP(arcstat_##notstat1##_##stat2##_##stat); \ } else { \ ARCSTAT_BUMP(arcstat_##notstat1##_##notstat2##_##stat);\ } \ } /* * This macro allows us to use kstats as floating averages. Each time we * update this kstat, we first factor it and the update value by * ARCSTAT_AVG_FACTOR to shrink the new value's contribution to the overall * average. This macro assumes that integer loads and stores are atomic, but * is not safe for multiple writers updating the kstat in parallel (only the * last writer's update will remain). */ #define ARCSTAT_F_AVG_FACTOR 3 #define ARCSTAT_F_AVG(stat, value) \ do { \ uint64_t x = ARCSTAT(stat); \ x = x - x / ARCSTAT_F_AVG_FACTOR + \ (value) / ARCSTAT_F_AVG_FACTOR; \ ARCSTAT(stat) = x; \ } while (0) static kstat_t *arc_ksp; /* * There are several ARC variables that are critical to export as kstats -- * but we don't want to have to grovel around in the kstat whenever we wish to * manipulate them. For these variables, we therefore define them to be in * terms of the statistic variable. This assures that we are not introducing * the possibility of inconsistency by having shadow copies of the variables, * while still allowing the code to be readable. */ #define arc_tempreserve ARCSTAT(arcstat_tempreserve) #define arc_loaned_bytes ARCSTAT(arcstat_loaned_bytes) #define arc_dnode_limit ARCSTAT(arcstat_dnode_limit) /* max size for dnodes */ #define arc_need_free ARCSTAT(arcstat_need_free) /* waiting to be evicted */ hrtime_t arc_growtime; list_t arc_prune_list; kmutex_t arc_prune_mtx; taskq_t *arc_prune_taskq; #define GHOST_STATE(state) \ ((state) == arc_mru_ghost || (state) == arc_mfu_ghost || \ (state) == arc_l2c_only) #define HDR_IN_HASH_TABLE(hdr) ((hdr)->b_flags & ARC_FLAG_IN_HASH_TABLE) #define HDR_IO_IN_PROGRESS(hdr) ((hdr)->b_flags & ARC_FLAG_IO_IN_PROGRESS) #define HDR_IO_ERROR(hdr) ((hdr)->b_flags & ARC_FLAG_IO_ERROR) #define HDR_PREFETCH(hdr) ((hdr)->b_flags & ARC_FLAG_PREFETCH) #define HDR_PRESCIENT_PREFETCH(hdr) \ ((hdr)->b_flags & ARC_FLAG_PRESCIENT_PREFETCH) #define HDR_COMPRESSION_ENABLED(hdr) \ ((hdr)->b_flags & ARC_FLAG_COMPRESSED_ARC) #define HDR_L2CACHE(hdr) ((hdr)->b_flags & ARC_FLAG_L2CACHE) #define HDR_UNCACHED(hdr) ((hdr)->b_flags & ARC_FLAG_UNCACHED) #define HDR_L2_READING(hdr) \ (((hdr)->b_flags & ARC_FLAG_IO_IN_PROGRESS) && \ ((hdr)->b_flags & ARC_FLAG_HAS_L2HDR)) #define HDR_L2_WRITING(hdr) ((hdr)->b_flags & ARC_FLAG_L2_WRITING) #define HDR_L2_EVICTED(hdr) ((hdr)->b_flags & ARC_FLAG_L2_EVICTED) #define HDR_L2_WRITE_HEAD(hdr) ((hdr)->b_flags & ARC_FLAG_L2_WRITE_HEAD) #define HDR_PROTECTED(hdr) ((hdr)->b_flags & ARC_FLAG_PROTECTED) #define HDR_NOAUTH(hdr) ((hdr)->b_flags & ARC_FLAG_NOAUTH) #define HDR_SHARED_DATA(hdr) ((hdr)->b_flags & ARC_FLAG_SHARED_DATA) #define HDR_ISTYPE_METADATA(hdr) \ ((hdr)->b_flags & ARC_FLAG_BUFC_METADATA) #define HDR_ISTYPE_DATA(hdr) (!HDR_ISTYPE_METADATA(hdr)) #define HDR_HAS_L1HDR(hdr) ((hdr)->b_flags & ARC_FLAG_HAS_L1HDR) #define HDR_HAS_L2HDR(hdr) ((hdr)->b_flags & ARC_FLAG_HAS_L2HDR) #define HDR_HAS_RABD(hdr) \ (HDR_HAS_L1HDR(hdr) && HDR_PROTECTED(hdr) && \ (hdr)->b_crypt_hdr.b_rabd != NULL) #define HDR_ENCRYPTED(hdr) \ (HDR_PROTECTED(hdr) && DMU_OT_IS_ENCRYPTED((hdr)->b_crypt_hdr.b_ot)) #define HDR_AUTHENTICATED(hdr) \ (HDR_PROTECTED(hdr) && !DMU_OT_IS_ENCRYPTED((hdr)->b_crypt_hdr.b_ot)) /* For storing compression mode in b_flags */ #define HDR_COMPRESS_OFFSET (highbit64(ARC_FLAG_COMPRESS_0) - 1) #define HDR_GET_COMPRESS(hdr) ((enum zio_compress)BF32_GET((hdr)->b_flags, \ HDR_COMPRESS_OFFSET, SPA_COMPRESSBITS)) #define HDR_SET_COMPRESS(hdr, cmp) BF32_SET((hdr)->b_flags, \ HDR_COMPRESS_OFFSET, SPA_COMPRESSBITS, (cmp)); #define ARC_BUF_LAST(buf) ((buf)->b_next == NULL) #define ARC_BUF_SHARED(buf) ((buf)->b_flags & ARC_BUF_FLAG_SHARED) #define ARC_BUF_COMPRESSED(buf) ((buf)->b_flags & ARC_BUF_FLAG_COMPRESSED) #define ARC_BUF_ENCRYPTED(buf) ((buf)->b_flags & ARC_BUF_FLAG_ENCRYPTED) /* * Other sizes */ #define HDR_FULL_SIZE ((int64_t)sizeof (arc_buf_hdr_t)) #define HDR_L2ONLY_SIZE ((int64_t)offsetof(arc_buf_hdr_t, b_l1hdr)) /* * Hash table routines */ #define BUF_LOCKS 2048 typedef struct buf_hash_table { uint64_t ht_mask; arc_buf_hdr_t **ht_table; kmutex_t ht_locks[BUF_LOCKS] ____cacheline_aligned; } buf_hash_table_t; static buf_hash_table_t buf_hash_table; #define BUF_HASH_INDEX(spa, dva, birth) \ (buf_hash(spa, dva, birth) & buf_hash_table.ht_mask) #define BUF_HASH_LOCK(idx) (&buf_hash_table.ht_locks[idx & (BUF_LOCKS-1)]) #define HDR_LOCK(hdr) \ (BUF_HASH_LOCK(BUF_HASH_INDEX(hdr->b_spa, &hdr->b_dva, hdr->b_birth))) uint64_t zfs_crc64_table[256]; /* * Level 2 ARC */ #define L2ARC_WRITE_SIZE (8 * 1024 * 1024) /* initial write max */ #define L2ARC_HEADROOM 2 /* num of writes */ /* * If we discover during ARC scan any buffers to be compressed, we boost * our headroom for the next scanning cycle by this percentage multiple. */ #define L2ARC_HEADROOM_BOOST 200 #define L2ARC_FEED_SECS 1 /* caching interval secs */ #define L2ARC_FEED_MIN_MS 200 /* min caching interval ms */ /* * We can feed L2ARC from two states of ARC buffers, mru and mfu, * and each of the state has two types: data and metadata. */ #define L2ARC_FEED_TYPES 4 /* L2ARC Performance Tunables */ uint64_t l2arc_write_max = L2ARC_WRITE_SIZE; /* def max write size */ uint64_t l2arc_write_boost = L2ARC_WRITE_SIZE; /* extra warmup write */ uint64_t l2arc_headroom = L2ARC_HEADROOM; /* # of dev writes */ uint64_t l2arc_headroom_boost = L2ARC_HEADROOM_BOOST; uint64_t l2arc_feed_secs = L2ARC_FEED_SECS; /* interval seconds */ uint64_t l2arc_feed_min_ms = L2ARC_FEED_MIN_MS; /* min interval msecs */ int l2arc_noprefetch = B_TRUE; /* don't cache prefetch bufs */ int l2arc_feed_again = B_TRUE; /* turbo warmup */ int l2arc_norw = B_FALSE; /* no reads during writes */ static uint_t l2arc_meta_percent = 33; /* limit on headers size */ /* * L2ARC Internals */ static list_t L2ARC_dev_list; /* device list */ static list_t *l2arc_dev_list; /* device list pointer */ static kmutex_t l2arc_dev_mtx; /* device list mutex */ static l2arc_dev_t *l2arc_dev_last; /* last device used */ static list_t L2ARC_free_on_write; /* free after write buf list */ static list_t *l2arc_free_on_write; /* free after write list ptr */ static kmutex_t l2arc_free_on_write_mtx; /* mutex for list */ static uint64_t l2arc_ndev; /* number of devices */ typedef struct l2arc_read_callback { arc_buf_hdr_t *l2rcb_hdr; /* read header */ blkptr_t l2rcb_bp; /* original blkptr */ zbookmark_phys_t l2rcb_zb; /* original bookmark */ int l2rcb_flags; /* original flags */ abd_t *l2rcb_abd; /* temporary buffer */ } l2arc_read_callback_t; typedef struct l2arc_data_free { /* protected by l2arc_free_on_write_mtx */ abd_t *l2df_abd; size_t l2df_size; arc_buf_contents_t l2df_type; list_node_t l2df_list_node; } l2arc_data_free_t; typedef enum arc_fill_flags { ARC_FILL_LOCKED = 1 << 0, /* hdr lock is held */ ARC_FILL_COMPRESSED = 1 << 1, /* fill with compressed data */ ARC_FILL_ENCRYPTED = 1 << 2, /* fill with encrypted data */ ARC_FILL_NOAUTH = 1 << 3, /* don't attempt to authenticate */ ARC_FILL_IN_PLACE = 1 << 4 /* fill in place (special case) */ } arc_fill_flags_t; typedef enum arc_ovf_level { ARC_OVF_NONE, /* ARC within target size. */ ARC_OVF_SOME, /* ARC is slightly overflowed. */ ARC_OVF_SEVERE /* ARC is severely overflowed. */ } arc_ovf_level_t; static kmutex_t l2arc_feed_thr_lock; static kcondvar_t l2arc_feed_thr_cv; static uint8_t l2arc_thread_exit; static kmutex_t l2arc_rebuild_thr_lock; static kcondvar_t l2arc_rebuild_thr_cv; enum arc_hdr_alloc_flags { ARC_HDR_ALLOC_RDATA = 0x1, ARC_HDR_USE_RESERVE = 0x4, ARC_HDR_ALLOC_LINEAR = 0x8, }; static abd_t *arc_get_data_abd(arc_buf_hdr_t *, uint64_t, const void *, int); static void *arc_get_data_buf(arc_buf_hdr_t *, uint64_t, const void *); static void arc_get_data_impl(arc_buf_hdr_t *, uint64_t, const void *, int); static void arc_free_data_abd(arc_buf_hdr_t *, abd_t *, uint64_t, const void *); static void arc_free_data_buf(arc_buf_hdr_t *, void *, uint64_t, const void *); static void arc_free_data_impl(arc_buf_hdr_t *hdr, uint64_t size, const void *tag); static void arc_hdr_free_abd(arc_buf_hdr_t *, boolean_t); static void arc_hdr_alloc_abd(arc_buf_hdr_t *, int); static void arc_hdr_destroy(arc_buf_hdr_t *); static void arc_access(arc_buf_hdr_t *, arc_flags_t, boolean_t); static void arc_buf_watch(arc_buf_t *); static void arc_change_state(arc_state_t *, arc_buf_hdr_t *); static arc_buf_contents_t arc_buf_type(arc_buf_hdr_t *); static uint32_t arc_bufc_to_flags(arc_buf_contents_t); static inline void arc_hdr_set_flags(arc_buf_hdr_t *hdr, arc_flags_t flags); static inline void arc_hdr_clear_flags(arc_buf_hdr_t *hdr, arc_flags_t flags); static boolean_t l2arc_write_eligible(uint64_t, arc_buf_hdr_t *); static void l2arc_read_done(zio_t *); static void l2arc_do_free_on_write(void); static void l2arc_hdr_arcstats_update(arc_buf_hdr_t *hdr, boolean_t incr, boolean_t state_only); #define l2arc_hdr_arcstats_increment(hdr) \ l2arc_hdr_arcstats_update((hdr), B_TRUE, B_FALSE) #define l2arc_hdr_arcstats_decrement(hdr) \ l2arc_hdr_arcstats_update((hdr), B_FALSE, B_FALSE) #define l2arc_hdr_arcstats_increment_state(hdr) \ l2arc_hdr_arcstats_update((hdr), B_TRUE, B_TRUE) #define l2arc_hdr_arcstats_decrement_state(hdr) \ l2arc_hdr_arcstats_update((hdr), B_FALSE, B_TRUE) /* * l2arc_exclude_special : A zfs module parameter that controls whether buffers * present on special vdevs are eligibile for caching in L2ARC. If * set to 1, exclude dbufs on special vdevs from being cached to * L2ARC. */ int l2arc_exclude_special = 0; /* * l2arc_mfuonly : A ZFS module parameter that controls whether only MFU * metadata and data are cached from ARC into L2ARC. */ static int l2arc_mfuonly = 0; /* * L2ARC TRIM * l2arc_trim_ahead : A ZFS module parameter that controls how much ahead of * the current write size (l2arc_write_max) we should TRIM if we * have filled the device. It is defined as a percentage of the * write size. If set to 100 we trim twice the space required to * accommodate upcoming writes. A minimum of 64MB will be trimmed. * It also enables TRIM of the whole L2ARC device upon creation or * addition to an existing pool or if the header of the device is * invalid upon importing a pool or onlining a cache device. The * default is 0, which disables TRIM on L2ARC altogether as it can * put significant stress on the underlying storage devices. This * will vary depending of how well the specific device handles * these commands. */ static uint64_t l2arc_trim_ahead = 0; /* * Performance tuning of L2ARC persistence: * * l2arc_rebuild_enabled : A ZFS module parameter that controls whether adding * an L2ARC device (either at pool import or later) will attempt * to rebuild L2ARC buffer contents. * l2arc_rebuild_blocks_min_l2size : A ZFS module parameter that controls * whether log blocks are written to the L2ARC device. If the L2ARC * device is less than 1GB, the amount of data l2arc_evict() * evicts is significant compared to the amount of restored L2ARC * data. In this case do not write log blocks in L2ARC in order * not to waste space. */ static int l2arc_rebuild_enabled = B_TRUE; static uint64_t l2arc_rebuild_blocks_min_l2size = 1024 * 1024 * 1024; /* L2ARC persistence rebuild control routines. */ void l2arc_rebuild_vdev(vdev_t *vd, boolean_t reopen); static __attribute__((noreturn)) void l2arc_dev_rebuild_thread(void *arg); static int l2arc_rebuild(l2arc_dev_t *dev); /* L2ARC persistence read I/O routines. */ static int l2arc_dev_hdr_read(l2arc_dev_t *dev); static int l2arc_log_blk_read(l2arc_dev_t *dev, const l2arc_log_blkptr_t *this_lp, const l2arc_log_blkptr_t *next_lp, l2arc_log_blk_phys_t *this_lb, l2arc_log_blk_phys_t *next_lb, zio_t *this_io, zio_t **next_io); static zio_t *l2arc_log_blk_fetch(vdev_t *vd, const l2arc_log_blkptr_t *lp, l2arc_log_blk_phys_t *lb); static void l2arc_log_blk_fetch_abort(zio_t *zio); /* L2ARC persistence block restoration routines. */ static void l2arc_log_blk_restore(l2arc_dev_t *dev, const l2arc_log_blk_phys_t *lb, uint64_t lb_asize); static void l2arc_hdr_restore(const l2arc_log_ent_phys_t *le, l2arc_dev_t *dev); /* L2ARC persistence write I/O routines. */ static uint64_t l2arc_log_blk_commit(l2arc_dev_t *dev, zio_t *pio, l2arc_write_callback_t *cb); /* L2ARC persistence auxiliary routines. */ boolean_t l2arc_log_blkptr_valid(l2arc_dev_t *dev, const l2arc_log_blkptr_t *lbp); static boolean_t l2arc_log_blk_insert(l2arc_dev_t *dev, const arc_buf_hdr_t *ab); boolean_t l2arc_range_check_overlap(uint64_t bottom, uint64_t top, uint64_t check); static void l2arc_blk_fetch_done(zio_t *zio); static inline uint64_t l2arc_log_blk_overhead(uint64_t write_sz, l2arc_dev_t *dev); /* * We use Cityhash for this. It's fast, and has good hash properties without * requiring any large static buffers. */ static uint64_t buf_hash(uint64_t spa, const dva_t *dva, uint64_t birth) { return (cityhash4(spa, dva->dva_word[0], dva->dva_word[1], birth)); } #define HDR_EMPTY(hdr) \ ((hdr)->b_dva.dva_word[0] == 0 && \ (hdr)->b_dva.dva_word[1] == 0) #define HDR_EMPTY_OR_LOCKED(hdr) \ (HDR_EMPTY(hdr) || MUTEX_HELD(HDR_LOCK(hdr))) #define HDR_EQUAL(spa, dva, birth, hdr) \ ((hdr)->b_dva.dva_word[0] == (dva)->dva_word[0]) && \ ((hdr)->b_dva.dva_word[1] == (dva)->dva_word[1]) && \ ((hdr)->b_birth == birth) && ((hdr)->b_spa == spa) static void buf_discard_identity(arc_buf_hdr_t *hdr) { hdr->b_dva.dva_word[0] = 0; hdr->b_dva.dva_word[1] = 0; hdr->b_birth = 0; } static arc_buf_hdr_t * buf_hash_find(uint64_t spa, const blkptr_t *bp, kmutex_t **lockp) { const dva_t *dva = BP_IDENTITY(bp); uint64_t birth = BP_PHYSICAL_BIRTH(bp); uint64_t idx = BUF_HASH_INDEX(spa, dva, birth); kmutex_t *hash_lock = BUF_HASH_LOCK(idx); arc_buf_hdr_t *hdr; mutex_enter(hash_lock); for (hdr = buf_hash_table.ht_table[idx]; hdr != NULL; hdr = hdr->b_hash_next) { if (HDR_EQUAL(spa, dva, birth, hdr)) { *lockp = hash_lock; return (hdr); } } mutex_exit(hash_lock); *lockp = NULL; return (NULL); } /* * Insert an entry into the hash table. If there is already an element * equal to elem in the hash table, then the already existing element * will be returned and the new element will not be inserted. * Otherwise returns NULL. * If lockp == NULL, the caller is assumed to already hold the hash lock. */ static arc_buf_hdr_t * buf_hash_insert(arc_buf_hdr_t *hdr, kmutex_t **lockp) { uint64_t idx = BUF_HASH_INDEX(hdr->b_spa, &hdr->b_dva, hdr->b_birth); kmutex_t *hash_lock = BUF_HASH_LOCK(idx); arc_buf_hdr_t *fhdr; uint32_t i; ASSERT(!DVA_IS_EMPTY(&hdr->b_dva)); ASSERT(hdr->b_birth != 0); ASSERT(!HDR_IN_HASH_TABLE(hdr)); if (lockp != NULL) { *lockp = hash_lock; mutex_enter(hash_lock); } else { ASSERT(MUTEX_HELD(hash_lock)); } for (fhdr = buf_hash_table.ht_table[idx], i = 0; fhdr != NULL; fhdr = fhdr->b_hash_next, i++) { if (HDR_EQUAL(hdr->b_spa, &hdr->b_dva, hdr->b_birth, fhdr)) return (fhdr); } hdr->b_hash_next = buf_hash_table.ht_table[idx]; buf_hash_table.ht_table[idx] = hdr; arc_hdr_set_flags(hdr, ARC_FLAG_IN_HASH_TABLE); /* collect some hash table performance data */ if (i > 0) { ARCSTAT_BUMP(arcstat_hash_collisions); if (i == 1) ARCSTAT_BUMP(arcstat_hash_chains); ARCSTAT_MAX(arcstat_hash_chain_max, i); } uint64_t he = atomic_inc_64_nv( &arc_stats.arcstat_hash_elements.value.ui64); ARCSTAT_MAX(arcstat_hash_elements_max, he); return (NULL); } static void buf_hash_remove(arc_buf_hdr_t *hdr) { arc_buf_hdr_t *fhdr, **hdrp; uint64_t idx = BUF_HASH_INDEX(hdr->b_spa, &hdr->b_dva, hdr->b_birth); ASSERT(MUTEX_HELD(BUF_HASH_LOCK(idx))); ASSERT(HDR_IN_HASH_TABLE(hdr)); hdrp = &buf_hash_table.ht_table[idx]; while ((fhdr = *hdrp) != hdr) { ASSERT3P(fhdr, !=, NULL); hdrp = &fhdr->b_hash_next; } *hdrp = hdr->b_hash_next; hdr->b_hash_next = NULL; arc_hdr_clear_flags(hdr, ARC_FLAG_IN_HASH_TABLE); /* collect some hash table performance data */ atomic_dec_64(&arc_stats.arcstat_hash_elements.value.ui64); if (buf_hash_table.ht_table[idx] && buf_hash_table.ht_table[idx]->b_hash_next == NULL) ARCSTAT_BUMPDOWN(arcstat_hash_chains); } /* * Global data structures and functions for the buf kmem cache. */ static kmem_cache_t *hdr_full_cache; static kmem_cache_t *hdr_l2only_cache; static kmem_cache_t *buf_cache; static void buf_fini(void) { #if defined(_KERNEL) /* * Large allocations which do not require contiguous pages * should be using vmem_free() in the linux kernel\ */ vmem_free(buf_hash_table.ht_table, (buf_hash_table.ht_mask + 1) * sizeof (void *)); #else kmem_free(buf_hash_table.ht_table, (buf_hash_table.ht_mask + 1) * sizeof (void *)); #endif for (int i = 0; i < BUF_LOCKS; i++) mutex_destroy(BUF_HASH_LOCK(i)); kmem_cache_destroy(hdr_full_cache); kmem_cache_destroy(hdr_l2only_cache); kmem_cache_destroy(buf_cache); } /* * Constructor callback - called when the cache is empty * and a new buf is requested. */ static int hdr_full_cons(void *vbuf, void *unused, int kmflag) { (void) unused, (void) kmflag; arc_buf_hdr_t *hdr = vbuf; memset(hdr, 0, HDR_FULL_SIZE); hdr->b_l1hdr.b_byteswap = DMU_BSWAP_NUMFUNCS; zfs_refcount_create(&hdr->b_l1hdr.b_refcnt); #ifdef ZFS_DEBUG mutex_init(&hdr->b_l1hdr.b_freeze_lock, NULL, MUTEX_DEFAULT, NULL); #endif multilist_link_init(&hdr->b_l1hdr.b_arc_node); list_link_init(&hdr->b_l2hdr.b_l2node); arc_space_consume(HDR_FULL_SIZE, ARC_SPACE_HDRS); return (0); } static int hdr_l2only_cons(void *vbuf, void *unused, int kmflag) { (void) unused, (void) kmflag; arc_buf_hdr_t *hdr = vbuf; memset(hdr, 0, HDR_L2ONLY_SIZE); arc_space_consume(HDR_L2ONLY_SIZE, ARC_SPACE_L2HDRS); return (0); } static int buf_cons(void *vbuf, void *unused, int kmflag) { (void) unused, (void) kmflag; arc_buf_t *buf = vbuf; memset(buf, 0, sizeof (arc_buf_t)); arc_space_consume(sizeof (arc_buf_t), ARC_SPACE_HDRS); return (0); } /* * Destructor callback - called when a cached buf is * no longer required. */ static void hdr_full_dest(void *vbuf, void *unused) { (void) unused; arc_buf_hdr_t *hdr = vbuf; ASSERT(HDR_EMPTY(hdr)); zfs_refcount_destroy(&hdr->b_l1hdr.b_refcnt); #ifdef ZFS_DEBUG mutex_destroy(&hdr->b_l1hdr.b_freeze_lock); #endif ASSERT(!multilist_link_active(&hdr->b_l1hdr.b_arc_node)); arc_space_return(HDR_FULL_SIZE, ARC_SPACE_HDRS); } static void hdr_l2only_dest(void *vbuf, void *unused) { (void) unused; arc_buf_hdr_t *hdr = vbuf; ASSERT(HDR_EMPTY(hdr)); arc_space_return(HDR_L2ONLY_SIZE, ARC_SPACE_L2HDRS); } static void buf_dest(void *vbuf, void *unused) { (void) unused; (void) vbuf; arc_space_return(sizeof (arc_buf_t), ARC_SPACE_HDRS); } static void buf_init(void) { uint64_t *ct = NULL; uint64_t hsize = 1ULL << 12; int i, j; /* * The hash table is big enough to fill all of physical memory * with an average block size of zfs_arc_average_blocksize (default 8K). * By default, the table will take up * totalmem * sizeof(void*) / 8K (1MB per GB with 8-byte pointers). */ while (hsize * zfs_arc_average_blocksize < arc_all_memory()) hsize <<= 1; retry: buf_hash_table.ht_mask = hsize - 1; #if defined(_KERNEL) /* * Large allocations which do not require contiguous pages * should be using vmem_alloc() in the linux kernel */ buf_hash_table.ht_table = vmem_zalloc(hsize * sizeof (void*), KM_SLEEP); #else buf_hash_table.ht_table = kmem_zalloc(hsize * sizeof (void*), KM_NOSLEEP); #endif if (buf_hash_table.ht_table == NULL) { ASSERT(hsize > (1ULL << 8)); hsize >>= 1; goto retry; } hdr_full_cache = kmem_cache_create("arc_buf_hdr_t_full", HDR_FULL_SIZE, 0, hdr_full_cons, hdr_full_dest, NULL, NULL, NULL, 0); hdr_l2only_cache = kmem_cache_create("arc_buf_hdr_t_l2only", HDR_L2ONLY_SIZE, 0, hdr_l2only_cons, hdr_l2only_dest, NULL, NULL, NULL, 0); buf_cache = kmem_cache_create("arc_buf_t", sizeof (arc_buf_t), 0, buf_cons, buf_dest, NULL, NULL, NULL, 0); for (i = 0; i < 256; i++) for (ct = zfs_crc64_table + i, *ct = i, j = 8; j > 0; j--) *ct = (*ct >> 1) ^ (-(*ct & 1) & ZFS_CRC64_POLY); for (i = 0; i < BUF_LOCKS; i++) mutex_init(BUF_HASH_LOCK(i), NULL, MUTEX_DEFAULT, NULL); } #define ARC_MINTIME (hz>>4) /* 62 ms */ /* * This is the size that the buf occupies in memory. If the buf is compressed, * it will correspond to the compressed size. You should use this method of * getting the buf size unless you explicitly need the logical size. */ uint64_t arc_buf_size(arc_buf_t *buf) { return (ARC_BUF_COMPRESSED(buf) ? HDR_GET_PSIZE(buf->b_hdr) : HDR_GET_LSIZE(buf->b_hdr)); } uint64_t arc_buf_lsize(arc_buf_t *buf) { return (HDR_GET_LSIZE(buf->b_hdr)); } /* * This function will return B_TRUE if the buffer is encrypted in memory. * This buffer can be decrypted by calling arc_untransform(). */ boolean_t arc_is_encrypted(arc_buf_t *buf) { return (ARC_BUF_ENCRYPTED(buf) != 0); } /* * Returns B_TRUE if the buffer represents data that has not had its MAC * verified yet. */ boolean_t arc_is_unauthenticated(arc_buf_t *buf) { return (HDR_NOAUTH(buf->b_hdr) != 0); } void arc_get_raw_params(arc_buf_t *buf, boolean_t *byteorder, uint8_t *salt, uint8_t *iv, uint8_t *mac) { arc_buf_hdr_t *hdr = buf->b_hdr; ASSERT(HDR_PROTECTED(hdr)); memcpy(salt, hdr->b_crypt_hdr.b_salt, ZIO_DATA_SALT_LEN); memcpy(iv, hdr->b_crypt_hdr.b_iv, ZIO_DATA_IV_LEN); memcpy(mac, hdr->b_crypt_hdr.b_mac, ZIO_DATA_MAC_LEN); *byteorder = (hdr->b_l1hdr.b_byteswap == DMU_BSWAP_NUMFUNCS) ? ZFS_HOST_BYTEORDER : !ZFS_HOST_BYTEORDER; } /* * Indicates how this buffer is compressed in memory. If it is not compressed * the value will be ZIO_COMPRESS_OFF. It can be made normally readable with * arc_untransform() as long as it is also unencrypted. */ enum zio_compress arc_get_compression(arc_buf_t *buf) { return (ARC_BUF_COMPRESSED(buf) ? HDR_GET_COMPRESS(buf->b_hdr) : ZIO_COMPRESS_OFF); } /* * Return the compression algorithm used to store this data in the ARC. If ARC * compression is enabled or this is an encrypted block, this will be the same * as what's used to store it on-disk. Otherwise, this will be ZIO_COMPRESS_OFF. */ static inline enum zio_compress arc_hdr_get_compress(arc_buf_hdr_t *hdr) { return (HDR_COMPRESSION_ENABLED(hdr) ? HDR_GET_COMPRESS(hdr) : ZIO_COMPRESS_OFF); } uint8_t arc_get_complevel(arc_buf_t *buf) { return (buf->b_hdr->b_complevel); } static inline boolean_t arc_buf_is_shared(arc_buf_t *buf) { boolean_t shared = (buf->b_data != NULL && buf->b_hdr->b_l1hdr.b_pabd != NULL && abd_is_linear(buf->b_hdr->b_l1hdr.b_pabd) && buf->b_data == abd_to_buf(buf->b_hdr->b_l1hdr.b_pabd)); IMPLY(shared, HDR_SHARED_DATA(buf->b_hdr)); - IMPLY(shared, ARC_BUF_SHARED(buf)); + EQUIV(shared, ARC_BUF_SHARED(buf)); IMPLY(shared, ARC_BUF_COMPRESSED(buf) || ARC_BUF_LAST(buf)); /* * It would be nice to assert arc_can_share() too, but the "hdr isn't * already being shared" requirement prevents us from doing that. */ return (shared); } /* * Free the checksum associated with this header. If there is no checksum, this * is a no-op. */ static inline void arc_cksum_free(arc_buf_hdr_t *hdr) { #ifdef ZFS_DEBUG ASSERT(HDR_HAS_L1HDR(hdr)); mutex_enter(&hdr->b_l1hdr.b_freeze_lock); if (hdr->b_l1hdr.b_freeze_cksum != NULL) { kmem_free(hdr->b_l1hdr.b_freeze_cksum, sizeof (zio_cksum_t)); hdr->b_l1hdr.b_freeze_cksum = NULL; } mutex_exit(&hdr->b_l1hdr.b_freeze_lock); #endif } /* * Return true iff at least one of the bufs on hdr is not compressed. * Encrypted buffers count as compressed. */ static boolean_t arc_hdr_has_uncompressed_buf(arc_buf_hdr_t *hdr) { ASSERT(hdr->b_l1hdr.b_state == arc_anon || HDR_EMPTY_OR_LOCKED(hdr)); for (arc_buf_t *b = hdr->b_l1hdr.b_buf; b != NULL; b = b->b_next) { if (!ARC_BUF_COMPRESSED(b)) { return (B_TRUE); } } return (B_FALSE); } /* * If we've turned on the ZFS_DEBUG_MODIFY flag, verify that the buf's data * matches the checksum that is stored in the hdr. If there is no checksum, * or if the buf is compressed, this is a no-op. */ static void arc_cksum_verify(arc_buf_t *buf) { #ifdef ZFS_DEBUG arc_buf_hdr_t *hdr = buf->b_hdr; zio_cksum_t zc; if (!(zfs_flags & ZFS_DEBUG_MODIFY)) return; if (ARC_BUF_COMPRESSED(buf)) return; ASSERT(HDR_HAS_L1HDR(hdr)); mutex_enter(&hdr->b_l1hdr.b_freeze_lock); if (hdr->b_l1hdr.b_freeze_cksum == NULL || HDR_IO_ERROR(hdr)) { mutex_exit(&hdr->b_l1hdr.b_freeze_lock); return; } fletcher_2_native(buf->b_data, arc_buf_size(buf), NULL, &zc); if (!ZIO_CHECKSUM_EQUAL(*hdr->b_l1hdr.b_freeze_cksum, zc)) panic("buffer modified while frozen!"); mutex_exit(&hdr->b_l1hdr.b_freeze_lock); #endif } /* * This function makes the assumption that data stored in the L2ARC * will be transformed exactly as it is in the main pool. Because of * this we can verify the checksum against the reading process's bp. */ static boolean_t arc_cksum_is_equal(arc_buf_hdr_t *hdr, zio_t *zio) { ASSERT(!BP_IS_EMBEDDED(zio->io_bp)); VERIFY3U(BP_GET_PSIZE(zio->io_bp), ==, HDR_GET_PSIZE(hdr)); /* * Block pointers always store the checksum for the logical data. * If the block pointer has the gang bit set, then the checksum * it represents is for the reconstituted data and not for an * individual gang member. The zio pipeline, however, must be able to * determine the checksum of each of the gang constituents so it * treats the checksum comparison differently than what we need * for l2arc blocks. This prevents us from using the * zio_checksum_error() interface directly. Instead we must call the * zio_checksum_error_impl() so that we can ensure the checksum is * generated using the correct checksum algorithm and accounts for the * logical I/O size and not just a gang fragment. */ return (zio_checksum_error_impl(zio->io_spa, zio->io_bp, BP_GET_CHECKSUM(zio->io_bp), zio->io_abd, zio->io_size, zio->io_offset, NULL) == 0); } /* * Given a buf full of data, if ZFS_DEBUG_MODIFY is enabled this computes a * checksum and attaches it to the buf's hdr so that we can ensure that the buf * isn't modified later on. If buf is compressed or there is already a checksum * on the hdr, this is a no-op (we only checksum uncompressed bufs). */ static void arc_cksum_compute(arc_buf_t *buf) { if (!(zfs_flags & ZFS_DEBUG_MODIFY)) return; #ifdef ZFS_DEBUG arc_buf_hdr_t *hdr = buf->b_hdr; ASSERT(HDR_HAS_L1HDR(hdr)); mutex_enter(&hdr->b_l1hdr.b_freeze_lock); if (hdr->b_l1hdr.b_freeze_cksum != NULL || ARC_BUF_COMPRESSED(buf)) { mutex_exit(&hdr->b_l1hdr.b_freeze_lock); return; } ASSERT(!ARC_BUF_ENCRYPTED(buf)); ASSERT(!ARC_BUF_COMPRESSED(buf)); hdr->b_l1hdr.b_freeze_cksum = kmem_alloc(sizeof (zio_cksum_t), KM_SLEEP); fletcher_2_native(buf->b_data, arc_buf_size(buf), NULL, hdr->b_l1hdr.b_freeze_cksum); mutex_exit(&hdr->b_l1hdr.b_freeze_lock); #endif arc_buf_watch(buf); } #ifndef _KERNEL void arc_buf_sigsegv(int sig, siginfo_t *si, void *unused) { (void) sig, (void) unused; panic("Got SIGSEGV at address: 0x%lx\n", (long)si->si_addr); } #endif static void arc_buf_unwatch(arc_buf_t *buf) { #ifndef _KERNEL if (arc_watch) { ASSERT0(mprotect(buf->b_data, arc_buf_size(buf), PROT_READ | PROT_WRITE)); } #else (void) buf; #endif } static void arc_buf_watch(arc_buf_t *buf) { #ifndef _KERNEL if (arc_watch) ASSERT0(mprotect(buf->b_data, arc_buf_size(buf), PROT_READ)); #else (void) buf; #endif } static arc_buf_contents_t arc_buf_type(arc_buf_hdr_t *hdr) { arc_buf_contents_t type; if (HDR_ISTYPE_METADATA(hdr)) { type = ARC_BUFC_METADATA; } else { type = ARC_BUFC_DATA; } VERIFY3U(hdr->b_type, ==, type); return (type); } boolean_t arc_is_metadata(arc_buf_t *buf) { return (HDR_ISTYPE_METADATA(buf->b_hdr) != 0); } static uint32_t arc_bufc_to_flags(arc_buf_contents_t type) { switch (type) { case ARC_BUFC_DATA: /* metadata field is 0 if buffer contains normal data */ return (0); case ARC_BUFC_METADATA: return (ARC_FLAG_BUFC_METADATA); default: break; } panic("undefined ARC buffer type!"); return ((uint32_t)-1); } void arc_buf_thaw(arc_buf_t *buf) { arc_buf_hdr_t *hdr = buf->b_hdr; ASSERT3P(hdr->b_l1hdr.b_state, ==, arc_anon); ASSERT(!HDR_IO_IN_PROGRESS(hdr)); arc_cksum_verify(buf); /* * Compressed buffers do not manipulate the b_freeze_cksum. */ if (ARC_BUF_COMPRESSED(buf)) return; ASSERT(HDR_HAS_L1HDR(hdr)); arc_cksum_free(hdr); arc_buf_unwatch(buf); } void arc_buf_freeze(arc_buf_t *buf) { if (!(zfs_flags & ZFS_DEBUG_MODIFY)) return; if (ARC_BUF_COMPRESSED(buf)) return; ASSERT(HDR_HAS_L1HDR(buf->b_hdr)); arc_cksum_compute(buf); } /* * The arc_buf_hdr_t's b_flags should never be modified directly. Instead, * the following functions should be used to ensure that the flags are * updated in a thread-safe way. When manipulating the flags either * the hash_lock must be held or the hdr must be undiscoverable. This * ensures that we're not racing with any other threads when updating * the flags. */ static inline void arc_hdr_set_flags(arc_buf_hdr_t *hdr, arc_flags_t flags) { ASSERT(HDR_EMPTY_OR_LOCKED(hdr)); hdr->b_flags |= flags; } static inline void arc_hdr_clear_flags(arc_buf_hdr_t *hdr, arc_flags_t flags) { ASSERT(HDR_EMPTY_OR_LOCKED(hdr)); hdr->b_flags &= ~flags; } /* * Setting the compression bits in the arc_buf_hdr_t's b_flags is * done in a special way since we have to clear and set bits * at the same time. Consumers that wish to set the compression bits * must use this function to ensure that the flags are updated in * thread-safe manner. */ static void arc_hdr_set_compress(arc_buf_hdr_t *hdr, enum zio_compress cmp) { ASSERT(HDR_EMPTY_OR_LOCKED(hdr)); /* * Holes and embedded blocks will always have a psize = 0 so * we ignore the compression of the blkptr and set the * want to uncompress them. Mark them as uncompressed. */ if (!zfs_compressed_arc_enabled || HDR_GET_PSIZE(hdr) == 0) { arc_hdr_clear_flags(hdr, ARC_FLAG_COMPRESSED_ARC); ASSERT(!HDR_COMPRESSION_ENABLED(hdr)); } else { arc_hdr_set_flags(hdr, ARC_FLAG_COMPRESSED_ARC); ASSERT(HDR_COMPRESSION_ENABLED(hdr)); } HDR_SET_COMPRESS(hdr, cmp); ASSERT3U(HDR_GET_COMPRESS(hdr), ==, cmp); } /* * Looks for another buf on the same hdr which has the data decompressed, copies * from it, and returns true. If no such buf exists, returns false. */ static boolean_t arc_buf_try_copy_decompressed_data(arc_buf_t *buf) { arc_buf_hdr_t *hdr = buf->b_hdr; boolean_t copied = B_FALSE; ASSERT(HDR_HAS_L1HDR(hdr)); ASSERT3P(buf->b_data, !=, NULL); ASSERT(!ARC_BUF_COMPRESSED(buf)); for (arc_buf_t *from = hdr->b_l1hdr.b_buf; from != NULL; from = from->b_next) { /* can't use our own data buffer */ if (from == buf) { continue; } if (!ARC_BUF_COMPRESSED(from)) { memcpy(buf->b_data, from->b_data, arc_buf_size(buf)); copied = B_TRUE; break; } } #ifdef ZFS_DEBUG /* * There were no decompressed bufs, so there should not be a * checksum on the hdr either. */ if (zfs_flags & ZFS_DEBUG_MODIFY) EQUIV(!copied, hdr->b_l1hdr.b_freeze_cksum == NULL); #endif return (copied); } /* * Allocates an ARC buf header that's in an evicted & L2-cached state. * This is used during l2arc reconstruction to make empty ARC buffers * which circumvent the regular disk->arc->l2arc path and instead come * into being in the reverse order, i.e. l2arc->arc. */ static arc_buf_hdr_t * arc_buf_alloc_l2only(size_t size, arc_buf_contents_t type, l2arc_dev_t *dev, dva_t dva, uint64_t daddr, int32_t psize, uint64_t birth, enum zio_compress compress, uint8_t complevel, boolean_t protected, boolean_t prefetch, arc_state_type_t arcs_state) { arc_buf_hdr_t *hdr; ASSERT(size != 0); hdr = kmem_cache_alloc(hdr_l2only_cache, KM_SLEEP); hdr->b_birth = birth; hdr->b_type = type; hdr->b_flags = 0; arc_hdr_set_flags(hdr, arc_bufc_to_flags(type) | ARC_FLAG_HAS_L2HDR); HDR_SET_LSIZE(hdr, size); HDR_SET_PSIZE(hdr, psize); arc_hdr_set_compress(hdr, compress); hdr->b_complevel = complevel; if (protected) arc_hdr_set_flags(hdr, ARC_FLAG_PROTECTED); if (prefetch) arc_hdr_set_flags(hdr, ARC_FLAG_PREFETCH); hdr->b_spa = spa_load_guid(dev->l2ad_vdev->vdev_spa); hdr->b_dva = dva; hdr->b_l2hdr.b_dev = dev; hdr->b_l2hdr.b_daddr = daddr; hdr->b_l2hdr.b_arcs_state = arcs_state; return (hdr); } /* * Return the size of the block, b_pabd, that is stored in the arc_buf_hdr_t. */ static uint64_t arc_hdr_size(arc_buf_hdr_t *hdr) { uint64_t size; if (arc_hdr_get_compress(hdr) != ZIO_COMPRESS_OFF && HDR_GET_PSIZE(hdr) > 0) { size = HDR_GET_PSIZE(hdr); } else { ASSERT3U(HDR_GET_LSIZE(hdr), !=, 0); size = HDR_GET_LSIZE(hdr); } return (size); } static int arc_hdr_authenticate(arc_buf_hdr_t *hdr, spa_t *spa, uint64_t dsobj) { int ret; uint64_t csize; uint64_t lsize = HDR_GET_LSIZE(hdr); uint64_t psize = HDR_GET_PSIZE(hdr); void *tmpbuf = NULL; abd_t *abd = hdr->b_l1hdr.b_pabd; ASSERT(HDR_EMPTY_OR_LOCKED(hdr)); ASSERT(HDR_AUTHENTICATED(hdr)); ASSERT3P(hdr->b_l1hdr.b_pabd, !=, NULL); /* * The MAC is calculated on the compressed data that is stored on disk. * However, if compressed arc is disabled we will only have the * decompressed data available to us now. Compress it into a temporary * abd so we can verify the MAC. The performance overhead of this will * be relatively low, since most objects in an encrypted objset will * be encrypted (instead of authenticated) anyway. */ if (HDR_GET_COMPRESS(hdr) != ZIO_COMPRESS_OFF && !HDR_COMPRESSION_ENABLED(hdr)) { csize = zio_compress_data(HDR_GET_COMPRESS(hdr), hdr->b_l1hdr.b_pabd, &tmpbuf, lsize, hdr->b_complevel); ASSERT3P(tmpbuf, !=, NULL); ASSERT3U(csize, <=, psize); abd = abd_get_from_buf(tmpbuf, lsize); abd_take_ownership_of_buf(abd, B_TRUE); abd_zero_off(abd, csize, psize - csize); } /* * Authentication is best effort. We authenticate whenever the key is * available. If we succeed we clear ARC_FLAG_NOAUTH. */ if (hdr->b_crypt_hdr.b_ot == DMU_OT_OBJSET) { ASSERT3U(HDR_GET_COMPRESS(hdr), ==, ZIO_COMPRESS_OFF); ASSERT3U(lsize, ==, psize); ret = spa_do_crypt_objset_mac_abd(B_FALSE, spa, dsobj, abd, psize, hdr->b_l1hdr.b_byteswap != DMU_BSWAP_NUMFUNCS); } else { ret = spa_do_crypt_mac_abd(B_FALSE, spa, dsobj, abd, psize, hdr->b_crypt_hdr.b_mac); } if (ret == 0) arc_hdr_clear_flags(hdr, ARC_FLAG_NOAUTH); else if (ret != ENOENT) goto error; if (tmpbuf != NULL) abd_free(abd); return (0); error: if (tmpbuf != NULL) abd_free(abd); return (ret); } /* * This function will take a header that only has raw encrypted data in * b_crypt_hdr.b_rabd and decrypt it into a new buffer which is stored in * b_l1hdr.b_pabd. If designated in the header flags, this function will * also decompress the data. */ static int arc_hdr_decrypt(arc_buf_hdr_t *hdr, spa_t *spa, const zbookmark_phys_t *zb) { int ret; abd_t *cabd = NULL; void *tmp = NULL; boolean_t no_crypt = B_FALSE; boolean_t bswap = (hdr->b_l1hdr.b_byteswap != DMU_BSWAP_NUMFUNCS); ASSERT(HDR_EMPTY_OR_LOCKED(hdr)); ASSERT(HDR_ENCRYPTED(hdr)); arc_hdr_alloc_abd(hdr, 0); ret = spa_do_crypt_abd(B_FALSE, spa, zb, hdr->b_crypt_hdr.b_ot, B_FALSE, bswap, hdr->b_crypt_hdr.b_salt, hdr->b_crypt_hdr.b_iv, hdr->b_crypt_hdr.b_mac, HDR_GET_PSIZE(hdr), hdr->b_l1hdr.b_pabd, hdr->b_crypt_hdr.b_rabd, &no_crypt); if (ret != 0) goto error; if (no_crypt) { abd_copy(hdr->b_l1hdr.b_pabd, hdr->b_crypt_hdr.b_rabd, HDR_GET_PSIZE(hdr)); } /* * If this header has disabled arc compression but the b_pabd is * compressed after decrypting it, we need to decompress the newly * decrypted data. */ if (HDR_GET_COMPRESS(hdr) != ZIO_COMPRESS_OFF && !HDR_COMPRESSION_ENABLED(hdr)) { /* * We want to make sure that we are correctly honoring the * zfs_abd_scatter_enabled setting, so we allocate an abd here * and then loan a buffer from it, rather than allocating a * linear buffer and wrapping it in an abd later. */ cabd = arc_get_data_abd(hdr, arc_hdr_size(hdr), hdr, 0); tmp = abd_borrow_buf(cabd, arc_hdr_size(hdr)); ret = zio_decompress_data(HDR_GET_COMPRESS(hdr), hdr->b_l1hdr.b_pabd, tmp, HDR_GET_PSIZE(hdr), HDR_GET_LSIZE(hdr), &hdr->b_complevel); if (ret != 0) { abd_return_buf(cabd, tmp, arc_hdr_size(hdr)); goto error; } abd_return_buf_copy(cabd, tmp, arc_hdr_size(hdr)); arc_free_data_abd(hdr, hdr->b_l1hdr.b_pabd, arc_hdr_size(hdr), hdr); hdr->b_l1hdr.b_pabd = cabd; } return (0); error: arc_hdr_free_abd(hdr, B_FALSE); if (cabd != NULL) arc_free_data_buf(hdr, cabd, arc_hdr_size(hdr), hdr); return (ret); } /* * This function is called during arc_buf_fill() to prepare the header's * abd plaintext pointer for use. This involves authenticated protected * data and decrypting encrypted data into the plaintext abd. */ static int arc_fill_hdr_crypt(arc_buf_hdr_t *hdr, kmutex_t *hash_lock, spa_t *spa, const zbookmark_phys_t *zb, boolean_t noauth) { int ret; ASSERT(HDR_PROTECTED(hdr)); if (hash_lock != NULL) mutex_enter(hash_lock); if (HDR_NOAUTH(hdr) && !noauth) { /* * The caller requested authenticated data but our data has * not been authenticated yet. Verify the MAC now if we can. */ ret = arc_hdr_authenticate(hdr, spa, zb->zb_objset); if (ret != 0) goto error; } else if (HDR_HAS_RABD(hdr) && hdr->b_l1hdr.b_pabd == NULL) { /* * If we only have the encrypted version of the data, but the * unencrypted version was requested we take this opportunity * to store the decrypted version in the header for future use. */ ret = arc_hdr_decrypt(hdr, spa, zb); if (ret != 0) goto error; } ASSERT3P(hdr->b_l1hdr.b_pabd, !=, NULL); if (hash_lock != NULL) mutex_exit(hash_lock); return (0); error: if (hash_lock != NULL) mutex_exit(hash_lock); return (ret); } /* * This function is used by the dbuf code to decrypt bonus buffers in place. * The dbuf code itself doesn't have any locking for decrypting a shared dnode * block, so we use the hash lock here to protect against concurrent calls to * arc_buf_fill(). */ static void arc_buf_untransform_in_place(arc_buf_t *buf) { arc_buf_hdr_t *hdr = buf->b_hdr; ASSERT(HDR_ENCRYPTED(hdr)); ASSERT3U(hdr->b_crypt_hdr.b_ot, ==, DMU_OT_DNODE); ASSERT(HDR_EMPTY_OR_LOCKED(hdr)); ASSERT3P(hdr->b_l1hdr.b_pabd, !=, NULL); zio_crypt_copy_dnode_bonus(hdr->b_l1hdr.b_pabd, buf->b_data, arc_buf_size(buf)); buf->b_flags &= ~ARC_BUF_FLAG_ENCRYPTED; buf->b_flags &= ~ARC_BUF_FLAG_COMPRESSED; } /* * Given a buf that has a data buffer attached to it, this function will * efficiently fill the buf with data of the specified compression setting from * the hdr and update the hdr's b_freeze_cksum if necessary. If the buf and hdr * are already sharing a data buf, no copy is performed. * * If the buf is marked as compressed but uncompressed data was requested, this * will allocate a new data buffer for the buf, remove that flag, and fill the * buf with uncompressed data. You can't request a compressed buf on a hdr with * uncompressed data, and (since we haven't added support for it yet) if you * want compressed data your buf must already be marked as compressed and have * the correct-sized data buffer. */ static int arc_buf_fill(arc_buf_t *buf, spa_t *spa, const zbookmark_phys_t *zb, arc_fill_flags_t flags) { int error = 0; arc_buf_hdr_t *hdr = buf->b_hdr; boolean_t hdr_compressed = (arc_hdr_get_compress(hdr) != ZIO_COMPRESS_OFF); boolean_t compressed = (flags & ARC_FILL_COMPRESSED) != 0; boolean_t encrypted = (flags & ARC_FILL_ENCRYPTED) != 0; dmu_object_byteswap_t bswap = hdr->b_l1hdr.b_byteswap; kmutex_t *hash_lock = (flags & ARC_FILL_LOCKED) ? NULL : HDR_LOCK(hdr); ASSERT3P(buf->b_data, !=, NULL); IMPLY(compressed, hdr_compressed || ARC_BUF_ENCRYPTED(buf)); IMPLY(compressed, ARC_BUF_COMPRESSED(buf)); IMPLY(encrypted, HDR_ENCRYPTED(hdr)); IMPLY(encrypted, ARC_BUF_ENCRYPTED(buf)); IMPLY(encrypted, ARC_BUF_COMPRESSED(buf)); - IMPLY(encrypted, !ARC_BUF_SHARED(buf)); + IMPLY(encrypted, !arc_buf_is_shared(buf)); /* * If the caller wanted encrypted data we just need to copy it from * b_rabd and potentially byteswap it. We won't be able to do any * further transforms on it. */ if (encrypted) { ASSERT(HDR_HAS_RABD(hdr)); abd_copy_to_buf(buf->b_data, hdr->b_crypt_hdr.b_rabd, HDR_GET_PSIZE(hdr)); goto byteswap; } /* * Adjust encrypted and authenticated headers to accommodate * the request if needed. Dnode blocks (ARC_FILL_IN_PLACE) are * allowed to fail decryption due to keys not being loaded * without being marked as an IO error. */ if (HDR_PROTECTED(hdr)) { error = arc_fill_hdr_crypt(hdr, hash_lock, spa, zb, !!(flags & ARC_FILL_NOAUTH)); if (error == EACCES && (flags & ARC_FILL_IN_PLACE) != 0) { return (error); } else if (error != 0) { if (hash_lock != NULL) mutex_enter(hash_lock); arc_hdr_set_flags(hdr, ARC_FLAG_IO_ERROR); if (hash_lock != NULL) mutex_exit(hash_lock); return (error); } } /* * There is a special case here for dnode blocks which are * decrypting their bonus buffers. These blocks may request to * be decrypted in-place. This is necessary because there may * be many dnodes pointing into this buffer and there is * currently no method to synchronize replacing the backing * b_data buffer and updating all of the pointers. Here we use * the hash lock to ensure there are no races. If the need * arises for other types to be decrypted in-place, they must * add handling here as well. */ if ((flags & ARC_FILL_IN_PLACE) != 0) { ASSERT(!hdr_compressed); ASSERT(!compressed); ASSERT(!encrypted); if (HDR_ENCRYPTED(hdr) && ARC_BUF_ENCRYPTED(buf)) { ASSERT3U(hdr->b_crypt_hdr.b_ot, ==, DMU_OT_DNODE); if (hash_lock != NULL) mutex_enter(hash_lock); arc_buf_untransform_in_place(buf); if (hash_lock != NULL) mutex_exit(hash_lock); /* Compute the hdr's checksum if necessary */ arc_cksum_compute(buf); } return (0); } if (hdr_compressed == compressed) { - if (!arc_buf_is_shared(buf)) { + if (ARC_BUF_SHARED(buf)) { + ASSERT(arc_buf_is_shared(buf)); + } else { abd_copy_to_buf(buf->b_data, hdr->b_l1hdr.b_pabd, arc_buf_size(buf)); } } else { ASSERT(hdr_compressed); ASSERT(!compressed); /* * If the buf is sharing its data with the hdr, unlink it and * allocate a new data buffer for the buf. */ - if (arc_buf_is_shared(buf)) { + if (ARC_BUF_SHARED(buf)) { ASSERT(ARC_BUF_COMPRESSED(buf)); /* We need to give the buf its own b_data */ buf->b_flags &= ~ARC_BUF_FLAG_SHARED; buf->b_data = arc_get_data_buf(hdr, HDR_GET_LSIZE(hdr), buf); arc_hdr_clear_flags(hdr, ARC_FLAG_SHARED_DATA); /* Previously overhead was 0; just add new overhead */ ARCSTAT_INCR(arcstat_overhead_size, HDR_GET_LSIZE(hdr)); } else if (ARC_BUF_COMPRESSED(buf)) { + ASSERT(!arc_buf_is_shared(buf)); + /* We need to reallocate the buf's b_data */ arc_free_data_buf(hdr, buf->b_data, HDR_GET_PSIZE(hdr), buf); buf->b_data = arc_get_data_buf(hdr, HDR_GET_LSIZE(hdr), buf); /* We increased the size of b_data; update overhead */ ARCSTAT_INCR(arcstat_overhead_size, HDR_GET_LSIZE(hdr) - HDR_GET_PSIZE(hdr)); } /* * Regardless of the buf's previous compression settings, it * should not be compressed at the end of this function. */ buf->b_flags &= ~ARC_BUF_FLAG_COMPRESSED; /* * Try copying the data from another buf which already has a * decompressed version. If that's not possible, it's time to * bite the bullet and decompress the data from the hdr. */ if (arc_buf_try_copy_decompressed_data(buf)) { /* Skip byteswapping and checksumming (already done) */ return (0); } else { error = zio_decompress_data(HDR_GET_COMPRESS(hdr), hdr->b_l1hdr.b_pabd, buf->b_data, HDR_GET_PSIZE(hdr), HDR_GET_LSIZE(hdr), &hdr->b_complevel); /* * Absent hardware errors or software bugs, this should * be impossible, but log it anyway so we can debug it. */ if (error != 0) { zfs_dbgmsg( "hdr %px, compress %d, psize %d, lsize %d", hdr, arc_hdr_get_compress(hdr), HDR_GET_PSIZE(hdr), HDR_GET_LSIZE(hdr)); if (hash_lock != NULL) mutex_enter(hash_lock); arc_hdr_set_flags(hdr, ARC_FLAG_IO_ERROR); if (hash_lock != NULL) mutex_exit(hash_lock); return (SET_ERROR(EIO)); } } } byteswap: /* Byteswap the buf's data if necessary */ if (bswap != DMU_BSWAP_NUMFUNCS) { ASSERT(!HDR_SHARED_DATA(hdr)); ASSERT3U(bswap, <, DMU_BSWAP_NUMFUNCS); dmu_ot_byteswap[bswap].ob_func(buf->b_data, HDR_GET_LSIZE(hdr)); } /* Compute the hdr's checksum if necessary */ arc_cksum_compute(buf); return (0); } /* * If this function is being called to decrypt an encrypted buffer or verify an * authenticated one, the key must be loaded and a mapping must be made * available in the keystore via spa_keystore_create_mapping() or one of its * callers. */ int arc_untransform(arc_buf_t *buf, spa_t *spa, const zbookmark_phys_t *zb, boolean_t in_place) { int ret; arc_fill_flags_t flags = 0; if (in_place) flags |= ARC_FILL_IN_PLACE; ret = arc_buf_fill(buf, spa, zb, flags); if (ret == ECKSUM) { /* * Convert authentication and decryption errors to EIO * (and generate an ereport) before leaving the ARC. */ ret = SET_ERROR(EIO); spa_log_error(spa, zb, &buf->b_hdr->b_birth); (void) zfs_ereport_post(FM_EREPORT_ZFS_AUTHENTICATION, spa, NULL, zb, NULL, 0); } return (ret); } /* * Increment the amount of evictable space in the arc_state_t's refcount. * We account for the space used by the hdr and the arc buf individually * so that we can add and remove them from the refcount individually. */ static void arc_evictable_space_increment(arc_buf_hdr_t *hdr, arc_state_t *state) { arc_buf_contents_t type = arc_buf_type(hdr); ASSERT(HDR_HAS_L1HDR(hdr)); if (GHOST_STATE(state)) { ASSERT3P(hdr->b_l1hdr.b_buf, ==, NULL); ASSERT3P(hdr->b_l1hdr.b_pabd, ==, NULL); ASSERT(!HDR_HAS_RABD(hdr)); (void) zfs_refcount_add_many(&state->arcs_esize[type], HDR_GET_LSIZE(hdr), hdr); return; } if (hdr->b_l1hdr.b_pabd != NULL) { (void) zfs_refcount_add_many(&state->arcs_esize[type], arc_hdr_size(hdr), hdr); } if (HDR_HAS_RABD(hdr)) { (void) zfs_refcount_add_many(&state->arcs_esize[type], HDR_GET_PSIZE(hdr), hdr); } for (arc_buf_t *buf = hdr->b_l1hdr.b_buf; buf != NULL; buf = buf->b_next) { - if (arc_buf_is_shared(buf)) + if (ARC_BUF_SHARED(buf)) continue; (void) zfs_refcount_add_many(&state->arcs_esize[type], arc_buf_size(buf), buf); } } /* * Decrement the amount of evictable space in the arc_state_t's refcount. * We account for the space used by the hdr and the arc buf individually * so that we can add and remove them from the refcount individually. */ static void arc_evictable_space_decrement(arc_buf_hdr_t *hdr, arc_state_t *state) { arc_buf_contents_t type = arc_buf_type(hdr); ASSERT(HDR_HAS_L1HDR(hdr)); if (GHOST_STATE(state)) { ASSERT3P(hdr->b_l1hdr.b_buf, ==, NULL); ASSERT3P(hdr->b_l1hdr.b_pabd, ==, NULL); ASSERT(!HDR_HAS_RABD(hdr)); (void) zfs_refcount_remove_many(&state->arcs_esize[type], HDR_GET_LSIZE(hdr), hdr); return; } if (hdr->b_l1hdr.b_pabd != NULL) { (void) zfs_refcount_remove_many(&state->arcs_esize[type], arc_hdr_size(hdr), hdr); } if (HDR_HAS_RABD(hdr)) { (void) zfs_refcount_remove_many(&state->arcs_esize[type], HDR_GET_PSIZE(hdr), hdr); } for (arc_buf_t *buf = hdr->b_l1hdr.b_buf; buf != NULL; buf = buf->b_next) { - if (arc_buf_is_shared(buf)) + if (ARC_BUF_SHARED(buf)) continue; (void) zfs_refcount_remove_many(&state->arcs_esize[type], arc_buf_size(buf), buf); } } /* * Add a reference to this hdr indicating that someone is actively * referencing that memory. When the refcount transitions from 0 to 1, * we remove it from the respective arc_state_t list to indicate that * it is not evictable. */ static void add_reference(arc_buf_hdr_t *hdr, const void *tag) { arc_state_t *state = hdr->b_l1hdr.b_state; ASSERT(HDR_HAS_L1HDR(hdr)); if (!HDR_EMPTY(hdr) && !MUTEX_HELD(HDR_LOCK(hdr))) { ASSERT(state == arc_anon); ASSERT(zfs_refcount_is_zero(&hdr->b_l1hdr.b_refcnt)); ASSERT3P(hdr->b_l1hdr.b_buf, ==, NULL); } if ((zfs_refcount_add(&hdr->b_l1hdr.b_refcnt, tag) == 1) && state != arc_anon && state != arc_l2c_only) { /* We don't use the L2-only state list. */ multilist_remove(&state->arcs_list[arc_buf_type(hdr)], hdr); arc_evictable_space_decrement(hdr, state); } } /* * Remove a reference from this hdr. When the reference transitions from * 1 to 0 and we're not anonymous, then we add this hdr to the arc_state_t's * list making it eligible for eviction. */ static int remove_reference(arc_buf_hdr_t *hdr, const void *tag) { int cnt; arc_state_t *state = hdr->b_l1hdr.b_state; ASSERT(HDR_HAS_L1HDR(hdr)); ASSERT(state == arc_anon || MUTEX_HELD(HDR_LOCK(hdr))); ASSERT(!GHOST_STATE(state)); /* arc_l2c_only counts as a ghost. */ if ((cnt = zfs_refcount_remove(&hdr->b_l1hdr.b_refcnt, tag)) != 0) return (cnt); if (state == arc_anon) { arc_hdr_destroy(hdr); return (0); } if (state == arc_uncached && !HDR_PREFETCH(hdr)) { arc_change_state(arc_anon, hdr); arc_hdr_destroy(hdr); return (0); } multilist_insert(&state->arcs_list[arc_buf_type(hdr)], hdr); arc_evictable_space_increment(hdr, state); return (0); } /* * Returns detailed information about a specific arc buffer. When the * state_index argument is set the function will calculate the arc header * list position for its arc state. Since this requires a linear traversal * callers are strongly encourage not to do this. However, it can be helpful * for targeted analysis so the functionality is provided. */ void arc_buf_info(arc_buf_t *ab, arc_buf_info_t *abi, int state_index) { (void) state_index; arc_buf_hdr_t *hdr = ab->b_hdr; l1arc_buf_hdr_t *l1hdr = NULL; l2arc_buf_hdr_t *l2hdr = NULL; arc_state_t *state = NULL; memset(abi, 0, sizeof (arc_buf_info_t)); if (hdr == NULL) return; abi->abi_flags = hdr->b_flags; if (HDR_HAS_L1HDR(hdr)) { l1hdr = &hdr->b_l1hdr; state = l1hdr->b_state; } if (HDR_HAS_L2HDR(hdr)) l2hdr = &hdr->b_l2hdr; if (l1hdr) { abi->abi_bufcnt = 0; for (arc_buf_t *buf = l1hdr->b_buf; buf; buf = buf->b_next) abi->abi_bufcnt++; abi->abi_access = l1hdr->b_arc_access; abi->abi_mru_hits = l1hdr->b_mru_hits; abi->abi_mru_ghost_hits = l1hdr->b_mru_ghost_hits; abi->abi_mfu_hits = l1hdr->b_mfu_hits; abi->abi_mfu_ghost_hits = l1hdr->b_mfu_ghost_hits; abi->abi_holds = zfs_refcount_count(&l1hdr->b_refcnt); } if (l2hdr) { abi->abi_l2arc_dattr = l2hdr->b_daddr; abi->abi_l2arc_hits = l2hdr->b_hits; } abi->abi_state_type = state ? state->arcs_state : ARC_STATE_ANON; abi->abi_state_contents = arc_buf_type(hdr); abi->abi_size = arc_hdr_size(hdr); } /* * Move the supplied buffer to the indicated state. The hash lock * for the buffer must be held by the caller. */ static void arc_change_state(arc_state_t *new_state, arc_buf_hdr_t *hdr) { arc_state_t *old_state; int64_t refcnt; boolean_t update_old, update_new; arc_buf_contents_t type = arc_buf_type(hdr); /* * We almost always have an L1 hdr here, since we call arc_hdr_realloc() * in arc_read() when bringing a buffer out of the L2ARC. However, the * L1 hdr doesn't always exist when we change state to arc_anon before * destroying a header, in which case reallocating to add the L1 hdr is * pointless. */ if (HDR_HAS_L1HDR(hdr)) { old_state = hdr->b_l1hdr.b_state; refcnt = zfs_refcount_count(&hdr->b_l1hdr.b_refcnt); update_old = (hdr->b_l1hdr.b_buf != NULL || hdr->b_l1hdr.b_pabd != NULL || HDR_HAS_RABD(hdr)); IMPLY(GHOST_STATE(old_state), hdr->b_l1hdr.b_buf == NULL); IMPLY(GHOST_STATE(new_state), hdr->b_l1hdr.b_buf == NULL); IMPLY(old_state == arc_anon, hdr->b_l1hdr.b_buf == NULL || ARC_BUF_LAST(hdr->b_l1hdr.b_buf)); } else { old_state = arc_l2c_only; refcnt = 0; update_old = B_FALSE; } update_new = update_old; if (GHOST_STATE(old_state)) update_old = B_TRUE; if (GHOST_STATE(new_state)) update_new = B_TRUE; ASSERT(MUTEX_HELD(HDR_LOCK(hdr))); ASSERT3P(new_state, !=, old_state); /* * If this buffer is evictable, transfer it from the * old state list to the new state list. */ if (refcnt == 0) { if (old_state != arc_anon && old_state != arc_l2c_only) { ASSERT(HDR_HAS_L1HDR(hdr)); /* remove_reference() saves on insert. */ if (multilist_link_active(&hdr->b_l1hdr.b_arc_node)) { multilist_remove(&old_state->arcs_list[type], hdr); arc_evictable_space_decrement(hdr, old_state); } } if (new_state != arc_anon && new_state != arc_l2c_only) { /* * An L1 header always exists here, since if we're * moving to some L1-cached state (i.e. not l2c_only or * anonymous), we realloc the header to add an L1hdr * beforehand. */ ASSERT(HDR_HAS_L1HDR(hdr)); multilist_insert(&new_state->arcs_list[type], hdr); arc_evictable_space_increment(hdr, new_state); } } ASSERT(!HDR_EMPTY(hdr)); if (new_state == arc_anon && HDR_IN_HASH_TABLE(hdr)) buf_hash_remove(hdr); /* adjust state sizes (ignore arc_l2c_only) */ if (update_new && new_state != arc_l2c_only) { ASSERT(HDR_HAS_L1HDR(hdr)); if (GHOST_STATE(new_state)) { /* * When moving a header to a ghost state, we first * remove all arc buffers. Thus, we'll have no arc * buffer to use for the reference. As a result, we * use the arc header pointer for the reference. */ (void) zfs_refcount_add_many( &new_state->arcs_size[type], HDR_GET_LSIZE(hdr), hdr); ASSERT3P(hdr->b_l1hdr.b_pabd, ==, NULL); ASSERT(!HDR_HAS_RABD(hdr)); } else { /* * Each individual buffer holds a unique reference, * thus we must remove each of these references one * at a time. */ for (arc_buf_t *buf = hdr->b_l1hdr.b_buf; buf != NULL; buf = buf->b_next) { /* * When the arc_buf_t is sharing the data * block with the hdr, the owner of the * reference belongs to the hdr. Only * add to the refcount if the arc_buf_t is * not shared. */ - if (arc_buf_is_shared(buf)) + if (ARC_BUF_SHARED(buf)) continue; (void) zfs_refcount_add_many( &new_state->arcs_size[type], arc_buf_size(buf), buf); } if (hdr->b_l1hdr.b_pabd != NULL) { (void) zfs_refcount_add_many( &new_state->arcs_size[type], arc_hdr_size(hdr), hdr); } if (HDR_HAS_RABD(hdr)) { (void) zfs_refcount_add_many( &new_state->arcs_size[type], HDR_GET_PSIZE(hdr), hdr); } } } if (update_old && old_state != arc_l2c_only) { ASSERT(HDR_HAS_L1HDR(hdr)); if (GHOST_STATE(old_state)) { ASSERT3P(hdr->b_l1hdr.b_pabd, ==, NULL); ASSERT(!HDR_HAS_RABD(hdr)); /* * When moving a header off of a ghost state, * the header will not contain any arc buffers. * We use the arc header pointer for the reference * which is exactly what we did when we put the * header on the ghost state. */ (void) zfs_refcount_remove_many( &old_state->arcs_size[type], HDR_GET_LSIZE(hdr), hdr); } else { /* * Each individual buffer holds a unique reference, * thus we must remove each of these references one * at a time. */ for (arc_buf_t *buf = hdr->b_l1hdr.b_buf; buf != NULL; buf = buf->b_next) { /* * When the arc_buf_t is sharing the data * block with the hdr, the owner of the * reference belongs to the hdr. Only * add to the refcount if the arc_buf_t is * not shared. */ - if (arc_buf_is_shared(buf)) + if (ARC_BUF_SHARED(buf)) continue; (void) zfs_refcount_remove_many( &old_state->arcs_size[type], arc_buf_size(buf), buf); } ASSERT(hdr->b_l1hdr.b_pabd != NULL || HDR_HAS_RABD(hdr)); if (hdr->b_l1hdr.b_pabd != NULL) { (void) zfs_refcount_remove_many( &old_state->arcs_size[type], arc_hdr_size(hdr), hdr); } if (HDR_HAS_RABD(hdr)) { (void) zfs_refcount_remove_many( &old_state->arcs_size[type], HDR_GET_PSIZE(hdr), hdr); } } } if (HDR_HAS_L1HDR(hdr)) { hdr->b_l1hdr.b_state = new_state; if (HDR_HAS_L2HDR(hdr) && new_state != arc_l2c_only) { l2arc_hdr_arcstats_decrement_state(hdr); hdr->b_l2hdr.b_arcs_state = new_state->arcs_state; l2arc_hdr_arcstats_increment_state(hdr); } } } void arc_space_consume(uint64_t space, arc_space_type_t type) { ASSERT(type >= 0 && type < ARC_SPACE_NUMTYPES); switch (type) { default: break; case ARC_SPACE_DATA: ARCSTAT_INCR(arcstat_data_size, space); break; case ARC_SPACE_META: ARCSTAT_INCR(arcstat_metadata_size, space); break; case ARC_SPACE_BONUS: ARCSTAT_INCR(arcstat_bonus_size, space); break; case ARC_SPACE_DNODE: ARCSTAT_INCR(arcstat_dnode_size, space); break; case ARC_SPACE_DBUF: ARCSTAT_INCR(arcstat_dbuf_size, space); break; case ARC_SPACE_HDRS: ARCSTAT_INCR(arcstat_hdr_size, space); break; case ARC_SPACE_L2HDRS: aggsum_add(&arc_sums.arcstat_l2_hdr_size, space); break; case ARC_SPACE_ABD_CHUNK_WASTE: /* * Note: this includes space wasted by all scatter ABD's, not * just those allocated by the ARC. But the vast majority of * scatter ABD's come from the ARC, because other users are * very short-lived. */ ARCSTAT_INCR(arcstat_abd_chunk_waste_size, space); break; } if (type != ARC_SPACE_DATA && type != ARC_SPACE_ABD_CHUNK_WASTE) ARCSTAT_INCR(arcstat_meta_used, space); aggsum_add(&arc_sums.arcstat_size, space); } void arc_space_return(uint64_t space, arc_space_type_t type) { ASSERT(type >= 0 && type < ARC_SPACE_NUMTYPES); switch (type) { default: break; case ARC_SPACE_DATA: ARCSTAT_INCR(arcstat_data_size, -space); break; case ARC_SPACE_META: ARCSTAT_INCR(arcstat_metadata_size, -space); break; case ARC_SPACE_BONUS: ARCSTAT_INCR(arcstat_bonus_size, -space); break; case ARC_SPACE_DNODE: ARCSTAT_INCR(arcstat_dnode_size, -space); break; case ARC_SPACE_DBUF: ARCSTAT_INCR(arcstat_dbuf_size, -space); break; case ARC_SPACE_HDRS: ARCSTAT_INCR(arcstat_hdr_size, -space); break; case ARC_SPACE_L2HDRS: aggsum_add(&arc_sums.arcstat_l2_hdr_size, -space); break; case ARC_SPACE_ABD_CHUNK_WASTE: ARCSTAT_INCR(arcstat_abd_chunk_waste_size, -space); break; } if (type != ARC_SPACE_DATA && type != ARC_SPACE_ABD_CHUNK_WASTE) ARCSTAT_INCR(arcstat_meta_used, -space); ASSERT(aggsum_compare(&arc_sums.arcstat_size, space) >= 0); aggsum_add(&arc_sums.arcstat_size, -space); } /* * Given a hdr and a buf, returns whether that buf can share its b_data buffer * with the hdr's b_pabd. */ static boolean_t arc_can_share(arc_buf_hdr_t *hdr, arc_buf_t *buf) { /* * The criteria for sharing a hdr's data are: * 1. the buffer is not encrypted * 2. the hdr's compression matches the buf's compression * 3. the hdr doesn't need to be byteswapped * 4. the hdr isn't already being shared * 5. the buf is either compressed or it is the last buf in the hdr list * * Criterion #5 maintains the invariant that shared uncompressed * bufs must be the final buf in the hdr's b_buf list. Reading this, you * might ask, "if a compressed buf is allocated first, won't that be the * last thing in the list?", but in that case it's impossible to create * a shared uncompressed buf anyway (because the hdr must be compressed * to have the compressed buf). You might also think that #3 is * sufficient to make this guarantee, however it's possible * (specifically in the rare L2ARC write race mentioned in * arc_buf_alloc_impl()) there will be an existing uncompressed buf that * is shareable, but wasn't at the time of its allocation. Rather than * allow a new shared uncompressed buf to be created and then shuffle * the list around to make it the last element, this simply disallows * sharing if the new buf isn't the first to be added. */ ASSERT3P(buf->b_hdr, ==, hdr); boolean_t hdr_compressed = arc_hdr_get_compress(hdr) != ZIO_COMPRESS_OFF; boolean_t buf_compressed = ARC_BUF_COMPRESSED(buf) != 0; return (!ARC_BUF_ENCRYPTED(buf) && buf_compressed == hdr_compressed && hdr->b_l1hdr.b_byteswap == DMU_BSWAP_NUMFUNCS && !HDR_SHARED_DATA(hdr) && (ARC_BUF_LAST(buf) || ARC_BUF_COMPRESSED(buf))); } /* * Allocate a buf for this hdr. If you care about the data that's in the hdr, * or if you want a compressed buffer, pass those flags in. Returns 0 if the * copy was made successfully, or an error code otherwise. */ static int arc_buf_alloc_impl(arc_buf_hdr_t *hdr, spa_t *spa, const zbookmark_phys_t *zb, const void *tag, boolean_t encrypted, boolean_t compressed, boolean_t noauth, boolean_t fill, arc_buf_t **ret) { arc_buf_t *buf; arc_fill_flags_t flags = ARC_FILL_LOCKED; ASSERT(HDR_HAS_L1HDR(hdr)); ASSERT3U(HDR_GET_LSIZE(hdr), >, 0); VERIFY(hdr->b_type == ARC_BUFC_DATA || hdr->b_type == ARC_BUFC_METADATA); ASSERT3P(ret, !=, NULL); ASSERT3P(*ret, ==, NULL); IMPLY(encrypted, compressed); buf = *ret = kmem_cache_alloc(buf_cache, KM_PUSHPAGE); buf->b_hdr = hdr; buf->b_data = NULL; buf->b_next = hdr->b_l1hdr.b_buf; buf->b_flags = 0; add_reference(hdr, tag); /* * We're about to change the hdr's b_flags. We must either * hold the hash_lock or be undiscoverable. */ ASSERT(HDR_EMPTY_OR_LOCKED(hdr)); /* * Only honor requests for compressed bufs if the hdr is actually * compressed. This must be overridden if the buffer is encrypted since * encrypted buffers cannot be decompressed. */ if (encrypted) { buf->b_flags |= ARC_BUF_FLAG_COMPRESSED; buf->b_flags |= ARC_BUF_FLAG_ENCRYPTED; flags |= ARC_FILL_COMPRESSED | ARC_FILL_ENCRYPTED; } else if (compressed && arc_hdr_get_compress(hdr) != ZIO_COMPRESS_OFF) { buf->b_flags |= ARC_BUF_FLAG_COMPRESSED; flags |= ARC_FILL_COMPRESSED; } if (noauth) { ASSERT0(encrypted); flags |= ARC_FILL_NOAUTH; } /* * If the hdr's data can be shared then we share the data buffer and * set the appropriate bit in the hdr's b_flags to indicate the hdr is * sharing it's b_pabd with the arc_buf_t. Otherwise, we allocate a new * buffer to store the buf's data. * * There are two additional restrictions here because we're sharing * hdr -> buf instead of the usual buf -> hdr. First, the hdr can't be * actively involved in an L2ARC write, because if this buf is used by * an arc_write() then the hdr's data buffer will be released when the * write completes, even though the L2ARC write might still be using it. * Second, the hdr's ABD must be linear so that the buf's user doesn't * need to be ABD-aware. It must be allocated via * zio_[data_]buf_alloc(), not as a page, because we need to be able * to abd_release_ownership_of_buf(), which isn't allowed on "linear * page" buffers because the ABD code needs to handle freeing them * specially. */ boolean_t can_share = arc_can_share(hdr, buf) && !HDR_L2_WRITING(hdr) && hdr->b_l1hdr.b_pabd != NULL && abd_is_linear(hdr->b_l1hdr.b_pabd) && !abd_is_linear_page(hdr->b_l1hdr.b_pabd); /* Set up b_data and sharing */ if (can_share) { buf->b_data = abd_to_buf(hdr->b_l1hdr.b_pabd); buf->b_flags |= ARC_BUF_FLAG_SHARED; arc_hdr_set_flags(hdr, ARC_FLAG_SHARED_DATA); } else { buf->b_data = arc_get_data_buf(hdr, arc_buf_size(buf), buf); ARCSTAT_INCR(arcstat_overhead_size, arc_buf_size(buf)); } VERIFY3P(buf->b_data, !=, NULL); hdr->b_l1hdr.b_buf = buf; /* * If the user wants the data from the hdr, we need to either copy or * decompress the data. */ if (fill) { ASSERT3P(zb, !=, NULL); return (arc_buf_fill(buf, spa, zb, flags)); } return (0); } static const char *arc_onloan_tag = "onloan"; static inline void arc_loaned_bytes_update(int64_t delta) { atomic_add_64(&arc_loaned_bytes, delta); /* assert that it did not wrap around */ ASSERT3S(atomic_add_64_nv(&arc_loaned_bytes, 0), >=, 0); } /* * Loan out an anonymous arc buffer. Loaned buffers are not counted as in * flight data by arc_tempreserve_space() until they are "returned". Loaned * buffers must be returned to the arc before they can be used by the DMU or * freed. */ arc_buf_t * arc_loan_buf(spa_t *spa, boolean_t is_metadata, int size) { arc_buf_t *buf = arc_alloc_buf(spa, arc_onloan_tag, is_metadata ? ARC_BUFC_METADATA : ARC_BUFC_DATA, size); arc_loaned_bytes_update(arc_buf_size(buf)); return (buf); } arc_buf_t * arc_loan_compressed_buf(spa_t *spa, uint64_t psize, uint64_t lsize, enum zio_compress compression_type, uint8_t complevel) { arc_buf_t *buf = arc_alloc_compressed_buf(spa, arc_onloan_tag, psize, lsize, compression_type, complevel); arc_loaned_bytes_update(arc_buf_size(buf)); return (buf); } arc_buf_t * arc_loan_raw_buf(spa_t *spa, uint64_t dsobj, boolean_t byteorder, const uint8_t *salt, const uint8_t *iv, const uint8_t *mac, dmu_object_type_t ot, uint64_t psize, uint64_t lsize, enum zio_compress compression_type, uint8_t complevel) { arc_buf_t *buf = arc_alloc_raw_buf(spa, arc_onloan_tag, dsobj, byteorder, salt, iv, mac, ot, psize, lsize, compression_type, complevel); atomic_add_64(&arc_loaned_bytes, psize); return (buf); } /* * Return a loaned arc buffer to the arc. */ void arc_return_buf(arc_buf_t *buf, const void *tag) { arc_buf_hdr_t *hdr = buf->b_hdr; ASSERT3P(buf->b_data, !=, NULL); ASSERT(HDR_HAS_L1HDR(hdr)); (void) zfs_refcount_add(&hdr->b_l1hdr.b_refcnt, tag); (void) zfs_refcount_remove(&hdr->b_l1hdr.b_refcnt, arc_onloan_tag); arc_loaned_bytes_update(-arc_buf_size(buf)); } /* Detach an arc_buf from a dbuf (tag) */ void arc_loan_inuse_buf(arc_buf_t *buf, const void *tag) { arc_buf_hdr_t *hdr = buf->b_hdr; ASSERT3P(buf->b_data, !=, NULL); ASSERT(HDR_HAS_L1HDR(hdr)); (void) zfs_refcount_add(&hdr->b_l1hdr.b_refcnt, arc_onloan_tag); (void) zfs_refcount_remove(&hdr->b_l1hdr.b_refcnt, tag); arc_loaned_bytes_update(arc_buf_size(buf)); } static void l2arc_free_abd_on_write(abd_t *abd, size_t size, arc_buf_contents_t type) { l2arc_data_free_t *df = kmem_alloc(sizeof (*df), KM_SLEEP); df->l2df_abd = abd; df->l2df_size = size; df->l2df_type = type; mutex_enter(&l2arc_free_on_write_mtx); list_insert_head(l2arc_free_on_write, df); mutex_exit(&l2arc_free_on_write_mtx); } static void arc_hdr_free_on_write(arc_buf_hdr_t *hdr, boolean_t free_rdata) { arc_state_t *state = hdr->b_l1hdr.b_state; arc_buf_contents_t type = arc_buf_type(hdr); uint64_t size = (free_rdata) ? HDR_GET_PSIZE(hdr) : arc_hdr_size(hdr); /* protected by hash lock, if in the hash table */ if (multilist_link_active(&hdr->b_l1hdr.b_arc_node)) { ASSERT(zfs_refcount_is_zero(&hdr->b_l1hdr.b_refcnt)); ASSERT(state != arc_anon && state != arc_l2c_only); (void) zfs_refcount_remove_many(&state->arcs_esize[type], size, hdr); } (void) zfs_refcount_remove_many(&state->arcs_size[type], size, hdr); if (type == ARC_BUFC_METADATA) { arc_space_return(size, ARC_SPACE_META); } else { ASSERT(type == ARC_BUFC_DATA); arc_space_return(size, ARC_SPACE_DATA); } if (free_rdata) { l2arc_free_abd_on_write(hdr->b_crypt_hdr.b_rabd, size, type); } else { l2arc_free_abd_on_write(hdr->b_l1hdr.b_pabd, size, type); } } /* * Share the arc_buf_t's data with the hdr. Whenever we are sharing the * data buffer, we transfer the refcount ownership to the hdr and update * the appropriate kstats. */ static void arc_share_buf(arc_buf_hdr_t *hdr, arc_buf_t *buf) { ASSERT(arc_can_share(hdr, buf)); ASSERT3P(hdr->b_l1hdr.b_pabd, ==, NULL); ASSERT(!ARC_BUF_ENCRYPTED(buf)); ASSERT(HDR_EMPTY_OR_LOCKED(hdr)); /* * Start sharing the data buffer. We transfer the * refcount ownership to the hdr since it always owns * the refcount whenever an arc_buf_t is shared. */ zfs_refcount_transfer_ownership_many( &hdr->b_l1hdr.b_state->arcs_size[arc_buf_type(hdr)], arc_hdr_size(hdr), buf, hdr); hdr->b_l1hdr.b_pabd = abd_get_from_buf(buf->b_data, arc_buf_size(buf)); abd_take_ownership_of_buf(hdr->b_l1hdr.b_pabd, HDR_ISTYPE_METADATA(hdr)); arc_hdr_set_flags(hdr, ARC_FLAG_SHARED_DATA); buf->b_flags |= ARC_BUF_FLAG_SHARED; /* * Since we've transferred ownership to the hdr we need * to increment its compressed and uncompressed kstats and * decrement the overhead size. */ ARCSTAT_INCR(arcstat_compressed_size, arc_hdr_size(hdr)); ARCSTAT_INCR(arcstat_uncompressed_size, HDR_GET_LSIZE(hdr)); ARCSTAT_INCR(arcstat_overhead_size, -arc_buf_size(buf)); } static void arc_unshare_buf(arc_buf_hdr_t *hdr, arc_buf_t *buf) { ASSERT(arc_buf_is_shared(buf)); ASSERT3P(hdr->b_l1hdr.b_pabd, !=, NULL); ASSERT(HDR_EMPTY_OR_LOCKED(hdr)); /* * We are no longer sharing this buffer so we need * to transfer its ownership to the rightful owner. */ zfs_refcount_transfer_ownership_many( &hdr->b_l1hdr.b_state->arcs_size[arc_buf_type(hdr)], arc_hdr_size(hdr), hdr, buf); arc_hdr_clear_flags(hdr, ARC_FLAG_SHARED_DATA); abd_release_ownership_of_buf(hdr->b_l1hdr.b_pabd); abd_free(hdr->b_l1hdr.b_pabd); hdr->b_l1hdr.b_pabd = NULL; buf->b_flags &= ~ARC_BUF_FLAG_SHARED; /* * Since the buffer is no longer shared between * the arc buf and the hdr, count it as overhead. */ ARCSTAT_INCR(arcstat_compressed_size, -arc_hdr_size(hdr)); ARCSTAT_INCR(arcstat_uncompressed_size, -HDR_GET_LSIZE(hdr)); ARCSTAT_INCR(arcstat_overhead_size, arc_buf_size(buf)); } /* * Remove an arc_buf_t from the hdr's buf list and return the last * arc_buf_t on the list. If no buffers remain on the list then return * NULL. */ static arc_buf_t * arc_buf_remove(arc_buf_hdr_t *hdr, arc_buf_t *buf) { ASSERT(HDR_HAS_L1HDR(hdr)); ASSERT(HDR_EMPTY_OR_LOCKED(hdr)); arc_buf_t **bufp = &hdr->b_l1hdr.b_buf; arc_buf_t *lastbuf = NULL; /* * Remove the buf from the hdr list and locate the last * remaining buffer on the list. */ while (*bufp != NULL) { if (*bufp == buf) *bufp = buf->b_next; /* * If we've removed a buffer in the middle of * the list then update the lastbuf and update * bufp. */ if (*bufp != NULL) { lastbuf = *bufp; bufp = &(*bufp)->b_next; } } buf->b_next = NULL; ASSERT3P(lastbuf, !=, buf); IMPLY(lastbuf != NULL, ARC_BUF_LAST(lastbuf)); return (lastbuf); } /* * Free up buf->b_data and pull the arc_buf_t off of the arc_buf_hdr_t's * list and free it. */ static void arc_buf_destroy_impl(arc_buf_t *buf) { arc_buf_hdr_t *hdr = buf->b_hdr; /* * Free up the data associated with the buf but only if we're not * sharing this with the hdr. If we are sharing it with the hdr, the * hdr is responsible for doing the free. */ if (buf->b_data != NULL) { /* * We're about to change the hdr's b_flags. We must either * hold the hash_lock or be undiscoverable. */ ASSERT(HDR_EMPTY_OR_LOCKED(hdr)); arc_cksum_verify(buf); arc_buf_unwatch(buf); - if (arc_buf_is_shared(buf)) { + if (ARC_BUF_SHARED(buf)) { arc_hdr_clear_flags(hdr, ARC_FLAG_SHARED_DATA); } else { + ASSERT(!arc_buf_is_shared(buf)); uint64_t size = arc_buf_size(buf); arc_free_data_buf(hdr, buf->b_data, size, buf); ARCSTAT_INCR(arcstat_overhead_size, -size); } buf->b_data = NULL; /* * If we have no more encrypted buffers and we've already * gotten a copy of the decrypted data we can free b_rabd * to save some space. */ if (ARC_BUF_ENCRYPTED(buf) && HDR_HAS_RABD(hdr) && hdr->b_l1hdr.b_pabd != NULL && !HDR_IO_IN_PROGRESS(hdr)) { arc_buf_t *b; for (b = hdr->b_l1hdr.b_buf; b; b = b->b_next) { if (b != buf && ARC_BUF_ENCRYPTED(b)) break; } if (b == NULL) arc_hdr_free_abd(hdr, B_TRUE); } } arc_buf_t *lastbuf = arc_buf_remove(hdr, buf); if (ARC_BUF_SHARED(buf) && !ARC_BUF_COMPRESSED(buf)) { /* * If the current arc_buf_t is sharing its data buffer with the * hdr, then reassign the hdr's b_pabd to share it with the new * buffer at the end of the list. The shared buffer is always * the last one on the hdr's buffer list. * * There is an equivalent case for compressed bufs, but since * they aren't guaranteed to be the last buf in the list and * that is an exceedingly rare case, we just allow that space be * wasted temporarily. We must also be careful not to share * encrypted buffers, since they cannot be shared. */ if (lastbuf != NULL && !ARC_BUF_ENCRYPTED(lastbuf)) { /* Only one buf can be shared at once */ - VERIFY(!arc_buf_is_shared(lastbuf)); + ASSERT(!arc_buf_is_shared(lastbuf)); /* hdr is uncompressed so can't have compressed buf */ - VERIFY(!ARC_BUF_COMPRESSED(lastbuf)); + ASSERT(!ARC_BUF_COMPRESSED(lastbuf)); ASSERT3P(hdr->b_l1hdr.b_pabd, !=, NULL); arc_hdr_free_abd(hdr, B_FALSE); /* * We must setup a new shared block between the * last buffer and the hdr. The data would have * been allocated by the arc buf so we need to transfer * ownership to the hdr since it's now being shared. */ arc_share_buf(hdr, lastbuf); } } else if (HDR_SHARED_DATA(hdr)) { /* * Uncompressed shared buffers are always at the end * of the list. Compressed buffers don't have the * same requirements. This makes it hard to * simply assert that the lastbuf is shared so * we rely on the hdr's compression flags to determine * if we have a compressed, shared buffer. */ ASSERT3P(lastbuf, !=, NULL); ASSERT(arc_buf_is_shared(lastbuf) || arc_hdr_get_compress(hdr) != ZIO_COMPRESS_OFF); } /* * Free the checksum if we're removing the last uncompressed buf from * this hdr. */ if (!arc_hdr_has_uncompressed_buf(hdr)) { arc_cksum_free(hdr); } /* clean up the buf */ buf->b_hdr = NULL; kmem_cache_free(buf_cache, buf); } static void arc_hdr_alloc_abd(arc_buf_hdr_t *hdr, int alloc_flags) { uint64_t size; boolean_t alloc_rdata = ((alloc_flags & ARC_HDR_ALLOC_RDATA) != 0); ASSERT3U(HDR_GET_LSIZE(hdr), >, 0); ASSERT(HDR_HAS_L1HDR(hdr)); ASSERT(!HDR_SHARED_DATA(hdr) || alloc_rdata); IMPLY(alloc_rdata, HDR_PROTECTED(hdr)); if (alloc_rdata) { size = HDR_GET_PSIZE(hdr); ASSERT3P(hdr->b_crypt_hdr.b_rabd, ==, NULL); hdr->b_crypt_hdr.b_rabd = arc_get_data_abd(hdr, size, hdr, alloc_flags); ASSERT3P(hdr->b_crypt_hdr.b_rabd, !=, NULL); ARCSTAT_INCR(arcstat_raw_size, size); } else { size = arc_hdr_size(hdr); ASSERT3P(hdr->b_l1hdr.b_pabd, ==, NULL); hdr->b_l1hdr.b_pabd = arc_get_data_abd(hdr, size, hdr, alloc_flags); ASSERT3P(hdr->b_l1hdr.b_pabd, !=, NULL); } ARCSTAT_INCR(arcstat_compressed_size, size); ARCSTAT_INCR(arcstat_uncompressed_size, HDR_GET_LSIZE(hdr)); } static void arc_hdr_free_abd(arc_buf_hdr_t *hdr, boolean_t free_rdata) { uint64_t size = (free_rdata) ? HDR_GET_PSIZE(hdr) : arc_hdr_size(hdr); ASSERT(HDR_HAS_L1HDR(hdr)); ASSERT(hdr->b_l1hdr.b_pabd != NULL || HDR_HAS_RABD(hdr)); IMPLY(free_rdata, HDR_HAS_RABD(hdr)); /* * If the hdr is currently being written to the l2arc then * we defer freeing the data by adding it to the l2arc_free_on_write * list. The l2arc will free the data once it's finished * writing it to the l2arc device. */ if (HDR_L2_WRITING(hdr)) { arc_hdr_free_on_write(hdr, free_rdata); ARCSTAT_BUMP(arcstat_l2_free_on_write); } else if (free_rdata) { arc_free_data_abd(hdr, hdr->b_crypt_hdr.b_rabd, size, hdr); } else { arc_free_data_abd(hdr, hdr->b_l1hdr.b_pabd, size, hdr); } if (free_rdata) { hdr->b_crypt_hdr.b_rabd = NULL; ARCSTAT_INCR(arcstat_raw_size, -size); } else { hdr->b_l1hdr.b_pabd = NULL; } if (hdr->b_l1hdr.b_pabd == NULL && !HDR_HAS_RABD(hdr)) hdr->b_l1hdr.b_byteswap = DMU_BSWAP_NUMFUNCS; ARCSTAT_INCR(arcstat_compressed_size, -size); ARCSTAT_INCR(arcstat_uncompressed_size, -HDR_GET_LSIZE(hdr)); } /* * Allocate empty anonymous ARC header. The header will get its identity * assigned and buffers attached later as part of read or write operations. * * In case of read arc_read() assigns header its identify (b_dva + b_birth), * inserts it into ARC hash to become globally visible and allocates physical * (b_pabd) or raw (b_rabd) ABD buffer to read into from disk. On disk read * completion arc_read_done() allocates ARC buffer(s) as needed, potentially * sharing one of them with the physical ABD buffer. * * In case of write arc_alloc_buf() allocates ARC buffer to be filled with * data. Then after compression and/or encryption arc_write_ready() allocates * and fills (or potentially shares) physical (b_pabd) or raw (b_rabd) ABD * buffer. On disk write completion arc_write_done() assigns the header its * new identity (b_dva + b_birth) and inserts into ARC hash. * * In case of partial overwrite the old data is read first as described. Then * arc_release() either allocates new anonymous ARC header and moves the ARC * buffer to it, or reuses the old ARC header by discarding its identity and * removing it from ARC hash. After buffer modification normal write process * follows as described. */ static arc_buf_hdr_t * arc_hdr_alloc(uint64_t spa, int32_t psize, int32_t lsize, boolean_t protected, enum zio_compress compression_type, uint8_t complevel, arc_buf_contents_t type) { arc_buf_hdr_t *hdr; VERIFY(type == ARC_BUFC_DATA || type == ARC_BUFC_METADATA); hdr = kmem_cache_alloc(hdr_full_cache, KM_PUSHPAGE); ASSERT(HDR_EMPTY(hdr)); #ifdef ZFS_DEBUG ASSERT3P(hdr->b_l1hdr.b_freeze_cksum, ==, NULL); #endif HDR_SET_PSIZE(hdr, psize); HDR_SET_LSIZE(hdr, lsize); hdr->b_spa = spa; hdr->b_type = type; hdr->b_flags = 0; arc_hdr_set_flags(hdr, arc_bufc_to_flags(type) | ARC_FLAG_HAS_L1HDR); arc_hdr_set_compress(hdr, compression_type); hdr->b_complevel = complevel; if (protected) arc_hdr_set_flags(hdr, ARC_FLAG_PROTECTED); hdr->b_l1hdr.b_state = arc_anon; hdr->b_l1hdr.b_arc_access = 0; hdr->b_l1hdr.b_mru_hits = 0; hdr->b_l1hdr.b_mru_ghost_hits = 0; hdr->b_l1hdr.b_mfu_hits = 0; hdr->b_l1hdr.b_mfu_ghost_hits = 0; hdr->b_l1hdr.b_buf = NULL; ASSERT(zfs_refcount_is_zero(&hdr->b_l1hdr.b_refcnt)); return (hdr); } /* * Transition between the two allocation states for the arc_buf_hdr struct. * The arc_buf_hdr struct can be allocated with (hdr_full_cache) or without * (hdr_l2only_cache) the fields necessary for the L1 cache - the smaller * version is used when a cache buffer is only in the L2ARC in order to reduce * memory usage. */ static arc_buf_hdr_t * arc_hdr_realloc(arc_buf_hdr_t *hdr, kmem_cache_t *old, kmem_cache_t *new) { ASSERT(HDR_HAS_L2HDR(hdr)); arc_buf_hdr_t *nhdr; l2arc_dev_t *dev = hdr->b_l2hdr.b_dev; ASSERT((old == hdr_full_cache && new == hdr_l2only_cache) || (old == hdr_l2only_cache && new == hdr_full_cache)); nhdr = kmem_cache_alloc(new, KM_PUSHPAGE); ASSERT(MUTEX_HELD(HDR_LOCK(hdr))); buf_hash_remove(hdr); memcpy(nhdr, hdr, HDR_L2ONLY_SIZE); if (new == hdr_full_cache) { arc_hdr_set_flags(nhdr, ARC_FLAG_HAS_L1HDR); /* * arc_access and arc_change_state need to be aware that a * header has just come out of L2ARC, so we set its state to * l2c_only even though it's about to change. */ nhdr->b_l1hdr.b_state = arc_l2c_only; /* Verify previous threads set to NULL before freeing */ ASSERT3P(nhdr->b_l1hdr.b_pabd, ==, NULL); ASSERT(!HDR_HAS_RABD(hdr)); } else { ASSERT3P(hdr->b_l1hdr.b_buf, ==, NULL); #ifdef ZFS_DEBUG ASSERT3P(hdr->b_l1hdr.b_freeze_cksum, ==, NULL); #endif /* * If we've reached here, We must have been called from * arc_evict_hdr(), as such we should have already been * removed from any ghost list we were previously on * (which protects us from racing with arc_evict_state), * thus no locking is needed during this check. */ ASSERT(!multilist_link_active(&hdr->b_l1hdr.b_arc_node)); /* * A buffer must not be moved into the arc_l2c_only * state if it's not finished being written out to the * l2arc device. Otherwise, the b_l1hdr.b_pabd field * might try to be accessed, even though it was removed. */ VERIFY(!HDR_L2_WRITING(hdr)); VERIFY3P(hdr->b_l1hdr.b_pabd, ==, NULL); ASSERT(!HDR_HAS_RABD(hdr)); arc_hdr_clear_flags(nhdr, ARC_FLAG_HAS_L1HDR); } /* * The header has been reallocated so we need to re-insert it into any * lists it was on. */ (void) buf_hash_insert(nhdr, NULL); ASSERT(list_link_active(&hdr->b_l2hdr.b_l2node)); mutex_enter(&dev->l2ad_mtx); /* * We must place the realloc'ed header back into the list at * the same spot. Otherwise, if it's placed earlier in the list, * l2arc_write_buffers() could find it during the function's * write phase, and try to write it out to the l2arc. */ list_insert_after(&dev->l2ad_buflist, hdr, nhdr); list_remove(&dev->l2ad_buflist, hdr); mutex_exit(&dev->l2ad_mtx); /* * Since we're using the pointer address as the tag when * incrementing and decrementing the l2ad_alloc refcount, we * must remove the old pointer (that we're about to destroy) and * add the new pointer to the refcount. Otherwise we'd remove * the wrong pointer address when calling arc_hdr_destroy() later. */ (void) zfs_refcount_remove_many(&dev->l2ad_alloc, arc_hdr_size(hdr), hdr); (void) zfs_refcount_add_many(&dev->l2ad_alloc, arc_hdr_size(nhdr), nhdr); buf_discard_identity(hdr); kmem_cache_free(old, hdr); return (nhdr); } /* * This function is used by the send / receive code to convert a newly * allocated arc_buf_t to one that is suitable for a raw encrypted write. It * is also used to allow the root objset block to be updated without altering * its embedded MACs. Both block types will always be uncompressed so we do not * have to worry about compression type or psize. */ void arc_convert_to_raw(arc_buf_t *buf, uint64_t dsobj, boolean_t byteorder, dmu_object_type_t ot, const uint8_t *salt, const uint8_t *iv, const uint8_t *mac) { arc_buf_hdr_t *hdr = buf->b_hdr; ASSERT(ot == DMU_OT_DNODE || ot == DMU_OT_OBJSET); ASSERT(HDR_HAS_L1HDR(hdr)); ASSERT3P(hdr->b_l1hdr.b_state, ==, arc_anon); buf->b_flags |= (ARC_BUF_FLAG_COMPRESSED | ARC_BUF_FLAG_ENCRYPTED); arc_hdr_set_flags(hdr, ARC_FLAG_PROTECTED); hdr->b_crypt_hdr.b_dsobj = dsobj; hdr->b_crypt_hdr.b_ot = ot; hdr->b_l1hdr.b_byteswap = (byteorder == ZFS_HOST_BYTEORDER) ? DMU_BSWAP_NUMFUNCS : DMU_OT_BYTESWAP(ot); if (!arc_hdr_has_uncompressed_buf(hdr)) arc_cksum_free(hdr); if (salt != NULL) memcpy(hdr->b_crypt_hdr.b_salt, salt, ZIO_DATA_SALT_LEN); if (iv != NULL) memcpy(hdr->b_crypt_hdr.b_iv, iv, ZIO_DATA_IV_LEN); if (mac != NULL) memcpy(hdr->b_crypt_hdr.b_mac, mac, ZIO_DATA_MAC_LEN); } /* * Allocate a new arc_buf_hdr_t and arc_buf_t and return the buf to the caller. * The buf is returned thawed since we expect the consumer to modify it. */ arc_buf_t * arc_alloc_buf(spa_t *spa, const void *tag, arc_buf_contents_t type, int32_t size) { arc_buf_hdr_t *hdr = arc_hdr_alloc(spa_load_guid(spa), size, size, B_FALSE, ZIO_COMPRESS_OFF, 0, type); arc_buf_t *buf = NULL; VERIFY0(arc_buf_alloc_impl(hdr, spa, NULL, tag, B_FALSE, B_FALSE, B_FALSE, B_FALSE, &buf)); arc_buf_thaw(buf); return (buf); } /* * Allocate a compressed buf in the same manner as arc_alloc_buf. Don't use this * for bufs containing metadata. */ arc_buf_t * arc_alloc_compressed_buf(spa_t *spa, const void *tag, uint64_t psize, uint64_t lsize, enum zio_compress compression_type, uint8_t complevel) { ASSERT3U(lsize, >, 0); ASSERT3U(lsize, >=, psize); ASSERT3U(compression_type, >, ZIO_COMPRESS_OFF); ASSERT3U(compression_type, <, ZIO_COMPRESS_FUNCTIONS); arc_buf_hdr_t *hdr = arc_hdr_alloc(spa_load_guid(spa), psize, lsize, B_FALSE, compression_type, complevel, ARC_BUFC_DATA); arc_buf_t *buf = NULL; VERIFY0(arc_buf_alloc_impl(hdr, spa, NULL, tag, B_FALSE, B_TRUE, B_FALSE, B_FALSE, &buf)); arc_buf_thaw(buf); /* * To ensure that the hdr has the correct data in it if we call * arc_untransform() on this buf before it's been written to disk, * it's easiest if we just set up sharing between the buf and the hdr. */ arc_share_buf(hdr, buf); return (buf); } arc_buf_t * arc_alloc_raw_buf(spa_t *spa, const void *tag, uint64_t dsobj, boolean_t byteorder, const uint8_t *salt, const uint8_t *iv, const uint8_t *mac, dmu_object_type_t ot, uint64_t psize, uint64_t lsize, enum zio_compress compression_type, uint8_t complevel) { arc_buf_hdr_t *hdr; arc_buf_t *buf; arc_buf_contents_t type = DMU_OT_IS_METADATA(ot) ? ARC_BUFC_METADATA : ARC_BUFC_DATA; ASSERT3U(lsize, >, 0); ASSERT3U(lsize, >=, psize); ASSERT3U(compression_type, >=, ZIO_COMPRESS_OFF); ASSERT3U(compression_type, <, ZIO_COMPRESS_FUNCTIONS); hdr = arc_hdr_alloc(spa_load_guid(spa), psize, lsize, B_TRUE, compression_type, complevel, type); hdr->b_crypt_hdr.b_dsobj = dsobj; hdr->b_crypt_hdr.b_ot = ot; hdr->b_l1hdr.b_byteswap = (byteorder == ZFS_HOST_BYTEORDER) ? DMU_BSWAP_NUMFUNCS : DMU_OT_BYTESWAP(ot); memcpy(hdr->b_crypt_hdr.b_salt, salt, ZIO_DATA_SALT_LEN); memcpy(hdr->b_crypt_hdr.b_iv, iv, ZIO_DATA_IV_LEN); memcpy(hdr->b_crypt_hdr.b_mac, mac, ZIO_DATA_MAC_LEN); /* * This buffer will be considered encrypted even if the ot is not an * encrypted type. It will become authenticated instead in * arc_write_ready(). */ buf = NULL; VERIFY0(arc_buf_alloc_impl(hdr, spa, NULL, tag, B_TRUE, B_TRUE, B_FALSE, B_FALSE, &buf)); arc_buf_thaw(buf); return (buf); } static void l2arc_hdr_arcstats_update(arc_buf_hdr_t *hdr, boolean_t incr, boolean_t state_only) { l2arc_buf_hdr_t *l2hdr = &hdr->b_l2hdr; l2arc_dev_t *dev = l2hdr->b_dev; uint64_t lsize = HDR_GET_LSIZE(hdr); uint64_t psize = HDR_GET_PSIZE(hdr); uint64_t asize = vdev_psize_to_asize(dev->l2ad_vdev, psize); arc_buf_contents_t type = hdr->b_type; int64_t lsize_s; int64_t psize_s; int64_t asize_s; if (incr) { lsize_s = lsize; psize_s = psize; asize_s = asize; } else { lsize_s = -lsize; psize_s = -psize; asize_s = -asize; } /* If the buffer is a prefetch, count it as such. */ if (HDR_PREFETCH(hdr)) { ARCSTAT_INCR(arcstat_l2_prefetch_asize, asize_s); } else { /* * We use the value stored in the L2 header upon initial * caching in L2ARC. This value will be updated in case * an MRU/MRU_ghost buffer transitions to MFU but the L2ARC * metadata (log entry) cannot currently be updated. Having * the ARC state in the L2 header solves the problem of a * possibly absent L1 header (apparent in buffers restored * from persistent L2ARC). */ switch (hdr->b_l2hdr.b_arcs_state) { case ARC_STATE_MRU_GHOST: case ARC_STATE_MRU: ARCSTAT_INCR(arcstat_l2_mru_asize, asize_s); break; case ARC_STATE_MFU_GHOST: case ARC_STATE_MFU: ARCSTAT_INCR(arcstat_l2_mfu_asize, asize_s); break; default: break; } } if (state_only) return; ARCSTAT_INCR(arcstat_l2_psize, psize_s); ARCSTAT_INCR(arcstat_l2_lsize, lsize_s); switch (type) { case ARC_BUFC_DATA: ARCSTAT_INCR(arcstat_l2_bufc_data_asize, asize_s); break; case ARC_BUFC_METADATA: ARCSTAT_INCR(arcstat_l2_bufc_metadata_asize, asize_s); break; default: break; } } static void arc_hdr_l2hdr_destroy(arc_buf_hdr_t *hdr) { l2arc_buf_hdr_t *l2hdr = &hdr->b_l2hdr; l2arc_dev_t *dev = l2hdr->b_dev; uint64_t psize = HDR_GET_PSIZE(hdr); uint64_t asize = vdev_psize_to_asize(dev->l2ad_vdev, psize); ASSERT(MUTEX_HELD(&dev->l2ad_mtx)); ASSERT(HDR_HAS_L2HDR(hdr)); list_remove(&dev->l2ad_buflist, hdr); l2arc_hdr_arcstats_decrement(hdr); vdev_space_update(dev->l2ad_vdev, -asize, 0, 0); (void) zfs_refcount_remove_many(&dev->l2ad_alloc, arc_hdr_size(hdr), hdr); arc_hdr_clear_flags(hdr, ARC_FLAG_HAS_L2HDR); } static void arc_hdr_destroy(arc_buf_hdr_t *hdr) { if (HDR_HAS_L1HDR(hdr)) { ASSERT(zfs_refcount_is_zero(&hdr->b_l1hdr.b_refcnt)); ASSERT3P(hdr->b_l1hdr.b_state, ==, arc_anon); } ASSERT(!HDR_IO_IN_PROGRESS(hdr)); ASSERT(!HDR_IN_HASH_TABLE(hdr)); if (HDR_HAS_L2HDR(hdr)) { l2arc_dev_t *dev = hdr->b_l2hdr.b_dev; boolean_t buflist_held = MUTEX_HELD(&dev->l2ad_mtx); if (!buflist_held) mutex_enter(&dev->l2ad_mtx); /* * Even though we checked this conditional above, we * need to check this again now that we have the * l2ad_mtx. This is because we could be racing with * another thread calling l2arc_evict() which might have * destroyed this header's L2 portion as we were waiting * to acquire the l2ad_mtx. If that happens, we don't * want to re-destroy the header's L2 portion. */ if (HDR_HAS_L2HDR(hdr)) { if (!HDR_EMPTY(hdr)) buf_discard_identity(hdr); arc_hdr_l2hdr_destroy(hdr); } if (!buflist_held) mutex_exit(&dev->l2ad_mtx); } /* * The header's identify can only be safely discarded once it is no * longer discoverable. This requires removing it from the hash table * and the l2arc header list. After this point the hash lock can not * be used to protect the header. */ if (!HDR_EMPTY(hdr)) buf_discard_identity(hdr); if (HDR_HAS_L1HDR(hdr)) { arc_cksum_free(hdr); while (hdr->b_l1hdr.b_buf != NULL) arc_buf_destroy_impl(hdr->b_l1hdr.b_buf); if (hdr->b_l1hdr.b_pabd != NULL) arc_hdr_free_abd(hdr, B_FALSE); if (HDR_HAS_RABD(hdr)) arc_hdr_free_abd(hdr, B_TRUE); } ASSERT3P(hdr->b_hash_next, ==, NULL); if (HDR_HAS_L1HDR(hdr)) { ASSERT(!multilist_link_active(&hdr->b_l1hdr.b_arc_node)); ASSERT3P(hdr->b_l1hdr.b_acb, ==, NULL); #ifdef ZFS_DEBUG ASSERT3P(hdr->b_l1hdr.b_freeze_cksum, ==, NULL); #endif kmem_cache_free(hdr_full_cache, hdr); } else { kmem_cache_free(hdr_l2only_cache, hdr); } } void arc_buf_destroy(arc_buf_t *buf, const void *tag) { arc_buf_hdr_t *hdr = buf->b_hdr; if (hdr->b_l1hdr.b_state == arc_anon) { ASSERT3P(hdr->b_l1hdr.b_buf, ==, buf); ASSERT(ARC_BUF_LAST(buf)); ASSERT(!HDR_IO_IN_PROGRESS(hdr)); VERIFY0(remove_reference(hdr, tag)); return; } kmutex_t *hash_lock = HDR_LOCK(hdr); mutex_enter(hash_lock); ASSERT3P(hdr, ==, buf->b_hdr); ASSERT3P(hdr->b_l1hdr.b_buf, !=, NULL); ASSERT3P(hash_lock, ==, HDR_LOCK(hdr)); ASSERT3P(hdr->b_l1hdr.b_state, !=, arc_anon); ASSERT3P(buf->b_data, !=, NULL); arc_buf_destroy_impl(buf); (void) remove_reference(hdr, tag); mutex_exit(hash_lock); } /* * Evict the arc_buf_hdr that is provided as a parameter. The resultant * state of the header is dependent on its state prior to entering this * function. The following transitions are possible: * * - arc_mru -> arc_mru_ghost * - arc_mfu -> arc_mfu_ghost * - arc_mru_ghost -> arc_l2c_only * - arc_mru_ghost -> deleted * - arc_mfu_ghost -> arc_l2c_only * - arc_mfu_ghost -> deleted * - arc_uncached -> deleted * * Return total size of evicted data buffers for eviction progress tracking. * When evicting from ghost states return logical buffer size to make eviction * progress at the same (or at least comparable) rate as from non-ghost states. * * Return *real_evicted for actual ARC size reduction to wake up threads * waiting for it. For non-ghost states it includes size of evicted data * buffers (the headers are not freed there). For ghost states it includes * only the evicted headers size. */ static int64_t arc_evict_hdr(arc_buf_hdr_t *hdr, uint64_t *real_evicted) { arc_state_t *evicted_state, *state; int64_t bytes_evicted = 0; uint_t min_lifetime = HDR_PRESCIENT_PREFETCH(hdr) ? arc_min_prescient_prefetch_ms : arc_min_prefetch_ms; ASSERT(MUTEX_HELD(HDR_LOCK(hdr))); ASSERT(HDR_HAS_L1HDR(hdr)); ASSERT(!HDR_IO_IN_PROGRESS(hdr)); ASSERT3P(hdr->b_l1hdr.b_buf, ==, NULL); ASSERT0(zfs_refcount_count(&hdr->b_l1hdr.b_refcnt)); *real_evicted = 0; state = hdr->b_l1hdr.b_state; if (GHOST_STATE(state)) { /* * l2arc_write_buffers() relies on a header's L1 portion * (i.e. its b_pabd field) during it's write phase. * Thus, we cannot push a header onto the arc_l2c_only * state (removing its L1 piece) until the header is * done being written to the l2arc. */ if (HDR_HAS_L2HDR(hdr) && HDR_L2_WRITING(hdr)) { ARCSTAT_BUMP(arcstat_evict_l2_skip); return (bytes_evicted); } ARCSTAT_BUMP(arcstat_deleted); bytes_evicted += HDR_GET_LSIZE(hdr); DTRACE_PROBE1(arc__delete, arc_buf_hdr_t *, hdr); if (HDR_HAS_L2HDR(hdr)) { ASSERT(hdr->b_l1hdr.b_pabd == NULL); ASSERT(!HDR_HAS_RABD(hdr)); /* * This buffer is cached on the 2nd Level ARC; * don't destroy the header. */ arc_change_state(arc_l2c_only, hdr); /* * dropping from L1+L2 cached to L2-only, * realloc to remove the L1 header. */ (void) arc_hdr_realloc(hdr, hdr_full_cache, hdr_l2only_cache); *real_evicted += HDR_FULL_SIZE - HDR_L2ONLY_SIZE; } else { arc_change_state(arc_anon, hdr); arc_hdr_destroy(hdr); *real_evicted += HDR_FULL_SIZE; } return (bytes_evicted); } ASSERT(state == arc_mru || state == arc_mfu || state == arc_uncached); evicted_state = (state == arc_uncached) ? arc_anon : ((state == arc_mru) ? arc_mru_ghost : arc_mfu_ghost); /* prefetch buffers have a minimum lifespan */ if ((hdr->b_flags & (ARC_FLAG_PREFETCH | ARC_FLAG_INDIRECT)) && ddi_get_lbolt() - hdr->b_l1hdr.b_arc_access < MSEC_TO_TICK(min_lifetime)) { ARCSTAT_BUMP(arcstat_evict_skip); return (bytes_evicted); } if (HDR_HAS_L2HDR(hdr)) { ARCSTAT_INCR(arcstat_evict_l2_cached, HDR_GET_LSIZE(hdr)); } else { if (l2arc_write_eligible(hdr->b_spa, hdr)) { ARCSTAT_INCR(arcstat_evict_l2_eligible, HDR_GET_LSIZE(hdr)); switch (state->arcs_state) { case ARC_STATE_MRU: ARCSTAT_INCR( arcstat_evict_l2_eligible_mru, HDR_GET_LSIZE(hdr)); break; case ARC_STATE_MFU: ARCSTAT_INCR( arcstat_evict_l2_eligible_mfu, HDR_GET_LSIZE(hdr)); break; default: break; } } else { ARCSTAT_INCR(arcstat_evict_l2_ineligible, HDR_GET_LSIZE(hdr)); } } bytes_evicted += arc_hdr_size(hdr); *real_evicted += arc_hdr_size(hdr); /* * If this hdr is being evicted and has a compressed buffer then we * discard it here before we change states. This ensures that the * accounting is updated correctly in arc_free_data_impl(). */ if (hdr->b_l1hdr.b_pabd != NULL) arc_hdr_free_abd(hdr, B_FALSE); if (HDR_HAS_RABD(hdr)) arc_hdr_free_abd(hdr, B_TRUE); arc_change_state(evicted_state, hdr); DTRACE_PROBE1(arc__evict, arc_buf_hdr_t *, hdr); if (evicted_state == arc_anon) { arc_hdr_destroy(hdr); *real_evicted += HDR_FULL_SIZE; } else { ASSERT(HDR_IN_HASH_TABLE(hdr)); } return (bytes_evicted); } static void arc_set_need_free(void) { ASSERT(MUTEX_HELD(&arc_evict_lock)); int64_t remaining = arc_free_memory() - arc_sys_free / 2; arc_evict_waiter_t *aw = list_tail(&arc_evict_waiters); if (aw == NULL) { arc_need_free = MAX(-remaining, 0); } else { arc_need_free = MAX(-remaining, (int64_t)(aw->aew_count - arc_evict_count)); } } static uint64_t arc_evict_state_impl(multilist_t *ml, int idx, arc_buf_hdr_t *marker, uint64_t spa, uint64_t bytes) { multilist_sublist_t *mls; uint64_t bytes_evicted = 0, real_evicted = 0; arc_buf_hdr_t *hdr; kmutex_t *hash_lock; uint_t evict_count = zfs_arc_evict_batch_limit; ASSERT3P(marker, !=, NULL); mls = multilist_sublist_lock(ml, idx); for (hdr = multilist_sublist_prev(mls, marker); likely(hdr != NULL); hdr = multilist_sublist_prev(mls, marker)) { if ((evict_count == 0) || (bytes_evicted >= bytes)) break; /* * To keep our iteration location, move the marker * forward. Since we're not holding hdr's hash lock, we * must be very careful and not remove 'hdr' from the * sublist. Otherwise, other consumers might mistake the * 'hdr' as not being on a sublist when they call the * multilist_link_active() function (they all rely on * the hash lock protecting concurrent insertions and * removals). multilist_sublist_move_forward() was * specifically implemented to ensure this is the case * (only 'marker' will be removed and re-inserted). */ multilist_sublist_move_forward(mls, marker); /* * The only case where the b_spa field should ever be * zero, is the marker headers inserted by * arc_evict_state(). It's possible for multiple threads * to be calling arc_evict_state() concurrently (e.g. * dsl_pool_close() and zio_inject_fault()), so we must * skip any markers we see from these other threads. */ if (hdr->b_spa == 0) continue; /* we're only interested in evicting buffers of a certain spa */ if (spa != 0 && hdr->b_spa != spa) { ARCSTAT_BUMP(arcstat_evict_skip); continue; } hash_lock = HDR_LOCK(hdr); /* * We aren't calling this function from any code path * that would already be holding a hash lock, so we're * asserting on this assumption to be defensive in case * this ever changes. Without this check, it would be * possible to incorrectly increment arcstat_mutex_miss * below (e.g. if the code changed such that we called * this function with a hash lock held). */ ASSERT(!MUTEX_HELD(hash_lock)); if (mutex_tryenter(hash_lock)) { uint64_t revicted; uint64_t evicted = arc_evict_hdr(hdr, &revicted); mutex_exit(hash_lock); bytes_evicted += evicted; real_evicted += revicted; /* * If evicted is zero, arc_evict_hdr() must have * decided to skip this header, don't increment * evict_count in this case. */ if (evicted != 0) evict_count--; } else { ARCSTAT_BUMP(arcstat_mutex_miss); } } multilist_sublist_unlock(mls); /* * Increment the count of evicted bytes, and wake up any threads that * are waiting for the count to reach this value. Since the list is * ordered by ascending aew_count, we pop off the beginning of the * list until we reach the end, or a waiter that's past the current * "count". Doing this outside the loop reduces the number of times * we need to acquire the global arc_evict_lock. * * Only wake when there's sufficient free memory in the system * (specifically, arc_sys_free/2, which by default is a bit more than * 1/64th of RAM). See the comments in arc_wait_for_eviction(). */ mutex_enter(&arc_evict_lock); arc_evict_count += real_evicted; if (arc_free_memory() > arc_sys_free / 2) { arc_evict_waiter_t *aw; while ((aw = list_head(&arc_evict_waiters)) != NULL && aw->aew_count <= arc_evict_count) { list_remove(&arc_evict_waiters, aw); cv_broadcast(&aw->aew_cv); } } arc_set_need_free(); mutex_exit(&arc_evict_lock); /* * If the ARC size is reduced from arc_c_max to arc_c_min (especially * if the average cached block is small), eviction can be on-CPU for * many seconds. To ensure that other threads that may be bound to * this CPU are able to make progress, make a voluntary preemption * call here. */ kpreempt(KPREEMPT_SYNC); return (bytes_evicted); } /* * Allocate an array of buffer headers used as placeholders during arc state * eviction. */ static arc_buf_hdr_t ** arc_state_alloc_markers(int count) { arc_buf_hdr_t **markers; markers = kmem_zalloc(sizeof (*markers) * count, KM_SLEEP); for (int i = 0; i < count; i++) { markers[i] = kmem_cache_alloc(hdr_full_cache, KM_SLEEP); /* * A b_spa of 0 is used to indicate that this header is * a marker. This fact is used in arc_evict_state_impl(). */ markers[i]->b_spa = 0; } return (markers); } static void arc_state_free_markers(arc_buf_hdr_t **markers, int count) { for (int i = 0; i < count; i++) kmem_cache_free(hdr_full_cache, markers[i]); kmem_free(markers, sizeof (*markers) * count); } /* * Evict buffers from the given arc state, until we've removed the * specified number of bytes. Move the removed buffers to the * appropriate evict state. * * This function makes a "best effort". It skips over any buffers * it can't get a hash_lock on, and so, may not catch all candidates. * It may also return without evicting as much space as requested. * * If bytes is specified using the special value ARC_EVICT_ALL, this * will evict all available (i.e. unlocked and evictable) buffers from * the given arc state; which is used by arc_flush(). */ static uint64_t arc_evict_state(arc_state_t *state, arc_buf_contents_t type, uint64_t spa, uint64_t bytes) { uint64_t total_evicted = 0; multilist_t *ml = &state->arcs_list[type]; int num_sublists; arc_buf_hdr_t **markers; num_sublists = multilist_get_num_sublists(ml); /* * If we've tried to evict from each sublist, made some * progress, but still have not hit the target number of bytes * to evict, we want to keep trying. The markers allow us to * pick up where we left off for each individual sublist, rather * than starting from the tail each time. */ if (zthr_iscurthread(arc_evict_zthr)) { markers = arc_state_evict_markers; ASSERT3S(num_sublists, <=, arc_state_evict_marker_count); } else { markers = arc_state_alloc_markers(num_sublists); } for (int i = 0; i < num_sublists; i++) { multilist_sublist_t *mls; mls = multilist_sublist_lock(ml, i); multilist_sublist_insert_tail(mls, markers[i]); multilist_sublist_unlock(mls); } /* * While we haven't hit our target number of bytes to evict, or * we're evicting all available buffers. */ while (total_evicted < bytes) { int sublist_idx = multilist_get_random_index(ml); uint64_t scan_evicted = 0; /* * Start eviction using a randomly selected sublist, * this is to try and evenly balance eviction across all * sublists. Always starting at the same sublist * (e.g. index 0) would cause evictions to favor certain * sublists over others. */ for (int i = 0; i < num_sublists; i++) { uint64_t bytes_remaining; uint64_t bytes_evicted; if (total_evicted < bytes) bytes_remaining = bytes - total_evicted; else break; bytes_evicted = arc_evict_state_impl(ml, sublist_idx, markers[sublist_idx], spa, bytes_remaining); scan_evicted += bytes_evicted; total_evicted += bytes_evicted; /* we've reached the end, wrap to the beginning */ if (++sublist_idx >= num_sublists) sublist_idx = 0; } /* * If we didn't evict anything during this scan, we have * no reason to believe we'll evict more during another * scan, so break the loop. */ if (scan_evicted == 0) { /* This isn't possible, let's make that obvious */ ASSERT3S(bytes, !=, 0); /* * When bytes is ARC_EVICT_ALL, the only way to * break the loop is when scan_evicted is zero. * In that case, we actually have evicted enough, * so we don't want to increment the kstat. */ if (bytes != ARC_EVICT_ALL) { ASSERT3S(total_evicted, <, bytes); ARCSTAT_BUMP(arcstat_evict_not_enough); } break; } } for (int i = 0; i < num_sublists; i++) { multilist_sublist_t *mls = multilist_sublist_lock(ml, i); multilist_sublist_remove(mls, markers[i]); multilist_sublist_unlock(mls); } if (markers != arc_state_evict_markers) arc_state_free_markers(markers, num_sublists); return (total_evicted); } /* * Flush all "evictable" data of the given type from the arc state * specified. This will not evict any "active" buffers (i.e. referenced). * * When 'retry' is set to B_FALSE, the function will make a single pass * over the state and evict any buffers that it can. Since it doesn't * continually retry the eviction, it might end up leaving some buffers * in the ARC due to lock misses. * * When 'retry' is set to B_TRUE, the function will continually retry the * eviction until *all* evictable buffers have been removed from the * state. As a result, if concurrent insertions into the state are * allowed (e.g. if the ARC isn't shutting down), this function might * wind up in an infinite loop, continually trying to evict buffers. */ static uint64_t arc_flush_state(arc_state_t *state, uint64_t spa, arc_buf_contents_t type, boolean_t retry) { uint64_t evicted = 0; while (zfs_refcount_count(&state->arcs_esize[type]) != 0) { evicted += arc_evict_state(state, type, spa, ARC_EVICT_ALL); if (!retry) break; } return (evicted); } /* * Evict the specified number of bytes from the state specified. This * function prevents us from trying to evict more from a state's list * than is "evictable", and to skip evicting altogether when passed a * negative value for "bytes". In contrast, arc_evict_state() will * evict everything it can, when passed a negative value for "bytes". */ static uint64_t arc_evict_impl(arc_state_t *state, arc_buf_contents_t type, int64_t bytes) { uint64_t delta; if (bytes > 0 && zfs_refcount_count(&state->arcs_esize[type]) > 0) { delta = MIN(zfs_refcount_count(&state->arcs_esize[type]), bytes); return (arc_evict_state(state, type, 0, delta)); } return (0); } /* * Adjust specified fraction, taking into account initial ghost state(s) size, * ghost hit bytes towards increasing the fraction, ghost hit bytes towards * decreasing it, plus a balance factor, controlling the decrease rate, used * to balance metadata vs data. */ static uint64_t arc_evict_adj(uint64_t frac, uint64_t total, uint64_t up, uint64_t down, uint_t balance) { if (total < 8 || up + down == 0) return (frac); /* * We should not have more ghost hits than ghost size, but they * may get close. Restrict maximum adjustment in that case. */ if (up + down >= total / 4) { uint64_t scale = (up + down) / (total / 8); up /= scale; down /= scale; } /* Get maximal dynamic range by choosing optimal shifts. */ int s = highbit64(total); s = MIN(64 - s, 32); uint64_t ofrac = (1ULL << 32) - frac; if (frac >= 4 * ofrac) up /= frac / (2 * ofrac + 1); up = (up << s) / (total >> (32 - s)); if (ofrac >= 4 * frac) down /= ofrac / (2 * frac + 1); down = (down << s) / (total >> (32 - s)); down = down * 100 / balance; return (frac + up - down); } /* * Evict buffers from the cache, such that arcstat_size is capped by arc_c. */ static uint64_t arc_evict(void) { uint64_t asize, bytes, total_evicted = 0; int64_t e, mrud, mrum, mfud, mfum, w; static uint64_t ogrd, ogrm, ogfd, ogfm; static uint64_t gsrd, gsrm, gsfd, gsfm; uint64_t ngrd, ngrm, ngfd, ngfm; /* Get current size of ARC states we can evict from. */ mrud = zfs_refcount_count(&arc_mru->arcs_size[ARC_BUFC_DATA]) + zfs_refcount_count(&arc_anon->arcs_size[ARC_BUFC_DATA]); mrum = zfs_refcount_count(&arc_mru->arcs_size[ARC_BUFC_METADATA]) + zfs_refcount_count(&arc_anon->arcs_size[ARC_BUFC_METADATA]); mfud = zfs_refcount_count(&arc_mfu->arcs_size[ARC_BUFC_DATA]); mfum = zfs_refcount_count(&arc_mfu->arcs_size[ARC_BUFC_METADATA]); uint64_t d = mrud + mfud; uint64_t m = mrum + mfum; uint64_t t = d + m; /* Get ARC ghost hits since last eviction. */ ngrd = wmsum_value(&arc_mru_ghost->arcs_hits[ARC_BUFC_DATA]); uint64_t grd = ngrd - ogrd; ogrd = ngrd; ngrm = wmsum_value(&arc_mru_ghost->arcs_hits[ARC_BUFC_METADATA]); uint64_t grm = ngrm - ogrm; ogrm = ngrm; ngfd = wmsum_value(&arc_mfu_ghost->arcs_hits[ARC_BUFC_DATA]); uint64_t gfd = ngfd - ogfd; ogfd = ngfd; ngfm = wmsum_value(&arc_mfu_ghost->arcs_hits[ARC_BUFC_METADATA]); uint64_t gfm = ngfm - ogfm; ogfm = ngfm; /* Adjust ARC states balance based on ghost hits. */ arc_meta = arc_evict_adj(arc_meta, gsrd + gsrm + gsfd + gsfm, grm + gfm, grd + gfd, zfs_arc_meta_balance); arc_pd = arc_evict_adj(arc_pd, gsrd + gsfd, grd, gfd, 100); arc_pm = arc_evict_adj(arc_pm, gsrm + gsfm, grm, gfm, 100); asize = aggsum_value(&arc_sums.arcstat_size); int64_t wt = t - (asize - arc_c); /* * Try to reduce pinned dnodes if more than 3/4 of wanted metadata * target is not evictable or if they go over arc_dnode_limit. */ int64_t prune = 0; int64_t dn = wmsum_value(&arc_sums.arcstat_dnode_size); w = wt * (int64_t)(arc_meta >> 16) >> 16; if (zfs_refcount_count(&arc_mru->arcs_size[ARC_BUFC_METADATA]) + zfs_refcount_count(&arc_mfu->arcs_size[ARC_BUFC_METADATA]) - zfs_refcount_count(&arc_mru->arcs_esize[ARC_BUFC_METADATA]) - zfs_refcount_count(&arc_mfu->arcs_esize[ARC_BUFC_METADATA]) > w * 3 / 4) { prune = dn / sizeof (dnode_t) * zfs_arc_dnode_reduce_percent / 100; } else if (dn > arc_dnode_limit) { prune = (dn - arc_dnode_limit) / sizeof (dnode_t) * zfs_arc_dnode_reduce_percent / 100; } if (prune > 0) arc_prune_async(prune); /* Evict MRU metadata. */ w = wt * (int64_t)(arc_meta * arc_pm >> 48) >> 16; e = MIN((int64_t)(asize - arc_c), (int64_t)(mrum - w)); bytes = arc_evict_impl(arc_mru, ARC_BUFC_METADATA, e); total_evicted += bytes; mrum -= bytes; asize -= bytes; /* Evict MFU metadata. */ w = wt * (int64_t)(arc_meta >> 16) >> 16; e = MIN((int64_t)(asize - arc_c), (int64_t)(m - w)); bytes = arc_evict_impl(arc_mfu, ARC_BUFC_METADATA, e); total_evicted += bytes; mfum -= bytes; asize -= bytes; /* Evict MRU data. */ wt -= m - total_evicted; w = wt * (int64_t)(arc_pd >> 16) >> 16; e = MIN((int64_t)(asize - arc_c), (int64_t)(mrud - w)); bytes = arc_evict_impl(arc_mru, ARC_BUFC_DATA, e); total_evicted += bytes; mrud -= bytes; asize -= bytes; /* Evict MFU data. */ e = asize - arc_c; bytes = arc_evict_impl(arc_mfu, ARC_BUFC_DATA, e); mfud -= bytes; total_evicted += bytes; /* * Evict ghost lists * * Size of each state's ghost list represents how much that state * may grow by shrinking the other states. Would it need to shrink * other states to zero (that is unlikely), its ghost size would be * equal to sum of other three state sizes. But excessive ghost * size may result in false ghost hits (too far back), that may * never result in real cache hits if several states are competing. * So choose some arbitraty point of 1/2 of other state sizes. */ gsrd = (mrum + mfud + mfum) / 2; e = zfs_refcount_count(&arc_mru_ghost->arcs_size[ARC_BUFC_DATA]) - gsrd; (void) arc_evict_impl(arc_mru_ghost, ARC_BUFC_DATA, e); gsrm = (mrud + mfud + mfum) / 2; e = zfs_refcount_count(&arc_mru_ghost->arcs_size[ARC_BUFC_METADATA]) - gsrm; (void) arc_evict_impl(arc_mru_ghost, ARC_BUFC_METADATA, e); gsfd = (mrud + mrum + mfum) / 2; e = zfs_refcount_count(&arc_mfu_ghost->arcs_size[ARC_BUFC_DATA]) - gsfd; (void) arc_evict_impl(arc_mfu_ghost, ARC_BUFC_DATA, e); gsfm = (mrud + mrum + mfud) / 2; e = zfs_refcount_count(&arc_mfu_ghost->arcs_size[ARC_BUFC_METADATA]) - gsfm; (void) arc_evict_impl(arc_mfu_ghost, ARC_BUFC_METADATA, e); return (total_evicted); } void arc_flush(spa_t *spa, boolean_t retry) { uint64_t guid = 0; /* * If retry is B_TRUE, a spa must not be specified since we have * no good way to determine if all of a spa's buffers have been * evicted from an arc state. */ ASSERT(!retry || spa == NULL); if (spa != NULL) guid = spa_load_guid(spa); (void) arc_flush_state(arc_mru, guid, ARC_BUFC_DATA, retry); (void) arc_flush_state(arc_mru, guid, ARC_BUFC_METADATA, retry); (void) arc_flush_state(arc_mfu, guid, ARC_BUFC_DATA, retry); (void) arc_flush_state(arc_mfu, guid, ARC_BUFC_METADATA, retry); (void) arc_flush_state(arc_mru_ghost, guid, ARC_BUFC_DATA, retry); (void) arc_flush_state(arc_mru_ghost, guid, ARC_BUFC_METADATA, retry); (void) arc_flush_state(arc_mfu_ghost, guid, ARC_BUFC_DATA, retry); (void) arc_flush_state(arc_mfu_ghost, guid, ARC_BUFC_METADATA, retry); (void) arc_flush_state(arc_uncached, guid, ARC_BUFC_DATA, retry); (void) arc_flush_state(arc_uncached, guid, ARC_BUFC_METADATA, retry); } void arc_reduce_target_size(int64_t to_free) { uint64_t c = arc_c; if (c <= arc_c_min) return; /* * All callers want the ARC to actually evict (at least) this much * memory. Therefore we reduce from the lower of the current size and * the target size. This way, even if arc_c is much higher than * arc_size (as can be the case after many calls to arc_freed(), we will * immediately have arc_c < arc_size and therefore the arc_evict_zthr * will evict. */ uint64_t asize = aggsum_value(&arc_sums.arcstat_size); if (asize < c) to_free += c - asize; arc_c = MAX((int64_t)c - to_free, (int64_t)arc_c_min); /* See comment in arc_evict_cb_check() on why lock+flag */ mutex_enter(&arc_evict_lock); arc_evict_needed = B_TRUE; mutex_exit(&arc_evict_lock); zthr_wakeup(arc_evict_zthr); } /* * Determine if the system is under memory pressure and is asking * to reclaim memory. A return value of B_TRUE indicates that the system * is under memory pressure and that the arc should adjust accordingly. */ boolean_t arc_reclaim_needed(void) { return (arc_available_memory() < 0); } void arc_kmem_reap_soon(void) { size_t i; kmem_cache_t *prev_cache = NULL; kmem_cache_t *prev_data_cache = NULL; #ifdef _KERNEL #if defined(_ILP32) /* * Reclaim unused memory from all kmem caches. */ kmem_reap(); #endif #endif for (i = 0; i < SPA_MAXBLOCKSIZE >> SPA_MINBLOCKSHIFT; i++) { #if defined(_ILP32) /* reach upper limit of cache size on 32-bit */ if (zio_buf_cache[i] == NULL) break; #endif if (zio_buf_cache[i] != prev_cache) { prev_cache = zio_buf_cache[i]; kmem_cache_reap_now(zio_buf_cache[i]); } if (zio_data_buf_cache[i] != prev_data_cache) { prev_data_cache = zio_data_buf_cache[i]; kmem_cache_reap_now(zio_data_buf_cache[i]); } } kmem_cache_reap_now(buf_cache); kmem_cache_reap_now(hdr_full_cache); kmem_cache_reap_now(hdr_l2only_cache); kmem_cache_reap_now(zfs_btree_leaf_cache); abd_cache_reap_now(); } static boolean_t arc_evict_cb_check(void *arg, zthr_t *zthr) { (void) arg, (void) zthr; #ifdef ZFS_DEBUG /* * This is necessary in order to keep the kstat information * up to date for tools that display kstat data such as the * mdb ::arc dcmd and the Linux crash utility. These tools * typically do not call kstat's update function, but simply * dump out stats from the most recent update. Without * this call, these commands may show stale stats for the * anon, mru, mru_ghost, mfu, and mfu_ghost lists. Even * with this call, the data might be out of date if the * evict thread hasn't been woken recently; but that should * suffice. The arc_state_t structures can be queried * directly if more accurate information is needed. */ if (arc_ksp != NULL) arc_ksp->ks_update(arc_ksp, KSTAT_READ); #endif /* * We have to rely on arc_wait_for_eviction() to tell us when to * evict, rather than checking if we are overflowing here, so that we * are sure to not leave arc_wait_for_eviction() waiting on aew_cv. * If we have become "not overflowing" since arc_wait_for_eviction() * checked, we need to wake it up. We could broadcast the CV here, * but arc_wait_for_eviction() may have not yet gone to sleep. We * would need to use a mutex to ensure that this function doesn't * broadcast until arc_wait_for_eviction() has gone to sleep (e.g. * the arc_evict_lock). However, the lock ordering of such a lock * would necessarily be incorrect with respect to the zthr_lock, * which is held before this function is called, and is held by * arc_wait_for_eviction() when it calls zthr_wakeup(). */ if (arc_evict_needed) return (B_TRUE); /* * If we have buffers in uncached state, evict them periodically. */ return ((zfs_refcount_count(&arc_uncached->arcs_esize[ARC_BUFC_DATA]) + zfs_refcount_count(&arc_uncached->arcs_esize[ARC_BUFC_METADATA]) && ddi_get_lbolt() - arc_last_uncached_flush > MSEC_TO_TICK(arc_min_prefetch_ms / 2))); } /* * Keep arc_size under arc_c by running arc_evict which evicts data * from the ARC. */ static void arc_evict_cb(void *arg, zthr_t *zthr) { (void) arg, (void) zthr; uint64_t evicted = 0; fstrans_cookie_t cookie = spl_fstrans_mark(); /* Always try to evict from uncached state. */ arc_last_uncached_flush = ddi_get_lbolt(); evicted += arc_flush_state(arc_uncached, 0, ARC_BUFC_DATA, B_FALSE); evicted += arc_flush_state(arc_uncached, 0, ARC_BUFC_METADATA, B_FALSE); /* Evict from other states only if told to. */ if (arc_evict_needed) evicted += arc_evict(); /* * If evicted is zero, we couldn't evict anything * via arc_evict(). This could be due to hash lock * collisions, but more likely due to the majority of * arc buffers being unevictable. Therefore, even if * arc_size is above arc_c, another pass is unlikely to * be helpful and could potentially cause us to enter an * infinite loop. Additionally, zthr_iscancelled() is * checked here so that if the arc is shutting down, the * broadcast will wake any remaining arc evict waiters. */ mutex_enter(&arc_evict_lock); arc_evict_needed = !zthr_iscancelled(arc_evict_zthr) && evicted > 0 && aggsum_compare(&arc_sums.arcstat_size, arc_c) > 0; if (!arc_evict_needed) { /* * We're either no longer overflowing, or we * can't evict anything more, so we should wake * arc_get_data_impl() sooner. */ arc_evict_waiter_t *aw; while ((aw = list_remove_head(&arc_evict_waiters)) != NULL) { cv_broadcast(&aw->aew_cv); } arc_set_need_free(); } mutex_exit(&arc_evict_lock); spl_fstrans_unmark(cookie); } static boolean_t arc_reap_cb_check(void *arg, zthr_t *zthr) { (void) arg, (void) zthr; int64_t free_memory = arc_available_memory(); static int reap_cb_check_counter = 0; /* * If a kmem reap is already active, don't schedule more. We must * check for this because kmem_cache_reap_soon() won't actually * block on the cache being reaped (this is to prevent callers from * becoming implicitly blocked by a system-wide kmem reap -- which, * on a system with many, many full magazines, can take minutes). */ if (!kmem_cache_reap_active() && free_memory < 0) { arc_no_grow = B_TRUE; arc_warm = B_TRUE; /* * Wait at least zfs_grow_retry (default 5) seconds * before considering growing. */ arc_growtime = gethrtime() + SEC2NSEC(arc_grow_retry); return (B_TRUE); } else if (free_memory < arc_c >> arc_no_grow_shift) { arc_no_grow = B_TRUE; } else if (gethrtime() >= arc_growtime) { arc_no_grow = B_FALSE; } /* * Called unconditionally every 60 seconds to reclaim unused * zstd compression and decompression context. This is done * here to avoid the need for an independent thread. */ if (!((reap_cb_check_counter++) % 60)) zfs_zstd_cache_reap_now(); return (B_FALSE); } /* * Keep enough free memory in the system by reaping the ARC's kmem * caches. To cause more slabs to be reapable, we may reduce the * target size of the cache (arc_c), causing the arc_evict_cb() * to free more buffers. */ static void arc_reap_cb(void *arg, zthr_t *zthr) { (void) arg, (void) zthr; int64_t free_memory; fstrans_cookie_t cookie = spl_fstrans_mark(); /* * Kick off asynchronous kmem_reap()'s of all our caches. */ arc_kmem_reap_soon(); /* * Wait at least arc_kmem_cache_reap_retry_ms between * arc_kmem_reap_soon() calls. Without this check it is possible to * end up in a situation where we spend lots of time reaping * caches, while we're near arc_c_min. Waiting here also gives the * subsequent free memory check a chance of finding that the * asynchronous reap has already freed enough memory, and we don't * need to call arc_reduce_target_size(). */ delay((hz * arc_kmem_cache_reap_retry_ms + 999) / 1000); /* * Reduce the target size as needed to maintain the amount of free * memory in the system at a fraction of the arc_size (1/128th by * default). If oversubscribed (free_memory < 0) then reduce the * target arc_size by the deficit amount plus the fractional * amount. If free memory is positive but less than the fractional * amount, reduce by what is needed to hit the fractional amount. */ free_memory = arc_available_memory(); int64_t can_free = arc_c - arc_c_min; if (can_free > 0) { int64_t to_free = (can_free >> arc_shrink_shift) - free_memory; if (to_free > 0) arc_reduce_target_size(to_free); } spl_fstrans_unmark(cookie); } #ifdef _KERNEL /* * Determine the amount of memory eligible for eviction contained in the * ARC. All clean data reported by the ghost lists can always be safely * evicted. Due to arc_c_min, the same does not hold for all clean data * contained by the regular mru and mfu lists. * * In the case of the regular mru and mfu lists, we need to report as * much clean data as possible, such that evicting that same reported * data will not bring arc_size below arc_c_min. Thus, in certain * circumstances, the total amount of clean data in the mru and mfu * lists might not actually be evictable. * * The following two distinct cases are accounted for: * * 1. The sum of the amount of dirty data contained by both the mru and * mfu lists, plus the ARC's other accounting (e.g. the anon list), * is greater than or equal to arc_c_min. * (i.e. amount of dirty data >= arc_c_min) * * This is the easy case; all clean data contained by the mru and mfu * lists is evictable. Evicting all clean data can only drop arc_size * to the amount of dirty data, which is greater than arc_c_min. * * 2. The sum of the amount of dirty data contained by both the mru and * mfu lists, plus the ARC's other accounting (e.g. the anon list), * is less than arc_c_min. * (i.e. arc_c_min > amount of dirty data) * * 2.1. arc_size is greater than or equal arc_c_min. * (i.e. arc_size >= arc_c_min > amount of dirty data) * * In this case, not all clean data from the regular mru and mfu * lists is actually evictable; we must leave enough clean data * to keep arc_size above arc_c_min. Thus, the maximum amount of * evictable data from the two lists combined, is exactly the * difference between arc_size and arc_c_min. * * 2.2. arc_size is less than arc_c_min * (i.e. arc_c_min > arc_size > amount of dirty data) * * In this case, none of the data contained in the mru and mfu * lists is evictable, even if it's clean. Since arc_size is * already below arc_c_min, evicting any more would only * increase this negative difference. */ #endif /* _KERNEL */ /* * Adapt arc info given the number of bytes we are trying to add and * the state that we are coming from. This function is only called * when we are adding new content to the cache. */ static void arc_adapt(uint64_t bytes) { /* * Wake reap thread if we do not have any available memory */ if (arc_reclaim_needed()) { zthr_wakeup(arc_reap_zthr); return; } if (arc_no_grow) return; if (arc_c >= arc_c_max) return; /* * If we're within (2 * maxblocksize) bytes of the target * cache size, increment the target cache size */ if (aggsum_upper_bound(&arc_sums.arcstat_size) + 2 * SPA_MAXBLOCKSIZE >= arc_c) { uint64_t dc = MAX(bytes, SPA_OLD_MAXBLOCKSIZE); if (atomic_add_64_nv(&arc_c, dc) > arc_c_max) arc_c = arc_c_max; } } /* * Check if arc_size has grown past our upper threshold, determined by * zfs_arc_overflow_shift. */ static arc_ovf_level_t arc_is_overflowing(boolean_t use_reserve) { /* Always allow at least one block of overflow */ int64_t overflow = MAX(SPA_MAXBLOCKSIZE, arc_c >> zfs_arc_overflow_shift); /* * We just compare the lower bound here for performance reasons. Our * primary goals are to make sure that the arc never grows without * bound, and that it can reach its maximum size. This check * accomplishes both goals. The maximum amount we could run over by is * 2 * aggsum_borrow_multiplier * NUM_CPUS * the average size of a block * in the ARC. In practice, that's in the tens of MB, which is low * enough to be safe. */ int64_t over = aggsum_lower_bound(&arc_sums.arcstat_size) - arc_c - overflow / 2; if (!use_reserve) overflow /= 2; return (over < 0 ? ARC_OVF_NONE : over < overflow ? ARC_OVF_SOME : ARC_OVF_SEVERE); } static abd_t * arc_get_data_abd(arc_buf_hdr_t *hdr, uint64_t size, const void *tag, int alloc_flags) { arc_buf_contents_t type = arc_buf_type(hdr); arc_get_data_impl(hdr, size, tag, alloc_flags); if (alloc_flags & ARC_HDR_ALLOC_LINEAR) return (abd_alloc_linear(size, type == ARC_BUFC_METADATA)); else return (abd_alloc(size, type == ARC_BUFC_METADATA)); } static void * arc_get_data_buf(arc_buf_hdr_t *hdr, uint64_t size, const void *tag) { arc_buf_contents_t type = arc_buf_type(hdr); arc_get_data_impl(hdr, size, tag, 0); if (type == ARC_BUFC_METADATA) { return (zio_buf_alloc(size)); } else { ASSERT(type == ARC_BUFC_DATA); return (zio_data_buf_alloc(size)); } } /* * Wait for the specified amount of data (in bytes) to be evicted from the * ARC, and for there to be sufficient free memory in the system. Waiting for * eviction ensures that the memory used by the ARC decreases. Waiting for * free memory ensures that the system won't run out of free pages, regardless * of ARC behavior and settings. See arc_lowmem_init(). */ void arc_wait_for_eviction(uint64_t amount, boolean_t use_reserve) { switch (arc_is_overflowing(use_reserve)) { case ARC_OVF_NONE: return; case ARC_OVF_SOME: /* * This is a bit racy without taking arc_evict_lock, but the * worst that can happen is we either call zthr_wakeup() extra * time due to race with other thread here, or the set flag * get cleared by arc_evict_cb(), which is unlikely due to * big hysteresis, but also not important since at this level * of overflow the eviction is purely advisory. Same time * taking the global lock here every time without waiting for * the actual eviction creates a significant lock contention. */ if (!arc_evict_needed) { arc_evict_needed = B_TRUE; zthr_wakeup(arc_evict_zthr); } return; case ARC_OVF_SEVERE: default: { arc_evict_waiter_t aw; list_link_init(&aw.aew_node); cv_init(&aw.aew_cv, NULL, CV_DEFAULT, NULL); uint64_t last_count = 0; mutex_enter(&arc_evict_lock); if (!list_is_empty(&arc_evict_waiters)) { arc_evict_waiter_t *last = list_tail(&arc_evict_waiters); last_count = last->aew_count; } else if (!arc_evict_needed) { arc_evict_needed = B_TRUE; zthr_wakeup(arc_evict_zthr); } /* * Note, the last waiter's count may be less than * arc_evict_count if we are low on memory in which * case arc_evict_state_impl() may have deferred * wakeups (but still incremented arc_evict_count). */ aw.aew_count = MAX(last_count, arc_evict_count) + amount; list_insert_tail(&arc_evict_waiters, &aw); arc_set_need_free(); DTRACE_PROBE3(arc__wait__for__eviction, uint64_t, amount, uint64_t, arc_evict_count, uint64_t, aw.aew_count); /* * We will be woken up either when arc_evict_count reaches * aew_count, or when the ARC is no longer overflowing and * eviction completes. * In case of "false" wakeup, we will still be on the list. */ do { cv_wait(&aw.aew_cv, &arc_evict_lock); } while (list_link_active(&aw.aew_node)); mutex_exit(&arc_evict_lock); cv_destroy(&aw.aew_cv); } } } /* * Allocate a block and return it to the caller. If we are hitting the * hard limit for the cache size, we must sleep, waiting for the eviction * thread to catch up. If we're past the target size but below the hard * limit, we'll only signal the reclaim thread and continue on. */ static void arc_get_data_impl(arc_buf_hdr_t *hdr, uint64_t size, const void *tag, int alloc_flags) { arc_adapt(size); /* * If arc_size is currently overflowing, we must be adding data * faster than we are evicting. To ensure we don't compound the * problem by adding more data and forcing arc_size to grow even * further past it's target size, we wait for the eviction thread to * make some progress. We also wait for there to be sufficient free * memory in the system, as measured by arc_free_memory(). * * Specifically, we wait for zfs_arc_eviction_pct percent of the * requested size to be evicted. This should be more than 100%, to * ensure that that progress is also made towards getting arc_size * under arc_c. See the comment above zfs_arc_eviction_pct. */ arc_wait_for_eviction(size * zfs_arc_eviction_pct / 100, alloc_flags & ARC_HDR_USE_RESERVE); arc_buf_contents_t type = arc_buf_type(hdr); if (type == ARC_BUFC_METADATA) { arc_space_consume(size, ARC_SPACE_META); } else { arc_space_consume(size, ARC_SPACE_DATA); } /* * Update the state size. Note that ghost states have a * "ghost size" and so don't need to be updated. */ arc_state_t *state = hdr->b_l1hdr.b_state; if (!GHOST_STATE(state)) { (void) zfs_refcount_add_many(&state->arcs_size[type], size, tag); /* * If this is reached via arc_read, the link is * protected by the hash lock. If reached via * arc_buf_alloc, the header should not be accessed by * any other thread. And, if reached via arc_read_done, * the hash lock will protect it if it's found in the * hash table; otherwise no other thread should be * trying to [add|remove]_reference it. */ if (multilist_link_active(&hdr->b_l1hdr.b_arc_node)) { ASSERT(zfs_refcount_is_zero(&hdr->b_l1hdr.b_refcnt)); (void) zfs_refcount_add_many(&state->arcs_esize[type], size, tag); } } } static void arc_free_data_abd(arc_buf_hdr_t *hdr, abd_t *abd, uint64_t size, const void *tag) { arc_free_data_impl(hdr, size, tag); abd_free(abd); } static void arc_free_data_buf(arc_buf_hdr_t *hdr, void *buf, uint64_t size, const void *tag) { arc_buf_contents_t type = arc_buf_type(hdr); arc_free_data_impl(hdr, size, tag); if (type == ARC_BUFC_METADATA) { zio_buf_free(buf, size); } else { ASSERT(type == ARC_BUFC_DATA); zio_data_buf_free(buf, size); } } /* * Free the arc data buffer. */ static void arc_free_data_impl(arc_buf_hdr_t *hdr, uint64_t size, const void *tag) { arc_state_t *state = hdr->b_l1hdr.b_state; arc_buf_contents_t type = arc_buf_type(hdr); /* protected by hash lock, if in the hash table */ if (multilist_link_active(&hdr->b_l1hdr.b_arc_node)) { ASSERT(zfs_refcount_is_zero(&hdr->b_l1hdr.b_refcnt)); ASSERT(state != arc_anon && state != arc_l2c_only); (void) zfs_refcount_remove_many(&state->arcs_esize[type], size, tag); } (void) zfs_refcount_remove_many(&state->arcs_size[type], size, tag); VERIFY3U(hdr->b_type, ==, type); if (type == ARC_BUFC_METADATA) { arc_space_return(size, ARC_SPACE_META); } else { ASSERT(type == ARC_BUFC_DATA); arc_space_return(size, ARC_SPACE_DATA); } } /* * This routine is called whenever a buffer is accessed. */ static void arc_access(arc_buf_hdr_t *hdr, arc_flags_t arc_flags, boolean_t hit) { ASSERT(MUTEX_HELD(HDR_LOCK(hdr))); ASSERT(HDR_HAS_L1HDR(hdr)); /* * Update buffer prefetch status. */ boolean_t was_prefetch = HDR_PREFETCH(hdr); boolean_t now_prefetch = arc_flags & ARC_FLAG_PREFETCH; if (was_prefetch != now_prefetch) { if (was_prefetch) { ARCSTAT_CONDSTAT(hit, demand_hit, demand_iohit, HDR_PRESCIENT_PREFETCH(hdr), prescient, predictive, prefetch); } if (HDR_HAS_L2HDR(hdr)) l2arc_hdr_arcstats_decrement_state(hdr); if (was_prefetch) { arc_hdr_clear_flags(hdr, ARC_FLAG_PREFETCH | ARC_FLAG_PRESCIENT_PREFETCH); } else { arc_hdr_set_flags(hdr, ARC_FLAG_PREFETCH); } if (HDR_HAS_L2HDR(hdr)) l2arc_hdr_arcstats_increment_state(hdr); } if (now_prefetch) { if (arc_flags & ARC_FLAG_PRESCIENT_PREFETCH) { arc_hdr_set_flags(hdr, ARC_FLAG_PRESCIENT_PREFETCH); ARCSTAT_BUMP(arcstat_prescient_prefetch); } else { ARCSTAT_BUMP(arcstat_predictive_prefetch); } } if (arc_flags & ARC_FLAG_L2CACHE) arc_hdr_set_flags(hdr, ARC_FLAG_L2CACHE); clock_t now = ddi_get_lbolt(); if (hdr->b_l1hdr.b_state == arc_anon) { arc_state_t *new_state; /* * This buffer is not in the cache, and does not appear in * our "ghost" lists. Add it to the MRU or uncached state. */ ASSERT0(hdr->b_l1hdr.b_arc_access); hdr->b_l1hdr.b_arc_access = now; if (HDR_UNCACHED(hdr)) { new_state = arc_uncached; DTRACE_PROBE1(new_state__uncached, arc_buf_hdr_t *, hdr); } else { new_state = arc_mru; DTRACE_PROBE1(new_state__mru, arc_buf_hdr_t *, hdr); } arc_change_state(new_state, hdr); } else if (hdr->b_l1hdr.b_state == arc_mru) { /* * This buffer has been accessed once recently and either * its read is still in progress or it is in the cache. */ if (HDR_IO_IN_PROGRESS(hdr)) { hdr->b_l1hdr.b_arc_access = now; return; } hdr->b_l1hdr.b_mru_hits++; ARCSTAT_BUMP(arcstat_mru_hits); /* * If the previous access was a prefetch, then it already * handled possible promotion, so nothing more to do for now. */ if (was_prefetch) { hdr->b_l1hdr.b_arc_access = now; return; } /* * If more than ARC_MINTIME have passed from the previous * hit, promote the buffer to the MFU state. */ if (ddi_time_after(now, hdr->b_l1hdr.b_arc_access + ARC_MINTIME)) { hdr->b_l1hdr.b_arc_access = now; DTRACE_PROBE1(new_state__mfu, arc_buf_hdr_t *, hdr); arc_change_state(arc_mfu, hdr); } } else if (hdr->b_l1hdr.b_state == arc_mru_ghost) { arc_state_t *new_state; /* * This buffer has been accessed once recently, but was * evicted from the cache. Would we have bigger MRU, it * would be an MRU hit, so handle it the same way, except * we don't need to check the previous access time. */ hdr->b_l1hdr.b_mru_ghost_hits++; ARCSTAT_BUMP(arcstat_mru_ghost_hits); hdr->b_l1hdr.b_arc_access = now; wmsum_add(&arc_mru_ghost->arcs_hits[arc_buf_type(hdr)], arc_hdr_size(hdr)); if (was_prefetch) { new_state = arc_mru; DTRACE_PROBE1(new_state__mru, arc_buf_hdr_t *, hdr); } else { new_state = arc_mfu; DTRACE_PROBE1(new_state__mfu, arc_buf_hdr_t *, hdr); } arc_change_state(new_state, hdr); } else if (hdr->b_l1hdr.b_state == arc_mfu) { /* * This buffer has been accessed more than once and either * still in the cache or being restored from one of ghosts. */ if (!HDR_IO_IN_PROGRESS(hdr)) { hdr->b_l1hdr.b_mfu_hits++; ARCSTAT_BUMP(arcstat_mfu_hits); } hdr->b_l1hdr.b_arc_access = now; } else if (hdr->b_l1hdr.b_state == arc_mfu_ghost) { /* * This buffer has been accessed more than once recently, but * has been evicted from the cache. Would we have bigger MFU * it would stay in cache, so move it back to MFU state. */ hdr->b_l1hdr.b_mfu_ghost_hits++; ARCSTAT_BUMP(arcstat_mfu_ghost_hits); hdr->b_l1hdr.b_arc_access = now; wmsum_add(&arc_mfu_ghost->arcs_hits[arc_buf_type(hdr)], arc_hdr_size(hdr)); DTRACE_PROBE1(new_state__mfu, arc_buf_hdr_t *, hdr); arc_change_state(arc_mfu, hdr); } else if (hdr->b_l1hdr.b_state == arc_uncached) { /* * This buffer is uncacheable, but we got a hit. Probably * a demand read after prefetch. Nothing more to do here. */ if (!HDR_IO_IN_PROGRESS(hdr)) ARCSTAT_BUMP(arcstat_uncached_hits); hdr->b_l1hdr.b_arc_access = now; } else if (hdr->b_l1hdr.b_state == arc_l2c_only) { /* * This buffer is on the 2nd Level ARC and was not accessed * for a long time, so treat it as new and put into MRU. */ hdr->b_l1hdr.b_arc_access = now; DTRACE_PROBE1(new_state__mru, arc_buf_hdr_t *, hdr); arc_change_state(arc_mru, hdr); } else { cmn_err(CE_PANIC, "invalid arc state 0x%p", hdr->b_l1hdr.b_state); } } /* * This routine is called by dbuf_hold() to update the arc_access() state * which otherwise would be skipped for entries in the dbuf cache. */ void arc_buf_access(arc_buf_t *buf) { arc_buf_hdr_t *hdr = buf->b_hdr; /* * Avoid taking the hash_lock when possible as an optimization. * The header must be checked again under the hash_lock in order * to handle the case where it is concurrently being released. */ if (hdr->b_l1hdr.b_state == arc_anon || HDR_EMPTY(hdr)) return; kmutex_t *hash_lock = HDR_LOCK(hdr); mutex_enter(hash_lock); if (hdr->b_l1hdr.b_state == arc_anon || HDR_EMPTY(hdr)) { mutex_exit(hash_lock); ARCSTAT_BUMP(arcstat_access_skip); return; } ASSERT(hdr->b_l1hdr.b_state == arc_mru || hdr->b_l1hdr.b_state == arc_mfu || hdr->b_l1hdr.b_state == arc_uncached); DTRACE_PROBE1(arc__hit, arc_buf_hdr_t *, hdr); arc_access(hdr, 0, B_TRUE); mutex_exit(hash_lock); ARCSTAT_BUMP(arcstat_hits); ARCSTAT_CONDSTAT(B_TRUE /* demand */, demand, prefetch, !HDR_ISTYPE_METADATA(hdr), data, metadata, hits); } /* a generic arc_read_done_func_t which you can use */ void arc_bcopy_func(zio_t *zio, const zbookmark_phys_t *zb, const blkptr_t *bp, arc_buf_t *buf, void *arg) { (void) zio, (void) zb, (void) bp; if (buf == NULL) return; memcpy(arg, buf->b_data, arc_buf_size(buf)); arc_buf_destroy(buf, arg); } /* a generic arc_read_done_func_t */ void arc_getbuf_func(zio_t *zio, const zbookmark_phys_t *zb, const blkptr_t *bp, arc_buf_t *buf, void *arg) { (void) zb, (void) bp; arc_buf_t **bufp = arg; if (buf == NULL) { ASSERT(zio == NULL || zio->io_error != 0); *bufp = NULL; } else { ASSERT(zio == NULL || zio->io_error == 0); *bufp = buf; ASSERT(buf->b_data != NULL); } } static void arc_hdr_verify(arc_buf_hdr_t *hdr, blkptr_t *bp) { if (BP_IS_HOLE(bp) || BP_IS_EMBEDDED(bp)) { ASSERT3U(HDR_GET_PSIZE(hdr), ==, 0); ASSERT3U(arc_hdr_get_compress(hdr), ==, ZIO_COMPRESS_OFF); } else { if (HDR_COMPRESSION_ENABLED(hdr)) { ASSERT3U(arc_hdr_get_compress(hdr), ==, BP_GET_COMPRESS(bp)); } ASSERT3U(HDR_GET_LSIZE(hdr), ==, BP_GET_LSIZE(bp)); ASSERT3U(HDR_GET_PSIZE(hdr), ==, BP_GET_PSIZE(bp)); ASSERT3U(!!HDR_PROTECTED(hdr), ==, BP_IS_PROTECTED(bp)); } } static void arc_read_done(zio_t *zio) { blkptr_t *bp = zio->io_bp; arc_buf_hdr_t *hdr = zio->io_private; kmutex_t *hash_lock = NULL; arc_callback_t *callback_list; arc_callback_t *acb; /* * The hdr was inserted into hash-table and removed from lists * prior to starting I/O. We should find this header, since * it's in the hash table, and it should be legit since it's * not possible to evict it during the I/O. The only possible * reason for it not to be found is if we were freed during the * read. */ if (HDR_IN_HASH_TABLE(hdr)) { arc_buf_hdr_t *found; ASSERT3U(hdr->b_birth, ==, BP_PHYSICAL_BIRTH(zio->io_bp)); ASSERT3U(hdr->b_dva.dva_word[0], ==, BP_IDENTITY(zio->io_bp)->dva_word[0]); ASSERT3U(hdr->b_dva.dva_word[1], ==, BP_IDENTITY(zio->io_bp)->dva_word[1]); found = buf_hash_find(hdr->b_spa, zio->io_bp, &hash_lock); ASSERT((found == hdr && DVA_EQUAL(&hdr->b_dva, BP_IDENTITY(zio->io_bp))) || (found == hdr && HDR_L2_READING(hdr))); ASSERT3P(hash_lock, !=, NULL); } if (BP_IS_PROTECTED(bp)) { hdr->b_crypt_hdr.b_ot = BP_GET_TYPE(bp); hdr->b_crypt_hdr.b_dsobj = zio->io_bookmark.zb_objset; zio_crypt_decode_params_bp(bp, hdr->b_crypt_hdr.b_salt, hdr->b_crypt_hdr.b_iv); if (zio->io_error == 0) { if (BP_GET_TYPE(bp) == DMU_OT_INTENT_LOG) { void *tmpbuf; tmpbuf = abd_borrow_buf_copy(zio->io_abd, sizeof (zil_chain_t)); zio_crypt_decode_mac_zil(tmpbuf, hdr->b_crypt_hdr.b_mac); abd_return_buf(zio->io_abd, tmpbuf, sizeof (zil_chain_t)); } else { zio_crypt_decode_mac_bp(bp, hdr->b_crypt_hdr.b_mac); } } } if (zio->io_error == 0) { /* byteswap if necessary */ if (BP_SHOULD_BYTESWAP(zio->io_bp)) { if (BP_GET_LEVEL(zio->io_bp) > 0) { hdr->b_l1hdr.b_byteswap = DMU_BSWAP_UINT64; } else { hdr->b_l1hdr.b_byteswap = DMU_OT_BYTESWAP(BP_GET_TYPE(zio->io_bp)); } } else { hdr->b_l1hdr.b_byteswap = DMU_BSWAP_NUMFUNCS; } if (!HDR_L2_READING(hdr)) { hdr->b_complevel = zio->io_prop.zp_complevel; } } arc_hdr_clear_flags(hdr, ARC_FLAG_L2_EVICTED); if (l2arc_noprefetch && HDR_PREFETCH(hdr)) arc_hdr_clear_flags(hdr, ARC_FLAG_L2CACHE); callback_list = hdr->b_l1hdr.b_acb; ASSERT3P(callback_list, !=, NULL); hdr->b_l1hdr.b_acb = NULL; /* * If a read request has a callback (i.e. acb_done is not NULL), then we * make a buf containing the data according to the parameters which were * passed in. The implementation of arc_buf_alloc_impl() ensures that we * aren't needlessly decompressing the data multiple times. */ int callback_cnt = 0; for (acb = callback_list; acb != NULL; acb = acb->acb_next) { /* We need the last one to call below in original order. */ callback_list = acb; if (!acb->acb_done || acb->acb_nobuf) continue; callback_cnt++; if (zio->io_error != 0) continue; int error = arc_buf_alloc_impl(hdr, zio->io_spa, &acb->acb_zb, acb->acb_private, acb->acb_encrypted, acb->acb_compressed, acb->acb_noauth, B_TRUE, &acb->acb_buf); /* * Assert non-speculative zios didn't fail because an * encryption key wasn't loaded */ ASSERT((zio->io_flags & ZIO_FLAG_SPECULATIVE) || error != EACCES); /* * If we failed to decrypt, report an error now (as the zio * layer would have done if it had done the transforms). */ if (error == ECKSUM) { ASSERT(BP_IS_PROTECTED(bp)); error = SET_ERROR(EIO); if ((zio->io_flags & ZIO_FLAG_SPECULATIVE) == 0) { spa_log_error(zio->io_spa, &acb->acb_zb, &zio->io_bp->blk_birth); (void) zfs_ereport_post( FM_EREPORT_ZFS_AUTHENTICATION, zio->io_spa, NULL, &acb->acb_zb, zio, 0); } } if (error != 0) { /* * Decompression or decryption failed. Set * io_error so that when we call acb_done * (below), we will indicate that the read * failed. Note that in the unusual case * where one callback is compressed and another * uncompressed, we will mark all of them * as failed, even though the uncompressed * one can't actually fail. In this case, * the hdr will not be anonymous, because * if there are multiple callbacks, it's * because multiple threads found the same * arc buf in the hash table. */ zio->io_error = error; } } /* * If there are multiple callbacks, we must have the hash lock, * because the only way for multiple threads to find this hdr is * in the hash table. This ensures that if there are multiple * callbacks, the hdr is not anonymous. If it were anonymous, * we couldn't use arc_buf_destroy() in the error case below. */ ASSERT(callback_cnt < 2 || hash_lock != NULL); if (zio->io_error == 0) { arc_hdr_verify(hdr, zio->io_bp); } else { arc_hdr_set_flags(hdr, ARC_FLAG_IO_ERROR); if (hdr->b_l1hdr.b_state != arc_anon) arc_change_state(arc_anon, hdr); if (HDR_IN_HASH_TABLE(hdr)) buf_hash_remove(hdr); } arc_hdr_clear_flags(hdr, ARC_FLAG_IO_IN_PROGRESS); (void) remove_reference(hdr, hdr); if (hash_lock != NULL) mutex_exit(hash_lock); /* execute each callback and free its structure */ while ((acb = callback_list) != NULL) { if (acb->acb_done != NULL) { if (zio->io_error != 0 && acb->acb_buf != NULL) { /* * If arc_buf_alloc_impl() fails during * decompression, the buf will still be * allocated, and needs to be freed here. */ arc_buf_destroy(acb->acb_buf, acb->acb_private); acb->acb_buf = NULL; } acb->acb_done(zio, &zio->io_bookmark, zio->io_bp, acb->acb_buf, acb->acb_private); } if (acb->acb_zio_dummy != NULL) { acb->acb_zio_dummy->io_error = zio->io_error; zio_nowait(acb->acb_zio_dummy); } callback_list = acb->acb_prev; if (acb->acb_wait) { mutex_enter(&acb->acb_wait_lock); acb->acb_wait_error = zio->io_error; acb->acb_wait = B_FALSE; cv_signal(&acb->acb_wait_cv); mutex_exit(&acb->acb_wait_lock); /* acb will be freed by the waiting thread. */ } else { kmem_free(acb, sizeof (arc_callback_t)); } } } /* * "Read" the block at the specified DVA (in bp) via the * cache. If the block is found in the cache, invoke the provided * callback immediately and return. Note that the `zio' parameter * in the callback will be NULL in this case, since no IO was * required. If the block is not in the cache pass the read request * on to the spa with a substitute callback function, so that the * requested block will be added to the cache. * * If a read request arrives for a block that has a read in-progress, * either wait for the in-progress read to complete (and return the * results); or, if this is a read with a "done" func, add a record * to the read to invoke the "done" func when the read completes, * and return; or just return. * * arc_read_done() will invoke all the requested "done" functions * for readers of this block. */ int arc_read(zio_t *pio, spa_t *spa, const blkptr_t *bp, arc_read_done_func_t *done, void *private, zio_priority_t priority, int zio_flags, arc_flags_t *arc_flags, const zbookmark_phys_t *zb) { arc_buf_hdr_t *hdr = NULL; kmutex_t *hash_lock = NULL; zio_t *rzio; uint64_t guid = spa_load_guid(spa); boolean_t compressed_read = (zio_flags & ZIO_FLAG_RAW_COMPRESS) != 0; boolean_t encrypted_read = BP_IS_ENCRYPTED(bp) && (zio_flags & ZIO_FLAG_RAW_ENCRYPT) != 0; boolean_t noauth_read = BP_IS_AUTHENTICATED(bp) && (zio_flags & ZIO_FLAG_RAW_ENCRYPT) != 0; boolean_t embedded_bp = !!BP_IS_EMBEDDED(bp); boolean_t no_buf = *arc_flags & ARC_FLAG_NO_BUF; arc_buf_t *buf = NULL; int rc = 0; ASSERT(!embedded_bp || BPE_GET_ETYPE(bp) == BP_EMBEDDED_TYPE_DATA); ASSERT(!BP_IS_HOLE(bp)); ASSERT(!BP_IS_REDACTED(bp)); /* * Normally SPL_FSTRANS will already be set since kernel threads which * expect to call the DMU interfaces will set it when created. System * calls are similarly handled by setting/cleaning the bit in the * registered callback (module/os/.../zfs/zpl_*). * * External consumers such as Lustre which call the exported DMU * interfaces may not have set SPL_FSTRANS. To avoid a deadlock * on the hash_lock always set and clear the bit. */ fstrans_cookie_t cookie = spl_fstrans_mark(); top: /* * Verify the block pointer contents are reasonable. This should * always be the case since the blkptr is protected by a checksum. * However, if there is damage it's desirable to detect this early * and treat it as a checksum error. This allows an alternate blkptr * to be tried when one is available (e.g. ditto blocks). */ if (!zfs_blkptr_verify(spa, bp, (zio_flags & ZIO_FLAG_CONFIG_WRITER) ? BLK_CONFIG_HELD : BLK_CONFIG_NEEDED, BLK_VERIFY_LOG)) { rc = SET_ERROR(ECKSUM); goto done; } if (!embedded_bp) { /* * Embedded BP's have no DVA and require no I/O to "read". * Create an anonymous arc buf to back it. */ hdr = buf_hash_find(guid, bp, &hash_lock); } /* * Determine if we have an L1 cache hit or a cache miss. For simplicity * we maintain encrypted data separately from compressed / uncompressed * data. If the user is requesting raw encrypted data and we don't have * that in the header we will read from disk to guarantee that we can * get it even if the encryption keys aren't loaded. */ if (hdr != NULL && HDR_HAS_L1HDR(hdr) && (HDR_HAS_RABD(hdr) || (hdr->b_l1hdr.b_pabd != NULL && !encrypted_read))) { boolean_t is_data = !HDR_ISTYPE_METADATA(hdr); if (HDR_IO_IN_PROGRESS(hdr)) { if (*arc_flags & ARC_FLAG_CACHED_ONLY) { mutex_exit(hash_lock); ARCSTAT_BUMP(arcstat_cached_only_in_progress); rc = SET_ERROR(ENOENT); goto done; } zio_t *head_zio = hdr->b_l1hdr.b_acb->acb_zio_head; ASSERT3P(head_zio, !=, NULL); if ((hdr->b_flags & ARC_FLAG_PRIO_ASYNC_READ) && priority == ZIO_PRIORITY_SYNC_READ) { /* * This is a sync read that needs to wait for * an in-flight async read. Request that the * zio have its priority upgraded. */ zio_change_priority(head_zio, priority); DTRACE_PROBE1(arc__async__upgrade__sync, arc_buf_hdr_t *, hdr); ARCSTAT_BUMP(arcstat_async_upgrade_sync); } DTRACE_PROBE1(arc__iohit, arc_buf_hdr_t *, hdr); arc_access(hdr, *arc_flags, B_FALSE); /* * If there are multiple threads reading the same block * and that block is not yet in the ARC, then only one * thread will do the physical I/O and all other * threads will wait until that I/O completes. * Synchronous reads use the acb_wait_cv whereas nowait * reads register a callback. Both are signalled/called * in arc_read_done. * * Errors of the physical I/O may need to be propagated. * Synchronous read errors are returned here from * arc_read_done via acb_wait_error. Nowait reads * attach the acb_zio_dummy zio to pio and * arc_read_done propagates the physical I/O's io_error * to acb_zio_dummy, and thereby to pio. */ arc_callback_t *acb = NULL; if (done || pio || *arc_flags & ARC_FLAG_WAIT) { acb = kmem_zalloc(sizeof (arc_callback_t), KM_SLEEP); acb->acb_done = done; acb->acb_private = private; acb->acb_compressed = compressed_read; acb->acb_encrypted = encrypted_read; acb->acb_noauth = noauth_read; acb->acb_nobuf = no_buf; if (*arc_flags & ARC_FLAG_WAIT) { acb->acb_wait = B_TRUE; mutex_init(&acb->acb_wait_lock, NULL, MUTEX_DEFAULT, NULL); cv_init(&acb->acb_wait_cv, NULL, CV_DEFAULT, NULL); } acb->acb_zb = *zb; if (pio != NULL) { acb->acb_zio_dummy = zio_null(pio, spa, NULL, NULL, NULL, zio_flags); } acb->acb_zio_head = head_zio; acb->acb_next = hdr->b_l1hdr.b_acb; hdr->b_l1hdr.b_acb->acb_prev = acb; hdr->b_l1hdr.b_acb = acb; } mutex_exit(hash_lock); ARCSTAT_BUMP(arcstat_iohits); ARCSTAT_CONDSTAT(!(*arc_flags & ARC_FLAG_PREFETCH), demand, prefetch, is_data, data, metadata, iohits); if (*arc_flags & ARC_FLAG_WAIT) { mutex_enter(&acb->acb_wait_lock); while (acb->acb_wait) { cv_wait(&acb->acb_wait_cv, &acb->acb_wait_lock); } rc = acb->acb_wait_error; mutex_exit(&acb->acb_wait_lock); mutex_destroy(&acb->acb_wait_lock); cv_destroy(&acb->acb_wait_cv); kmem_free(acb, sizeof (arc_callback_t)); } goto out; } ASSERT(hdr->b_l1hdr.b_state == arc_mru || hdr->b_l1hdr.b_state == arc_mfu || hdr->b_l1hdr.b_state == arc_uncached); DTRACE_PROBE1(arc__hit, arc_buf_hdr_t *, hdr); arc_access(hdr, *arc_flags, B_TRUE); if (done && !no_buf) { ASSERT(!embedded_bp || !BP_IS_HOLE(bp)); /* Get a buf with the desired data in it. */ rc = arc_buf_alloc_impl(hdr, spa, zb, private, encrypted_read, compressed_read, noauth_read, B_TRUE, &buf); if (rc == ECKSUM) { /* * Convert authentication and decryption errors * to EIO (and generate an ereport if needed) * before leaving the ARC. */ rc = SET_ERROR(EIO); if ((zio_flags & ZIO_FLAG_SPECULATIVE) == 0) { spa_log_error(spa, zb, &hdr->b_birth); (void) zfs_ereport_post( FM_EREPORT_ZFS_AUTHENTICATION, spa, NULL, zb, NULL, 0); } } if (rc != 0) { arc_buf_destroy_impl(buf); buf = NULL; (void) remove_reference(hdr, private); } /* assert any errors weren't due to unloaded keys */ ASSERT((zio_flags & ZIO_FLAG_SPECULATIVE) || rc != EACCES); } mutex_exit(hash_lock); ARCSTAT_BUMP(arcstat_hits); ARCSTAT_CONDSTAT(!(*arc_flags & ARC_FLAG_PREFETCH), demand, prefetch, is_data, data, metadata, hits); *arc_flags |= ARC_FLAG_CACHED; goto done; } else { uint64_t lsize = BP_GET_LSIZE(bp); uint64_t psize = BP_GET_PSIZE(bp); arc_callback_t *acb; vdev_t *vd = NULL; uint64_t addr = 0; boolean_t devw = B_FALSE; uint64_t size; abd_t *hdr_abd; int alloc_flags = encrypted_read ? ARC_HDR_ALLOC_RDATA : 0; arc_buf_contents_t type = BP_GET_BUFC_TYPE(bp); if (*arc_flags & ARC_FLAG_CACHED_ONLY) { if (hash_lock != NULL) mutex_exit(hash_lock); rc = SET_ERROR(ENOENT); goto done; } if (hdr == NULL) { /* * This block is not in the cache or it has * embedded data. */ arc_buf_hdr_t *exists = NULL; hdr = arc_hdr_alloc(spa_load_guid(spa), psize, lsize, BP_IS_PROTECTED(bp), BP_GET_COMPRESS(bp), 0, type); if (!embedded_bp) { hdr->b_dva = *BP_IDENTITY(bp); hdr->b_birth = BP_PHYSICAL_BIRTH(bp); exists = buf_hash_insert(hdr, &hash_lock); } if (exists != NULL) { /* somebody beat us to the hash insert */ mutex_exit(hash_lock); buf_discard_identity(hdr); arc_hdr_destroy(hdr); goto top; /* restart the IO request */ } } else { /* * This block is in the ghost cache or encrypted data * was requested and we didn't have it. If it was * L2-only (and thus didn't have an L1 hdr), * we realloc the header to add an L1 hdr. */ if (!HDR_HAS_L1HDR(hdr)) { hdr = arc_hdr_realloc(hdr, hdr_l2only_cache, hdr_full_cache); } if (GHOST_STATE(hdr->b_l1hdr.b_state)) { ASSERT3P(hdr->b_l1hdr.b_pabd, ==, NULL); ASSERT(!HDR_HAS_RABD(hdr)); ASSERT(!HDR_IO_IN_PROGRESS(hdr)); ASSERT0(zfs_refcount_count( &hdr->b_l1hdr.b_refcnt)); ASSERT3P(hdr->b_l1hdr.b_buf, ==, NULL); #ifdef ZFS_DEBUG ASSERT3P(hdr->b_l1hdr.b_freeze_cksum, ==, NULL); #endif } else if (HDR_IO_IN_PROGRESS(hdr)) { /* * If this header already had an IO in progress * and we are performing another IO to fetch * encrypted data we must wait until the first * IO completes so as not to confuse * arc_read_done(). This should be very rare * and so the performance impact shouldn't * matter. */ arc_callback_t *acb = kmem_zalloc( sizeof (arc_callback_t), KM_SLEEP); acb->acb_wait = B_TRUE; mutex_init(&acb->acb_wait_lock, NULL, MUTEX_DEFAULT, NULL); cv_init(&acb->acb_wait_cv, NULL, CV_DEFAULT, NULL); acb->acb_zio_head = hdr->b_l1hdr.b_acb->acb_zio_head; acb->acb_next = hdr->b_l1hdr.b_acb; hdr->b_l1hdr.b_acb->acb_prev = acb; hdr->b_l1hdr.b_acb = acb; mutex_exit(hash_lock); mutex_enter(&acb->acb_wait_lock); while (acb->acb_wait) { cv_wait(&acb->acb_wait_cv, &acb->acb_wait_lock); } mutex_exit(&acb->acb_wait_lock); mutex_destroy(&acb->acb_wait_lock); cv_destroy(&acb->acb_wait_cv); kmem_free(acb, sizeof (arc_callback_t)); goto top; } } if (*arc_flags & ARC_FLAG_UNCACHED) { arc_hdr_set_flags(hdr, ARC_FLAG_UNCACHED); if (!encrypted_read) alloc_flags |= ARC_HDR_ALLOC_LINEAR; } /* * Take additional reference for IO_IN_PROGRESS. It stops * arc_access() from putting this header without any buffers * and so other references but obviously nonevictable onto * the evictable list of MRU or MFU state. */ add_reference(hdr, hdr); if (!embedded_bp) arc_access(hdr, *arc_flags, B_FALSE); arc_hdr_set_flags(hdr, ARC_FLAG_IO_IN_PROGRESS); arc_hdr_alloc_abd(hdr, alloc_flags); if (encrypted_read) { ASSERT(HDR_HAS_RABD(hdr)); size = HDR_GET_PSIZE(hdr); hdr_abd = hdr->b_crypt_hdr.b_rabd; zio_flags |= ZIO_FLAG_RAW; } else { ASSERT3P(hdr->b_l1hdr.b_pabd, !=, NULL); size = arc_hdr_size(hdr); hdr_abd = hdr->b_l1hdr.b_pabd; if (arc_hdr_get_compress(hdr) != ZIO_COMPRESS_OFF) { zio_flags |= ZIO_FLAG_RAW_COMPRESS; } /* * For authenticated bp's, we do not ask the ZIO layer * to authenticate them since this will cause the entire * IO to fail if the key isn't loaded. Instead, we * defer authentication until arc_buf_fill(), which will * verify the data when the key is available. */ if (BP_IS_AUTHENTICATED(bp)) zio_flags |= ZIO_FLAG_RAW_ENCRYPT; } if (BP_IS_AUTHENTICATED(bp)) arc_hdr_set_flags(hdr, ARC_FLAG_NOAUTH); if (BP_GET_LEVEL(bp) > 0) arc_hdr_set_flags(hdr, ARC_FLAG_INDIRECT); ASSERT(!GHOST_STATE(hdr->b_l1hdr.b_state)); acb = kmem_zalloc(sizeof (arc_callback_t), KM_SLEEP); acb->acb_done = done; acb->acb_private = private; acb->acb_compressed = compressed_read; acb->acb_encrypted = encrypted_read; acb->acb_noauth = noauth_read; acb->acb_zb = *zb; ASSERT3P(hdr->b_l1hdr.b_acb, ==, NULL); hdr->b_l1hdr.b_acb = acb; if (HDR_HAS_L2HDR(hdr) && (vd = hdr->b_l2hdr.b_dev->l2ad_vdev) != NULL) { devw = hdr->b_l2hdr.b_dev->l2ad_writing; addr = hdr->b_l2hdr.b_daddr; /* * Lock out L2ARC device removal. */ if (vdev_is_dead(vd) || !spa_config_tryenter(spa, SCL_L2ARC, vd, RW_READER)) vd = NULL; } /* * We count both async reads and scrub IOs as asynchronous so * that both can be upgraded in the event of a cache hit while * the read IO is still in-flight. */ if (priority == ZIO_PRIORITY_ASYNC_READ || priority == ZIO_PRIORITY_SCRUB) arc_hdr_set_flags(hdr, ARC_FLAG_PRIO_ASYNC_READ); else arc_hdr_clear_flags(hdr, ARC_FLAG_PRIO_ASYNC_READ); /* * At this point, we have a level 1 cache miss or a blkptr * with embedded data. Try again in L2ARC if possible. */ ASSERT3U(HDR_GET_LSIZE(hdr), ==, lsize); /* * Skip ARC stat bump for block pointers with embedded * data. The data are read from the blkptr itself via * decode_embedded_bp_compressed(). */ if (!embedded_bp) { DTRACE_PROBE4(arc__miss, arc_buf_hdr_t *, hdr, blkptr_t *, bp, uint64_t, lsize, zbookmark_phys_t *, zb); ARCSTAT_BUMP(arcstat_misses); ARCSTAT_CONDSTAT(!(*arc_flags & ARC_FLAG_PREFETCH), demand, prefetch, !HDR_ISTYPE_METADATA(hdr), data, metadata, misses); zfs_racct_read(size, 1); } /* Check if the spa even has l2 configured */ const boolean_t spa_has_l2 = l2arc_ndev != 0 && spa->spa_l2cache.sav_count > 0; if (vd != NULL && spa_has_l2 && !(l2arc_norw && devw)) { /* * Read from the L2ARC if the following are true: * 1. The L2ARC vdev was previously cached. * 2. This buffer still has L2ARC metadata. * 3. This buffer isn't currently writing to the L2ARC. * 4. The L2ARC entry wasn't evicted, which may * also have invalidated the vdev. * 5. This isn't prefetch or l2arc_noprefetch is 0. */ if (HDR_HAS_L2HDR(hdr) && !HDR_L2_WRITING(hdr) && !HDR_L2_EVICTED(hdr) && !(l2arc_noprefetch && (*arc_flags & ARC_FLAG_PREFETCH))) { l2arc_read_callback_t *cb; abd_t *abd; uint64_t asize; DTRACE_PROBE1(l2arc__hit, arc_buf_hdr_t *, hdr); ARCSTAT_BUMP(arcstat_l2_hits); hdr->b_l2hdr.b_hits++; cb = kmem_zalloc(sizeof (l2arc_read_callback_t), KM_SLEEP); cb->l2rcb_hdr = hdr; cb->l2rcb_bp = *bp; cb->l2rcb_zb = *zb; cb->l2rcb_flags = zio_flags; /* * When Compressed ARC is disabled, but the * L2ARC block is compressed, arc_hdr_size() * will have returned LSIZE rather than PSIZE. */ if (HDR_GET_COMPRESS(hdr) != ZIO_COMPRESS_OFF && !HDR_COMPRESSION_ENABLED(hdr) && HDR_GET_PSIZE(hdr) != 0) { size = HDR_GET_PSIZE(hdr); } asize = vdev_psize_to_asize(vd, size); if (asize != size) { abd = abd_alloc_for_io(asize, HDR_ISTYPE_METADATA(hdr)); cb->l2rcb_abd = abd; } else { abd = hdr_abd; } ASSERT(addr >= VDEV_LABEL_START_SIZE && addr + asize <= vd->vdev_psize - VDEV_LABEL_END_SIZE); /* * l2arc read. The SCL_L2ARC lock will be * released by l2arc_read_done(). * Issue a null zio if the underlying buffer * was squashed to zero size by compression. */ ASSERT3U(arc_hdr_get_compress(hdr), !=, ZIO_COMPRESS_EMPTY); rzio = zio_read_phys(pio, vd, addr, asize, abd, ZIO_CHECKSUM_OFF, l2arc_read_done, cb, priority, zio_flags | ZIO_FLAG_CANFAIL | ZIO_FLAG_DONT_PROPAGATE | ZIO_FLAG_DONT_RETRY, B_FALSE); acb->acb_zio_head = rzio; if (hash_lock != NULL) mutex_exit(hash_lock); DTRACE_PROBE2(l2arc__read, vdev_t *, vd, zio_t *, rzio); ARCSTAT_INCR(arcstat_l2_read_bytes, HDR_GET_PSIZE(hdr)); if (*arc_flags & ARC_FLAG_NOWAIT) { zio_nowait(rzio); goto out; } ASSERT(*arc_flags & ARC_FLAG_WAIT); if (zio_wait(rzio) == 0) goto out; /* l2arc read error; goto zio_read() */ if (hash_lock != NULL) mutex_enter(hash_lock); } else { DTRACE_PROBE1(l2arc__miss, arc_buf_hdr_t *, hdr); ARCSTAT_BUMP(arcstat_l2_misses); if (HDR_L2_WRITING(hdr)) ARCSTAT_BUMP(arcstat_l2_rw_clash); spa_config_exit(spa, SCL_L2ARC, vd); } } else { if (vd != NULL) spa_config_exit(spa, SCL_L2ARC, vd); /* * Only a spa with l2 should contribute to l2 * miss stats. (Including the case of having a * faulted cache device - that's also a miss.) */ if (spa_has_l2) { /* * Skip ARC stat bump for block pointers with * embedded data. The data are read from the * blkptr itself via * decode_embedded_bp_compressed(). */ if (!embedded_bp) { DTRACE_PROBE1(l2arc__miss, arc_buf_hdr_t *, hdr); ARCSTAT_BUMP(arcstat_l2_misses); } } } rzio = zio_read(pio, spa, bp, hdr_abd, size, arc_read_done, hdr, priority, zio_flags, zb); acb->acb_zio_head = rzio; if (hash_lock != NULL) mutex_exit(hash_lock); if (*arc_flags & ARC_FLAG_WAIT) { rc = zio_wait(rzio); goto out; } ASSERT(*arc_flags & ARC_FLAG_NOWAIT); zio_nowait(rzio); } out: /* embedded bps don't actually go to disk */ if (!embedded_bp) spa_read_history_add(spa, zb, *arc_flags); spl_fstrans_unmark(cookie); return (rc); done: if (done) done(NULL, zb, bp, buf, private); if (pio && rc != 0) { zio_t *zio = zio_null(pio, spa, NULL, NULL, NULL, zio_flags); zio->io_error = rc; zio_nowait(zio); } goto out; } arc_prune_t * arc_add_prune_callback(arc_prune_func_t *func, void *private) { arc_prune_t *p; p = kmem_alloc(sizeof (*p), KM_SLEEP); p->p_pfunc = func; p->p_private = private; list_link_init(&p->p_node); zfs_refcount_create(&p->p_refcnt); mutex_enter(&arc_prune_mtx); zfs_refcount_add(&p->p_refcnt, &arc_prune_list); list_insert_head(&arc_prune_list, p); mutex_exit(&arc_prune_mtx); return (p); } void arc_remove_prune_callback(arc_prune_t *p) { boolean_t wait = B_FALSE; mutex_enter(&arc_prune_mtx); list_remove(&arc_prune_list, p); if (zfs_refcount_remove(&p->p_refcnt, &arc_prune_list) > 0) wait = B_TRUE; mutex_exit(&arc_prune_mtx); /* wait for arc_prune_task to finish */ if (wait) taskq_wait_outstanding(arc_prune_taskq, 0); ASSERT0(zfs_refcount_count(&p->p_refcnt)); zfs_refcount_destroy(&p->p_refcnt); kmem_free(p, sizeof (*p)); } /* * Notify the arc that a block was freed, and thus will never be used again. */ void arc_freed(spa_t *spa, const blkptr_t *bp) { arc_buf_hdr_t *hdr; kmutex_t *hash_lock; uint64_t guid = spa_load_guid(spa); ASSERT(!BP_IS_EMBEDDED(bp)); hdr = buf_hash_find(guid, bp, &hash_lock); if (hdr == NULL) return; /* * We might be trying to free a block that is still doing I/O * (i.e. prefetch) or has some other reference (i.e. a dedup-ed, * dmu_sync-ed block). A block may also have a reference if it is * part of a dedup-ed, dmu_synced write. The dmu_sync() function would * have written the new block to its final resting place on disk but * without the dedup flag set. This would have left the hdr in the MRU * state and discoverable. When the txg finally syncs it detects that * the block was overridden in open context and issues an override I/O. * Since this is a dedup block, the override I/O will determine if the * block is already in the DDT. If so, then it will replace the io_bp * with the bp from the DDT and allow the I/O to finish. When the I/O * reaches the done callback, dbuf_write_override_done, it will * check to see if the io_bp and io_bp_override are identical. * If they are not, then it indicates that the bp was replaced with * the bp in the DDT and the override bp is freed. This allows * us to arrive here with a reference on a block that is being * freed. So if we have an I/O in progress, or a reference to * this hdr, then we don't destroy the hdr. */ if (!HDR_HAS_L1HDR(hdr) || zfs_refcount_is_zero(&hdr->b_l1hdr.b_refcnt)) { arc_change_state(arc_anon, hdr); arc_hdr_destroy(hdr); mutex_exit(hash_lock); } else { mutex_exit(hash_lock); } } /* * Release this buffer from the cache, making it an anonymous buffer. This * must be done after a read and prior to modifying the buffer contents. * If the buffer has more than one reference, we must make * a new hdr for the buffer. */ void arc_release(arc_buf_t *buf, const void *tag) { arc_buf_hdr_t *hdr = buf->b_hdr; /* * It would be nice to assert that if its DMU metadata (level > * 0 || it's the dnode file), then it must be syncing context. * But we don't know that information at this level. */ ASSERT(HDR_HAS_L1HDR(hdr)); /* * We don't grab the hash lock prior to this check, because if * the buffer's header is in the arc_anon state, it won't be * linked into the hash table. */ if (hdr->b_l1hdr.b_state == arc_anon) { ASSERT(!HDR_IO_IN_PROGRESS(hdr)); ASSERT(!HDR_IN_HASH_TABLE(hdr)); ASSERT(!HDR_HAS_L2HDR(hdr)); ASSERT3P(hdr->b_l1hdr.b_buf, ==, buf); ASSERT(ARC_BUF_LAST(buf)); ASSERT3S(zfs_refcount_count(&hdr->b_l1hdr.b_refcnt), ==, 1); ASSERT(!multilist_link_active(&hdr->b_l1hdr.b_arc_node)); hdr->b_l1hdr.b_arc_access = 0; /* * If the buf is being overridden then it may already * have a hdr that is not empty. */ buf_discard_identity(hdr); arc_buf_thaw(buf); return; } kmutex_t *hash_lock = HDR_LOCK(hdr); mutex_enter(hash_lock); /* * This assignment is only valid as long as the hash_lock is * held, we must be careful not to reference state or the * b_state field after dropping the lock. */ arc_state_t *state = hdr->b_l1hdr.b_state; ASSERT3P(hash_lock, ==, HDR_LOCK(hdr)); ASSERT3P(state, !=, arc_anon); /* this buffer is not on any list */ ASSERT3S(zfs_refcount_count(&hdr->b_l1hdr.b_refcnt), >, 0); if (HDR_HAS_L2HDR(hdr)) { mutex_enter(&hdr->b_l2hdr.b_dev->l2ad_mtx); /* * We have to recheck this conditional again now that * we're holding the l2ad_mtx to prevent a race with * another thread which might be concurrently calling * l2arc_evict(). In that case, l2arc_evict() might have * destroyed the header's L2 portion as we were waiting * to acquire the l2ad_mtx. */ if (HDR_HAS_L2HDR(hdr)) arc_hdr_l2hdr_destroy(hdr); mutex_exit(&hdr->b_l2hdr.b_dev->l2ad_mtx); } /* * Do we have more than one buf? */ if (hdr->b_l1hdr.b_buf != buf || !ARC_BUF_LAST(buf)) { arc_buf_hdr_t *nhdr; uint64_t spa = hdr->b_spa; uint64_t psize = HDR_GET_PSIZE(hdr); uint64_t lsize = HDR_GET_LSIZE(hdr); boolean_t protected = HDR_PROTECTED(hdr); enum zio_compress compress = arc_hdr_get_compress(hdr); arc_buf_contents_t type = arc_buf_type(hdr); VERIFY3U(hdr->b_type, ==, type); ASSERT(hdr->b_l1hdr.b_buf != buf || buf->b_next != NULL); VERIFY3S(remove_reference(hdr, tag), >, 0); - if (arc_buf_is_shared(buf) && !ARC_BUF_COMPRESSED(buf)) { + if (ARC_BUF_SHARED(buf) && !ARC_BUF_COMPRESSED(buf)) { ASSERT3P(hdr->b_l1hdr.b_buf, !=, buf); ASSERT(ARC_BUF_LAST(buf)); } /* * Pull the data off of this hdr and attach it to * a new anonymous hdr. Also find the last buffer * in the hdr's buffer list. */ arc_buf_t *lastbuf = arc_buf_remove(hdr, buf); ASSERT3P(lastbuf, !=, NULL); /* * If the current arc_buf_t and the hdr are sharing their data * buffer, then we must stop sharing that block. */ - if (arc_buf_is_shared(buf)) { + if (ARC_BUF_SHARED(buf)) { ASSERT3P(hdr->b_l1hdr.b_buf, !=, buf); - VERIFY(!arc_buf_is_shared(lastbuf)); + ASSERT(!arc_buf_is_shared(lastbuf)); /* * First, sever the block sharing relationship between * buf and the arc_buf_hdr_t. */ arc_unshare_buf(hdr, buf); /* * Now we need to recreate the hdr's b_pabd. Since we * have lastbuf handy, we try to share with it, but if * we can't then we allocate a new b_pabd and copy the * data from buf into it. */ if (arc_can_share(hdr, lastbuf)) { arc_share_buf(hdr, lastbuf); } else { arc_hdr_alloc_abd(hdr, 0); abd_copy_from_buf(hdr->b_l1hdr.b_pabd, buf->b_data, psize); } VERIFY3P(lastbuf->b_data, !=, NULL); } else if (HDR_SHARED_DATA(hdr)) { /* * Uncompressed shared buffers are always at the end * of the list. Compressed buffers don't have the * same requirements. This makes it hard to * simply assert that the lastbuf is shared so * we rely on the hdr's compression flags to determine * if we have a compressed, shared buffer. */ ASSERT(arc_buf_is_shared(lastbuf) || arc_hdr_get_compress(hdr) != ZIO_COMPRESS_OFF); - ASSERT(!ARC_BUF_SHARED(buf)); + ASSERT(!arc_buf_is_shared(buf)); } ASSERT(hdr->b_l1hdr.b_pabd != NULL || HDR_HAS_RABD(hdr)); ASSERT3P(state, !=, arc_l2c_only); (void) zfs_refcount_remove_many(&state->arcs_size[type], arc_buf_size(buf), buf); if (zfs_refcount_is_zero(&hdr->b_l1hdr.b_refcnt)) { ASSERT3P(state, !=, arc_l2c_only); (void) zfs_refcount_remove_many( &state->arcs_esize[type], arc_buf_size(buf), buf); } arc_cksum_verify(buf); arc_buf_unwatch(buf); /* if this is the last uncompressed buf free the checksum */ if (!arc_hdr_has_uncompressed_buf(hdr)) arc_cksum_free(hdr); mutex_exit(hash_lock); nhdr = arc_hdr_alloc(spa, psize, lsize, protected, compress, hdr->b_complevel, type); ASSERT3P(nhdr->b_l1hdr.b_buf, ==, NULL); ASSERT0(zfs_refcount_count(&nhdr->b_l1hdr.b_refcnt)); VERIFY3U(nhdr->b_type, ==, type); ASSERT(!HDR_SHARED_DATA(nhdr)); nhdr->b_l1hdr.b_buf = buf; (void) zfs_refcount_add(&nhdr->b_l1hdr.b_refcnt, tag); buf->b_hdr = nhdr; (void) zfs_refcount_add_many(&arc_anon->arcs_size[type], arc_buf_size(buf), buf); } else { ASSERT(zfs_refcount_count(&hdr->b_l1hdr.b_refcnt) == 1); /* protected by hash lock, or hdr is on arc_anon */ ASSERT(!multilist_link_active(&hdr->b_l1hdr.b_arc_node)); ASSERT(!HDR_IO_IN_PROGRESS(hdr)); hdr->b_l1hdr.b_mru_hits = 0; hdr->b_l1hdr.b_mru_ghost_hits = 0; hdr->b_l1hdr.b_mfu_hits = 0; hdr->b_l1hdr.b_mfu_ghost_hits = 0; arc_change_state(arc_anon, hdr); hdr->b_l1hdr.b_arc_access = 0; mutex_exit(hash_lock); buf_discard_identity(hdr); arc_buf_thaw(buf); } } int arc_released(arc_buf_t *buf) { return (buf->b_data != NULL && buf->b_hdr->b_l1hdr.b_state == arc_anon); } #ifdef ZFS_DEBUG int arc_referenced(arc_buf_t *buf) { return (zfs_refcount_count(&buf->b_hdr->b_l1hdr.b_refcnt)); } #endif static void arc_write_ready(zio_t *zio) { arc_write_callback_t *callback = zio->io_private; arc_buf_t *buf = callback->awcb_buf; arc_buf_hdr_t *hdr = buf->b_hdr; blkptr_t *bp = zio->io_bp; uint64_t psize = BP_IS_HOLE(bp) ? 0 : BP_GET_PSIZE(bp); fstrans_cookie_t cookie = spl_fstrans_mark(); ASSERT(HDR_HAS_L1HDR(hdr)); ASSERT(!zfs_refcount_is_zero(&buf->b_hdr->b_l1hdr.b_refcnt)); ASSERT3P(hdr->b_l1hdr.b_buf, !=, NULL); /* * If we're reexecuting this zio because the pool suspended, then * cleanup any state that was previously set the first time the * callback was invoked. */ if (zio->io_flags & ZIO_FLAG_REEXECUTED) { arc_cksum_free(hdr); arc_buf_unwatch(buf); if (hdr->b_l1hdr.b_pabd != NULL) { - if (arc_buf_is_shared(buf)) { + if (ARC_BUF_SHARED(buf)) { arc_unshare_buf(hdr, buf); } else { + ASSERT(!arc_buf_is_shared(buf)); arc_hdr_free_abd(hdr, B_FALSE); } } if (HDR_HAS_RABD(hdr)) arc_hdr_free_abd(hdr, B_TRUE); } ASSERT3P(hdr->b_l1hdr.b_pabd, ==, NULL); ASSERT(!HDR_HAS_RABD(hdr)); ASSERT(!HDR_SHARED_DATA(hdr)); ASSERT(!arc_buf_is_shared(buf)); callback->awcb_ready(zio, buf, callback->awcb_private); if (HDR_IO_IN_PROGRESS(hdr)) { ASSERT(zio->io_flags & ZIO_FLAG_REEXECUTED); } else { arc_hdr_set_flags(hdr, ARC_FLAG_IO_IN_PROGRESS); add_reference(hdr, hdr); /* For IO_IN_PROGRESS. */ } if (BP_IS_PROTECTED(bp)) { /* ZIL blocks are written through zio_rewrite */ ASSERT3U(BP_GET_TYPE(bp), !=, DMU_OT_INTENT_LOG); if (BP_SHOULD_BYTESWAP(bp)) { if (BP_GET_LEVEL(bp) > 0) { hdr->b_l1hdr.b_byteswap = DMU_BSWAP_UINT64; } else { hdr->b_l1hdr.b_byteswap = DMU_OT_BYTESWAP(BP_GET_TYPE(bp)); } } else { hdr->b_l1hdr.b_byteswap = DMU_BSWAP_NUMFUNCS; } arc_hdr_set_flags(hdr, ARC_FLAG_PROTECTED); hdr->b_crypt_hdr.b_ot = BP_GET_TYPE(bp); hdr->b_crypt_hdr.b_dsobj = zio->io_bookmark.zb_objset; zio_crypt_decode_params_bp(bp, hdr->b_crypt_hdr.b_salt, hdr->b_crypt_hdr.b_iv); zio_crypt_decode_mac_bp(bp, hdr->b_crypt_hdr.b_mac); } else { arc_hdr_clear_flags(hdr, ARC_FLAG_PROTECTED); } /* * If this block was written for raw encryption but the zio layer * ended up only authenticating it, adjust the buffer flags now. */ if (BP_IS_AUTHENTICATED(bp) && ARC_BUF_ENCRYPTED(buf)) { arc_hdr_set_flags(hdr, ARC_FLAG_NOAUTH); buf->b_flags &= ~ARC_BUF_FLAG_ENCRYPTED; if (BP_GET_COMPRESS(bp) == ZIO_COMPRESS_OFF) buf->b_flags &= ~ARC_BUF_FLAG_COMPRESSED; } else if (BP_IS_HOLE(bp) && ARC_BUF_ENCRYPTED(buf)) { buf->b_flags &= ~ARC_BUF_FLAG_ENCRYPTED; buf->b_flags &= ~ARC_BUF_FLAG_COMPRESSED; } /* this must be done after the buffer flags are adjusted */ arc_cksum_compute(buf); enum zio_compress compress; if (BP_IS_HOLE(bp) || BP_IS_EMBEDDED(bp)) { compress = ZIO_COMPRESS_OFF; } else { ASSERT3U(HDR_GET_LSIZE(hdr), ==, BP_GET_LSIZE(bp)); compress = BP_GET_COMPRESS(bp); } HDR_SET_PSIZE(hdr, psize); arc_hdr_set_compress(hdr, compress); hdr->b_complevel = zio->io_prop.zp_complevel; if (zio->io_error != 0 || psize == 0) goto out; /* * Fill the hdr with data. If the buffer is encrypted we have no choice * but to copy the data into b_radb. If the hdr is compressed, the data * we want is available from the zio, otherwise we can take it from * the buf. * * We might be able to share the buf's data with the hdr here. However, * doing so would cause the ARC to be full of linear ABDs if we write a * lot of shareable data. As a compromise, we check whether scattered * ABDs are allowed, and assume that if they are then the user wants * the ARC to be primarily filled with them regardless of the data being * written. Therefore, if they're allowed then we allocate one and copy * the data into it; otherwise, we share the data directly if we can. */ if (ARC_BUF_ENCRYPTED(buf)) { ASSERT3U(psize, >, 0); ASSERT(ARC_BUF_COMPRESSED(buf)); arc_hdr_alloc_abd(hdr, ARC_HDR_ALLOC_RDATA | ARC_HDR_USE_RESERVE); abd_copy(hdr->b_crypt_hdr.b_rabd, zio->io_abd, psize); } else if (!(HDR_UNCACHED(hdr) || abd_size_alloc_linear(arc_buf_size(buf))) || !arc_can_share(hdr, buf)) { /* * Ideally, we would always copy the io_abd into b_pabd, but the * user may have disabled compressed ARC, thus we must check the * hdr's compression setting rather than the io_bp's. */ if (BP_IS_ENCRYPTED(bp)) { ASSERT3U(psize, >, 0); arc_hdr_alloc_abd(hdr, ARC_HDR_ALLOC_RDATA | ARC_HDR_USE_RESERVE); abd_copy(hdr->b_crypt_hdr.b_rabd, zio->io_abd, psize); } else if (arc_hdr_get_compress(hdr) != ZIO_COMPRESS_OFF && !ARC_BUF_COMPRESSED(buf)) { ASSERT3U(psize, >, 0); arc_hdr_alloc_abd(hdr, ARC_HDR_USE_RESERVE); abd_copy(hdr->b_l1hdr.b_pabd, zio->io_abd, psize); } else { ASSERT3U(zio->io_orig_size, ==, arc_hdr_size(hdr)); arc_hdr_alloc_abd(hdr, ARC_HDR_USE_RESERVE); abd_copy_from_buf(hdr->b_l1hdr.b_pabd, buf->b_data, arc_buf_size(buf)); } } else { ASSERT3P(buf->b_data, ==, abd_to_buf(zio->io_orig_abd)); ASSERT3U(zio->io_orig_size, ==, arc_buf_size(buf)); ASSERT3P(hdr->b_l1hdr.b_buf, ==, buf); ASSERT(ARC_BUF_LAST(buf)); arc_share_buf(hdr, buf); } out: arc_hdr_verify(hdr, bp); spl_fstrans_unmark(cookie); } static void arc_write_children_ready(zio_t *zio) { arc_write_callback_t *callback = zio->io_private; arc_buf_t *buf = callback->awcb_buf; callback->awcb_children_ready(zio, buf, callback->awcb_private); } static void arc_write_done(zio_t *zio) { arc_write_callback_t *callback = zio->io_private; arc_buf_t *buf = callback->awcb_buf; arc_buf_hdr_t *hdr = buf->b_hdr; ASSERT3P(hdr->b_l1hdr.b_acb, ==, NULL); if (zio->io_error == 0) { arc_hdr_verify(hdr, zio->io_bp); if (BP_IS_HOLE(zio->io_bp) || BP_IS_EMBEDDED(zio->io_bp)) { buf_discard_identity(hdr); } else { hdr->b_dva = *BP_IDENTITY(zio->io_bp); hdr->b_birth = BP_PHYSICAL_BIRTH(zio->io_bp); } } else { ASSERT(HDR_EMPTY(hdr)); } /* * If the block to be written was all-zero or compressed enough to be * embedded in the BP, no write was performed so there will be no * dva/birth/checksum. The buffer must therefore remain anonymous * (and uncached). */ if (!HDR_EMPTY(hdr)) { arc_buf_hdr_t *exists; kmutex_t *hash_lock; ASSERT3U(zio->io_error, ==, 0); arc_cksum_verify(buf); exists = buf_hash_insert(hdr, &hash_lock); if (exists != NULL) { /* * This can only happen if we overwrite for * sync-to-convergence, because we remove * buffers from the hash table when we arc_free(). */ if (zio->io_flags & ZIO_FLAG_IO_REWRITE) { if (!BP_EQUAL(&zio->io_bp_orig, zio->io_bp)) panic("bad overwrite, hdr=%p exists=%p", (void *)hdr, (void *)exists); ASSERT(zfs_refcount_is_zero( &exists->b_l1hdr.b_refcnt)); arc_change_state(arc_anon, exists); arc_hdr_destroy(exists); mutex_exit(hash_lock); exists = buf_hash_insert(hdr, &hash_lock); ASSERT3P(exists, ==, NULL); } else if (zio->io_flags & ZIO_FLAG_NOPWRITE) { /* nopwrite */ ASSERT(zio->io_prop.zp_nopwrite); if (!BP_EQUAL(&zio->io_bp_orig, zio->io_bp)) panic("bad nopwrite, hdr=%p exists=%p", (void *)hdr, (void *)exists); } else { /* Dedup */ ASSERT3P(hdr->b_l1hdr.b_buf, !=, NULL); ASSERT(ARC_BUF_LAST(hdr->b_l1hdr.b_buf)); ASSERT(hdr->b_l1hdr.b_state == arc_anon); ASSERT(BP_GET_DEDUP(zio->io_bp)); ASSERT(BP_GET_LEVEL(zio->io_bp) == 0); } } arc_hdr_clear_flags(hdr, ARC_FLAG_IO_IN_PROGRESS); VERIFY3S(remove_reference(hdr, hdr), >, 0); /* if it's not anon, we are doing a scrub */ if (exists == NULL && hdr->b_l1hdr.b_state == arc_anon) arc_access(hdr, 0, B_FALSE); mutex_exit(hash_lock); } else { arc_hdr_clear_flags(hdr, ARC_FLAG_IO_IN_PROGRESS); VERIFY3S(remove_reference(hdr, hdr), >, 0); } callback->awcb_done(zio, buf, callback->awcb_private); abd_free(zio->io_abd); kmem_free(callback, sizeof (arc_write_callback_t)); } zio_t * arc_write(zio_t *pio, spa_t *spa, uint64_t txg, blkptr_t *bp, arc_buf_t *buf, boolean_t uncached, boolean_t l2arc, const zio_prop_t *zp, arc_write_done_func_t *ready, arc_write_done_func_t *children_ready, arc_write_done_func_t *done, void *private, zio_priority_t priority, int zio_flags, const zbookmark_phys_t *zb) { arc_buf_hdr_t *hdr = buf->b_hdr; arc_write_callback_t *callback; zio_t *zio; zio_prop_t localprop = *zp; ASSERT3P(ready, !=, NULL); ASSERT3P(done, !=, NULL); ASSERT(!HDR_IO_ERROR(hdr)); ASSERT(!HDR_IO_IN_PROGRESS(hdr)); ASSERT3P(hdr->b_l1hdr.b_acb, ==, NULL); ASSERT3P(hdr->b_l1hdr.b_buf, !=, NULL); if (uncached) arc_hdr_set_flags(hdr, ARC_FLAG_UNCACHED); else if (l2arc) arc_hdr_set_flags(hdr, ARC_FLAG_L2CACHE); if (ARC_BUF_ENCRYPTED(buf)) { ASSERT(ARC_BUF_COMPRESSED(buf)); localprop.zp_encrypt = B_TRUE; localprop.zp_compress = HDR_GET_COMPRESS(hdr); localprop.zp_complevel = hdr->b_complevel; localprop.zp_byteorder = (hdr->b_l1hdr.b_byteswap == DMU_BSWAP_NUMFUNCS) ? ZFS_HOST_BYTEORDER : !ZFS_HOST_BYTEORDER; memcpy(localprop.zp_salt, hdr->b_crypt_hdr.b_salt, ZIO_DATA_SALT_LEN); memcpy(localprop.zp_iv, hdr->b_crypt_hdr.b_iv, ZIO_DATA_IV_LEN); memcpy(localprop.zp_mac, hdr->b_crypt_hdr.b_mac, ZIO_DATA_MAC_LEN); if (DMU_OT_IS_ENCRYPTED(localprop.zp_type)) { localprop.zp_nopwrite = B_FALSE; localprop.zp_copies = MIN(localprop.zp_copies, SPA_DVAS_PER_BP - 1); } zio_flags |= ZIO_FLAG_RAW; } else if (ARC_BUF_COMPRESSED(buf)) { ASSERT3U(HDR_GET_LSIZE(hdr), !=, arc_buf_size(buf)); localprop.zp_compress = HDR_GET_COMPRESS(hdr); localprop.zp_complevel = hdr->b_complevel; zio_flags |= ZIO_FLAG_RAW_COMPRESS; } callback = kmem_zalloc(sizeof (arc_write_callback_t), KM_SLEEP); callback->awcb_ready = ready; callback->awcb_children_ready = children_ready; callback->awcb_done = done; callback->awcb_private = private; callback->awcb_buf = buf; /* * The hdr's b_pabd is now stale, free it now. A new data block * will be allocated when the zio pipeline calls arc_write_ready(). */ if (hdr->b_l1hdr.b_pabd != NULL) { /* * If the buf is currently sharing the data block with * the hdr then we need to break that relationship here. * The hdr will remain with a NULL data pointer and the * buf will take sole ownership of the block. */ - if (arc_buf_is_shared(buf)) { + if (ARC_BUF_SHARED(buf)) { arc_unshare_buf(hdr, buf); } else { + ASSERT(!arc_buf_is_shared(buf)); arc_hdr_free_abd(hdr, B_FALSE); } VERIFY3P(buf->b_data, !=, NULL); } if (HDR_HAS_RABD(hdr)) arc_hdr_free_abd(hdr, B_TRUE); if (!(zio_flags & ZIO_FLAG_RAW)) arc_hdr_set_compress(hdr, ZIO_COMPRESS_OFF); ASSERT(!arc_buf_is_shared(buf)); ASSERT3P(hdr->b_l1hdr.b_pabd, ==, NULL); zio = zio_write(pio, spa, txg, bp, abd_get_from_buf(buf->b_data, HDR_GET_LSIZE(hdr)), HDR_GET_LSIZE(hdr), arc_buf_size(buf), &localprop, arc_write_ready, (children_ready != NULL) ? arc_write_children_ready : NULL, arc_write_done, callback, priority, zio_flags, zb); return (zio); } void arc_tempreserve_clear(uint64_t reserve) { atomic_add_64(&arc_tempreserve, -reserve); ASSERT((int64_t)arc_tempreserve >= 0); } int arc_tempreserve_space(spa_t *spa, uint64_t reserve, uint64_t txg) { int error; uint64_t anon_size; if (!arc_no_grow && reserve > arc_c/4 && reserve * 4 > (2ULL << SPA_MAXBLOCKSHIFT)) arc_c = MIN(arc_c_max, reserve * 4); /* * Throttle when the calculated memory footprint for the TXG * exceeds the target ARC size. */ if (reserve > arc_c) { DMU_TX_STAT_BUMP(dmu_tx_memory_reserve); return (SET_ERROR(ERESTART)); } /* * Don't count loaned bufs as in flight dirty data to prevent long * network delays from blocking transactions that are ready to be * assigned to a txg. */ /* assert that it has not wrapped around */ ASSERT3S(atomic_add_64_nv(&arc_loaned_bytes, 0), >=, 0); anon_size = MAX((int64_t) (zfs_refcount_count(&arc_anon->arcs_size[ARC_BUFC_DATA]) + zfs_refcount_count(&arc_anon->arcs_size[ARC_BUFC_METADATA]) - arc_loaned_bytes), 0); /* * Writes will, almost always, require additional memory allocations * in order to compress/encrypt/etc the data. We therefore need to * make sure that there is sufficient available memory for this. */ error = arc_memory_throttle(spa, reserve, txg); if (error != 0) return (error); /* * Throttle writes when the amount of dirty data in the cache * gets too large. We try to keep the cache less than half full * of dirty blocks so that our sync times don't grow too large. * * In the case of one pool being built on another pool, we want * to make sure we don't end up throttling the lower (backing) * pool when the upper pool is the majority contributor to dirty * data. To insure we make forward progress during throttling, we * also check the current pool's net dirty data and only throttle * if it exceeds zfs_arc_pool_dirty_percent of the anonymous dirty * data in the cache. * * Note: if two requests come in concurrently, we might let them * both succeed, when one of them should fail. Not a huge deal. */ uint64_t total_dirty = reserve + arc_tempreserve + anon_size; uint64_t spa_dirty_anon = spa_dirty_data(spa); uint64_t rarc_c = arc_warm ? arc_c : arc_c_max; if (total_dirty > rarc_c * zfs_arc_dirty_limit_percent / 100 && anon_size > rarc_c * zfs_arc_anon_limit_percent / 100 && spa_dirty_anon > anon_size * zfs_arc_pool_dirty_percent / 100) { #ifdef ZFS_DEBUG uint64_t meta_esize = zfs_refcount_count( &arc_anon->arcs_esize[ARC_BUFC_METADATA]); uint64_t data_esize = zfs_refcount_count(&arc_anon->arcs_esize[ARC_BUFC_DATA]); dprintf("failing, arc_tempreserve=%lluK anon_meta=%lluK " "anon_data=%lluK tempreserve=%lluK rarc_c=%lluK\n", (u_longlong_t)arc_tempreserve >> 10, (u_longlong_t)meta_esize >> 10, (u_longlong_t)data_esize >> 10, (u_longlong_t)reserve >> 10, (u_longlong_t)rarc_c >> 10); #endif DMU_TX_STAT_BUMP(dmu_tx_dirty_throttle); return (SET_ERROR(ERESTART)); } atomic_add_64(&arc_tempreserve, reserve); return (0); } static void arc_kstat_update_state(arc_state_t *state, kstat_named_t *size, kstat_named_t *data, kstat_named_t *metadata, kstat_named_t *evict_data, kstat_named_t *evict_metadata) { data->value.ui64 = zfs_refcount_count(&state->arcs_size[ARC_BUFC_DATA]); metadata->value.ui64 = zfs_refcount_count(&state->arcs_size[ARC_BUFC_METADATA]); size->value.ui64 = data->value.ui64 + metadata->value.ui64; evict_data->value.ui64 = zfs_refcount_count(&state->arcs_esize[ARC_BUFC_DATA]); evict_metadata->value.ui64 = zfs_refcount_count(&state->arcs_esize[ARC_BUFC_METADATA]); } static int arc_kstat_update(kstat_t *ksp, int rw) { arc_stats_t *as = ksp->ks_data; if (rw == KSTAT_WRITE) return (SET_ERROR(EACCES)); as->arcstat_hits.value.ui64 = wmsum_value(&arc_sums.arcstat_hits); as->arcstat_iohits.value.ui64 = wmsum_value(&arc_sums.arcstat_iohits); as->arcstat_misses.value.ui64 = wmsum_value(&arc_sums.arcstat_misses); as->arcstat_demand_data_hits.value.ui64 = wmsum_value(&arc_sums.arcstat_demand_data_hits); as->arcstat_demand_data_iohits.value.ui64 = wmsum_value(&arc_sums.arcstat_demand_data_iohits); as->arcstat_demand_data_misses.value.ui64 = wmsum_value(&arc_sums.arcstat_demand_data_misses); as->arcstat_demand_metadata_hits.value.ui64 = wmsum_value(&arc_sums.arcstat_demand_metadata_hits); as->arcstat_demand_metadata_iohits.value.ui64 = wmsum_value(&arc_sums.arcstat_demand_metadata_iohits); as->arcstat_demand_metadata_misses.value.ui64 = wmsum_value(&arc_sums.arcstat_demand_metadata_misses); as->arcstat_prefetch_data_hits.value.ui64 = wmsum_value(&arc_sums.arcstat_prefetch_data_hits); as->arcstat_prefetch_data_iohits.value.ui64 = wmsum_value(&arc_sums.arcstat_prefetch_data_iohits); as->arcstat_prefetch_data_misses.value.ui64 = wmsum_value(&arc_sums.arcstat_prefetch_data_misses); as->arcstat_prefetch_metadata_hits.value.ui64 = wmsum_value(&arc_sums.arcstat_prefetch_metadata_hits); as->arcstat_prefetch_metadata_iohits.value.ui64 = wmsum_value(&arc_sums.arcstat_prefetch_metadata_iohits); as->arcstat_prefetch_metadata_misses.value.ui64 = wmsum_value(&arc_sums.arcstat_prefetch_metadata_misses); as->arcstat_mru_hits.value.ui64 = wmsum_value(&arc_sums.arcstat_mru_hits); as->arcstat_mru_ghost_hits.value.ui64 = wmsum_value(&arc_sums.arcstat_mru_ghost_hits); as->arcstat_mfu_hits.value.ui64 = wmsum_value(&arc_sums.arcstat_mfu_hits); as->arcstat_mfu_ghost_hits.value.ui64 = wmsum_value(&arc_sums.arcstat_mfu_ghost_hits); as->arcstat_uncached_hits.value.ui64 = wmsum_value(&arc_sums.arcstat_uncached_hits); as->arcstat_deleted.value.ui64 = wmsum_value(&arc_sums.arcstat_deleted); as->arcstat_mutex_miss.value.ui64 = wmsum_value(&arc_sums.arcstat_mutex_miss); as->arcstat_access_skip.value.ui64 = wmsum_value(&arc_sums.arcstat_access_skip); as->arcstat_evict_skip.value.ui64 = wmsum_value(&arc_sums.arcstat_evict_skip); as->arcstat_evict_not_enough.value.ui64 = wmsum_value(&arc_sums.arcstat_evict_not_enough); as->arcstat_evict_l2_cached.value.ui64 = wmsum_value(&arc_sums.arcstat_evict_l2_cached); as->arcstat_evict_l2_eligible.value.ui64 = wmsum_value(&arc_sums.arcstat_evict_l2_eligible); as->arcstat_evict_l2_eligible_mfu.value.ui64 = wmsum_value(&arc_sums.arcstat_evict_l2_eligible_mfu); as->arcstat_evict_l2_eligible_mru.value.ui64 = wmsum_value(&arc_sums.arcstat_evict_l2_eligible_mru); as->arcstat_evict_l2_ineligible.value.ui64 = wmsum_value(&arc_sums.arcstat_evict_l2_ineligible); as->arcstat_evict_l2_skip.value.ui64 = wmsum_value(&arc_sums.arcstat_evict_l2_skip); as->arcstat_hash_collisions.value.ui64 = wmsum_value(&arc_sums.arcstat_hash_collisions); as->arcstat_hash_chains.value.ui64 = wmsum_value(&arc_sums.arcstat_hash_chains); as->arcstat_size.value.ui64 = aggsum_value(&arc_sums.arcstat_size); as->arcstat_compressed_size.value.ui64 = wmsum_value(&arc_sums.arcstat_compressed_size); as->arcstat_uncompressed_size.value.ui64 = wmsum_value(&arc_sums.arcstat_uncompressed_size); as->arcstat_overhead_size.value.ui64 = wmsum_value(&arc_sums.arcstat_overhead_size); as->arcstat_hdr_size.value.ui64 = wmsum_value(&arc_sums.arcstat_hdr_size); as->arcstat_data_size.value.ui64 = wmsum_value(&arc_sums.arcstat_data_size); as->arcstat_metadata_size.value.ui64 = wmsum_value(&arc_sums.arcstat_metadata_size); as->arcstat_dbuf_size.value.ui64 = wmsum_value(&arc_sums.arcstat_dbuf_size); #if defined(COMPAT_FREEBSD11) as->arcstat_other_size.value.ui64 = wmsum_value(&arc_sums.arcstat_bonus_size) + wmsum_value(&arc_sums.arcstat_dnode_size) + wmsum_value(&arc_sums.arcstat_dbuf_size); #endif arc_kstat_update_state(arc_anon, &as->arcstat_anon_size, &as->arcstat_anon_data, &as->arcstat_anon_metadata, &as->arcstat_anon_evictable_data, &as->arcstat_anon_evictable_metadata); arc_kstat_update_state(arc_mru, &as->arcstat_mru_size, &as->arcstat_mru_data, &as->arcstat_mru_metadata, &as->arcstat_mru_evictable_data, &as->arcstat_mru_evictable_metadata); arc_kstat_update_state(arc_mru_ghost, &as->arcstat_mru_ghost_size, &as->arcstat_mru_ghost_data, &as->arcstat_mru_ghost_metadata, &as->arcstat_mru_ghost_evictable_data, &as->arcstat_mru_ghost_evictable_metadata); arc_kstat_update_state(arc_mfu, &as->arcstat_mfu_size, &as->arcstat_mfu_data, &as->arcstat_mfu_metadata, &as->arcstat_mfu_evictable_data, &as->arcstat_mfu_evictable_metadata); arc_kstat_update_state(arc_mfu_ghost, &as->arcstat_mfu_ghost_size, &as->arcstat_mfu_ghost_data, &as->arcstat_mfu_ghost_metadata, &as->arcstat_mfu_ghost_evictable_data, &as->arcstat_mfu_ghost_evictable_metadata); arc_kstat_update_state(arc_uncached, &as->arcstat_uncached_size, &as->arcstat_uncached_data, &as->arcstat_uncached_metadata, &as->arcstat_uncached_evictable_data, &as->arcstat_uncached_evictable_metadata); as->arcstat_dnode_size.value.ui64 = wmsum_value(&arc_sums.arcstat_dnode_size); as->arcstat_bonus_size.value.ui64 = wmsum_value(&arc_sums.arcstat_bonus_size); as->arcstat_l2_hits.value.ui64 = wmsum_value(&arc_sums.arcstat_l2_hits); as->arcstat_l2_misses.value.ui64 = wmsum_value(&arc_sums.arcstat_l2_misses); as->arcstat_l2_prefetch_asize.value.ui64 = wmsum_value(&arc_sums.arcstat_l2_prefetch_asize); as->arcstat_l2_mru_asize.value.ui64 = wmsum_value(&arc_sums.arcstat_l2_mru_asize); as->arcstat_l2_mfu_asize.value.ui64 = wmsum_value(&arc_sums.arcstat_l2_mfu_asize); as->arcstat_l2_bufc_data_asize.value.ui64 = wmsum_value(&arc_sums.arcstat_l2_bufc_data_asize); as->arcstat_l2_bufc_metadata_asize.value.ui64 = wmsum_value(&arc_sums.arcstat_l2_bufc_metadata_asize); as->arcstat_l2_feeds.value.ui64 = wmsum_value(&arc_sums.arcstat_l2_feeds); as->arcstat_l2_rw_clash.value.ui64 = wmsum_value(&arc_sums.arcstat_l2_rw_clash); as->arcstat_l2_read_bytes.value.ui64 = wmsum_value(&arc_sums.arcstat_l2_read_bytes); as->arcstat_l2_write_bytes.value.ui64 = wmsum_value(&arc_sums.arcstat_l2_write_bytes); as->arcstat_l2_writes_sent.value.ui64 = wmsum_value(&arc_sums.arcstat_l2_writes_sent); as->arcstat_l2_writes_done.value.ui64 = wmsum_value(&arc_sums.arcstat_l2_writes_done); as->arcstat_l2_writes_error.value.ui64 = wmsum_value(&arc_sums.arcstat_l2_writes_error); as->arcstat_l2_writes_lock_retry.value.ui64 = wmsum_value(&arc_sums.arcstat_l2_writes_lock_retry); as->arcstat_l2_evict_lock_retry.value.ui64 = wmsum_value(&arc_sums.arcstat_l2_evict_lock_retry); as->arcstat_l2_evict_reading.value.ui64 = wmsum_value(&arc_sums.arcstat_l2_evict_reading); as->arcstat_l2_evict_l1cached.value.ui64 = wmsum_value(&arc_sums.arcstat_l2_evict_l1cached); as->arcstat_l2_free_on_write.value.ui64 = wmsum_value(&arc_sums.arcstat_l2_free_on_write); as->arcstat_l2_abort_lowmem.value.ui64 = wmsum_value(&arc_sums.arcstat_l2_abort_lowmem); as->arcstat_l2_cksum_bad.value.ui64 = wmsum_value(&arc_sums.arcstat_l2_cksum_bad); as->arcstat_l2_io_error.value.ui64 = wmsum_value(&arc_sums.arcstat_l2_io_error); as->arcstat_l2_lsize.value.ui64 = wmsum_value(&arc_sums.arcstat_l2_lsize); as->arcstat_l2_psize.value.ui64 = wmsum_value(&arc_sums.arcstat_l2_psize); as->arcstat_l2_hdr_size.value.ui64 = aggsum_value(&arc_sums.arcstat_l2_hdr_size); as->arcstat_l2_log_blk_writes.value.ui64 = wmsum_value(&arc_sums.arcstat_l2_log_blk_writes); as->arcstat_l2_log_blk_asize.value.ui64 = wmsum_value(&arc_sums.arcstat_l2_log_blk_asize); as->arcstat_l2_log_blk_count.value.ui64 = wmsum_value(&arc_sums.arcstat_l2_log_blk_count); as->arcstat_l2_rebuild_success.value.ui64 = wmsum_value(&arc_sums.arcstat_l2_rebuild_success); as->arcstat_l2_rebuild_abort_unsupported.value.ui64 = wmsum_value(&arc_sums.arcstat_l2_rebuild_abort_unsupported); as->arcstat_l2_rebuild_abort_io_errors.value.ui64 = wmsum_value(&arc_sums.arcstat_l2_rebuild_abort_io_errors); as->arcstat_l2_rebuild_abort_dh_errors.value.ui64 = wmsum_value(&arc_sums.arcstat_l2_rebuild_abort_dh_errors); as->arcstat_l2_rebuild_abort_cksum_lb_errors.value.ui64 = wmsum_value(&arc_sums.arcstat_l2_rebuild_abort_cksum_lb_errors); as->arcstat_l2_rebuild_abort_lowmem.value.ui64 = wmsum_value(&arc_sums.arcstat_l2_rebuild_abort_lowmem); as->arcstat_l2_rebuild_size.value.ui64 = wmsum_value(&arc_sums.arcstat_l2_rebuild_size); as->arcstat_l2_rebuild_asize.value.ui64 = wmsum_value(&arc_sums.arcstat_l2_rebuild_asize); as->arcstat_l2_rebuild_bufs.value.ui64 = wmsum_value(&arc_sums.arcstat_l2_rebuild_bufs); as->arcstat_l2_rebuild_bufs_precached.value.ui64 = wmsum_value(&arc_sums.arcstat_l2_rebuild_bufs_precached); as->arcstat_l2_rebuild_log_blks.value.ui64 = wmsum_value(&arc_sums.arcstat_l2_rebuild_log_blks); as->arcstat_memory_throttle_count.value.ui64 = wmsum_value(&arc_sums.arcstat_memory_throttle_count); as->arcstat_memory_direct_count.value.ui64 = wmsum_value(&arc_sums.arcstat_memory_direct_count); as->arcstat_memory_indirect_count.value.ui64 = wmsum_value(&arc_sums.arcstat_memory_indirect_count); as->arcstat_memory_all_bytes.value.ui64 = arc_all_memory(); as->arcstat_memory_free_bytes.value.ui64 = arc_free_memory(); as->arcstat_memory_available_bytes.value.i64 = arc_available_memory(); as->arcstat_prune.value.ui64 = wmsum_value(&arc_sums.arcstat_prune); as->arcstat_meta_used.value.ui64 = wmsum_value(&arc_sums.arcstat_meta_used); as->arcstat_async_upgrade_sync.value.ui64 = wmsum_value(&arc_sums.arcstat_async_upgrade_sync); as->arcstat_predictive_prefetch.value.ui64 = wmsum_value(&arc_sums.arcstat_predictive_prefetch); as->arcstat_demand_hit_predictive_prefetch.value.ui64 = wmsum_value(&arc_sums.arcstat_demand_hit_predictive_prefetch); as->arcstat_demand_iohit_predictive_prefetch.value.ui64 = wmsum_value(&arc_sums.arcstat_demand_iohit_predictive_prefetch); as->arcstat_prescient_prefetch.value.ui64 = wmsum_value(&arc_sums.arcstat_prescient_prefetch); as->arcstat_demand_hit_prescient_prefetch.value.ui64 = wmsum_value(&arc_sums.arcstat_demand_hit_prescient_prefetch); as->arcstat_demand_iohit_prescient_prefetch.value.ui64 = wmsum_value(&arc_sums.arcstat_demand_iohit_prescient_prefetch); as->arcstat_raw_size.value.ui64 = wmsum_value(&arc_sums.arcstat_raw_size); as->arcstat_cached_only_in_progress.value.ui64 = wmsum_value(&arc_sums.arcstat_cached_only_in_progress); as->arcstat_abd_chunk_waste_size.value.ui64 = wmsum_value(&arc_sums.arcstat_abd_chunk_waste_size); return (0); } /* * This function *must* return indices evenly distributed between all * sublists of the multilist. This is needed due to how the ARC eviction * code is laid out; arc_evict_state() assumes ARC buffers are evenly * distributed between all sublists and uses this assumption when * deciding which sublist to evict from and how much to evict from it. */ static unsigned int arc_state_multilist_index_func(multilist_t *ml, void *obj) { arc_buf_hdr_t *hdr = obj; /* * We rely on b_dva to generate evenly distributed index * numbers using buf_hash below. So, as an added precaution, * let's make sure we never add empty buffers to the arc lists. */ ASSERT(!HDR_EMPTY(hdr)); /* * The assumption here, is the hash value for a given * arc_buf_hdr_t will remain constant throughout its lifetime * (i.e. its b_spa, b_dva, and b_birth fields don't change). * Thus, we don't need to store the header's sublist index * on insertion, as this index can be recalculated on removal. * * Also, the low order bits of the hash value are thought to be * distributed evenly. Otherwise, in the case that the multilist * has a power of two number of sublists, each sublists' usage * would not be evenly distributed. In this context full 64bit * division would be a waste of time, so limit it to 32 bits. */ return ((unsigned int)buf_hash(hdr->b_spa, &hdr->b_dva, hdr->b_birth) % multilist_get_num_sublists(ml)); } static unsigned int arc_state_l2c_multilist_index_func(multilist_t *ml, void *obj) { panic("Header %p insert into arc_l2c_only %p", obj, ml); } #define WARN_IF_TUNING_IGNORED(tuning, value, do_warn) do { \ if ((do_warn) && (tuning) && ((tuning) != (value))) { \ cmn_err(CE_WARN, \ "ignoring tunable %s (using %llu instead)", \ (#tuning), (u_longlong_t)(value)); \ } \ } while (0) /* * Called during module initialization and periodically thereafter to * apply reasonable changes to the exposed performance tunings. Can also be * called explicitly by param_set_arc_*() functions when ARC tunables are * updated manually. Non-zero zfs_* values which differ from the currently set * values will be applied. */ void arc_tuning_update(boolean_t verbose) { uint64_t allmem = arc_all_memory(); /* Valid range: 32M - */ if ((zfs_arc_min) && (zfs_arc_min != arc_c_min) && (zfs_arc_min >= 2ULL << SPA_MAXBLOCKSHIFT) && (zfs_arc_min <= arc_c_max)) { arc_c_min = zfs_arc_min; arc_c = MAX(arc_c, arc_c_min); } WARN_IF_TUNING_IGNORED(zfs_arc_min, arc_c_min, verbose); /* Valid range: 64M - */ if ((zfs_arc_max) && (zfs_arc_max != arc_c_max) && (zfs_arc_max >= MIN_ARC_MAX) && (zfs_arc_max < allmem) && (zfs_arc_max > arc_c_min)) { arc_c_max = zfs_arc_max; arc_c = MIN(arc_c, arc_c_max); if (arc_dnode_limit > arc_c_max) arc_dnode_limit = arc_c_max; } WARN_IF_TUNING_IGNORED(zfs_arc_max, arc_c_max, verbose); /* Valid range: 0 - */ arc_dnode_limit = zfs_arc_dnode_limit ? zfs_arc_dnode_limit : MIN(zfs_arc_dnode_limit_percent, 100) * arc_c_max / 100; WARN_IF_TUNING_IGNORED(zfs_arc_dnode_limit, arc_dnode_limit, verbose); /* Valid range: 1 - N */ if (zfs_arc_grow_retry) arc_grow_retry = zfs_arc_grow_retry; /* Valid range: 1 - N */ if (zfs_arc_shrink_shift) { arc_shrink_shift = zfs_arc_shrink_shift; arc_no_grow_shift = MIN(arc_no_grow_shift, arc_shrink_shift -1); } /* Valid range: 1 - N ms */ if (zfs_arc_min_prefetch_ms) arc_min_prefetch_ms = zfs_arc_min_prefetch_ms; /* Valid range: 1 - N ms */ if (zfs_arc_min_prescient_prefetch_ms) { arc_min_prescient_prefetch_ms = zfs_arc_min_prescient_prefetch_ms; } /* Valid range: 0 - 100 */ if (zfs_arc_lotsfree_percent <= 100) arc_lotsfree_percent = zfs_arc_lotsfree_percent; WARN_IF_TUNING_IGNORED(zfs_arc_lotsfree_percent, arc_lotsfree_percent, verbose); /* Valid range: 0 - */ if ((zfs_arc_sys_free) && (zfs_arc_sys_free != arc_sys_free)) arc_sys_free = MIN(zfs_arc_sys_free, allmem); WARN_IF_TUNING_IGNORED(zfs_arc_sys_free, arc_sys_free, verbose); } static void arc_state_multilist_init(multilist_t *ml, multilist_sublist_index_func_t *index_func, int *maxcountp) { multilist_create(ml, sizeof (arc_buf_hdr_t), offsetof(arc_buf_hdr_t, b_l1hdr.b_arc_node), index_func); *maxcountp = MAX(*maxcountp, multilist_get_num_sublists(ml)); } static void arc_state_init(void) { int num_sublists = 0; arc_state_multilist_init(&arc_mru->arcs_list[ARC_BUFC_METADATA], arc_state_multilist_index_func, &num_sublists); arc_state_multilist_init(&arc_mru->arcs_list[ARC_BUFC_DATA], arc_state_multilist_index_func, &num_sublists); arc_state_multilist_init(&arc_mru_ghost->arcs_list[ARC_BUFC_METADATA], arc_state_multilist_index_func, &num_sublists); arc_state_multilist_init(&arc_mru_ghost->arcs_list[ARC_BUFC_DATA], arc_state_multilist_index_func, &num_sublists); arc_state_multilist_init(&arc_mfu->arcs_list[ARC_BUFC_METADATA], arc_state_multilist_index_func, &num_sublists); arc_state_multilist_init(&arc_mfu->arcs_list[ARC_BUFC_DATA], arc_state_multilist_index_func, &num_sublists); arc_state_multilist_init(&arc_mfu_ghost->arcs_list[ARC_BUFC_METADATA], arc_state_multilist_index_func, &num_sublists); arc_state_multilist_init(&arc_mfu_ghost->arcs_list[ARC_BUFC_DATA], arc_state_multilist_index_func, &num_sublists); arc_state_multilist_init(&arc_uncached->arcs_list[ARC_BUFC_METADATA], arc_state_multilist_index_func, &num_sublists); arc_state_multilist_init(&arc_uncached->arcs_list[ARC_BUFC_DATA], arc_state_multilist_index_func, &num_sublists); /* * L2 headers should never be on the L2 state list since they don't * have L1 headers allocated. Special index function asserts that. */ arc_state_multilist_init(&arc_l2c_only->arcs_list[ARC_BUFC_METADATA], arc_state_l2c_multilist_index_func, &num_sublists); arc_state_multilist_init(&arc_l2c_only->arcs_list[ARC_BUFC_DATA], arc_state_l2c_multilist_index_func, &num_sublists); /* * Keep track of the number of markers needed to reclaim buffers from * any ARC state. The markers will be pre-allocated so as to minimize * the number of memory allocations performed by the eviction thread. */ arc_state_evict_marker_count = num_sublists; zfs_refcount_create(&arc_anon->arcs_esize[ARC_BUFC_METADATA]); zfs_refcount_create(&arc_anon->arcs_esize[ARC_BUFC_DATA]); zfs_refcount_create(&arc_mru->arcs_esize[ARC_BUFC_METADATA]); zfs_refcount_create(&arc_mru->arcs_esize[ARC_BUFC_DATA]); zfs_refcount_create(&arc_mru_ghost->arcs_esize[ARC_BUFC_METADATA]); zfs_refcount_create(&arc_mru_ghost->arcs_esize[ARC_BUFC_DATA]); zfs_refcount_create(&arc_mfu->arcs_esize[ARC_BUFC_METADATA]); zfs_refcount_create(&arc_mfu->arcs_esize[ARC_BUFC_DATA]); zfs_refcount_create(&arc_mfu_ghost->arcs_esize[ARC_BUFC_METADATA]); zfs_refcount_create(&arc_mfu_ghost->arcs_esize[ARC_BUFC_DATA]); zfs_refcount_create(&arc_l2c_only->arcs_esize[ARC_BUFC_METADATA]); zfs_refcount_create(&arc_l2c_only->arcs_esize[ARC_BUFC_DATA]); zfs_refcount_create(&arc_uncached->arcs_esize[ARC_BUFC_METADATA]); zfs_refcount_create(&arc_uncached->arcs_esize[ARC_BUFC_DATA]); zfs_refcount_create(&arc_anon->arcs_size[ARC_BUFC_DATA]); zfs_refcount_create(&arc_anon->arcs_size[ARC_BUFC_METADATA]); zfs_refcount_create(&arc_mru->arcs_size[ARC_BUFC_DATA]); zfs_refcount_create(&arc_mru->arcs_size[ARC_BUFC_METADATA]); zfs_refcount_create(&arc_mru_ghost->arcs_size[ARC_BUFC_DATA]); zfs_refcount_create(&arc_mru_ghost->arcs_size[ARC_BUFC_METADATA]); zfs_refcount_create(&arc_mfu->arcs_size[ARC_BUFC_DATA]); zfs_refcount_create(&arc_mfu->arcs_size[ARC_BUFC_METADATA]); zfs_refcount_create(&arc_mfu_ghost->arcs_size[ARC_BUFC_DATA]); zfs_refcount_create(&arc_mfu_ghost->arcs_size[ARC_BUFC_METADATA]); zfs_refcount_create(&arc_l2c_only->arcs_size[ARC_BUFC_DATA]); zfs_refcount_create(&arc_l2c_only->arcs_size[ARC_BUFC_METADATA]); zfs_refcount_create(&arc_uncached->arcs_size[ARC_BUFC_DATA]); zfs_refcount_create(&arc_uncached->arcs_size[ARC_BUFC_METADATA]); wmsum_init(&arc_mru_ghost->arcs_hits[ARC_BUFC_DATA], 0); wmsum_init(&arc_mru_ghost->arcs_hits[ARC_BUFC_METADATA], 0); wmsum_init(&arc_mfu_ghost->arcs_hits[ARC_BUFC_DATA], 0); wmsum_init(&arc_mfu_ghost->arcs_hits[ARC_BUFC_METADATA], 0); wmsum_init(&arc_sums.arcstat_hits, 0); wmsum_init(&arc_sums.arcstat_iohits, 0); wmsum_init(&arc_sums.arcstat_misses, 0); wmsum_init(&arc_sums.arcstat_demand_data_hits, 0); wmsum_init(&arc_sums.arcstat_demand_data_iohits, 0); wmsum_init(&arc_sums.arcstat_demand_data_misses, 0); wmsum_init(&arc_sums.arcstat_demand_metadata_hits, 0); wmsum_init(&arc_sums.arcstat_demand_metadata_iohits, 0); wmsum_init(&arc_sums.arcstat_demand_metadata_misses, 0); wmsum_init(&arc_sums.arcstat_prefetch_data_hits, 0); wmsum_init(&arc_sums.arcstat_prefetch_data_iohits, 0); wmsum_init(&arc_sums.arcstat_prefetch_data_misses, 0); wmsum_init(&arc_sums.arcstat_prefetch_metadata_hits, 0); wmsum_init(&arc_sums.arcstat_prefetch_metadata_iohits, 0); wmsum_init(&arc_sums.arcstat_prefetch_metadata_misses, 0); wmsum_init(&arc_sums.arcstat_mru_hits, 0); wmsum_init(&arc_sums.arcstat_mru_ghost_hits, 0); wmsum_init(&arc_sums.arcstat_mfu_hits, 0); wmsum_init(&arc_sums.arcstat_mfu_ghost_hits, 0); wmsum_init(&arc_sums.arcstat_uncached_hits, 0); wmsum_init(&arc_sums.arcstat_deleted, 0); wmsum_init(&arc_sums.arcstat_mutex_miss, 0); wmsum_init(&arc_sums.arcstat_access_skip, 0); wmsum_init(&arc_sums.arcstat_evict_skip, 0); wmsum_init(&arc_sums.arcstat_evict_not_enough, 0); wmsum_init(&arc_sums.arcstat_evict_l2_cached, 0); wmsum_init(&arc_sums.arcstat_evict_l2_eligible, 0); wmsum_init(&arc_sums.arcstat_evict_l2_eligible_mfu, 0); wmsum_init(&arc_sums.arcstat_evict_l2_eligible_mru, 0); wmsum_init(&arc_sums.arcstat_evict_l2_ineligible, 0); wmsum_init(&arc_sums.arcstat_evict_l2_skip, 0); wmsum_init(&arc_sums.arcstat_hash_collisions, 0); wmsum_init(&arc_sums.arcstat_hash_chains, 0); aggsum_init(&arc_sums.arcstat_size, 0); wmsum_init(&arc_sums.arcstat_compressed_size, 0); wmsum_init(&arc_sums.arcstat_uncompressed_size, 0); wmsum_init(&arc_sums.arcstat_overhead_size, 0); wmsum_init(&arc_sums.arcstat_hdr_size, 0); wmsum_init(&arc_sums.arcstat_data_size, 0); wmsum_init(&arc_sums.arcstat_metadata_size, 0); wmsum_init(&arc_sums.arcstat_dbuf_size, 0); wmsum_init(&arc_sums.arcstat_dnode_size, 0); wmsum_init(&arc_sums.arcstat_bonus_size, 0); wmsum_init(&arc_sums.arcstat_l2_hits, 0); wmsum_init(&arc_sums.arcstat_l2_misses, 0); wmsum_init(&arc_sums.arcstat_l2_prefetch_asize, 0); wmsum_init(&arc_sums.arcstat_l2_mru_asize, 0); wmsum_init(&arc_sums.arcstat_l2_mfu_asize, 0); wmsum_init(&arc_sums.arcstat_l2_bufc_data_asize, 0); wmsum_init(&arc_sums.arcstat_l2_bufc_metadata_asize, 0); wmsum_init(&arc_sums.arcstat_l2_feeds, 0); wmsum_init(&arc_sums.arcstat_l2_rw_clash, 0); wmsum_init(&arc_sums.arcstat_l2_read_bytes, 0); wmsum_init(&arc_sums.arcstat_l2_write_bytes, 0); wmsum_init(&arc_sums.arcstat_l2_writes_sent, 0); wmsum_init(&arc_sums.arcstat_l2_writes_done, 0); wmsum_init(&arc_sums.arcstat_l2_writes_error, 0); wmsum_init(&arc_sums.arcstat_l2_writes_lock_retry, 0); wmsum_init(&arc_sums.arcstat_l2_evict_lock_retry, 0); wmsum_init(&arc_sums.arcstat_l2_evict_reading, 0); wmsum_init(&arc_sums.arcstat_l2_evict_l1cached, 0); wmsum_init(&arc_sums.arcstat_l2_free_on_write, 0); wmsum_init(&arc_sums.arcstat_l2_abort_lowmem, 0); wmsum_init(&arc_sums.arcstat_l2_cksum_bad, 0); wmsum_init(&arc_sums.arcstat_l2_io_error, 0); wmsum_init(&arc_sums.arcstat_l2_lsize, 0); wmsum_init(&arc_sums.arcstat_l2_psize, 0); aggsum_init(&arc_sums.arcstat_l2_hdr_size, 0); wmsum_init(&arc_sums.arcstat_l2_log_blk_writes, 0); wmsum_init(&arc_sums.arcstat_l2_log_blk_asize, 0); wmsum_init(&arc_sums.arcstat_l2_log_blk_count, 0); wmsum_init(&arc_sums.arcstat_l2_rebuild_success, 0); wmsum_init(&arc_sums.arcstat_l2_rebuild_abort_unsupported, 0); wmsum_init(&arc_sums.arcstat_l2_rebuild_abort_io_errors, 0); wmsum_init(&arc_sums.arcstat_l2_rebuild_abort_dh_errors, 0); wmsum_init(&arc_sums.arcstat_l2_rebuild_abort_cksum_lb_errors, 0); wmsum_init(&arc_sums.arcstat_l2_rebuild_abort_lowmem, 0); wmsum_init(&arc_sums.arcstat_l2_rebuild_size, 0); wmsum_init(&arc_sums.arcstat_l2_rebuild_asize, 0); wmsum_init(&arc_sums.arcstat_l2_rebuild_bufs, 0); wmsum_init(&arc_sums.arcstat_l2_rebuild_bufs_precached, 0); wmsum_init(&arc_sums.arcstat_l2_rebuild_log_blks, 0); wmsum_init(&arc_sums.arcstat_memory_throttle_count, 0); wmsum_init(&arc_sums.arcstat_memory_direct_count, 0); wmsum_init(&arc_sums.arcstat_memory_indirect_count, 0); wmsum_init(&arc_sums.arcstat_prune, 0); wmsum_init(&arc_sums.arcstat_meta_used, 0); wmsum_init(&arc_sums.arcstat_async_upgrade_sync, 0); wmsum_init(&arc_sums.arcstat_predictive_prefetch, 0); wmsum_init(&arc_sums.arcstat_demand_hit_predictive_prefetch, 0); wmsum_init(&arc_sums.arcstat_demand_iohit_predictive_prefetch, 0); wmsum_init(&arc_sums.arcstat_prescient_prefetch, 0); wmsum_init(&arc_sums.arcstat_demand_hit_prescient_prefetch, 0); wmsum_init(&arc_sums.arcstat_demand_iohit_prescient_prefetch, 0); wmsum_init(&arc_sums.arcstat_raw_size, 0); wmsum_init(&arc_sums.arcstat_cached_only_in_progress, 0); wmsum_init(&arc_sums.arcstat_abd_chunk_waste_size, 0); arc_anon->arcs_state = ARC_STATE_ANON; arc_mru->arcs_state = ARC_STATE_MRU; arc_mru_ghost->arcs_state = ARC_STATE_MRU_GHOST; arc_mfu->arcs_state = ARC_STATE_MFU; arc_mfu_ghost->arcs_state = ARC_STATE_MFU_GHOST; arc_l2c_only->arcs_state = ARC_STATE_L2C_ONLY; arc_uncached->arcs_state = ARC_STATE_UNCACHED; } static void arc_state_fini(void) { zfs_refcount_destroy(&arc_anon->arcs_esize[ARC_BUFC_METADATA]); zfs_refcount_destroy(&arc_anon->arcs_esize[ARC_BUFC_DATA]); zfs_refcount_destroy(&arc_mru->arcs_esize[ARC_BUFC_METADATA]); zfs_refcount_destroy(&arc_mru->arcs_esize[ARC_BUFC_DATA]); zfs_refcount_destroy(&arc_mru_ghost->arcs_esize[ARC_BUFC_METADATA]); zfs_refcount_destroy(&arc_mru_ghost->arcs_esize[ARC_BUFC_DATA]); zfs_refcount_destroy(&arc_mfu->arcs_esize[ARC_BUFC_METADATA]); zfs_refcount_destroy(&arc_mfu->arcs_esize[ARC_BUFC_DATA]); zfs_refcount_destroy(&arc_mfu_ghost->arcs_esize[ARC_BUFC_METADATA]); zfs_refcount_destroy(&arc_mfu_ghost->arcs_esize[ARC_BUFC_DATA]); zfs_refcount_destroy(&arc_l2c_only->arcs_esize[ARC_BUFC_METADATA]); zfs_refcount_destroy(&arc_l2c_only->arcs_esize[ARC_BUFC_DATA]); zfs_refcount_destroy(&arc_uncached->arcs_esize[ARC_BUFC_METADATA]); zfs_refcount_destroy(&arc_uncached->arcs_esize[ARC_BUFC_DATA]); zfs_refcount_destroy(&arc_anon->arcs_size[ARC_BUFC_DATA]); zfs_refcount_destroy(&arc_anon->arcs_size[ARC_BUFC_METADATA]); zfs_refcount_destroy(&arc_mru->arcs_size[ARC_BUFC_DATA]); zfs_refcount_destroy(&arc_mru->arcs_size[ARC_BUFC_METADATA]); zfs_refcount_destroy(&arc_mru_ghost->arcs_size[ARC_BUFC_DATA]); zfs_refcount_destroy(&arc_mru_ghost->arcs_size[ARC_BUFC_METADATA]); zfs_refcount_destroy(&arc_mfu->arcs_size[ARC_BUFC_DATA]); zfs_refcount_destroy(&arc_mfu->arcs_size[ARC_BUFC_METADATA]); zfs_refcount_destroy(&arc_mfu_ghost->arcs_size[ARC_BUFC_DATA]); zfs_refcount_destroy(&arc_mfu_ghost->arcs_size[ARC_BUFC_METADATA]); zfs_refcount_destroy(&arc_l2c_only->arcs_size[ARC_BUFC_DATA]); zfs_refcount_destroy(&arc_l2c_only->arcs_size[ARC_BUFC_METADATA]); zfs_refcount_destroy(&arc_uncached->arcs_size[ARC_BUFC_DATA]); zfs_refcount_destroy(&arc_uncached->arcs_size[ARC_BUFC_METADATA]); multilist_destroy(&arc_mru->arcs_list[ARC_BUFC_METADATA]); multilist_destroy(&arc_mru_ghost->arcs_list[ARC_BUFC_METADATA]); multilist_destroy(&arc_mfu->arcs_list[ARC_BUFC_METADATA]); multilist_destroy(&arc_mfu_ghost->arcs_list[ARC_BUFC_METADATA]); multilist_destroy(&arc_mru->arcs_list[ARC_BUFC_DATA]); multilist_destroy(&arc_mru_ghost->arcs_list[ARC_BUFC_DATA]); multilist_destroy(&arc_mfu->arcs_list[ARC_BUFC_DATA]); multilist_destroy(&arc_mfu_ghost->arcs_list[ARC_BUFC_DATA]); multilist_destroy(&arc_l2c_only->arcs_list[ARC_BUFC_METADATA]); multilist_destroy(&arc_l2c_only->arcs_list[ARC_BUFC_DATA]); multilist_destroy(&arc_uncached->arcs_list[ARC_BUFC_METADATA]); multilist_destroy(&arc_uncached->arcs_list[ARC_BUFC_DATA]); wmsum_fini(&arc_mru_ghost->arcs_hits[ARC_BUFC_DATA]); wmsum_fini(&arc_mru_ghost->arcs_hits[ARC_BUFC_METADATA]); wmsum_fini(&arc_mfu_ghost->arcs_hits[ARC_BUFC_DATA]); wmsum_fini(&arc_mfu_ghost->arcs_hits[ARC_BUFC_METADATA]); wmsum_fini(&arc_sums.arcstat_hits); wmsum_fini(&arc_sums.arcstat_iohits); wmsum_fini(&arc_sums.arcstat_misses); wmsum_fini(&arc_sums.arcstat_demand_data_hits); wmsum_fini(&arc_sums.arcstat_demand_data_iohits); wmsum_fini(&arc_sums.arcstat_demand_data_misses); wmsum_fini(&arc_sums.arcstat_demand_metadata_hits); wmsum_fini(&arc_sums.arcstat_demand_metadata_iohits); wmsum_fini(&arc_sums.arcstat_demand_metadata_misses); wmsum_fini(&arc_sums.arcstat_prefetch_data_hits); wmsum_fini(&arc_sums.arcstat_prefetch_data_iohits); wmsum_fini(&arc_sums.arcstat_prefetch_data_misses); wmsum_fini(&arc_sums.arcstat_prefetch_metadata_hits); wmsum_fini(&arc_sums.arcstat_prefetch_metadata_iohits); wmsum_fini(&arc_sums.arcstat_prefetch_metadata_misses); wmsum_fini(&arc_sums.arcstat_mru_hits); wmsum_fini(&arc_sums.arcstat_mru_ghost_hits); wmsum_fini(&arc_sums.arcstat_mfu_hits); wmsum_fini(&arc_sums.arcstat_mfu_ghost_hits); wmsum_fini(&arc_sums.arcstat_uncached_hits); wmsum_fini(&arc_sums.arcstat_deleted); wmsum_fini(&arc_sums.arcstat_mutex_miss); wmsum_fini(&arc_sums.arcstat_access_skip); wmsum_fini(&arc_sums.arcstat_evict_skip); wmsum_fini(&arc_sums.arcstat_evict_not_enough); wmsum_fini(&arc_sums.arcstat_evict_l2_cached); wmsum_fini(&arc_sums.arcstat_evict_l2_eligible); wmsum_fini(&arc_sums.arcstat_evict_l2_eligible_mfu); wmsum_fini(&arc_sums.arcstat_evict_l2_eligible_mru); wmsum_fini(&arc_sums.arcstat_evict_l2_ineligible); wmsum_fini(&arc_sums.arcstat_evict_l2_skip); wmsum_fini(&arc_sums.arcstat_hash_collisions); wmsum_fini(&arc_sums.arcstat_hash_chains); aggsum_fini(&arc_sums.arcstat_size); wmsum_fini(&arc_sums.arcstat_compressed_size); wmsum_fini(&arc_sums.arcstat_uncompressed_size); wmsum_fini(&arc_sums.arcstat_overhead_size); wmsum_fini(&arc_sums.arcstat_hdr_size); wmsum_fini(&arc_sums.arcstat_data_size); wmsum_fini(&arc_sums.arcstat_metadata_size); wmsum_fini(&arc_sums.arcstat_dbuf_size); wmsum_fini(&arc_sums.arcstat_dnode_size); wmsum_fini(&arc_sums.arcstat_bonus_size); wmsum_fini(&arc_sums.arcstat_l2_hits); wmsum_fini(&arc_sums.arcstat_l2_misses); wmsum_fini(&arc_sums.arcstat_l2_prefetch_asize); wmsum_fini(&arc_sums.arcstat_l2_mru_asize); wmsum_fini(&arc_sums.arcstat_l2_mfu_asize); wmsum_fini(&arc_sums.arcstat_l2_bufc_data_asize); wmsum_fini(&arc_sums.arcstat_l2_bufc_metadata_asize); wmsum_fini(&arc_sums.arcstat_l2_feeds); wmsum_fini(&arc_sums.arcstat_l2_rw_clash); wmsum_fini(&arc_sums.arcstat_l2_read_bytes); wmsum_fini(&arc_sums.arcstat_l2_write_bytes); wmsum_fini(&arc_sums.arcstat_l2_writes_sent); wmsum_fini(&arc_sums.arcstat_l2_writes_done); wmsum_fini(&arc_sums.arcstat_l2_writes_error); wmsum_fini(&arc_sums.arcstat_l2_writes_lock_retry); wmsum_fini(&arc_sums.arcstat_l2_evict_lock_retry); wmsum_fini(&arc_sums.arcstat_l2_evict_reading); wmsum_fini(&arc_sums.arcstat_l2_evict_l1cached); wmsum_fini(&arc_sums.arcstat_l2_free_on_write); wmsum_fini(&arc_sums.arcstat_l2_abort_lowmem); wmsum_fini(&arc_sums.arcstat_l2_cksum_bad); wmsum_fini(&arc_sums.arcstat_l2_io_error); wmsum_fini(&arc_sums.arcstat_l2_lsize); wmsum_fini(&arc_sums.arcstat_l2_psize); aggsum_fini(&arc_sums.arcstat_l2_hdr_size); wmsum_fini(&arc_sums.arcstat_l2_log_blk_writes); wmsum_fini(&arc_sums.arcstat_l2_log_blk_asize); wmsum_fini(&arc_sums.arcstat_l2_log_blk_count); wmsum_fini(&arc_sums.arcstat_l2_rebuild_success); wmsum_fini(&arc_sums.arcstat_l2_rebuild_abort_unsupported); wmsum_fini(&arc_sums.arcstat_l2_rebuild_abort_io_errors); wmsum_fini(&arc_sums.arcstat_l2_rebuild_abort_dh_errors); wmsum_fini(&arc_sums.arcstat_l2_rebuild_abort_cksum_lb_errors); wmsum_fini(&arc_sums.arcstat_l2_rebuild_abort_lowmem); wmsum_fini(&arc_sums.arcstat_l2_rebuild_size); wmsum_fini(&arc_sums.arcstat_l2_rebuild_asize); wmsum_fini(&arc_sums.arcstat_l2_rebuild_bufs); wmsum_fini(&arc_sums.arcstat_l2_rebuild_bufs_precached); wmsum_fini(&arc_sums.arcstat_l2_rebuild_log_blks); wmsum_fini(&arc_sums.arcstat_memory_throttle_count); wmsum_fini(&arc_sums.arcstat_memory_direct_count); wmsum_fini(&arc_sums.arcstat_memory_indirect_count); wmsum_fini(&arc_sums.arcstat_prune); wmsum_fini(&arc_sums.arcstat_meta_used); wmsum_fini(&arc_sums.arcstat_async_upgrade_sync); wmsum_fini(&arc_sums.arcstat_predictive_prefetch); wmsum_fini(&arc_sums.arcstat_demand_hit_predictive_prefetch); wmsum_fini(&arc_sums.arcstat_demand_iohit_predictive_prefetch); wmsum_fini(&arc_sums.arcstat_prescient_prefetch); wmsum_fini(&arc_sums.arcstat_demand_hit_prescient_prefetch); wmsum_fini(&arc_sums.arcstat_demand_iohit_prescient_prefetch); wmsum_fini(&arc_sums.arcstat_raw_size); wmsum_fini(&arc_sums.arcstat_cached_only_in_progress); wmsum_fini(&arc_sums.arcstat_abd_chunk_waste_size); } uint64_t arc_target_bytes(void) { return (arc_c); } void arc_set_limits(uint64_t allmem) { /* Set min cache to 1/32 of all memory, or 32MB, whichever is more. */ arc_c_min = MAX(allmem / 32, 2ULL << SPA_MAXBLOCKSHIFT); /* How to set default max varies by platform. */ arc_c_max = arc_default_max(arc_c_min, allmem); } void arc_init(void) { uint64_t percent, allmem = arc_all_memory(); mutex_init(&arc_evict_lock, NULL, MUTEX_DEFAULT, NULL); list_create(&arc_evict_waiters, sizeof (arc_evict_waiter_t), offsetof(arc_evict_waiter_t, aew_node)); arc_min_prefetch_ms = 1000; arc_min_prescient_prefetch_ms = 6000; #if defined(_KERNEL) arc_lowmem_init(); #endif arc_set_limits(allmem); #ifdef _KERNEL /* * If zfs_arc_max is non-zero at init, meaning it was set in the kernel * environment before the module was loaded, don't block setting the * maximum because it is less than arc_c_min, instead, reset arc_c_min * to a lower value. * zfs_arc_min will be handled by arc_tuning_update(). */ if (zfs_arc_max != 0 && zfs_arc_max >= MIN_ARC_MAX && zfs_arc_max < allmem) { arc_c_max = zfs_arc_max; if (arc_c_min >= arc_c_max) { arc_c_min = MAX(zfs_arc_max / 2, 2ULL << SPA_MAXBLOCKSHIFT); } } #else /* * In userland, there's only the memory pressure that we artificially * create (see arc_available_memory()). Don't let arc_c get too * small, because it can cause transactions to be larger than * arc_c, causing arc_tempreserve_space() to fail. */ arc_c_min = MAX(arc_c_max / 2, 2ULL << SPA_MAXBLOCKSHIFT); #endif arc_c = arc_c_min; /* * 32-bit fixed point fractions of metadata from total ARC size, * MRU data from all data and MRU metadata from all metadata. */ arc_meta = (1ULL << 32) / 4; /* Metadata is 25% of arc_c. */ arc_pd = (1ULL << 32) / 2; /* Data MRU is 50% of data. */ arc_pm = (1ULL << 32) / 2; /* Metadata MRU is 50% of metadata. */ percent = MIN(zfs_arc_dnode_limit_percent, 100); arc_dnode_limit = arc_c_max * percent / 100; /* Apply user specified tunings */ arc_tuning_update(B_TRUE); /* if kmem_flags are set, lets try to use less memory */ if (kmem_debugging()) arc_c = arc_c / 2; if (arc_c < arc_c_min) arc_c = arc_c_min; arc_register_hotplug(); arc_state_init(); buf_init(); list_create(&arc_prune_list, sizeof (arc_prune_t), offsetof(arc_prune_t, p_node)); mutex_init(&arc_prune_mtx, NULL, MUTEX_DEFAULT, NULL); arc_prune_taskq = taskq_create("arc_prune", zfs_arc_prune_task_threads, defclsyspri, 100, INT_MAX, TASKQ_PREPOPULATE | TASKQ_DYNAMIC); arc_ksp = kstat_create("zfs", 0, "arcstats", "misc", KSTAT_TYPE_NAMED, sizeof (arc_stats) / sizeof (kstat_named_t), KSTAT_FLAG_VIRTUAL); if (arc_ksp != NULL) { arc_ksp->ks_data = &arc_stats; arc_ksp->ks_update = arc_kstat_update; kstat_install(arc_ksp); } arc_state_evict_markers = arc_state_alloc_markers(arc_state_evict_marker_count); arc_evict_zthr = zthr_create_timer("arc_evict", arc_evict_cb_check, arc_evict_cb, NULL, SEC2NSEC(1), defclsyspri); arc_reap_zthr = zthr_create_timer("arc_reap", arc_reap_cb_check, arc_reap_cb, NULL, SEC2NSEC(1), minclsyspri); arc_warm = B_FALSE; /* * Calculate maximum amount of dirty data per pool. * * If it has been set by a module parameter, take that. * Otherwise, use a percentage of physical memory defined by * zfs_dirty_data_max_percent (default 10%) with a cap at * zfs_dirty_data_max_max (default 4G or 25% of physical memory). */ #ifdef __LP64__ if (zfs_dirty_data_max_max == 0) zfs_dirty_data_max_max = MIN(4ULL * 1024 * 1024 * 1024, allmem * zfs_dirty_data_max_max_percent / 100); #else if (zfs_dirty_data_max_max == 0) zfs_dirty_data_max_max = MIN(1ULL * 1024 * 1024 * 1024, allmem * zfs_dirty_data_max_max_percent / 100); #endif if (zfs_dirty_data_max == 0) { zfs_dirty_data_max = allmem * zfs_dirty_data_max_percent / 100; zfs_dirty_data_max = MIN(zfs_dirty_data_max, zfs_dirty_data_max_max); } if (zfs_wrlog_data_max == 0) { /* * dp_wrlog_total is reduced for each txg at the end of * spa_sync(). However, dp_dirty_total is reduced every time * a block is written out. Thus under normal operation, * dp_wrlog_total could grow 2 times as big as * zfs_dirty_data_max. */ zfs_wrlog_data_max = zfs_dirty_data_max * 2; } } void arc_fini(void) { arc_prune_t *p; #ifdef _KERNEL arc_lowmem_fini(); #endif /* _KERNEL */ /* Use B_TRUE to ensure *all* buffers are evicted */ arc_flush(NULL, B_TRUE); if (arc_ksp != NULL) { kstat_delete(arc_ksp); arc_ksp = NULL; } taskq_wait(arc_prune_taskq); taskq_destroy(arc_prune_taskq); mutex_enter(&arc_prune_mtx); while ((p = list_remove_head(&arc_prune_list)) != NULL) { zfs_refcount_remove(&p->p_refcnt, &arc_prune_list); zfs_refcount_destroy(&p->p_refcnt); kmem_free(p, sizeof (*p)); } mutex_exit(&arc_prune_mtx); list_destroy(&arc_prune_list); mutex_destroy(&arc_prune_mtx); (void) zthr_cancel(arc_evict_zthr); (void) zthr_cancel(arc_reap_zthr); arc_state_free_markers(arc_state_evict_markers, arc_state_evict_marker_count); mutex_destroy(&arc_evict_lock); list_destroy(&arc_evict_waiters); /* * Free any buffers that were tagged for destruction. This needs * to occur before arc_state_fini() runs and destroys the aggsum * values which are updated when freeing scatter ABDs. */ l2arc_do_free_on_write(); /* * buf_fini() must proceed arc_state_fini() because buf_fin() may * trigger the release of kmem magazines, which can callback to * arc_space_return() which accesses aggsums freed in act_state_fini(). */ buf_fini(); arc_state_fini(); arc_unregister_hotplug(); /* * We destroy the zthrs after all the ARC state has been * torn down to avoid the case of them receiving any * wakeup() signals after they are destroyed. */ zthr_destroy(arc_evict_zthr); zthr_destroy(arc_reap_zthr); ASSERT0(arc_loaned_bytes); } /* * Level 2 ARC * * The level 2 ARC (L2ARC) is a cache layer in-between main memory and disk. * It uses dedicated storage devices to hold cached data, which are populated * using large infrequent writes. The main role of this cache is to boost * the performance of random read workloads. The intended L2ARC devices * include short-stroked disks, solid state disks, and other media with * substantially faster read latency than disk. * * +-----------------------+ * | ARC | * +-----------------------+ * | ^ ^ * | | | * l2arc_feed_thread() arc_read() * | | | * | l2arc read | * V | | * +---------------+ | * | L2ARC | | * +---------------+ | * | ^ | * l2arc_write() | | * | | | * V | | * +-------+ +-------+ * | vdev | | vdev | * | cache | | cache | * +-------+ +-------+ * +=========+ .-----. * : L2ARC : |-_____-| * : devices : | Disks | * +=========+ `-_____-' * * Read requests are satisfied from the following sources, in order: * * 1) ARC * 2) vdev cache of L2ARC devices * 3) L2ARC devices * 4) vdev cache of disks * 5) disks * * Some L2ARC device types exhibit extremely slow write performance. * To accommodate for this there are some significant differences between * the L2ARC and traditional cache design: * * 1. There is no eviction path from the ARC to the L2ARC. Evictions from * the ARC behave as usual, freeing buffers and placing headers on ghost * lists. The ARC does not send buffers to the L2ARC during eviction as * this would add inflated write latencies for all ARC memory pressure. * * 2. The L2ARC attempts to cache data from the ARC before it is evicted. * It does this by periodically scanning buffers from the eviction-end of * the MFU and MRU ARC lists, copying them to the L2ARC devices if they are * not already there. It scans until a headroom of buffers is satisfied, * which itself is a buffer for ARC eviction. If a compressible buffer is * found during scanning and selected for writing to an L2ARC device, we * temporarily boost scanning headroom during the next scan cycle to make * sure we adapt to compression effects (which might significantly reduce * the data volume we write to L2ARC). The thread that does this is * l2arc_feed_thread(), illustrated below; example sizes are included to * provide a better sense of ratio than this diagram: * * head --> tail * +---------------------+----------+ * ARC_mfu |:::::#:::::::::::::::|o#o###o###|-->. # already on L2ARC * +---------------------+----------+ | o L2ARC eligible * ARC_mru |:#:::::::::::::::::::|#o#ooo####|-->| : ARC buffer * +---------------------+----------+ | * 15.9 Gbytes ^ 32 Mbytes | * headroom | * l2arc_feed_thread() * | * l2arc write hand <--[oooo]--' * | 8 Mbyte * | write max * V * +==============================+ * L2ARC dev |####|#|###|###| |####| ... | * +==============================+ * 32 Gbytes * * 3. If an ARC buffer is copied to the L2ARC but then hit instead of * evicted, then the L2ARC has cached a buffer much sooner than it probably * needed to, potentially wasting L2ARC device bandwidth and storage. It is * safe to say that this is an uncommon case, since buffers at the end of * the ARC lists have moved there due to inactivity. * * 4. If the ARC evicts faster than the L2ARC can maintain a headroom, * then the L2ARC simply misses copying some buffers. This serves as a * pressure valve to prevent heavy read workloads from both stalling the ARC * with waits and clogging the L2ARC with writes. This also helps prevent * the potential for the L2ARC to churn if it attempts to cache content too * quickly, such as during backups of the entire pool. * * 5. After system boot and before the ARC has filled main memory, there are * no evictions from the ARC and so the tails of the ARC_mfu and ARC_mru * lists can remain mostly static. Instead of searching from tail of these * lists as pictured, the l2arc_feed_thread() will search from the list heads * for eligible buffers, greatly increasing its chance of finding them. * * The L2ARC device write speed is also boosted during this time so that * the L2ARC warms up faster. Since there have been no ARC evictions yet, * there are no L2ARC reads, and no fear of degrading read performance * through increased writes. * * 6. Writes to the L2ARC devices are grouped and sent in-sequence, so that * the vdev queue can aggregate them into larger and fewer writes. Each * device is written to in a rotor fashion, sweeping writes through * available space then repeating. * * 7. The L2ARC does not store dirty content. It never needs to flush * write buffers back to disk based storage. * * 8. If an ARC buffer is written (and dirtied) which also exists in the * L2ARC, the now stale L2ARC buffer is immediately dropped. * * The performance of the L2ARC can be tweaked by a number of tunables, which * may be necessary for different workloads: * * l2arc_write_max max write bytes per interval * l2arc_write_boost extra write bytes during device warmup * l2arc_noprefetch skip caching prefetched buffers * l2arc_headroom number of max device writes to precache * l2arc_headroom_boost when we find compressed buffers during ARC * scanning, we multiply headroom by this * percentage factor for the next scan cycle, * since more compressed buffers are likely to * be present * l2arc_feed_secs seconds between L2ARC writing * * Tunables may be removed or added as future performance improvements are * integrated, and also may become zpool properties. * * There are three key functions that control how the L2ARC warms up: * * l2arc_write_eligible() check if a buffer is eligible to cache * l2arc_write_size() calculate how much to write * l2arc_write_interval() calculate sleep delay between writes * * These three functions determine what to write, how much, and how quickly * to send writes. * * L2ARC persistence: * * When writing buffers to L2ARC, we periodically add some metadata to * make sure we can pick them up after reboot, thus dramatically reducing * the impact that any downtime has on the performance of storage systems * with large caches. * * The implementation works fairly simply by integrating the following two * modifications: * * *) When writing to the L2ARC, we occasionally write a "l2arc log block", * which is an additional piece of metadata which describes what's been * written. This allows us to rebuild the arc_buf_hdr_t structures of the * main ARC buffers. There are 2 linked-lists of log blocks headed by * dh_start_lbps[2]. We alternate which chain we append to, so they are * time-wise and offset-wise interleaved, but that is an optimization rather * than for correctness. The log block also includes a pointer to the * previous block in its chain. * * *) We reserve SPA_MINBLOCKSIZE of space at the start of each L2ARC device * for our header bookkeeping purposes. This contains a device header, * which contains our top-level reference structures. We update it each * time we write a new log block, so that we're able to locate it in the * L2ARC device. If this write results in an inconsistent device header * (e.g. due to power failure), we detect this by verifying the header's * checksum and simply fail to reconstruct the L2ARC after reboot. * * Implementation diagram: * * +=== L2ARC device (not to scale) ======================================+ * | ___two newest log block pointers__.__________ | * | / \dh_start_lbps[1] | * | / \ \dh_start_lbps[0]| * |.___/__. V V | * ||L2 dev|....|lb |bufs |lb |bufs |lb |bufs |lb |bufs |lb |---(empty)---| * || hdr| ^ /^ /^ / / | * |+------+ ...--\-------/ \-----/--\------/ / | * | \--------------/ \--------------/ | * +======================================================================+ * * As can be seen on the diagram, rather than using a simple linked list, * we use a pair of linked lists with alternating elements. This is a * performance enhancement due to the fact that we only find out the * address of the next log block access once the current block has been * completely read in. Obviously, this hurts performance, because we'd be * keeping the device's I/O queue at only a 1 operation deep, thus * incurring a large amount of I/O round-trip latency. Having two lists * allows us to fetch two log blocks ahead of where we are currently * rebuilding L2ARC buffers. * * On-device data structures: * * L2ARC device header: l2arc_dev_hdr_phys_t * L2ARC log block: l2arc_log_blk_phys_t * * L2ARC reconstruction: * * When writing data, we simply write in the standard rotary fashion, * evicting buffers as we go and simply writing new data over them (writing * a new log block every now and then). This obviously means that once we * loop around the end of the device, we will start cutting into an already * committed log block (and its referenced data buffers), like so: * * current write head__ __old tail * \ / * V V * <--|bufs |lb |bufs |lb | |bufs |lb |bufs |lb |--> * ^ ^^^^^^^^^___________________________________ * | \ * <> may overwrite this blk and/or its bufs --' * * When importing the pool, we detect this situation and use it to stop * our scanning process (see l2arc_rebuild). * * There is one significant caveat to consider when rebuilding ARC contents * from an L2ARC device: what about invalidated buffers? Given the above * construction, we cannot update blocks which we've already written to amend * them to remove buffers which were invalidated. Thus, during reconstruction, * we might be populating the cache with buffers for data that's not on the * main pool anymore, or may have been overwritten! * * As it turns out, this isn't a problem. Every arc_read request includes * both the DVA and, crucially, the birth TXG of the BP the caller is * looking for. So even if the cache were populated by completely rotten * blocks for data that had been long deleted and/or overwritten, we'll * never actually return bad data from the cache, since the DVA with the * birth TXG uniquely identify a block in space and time - once created, * a block is immutable on disk. The worst thing we have done is wasted * some time and memory at l2arc rebuild to reconstruct outdated ARC * entries that will get dropped from the l2arc as it is being updated * with new blocks. * * L2ARC buffers that have been evicted by l2arc_evict() ahead of the write * hand are not restored. This is done by saving the offset (in bytes) * l2arc_evict() has evicted to in the L2ARC device header and taking it * into account when restoring buffers. */ static boolean_t l2arc_write_eligible(uint64_t spa_guid, arc_buf_hdr_t *hdr) { /* * A buffer is *not* eligible for the L2ARC if it: * 1. belongs to a different spa. * 2. is already cached on the L2ARC. * 3. has an I/O in progress (it may be an incomplete read). * 4. is flagged not eligible (zfs property). */ if (hdr->b_spa != spa_guid || HDR_HAS_L2HDR(hdr) || HDR_IO_IN_PROGRESS(hdr) || !HDR_L2CACHE(hdr)) return (B_FALSE); return (B_TRUE); } static uint64_t l2arc_write_size(l2arc_dev_t *dev) { uint64_t size; /* * Make sure our globals have meaningful values in case the user * altered them. */ size = l2arc_write_max; if (size == 0) { cmn_err(CE_NOTE, "Bad value for l2arc_write_max, value must " "be greater than zero, resetting it to the default (%d)", L2ARC_WRITE_SIZE); size = l2arc_write_max = L2ARC_WRITE_SIZE; } if (arc_warm == B_FALSE) size += l2arc_write_boost; /* We need to add in the worst case scenario of log block overhead. */ size += l2arc_log_blk_overhead(size, dev); if (dev->l2ad_vdev->vdev_has_trim && l2arc_trim_ahead > 0) { /* * Trim ahead of the write size 64MB or (l2arc_trim_ahead/100) * times the writesize, whichever is greater. */ size += MAX(64 * 1024 * 1024, (size * l2arc_trim_ahead) / 100); } /* * Make sure the write size does not exceed the size of the cache * device. This is important in l2arc_evict(), otherwise infinite * iteration can occur. */ if (size > dev->l2ad_end - dev->l2ad_start) { cmn_err(CE_NOTE, "l2arc_write_max or l2arc_write_boost " "plus the overhead of log blocks (persistent L2ARC, " "%llu bytes) exceeds the size of the cache device " "(guid %llu), resetting them to the default (%d)", (u_longlong_t)l2arc_log_blk_overhead(size, dev), (u_longlong_t)dev->l2ad_vdev->vdev_guid, L2ARC_WRITE_SIZE); size = l2arc_write_max = l2arc_write_boost = L2ARC_WRITE_SIZE; if (l2arc_trim_ahead > 1) { cmn_err(CE_NOTE, "l2arc_trim_ahead set to 1"); l2arc_trim_ahead = 1; } if (arc_warm == B_FALSE) size += l2arc_write_boost; size += l2arc_log_blk_overhead(size, dev); if (dev->l2ad_vdev->vdev_has_trim && l2arc_trim_ahead > 0) { size += MAX(64 * 1024 * 1024, (size * l2arc_trim_ahead) / 100); } } return (size); } static clock_t l2arc_write_interval(clock_t began, uint64_t wanted, uint64_t wrote) { clock_t interval, next, now; /* * If the ARC lists are busy, increase our write rate; if the * lists are stale, idle back. This is achieved by checking * how much we previously wrote - if it was more than half of * what we wanted, schedule the next write much sooner. */ if (l2arc_feed_again && wrote > (wanted / 2)) interval = (hz * l2arc_feed_min_ms) / 1000; else interval = hz * l2arc_feed_secs; now = ddi_get_lbolt(); next = MAX(now, MIN(now + interval, began + interval)); return (next); } /* * Cycle through L2ARC devices. This is how L2ARC load balances. * If a device is returned, this also returns holding the spa config lock. */ static l2arc_dev_t * l2arc_dev_get_next(void) { l2arc_dev_t *first, *next = NULL; /* * Lock out the removal of spas (spa_namespace_lock), then removal * of cache devices (l2arc_dev_mtx). Once a device has been selected, * both locks will be dropped and a spa config lock held instead. */ mutex_enter(&spa_namespace_lock); mutex_enter(&l2arc_dev_mtx); /* if there are no vdevs, there is nothing to do */ if (l2arc_ndev == 0) goto out; first = NULL; next = l2arc_dev_last; do { /* loop around the list looking for a non-faulted vdev */ if (next == NULL) { next = list_head(l2arc_dev_list); } else { next = list_next(l2arc_dev_list, next); if (next == NULL) next = list_head(l2arc_dev_list); } /* if we have come back to the start, bail out */ if (first == NULL) first = next; else if (next == first) break; ASSERT3P(next, !=, NULL); } while (vdev_is_dead(next->l2ad_vdev) || next->l2ad_rebuild || next->l2ad_trim_all); /* if we were unable to find any usable vdevs, return NULL */ if (vdev_is_dead(next->l2ad_vdev) || next->l2ad_rebuild || next->l2ad_trim_all) next = NULL; l2arc_dev_last = next; out: mutex_exit(&l2arc_dev_mtx); /* * Grab the config lock to prevent the 'next' device from being * removed while we are writing to it. */ if (next != NULL) spa_config_enter(next->l2ad_spa, SCL_L2ARC, next, RW_READER); mutex_exit(&spa_namespace_lock); return (next); } /* * Free buffers that were tagged for destruction. */ static void l2arc_do_free_on_write(void) { l2arc_data_free_t *df; mutex_enter(&l2arc_free_on_write_mtx); while ((df = list_remove_head(l2arc_free_on_write)) != NULL) { ASSERT3P(df->l2df_abd, !=, NULL); abd_free(df->l2df_abd); kmem_free(df, sizeof (l2arc_data_free_t)); } mutex_exit(&l2arc_free_on_write_mtx); } /* * A write to a cache device has completed. Update all headers to allow * reads from these buffers to begin. */ static void l2arc_write_done(zio_t *zio) { l2arc_write_callback_t *cb; l2arc_lb_abd_buf_t *abd_buf; l2arc_lb_ptr_buf_t *lb_ptr_buf; l2arc_dev_t *dev; l2arc_dev_hdr_phys_t *l2dhdr; list_t *buflist; arc_buf_hdr_t *head, *hdr, *hdr_prev; kmutex_t *hash_lock; int64_t bytes_dropped = 0; cb = zio->io_private; ASSERT3P(cb, !=, NULL); dev = cb->l2wcb_dev; l2dhdr = dev->l2ad_dev_hdr; ASSERT3P(dev, !=, NULL); head = cb->l2wcb_head; ASSERT3P(head, !=, NULL); buflist = &dev->l2ad_buflist; ASSERT3P(buflist, !=, NULL); DTRACE_PROBE2(l2arc__iodone, zio_t *, zio, l2arc_write_callback_t *, cb); /* * All writes completed, or an error was hit. */ top: mutex_enter(&dev->l2ad_mtx); for (hdr = list_prev(buflist, head); hdr; hdr = hdr_prev) { hdr_prev = list_prev(buflist, hdr); hash_lock = HDR_LOCK(hdr); /* * We cannot use mutex_enter or else we can deadlock * with l2arc_write_buffers (due to swapping the order * the hash lock and l2ad_mtx are taken). */ if (!mutex_tryenter(hash_lock)) { /* * Missed the hash lock. We must retry so we * don't leave the ARC_FLAG_L2_WRITING bit set. */ ARCSTAT_BUMP(arcstat_l2_writes_lock_retry); /* * We don't want to rescan the headers we've * already marked as having been written out, so * we reinsert the head node so we can pick up * where we left off. */ list_remove(buflist, head); list_insert_after(buflist, hdr, head); mutex_exit(&dev->l2ad_mtx); /* * We wait for the hash lock to become available * to try and prevent busy waiting, and increase * the chance we'll be able to acquire the lock * the next time around. */ mutex_enter(hash_lock); mutex_exit(hash_lock); goto top; } /* * We could not have been moved into the arc_l2c_only * state while in-flight due to our ARC_FLAG_L2_WRITING * bit being set. Let's just ensure that's being enforced. */ ASSERT(HDR_HAS_L1HDR(hdr)); /* * Skipped - drop L2ARC entry and mark the header as no * longer L2 eligibile. */ if (zio->io_error != 0) { /* * Error - drop L2ARC entry. */ list_remove(buflist, hdr); arc_hdr_clear_flags(hdr, ARC_FLAG_HAS_L2HDR); uint64_t psize = HDR_GET_PSIZE(hdr); l2arc_hdr_arcstats_decrement(hdr); bytes_dropped += vdev_psize_to_asize(dev->l2ad_vdev, psize); (void) zfs_refcount_remove_many(&dev->l2ad_alloc, arc_hdr_size(hdr), hdr); } /* * Allow ARC to begin reads and ghost list evictions to * this L2ARC entry. */ arc_hdr_clear_flags(hdr, ARC_FLAG_L2_WRITING); mutex_exit(hash_lock); } /* * Free the allocated abd buffers for writing the log blocks. * If the zio failed reclaim the allocated space and remove the * pointers to these log blocks from the log block pointer list * of the L2ARC device. */ while ((abd_buf = list_remove_tail(&cb->l2wcb_abd_list)) != NULL) { abd_free(abd_buf->abd); zio_buf_free(abd_buf, sizeof (*abd_buf)); if (zio->io_error != 0) { lb_ptr_buf = list_remove_head(&dev->l2ad_lbptr_list); /* * L2BLK_GET_PSIZE returns aligned size for log * blocks. */ uint64_t asize = L2BLK_GET_PSIZE((lb_ptr_buf->lb_ptr)->lbp_prop); bytes_dropped += asize; ARCSTAT_INCR(arcstat_l2_log_blk_asize, -asize); ARCSTAT_BUMPDOWN(arcstat_l2_log_blk_count); zfs_refcount_remove_many(&dev->l2ad_lb_asize, asize, lb_ptr_buf); zfs_refcount_remove(&dev->l2ad_lb_count, lb_ptr_buf); kmem_free(lb_ptr_buf->lb_ptr, sizeof (l2arc_log_blkptr_t)); kmem_free(lb_ptr_buf, sizeof (l2arc_lb_ptr_buf_t)); } } list_destroy(&cb->l2wcb_abd_list); if (zio->io_error != 0) { ARCSTAT_BUMP(arcstat_l2_writes_error); /* * Restore the lbps array in the header to its previous state. * If the list of log block pointers is empty, zero out the * log block pointers in the device header. */ lb_ptr_buf = list_head(&dev->l2ad_lbptr_list); for (int i = 0; i < 2; i++) { if (lb_ptr_buf == NULL) { /* * If the list is empty zero out the device * header. Otherwise zero out the second log * block pointer in the header. */ if (i == 0) { memset(l2dhdr, 0, dev->l2ad_dev_hdr_asize); } else { memset(&l2dhdr->dh_start_lbps[i], 0, sizeof (l2arc_log_blkptr_t)); } break; } memcpy(&l2dhdr->dh_start_lbps[i], lb_ptr_buf->lb_ptr, sizeof (l2arc_log_blkptr_t)); lb_ptr_buf = list_next(&dev->l2ad_lbptr_list, lb_ptr_buf); } } ARCSTAT_BUMP(arcstat_l2_writes_done); list_remove(buflist, head); ASSERT(!HDR_HAS_L1HDR(head)); kmem_cache_free(hdr_l2only_cache, head); mutex_exit(&dev->l2ad_mtx); ASSERT(dev->l2ad_vdev != NULL); vdev_space_update(dev->l2ad_vdev, -bytes_dropped, 0, 0); l2arc_do_free_on_write(); kmem_free(cb, sizeof (l2arc_write_callback_t)); } static int l2arc_untransform(zio_t *zio, l2arc_read_callback_t *cb) { int ret; spa_t *spa = zio->io_spa; arc_buf_hdr_t *hdr = cb->l2rcb_hdr; blkptr_t *bp = zio->io_bp; uint8_t salt[ZIO_DATA_SALT_LEN]; uint8_t iv[ZIO_DATA_IV_LEN]; uint8_t mac[ZIO_DATA_MAC_LEN]; boolean_t no_crypt = B_FALSE; /* * ZIL data is never be written to the L2ARC, so we don't need * special handling for its unique MAC storage. */ ASSERT3U(BP_GET_TYPE(bp), !=, DMU_OT_INTENT_LOG); ASSERT(MUTEX_HELD(HDR_LOCK(hdr))); ASSERT3P(hdr->b_l1hdr.b_pabd, !=, NULL); /* * If the data was encrypted, decrypt it now. Note that * we must check the bp here and not the hdr, since the * hdr does not have its encryption parameters updated * until arc_read_done(). */ if (BP_IS_ENCRYPTED(bp)) { abd_t *eabd = arc_get_data_abd(hdr, arc_hdr_size(hdr), hdr, ARC_HDR_USE_RESERVE); zio_crypt_decode_params_bp(bp, salt, iv); zio_crypt_decode_mac_bp(bp, mac); ret = spa_do_crypt_abd(B_FALSE, spa, &cb->l2rcb_zb, BP_GET_TYPE(bp), BP_GET_DEDUP(bp), BP_SHOULD_BYTESWAP(bp), salt, iv, mac, HDR_GET_PSIZE(hdr), eabd, hdr->b_l1hdr.b_pabd, &no_crypt); if (ret != 0) { arc_free_data_abd(hdr, eabd, arc_hdr_size(hdr), hdr); goto error; } /* * If we actually performed decryption, replace b_pabd * with the decrypted data. Otherwise we can just throw * our decryption buffer away. */ if (!no_crypt) { arc_free_data_abd(hdr, hdr->b_l1hdr.b_pabd, arc_hdr_size(hdr), hdr); hdr->b_l1hdr.b_pabd = eabd; zio->io_abd = eabd; } else { arc_free_data_abd(hdr, eabd, arc_hdr_size(hdr), hdr); } } /* * If the L2ARC block was compressed, but ARC compression * is disabled we decompress the data into a new buffer and * replace the existing data. */ if (HDR_GET_COMPRESS(hdr) != ZIO_COMPRESS_OFF && !HDR_COMPRESSION_ENABLED(hdr)) { abd_t *cabd = arc_get_data_abd(hdr, arc_hdr_size(hdr), hdr, ARC_HDR_USE_RESERVE); void *tmp = abd_borrow_buf(cabd, arc_hdr_size(hdr)); ret = zio_decompress_data(HDR_GET_COMPRESS(hdr), hdr->b_l1hdr.b_pabd, tmp, HDR_GET_PSIZE(hdr), HDR_GET_LSIZE(hdr), &hdr->b_complevel); if (ret != 0) { abd_return_buf_copy(cabd, tmp, arc_hdr_size(hdr)); arc_free_data_abd(hdr, cabd, arc_hdr_size(hdr), hdr); goto error; } abd_return_buf_copy(cabd, tmp, arc_hdr_size(hdr)); arc_free_data_abd(hdr, hdr->b_l1hdr.b_pabd, arc_hdr_size(hdr), hdr); hdr->b_l1hdr.b_pabd = cabd; zio->io_abd = cabd; zio->io_size = HDR_GET_LSIZE(hdr); } return (0); error: return (ret); } /* * A read to a cache device completed. Validate buffer contents before * handing over to the regular ARC routines. */ static void l2arc_read_done(zio_t *zio) { int tfm_error = 0; l2arc_read_callback_t *cb = zio->io_private; arc_buf_hdr_t *hdr; kmutex_t *hash_lock; boolean_t valid_cksum; boolean_t using_rdata = (BP_IS_ENCRYPTED(&cb->l2rcb_bp) && (cb->l2rcb_flags & ZIO_FLAG_RAW_ENCRYPT)); ASSERT3P(zio->io_vd, !=, NULL); ASSERT(zio->io_flags & ZIO_FLAG_DONT_PROPAGATE); spa_config_exit(zio->io_spa, SCL_L2ARC, zio->io_vd); ASSERT3P(cb, !=, NULL); hdr = cb->l2rcb_hdr; ASSERT3P(hdr, !=, NULL); hash_lock = HDR_LOCK(hdr); mutex_enter(hash_lock); ASSERT3P(hash_lock, ==, HDR_LOCK(hdr)); /* * If the data was read into a temporary buffer, * move it and free the buffer. */ if (cb->l2rcb_abd != NULL) { ASSERT3U(arc_hdr_size(hdr), <, zio->io_size); if (zio->io_error == 0) { if (using_rdata) { abd_copy(hdr->b_crypt_hdr.b_rabd, cb->l2rcb_abd, arc_hdr_size(hdr)); } else { abd_copy(hdr->b_l1hdr.b_pabd, cb->l2rcb_abd, arc_hdr_size(hdr)); } } /* * The following must be done regardless of whether * there was an error: * - free the temporary buffer * - point zio to the real ARC buffer * - set zio size accordingly * These are required because zio is either re-used for * an I/O of the block in the case of the error * or the zio is passed to arc_read_done() and it * needs real data. */ abd_free(cb->l2rcb_abd); zio->io_size = zio->io_orig_size = arc_hdr_size(hdr); if (using_rdata) { ASSERT(HDR_HAS_RABD(hdr)); zio->io_abd = zio->io_orig_abd = hdr->b_crypt_hdr.b_rabd; } else { ASSERT3P(hdr->b_l1hdr.b_pabd, !=, NULL); zio->io_abd = zio->io_orig_abd = hdr->b_l1hdr.b_pabd; } } ASSERT3P(zio->io_abd, !=, NULL); /* * Check this survived the L2ARC journey. */ ASSERT(zio->io_abd == hdr->b_l1hdr.b_pabd || (HDR_HAS_RABD(hdr) && zio->io_abd == hdr->b_crypt_hdr.b_rabd)); zio->io_bp_copy = cb->l2rcb_bp; /* XXX fix in L2ARC 2.0 */ zio->io_bp = &zio->io_bp_copy; /* XXX fix in L2ARC 2.0 */ zio->io_prop.zp_complevel = hdr->b_complevel; valid_cksum = arc_cksum_is_equal(hdr, zio); /* * b_rabd will always match the data as it exists on disk if it is * being used. Therefore if we are reading into b_rabd we do not * attempt to untransform the data. */ if (valid_cksum && !using_rdata) tfm_error = l2arc_untransform(zio, cb); if (valid_cksum && tfm_error == 0 && zio->io_error == 0 && !HDR_L2_EVICTED(hdr)) { mutex_exit(hash_lock); zio->io_private = hdr; arc_read_done(zio); } else { /* * Buffer didn't survive caching. Increment stats and * reissue to the original storage device. */ if (zio->io_error != 0) { ARCSTAT_BUMP(arcstat_l2_io_error); } else { zio->io_error = SET_ERROR(EIO); } if (!valid_cksum || tfm_error != 0) ARCSTAT_BUMP(arcstat_l2_cksum_bad); /* * If there's no waiter, issue an async i/o to the primary * storage now. If there *is* a waiter, the caller must * issue the i/o in a context where it's OK to block. */ if (zio->io_waiter == NULL) { zio_t *pio = zio_unique_parent(zio); void *abd = (using_rdata) ? hdr->b_crypt_hdr.b_rabd : hdr->b_l1hdr.b_pabd; ASSERT(!pio || pio->io_child_type == ZIO_CHILD_LOGICAL); zio = zio_read(pio, zio->io_spa, zio->io_bp, abd, zio->io_size, arc_read_done, hdr, zio->io_priority, cb->l2rcb_flags, &cb->l2rcb_zb); /* * Original ZIO will be freed, so we need to update * ARC header with the new ZIO pointer to be used * by zio_change_priority() in arc_read(). */ for (struct arc_callback *acb = hdr->b_l1hdr.b_acb; acb != NULL; acb = acb->acb_next) acb->acb_zio_head = zio; mutex_exit(hash_lock); zio_nowait(zio); } else { mutex_exit(hash_lock); } } kmem_free(cb, sizeof (l2arc_read_callback_t)); } /* * This is the list priority from which the L2ARC will search for pages to * cache. This is used within loops (0..3) to cycle through lists in the * desired order. This order can have a significant effect on cache * performance. * * Currently the metadata lists are hit first, MFU then MRU, followed by * the data lists. This function returns a locked list, and also returns * the lock pointer. */ static multilist_sublist_t * l2arc_sublist_lock(int list_num) { multilist_t *ml = NULL; unsigned int idx; ASSERT(list_num >= 0 && list_num < L2ARC_FEED_TYPES); switch (list_num) { case 0: ml = &arc_mfu->arcs_list[ARC_BUFC_METADATA]; break; case 1: ml = &arc_mru->arcs_list[ARC_BUFC_METADATA]; break; case 2: ml = &arc_mfu->arcs_list[ARC_BUFC_DATA]; break; case 3: ml = &arc_mru->arcs_list[ARC_BUFC_DATA]; break; default: return (NULL); } /* * Return a randomly-selected sublist. This is acceptable * because the caller feeds only a little bit of data for each * call (8MB). Subsequent calls will result in different * sublists being selected. */ idx = multilist_get_random_index(ml); return (multilist_sublist_lock(ml, idx)); } /* * Calculates the maximum overhead of L2ARC metadata log blocks for a given * L2ARC write size. l2arc_evict and l2arc_write_size need to include this * overhead in processing to make sure there is enough headroom available * when writing buffers. */ static inline uint64_t l2arc_log_blk_overhead(uint64_t write_sz, l2arc_dev_t *dev) { if (dev->l2ad_log_entries == 0) { return (0); } else { uint64_t log_entries = write_sz >> SPA_MINBLOCKSHIFT; uint64_t log_blocks = (log_entries + dev->l2ad_log_entries - 1) / dev->l2ad_log_entries; return (vdev_psize_to_asize(dev->l2ad_vdev, sizeof (l2arc_log_blk_phys_t)) * log_blocks); } } /* * Evict buffers from the device write hand to the distance specified in * bytes. This distance may span populated buffers, it may span nothing. * This is clearing a region on the L2ARC device ready for writing. * If the 'all' boolean is set, every buffer is evicted. */ static void l2arc_evict(l2arc_dev_t *dev, uint64_t distance, boolean_t all) { list_t *buflist; arc_buf_hdr_t *hdr, *hdr_prev; kmutex_t *hash_lock; uint64_t taddr; l2arc_lb_ptr_buf_t *lb_ptr_buf, *lb_ptr_buf_prev; vdev_t *vd = dev->l2ad_vdev; boolean_t rerun; buflist = &dev->l2ad_buflist; top: rerun = B_FALSE; if (dev->l2ad_hand + distance > dev->l2ad_end) { /* * When there is no space to accommodate upcoming writes, * evict to the end. Then bump the write and evict hands * to the start and iterate. This iteration does not * happen indefinitely as we make sure in * l2arc_write_size() that when the write hand is reset, * the write size does not exceed the end of the device. */ rerun = B_TRUE; taddr = dev->l2ad_end; } else { taddr = dev->l2ad_hand + distance; } DTRACE_PROBE4(l2arc__evict, l2arc_dev_t *, dev, list_t *, buflist, uint64_t, taddr, boolean_t, all); if (!all) { /* * This check has to be placed after deciding whether to * iterate (rerun). */ if (dev->l2ad_first) { /* * This is the first sweep through the device. There is * nothing to evict. We have already trimmmed the * whole device. */ goto out; } else { /* * Trim the space to be evicted. */ if (vd->vdev_has_trim && dev->l2ad_evict < taddr && l2arc_trim_ahead > 0) { /* * We have to drop the spa_config lock because * vdev_trim_range() will acquire it. * l2ad_evict already accounts for the label * size. To prevent vdev_trim_ranges() from * adding it again, we subtract it from * l2ad_evict. */ spa_config_exit(dev->l2ad_spa, SCL_L2ARC, dev); vdev_trim_simple(vd, dev->l2ad_evict - VDEV_LABEL_START_SIZE, taddr - dev->l2ad_evict); spa_config_enter(dev->l2ad_spa, SCL_L2ARC, dev, RW_READER); } /* * When rebuilding L2ARC we retrieve the evict hand * from the header of the device. Of note, l2arc_evict() * does not actually delete buffers from the cache * device, but trimming may do so depending on the * hardware implementation. Thus keeping track of the * evict hand is useful. */ dev->l2ad_evict = MAX(dev->l2ad_evict, taddr); } } retry: mutex_enter(&dev->l2ad_mtx); /* * We have to account for evicted log blocks. Run vdev_space_update() * on log blocks whose offset (in bytes) is before the evicted offset * (in bytes) by searching in the list of pointers to log blocks * present in the L2ARC device. */ for (lb_ptr_buf = list_tail(&dev->l2ad_lbptr_list); lb_ptr_buf; lb_ptr_buf = lb_ptr_buf_prev) { lb_ptr_buf_prev = list_prev(&dev->l2ad_lbptr_list, lb_ptr_buf); /* L2BLK_GET_PSIZE returns aligned size for log blocks */ uint64_t asize = L2BLK_GET_PSIZE( (lb_ptr_buf->lb_ptr)->lbp_prop); /* * We don't worry about log blocks left behind (ie * lbp_payload_start < l2ad_hand) because l2arc_write_buffers() * will never write more than l2arc_evict() evicts. */ if (!all && l2arc_log_blkptr_valid(dev, lb_ptr_buf->lb_ptr)) { break; } else { vdev_space_update(vd, -asize, 0, 0); ARCSTAT_INCR(arcstat_l2_log_blk_asize, -asize); ARCSTAT_BUMPDOWN(arcstat_l2_log_blk_count); zfs_refcount_remove_many(&dev->l2ad_lb_asize, asize, lb_ptr_buf); zfs_refcount_remove(&dev->l2ad_lb_count, lb_ptr_buf); list_remove(&dev->l2ad_lbptr_list, lb_ptr_buf); kmem_free(lb_ptr_buf->lb_ptr, sizeof (l2arc_log_blkptr_t)); kmem_free(lb_ptr_buf, sizeof (l2arc_lb_ptr_buf_t)); } } for (hdr = list_tail(buflist); hdr; hdr = hdr_prev) { hdr_prev = list_prev(buflist, hdr); ASSERT(!HDR_EMPTY(hdr)); hash_lock = HDR_LOCK(hdr); /* * We cannot use mutex_enter or else we can deadlock * with l2arc_write_buffers (due to swapping the order * the hash lock and l2ad_mtx are taken). */ if (!mutex_tryenter(hash_lock)) { /* * Missed the hash lock. Retry. */ ARCSTAT_BUMP(arcstat_l2_evict_lock_retry); mutex_exit(&dev->l2ad_mtx); mutex_enter(hash_lock); mutex_exit(hash_lock); goto retry; } /* * A header can't be on this list if it doesn't have L2 header. */ ASSERT(HDR_HAS_L2HDR(hdr)); /* Ensure this header has finished being written. */ ASSERT(!HDR_L2_WRITING(hdr)); ASSERT(!HDR_L2_WRITE_HEAD(hdr)); if (!all && (hdr->b_l2hdr.b_daddr >= dev->l2ad_evict || hdr->b_l2hdr.b_daddr < dev->l2ad_hand)) { /* * We've evicted to the target address, * or the end of the device. */ mutex_exit(hash_lock); break; } if (!HDR_HAS_L1HDR(hdr)) { ASSERT(!HDR_L2_READING(hdr)); /* * This doesn't exist in the ARC. Destroy. * arc_hdr_destroy() will call list_remove() * and decrement arcstat_l2_lsize. */ arc_change_state(arc_anon, hdr); arc_hdr_destroy(hdr); } else { ASSERT(hdr->b_l1hdr.b_state != arc_l2c_only); ARCSTAT_BUMP(arcstat_l2_evict_l1cached); /* * Invalidate issued or about to be issued * reads, since we may be about to write * over this location. */ if (HDR_L2_READING(hdr)) { ARCSTAT_BUMP(arcstat_l2_evict_reading); arc_hdr_set_flags(hdr, ARC_FLAG_L2_EVICTED); } arc_hdr_l2hdr_destroy(hdr); } mutex_exit(hash_lock); } mutex_exit(&dev->l2ad_mtx); out: /* * We need to check if we evict all buffers, otherwise we may iterate * unnecessarily. */ if (!all && rerun) { /* * Bump device hand to the device start if it is approaching the * end. l2arc_evict() has already evicted ahead for this case. */ dev->l2ad_hand = dev->l2ad_start; dev->l2ad_evict = dev->l2ad_start; dev->l2ad_first = B_FALSE; goto top; } if (!all) { /* * In case of cache device removal (all) the following * assertions may be violated without functional consequences * as the device is about to be removed. */ ASSERT3U(dev->l2ad_hand + distance, <, dev->l2ad_end); if (!dev->l2ad_first) ASSERT3U(dev->l2ad_hand, <=, dev->l2ad_evict); } } /* * Handle any abd transforms that might be required for writing to the L2ARC. * If successful, this function will always return an abd with the data * transformed as it is on disk in a new abd of asize bytes. */ static int l2arc_apply_transforms(spa_t *spa, arc_buf_hdr_t *hdr, uint64_t asize, abd_t **abd_out) { int ret; void *tmp = NULL; abd_t *cabd = NULL, *eabd = NULL, *to_write = hdr->b_l1hdr.b_pabd; enum zio_compress compress = HDR_GET_COMPRESS(hdr); uint64_t psize = HDR_GET_PSIZE(hdr); uint64_t size = arc_hdr_size(hdr); boolean_t ismd = HDR_ISTYPE_METADATA(hdr); boolean_t bswap = (hdr->b_l1hdr.b_byteswap != DMU_BSWAP_NUMFUNCS); dsl_crypto_key_t *dck = NULL; uint8_t mac[ZIO_DATA_MAC_LEN] = { 0 }; boolean_t no_crypt = B_FALSE; ASSERT((HDR_GET_COMPRESS(hdr) != ZIO_COMPRESS_OFF && !HDR_COMPRESSION_ENABLED(hdr)) || HDR_ENCRYPTED(hdr) || HDR_SHARED_DATA(hdr) || psize != asize); ASSERT3U(psize, <=, asize); /* * If this data simply needs its own buffer, we simply allocate it * and copy the data. This may be done to eliminate a dependency on a * shared buffer or to reallocate the buffer to match asize. */ if (HDR_HAS_RABD(hdr) && asize != psize) { ASSERT3U(asize, >=, psize); to_write = abd_alloc_for_io(asize, ismd); abd_copy(to_write, hdr->b_crypt_hdr.b_rabd, psize); if (psize != asize) abd_zero_off(to_write, psize, asize - psize); goto out; } if ((compress == ZIO_COMPRESS_OFF || HDR_COMPRESSION_ENABLED(hdr)) && !HDR_ENCRYPTED(hdr)) { ASSERT3U(size, ==, psize); to_write = abd_alloc_for_io(asize, ismd); abd_copy(to_write, hdr->b_l1hdr.b_pabd, size); if (size != asize) abd_zero_off(to_write, size, asize - size); goto out; } if (compress != ZIO_COMPRESS_OFF && !HDR_COMPRESSION_ENABLED(hdr)) { /* * In some cases, we can wind up with size > asize, so * we need to opt for the larger allocation option here. * * (We also need abd_return_buf_copy in all cases because * it's an ASSERT() to modify the buffer before returning it * with arc_return_buf(), and all the compressors * write things before deciding to fail compression in nearly * every case.) */ uint64_t bufsize = MAX(size, asize); cabd = abd_alloc_for_io(bufsize, ismd); tmp = abd_borrow_buf(cabd, bufsize); psize = zio_compress_data(compress, to_write, &tmp, size, hdr->b_complevel); if (psize >= asize) { psize = HDR_GET_PSIZE(hdr); abd_return_buf_copy(cabd, tmp, bufsize); HDR_SET_COMPRESS(hdr, ZIO_COMPRESS_OFF); to_write = cabd; abd_copy(to_write, hdr->b_l1hdr.b_pabd, psize); if (psize != asize) abd_zero_off(to_write, psize, asize - psize); goto encrypt; } ASSERT3U(psize, <=, HDR_GET_PSIZE(hdr)); if (psize < asize) memset((char *)tmp + psize, 0, bufsize - psize); psize = HDR_GET_PSIZE(hdr); abd_return_buf_copy(cabd, tmp, bufsize); to_write = cabd; } encrypt: if (HDR_ENCRYPTED(hdr)) { eabd = abd_alloc_for_io(asize, ismd); /* * If the dataset was disowned before the buffer * made it to this point, the key to re-encrypt * it won't be available. In this case we simply * won't write the buffer to the L2ARC. */ ret = spa_keystore_lookup_key(spa, hdr->b_crypt_hdr.b_dsobj, FTAG, &dck); if (ret != 0) goto error; ret = zio_do_crypt_abd(B_TRUE, &dck->dck_key, hdr->b_crypt_hdr.b_ot, bswap, hdr->b_crypt_hdr.b_salt, hdr->b_crypt_hdr.b_iv, mac, psize, to_write, eabd, &no_crypt); if (ret != 0) goto error; if (no_crypt) abd_copy(eabd, to_write, psize); if (psize != asize) abd_zero_off(eabd, psize, asize - psize); /* assert that the MAC we got here matches the one we saved */ ASSERT0(memcmp(mac, hdr->b_crypt_hdr.b_mac, ZIO_DATA_MAC_LEN)); spa_keystore_dsl_key_rele(spa, dck, FTAG); if (to_write == cabd) abd_free(cabd); to_write = eabd; } out: ASSERT3P(to_write, !=, hdr->b_l1hdr.b_pabd); *abd_out = to_write; return (0); error: if (dck != NULL) spa_keystore_dsl_key_rele(spa, dck, FTAG); if (cabd != NULL) abd_free(cabd); if (eabd != NULL) abd_free(eabd); *abd_out = NULL; return (ret); } static void l2arc_blk_fetch_done(zio_t *zio) { l2arc_read_callback_t *cb; cb = zio->io_private; if (cb->l2rcb_abd != NULL) abd_free(cb->l2rcb_abd); kmem_free(cb, sizeof (l2arc_read_callback_t)); } /* * Find and write ARC buffers to the L2ARC device. * * An ARC_FLAG_L2_WRITING flag is set so that the L2ARC buffers are not valid * for reading until they have completed writing. * The headroom_boost is an in-out parameter used to maintain headroom boost * state between calls to this function. * * Returns the number of bytes actually written (which may be smaller than * the delta by which the device hand has changed due to alignment and the * writing of log blocks). */ static uint64_t l2arc_write_buffers(spa_t *spa, l2arc_dev_t *dev, uint64_t target_sz) { arc_buf_hdr_t *hdr, *hdr_prev, *head; uint64_t write_asize, write_psize, write_lsize, headroom; boolean_t full; l2arc_write_callback_t *cb = NULL; zio_t *pio, *wzio; uint64_t guid = spa_load_guid(spa); l2arc_dev_hdr_phys_t *l2dhdr = dev->l2ad_dev_hdr; ASSERT3P(dev->l2ad_vdev, !=, NULL); pio = NULL; write_lsize = write_asize = write_psize = 0; full = B_FALSE; head = kmem_cache_alloc(hdr_l2only_cache, KM_PUSHPAGE); arc_hdr_set_flags(head, ARC_FLAG_L2_WRITE_HEAD | ARC_FLAG_HAS_L2HDR); /* * Copy buffers for L2ARC writing. */ for (int pass = 0; pass < L2ARC_FEED_TYPES; pass++) { /* * If pass == 1 or 3, we cache MRU metadata and data * respectively. */ if (l2arc_mfuonly) { if (pass == 1 || pass == 3) continue; } multilist_sublist_t *mls = l2arc_sublist_lock(pass); uint64_t passed_sz = 0; VERIFY3P(mls, !=, NULL); /* * L2ARC fast warmup. * * Until the ARC is warm and starts to evict, read from the * head of the ARC lists rather than the tail. */ if (arc_warm == B_FALSE) hdr = multilist_sublist_head(mls); else hdr = multilist_sublist_tail(mls); headroom = target_sz * l2arc_headroom; if (zfs_compressed_arc_enabled) headroom = (headroom * l2arc_headroom_boost) / 100; for (; hdr; hdr = hdr_prev) { kmutex_t *hash_lock; abd_t *to_write = NULL; if (arc_warm == B_FALSE) hdr_prev = multilist_sublist_next(mls, hdr); else hdr_prev = multilist_sublist_prev(mls, hdr); hash_lock = HDR_LOCK(hdr); if (!mutex_tryenter(hash_lock)) { /* * Skip this buffer rather than waiting. */ continue; } passed_sz += HDR_GET_LSIZE(hdr); if (l2arc_headroom != 0 && passed_sz > headroom) { /* * Searched too far. */ mutex_exit(hash_lock); break; } if (!l2arc_write_eligible(guid, hdr)) { mutex_exit(hash_lock); continue; } ASSERT(HDR_HAS_L1HDR(hdr)); ASSERT3U(HDR_GET_PSIZE(hdr), >, 0); ASSERT3U(arc_hdr_size(hdr), >, 0); ASSERT(hdr->b_l1hdr.b_pabd != NULL || HDR_HAS_RABD(hdr)); uint64_t psize = HDR_GET_PSIZE(hdr); uint64_t asize = vdev_psize_to_asize(dev->l2ad_vdev, psize); /* * If the allocated size of this buffer plus the max * size for the pending log block exceeds the evicted * target size, terminate writing buffers for this run. */ if (write_asize + asize + sizeof (l2arc_log_blk_phys_t) > target_sz) { full = B_TRUE; mutex_exit(hash_lock); break; } /* * We rely on the L1 portion of the header below, so * it's invalid for this header to have been evicted out * of the ghost cache, prior to being written out. The * ARC_FLAG_L2_WRITING bit ensures this won't happen. */ arc_hdr_set_flags(hdr, ARC_FLAG_L2_WRITING); /* * If this header has b_rabd, we can use this since it * must always match the data exactly as it exists on * disk. Otherwise, the L2ARC can normally use the * hdr's data, but if we're sharing data between the * hdr and one of its bufs, L2ARC needs its own copy of * the data so that the ZIO below can't race with the * buf consumer. To ensure that this copy will be * available for the lifetime of the ZIO and be cleaned * up afterwards, we add it to the l2arc_free_on_write * queue. If we need to apply any transforms to the * data (compression, encryption) we will also need the * extra buffer. */ if (HDR_HAS_RABD(hdr) && psize == asize) { to_write = hdr->b_crypt_hdr.b_rabd; } else if ((HDR_COMPRESSION_ENABLED(hdr) || HDR_GET_COMPRESS(hdr) == ZIO_COMPRESS_OFF) && !HDR_ENCRYPTED(hdr) && !HDR_SHARED_DATA(hdr) && psize == asize) { to_write = hdr->b_l1hdr.b_pabd; } else { int ret; arc_buf_contents_t type = arc_buf_type(hdr); ret = l2arc_apply_transforms(spa, hdr, asize, &to_write); if (ret != 0) { arc_hdr_clear_flags(hdr, ARC_FLAG_L2_WRITING); mutex_exit(hash_lock); continue; } l2arc_free_abd_on_write(to_write, asize, type); } if (pio == NULL) { /* * Insert a dummy header on the buflist so * l2arc_write_done() can find where the * write buffers begin without searching. */ mutex_enter(&dev->l2ad_mtx); list_insert_head(&dev->l2ad_buflist, head); mutex_exit(&dev->l2ad_mtx); cb = kmem_alloc( sizeof (l2arc_write_callback_t), KM_SLEEP); cb->l2wcb_dev = dev; cb->l2wcb_head = head; /* * Create a list to save allocated abd buffers * for l2arc_log_blk_commit(). */ list_create(&cb->l2wcb_abd_list, sizeof (l2arc_lb_abd_buf_t), offsetof(l2arc_lb_abd_buf_t, node)); pio = zio_root(spa, l2arc_write_done, cb, ZIO_FLAG_CANFAIL); } hdr->b_l2hdr.b_dev = dev; hdr->b_l2hdr.b_hits = 0; hdr->b_l2hdr.b_daddr = dev->l2ad_hand; hdr->b_l2hdr.b_arcs_state = hdr->b_l1hdr.b_state->arcs_state; arc_hdr_set_flags(hdr, ARC_FLAG_HAS_L2HDR); mutex_enter(&dev->l2ad_mtx); list_insert_head(&dev->l2ad_buflist, hdr); mutex_exit(&dev->l2ad_mtx); (void) zfs_refcount_add_many(&dev->l2ad_alloc, arc_hdr_size(hdr), hdr); wzio = zio_write_phys(pio, dev->l2ad_vdev, hdr->b_l2hdr.b_daddr, asize, to_write, ZIO_CHECKSUM_OFF, NULL, hdr, ZIO_PRIORITY_ASYNC_WRITE, ZIO_FLAG_CANFAIL, B_FALSE); write_lsize += HDR_GET_LSIZE(hdr); DTRACE_PROBE2(l2arc__write, vdev_t *, dev->l2ad_vdev, zio_t *, wzio); write_psize += psize; write_asize += asize; dev->l2ad_hand += asize; l2arc_hdr_arcstats_increment(hdr); vdev_space_update(dev->l2ad_vdev, asize, 0, 0); mutex_exit(hash_lock); /* * Append buf info to current log and commit if full. * arcstat_l2_{size,asize} kstats are updated * internally. */ if (l2arc_log_blk_insert(dev, hdr)) { /* * l2ad_hand will be adjusted in * l2arc_log_blk_commit(). */ write_asize += l2arc_log_blk_commit(dev, pio, cb); } zio_nowait(wzio); } multilist_sublist_unlock(mls); if (full == B_TRUE) break; } /* No buffers selected for writing? */ if (pio == NULL) { ASSERT0(write_lsize); ASSERT(!HDR_HAS_L1HDR(head)); kmem_cache_free(hdr_l2only_cache, head); /* * Although we did not write any buffers l2ad_evict may * have advanced. */ if (dev->l2ad_evict != l2dhdr->dh_evict) l2arc_dev_hdr_update(dev); return (0); } if (!dev->l2ad_first) ASSERT3U(dev->l2ad_hand, <=, dev->l2ad_evict); ASSERT3U(write_asize, <=, target_sz); ARCSTAT_BUMP(arcstat_l2_writes_sent); ARCSTAT_INCR(arcstat_l2_write_bytes, write_psize); dev->l2ad_writing = B_TRUE; (void) zio_wait(pio); dev->l2ad_writing = B_FALSE; /* * Update the device header after the zio completes as * l2arc_write_done() may have updated the memory holding the log block * pointers in the device header. */ l2arc_dev_hdr_update(dev); return (write_asize); } static boolean_t l2arc_hdr_limit_reached(void) { int64_t s = aggsum_upper_bound(&arc_sums.arcstat_l2_hdr_size); return (arc_reclaim_needed() || (s > (arc_warm ? arc_c : arc_c_max) * l2arc_meta_percent / 100)); } /* * This thread feeds the L2ARC at regular intervals. This is the beating * heart of the L2ARC. */ static __attribute__((noreturn)) void l2arc_feed_thread(void *unused) { (void) unused; callb_cpr_t cpr; l2arc_dev_t *dev; spa_t *spa; uint64_t size, wrote; clock_t begin, next = ddi_get_lbolt(); fstrans_cookie_t cookie; CALLB_CPR_INIT(&cpr, &l2arc_feed_thr_lock, callb_generic_cpr, FTAG); mutex_enter(&l2arc_feed_thr_lock); cookie = spl_fstrans_mark(); while (l2arc_thread_exit == 0) { CALLB_CPR_SAFE_BEGIN(&cpr); (void) cv_timedwait_idle(&l2arc_feed_thr_cv, &l2arc_feed_thr_lock, next); CALLB_CPR_SAFE_END(&cpr, &l2arc_feed_thr_lock); next = ddi_get_lbolt() + hz; /* * Quick check for L2ARC devices. */ mutex_enter(&l2arc_dev_mtx); if (l2arc_ndev == 0) { mutex_exit(&l2arc_dev_mtx); continue; } mutex_exit(&l2arc_dev_mtx); begin = ddi_get_lbolt(); /* * This selects the next l2arc device to write to, and in * doing so the next spa to feed from: dev->l2ad_spa. This * will return NULL if there are now no l2arc devices or if * they are all faulted. * * If a device is returned, its spa's config lock is also * held to prevent device removal. l2arc_dev_get_next() * will grab and release l2arc_dev_mtx. */ if ((dev = l2arc_dev_get_next()) == NULL) continue; spa = dev->l2ad_spa; ASSERT3P(spa, !=, NULL); /* * If the pool is read-only then force the feed thread to * sleep a little longer. */ if (!spa_writeable(spa)) { next = ddi_get_lbolt() + 5 * l2arc_feed_secs * hz; spa_config_exit(spa, SCL_L2ARC, dev); continue; } /* * Avoid contributing to memory pressure. */ if (l2arc_hdr_limit_reached()) { ARCSTAT_BUMP(arcstat_l2_abort_lowmem); spa_config_exit(spa, SCL_L2ARC, dev); continue; } ARCSTAT_BUMP(arcstat_l2_feeds); size = l2arc_write_size(dev); /* * Evict L2ARC buffers that will be overwritten. */ l2arc_evict(dev, size, B_FALSE); /* * Write ARC buffers. */ wrote = l2arc_write_buffers(spa, dev, size); /* * Calculate interval between writes. */ next = l2arc_write_interval(begin, size, wrote); spa_config_exit(spa, SCL_L2ARC, dev); } spl_fstrans_unmark(cookie); l2arc_thread_exit = 0; cv_broadcast(&l2arc_feed_thr_cv); CALLB_CPR_EXIT(&cpr); /* drops l2arc_feed_thr_lock */ thread_exit(); } boolean_t l2arc_vdev_present(vdev_t *vd) { return (l2arc_vdev_get(vd) != NULL); } /* * Returns the l2arc_dev_t associated with a particular vdev_t or NULL if * the vdev_t isn't an L2ARC device. */ l2arc_dev_t * l2arc_vdev_get(vdev_t *vd) { l2arc_dev_t *dev; mutex_enter(&l2arc_dev_mtx); for (dev = list_head(l2arc_dev_list); dev != NULL; dev = list_next(l2arc_dev_list, dev)) { if (dev->l2ad_vdev == vd) break; } mutex_exit(&l2arc_dev_mtx); return (dev); } static void l2arc_rebuild_dev(l2arc_dev_t *dev, boolean_t reopen) { l2arc_dev_hdr_phys_t *l2dhdr = dev->l2ad_dev_hdr; uint64_t l2dhdr_asize = dev->l2ad_dev_hdr_asize; spa_t *spa = dev->l2ad_spa; /* * The L2ARC has to hold at least the payload of one log block for * them to be restored (persistent L2ARC). The payload of a log block * depends on the amount of its log entries. We always write log blocks * with 1022 entries. How many of them are committed or restored depends * on the size of the L2ARC device. Thus the maximum payload of * one log block is 1022 * SPA_MAXBLOCKSIZE = 16GB. If the L2ARC device * is less than that, we reduce the amount of committed and restored * log entries per block so as to enable persistence. */ if (dev->l2ad_end < l2arc_rebuild_blocks_min_l2size) { dev->l2ad_log_entries = 0; } else { dev->l2ad_log_entries = MIN((dev->l2ad_end - dev->l2ad_start) >> SPA_MAXBLOCKSHIFT, L2ARC_LOG_BLK_MAX_ENTRIES); } /* * Read the device header, if an error is returned do not rebuild L2ARC. */ if (l2arc_dev_hdr_read(dev) == 0 && dev->l2ad_log_entries > 0) { /* * If we are onlining a cache device (vdev_reopen) that was * still present (l2arc_vdev_present()) and rebuild is enabled, * we should evict all ARC buffers and pointers to log blocks * and reclaim their space before restoring its contents to * L2ARC. */ if (reopen) { if (!l2arc_rebuild_enabled) { return; } else { l2arc_evict(dev, 0, B_TRUE); /* start a new log block */ dev->l2ad_log_ent_idx = 0; dev->l2ad_log_blk_payload_asize = 0; dev->l2ad_log_blk_payload_start = 0; } } /* * Just mark the device as pending for a rebuild. We won't * be starting a rebuild in line here as it would block pool * import. Instead spa_load_impl will hand that off to an * async task which will call l2arc_spa_rebuild_start. */ dev->l2ad_rebuild = B_TRUE; } else if (spa_writeable(spa)) { /* * In this case TRIM the whole device if l2arc_trim_ahead > 0, * otherwise create a new header. We zero out the memory holding * the header to reset dh_start_lbps. If we TRIM the whole * device the new header will be written by * vdev_trim_l2arc_thread() at the end of the TRIM to update the * trim_state in the header too. When reading the header, if * trim_state is not VDEV_TRIM_COMPLETE and l2arc_trim_ahead > 0 * we opt to TRIM the whole device again. */ if (l2arc_trim_ahead > 0) { dev->l2ad_trim_all = B_TRUE; } else { memset(l2dhdr, 0, l2dhdr_asize); l2arc_dev_hdr_update(dev); } } } /* * Add a vdev for use by the L2ARC. By this point the spa has already * validated the vdev and opened it. */ void l2arc_add_vdev(spa_t *spa, vdev_t *vd) { l2arc_dev_t *adddev; uint64_t l2dhdr_asize; ASSERT(!l2arc_vdev_present(vd)); /* * Create a new l2arc device entry. */ adddev = vmem_zalloc(sizeof (l2arc_dev_t), KM_SLEEP); adddev->l2ad_spa = spa; adddev->l2ad_vdev = vd; /* leave extra size for an l2arc device header */ l2dhdr_asize = adddev->l2ad_dev_hdr_asize = MAX(sizeof (*adddev->l2ad_dev_hdr), 1 << vd->vdev_ashift); adddev->l2ad_start = VDEV_LABEL_START_SIZE + l2dhdr_asize; adddev->l2ad_end = VDEV_LABEL_START_SIZE + vdev_get_min_asize(vd); ASSERT3U(adddev->l2ad_start, <, adddev->l2ad_end); adddev->l2ad_hand = adddev->l2ad_start; adddev->l2ad_evict = adddev->l2ad_start; adddev->l2ad_first = B_TRUE; adddev->l2ad_writing = B_FALSE; adddev->l2ad_trim_all = B_FALSE; list_link_init(&adddev->l2ad_node); adddev->l2ad_dev_hdr = kmem_zalloc(l2dhdr_asize, KM_SLEEP); mutex_init(&adddev->l2ad_mtx, NULL, MUTEX_DEFAULT, NULL); /* * This is a list of all ARC buffers that are still valid on the * device. */ list_create(&adddev->l2ad_buflist, sizeof (arc_buf_hdr_t), offsetof(arc_buf_hdr_t, b_l2hdr.b_l2node)); /* * This is a list of pointers to log blocks that are still present * on the device. */ list_create(&adddev->l2ad_lbptr_list, sizeof (l2arc_lb_ptr_buf_t), offsetof(l2arc_lb_ptr_buf_t, node)); vdev_space_update(vd, 0, 0, adddev->l2ad_end - adddev->l2ad_hand); zfs_refcount_create(&adddev->l2ad_alloc); zfs_refcount_create(&adddev->l2ad_lb_asize); zfs_refcount_create(&adddev->l2ad_lb_count); /* * Decide if dev is eligible for L2ARC rebuild or whole device * trimming. This has to happen before the device is added in the * cache device list and l2arc_dev_mtx is released. Otherwise * l2arc_feed_thread() might already start writing on the * device. */ l2arc_rebuild_dev(adddev, B_FALSE); /* * Add device to global list */ mutex_enter(&l2arc_dev_mtx); list_insert_head(l2arc_dev_list, adddev); atomic_inc_64(&l2arc_ndev); mutex_exit(&l2arc_dev_mtx); } /* * Decide if a vdev is eligible for L2ARC rebuild, called from vdev_reopen() * in case of onlining a cache device. */ void l2arc_rebuild_vdev(vdev_t *vd, boolean_t reopen) { l2arc_dev_t *dev = NULL; dev = l2arc_vdev_get(vd); ASSERT3P(dev, !=, NULL); /* * In contrast to l2arc_add_vdev() we do not have to worry about * l2arc_feed_thread() invalidating previous content when onlining a * cache device. The device parameters (l2ad*) are not cleared when * offlining the device and writing new buffers will not invalidate * all previous content. In worst case only buffers that have not had * their log block written to the device will be lost. * When onlining the cache device (ie offline->online without exporting * the pool in between) this happens: * vdev_reopen() -> vdev_open() -> l2arc_rebuild_vdev() * | | * vdev_is_dead() = B_FALSE l2ad_rebuild = B_TRUE * During the time where vdev_is_dead = B_FALSE and until l2ad_rebuild * is set to B_TRUE we might write additional buffers to the device. */ l2arc_rebuild_dev(dev, reopen); } /* * Remove a vdev from the L2ARC. */ void l2arc_remove_vdev(vdev_t *vd) { l2arc_dev_t *remdev = NULL; /* * Find the device by vdev */ remdev = l2arc_vdev_get(vd); ASSERT3P(remdev, !=, NULL); /* * Cancel any ongoing or scheduled rebuild. */ mutex_enter(&l2arc_rebuild_thr_lock); if (remdev->l2ad_rebuild_began == B_TRUE) { remdev->l2ad_rebuild_cancel = B_TRUE; while (remdev->l2ad_rebuild == B_TRUE) cv_wait(&l2arc_rebuild_thr_cv, &l2arc_rebuild_thr_lock); } mutex_exit(&l2arc_rebuild_thr_lock); /* * Remove device from global list */ mutex_enter(&l2arc_dev_mtx); list_remove(l2arc_dev_list, remdev); l2arc_dev_last = NULL; /* may have been invalidated */ atomic_dec_64(&l2arc_ndev); mutex_exit(&l2arc_dev_mtx); /* * Clear all buflists and ARC references. L2ARC device flush. */ l2arc_evict(remdev, 0, B_TRUE); list_destroy(&remdev->l2ad_buflist); ASSERT(list_is_empty(&remdev->l2ad_lbptr_list)); list_destroy(&remdev->l2ad_lbptr_list); mutex_destroy(&remdev->l2ad_mtx); zfs_refcount_destroy(&remdev->l2ad_alloc); zfs_refcount_destroy(&remdev->l2ad_lb_asize); zfs_refcount_destroy(&remdev->l2ad_lb_count); kmem_free(remdev->l2ad_dev_hdr, remdev->l2ad_dev_hdr_asize); vmem_free(remdev, sizeof (l2arc_dev_t)); } void l2arc_init(void) { l2arc_thread_exit = 0; l2arc_ndev = 0; mutex_init(&l2arc_feed_thr_lock, NULL, MUTEX_DEFAULT, NULL); cv_init(&l2arc_feed_thr_cv, NULL, CV_DEFAULT, NULL); mutex_init(&l2arc_rebuild_thr_lock, NULL, MUTEX_DEFAULT, NULL); cv_init(&l2arc_rebuild_thr_cv, NULL, CV_DEFAULT, NULL); mutex_init(&l2arc_dev_mtx, NULL, MUTEX_DEFAULT, NULL); mutex_init(&l2arc_free_on_write_mtx, NULL, MUTEX_DEFAULT, NULL); l2arc_dev_list = &L2ARC_dev_list; l2arc_free_on_write = &L2ARC_free_on_write; list_create(l2arc_dev_list, sizeof (l2arc_dev_t), offsetof(l2arc_dev_t, l2ad_node)); list_create(l2arc_free_on_write, sizeof (l2arc_data_free_t), offsetof(l2arc_data_free_t, l2df_list_node)); } void l2arc_fini(void) { mutex_destroy(&l2arc_feed_thr_lock); cv_destroy(&l2arc_feed_thr_cv); mutex_destroy(&l2arc_rebuild_thr_lock); cv_destroy(&l2arc_rebuild_thr_cv); mutex_destroy(&l2arc_dev_mtx); mutex_destroy(&l2arc_free_on_write_mtx); list_destroy(l2arc_dev_list); list_destroy(l2arc_free_on_write); } void l2arc_start(void) { if (!(spa_mode_global & SPA_MODE_WRITE)) return; (void) thread_create(NULL, 0, l2arc_feed_thread, NULL, 0, &p0, TS_RUN, defclsyspri); } void l2arc_stop(void) { if (!(spa_mode_global & SPA_MODE_WRITE)) return; mutex_enter(&l2arc_feed_thr_lock); cv_signal(&l2arc_feed_thr_cv); /* kick thread out of startup */ l2arc_thread_exit = 1; while (l2arc_thread_exit != 0) cv_wait(&l2arc_feed_thr_cv, &l2arc_feed_thr_lock); mutex_exit(&l2arc_feed_thr_lock); } /* * Punches out rebuild threads for the L2ARC devices in a spa. This should * be called after pool import from the spa async thread, since starting * these threads directly from spa_import() will make them part of the * "zpool import" context and delay process exit (and thus pool import). */ void l2arc_spa_rebuild_start(spa_t *spa) { ASSERT(MUTEX_HELD(&spa_namespace_lock)); /* * Locate the spa's l2arc devices and kick off rebuild threads. */ for (int i = 0; i < spa->spa_l2cache.sav_count; i++) { l2arc_dev_t *dev = l2arc_vdev_get(spa->spa_l2cache.sav_vdevs[i]); if (dev == NULL) { /* Don't attempt a rebuild if the vdev is UNAVAIL */ continue; } mutex_enter(&l2arc_rebuild_thr_lock); if (dev->l2ad_rebuild && !dev->l2ad_rebuild_cancel) { dev->l2ad_rebuild_began = B_TRUE; (void) thread_create(NULL, 0, l2arc_dev_rebuild_thread, dev, 0, &p0, TS_RUN, minclsyspri); } mutex_exit(&l2arc_rebuild_thr_lock); } } /* * Main entry point for L2ARC rebuilding. */ static __attribute__((noreturn)) void l2arc_dev_rebuild_thread(void *arg) { l2arc_dev_t *dev = arg; VERIFY(!dev->l2ad_rebuild_cancel); VERIFY(dev->l2ad_rebuild); (void) l2arc_rebuild(dev); mutex_enter(&l2arc_rebuild_thr_lock); dev->l2ad_rebuild_began = B_FALSE; dev->l2ad_rebuild = B_FALSE; mutex_exit(&l2arc_rebuild_thr_lock); thread_exit(); } /* * This function implements the actual L2ARC metadata rebuild. It: * starts reading the log block chain and restores each block's contents * to memory (reconstructing arc_buf_hdr_t's). * * Operation stops under any of the following conditions: * * 1) We reach the end of the log block chain. * 2) We encounter *any* error condition (cksum errors, io errors) */ static int l2arc_rebuild(l2arc_dev_t *dev) { vdev_t *vd = dev->l2ad_vdev; spa_t *spa = vd->vdev_spa; int err = 0; l2arc_dev_hdr_phys_t *l2dhdr = dev->l2ad_dev_hdr; l2arc_log_blk_phys_t *this_lb, *next_lb; zio_t *this_io = NULL, *next_io = NULL; l2arc_log_blkptr_t lbps[2]; l2arc_lb_ptr_buf_t *lb_ptr_buf; boolean_t lock_held; this_lb = vmem_zalloc(sizeof (*this_lb), KM_SLEEP); next_lb = vmem_zalloc(sizeof (*next_lb), KM_SLEEP); /* * We prevent device removal while issuing reads to the device, * then during the rebuilding phases we drop this lock again so * that a spa_unload or device remove can be initiated - this is * safe, because the spa will signal us to stop before removing * our device and wait for us to stop. */ spa_config_enter(spa, SCL_L2ARC, vd, RW_READER); lock_held = B_TRUE; /* * Retrieve the persistent L2ARC device state. * L2BLK_GET_PSIZE returns aligned size for log blocks. */ dev->l2ad_evict = MAX(l2dhdr->dh_evict, dev->l2ad_start); dev->l2ad_hand = MAX(l2dhdr->dh_start_lbps[0].lbp_daddr + L2BLK_GET_PSIZE((&l2dhdr->dh_start_lbps[0])->lbp_prop), dev->l2ad_start); dev->l2ad_first = !!(l2dhdr->dh_flags & L2ARC_DEV_HDR_EVICT_FIRST); vd->vdev_trim_action_time = l2dhdr->dh_trim_action_time; vd->vdev_trim_state = l2dhdr->dh_trim_state; /* * In case the zfs module parameter l2arc_rebuild_enabled is false * we do not start the rebuild process. */ if (!l2arc_rebuild_enabled) goto out; /* Prepare the rebuild process */ memcpy(lbps, l2dhdr->dh_start_lbps, sizeof (lbps)); /* Start the rebuild process */ for (;;) { if (!l2arc_log_blkptr_valid(dev, &lbps[0])) break; if ((err = l2arc_log_blk_read(dev, &lbps[0], &lbps[1], this_lb, next_lb, this_io, &next_io)) != 0) goto out; /* * Our memory pressure valve. If the system is running low * on memory, rather than swamping memory with new ARC buf * hdrs, we opt not to rebuild the L2ARC. At this point, * however, we have already set up our L2ARC dev to chain in * new metadata log blocks, so the user may choose to offline/ * online the L2ARC dev at a later time (or re-import the pool) * to reconstruct it (when there's less memory pressure). */ if (l2arc_hdr_limit_reached()) { ARCSTAT_BUMP(arcstat_l2_rebuild_abort_lowmem); cmn_err(CE_NOTE, "System running low on memory, " "aborting L2ARC rebuild."); err = SET_ERROR(ENOMEM); goto out; } spa_config_exit(spa, SCL_L2ARC, vd); lock_held = B_FALSE; /* * Now that we know that the next_lb checks out alright, we * can start reconstruction from this log block. * L2BLK_GET_PSIZE returns aligned size for log blocks. */ uint64_t asize = L2BLK_GET_PSIZE((&lbps[0])->lbp_prop); l2arc_log_blk_restore(dev, this_lb, asize); /* * log block restored, include its pointer in the list of * pointers to log blocks present in the L2ARC device. */ lb_ptr_buf = kmem_zalloc(sizeof (l2arc_lb_ptr_buf_t), KM_SLEEP); lb_ptr_buf->lb_ptr = kmem_zalloc(sizeof (l2arc_log_blkptr_t), KM_SLEEP); memcpy(lb_ptr_buf->lb_ptr, &lbps[0], sizeof (l2arc_log_blkptr_t)); mutex_enter(&dev->l2ad_mtx); list_insert_tail(&dev->l2ad_lbptr_list, lb_ptr_buf); ARCSTAT_INCR(arcstat_l2_log_blk_asize, asize); ARCSTAT_BUMP(arcstat_l2_log_blk_count); zfs_refcount_add_many(&dev->l2ad_lb_asize, asize, lb_ptr_buf); zfs_refcount_add(&dev->l2ad_lb_count, lb_ptr_buf); mutex_exit(&dev->l2ad_mtx); vdev_space_update(vd, asize, 0, 0); /* * Protection against loops of log blocks: * * l2ad_hand l2ad_evict * V V * l2ad_start |=======================================| l2ad_end * -----|||----|||---|||----||| * (3) (2) (1) (0) * ---|||---|||----|||---||| * (7) (6) (5) (4) * * In this situation the pointer of log block (4) passes * l2arc_log_blkptr_valid() but the log block should not be * restored as it is overwritten by the payload of log block * (0). Only log blocks (0)-(3) should be restored. We check * whether l2ad_evict lies in between the payload starting * offset of the next log block (lbps[1].lbp_payload_start) * and the payload starting offset of the present log block * (lbps[0].lbp_payload_start). If true and this isn't the * first pass, we are looping from the beginning and we should * stop. */ if (l2arc_range_check_overlap(lbps[1].lbp_payload_start, lbps[0].lbp_payload_start, dev->l2ad_evict) && !dev->l2ad_first) goto out; kpreempt(KPREEMPT_SYNC); for (;;) { mutex_enter(&l2arc_rebuild_thr_lock); if (dev->l2ad_rebuild_cancel) { dev->l2ad_rebuild = B_FALSE; cv_signal(&l2arc_rebuild_thr_cv); mutex_exit(&l2arc_rebuild_thr_lock); err = SET_ERROR(ECANCELED); goto out; } mutex_exit(&l2arc_rebuild_thr_lock); if (spa_config_tryenter(spa, SCL_L2ARC, vd, RW_READER)) { lock_held = B_TRUE; break; } /* * L2ARC config lock held by somebody in writer, * possibly due to them trying to remove us. They'll * likely to want us to shut down, so after a little * delay, we check l2ad_rebuild_cancel and retry * the lock again. */ delay(1); } /* * Continue with the next log block. */ lbps[0] = lbps[1]; lbps[1] = this_lb->lb_prev_lbp; PTR_SWAP(this_lb, next_lb); this_io = next_io; next_io = NULL; } if (this_io != NULL) l2arc_log_blk_fetch_abort(this_io); out: if (next_io != NULL) l2arc_log_blk_fetch_abort(next_io); vmem_free(this_lb, sizeof (*this_lb)); vmem_free(next_lb, sizeof (*next_lb)); if (!l2arc_rebuild_enabled) { spa_history_log_internal(spa, "L2ARC rebuild", NULL, "disabled"); } else if (err == 0 && zfs_refcount_count(&dev->l2ad_lb_count) > 0) { ARCSTAT_BUMP(arcstat_l2_rebuild_success); spa_history_log_internal(spa, "L2ARC rebuild", NULL, "successful, restored %llu blocks", (u_longlong_t)zfs_refcount_count(&dev->l2ad_lb_count)); } else if (err == 0 && zfs_refcount_count(&dev->l2ad_lb_count) == 0) { /* * No error but also nothing restored, meaning the lbps array * in the device header points to invalid/non-present log * blocks. Reset the header. */ spa_history_log_internal(spa, "L2ARC rebuild", NULL, "no valid log blocks"); memset(l2dhdr, 0, dev->l2ad_dev_hdr_asize); l2arc_dev_hdr_update(dev); } else if (err == ECANCELED) { /* * In case the rebuild was canceled do not log to spa history * log as the pool may be in the process of being removed. */ zfs_dbgmsg("L2ARC rebuild aborted, restored %llu blocks", (u_longlong_t)zfs_refcount_count(&dev->l2ad_lb_count)); } else if (err != 0) { spa_history_log_internal(spa, "L2ARC rebuild", NULL, "aborted, restored %llu blocks", (u_longlong_t)zfs_refcount_count(&dev->l2ad_lb_count)); } if (lock_held) spa_config_exit(spa, SCL_L2ARC, vd); return (err); } /* * Attempts to read the device header on the provided L2ARC device and writes * it to `hdr'. On success, this function returns 0, otherwise the appropriate * error code is returned. */ static int l2arc_dev_hdr_read(l2arc_dev_t *dev) { int err; uint64_t guid; l2arc_dev_hdr_phys_t *l2dhdr = dev->l2ad_dev_hdr; const uint64_t l2dhdr_asize = dev->l2ad_dev_hdr_asize; abd_t *abd; guid = spa_guid(dev->l2ad_vdev->vdev_spa); abd = abd_get_from_buf(l2dhdr, l2dhdr_asize); err = zio_wait(zio_read_phys(NULL, dev->l2ad_vdev, VDEV_LABEL_START_SIZE, l2dhdr_asize, abd, ZIO_CHECKSUM_LABEL, NULL, NULL, ZIO_PRIORITY_SYNC_READ, ZIO_FLAG_CANFAIL | ZIO_FLAG_DONT_PROPAGATE | ZIO_FLAG_DONT_RETRY | ZIO_FLAG_SPECULATIVE, B_FALSE)); abd_free(abd); if (err != 0) { ARCSTAT_BUMP(arcstat_l2_rebuild_abort_dh_errors); zfs_dbgmsg("L2ARC IO error (%d) while reading device header, " "vdev guid: %llu", err, (u_longlong_t)dev->l2ad_vdev->vdev_guid); return (err); } if (l2dhdr->dh_magic == BSWAP_64(L2ARC_DEV_HDR_MAGIC)) byteswap_uint64_array(l2dhdr, sizeof (*l2dhdr)); if (l2dhdr->dh_magic != L2ARC_DEV_HDR_MAGIC || l2dhdr->dh_spa_guid != guid || l2dhdr->dh_vdev_guid != dev->l2ad_vdev->vdev_guid || l2dhdr->dh_version != L2ARC_PERSISTENT_VERSION || l2dhdr->dh_log_entries != dev->l2ad_log_entries || l2dhdr->dh_end != dev->l2ad_end || !l2arc_range_check_overlap(dev->l2ad_start, dev->l2ad_end, l2dhdr->dh_evict) || (l2dhdr->dh_trim_state != VDEV_TRIM_COMPLETE && l2arc_trim_ahead > 0)) { /* * Attempt to rebuild a device containing no actual dev hdr * or containing a header from some other pool or from another * version of persistent L2ARC. */ ARCSTAT_BUMP(arcstat_l2_rebuild_abort_unsupported); return (SET_ERROR(ENOTSUP)); } return (0); } /* * Reads L2ARC log blocks from storage and validates their contents. * * This function implements a simple fetcher to make sure that while * we're processing one buffer the L2ARC is already fetching the next * one in the chain. * * The arguments this_lp and next_lp point to the current and next log block * address in the block chain. Similarly, this_lb and next_lb hold the * l2arc_log_blk_phys_t's of the current and next L2ARC blk. * * The `this_io' and `next_io' arguments are used for block fetching. * When issuing the first blk IO during rebuild, you should pass NULL for * `this_io'. This function will then issue a sync IO to read the block and * also issue an async IO to fetch the next block in the block chain. The * fetched IO is returned in `next_io'. On subsequent calls to this * function, pass the value returned in `next_io' from the previous call * as `this_io' and a fresh `next_io' pointer to hold the next fetch IO. * Prior to the call, you should initialize your `next_io' pointer to be * NULL. If no fetch IO was issued, the pointer is left set at NULL. * * On success, this function returns 0, otherwise it returns an appropriate * error code. On error the fetching IO is aborted and cleared before * returning from this function. Therefore, if we return `success', the * caller can assume that we have taken care of cleanup of fetch IOs. */ static int l2arc_log_blk_read(l2arc_dev_t *dev, const l2arc_log_blkptr_t *this_lbp, const l2arc_log_blkptr_t *next_lbp, l2arc_log_blk_phys_t *this_lb, l2arc_log_blk_phys_t *next_lb, zio_t *this_io, zio_t **next_io) { int err = 0; zio_cksum_t cksum; abd_t *abd = NULL; uint64_t asize; ASSERT(this_lbp != NULL && next_lbp != NULL); ASSERT(this_lb != NULL && next_lb != NULL); ASSERT(next_io != NULL && *next_io == NULL); ASSERT(l2arc_log_blkptr_valid(dev, this_lbp)); /* * Check to see if we have issued the IO for this log block in a * previous run. If not, this is the first call, so issue it now. */ if (this_io == NULL) { this_io = l2arc_log_blk_fetch(dev->l2ad_vdev, this_lbp, this_lb); } /* * Peek to see if we can start issuing the next IO immediately. */ if (l2arc_log_blkptr_valid(dev, next_lbp)) { /* * Start issuing IO for the next log block early - this * should help keep the L2ARC device busy while we * decompress and restore this log block. */ *next_io = l2arc_log_blk_fetch(dev->l2ad_vdev, next_lbp, next_lb); } /* Wait for the IO to read this log block to complete */ if ((err = zio_wait(this_io)) != 0) { ARCSTAT_BUMP(arcstat_l2_rebuild_abort_io_errors); zfs_dbgmsg("L2ARC IO error (%d) while reading log block, " "offset: %llu, vdev guid: %llu", err, (u_longlong_t)this_lbp->lbp_daddr, (u_longlong_t)dev->l2ad_vdev->vdev_guid); goto cleanup; } /* * Make sure the buffer checks out. * L2BLK_GET_PSIZE returns aligned size for log blocks. */ asize = L2BLK_GET_PSIZE((this_lbp)->lbp_prop); fletcher_4_native(this_lb, asize, NULL, &cksum); if (!ZIO_CHECKSUM_EQUAL(cksum, this_lbp->lbp_cksum)) { ARCSTAT_BUMP(arcstat_l2_rebuild_abort_cksum_lb_errors); zfs_dbgmsg("L2ARC log block cksum failed, offset: %llu, " "vdev guid: %llu, l2ad_hand: %llu, l2ad_evict: %llu", (u_longlong_t)this_lbp->lbp_daddr, (u_longlong_t)dev->l2ad_vdev->vdev_guid, (u_longlong_t)dev->l2ad_hand, (u_longlong_t)dev->l2ad_evict); err = SET_ERROR(ECKSUM); goto cleanup; } /* Now we can take our time decoding this buffer */ switch (L2BLK_GET_COMPRESS((this_lbp)->lbp_prop)) { case ZIO_COMPRESS_OFF: break; case ZIO_COMPRESS_LZ4: abd = abd_alloc_for_io(asize, B_TRUE); abd_copy_from_buf_off(abd, this_lb, 0, asize); if ((err = zio_decompress_data( L2BLK_GET_COMPRESS((this_lbp)->lbp_prop), abd, this_lb, asize, sizeof (*this_lb), NULL)) != 0) { err = SET_ERROR(EINVAL); goto cleanup; } break; default: err = SET_ERROR(EINVAL); goto cleanup; } if (this_lb->lb_magic == BSWAP_64(L2ARC_LOG_BLK_MAGIC)) byteswap_uint64_array(this_lb, sizeof (*this_lb)); if (this_lb->lb_magic != L2ARC_LOG_BLK_MAGIC) { err = SET_ERROR(EINVAL); goto cleanup; } cleanup: /* Abort an in-flight fetch I/O in case of error */ if (err != 0 && *next_io != NULL) { l2arc_log_blk_fetch_abort(*next_io); *next_io = NULL; } if (abd != NULL) abd_free(abd); return (err); } /* * Restores the payload of a log block to ARC. This creates empty ARC hdr * entries which only contain an l2arc hdr, essentially restoring the * buffers to their L2ARC evicted state. This function also updates space * usage on the L2ARC vdev to make sure it tracks restored buffers. */ static void l2arc_log_blk_restore(l2arc_dev_t *dev, const l2arc_log_blk_phys_t *lb, uint64_t lb_asize) { uint64_t size = 0, asize = 0; uint64_t log_entries = dev->l2ad_log_entries; /* * Usually arc_adapt() is called only for data, not headers, but * since we may allocate significant amount of memory here, let ARC * grow its arc_c. */ arc_adapt(log_entries * HDR_L2ONLY_SIZE); for (int i = log_entries - 1; i >= 0; i--) { /* * Restore goes in the reverse temporal direction to preserve * correct temporal ordering of buffers in the l2ad_buflist. * l2arc_hdr_restore also does a list_insert_tail instead of * list_insert_head on the l2ad_buflist: * * LIST l2ad_buflist LIST * HEAD <------ (time) ------ TAIL * direction +-----+-----+-----+-----+-----+ direction * of l2arc <== | buf | buf | buf | buf | buf | ===> of rebuild * fill +-----+-----+-----+-----+-----+ * ^ ^ * | | * | | * l2arc_feed_thread l2arc_rebuild * will place new bufs here restores bufs here * * During l2arc_rebuild() the device is not used by * l2arc_feed_thread() as dev->l2ad_rebuild is set to true. */ size += L2BLK_GET_LSIZE((&lb->lb_entries[i])->le_prop); asize += vdev_psize_to_asize(dev->l2ad_vdev, L2BLK_GET_PSIZE((&lb->lb_entries[i])->le_prop)); l2arc_hdr_restore(&lb->lb_entries[i], dev); } /* * Record rebuild stats: * size Logical size of restored buffers in the L2ARC * asize Aligned size of restored buffers in the L2ARC */ ARCSTAT_INCR(arcstat_l2_rebuild_size, size); ARCSTAT_INCR(arcstat_l2_rebuild_asize, asize); ARCSTAT_INCR(arcstat_l2_rebuild_bufs, log_entries); ARCSTAT_F_AVG(arcstat_l2_log_blk_avg_asize, lb_asize); ARCSTAT_F_AVG(arcstat_l2_data_to_meta_ratio, asize / lb_asize); ARCSTAT_BUMP(arcstat_l2_rebuild_log_blks); } /* * Restores a single ARC buf hdr from a log entry. The ARC buffer is put * into a state indicating that it has been evicted to L2ARC. */ static void l2arc_hdr_restore(const l2arc_log_ent_phys_t *le, l2arc_dev_t *dev) { arc_buf_hdr_t *hdr, *exists; kmutex_t *hash_lock; arc_buf_contents_t type = L2BLK_GET_TYPE((le)->le_prop); uint64_t asize; /* * Do all the allocation before grabbing any locks, this lets us * sleep if memory is full and we don't have to deal with failed * allocations. */ hdr = arc_buf_alloc_l2only(L2BLK_GET_LSIZE((le)->le_prop), type, dev, le->le_dva, le->le_daddr, L2BLK_GET_PSIZE((le)->le_prop), le->le_birth, L2BLK_GET_COMPRESS((le)->le_prop), le->le_complevel, L2BLK_GET_PROTECTED((le)->le_prop), L2BLK_GET_PREFETCH((le)->le_prop), L2BLK_GET_STATE((le)->le_prop)); asize = vdev_psize_to_asize(dev->l2ad_vdev, L2BLK_GET_PSIZE((le)->le_prop)); /* * vdev_space_update() has to be called before arc_hdr_destroy() to * avoid underflow since the latter also calls vdev_space_update(). */ l2arc_hdr_arcstats_increment(hdr); vdev_space_update(dev->l2ad_vdev, asize, 0, 0); mutex_enter(&dev->l2ad_mtx); list_insert_tail(&dev->l2ad_buflist, hdr); (void) zfs_refcount_add_many(&dev->l2ad_alloc, arc_hdr_size(hdr), hdr); mutex_exit(&dev->l2ad_mtx); exists = buf_hash_insert(hdr, &hash_lock); if (exists) { /* Buffer was already cached, no need to restore it. */ arc_hdr_destroy(hdr); /* * If the buffer is already cached, check whether it has * L2ARC metadata. If not, enter them and update the flag. * This is important is case of onlining a cache device, since * we previously evicted all L2ARC metadata from ARC. */ if (!HDR_HAS_L2HDR(exists)) { arc_hdr_set_flags(exists, ARC_FLAG_HAS_L2HDR); exists->b_l2hdr.b_dev = dev; exists->b_l2hdr.b_daddr = le->le_daddr; exists->b_l2hdr.b_arcs_state = L2BLK_GET_STATE((le)->le_prop); mutex_enter(&dev->l2ad_mtx); list_insert_tail(&dev->l2ad_buflist, exists); (void) zfs_refcount_add_many(&dev->l2ad_alloc, arc_hdr_size(exists), exists); mutex_exit(&dev->l2ad_mtx); l2arc_hdr_arcstats_increment(exists); vdev_space_update(dev->l2ad_vdev, asize, 0, 0); } ARCSTAT_BUMP(arcstat_l2_rebuild_bufs_precached); } mutex_exit(hash_lock); } /* * Starts an asynchronous read IO to read a log block. This is used in log * block reconstruction to start reading the next block before we are done * decoding and reconstructing the current block, to keep the l2arc device * nice and hot with read IO to process. * The returned zio will contain a newly allocated memory buffers for the IO * data which should then be freed by the caller once the zio is no longer * needed (i.e. due to it having completed). If you wish to abort this * zio, you should do so using l2arc_log_blk_fetch_abort, which takes * care of disposing of the allocated buffers correctly. */ static zio_t * l2arc_log_blk_fetch(vdev_t *vd, const l2arc_log_blkptr_t *lbp, l2arc_log_blk_phys_t *lb) { uint32_t asize; zio_t *pio; l2arc_read_callback_t *cb; /* L2BLK_GET_PSIZE returns aligned size for log blocks */ asize = L2BLK_GET_PSIZE((lbp)->lbp_prop); ASSERT(asize <= sizeof (l2arc_log_blk_phys_t)); cb = kmem_zalloc(sizeof (l2arc_read_callback_t), KM_SLEEP); cb->l2rcb_abd = abd_get_from_buf(lb, asize); pio = zio_root(vd->vdev_spa, l2arc_blk_fetch_done, cb, ZIO_FLAG_CANFAIL | ZIO_FLAG_DONT_PROPAGATE | ZIO_FLAG_DONT_RETRY); (void) zio_nowait(zio_read_phys(pio, vd, lbp->lbp_daddr, asize, cb->l2rcb_abd, ZIO_CHECKSUM_OFF, NULL, NULL, ZIO_PRIORITY_ASYNC_READ, ZIO_FLAG_CANFAIL | ZIO_FLAG_DONT_PROPAGATE | ZIO_FLAG_DONT_RETRY, B_FALSE)); return (pio); } /* * Aborts a zio returned from l2arc_log_blk_fetch and frees the data * buffers allocated for it. */ static void l2arc_log_blk_fetch_abort(zio_t *zio) { (void) zio_wait(zio); } /* * Creates a zio to update the device header on an l2arc device. */ void l2arc_dev_hdr_update(l2arc_dev_t *dev) { l2arc_dev_hdr_phys_t *l2dhdr = dev->l2ad_dev_hdr; const uint64_t l2dhdr_asize = dev->l2ad_dev_hdr_asize; abd_t *abd; int err; VERIFY(spa_config_held(dev->l2ad_spa, SCL_STATE_ALL, RW_READER)); l2dhdr->dh_magic = L2ARC_DEV_HDR_MAGIC; l2dhdr->dh_version = L2ARC_PERSISTENT_VERSION; l2dhdr->dh_spa_guid = spa_guid(dev->l2ad_vdev->vdev_spa); l2dhdr->dh_vdev_guid = dev->l2ad_vdev->vdev_guid; l2dhdr->dh_log_entries = dev->l2ad_log_entries; l2dhdr->dh_evict = dev->l2ad_evict; l2dhdr->dh_start = dev->l2ad_start; l2dhdr->dh_end = dev->l2ad_end; l2dhdr->dh_lb_asize = zfs_refcount_count(&dev->l2ad_lb_asize); l2dhdr->dh_lb_count = zfs_refcount_count(&dev->l2ad_lb_count); l2dhdr->dh_flags = 0; l2dhdr->dh_trim_action_time = dev->l2ad_vdev->vdev_trim_action_time; l2dhdr->dh_trim_state = dev->l2ad_vdev->vdev_trim_state; if (dev->l2ad_first) l2dhdr->dh_flags |= L2ARC_DEV_HDR_EVICT_FIRST; abd = abd_get_from_buf(l2dhdr, l2dhdr_asize); err = zio_wait(zio_write_phys(NULL, dev->l2ad_vdev, VDEV_LABEL_START_SIZE, l2dhdr_asize, abd, ZIO_CHECKSUM_LABEL, NULL, NULL, ZIO_PRIORITY_ASYNC_WRITE, ZIO_FLAG_CANFAIL, B_FALSE)); abd_free(abd); if (err != 0) { zfs_dbgmsg("L2ARC IO error (%d) while writing device header, " "vdev guid: %llu", err, (u_longlong_t)dev->l2ad_vdev->vdev_guid); } } /* * Commits a log block to the L2ARC device. This routine is invoked from * l2arc_write_buffers when the log block fills up. * This function allocates some memory to temporarily hold the serialized * buffer to be written. This is then released in l2arc_write_done. */ static uint64_t l2arc_log_blk_commit(l2arc_dev_t *dev, zio_t *pio, l2arc_write_callback_t *cb) { l2arc_log_blk_phys_t *lb = &dev->l2ad_log_blk; l2arc_dev_hdr_phys_t *l2dhdr = dev->l2ad_dev_hdr; uint64_t psize, asize; zio_t *wzio; l2arc_lb_abd_buf_t *abd_buf; uint8_t *tmpbuf = NULL; l2arc_lb_ptr_buf_t *lb_ptr_buf; VERIFY3S(dev->l2ad_log_ent_idx, ==, dev->l2ad_log_entries); abd_buf = zio_buf_alloc(sizeof (*abd_buf)); abd_buf->abd = abd_get_from_buf(lb, sizeof (*lb)); lb_ptr_buf = kmem_zalloc(sizeof (l2arc_lb_ptr_buf_t), KM_SLEEP); lb_ptr_buf->lb_ptr = kmem_zalloc(sizeof (l2arc_log_blkptr_t), KM_SLEEP); /* link the buffer into the block chain */ lb->lb_prev_lbp = l2dhdr->dh_start_lbps[1]; lb->lb_magic = L2ARC_LOG_BLK_MAGIC; /* * l2arc_log_blk_commit() may be called multiple times during a single * l2arc_write_buffers() call. Save the allocated abd buffers in a list * so we can free them in l2arc_write_done() later on. */ list_insert_tail(&cb->l2wcb_abd_list, abd_buf); /* try to compress the buffer */ psize = zio_compress_data(ZIO_COMPRESS_LZ4, abd_buf->abd, (void **) &tmpbuf, sizeof (*lb), 0); /* a log block is never entirely zero */ ASSERT(psize != 0); asize = vdev_psize_to_asize(dev->l2ad_vdev, psize); ASSERT(asize <= sizeof (*lb)); /* * Update the start log block pointer in the device header to point * to the log block we're about to write. */ l2dhdr->dh_start_lbps[1] = l2dhdr->dh_start_lbps[0]; l2dhdr->dh_start_lbps[0].lbp_daddr = dev->l2ad_hand; l2dhdr->dh_start_lbps[0].lbp_payload_asize = dev->l2ad_log_blk_payload_asize; l2dhdr->dh_start_lbps[0].lbp_payload_start = dev->l2ad_log_blk_payload_start; L2BLK_SET_LSIZE( (&l2dhdr->dh_start_lbps[0])->lbp_prop, sizeof (*lb)); L2BLK_SET_PSIZE( (&l2dhdr->dh_start_lbps[0])->lbp_prop, asize); L2BLK_SET_CHECKSUM( (&l2dhdr->dh_start_lbps[0])->lbp_prop, ZIO_CHECKSUM_FLETCHER_4); if (asize < sizeof (*lb)) { /* compression succeeded */ memset(tmpbuf + psize, 0, asize - psize); L2BLK_SET_COMPRESS( (&l2dhdr->dh_start_lbps[0])->lbp_prop, ZIO_COMPRESS_LZ4); } else { /* compression failed */ memcpy(tmpbuf, lb, sizeof (*lb)); L2BLK_SET_COMPRESS( (&l2dhdr->dh_start_lbps[0])->lbp_prop, ZIO_COMPRESS_OFF); } /* checksum what we're about to write */ fletcher_4_native(tmpbuf, asize, NULL, &l2dhdr->dh_start_lbps[0].lbp_cksum); abd_free(abd_buf->abd); /* perform the write itself */ abd_buf->abd = abd_get_from_buf(tmpbuf, sizeof (*lb)); abd_take_ownership_of_buf(abd_buf->abd, B_TRUE); wzio = zio_write_phys(pio, dev->l2ad_vdev, dev->l2ad_hand, asize, abd_buf->abd, ZIO_CHECKSUM_OFF, NULL, NULL, ZIO_PRIORITY_ASYNC_WRITE, ZIO_FLAG_CANFAIL, B_FALSE); DTRACE_PROBE2(l2arc__write, vdev_t *, dev->l2ad_vdev, zio_t *, wzio); (void) zio_nowait(wzio); dev->l2ad_hand += asize; /* * Include the committed log block's pointer in the list of pointers * to log blocks present in the L2ARC device. */ memcpy(lb_ptr_buf->lb_ptr, &l2dhdr->dh_start_lbps[0], sizeof (l2arc_log_blkptr_t)); mutex_enter(&dev->l2ad_mtx); list_insert_head(&dev->l2ad_lbptr_list, lb_ptr_buf); ARCSTAT_INCR(arcstat_l2_log_blk_asize, asize); ARCSTAT_BUMP(arcstat_l2_log_blk_count); zfs_refcount_add_many(&dev->l2ad_lb_asize, asize, lb_ptr_buf); zfs_refcount_add(&dev->l2ad_lb_count, lb_ptr_buf); mutex_exit(&dev->l2ad_mtx); vdev_space_update(dev->l2ad_vdev, asize, 0, 0); /* bump the kstats */ ARCSTAT_INCR(arcstat_l2_write_bytes, asize); ARCSTAT_BUMP(arcstat_l2_log_blk_writes); ARCSTAT_F_AVG(arcstat_l2_log_blk_avg_asize, asize); ARCSTAT_F_AVG(arcstat_l2_data_to_meta_ratio, dev->l2ad_log_blk_payload_asize / asize); /* start a new log block */ dev->l2ad_log_ent_idx = 0; dev->l2ad_log_blk_payload_asize = 0; dev->l2ad_log_blk_payload_start = 0; return (asize); } /* * Validates an L2ARC log block address to make sure that it can be read * from the provided L2ARC device. */ boolean_t l2arc_log_blkptr_valid(l2arc_dev_t *dev, const l2arc_log_blkptr_t *lbp) { /* L2BLK_GET_PSIZE returns aligned size for log blocks */ uint64_t asize = L2BLK_GET_PSIZE((lbp)->lbp_prop); uint64_t end = lbp->lbp_daddr + asize - 1; uint64_t start = lbp->lbp_payload_start; boolean_t evicted = B_FALSE; /* * A log block is valid if all of the following conditions are true: * - it fits entirely (including its payload) between l2ad_start and * l2ad_end * - it has a valid size * - neither the log block itself nor part of its payload was evicted * by l2arc_evict(): * * l2ad_hand l2ad_evict * | | lbp_daddr * | start | | end * | | | | | * V V V V V * l2ad_start ============================================ l2ad_end * --------------------------|||| * ^ ^ * | log block * payload */ evicted = l2arc_range_check_overlap(start, end, dev->l2ad_hand) || l2arc_range_check_overlap(start, end, dev->l2ad_evict) || l2arc_range_check_overlap(dev->l2ad_hand, dev->l2ad_evict, start) || l2arc_range_check_overlap(dev->l2ad_hand, dev->l2ad_evict, end); return (start >= dev->l2ad_start && end <= dev->l2ad_end && asize > 0 && asize <= sizeof (l2arc_log_blk_phys_t) && (!evicted || dev->l2ad_first)); } /* * Inserts ARC buffer header `hdr' into the current L2ARC log block on * the device. The buffer being inserted must be present in L2ARC. * Returns B_TRUE if the L2ARC log block is full and needs to be committed * to L2ARC, or B_FALSE if it still has room for more ARC buffers. */ static boolean_t l2arc_log_blk_insert(l2arc_dev_t *dev, const arc_buf_hdr_t *hdr) { l2arc_log_blk_phys_t *lb = &dev->l2ad_log_blk; l2arc_log_ent_phys_t *le; if (dev->l2ad_log_entries == 0) return (B_FALSE); int index = dev->l2ad_log_ent_idx++; ASSERT3S(index, <, dev->l2ad_log_entries); ASSERT(HDR_HAS_L2HDR(hdr)); le = &lb->lb_entries[index]; memset(le, 0, sizeof (*le)); le->le_dva = hdr->b_dva; le->le_birth = hdr->b_birth; le->le_daddr = hdr->b_l2hdr.b_daddr; if (index == 0) dev->l2ad_log_blk_payload_start = le->le_daddr; L2BLK_SET_LSIZE((le)->le_prop, HDR_GET_LSIZE(hdr)); L2BLK_SET_PSIZE((le)->le_prop, HDR_GET_PSIZE(hdr)); L2BLK_SET_COMPRESS((le)->le_prop, HDR_GET_COMPRESS(hdr)); le->le_complevel = hdr->b_complevel; L2BLK_SET_TYPE((le)->le_prop, hdr->b_type); L2BLK_SET_PROTECTED((le)->le_prop, !!(HDR_PROTECTED(hdr))); L2BLK_SET_PREFETCH((le)->le_prop, !!(HDR_PREFETCH(hdr))); L2BLK_SET_STATE((le)->le_prop, hdr->b_l1hdr.b_state->arcs_state); dev->l2ad_log_blk_payload_asize += vdev_psize_to_asize(dev->l2ad_vdev, HDR_GET_PSIZE(hdr)); return (dev->l2ad_log_ent_idx == dev->l2ad_log_entries); } /* * Checks whether a given L2ARC device address sits in a time-sequential * range. The trick here is that the L2ARC is a rotary buffer, so we can't * just do a range comparison, we need to handle the situation in which the * range wraps around the end of the L2ARC device. Arguments: * bottom -- Lower end of the range to check (written to earlier). * top -- Upper end of the range to check (written to later). * check -- The address for which we want to determine if it sits in * between the top and bottom. * * The 3-way conditional below represents the following cases: * * bottom < top : Sequentially ordered case: * --------+-------------------+ * | (overlap here?) | * L2ARC dev V V * |---------------============--------------| * * bottom > top: Looped-around case: * --------+------------------+ * | (overlap here?) | * L2ARC dev V V * |===============---------------===========| * ^ ^ * | (or here?) | * +---------------+--------- * * top == bottom : Just a single address comparison. */ boolean_t l2arc_range_check_overlap(uint64_t bottom, uint64_t top, uint64_t check) { if (bottom < top) return (bottom <= check && check <= top); else if (bottom > top) return (check <= top || bottom <= check); else return (check == top); } EXPORT_SYMBOL(arc_buf_size); EXPORT_SYMBOL(arc_write); EXPORT_SYMBOL(arc_read); EXPORT_SYMBOL(arc_buf_info); EXPORT_SYMBOL(arc_getbuf_func); EXPORT_SYMBOL(arc_add_prune_callback); EXPORT_SYMBOL(arc_remove_prune_callback); ZFS_MODULE_PARAM_CALL(zfs_arc, zfs_arc_, min, param_set_arc_min, spl_param_get_u64, ZMOD_RW, "Minimum ARC size in bytes"); ZFS_MODULE_PARAM_CALL(zfs_arc, zfs_arc_, max, param_set_arc_max, spl_param_get_u64, ZMOD_RW, "Maximum ARC size in bytes"); ZFS_MODULE_PARAM(zfs_arc, zfs_arc_, meta_balance, UINT, ZMOD_RW, "Balance between metadata and data on ghost hits."); ZFS_MODULE_PARAM_CALL(zfs_arc, zfs_arc_, grow_retry, param_set_arc_int, param_get_uint, ZMOD_RW, "Seconds before growing ARC size"); ZFS_MODULE_PARAM_CALL(zfs_arc, zfs_arc_, shrink_shift, param_set_arc_int, param_get_uint, ZMOD_RW, "log2(fraction of ARC to reclaim)"); ZFS_MODULE_PARAM(zfs_arc, zfs_arc_, pc_percent, UINT, ZMOD_RW, "Percent of pagecache to reclaim ARC to"); ZFS_MODULE_PARAM(zfs_arc, zfs_arc_, average_blocksize, UINT, ZMOD_RD, "Target average block size"); ZFS_MODULE_PARAM(zfs, zfs_, compressed_arc_enabled, INT, ZMOD_RW, "Disable compressed ARC buffers"); ZFS_MODULE_PARAM_CALL(zfs_arc, zfs_arc_, min_prefetch_ms, param_set_arc_int, param_get_uint, ZMOD_RW, "Min life of prefetch block in ms"); ZFS_MODULE_PARAM_CALL(zfs_arc, zfs_arc_, min_prescient_prefetch_ms, param_set_arc_int, param_get_uint, ZMOD_RW, "Min life of prescient prefetched block in ms"); ZFS_MODULE_PARAM(zfs_l2arc, l2arc_, write_max, U64, ZMOD_RW, "Max write bytes per interval"); ZFS_MODULE_PARAM(zfs_l2arc, l2arc_, write_boost, U64, ZMOD_RW, "Extra write bytes during device warmup"); ZFS_MODULE_PARAM(zfs_l2arc, l2arc_, headroom, U64, ZMOD_RW, "Number of max device writes to precache"); ZFS_MODULE_PARAM(zfs_l2arc, l2arc_, headroom_boost, U64, ZMOD_RW, "Compressed l2arc_headroom multiplier"); ZFS_MODULE_PARAM(zfs_l2arc, l2arc_, trim_ahead, U64, ZMOD_RW, "TRIM ahead L2ARC write size multiplier"); ZFS_MODULE_PARAM(zfs_l2arc, l2arc_, feed_secs, U64, ZMOD_RW, "Seconds between L2ARC writing"); ZFS_MODULE_PARAM(zfs_l2arc, l2arc_, feed_min_ms, U64, ZMOD_RW, "Min feed interval in milliseconds"); ZFS_MODULE_PARAM(zfs_l2arc, l2arc_, noprefetch, INT, ZMOD_RW, "Skip caching prefetched buffers"); ZFS_MODULE_PARAM(zfs_l2arc, l2arc_, feed_again, INT, ZMOD_RW, "Turbo L2ARC warmup"); ZFS_MODULE_PARAM(zfs_l2arc, l2arc_, norw, INT, ZMOD_RW, "No reads during writes"); ZFS_MODULE_PARAM(zfs_l2arc, l2arc_, meta_percent, UINT, ZMOD_RW, "Percent of ARC size allowed for L2ARC-only headers"); ZFS_MODULE_PARAM(zfs_l2arc, l2arc_, rebuild_enabled, INT, ZMOD_RW, "Rebuild the L2ARC when importing a pool"); ZFS_MODULE_PARAM(zfs_l2arc, l2arc_, rebuild_blocks_min_l2size, U64, ZMOD_RW, "Min size in bytes to write rebuild log blocks in L2ARC"); ZFS_MODULE_PARAM(zfs_l2arc, l2arc_, mfuonly, INT, ZMOD_RW, "Cache only MFU data from ARC into L2ARC"); ZFS_MODULE_PARAM(zfs_l2arc, l2arc_, exclude_special, INT, ZMOD_RW, "Exclude dbufs on special vdevs from being cached to L2ARC if set."); ZFS_MODULE_PARAM_CALL(zfs_arc, zfs_arc_, lotsfree_percent, param_set_arc_int, param_get_uint, ZMOD_RW, "System free memory I/O throttle in bytes"); ZFS_MODULE_PARAM_CALL(zfs_arc, zfs_arc_, sys_free, param_set_arc_u64, spl_param_get_u64, ZMOD_RW, "System free memory target size in bytes"); ZFS_MODULE_PARAM_CALL(zfs_arc, zfs_arc_, dnode_limit, param_set_arc_u64, spl_param_get_u64, ZMOD_RW, "Minimum bytes of dnodes in ARC"); ZFS_MODULE_PARAM_CALL(zfs_arc, zfs_arc_, dnode_limit_percent, param_set_arc_int, param_get_uint, ZMOD_RW, "Percent of ARC meta buffers for dnodes"); ZFS_MODULE_PARAM(zfs_arc, zfs_arc_, dnode_reduce_percent, UINT, ZMOD_RW, "Percentage of excess dnodes to try to unpin"); ZFS_MODULE_PARAM(zfs_arc, zfs_arc_, eviction_pct, UINT, ZMOD_RW, "When full, ARC allocation waits for eviction of this % of alloc size"); ZFS_MODULE_PARAM(zfs_arc, zfs_arc_, evict_batch_limit, UINT, ZMOD_RW, "The number of headers to evict per sublist before moving to the next"); ZFS_MODULE_PARAM(zfs_arc, zfs_arc_, prune_task_threads, INT, ZMOD_RW, "Number of arc_prune threads"); diff --git a/sys/contrib/openzfs/module/zfs/dsl_pool.c b/sys/contrib/openzfs/module/zfs/dsl_pool.c index 9120fef93c74..17b971248283 100644 --- a/sys/contrib/openzfs/module/zfs/dsl_pool.c +++ b/sys/contrib/openzfs/module/zfs/dsl_pool.c @@ -1,1494 +1,1494 @@ /* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or https://opensource.org/licenses/CDDL-1.0. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright (c) 2005, 2010, Oracle and/or its affiliates. All rights reserved. * Copyright (c) 2011, 2020 by Delphix. All rights reserved. * Copyright (c) 2013 Steven Hartland. All rights reserved. * Copyright (c) 2014 Spectra Logic Corporation, All rights reserved. * Copyright 2016 Nexenta Systems, Inc. All rights reserved. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* * ZFS Write Throttle * ------------------ * * ZFS must limit the rate of incoming writes to the rate at which it is able * to sync data modifications to the backend storage. Throttling by too much * creates an artificial limit; throttling by too little can only be sustained * for short periods and would lead to highly lumpy performance. On a per-pool * basis, ZFS tracks the amount of modified (dirty) data. As operations change * data, the amount of dirty data increases; as ZFS syncs out data, the amount * of dirty data decreases. When the amount of dirty data exceeds a * predetermined threshold further modifications are blocked until the amount * of dirty data decreases (as data is synced out). * * The limit on dirty data is tunable, and should be adjusted according to * both the IO capacity and available memory of the system. The larger the * window, the more ZFS is able to aggregate and amortize metadata (and data) * changes. However, memory is a limited resource, and allowing for more dirty * data comes at the cost of keeping other useful data in memory (for example * ZFS data cached by the ARC). * * Implementation * * As buffers are modified dsl_pool_willuse_space() increments both the per- * txg (dp_dirty_pertxg[]) and poolwide (dp_dirty_total) accounting of * dirty space used; dsl_pool_dirty_space() decrements those values as data * is synced out from dsl_pool_sync(). While only the poolwide value is * relevant, the per-txg value is useful for debugging. The tunable * zfs_dirty_data_max determines the dirty space limit. Once that value is * exceeded, new writes are halted until space frees up. * * The zfs_dirty_data_sync_percent tunable dictates the threshold at which we * ensure that there is a txg syncing (see the comment in txg.c for a full * description of transaction group stages). * * The IO scheduler uses both the dirty space limit and current amount of * dirty data as inputs. Those values affect the number of concurrent IOs ZFS * issues. See the comment in vdev_queue.c for details of the IO scheduler. * * The delay is also calculated based on the amount of dirty data. See the * comment above dmu_tx_delay() for details. */ /* * zfs_dirty_data_max will be set to zfs_dirty_data_max_percent% of all memory, * capped at zfs_dirty_data_max_max. It can also be overridden with a module * parameter. */ uint64_t zfs_dirty_data_max = 0; uint64_t zfs_dirty_data_max_max = 0; uint_t zfs_dirty_data_max_percent = 10; uint_t zfs_dirty_data_max_max_percent = 25; /* * The upper limit of TX_WRITE log data. Write operations are throttled * when approaching the limit until log data is cleared out after txg sync. * It only counts TX_WRITE log with WR_COPIED or WR_NEED_COPY. */ uint64_t zfs_wrlog_data_max = 0; /* * If there's at least this much dirty data (as a percentage of * zfs_dirty_data_max), push out a txg. This should be less than * zfs_vdev_async_write_active_min_dirty_percent. */ static uint_t zfs_dirty_data_sync_percent = 20; /* * Once there is this amount of dirty data, the dmu_tx_delay() will kick in * and delay each transaction. * This value should be >= zfs_vdev_async_write_active_max_dirty_percent. */ uint_t zfs_delay_min_dirty_percent = 60; /* * This controls how quickly the delay approaches infinity. * Larger values cause it to delay more for a given amount of dirty data. * Therefore larger values will cause there to be less dirty data for a * given throughput. * * For the smoothest delay, this value should be about 1 billion divided * by the maximum number of operations per second. This will smoothly * handle between 10x and 1/10th this number. * * Note: zfs_delay_scale * zfs_dirty_data_max must be < 2^64, due to the * multiply in dmu_tx_delay(). */ uint64_t zfs_delay_scale = 1000 * 1000 * 1000 / 2000; /* * This determines the number of threads used by the dp_sync_taskq. */ static int zfs_sync_taskq_batch_pct = 75; /* * These tunables determine the behavior of how zil_itxg_clean() is * called via zil_clean() in the context of spa_sync(). When an itxg * list needs to be cleaned, TQ_NOSLEEP will be used when dispatching. * If the dispatch fails, the call to zil_itxg_clean() will occur * synchronously in the context of spa_sync(), which can negatively * impact the performance of spa_sync() (e.g. in the case of the itxg * list having a large number of itxs that needs to be cleaned). * * Thus, these tunables can be used to manipulate the behavior of the * taskq used by zil_clean(); they determine the number of taskq entries * that are pre-populated when the taskq is first created (via the * "zfs_zil_clean_taskq_minalloc" tunable) and the maximum number of * taskq entries that are cached after an on-demand allocation (via the * "zfs_zil_clean_taskq_maxalloc"). * * The idea being, we want to try reasonably hard to ensure there will * already be a taskq entry pre-allocated by the time that it is needed * by zil_clean(). This way, we can avoid the possibility of an * on-demand allocation of a new taskq entry from failing, which would * result in zil_itxg_clean() being called synchronously from zil_clean() * (which can adversely affect performance of spa_sync()). * * Additionally, the number of threads used by the taskq can be * configured via the "zfs_zil_clean_taskq_nthr_pct" tunable. */ static int zfs_zil_clean_taskq_nthr_pct = 100; static int zfs_zil_clean_taskq_minalloc = 1024; static int zfs_zil_clean_taskq_maxalloc = 1024 * 1024; int dsl_pool_open_special_dir(dsl_pool_t *dp, const char *name, dsl_dir_t **ddp) { uint64_t obj; int err; err = zap_lookup(dp->dp_meta_objset, dsl_dir_phys(dp->dp_root_dir)->dd_child_dir_zapobj, name, sizeof (obj), 1, &obj); if (err) return (err); return (dsl_dir_hold_obj(dp, obj, name, dp, ddp)); } static dsl_pool_t * dsl_pool_open_impl(spa_t *spa, uint64_t txg) { dsl_pool_t *dp; blkptr_t *bp = spa_get_rootblkptr(spa); dp = kmem_zalloc(sizeof (dsl_pool_t), KM_SLEEP); dp->dp_spa = spa; dp->dp_meta_rootbp = *bp; rrw_init(&dp->dp_config_rwlock, B_TRUE); txg_init(dp, txg); mmp_init(spa); txg_list_create(&dp->dp_dirty_datasets, spa, offsetof(dsl_dataset_t, ds_dirty_link)); txg_list_create(&dp->dp_dirty_zilogs, spa, offsetof(zilog_t, zl_dirty_link)); txg_list_create(&dp->dp_dirty_dirs, spa, offsetof(dsl_dir_t, dd_dirty_link)); txg_list_create(&dp->dp_sync_tasks, spa, offsetof(dsl_sync_task_t, dst_node)); txg_list_create(&dp->dp_early_sync_tasks, spa, offsetof(dsl_sync_task_t, dst_node)); dp->dp_sync_taskq = taskq_create("dp_sync_taskq", zfs_sync_taskq_batch_pct, minclsyspri, 1, INT_MAX, TASKQ_THREADS_CPU_PCT); dp->dp_zil_clean_taskq = taskq_create("dp_zil_clean_taskq", zfs_zil_clean_taskq_nthr_pct, minclsyspri, zfs_zil_clean_taskq_minalloc, zfs_zil_clean_taskq_maxalloc, TASKQ_PREPOPULATE | TASKQ_THREADS_CPU_PCT); mutex_init(&dp->dp_lock, NULL, MUTEX_DEFAULT, NULL); cv_init(&dp->dp_spaceavail_cv, NULL, CV_DEFAULT, NULL); aggsum_init(&dp->dp_wrlog_total, 0); for (int i = 0; i < TXG_SIZE; i++) { aggsum_init(&dp->dp_wrlog_pertxg[i], 0); } dp->dp_zrele_taskq = taskq_create("z_zrele", 100, defclsyspri, boot_ncpus * 8, INT_MAX, TASKQ_PREPOPULATE | TASKQ_DYNAMIC | TASKQ_THREADS_CPU_PCT); dp->dp_unlinked_drain_taskq = taskq_create("z_unlinked_drain", 100, defclsyspri, boot_ncpus, INT_MAX, TASKQ_PREPOPULATE | TASKQ_DYNAMIC | TASKQ_THREADS_CPU_PCT); return (dp); } int dsl_pool_init(spa_t *spa, uint64_t txg, dsl_pool_t **dpp) { int err; dsl_pool_t *dp = dsl_pool_open_impl(spa, txg); /* * Initialize the caller's dsl_pool_t structure before we actually open * the meta objset. This is done because a self-healing write zio may * be issued as part of dmu_objset_open_impl() and the spa needs its * dsl_pool_t initialized in order to handle the write. */ *dpp = dp; err = dmu_objset_open_impl(spa, NULL, &dp->dp_meta_rootbp, &dp->dp_meta_objset); if (err != 0) { dsl_pool_close(dp); *dpp = NULL; } return (err); } int dsl_pool_open(dsl_pool_t *dp) { int err; dsl_dir_t *dd; dsl_dataset_t *ds; uint64_t obj; rrw_enter(&dp->dp_config_rwlock, RW_WRITER, FTAG); err = zap_lookup(dp->dp_meta_objset, DMU_POOL_DIRECTORY_OBJECT, DMU_POOL_ROOT_DATASET, sizeof (uint64_t), 1, &dp->dp_root_dir_obj); if (err) goto out; err = dsl_dir_hold_obj(dp, dp->dp_root_dir_obj, NULL, dp, &dp->dp_root_dir); if (err) goto out; err = dsl_pool_open_special_dir(dp, MOS_DIR_NAME, &dp->dp_mos_dir); if (err) goto out; if (spa_version(dp->dp_spa) >= SPA_VERSION_ORIGIN) { err = dsl_pool_open_special_dir(dp, ORIGIN_DIR_NAME, &dd); if (err) goto out; err = dsl_dataset_hold_obj(dp, dsl_dir_phys(dd)->dd_head_dataset_obj, FTAG, &ds); if (err == 0) { err = dsl_dataset_hold_obj(dp, dsl_dataset_phys(ds)->ds_prev_snap_obj, dp, &dp->dp_origin_snap); dsl_dataset_rele(ds, FTAG); } dsl_dir_rele(dd, dp); if (err) goto out; } if (spa_version(dp->dp_spa) >= SPA_VERSION_DEADLISTS) { err = dsl_pool_open_special_dir(dp, FREE_DIR_NAME, &dp->dp_free_dir); if (err) goto out; err = zap_lookup(dp->dp_meta_objset, DMU_POOL_DIRECTORY_OBJECT, DMU_POOL_FREE_BPOBJ, sizeof (uint64_t), 1, &obj); if (err) goto out; VERIFY0(bpobj_open(&dp->dp_free_bpobj, dp->dp_meta_objset, obj)); } if (spa_feature_is_active(dp->dp_spa, SPA_FEATURE_OBSOLETE_COUNTS)) { err = zap_lookup(dp->dp_meta_objset, DMU_POOL_DIRECTORY_OBJECT, DMU_POOL_OBSOLETE_BPOBJ, sizeof (uint64_t), 1, &obj); if (err == 0) { VERIFY0(bpobj_open(&dp->dp_obsolete_bpobj, dp->dp_meta_objset, obj)); } else if (err == ENOENT) { /* * We might not have created the remap bpobj yet. */ } else { goto out; } } /* * Note: errors ignored, because the these special dirs, used for * space accounting, are only created on demand. */ (void) dsl_pool_open_special_dir(dp, LEAK_DIR_NAME, &dp->dp_leak_dir); if (spa_feature_is_active(dp->dp_spa, SPA_FEATURE_ASYNC_DESTROY)) { err = zap_lookup(dp->dp_meta_objset, DMU_POOL_DIRECTORY_OBJECT, DMU_POOL_BPTREE_OBJ, sizeof (uint64_t), 1, &dp->dp_bptree_obj); if (err != 0) goto out; } if (spa_feature_is_active(dp->dp_spa, SPA_FEATURE_EMPTY_BPOBJ)) { err = zap_lookup(dp->dp_meta_objset, DMU_POOL_DIRECTORY_OBJECT, DMU_POOL_EMPTY_BPOBJ, sizeof (uint64_t), 1, &dp->dp_empty_bpobj); if (err != 0) goto out; } err = zap_lookup(dp->dp_meta_objset, DMU_POOL_DIRECTORY_OBJECT, DMU_POOL_TMP_USERREFS, sizeof (uint64_t), 1, &dp->dp_tmp_userrefs_obj); if (err == ENOENT) err = 0; if (err) goto out; err = dsl_scan_init(dp, dp->dp_tx.tx_open_txg); out: rrw_exit(&dp->dp_config_rwlock, FTAG); return (err); } void dsl_pool_close(dsl_pool_t *dp) { /* * Drop our references from dsl_pool_open(). * * Since we held the origin_snap from "syncing" context (which * includes pool-opening context), it actually only got a "ref" * and not a hold, so just drop that here. */ if (dp->dp_origin_snap != NULL) dsl_dataset_rele(dp->dp_origin_snap, dp); if (dp->dp_mos_dir != NULL) dsl_dir_rele(dp->dp_mos_dir, dp); if (dp->dp_free_dir != NULL) dsl_dir_rele(dp->dp_free_dir, dp); if (dp->dp_leak_dir != NULL) dsl_dir_rele(dp->dp_leak_dir, dp); if (dp->dp_root_dir != NULL) dsl_dir_rele(dp->dp_root_dir, dp); bpobj_close(&dp->dp_free_bpobj); bpobj_close(&dp->dp_obsolete_bpobj); /* undo the dmu_objset_open_impl(mos) from dsl_pool_open() */ if (dp->dp_meta_objset != NULL) dmu_objset_evict(dp->dp_meta_objset); txg_list_destroy(&dp->dp_dirty_datasets); txg_list_destroy(&dp->dp_dirty_zilogs); txg_list_destroy(&dp->dp_sync_tasks); txg_list_destroy(&dp->dp_early_sync_tasks); txg_list_destroy(&dp->dp_dirty_dirs); taskq_destroy(dp->dp_zil_clean_taskq); taskq_destroy(dp->dp_sync_taskq); /* * We can't set retry to TRUE since we're explicitly specifying * a spa to flush. This is good enough; any missed buffers for * this spa won't cause trouble, and they'll eventually fall * out of the ARC just like any other unused buffer. */ arc_flush(dp->dp_spa, FALSE); mmp_fini(dp->dp_spa); txg_fini(dp); dsl_scan_fini(dp); dmu_buf_user_evict_wait(); rrw_destroy(&dp->dp_config_rwlock); mutex_destroy(&dp->dp_lock); cv_destroy(&dp->dp_spaceavail_cv); ASSERT0(aggsum_value(&dp->dp_wrlog_total)); aggsum_fini(&dp->dp_wrlog_total); for (int i = 0; i < TXG_SIZE; i++) { ASSERT0(aggsum_value(&dp->dp_wrlog_pertxg[i])); aggsum_fini(&dp->dp_wrlog_pertxg[i]); } taskq_destroy(dp->dp_unlinked_drain_taskq); taskq_destroy(dp->dp_zrele_taskq); if (dp->dp_blkstats != NULL) vmem_free(dp->dp_blkstats, sizeof (zfs_all_blkstats_t)); kmem_free(dp, sizeof (dsl_pool_t)); } void dsl_pool_create_obsolete_bpobj(dsl_pool_t *dp, dmu_tx_t *tx) { uint64_t obj; /* * Currently, we only create the obsolete_bpobj where there are * indirect vdevs with referenced mappings. */ ASSERT(spa_feature_is_active(dp->dp_spa, SPA_FEATURE_DEVICE_REMOVAL)); /* create and open the obsolete_bpobj */ obj = bpobj_alloc(dp->dp_meta_objset, SPA_OLD_MAXBLOCKSIZE, tx); VERIFY0(bpobj_open(&dp->dp_obsolete_bpobj, dp->dp_meta_objset, obj)); VERIFY0(zap_add(dp->dp_meta_objset, DMU_POOL_DIRECTORY_OBJECT, DMU_POOL_OBSOLETE_BPOBJ, sizeof (uint64_t), 1, &obj, tx)); spa_feature_incr(dp->dp_spa, SPA_FEATURE_OBSOLETE_COUNTS, tx); } void dsl_pool_destroy_obsolete_bpobj(dsl_pool_t *dp, dmu_tx_t *tx) { spa_feature_decr(dp->dp_spa, SPA_FEATURE_OBSOLETE_COUNTS, tx); VERIFY0(zap_remove(dp->dp_meta_objset, DMU_POOL_DIRECTORY_OBJECT, DMU_POOL_OBSOLETE_BPOBJ, tx)); bpobj_free(dp->dp_meta_objset, dp->dp_obsolete_bpobj.bpo_object, tx); bpobj_close(&dp->dp_obsolete_bpobj); } dsl_pool_t * dsl_pool_create(spa_t *spa, nvlist_t *zplprops __attribute__((unused)), dsl_crypto_params_t *dcp, uint64_t txg) { int err; dsl_pool_t *dp = dsl_pool_open_impl(spa, txg); dmu_tx_t *tx = dmu_tx_create_assigned(dp, txg); #ifdef _KERNEL objset_t *os; #else objset_t *os __attribute__((unused)); #endif dsl_dataset_t *ds; uint64_t obj; rrw_enter(&dp->dp_config_rwlock, RW_WRITER, FTAG); /* create and open the MOS (meta-objset) */ dp->dp_meta_objset = dmu_objset_create_impl(spa, NULL, &dp->dp_meta_rootbp, DMU_OST_META, tx); spa->spa_meta_objset = dp->dp_meta_objset; /* create the pool directory */ err = zap_create_claim(dp->dp_meta_objset, DMU_POOL_DIRECTORY_OBJECT, DMU_OT_OBJECT_DIRECTORY, DMU_OT_NONE, 0, tx); ASSERT0(err); /* Initialize scan structures */ VERIFY0(dsl_scan_init(dp, txg)); /* create and open the root dir */ dp->dp_root_dir_obj = dsl_dir_create_sync(dp, NULL, NULL, tx); VERIFY0(dsl_dir_hold_obj(dp, dp->dp_root_dir_obj, NULL, dp, &dp->dp_root_dir)); /* create and open the meta-objset dir */ (void) dsl_dir_create_sync(dp, dp->dp_root_dir, MOS_DIR_NAME, tx); VERIFY0(dsl_pool_open_special_dir(dp, MOS_DIR_NAME, &dp->dp_mos_dir)); if (spa_version(spa) >= SPA_VERSION_DEADLISTS) { /* create and open the free dir */ (void) dsl_dir_create_sync(dp, dp->dp_root_dir, FREE_DIR_NAME, tx); VERIFY0(dsl_pool_open_special_dir(dp, FREE_DIR_NAME, &dp->dp_free_dir)); /* create and open the free_bplist */ obj = bpobj_alloc(dp->dp_meta_objset, SPA_OLD_MAXBLOCKSIZE, tx); VERIFY(zap_add(dp->dp_meta_objset, DMU_POOL_DIRECTORY_OBJECT, DMU_POOL_FREE_BPOBJ, sizeof (uint64_t), 1, &obj, tx) == 0); VERIFY0(bpobj_open(&dp->dp_free_bpobj, dp->dp_meta_objset, obj)); } if (spa_version(spa) >= SPA_VERSION_DSL_SCRUB) dsl_pool_create_origin(dp, tx); /* * Some features may be needed when creating the root dataset, so we * create the feature objects here. */ if (spa_version(spa) >= SPA_VERSION_FEATURES) spa_feature_create_zap_objects(spa, tx); if (dcp != NULL && dcp->cp_crypt != ZIO_CRYPT_OFF && dcp->cp_crypt != ZIO_CRYPT_INHERIT) spa_feature_enable(spa, SPA_FEATURE_ENCRYPTION, tx); /* create the root dataset */ obj = dsl_dataset_create_sync_dd(dp->dp_root_dir, NULL, dcp, 0, tx); /* create the root objset */ VERIFY0(dsl_dataset_hold_obj_flags(dp, obj, DS_HOLD_FLAG_DECRYPT, FTAG, &ds)); rrw_enter(&ds->ds_bp_rwlock, RW_READER, FTAG); os = dmu_objset_create_impl(dp->dp_spa, ds, dsl_dataset_get_blkptr(ds), DMU_OST_ZFS, tx); rrw_exit(&ds->ds_bp_rwlock, FTAG); #ifdef _KERNEL zfs_create_fs(os, kcred, zplprops, tx); #endif dsl_dataset_rele_flags(ds, DS_HOLD_FLAG_DECRYPT, FTAG); dmu_tx_commit(tx); rrw_exit(&dp->dp_config_rwlock, FTAG); return (dp); } /* * Account for the meta-objset space in its placeholder dsl_dir. */ void dsl_pool_mos_diduse_space(dsl_pool_t *dp, int64_t used, int64_t comp, int64_t uncomp) { ASSERT3U(comp, ==, uncomp); /* it's all metadata */ mutex_enter(&dp->dp_lock); dp->dp_mos_used_delta += used; dp->dp_mos_compressed_delta += comp; dp->dp_mos_uncompressed_delta += uncomp; mutex_exit(&dp->dp_lock); } static void dsl_pool_sync_mos(dsl_pool_t *dp, dmu_tx_t *tx) { zio_t *zio = zio_root(dp->dp_spa, NULL, NULL, ZIO_FLAG_MUSTSUCCEED); dmu_objset_sync(dp->dp_meta_objset, zio, tx); VERIFY0(zio_wait(zio)); dmu_objset_sync_done(dp->dp_meta_objset, tx); taskq_wait(dp->dp_sync_taskq); multilist_destroy(&dp->dp_meta_objset->os_synced_dnodes); dprintf_bp(&dp->dp_meta_rootbp, "meta objset rootbp is %s", ""); spa_set_rootblkptr(dp->dp_spa, &dp->dp_meta_rootbp); } static void dsl_pool_dirty_delta(dsl_pool_t *dp, int64_t delta) { ASSERT(MUTEX_HELD(&dp->dp_lock)); if (delta < 0) ASSERT3U(-delta, <=, dp->dp_dirty_total); dp->dp_dirty_total += delta; /* * Note: we signal even when increasing dp_dirty_total. * This ensures forward progress -- each thread wakes the next waiter. */ if (dp->dp_dirty_total < zfs_dirty_data_max) cv_signal(&dp->dp_spaceavail_cv); } void dsl_pool_wrlog_count(dsl_pool_t *dp, int64_t size, uint64_t txg) { ASSERT3S(size, >=, 0); aggsum_add(&dp->dp_wrlog_pertxg[txg & TXG_MASK], size); aggsum_add(&dp->dp_wrlog_total, size); /* Choose a value slightly bigger than min dirty sync bytes */ uint64_t sync_min = zfs_wrlog_data_max * (zfs_dirty_data_sync_percent + 10) / 200; if (aggsum_compare(&dp->dp_wrlog_pertxg[txg & TXG_MASK], sync_min) > 0) txg_kick(dp, txg); } boolean_t dsl_pool_need_wrlog_delay(dsl_pool_t *dp) { uint64_t delay_min_bytes = zfs_wrlog_data_max * zfs_delay_min_dirty_percent / 100; return (aggsum_compare(&dp->dp_wrlog_total, delay_min_bytes) > 0); } static void dsl_pool_wrlog_clear(dsl_pool_t *dp, uint64_t txg) { int64_t delta; delta = -(int64_t)aggsum_value(&dp->dp_wrlog_pertxg[txg & TXG_MASK]); aggsum_add(&dp->dp_wrlog_pertxg[txg & TXG_MASK], delta); aggsum_add(&dp->dp_wrlog_total, delta); /* Compact per-CPU sums after the big change. */ (void) aggsum_value(&dp->dp_wrlog_pertxg[txg & TXG_MASK]); (void) aggsum_value(&dp->dp_wrlog_total); } #ifdef ZFS_DEBUG static boolean_t dsl_early_sync_task_verify(dsl_pool_t *dp, uint64_t txg) { spa_t *spa = dp->dp_spa; vdev_t *rvd = spa->spa_root_vdev; for (uint64_t c = 0; c < rvd->vdev_children; c++) { vdev_t *vd = rvd->vdev_child[c]; txg_list_t *tl = &vd->vdev_ms_list; metaslab_t *ms; for (ms = txg_list_head(tl, TXG_CLEAN(txg)); ms; ms = txg_list_next(tl, ms, TXG_CLEAN(txg))) { VERIFY(range_tree_is_empty(ms->ms_freeing)); VERIFY(range_tree_is_empty(ms->ms_checkpointing)); } } return (B_TRUE); } #else #define dsl_early_sync_task_verify(dp, txg) \ ((void) sizeof (dp), (void) sizeof (txg), B_TRUE) #endif void dsl_pool_sync(dsl_pool_t *dp, uint64_t txg) { zio_t *zio; dmu_tx_t *tx; dsl_dir_t *dd; dsl_dataset_t *ds; objset_t *mos = dp->dp_meta_objset; list_t synced_datasets; list_create(&synced_datasets, sizeof (dsl_dataset_t), offsetof(dsl_dataset_t, ds_synced_link)); tx = dmu_tx_create_assigned(dp, txg); /* * Run all early sync tasks before writing out any dirty blocks. * For more info on early sync tasks see block comment in * dsl_early_sync_task(). */ if (!txg_list_empty(&dp->dp_early_sync_tasks, txg)) { dsl_sync_task_t *dst; ASSERT3U(spa_sync_pass(dp->dp_spa), ==, 1); while ((dst = txg_list_remove(&dp->dp_early_sync_tasks, txg)) != NULL) { ASSERT(dsl_early_sync_task_verify(dp, txg)); dsl_sync_task_sync(dst, tx); } ASSERT(dsl_early_sync_task_verify(dp, txg)); } /* * Write out all dirty blocks of dirty datasets. */ zio = zio_root(dp->dp_spa, NULL, NULL, ZIO_FLAG_MUSTSUCCEED); while ((ds = txg_list_remove(&dp->dp_dirty_datasets, txg)) != NULL) { /* * We must not sync any non-MOS datasets twice, because * we may have taken a snapshot of them. However, we * may sync newly-created datasets on pass 2. */ ASSERT(!list_link_active(&ds->ds_synced_link)); list_insert_tail(&synced_datasets, ds); dsl_dataset_sync(ds, zio, tx); } VERIFY0(zio_wait(zio)); /* * Update the long range free counter after * we're done syncing user data */ mutex_enter(&dp->dp_lock); ASSERT(spa_sync_pass(dp->dp_spa) == 1 || dp->dp_long_free_dirty_pertxg[txg & TXG_MASK] == 0); dp->dp_long_free_dirty_pertxg[txg & TXG_MASK] = 0; mutex_exit(&dp->dp_lock); /* * After the data blocks have been written (ensured by the zio_wait() * above), update the user/group/project space accounting. This happens * in tasks dispatched to dp_sync_taskq, so wait for them before * continuing. */ for (ds = list_head(&synced_datasets); ds != NULL; ds = list_next(&synced_datasets, ds)) { dmu_objset_sync_done(ds->ds_objset, tx); } taskq_wait(dp->dp_sync_taskq); /* * Sync the datasets again to push out the changes due to * userspace updates. This must be done before we process the * sync tasks, so that any snapshots will have the correct * user accounting information (and we won't get confused * about which blocks are part of the snapshot). */ zio = zio_root(dp->dp_spa, NULL, NULL, ZIO_FLAG_MUSTSUCCEED); while ((ds = txg_list_remove(&dp->dp_dirty_datasets, txg)) != NULL) { objset_t *os = ds->ds_objset; ASSERT(list_link_active(&ds->ds_synced_link)); dmu_buf_rele(ds->ds_dbuf, ds); dsl_dataset_sync(ds, zio, tx); /* * Release any key mappings created by calls to * dsl_dataset_dirty() from the userquota accounting * code paths. */ if (os->os_encrypted && !os->os_raw_receive && !os->os_next_write_raw[txg & TXG_MASK]) { ASSERT3P(ds->ds_key_mapping, !=, NULL); key_mapping_rele(dp->dp_spa, ds->ds_key_mapping, ds); } } VERIFY0(zio_wait(zio)); /* * Now that the datasets have been completely synced, we can * clean up our in-memory structures accumulated while syncing: * * - move dead blocks from the pending deadlist and livelists * to the on-disk versions * - release hold from dsl_dataset_dirty() * - release key mapping hold from dsl_dataset_dirty() */ while ((ds = list_remove_head(&synced_datasets)) != NULL) { objset_t *os = ds->ds_objset; if (os->os_encrypted && !os->os_raw_receive && !os->os_next_write_raw[txg & TXG_MASK]) { ASSERT3P(ds->ds_key_mapping, !=, NULL); key_mapping_rele(dp->dp_spa, ds->ds_key_mapping, ds); } dsl_dataset_sync_done(ds, tx); dmu_buf_rele(ds->ds_dbuf, ds); } while ((dd = txg_list_remove(&dp->dp_dirty_dirs, txg)) != NULL) { dsl_dir_sync(dd, tx); } /* * The MOS's space is accounted for in the pool/$MOS * (dp_mos_dir). We can't modify the mos while we're syncing * it, so we remember the deltas and apply them here. */ if (dp->dp_mos_used_delta != 0 || dp->dp_mos_compressed_delta != 0 || dp->dp_mos_uncompressed_delta != 0) { dsl_dir_diduse_space(dp->dp_mos_dir, DD_USED_HEAD, dp->dp_mos_used_delta, dp->dp_mos_compressed_delta, dp->dp_mos_uncompressed_delta, tx); dp->dp_mos_used_delta = 0; dp->dp_mos_compressed_delta = 0; dp->dp_mos_uncompressed_delta = 0; } if (dmu_objset_is_dirty(mos, txg)) { dsl_pool_sync_mos(dp, tx); } /* * We have written all of the accounted dirty data, so our * dp_space_towrite should now be zero. However, some seldom-used * code paths do not adhere to this (e.g. dbuf_undirty()). Shore up * the accounting of any dirtied space now. * * Note that, besides any dirty data from datasets, the amount of * dirty data in the MOS is also accounted by the pool. Therefore, * we want to do this cleanup after dsl_pool_sync_mos() so we don't * attempt to update the accounting for the same dirty data twice. * (i.e. at this point we only update the accounting for the space * that we know that we "leaked"). */ dsl_pool_undirty_space(dp, dp->dp_dirty_pertxg[txg & TXG_MASK], txg); /* * If we modify a dataset in the same txg that we want to destroy it, * its dsl_dir's dd_dbuf will be dirty, and thus have a hold on it. * dsl_dir_destroy_check() will fail if there are unexpected holds. * Therefore, we want to sync the MOS (thus syncing the dd_dbuf * and clearing the hold on it) before we process the sync_tasks. * The MOS data dirtied by the sync_tasks will be synced on the next * pass. */ if (!txg_list_empty(&dp->dp_sync_tasks, txg)) { dsl_sync_task_t *dst; /* * No more sync tasks should have been added while we * were syncing. */ ASSERT3U(spa_sync_pass(dp->dp_spa), ==, 1); while ((dst = txg_list_remove(&dp->dp_sync_tasks, txg)) != NULL) dsl_sync_task_sync(dst, tx); } dmu_tx_commit(tx); DTRACE_PROBE2(dsl_pool_sync__done, dsl_pool_t *dp, dp, uint64_t, txg); } void dsl_pool_sync_done(dsl_pool_t *dp, uint64_t txg) { zilog_t *zilog; while ((zilog = txg_list_head(&dp->dp_dirty_zilogs, txg))) { dsl_dataset_t *ds = dmu_objset_ds(zilog->zl_os); /* * We don't remove the zilog from the dp_dirty_zilogs * list until after we've cleaned it. This ensures that * callers of zilog_is_dirty() receive an accurate * answer when they are racing with the spa sync thread. */ zil_clean(zilog, txg); (void) txg_list_remove_this(&dp->dp_dirty_zilogs, zilog, txg); ASSERT(!dmu_objset_is_dirty(zilog->zl_os, txg)); dmu_buf_rele(ds->ds_dbuf, zilog); } dsl_pool_wrlog_clear(dp, txg); ASSERT(!dmu_objset_is_dirty(dp->dp_meta_objset, txg)); } /* * TRUE if the current thread is the tx_sync_thread or if we * are being called from SPA context during pool initialization. */ int dsl_pool_sync_context(dsl_pool_t *dp) { return (curthread == dp->dp_tx.tx_sync_thread || spa_is_initializing(dp->dp_spa) || taskq_member(dp->dp_sync_taskq, curthread)); } /* * This function returns the amount of allocatable space in the pool * minus whatever space is currently reserved by ZFS for specific * purposes. Specifically: * * 1] Any reserved SLOP space * 2] Any space used by the checkpoint * 3] Any space used for deferred frees * * The latter 2 are especially important because they are needed to * rectify the SPA's and DMU's different understanding of how much space * is used. Now the DMU is aware of that extra space tracked by the SPA * without having to maintain a separate special dir (e.g similar to * $MOS, $FREEING, and $LEAKED). * * Note: By deferred frees here, we mean the frees that were deferred * in spa_sync() after sync pass 1 (spa_deferred_bpobj), and not the * segments placed in ms_defer trees during metaslab_sync_done(). */ uint64_t dsl_pool_adjustedsize(dsl_pool_t *dp, zfs_space_check_t slop_policy) { spa_t *spa = dp->dp_spa; uint64_t space, resv, adjustedsize; uint64_t spa_deferred_frees = spa->spa_deferred_bpobj.bpo_phys->bpo_bytes; space = spa_get_dspace(spa) - spa_get_checkpoint_space(spa) - spa_deferred_frees; resv = spa_get_slop_space(spa); switch (slop_policy) { case ZFS_SPACE_CHECK_NORMAL: break; case ZFS_SPACE_CHECK_RESERVED: resv >>= 1; break; case ZFS_SPACE_CHECK_EXTRA_RESERVED: resv >>= 2; break; case ZFS_SPACE_CHECK_NONE: resv = 0; break; default: panic("invalid slop policy value: %d", slop_policy); break; } adjustedsize = (space >= resv) ? (space - resv) : 0; return (adjustedsize); } uint64_t dsl_pool_unreserved_space(dsl_pool_t *dp, zfs_space_check_t slop_policy) { uint64_t poolsize = dsl_pool_adjustedsize(dp, slop_policy); uint64_t deferred = metaslab_class_get_deferred(spa_normal_class(dp->dp_spa)); uint64_t quota = (poolsize >= deferred) ? (poolsize - deferred) : 0; return (quota); } uint64_t dsl_pool_deferred_space(dsl_pool_t *dp) { return (metaslab_class_get_deferred(spa_normal_class(dp->dp_spa))); } boolean_t dsl_pool_need_dirty_delay(dsl_pool_t *dp) { uint64_t delay_min_bytes = zfs_dirty_data_max * zfs_delay_min_dirty_percent / 100; - mutex_enter(&dp->dp_lock); - uint64_t dirty = dp->dp_dirty_total; - mutex_exit(&dp->dp_lock); - - return (dirty > delay_min_bytes); + /* + * We are not taking the dp_lock here and few other places, since torn + * reads are unlikely: on 64-bit systems due to register size and on + * 32-bit due to memory constraints. Pool-wide locks in hot path may + * be too expensive, while we do not need a precise result here. + */ + return (dp->dp_dirty_total > delay_min_bytes); } static boolean_t dsl_pool_need_dirty_sync(dsl_pool_t *dp, uint64_t txg) { - ASSERT(MUTEX_HELD(&dp->dp_lock)); - uint64_t dirty_min_bytes = zfs_dirty_data_max * zfs_dirty_data_sync_percent / 100; uint64_t dirty = dp->dp_dirty_pertxg[txg & TXG_MASK]; return (dirty > dirty_min_bytes); } void dsl_pool_dirty_space(dsl_pool_t *dp, int64_t space, dmu_tx_t *tx) { if (space > 0) { mutex_enter(&dp->dp_lock); dp->dp_dirty_pertxg[tx->tx_txg & TXG_MASK] += space; dsl_pool_dirty_delta(dp, space); boolean_t needsync = !dmu_tx_is_syncing(tx) && dsl_pool_need_dirty_sync(dp, tx->tx_txg); mutex_exit(&dp->dp_lock); if (needsync) txg_kick(dp, tx->tx_txg); } } void dsl_pool_undirty_space(dsl_pool_t *dp, int64_t space, uint64_t txg) { ASSERT3S(space, >=, 0); if (space == 0) return; mutex_enter(&dp->dp_lock); if (dp->dp_dirty_pertxg[txg & TXG_MASK] < space) { /* XXX writing something we didn't dirty? */ space = dp->dp_dirty_pertxg[txg & TXG_MASK]; } ASSERT3U(dp->dp_dirty_pertxg[txg & TXG_MASK], >=, space); dp->dp_dirty_pertxg[txg & TXG_MASK] -= space; ASSERT3U(dp->dp_dirty_total, >=, space); dsl_pool_dirty_delta(dp, -space); mutex_exit(&dp->dp_lock); } static int upgrade_clones_cb(dsl_pool_t *dp, dsl_dataset_t *hds, void *arg) { dmu_tx_t *tx = arg; dsl_dataset_t *ds, *prev = NULL; int err; err = dsl_dataset_hold_obj(dp, hds->ds_object, FTAG, &ds); if (err) return (err); while (dsl_dataset_phys(ds)->ds_prev_snap_obj != 0) { err = dsl_dataset_hold_obj(dp, dsl_dataset_phys(ds)->ds_prev_snap_obj, FTAG, &prev); if (err) { dsl_dataset_rele(ds, FTAG); return (err); } if (dsl_dataset_phys(prev)->ds_next_snap_obj != ds->ds_object) break; dsl_dataset_rele(ds, FTAG); ds = prev; prev = NULL; } if (prev == NULL) { prev = dp->dp_origin_snap; /* * The $ORIGIN can't have any data, or the accounting * will be wrong. */ rrw_enter(&ds->ds_bp_rwlock, RW_READER, FTAG); ASSERT0(dsl_dataset_phys(prev)->ds_bp.blk_birth); rrw_exit(&ds->ds_bp_rwlock, FTAG); /* The origin doesn't get attached to itself */ if (ds->ds_object == prev->ds_object) { dsl_dataset_rele(ds, FTAG); return (0); } dmu_buf_will_dirty(ds->ds_dbuf, tx); dsl_dataset_phys(ds)->ds_prev_snap_obj = prev->ds_object; dsl_dataset_phys(ds)->ds_prev_snap_txg = dsl_dataset_phys(prev)->ds_creation_txg; dmu_buf_will_dirty(ds->ds_dir->dd_dbuf, tx); dsl_dir_phys(ds->ds_dir)->dd_origin_obj = prev->ds_object; dmu_buf_will_dirty(prev->ds_dbuf, tx); dsl_dataset_phys(prev)->ds_num_children++; if (dsl_dataset_phys(ds)->ds_next_snap_obj == 0) { ASSERT(ds->ds_prev == NULL); VERIFY0(dsl_dataset_hold_obj(dp, dsl_dataset_phys(ds)->ds_prev_snap_obj, ds, &ds->ds_prev)); } } ASSERT3U(dsl_dir_phys(ds->ds_dir)->dd_origin_obj, ==, prev->ds_object); ASSERT3U(dsl_dataset_phys(ds)->ds_prev_snap_obj, ==, prev->ds_object); if (dsl_dataset_phys(prev)->ds_next_clones_obj == 0) { dmu_buf_will_dirty(prev->ds_dbuf, tx); dsl_dataset_phys(prev)->ds_next_clones_obj = zap_create(dp->dp_meta_objset, DMU_OT_NEXT_CLONES, DMU_OT_NONE, 0, tx); } VERIFY0(zap_add_int(dp->dp_meta_objset, dsl_dataset_phys(prev)->ds_next_clones_obj, ds->ds_object, tx)); dsl_dataset_rele(ds, FTAG); if (prev != dp->dp_origin_snap) dsl_dataset_rele(prev, FTAG); return (0); } void dsl_pool_upgrade_clones(dsl_pool_t *dp, dmu_tx_t *tx) { ASSERT(dmu_tx_is_syncing(tx)); ASSERT(dp->dp_origin_snap != NULL); VERIFY0(dmu_objset_find_dp(dp, dp->dp_root_dir_obj, upgrade_clones_cb, tx, DS_FIND_CHILDREN | DS_FIND_SERIALIZE)); } static int upgrade_dir_clones_cb(dsl_pool_t *dp, dsl_dataset_t *ds, void *arg) { dmu_tx_t *tx = arg; objset_t *mos = dp->dp_meta_objset; if (dsl_dir_phys(ds->ds_dir)->dd_origin_obj != 0) { dsl_dataset_t *origin; VERIFY0(dsl_dataset_hold_obj(dp, dsl_dir_phys(ds->ds_dir)->dd_origin_obj, FTAG, &origin)); if (dsl_dir_phys(origin->ds_dir)->dd_clones == 0) { dmu_buf_will_dirty(origin->ds_dir->dd_dbuf, tx); dsl_dir_phys(origin->ds_dir)->dd_clones = zap_create(mos, DMU_OT_DSL_CLONES, DMU_OT_NONE, 0, tx); } VERIFY0(zap_add_int(dp->dp_meta_objset, dsl_dir_phys(origin->ds_dir)->dd_clones, ds->ds_object, tx)); dsl_dataset_rele(origin, FTAG); } return (0); } void dsl_pool_upgrade_dir_clones(dsl_pool_t *dp, dmu_tx_t *tx) { uint64_t obj; ASSERT(dmu_tx_is_syncing(tx)); (void) dsl_dir_create_sync(dp, dp->dp_root_dir, FREE_DIR_NAME, tx); VERIFY0(dsl_pool_open_special_dir(dp, FREE_DIR_NAME, &dp->dp_free_dir)); /* * We can't use bpobj_alloc(), because spa_version() still * returns the old version, and we need a new-version bpobj with * subobj support. So call dmu_object_alloc() directly. */ obj = dmu_object_alloc(dp->dp_meta_objset, DMU_OT_BPOBJ, SPA_OLD_MAXBLOCKSIZE, DMU_OT_BPOBJ_HDR, sizeof (bpobj_phys_t), tx); VERIFY0(zap_add(dp->dp_meta_objset, DMU_POOL_DIRECTORY_OBJECT, DMU_POOL_FREE_BPOBJ, sizeof (uint64_t), 1, &obj, tx)); VERIFY0(bpobj_open(&dp->dp_free_bpobj, dp->dp_meta_objset, obj)); VERIFY0(dmu_objset_find_dp(dp, dp->dp_root_dir_obj, upgrade_dir_clones_cb, tx, DS_FIND_CHILDREN | DS_FIND_SERIALIZE)); } void dsl_pool_create_origin(dsl_pool_t *dp, dmu_tx_t *tx) { uint64_t dsobj; dsl_dataset_t *ds; ASSERT(dmu_tx_is_syncing(tx)); ASSERT(dp->dp_origin_snap == NULL); ASSERT(rrw_held(&dp->dp_config_rwlock, RW_WRITER)); /* create the origin dir, ds, & snap-ds */ dsobj = dsl_dataset_create_sync(dp->dp_root_dir, ORIGIN_DIR_NAME, NULL, 0, kcred, NULL, tx); VERIFY0(dsl_dataset_hold_obj(dp, dsobj, FTAG, &ds)); dsl_dataset_snapshot_sync_impl(ds, ORIGIN_DIR_NAME, tx); VERIFY0(dsl_dataset_hold_obj(dp, dsl_dataset_phys(ds)->ds_prev_snap_obj, dp, &dp->dp_origin_snap)); dsl_dataset_rele(ds, FTAG); } taskq_t * dsl_pool_zrele_taskq(dsl_pool_t *dp) { return (dp->dp_zrele_taskq); } taskq_t * dsl_pool_unlinked_drain_taskq(dsl_pool_t *dp) { return (dp->dp_unlinked_drain_taskq); } /* * Walk through the pool-wide zap object of temporary snapshot user holds * and release them. */ void dsl_pool_clean_tmp_userrefs(dsl_pool_t *dp) { zap_attribute_t za; zap_cursor_t zc; objset_t *mos = dp->dp_meta_objset; uint64_t zapobj = dp->dp_tmp_userrefs_obj; nvlist_t *holds; if (zapobj == 0) return; ASSERT(spa_version(dp->dp_spa) >= SPA_VERSION_USERREFS); holds = fnvlist_alloc(); for (zap_cursor_init(&zc, mos, zapobj); zap_cursor_retrieve(&zc, &za) == 0; zap_cursor_advance(&zc)) { char *htag; nvlist_t *tags; htag = strchr(za.za_name, '-'); *htag = '\0'; ++htag; if (nvlist_lookup_nvlist(holds, za.za_name, &tags) != 0) { tags = fnvlist_alloc(); fnvlist_add_boolean(tags, htag); fnvlist_add_nvlist(holds, za.za_name, tags); fnvlist_free(tags); } else { fnvlist_add_boolean(tags, htag); } } dsl_dataset_user_release_tmp(dp, holds); fnvlist_free(holds); zap_cursor_fini(&zc); } /* * Create the pool-wide zap object for storing temporary snapshot holds. */ static void dsl_pool_user_hold_create_obj(dsl_pool_t *dp, dmu_tx_t *tx) { objset_t *mos = dp->dp_meta_objset; ASSERT(dp->dp_tmp_userrefs_obj == 0); ASSERT(dmu_tx_is_syncing(tx)); dp->dp_tmp_userrefs_obj = zap_create_link(mos, DMU_OT_USERREFS, DMU_POOL_DIRECTORY_OBJECT, DMU_POOL_TMP_USERREFS, tx); } static int dsl_pool_user_hold_rele_impl(dsl_pool_t *dp, uint64_t dsobj, const char *tag, uint64_t now, dmu_tx_t *tx, boolean_t holding) { objset_t *mos = dp->dp_meta_objset; uint64_t zapobj = dp->dp_tmp_userrefs_obj; char *name; int error; ASSERT(spa_version(dp->dp_spa) >= SPA_VERSION_USERREFS); ASSERT(dmu_tx_is_syncing(tx)); /* * If the pool was created prior to SPA_VERSION_USERREFS, the * zap object for temporary holds might not exist yet. */ if (zapobj == 0) { if (holding) { dsl_pool_user_hold_create_obj(dp, tx); zapobj = dp->dp_tmp_userrefs_obj; } else { return (SET_ERROR(ENOENT)); } } name = kmem_asprintf("%llx-%s", (u_longlong_t)dsobj, tag); if (holding) error = zap_add(mos, zapobj, name, 8, 1, &now, tx); else error = zap_remove(mos, zapobj, name, tx); kmem_strfree(name); return (error); } /* * Add a temporary hold for the given dataset object and tag. */ int dsl_pool_user_hold(dsl_pool_t *dp, uint64_t dsobj, const char *tag, uint64_t now, dmu_tx_t *tx) { return (dsl_pool_user_hold_rele_impl(dp, dsobj, tag, now, tx, B_TRUE)); } /* * Release a temporary hold for the given dataset object and tag. */ int dsl_pool_user_release(dsl_pool_t *dp, uint64_t dsobj, const char *tag, dmu_tx_t *tx) { return (dsl_pool_user_hold_rele_impl(dp, dsobj, tag, 0, tx, B_FALSE)); } /* * DSL Pool Configuration Lock * * The dp_config_rwlock protects against changes to DSL state (e.g. dataset * creation / destruction / rename / property setting). It must be held for * read to hold a dataset or dsl_dir. I.e. you must call * dsl_pool_config_enter() or dsl_pool_hold() before calling * dsl_{dataset,dir}_hold{_obj}. In most circumstances, the dp_config_rwlock * must be held continuously until all datasets and dsl_dirs are released. * * The only exception to this rule is that if a "long hold" is placed on * a dataset, then the dp_config_rwlock may be dropped while the dataset * is still held. The long hold will prevent the dataset from being * destroyed -- the destroy will fail with EBUSY. A long hold can be * obtained by calling dsl_dataset_long_hold(), or by "owning" a dataset * (by calling dsl_{dataset,objset}_{try}own{_obj}). * * Legitimate long-holders (including owners) should be long-running, cancelable * tasks that should cause "zfs destroy" to fail. This includes DMU * consumers (i.e. a ZPL filesystem being mounted or ZVOL being open), * "zfs send", and "zfs diff". There are several other long-holders whose * uses are suboptimal (e.g. "zfs promote", and zil_suspend()). * * The usual formula for long-holding would be: * dsl_pool_hold() * dsl_dataset_hold() * ... perform checks ... * dsl_dataset_long_hold() * dsl_pool_rele() * ... perform long-running task ... * dsl_dataset_long_rele() * dsl_dataset_rele() * * Note that when the long hold is released, the dataset is still held but * the pool is not held. The dataset may change arbitrarily during this time * (e.g. it could be destroyed). Therefore you shouldn't do anything to the * dataset except release it. * * Operations generally fall somewhere into the following taxonomy: * * Read-Only Modifying * * Dataset Layer / MOS zfs get zfs destroy * * Individual Dataset read() write() * * * Dataset Layer Operations * * Modifying operations should generally use dsl_sync_task(). The synctask * infrastructure enforces proper locking strategy with respect to the * dp_config_rwlock. See the comment above dsl_sync_task() for details. * * Read-only operations will manually hold the pool, then the dataset, obtain * information from the dataset, then release the pool and dataset. * dmu_objset_{hold,rele}() are convenience routines that also do the pool * hold/rele. * * * Operations On Individual Datasets * * Objects _within_ an objset should only be modified by the current 'owner' * of the objset to prevent incorrect concurrent modification. Thus, use * {dmu_objset,dsl_dataset}_own to mark some entity as the current owner, * and fail with EBUSY if there is already an owner. The owner can then * implement its own locking strategy, independent of the dataset layer's * locking infrastructure. * (E.g., the ZPL has its own set of locks to control concurrency. A regular * vnop will not reach into the dataset layer). * * Ideally, objects would also only be read by the objset’s owner, so that we * don’t observe state mid-modification. * (E.g. the ZPL is creating a new object and linking it into a directory; if * you don’t coordinate with the ZPL to hold ZPL-level locks, you could see an * intermediate state. The ioctl level violates this but in pretty benign * ways, e.g. reading the zpl props object.) */ int dsl_pool_hold(const char *name, const void *tag, dsl_pool_t **dp) { spa_t *spa; int error; error = spa_open(name, &spa, tag); if (error == 0) { *dp = spa_get_dsl(spa); dsl_pool_config_enter(*dp, tag); } return (error); } void dsl_pool_rele(dsl_pool_t *dp, const void *tag) { dsl_pool_config_exit(dp, tag); spa_close(dp->dp_spa, tag); } void dsl_pool_config_enter(dsl_pool_t *dp, const void *tag) { /* * We use a "reentrant" reader-writer lock, but not reentrantly. * * The rrwlock can (with the track_all flag) track all reading threads, * which is very useful for debugging which code path failed to release * the lock, and for verifying that the *current* thread does hold * the lock. * * (Unlike a rwlock, which knows that N threads hold it for * read, but not *which* threads, so rw_held(RW_READER) returns TRUE * if any thread holds it for read, even if this thread doesn't). */ ASSERT(!rrw_held(&dp->dp_config_rwlock, RW_READER)); rrw_enter(&dp->dp_config_rwlock, RW_READER, tag); } void dsl_pool_config_enter_prio(dsl_pool_t *dp, const void *tag) { ASSERT(!rrw_held(&dp->dp_config_rwlock, RW_READER)); rrw_enter_read_prio(&dp->dp_config_rwlock, tag); } void dsl_pool_config_exit(dsl_pool_t *dp, const void *tag) { rrw_exit(&dp->dp_config_rwlock, tag); } boolean_t dsl_pool_config_held(dsl_pool_t *dp) { return (RRW_LOCK_HELD(&dp->dp_config_rwlock)); } boolean_t dsl_pool_config_held_writer(dsl_pool_t *dp) { return (RRW_WRITE_HELD(&dp->dp_config_rwlock)); } EXPORT_SYMBOL(dsl_pool_config_enter); EXPORT_SYMBOL(dsl_pool_config_exit); /* zfs_dirty_data_max_percent only applied at module load in arc_init(). */ ZFS_MODULE_PARAM(zfs, zfs_, dirty_data_max_percent, UINT, ZMOD_RD, "Max percent of RAM allowed to be dirty"); /* zfs_dirty_data_max_max_percent only applied at module load in arc_init(). */ ZFS_MODULE_PARAM(zfs, zfs_, dirty_data_max_max_percent, UINT, ZMOD_RD, "zfs_dirty_data_max upper bound as % of RAM"); ZFS_MODULE_PARAM(zfs, zfs_, delay_min_dirty_percent, UINT, ZMOD_RW, "Transaction delay threshold"); ZFS_MODULE_PARAM(zfs, zfs_, dirty_data_max, U64, ZMOD_RW, "Determines the dirty space limit"); ZFS_MODULE_PARAM(zfs, zfs_, wrlog_data_max, U64, ZMOD_RW, "The size limit of write-transaction zil log data"); /* zfs_dirty_data_max_max only applied at module load in arc_init(). */ ZFS_MODULE_PARAM(zfs, zfs_, dirty_data_max_max, U64, ZMOD_RD, "zfs_dirty_data_max upper bound in bytes"); ZFS_MODULE_PARAM(zfs, zfs_, dirty_data_sync_percent, UINT, ZMOD_RW, "Dirty data txg sync threshold as a percentage of zfs_dirty_data_max"); ZFS_MODULE_PARAM(zfs, zfs_, delay_scale, U64, ZMOD_RW, "How quickly delay approaches infinity"); ZFS_MODULE_PARAM(zfs, zfs_, sync_taskq_batch_pct, INT, ZMOD_RW, "Max percent of CPUs that are used to sync dirty data"); ZFS_MODULE_PARAM(zfs_zil, zfs_zil_, clean_taskq_nthr_pct, INT, ZMOD_RW, "Max percent of CPUs that are used per dp_sync_taskq"); ZFS_MODULE_PARAM(zfs_zil, zfs_zil_, clean_taskq_minalloc, INT, ZMOD_RW, "Number of taskq entries that are pre-populated"); ZFS_MODULE_PARAM(zfs_zil, zfs_zil_, clean_taskq_maxalloc, INT, ZMOD_RW, "Max number of taskq entries that are cached"); diff --git a/sys/contrib/openzfs/module/zfs/vdev.c b/sys/contrib/openzfs/module/zfs/vdev.c index 87c145593237..afb01c0ef7fd 100644 --- a/sys/contrib/openzfs/module/zfs/vdev.c +++ b/sys/contrib/openzfs/module/zfs/vdev.c @@ -1,6412 +1,6413 @@ /* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or https://opensource.org/licenses/CDDL-1.0. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright (c) 2005, 2010, Oracle and/or its affiliates. All rights reserved. * Copyright (c) 2011, 2021 by Delphix. All rights reserved. * Copyright 2017 Nexenta Systems, Inc. * Copyright (c) 2014 Integros [integros.com] * Copyright 2016 Toomas Soome * Copyright 2017 Joyent, Inc. * Copyright (c) 2017, Intel Corporation. * Copyright (c) 2019, Datto Inc. All rights reserved. * Copyright (c) 2021, Klara Inc. * Copyright (c) 2021, 2023 Hewlett Packard Enterprise Development LP. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "zfs_prop.h" /* * One metaslab from each (normal-class) vdev is used by the ZIL. These are * called "embedded slog metaslabs", are referenced by vdev_log_mg, and are * part of the spa_embedded_log_class. The metaslab with the most free space * in each vdev is selected for this purpose when the pool is opened (or a * vdev is added). See vdev_metaslab_init(). * * Log blocks can be allocated from the following locations. Each one is tried * in order until the allocation succeeds: * 1. dedicated log vdevs, aka "slog" (spa_log_class) * 2. embedded slog metaslabs (spa_embedded_log_class) * 3. other metaslabs in normal vdevs (spa_normal_class) * * zfs_embedded_slog_min_ms disables the embedded slog if there are fewer * than this number of metaslabs in the vdev. This ensures that we don't set * aside an unreasonable amount of space for the ZIL. If set to less than * 1 << (spa_slop_shift + 1), on small pools the usable space may be reduced * (by more than 1<vdev_path != NULL) { zfs_dbgmsg("%s vdev '%s': %s", vd->vdev_ops->vdev_op_type, vd->vdev_path, buf); } else { zfs_dbgmsg("%s-%llu vdev (guid %llu): %s", vd->vdev_ops->vdev_op_type, (u_longlong_t)vd->vdev_id, (u_longlong_t)vd->vdev_guid, buf); } } void vdev_dbgmsg_print_tree(vdev_t *vd, int indent) { char state[20]; if (vd->vdev_ishole || vd->vdev_ops == &vdev_missing_ops) { zfs_dbgmsg("%*svdev %llu: %s", indent, "", (u_longlong_t)vd->vdev_id, vd->vdev_ops->vdev_op_type); return; } switch (vd->vdev_state) { case VDEV_STATE_UNKNOWN: (void) snprintf(state, sizeof (state), "unknown"); break; case VDEV_STATE_CLOSED: (void) snprintf(state, sizeof (state), "closed"); break; case VDEV_STATE_OFFLINE: (void) snprintf(state, sizeof (state), "offline"); break; case VDEV_STATE_REMOVED: (void) snprintf(state, sizeof (state), "removed"); break; case VDEV_STATE_CANT_OPEN: (void) snprintf(state, sizeof (state), "can't open"); break; case VDEV_STATE_FAULTED: (void) snprintf(state, sizeof (state), "faulted"); break; case VDEV_STATE_DEGRADED: (void) snprintf(state, sizeof (state), "degraded"); break; case VDEV_STATE_HEALTHY: (void) snprintf(state, sizeof (state), "healthy"); break; default: (void) snprintf(state, sizeof (state), "", (uint_t)vd->vdev_state); } zfs_dbgmsg("%*svdev %u: %s%s, guid: %llu, path: %s, %s", indent, "", (int)vd->vdev_id, vd->vdev_ops->vdev_op_type, vd->vdev_islog ? " (log)" : "", (u_longlong_t)vd->vdev_guid, vd->vdev_path ? vd->vdev_path : "N/A", state); for (uint64_t i = 0; i < vd->vdev_children; i++) vdev_dbgmsg_print_tree(vd->vdev_child[i], indent + 2); } /* * Virtual device management. */ static vdev_ops_t *const vdev_ops_table[] = { &vdev_root_ops, &vdev_raidz_ops, &vdev_draid_ops, &vdev_draid_spare_ops, &vdev_mirror_ops, &vdev_replacing_ops, &vdev_spare_ops, &vdev_disk_ops, &vdev_file_ops, &vdev_missing_ops, &vdev_hole_ops, &vdev_indirect_ops, NULL }; /* * Given a vdev type, return the appropriate ops vector. */ static vdev_ops_t * vdev_getops(const char *type) { vdev_ops_t *ops, *const *opspp; for (opspp = vdev_ops_table; (ops = *opspp) != NULL; opspp++) if (strcmp(ops->vdev_op_type, type) == 0) break; return (ops); } /* * Given a vdev and a metaslab class, find which metaslab group we're * interested in. All vdevs may belong to two different metaslab classes. * Dedicated slog devices use only the primary metaslab group, rather than a * separate log group. For embedded slogs, the vdev_log_mg will be non-NULL. */ metaslab_group_t * vdev_get_mg(vdev_t *vd, metaslab_class_t *mc) { if (mc == spa_embedded_log_class(vd->vdev_spa) && vd->vdev_log_mg != NULL) return (vd->vdev_log_mg); else return (vd->vdev_mg); } void vdev_default_xlate(vdev_t *vd, const range_seg64_t *logical_rs, range_seg64_t *physical_rs, range_seg64_t *remain_rs) { (void) vd, (void) remain_rs; physical_rs->rs_start = logical_rs->rs_start; physical_rs->rs_end = logical_rs->rs_end; } /* * Derive the enumerated allocation bias from string input. * String origin is either the per-vdev zap or zpool(8). */ static vdev_alloc_bias_t vdev_derive_alloc_bias(const char *bias) { vdev_alloc_bias_t alloc_bias = VDEV_BIAS_NONE; if (strcmp(bias, VDEV_ALLOC_BIAS_LOG) == 0) alloc_bias = VDEV_BIAS_LOG; else if (strcmp(bias, VDEV_ALLOC_BIAS_SPECIAL) == 0) alloc_bias = VDEV_BIAS_SPECIAL; else if (strcmp(bias, VDEV_ALLOC_BIAS_DEDUP) == 0) alloc_bias = VDEV_BIAS_DEDUP; return (alloc_bias); } /* * Default asize function: return the MAX of psize with the asize of * all children. This is what's used by anything other than RAID-Z. */ uint64_t vdev_default_asize(vdev_t *vd, uint64_t psize) { uint64_t asize = P2ROUNDUP(psize, 1ULL << vd->vdev_top->vdev_ashift); uint64_t csize; for (int c = 0; c < vd->vdev_children; c++) { csize = vdev_psize_to_asize(vd->vdev_child[c], psize); asize = MAX(asize, csize); } return (asize); } uint64_t vdev_default_min_asize(vdev_t *vd) { return (vd->vdev_min_asize); } /* * Get the minimum allocatable size. We define the allocatable size as * the vdev's asize rounded to the nearest metaslab. This allows us to * replace or attach devices which don't have the same physical size but * can still satisfy the same number of allocations. */ uint64_t vdev_get_min_asize(vdev_t *vd) { vdev_t *pvd = vd->vdev_parent; /* * If our parent is NULL (inactive spare or cache) or is the root, * just return our own asize. */ if (pvd == NULL) return (vd->vdev_asize); /* * The top-level vdev just returns the allocatable size rounded * to the nearest metaslab. */ if (vd == vd->vdev_top) return (P2ALIGN(vd->vdev_asize, 1ULL << vd->vdev_ms_shift)); return (pvd->vdev_ops->vdev_op_min_asize(pvd)); } void vdev_set_min_asize(vdev_t *vd) { vd->vdev_min_asize = vdev_get_min_asize(vd); for (int c = 0; c < vd->vdev_children; c++) vdev_set_min_asize(vd->vdev_child[c]); } /* * Get the minimal allocation size for the top-level vdev. */ uint64_t vdev_get_min_alloc(vdev_t *vd) { uint64_t min_alloc = 1ULL << vd->vdev_ashift; if (vd->vdev_ops->vdev_op_min_alloc != NULL) min_alloc = vd->vdev_ops->vdev_op_min_alloc(vd); return (min_alloc); } /* * Get the parity level for a top-level vdev. */ uint64_t vdev_get_nparity(vdev_t *vd) { uint64_t nparity = 0; if (vd->vdev_ops->vdev_op_nparity != NULL) nparity = vd->vdev_ops->vdev_op_nparity(vd); return (nparity); } static int vdev_prop_get_int(vdev_t *vd, vdev_prop_t prop, uint64_t *value) { spa_t *spa = vd->vdev_spa; objset_t *mos = spa->spa_meta_objset; uint64_t objid; int err; if (vd->vdev_root_zap != 0) { objid = vd->vdev_root_zap; } else if (vd->vdev_top_zap != 0) { objid = vd->vdev_top_zap; } else if (vd->vdev_leaf_zap != 0) { objid = vd->vdev_leaf_zap; } else { return (EINVAL); } err = zap_lookup(mos, objid, vdev_prop_to_name(prop), sizeof (uint64_t), 1, value); if (err == ENOENT) *value = vdev_prop_default_numeric(prop); return (err); } /* * Get the number of data disks for a top-level vdev. */ uint64_t vdev_get_ndisks(vdev_t *vd) { uint64_t ndisks = 1; if (vd->vdev_ops->vdev_op_ndisks != NULL) ndisks = vd->vdev_ops->vdev_op_ndisks(vd); return (ndisks); } vdev_t * vdev_lookup_top(spa_t *spa, uint64_t vdev) { vdev_t *rvd = spa->spa_root_vdev; ASSERT(spa_config_held(spa, SCL_ALL, RW_READER) != 0); if (vdev < rvd->vdev_children) { ASSERT(rvd->vdev_child[vdev] != NULL); return (rvd->vdev_child[vdev]); } return (NULL); } vdev_t * vdev_lookup_by_guid(vdev_t *vd, uint64_t guid) { vdev_t *mvd; if (vd->vdev_guid == guid) return (vd); for (int c = 0; c < vd->vdev_children; c++) if ((mvd = vdev_lookup_by_guid(vd->vdev_child[c], guid)) != NULL) return (mvd); return (NULL); } static int vdev_count_leaves_impl(vdev_t *vd) { int n = 0; if (vd->vdev_ops->vdev_op_leaf) return (1); for (int c = 0; c < vd->vdev_children; c++) n += vdev_count_leaves_impl(vd->vdev_child[c]); return (n); } int vdev_count_leaves(spa_t *spa) { int rc; spa_config_enter(spa, SCL_VDEV, FTAG, RW_READER); rc = vdev_count_leaves_impl(spa->spa_root_vdev); spa_config_exit(spa, SCL_VDEV, FTAG); return (rc); } void vdev_add_child(vdev_t *pvd, vdev_t *cvd) { size_t oldsize, newsize; uint64_t id = cvd->vdev_id; vdev_t **newchild; ASSERT(spa_config_held(cvd->vdev_spa, SCL_ALL, RW_WRITER) == SCL_ALL); ASSERT(cvd->vdev_parent == NULL); cvd->vdev_parent = pvd; if (pvd == NULL) return; ASSERT(id >= pvd->vdev_children || pvd->vdev_child[id] == NULL); oldsize = pvd->vdev_children * sizeof (vdev_t *); pvd->vdev_children = MAX(pvd->vdev_children, id + 1); newsize = pvd->vdev_children * sizeof (vdev_t *); newchild = kmem_alloc(newsize, KM_SLEEP); if (pvd->vdev_child != NULL) { memcpy(newchild, pvd->vdev_child, oldsize); kmem_free(pvd->vdev_child, oldsize); } pvd->vdev_child = newchild; pvd->vdev_child[id] = cvd; cvd->vdev_top = (pvd->vdev_top ? pvd->vdev_top: cvd); ASSERT(cvd->vdev_top->vdev_parent->vdev_parent == NULL); /* * Walk up all ancestors to update guid sum. */ for (; pvd != NULL; pvd = pvd->vdev_parent) pvd->vdev_guid_sum += cvd->vdev_guid_sum; if (cvd->vdev_ops->vdev_op_leaf) { list_insert_head(&cvd->vdev_spa->spa_leaf_list, cvd); cvd->vdev_spa->spa_leaf_list_gen++; } } void vdev_remove_child(vdev_t *pvd, vdev_t *cvd) { int c; uint_t id = cvd->vdev_id; ASSERT(cvd->vdev_parent == pvd); if (pvd == NULL) return; ASSERT(id < pvd->vdev_children); ASSERT(pvd->vdev_child[id] == cvd); pvd->vdev_child[id] = NULL; cvd->vdev_parent = NULL; for (c = 0; c < pvd->vdev_children; c++) if (pvd->vdev_child[c]) break; if (c == pvd->vdev_children) { kmem_free(pvd->vdev_child, c * sizeof (vdev_t *)); pvd->vdev_child = NULL; pvd->vdev_children = 0; } if (cvd->vdev_ops->vdev_op_leaf) { spa_t *spa = cvd->vdev_spa; list_remove(&spa->spa_leaf_list, cvd); spa->spa_leaf_list_gen++; } /* * Walk up all ancestors to update guid sum. */ for (; pvd != NULL; pvd = pvd->vdev_parent) pvd->vdev_guid_sum -= cvd->vdev_guid_sum; } /* * Remove any holes in the child array. */ void vdev_compact_children(vdev_t *pvd) { vdev_t **newchild, *cvd; int oldc = pvd->vdev_children; int newc; ASSERT(spa_config_held(pvd->vdev_spa, SCL_ALL, RW_WRITER) == SCL_ALL); if (oldc == 0) return; for (int c = newc = 0; c < oldc; c++) if (pvd->vdev_child[c]) newc++; if (newc > 0) { newchild = kmem_zalloc(newc * sizeof (vdev_t *), KM_SLEEP); for (int c = newc = 0; c < oldc; c++) { if ((cvd = pvd->vdev_child[c]) != NULL) { newchild[newc] = cvd; cvd->vdev_id = newc++; } } } else { newchild = NULL; } kmem_free(pvd->vdev_child, oldc * sizeof (vdev_t *)); pvd->vdev_child = newchild; pvd->vdev_children = newc; } /* * Allocate and minimally initialize a vdev_t. */ vdev_t * vdev_alloc_common(spa_t *spa, uint_t id, uint64_t guid, vdev_ops_t *ops) { vdev_t *vd; vdev_indirect_config_t *vic; vd = kmem_zalloc(sizeof (vdev_t), KM_SLEEP); vic = &vd->vdev_indirect_config; if (spa->spa_root_vdev == NULL) { ASSERT(ops == &vdev_root_ops); spa->spa_root_vdev = vd; spa->spa_load_guid = spa_generate_guid(NULL); } if (guid == 0 && ops != &vdev_hole_ops) { if (spa->spa_root_vdev == vd) { /* * The root vdev's guid will also be the pool guid, * which must be unique among all pools. */ guid = spa_generate_guid(NULL); } else { /* * Any other vdev's guid must be unique within the pool. */ guid = spa_generate_guid(spa); } ASSERT(!spa_guid_exists(spa_guid(spa), guid)); } vd->vdev_spa = spa; vd->vdev_id = id; vd->vdev_guid = guid; vd->vdev_guid_sum = guid; vd->vdev_ops = ops; vd->vdev_state = VDEV_STATE_CLOSED; vd->vdev_ishole = (ops == &vdev_hole_ops); vic->vic_prev_indirect_vdev = UINT64_MAX; rw_init(&vd->vdev_indirect_rwlock, NULL, RW_DEFAULT, NULL); mutex_init(&vd->vdev_obsolete_lock, NULL, MUTEX_DEFAULT, NULL); vd->vdev_obsolete_segments = range_tree_create(NULL, RANGE_SEG64, NULL, 0, 0); /* * Initialize rate limit structs for events. We rate limit ZIO delay * and checksum events so that we don't overwhelm ZED with thousands * of events when a disk is acting up. */ zfs_ratelimit_init(&vd->vdev_delay_rl, &zfs_slow_io_events_per_second, 1); zfs_ratelimit_init(&vd->vdev_deadman_rl, &zfs_slow_io_events_per_second, 1); zfs_ratelimit_init(&vd->vdev_checksum_rl, &zfs_checksum_events_per_second, 1); /* * Default Thresholds for tuning ZED */ vd->vdev_checksum_n = vdev_prop_default_numeric(VDEV_PROP_CHECKSUM_N); vd->vdev_checksum_t = vdev_prop_default_numeric(VDEV_PROP_CHECKSUM_T); vd->vdev_io_n = vdev_prop_default_numeric(VDEV_PROP_IO_N); vd->vdev_io_t = vdev_prop_default_numeric(VDEV_PROP_IO_T); list_link_init(&vd->vdev_config_dirty_node); list_link_init(&vd->vdev_state_dirty_node); list_link_init(&vd->vdev_initialize_node); list_link_init(&vd->vdev_leaf_node); list_link_init(&vd->vdev_trim_node); mutex_init(&vd->vdev_dtl_lock, NULL, MUTEX_NOLOCKDEP, NULL); mutex_init(&vd->vdev_stat_lock, NULL, MUTEX_DEFAULT, NULL); mutex_init(&vd->vdev_probe_lock, NULL, MUTEX_DEFAULT, NULL); mutex_init(&vd->vdev_scan_io_queue_lock, NULL, MUTEX_DEFAULT, NULL); mutex_init(&vd->vdev_initialize_lock, NULL, MUTEX_DEFAULT, NULL); mutex_init(&vd->vdev_initialize_io_lock, NULL, MUTEX_DEFAULT, NULL); cv_init(&vd->vdev_initialize_cv, NULL, CV_DEFAULT, NULL); cv_init(&vd->vdev_initialize_io_cv, NULL, CV_DEFAULT, NULL); mutex_init(&vd->vdev_trim_lock, NULL, MUTEX_DEFAULT, NULL); mutex_init(&vd->vdev_autotrim_lock, NULL, MUTEX_DEFAULT, NULL); mutex_init(&vd->vdev_trim_io_lock, NULL, MUTEX_DEFAULT, NULL); cv_init(&vd->vdev_trim_cv, NULL, CV_DEFAULT, NULL); cv_init(&vd->vdev_autotrim_cv, NULL, CV_DEFAULT, NULL); cv_init(&vd->vdev_autotrim_kick_cv, NULL, CV_DEFAULT, NULL); cv_init(&vd->vdev_trim_io_cv, NULL, CV_DEFAULT, NULL); mutex_init(&vd->vdev_rebuild_lock, NULL, MUTEX_DEFAULT, NULL); cv_init(&vd->vdev_rebuild_cv, NULL, CV_DEFAULT, NULL); for (int t = 0; t < DTL_TYPES; t++) { vd->vdev_dtl[t] = range_tree_create(NULL, RANGE_SEG64, NULL, 0, 0); } txg_list_create(&vd->vdev_ms_list, spa, offsetof(struct metaslab, ms_txg_node)); txg_list_create(&vd->vdev_dtl_list, spa, offsetof(struct vdev, vdev_dtl_node)); vd->vdev_stat.vs_timestamp = gethrtime(); vdev_queue_init(vd); return (vd); } /* * Allocate a new vdev. The 'alloctype' is used to control whether we are * creating a new vdev or loading an existing one - the behavior is slightly * different for each case. */ int vdev_alloc(spa_t *spa, vdev_t **vdp, nvlist_t *nv, vdev_t *parent, uint_t id, int alloctype) { vdev_ops_t *ops; const char *type; uint64_t guid = 0, islog; vdev_t *vd; vdev_indirect_config_t *vic; const char *tmp = NULL; int rc; vdev_alloc_bias_t alloc_bias = VDEV_BIAS_NONE; boolean_t top_level = (parent && !parent->vdev_parent); ASSERT(spa_config_held(spa, SCL_ALL, RW_WRITER) == SCL_ALL); if (nvlist_lookup_string(nv, ZPOOL_CONFIG_TYPE, &type) != 0) return (SET_ERROR(EINVAL)); if ((ops = vdev_getops(type)) == NULL) return (SET_ERROR(EINVAL)); /* * If this is a load, get the vdev guid from the nvlist. * Otherwise, vdev_alloc_common() will generate one for us. */ if (alloctype == VDEV_ALLOC_LOAD) { uint64_t label_id; if (nvlist_lookup_uint64(nv, ZPOOL_CONFIG_ID, &label_id) || label_id != id) return (SET_ERROR(EINVAL)); if (nvlist_lookup_uint64(nv, ZPOOL_CONFIG_GUID, &guid) != 0) return (SET_ERROR(EINVAL)); } else if (alloctype == VDEV_ALLOC_SPARE) { if (nvlist_lookup_uint64(nv, ZPOOL_CONFIG_GUID, &guid) != 0) return (SET_ERROR(EINVAL)); } else if (alloctype == VDEV_ALLOC_L2CACHE) { if (nvlist_lookup_uint64(nv, ZPOOL_CONFIG_GUID, &guid) != 0) return (SET_ERROR(EINVAL)); } else if (alloctype == VDEV_ALLOC_ROOTPOOL) { if (nvlist_lookup_uint64(nv, ZPOOL_CONFIG_GUID, &guid) != 0) return (SET_ERROR(EINVAL)); } /* * The first allocated vdev must be of type 'root'. */ if (ops != &vdev_root_ops && spa->spa_root_vdev == NULL) return (SET_ERROR(EINVAL)); /* * Determine whether we're a log vdev. */ islog = 0; (void) nvlist_lookup_uint64(nv, ZPOOL_CONFIG_IS_LOG, &islog); if (islog && spa_version(spa) < SPA_VERSION_SLOGS) return (SET_ERROR(ENOTSUP)); if (ops == &vdev_hole_ops && spa_version(spa) < SPA_VERSION_HOLES) return (SET_ERROR(ENOTSUP)); if (top_level && alloctype == VDEV_ALLOC_ADD) { const char *bias; /* * If creating a top-level vdev, check for allocation * classes input. */ if (nvlist_lookup_string(nv, ZPOOL_CONFIG_ALLOCATION_BIAS, &bias) == 0) { alloc_bias = vdev_derive_alloc_bias(bias); /* spa_vdev_add() expects feature to be enabled */ if (spa->spa_load_state != SPA_LOAD_CREATE && !spa_feature_is_enabled(spa, SPA_FEATURE_ALLOCATION_CLASSES)) { return (SET_ERROR(ENOTSUP)); } } /* spa_vdev_add() expects feature to be enabled */ if (ops == &vdev_draid_ops && spa->spa_load_state != SPA_LOAD_CREATE && !spa_feature_is_enabled(spa, SPA_FEATURE_DRAID)) { return (SET_ERROR(ENOTSUP)); } } /* * Initialize the vdev specific data. This is done before calling * vdev_alloc_common() since it may fail and this simplifies the * error reporting and cleanup code paths. */ void *tsd = NULL; if (ops->vdev_op_init != NULL) { rc = ops->vdev_op_init(spa, nv, &tsd); if (rc != 0) { return (rc); } } vd = vdev_alloc_common(spa, id, guid, ops); vd->vdev_tsd = tsd; vd->vdev_islog = islog; if (top_level && alloc_bias != VDEV_BIAS_NONE) vd->vdev_alloc_bias = alloc_bias; if (nvlist_lookup_string(nv, ZPOOL_CONFIG_PATH, &tmp) == 0) vd->vdev_path = spa_strdup(tmp); /* * ZPOOL_CONFIG_AUX_STATE = "external" means we previously forced a * fault on a vdev and want it to persist across imports (like with * zpool offline -f). */ rc = nvlist_lookup_string(nv, ZPOOL_CONFIG_AUX_STATE, &tmp); if (rc == 0 && tmp != NULL && strcmp(tmp, "external") == 0) { vd->vdev_stat.vs_aux = VDEV_AUX_EXTERNAL; vd->vdev_faulted = 1; vd->vdev_label_aux = VDEV_AUX_EXTERNAL; } if (nvlist_lookup_string(nv, ZPOOL_CONFIG_DEVID, &tmp) == 0) vd->vdev_devid = spa_strdup(tmp); if (nvlist_lookup_string(nv, ZPOOL_CONFIG_PHYS_PATH, &tmp) == 0) vd->vdev_physpath = spa_strdup(tmp); if (nvlist_lookup_string(nv, ZPOOL_CONFIG_VDEV_ENC_SYSFS_PATH, &tmp) == 0) vd->vdev_enc_sysfs_path = spa_strdup(tmp); if (nvlist_lookup_string(nv, ZPOOL_CONFIG_FRU, &tmp) == 0) vd->vdev_fru = spa_strdup(tmp); /* * Set the whole_disk property. If it's not specified, leave the value * as -1. */ if (nvlist_lookup_uint64(nv, ZPOOL_CONFIG_WHOLE_DISK, &vd->vdev_wholedisk) != 0) vd->vdev_wholedisk = -1ULL; vic = &vd->vdev_indirect_config; ASSERT0(vic->vic_mapping_object); (void) nvlist_lookup_uint64(nv, ZPOOL_CONFIG_INDIRECT_OBJECT, &vic->vic_mapping_object); ASSERT0(vic->vic_births_object); (void) nvlist_lookup_uint64(nv, ZPOOL_CONFIG_INDIRECT_BIRTHS, &vic->vic_births_object); ASSERT3U(vic->vic_prev_indirect_vdev, ==, UINT64_MAX); (void) nvlist_lookup_uint64(nv, ZPOOL_CONFIG_PREV_INDIRECT_VDEV, &vic->vic_prev_indirect_vdev); /* * Look for the 'not present' flag. This will only be set if the device * was not present at the time of import. */ (void) nvlist_lookup_uint64(nv, ZPOOL_CONFIG_NOT_PRESENT, &vd->vdev_not_present); /* * Get the alignment requirement. Ignore pool ashift for vdev * attach case. */ if (alloctype != VDEV_ALLOC_ATTACH) { (void) nvlist_lookup_uint64(nv, ZPOOL_CONFIG_ASHIFT, &vd->vdev_ashift); } else { vd->vdev_attaching = B_TRUE; } /* * Retrieve the vdev creation time. */ (void) nvlist_lookup_uint64(nv, ZPOOL_CONFIG_CREATE_TXG, &vd->vdev_crtxg); if (vd->vdev_ops == &vdev_root_ops && (alloctype == VDEV_ALLOC_LOAD || alloctype == VDEV_ALLOC_SPLIT || alloctype == VDEV_ALLOC_ROOTPOOL)) { (void) nvlist_lookup_uint64(nv, ZPOOL_CONFIG_VDEV_ROOT_ZAP, &vd->vdev_root_zap); } /* * If we're a top-level vdev, try to load the allocation parameters. */ if (top_level && (alloctype == VDEV_ALLOC_LOAD || alloctype == VDEV_ALLOC_SPLIT)) { (void) nvlist_lookup_uint64(nv, ZPOOL_CONFIG_METASLAB_ARRAY, &vd->vdev_ms_array); (void) nvlist_lookup_uint64(nv, ZPOOL_CONFIG_METASLAB_SHIFT, &vd->vdev_ms_shift); (void) nvlist_lookup_uint64(nv, ZPOOL_CONFIG_ASIZE, &vd->vdev_asize); (void) nvlist_lookup_uint64(nv, ZPOOL_CONFIG_NONALLOCATING, &vd->vdev_noalloc); (void) nvlist_lookup_uint64(nv, ZPOOL_CONFIG_REMOVING, &vd->vdev_removing); (void) nvlist_lookup_uint64(nv, ZPOOL_CONFIG_VDEV_TOP_ZAP, &vd->vdev_top_zap); } else { ASSERT0(vd->vdev_top_zap); } if (top_level && alloctype != VDEV_ALLOC_ATTACH) { ASSERT(alloctype == VDEV_ALLOC_LOAD || alloctype == VDEV_ALLOC_ADD || alloctype == VDEV_ALLOC_SPLIT || alloctype == VDEV_ALLOC_ROOTPOOL); /* Note: metaslab_group_create() is now deferred */ } if (vd->vdev_ops->vdev_op_leaf && (alloctype == VDEV_ALLOC_LOAD || alloctype == VDEV_ALLOC_SPLIT)) { (void) nvlist_lookup_uint64(nv, ZPOOL_CONFIG_VDEV_LEAF_ZAP, &vd->vdev_leaf_zap); } else { ASSERT0(vd->vdev_leaf_zap); } /* * If we're a leaf vdev, try to load the DTL object and other state. */ if (vd->vdev_ops->vdev_op_leaf && (alloctype == VDEV_ALLOC_LOAD || alloctype == VDEV_ALLOC_L2CACHE || alloctype == VDEV_ALLOC_ROOTPOOL)) { if (alloctype == VDEV_ALLOC_LOAD) { (void) nvlist_lookup_uint64(nv, ZPOOL_CONFIG_DTL, &vd->vdev_dtl_object); (void) nvlist_lookup_uint64(nv, ZPOOL_CONFIG_UNSPARE, &vd->vdev_unspare); } if (alloctype == VDEV_ALLOC_ROOTPOOL) { uint64_t spare = 0; if (nvlist_lookup_uint64(nv, ZPOOL_CONFIG_IS_SPARE, &spare) == 0 && spare) spa_spare_add(vd); } (void) nvlist_lookup_uint64(nv, ZPOOL_CONFIG_OFFLINE, &vd->vdev_offline); (void) nvlist_lookup_uint64(nv, ZPOOL_CONFIG_RESILVER_TXG, &vd->vdev_resilver_txg); (void) nvlist_lookup_uint64(nv, ZPOOL_CONFIG_REBUILD_TXG, &vd->vdev_rebuild_txg); if (nvlist_exists(nv, ZPOOL_CONFIG_RESILVER_DEFER)) vdev_defer_resilver(vd); /* * In general, when importing a pool we want to ignore the * persistent fault state, as the diagnosis made on another * system may not be valid in the current context. The only * exception is if we forced a vdev to a persistently faulted * state with 'zpool offline -f'. The persistent fault will * remain across imports until cleared. * * Local vdevs will remain in the faulted state. */ if (spa_load_state(spa) == SPA_LOAD_OPEN || spa_load_state(spa) == SPA_LOAD_IMPORT) { (void) nvlist_lookup_uint64(nv, ZPOOL_CONFIG_FAULTED, &vd->vdev_faulted); (void) nvlist_lookup_uint64(nv, ZPOOL_CONFIG_DEGRADED, &vd->vdev_degraded); (void) nvlist_lookup_uint64(nv, ZPOOL_CONFIG_REMOVED, &vd->vdev_removed); if (vd->vdev_faulted || vd->vdev_degraded) { const char *aux; vd->vdev_label_aux = VDEV_AUX_ERR_EXCEEDED; if (nvlist_lookup_string(nv, ZPOOL_CONFIG_AUX_STATE, &aux) == 0 && strcmp(aux, "external") == 0) vd->vdev_label_aux = VDEV_AUX_EXTERNAL; else vd->vdev_faulted = 0ULL; } } } /* * Add ourselves to the parent's list of children. */ vdev_add_child(parent, vd); *vdp = vd; return (0); } void vdev_free(vdev_t *vd) { spa_t *spa = vd->vdev_spa; ASSERT3P(vd->vdev_initialize_thread, ==, NULL); ASSERT3P(vd->vdev_trim_thread, ==, NULL); ASSERT3P(vd->vdev_autotrim_thread, ==, NULL); ASSERT3P(vd->vdev_rebuild_thread, ==, NULL); /* * Scan queues are normally destroyed at the end of a scan. If the * queue exists here, that implies the vdev is being removed while * the scan is still running. */ if (vd->vdev_scan_io_queue != NULL) { mutex_enter(&vd->vdev_scan_io_queue_lock); dsl_scan_io_queue_destroy(vd->vdev_scan_io_queue); vd->vdev_scan_io_queue = NULL; mutex_exit(&vd->vdev_scan_io_queue_lock); } /* * vdev_free() implies closing the vdev first. This is simpler than * trying to ensure complicated semantics for all callers. */ vdev_close(vd); ASSERT(!list_link_active(&vd->vdev_config_dirty_node)); ASSERT(!list_link_active(&vd->vdev_state_dirty_node)); /* * Free all children. */ for (int c = 0; c < vd->vdev_children; c++) vdev_free(vd->vdev_child[c]); ASSERT(vd->vdev_child == NULL); ASSERT(vd->vdev_guid_sum == vd->vdev_guid); if (vd->vdev_ops->vdev_op_fini != NULL) vd->vdev_ops->vdev_op_fini(vd); /* * Discard allocation state. */ if (vd->vdev_mg != NULL) { vdev_metaslab_fini(vd); metaslab_group_destroy(vd->vdev_mg); vd->vdev_mg = NULL; } if (vd->vdev_log_mg != NULL) { ASSERT0(vd->vdev_ms_count); metaslab_group_destroy(vd->vdev_log_mg); vd->vdev_log_mg = NULL; } ASSERT0(vd->vdev_stat.vs_space); ASSERT0(vd->vdev_stat.vs_dspace); ASSERT0(vd->vdev_stat.vs_alloc); /* * Remove this vdev from its parent's child list. */ vdev_remove_child(vd->vdev_parent, vd); ASSERT(vd->vdev_parent == NULL); ASSERT(!list_link_active(&vd->vdev_leaf_node)); /* * Clean up vdev structure. */ vdev_queue_fini(vd); if (vd->vdev_path) spa_strfree(vd->vdev_path); if (vd->vdev_devid) spa_strfree(vd->vdev_devid); if (vd->vdev_physpath) spa_strfree(vd->vdev_physpath); if (vd->vdev_enc_sysfs_path) spa_strfree(vd->vdev_enc_sysfs_path); if (vd->vdev_fru) spa_strfree(vd->vdev_fru); if (vd->vdev_isspare) spa_spare_remove(vd); if (vd->vdev_isl2cache) spa_l2cache_remove(vd); txg_list_destroy(&vd->vdev_ms_list); txg_list_destroy(&vd->vdev_dtl_list); mutex_enter(&vd->vdev_dtl_lock); space_map_close(vd->vdev_dtl_sm); for (int t = 0; t < DTL_TYPES; t++) { range_tree_vacate(vd->vdev_dtl[t], NULL, NULL); range_tree_destroy(vd->vdev_dtl[t]); } mutex_exit(&vd->vdev_dtl_lock); EQUIV(vd->vdev_indirect_births != NULL, vd->vdev_indirect_mapping != NULL); if (vd->vdev_indirect_births != NULL) { vdev_indirect_mapping_close(vd->vdev_indirect_mapping); vdev_indirect_births_close(vd->vdev_indirect_births); } if (vd->vdev_obsolete_sm != NULL) { ASSERT(vd->vdev_removing || vd->vdev_ops == &vdev_indirect_ops); space_map_close(vd->vdev_obsolete_sm); vd->vdev_obsolete_sm = NULL; } range_tree_destroy(vd->vdev_obsolete_segments); rw_destroy(&vd->vdev_indirect_rwlock); mutex_destroy(&vd->vdev_obsolete_lock); mutex_destroy(&vd->vdev_dtl_lock); mutex_destroy(&vd->vdev_stat_lock); mutex_destroy(&vd->vdev_probe_lock); mutex_destroy(&vd->vdev_scan_io_queue_lock); mutex_destroy(&vd->vdev_initialize_lock); mutex_destroy(&vd->vdev_initialize_io_lock); cv_destroy(&vd->vdev_initialize_io_cv); cv_destroy(&vd->vdev_initialize_cv); mutex_destroy(&vd->vdev_trim_lock); mutex_destroy(&vd->vdev_autotrim_lock); mutex_destroy(&vd->vdev_trim_io_lock); cv_destroy(&vd->vdev_trim_cv); cv_destroy(&vd->vdev_autotrim_cv); cv_destroy(&vd->vdev_autotrim_kick_cv); cv_destroy(&vd->vdev_trim_io_cv); mutex_destroy(&vd->vdev_rebuild_lock); cv_destroy(&vd->vdev_rebuild_cv); zfs_ratelimit_fini(&vd->vdev_delay_rl); zfs_ratelimit_fini(&vd->vdev_deadman_rl); zfs_ratelimit_fini(&vd->vdev_checksum_rl); if (vd == spa->spa_root_vdev) spa->spa_root_vdev = NULL; kmem_free(vd, sizeof (vdev_t)); } /* * Transfer top-level vdev state from svd to tvd. */ static void vdev_top_transfer(vdev_t *svd, vdev_t *tvd) { spa_t *spa = svd->vdev_spa; metaslab_t *msp; vdev_t *vd; int t; ASSERT(tvd == tvd->vdev_top); tvd->vdev_ms_array = svd->vdev_ms_array; tvd->vdev_ms_shift = svd->vdev_ms_shift; tvd->vdev_ms_count = svd->vdev_ms_count; tvd->vdev_top_zap = svd->vdev_top_zap; svd->vdev_ms_array = 0; svd->vdev_ms_shift = 0; svd->vdev_ms_count = 0; svd->vdev_top_zap = 0; if (tvd->vdev_mg) ASSERT3P(tvd->vdev_mg, ==, svd->vdev_mg); if (tvd->vdev_log_mg) ASSERT3P(tvd->vdev_log_mg, ==, svd->vdev_log_mg); tvd->vdev_mg = svd->vdev_mg; tvd->vdev_log_mg = svd->vdev_log_mg; tvd->vdev_ms = svd->vdev_ms; svd->vdev_mg = NULL; svd->vdev_log_mg = NULL; svd->vdev_ms = NULL; if (tvd->vdev_mg != NULL) tvd->vdev_mg->mg_vd = tvd; if (tvd->vdev_log_mg != NULL) tvd->vdev_log_mg->mg_vd = tvd; tvd->vdev_checkpoint_sm = svd->vdev_checkpoint_sm; svd->vdev_checkpoint_sm = NULL; tvd->vdev_alloc_bias = svd->vdev_alloc_bias; svd->vdev_alloc_bias = VDEV_BIAS_NONE; tvd->vdev_stat.vs_alloc = svd->vdev_stat.vs_alloc; tvd->vdev_stat.vs_space = svd->vdev_stat.vs_space; tvd->vdev_stat.vs_dspace = svd->vdev_stat.vs_dspace; svd->vdev_stat.vs_alloc = 0; svd->vdev_stat.vs_space = 0; svd->vdev_stat.vs_dspace = 0; /* * State which may be set on a top-level vdev that's in the * process of being removed. */ ASSERT0(tvd->vdev_indirect_config.vic_births_object); ASSERT0(tvd->vdev_indirect_config.vic_mapping_object); ASSERT3U(tvd->vdev_indirect_config.vic_prev_indirect_vdev, ==, -1ULL); ASSERT3P(tvd->vdev_indirect_mapping, ==, NULL); ASSERT3P(tvd->vdev_indirect_births, ==, NULL); ASSERT3P(tvd->vdev_obsolete_sm, ==, NULL); ASSERT0(tvd->vdev_noalloc); ASSERT0(tvd->vdev_removing); ASSERT0(tvd->vdev_rebuilding); tvd->vdev_noalloc = svd->vdev_noalloc; tvd->vdev_removing = svd->vdev_removing; tvd->vdev_rebuilding = svd->vdev_rebuilding; tvd->vdev_rebuild_config = svd->vdev_rebuild_config; tvd->vdev_indirect_config = svd->vdev_indirect_config; tvd->vdev_indirect_mapping = svd->vdev_indirect_mapping; tvd->vdev_indirect_births = svd->vdev_indirect_births; range_tree_swap(&svd->vdev_obsolete_segments, &tvd->vdev_obsolete_segments); tvd->vdev_obsolete_sm = svd->vdev_obsolete_sm; svd->vdev_indirect_config.vic_mapping_object = 0; svd->vdev_indirect_config.vic_births_object = 0; svd->vdev_indirect_config.vic_prev_indirect_vdev = -1ULL; svd->vdev_indirect_mapping = NULL; svd->vdev_indirect_births = NULL; svd->vdev_obsolete_sm = NULL; svd->vdev_noalloc = 0; svd->vdev_removing = 0; svd->vdev_rebuilding = 0; for (t = 0; t < TXG_SIZE; t++) { while ((msp = txg_list_remove(&svd->vdev_ms_list, t)) != NULL) (void) txg_list_add(&tvd->vdev_ms_list, msp, t); while ((vd = txg_list_remove(&svd->vdev_dtl_list, t)) != NULL) (void) txg_list_add(&tvd->vdev_dtl_list, vd, t); if (txg_list_remove_this(&spa->spa_vdev_txg_list, svd, t)) (void) txg_list_add(&spa->spa_vdev_txg_list, tvd, t); } if (list_link_active(&svd->vdev_config_dirty_node)) { vdev_config_clean(svd); vdev_config_dirty(tvd); } if (list_link_active(&svd->vdev_state_dirty_node)) { vdev_state_clean(svd); vdev_state_dirty(tvd); } tvd->vdev_deflate_ratio = svd->vdev_deflate_ratio; svd->vdev_deflate_ratio = 0; tvd->vdev_islog = svd->vdev_islog; svd->vdev_islog = 0; dsl_scan_io_queue_vdev_xfer(svd, tvd); } static void vdev_top_update(vdev_t *tvd, vdev_t *vd) { if (vd == NULL) return; vd->vdev_top = tvd; for (int c = 0; c < vd->vdev_children; c++) vdev_top_update(tvd, vd->vdev_child[c]); } /* * Add a mirror/replacing vdev above an existing vdev. There is no need to * call .vdev_op_init() since mirror/replacing vdevs do not have private state. */ vdev_t * vdev_add_parent(vdev_t *cvd, vdev_ops_t *ops) { spa_t *spa = cvd->vdev_spa; vdev_t *pvd = cvd->vdev_parent; vdev_t *mvd; ASSERT(spa_config_held(spa, SCL_ALL, RW_WRITER) == SCL_ALL); mvd = vdev_alloc_common(spa, cvd->vdev_id, 0, ops); mvd->vdev_asize = cvd->vdev_asize; mvd->vdev_min_asize = cvd->vdev_min_asize; mvd->vdev_max_asize = cvd->vdev_max_asize; mvd->vdev_psize = cvd->vdev_psize; mvd->vdev_ashift = cvd->vdev_ashift; mvd->vdev_logical_ashift = cvd->vdev_logical_ashift; mvd->vdev_physical_ashift = cvd->vdev_physical_ashift; mvd->vdev_state = cvd->vdev_state; mvd->vdev_crtxg = cvd->vdev_crtxg; vdev_remove_child(pvd, cvd); vdev_add_child(pvd, mvd); cvd->vdev_id = mvd->vdev_children; vdev_add_child(mvd, cvd); vdev_top_update(cvd->vdev_top, cvd->vdev_top); if (mvd == mvd->vdev_top) vdev_top_transfer(cvd, mvd); return (mvd); } /* * Remove a 1-way mirror/replacing vdev from the tree. */ void vdev_remove_parent(vdev_t *cvd) { vdev_t *mvd = cvd->vdev_parent; vdev_t *pvd = mvd->vdev_parent; ASSERT(spa_config_held(cvd->vdev_spa, SCL_ALL, RW_WRITER) == SCL_ALL); ASSERT(mvd->vdev_children == 1); ASSERT(mvd->vdev_ops == &vdev_mirror_ops || mvd->vdev_ops == &vdev_replacing_ops || mvd->vdev_ops == &vdev_spare_ops); cvd->vdev_ashift = mvd->vdev_ashift; cvd->vdev_logical_ashift = mvd->vdev_logical_ashift; cvd->vdev_physical_ashift = mvd->vdev_physical_ashift; vdev_remove_child(mvd, cvd); vdev_remove_child(pvd, mvd); /* * If cvd will replace mvd as a top-level vdev, preserve mvd's guid. * Otherwise, we could have detached an offline device, and when we * go to import the pool we'll think we have two top-level vdevs, * instead of a different version of the same top-level vdev. */ if (mvd->vdev_top == mvd) { uint64_t guid_delta = mvd->vdev_guid - cvd->vdev_guid; cvd->vdev_orig_guid = cvd->vdev_guid; cvd->vdev_guid += guid_delta; cvd->vdev_guid_sum += guid_delta; /* * If pool not set for autoexpand, we need to also preserve * mvd's asize to prevent automatic expansion of cvd. * Otherwise if we are adjusting the mirror by attaching and * detaching children of non-uniform sizes, the mirror could * autoexpand, unexpectedly requiring larger devices to * re-establish the mirror. */ if (!cvd->vdev_spa->spa_autoexpand) cvd->vdev_asize = mvd->vdev_asize; } cvd->vdev_id = mvd->vdev_id; vdev_add_child(pvd, cvd); vdev_top_update(cvd->vdev_top, cvd->vdev_top); if (cvd == cvd->vdev_top) vdev_top_transfer(mvd, cvd); ASSERT(mvd->vdev_children == 0); vdev_free(mvd); } /* * Choose GCD for spa_gcd_alloc. */ static uint64_t vdev_gcd(uint64_t a, uint64_t b) { while (b != 0) { uint64_t t = b; b = a % b; a = t; } return (a); } /* * Set spa_min_alloc and spa_gcd_alloc. */ static void vdev_spa_set_alloc(spa_t *spa, uint64_t min_alloc) { if (min_alloc < spa->spa_min_alloc) spa->spa_min_alloc = min_alloc; if (spa->spa_gcd_alloc == INT_MAX) { spa->spa_gcd_alloc = min_alloc; } else { spa->spa_gcd_alloc = vdev_gcd(min_alloc, spa->spa_gcd_alloc); } } void vdev_metaslab_group_create(vdev_t *vd) { spa_t *spa = vd->vdev_spa; /* * metaslab_group_create was delayed until allocation bias was available */ if (vd->vdev_mg == NULL) { metaslab_class_t *mc; if (vd->vdev_islog && vd->vdev_alloc_bias == VDEV_BIAS_NONE) vd->vdev_alloc_bias = VDEV_BIAS_LOG; ASSERT3U(vd->vdev_islog, ==, (vd->vdev_alloc_bias == VDEV_BIAS_LOG)); switch (vd->vdev_alloc_bias) { case VDEV_BIAS_LOG: mc = spa_log_class(spa); break; case VDEV_BIAS_SPECIAL: mc = spa_special_class(spa); break; case VDEV_BIAS_DEDUP: mc = spa_dedup_class(spa); break; default: mc = spa_normal_class(spa); } vd->vdev_mg = metaslab_group_create(mc, vd, spa->spa_alloc_count); if (!vd->vdev_islog) { vd->vdev_log_mg = metaslab_group_create( spa_embedded_log_class(spa), vd, 1); } /* * The spa ashift min/max only apply for the normal metaslab * class. Class destination is late binding so ashift boundary * setting had to wait until now. */ if (vd->vdev_top == vd && vd->vdev_ashift != 0 && mc == spa_normal_class(spa) && vd->vdev_aux == NULL) { if (vd->vdev_ashift > spa->spa_max_ashift) spa->spa_max_ashift = vd->vdev_ashift; if (vd->vdev_ashift < spa->spa_min_ashift) spa->spa_min_ashift = vd->vdev_ashift; uint64_t min_alloc = vdev_get_min_alloc(vd); vdev_spa_set_alloc(spa, min_alloc); } } } int vdev_metaslab_init(vdev_t *vd, uint64_t txg) { spa_t *spa = vd->vdev_spa; uint64_t oldc = vd->vdev_ms_count; uint64_t newc = vd->vdev_asize >> vd->vdev_ms_shift; metaslab_t **mspp; int error; boolean_t expanding = (oldc != 0); ASSERT(txg == 0 || spa_config_held(spa, SCL_ALLOC, RW_WRITER)); /* * This vdev is not being allocated from yet or is a hole. */ if (vd->vdev_ms_shift == 0) return (0); ASSERT(!vd->vdev_ishole); ASSERT(oldc <= newc); mspp = vmem_zalloc(newc * sizeof (*mspp), KM_SLEEP); if (expanding) { memcpy(mspp, vd->vdev_ms, oldc * sizeof (*mspp)); vmem_free(vd->vdev_ms, oldc * sizeof (*mspp)); } vd->vdev_ms = mspp; vd->vdev_ms_count = newc; for (uint64_t m = oldc; m < newc; m++) { uint64_t object = 0; /* * vdev_ms_array may be 0 if we are creating the "fake" * metaslabs for an indirect vdev for zdb's leak detection. * See zdb_leak_init(). */ if (txg == 0 && vd->vdev_ms_array != 0) { error = dmu_read(spa->spa_meta_objset, vd->vdev_ms_array, m * sizeof (uint64_t), sizeof (uint64_t), &object, DMU_READ_PREFETCH); if (error != 0) { vdev_dbgmsg(vd, "unable to read the metaslab " "array [error=%d]", error); return (error); } } error = metaslab_init(vd->vdev_mg, m, object, txg, &(vd->vdev_ms[m])); if (error != 0) { vdev_dbgmsg(vd, "metaslab_init failed [error=%d]", error); return (error); } } /* * Find the emptiest metaslab on the vdev and mark it for use for * embedded slog by moving it from the regular to the log metaslab * group. */ if (vd->vdev_mg->mg_class == spa_normal_class(spa) && vd->vdev_ms_count > zfs_embedded_slog_min_ms && avl_is_empty(&vd->vdev_log_mg->mg_metaslab_tree)) { uint64_t slog_msid = 0; uint64_t smallest = UINT64_MAX; /* * Note, we only search the new metaslabs, because the old * (pre-existing) ones may be active (e.g. have non-empty * range_tree's), and we don't move them to the new * metaslab_t. */ for (uint64_t m = oldc; m < newc; m++) { uint64_t alloc = space_map_allocated(vd->vdev_ms[m]->ms_sm); if (alloc < smallest) { slog_msid = m; smallest = alloc; } } metaslab_t *slog_ms = vd->vdev_ms[slog_msid]; /* * The metaslab was marked as dirty at the end of * metaslab_init(). Remove it from the dirty list so that we * can uninitialize and reinitialize it to the new class. */ if (txg != 0) { (void) txg_list_remove_this(&vd->vdev_ms_list, slog_ms, txg); } uint64_t sm_obj = space_map_object(slog_ms->ms_sm); metaslab_fini(slog_ms); VERIFY0(metaslab_init(vd->vdev_log_mg, slog_msid, sm_obj, txg, &vd->vdev_ms[slog_msid])); } if (txg == 0) spa_config_enter(spa, SCL_ALLOC, FTAG, RW_WRITER); /* * If the vdev is marked as non-allocating then don't * activate the metaslabs since we want to ensure that * no allocations are performed on this device. */ if (vd->vdev_noalloc) { /* track non-allocating vdev space */ spa->spa_nonallocating_dspace += spa_deflate(spa) ? vd->vdev_stat.vs_dspace : vd->vdev_stat.vs_space; } else if (!expanding) { metaslab_group_activate(vd->vdev_mg); if (vd->vdev_log_mg != NULL) metaslab_group_activate(vd->vdev_log_mg); } if (txg == 0) spa_config_exit(spa, SCL_ALLOC, FTAG); return (0); } void vdev_metaslab_fini(vdev_t *vd) { if (vd->vdev_checkpoint_sm != NULL) { ASSERT(spa_feature_is_active(vd->vdev_spa, SPA_FEATURE_POOL_CHECKPOINT)); space_map_close(vd->vdev_checkpoint_sm); /* * Even though we close the space map, we need to set its * pointer to NULL. The reason is that vdev_metaslab_fini() * may be called multiple times for certain operations * (i.e. when destroying a pool) so we need to ensure that * this clause never executes twice. This logic is similar * to the one used for the vdev_ms clause below. */ vd->vdev_checkpoint_sm = NULL; } if (vd->vdev_ms != NULL) { metaslab_group_t *mg = vd->vdev_mg; metaslab_group_passivate(mg); if (vd->vdev_log_mg != NULL) { ASSERT(!vd->vdev_islog); metaslab_group_passivate(vd->vdev_log_mg); } uint64_t count = vd->vdev_ms_count; for (uint64_t m = 0; m < count; m++) { metaslab_t *msp = vd->vdev_ms[m]; if (msp != NULL) metaslab_fini(msp); } vmem_free(vd->vdev_ms, count * sizeof (metaslab_t *)); vd->vdev_ms = NULL; vd->vdev_ms_count = 0; for (int i = 0; i < RANGE_TREE_HISTOGRAM_SIZE; i++) { ASSERT0(mg->mg_histogram[i]); if (vd->vdev_log_mg != NULL) ASSERT0(vd->vdev_log_mg->mg_histogram[i]); } } ASSERT0(vd->vdev_ms_count); } typedef struct vdev_probe_stats { boolean_t vps_readable; boolean_t vps_writeable; int vps_flags; } vdev_probe_stats_t; static void vdev_probe_done(zio_t *zio) { spa_t *spa = zio->io_spa; vdev_t *vd = zio->io_vd; vdev_probe_stats_t *vps = zio->io_private; ASSERT(vd->vdev_probe_zio != NULL); if (zio->io_type == ZIO_TYPE_READ) { if (zio->io_error == 0) vps->vps_readable = 1; if (zio->io_error == 0 && spa_writeable(spa)) { zio_nowait(zio_write_phys(vd->vdev_probe_zio, vd, zio->io_offset, zio->io_size, zio->io_abd, ZIO_CHECKSUM_OFF, vdev_probe_done, vps, ZIO_PRIORITY_SYNC_WRITE, vps->vps_flags, B_TRUE)); } else { abd_free(zio->io_abd); } } else if (zio->io_type == ZIO_TYPE_WRITE) { if (zio->io_error == 0) vps->vps_writeable = 1; abd_free(zio->io_abd); } else if (zio->io_type == ZIO_TYPE_NULL) { zio_t *pio; zio_link_t *zl; vd->vdev_cant_read |= !vps->vps_readable; vd->vdev_cant_write |= !vps->vps_writeable; if (vdev_readable(vd) && (vdev_writeable(vd) || !spa_writeable(spa))) { zio->io_error = 0; } else { ASSERT(zio->io_error != 0); vdev_dbgmsg(vd, "failed probe"); (void) zfs_ereport_post(FM_EREPORT_ZFS_PROBE_FAILURE, spa, vd, NULL, NULL, 0); zio->io_error = SET_ERROR(ENXIO); } mutex_enter(&vd->vdev_probe_lock); ASSERT(vd->vdev_probe_zio == zio); vd->vdev_probe_zio = NULL; mutex_exit(&vd->vdev_probe_lock); zl = NULL; while ((pio = zio_walk_parents(zio, &zl)) != NULL) if (!vdev_accessible(vd, pio)) pio->io_error = SET_ERROR(ENXIO); kmem_free(vps, sizeof (*vps)); } } /* * Determine whether this device is accessible. * * Read and write to several known locations: the pad regions of each * vdev label but the first, which we leave alone in case it contains * a VTOC. */ zio_t * vdev_probe(vdev_t *vd, zio_t *zio) { spa_t *spa = vd->vdev_spa; vdev_probe_stats_t *vps = NULL; zio_t *pio; ASSERT(vd->vdev_ops->vdev_op_leaf); /* * Don't probe the probe. */ if (zio && (zio->io_flags & ZIO_FLAG_PROBE)) return (NULL); /* * To prevent 'probe storms' when a device fails, we create * just one probe i/o at a time. All zios that want to probe * this vdev will become parents of the probe io. */ mutex_enter(&vd->vdev_probe_lock); if ((pio = vd->vdev_probe_zio) == NULL) { vps = kmem_zalloc(sizeof (*vps), KM_SLEEP); vps->vps_flags = ZIO_FLAG_CANFAIL | ZIO_FLAG_PROBE | ZIO_FLAG_DONT_AGGREGATE | ZIO_FLAG_TRYHARD; if (spa_config_held(spa, SCL_ZIO, RW_WRITER)) { /* * vdev_cant_read and vdev_cant_write can only * transition from TRUE to FALSE when we have the * SCL_ZIO lock as writer; otherwise they can only * transition from FALSE to TRUE. This ensures that * any zio looking at these values can assume that * failures persist for the life of the I/O. That's * important because when a device has intermittent * connectivity problems, we want to ensure that * they're ascribed to the device (ENXIO) and not * the zio (EIO). * * Since we hold SCL_ZIO as writer here, clear both * values so the probe can reevaluate from first * principles. */ vps->vps_flags |= ZIO_FLAG_CONFIG_WRITER; vd->vdev_cant_read = B_FALSE; vd->vdev_cant_write = B_FALSE; } vd->vdev_probe_zio = pio = zio_null(NULL, spa, vd, vdev_probe_done, vps, vps->vps_flags | ZIO_FLAG_DONT_PROPAGATE); /* * We can't change the vdev state in this context, so we * kick off an async task to do it on our behalf. */ if (zio != NULL) { vd->vdev_probe_wanted = B_TRUE; spa_async_request(spa, SPA_ASYNC_PROBE); } } if (zio != NULL) zio_add_child(zio, pio); mutex_exit(&vd->vdev_probe_lock); if (vps == NULL) { ASSERT(zio != NULL); return (NULL); } for (int l = 1; l < VDEV_LABELS; l++) { zio_nowait(zio_read_phys(pio, vd, vdev_label_offset(vd->vdev_psize, l, offsetof(vdev_label_t, vl_be)), VDEV_PAD_SIZE, abd_alloc_for_io(VDEV_PAD_SIZE, B_TRUE), ZIO_CHECKSUM_OFF, vdev_probe_done, vps, ZIO_PRIORITY_SYNC_READ, vps->vps_flags, B_TRUE)); } if (zio == NULL) return (pio); zio_nowait(pio); return (NULL); } static void vdev_load_child(void *arg) { vdev_t *vd = arg; vd->vdev_load_error = vdev_load(vd); } static void vdev_open_child(void *arg) { vdev_t *vd = arg; vd->vdev_open_thread = curthread; vd->vdev_open_error = vdev_open(vd); vd->vdev_open_thread = NULL; } static boolean_t vdev_uses_zvols(vdev_t *vd) { #ifdef _KERNEL if (zvol_is_zvol(vd->vdev_path)) return (B_TRUE); #endif for (int c = 0; c < vd->vdev_children; c++) if (vdev_uses_zvols(vd->vdev_child[c])) return (B_TRUE); return (B_FALSE); } /* * Returns B_TRUE if the passed child should be opened. */ static boolean_t vdev_default_open_children_func(vdev_t *vd) { (void) vd; return (B_TRUE); } /* * Open the requested child vdevs. If any of the leaf vdevs are using * a ZFS volume then do the opens in a single thread. This avoids a * deadlock when the current thread is holding the spa_namespace_lock. */ static void vdev_open_children_impl(vdev_t *vd, vdev_open_children_func_t *open_func) { int children = vd->vdev_children; taskq_t *tq = taskq_create("vdev_open", children, minclsyspri, children, children, TASKQ_PREPOPULATE); vd->vdev_nonrot = B_TRUE; for (int c = 0; c < children; c++) { vdev_t *cvd = vd->vdev_child[c]; if (open_func(cvd) == B_FALSE) continue; if (tq == NULL || vdev_uses_zvols(vd)) { cvd->vdev_open_error = vdev_open(cvd); } else { VERIFY(taskq_dispatch(tq, vdev_open_child, cvd, TQ_SLEEP) != TASKQID_INVALID); } vd->vdev_nonrot &= cvd->vdev_nonrot; } if (tq != NULL) { taskq_wait(tq); taskq_destroy(tq); } } /* * Open all child vdevs. */ void vdev_open_children(vdev_t *vd) { vdev_open_children_impl(vd, vdev_default_open_children_func); } /* * Conditionally open a subset of child vdevs. */ void vdev_open_children_subset(vdev_t *vd, vdev_open_children_func_t *open_func) { vdev_open_children_impl(vd, open_func); } /* * Compute the raidz-deflation ratio. Note, we hard-code * in 128k (1 << 17) because it is the "typical" blocksize. * Even though SPA_MAXBLOCKSIZE changed, this algorithm can not change, * otherwise it would inconsistently account for existing bp's. */ static void vdev_set_deflate_ratio(vdev_t *vd) { if (vd == vd->vdev_top && !vd->vdev_ishole && vd->vdev_ashift != 0) { vd->vdev_deflate_ratio = (1 << 17) / (vdev_psize_to_asize(vd, 1 << 17) >> SPA_MINBLOCKSHIFT); } } /* * Choose the best of two ashifts, preferring one between logical ashift * (absolute minimum) and administrator defined maximum, otherwise take * the biggest of the two. */ uint64_t vdev_best_ashift(uint64_t logical, uint64_t a, uint64_t b) { if (a > logical && a <= zfs_vdev_max_auto_ashift) { if (b <= logical || b > zfs_vdev_max_auto_ashift) return (a); else return (MAX(a, b)); } else if (b <= logical || b > zfs_vdev_max_auto_ashift) return (MAX(a, b)); return (b); } /* * Maximize performance by inflating the configured ashift for top level * vdevs to be as close to the physical ashift as possible while maintaining * administrator defined limits and ensuring it doesn't go below the * logical ashift. */ static void vdev_ashift_optimize(vdev_t *vd) { ASSERT(vd == vd->vdev_top); if (vd->vdev_ashift < vd->vdev_physical_ashift && vd->vdev_physical_ashift <= zfs_vdev_max_auto_ashift) { vd->vdev_ashift = MIN( MAX(zfs_vdev_max_auto_ashift, vd->vdev_ashift), MAX(zfs_vdev_min_auto_ashift, vd->vdev_physical_ashift)); } else { /* * If the logical and physical ashifts are the same, then * we ensure that the top-level vdev's ashift is not smaller * than our minimum ashift value. For the unusual case * where logical ashift > physical ashift, we can't cap * the calculated ashift based on max ashift as that * would cause failures. * We still check if we need to increase it to match * the min ashift. */ vd->vdev_ashift = MAX(zfs_vdev_min_auto_ashift, vd->vdev_ashift); } } /* * Prepare a virtual device for access. */ int vdev_open(vdev_t *vd) { spa_t *spa = vd->vdev_spa; int error; uint64_t osize = 0; uint64_t max_osize = 0; uint64_t asize, max_asize, psize; uint64_t logical_ashift = 0; uint64_t physical_ashift = 0; ASSERT(vd->vdev_open_thread == curthread || spa_config_held(spa, SCL_STATE_ALL, RW_WRITER) == SCL_STATE_ALL); ASSERT(vd->vdev_state == VDEV_STATE_CLOSED || vd->vdev_state == VDEV_STATE_CANT_OPEN || vd->vdev_state == VDEV_STATE_OFFLINE); vd->vdev_stat.vs_aux = VDEV_AUX_NONE; vd->vdev_cant_read = B_FALSE; vd->vdev_cant_write = B_FALSE; vd->vdev_min_asize = vdev_get_min_asize(vd); /* * If this vdev is not removed, check its fault status. If it's * faulted, bail out of the open. */ if (!vd->vdev_removed && vd->vdev_faulted) { ASSERT(vd->vdev_children == 0); ASSERT(vd->vdev_label_aux == VDEV_AUX_ERR_EXCEEDED || vd->vdev_label_aux == VDEV_AUX_EXTERNAL); vdev_set_state(vd, B_TRUE, VDEV_STATE_FAULTED, vd->vdev_label_aux); return (SET_ERROR(ENXIO)); } else if (vd->vdev_offline) { ASSERT(vd->vdev_children == 0); vdev_set_state(vd, B_TRUE, VDEV_STATE_OFFLINE, VDEV_AUX_NONE); return (SET_ERROR(ENXIO)); } error = vd->vdev_ops->vdev_op_open(vd, &osize, &max_osize, &logical_ashift, &physical_ashift); /* Keep the device in removed state if unplugged */ if (error == ENOENT && vd->vdev_removed) { vdev_set_state(vd, B_TRUE, VDEV_STATE_REMOVED, VDEV_AUX_NONE); return (error); } /* * Physical volume size should never be larger than its max size, unless * the disk has shrunk while we were reading it or the device is buggy * or damaged: either way it's not safe for use, bail out of the open. */ if (osize > max_osize) { vdev_set_state(vd, B_TRUE, VDEV_STATE_CANT_OPEN, VDEV_AUX_OPEN_FAILED); return (SET_ERROR(ENXIO)); } /* * Reset the vdev_reopening flag so that we actually close * the vdev on error. */ vd->vdev_reopening = B_FALSE; if (zio_injection_enabled && error == 0) error = zio_handle_device_injection(vd, NULL, SET_ERROR(ENXIO)); if (error) { if (vd->vdev_removed && vd->vdev_stat.vs_aux != VDEV_AUX_OPEN_FAILED) vd->vdev_removed = B_FALSE; if (vd->vdev_stat.vs_aux == VDEV_AUX_CHILDREN_OFFLINE) { vdev_set_state(vd, B_TRUE, VDEV_STATE_OFFLINE, vd->vdev_stat.vs_aux); } else { vdev_set_state(vd, B_TRUE, VDEV_STATE_CANT_OPEN, vd->vdev_stat.vs_aux); } return (error); } vd->vdev_removed = B_FALSE; /* * Recheck the faulted flag now that we have confirmed that * the vdev is accessible. If we're faulted, bail. */ if (vd->vdev_faulted) { ASSERT(vd->vdev_children == 0); ASSERT(vd->vdev_label_aux == VDEV_AUX_ERR_EXCEEDED || vd->vdev_label_aux == VDEV_AUX_EXTERNAL); vdev_set_state(vd, B_TRUE, VDEV_STATE_FAULTED, vd->vdev_label_aux); return (SET_ERROR(ENXIO)); } if (vd->vdev_degraded) { ASSERT(vd->vdev_children == 0); vdev_set_state(vd, B_TRUE, VDEV_STATE_DEGRADED, VDEV_AUX_ERR_EXCEEDED); } else { vdev_set_state(vd, B_TRUE, VDEV_STATE_HEALTHY, 0); } /* * For hole or missing vdevs we just return success. */ if (vd->vdev_ishole || vd->vdev_ops == &vdev_missing_ops) return (0); for (int c = 0; c < vd->vdev_children; c++) { if (vd->vdev_child[c]->vdev_state != VDEV_STATE_HEALTHY) { vdev_set_state(vd, B_TRUE, VDEV_STATE_DEGRADED, VDEV_AUX_NONE); break; } } osize = P2ALIGN(osize, (uint64_t)sizeof (vdev_label_t)); max_osize = P2ALIGN(max_osize, (uint64_t)sizeof (vdev_label_t)); if (vd->vdev_children == 0) { if (osize < SPA_MINDEVSIZE) { vdev_set_state(vd, B_TRUE, VDEV_STATE_CANT_OPEN, VDEV_AUX_TOO_SMALL); return (SET_ERROR(EOVERFLOW)); } psize = osize; asize = osize - (VDEV_LABEL_START_SIZE + VDEV_LABEL_END_SIZE); max_asize = max_osize - (VDEV_LABEL_START_SIZE + VDEV_LABEL_END_SIZE); } else { if (vd->vdev_parent != NULL && osize < SPA_MINDEVSIZE - (VDEV_LABEL_START_SIZE + VDEV_LABEL_END_SIZE)) { vdev_set_state(vd, B_TRUE, VDEV_STATE_CANT_OPEN, VDEV_AUX_TOO_SMALL); return (SET_ERROR(EOVERFLOW)); } psize = 0; asize = osize; max_asize = max_osize; } /* * If the vdev was expanded, record this so that we can re-create the * uberblock rings in labels {2,3}, during the next sync. */ if ((psize > vd->vdev_psize) && (vd->vdev_psize != 0)) vd->vdev_copy_uberblocks = B_TRUE; vd->vdev_psize = psize; /* * Make sure the allocatable size hasn't shrunk too much. */ if (asize < vd->vdev_min_asize) { vdev_set_state(vd, B_TRUE, VDEV_STATE_CANT_OPEN, VDEV_AUX_BAD_LABEL); return (SET_ERROR(EINVAL)); } /* * We can always set the logical/physical ashift members since * their values are only used to calculate the vdev_ashift when * the device is first added to the config. These values should * not be used for anything else since they may change whenever * the device is reopened and we don't store them in the label. */ vd->vdev_physical_ashift = MAX(physical_ashift, vd->vdev_physical_ashift); vd->vdev_logical_ashift = MAX(logical_ashift, vd->vdev_logical_ashift); if (vd->vdev_asize == 0) { /* * This is the first-ever open, so use the computed values. * For compatibility, a different ashift can be requested. */ vd->vdev_asize = asize; vd->vdev_max_asize = max_asize; /* * If the vdev_ashift was not overridden at creation time, * then set it the logical ashift and optimize the ashift. */ if (vd->vdev_ashift == 0) { vd->vdev_ashift = vd->vdev_logical_ashift; if (vd->vdev_logical_ashift > ASHIFT_MAX) { vdev_set_state(vd, B_TRUE, VDEV_STATE_CANT_OPEN, VDEV_AUX_ASHIFT_TOO_BIG); return (SET_ERROR(EDOM)); } if (vd->vdev_top == vd && vd->vdev_attaching == B_FALSE) vdev_ashift_optimize(vd); vd->vdev_attaching = B_FALSE; } if (vd->vdev_ashift != 0 && (vd->vdev_ashift < ASHIFT_MIN || vd->vdev_ashift > ASHIFT_MAX)) { vdev_set_state(vd, B_TRUE, VDEV_STATE_CANT_OPEN, VDEV_AUX_BAD_ASHIFT); return (SET_ERROR(EDOM)); } } else { /* * Make sure the alignment required hasn't increased. */ if (vd->vdev_ashift > vd->vdev_top->vdev_ashift && vd->vdev_ops->vdev_op_leaf) { (void) zfs_ereport_post( FM_EREPORT_ZFS_DEVICE_BAD_ASHIFT, spa, vd, NULL, NULL, 0); vdev_set_state(vd, B_TRUE, VDEV_STATE_CANT_OPEN, VDEV_AUX_BAD_LABEL); return (SET_ERROR(EDOM)); } vd->vdev_max_asize = max_asize; } /* * If all children are healthy we update asize if either: * The asize has increased, due to a device expansion caused by dynamic * LUN growth or vdev replacement, and automatic expansion is enabled; * making the additional space available. * * The asize has decreased, due to a device shrink usually caused by a * vdev replace with a smaller device. This ensures that calculations * based of max_asize and asize e.g. esize are always valid. It's safe * to do this as we've already validated that asize is greater than * vdev_min_asize. */ if (vd->vdev_state == VDEV_STATE_HEALTHY && ((asize > vd->vdev_asize && (vd->vdev_expanding || spa->spa_autoexpand)) || (asize < vd->vdev_asize))) vd->vdev_asize = asize; vdev_set_min_asize(vd); /* * Ensure we can issue some IO before declaring the * vdev open for business. */ if (vd->vdev_ops->vdev_op_leaf && (error = zio_wait(vdev_probe(vd, NULL))) != 0) { vdev_set_state(vd, B_TRUE, VDEV_STATE_FAULTED, VDEV_AUX_ERR_EXCEEDED); return (error); } /* * Track the minimum allocation size. */ if (vd->vdev_top == vd && vd->vdev_ashift != 0 && vd->vdev_islog == 0 && vd->vdev_aux == NULL) { uint64_t min_alloc = vdev_get_min_alloc(vd); vdev_spa_set_alloc(spa, min_alloc); } /* * If this is a leaf vdev, assess whether a resilver is needed. * But don't do this if we are doing a reopen for a scrub, since * this would just restart the scrub we are already doing. */ if (vd->vdev_ops->vdev_op_leaf && !spa->spa_scrub_reopen) dsl_scan_assess_vdev(spa->spa_dsl_pool, vd); return (0); } static void vdev_validate_child(void *arg) { vdev_t *vd = arg; vd->vdev_validate_thread = curthread; vd->vdev_validate_error = vdev_validate(vd); vd->vdev_validate_thread = NULL; } /* * Called once the vdevs are all opened, this routine validates the label * contents. This needs to be done before vdev_load() so that we don't * inadvertently do repair I/Os to the wrong device. * * This function will only return failure if one of the vdevs indicates that it * has since been destroyed or exported. This is only possible if * /etc/zfs/zpool.cache was readonly at the time. Otherwise, the vdev state * will be updated but the function will return 0. */ int vdev_validate(vdev_t *vd) { spa_t *spa = vd->vdev_spa; taskq_t *tq = NULL; nvlist_t *label; uint64_t guid = 0, aux_guid = 0, top_guid; uint64_t state; nvlist_t *nvl; uint64_t txg; int children = vd->vdev_children; if (vdev_validate_skip) return (0); if (children > 0) { tq = taskq_create("vdev_validate", children, minclsyspri, children, children, TASKQ_PREPOPULATE); } for (uint64_t c = 0; c < children; c++) { vdev_t *cvd = vd->vdev_child[c]; if (tq == NULL || vdev_uses_zvols(cvd)) { vdev_validate_child(cvd); } else { VERIFY(taskq_dispatch(tq, vdev_validate_child, cvd, TQ_SLEEP) != TASKQID_INVALID); } } if (tq != NULL) { taskq_wait(tq); taskq_destroy(tq); } for (int c = 0; c < children; c++) { int error = vd->vdev_child[c]->vdev_validate_error; if (error != 0) return (SET_ERROR(EBADF)); } /* * If the device has already failed, or was marked offline, don't do * any further validation. Otherwise, label I/O will fail and we will * overwrite the previous state. */ if (!vd->vdev_ops->vdev_op_leaf || !vdev_readable(vd)) return (0); /* * If we are performing an extreme rewind, we allow for a label that * was modified at a point after the current txg. * If config lock is not held do not check for the txg. spa_sync could * be updating the vdev's label before updating spa_last_synced_txg. */ if (spa->spa_extreme_rewind || spa_last_synced_txg(spa) == 0 || spa_config_held(spa, SCL_CONFIG, RW_WRITER) != SCL_CONFIG) txg = UINT64_MAX; else txg = spa_last_synced_txg(spa); if ((label = vdev_label_read_config(vd, txg)) == NULL) { vdev_set_state(vd, B_FALSE, VDEV_STATE_CANT_OPEN, VDEV_AUX_BAD_LABEL); vdev_dbgmsg(vd, "vdev_validate: failed reading config for " "txg %llu", (u_longlong_t)txg); return (0); } /* * Determine if this vdev has been split off into another * pool. If so, then refuse to open it. */ if (nvlist_lookup_uint64(label, ZPOOL_CONFIG_SPLIT_GUID, &aux_guid) == 0 && aux_guid == spa_guid(spa)) { vdev_set_state(vd, B_FALSE, VDEV_STATE_CANT_OPEN, VDEV_AUX_SPLIT_POOL); nvlist_free(label); vdev_dbgmsg(vd, "vdev_validate: vdev split into other pool"); return (0); } if (nvlist_lookup_uint64(label, ZPOOL_CONFIG_POOL_GUID, &guid) != 0) { vdev_set_state(vd, B_FALSE, VDEV_STATE_CANT_OPEN, VDEV_AUX_CORRUPT_DATA); nvlist_free(label); vdev_dbgmsg(vd, "vdev_validate: '%s' missing from label", ZPOOL_CONFIG_POOL_GUID); return (0); } /* * If config is not trusted then ignore the spa guid check. This is * necessary because if the machine crashed during a re-guid the new * guid might have been written to all of the vdev labels, but not the * cached config. The check will be performed again once we have the * trusted config from the MOS. */ if (spa->spa_trust_config && guid != spa_guid(spa)) { vdev_set_state(vd, B_FALSE, VDEV_STATE_CANT_OPEN, VDEV_AUX_CORRUPT_DATA); nvlist_free(label); vdev_dbgmsg(vd, "vdev_validate: vdev label pool_guid doesn't " "match config (%llu != %llu)", (u_longlong_t)guid, (u_longlong_t)spa_guid(spa)); return (0); } if (nvlist_lookup_nvlist(label, ZPOOL_CONFIG_VDEV_TREE, &nvl) != 0 || nvlist_lookup_uint64(nvl, ZPOOL_CONFIG_ORIG_GUID, &aux_guid) != 0) aux_guid = 0; if (nvlist_lookup_uint64(label, ZPOOL_CONFIG_GUID, &guid) != 0) { vdev_set_state(vd, B_FALSE, VDEV_STATE_CANT_OPEN, VDEV_AUX_CORRUPT_DATA); nvlist_free(label); vdev_dbgmsg(vd, "vdev_validate: '%s' missing from label", ZPOOL_CONFIG_GUID); return (0); } if (nvlist_lookup_uint64(label, ZPOOL_CONFIG_TOP_GUID, &top_guid) != 0) { vdev_set_state(vd, B_FALSE, VDEV_STATE_CANT_OPEN, VDEV_AUX_CORRUPT_DATA); nvlist_free(label); vdev_dbgmsg(vd, "vdev_validate: '%s' missing from label", ZPOOL_CONFIG_TOP_GUID); return (0); } /* * If this vdev just became a top-level vdev because its sibling was * detached, it will have adopted the parent's vdev guid -- but the * label may or may not be on disk yet. Fortunately, either version * of the label will have the same top guid, so if we're a top-level * vdev, we can safely compare to that instead. * However, if the config comes from a cachefile that failed to update * after the detach, a top-level vdev will appear as a non top-level * vdev in the config. Also relax the constraints if we perform an * extreme rewind. * * If we split this vdev off instead, then we also check the * original pool's guid. We don't want to consider the vdev * corrupt if it is partway through a split operation. */ if (vd->vdev_guid != guid && vd->vdev_guid != aux_guid) { boolean_t mismatch = B_FALSE; if (spa->spa_trust_config && !spa->spa_extreme_rewind) { if (vd != vd->vdev_top || vd->vdev_guid != top_guid) mismatch = B_TRUE; } else { if (vd->vdev_guid != top_guid && vd->vdev_top->vdev_guid != guid) mismatch = B_TRUE; } if (mismatch) { vdev_set_state(vd, B_FALSE, VDEV_STATE_CANT_OPEN, VDEV_AUX_CORRUPT_DATA); nvlist_free(label); vdev_dbgmsg(vd, "vdev_validate: config guid " "doesn't match label guid"); vdev_dbgmsg(vd, "CONFIG: guid %llu, top_guid %llu", (u_longlong_t)vd->vdev_guid, (u_longlong_t)vd->vdev_top->vdev_guid); vdev_dbgmsg(vd, "LABEL: guid %llu, top_guid %llu, " "aux_guid %llu", (u_longlong_t)guid, (u_longlong_t)top_guid, (u_longlong_t)aux_guid); return (0); } } if (nvlist_lookup_uint64(label, ZPOOL_CONFIG_POOL_STATE, &state) != 0) { vdev_set_state(vd, B_FALSE, VDEV_STATE_CANT_OPEN, VDEV_AUX_CORRUPT_DATA); nvlist_free(label); vdev_dbgmsg(vd, "vdev_validate: '%s' missing from label", ZPOOL_CONFIG_POOL_STATE); return (0); } nvlist_free(label); /* * If this is a verbatim import, no need to check the * state of the pool. */ if (!(spa->spa_import_flags & ZFS_IMPORT_VERBATIM) && spa_load_state(spa) == SPA_LOAD_OPEN && state != POOL_STATE_ACTIVE) { vdev_dbgmsg(vd, "vdev_validate: invalid pool state (%llu) " "for spa %s", (u_longlong_t)state, spa->spa_name); return (SET_ERROR(EBADF)); } /* * If we were able to open and validate a vdev that was * previously marked permanently unavailable, clear that state * now. */ if (vd->vdev_not_present) vd->vdev_not_present = 0; return (0); } static void vdev_copy_path_impl(vdev_t *svd, vdev_t *dvd) { char *old, *new; if (svd->vdev_path != NULL && dvd->vdev_path != NULL) { if (strcmp(svd->vdev_path, dvd->vdev_path) != 0) { zfs_dbgmsg("vdev_copy_path: vdev %llu: path changed " "from '%s' to '%s'", (u_longlong_t)dvd->vdev_guid, dvd->vdev_path, svd->vdev_path); spa_strfree(dvd->vdev_path); dvd->vdev_path = spa_strdup(svd->vdev_path); } } else if (svd->vdev_path != NULL) { dvd->vdev_path = spa_strdup(svd->vdev_path); zfs_dbgmsg("vdev_copy_path: vdev %llu: path set to '%s'", (u_longlong_t)dvd->vdev_guid, dvd->vdev_path); } /* * Our enclosure sysfs path may have changed between imports */ old = dvd->vdev_enc_sysfs_path; new = svd->vdev_enc_sysfs_path; if ((old != NULL && new == NULL) || (old == NULL && new != NULL) || ((old != NULL && new != NULL) && strcmp(new, old) != 0)) { zfs_dbgmsg("vdev_copy_path: vdev %llu: vdev_enc_sysfs_path " "changed from '%s' to '%s'", (u_longlong_t)dvd->vdev_guid, old, new); if (dvd->vdev_enc_sysfs_path) spa_strfree(dvd->vdev_enc_sysfs_path); if (svd->vdev_enc_sysfs_path) { dvd->vdev_enc_sysfs_path = spa_strdup( svd->vdev_enc_sysfs_path); } else { dvd->vdev_enc_sysfs_path = NULL; } } } /* * Recursively copy vdev paths from one vdev to another. Source and destination * vdev trees must have same geometry otherwise return error. Intended to copy * paths from userland config into MOS config. */ int vdev_copy_path_strict(vdev_t *svd, vdev_t *dvd) { if ((svd->vdev_ops == &vdev_missing_ops) || (svd->vdev_ishole && dvd->vdev_ishole) || (dvd->vdev_ops == &vdev_indirect_ops)) return (0); if (svd->vdev_ops != dvd->vdev_ops) { vdev_dbgmsg(svd, "vdev_copy_path: vdev type mismatch: %s != %s", svd->vdev_ops->vdev_op_type, dvd->vdev_ops->vdev_op_type); return (SET_ERROR(EINVAL)); } if (svd->vdev_guid != dvd->vdev_guid) { vdev_dbgmsg(svd, "vdev_copy_path: guids mismatch (%llu != " "%llu)", (u_longlong_t)svd->vdev_guid, (u_longlong_t)dvd->vdev_guid); return (SET_ERROR(EINVAL)); } if (svd->vdev_children != dvd->vdev_children) { vdev_dbgmsg(svd, "vdev_copy_path: children count mismatch: " "%llu != %llu", (u_longlong_t)svd->vdev_children, (u_longlong_t)dvd->vdev_children); return (SET_ERROR(EINVAL)); } for (uint64_t i = 0; i < svd->vdev_children; i++) { int error = vdev_copy_path_strict(svd->vdev_child[i], dvd->vdev_child[i]); if (error != 0) return (error); } if (svd->vdev_ops->vdev_op_leaf) vdev_copy_path_impl(svd, dvd); return (0); } static void vdev_copy_path_search(vdev_t *stvd, vdev_t *dvd) { ASSERT(stvd->vdev_top == stvd); ASSERT3U(stvd->vdev_id, ==, dvd->vdev_top->vdev_id); for (uint64_t i = 0; i < dvd->vdev_children; i++) { vdev_copy_path_search(stvd, dvd->vdev_child[i]); } if (!dvd->vdev_ops->vdev_op_leaf || !vdev_is_concrete(dvd)) return; /* * The idea here is that while a vdev can shift positions within * a top vdev (when replacing, attaching mirror, etc.) it cannot * step outside of it. */ vdev_t *vd = vdev_lookup_by_guid(stvd, dvd->vdev_guid); if (vd == NULL || vd->vdev_ops != dvd->vdev_ops) return; ASSERT(vd->vdev_ops->vdev_op_leaf); vdev_copy_path_impl(vd, dvd); } /* * Recursively copy vdev paths from one root vdev to another. Source and * destination vdev trees may differ in geometry. For each destination leaf * vdev, search a vdev with the same guid and top vdev id in the source. * Intended to copy paths from userland config into MOS config. */ void vdev_copy_path_relaxed(vdev_t *srvd, vdev_t *drvd) { uint64_t children = MIN(srvd->vdev_children, drvd->vdev_children); ASSERT(srvd->vdev_ops == &vdev_root_ops); ASSERT(drvd->vdev_ops == &vdev_root_ops); for (uint64_t i = 0; i < children; i++) { vdev_copy_path_search(srvd->vdev_child[i], drvd->vdev_child[i]); } } /* * Close a virtual device. */ void vdev_close(vdev_t *vd) { vdev_t *pvd = vd->vdev_parent; spa_t *spa __maybe_unused = vd->vdev_spa; ASSERT(vd != NULL); ASSERT(vd->vdev_open_thread == curthread || spa_config_held(spa, SCL_STATE_ALL, RW_WRITER) == SCL_STATE_ALL); /* * If our parent is reopening, then we are as well, unless we are * going offline. */ if (pvd != NULL && pvd->vdev_reopening) vd->vdev_reopening = (pvd->vdev_reopening && !vd->vdev_offline); vd->vdev_ops->vdev_op_close(vd); /* * We record the previous state before we close it, so that if we are * doing a reopen(), we don't generate FMA ereports if we notice that * it's still faulted. */ vd->vdev_prevstate = vd->vdev_state; if (vd->vdev_offline) vd->vdev_state = VDEV_STATE_OFFLINE; else vd->vdev_state = VDEV_STATE_CLOSED; vd->vdev_stat.vs_aux = VDEV_AUX_NONE; } void vdev_hold(vdev_t *vd) { spa_t *spa = vd->vdev_spa; ASSERT(spa_is_root(spa)); if (spa->spa_state == POOL_STATE_UNINITIALIZED) return; for (int c = 0; c < vd->vdev_children; c++) vdev_hold(vd->vdev_child[c]); if (vd->vdev_ops->vdev_op_leaf && vd->vdev_ops->vdev_op_hold != NULL) vd->vdev_ops->vdev_op_hold(vd); } void vdev_rele(vdev_t *vd) { ASSERT(spa_is_root(vd->vdev_spa)); for (int c = 0; c < vd->vdev_children; c++) vdev_rele(vd->vdev_child[c]); if (vd->vdev_ops->vdev_op_leaf && vd->vdev_ops->vdev_op_rele != NULL) vd->vdev_ops->vdev_op_rele(vd); } /* * Reopen all interior vdevs and any unopened leaves. We don't actually * reopen leaf vdevs which had previously been opened as they might deadlock * on the spa_config_lock. Instead we only obtain the leaf's physical size. * If the leaf has never been opened then open it, as usual. */ void vdev_reopen(vdev_t *vd) { spa_t *spa = vd->vdev_spa; ASSERT(spa_config_held(spa, SCL_STATE_ALL, RW_WRITER) == SCL_STATE_ALL); /* set the reopening flag unless we're taking the vdev offline */ vd->vdev_reopening = !vd->vdev_offline; vdev_close(vd); (void) vdev_open(vd); /* * Call vdev_validate() here to make sure we have the same device. * Otherwise, a device with an invalid label could be successfully * opened in response to vdev_reopen(). */ if (vd->vdev_aux) { (void) vdev_validate_aux(vd); if (vdev_readable(vd) && vdev_writeable(vd) && vd->vdev_aux == &spa->spa_l2cache) { /* * In case the vdev is present we should evict all ARC * buffers and pointers to log blocks and reclaim their * space before restoring its contents to L2ARC. */ if (l2arc_vdev_present(vd)) { l2arc_rebuild_vdev(vd, B_TRUE); } else { l2arc_add_vdev(spa, vd); } spa_async_request(spa, SPA_ASYNC_L2CACHE_REBUILD); spa_async_request(spa, SPA_ASYNC_L2CACHE_TRIM); } } else { (void) vdev_validate(vd); } /* * Recheck if resilver is still needed and cancel any * scheduled resilver if resilver is unneeded. */ if (!vdev_resilver_needed(spa->spa_root_vdev, NULL, NULL) && spa->spa_async_tasks & SPA_ASYNC_RESILVER) { mutex_enter(&spa->spa_async_lock); spa->spa_async_tasks &= ~SPA_ASYNC_RESILVER; mutex_exit(&spa->spa_async_lock); } /* * Reassess parent vdev's health. */ vdev_propagate_state(vd); } int vdev_create(vdev_t *vd, uint64_t txg, boolean_t isreplacing) { int error; /* * Normally, partial opens (e.g. of a mirror) are allowed. * For a create, however, we want to fail the request if * there are any components we can't open. */ error = vdev_open(vd); if (error || vd->vdev_state != VDEV_STATE_HEALTHY) { vdev_close(vd); return (error ? error : SET_ERROR(ENXIO)); } /* * Recursively load DTLs and initialize all labels. */ if ((error = vdev_dtl_load(vd)) != 0 || (error = vdev_label_init(vd, txg, isreplacing ? VDEV_LABEL_REPLACE : VDEV_LABEL_CREATE)) != 0) { vdev_close(vd); return (error); } return (0); } void vdev_metaslab_set_size(vdev_t *vd) { uint64_t asize = vd->vdev_asize; uint64_t ms_count = asize >> zfs_vdev_default_ms_shift; uint64_t ms_shift; /* * There are two dimensions to the metaslab sizing calculation: * the size of the metaslab and the count of metaslabs per vdev. * * The default values used below are a good balance between memory * usage (larger metaslab size means more memory needed for loaded * metaslabs; more metaslabs means more memory needed for the * metaslab_t structs), metaslab load time (larger metaslabs take * longer to load), and metaslab sync time (more metaslabs means * more time spent syncing all of them). * * In general, we aim for zfs_vdev_default_ms_count (200) metaslabs. * The range of the dimensions are as follows: * * 2^29 <= ms_size <= 2^34 * 16 <= ms_count <= 131,072 * * On the lower end of vdev sizes, we aim for metaslabs sizes of * at least 512MB (2^29) to minimize fragmentation effects when * testing with smaller devices. However, the count constraint * of at least 16 metaslabs will override this minimum size goal. * * On the upper end of vdev sizes, we aim for a maximum metaslab * size of 16GB. However, we will cap the total count to 2^17 * metaslabs to keep our memory footprint in check and let the * metaslab size grow from there if that limit is hit. * * The net effect of applying above constrains is summarized below. * * vdev size metaslab count * --------------|----------------- * < 8GB ~16 * 8GB - 100GB one per 512MB * 100GB - 3TB ~200 * 3TB - 2PB one per 16GB * > 2PB ~131,072 * -------------------------------- * * Finally, note that all of the above calculate the initial * number of metaslabs. Expanding a top-level vdev will result * in additional metaslabs being allocated making it possible * to exceed the zfs_vdev_ms_count_limit. */ if (ms_count < zfs_vdev_min_ms_count) ms_shift = highbit64(asize / zfs_vdev_min_ms_count); else if (ms_count > zfs_vdev_default_ms_count) ms_shift = highbit64(asize / zfs_vdev_default_ms_count); else ms_shift = zfs_vdev_default_ms_shift; if (ms_shift < SPA_MAXBLOCKSHIFT) { ms_shift = SPA_MAXBLOCKSHIFT; } else if (ms_shift > zfs_vdev_max_ms_shift) { ms_shift = zfs_vdev_max_ms_shift; /* cap the total count to constrain memory footprint */ if ((asize >> ms_shift) > zfs_vdev_ms_count_limit) ms_shift = highbit64(asize / zfs_vdev_ms_count_limit); } vd->vdev_ms_shift = ms_shift; ASSERT3U(vd->vdev_ms_shift, >=, SPA_MAXBLOCKSHIFT); } void vdev_dirty(vdev_t *vd, int flags, void *arg, uint64_t txg) { ASSERT(vd == vd->vdev_top); /* indirect vdevs don't have metaslabs or dtls */ ASSERT(vdev_is_concrete(vd) || flags == 0); ASSERT(ISP2(flags)); ASSERT(spa_writeable(vd->vdev_spa)); if (flags & VDD_METASLAB) (void) txg_list_add(&vd->vdev_ms_list, arg, txg); if (flags & VDD_DTL) (void) txg_list_add(&vd->vdev_dtl_list, arg, txg); (void) txg_list_add(&vd->vdev_spa->spa_vdev_txg_list, vd, txg); } void vdev_dirty_leaves(vdev_t *vd, int flags, uint64_t txg) { for (int c = 0; c < vd->vdev_children; c++) vdev_dirty_leaves(vd->vdev_child[c], flags, txg); if (vd->vdev_ops->vdev_op_leaf) vdev_dirty(vd->vdev_top, flags, vd, txg); } /* * DTLs. * * A vdev's DTL (dirty time log) is the set of transaction groups for which * the vdev has less than perfect replication. There are four kinds of DTL: * * DTL_MISSING: txgs for which the vdev has no valid copies of the data * * DTL_PARTIAL: txgs for which data is available, but not fully replicated * * DTL_SCRUB: the txgs that could not be repaired by the last scrub; upon * scrub completion, DTL_SCRUB replaces DTL_MISSING in the range of * txgs that was scrubbed. * * DTL_OUTAGE: txgs which cannot currently be read, whether due to * persistent errors or just some device being offline. * Unlike the other three, the DTL_OUTAGE map is not generally * maintained; it's only computed when needed, typically to * determine whether a device can be detached. * * For leaf vdevs, DTL_MISSING and DTL_PARTIAL are identical: the device * either has the data or it doesn't. * * For interior vdevs such as mirror and RAID-Z the picture is more complex. * A vdev's DTL_PARTIAL is the union of its children's DTL_PARTIALs, because * if any child is less than fully replicated, then so is its parent. * A vdev's DTL_MISSING is a modified union of its children's DTL_MISSINGs, * comprising only those txgs which appear in 'maxfaults' or more children; * those are the txgs we don't have enough replication to read. For example, * double-parity RAID-Z can tolerate up to two missing devices (maxfaults == 2); * thus, its DTL_MISSING consists of the set of txgs that appear in more than * two child DTL_MISSING maps. * * It should be clear from the above that to compute the DTLs and outage maps * for all vdevs, it suffices to know just the leaf vdevs' DTL_MISSING maps. * Therefore, that is all we keep on disk. When loading the pool, or after * a configuration change, we generate all other DTLs from first principles. */ void vdev_dtl_dirty(vdev_t *vd, vdev_dtl_type_t t, uint64_t txg, uint64_t size) { range_tree_t *rt = vd->vdev_dtl[t]; ASSERT(t < DTL_TYPES); ASSERT(vd != vd->vdev_spa->spa_root_vdev); ASSERT(spa_writeable(vd->vdev_spa)); mutex_enter(&vd->vdev_dtl_lock); if (!range_tree_contains(rt, txg, size)) range_tree_add(rt, txg, size); mutex_exit(&vd->vdev_dtl_lock); } boolean_t vdev_dtl_contains(vdev_t *vd, vdev_dtl_type_t t, uint64_t txg, uint64_t size) { range_tree_t *rt = vd->vdev_dtl[t]; boolean_t dirty = B_FALSE; ASSERT(t < DTL_TYPES); ASSERT(vd != vd->vdev_spa->spa_root_vdev); /* * While we are loading the pool, the DTLs have not been loaded yet. * This isn't a problem but it can result in devices being tried * which are known to not have the data. In which case, the import * is relying on the checksum to ensure that we get the right data. * Note that while importing we are only reading the MOS, which is * always checksummed. */ mutex_enter(&vd->vdev_dtl_lock); if (!range_tree_is_empty(rt)) dirty = range_tree_contains(rt, txg, size); mutex_exit(&vd->vdev_dtl_lock); return (dirty); } boolean_t vdev_dtl_empty(vdev_t *vd, vdev_dtl_type_t t) { range_tree_t *rt = vd->vdev_dtl[t]; boolean_t empty; mutex_enter(&vd->vdev_dtl_lock); empty = range_tree_is_empty(rt); mutex_exit(&vd->vdev_dtl_lock); return (empty); } /* * Check if the txg falls within the range which must be * resilvered. DVAs outside this range can always be skipped. */ boolean_t vdev_default_need_resilver(vdev_t *vd, const dva_t *dva, size_t psize, uint64_t phys_birth) { (void) dva, (void) psize; /* Set by sequential resilver. */ if (phys_birth == TXG_UNKNOWN) return (B_TRUE); return (vdev_dtl_contains(vd, DTL_PARTIAL, phys_birth, 1)); } /* * Returns B_TRUE if the vdev determines the DVA needs to be resilvered. */ boolean_t vdev_dtl_need_resilver(vdev_t *vd, const dva_t *dva, size_t psize, uint64_t phys_birth) { ASSERT(vd != vd->vdev_spa->spa_root_vdev); if (vd->vdev_ops->vdev_op_need_resilver == NULL || vd->vdev_ops->vdev_op_leaf) return (B_TRUE); return (vd->vdev_ops->vdev_op_need_resilver(vd, dva, psize, phys_birth)); } /* * Returns the lowest txg in the DTL range. */ static uint64_t vdev_dtl_min(vdev_t *vd) { ASSERT(MUTEX_HELD(&vd->vdev_dtl_lock)); ASSERT3U(range_tree_space(vd->vdev_dtl[DTL_MISSING]), !=, 0); ASSERT0(vd->vdev_children); return (range_tree_min(vd->vdev_dtl[DTL_MISSING]) - 1); } /* * Returns the highest txg in the DTL. */ static uint64_t vdev_dtl_max(vdev_t *vd) { ASSERT(MUTEX_HELD(&vd->vdev_dtl_lock)); ASSERT3U(range_tree_space(vd->vdev_dtl[DTL_MISSING]), !=, 0); ASSERT0(vd->vdev_children); return (range_tree_max(vd->vdev_dtl[DTL_MISSING])); } /* * Determine if a resilvering vdev should remove any DTL entries from * its range. If the vdev was resilvering for the entire duration of the * scan then it should excise that range from its DTLs. Otherwise, this * vdev is considered partially resilvered and should leave its DTL * entries intact. The comment in vdev_dtl_reassess() describes how we * excise the DTLs. */ static boolean_t vdev_dtl_should_excise(vdev_t *vd, boolean_t rebuild_done) { ASSERT0(vd->vdev_children); if (vd->vdev_state < VDEV_STATE_DEGRADED) return (B_FALSE); if (vd->vdev_resilver_deferred) return (B_FALSE); if (range_tree_is_empty(vd->vdev_dtl[DTL_MISSING])) return (B_TRUE); if (rebuild_done) { vdev_rebuild_t *vr = &vd->vdev_top->vdev_rebuild_config; vdev_rebuild_phys_t *vrp = &vr->vr_rebuild_phys; /* Rebuild not initiated by attach */ if (vd->vdev_rebuild_txg == 0) return (B_TRUE); /* * When a rebuild completes without error then all missing data * up to the rebuild max txg has been reconstructed and the DTL * is eligible for excision. */ if (vrp->vrp_rebuild_state == VDEV_REBUILD_COMPLETE && vdev_dtl_max(vd) <= vrp->vrp_max_txg) { ASSERT3U(vrp->vrp_min_txg, <=, vdev_dtl_min(vd)); ASSERT3U(vrp->vrp_min_txg, <, vd->vdev_rebuild_txg); ASSERT3U(vd->vdev_rebuild_txg, <=, vrp->vrp_max_txg); return (B_TRUE); } } else { dsl_scan_t *scn = vd->vdev_spa->spa_dsl_pool->dp_scan; dsl_scan_phys_t *scnp __maybe_unused = &scn->scn_phys; /* Resilver not initiated by attach */ if (vd->vdev_resilver_txg == 0) return (B_TRUE); /* * When a resilver is initiated the scan will assign the * scn_max_txg value to the highest txg value that exists * in all DTLs. If this device's max DTL is not part of this * scan (i.e. it is not in the range (scn_min_txg, scn_max_txg] * then it is not eligible for excision. */ if (vdev_dtl_max(vd) <= scn->scn_phys.scn_max_txg) { ASSERT3U(scnp->scn_min_txg, <=, vdev_dtl_min(vd)); ASSERT3U(scnp->scn_min_txg, <, vd->vdev_resilver_txg); ASSERT3U(vd->vdev_resilver_txg, <=, scnp->scn_max_txg); return (B_TRUE); } } return (B_FALSE); } /* * Reassess DTLs after a config change or scrub completion. If txg == 0 no * write operations will be issued to the pool. */ void vdev_dtl_reassess(vdev_t *vd, uint64_t txg, uint64_t scrub_txg, boolean_t scrub_done, boolean_t rebuild_done) { spa_t *spa = vd->vdev_spa; avl_tree_t reftree; int minref; ASSERT(spa_config_held(spa, SCL_ALL, RW_READER) != 0); for (int c = 0; c < vd->vdev_children; c++) vdev_dtl_reassess(vd->vdev_child[c], txg, scrub_txg, scrub_done, rebuild_done); if (vd == spa->spa_root_vdev || !vdev_is_concrete(vd) || vd->vdev_aux) return; if (vd->vdev_ops->vdev_op_leaf) { dsl_scan_t *scn = spa->spa_dsl_pool->dp_scan; vdev_rebuild_t *vr = &vd->vdev_top->vdev_rebuild_config; boolean_t check_excise = B_FALSE; boolean_t wasempty = B_TRUE; mutex_enter(&vd->vdev_dtl_lock); /* * If requested, pretend the scan or rebuild completed cleanly. */ if (zfs_scan_ignore_errors) { if (scn != NULL) scn->scn_phys.scn_errors = 0; if (vr != NULL) vr->vr_rebuild_phys.vrp_errors = 0; } if (scrub_txg != 0 && !range_tree_is_empty(vd->vdev_dtl[DTL_MISSING])) { wasempty = B_FALSE; zfs_dbgmsg("guid:%llu txg:%llu scrub:%llu started:%d " "dtl:%llu/%llu errors:%llu", (u_longlong_t)vd->vdev_guid, (u_longlong_t)txg, (u_longlong_t)scrub_txg, spa->spa_scrub_started, (u_longlong_t)vdev_dtl_min(vd), (u_longlong_t)vdev_dtl_max(vd), (u_longlong_t)(scn ? scn->scn_phys.scn_errors : 0)); } /* * If we've completed a scrub/resilver or a rebuild cleanly * then determine if this vdev should remove any DTLs. We * only want to excise regions on vdevs that were available * during the entire duration of this scan. */ if (rebuild_done && vr != NULL && vr->vr_rebuild_phys.vrp_errors == 0) { check_excise = B_TRUE; } else { if (spa->spa_scrub_started || (scn != NULL && scn->scn_phys.scn_errors == 0)) { check_excise = B_TRUE; } } if (scrub_txg && check_excise && vdev_dtl_should_excise(vd, rebuild_done)) { /* * We completed a scrub, resilver or rebuild up to * scrub_txg. If we did it without rebooting, then * the scrub dtl will be valid, so excise the old * region and fold in the scrub dtl. Otherwise, * leave the dtl as-is if there was an error. * * There's little trick here: to excise the beginning * of the DTL_MISSING map, we put it into a reference * tree and then add a segment with refcnt -1 that * covers the range [0, scrub_txg). This means * that each txg in that range has refcnt -1 or 0. * We then add DTL_SCRUB with a refcnt of 2, so that * entries in the range [0, scrub_txg) will have a * positive refcnt -- either 1 or 2. We then convert * the reference tree into the new DTL_MISSING map. */ space_reftree_create(&reftree); space_reftree_add_map(&reftree, vd->vdev_dtl[DTL_MISSING], 1); space_reftree_add_seg(&reftree, 0, scrub_txg, -1); space_reftree_add_map(&reftree, vd->vdev_dtl[DTL_SCRUB], 2); space_reftree_generate_map(&reftree, vd->vdev_dtl[DTL_MISSING], 1); space_reftree_destroy(&reftree); if (!range_tree_is_empty(vd->vdev_dtl[DTL_MISSING])) { zfs_dbgmsg("update DTL_MISSING:%llu/%llu", (u_longlong_t)vdev_dtl_min(vd), (u_longlong_t)vdev_dtl_max(vd)); } else if (!wasempty) { zfs_dbgmsg("DTL_MISSING is now empty"); } } range_tree_vacate(vd->vdev_dtl[DTL_PARTIAL], NULL, NULL); range_tree_walk(vd->vdev_dtl[DTL_MISSING], range_tree_add, vd->vdev_dtl[DTL_PARTIAL]); if (scrub_done) range_tree_vacate(vd->vdev_dtl[DTL_SCRUB], NULL, NULL); range_tree_vacate(vd->vdev_dtl[DTL_OUTAGE], NULL, NULL); if (!vdev_readable(vd)) range_tree_add(vd->vdev_dtl[DTL_OUTAGE], 0, -1ULL); else range_tree_walk(vd->vdev_dtl[DTL_MISSING], range_tree_add, vd->vdev_dtl[DTL_OUTAGE]); /* * If the vdev was resilvering or rebuilding and no longer * has any DTLs then reset the appropriate flag and dirty * the top level so that we persist the change. */ if (txg != 0 && range_tree_is_empty(vd->vdev_dtl[DTL_MISSING]) && range_tree_is_empty(vd->vdev_dtl[DTL_OUTAGE])) { if (vd->vdev_rebuild_txg != 0) { vd->vdev_rebuild_txg = 0; vdev_config_dirty(vd->vdev_top); } else if (vd->vdev_resilver_txg != 0) { vd->vdev_resilver_txg = 0; vdev_config_dirty(vd->vdev_top); } } mutex_exit(&vd->vdev_dtl_lock); if (txg != 0) vdev_dirty(vd->vdev_top, VDD_DTL, vd, txg); return; } mutex_enter(&vd->vdev_dtl_lock); for (int t = 0; t < DTL_TYPES; t++) { /* account for child's outage in parent's missing map */ int s = (t == DTL_MISSING) ? DTL_OUTAGE: t; if (t == DTL_SCRUB) continue; /* leaf vdevs only */ if (t == DTL_PARTIAL) minref = 1; /* i.e. non-zero */ else if (vdev_get_nparity(vd) != 0) minref = vdev_get_nparity(vd) + 1; /* RAID-Z, dRAID */ else minref = vd->vdev_children; /* any kind of mirror */ space_reftree_create(&reftree); for (int c = 0; c < vd->vdev_children; c++) { vdev_t *cvd = vd->vdev_child[c]; mutex_enter(&cvd->vdev_dtl_lock); space_reftree_add_map(&reftree, cvd->vdev_dtl[s], 1); mutex_exit(&cvd->vdev_dtl_lock); } space_reftree_generate_map(&reftree, vd->vdev_dtl[t], minref); space_reftree_destroy(&reftree); } mutex_exit(&vd->vdev_dtl_lock); } /* * Iterate over all the vdevs except spare, and post kobj events */ void vdev_post_kobj_evt(vdev_t *vd) { if (vd->vdev_ops->vdev_op_kobj_evt_post && vd->vdev_kobj_flag == B_FALSE) { vd->vdev_kobj_flag = B_TRUE; vd->vdev_ops->vdev_op_kobj_evt_post(vd); } for (int c = 0; c < vd->vdev_children; c++) vdev_post_kobj_evt(vd->vdev_child[c]); } /* * Iterate over all the vdevs except spare, and clear kobj events */ void vdev_clear_kobj_evt(vdev_t *vd) { vd->vdev_kobj_flag = B_FALSE; for (int c = 0; c < vd->vdev_children; c++) vdev_clear_kobj_evt(vd->vdev_child[c]); } int vdev_dtl_load(vdev_t *vd) { spa_t *spa = vd->vdev_spa; objset_t *mos = spa->spa_meta_objset; range_tree_t *rt; int error = 0; if (vd->vdev_ops->vdev_op_leaf && vd->vdev_dtl_object != 0) { ASSERT(vdev_is_concrete(vd)); /* * If the dtl cannot be sync'd there is no need to open it. */ if (spa->spa_mode == SPA_MODE_READ && !spa->spa_read_spacemaps) return (0); error = space_map_open(&vd->vdev_dtl_sm, mos, vd->vdev_dtl_object, 0, -1ULL, 0); if (error) return (error); ASSERT(vd->vdev_dtl_sm != NULL); rt = range_tree_create(NULL, RANGE_SEG64, NULL, 0, 0); error = space_map_load(vd->vdev_dtl_sm, rt, SM_ALLOC); if (error == 0) { mutex_enter(&vd->vdev_dtl_lock); range_tree_walk(rt, range_tree_add, vd->vdev_dtl[DTL_MISSING]); mutex_exit(&vd->vdev_dtl_lock); } range_tree_vacate(rt, NULL, NULL); range_tree_destroy(rt); return (error); } for (int c = 0; c < vd->vdev_children; c++) { error = vdev_dtl_load(vd->vdev_child[c]); if (error != 0) break; } return (error); } static void vdev_zap_allocation_data(vdev_t *vd, dmu_tx_t *tx) { spa_t *spa = vd->vdev_spa; objset_t *mos = spa->spa_meta_objset; vdev_alloc_bias_t alloc_bias = vd->vdev_alloc_bias; const char *string; ASSERT(alloc_bias != VDEV_BIAS_NONE); string = (alloc_bias == VDEV_BIAS_LOG) ? VDEV_ALLOC_BIAS_LOG : (alloc_bias == VDEV_BIAS_SPECIAL) ? VDEV_ALLOC_BIAS_SPECIAL : (alloc_bias == VDEV_BIAS_DEDUP) ? VDEV_ALLOC_BIAS_DEDUP : NULL; ASSERT(string != NULL); VERIFY0(zap_add(mos, vd->vdev_top_zap, VDEV_TOP_ZAP_ALLOCATION_BIAS, 1, strlen(string) + 1, string, tx)); if (alloc_bias == VDEV_BIAS_SPECIAL || alloc_bias == VDEV_BIAS_DEDUP) { spa_activate_allocation_classes(spa, tx); } } void vdev_destroy_unlink_zap(vdev_t *vd, uint64_t zapobj, dmu_tx_t *tx) { spa_t *spa = vd->vdev_spa; VERIFY0(zap_destroy(spa->spa_meta_objset, zapobj, tx)); VERIFY0(zap_remove_int(spa->spa_meta_objset, spa->spa_all_vdev_zaps, zapobj, tx)); } uint64_t vdev_create_link_zap(vdev_t *vd, dmu_tx_t *tx) { spa_t *spa = vd->vdev_spa; uint64_t zap = zap_create(spa->spa_meta_objset, DMU_OTN_ZAP_METADATA, DMU_OT_NONE, 0, tx); ASSERT(zap != 0); VERIFY0(zap_add_int(spa->spa_meta_objset, spa->spa_all_vdev_zaps, zap, tx)); return (zap); } void vdev_construct_zaps(vdev_t *vd, dmu_tx_t *tx) { if (vd->vdev_ops != &vdev_hole_ops && vd->vdev_ops != &vdev_missing_ops && vd->vdev_ops != &vdev_root_ops && !vd->vdev_top->vdev_removing) { if (vd->vdev_ops->vdev_op_leaf && vd->vdev_leaf_zap == 0) { vd->vdev_leaf_zap = vdev_create_link_zap(vd, tx); } if (vd == vd->vdev_top && vd->vdev_top_zap == 0) { vd->vdev_top_zap = vdev_create_link_zap(vd, tx); if (vd->vdev_alloc_bias != VDEV_BIAS_NONE) vdev_zap_allocation_data(vd, tx); } } if (vd->vdev_ops == &vdev_root_ops && vd->vdev_root_zap == 0 && spa_feature_is_enabled(vd->vdev_spa, SPA_FEATURE_AVZ_V2)) { if (!spa_feature_is_active(vd->vdev_spa, SPA_FEATURE_AVZ_V2)) spa_feature_incr(vd->vdev_spa, SPA_FEATURE_AVZ_V2, tx); vd->vdev_root_zap = vdev_create_link_zap(vd, tx); } for (uint64_t i = 0; i < vd->vdev_children; i++) { vdev_construct_zaps(vd->vdev_child[i], tx); } } static void vdev_dtl_sync(vdev_t *vd, uint64_t txg) { spa_t *spa = vd->vdev_spa; range_tree_t *rt = vd->vdev_dtl[DTL_MISSING]; objset_t *mos = spa->spa_meta_objset; range_tree_t *rtsync; dmu_tx_t *tx; uint64_t object = space_map_object(vd->vdev_dtl_sm); ASSERT(vdev_is_concrete(vd)); ASSERT(vd->vdev_ops->vdev_op_leaf); tx = dmu_tx_create_assigned(spa->spa_dsl_pool, txg); if (vd->vdev_detached || vd->vdev_top->vdev_removing) { mutex_enter(&vd->vdev_dtl_lock); space_map_free(vd->vdev_dtl_sm, tx); space_map_close(vd->vdev_dtl_sm); vd->vdev_dtl_sm = NULL; mutex_exit(&vd->vdev_dtl_lock); /* * We only destroy the leaf ZAP for detached leaves or for * removed log devices. Removed data devices handle leaf ZAP * cleanup later, once cancellation is no longer possible. */ if (vd->vdev_leaf_zap != 0 && (vd->vdev_detached || vd->vdev_top->vdev_islog)) { vdev_destroy_unlink_zap(vd, vd->vdev_leaf_zap, tx); vd->vdev_leaf_zap = 0; } dmu_tx_commit(tx); return; } if (vd->vdev_dtl_sm == NULL) { uint64_t new_object; new_object = space_map_alloc(mos, zfs_vdev_dtl_sm_blksz, tx); VERIFY3U(new_object, !=, 0); VERIFY0(space_map_open(&vd->vdev_dtl_sm, mos, new_object, 0, -1ULL, 0)); ASSERT(vd->vdev_dtl_sm != NULL); } rtsync = range_tree_create(NULL, RANGE_SEG64, NULL, 0, 0); mutex_enter(&vd->vdev_dtl_lock); range_tree_walk(rt, range_tree_add, rtsync); mutex_exit(&vd->vdev_dtl_lock); space_map_truncate(vd->vdev_dtl_sm, zfs_vdev_dtl_sm_blksz, tx); space_map_write(vd->vdev_dtl_sm, rtsync, SM_ALLOC, SM_NO_VDEVID, tx); range_tree_vacate(rtsync, NULL, NULL); range_tree_destroy(rtsync); /* * If the object for the space map has changed then dirty * the top level so that we update the config. */ if (object != space_map_object(vd->vdev_dtl_sm)) { vdev_dbgmsg(vd, "txg %llu, spa %s, DTL old object %llu, " "new object %llu", (u_longlong_t)txg, spa_name(spa), (u_longlong_t)object, (u_longlong_t)space_map_object(vd->vdev_dtl_sm)); vdev_config_dirty(vd->vdev_top); } dmu_tx_commit(tx); } /* * Determine whether the specified vdev can be offlined/detached/removed * without losing data. */ boolean_t vdev_dtl_required(vdev_t *vd) { spa_t *spa = vd->vdev_spa; vdev_t *tvd = vd->vdev_top; uint8_t cant_read = vd->vdev_cant_read; boolean_t required; ASSERT(spa_config_held(spa, SCL_STATE_ALL, RW_WRITER) == SCL_STATE_ALL); if (vd == spa->spa_root_vdev || vd == tvd) return (B_TRUE); /* * Temporarily mark the device as unreadable, and then determine * whether this results in any DTL outages in the top-level vdev. * If not, we can safely offline/detach/remove the device. */ vd->vdev_cant_read = B_TRUE; vdev_dtl_reassess(tvd, 0, 0, B_FALSE, B_FALSE); required = !vdev_dtl_empty(tvd, DTL_OUTAGE); vd->vdev_cant_read = cant_read; vdev_dtl_reassess(tvd, 0, 0, B_FALSE, B_FALSE); if (!required && zio_injection_enabled) { required = !!zio_handle_device_injection(vd, NULL, SET_ERROR(ECHILD)); } return (required); } /* * Determine if resilver is needed, and if so the txg range. */ boolean_t vdev_resilver_needed(vdev_t *vd, uint64_t *minp, uint64_t *maxp) { boolean_t needed = B_FALSE; uint64_t thismin = UINT64_MAX; uint64_t thismax = 0; if (vd->vdev_children == 0) { mutex_enter(&vd->vdev_dtl_lock); if (!range_tree_is_empty(vd->vdev_dtl[DTL_MISSING]) && vdev_writeable(vd)) { thismin = vdev_dtl_min(vd); thismax = vdev_dtl_max(vd); needed = B_TRUE; } mutex_exit(&vd->vdev_dtl_lock); } else { for (int c = 0; c < vd->vdev_children; c++) { vdev_t *cvd = vd->vdev_child[c]; uint64_t cmin, cmax; if (vdev_resilver_needed(cvd, &cmin, &cmax)) { thismin = MIN(thismin, cmin); thismax = MAX(thismax, cmax); needed = B_TRUE; } } } if (needed && minp) { *minp = thismin; *maxp = thismax; } return (needed); } /* * Gets the checkpoint space map object from the vdev's ZAP. On success sm_obj * will contain either the checkpoint spacemap object or zero if none exists. * All other errors are returned to the caller. */ int vdev_checkpoint_sm_object(vdev_t *vd, uint64_t *sm_obj) { ASSERT0(spa_config_held(vd->vdev_spa, SCL_ALL, RW_WRITER)); if (vd->vdev_top_zap == 0) { *sm_obj = 0; return (0); } int error = zap_lookup(spa_meta_objset(vd->vdev_spa), vd->vdev_top_zap, VDEV_TOP_ZAP_POOL_CHECKPOINT_SM, sizeof (uint64_t), 1, sm_obj); if (error == ENOENT) { *sm_obj = 0; error = 0; } return (error); } int vdev_load(vdev_t *vd) { int children = vd->vdev_children; int error = 0; taskq_t *tq = NULL; /* * It's only worthwhile to use the taskq for the root vdev, because the * slow part is metaslab_init, and that only happens for top-level * vdevs. */ if (vd->vdev_ops == &vdev_root_ops && vd->vdev_children > 0) { tq = taskq_create("vdev_load", children, minclsyspri, children, children, TASKQ_PREPOPULATE); } /* * Recursively load all children. */ for (int c = 0; c < vd->vdev_children; c++) { vdev_t *cvd = vd->vdev_child[c]; if (tq == NULL || vdev_uses_zvols(cvd)) { cvd->vdev_load_error = vdev_load(cvd); } else { VERIFY(taskq_dispatch(tq, vdev_load_child, cvd, TQ_SLEEP) != TASKQID_INVALID); } } if (tq != NULL) { taskq_wait(tq); taskq_destroy(tq); } for (int c = 0; c < vd->vdev_children; c++) { int error = vd->vdev_child[c]->vdev_load_error; if (error != 0) return (error); } vdev_set_deflate_ratio(vd); /* * On spa_load path, grab the allocation bias from our zap */ if (vd == vd->vdev_top && vd->vdev_top_zap != 0) { spa_t *spa = vd->vdev_spa; char bias_str[64]; error = zap_lookup(spa->spa_meta_objset, vd->vdev_top_zap, VDEV_TOP_ZAP_ALLOCATION_BIAS, 1, sizeof (bias_str), bias_str); if (error == 0) { ASSERT(vd->vdev_alloc_bias == VDEV_BIAS_NONE); vd->vdev_alloc_bias = vdev_derive_alloc_bias(bias_str); } else if (error != ENOENT) { vdev_set_state(vd, B_FALSE, VDEV_STATE_CANT_OPEN, VDEV_AUX_CORRUPT_DATA); vdev_dbgmsg(vd, "vdev_load: zap_lookup(top_zap=%llu) " "failed [error=%d]", (u_longlong_t)vd->vdev_top_zap, error); return (error); } } if (vd == vd->vdev_top && vd->vdev_top_zap != 0) { spa_t *spa = vd->vdev_spa; uint64_t failfast; error = zap_lookup(spa->spa_meta_objset, vd->vdev_top_zap, vdev_prop_to_name(VDEV_PROP_FAILFAST), sizeof (failfast), 1, &failfast); if (error == 0) { vd->vdev_failfast = failfast & 1; } else if (error == ENOENT) { vd->vdev_failfast = vdev_prop_default_numeric( VDEV_PROP_FAILFAST); } else { vdev_dbgmsg(vd, "vdev_load: zap_lookup(top_zap=%llu) " "failed [error=%d]", (u_longlong_t)vd->vdev_top_zap, error); } } /* * Load any rebuild state from the top-level vdev zap. */ if (vd == vd->vdev_top && vd->vdev_top_zap != 0) { error = vdev_rebuild_load(vd); if (error && error != ENOTSUP) { vdev_set_state(vd, B_FALSE, VDEV_STATE_CANT_OPEN, VDEV_AUX_CORRUPT_DATA); vdev_dbgmsg(vd, "vdev_load: vdev_rebuild_load " "failed [error=%d]", error); return (error); } } if (vd->vdev_top_zap != 0 || vd->vdev_leaf_zap != 0) { uint64_t zapobj; if (vd->vdev_top_zap != 0) zapobj = vd->vdev_top_zap; else zapobj = vd->vdev_leaf_zap; error = vdev_prop_get_int(vd, VDEV_PROP_CHECKSUM_N, &vd->vdev_checksum_n); if (error && error != ENOENT) vdev_dbgmsg(vd, "vdev_load: zap_lookup(zap=%llu) " "failed [error=%d]", (u_longlong_t)zapobj, error); error = vdev_prop_get_int(vd, VDEV_PROP_CHECKSUM_T, &vd->vdev_checksum_t); if (error && error != ENOENT) vdev_dbgmsg(vd, "vdev_load: zap_lookup(zap=%llu) " "failed [error=%d]", (u_longlong_t)zapobj, error); error = vdev_prop_get_int(vd, VDEV_PROP_IO_N, &vd->vdev_io_n); if (error && error != ENOENT) vdev_dbgmsg(vd, "vdev_load: zap_lookup(zap=%llu) " "failed [error=%d]", (u_longlong_t)zapobj, error); error = vdev_prop_get_int(vd, VDEV_PROP_IO_T, &vd->vdev_io_t); if (error && error != ENOENT) vdev_dbgmsg(vd, "vdev_load: zap_lookup(zap=%llu) " "failed [error=%d]", (u_longlong_t)zapobj, error); } /* * If this is a top-level vdev, initialize its metaslabs. */ if (vd == vd->vdev_top && vdev_is_concrete(vd)) { vdev_metaslab_group_create(vd); if (vd->vdev_ashift == 0 || vd->vdev_asize == 0) { vdev_set_state(vd, B_FALSE, VDEV_STATE_CANT_OPEN, VDEV_AUX_CORRUPT_DATA); vdev_dbgmsg(vd, "vdev_load: invalid size. ashift=%llu, " "asize=%llu", (u_longlong_t)vd->vdev_ashift, (u_longlong_t)vd->vdev_asize); return (SET_ERROR(ENXIO)); } error = vdev_metaslab_init(vd, 0); if (error != 0) { vdev_dbgmsg(vd, "vdev_load: metaslab_init failed " "[error=%d]", error); vdev_set_state(vd, B_FALSE, VDEV_STATE_CANT_OPEN, VDEV_AUX_CORRUPT_DATA); return (error); } uint64_t checkpoint_sm_obj; error = vdev_checkpoint_sm_object(vd, &checkpoint_sm_obj); if (error == 0 && checkpoint_sm_obj != 0) { objset_t *mos = spa_meta_objset(vd->vdev_spa); ASSERT(vd->vdev_asize != 0); ASSERT3P(vd->vdev_checkpoint_sm, ==, NULL); error = space_map_open(&vd->vdev_checkpoint_sm, mos, checkpoint_sm_obj, 0, vd->vdev_asize, vd->vdev_ashift); if (error != 0) { vdev_dbgmsg(vd, "vdev_load: space_map_open " "failed for checkpoint spacemap (obj %llu) " "[error=%d]", (u_longlong_t)checkpoint_sm_obj, error); return (error); } ASSERT3P(vd->vdev_checkpoint_sm, !=, NULL); /* * Since the checkpoint_sm contains free entries * exclusively we can use space_map_allocated() to * indicate the cumulative checkpointed space that * has been freed. */ vd->vdev_stat.vs_checkpoint_space = -space_map_allocated(vd->vdev_checkpoint_sm); vd->vdev_spa->spa_checkpoint_info.sci_dspace += vd->vdev_stat.vs_checkpoint_space; } else if (error != 0) { vdev_dbgmsg(vd, "vdev_load: failed to retrieve " "checkpoint space map object from vdev ZAP " "[error=%d]", error); return (error); } } /* * If this is a leaf vdev, load its DTL. */ if (vd->vdev_ops->vdev_op_leaf && (error = vdev_dtl_load(vd)) != 0) { vdev_set_state(vd, B_FALSE, VDEV_STATE_CANT_OPEN, VDEV_AUX_CORRUPT_DATA); vdev_dbgmsg(vd, "vdev_load: vdev_dtl_load failed " "[error=%d]", error); return (error); } uint64_t obsolete_sm_object; error = vdev_obsolete_sm_object(vd, &obsolete_sm_object); if (error == 0 && obsolete_sm_object != 0) { objset_t *mos = vd->vdev_spa->spa_meta_objset; ASSERT(vd->vdev_asize != 0); ASSERT3P(vd->vdev_obsolete_sm, ==, NULL); if ((error = space_map_open(&vd->vdev_obsolete_sm, mos, obsolete_sm_object, 0, vd->vdev_asize, 0))) { vdev_set_state(vd, B_FALSE, VDEV_STATE_CANT_OPEN, VDEV_AUX_CORRUPT_DATA); vdev_dbgmsg(vd, "vdev_load: space_map_open failed for " "obsolete spacemap (obj %llu) [error=%d]", (u_longlong_t)obsolete_sm_object, error); return (error); } } else if (error != 0) { vdev_dbgmsg(vd, "vdev_load: failed to retrieve obsolete " "space map object from vdev ZAP [error=%d]", error); return (error); } return (0); } /* * The special vdev case is used for hot spares and l2cache devices. Its * sole purpose it to set the vdev state for the associated vdev. To do this, * we make sure that we can open the underlying device, then try to read the * label, and make sure that the label is sane and that it hasn't been * repurposed to another pool. */ int vdev_validate_aux(vdev_t *vd) { nvlist_t *label; uint64_t guid, version; uint64_t state; if (!vdev_readable(vd)) return (0); if ((label = vdev_label_read_config(vd, -1ULL)) == NULL) { vdev_set_state(vd, B_TRUE, VDEV_STATE_CANT_OPEN, VDEV_AUX_CORRUPT_DATA); return (-1); } if (nvlist_lookup_uint64(label, ZPOOL_CONFIG_VERSION, &version) != 0 || !SPA_VERSION_IS_SUPPORTED(version) || nvlist_lookup_uint64(label, ZPOOL_CONFIG_GUID, &guid) != 0 || guid != vd->vdev_guid || nvlist_lookup_uint64(label, ZPOOL_CONFIG_POOL_STATE, &state) != 0) { vdev_set_state(vd, B_TRUE, VDEV_STATE_CANT_OPEN, VDEV_AUX_CORRUPT_DATA); nvlist_free(label); return (-1); } /* * We don't actually check the pool state here. If it's in fact in * use by another pool, we update this fact on the fly when requested. */ nvlist_free(label); return (0); } static void vdev_destroy_ms_flush_data(vdev_t *vd, dmu_tx_t *tx) { objset_t *mos = spa_meta_objset(vd->vdev_spa); if (vd->vdev_top_zap == 0) return; uint64_t object = 0; int err = zap_lookup(mos, vd->vdev_top_zap, VDEV_TOP_ZAP_MS_UNFLUSHED_PHYS_TXGS, sizeof (uint64_t), 1, &object); if (err == ENOENT) return; VERIFY0(err); VERIFY0(dmu_object_free(mos, object, tx)); VERIFY0(zap_remove(mos, vd->vdev_top_zap, VDEV_TOP_ZAP_MS_UNFLUSHED_PHYS_TXGS, tx)); } /* * Free the objects used to store this vdev's spacemaps, and the array * that points to them. */ void vdev_destroy_spacemaps(vdev_t *vd, dmu_tx_t *tx) { if (vd->vdev_ms_array == 0) return; objset_t *mos = vd->vdev_spa->spa_meta_objset; uint64_t array_count = vd->vdev_asize >> vd->vdev_ms_shift; size_t array_bytes = array_count * sizeof (uint64_t); uint64_t *smobj_array = kmem_alloc(array_bytes, KM_SLEEP); VERIFY0(dmu_read(mos, vd->vdev_ms_array, 0, array_bytes, smobj_array, 0)); for (uint64_t i = 0; i < array_count; i++) { uint64_t smobj = smobj_array[i]; if (smobj == 0) continue; space_map_free_obj(mos, smobj, tx); } kmem_free(smobj_array, array_bytes); VERIFY0(dmu_object_free(mos, vd->vdev_ms_array, tx)); vdev_destroy_ms_flush_data(vd, tx); vd->vdev_ms_array = 0; } static void vdev_remove_empty_log(vdev_t *vd, uint64_t txg) { spa_t *spa = vd->vdev_spa; ASSERT(vd->vdev_islog); ASSERT(vd == vd->vdev_top); ASSERT3U(txg, ==, spa_syncing_txg(spa)); dmu_tx_t *tx = dmu_tx_create_assigned(spa_get_dsl(spa), txg); vdev_destroy_spacemaps(vd, tx); if (vd->vdev_top_zap != 0) { vdev_destroy_unlink_zap(vd, vd->vdev_top_zap, tx); vd->vdev_top_zap = 0; } dmu_tx_commit(tx); } void vdev_sync_done(vdev_t *vd, uint64_t txg) { metaslab_t *msp; boolean_t reassess = !txg_list_empty(&vd->vdev_ms_list, TXG_CLEAN(txg)); ASSERT(vdev_is_concrete(vd)); while ((msp = txg_list_remove(&vd->vdev_ms_list, TXG_CLEAN(txg))) != NULL) metaslab_sync_done(msp, txg); if (reassess) { metaslab_sync_reassess(vd->vdev_mg); if (vd->vdev_log_mg != NULL) metaslab_sync_reassess(vd->vdev_log_mg); } } void vdev_sync(vdev_t *vd, uint64_t txg) { spa_t *spa = vd->vdev_spa; vdev_t *lvd; metaslab_t *msp; ASSERT3U(txg, ==, spa->spa_syncing_txg); dmu_tx_t *tx = dmu_tx_create_assigned(spa->spa_dsl_pool, txg); if (range_tree_space(vd->vdev_obsolete_segments) > 0) { ASSERT(vd->vdev_removing || vd->vdev_ops == &vdev_indirect_ops); vdev_indirect_sync_obsolete(vd, tx); /* * If the vdev is indirect, it can't have dirty * metaslabs or DTLs. */ if (vd->vdev_ops == &vdev_indirect_ops) { ASSERT(txg_list_empty(&vd->vdev_ms_list, txg)); ASSERT(txg_list_empty(&vd->vdev_dtl_list, txg)); dmu_tx_commit(tx); return; } } ASSERT(vdev_is_concrete(vd)); if (vd->vdev_ms_array == 0 && vd->vdev_ms_shift != 0 && !vd->vdev_removing) { ASSERT(vd == vd->vdev_top); ASSERT0(vd->vdev_indirect_config.vic_mapping_object); vd->vdev_ms_array = dmu_object_alloc(spa->spa_meta_objset, DMU_OT_OBJECT_ARRAY, 0, DMU_OT_NONE, 0, tx); ASSERT(vd->vdev_ms_array != 0); vdev_config_dirty(vd); } while ((msp = txg_list_remove(&vd->vdev_ms_list, txg)) != NULL) { metaslab_sync(msp, txg); (void) txg_list_add(&vd->vdev_ms_list, msp, TXG_CLEAN(txg)); } while ((lvd = txg_list_remove(&vd->vdev_dtl_list, txg)) != NULL) vdev_dtl_sync(lvd, txg); /* * If this is an empty log device being removed, destroy the * metadata associated with it. */ if (vd->vdev_islog && vd->vdev_stat.vs_alloc == 0 && vd->vdev_removing) vdev_remove_empty_log(vd, txg); (void) txg_list_add(&spa->spa_vdev_txg_list, vd, TXG_CLEAN(txg)); dmu_tx_commit(tx); } uint64_t vdev_psize_to_asize(vdev_t *vd, uint64_t psize) { return (vd->vdev_ops->vdev_op_asize(vd, psize)); } /* * Mark the given vdev faulted. A faulted vdev behaves as if the device could * not be opened, and no I/O is attempted. */ int vdev_fault(spa_t *spa, uint64_t guid, vdev_aux_t aux) { vdev_t *vd, *tvd; spa_vdev_state_enter(spa, SCL_NONE); if ((vd = spa_lookup_by_guid(spa, guid, B_TRUE)) == NULL) return (spa_vdev_state_exit(spa, NULL, SET_ERROR(ENODEV))); if (!vd->vdev_ops->vdev_op_leaf) return (spa_vdev_state_exit(spa, NULL, SET_ERROR(ENOTSUP))); tvd = vd->vdev_top; /* * If user did a 'zpool offline -f' then make the fault persist across * reboots. */ if (aux == VDEV_AUX_EXTERNAL_PERSIST) { /* * There are two kinds of forced faults: temporary and * persistent. Temporary faults go away at pool import, while * persistent faults stay set. Both types of faults can be * cleared with a zpool clear. * * We tell if a vdev is persistently faulted by looking at the * ZPOOL_CONFIG_AUX_STATE nvpair. If it's set to "external" at * import then it's a persistent fault. Otherwise, it's * temporary. We get ZPOOL_CONFIG_AUX_STATE set to "external" * by setting vd.vdev_stat.vs_aux to VDEV_AUX_EXTERNAL. This * tells vdev_config_generate() (which gets run later) to set * ZPOOL_CONFIG_AUX_STATE to "external" in the nvlist. */ vd->vdev_stat.vs_aux = VDEV_AUX_EXTERNAL; vd->vdev_tmpoffline = B_FALSE; aux = VDEV_AUX_EXTERNAL; } else { vd->vdev_tmpoffline = B_TRUE; } /* * We don't directly use the aux state here, but if we do a * vdev_reopen(), we need this value to be present to remember why we * were faulted. */ vd->vdev_label_aux = aux; /* * Faulted state takes precedence over degraded. */ vd->vdev_delayed_close = B_FALSE; vd->vdev_faulted = 1ULL; vd->vdev_degraded = 0ULL; vdev_set_state(vd, B_FALSE, VDEV_STATE_FAULTED, aux); /* * If this device has the only valid copy of the data, then * back off and simply mark the vdev as degraded instead. */ if (!tvd->vdev_islog && vd->vdev_aux == NULL && vdev_dtl_required(vd)) { vd->vdev_degraded = 1ULL; vd->vdev_faulted = 0ULL; /* * If we reopen the device and it's not dead, only then do we * mark it degraded. */ vdev_reopen(tvd); if (vdev_readable(vd)) vdev_set_state(vd, B_FALSE, VDEV_STATE_DEGRADED, aux); } return (spa_vdev_state_exit(spa, vd, 0)); } /* * Mark the given vdev degraded. A degraded vdev is purely an indication to the * user that something is wrong. The vdev continues to operate as normal as far * as I/O is concerned. */ int vdev_degrade(spa_t *spa, uint64_t guid, vdev_aux_t aux) { vdev_t *vd; spa_vdev_state_enter(spa, SCL_NONE); if ((vd = spa_lookup_by_guid(spa, guid, B_TRUE)) == NULL) return (spa_vdev_state_exit(spa, NULL, SET_ERROR(ENODEV))); if (!vd->vdev_ops->vdev_op_leaf) return (spa_vdev_state_exit(spa, NULL, SET_ERROR(ENOTSUP))); /* * If the vdev is already faulted, then don't do anything. */ if (vd->vdev_faulted || vd->vdev_degraded) return (spa_vdev_state_exit(spa, NULL, 0)); vd->vdev_degraded = 1ULL; if (!vdev_is_dead(vd)) vdev_set_state(vd, B_FALSE, VDEV_STATE_DEGRADED, aux); return (spa_vdev_state_exit(spa, vd, 0)); } int vdev_remove_wanted(spa_t *spa, uint64_t guid) { vdev_t *vd; spa_vdev_state_enter(spa, SCL_NONE); if ((vd = spa_lookup_by_guid(spa, guid, B_TRUE)) == NULL) return (spa_vdev_state_exit(spa, NULL, SET_ERROR(ENODEV))); /* * If the vdev is already removed, or expanding which can trigger * repartition add/remove events, then don't do anything. */ if (vd->vdev_removed || vd->vdev_expanding) return (spa_vdev_state_exit(spa, NULL, 0)); /* * Confirm the vdev has been removed, otherwise don't do anything. */ if (vd->vdev_ops->vdev_op_leaf && !zio_wait(vdev_probe(vd, NULL))) return (spa_vdev_state_exit(spa, NULL, SET_ERROR(EEXIST))); vd->vdev_remove_wanted = B_TRUE; spa_async_request(spa, SPA_ASYNC_REMOVE); return (spa_vdev_state_exit(spa, vd, 0)); } /* * Online the given vdev. * * If 'ZFS_ONLINE_UNSPARE' is set, it implies two things. First, any attached * spare device should be detached when the device finishes resilvering. * Second, the online should be treated like a 'test' online case, so no FMA * events are generated if the device fails to open. */ int vdev_online(spa_t *spa, uint64_t guid, uint64_t flags, vdev_state_t *newstate) { vdev_t *vd, *tvd, *pvd, *rvd = spa->spa_root_vdev; boolean_t wasoffline; vdev_state_t oldstate; spa_vdev_state_enter(spa, SCL_NONE); if ((vd = spa_lookup_by_guid(spa, guid, B_TRUE)) == NULL) return (spa_vdev_state_exit(spa, NULL, SET_ERROR(ENODEV))); if (!vd->vdev_ops->vdev_op_leaf) return (spa_vdev_state_exit(spa, NULL, SET_ERROR(ENOTSUP))); wasoffline = (vd->vdev_offline || vd->vdev_tmpoffline); oldstate = vd->vdev_state; tvd = vd->vdev_top; vd->vdev_offline = B_FALSE; vd->vdev_tmpoffline = B_FALSE; vd->vdev_checkremove = !!(flags & ZFS_ONLINE_CHECKREMOVE); vd->vdev_forcefault = !!(flags & ZFS_ONLINE_FORCEFAULT); /* XXX - L2ARC 1.0 does not support expansion */ if (!vd->vdev_aux) { for (pvd = vd; pvd != rvd; pvd = pvd->vdev_parent) pvd->vdev_expanding = !!((flags & ZFS_ONLINE_EXPAND) || spa->spa_autoexpand); vd->vdev_expansion_time = gethrestime_sec(); } vdev_reopen(tvd); vd->vdev_checkremove = vd->vdev_forcefault = B_FALSE; if (!vd->vdev_aux) { for (pvd = vd; pvd != rvd; pvd = pvd->vdev_parent) pvd->vdev_expanding = B_FALSE; } if (newstate) *newstate = vd->vdev_state; if ((flags & ZFS_ONLINE_UNSPARE) && !vdev_is_dead(vd) && vd->vdev_parent && vd->vdev_parent->vdev_ops == &vdev_spare_ops && vd->vdev_parent->vdev_child[0] == vd) vd->vdev_unspare = B_TRUE; if ((flags & ZFS_ONLINE_EXPAND) || spa->spa_autoexpand) { /* XXX - L2ARC 1.0 does not support expansion */ if (vd->vdev_aux) return (spa_vdev_state_exit(spa, vd, ENOTSUP)); + spa->spa_ccw_fail_time = 0; spa_async_request(spa, SPA_ASYNC_CONFIG_UPDATE); } /* Restart initializing if necessary */ mutex_enter(&vd->vdev_initialize_lock); if (vdev_writeable(vd) && vd->vdev_initialize_thread == NULL && vd->vdev_initialize_state == VDEV_INITIALIZE_ACTIVE) { (void) vdev_initialize(vd); } mutex_exit(&vd->vdev_initialize_lock); /* * Restart trimming if necessary. We do not restart trimming for cache * devices here. This is triggered by l2arc_rebuild_vdev() * asynchronously for the whole device or in l2arc_evict() as it evicts * space for upcoming writes. */ mutex_enter(&vd->vdev_trim_lock); if (vdev_writeable(vd) && !vd->vdev_isl2cache && vd->vdev_trim_thread == NULL && vd->vdev_trim_state == VDEV_TRIM_ACTIVE) { (void) vdev_trim(vd, vd->vdev_trim_rate, vd->vdev_trim_partial, vd->vdev_trim_secure); } mutex_exit(&vd->vdev_trim_lock); if (wasoffline || (oldstate < VDEV_STATE_DEGRADED && vd->vdev_state >= VDEV_STATE_DEGRADED)) { spa_event_notify(spa, vd, NULL, ESC_ZFS_VDEV_ONLINE); /* * Asynchronously detach spare vdev if resilver or * rebuild is not required */ if (vd->vdev_unspare && !dsl_scan_resilvering(spa->spa_dsl_pool) && !dsl_scan_resilver_scheduled(spa->spa_dsl_pool) && !vdev_rebuild_active(tvd)) spa_async_request(spa, SPA_ASYNC_DETACH_SPARE); } return (spa_vdev_state_exit(spa, vd, 0)); } static int vdev_offline_locked(spa_t *spa, uint64_t guid, uint64_t flags) { vdev_t *vd, *tvd; int error = 0; uint64_t generation; metaslab_group_t *mg; top: spa_vdev_state_enter(spa, SCL_ALLOC); if ((vd = spa_lookup_by_guid(spa, guid, B_TRUE)) == NULL) return (spa_vdev_state_exit(spa, NULL, SET_ERROR(ENODEV))); if (!vd->vdev_ops->vdev_op_leaf) return (spa_vdev_state_exit(spa, NULL, SET_ERROR(ENOTSUP))); if (vd->vdev_ops == &vdev_draid_spare_ops) return (spa_vdev_state_exit(spa, NULL, ENOTSUP)); tvd = vd->vdev_top; mg = tvd->vdev_mg; generation = spa->spa_config_generation + 1; /* * If the device isn't already offline, try to offline it. */ if (!vd->vdev_offline) { /* * If this device has the only valid copy of some data, * don't allow it to be offlined. Log devices are always * expendable. */ if (!tvd->vdev_islog && vd->vdev_aux == NULL && vdev_dtl_required(vd)) return (spa_vdev_state_exit(spa, NULL, SET_ERROR(EBUSY))); /* * If the top-level is a slog and it has had allocations * then proceed. We check that the vdev's metaslab group * is not NULL since it's possible that we may have just * added this vdev but not yet initialized its metaslabs. */ if (tvd->vdev_islog && mg != NULL) { /* * Prevent any future allocations. */ ASSERT3P(tvd->vdev_log_mg, ==, NULL); metaslab_group_passivate(mg); (void) spa_vdev_state_exit(spa, vd, 0); error = spa_reset_logs(spa); /* * If the log device was successfully reset but has * checkpointed data, do not offline it. */ if (error == 0 && tvd->vdev_checkpoint_sm != NULL) { ASSERT3U(space_map_allocated( tvd->vdev_checkpoint_sm), !=, 0); error = ZFS_ERR_CHECKPOINT_EXISTS; } spa_vdev_state_enter(spa, SCL_ALLOC); /* * Check to see if the config has changed. */ if (error || generation != spa->spa_config_generation) { metaslab_group_activate(mg); if (error) return (spa_vdev_state_exit(spa, vd, error)); (void) spa_vdev_state_exit(spa, vd, 0); goto top; } ASSERT0(tvd->vdev_stat.vs_alloc); } /* * Offline this device and reopen its top-level vdev. * If the top-level vdev is a log device then just offline * it. Otherwise, if this action results in the top-level * vdev becoming unusable, undo it and fail the request. */ vd->vdev_offline = B_TRUE; vdev_reopen(tvd); if (!tvd->vdev_islog && vd->vdev_aux == NULL && vdev_is_dead(tvd)) { vd->vdev_offline = B_FALSE; vdev_reopen(tvd); return (spa_vdev_state_exit(spa, NULL, SET_ERROR(EBUSY))); } /* * Add the device back into the metaslab rotor so that * once we online the device it's open for business. */ if (tvd->vdev_islog && mg != NULL) metaslab_group_activate(mg); } vd->vdev_tmpoffline = !!(flags & ZFS_OFFLINE_TEMPORARY); return (spa_vdev_state_exit(spa, vd, 0)); } int vdev_offline(spa_t *spa, uint64_t guid, uint64_t flags) { int error; mutex_enter(&spa->spa_vdev_top_lock); error = vdev_offline_locked(spa, guid, flags); mutex_exit(&spa->spa_vdev_top_lock); return (error); } /* * Clear the error counts associated with this vdev. Unlike vdev_online() and * vdev_offline(), we assume the spa config is locked. We also clear all * children. If 'vd' is NULL, then the user wants to clear all vdevs. */ void vdev_clear(spa_t *spa, vdev_t *vd) { vdev_t *rvd = spa->spa_root_vdev; ASSERT(spa_config_held(spa, SCL_STATE_ALL, RW_WRITER) == SCL_STATE_ALL); if (vd == NULL) vd = rvd; vd->vdev_stat.vs_read_errors = 0; vd->vdev_stat.vs_write_errors = 0; vd->vdev_stat.vs_checksum_errors = 0; vd->vdev_stat.vs_slow_ios = 0; for (int c = 0; c < vd->vdev_children; c++) vdev_clear(spa, vd->vdev_child[c]); /* * It makes no sense to "clear" an indirect or removed vdev. */ if (!vdev_is_concrete(vd) || vd->vdev_removed) return; /* * If we're in the FAULTED state or have experienced failed I/O, then * clear the persistent state and attempt to reopen the device. We * also mark the vdev config dirty, so that the new faulted state is * written out to disk. */ if (vd->vdev_faulted || vd->vdev_degraded || !vdev_readable(vd) || !vdev_writeable(vd)) { /* * When reopening in response to a clear event, it may be due to * a fmadm repair request. In this case, if the device is * still broken, we want to still post the ereport again. */ vd->vdev_forcefault = B_TRUE; vd->vdev_faulted = vd->vdev_degraded = 0ULL; vd->vdev_cant_read = B_FALSE; vd->vdev_cant_write = B_FALSE; vd->vdev_stat.vs_aux = 0; vdev_reopen(vd == rvd ? rvd : vd->vdev_top); vd->vdev_forcefault = B_FALSE; if (vd != rvd && vdev_writeable(vd->vdev_top)) vdev_state_dirty(vd->vdev_top); /* If a resilver isn't required, check if vdevs can be culled */ if (vd->vdev_aux == NULL && !vdev_is_dead(vd) && !dsl_scan_resilvering(spa->spa_dsl_pool) && !dsl_scan_resilver_scheduled(spa->spa_dsl_pool)) spa_async_request(spa, SPA_ASYNC_RESILVER_DONE); spa_event_notify(spa, vd, NULL, ESC_ZFS_VDEV_CLEAR); } /* * When clearing a FMA-diagnosed fault, we always want to * unspare the device, as we assume that the original spare was * done in response to the FMA fault. */ if (!vdev_is_dead(vd) && vd->vdev_parent != NULL && vd->vdev_parent->vdev_ops == &vdev_spare_ops && vd->vdev_parent->vdev_child[0] == vd) vd->vdev_unspare = B_TRUE; /* Clear recent error events cache (i.e. duplicate events tracking) */ zfs_ereport_clear(spa, vd); } boolean_t vdev_is_dead(vdev_t *vd) { /* * Holes and missing devices are always considered "dead". * This simplifies the code since we don't have to check for * these types of devices in the various code paths. * Instead we rely on the fact that we skip over dead devices * before issuing I/O to them. */ return (vd->vdev_state < VDEV_STATE_DEGRADED || vd->vdev_ops == &vdev_hole_ops || vd->vdev_ops == &vdev_missing_ops); } boolean_t vdev_readable(vdev_t *vd) { return (!vdev_is_dead(vd) && !vd->vdev_cant_read); } boolean_t vdev_writeable(vdev_t *vd) { return (!vdev_is_dead(vd) && !vd->vdev_cant_write && vdev_is_concrete(vd)); } boolean_t vdev_allocatable(vdev_t *vd) { uint64_t state = vd->vdev_state; /* * We currently allow allocations from vdevs which may be in the * process of reopening (i.e. VDEV_STATE_CLOSED). If the device * fails to reopen then we'll catch it later when we're holding * the proper locks. Note that we have to get the vdev state * in a local variable because although it changes atomically, * we're asking two separate questions about it. */ return (!(state < VDEV_STATE_DEGRADED && state != VDEV_STATE_CLOSED) && !vd->vdev_cant_write && vdev_is_concrete(vd) && vd->vdev_mg->mg_initialized); } boolean_t vdev_accessible(vdev_t *vd, zio_t *zio) { ASSERT(zio->io_vd == vd); if (vdev_is_dead(vd) || vd->vdev_remove_wanted) return (B_FALSE); if (zio->io_type == ZIO_TYPE_READ) return (!vd->vdev_cant_read); if (zio->io_type == ZIO_TYPE_WRITE) return (!vd->vdev_cant_write); return (B_TRUE); } static void vdev_get_child_stat(vdev_t *cvd, vdev_stat_t *vs, vdev_stat_t *cvs) { /* * Exclude the dRAID spare when aggregating to avoid double counting * the ops and bytes. These IOs are counted by the physical leaves. */ if (cvd->vdev_ops == &vdev_draid_spare_ops) return; for (int t = 0; t < VS_ZIO_TYPES; t++) { vs->vs_ops[t] += cvs->vs_ops[t]; vs->vs_bytes[t] += cvs->vs_bytes[t]; } cvs->vs_scan_removing = cvd->vdev_removing; } /* * Get extended stats */ static void vdev_get_child_stat_ex(vdev_t *cvd, vdev_stat_ex_t *vsx, vdev_stat_ex_t *cvsx) { (void) cvd; int t, b; for (t = 0; t < ZIO_TYPES; t++) { for (b = 0; b < ARRAY_SIZE(vsx->vsx_disk_histo[0]); b++) vsx->vsx_disk_histo[t][b] += cvsx->vsx_disk_histo[t][b]; for (b = 0; b < ARRAY_SIZE(vsx->vsx_total_histo[0]); b++) { vsx->vsx_total_histo[t][b] += cvsx->vsx_total_histo[t][b]; } } for (t = 0; t < ZIO_PRIORITY_NUM_QUEUEABLE; t++) { for (b = 0; b < ARRAY_SIZE(vsx->vsx_queue_histo[0]); b++) { vsx->vsx_queue_histo[t][b] += cvsx->vsx_queue_histo[t][b]; } vsx->vsx_active_queue[t] += cvsx->vsx_active_queue[t]; vsx->vsx_pend_queue[t] += cvsx->vsx_pend_queue[t]; for (b = 0; b < ARRAY_SIZE(vsx->vsx_ind_histo[0]); b++) vsx->vsx_ind_histo[t][b] += cvsx->vsx_ind_histo[t][b]; for (b = 0; b < ARRAY_SIZE(vsx->vsx_agg_histo[0]); b++) vsx->vsx_agg_histo[t][b] += cvsx->vsx_agg_histo[t][b]; } } boolean_t vdev_is_spacemap_addressable(vdev_t *vd) { if (spa_feature_is_active(vd->vdev_spa, SPA_FEATURE_SPACEMAP_V2)) return (B_TRUE); /* * If double-word space map entries are not enabled we assume * 47 bits of the space map entry are dedicated to the entry's * offset (see SM_OFFSET_BITS in space_map.h). We then use that * to calculate the maximum address that can be described by a * space map entry for the given device. */ uint64_t shift = vd->vdev_ashift + SM_OFFSET_BITS; if (shift >= 63) /* detect potential overflow */ return (B_TRUE); return (vd->vdev_asize < (1ULL << shift)); } /* * Get statistics for the given vdev. */ static void vdev_get_stats_ex_impl(vdev_t *vd, vdev_stat_t *vs, vdev_stat_ex_t *vsx) { int t; /* * If we're getting stats on the root vdev, aggregate the I/O counts * over all top-level vdevs (i.e. the direct children of the root). */ if (!vd->vdev_ops->vdev_op_leaf) { if (vs) { memset(vs->vs_ops, 0, sizeof (vs->vs_ops)); memset(vs->vs_bytes, 0, sizeof (vs->vs_bytes)); } if (vsx) memset(vsx, 0, sizeof (*vsx)); for (int c = 0; c < vd->vdev_children; c++) { vdev_t *cvd = vd->vdev_child[c]; vdev_stat_t *cvs = &cvd->vdev_stat; vdev_stat_ex_t *cvsx = &cvd->vdev_stat_ex; vdev_get_stats_ex_impl(cvd, cvs, cvsx); if (vs) vdev_get_child_stat(cvd, vs, cvs); if (vsx) vdev_get_child_stat_ex(cvd, vsx, cvsx); } } else { /* * We're a leaf. Just copy our ZIO active queue stats in. The * other leaf stats are updated in vdev_stat_update(). */ if (!vsx) return; memcpy(vsx, &vd->vdev_stat_ex, sizeof (vd->vdev_stat_ex)); for (t = 0; t < ZIO_PRIORITY_NUM_QUEUEABLE; t++) { vsx->vsx_active_queue[t] = vd->vdev_queue.vq_cactive[t]; vsx->vsx_pend_queue[t] = vdev_queue_class_length(vd, t); } } } void vdev_get_stats_ex(vdev_t *vd, vdev_stat_t *vs, vdev_stat_ex_t *vsx) { vdev_t *tvd = vd->vdev_top; mutex_enter(&vd->vdev_stat_lock); if (vs) { memcpy(vs, &vd->vdev_stat, sizeof (*vs)); vs->vs_timestamp = gethrtime() - vs->vs_timestamp; vs->vs_state = vd->vdev_state; vs->vs_rsize = vdev_get_min_asize(vd); if (vd->vdev_ops->vdev_op_leaf) { vs->vs_pspace = vd->vdev_psize; vs->vs_rsize += VDEV_LABEL_START_SIZE + VDEV_LABEL_END_SIZE; /* * Report initializing progress. Since we don't * have the initializing locks held, this is only * an estimate (although a fairly accurate one). */ vs->vs_initialize_bytes_done = vd->vdev_initialize_bytes_done; vs->vs_initialize_bytes_est = vd->vdev_initialize_bytes_est; vs->vs_initialize_state = vd->vdev_initialize_state; vs->vs_initialize_action_time = vd->vdev_initialize_action_time; /* * Report manual TRIM progress. Since we don't have * the manual TRIM locks held, this is only an * estimate (although fairly accurate one). */ vs->vs_trim_notsup = !vd->vdev_has_trim; vs->vs_trim_bytes_done = vd->vdev_trim_bytes_done; vs->vs_trim_bytes_est = vd->vdev_trim_bytes_est; vs->vs_trim_state = vd->vdev_trim_state; vs->vs_trim_action_time = vd->vdev_trim_action_time; /* Set when there is a deferred resilver. */ vs->vs_resilver_deferred = vd->vdev_resilver_deferred; } /* * Report expandable space on top-level, non-auxiliary devices * only. The expandable space is reported in terms of metaslab * sized units since that determines how much space the pool * can expand. */ if (vd->vdev_aux == NULL && tvd != NULL) { vs->vs_esize = P2ALIGN( vd->vdev_max_asize - vd->vdev_asize, 1ULL << tvd->vdev_ms_shift); } vs->vs_configured_ashift = vd->vdev_top != NULL ? vd->vdev_top->vdev_ashift : vd->vdev_ashift; vs->vs_logical_ashift = vd->vdev_logical_ashift; if (vd->vdev_physical_ashift <= ASHIFT_MAX) vs->vs_physical_ashift = vd->vdev_physical_ashift; else vs->vs_physical_ashift = 0; /* * Report fragmentation and rebuild progress for top-level, * non-auxiliary, concrete devices. */ if (vd->vdev_aux == NULL && vd == vd->vdev_top && vdev_is_concrete(vd)) { /* * The vdev fragmentation rating doesn't take into * account the embedded slog metaslab (vdev_log_mg). * Since it's only one metaslab, it would have a tiny * impact on the overall fragmentation. */ vs->vs_fragmentation = (vd->vdev_mg != NULL) ? vd->vdev_mg->mg_fragmentation : 0; } vs->vs_noalloc = MAX(vd->vdev_noalloc, tvd ? tvd->vdev_noalloc : 0); } vdev_get_stats_ex_impl(vd, vs, vsx); mutex_exit(&vd->vdev_stat_lock); } void vdev_get_stats(vdev_t *vd, vdev_stat_t *vs) { return (vdev_get_stats_ex(vd, vs, NULL)); } void vdev_clear_stats(vdev_t *vd) { mutex_enter(&vd->vdev_stat_lock); vd->vdev_stat.vs_space = 0; vd->vdev_stat.vs_dspace = 0; vd->vdev_stat.vs_alloc = 0; mutex_exit(&vd->vdev_stat_lock); } void vdev_scan_stat_init(vdev_t *vd) { vdev_stat_t *vs = &vd->vdev_stat; for (int c = 0; c < vd->vdev_children; c++) vdev_scan_stat_init(vd->vdev_child[c]); mutex_enter(&vd->vdev_stat_lock); vs->vs_scan_processed = 0; mutex_exit(&vd->vdev_stat_lock); } void vdev_stat_update(zio_t *zio, uint64_t psize) { spa_t *spa = zio->io_spa; vdev_t *rvd = spa->spa_root_vdev; vdev_t *vd = zio->io_vd ? zio->io_vd : rvd; vdev_t *pvd; uint64_t txg = zio->io_txg; /* Suppress ASAN false positive */ #ifdef __SANITIZE_ADDRESS__ vdev_stat_t *vs = vd ? &vd->vdev_stat : NULL; vdev_stat_ex_t *vsx = vd ? &vd->vdev_stat_ex : NULL; #else vdev_stat_t *vs = &vd->vdev_stat; vdev_stat_ex_t *vsx = &vd->vdev_stat_ex; #endif zio_type_t type = zio->io_type; int flags = zio->io_flags; /* * If this i/o is a gang leader, it didn't do any actual work. */ if (zio->io_gang_tree) return; if (zio->io_error == 0) { /* * If this is a root i/o, don't count it -- we've already * counted the top-level vdevs, and vdev_get_stats() will * aggregate them when asked. This reduces contention on * the root vdev_stat_lock and implicitly handles blocks * that compress away to holes, for which there is no i/o. * (Holes never create vdev children, so all the counters * remain zero, which is what we want.) * * Note: this only applies to successful i/o (io_error == 0) * because unlike i/o counts, errors are not additive. * When reading a ditto block, for example, failure of * one top-level vdev does not imply a root-level error. */ if (vd == rvd) return; ASSERT(vd == zio->io_vd); if (flags & ZIO_FLAG_IO_BYPASS) return; mutex_enter(&vd->vdev_stat_lock); if (flags & ZIO_FLAG_IO_REPAIR) { /* * Repair is the result of a resilver issued by the * scan thread (spa_sync). */ if (flags & ZIO_FLAG_SCAN_THREAD) { dsl_scan_t *scn = spa->spa_dsl_pool->dp_scan; dsl_scan_phys_t *scn_phys = &scn->scn_phys; uint64_t *processed = &scn_phys->scn_processed; if (vd->vdev_ops->vdev_op_leaf) atomic_add_64(processed, psize); vs->vs_scan_processed += psize; } /* * Repair is the result of a rebuild issued by the * rebuild thread (vdev_rebuild_thread). To avoid * double counting repaired bytes the virtual dRAID * spare vdev is excluded from the processed bytes. */ if (zio->io_priority == ZIO_PRIORITY_REBUILD) { vdev_t *tvd = vd->vdev_top; vdev_rebuild_t *vr = &tvd->vdev_rebuild_config; vdev_rebuild_phys_t *vrp = &vr->vr_rebuild_phys; uint64_t *rebuilt = &vrp->vrp_bytes_rebuilt; if (vd->vdev_ops->vdev_op_leaf && vd->vdev_ops != &vdev_draid_spare_ops) { atomic_add_64(rebuilt, psize); } vs->vs_rebuild_processed += psize; } if (flags & ZIO_FLAG_SELF_HEAL) vs->vs_self_healed += psize; } /* * The bytes/ops/histograms are recorded at the leaf level and * aggregated into the higher level vdevs in vdev_get_stats(). */ if (vd->vdev_ops->vdev_op_leaf && (zio->io_priority < ZIO_PRIORITY_NUM_QUEUEABLE)) { zio_type_t vs_type = type; zio_priority_t priority = zio->io_priority; /* * TRIM ops and bytes are reported to user space as * ZIO_TYPE_IOCTL. This is done to preserve the * vdev_stat_t structure layout for user space. */ if (type == ZIO_TYPE_TRIM) vs_type = ZIO_TYPE_IOCTL; /* * Solely for the purposes of 'zpool iostat -lqrw' * reporting use the priority to categorize the IO. * Only the following are reported to user space: * * ZIO_PRIORITY_SYNC_READ, * ZIO_PRIORITY_SYNC_WRITE, * ZIO_PRIORITY_ASYNC_READ, * ZIO_PRIORITY_ASYNC_WRITE, * ZIO_PRIORITY_SCRUB, * ZIO_PRIORITY_TRIM, * ZIO_PRIORITY_REBUILD. */ if (priority == ZIO_PRIORITY_INITIALIZING) { ASSERT3U(type, ==, ZIO_TYPE_WRITE); priority = ZIO_PRIORITY_ASYNC_WRITE; } else if (priority == ZIO_PRIORITY_REMOVAL) { priority = ((type == ZIO_TYPE_WRITE) ? ZIO_PRIORITY_ASYNC_WRITE : ZIO_PRIORITY_ASYNC_READ); } vs->vs_ops[vs_type]++; vs->vs_bytes[vs_type] += psize; if (flags & ZIO_FLAG_DELEGATED) { vsx->vsx_agg_histo[priority] [RQ_HISTO(zio->io_size)]++; } else { vsx->vsx_ind_histo[priority] [RQ_HISTO(zio->io_size)]++; } if (zio->io_delta && zio->io_delay) { vsx->vsx_queue_histo[priority] [L_HISTO(zio->io_delta - zio->io_delay)]++; vsx->vsx_disk_histo[type] [L_HISTO(zio->io_delay)]++; vsx->vsx_total_histo[type] [L_HISTO(zio->io_delta)]++; } } mutex_exit(&vd->vdev_stat_lock); return; } if (flags & ZIO_FLAG_SPECULATIVE) return; /* * If this is an I/O error that is going to be retried, then ignore the * error. Otherwise, the user may interpret B_FAILFAST I/O errors as * hard errors, when in reality they can happen for any number of * innocuous reasons (bus resets, MPxIO link failure, etc). */ if (zio->io_error == EIO && !(zio->io_flags & ZIO_FLAG_IO_RETRY)) return; /* * Intent logs writes won't propagate their error to the root * I/O so don't mark these types of failures as pool-level * errors. */ if (zio->io_vd == NULL && (zio->io_flags & ZIO_FLAG_DONT_PROPAGATE)) return; if (type == ZIO_TYPE_WRITE && txg != 0 && (!(flags & ZIO_FLAG_IO_REPAIR) || (flags & ZIO_FLAG_SCAN_THREAD) || spa->spa_claiming)) { /* * This is either a normal write (not a repair), or it's * a repair induced by the scrub thread, or it's a repair * made by zil_claim() during spa_load() in the first txg. * In the normal case, we commit the DTL change in the same * txg as the block was born. In the scrub-induced repair * case, we know that scrubs run in first-pass syncing context, * so we commit the DTL change in spa_syncing_txg(spa). * In the zil_claim() case, we commit in spa_first_txg(spa). * * We currently do not make DTL entries for failed spontaneous * self-healing writes triggered by normal (non-scrubbing) * reads, because we have no transactional context in which to * do so -- and it's not clear that it'd be desirable anyway. */ if (vd->vdev_ops->vdev_op_leaf) { uint64_t commit_txg = txg; if (flags & ZIO_FLAG_SCAN_THREAD) { ASSERT(flags & ZIO_FLAG_IO_REPAIR); ASSERT(spa_sync_pass(spa) == 1); vdev_dtl_dirty(vd, DTL_SCRUB, txg, 1); commit_txg = spa_syncing_txg(spa); } else if (spa->spa_claiming) { ASSERT(flags & ZIO_FLAG_IO_REPAIR); commit_txg = spa_first_txg(spa); } ASSERT(commit_txg >= spa_syncing_txg(spa)); if (vdev_dtl_contains(vd, DTL_MISSING, txg, 1)) return; for (pvd = vd; pvd != rvd; pvd = pvd->vdev_parent) vdev_dtl_dirty(pvd, DTL_PARTIAL, txg, 1); vdev_dirty(vd->vdev_top, VDD_DTL, vd, commit_txg); } if (vd != rvd) vdev_dtl_dirty(vd, DTL_MISSING, txg, 1); } } int64_t vdev_deflated_space(vdev_t *vd, int64_t space) { ASSERT((space & (SPA_MINBLOCKSIZE-1)) == 0); ASSERT(vd->vdev_deflate_ratio != 0 || vd->vdev_isl2cache); return ((space >> SPA_MINBLOCKSHIFT) * vd->vdev_deflate_ratio); } /* * Update the in-core space usage stats for this vdev, its metaslab class, * and the root vdev. */ void vdev_space_update(vdev_t *vd, int64_t alloc_delta, int64_t defer_delta, int64_t space_delta) { (void) defer_delta; int64_t dspace_delta; spa_t *spa = vd->vdev_spa; vdev_t *rvd = spa->spa_root_vdev; ASSERT(vd == vd->vdev_top); /* * Apply the inverse of the psize-to-asize (ie. RAID-Z) space-expansion * factor. We must calculate this here and not at the root vdev * because the root vdev's psize-to-asize is simply the max of its * children's, thus not accurate enough for us. */ dspace_delta = vdev_deflated_space(vd, space_delta); mutex_enter(&vd->vdev_stat_lock); /* ensure we won't underflow */ if (alloc_delta < 0) { ASSERT3U(vd->vdev_stat.vs_alloc, >=, -alloc_delta); } vd->vdev_stat.vs_alloc += alloc_delta; vd->vdev_stat.vs_space += space_delta; vd->vdev_stat.vs_dspace += dspace_delta; mutex_exit(&vd->vdev_stat_lock); /* every class but log contributes to root space stats */ if (vd->vdev_mg != NULL && !vd->vdev_islog) { ASSERT(!vd->vdev_isl2cache); mutex_enter(&rvd->vdev_stat_lock); rvd->vdev_stat.vs_alloc += alloc_delta; rvd->vdev_stat.vs_space += space_delta; rvd->vdev_stat.vs_dspace += dspace_delta; mutex_exit(&rvd->vdev_stat_lock); } /* Note: metaslab_class_space_update moved to metaslab_space_update */ } /* * Mark a top-level vdev's config as dirty, placing it on the dirty list * so that it will be written out next time the vdev configuration is synced. * If the root vdev is specified (vdev_top == NULL), dirty all top-level vdevs. */ void vdev_config_dirty(vdev_t *vd) { spa_t *spa = vd->vdev_spa; vdev_t *rvd = spa->spa_root_vdev; int c; ASSERT(spa_writeable(spa)); /* * If this is an aux vdev (as with l2cache and spare devices), then we * update the vdev config manually and set the sync flag. */ if (vd->vdev_aux != NULL) { spa_aux_vdev_t *sav = vd->vdev_aux; nvlist_t **aux; uint_t naux; for (c = 0; c < sav->sav_count; c++) { if (sav->sav_vdevs[c] == vd) break; } if (c == sav->sav_count) { /* * We're being removed. There's nothing more to do. */ ASSERT(sav->sav_sync == B_TRUE); return; } sav->sav_sync = B_TRUE; if (nvlist_lookup_nvlist_array(sav->sav_config, ZPOOL_CONFIG_L2CACHE, &aux, &naux) != 0) { VERIFY(nvlist_lookup_nvlist_array(sav->sav_config, ZPOOL_CONFIG_SPARES, &aux, &naux) == 0); } ASSERT(c < naux); /* * Setting the nvlist in the middle if the array is a little * sketchy, but it will work. */ nvlist_free(aux[c]); aux[c] = vdev_config_generate(spa, vd, B_TRUE, 0); return; } /* * The dirty list is protected by the SCL_CONFIG lock. The caller * must either hold SCL_CONFIG as writer, or must be the sync thread * (which holds SCL_CONFIG as reader). There's only one sync thread, * so this is sufficient to ensure mutual exclusion. */ ASSERT(spa_config_held(spa, SCL_CONFIG, RW_WRITER) || (dsl_pool_sync_context(spa_get_dsl(spa)) && spa_config_held(spa, SCL_CONFIG, RW_READER))); if (vd == rvd) { for (c = 0; c < rvd->vdev_children; c++) vdev_config_dirty(rvd->vdev_child[c]); } else { ASSERT(vd == vd->vdev_top); if (!list_link_active(&vd->vdev_config_dirty_node) && vdev_is_concrete(vd)) { list_insert_head(&spa->spa_config_dirty_list, vd); } } } void vdev_config_clean(vdev_t *vd) { spa_t *spa = vd->vdev_spa; ASSERT(spa_config_held(spa, SCL_CONFIG, RW_WRITER) || (dsl_pool_sync_context(spa_get_dsl(spa)) && spa_config_held(spa, SCL_CONFIG, RW_READER))); ASSERT(list_link_active(&vd->vdev_config_dirty_node)); list_remove(&spa->spa_config_dirty_list, vd); } /* * Mark a top-level vdev's state as dirty, so that the next pass of * spa_sync() can convert this into vdev_config_dirty(). We distinguish * the state changes from larger config changes because they require * much less locking, and are often needed for administrative actions. */ void vdev_state_dirty(vdev_t *vd) { spa_t *spa = vd->vdev_spa; ASSERT(spa_writeable(spa)); ASSERT(vd == vd->vdev_top); /* * The state list is protected by the SCL_STATE lock. The caller * must either hold SCL_STATE as writer, or must be the sync thread * (which holds SCL_STATE as reader). There's only one sync thread, * so this is sufficient to ensure mutual exclusion. */ ASSERT(spa_config_held(spa, SCL_STATE, RW_WRITER) || (dsl_pool_sync_context(spa_get_dsl(spa)) && spa_config_held(spa, SCL_STATE, RW_READER))); if (!list_link_active(&vd->vdev_state_dirty_node) && vdev_is_concrete(vd)) list_insert_head(&spa->spa_state_dirty_list, vd); } void vdev_state_clean(vdev_t *vd) { spa_t *spa = vd->vdev_spa; ASSERT(spa_config_held(spa, SCL_STATE, RW_WRITER) || (dsl_pool_sync_context(spa_get_dsl(spa)) && spa_config_held(spa, SCL_STATE, RW_READER))); ASSERT(list_link_active(&vd->vdev_state_dirty_node)); list_remove(&spa->spa_state_dirty_list, vd); } /* * Propagate vdev state up from children to parent. */ void vdev_propagate_state(vdev_t *vd) { spa_t *spa = vd->vdev_spa; vdev_t *rvd = spa->spa_root_vdev; int degraded = 0, faulted = 0; int corrupted = 0; vdev_t *child; if (vd->vdev_children > 0) { for (int c = 0; c < vd->vdev_children; c++) { child = vd->vdev_child[c]; /* * Don't factor holes or indirect vdevs into the * decision. */ if (!vdev_is_concrete(child)) continue; if (!vdev_readable(child) || (!vdev_writeable(child) && spa_writeable(spa))) { /* * Root special: if there is a top-level log * device, treat the root vdev as if it were * degraded. */ if (child->vdev_islog && vd == rvd) degraded++; else faulted++; } else if (child->vdev_state <= VDEV_STATE_DEGRADED) { degraded++; } if (child->vdev_stat.vs_aux == VDEV_AUX_CORRUPT_DATA) corrupted++; } vd->vdev_ops->vdev_op_state_change(vd, faulted, degraded); /* * Root special: if there is a top-level vdev that cannot be * opened due to corrupted metadata, then propagate the root * vdev's aux state as 'corrupt' rather than 'insufficient * replicas'. */ if (corrupted && vd == rvd && rvd->vdev_state == VDEV_STATE_CANT_OPEN) vdev_set_state(rvd, B_FALSE, VDEV_STATE_CANT_OPEN, VDEV_AUX_CORRUPT_DATA); } if (vd->vdev_parent) vdev_propagate_state(vd->vdev_parent); } /* * Set a vdev's state. If this is during an open, we don't update the parent * state, because we're in the process of opening children depth-first. * Otherwise, we propagate the change to the parent. * * If this routine places a device in a faulted state, an appropriate ereport is * generated. */ void vdev_set_state(vdev_t *vd, boolean_t isopen, vdev_state_t state, vdev_aux_t aux) { uint64_t save_state; spa_t *spa = vd->vdev_spa; if (state == vd->vdev_state) { /* * Since vdev_offline() code path is already in an offline * state we can miss a statechange event to OFFLINE. Check * the previous state to catch this condition. */ if (vd->vdev_ops->vdev_op_leaf && (state == VDEV_STATE_OFFLINE) && (vd->vdev_prevstate >= VDEV_STATE_FAULTED)) { /* post an offline state change */ zfs_post_state_change(spa, vd, vd->vdev_prevstate); } vd->vdev_stat.vs_aux = aux; return; } save_state = vd->vdev_state; vd->vdev_state = state; vd->vdev_stat.vs_aux = aux; /* * If we are setting the vdev state to anything but an open state, then * always close the underlying device unless the device has requested * a delayed close (i.e. we're about to remove or fault the device). * Otherwise, we keep accessible but invalid devices open forever. * We don't call vdev_close() itself, because that implies some extra * checks (offline, etc) that we don't want here. This is limited to * leaf devices, because otherwise closing the device will affect other * children. */ if (!vd->vdev_delayed_close && vdev_is_dead(vd) && vd->vdev_ops->vdev_op_leaf) vd->vdev_ops->vdev_op_close(vd); if (vd->vdev_removed && state == VDEV_STATE_CANT_OPEN && (aux == VDEV_AUX_OPEN_FAILED || vd->vdev_checkremove)) { /* * If the previous state is set to VDEV_STATE_REMOVED, then this * device was previously marked removed and someone attempted to * reopen it. If this failed due to a nonexistent device, then * keep the device in the REMOVED state. We also let this be if * it is one of our special test online cases, which is only * attempting to online the device and shouldn't generate an FMA * fault. */ vd->vdev_state = VDEV_STATE_REMOVED; vd->vdev_stat.vs_aux = VDEV_AUX_NONE; } else if (state == VDEV_STATE_REMOVED) { vd->vdev_removed = B_TRUE; } else if (state == VDEV_STATE_CANT_OPEN) { /* * If we fail to open a vdev during an import or recovery, we * mark it as "not available", which signifies that it was * never there to begin with. Failure to open such a device * is not considered an error. */ if ((spa_load_state(spa) == SPA_LOAD_IMPORT || spa_load_state(spa) == SPA_LOAD_RECOVER) && vd->vdev_ops->vdev_op_leaf) vd->vdev_not_present = 1; /* * Post the appropriate ereport. If the 'prevstate' field is * set to something other than VDEV_STATE_UNKNOWN, it indicates * that this is part of a vdev_reopen(). In this case, we don't * want to post the ereport if the device was already in the * CANT_OPEN state beforehand. * * If the 'checkremove' flag is set, then this is an attempt to * online the device in response to an insertion event. If we * hit this case, then we have detected an insertion event for a * faulted or offline device that wasn't in the removed state. * In this scenario, we don't post an ereport because we are * about to replace the device, or attempt an online with * vdev_forcefault, which will generate the fault for us. */ if ((vd->vdev_prevstate != state || vd->vdev_forcefault) && !vd->vdev_not_present && !vd->vdev_checkremove && vd != spa->spa_root_vdev) { const char *class; switch (aux) { case VDEV_AUX_OPEN_FAILED: class = FM_EREPORT_ZFS_DEVICE_OPEN_FAILED; break; case VDEV_AUX_CORRUPT_DATA: class = FM_EREPORT_ZFS_DEVICE_CORRUPT_DATA; break; case VDEV_AUX_NO_REPLICAS: class = FM_EREPORT_ZFS_DEVICE_NO_REPLICAS; break; case VDEV_AUX_BAD_GUID_SUM: class = FM_EREPORT_ZFS_DEVICE_BAD_GUID_SUM; break; case VDEV_AUX_TOO_SMALL: class = FM_EREPORT_ZFS_DEVICE_TOO_SMALL; break; case VDEV_AUX_BAD_LABEL: class = FM_EREPORT_ZFS_DEVICE_BAD_LABEL; break; case VDEV_AUX_BAD_ASHIFT: class = FM_EREPORT_ZFS_DEVICE_BAD_ASHIFT; break; default: class = FM_EREPORT_ZFS_DEVICE_UNKNOWN; } (void) zfs_ereport_post(class, spa, vd, NULL, NULL, save_state); } /* Erase any notion of persistent removed state */ vd->vdev_removed = B_FALSE; } else { vd->vdev_removed = B_FALSE; } /* * Notify ZED of any significant state-change on a leaf vdev. * */ if (vd->vdev_ops->vdev_op_leaf) { /* preserve original state from a vdev_reopen() */ if ((vd->vdev_prevstate != VDEV_STATE_UNKNOWN) && (vd->vdev_prevstate != vd->vdev_state) && (save_state <= VDEV_STATE_CLOSED)) save_state = vd->vdev_prevstate; /* filter out state change due to initial vdev_open */ if (save_state > VDEV_STATE_CLOSED) zfs_post_state_change(spa, vd, save_state); } if (!isopen && vd->vdev_parent) vdev_propagate_state(vd->vdev_parent); } boolean_t vdev_children_are_offline(vdev_t *vd) { ASSERT(!vd->vdev_ops->vdev_op_leaf); for (uint64_t i = 0; i < vd->vdev_children; i++) { if (vd->vdev_child[i]->vdev_state != VDEV_STATE_OFFLINE) return (B_FALSE); } return (B_TRUE); } /* * Check the vdev configuration to ensure that it's capable of supporting * a root pool. We do not support partial configuration. */ boolean_t vdev_is_bootable(vdev_t *vd) { if (!vd->vdev_ops->vdev_op_leaf) { const char *vdev_type = vd->vdev_ops->vdev_op_type; if (strcmp(vdev_type, VDEV_TYPE_MISSING) == 0) return (B_FALSE); } for (int c = 0; c < vd->vdev_children; c++) { if (!vdev_is_bootable(vd->vdev_child[c])) return (B_FALSE); } return (B_TRUE); } boolean_t vdev_is_concrete(vdev_t *vd) { vdev_ops_t *ops = vd->vdev_ops; if (ops == &vdev_indirect_ops || ops == &vdev_hole_ops || ops == &vdev_missing_ops || ops == &vdev_root_ops) { return (B_FALSE); } else { return (B_TRUE); } } /* * Determine if a log device has valid content. If the vdev was * removed or faulted in the MOS config then we know that * the content on the log device has already been written to the pool. */ boolean_t vdev_log_state_valid(vdev_t *vd) { if (vd->vdev_ops->vdev_op_leaf && !vd->vdev_faulted && !vd->vdev_removed) return (B_TRUE); for (int c = 0; c < vd->vdev_children; c++) if (vdev_log_state_valid(vd->vdev_child[c])) return (B_TRUE); return (B_FALSE); } /* * Expand a vdev if possible. */ void vdev_expand(vdev_t *vd, uint64_t txg) { ASSERT(vd->vdev_top == vd); ASSERT(spa_config_held(vd->vdev_spa, SCL_ALL, RW_WRITER) == SCL_ALL); ASSERT(vdev_is_concrete(vd)); vdev_set_deflate_ratio(vd); if ((vd->vdev_asize >> vd->vdev_ms_shift) > vd->vdev_ms_count && vdev_is_concrete(vd)) { vdev_metaslab_group_create(vd); VERIFY(vdev_metaslab_init(vd, txg) == 0); vdev_config_dirty(vd); } } /* * Split a vdev. */ void vdev_split(vdev_t *vd) { vdev_t *cvd, *pvd = vd->vdev_parent; VERIFY3U(pvd->vdev_children, >, 1); vdev_remove_child(pvd, vd); vdev_compact_children(pvd); ASSERT3P(pvd->vdev_child, !=, NULL); cvd = pvd->vdev_child[0]; if (pvd->vdev_children == 1) { vdev_remove_parent(cvd); cvd->vdev_splitting = B_TRUE; } vdev_propagate_state(cvd); } void vdev_deadman(vdev_t *vd, const char *tag) { for (int c = 0; c < vd->vdev_children; c++) { vdev_t *cvd = vd->vdev_child[c]; vdev_deadman(cvd, tag); } if (vd->vdev_ops->vdev_op_leaf) { vdev_queue_t *vq = &vd->vdev_queue; mutex_enter(&vq->vq_lock); if (vq->vq_active > 0) { spa_t *spa = vd->vdev_spa; zio_t *fio; uint64_t delta; zfs_dbgmsg("slow vdev: %s has %u active IOs", vd->vdev_path, vq->vq_active); /* * Look at the head of all the pending queues, * if any I/O has been outstanding for longer than * the spa_deadman_synctime invoke the deadman logic. */ fio = list_head(&vq->vq_active_list); delta = gethrtime() - fio->io_timestamp; if (delta > spa_deadman_synctime(spa)) zio_deadman(fio, tag); } mutex_exit(&vq->vq_lock); } } void vdev_defer_resilver(vdev_t *vd) { ASSERT(vd->vdev_ops->vdev_op_leaf); vd->vdev_resilver_deferred = B_TRUE; vd->vdev_spa->spa_resilver_deferred = B_TRUE; } /* * Clears the resilver deferred flag on all leaf devs under vd. Returns * B_TRUE if we have devices that need to be resilvered and are available to * accept resilver I/Os. */ boolean_t vdev_clear_resilver_deferred(vdev_t *vd, dmu_tx_t *tx) { boolean_t resilver_needed = B_FALSE; spa_t *spa = vd->vdev_spa; for (int c = 0; c < vd->vdev_children; c++) { vdev_t *cvd = vd->vdev_child[c]; resilver_needed |= vdev_clear_resilver_deferred(cvd, tx); } if (vd == spa->spa_root_vdev && spa_feature_is_active(spa, SPA_FEATURE_RESILVER_DEFER)) { spa_feature_decr(spa, SPA_FEATURE_RESILVER_DEFER, tx); vdev_config_dirty(vd); spa->spa_resilver_deferred = B_FALSE; return (resilver_needed); } if (!vdev_is_concrete(vd) || vd->vdev_aux || !vd->vdev_ops->vdev_op_leaf) return (resilver_needed); vd->vdev_resilver_deferred = B_FALSE; return (!vdev_is_dead(vd) && !vd->vdev_offline && vdev_resilver_needed(vd, NULL, NULL)); } boolean_t vdev_xlate_is_empty(range_seg64_t *rs) { return (rs->rs_start == rs->rs_end); } /* * Translate a logical range to the first contiguous physical range for the * specified vdev_t. This function is initially called with a leaf vdev and * will walk each parent vdev until it reaches a top-level vdev. Once the * top-level is reached the physical range is initialized and the recursive * function begins to unwind. As it unwinds it calls the parent's vdev * specific translation function to do the real conversion. */ void vdev_xlate(vdev_t *vd, const range_seg64_t *logical_rs, range_seg64_t *physical_rs, range_seg64_t *remain_rs) { /* * Walk up the vdev tree */ if (vd != vd->vdev_top) { vdev_xlate(vd->vdev_parent, logical_rs, physical_rs, remain_rs); } else { /* * We've reached the top-level vdev, initialize the physical * range to the logical range and set an empty remaining * range then start to unwind. */ physical_rs->rs_start = logical_rs->rs_start; physical_rs->rs_end = logical_rs->rs_end; remain_rs->rs_start = logical_rs->rs_start; remain_rs->rs_end = logical_rs->rs_start; return; } vdev_t *pvd = vd->vdev_parent; ASSERT3P(pvd, !=, NULL); ASSERT3P(pvd->vdev_ops->vdev_op_xlate, !=, NULL); /* * As this recursive function unwinds, translate the logical * range into its physical and any remaining components by calling * the vdev specific translate function. */ range_seg64_t intermediate = { 0 }; pvd->vdev_ops->vdev_op_xlate(vd, physical_rs, &intermediate, remain_rs); physical_rs->rs_start = intermediate.rs_start; physical_rs->rs_end = intermediate.rs_end; } void vdev_xlate_walk(vdev_t *vd, const range_seg64_t *logical_rs, vdev_xlate_func_t *func, void *arg) { range_seg64_t iter_rs = *logical_rs; range_seg64_t physical_rs; range_seg64_t remain_rs; while (!vdev_xlate_is_empty(&iter_rs)) { vdev_xlate(vd, &iter_rs, &physical_rs, &remain_rs); /* * With raidz and dRAID, it's possible that the logical range * does not live on this leaf vdev. Only when there is a non- * zero physical size call the provided function. */ if (!vdev_xlate_is_empty(&physical_rs)) func(arg, &physical_rs); iter_rs = remain_rs; } } static char * vdev_name(vdev_t *vd, char *buf, int buflen) { if (vd->vdev_path == NULL) { if (strcmp(vd->vdev_ops->vdev_op_type, "root") == 0) { strlcpy(buf, vd->vdev_spa->spa_name, buflen); } else if (!vd->vdev_ops->vdev_op_leaf) { snprintf(buf, buflen, "%s-%llu", vd->vdev_ops->vdev_op_type, (u_longlong_t)vd->vdev_id); } } else { strlcpy(buf, vd->vdev_path, buflen); } return (buf); } /* * Look at the vdev tree and determine whether any devices are currently being * replaced. */ boolean_t vdev_replace_in_progress(vdev_t *vdev) { ASSERT(spa_config_held(vdev->vdev_spa, SCL_ALL, RW_READER) != 0); if (vdev->vdev_ops == &vdev_replacing_ops) return (B_TRUE); /* * A 'spare' vdev indicates that we have a replace in progress, unless * it has exactly two children, and the second, the hot spare, has * finished being resilvered. */ if (vdev->vdev_ops == &vdev_spare_ops && (vdev->vdev_children > 2 || !vdev_dtl_empty(vdev->vdev_child[1], DTL_MISSING))) return (B_TRUE); for (int i = 0; i < vdev->vdev_children; i++) { if (vdev_replace_in_progress(vdev->vdev_child[i])) return (B_TRUE); } return (B_FALSE); } /* * Add a (source=src, propname=propval) list to an nvlist. */ static void vdev_prop_add_list(nvlist_t *nvl, const char *propname, const char *strval, uint64_t intval, zprop_source_t src) { nvlist_t *propval; propval = fnvlist_alloc(); fnvlist_add_uint64(propval, ZPROP_SOURCE, src); if (strval != NULL) fnvlist_add_string(propval, ZPROP_VALUE, strval); else fnvlist_add_uint64(propval, ZPROP_VALUE, intval); fnvlist_add_nvlist(nvl, propname, propval); nvlist_free(propval); } static void vdev_props_set_sync(void *arg, dmu_tx_t *tx) { vdev_t *vd; nvlist_t *nvp = arg; spa_t *spa = dmu_tx_pool(tx)->dp_spa; objset_t *mos = spa->spa_meta_objset; nvpair_t *elem = NULL; uint64_t vdev_guid; uint64_t objid; nvlist_t *nvprops; vdev_guid = fnvlist_lookup_uint64(nvp, ZPOOL_VDEV_PROPS_SET_VDEV); nvprops = fnvlist_lookup_nvlist(nvp, ZPOOL_VDEV_PROPS_SET_PROPS); vd = spa_lookup_by_guid(spa, vdev_guid, B_TRUE); /* this vdev could get removed while waiting for this sync task */ if (vd == NULL) return; /* * Set vdev property values in the vdev props mos object. */ if (vd->vdev_root_zap != 0) { objid = vd->vdev_root_zap; } else if (vd->vdev_top_zap != 0) { objid = vd->vdev_top_zap; } else if (vd->vdev_leaf_zap != 0) { objid = vd->vdev_leaf_zap; } else { panic("unexpected vdev type"); } mutex_enter(&spa->spa_props_lock); while ((elem = nvlist_next_nvpair(nvprops, elem)) != NULL) { uint64_t intval; const char *strval; vdev_prop_t prop; const char *propname = nvpair_name(elem); zprop_type_t proptype; switch (prop = vdev_name_to_prop(propname)) { case VDEV_PROP_USERPROP: if (vdev_prop_user(propname)) { strval = fnvpair_value_string(elem); if (strlen(strval) == 0) { /* remove the property if value == "" */ (void) zap_remove(mos, objid, propname, tx); } else { VERIFY0(zap_update(mos, objid, propname, 1, strlen(strval) + 1, strval, tx)); } spa_history_log_internal(spa, "vdev set", tx, "vdev_guid=%llu: %s=%s", (u_longlong_t)vdev_guid, nvpair_name(elem), strval); } break; default: /* normalize the property name */ propname = vdev_prop_to_name(prop); proptype = vdev_prop_get_type(prop); if (nvpair_type(elem) == DATA_TYPE_STRING) { ASSERT(proptype == PROP_TYPE_STRING); strval = fnvpair_value_string(elem); VERIFY0(zap_update(mos, objid, propname, 1, strlen(strval) + 1, strval, tx)); spa_history_log_internal(spa, "vdev set", tx, "vdev_guid=%llu: %s=%s", (u_longlong_t)vdev_guid, nvpair_name(elem), strval); } else if (nvpair_type(elem) == DATA_TYPE_UINT64) { intval = fnvpair_value_uint64(elem); if (proptype == PROP_TYPE_INDEX) { const char *unused; VERIFY0(vdev_prop_index_to_string( prop, intval, &unused)); } VERIFY0(zap_update(mos, objid, propname, sizeof (uint64_t), 1, &intval, tx)); spa_history_log_internal(spa, "vdev set", tx, "vdev_guid=%llu: %s=%lld", (u_longlong_t)vdev_guid, nvpair_name(elem), (longlong_t)intval); } else { panic("invalid vdev property type %u", nvpair_type(elem)); } } } mutex_exit(&spa->spa_props_lock); } int vdev_prop_set(vdev_t *vd, nvlist_t *innvl, nvlist_t *outnvl) { spa_t *spa = vd->vdev_spa; nvpair_t *elem = NULL; uint64_t vdev_guid; nvlist_t *nvprops; int error = 0; ASSERT(vd != NULL); /* Check that vdev has a zap we can use */ if (vd->vdev_root_zap == 0 && vd->vdev_top_zap == 0 && vd->vdev_leaf_zap == 0) return (SET_ERROR(EINVAL)); if (nvlist_lookup_uint64(innvl, ZPOOL_VDEV_PROPS_SET_VDEV, &vdev_guid) != 0) return (SET_ERROR(EINVAL)); if (nvlist_lookup_nvlist(innvl, ZPOOL_VDEV_PROPS_SET_PROPS, &nvprops) != 0) return (SET_ERROR(EINVAL)); if ((vd = spa_lookup_by_guid(spa, vdev_guid, B_TRUE)) == NULL) return (SET_ERROR(EINVAL)); while ((elem = nvlist_next_nvpair(nvprops, elem)) != NULL) { const char *propname = nvpair_name(elem); vdev_prop_t prop = vdev_name_to_prop(propname); uint64_t intval = 0; const char *strval = NULL; if (prop == VDEV_PROP_USERPROP && !vdev_prop_user(propname)) { error = EINVAL; goto end; } if (vdev_prop_readonly(prop)) { error = EROFS; goto end; } /* Special Processing */ switch (prop) { case VDEV_PROP_PATH: if (vd->vdev_path == NULL) { error = EROFS; break; } if (nvpair_value_string(elem, &strval) != 0) { error = EINVAL; break; } /* New path must start with /dev/ */ if (strncmp(strval, "/dev/", 5)) { error = EINVAL; break; } error = spa_vdev_setpath(spa, vdev_guid, strval); break; case VDEV_PROP_ALLOCATING: if (nvpair_value_uint64(elem, &intval) != 0) { error = EINVAL; break; } if (intval != vd->vdev_noalloc) break; if (intval == 0) error = spa_vdev_noalloc(spa, vdev_guid); else error = spa_vdev_alloc(spa, vdev_guid); break; case VDEV_PROP_FAILFAST: if (nvpair_value_uint64(elem, &intval) != 0) { error = EINVAL; break; } vd->vdev_failfast = intval & 1; break; case VDEV_PROP_CHECKSUM_N: if (nvpair_value_uint64(elem, &intval) != 0) { error = EINVAL; break; } vd->vdev_checksum_n = intval; break; case VDEV_PROP_CHECKSUM_T: if (nvpair_value_uint64(elem, &intval) != 0) { error = EINVAL; break; } vd->vdev_checksum_t = intval; break; case VDEV_PROP_IO_N: if (nvpair_value_uint64(elem, &intval) != 0) { error = EINVAL; break; } vd->vdev_io_n = intval; break; case VDEV_PROP_IO_T: if (nvpair_value_uint64(elem, &intval) != 0) { error = EINVAL; break; } vd->vdev_io_t = intval; break; default: /* Most processing is done in vdev_props_set_sync */ break; } end: if (error != 0) { intval = error; vdev_prop_add_list(outnvl, propname, strval, intval, 0); return (error); } } return (dsl_sync_task(spa->spa_name, NULL, vdev_props_set_sync, innvl, 6, ZFS_SPACE_CHECK_EXTRA_RESERVED)); } int vdev_prop_get(vdev_t *vd, nvlist_t *innvl, nvlist_t *outnvl) { spa_t *spa = vd->vdev_spa; objset_t *mos = spa->spa_meta_objset; int err = 0; uint64_t objid; uint64_t vdev_guid; nvpair_t *elem = NULL; nvlist_t *nvprops = NULL; uint64_t intval = 0; char *strval = NULL; const char *propname = NULL; vdev_prop_t prop; ASSERT(vd != NULL); ASSERT(mos != NULL); if (nvlist_lookup_uint64(innvl, ZPOOL_VDEV_PROPS_GET_VDEV, &vdev_guid) != 0) return (SET_ERROR(EINVAL)); nvlist_lookup_nvlist(innvl, ZPOOL_VDEV_PROPS_GET_PROPS, &nvprops); if (vd->vdev_root_zap != 0) { objid = vd->vdev_root_zap; } else if (vd->vdev_top_zap != 0) { objid = vd->vdev_top_zap; } else if (vd->vdev_leaf_zap != 0) { objid = vd->vdev_leaf_zap; } else { return (SET_ERROR(EINVAL)); } ASSERT(objid != 0); mutex_enter(&spa->spa_props_lock); if (nvprops != NULL) { char namebuf[64] = { 0 }; while ((elem = nvlist_next_nvpair(nvprops, elem)) != NULL) { intval = 0; strval = NULL; propname = nvpair_name(elem); prop = vdev_name_to_prop(propname); zprop_source_t src = ZPROP_SRC_DEFAULT; uint64_t integer_size, num_integers; switch (prop) { /* Special Read-only Properties */ case VDEV_PROP_NAME: strval = vdev_name(vd, namebuf, sizeof (namebuf)); if (strval == NULL) continue; vdev_prop_add_list(outnvl, propname, strval, 0, ZPROP_SRC_NONE); continue; case VDEV_PROP_CAPACITY: /* percent used */ intval = (vd->vdev_stat.vs_dspace == 0) ? 0 : (vd->vdev_stat.vs_alloc * 100 / vd->vdev_stat.vs_dspace); vdev_prop_add_list(outnvl, propname, NULL, intval, ZPROP_SRC_NONE); continue; case VDEV_PROP_STATE: vdev_prop_add_list(outnvl, propname, NULL, vd->vdev_state, ZPROP_SRC_NONE); continue; case VDEV_PROP_GUID: vdev_prop_add_list(outnvl, propname, NULL, vd->vdev_guid, ZPROP_SRC_NONE); continue; case VDEV_PROP_ASIZE: vdev_prop_add_list(outnvl, propname, NULL, vd->vdev_asize, ZPROP_SRC_NONE); continue; case VDEV_PROP_PSIZE: vdev_prop_add_list(outnvl, propname, NULL, vd->vdev_psize, ZPROP_SRC_NONE); continue; case VDEV_PROP_ASHIFT: vdev_prop_add_list(outnvl, propname, NULL, vd->vdev_ashift, ZPROP_SRC_NONE); continue; case VDEV_PROP_SIZE: vdev_prop_add_list(outnvl, propname, NULL, vd->vdev_stat.vs_dspace, ZPROP_SRC_NONE); continue; case VDEV_PROP_FREE: vdev_prop_add_list(outnvl, propname, NULL, vd->vdev_stat.vs_dspace - vd->vdev_stat.vs_alloc, ZPROP_SRC_NONE); continue; case VDEV_PROP_ALLOCATED: vdev_prop_add_list(outnvl, propname, NULL, vd->vdev_stat.vs_alloc, ZPROP_SRC_NONE); continue; case VDEV_PROP_EXPANDSZ: vdev_prop_add_list(outnvl, propname, NULL, vd->vdev_stat.vs_esize, ZPROP_SRC_NONE); continue; case VDEV_PROP_FRAGMENTATION: vdev_prop_add_list(outnvl, propname, NULL, vd->vdev_stat.vs_fragmentation, ZPROP_SRC_NONE); continue; case VDEV_PROP_PARITY: vdev_prop_add_list(outnvl, propname, NULL, vdev_get_nparity(vd), ZPROP_SRC_NONE); continue; case VDEV_PROP_PATH: if (vd->vdev_path == NULL) continue; vdev_prop_add_list(outnvl, propname, vd->vdev_path, 0, ZPROP_SRC_NONE); continue; case VDEV_PROP_DEVID: if (vd->vdev_devid == NULL) continue; vdev_prop_add_list(outnvl, propname, vd->vdev_devid, 0, ZPROP_SRC_NONE); continue; case VDEV_PROP_PHYS_PATH: if (vd->vdev_physpath == NULL) continue; vdev_prop_add_list(outnvl, propname, vd->vdev_physpath, 0, ZPROP_SRC_NONE); continue; case VDEV_PROP_ENC_PATH: if (vd->vdev_enc_sysfs_path == NULL) continue; vdev_prop_add_list(outnvl, propname, vd->vdev_enc_sysfs_path, 0, ZPROP_SRC_NONE); continue; case VDEV_PROP_FRU: if (vd->vdev_fru == NULL) continue; vdev_prop_add_list(outnvl, propname, vd->vdev_fru, 0, ZPROP_SRC_NONE); continue; case VDEV_PROP_PARENT: if (vd->vdev_parent != NULL) { strval = vdev_name(vd->vdev_parent, namebuf, sizeof (namebuf)); vdev_prop_add_list(outnvl, propname, strval, 0, ZPROP_SRC_NONE); } continue; case VDEV_PROP_CHILDREN: if (vd->vdev_children > 0) strval = kmem_zalloc(ZAP_MAXVALUELEN, KM_SLEEP); for (uint64_t i = 0; i < vd->vdev_children; i++) { const char *vname; vname = vdev_name(vd->vdev_child[i], namebuf, sizeof (namebuf)); if (vname == NULL) vname = "(unknown)"; if (strlen(strval) > 0) strlcat(strval, ",", ZAP_MAXVALUELEN); strlcat(strval, vname, ZAP_MAXVALUELEN); } if (strval != NULL) { vdev_prop_add_list(outnvl, propname, strval, 0, ZPROP_SRC_NONE); kmem_free(strval, ZAP_MAXVALUELEN); } continue; case VDEV_PROP_NUMCHILDREN: vdev_prop_add_list(outnvl, propname, NULL, vd->vdev_children, ZPROP_SRC_NONE); continue; case VDEV_PROP_READ_ERRORS: vdev_prop_add_list(outnvl, propname, NULL, vd->vdev_stat.vs_read_errors, ZPROP_SRC_NONE); continue; case VDEV_PROP_WRITE_ERRORS: vdev_prop_add_list(outnvl, propname, NULL, vd->vdev_stat.vs_write_errors, ZPROP_SRC_NONE); continue; case VDEV_PROP_CHECKSUM_ERRORS: vdev_prop_add_list(outnvl, propname, NULL, vd->vdev_stat.vs_checksum_errors, ZPROP_SRC_NONE); continue; case VDEV_PROP_INITIALIZE_ERRORS: vdev_prop_add_list(outnvl, propname, NULL, vd->vdev_stat.vs_initialize_errors, ZPROP_SRC_NONE); continue; case VDEV_PROP_OPS_NULL: vdev_prop_add_list(outnvl, propname, NULL, vd->vdev_stat.vs_ops[ZIO_TYPE_NULL], ZPROP_SRC_NONE); continue; case VDEV_PROP_OPS_READ: vdev_prop_add_list(outnvl, propname, NULL, vd->vdev_stat.vs_ops[ZIO_TYPE_READ], ZPROP_SRC_NONE); continue; case VDEV_PROP_OPS_WRITE: vdev_prop_add_list(outnvl, propname, NULL, vd->vdev_stat.vs_ops[ZIO_TYPE_WRITE], ZPROP_SRC_NONE); continue; case VDEV_PROP_OPS_FREE: vdev_prop_add_list(outnvl, propname, NULL, vd->vdev_stat.vs_ops[ZIO_TYPE_FREE], ZPROP_SRC_NONE); continue; case VDEV_PROP_OPS_CLAIM: vdev_prop_add_list(outnvl, propname, NULL, vd->vdev_stat.vs_ops[ZIO_TYPE_CLAIM], ZPROP_SRC_NONE); continue; case VDEV_PROP_OPS_TRIM: /* * TRIM ops and bytes are reported to user * space as ZIO_TYPE_IOCTL. This is done to * preserve the vdev_stat_t structure layout * for user space. */ vdev_prop_add_list(outnvl, propname, NULL, vd->vdev_stat.vs_ops[ZIO_TYPE_IOCTL], ZPROP_SRC_NONE); continue; case VDEV_PROP_BYTES_NULL: vdev_prop_add_list(outnvl, propname, NULL, vd->vdev_stat.vs_bytes[ZIO_TYPE_NULL], ZPROP_SRC_NONE); continue; case VDEV_PROP_BYTES_READ: vdev_prop_add_list(outnvl, propname, NULL, vd->vdev_stat.vs_bytes[ZIO_TYPE_READ], ZPROP_SRC_NONE); continue; case VDEV_PROP_BYTES_WRITE: vdev_prop_add_list(outnvl, propname, NULL, vd->vdev_stat.vs_bytes[ZIO_TYPE_WRITE], ZPROP_SRC_NONE); continue; case VDEV_PROP_BYTES_FREE: vdev_prop_add_list(outnvl, propname, NULL, vd->vdev_stat.vs_bytes[ZIO_TYPE_FREE], ZPROP_SRC_NONE); continue; case VDEV_PROP_BYTES_CLAIM: vdev_prop_add_list(outnvl, propname, NULL, vd->vdev_stat.vs_bytes[ZIO_TYPE_CLAIM], ZPROP_SRC_NONE); continue; case VDEV_PROP_BYTES_TRIM: /* * TRIM ops and bytes are reported to user * space as ZIO_TYPE_IOCTL. This is done to * preserve the vdev_stat_t structure layout * for user space. */ vdev_prop_add_list(outnvl, propname, NULL, vd->vdev_stat.vs_bytes[ZIO_TYPE_IOCTL], ZPROP_SRC_NONE); continue; case VDEV_PROP_REMOVING: vdev_prop_add_list(outnvl, propname, NULL, vd->vdev_removing, ZPROP_SRC_NONE); continue; /* Numeric Properites */ case VDEV_PROP_ALLOCATING: /* Leaf vdevs cannot have this property */ if (vd->vdev_mg == NULL && vd->vdev_top != NULL) { src = ZPROP_SRC_NONE; intval = ZPROP_BOOLEAN_NA; } else { err = vdev_prop_get_int(vd, prop, &intval); if (err && err != ENOENT) break; if (intval == vdev_prop_default_numeric(prop)) src = ZPROP_SRC_DEFAULT; else src = ZPROP_SRC_LOCAL; } vdev_prop_add_list(outnvl, propname, NULL, intval, src); break; case VDEV_PROP_FAILFAST: src = ZPROP_SRC_LOCAL; strval = NULL; err = zap_lookup(mos, objid, nvpair_name(elem), sizeof (uint64_t), 1, &intval); if (err == ENOENT) { intval = vdev_prop_default_numeric( prop); err = 0; } else if (err) { break; } if (intval == vdev_prop_default_numeric(prop)) src = ZPROP_SRC_DEFAULT; vdev_prop_add_list(outnvl, propname, strval, intval, src); break; case VDEV_PROP_CHECKSUM_N: case VDEV_PROP_CHECKSUM_T: case VDEV_PROP_IO_N: case VDEV_PROP_IO_T: err = vdev_prop_get_int(vd, prop, &intval); if (err && err != ENOENT) break; if (intval == vdev_prop_default_numeric(prop)) src = ZPROP_SRC_DEFAULT; else src = ZPROP_SRC_LOCAL; vdev_prop_add_list(outnvl, propname, NULL, intval, src); break; /* Text Properties */ case VDEV_PROP_COMMENT: /* Exists in the ZAP below */ /* FALLTHRU */ case VDEV_PROP_USERPROP: /* User Properites */ src = ZPROP_SRC_LOCAL; err = zap_length(mos, objid, nvpair_name(elem), &integer_size, &num_integers); if (err) break; switch (integer_size) { case 8: /* User properties cannot be integers */ err = EINVAL; break; case 1: /* string property */ strval = kmem_alloc(num_integers, KM_SLEEP); err = zap_lookup(mos, objid, nvpair_name(elem), 1, num_integers, strval); if (err) { kmem_free(strval, num_integers); break; } vdev_prop_add_list(outnvl, propname, strval, 0, src); kmem_free(strval, num_integers); break; } break; default: err = ENOENT; break; } if (err) break; } } else { /* * Get all properties from the MOS vdev property object. */ zap_cursor_t zc; zap_attribute_t za; for (zap_cursor_init(&zc, mos, objid); (err = zap_cursor_retrieve(&zc, &za)) == 0; zap_cursor_advance(&zc)) { intval = 0; strval = NULL; zprop_source_t src = ZPROP_SRC_DEFAULT; propname = za.za_name; switch (za.za_integer_length) { case 8: /* We do not allow integer user properties */ /* This is likely an internal value */ break; case 1: /* string property */ strval = kmem_alloc(za.za_num_integers, KM_SLEEP); err = zap_lookup(mos, objid, za.za_name, 1, za.za_num_integers, strval); if (err) { kmem_free(strval, za.za_num_integers); break; } vdev_prop_add_list(outnvl, propname, strval, 0, src); kmem_free(strval, za.za_num_integers); break; default: break; } } zap_cursor_fini(&zc); } mutex_exit(&spa->spa_props_lock); if (err && err != ENOENT) { return (err); } return (0); } EXPORT_SYMBOL(vdev_fault); EXPORT_SYMBOL(vdev_degrade); EXPORT_SYMBOL(vdev_online); EXPORT_SYMBOL(vdev_offline); EXPORT_SYMBOL(vdev_clear); ZFS_MODULE_PARAM(zfs_vdev, zfs_vdev_, default_ms_count, UINT, ZMOD_RW, "Target number of metaslabs per top-level vdev"); ZFS_MODULE_PARAM(zfs_vdev, zfs_vdev_, default_ms_shift, UINT, ZMOD_RW, "Default lower limit for metaslab size"); ZFS_MODULE_PARAM(zfs_vdev, zfs_vdev_, max_ms_shift, UINT, ZMOD_RW, "Default upper limit for metaslab size"); ZFS_MODULE_PARAM(zfs_vdev, zfs_vdev_, min_ms_count, UINT, ZMOD_RW, "Minimum number of metaslabs per top-level vdev"); ZFS_MODULE_PARAM(zfs_vdev, zfs_vdev_, ms_count_limit, UINT, ZMOD_RW, "Practical upper limit of total metaslabs per top-level vdev"); ZFS_MODULE_PARAM(zfs, zfs_, slow_io_events_per_second, UINT, ZMOD_RW, "Rate limit slow IO (delay) events to this many per second"); /* BEGIN CSTYLED */ ZFS_MODULE_PARAM(zfs, zfs_, checksum_events_per_second, UINT, ZMOD_RW, "Rate limit checksum events to this many checksum errors per second " "(do not set below ZED threshold)."); /* END CSTYLED */ ZFS_MODULE_PARAM(zfs, zfs_, scan_ignore_errors, INT, ZMOD_RW, "Ignore errors during resilver/scrub"); ZFS_MODULE_PARAM(zfs_vdev, vdev_, validate_skip, INT, ZMOD_RW, "Bypass vdev_validate()"); ZFS_MODULE_PARAM(zfs, zfs_, nocacheflush, INT, ZMOD_RW, "Disable cache flushes"); ZFS_MODULE_PARAM(zfs, zfs_, embedded_slog_min_ms, UINT, ZMOD_RW, "Minimum number of metaslabs required to dedicate one for log blocks"); /* BEGIN CSTYLED */ ZFS_MODULE_PARAM_CALL(zfs_vdev, zfs_vdev_, min_auto_ashift, param_set_min_auto_ashift, param_get_uint, ZMOD_RW, "Minimum ashift used when creating new top-level vdevs"); ZFS_MODULE_PARAM_CALL(zfs_vdev, zfs_vdev_, max_auto_ashift, param_set_max_auto_ashift, param_get_uint, ZMOD_RW, "Maximum ashift used when optimizing for logical -> physical sector " "size on new top-level vdevs"); /* END CSTYLED */ diff --git a/sys/contrib/openzfs/module/zfs/zfs_quota.c b/sys/contrib/openzfs/module/zfs/zfs_quota.c index 9b351eefc04e..56f9d22ed0e5 100644 --- a/sys/contrib/openzfs/module/zfs/zfs_quota.c +++ b/sys/contrib/openzfs/module/zfs/zfs_quota.c @@ -1,475 +1,489 @@ /* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or https://opensource.org/licenses/CDDL-1.0. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright (c) 2005, 2010, Oracle and/or its affiliates. All rights reserved. * Copyright (c) 2011 Pawel Jakub Dawidek * Copyright (c) 2012, 2015, 2018 by Delphix. All rights reserved. * Copyright (c) 2014 Integros [integros.com] * Copyright 2016 Nexenta Systems, Inc. All rights reserved. */ /* Portions Copyright 2010 Robert Milkowski */ #include #include #include #include #include #include #include #include int zpl_get_file_info(dmu_object_type_t bonustype, const void *data, zfs_file_info_t *zoi) { /* * Is it a valid type of object to track? */ if (bonustype != DMU_OT_ZNODE && bonustype != DMU_OT_SA) return (SET_ERROR(ENOENT)); zoi->zfi_project = ZFS_DEFAULT_PROJID; /* * If we have a NULL data pointer * then assume the id's aren't changing and * return EEXIST to the dmu to let it know to * use the same ids */ if (data == NULL) return (SET_ERROR(EEXIST)); if (bonustype == DMU_OT_ZNODE) { const znode_phys_t *znp = data; zoi->zfi_user = znp->zp_uid; zoi->zfi_group = znp->zp_gid; zoi->zfi_generation = znp->zp_gen; return (0); } const sa_hdr_phys_t *sap = data; if (sap->sa_magic == 0) { /* * This should only happen for newly created files * that haven't had the znode data filled in yet. */ zoi->zfi_user = 0; zoi->zfi_group = 0; zoi->zfi_generation = 0; return (0); } sa_hdr_phys_t sa = *sap; boolean_t swap = B_FALSE; if (sa.sa_magic == BSWAP_32(SA_MAGIC)) { sa.sa_magic = SA_MAGIC; sa.sa_layout_info = BSWAP_16(sa.sa_layout_info); swap = B_TRUE; } VERIFY3U(sa.sa_magic, ==, SA_MAGIC); int hdrsize = sa_hdrsize(&sa); VERIFY3U(hdrsize, >=, sizeof (sa_hdr_phys_t)); uintptr_t data_after_hdr = (uintptr_t)data + hdrsize; zoi->zfi_user = *((uint64_t *)(data_after_hdr + SA_UID_OFFSET)); zoi->zfi_group = *((uint64_t *)(data_after_hdr + SA_GID_OFFSET)); zoi->zfi_generation = *((uint64_t *)(data_after_hdr + SA_GEN_OFFSET)); uint64_t flags = *((uint64_t *)(data_after_hdr + SA_FLAGS_OFFSET)); if (swap) flags = BSWAP_64(flags); if (flags & ZFS_PROJID) { zoi->zfi_project = *((uint64_t *)(data_after_hdr + SA_PROJID_OFFSET)); } if (swap) { zoi->zfi_user = BSWAP_64(zoi->zfi_user); zoi->zfi_group = BSWAP_64(zoi->zfi_group); zoi->zfi_project = BSWAP_64(zoi->zfi_project); zoi->zfi_generation = BSWAP_64(zoi->zfi_generation); } return (0); } static void fuidstr_to_sid(zfsvfs_t *zfsvfs, const char *fuidstr, char *domainbuf, int buflen, uid_t *ridp) { uint64_t fuid; const char *domain; fuid = zfs_strtonum(fuidstr, NULL); domain = zfs_fuid_find_by_idx(zfsvfs, FUID_INDEX(fuid)); if (domain) (void) strlcpy(domainbuf, domain, buflen); else domainbuf[0] = '\0'; *ridp = FUID_RID(fuid); } static uint64_t zfs_userquota_prop_to_obj(zfsvfs_t *zfsvfs, zfs_userquota_prop_t type) { switch (type) { case ZFS_PROP_USERUSED: case ZFS_PROP_USEROBJUSED: return (DMU_USERUSED_OBJECT); case ZFS_PROP_GROUPUSED: case ZFS_PROP_GROUPOBJUSED: return (DMU_GROUPUSED_OBJECT); case ZFS_PROP_PROJECTUSED: case ZFS_PROP_PROJECTOBJUSED: return (DMU_PROJECTUSED_OBJECT); case ZFS_PROP_USERQUOTA: return (zfsvfs->z_userquota_obj); case ZFS_PROP_GROUPQUOTA: return (zfsvfs->z_groupquota_obj); case ZFS_PROP_USEROBJQUOTA: return (zfsvfs->z_userobjquota_obj); case ZFS_PROP_GROUPOBJQUOTA: return (zfsvfs->z_groupobjquota_obj); case ZFS_PROP_PROJECTQUOTA: return (zfsvfs->z_projectquota_obj); case ZFS_PROP_PROJECTOBJQUOTA: return (zfsvfs->z_projectobjquota_obj); default: return (ZFS_NO_OBJECT); } } int zfs_userspace_many(zfsvfs_t *zfsvfs, zfs_userquota_prop_t type, uint64_t *cookiep, void *vbuf, uint64_t *bufsizep) { int error; zap_cursor_t zc; zap_attribute_t za; zfs_useracct_t *buf = vbuf; uint64_t obj; int offset = 0; if (!dmu_objset_userspace_present(zfsvfs->z_os)) return (SET_ERROR(ENOTSUP)); if ((type == ZFS_PROP_PROJECTQUOTA || type == ZFS_PROP_PROJECTUSED || type == ZFS_PROP_PROJECTOBJQUOTA || type == ZFS_PROP_PROJECTOBJUSED) && !dmu_objset_projectquota_present(zfsvfs->z_os)) return (SET_ERROR(ENOTSUP)); if ((type == ZFS_PROP_USEROBJUSED || type == ZFS_PROP_GROUPOBJUSED || type == ZFS_PROP_USEROBJQUOTA || type == ZFS_PROP_GROUPOBJQUOTA || type == ZFS_PROP_PROJECTOBJUSED || type == ZFS_PROP_PROJECTOBJQUOTA) && !dmu_objset_userobjspace_present(zfsvfs->z_os)) return (SET_ERROR(ENOTSUP)); obj = zfs_userquota_prop_to_obj(zfsvfs, type); if (obj == ZFS_NO_OBJECT) { *bufsizep = 0; return (0); } if (type == ZFS_PROP_USEROBJUSED || type == ZFS_PROP_GROUPOBJUSED || type == ZFS_PROP_PROJECTOBJUSED) offset = DMU_OBJACCT_PREFIX_LEN; for (zap_cursor_init_serialized(&zc, zfsvfs->z_os, obj, *cookiep); (error = zap_cursor_retrieve(&zc, &za)) == 0; zap_cursor_advance(&zc)) { if ((uintptr_t)buf - (uintptr_t)vbuf + sizeof (zfs_useracct_t) > *bufsizep) break; /* * skip object quota (with zap name prefix DMU_OBJACCT_PREFIX) * when dealing with block quota and vice versa. */ if ((offset > 0) != (strncmp(za.za_name, DMU_OBJACCT_PREFIX, DMU_OBJACCT_PREFIX_LEN) == 0)) continue; fuidstr_to_sid(zfsvfs, za.za_name + offset, buf->zu_domain, sizeof (buf->zu_domain), &buf->zu_rid); buf->zu_space = za.za_first_integer; buf++; } if (error == ENOENT) error = 0; ASSERT3U((uintptr_t)buf - (uintptr_t)vbuf, <=, *bufsizep); *bufsizep = (uintptr_t)buf - (uintptr_t)vbuf; *cookiep = zap_cursor_serialize(&zc); zap_cursor_fini(&zc); return (error); } int zfs_userspace_one(zfsvfs_t *zfsvfs, zfs_userquota_prop_t type, const char *domain, uint64_t rid, uint64_t *valp) { char buf[20 + DMU_OBJACCT_PREFIX_LEN]; int offset = 0; int err; uint64_t obj; *valp = 0; if (!dmu_objset_userspace_present(zfsvfs->z_os)) return (SET_ERROR(ENOTSUP)); if ((type == ZFS_PROP_USEROBJUSED || type == ZFS_PROP_GROUPOBJUSED || type == ZFS_PROP_USEROBJQUOTA || type == ZFS_PROP_GROUPOBJQUOTA || type == ZFS_PROP_PROJECTOBJUSED || type == ZFS_PROP_PROJECTOBJQUOTA) && !dmu_objset_userobjspace_present(zfsvfs->z_os)) return (SET_ERROR(ENOTSUP)); if (type == ZFS_PROP_PROJECTQUOTA || type == ZFS_PROP_PROJECTUSED || type == ZFS_PROP_PROJECTOBJQUOTA || type == ZFS_PROP_PROJECTOBJUSED) { if (!dmu_objset_projectquota_present(zfsvfs->z_os)) return (SET_ERROR(ENOTSUP)); if (!zpl_is_valid_projid(rid)) return (SET_ERROR(EINVAL)); } obj = zfs_userquota_prop_to_obj(zfsvfs, type); if (obj == ZFS_NO_OBJECT) return (0); if (type == ZFS_PROP_USEROBJUSED || type == ZFS_PROP_GROUPOBJUSED || type == ZFS_PROP_PROJECTOBJUSED) { strlcpy(buf, DMU_OBJACCT_PREFIX, DMU_OBJACCT_PREFIX_LEN + 1); offset = DMU_OBJACCT_PREFIX_LEN; } err = zfs_id_to_fuidstr(zfsvfs, domain, rid, buf + offset, sizeof (buf) - offset, B_FALSE); if (err) return (err); err = zap_lookup(zfsvfs->z_os, obj, buf, 8, 1, valp); if (err == ENOENT) err = 0; return (err); } int zfs_set_userquota(zfsvfs_t *zfsvfs, zfs_userquota_prop_t type, const char *domain, uint64_t rid, uint64_t quota) { char buf[32]; int err; dmu_tx_t *tx; uint64_t *objp; boolean_t fuid_dirtied; if (zfsvfs->z_version < ZPL_VERSION_USERSPACE) return (SET_ERROR(ENOTSUP)); switch (type) { case ZFS_PROP_USERQUOTA: objp = &zfsvfs->z_userquota_obj; break; case ZFS_PROP_GROUPQUOTA: objp = &zfsvfs->z_groupquota_obj; break; case ZFS_PROP_USEROBJQUOTA: objp = &zfsvfs->z_userobjquota_obj; break; case ZFS_PROP_GROUPOBJQUOTA: objp = &zfsvfs->z_groupobjquota_obj; break; case ZFS_PROP_PROJECTQUOTA: if (!dmu_objset_projectquota_enabled(zfsvfs->z_os)) return (SET_ERROR(ENOTSUP)); if (!zpl_is_valid_projid(rid)) return (SET_ERROR(EINVAL)); objp = &zfsvfs->z_projectquota_obj; break; case ZFS_PROP_PROJECTOBJQUOTA: if (!dmu_objset_projectquota_enabled(zfsvfs->z_os)) return (SET_ERROR(ENOTSUP)); if (!zpl_is_valid_projid(rid)) return (SET_ERROR(EINVAL)); objp = &zfsvfs->z_projectobjquota_obj; break; default: return (SET_ERROR(EINVAL)); } err = zfs_id_to_fuidstr(zfsvfs, domain, rid, buf, sizeof (buf), B_TRUE); if (err) return (err); fuid_dirtied = zfsvfs->z_fuid_dirty; tx = dmu_tx_create(zfsvfs->z_os); dmu_tx_hold_zap(tx, *objp ? *objp : DMU_NEW_OBJECT, B_TRUE, NULL); if (*objp == 0) { dmu_tx_hold_zap(tx, MASTER_NODE_OBJ, B_TRUE, zfs_userquota_prop_prefixes[type]); } if (fuid_dirtied) zfs_fuid_txhold(zfsvfs, tx); err = dmu_tx_assign(tx, TXG_WAIT); if (err) { dmu_tx_abort(tx); return (err); } mutex_enter(&zfsvfs->z_lock); if (*objp == 0) { *objp = zap_create(zfsvfs->z_os, DMU_OT_USERGROUP_QUOTA, DMU_OT_NONE, 0, tx); - VERIFY(0 == zap_add(zfsvfs->z_os, MASTER_NODE_OBJ, + VERIFY0(zap_add(zfsvfs->z_os, MASTER_NODE_OBJ, zfs_userquota_prop_prefixes[type], 8, 1, objp, tx)); } - mutex_exit(&zfsvfs->z_lock); if (quota == 0) { err = zap_remove(zfsvfs->z_os, *objp, buf, tx); if (err == ENOENT) err = 0; + /* + * If the quota contains no more entries after the entry + * was removed, destroy the quota zap and remove the + * reference from zfsvfs. This will save us unnecessary + * zap_lookups for the quota during writes. + */ + uint64_t zap_nentries; + VERIFY0(zap_count(zfsvfs->z_os, *objp, &zap_nentries)); + if (zap_nentries == 0) { + VERIFY0(zap_remove(zfsvfs->z_os, MASTER_NODE_OBJ, + zfs_userquota_prop_prefixes[type], tx)); + VERIFY0(zap_destroy(zfsvfs->z_os, *objp, tx)); + *objp = 0; + } } else { err = zap_update(zfsvfs->z_os, *objp, buf, 8, 1, "a, tx); } + mutex_exit(&zfsvfs->z_lock); ASSERT(err == 0); if (fuid_dirtied) zfs_fuid_sync(zfsvfs, tx); dmu_tx_commit(tx); return (err); } boolean_t zfs_id_overobjquota(zfsvfs_t *zfsvfs, uint64_t usedobj, uint64_t id) { char buf[20 + DMU_OBJACCT_PREFIX_LEN]; uint64_t used, quota, quotaobj; int err; if (!dmu_objset_userobjspace_present(zfsvfs->z_os)) { if (dmu_objset_userobjspace_upgradable(zfsvfs->z_os)) { dsl_pool_config_enter( dmu_objset_pool(zfsvfs->z_os), FTAG); dmu_objset_id_quota_upgrade(zfsvfs->z_os); dsl_pool_config_exit( dmu_objset_pool(zfsvfs->z_os), FTAG); } return (B_FALSE); } if (usedobj == DMU_PROJECTUSED_OBJECT) { if (!dmu_objset_projectquota_present(zfsvfs->z_os)) { if (dmu_objset_projectquota_upgradable(zfsvfs->z_os)) { dsl_pool_config_enter( dmu_objset_pool(zfsvfs->z_os), FTAG); dmu_objset_id_quota_upgrade(zfsvfs->z_os); dsl_pool_config_exit( dmu_objset_pool(zfsvfs->z_os), FTAG); } return (B_FALSE); } quotaobj = zfsvfs->z_projectobjquota_obj; } else if (usedobj == DMU_USERUSED_OBJECT) { quotaobj = zfsvfs->z_userobjquota_obj; } else if (usedobj == DMU_GROUPUSED_OBJECT) { quotaobj = zfsvfs->z_groupobjquota_obj; } else { return (B_FALSE); } if (quotaobj == 0 || zfsvfs->z_replay) return (B_FALSE); (void) snprintf(buf, sizeof (buf), "%llx", (longlong_t)id); err = zap_lookup(zfsvfs->z_os, quotaobj, buf, 8, 1, "a); if (err != 0) return (B_FALSE); (void) snprintf(buf, sizeof (buf), DMU_OBJACCT_PREFIX "%llx", (longlong_t)id); err = zap_lookup(zfsvfs->z_os, usedobj, buf, 8, 1, &used); if (err != 0) return (B_FALSE); return (used >= quota); } boolean_t zfs_id_overblockquota(zfsvfs_t *zfsvfs, uint64_t usedobj, uint64_t id) { char buf[20]; uint64_t used, quota, quotaobj; int err; if (usedobj == DMU_PROJECTUSED_OBJECT) { if (!dmu_objset_projectquota_present(zfsvfs->z_os)) { if (dmu_objset_projectquota_upgradable(zfsvfs->z_os)) { dsl_pool_config_enter( dmu_objset_pool(zfsvfs->z_os), FTAG); dmu_objset_id_quota_upgrade(zfsvfs->z_os); dsl_pool_config_exit( dmu_objset_pool(zfsvfs->z_os), FTAG); } return (B_FALSE); } quotaobj = zfsvfs->z_projectquota_obj; } else if (usedobj == DMU_USERUSED_OBJECT) { quotaobj = zfsvfs->z_userquota_obj; } else if (usedobj == DMU_GROUPUSED_OBJECT) { quotaobj = zfsvfs->z_groupquota_obj; } else { return (B_FALSE); } if (quotaobj == 0 || zfsvfs->z_replay) return (B_FALSE); (void) snprintf(buf, sizeof (buf), "%llx", (longlong_t)id); err = zap_lookup(zfsvfs->z_os, quotaobj, buf, 8, 1, "a); if (err != 0) return (B_FALSE); err = zap_lookup(zfsvfs->z_os, usedobj, buf, 8, 1, &used); if (err != 0) return (B_FALSE); return (used >= quota); } boolean_t zfs_id_overquota(zfsvfs_t *zfsvfs, uint64_t usedobj, uint64_t id) { return (zfs_id_overblockquota(zfsvfs, usedobj, id) || zfs_id_overobjquota(zfsvfs, usedobj, id)); } EXPORT_SYMBOL(zpl_get_file_info); EXPORT_SYMBOL(zfs_userspace_one); EXPORT_SYMBOL(zfs_userspace_many); EXPORT_SYMBOL(zfs_set_userquota); EXPORT_SYMBOL(zfs_id_overblockquota); EXPORT_SYMBOL(zfs_id_overobjquota); EXPORT_SYMBOL(zfs_id_overquota); diff --git a/sys/contrib/openzfs/module/zfs/zil.c b/sys/contrib/openzfs/module/zfs/zil.c index 18c6cbf028b3..a11886136994 100644 --- a/sys/contrib/openzfs/module/zfs/zil.c +++ b/sys/contrib/openzfs/module/zfs/zil.c @@ -1,4233 +1,4233 @@ /* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or https://opensource.org/licenses/CDDL-1.0. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright (c) 2005, 2010, Oracle and/or its affiliates. All rights reserved. * Copyright (c) 2011, 2018 by Delphix. All rights reserved. * Copyright (c) 2014 Integros [integros.com] * Copyright (c) 2018 Datto Inc. */ /* Portions Copyright 2010 Robert Milkowski */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* * The ZFS Intent Log (ZIL) saves "transaction records" (itxs) of system * calls that change the file system. Each itx has enough information to * be able to replay them after a system crash, power loss, or * equivalent failure mode. These are stored in memory until either: * * 1. they are committed to the pool by the DMU transaction group * (txg), at which point they can be discarded; or * 2. they are committed to the on-disk ZIL for the dataset being * modified (e.g. due to an fsync, O_DSYNC, or other synchronous * requirement). * * In the event of a crash or power loss, the itxs contained by each * dataset's on-disk ZIL will be replayed when that dataset is first * instantiated (e.g. if the dataset is a normal filesystem, when it is * first mounted). * * As hinted at above, there is one ZIL per dataset (both the in-memory * representation, and the on-disk representation). The on-disk format * consists of 3 parts: * * - a single, per-dataset, ZIL header; which points to a chain of * - zero or more ZIL blocks; each of which contains * - zero or more ZIL records * * A ZIL record holds the information necessary to replay a single * system call transaction. A ZIL block can hold many ZIL records, and * the blocks are chained together, similarly to a singly linked list. * * Each ZIL block contains a block pointer (blkptr_t) to the next ZIL * block in the chain, and the ZIL header points to the first block in * the chain. * * Note, there is not a fixed place in the pool to hold these ZIL * blocks; they are dynamically allocated and freed as needed from the * blocks available on the pool, though they can be preferentially * allocated from a dedicated "log" vdev. */ /* * This controls the amount of time that a ZIL block (lwb) will remain * "open" when it isn't "full", and it has a thread waiting for it to be * committed to stable storage. Please refer to the zil_commit_waiter() * function (and the comments within it) for more details. */ static uint_t zfs_commit_timeout_pct = 5; /* * Minimal time we care to delay commit waiting for more ZIL records. * At least FreeBSD kernel can't sleep for less than 2us at its best. * So requests to sleep for less then 5us is a waste of CPU time with * a risk of significant log latency increase due to oversleep. */ static uint64_t zil_min_commit_timeout = 5000; /* * See zil.h for more information about these fields. */ static zil_kstat_values_t zil_stats = { { "zil_commit_count", KSTAT_DATA_UINT64 }, { "zil_commit_writer_count", KSTAT_DATA_UINT64 }, { "zil_itx_count", KSTAT_DATA_UINT64 }, { "zil_itx_indirect_count", KSTAT_DATA_UINT64 }, { "zil_itx_indirect_bytes", KSTAT_DATA_UINT64 }, { "zil_itx_copied_count", KSTAT_DATA_UINT64 }, { "zil_itx_copied_bytes", KSTAT_DATA_UINT64 }, { "zil_itx_needcopy_count", KSTAT_DATA_UINT64 }, { "zil_itx_needcopy_bytes", KSTAT_DATA_UINT64 }, { "zil_itx_metaslab_normal_count", KSTAT_DATA_UINT64 }, { "zil_itx_metaslab_normal_bytes", KSTAT_DATA_UINT64 }, { "zil_itx_metaslab_normal_write", KSTAT_DATA_UINT64 }, { "zil_itx_metaslab_normal_alloc", KSTAT_DATA_UINT64 }, { "zil_itx_metaslab_slog_count", KSTAT_DATA_UINT64 }, { "zil_itx_metaslab_slog_bytes", KSTAT_DATA_UINT64 }, { "zil_itx_metaslab_slog_write", KSTAT_DATA_UINT64 }, { "zil_itx_metaslab_slog_alloc", KSTAT_DATA_UINT64 }, }; static zil_sums_t zil_sums_global; static kstat_t *zil_kstats_global; /* * Disable intent logging replay. This global ZIL switch affects all pools. */ int zil_replay_disable = 0; /* * Disable the DKIOCFLUSHWRITECACHE commands that are normally sent to * the disk(s) by the ZIL after an LWB write has completed. Setting this * will cause ZIL corruption on power loss if a volatile out-of-order * write cache is enabled. */ static int zil_nocacheflush = 0; /* * Limit SLOG write size per commit executed with synchronous priority. * Any writes above that will be executed with lower (asynchronous) priority * to limit potential SLOG device abuse by single active ZIL writer. */ -static uint64_t zil_slog_bulk = 768 * 1024; +static uint64_t zil_slog_bulk = 64 * 1024 * 1024; static kmem_cache_t *zil_lwb_cache; static kmem_cache_t *zil_zcw_cache; static void zil_lwb_commit(zilog_t *zilog, lwb_t *lwb, itx_t *itx); static itx_t *zil_itx_clone(itx_t *oitx); static int zil_bp_compare(const void *x1, const void *x2) { const dva_t *dva1 = &((zil_bp_node_t *)x1)->zn_dva; const dva_t *dva2 = &((zil_bp_node_t *)x2)->zn_dva; int cmp = TREE_CMP(DVA_GET_VDEV(dva1), DVA_GET_VDEV(dva2)); if (likely(cmp)) return (cmp); return (TREE_CMP(DVA_GET_OFFSET(dva1), DVA_GET_OFFSET(dva2))); } static void zil_bp_tree_init(zilog_t *zilog) { avl_create(&zilog->zl_bp_tree, zil_bp_compare, sizeof (zil_bp_node_t), offsetof(zil_bp_node_t, zn_node)); } static void zil_bp_tree_fini(zilog_t *zilog) { avl_tree_t *t = &zilog->zl_bp_tree; zil_bp_node_t *zn; void *cookie = NULL; while ((zn = avl_destroy_nodes(t, &cookie)) != NULL) kmem_free(zn, sizeof (zil_bp_node_t)); avl_destroy(t); } int zil_bp_tree_add(zilog_t *zilog, const blkptr_t *bp) { avl_tree_t *t = &zilog->zl_bp_tree; const dva_t *dva; zil_bp_node_t *zn; avl_index_t where; if (BP_IS_EMBEDDED(bp)) return (0); dva = BP_IDENTITY(bp); if (avl_find(t, dva, &where) != NULL) return (SET_ERROR(EEXIST)); zn = kmem_alloc(sizeof (zil_bp_node_t), KM_SLEEP); zn->zn_dva = *dva; avl_insert(t, zn, where); return (0); } static zil_header_t * zil_header_in_syncing_context(zilog_t *zilog) { return ((zil_header_t *)zilog->zl_header); } static void zil_init_log_chain(zilog_t *zilog, blkptr_t *bp) { zio_cksum_t *zc = &bp->blk_cksum; (void) random_get_pseudo_bytes((void *)&zc->zc_word[ZIL_ZC_GUID_0], sizeof (zc->zc_word[ZIL_ZC_GUID_0])); (void) random_get_pseudo_bytes((void *)&zc->zc_word[ZIL_ZC_GUID_1], sizeof (zc->zc_word[ZIL_ZC_GUID_1])); zc->zc_word[ZIL_ZC_OBJSET] = dmu_objset_id(zilog->zl_os); zc->zc_word[ZIL_ZC_SEQ] = 1ULL; } static int zil_kstats_global_update(kstat_t *ksp, int rw) { zil_kstat_values_t *zs = ksp->ks_data; ASSERT3P(&zil_stats, ==, zs); if (rw == KSTAT_WRITE) { return (SET_ERROR(EACCES)); } zil_kstat_values_update(zs, &zil_sums_global); return (0); } /* * Read a log block and make sure it's valid. */ static int zil_read_log_block(zilog_t *zilog, boolean_t decrypt, const blkptr_t *bp, blkptr_t *nbp, char **begin, char **end, arc_buf_t **abuf) { zio_flag_t zio_flags = ZIO_FLAG_CANFAIL; arc_flags_t aflags = ARC_FLAG_WAIT; zbookmark_phys_t zb; int error; if (zilog->zl_header->zh_claim_txg == 0) zio_flags |= ZIO_FLAG_SPECULATIVE | ZIO_FLAG_SCRUB; if (!(zilog->zl_header->zh_flags & ZIL_CLAIM_LR_SEQ_VALID)) zio_flags |= ZIO_FLAG_SPECULATIVE; if (!decrypt) zio_flags |= ZIO_FLAG_RAW; SET_BOOKMARK(&zb, bp->blk_cksum.zc_word[ZIL_ZC_OBJSET], ZB_ZIL_OBJECT, ZB_ZIL_LEVEL, bp->blk_cksum.zc_word[ZIL_ZC_SEQ]); error = arc_read(NULL, zilog->zl_spa, bp, arc_getbuf_func, abuf, ZIO_PRIORITY_SYNC_READ, zio_flags, &aflags, &zb); if (error == 0) { zio_cksum_t cksum = bp->blk_cksum; /* * Validate the checksummed log block. * * Sequence numbers should be... sequential. The checksum * verifier for the next block should be bp's checksum plus 1. * * Also check the log chain linkage and size used. */ cksum.zc_word[ZIL_ZC_SEQ]++; uint64_t size = BP_GET_LSIZE(bp); if (BP_GET_CHECKSUM(bp) == ZIO_CHECKSUM_ZILOG2) { zil_chain_t *zilc = (*abuf)->b_data; char *lr = (char *)(zilc + 1); if (memcmp(&cksum, &zilc->zc_next_blk.blk_cksum, sizeof (cksum)) || zilc->zc_nused < sizeof (*zilc) || zilc->zc_nused > size) { error = SET_ERROR(ECKSUM); } else { *begin = lr; *end = lr + zilc->zc_nused - sizeof (*zilc); *nbp = zilc->zc_next_blk; } } else { char *lr = (*abuf)->b_data; zil_chain_t *zilc = (zil_chain_t *)(lr + size) - 1; if (memcmp(&cksum, &zilc->zc_next_blk.blk_cksum, sizeof (cksum)) || (zilc->zc_nused > (size - sizeof (*zilc)))) { error = SET_ERROR(ECKSUM); } else { *begin = lr; *end = lr + zilc->zc_nused; *nbp = zilc->zc_next_blk; } } } return (error); } /* * Read a TX_WRITE log data block. */ static int zil_read_log_data(zilog_t *zilog, const lr_write_t *lr, void *wbuf) { zio_flag_t zio_flags = ZIO_FLAG_CANFAIL; const blkptr_t *bp = &lr->lr_blkptr; arc_flags_t aflags = ARC_FLAG_WAIT; arc_buf_t *abuf = NULL; zbookmark_phys_t zb; int error; if (BP_IS_HOLE(bp)) { if (wbuf != NULL) memset(wbuf, 0, MAX(BP_GET_LSIZE(bp), lr->lr_length)); return (0); } if (zilog->zl_header->zh_claim_txg == 0) zio_flags |= ZIO_FLAG_SPECULATIVE | ZIO_FLAG_SCRUB; /* * If we are not using the resulting data, we are just checking that * it hasn't been corrupted so we don't need to waste CPU time * decompressing and decrypting it. */ if (wbuf == NULL) zio_flags |= ZIO_FLAG_RAW; ASSERT3U(BP_GET_LSIZE(bp), !=, 0); SET_BOOKMARK(&zb, dmu_objset_id(zilog->zl_os), lr->lr_foid, ZB_ZIL_LEVEL, lr->lr_offset / BP_GET_LSIZE(bp)); error = arc_read(NULL, zilog->zl_spa, bp, arc_getbuf_func, &abuf, ZIO_PRIORITY_SYNC_READ, zio_flags, &aflags, &zb); if (error == 0) { if (wbuf != NULL) memcpy(wbuf, abuf->b_data, arc_buf_size(abuf)); arc_buf_destroy(abuf, &abuf); } return (error); } void zil_sums_init(zil_sums_t *zs) { wmsum_init(&zs->zil_commit_count, 0); wmsum_init(&zs->zil_commit_writer_count, 0); wmsum_init(&zs->zil_itx_count, 0); wmsum_init(&zs->zil_itx_indirect_count, 0); wmsum_init(&zs->zil_itx_indirect_bytes, 0); wmsum_init(&zs->zil_itx_copied_count, 0); wmsum_init(&zs->zil_itx_copied_bytes, 0); wmsum_init(&zs->zil_itx_needcopy_count, 0); wmsum_init(&zs->zil_itx_needcopy_bytes, 0); wmsum_init(&zs->zil_itx_metaslab_normal_count, 0); wmsum_init(&zs->zil_itx_metaslab_normal_bytes, 0); wmsum_init(&zs->zil_itx_metaslab_normal_write, 0); wmsum_init(&zs->zil_itx_metaslab_normal_alloc, 0); wmsum_init(&zs->zil_itx_metaslab_slog_count, 0); wmsum_init(&zs->zil_itx_metaslab_slog_bytes, 0); wmsum_init(&zs->zil_itx_metaslab_slog_write, 0); wmsum_init(&zs->zil_itx_metaslab_slog_alloc, 0); } void zil_sums_fini(zil_sums_t *zs) { wmsum_fini(&zs->zil_commit_count); wmsum_fini(&zs->zil_commit_writer_count); wmsum_fini(&zs->zil_itx_count); wmsum_fini(&zs->zil_itx_indirect_count); wmsum_fini(&zs->zil_itx_indirect_bytes); wmsum_fini(&zs->zil_itx_copied_count); wmsum_fini(&zs->zil_itx_copied_bytes); wmsum_fini(&zs->zil_itx_needcopy_count); wmsum_fini(&zs->zil_itx_needcopy_bytes); wmsum_fini(&zs->zil_itx_metaslab_normal_count); wmsum_fini(&zs->zil_itx_metaslab_normal_bytes); wmsum_fini(&zs->zil_itx_metaslab_normal_write); wmsum_fini(&zs->zil_itx_metaslab_normal_alloc); wmsum_fini(&zs->zil_itx_metaslab_slog_count); wmsum_fini(&zs->zil_itx_metaslab_slog_bytes); wmsum_fini(&zs->zil_itx_metaslab_slog_write); wmsum_fini(&zs->zil_itx_metaslab_slog_alloc); } void zil_kstat_values_update(zil_kstat_values_t *zs, zil_sums_t *zil_sums) { zs->zil_commit_count.value.ui64 = wmsum_value(&zil_sums->zil_commit_count); zs->zil_commit_writer_count.value.ui64 = wmsum_value(&zil_sums->zil_commit_writer_count); zs->zil_itx_count.value.ui64 = wmsum_value(&zil_sums->zil_itx_count); zs->zil_itx_indirect_count.value.ui64 = wmsum_value(&zil_sums->zil_itx_indirect_count); zs->zil_itx_indirect_bytes.value.ui64 = wmsum_value(&zil_sums->zil_itx_indirect_bytes); zs->zil_itx_copied_count.value.ui64 = wmsum_value(&zil_sums->zil_itx_copied_count); zs->zil_itx_copied_bytes.value.ui64 = wmsum_value(&zil_sums->zil_itx_copied_bytes); zs->zil_itx_needcopy_count.value.ui64 = wmsum_value(&zil_sums->zil_itx_needcopy_count); zs->zil_itx_needcopy_bytes.value.ui64 = wmsum_value(&zil_sums->zil_itx_needcopy_bytes); zs->zil_itx_metaslab_normal_count.value.ui64 = wmsum_value(&zil_sums->zil_itx_metaslab_normal_count); zs->zil_itx_metaslab_normal_bytes.value.ui64 = wmsum_value(&zil_sums->zil_itx_metaslab_normal_bytes); zs->zil_itx_metaslab_normal_write.value.ui64 = wmsum_value(&zil_sums->zil_itx_metaslab_normal_write); zs->zil_itx_metaslab_normal_alloc.value.ui64 = wmsum_value(&zil_sums->zil_itx_metaslab_normal_alloc); zs->zil_itx_metaslab_slog_count.value.ui64 = wmsum_value(&zil_sums->zil_itx_metaslab_slog_count); zs->zil_itx_metaslab_slog_bytes.value.ui64 = wmsum_value(&zil_sums->zil_itx_metaslab_slog_bytes); zs->zil_itx_metaslab_slog_write.value.ui64 = wmsum_value(&zil_sums->zil_itx_metaslab_slog_write); zs->zil_itx_metaslab_slog_alloc.value.ui64 = wmsum_value(&zil_sums->zil_itx_metaslab_slog_alloc); } /* * Parse the intent log, and call parse_func for each valid record within. */ int zil_parse(zilog_t *zilog, zil_parse_blk_func_t *parse_blk_func, zil_parse_lr_func_t *parse_lr_func, void *arg, uint64_t txg, boolean_t decrypt) { const zil_header_t *zh = zilog->zl_header; boolean_t claimed = !!zh->zh_claim_txg; uint64_t claim_blk_seq = claimed ? zh->zh_claim_blk_seq : UINT64_MAX; uint64_t claim_lr_seq = claimed ? zh->zh_claim_lr_seq : UINT64_MAX; uint64_t max_blk_seq = 0; uint64_t max_lr_seq = 0; uint64_t blk_count = 0; uint64_t lr_count = 0; blkptr_t blk, next_blk = {{{{0}}}}; int error = 0; /* * Old logs didn't record the maximum zh_claim_lr_seq. */ if (!(zh->zh_flags & ZIL_CLAIM_LR_SEQ_VALID)) claim_lr_seq = UINT64_MAX; /* * Starting at the block pointed to by zh_log we read the log chain. * For each block in the chain we strongly check that block to * ensure its validity. We stop when an invalid block is found. * For each block pointer in the chain we call parse_blk_func(). * For each record in each valid block we call parse_lr_func(). * If the log has been claimed, stop if we encounter a sequence * number greater than the highest claimed sequence number. */ zil_bp_tree_init(zilog); for (blk = zh->zh_log; !BP_IS_HOLE(&blk); blk = next_blk) { uint64_t blk_seq = blk.blk_cksum.zc_word[ZIL_ZC_SEQ]; int reclen; char *lrp, *end; arc_buf_t *abuf = NULL; if (blk_seq > claim_blk_seq) break; error = parse_blk_func(zilog, &blk, arg, txg); if (error != 0) break; ASSERT3U(max_blk_seq, <, blk_seq); max_blk_seq = blk_seq; blk_count++; if (max_lr_seq == claim_lr_seq && max_blk_seq == claim_blk_seq) break; error = zil_read_log_block(zilog, decrypt, &blk, &next_blk, &lrp, &end, &abuf); if (error != 0) { if (abuf) arc_buf_destroy(abuf, &abuf); if (claimed) { char name[ZFS_MAX_DATASET_NAME_LEN]; dmu_objset_name(zilog->zl_os, name); cmn_err(CE_WARN, "ZFS read log block error %d, " "dataset %s, seq 0x%llx\n", error, name, (u_longlong_t)blk_seq); } break; } for (; lrp < end; lrp += reclen) { lr_t *lr = (lr_t *)lrp; reclen = lr->lrc_reclen; ASSERT3U(reclen, >=, sizeof (lr_t)); if (lr->lrc_seq > claim_lr_seq) { arc_buf_destroy(abuf, &abuf); goto done; } error = parse_lr_func(zilog, lr, arg, txg); if (error != 0) { arc_buf_destroy(abuf, &abuf); goto done; } ASSERT3U(max_lr_seq, <, lr->lrc_seq); max_lr_seq = lr->lrc_seq; lr_count++; } arc_buf_destroy(abuf, &abuf); } done: zilog->zl_parse_error = error; zilog->zl_parse_blk_seq = max_blk_seq; zilog->zl_parse_lr_seq = max_lr_seq; zilog->zl_parse_blk_count = blk_count; zilog->zl_parse_lr_count = lr_count; zil_bp_tree_fini(zilog); return (error); } static int zil_clear_log_block(zilog_t *zilog, const blkptr_t *bp, void *tx, uint64_t first_txg) { (void) tx; ASSERT(!BP_IS_HOLE(bp)); /* * As we call this function from the context of a rewind to a * checkpoint, each ZIL block whose txg is later than the txg * that we rewind to is invalid. Thus, we return -1 so * zil_parse() doesn't attempt to read it. */ if (bp->blk_birth >= first_txg) return (-1); if (zil_bp_tree_add(zilog, bp) != 0) return (0); zio_free(zilog->zl_spa, first_txg, bp); return (0); } static int zil_noop_log_record(zilog_t *zilog, const lr_t *lrc, void *tx, uint64_t first_txg) { (void) zilog, (void) lrc, (void) tx, (void) first_txg; return (0); } static int zil_claim_log_block(zilog_t *zilog, const blkptr_t *bp, void *tx, uint64_t first_txg) { /* * Claim log block if not already committed and not already claimed. * If tx == NULL, just verify that the block is claimable. */ if (BP_IS_HOLE(bp) || bp->blk_birth < first_txg || zil_bp_tree_add(zilog, bp) != 0) return (0); return (zio_wait(zio_claim(NULL, zilog->zl_spa, tx == NULL ? 0 : first_txg, bp, spa_claim_notify, NULL, ZIO_FLAG_CANFAIL | ZIO_FLAG_SPECULATIVE | ZIO_FLAG_SCRUB))); } static int zil_claim_write(zilog_t *zilog, const lr_t *lrc, void *tx, uint64_t first_txg) { lr_write_t *lr = (lr_write_t *)lrc; int error; ASSERT(lrc->lrc_txtype == TX_WRITE); /* * If the block is not readable, don't claim it. This can happen * in normal operation when a log block is written to disk before * some of the dmu_sync() blocks it points to. In this case, the * transaction cannot have been committed to anyone (we would have * waited for all writes to be stable first), so it is semantically * correct to declare this the end of the log. */ if (lr->lr_blkptr.blk_birth >= first_txg) { error = zil_read_log_data(zilog, lr, NULL); if (error != 0) return (error); } return (zil_claim_log_block(zilog, &lr->lr_blkptr, tx, first_txg)); } static int zil_claim_clone_range(zilog_t *zilog, const lr_t *lrc, void *tx) { const lr_clone_range_t *lr = (const lr_clone_range_t *)lrc; const blkptr_t *bp; spa_t *spa; uint_t ii; ASSERT(lrc->lrc_txtype == TX_CLONE_RANGE); if (tx == NULL) { return (0); } /* * XXX: Do we need to byteswap lr? */ spa = zilog->zl_spa; for (ii = 0; ii < lr->lr_nbps; ii++) { bp = &lr->lr_bps[ii]; /* * When data in embedded into BP there is no need to create * BRT entry as there is no data block. Just copy the BP as * it contains the data. */ if (!BP_IS_HOLE(bp) && !BP_IS_EMBEDDED(bp)) { brt_pending_add(spa, bp, tx); } } return (0); } static int zil_claim_log_record(zilog_t *zilog, const lr_t *lrc, void *tx, uint64_t first_txg) { switch (lrc->lrc_txtype) { case TX_WRITE: return (zil_claim_write(zilog, lrc, tx, first_txg)); case TX_CLONE_RANGE: return (zil_claim_clone_range(zilog, lrc, tx)); default: return (0); } } static int zil_free_log_block(zilog_t *zilog, const blkptr_t *bp, void *tx, uint64_t claim_txg) { (void) claim_txg; zio_free(zilog->zl_spa, dmu_tx_get_txg(tx), bp); return (0); } static int zil_free_write(zilog_t *zilog, const lr_t *lrc, void *tx, uint64_t claim_txg) { lr_write_t *lr = (lr_write_t *)lrc; blkptr_t *bp = &lr->lr_blkptr; ASSERT(lrc->lrc_txtype == TX_WRITE); /* * If we previously claimed it, we need to free it. */ if (bp->blk_birth >= claim_txg && zil_bp_tree_add(zilog, bp) == 0 && !BP_IS_HOLE(bp)) { zio_free(zilog->zl_spa, dmu_tx_get_txg(tx), bp); } return (0); } static int zil_free_clone_range(zilog_t *zilog, const lr_t *lrc, void *tx) { const lr_clone_range_t *lr = (const lr_clone_range_t *)lrc; const blkptr_t *bp; spa_t *spa; uint_t ii; ASSERT(lrc->lrc_txtype == TX_CLONE_RANGE); if (tx == NULL) { return (0); } spa = zilog->zl_spa; for (ii = 0; ii < lr->lr_nbps; ii++) { bp = &lr->lr_bps[ii]; if (!BP_IS_HOLE(bp)) { zio_free(spa, dmu_tx_get_txg(tx), bp); } } return (0); } static int zil_free_log_record(zilog_t *zilog, const lr_t *lrc, void *tx, uint64_t claim_txg) { if (claim_txg == 0) { return (0); } switch (lrc->lrc_txtype) { case TX_WRITE: return (zil_free_write(zilog, lrc, tx, claim_txg)); case TX_CLONE_RANGE: return (zil_free_clone_range(zilog, lrc, tx)); default: return (0); } } static int zil_lwb_vdev_compare(const void *x1, const void *x2) { const uint64_t v1 = ((zil_vdev_node_t *)x1)->zv_vdev; const uint64_t v2 = ((zil_vdev_node_t *)x2)->zv_vdev; return (TREE_CMP(v1, v2)); } /* * Allocate a new lwb. We may already have a block pointer for it, in which * case we get size and version from there. Or we may not yet, in which case * we choose them here and later make the block allocation match. */ static lwb_t * zil_alloc_lwb(zilog_t *zilog, int sz, blkptr_t *bp, boolean_t slog, uint64_t txg, lwb_state_t state) { lwb_t *lwb; lwb = kmem_cache_alloc(zil_lwb_cache, KM_SLEEP); lwb->lwb_zilog = zilog; if (bp) { lwb->lwb_blk = *bp; lwb->lwb_slim = (BP_GET_CHECKSUM(bp) == ZIO_CHECKSUM_ZILOG2); sz = BP_GET_LSIZE(bp); } else { BP_ZERO(&lwb->lwb_blk); lwb->lwb_slim = (spa_version(zilog->zl_spa) >= SPA_VERSION_SLIM_ZIL); } lwb->lwb_slog = slog; lwb->lwb_error = 0; if (lwb->lwb_slim) { lwb->lwb_nmax = sz; lwb->lwb_nused = lwb->lwb_nfilled = sizeof (zil_chain_t); } else { lwb->lwb_nmax = sz - sizeof (zil_chain_t); lwb->lwb_nused = lwb->lwb_nfilled = 0; } lwb->lwb_sz = sz; lwb->lwb_state = state; lwb->lwb_buf = zio_buf_alloc(sz); lwb->lwb_child_zio = NULL; lwb->lwb_write_zio = NULL; lwb->lwb_root_zio = NULL; lwb->lwb_issued_timestamp = 0; lwb->lwb_issued_txg = 0; lwb->lwb_alloc_txg = txg; lwb->lwb_max_txg = 0; mutex_enter(&zilog->zl_lock); list_insert_tail(&zilog->zl_lwb_list, lwb); if (state != LWB_STATE_NEW) zilog->zl_last_lwb_opened = lwb; mutex_exit(&zilog->zl_lock); return (lwb); } static void zil_free_lwb(zilog_t *zilog, lwb_t *lwb) { ASSERT(MUTEX_HELD(&zilog->zl_lock)); ASSERT(lwb->lwb_state == LWB_STATE_NEW || lwb->lwb_state == LWB_STATE_FLUSH_DONE); ASSERT3P(lwb->lwb_child_zio, ==, NULL); ASSERT3P(lwb->lwb_write_zio, ==, NULL); ASSERT3P(lwb->lwb_root_zio, ==, NULL); ASSERT3U(lwb->lwb_alloc_txg, <=, spa_syncing_txg(zilog->zl_spa)); ASSERT3U(lwb->lwb_max_txg, <=, spa_syncing_txg(zilog->zl_spa)); VERIFY(list_is_empty(&lwb->lwb_itxs)); VERIFY(list_is_empty(&lwb->lwb_waiters)); ASSERT(avl_is_empty(&lwb->lwb_vdev_tree)); ASSERT(!MUTEX_HELD(&lwb->lwb_vdev_lock)); /* * Clear the zilog's field to indicate this lwb is no longer * valid, and prevent use-after-free errors. */ if (zilog->zl_last_lwb_opened == lwb) zilog->zl_last_lwb_opened = NULL; kmem_cache_free(zil_lwb_cache, lwb); } /* * Called when we create in-memory log transactions so that we know * to cleanup the itxs at the end of spa_sync(). */ static void zilog_dirty(zilog_t *zilog, uint64_t txg) { dsl_pool_t *dp = zilog->zl_dmu_pool; dsl_dataset_t *ds = dmu_objset_ds(zilog->zl_os); ASSERT(spa_writeable(zilog->zl_spa)); if (ds->ds_is_snapshot) panic("dirtying snapshot!"); if (txg_list_add(&dp->dp_dirty_zilogs, zilog, txg)) { /* up the hold count until we can be written out */ dmu_buf_add_ref(ds->ds_dbuf, zilog); zilog->zl_dirty_max_txg = MAX(txg, zilog->zl_dirty_max_txg); } } /* * Determine if the zil is dirty in the specified txg. Callers wanting to * ensure that the dirty state does not change must hold the itxg_lock for * the specified txg. Holding the lock will ensure that the zil cannot be * dirtied (zil_itx_assign) or cleaned (zil_clean) while we check its current * state. */ static boolean_t __maybe_unused zilog_is_dirty_in_txg(zilog_t *zilog, uint64_t txg) { dsl_pool_t *dp = zilog->zl_dmu_pool; if (txg_list_member(&dp->dp_dirty_zilogs, zilog, txg & TXG_MASK)) return (B_TRUE); return (B_FALSE); } /* * Determine if the zil is dirty. The zil is considered dirty if it has * any pending itx records that have not been cleaned by zil_clean(). */ static boolean_t zilog_is_dirty(zilog_t *zilog) { dsl_pool_t *dp = zilog->zl_dmu_pool; for (int t = 0; t < TXG_SIZE; t++) { if (txg_list_member(&dp->dp_dirty_zilogs, zilog, t)) return (B_TRUE); } return (B_FALSE); } /* * Its called in zil_commit context (zil_process_commit_list()/zil_create()). * It activates SPA_FEATURE_ZILSAXATTR feature, if its enabled. * Check dsl_dataset_feature_is_active to avoid txg_wait_synced() on every * zil_commit. */ static void zil_commit_activate_saxattr_feature(zilog_t *zilog) { dsl_dataset_t *ds = dmu_objset_ds(zilog->zl_os); uint64_t txg = 0; dmu_tx_t *tx = NULL; if (spa_feature_is_enabled(zilog->zl_spa, SPA_FEATURE_ZILSAXATTR) && dmu_objset_type(zilog->zl_os) != DMU_OST_ZVOL && !dsl_dataset_feature_is_active(ds, SPA_FEATURE_ZILSAXATTR)) { tx = dmu_tx_create(zilog->zl_os); VERIFY0(dmu_tx_assign(tx, TXG_WAIT)); dsl_dataset_dirty(ds, tx); txg = dmu_tx_get_txg(tx); mutex_enter(&ds->ds_lock); ds->ds_feature_activation[SPA_FEATURE_ZILSAXATTR] = (void *)B_TRUE; mutex_exit(&ds->ds_lock); dmu_tx_commit(tx); txg_wait_synced(zilog->zl_dmu_pool, txg); } } /* * Create an on-disk intent log. */ static lwb_t * zil_create(zilog_t *zilog) { const zil_header_t *zh = zilog->zl_header; lwb_t *lwb = NULL; uint64_t txg = 0; dmu_tx_t *tx = NULL; blkptr_t blk; int error = 0; boolean_t slog = FALSE; dsl_dataset_t *ds = dmu_objset_ds(zilog->zl_os); /* * Wait for any previous destroy to complete. */ txg_wait_synced(zilog->zl_dmu_pool, zilog->zl_destroy_txg); ASSERT(zh->zh_claim_txg == 0); ASSERT(zh->zh_replay_seq == 0); blk = zh->zh_log; /* * Allocate an initial log block if: * - there isn't one already * - the existing block is the wrong endianness */ if (BP_IS_HOLE(&blk) || BP_SHOULD_BYTESWAP(&blk)) { tx = dmu_tx_create(zilog->zl_os); VERIFY0(dmu_tx_assign(tx, TXG_WAIT)); dsl_dataset_dirty(dmu_objset_ds(zilog->zl_os), tx); txg = dmu_tx_get_txg(tx); if (!BP_IS_HOLE(&blk)) { zio_free(zilog->zl_spa, txg, &blk); BP_ZERO(&blk); } error = zio_alloc_zil(zilog->zl_spa, zilog->zl_os, txg, &blk, ZIL_MIN_BLKSZ, &slog); if (error == 0) zil_init_log_chain(zilog, &blk); } /* * Allocate a log write block (lwb) for the first log block. */ if (error == 0) lwb = zil_alloc_lwb(zilog, 0, &blk, slog, txg, LWB_STATE_NEW); /* * If we just allocated the first log block, commit our transaction * and wait for zil_sync() to stuff the block pointer into zh_log. * (zh is part of the MOS, so we cannot modify it in open context.) */ if (tx != NULL) { /* * If "zilsaxattr" feature is enabled on zpool, then activate * it now when we're creating the ZIL chain. We can't wait with * this until we write the first xattr log record because we * need to wait for the feature activation to sync out. */ if (spa_feature_is_enabled(zilog->zl_spa, SPA_FEATURE_ZILSAXATTR) && dmu_objset_type(zilog->zl_os) != DMU_OST_ZVOL) { mutex_enter(&ds->ds_lock); ds->ds_feature_activation[SPA_FEATURE_ZILSAXATTR] = (void *)B_TRUE; mutex_exit(&ds->ds_lock); } dmu_tx_commit(tx); txg_wait_synced(zilog->zl_dmu_pool, txg); } else { /* * This branch covers the case where we enable the feature on a * zpool that has existing ZIL headers. */ zil_commit_activate_saxattr_feature(zilog); } IMPLY(spa_feature_is_enabled(zilog->zl_spa, SPA_FEATURE_ZILSAXATTR) && dmu_objset_type(zilog->zl_os) != DMU_OST_ZVOL, dsl_dataset_feature_is_active(ds, SPA_FEATURE_ZILSAXATTR)); ASSERT(error != 0 || memcmp(&blk, &zh->zh_log, sizeof (blk)) == 0); IMPLY(error == 0, lwb != NULL); return (lwb); } /* * In one tx, free all log blocks and clear the log header. If keep_first * is set, then we're replaying a log with no content. We want to keep the * first block, however, so that the first synchronous transaction doesn't * require a txg_wait_synced() in zil_create(). We don't need to * txg_wait_synced() here either when keep_first is set, because both * zil_create() and zil_destroy() will wait for any in-progress destroys * to complete. * Return B_TRUE if there were any entries to replay. */ boolean_t zil_destroy(zilog_t *zilog, boolean_t keep_first) { const zil_header_t *zh = zilog->zl_header; lwb_t *lwb; dmu_tx_t *tx; uint64_t txg; /* * Wait for any previous destroy to complete. */ txg_wait_synced(zilog->zl_dmu_pool, zilog->zl_destroy_txg); zilog->zl_old_header = *zh; /* debugging aid */ if (BP_IS_HOLE(&zh->zh_log)) return (B_FALSE); tx = dmu_tx_create(zilog->zl_os); VERIFY0(dmu_tx_assign(tx, TXG_WAIT)); dsl_dataset_dirty(dmu_objset_ds(zilog->zl_os), tx); txg = dmu_tx_get_txg(tx); mutex_enter(&zilog->zl_lock); ASSERT3U(zilog->zl_destroy_txg, <, txg); zilog->zl_destroy_txg = txg; zilog->zl_keep_first = keep_first; if (!list_is_empty(&zilog->zl_lwb_list)) { ASSERT(zh->zh_claim_txg == 0); VERIFY(!keep_first); while ((lwb = list_remove_head(&zilog->zl_lwb_list)) != NULL) { if (lwb->lwb_buf != NULL) zio_buf_free(lwb->lwb_buf, lwb->lwb_sz); if (!BP_IS_HOLE(&lwb->lwb_blk)) zio_free(zilog->zl_spa, txg, &lwb->lwb_blk); zil_free_lwb(zilog, lwb); } } else if (!keep_first) { zil_destroy_sync(zilog, tx); } mutex_exit(&zilog->zl_lock); dmu_tx_commit(tx); return (B_TRUE); } void zil_destroy_sync(zilog_t *zilog, dmu_tx_t *tx) { ASSERT(list_is_empty(&zilog->zl_lwb_list)); (void) zil_parse(zilog, zil_free_log_block, zil_free_log_record, tx, zilog->zl_header->zh_claim_txg, B_FALSE); } int zil_claim(dsl_pool_t *dp, dsl_dataset_t *ds, void *txarg) { dmu_tx_t *tx = txarg; zilog_t *zilog; uint64_t first_txg; zil_header_t *zh; objset_t *os; int error; error = dmu_objset_own_obj(dp, ds->ds_object, DMU_OST_ANY, B_FALSE, B_FALSE, FTAG, &os); if (error != 0) { /* * EBUSY indicates that the objset is inconsistent, in which * case it can not have a ZIL. */ if (error != EBUSY) { cmn_err(CE_WARN, "can't open objset for %llu, error %u", (unsigned long long)ds->ds_object, error); } return (0); } zilog = dmu_objset_zil(os); zh = zil_header_in_syncing_context(zilog); ASSERT3U(tx->tx_txg, ==, spa_first_txg(zilog->zl_spa)); first_txg = spa_min_claim_txg(zilog->zl_spa); /* * If the spa_log_state is not set to be cleared, check whether * the current uberblock is a checkpoint one and if the current * header has been claimed before moving on. * * If the current uberblock is a checkpointed uberblock then * one of the following scenarios took place: * * 1] We are currently rewinding to the checkpoint of the pool. * 2] We crashed in the middle of a checkpoint rewind but we * did manage to write the checkpointed uberblock to the * vdev labels, so when we tried to import the pool again * the checkpointed uberblock was selected from the import * procedure. * * In both cases we want to zero out all the ZIL blocks, except * the ones that have been claimed at the time of the checkpoint * (their zh_claim_txg != 0). The reason is that these blocks * may be corrupted since we may have reused their locations on * disk after we took the checkpoint. * * We could try to set spa_log_state to SPA_LOG_CLEAR earlier * when we first figure out whether the current uberblock is * checkpointed or not. Unfortunately, that would discard all * the logs, including the ones that are claimed, and we would * leak space. */ if (spa_get_log_state(zilog->zl_spa) == SPA_LOG_CLEAR || (zilog->zl_spa->spa_uberblock.ub_checkpoint_txg != 0 && zh->zh_claim_txg == 0)) { if (!BP_IS_HOLE(&zh->zh_log)) { (void) zil_parse(zilog, zil_clear_log_block, zil_noop_log_record, tx, first_txg, B_FALSE); } BP_ZERO(&zh->zh_log); if (os->os_encrypted) os->os_next_write_raw[tx->tx_txg & TXG_MASK] = B_TRUE; dsl_dataset_dirty(dmu_objset_ds(os), tx); dmu_objset_disown(os, B_FALSE, FTAG); return (0); } /* * If we are not rewinding and opening the pool normally, then * the min_claim_txg should be equal to the first txg of the pool. */ ASSERT3U(first_txg, ==, spa_first_txg(zilog->zl_spa)); /* * Claim all log blocks if we haven't already done so, and remember * the highest claimed sequence number. This ensures that if we can * read only part of the log now (e.g. due to a missing device), * but we can read the entire log later, we will not try to replay * or destroy beyond the last block we successfully claimed. */ ASSERT3U(zh->zh_claim_txg, <=, first_txg); if (zh->zh_claim_txg == 0 && !BP_IS_HOLE(&zh->zh_log)) { (void) zil_parse(zilog, zil_claim_log_block, zil_claim_log_record, tx, first_txg, B_FALSE); zh->zh_claim_txg = first_txg; zh->zh_claim_blk_seq = zilog->zl_parse_blk_seq; zh->zh_claim_lr_seq = zilog->zl_parse_lr_seq; if (zilog->zl_parse_lr_count || zilog->zl_parse_blk_count > 1) zh->zh_flags |= ZIL_REPLAY_NEEDED; zh->zh_flags |= ZIL_CLAIM_LR_SEQ_VALID; if (os->os_encrypted) os->os_next_write_raw[tx->tx_txg & TXG_MASK] = B_TRUE; dsl_dataset_dirty(dmu_objset_ds(os), tx); } ASSERT3U(first_txg, ==, (spa_last_synced_txg(zilog->zl_spa) + 1)); dmu_objset_disown(os, B_FALSE, FTAG); return (0); } /* * Check the log by walking the log chain. * Checksum errors are ok as they indicate the end of the chain. * Any other error (no device or read failure) returns an error. */ int zil_check_log_chain(dsl_pool_t *dp, dsl_dataset_t *ds, void *tx) { (void) dp; zilog_t *zilog; objset_t *os; blkptr_t *bp; int error; ASSERT(tx == NULL); error = dmu_objset_from_ds(ds, &os); if (error != 0) { cmn_err(CE_WARN, "can't open objset %llu, error %d", (unsigned long long)ds->ds_object, error); return (0); } zilog = dmu_objset_zil(os); bp = (blkptr_t *)&zilog->zl_header->zh_log; if (!BP_IS_HOLE(bp)) { vdev_t *vd; boolean_t valid = B_TRUE; /* * Check the first block and determine if it's on a log device * which may have been removed or faulted prior to loading this * pool. If so, there's no point in checking the rest of the * log as its content should have already been synced to the * pool. */ spa_config_enter(os->os_spa, SCL_STATE, FTAG, RW_READER); vd = vdev_lookup_top(os->os_spa, DVA_GET_VDEV(&bp->blk_dva[0])); if (vd->vdev_islog && vdev_is_dead(vd)) valid = vdev_log_state_valid(vd); spa_config_exit(os->os_spa, SCL_STATE, FTAG); if (!valid) return (0); /* * Check whether the current uberblock is checkpointed (e.g. * we are rewinding) and whether the current header has been * claimed or not. If it hasn't then skip verifying it. We * do this because its ZIL blocks may be part of the pool's * state before the rewind, which is no longer valid. */ zil_header_t *zh = zil_header_in_syncing_context(zilog); if (zilog->zl_spa->spa_uberblock.ub_checkpoint_txg != 0 && zh->zh_claim_txg == 0) return (0); } /* * Because tx == NULL, zil_claim_log_block() will not actually claim * any blocks, but just determine whether it is possible to do so. * In addition to checking the log chain, zil_claim_log_block() * will invoke zio_claim() with a done func of spa_claim_notify(), * which will update spa_max_claim_txg. See spa_load() for details. */ error = zil_parse(zilog, zil_claim_log_block, zil_claim_log_record, tx, zilog->zl_header->zh_claim_txg ? -1ULL : spa_min_claim_txg(os->os_spa), B_FALSE); return ((error == ECKSUM || error == ENOENT) ? 0 : error); } /* * When an itx is "skipped", this function is used to properly mark the * waiter as "done, and signal any thread(s) waiting on it. An itx can * be skipped (and not committed to an lwb) for a variety of reasons, * one of them being that the itx was committed via spa_sync(), prior to * it being committed to an lwb; this can happen if a thread calling * zil_commit() is racing with spa_sync(). */ static void zil_commit_waiter_skip(zil_commit_waiter_t *zcw) { mutex_enter(&zcw->zcw_lock); ASSERT3B(zcw->zcw_done, ==, B_FALSE); zcw->zcw_done = B_TRUE; cv_broadcast(&zcw->zcw_cv); mutex_exit(&zcw->zcw_lock); } /* * This function is used when the given waiter is to be linked into an * lwb's "lwb_waiter" list; i.e. when the itx is committed to the lwb. * At this point, the waiter will no longer be referenced by the itx, * and instead, will be referenced by the lwb. */ static void zil_commit_waiter_link_lwb(zil_commit_waiter_t *zcw, lwb_t *lwb) { /* * The lwb_waiters field of the lwb is protected by the zilog's * zl_issuer_lock while the lwb is open and zl_lock otherwise. * zl_issuer_lock also protects leaving the open state. * zcw_lwb setting is protected by zl_issuer_lock and state != * flush_done, which transition is protected by zl_lock. */ ASSERT(MUTEX_HELD(&lwb->lwb_zilog->zl_issuer_lock)); IMPLY(lwb->lwb_state != LWB_STATE_OPENED, MUTEX_HELD(&lwb->lwb_zilog->zl_lock)); ASSERT3S(lwb->lwb_state, !=, LWB_STATE_NEW); ASSERT3S(lwb->lwb_state, !=, LWB_STATE_FLUSH_DONE); ASSERT(!list_link_active(&zcw->zcw_node)); list_insert_tail(&lwb->lwb_waiters, zcw); ASSERT3P(zcw->zcw_lwb, ==, NULL); zcw->zcw_lwb = lwb; } /* * This function is used when zio_alloc_zil() fails to allocate a ZIL * block, and the given waiter must be linked to the "nolwb waiters" * list inside of zil_process_commit_list(). */ static void zil_commit_waiter_link_nolwb(zil_commit_waiter_t *zcw, list_t *nolwb) { ASSERT(!list_link_active(&zcw->zcw_node)); list_insert_tail(nolwb, zcw); ASSERT3P(zcw->zcw_lwb, ==, NULL); } void zil_lwb_add_block(lwb_t *lwb, const blkptr_t *bp) { avl_tree_t *t = &lwb->lwb_vdev_tree; avl_index_t where; zil_vdev_node_t *zv, zvsearch; int ndvas = BP_GET_NDVAS(bp); int i; ASSERT3S(lwb->lwb_state, !=, LWB_STATE_WRITE_DONE); ASSERT3S(lwb->lwb_state, !=, LWB_STATE_FLUSH_DONE); if (zil_nocacheflush) return; mutex_enter(&lwb->lwb_vdev_lock); for (i = 0; i < ndvas; i++) { zvsearch.zv_vdev = DVA_GET_VDEV(&bp->blk_dva[i]); if (avl_find(t, &zvsearch, &where) == NULL) { zv = kmem_alloc(sizeof (*zv), KM_SLEEP); zv->zv_vdev = zvsearch.zv_vdev; avl_insert(t, zv, where); } } mutex_exit(&lwb->lwb_vdev_lock); } static void zil_lwb_flush_defer(lwb_t *lwb, lwb_t *nlwb) { avl_tree_t *src = &lwb->lwb_vdev_tree; avl_tree_t *dst = &nlwb->lwb_vdev_tree; void *cookie = NULL; zil_vdev_node_t *zv; ASSERT3S(lwb->lwb_state, ==, LWB_STATE_WRITE_DONE); ASSERT3S(nlwb->lwb_state, !=, LWB_STATE_WRITE_DONE); ASSERT3S(nlwb->lwb_state, !=, LWB_STATE_FLUSH_DONE); /* * While 'lwb' is at a point in its lifetime where lwb_vdev_tree does * not need the protection of lwb_vdev_lock (it will only be modified * while holding zilog->zl_lock) as its writes and those of its * children have all completed. The younger 'nlwb' may be waiting on * future writes to additional vdevs. */ mutex_enter(&nlwb->lwb_vdev_lock); /* * Tear down the 'lwb' vdev tree, ensuring that entries which do not * exist in 'nlwb' are moved to it, freeing any would-be duplicates. */ while ((zv = avl_destroy_nodes(src, &cookie)) != NULL) { avl_index_t where; if (avl_find(dst, zv, &where) == NULL) { avl_insert(dst, zv, where); } else { kmem_free(zv, sizeof (*zv)); } } mutex_exit(&nlwb->lwb_vdev_lock); } void zil_lwb_add_txg(lwb_t *lwb, uint64_t txg) { lwb->lwb_max_txg = MAX(lwb->lwb_max_txg, txg); } /* * This function is a called after all vdevs associated with a given lwb * write have completed their DKIOCFLUSHWRITECACHE command; or as soon * as the lwb write completes, if "zil_nocacheflush" is set. Further, * all "previous" lwb's will have completed before this function is * called; i.e. this function is called for all previous lwbs before * it's called for "this" lwb (enforced via zio the dependencies * configured in zil_lwb_set_zio_dependency()). * * The intention is for this function to be called as soon as the * contents of an lwb are considered "stable" on disk, and will survive * any sudden loss of power. At this point, any threads waiting for the * lwb to reach this state are signalled, and the "waiter" structures * are marked "done". */ static void zil_lwb_flush_vdevs_done(zio_t *zio) { lwb_t *lwb = zio->io_private; zilog_t *zilog = lwb->lwb_zilog; zil_commit_waiter_t *zcw; itx_t *itx; spa_config_exit(zilog->zl_spa, SCL_STATE, lwb); hrtime_t t = gethrtime() - lwb->lwb_issued_timestamp; mutex_enter(&zilog->zl_lock); zilog->zl_last_lwb_latency = (zilog->zl_last_lwb_latency * 7 + t) / 8; lwb->lwb_root_zio = NULL; ASSERT3S(lwb->lwb_state, ==, LWB_STATE_WRITE_DONE); lwb->lwb_state = LWB_STATE_FLUSH_DONE; if (zilog->zl_last_lwb_opened == lwb) { /* * Remember the highest committed log sequence number * for ztest. We only update this value when all the log * writes succeeded, because ztest wants to ASSERT that * it got the whole log chain. */ zilog->zl_commit_lr_seq = zilog->zl_lr_seq; } while ((itx = list_remove_head(&lwb->lwb_itxs)) != NULL) zil_itx_destroy(itx); while ((zcw = list_remove_head(&lwb->lwb_waiters)) != NULL) { mutex_enter(&zcw->zcw_lock); ASSERT3P(zcw->zcw_lwb, ==, lwb); zcw->zcw_lwb = NULL; /* * We expect any ZIO errors from child ZIOs to have been * propagated "up" to this specific LWB's root ZIO, in * order for this error handling to work correctly. This * includes ZIO errors from either this LWB's write or * flush, as well as any errors from other dependent LWBs * (e.g. a root LWB ZIO that might be a child of this LWB). * * With that said, it's important to note that LWB flush * errors are not propagated up to the LWB root ZIO. * This is incorrect behavior, and results in VDEV flush * errors not being handled correctly here. See the * comment above the call to "zio_flush" for details. */ zcw->zcw_zio_error = zio->io_error; ASSERT3B(zcw->zcw_done, ==, B_FALSE); zcw->zcw_done = B_TRUE; cv_broadcast(&zcw->zcw_cv); mutex_exit(&zcw->zcw_lock); } uint64_t txg = lwb->lwb_issued_txg; /* Once we drop the lock, lwb may be freed by zil_sync(). */ mutex_exit(&zilog->zl_lock); mutex_enter(&zilog->zl_lwb_io_lock); ASSERT3U(zilog->zl_lwb_inflight[txg & TXG_MASK], >, 0); zilog->zl_lwb_inflight[txg & TXG_MASK]--; if (zilog->zl_lwb_inflight[txg & TXG_MASK] == 0) cv_broadcast(&zilog->zl_lwb_io_cv); mutex_exit(&zilog->zl_lwb_io_lock); } /* * Wait for the completion of all issued write/flush of that txg provided. * It guarantees zil_lwb_flush_vdevs_done() is called and returned. */ static void zil_lwb_flush_wait_all(zilog_t *zilog, uint64_t txg) { ASSERT3U(txg, ==, spa_syncing_txg(zilog->zl_spa)); mutex_enter(&zilog->zl_lwb_io_lock); while (zilog->zl_lwb_inflight[txg & TXG_MASK] > 0) cv_wait(&zilog->zl_lwb_io_cv, &zilog->zl_lwb_io_lock); mutex_exit(&zilog->zl_lwb_io_lock); #ifdef ZFS_DEBUG mutex_enter(&zilog->zl_lock); mutex_enter(&zilog->zl_lwb_io_lock); lwb_t *lwb = list_head(&zilog->zl_lwb_list); while (lwb != NULL) { if (lwb->lwb_issued_txg <= txg) { ASSERT(lwb->lwb_state != LWB_STATE_ISSUED); ASSERT(lwb->lwb_state != LWB_STATE_WRITE_DONE); IMPLY(lwb->lwb_issued_txg > 0, lwb->lwb_state == LWB_STATE_FLUSH_DONE); } IMPLY(lwb->lwb_state == LWB_STATE_WRITE_DONE || lwb->lwb_state == LWB_STATE_FLUSH_DONE, lwb->lwb_buf == NULL); lwb = list_next(&zilog->zl_lwb_list, lwb); } mutex_exit(&zilog->zl_lwb_io_lock); mutex_exit(&zilog->zl_lock); #endif } /* * This is called when an lwb's write zio completes. The callback's * purpose is to issue the DKIOCFLUSHWRITECACHE commands for the vdevs * in the lwb's lwb_vdev_tree. The tree will contain the vdevs involved * in writing out this specific lwb's data, and in the case that cache * flushes have been deferred, vdevs involved in writing the data for * previous lwbs. The writes corresponding to all the vdevs in the * lwb_vdev_tree will have completed by the time this is called, due to * the zio dependencies configured in zil_lwb_set_zio_dependency(), * which takes deferred flushes into account. The lwb will be "done" * once zil_lwb_flush_vdevs_done() is called, which occurs in the zio * completion callback for the lwb's root zio. */ static void zil_lwb_write_done(zio_t *zio) { lwb_t *lwb = zio->io_private; spa_t *spa = zio->io_spa; zilog_t *zilog = lwb->lwb_zilog; avl_tree_t *t = &lwb->lwb_vdev_tree; void *cookie = NULL; zil_vdev_node_t *zv; lwb_t *nlwb; ASSERT3S(spa_config_held(spa, SCL_STATE, RW_READER), !=, 0); abd_free(zio->io_abd); zio_buf_free(lwb->lwb_buf, lwb->lwb_sz); lwb->lwb_buf = NULL; mutex_enter(&zilog->zl_lock); ASSERT3S(lwb->lwb_state, ==, LWB_STATE_ISSUED); lwb->lwb_state = LWB_STATE_WRITE_DONE; lwb->lwb_child_zio = NULL; lwb->lwb_write_zio = NULL; /* * If nlwb is not yet issued, zil_lwb_set_zio_dependency() is not * called for it yet, and when it will be, it won't be able to make * its write ZIO a parent this ZIO. In such case we can not defer * our flushes or below may be a race between the done callbacks. */ nlwb = list_next(&zilog->zl_lwb_list, lwb); if (nlwb && nlwb->lwb_state != LWB_STATE_ISSUED) nlwb = NULL; mutex_exit(&zilog->zl_lock); if (avl_numnodes(t) == 0) return; /* * If there was an IO error, we're not going to call zio_flush() * on these vdevs, so we simply empty the tree and free the * nodes. We avoid calling zio_flush() since there isn't any * good reason for doing so, after the lwb block failed to be * written out. * * Additionally, we don't perform any further error handling at * this point (e.g. setting "zcw_zio_error" appropriately), as * we expect that to occur in "zil_lwb_flush_vdevs_done" (thus, * we expect any error seen here, to have been propagated to * that function). */ if (zio->io_error != 0) { while ((zv = avl_destroy_nodes(t, &cookie)) != NULL) kmem_free(zv, sizeof (*zv)); return; } /* * If this lwb does not have any threads waiting for it to * complete, we want to defer issuing the DKIOCFLUSHWRITECACHE * command to the vdevs written to by "this" lwb, and instead * rely on the "next" lwb to handle the DKIOCFLUSHWRITECACHE * command for those vdevs. Thus, we merge the vdev tree of * "this" lwb with the vdev tree of the "next" lwb in the list, * and assume the "next" lwb will handle flushing the vdevs (or * deferring the flush(s) again). * * This is a useful performance optimization, especially for * workloads with lots of async write activity and few sync * write and/or fsync activity, as it has the potential to * coalesce multiple flush commands to a vdev into one. */ if (list_is_empty(&lwb->lwb_waiters) && nlwb != NULL) { zil_lwb_flush_defer(lwb, nlwb); ASSERT(avl_is_empty(&lwb->lwb_vdev_tree)); return; } while ((zv = avl_destroy_nodes(t, &cookie)) != NULL) { vdev_t *vd = vdev_lookup_top(spa, zv->zv_vdev); if (vd != NULL && !vd->vdev_nowritecache) { /* * The "ZIO_FLAG_DONT_PROPAGATE" is currently * always used within "zio_flush". This means, * any errors when flushing the vdev(s), will * (unfortunately) not be handled correctly, * since these "zio_flush" errors will not be * propagated up to "zil_lwb_flush_vdevs_done". */ zio_flush(lwb->lwb_root_zio, vd); } kmem_free(zv, sizeof (*zv)); } } /* * Build the zio dependency chain, which is used to preserve the ordering of * lwb completions that is required by the semantics of the ZIL. Each new lwb * zio becomes a parent of the previous lwb zio, such that the new lwb's zio * cannot complete until the previous lwb's zio completes. * * This is required by the semantics of zil_commit(): the commit waiters * attached to the lwbs will be woken in the lwb zio's completion callback, * so this zio dependency graph ensures the waiters are woken in the correct * order (the same order the lwbs were created). */ static void zil_lwb_set_zio_dependency(zilog_t *zilog, lwb_t *lwb) { ASSERT(MUTEX_HELD(&zilog->zl_lock)); lwb_t *prev_lwb = list_prev(&zilog->zl_lwb_list, lwb); if (prev_lwb == NULL || prev_lwb->lwb_state == LWB_STATE_FLUSH_DONE) return; /* * If the previous lwb's write hasn't already completed, we also want * to order the completion of the lwb write zios (above, we only order * the completion of the lwb root zios). This is required because of * how we can defer the DKIOCFLUSHWRITECACHE commands for each lwb. * * When the DKIOCFLUSHWRITECACHE commands are deferred, the previous * lwb will rely on this lwb to flush the vdevs written to by that * previous lwb. Thus, we need to ensure this lwb doesn't issue the * flush until after the previous lwb's write completes. We ensure * this ordering by setting the zio parent/child relationship here. * * Without this relationship on the lwb's write zio, it's possible * for this lwb's write to complete prior to the previous lwb's write * completing; and thus, the vdevs for the previous lwb would be * flushed prior to that lwb's data being written to those vdevs (the * vdevs are flushed in the lwb write zio's completion handler, * zil_lwb_write_done()). */ if (prev_lwb->lwb_state == LWB_STATE_ISSUED) { ASSERT3P(prev_lwb->lwb_write_zio, !=, NULL); zio_add_child(lwb->lwb_write_zio, prev_lwb->lwb_write_zio); } else { ASSERT3S(prev_lwb->lwb_state, ==, LWB_STATE_WRITE_DONE); } ASSERT3P(prev_lwb->lwb_root_zio, !=, NULL); zio_add_child(lwb->lwb_root_zio, prev_lwb->lwb_root_zio); } /* * This function's purpose is to "open" an lwb such that it is ready to * accept new itxs being committed to it. This function is idempotent; if * the passed in lwb has already been opened, it is essentially a no-op. */ static void zil_lwb_write_open(zilog_t *zilog, lwb_t *lwb) { ASSERT(MUTEX_HELD(&zilog->zl_issuer_lock)); if (lwb->lwb_state != LWB_STATE_NEW) { ASSERT3S(lwb->lwb_state, ==, LWB_STATE_OPENED); return; } mutex_enter(&zilog->zl_lock); lwb->lwb_state = LWB_STATE_OPENED; zilog->zl_last_lwb_opened = lwb; mutex_exit(&zilog->zl_lock); } /* * Define a limited set of intent log block sizes. * * These must be a multiple of 4KB. Note only the amount used (again * aligned to 4KB) actually gets written. However, we can't always just * allocate SPA_OLD_MAXBLOCKSIZE as the slog space could be exhausted. */ static const struct { uint64_t limit; uint64_t blksz; } zil_block_buckets[] = { { 4096, 4096 }, /* non TX_WRITE */ { 8192 + 4096, 8192 + 4096 }, /* database */ { 32768 + 4096, 32768 + 4096 }, /* NFS writes */ { 65536 + 4096, 65536 + 4096 }, /* 64KB writes */ { 131072, 131072 }, /* < 128KB writes */ { 131072 +4096, 65536 + 4096 }, /* 128KB writes */ { UINT64_MAX, SPA_OLD_MAXBLOCKSIZE}, /* > 128KB writes */ }; /* * Maximum block size used by the ZIL. This is picked up when the ZIL is * initialized. Otherwise this should not be used directly; see * zl_max_block_size instead. */ static uint_t zil_maxblocksize = SPA_OLD_MAXBLOCKSIZE; /* * Close the log block for being issued and allocate the next one. * Has to be called under zl_issuer_lock to chain more lwbs. */ static lwb_t * zil_lwb_write_close(zilog_t *zilog, lwb_t *lwb, lwb_state_t state) { int i; ASSERT(MUTEX_HELD(&zilog->zl_issuer_lock)); ASSERT3S(lwb->lwb_state, ==, LWB_STATE_OPENED); lwb->lwb_state = LWB_STATE_CLOSED; /* * If there was an allocation failure then returned NULL will trigger * zil_commit_writer_stall() at the caller. This is inherently racy, * since allocation may not have happened yet. */ if (lwb->lwb_error != 0) return (NULL); /* * Log blocks are pre-allocated. Here we select the size of the next * block, based on size used in the last block. * - first find the smallest bucket that will fit the block from a * limited set of block sizes. This is because it's faster to write * blocks allocated from the same metaslab as they are adjacent or * close. * - next find the maximum from the new suggested size and an array of * previous sizes. This lessens a picket fence effect of wrongly * guessing the size if we have a stream of say 2k, 64k, 2k, 64k * requests. * * Note we only write what is used, but we can't just allocate * the maximum block size because we can exhaust the available * pool log space. */ uint64_t zil_blksz = zilog->zl_cur_used + sizeof (zil_chain_t); for (i = 0; zil_blksz > zil_block_buckets[i].limit; i++) continue; zil_blksz = MIN(zil_block_buckets[i].blksz, zilog->zl_max_block_size); zilog->zl_prev_blks[zilog->zl_prev_rotor] = zil_blksz; for (i = 0; i < ZIL_PREV_BLKS; i++) zil_blksz = MAX(zil_blksz, zilog->zl_prev_blks[i]); DTRACE_PROBE3(zil__block__size, zilog_t *, zilog, uint64_t, zil_blksz, uint64_t, zilog->zl_prev_blks[zilog->zl_prev_rotor]); zilog->zl_prev_rotor = (zilog->zl_prev_rotor + 1) & (ZIL_PREV_BLKS - 1); return (zil_alloc_lwb(zilog, zil_blksz, NULL, 0, 0, state)); } /* * Finalize previously closed block and issue the write zio. */ static void zil_lwb_write_issue(zilog_t *zilog, lwb_t *lwb) { spa_t *spa = zilog->zl_spa; zil_chain_t *zilc; boolean_t slog; zbookmark_phys_t zb; zio_priority_t prio; int error; ASSERT3S(lwb->lwb_state, ==, LWB_STATE_CLOSED); /* Actually fill the lwb with the data. */ for (itx_t *itx = list_head(&lwb->lwb_itxs); itx; itx = list_next(&lwb->lwb_itxs, itx)) zil_lwb_commit(zilog, lwb, itx); lwb->lwb_nused = lwb->lwb_nfilled; lwb->lwb_root_zio = zio_root(spa, zil_lwb_flush_vdevs_done, lwb, ZIO_FLAG_CANFAIL); /* * The lwb is now ready to be issued, but it can be only if it already * got its block pointer allocated or the allocation has failed. * Otherwise leave it as-is, relying on some other thread to issue it * after allocating its block pointer via calling zil_lwb_write_issue() * for the previous lwb(s) in the chain. */ mutex_enter(&zilog->zl_lock); lwb->lwb_state = LWB_STATE_READY; if (BP_IS_HOLE(&lwb->lwb_blk) && lwb->lwb_error == 0) { mutex_exit(&zilog->zl_lock); return; } mutex_exit(&zilog->zl_lock); next_lwb: if (lwb->lwb_slim) zilc = (zil_chain_t *)lwb->lwb_buf; else zilc = (zil_chain_t *)(lwb->lwb_buf + lwb->lwb_nmax); int wsz = lwb->lwb_sz; if (lwb->lwb_error == 0) { abd_t *lwb_abd = abd_get_from_buf(lwb->lwb_buf, lwb->lwb_sz); if (!lwb->lwb_slog || zilog->zl_cur_used <= zil_slog_bulk) prio = ZIO_PRIORITY_SYNC_WRITE; else prio = ZIO_PRIORITY_ASYNC_WRITE; SET_BOOKMARK(&zb, lwb->lwb_blk.blk_cksum.zc_word[ZIL_ZC_OBJSET], ZB_ZIL_OBJECT, ZB_ZIL_LEVEL, lwb->lwb_blk.blk_cksum.zc_word[ZIL_ZC_SEQ]); lwb->lwb_write_zio = zio_rewrite(lwb->lwb_root_zio, spa, 0, &lwb->lwb_blk, lwb_abd, lwb->lwb_sz, zil_lwb_write_done, lwb, prio, ZIO_FLAG_CANFAIL, &zb); zil_lwb_add_block(lwb, &lwb->lwb_blk); if (lwb->lwb_slim) { /* For Slim ZIL only write what is used. */ wsz = P2ROUNDUP_TYPED(lwb->lwb_nused, ZIL_MIN_BLKSZ, int); ASSERT3S(wsz, <=, lwb->lwb_sz); zio_shrink(lwb->lwb_write_zio, wsz); wsz = lwb->lwb_write_zio->io_size; } memset(lwb->lwb_buf + lwb->lwb_nused, 0, wsz - lwb->lwb_nused); zilc->zc_pad = 0; zilc->zc_nused = lwb->lwb_nused; zilc->zc_eck.zec_cksum = lwb->lwb_blk.blk_cksum; } else { /* * We can't write the lwb if there was an allocation failure, * so create a null zio instead just to maintain dependencies. */ lwb->lwb_write_zio = zio_null(lwb->lwb_root_zio, spa, NULL, zil_lwb_write_done, lwb, ZIO_FLAG_CANFAIL); lwb->lwb_write_zio->io_error = lwb->lwb_error; } if (lwb->lwb_child_zio) zio_add_child(lwb->lwb_write_zio, lwb->lwb_child_zio); /* * Open transaction to allocate the next block pointer. */ dmu_tx_t *tx = dmu_tx_create(zilog->zl_os); VERIFY0(dmu_tx_assign(tx, TXG_WAIT | TXG_NOTHROTTLE)); dsl_dataset_dirty(dmu_objset_ds(zilog->zl_os), tx); uint64_t txg = dmu_tx_get_txg(tx); /* * Allocate next the block pointer unless we are already in error. */ lwb_t *nlwb = list_next(&zilog->zl_lwb_list, lwb); blkptr_t *bp = &zilc->zc_next_blk; BP_ZERO(bp); error = lwb->lwb_error; if (error == 0) { error = zio_alloc_zil(spa, zilog->zl_os, txg, bp, nlwb->lwb_sz, &slog); } if (error == 0) { ASSERT3U(bp->blk_birth, ==, txg); BP_SET_CHECKSUM(bp, nlwb->lwb_slim ? ZIO_CHECKSUM_ZILOG2 : ZIO_CHECKSUM_ZILOG); bp->blk_cksum = lwb->lwb_blk.blk_cksum; bp->blk_cksum.zc_word[ZIL_ZC_SEQ]++; } /* * Reduce TXG open time by incrementing inflight counter and committing * the transaciton. zil_sync() will wait for it to return to zero. */ mutex_enter(&zilog->zl_lwb_io_lock); lwb->lwb_issued_txg = txg; zilog->zl_lwb_inflight[txg & TXG_MASK]++; zilog->zl_lwb_max_issued_txg = MAX(txg, zilog->zl_lwb_max_issued_txg); mutex_exit(&zilog->zl_lwb_io_lock); dmu_tx_commit(tx); spa_config_enter(spa, SCL_STATE, lwb, RW_READER); /* * We've completed all potentially blocking operations. Update the * nlwb and allow it proceed without possible lock order reversals. */ mutex_enter(&zilog->zl_lock); zil_lwb_set_zio_dependency(zilog, lwb); lwb->lwb_state = LWB_STATE_ISSUED; if (nlwb) { nlwb->lwb_blk = *bp; nlwb->lwb_error = error; nlwb->lwb_slog = slog; nlwb->lwb_alloc_txg = txg; if (nlwb->lwb_state != LWB_STATE_READY) nlwb = NULL; } mutex_exit(&zilog->zl_lock); if (lwb->lwb_slog) { ZIL_STAT_BUMP(zilog, zil_itx_metaslab_slog_count); ZIL_STAT_INCR(zilog, zil_itx_metaslab_slog_bytes, lwb->lwb_nused); ZIL_STAT_INCR(zilog, zil_itx_metaslab_slog_write, wsz); ZIL_STAT_INCR(zilog, zil_itx_metaslab_slog_alloc, BP_GET_LSIZE(&lwb->lwb_blk)); } else { ZIL_STAT_BUMP(zilog, zil_itx_metaslab_normal_count); ZIL_STAT_INCR(zilog, zil_itx_metaslab_normal_bytes, lwb->lwb_nused); ZIL_STAT_INCR(zilog, zil_itx_metaslab_normal_write, wsz); ZIL_STAT_INCR(zilog, zil_itx_metaslab_normal_alloc, BP_GET_LSIZE(&lwb->lwb_blk)); } lwb->lwb_issued_timestamp = gethrtime(); if (lwb->lwb_child_zio) zio_nowait(lwb->lwb_child_zio); zio_nowait(lwb->lwb_write_zio); zio_nowait(lwb->lwb_root_zio); /* * If nlwb was ready when we gave it the block pointer, * it is on us to issue it and possibly following ones. */ lwb = nlwb; if (lwb) goto next_lwb; } /* * Maximum amount of data that can be put into single log block. */ uint64_t zil_max_log_data(zilog_t *zilog, size_t hdrsize) { return (zilog->zl_max_block_size - sizeof (zil_chain_t) - hdrsize); } /* * Maximum amount of log space we agree to waste to reduce number of * WR_NEED_COPY chunks to reduce zl_get_data() overhead (~6%). */ static inline uint64_t zil_max_waste_space(zilog_t *zilog) { return (zil_max_log_data(zilog, sizeof (lr_write_t)) / 16); } /* * Maximum amount of write data for WR_COPIED. For correctness, consumers * must fall back to WR_NEED_COPY if we can't fit the entire record into one * maximum sized log block, because each WR_COPIED record must fit in a * single log block. Below that it is a tradeoff of additional memory copy * and possibly worse log space efficiency vs additional range lock/unlock. */ static uint_t zil_maxcopied = 7680; uint64_t zil_max_copied_data(zilog_t *zilog) { uint64_t max_data = zil_max_log_data(zilog, sizeof (lr_write_t)); return (MIN(max_data, zil_maxcopied)); } /* * Estimate space needed in the lwb for the itx. Allocate more lwbs or * split the itx as needed, but don't touch the actual transaction data. * Has to be called under zl_issuer_lock to call zil_lwb_write_close() * to chain more lwbs. */ static lwb_t * zil_lwb_assign(zilog_t *zilog, lwb_t *lwb, itx_t *itx, list_t *ilwbs) { itx_t *citx; lr_t *lr, *clr; lr_write_t *lrw; uint64_t dlen, dnow, lwb_sp, reclen, max_log_data; ASSERT(MUTEX_HELD(&zilog->zl_issuer_lock)); ASSERT3P(lwb, !=, NULL); ASSERT3P(lwb->lwb_buf, !=, NULL); zil_lwb_write_open(zilog, lwb); lr = &itx->itx_lr; lrw = (lr_write_t *)lr; /* * A commit itx doesn't represent any on-disk state; instead * it's simply used as a place holder on the commit list, and * provides a mechanism for attaching a "commit waiter" onto the * correct lwb (such that the waiter can be signalled upon * completion of that lwb). Thus, we don't process this itx's * log record if it's a commit itx (these itx's don't have log * records), and instead link the itx's waiter onto the lwb's * list of waiters. * * For more details, see the comment above zil_commit(). */ if (lr->lrc_txtype == TX_COMMIT) { zil_commit_waiter_link_lwb(itx->itx_private, lwb); list_insert_tail(&lwb->lwb_itxs, itx); return (lwb); } if (lr->lrc_txtype == TX_WRITE && itx->itx_wr_state == WR_NEED_COPY) { dlen = P2ROUNDUP_TYPED( lrw->lr_length, sizeof (uint64_t), uint64_t); } else { dlen = 0; } reclen = lr->lrc_reclen; zilog->zl_cur_used += (reclen + dlen); cont: /* * If this record won't fit in the current log block, start a new one. * For WR_NEED_COPY optimize layout for minimal number of chunks. */ lwb_sp = lwb->lwb_nmax - lwb->lwb_nused; max_log_data = zil_max_log_data(zilog, sizeof (lr_write_t)); if (reclen > lwb_sp || (reclen + dlen > lwb_sp && lwb_sp < zil_max_waste_space(zilog) && (dlen % max_log_data == 0 || lwb_sp < reclen + dlen % max_log_data))) { list_insert_tail(ilwbs, lwb); lwb = zil_lwb_write_close(zilog, lwb, LWB_STATE_OPENED); if (lwb == NULL) return (NULL); lwb_sp = lwb->lwb_nmax - lwb->lwb_nused; /* * There must be enough space in the new, empty log block to * hold reclen. For WR_COPIED, we need to fit the whole * record in one block, and reclen is the header size + the * data size. For WR_NEED_COPY, we can create multiple * records, splitting the data into multiple blocks, so we * only need to fit one word of data per block; in this case * reclen is just the header size (no data). */ ASSERT3U(reclen + MIN(dlen, sizeof (uint64_t)), <=, lwb_sp); } dnow = MIN(dlen, lwb_sp - reclen); if (dlen > dnow) { ASSERT3U(lr->lrc_txtype, ==, TX_WRITE); ASSERT3U(itx->itx_wr_state, ==, WR_NEED_COPY); citx = zil_itx_clone(itx); clr = &citx->itx_lr; lr_write_t *clrw = (lr_write_t *)clr; clrw->lr_length = dnow; lrw->lr_offset += dnow; lrw->lr_length -= dnow; } else { citx = itx; clr = lr; } /* * We're actually making an entry, so update lrc_seq to be the * log record sequence number. Note that this is generally not * equal to the itx sequence number because not all transactions * are synchronous, and sometimes spa_sync() gets there first. */ clr->lrc_seq = ++zilog->zl_lr_seq; lwb->lwb_nused += reclen + dnow; ASSERT3U(lwb->lwb_nused, <=, lwb->lwb_nmax); ASSERT0(P2PHASE(lwb->lwb_nused, sizeof (uint64_t))); zil_lwb_add_txg(lwb, lr->lrc_txg); list_insert_tail(&lwb->lwb_itxs, citx); dlen -= dnow; if (dlen > 0) { zilog->zl_cur_used += reclen; goto cont; } if (lr->lrc_txtype == TX_WRITE && lr->lrc_txg > spa_freeze_txg(zilog->zl_spa)) txg_wait_synced(zilog->zl_dmu_pool, lr->lrc_txg); return (lwb); } /* * Fill the actual transaction data into the lwb, following zil_lwb_assign(). * Does not require locking. */ static void zil_lwb_commit(zilog_t *zilog, lwb_t *lwb, itx_t *itx) { lr_t *lr, *lrb; lr_write_t *lrw, *lrwb; char *lr_buf; uint64_t dlen, reclen; lr = &itx->itx_lr; lrw = (lr_write_t *)lr; if (lr->lrc_txtype == TX_COMMIT) return; if (lr->lrc_txtype == TX_WRITE && itx->itx_wr_state == WR_NEED_COPY) { dlen = P2ROUNDUP_TYPED( lrw->lr_length, sizeof (uint64_t), uint64_t); } else { dlen = 0; } reclen = lr->lrc_reclen; ASSERT3U(reclen + dlen, <=, lwb->lwb_nused - lwb->lwb_nfilled); lr_buf = lwb->lwb_buf + lwb->lwb_nfilled; memcpy(lr_buf, lr, reclen); lrb = (lr_t *)lr_buf; /* Like lr, but inside lwb. */ lrwb = (lr_write_t *)lrb; /* Like lrw, but inside lwb. */ ZIL_STAT_BUMP(zilog, zil_itx_count); /* * If it's a write, fetch the data or get its blkptr as appropriate. */ if (lr->lrc_txtype == TX_WRITE) { if (itx->itx_wr_state == WR_COPIED) { ZIL_STAT_BUMP(zilog, zil_itx_copied_count); ZIL_STAT_INCR(zilog, zil_itx_copied_bytes, lrw->lr_length); } else { char *dbuf; int error; if (itx->itx_wr_state == WR_NEED_COPY) { dbuf = lr_buf + reclen; lrb->lrc_reclen += dlen; ZIL_STAT_BUMP(zilog, zil_itx_needcopy_count); ZIL_STAT_INCR(zilog, zil_itx_needcopy_bytes, dlen); } else { ASSERT3S(itx->itx_wr_state, ==, WR_INDIRECT); dbuf = NULL; ZIL_STAT_BUMP(zilog, zil_itx_indirect_count); ZIL_STAT_INCR(zilog, zil_itx_indirect_bytes, lrw->lr_length); if (lwb->lwb_child_zio == NULL) { lwb->lwb_child_zio = zio_root( zilog->zl_spa, NULL, NULL, ZIO_FLAG_CANFAIL); } } /* * The "lwb_child_zio" we pass in will become a child of * "lwb_write_zio", when one is created, so one will be * a parent of any zio's created by the "zl_get_data". * This way "lwb_write_zio" will first wait for children * block pointers before own writing, and then for their * writing completion before the vdev cache flushing. */ error = zilog->zl_get_data(itx->itx_private, itx->itx_gen, lrwb, dbuf, lwb, lwb->lwb_child_zio); if (dbuf != NULL && error == 0) { /* Zero any padding bytes in the last block. */ memset((char *)dbuf + lrwb->lr_length, 0, dlen - lrwb->lr_length); } /* * Typically, the only return values we should see from * ->zl_get_data() are 0, EIO, ENOENT, EEXIST or * EALREADY. However, it is also possible to see other * error values such as ENOSPC or EINVAL from * dmu_read() -> dnode_hold() -> dnode_hold_impl() or * ENXIO as well as a multitude of others from the * block layer through dmu_buf_hold() -> dbuf_read() * -> zio_wait(), as well as through dmu_read() -> * dnode_hold() -> dnode_hold_impl() -> dbuf_read() -> * zio_wait(). When these errors happen, we can assume * that neither an immediate write nor an indirect * write occurred, so we need to fall back to * txg_wait_synced(). This is unusual, so we print to * dmesg whenever one of these errors occurs. */ switch (error) { case 0: break; default: cmn_err(CE_WARN, "zil_lwb_commit() received " "unexpected error %d from ->zl_get_data()" ". Falling back to txg_wait_synced().", error); zfs_fallthrough; case EIO: txg_wait_synced(zilog->zl_dmu_pool, lr->lrc_txg); zfs_fallthrough; case ENOENT: zfs_fallthrough; case EEXIST: zfs_fallthrough; case EALREADY: return; } } } lwb->lwb_nfilled += reclen + dlen; ASSERT3S(lwb->lwb_nfilled, <=, lwb->lwb_nused); ASSERT0(P2PHASE(lwb->lwb_nfilled, sizeof (uint64_t))); } itx_t * zil_itx_create(uint64_t txtype, size_t olrsize) { size_t itxsize, lrsize; itx_t *itx; lrsize = P2ROUNDUP_TYPED(olrsize, sizeof (uint64_t), size_t); itxsize = offsetof(itx_t, itx_lr) + lrsize; itx = zio_data_buf_alloc(itxsize); itx->itx_lr.lrc_txtype = txtype; itx->itx_lr.lrc_reclen = lrsize; itx->itx_lr.lrc_seq = 0; /* defensive */ memset((char *)&itx->itx_lr + olrsize, 0, lrsize - olrsize); itx->itx_sync = B_TRUE; /* default is synchronous */ itx->itx_callback = NULL; itx->itx_callback_data = NULL; itx->itx_size = itxsize; return (itx); } static itx_t * zil_itx_clone(itx_t *oitx) { itx_t *itx = zio_data_buf_alloc(oitx->itx_size); memcpy(itx, oitx, oitx->itx_size); itx->itx_callback = NULL; itx->itx_callback_data = NULL; return (itx); } void zil_itx_destroy(itx_t *itx) { IMPLY(itx->itx_lr.lrc_txtype == TX_COMMIT, itx->itx_callback == NULL); IMPLY(itx->itx_callback != NULL, itx->itx_lr.lrc_txtype != TX_COMMIT); if (itx->itx_callback != NULL) itx->itx_callback(itx->itx_callback_data); zio_data_buf_free(itx, itx->itx_size); } /* * Free up the sync and async itxs. The itxs_t has already been detached * so no locks are needed. */ static void zil_itxg_clean(void *arg) { itx_t *itx; list_t *list; avl_tree_t *t; void *cookie; itxs_t *itxs = arg; itx_async_node_t *ian; list = &itxs->i_sync_list; while ((itx = list_remove_head(list)) != NULL) { /* * In the general case, commit itxs will not be found * here, as they'll be committed to an lwb via * zil_lwb_assign(), and free'd in that function. Having * said that, it is still possible for commit itxs to be * found here, due to the following race: * * - a thread calls zil_commit() which assigns the * commit itx to a per-txg i_sync_list * - zil_itxg_clean() is called (e.g. via spa_sync()) * while the waiter is still on the i_sync_list * * There's nothing to prevent syncing the txg while the * waiter is on the i_sync_list. This normally doesn't * happen because spa_sync() is slower than zil_commit(), * but if zil_commit() calls txg_wait_synced() (e.g. * because zil_create() or zil_commit_writer_stall() is * called) we will hit this case. */ if (itx->itx_lr.lrc_txtype == TX_COMMIT) zil_commit_waiter_skip(itx->itx_private); zil_itx_destroy(itx); } cookie = NULL; t = &itxs->i_async_tree; while ((ian = avl_destroy_nodes(t, &cookie)) != NULL) { list = &ian->ia_list; while ((itx = list_remove_head(list)) != NULL) { /* commit itxs should never be on the async lists. */ ASSERT3U(itx->itx_lr.lrc_txtype, !=, TX_COMMIT); zil_itx_destroy(itx); } list_destroy(list); kmem_free(ian, sizeof (itx_async_node_t)); } avl_destroy(t); kmem_free(itxs, sizeof (itxs_t)); } static int zil_aitx_compare(const void *x1, const void *x2) { const uint64_t o1 = ((itx_async_node_t *)x1)->ia_foid; const uint64_t o2 = ((itx_async_node_t *)x2)->ia_foid; return (TREE_CMP(o1, o2)); } /* * Remove all async itx with the given oid. */ void zil_remove_async(zilog_t *zilog, uint64_t oid) { uint64_t otxg, txg; itx_async_node_t *ian; avl_tree_t *t; avl_index_t where; list_t clean_list; itx_t *itx; ASSERT(oid != 0); list_create(&clean_list, sizeof (itx_t), offsetof(itx_t, itx_node)); if (spa_freeze_txg(zilog->zl_spa) != UINT64_MAX) /* ziltest support */ otxg = ZILTEST_TXG; else otxg = spa_last_synced_txg(zilog->zl_spa) + 1; for (txg = otxg; txg < (otxg + TXG_CONCURRENT_STATES); txg++) { itxg_t *itxg = &zilog->zl_itxg[txg & TXG_MASK]; mutex_enter(&itxg->itxg_lock); if (itxg->itxg_txg != txg) { mutex_exit(&itxg->itxg_lock); continue; } /* * Locate the object node and append its list. */ t = &itxg->itxg_itxs->i_async_tree; ian = avl_find(t, &oid, &where); if (ian != NULL) list_move_tail(&clean_list, &ian->ia_list); mutex_exit(&itxg->itxg_lock); } while ((itx = list_remove_head(&clean_list)) != NULL) { /* commit itxs should never be on the async lists. */ ASSERT3U(itx->itx_lr.lrc_txtype, !=, TX_COMMIT); zil_itx_destroy(itx); } list_destroy(&clean_list); } void zil_itx_assign(zilog_t *zilog, itx_t *itx, dmu_tx_t *tx) { uint64_t txg; itxg_t *itxg; itxs_t *itxs, *clean = NULL; /* * Ensure the data of a renamed file is committed before the rename. */ if ((itx->itx_lr.lrc_txtype & ~TX_CI) == TX_RENAME) zil_async_to_sync(zilog, itx->itx_oid); if (spa_freeze_txg(zilog->zl_spa) != UINT64_MAX) txg = ZILTEST_TXG; else txg = dmu_tx_get_txg(tx); itxg = &zilog->zl_itxg[txg & TXG_MASK]; mutex_enter(&itxg->itxg_lock); itxs = itxg->itxg_itxs; if (itxg->itxg_txg != txg) { if (itxs != NULL) { /* * The zil_clean callback hasn't got around to cleaning * this itxg. Save the itxs for release below. * This should be rare. */ zfs_dbgmsg("zil_itx_assign: missed itx cleanup for " "txg %llu", (u_longlong_t)itxg->itxg_txg); clean = itxg->itxg_itxs; } itxg->itxg_txg = txg; itxs = itxg->itxg_itxs = kmem_zalloc(sizeof (itxs_t), KM_SLEEP); list_create(&itxs->i_sync_list, sizeof (itx_t), offsetof(itx_t, itx_node)); avl_create(&itxs->i_async_tree, zil_aitx_compare, sizeof (itx_async_node_t), offsetof(itx_async_node_t, ia_node)); } if (itx->itx_sync) { list_insert_tail(&itxs->i_sync_list, itx); } else { avl_tree_t *t = &itxs->i_async_tree; uint64_t foid = LR_FOID_GET_OBJ(((lr_ooo_t *)&itx->itx_lr)->lr_foid); itx_async_node_t *ian; avl_index_t where; ian = avl_find(t, &foid, &where); if (ian == NULL) { ian = kmem_alloc(sizeof (itx_async_node_t), KM_SLEEP); list_create(&ian->ia_list, sizeof (itx_t), offsetof(itx_t, itx_node)); ian->ia_foid = foid; avl_insert(t, ian, where); } list_insert_tail(&ian->ia_list, itx); } itx->itx_lr.lrc_txg = dmu_tx_get_txg(tx); /* * We don't want to dirty the ZIL using ZILTEST_TXG, because * zil_clean() will never be called using ZILTEST_TXG. Thus, we * need to be careful to always dirty the ZIL using the "real" * TXG (not itxg_txg) even when the SPA is frozen. */ zilog_dirty(zilog, dmu_tx_get_txg(tx)); mutex_exit(&itxg->itxg_lock); /* Release the old itxs now we've dropped the lock */ if (clean != NULL) zil_itxg_clean(clean); } /* * If there are any in-memory intent log transactions which have now been * synced then start up a taskq to free them. We should only do this after we * have written out the uberblocks (i.e. txg has been committed) so that * don't inadvertently clean out in-memory log records that would be required * by zil_commit(). */ void zil_clean(zilog_t *zilog, uint64_t synced_txg) { itxg_t *itxg = &zilog->zl_itxg[synced_txg & TXG_MASK]; itxs_t *clean_me; ASSERT3U(synced_txg, <, ZILTEST_TXG); mutex_enter(&itxg->itxg_lock); if (itxg->itxg_itxs == NULL || itxg->itxg_txg == ZILTEST_TXG) { mutex_exit(&itxg->itxg_lock); return; } ASSERT3U(itxg->itxg_txg, <=, synced_txg); ASSERT3U(itxg->itxg_txg, !=, 0); clean_me = itxg->itxg_itxs; itxg->itxg_itxs = NULL; itxg->itxg_txg = 0; mutex_exit(&itxg->itxg_lock); /* * Preferably start a task queue to free up the old itxs but * if taskq_dispatch can't allocate resources to do that then * free it in-line. This should be rare. Note, using TQ_SLEEP * created a bad performance problem. */ ASSERT3P(zilog->zl_dmu_pool, !=, NULL); ASSERT3P(zilog->zl_dmu_pool->dp_zil_clean_taskq, !=, NULL); taskqid_t id = taskq_dispatch(zilog->zl_dmu_pool->dp_zil_clean_taskq, zil_itxg_clean, clean_me, TQ_NOSLEEP); if (id == TASKQID_INVALID) zil_itxg_clean(clean_me); } /* * This function will traverse the queue of itxs that need to be * committed, and move them onto the ZIL's zl_itx_commit_list. */ static uint64_t zil_get_commit_list(zilog_t *zilog) { uint64_t otxg, txg, wtxg = 0; list_t *commit_list = &zilog->zl_itx_commit_list; ASSERT(MUTEX_HELD(&zilog->zl_issuer_lock)); if (spa_freeze_txg(zilog->zl_spa) != UINT64_MAX) /* ziltest support */ otxg = ZILTEST_TXG; else otxg = spa_last_synced_txg(zilog->zl_spa) + 1; /* * This is inherently racy, since there is nothing to prevent * the last synced txg from changing. That's okay since we'll * only commit things in the future. */ for (txg = otxg; txg < (otxg + TXG_CONCURRENT_STATES); txg++) { itxg_t *itxg = &zilog->zl_itxg[txg & TXG_MASK]; mutex_enter(&itxg->itxg_lock); if (itxg->itxg_txg != txg) { mutex_exit(&itxg->itxg_lock); continue; } /* * If we're adding itx records to the zl_itx_commit_list, * then the zil better be dirty in this "txg". We can assert * that here since we're holding the itxg_lock which will * prevent spa_sync from cleaning it. Once we add the itxs * to the zl_itx_commit_list we must commit it to disk even * if it's unnecessary (i.e. the txg was synced). */ ASSERT(zilog_is_dirty_in_txg(zilog, txg) || spa_freeze_txg(zilog->zl_spa) != UINT64_MAX); list_t *sync_list = &itxg->itxg_itxs->i_sync_list; if (unlikely(zilog->zl_suspend > 0)) { /* * ZIL was just suspended, but we lost the race. * Allow all earlier itxs to be committed, but ask * caller to do txg_wait_synced(txg) for any new. */ if (!list_is_empty(sync_list)) wtxg = MAX(wtxg, txg); } else { list_move_tail(commit_list, sync_list); } mutex_exit(&itxg->itxg_lock); } return (wtxg); } /* * Move the async itxs for a specified object to commit into sync lists. */ void zil_async_to_sync(zilog_t *zilog, uint64_t foid) { uint64_t otxg, txg; itx_async_node_t *ian; avl_tree_t *t; avl_index_t where; if (spa_freeze_txg(zilog->zl_spa) != UINT64_MAX) /* ziltest support */ otxg = ZILTEST_TXG; else otxg = spa_last_synced_txg(zilog->zl_spa) + 1; /* * This is inherently racy, since there is nothing to prevent * the last synced txg from changing. */ for (txg = otxg; txg < (otxg + TXG_CONCURRENT_STATES); txg++) { itxg_t *itxg = &zilog->zl_itxg[txg & TXG_MASK]; mutex_enter(&itxg->itxg_lock); if (itxg->itxg_txg != txg) { mutex_exit(&itxg->itxg_lock); continue; } /* * If a foid is specified then find that node and append its * list. Otherwise walk the tree appending all the lists * to the sync list. We add to the end rather than the * beginning to ensure the create has happened. */ t = &itxg->itxg_itxs->i_async_tree; if (foid != 0) { ian = avl_find(t, &foid, &where); if (ian != NULL) { list_move_tail(&itxg->itxg_itxs->i_sync_list, &ian->ia_list); } } else { void *cookie = NULL; while ((ian = avl_destroy_nodes(t, &cookie)) != NULL) { list_move_tail(&itxg->itxg_itxs->i_sync_list, &ian->ia_list); list_destroy(&ian->ia_list); kmem_free(ian, sizeof (itx_async_node_t)); } } mutex_exit(&itxg->itxg_lock); } } /* * This function will prune commit itxs that are at the head of the * commit list (it won't prune past the first non-commit itx), and * either: a) attach them to the last lwb that's still pending * completion, or b) skip them altogether. * * This is used as a performance optimization to prevent commit itxs * from generating new lwbs when it's unnecessary to do so. */ static void zil_prune_commit_list(zilog_t *zilog) { itx_t *itx; ASSERT(MUTEX_HELD(&zilog->zl_issuer_lock)); while ((itx = list_head(&zilog->zl_itx_commit_list)) != NULL) { lr_t *lrc = &itx->itx_lr; if (lrc->lrc_txtype != TX_COMMIT) break; mutex_enter(&zilog->zl_lock); lwb_t *last_lwb = zilog->zl_last_lwb_opened; if (last_lwb == NULL || last_lwb->lwb_state == LWB_STATE_FLUSH_DONE) { /* * All of the itxs this waiter was waiting on * must have already completed (or there were * never any itx's for it to wait on), so it's * safe to skip this waiter and mark it done. */ zil_commit_waiter_skip(itx->itx_private); } else { zil_commit_waiter_link_lwb(itx->itx_private, last_lwb); } mutex_exit(&zilog->zl_lock); list_remove(&zilog->zl_itx_commit_list, itx); zil_itx_destroy(itx); } IMPLY(itx != NULL, itx->itx_lr.lrc_txtype != TX_COMMIT); } static void zil_commit_writer_stall(zilog_t *zilog) { /* * When zio_alloc_zil() fails to allocate the next lwb block on * disk, we must call txg_wait_synced() to ensure all of the * lwbs in the zilog's zl_lwb_list are synced and then freed (in * zil_sync()), such that any subsequent ZIL writer (i.e. a call * to zil_process_commit_list()) will have to call zil_create(), * and start a new ZIL chain. * * Since zil_alloc_zil() failed, the lwb that was previously * issued does not have a pointer to the "next" lwb on disk. * Thus, if another ZIL writer thread was to allocate the "next" * on-disk lwb, that block could be leaked in the event of a * crash (because the previous lwb on-disk would not point to * it). * * We must hold the zilog's zl_issuer_lock while we do this, to * ensure no new threads enter zil_process_commit_list() until * all lwb's in the zl_lwb_list have been synced and freed * (which is achieved via the txg_wait_synced() call). */ ASSERT(MUTEX_HELD(&zilog->zl_issuer_lock)); txg_wait_synced(zilog->zl_dmu_pool, 0); ASSERT(list_is_empty(&zilog->zl_lwb_list)); } /* * This function will traverse the commit list, creating new lwbs as * needed, and committing the itxs from the commit list to these newly * created lwbs. Additionally, as a new lwb is created, the previous * lwb will be issued to the zio layer to be written to disk. */ static void zil_process_commit_list(zilog_t *zilog, zil_commit_waiter_t *zcw, list_t *ilwbs) { spa_t *spa = zilog->zl_spa; list_t nolwb_itxs; list_t nolwb_waiters; lwb_t *lwb, *plwb; itx_t *itx; boolean_t first = B_TRUE; ASSERT(MUTEX_HELD(&zilog->zl_issuer_lock)); /* * Return if there's nothing to commit before we dirty the fs by * calling zil_create(). */ if (list_is_empty(&zilog->zl_itx_commit_list)) return; list_create(&nolwb_itxs, sizeof (itx_t), offsetof(itx_t, itx_node)); list_create(&nolwb_waiters, sizeof (zil_commit_waiter_t), offsetof(zil_commit_waiter_t, zcw_node)); lwb = list_tail(&zilog->zl_lwb_list); if (lwb == NULL) { lwb = zil_create(zilog); } else { /* * Activate SPA_FEATURE_ZILSAXATTR for the cases where ZIL will * have already been created (zl_lwb_list not empty). */ zil_commit_activate_saxattr_feature(zilog); ASSERT(lwb->lwb_state == LWB_STATE_NEW || lwb->lwb_state == LWB_STATE_OPENED); first = (lwb->lwb_state == LWB_STATE_NEW) && ((plwb = list_prev(&zilog->zl_lwb_list, lwb)) == NULL || plwb->lwb_state == LWB_STATE_FLUSH_DONE); } while ((itx = list_remove_head(&zilog->zl_itx_commit_list)) != NULL) { lr_t *lrc = &itx->itx_lr; uint64_t txg = lrc->lrc_txg; ASSERT3U(txg, !=, 0); if (lrc->lrc_txtype == TX_COMMIT) { DTRACE_PROBE2(zil__process__commit__itx, zilog_t *, zilog, itx_t *, itx); } else { DTRACE_PROBE2(zil__process__normal__itx, zilog_t *, zilog, itx_t *, itx); } boolean_t synced = txg <= spa_last_synced_txg(spa); boolean_t frozen = txg > spa_freeze_txg(spa); /* * If the txg of this itx has already been synced out, then * we don't need to commit this itx to an lwb. This is * because the data of this itx will have already been * written to the main pool. This is inherently racy, and * it's still ok to commit an itx whose txg has already * been synced; this will result in a write that's * unnecessary, but will do no harm. * * With that said, we always want to commit TX_COMMIT itxs * to an lwb, regardless of whether or not that itx's txg * has been synced out. We do this to ensure any OPENED lwb * will always have at least one zil_commit_waiter_t linked * to the lwb. * * As a counter-example, if we skipped TX_COMMIT itx's * whose txg had already been synced, the following * situation could occur if we happened to be racing with * spa_sync: * * 1. We commit a non-TX_COMMIT itx to an lwb, where the * itx's txg is 10 and the last synced txg is 9. * 2. spa_sync finishes syncing out txg 10. * 3. We move to the next itx in the list, it's a TX_COMMIT * whose txg is 10, so we skip it rather than committing * it to the lwb used in (1). * * If the itx that is skipped in (3) is the last TX_COMMIT * itx in the commit list, than it's possible for the lwb * used in (1) to remain in the OPENED state indefinitely. * * To prevent the above scenario from occurring, ensuring * that once an lwb is OPENED it will transition to ISSUED * and eventually DONE, we always commit TX_COMMIT itx's to * an lwb here, even if that itx's txg has already been * synced. * * Finally, if the pool is frozen, we _always_ commit the * itx. The point of freezing the pool is to prevent data * from being written to the main pool via spa_sync, and * instead rely solely on the ZIL to persistently store the * data; i.e. when the pool is frozen, the last synced txg * value can't be trusted. */ if (frozen || !synced || lrc->lrc_txtype == TX_COMMIT) { if (lwb != NULL) { lwb = zil_lwb_assign(zilog, lwb, itx, ilwbs); if (lwb == NULL) { list_insert_tail(&nolwb_itxs, itx); } else if ((zcw->zcw_lwb != NULL && zcw->zcw_lwb != lwb) || zcw->zcw_done) { /* * Our lwb is done, leave the rest of * itx list to somebody else who care. */ first = B_FALSE; break; } } else { if (lrc->lrc_txtype == TX_COMMIT) { zil_commit_waiter_link_nolwb( itx->itx_private, &nolwb_waiters); } list_insert_tail(&nolwb_itxs, itx); } } else { ASSERT3S(lrc->lrc_txtype, !=, TX_COMMIT); zil_itx_destroy(itx); } } if (lwb == NULL) { /* * This indicates zio_alloc_zil() failed to allocate the * "next" lwb on-disk. When this happens, we must stall * the ZIL write pipeline; see the comment within * zil_commit_writer_stall() for more details. */ while ((lwb = list_remove_head(ilwbs)) != NULL) zil_lwb_write_issue(zilog, lwb); zil_commit_writer_stall(zilog); /* * Additionally, we have to signal and mark the "nolwb" * waiters as "done" here, since without an lwb, we * can't do this via zil_lwb_flush_vdevs_done() like * normal. */ zil_commit_waiter_t *zcw; while ((zcw = list_remove_head(&nolwb_waiters)) != NULL) zil_commit_waiter_skip(zcw); /* * And finally, we have to destroy the itx's that * couldn't be committed to an lwb; this will also call * the itx's callback if one exists for the itx. */ while ((itx = list_remove_head(&nolwb_itxs)) != NULL) zil_itx_destroy(itx); } else { ASSERT(list_is_empty(&nolwb_waiters)); ASSERT3P(lwb, !=, NULL); ASSERT(lwb->lwb_state == LWB_STATE_NEW || lwb->lwb_state == LWB_STATE_OPENED); /* * At this point, the ZIL block pointed at by the "lwb" * variable is in "new" or "opened" state. * * If it's "new", then no itxs have been committed to it, so * there's no point in issuing its zio (i.e. it's "empty"). * * If it's "opened", then it contains one or more itxs that * eventually need to be committed to stable storage. In * this case we intentionally do not issue the lwb's zio * to disk yet, and instead rely on one of the following * two mechanisms for issuing the zio: * * 1. Ideally, there will be more ZIL activity occurring on * the system, such that this function will be immediately * called again by different thread and this lwb will be * closed by zil_lwb_assign(). This way, the lwb will be * "full" when it is issued to disk, and we'll make use of * the lwb's size the best we can. * * 2. If there isn't sufficient ZIL activity occurring on * the system, zil_commit_waiter() will close it and issue * the zio. If this occurs, the lwb is not guaranteed * to be "full" by the time its zio is issued, and means * the size of the lwb was "too large" given the amount * of ZIL activity occurring on the system at that time. * * We do this for a couple of reasons: * * 1. To try and reduce the number of IOPs needed to * write the same number of itxs. If an lwb has space * available in its buffer for more itxs, and more itxs * will be committed relatively soon (relative to the * latency of performing a write), then it's beneficial * to wait for these "next" itxs. This way, more itxs * can be committed to stable storage with fewer writes. * * 2. To try and use the largest lwb block size that the * incoming rate of itxs can support. Again, this is to * try and pack as many itxs into as few lwbs as * possible, without significantly impacting the latency * of each individual itx. * * If we had no already running or open LWBs, it can be * the workload is single-threaded. And if the ZIL write * latency is very small or if the LWB is almost full, it * may be cheaper to bypass the delay. */ if (lwb->lwb_state == LWB_STATE_OPENED && first) { hrtime_t sleep = zilog->zl_last_lwb_latency * zfs_commit_timeout_pct / 100; if (sleep < zil_min_commit_timeout || lwb->lwb_nmax - lwb->lwb_nused < lwb->lwb_nmax / 8) { list_insert_tail(ilwbs, lwb); lwb = zil_lwb_write_close(zilog, lwb, LWB_STATE_NEW); zilog->zl_cur_used = 0; if (lwb == NULL) { while ((lwb = list_remove_head(ilwbs)) != NULL) zil_lwb_write_issue(zilog, lwb); zil_commit_writer_stall(zilog); } } } } } /* * This function is responsible for ensuring the passed in commit waiter * (and associated commit itx) is committed to an lwb. If the waiter is * not already committed to an lwb, all itxs in the zilog's queue of * itxs will be processed. The assumption is the passed in waiter's * commit itx will found in the queue just like the other non-commit * itxs, such that when the entire queue is processed, the waiter will * have been committed to an lwb. * * The lwb associated with the passed in waiter is not guaranteed to * have been issued by the time this function completes. If the lwb is * not issued, we rely on future calls to zil_commit_writer() to issue * the lwb, or the timeout mechanism found in zil_commit_waiter(). */ static uint64_t zil_commit_writer(zilog_t *zilog, zil_commit_waiter_t *zcw) { list_t ilwbs; lwb_t *lwb; uint64_t wtxg = 0; ASSERT(!MUTEX_HELD(&zilog->zl_lock)); ASSERT(spa_writeable(zilog->zl_spa)); list_create(&ilwbs, sizeof (lwb_t), offsetof(lwb_t, lwb_issue_node)); mutex_enter(&zilog->zl_issuer_lock); if (zcw->zcw_lwb != NULL || zcw->zcw_done) { /* * It's possible that, while we were waiting to acquire * the "zl_issuer_lock", another thread committed this * waiter to an lwb. If that occurs, we bail out early, * without processing any of the zilog's queue of itxs. * * On certain workloads and system configurations, the * "zl_issuer_lock" can become highly contended. In an * attempt to reduce this contention, we immediately drop * the lock if the waiter has already been processed. * * We've measured this optimization to reduce CPU spent * contending on this lock by up to 5%, using a system * with 32 CPUs, low latency storage (~50 usec writes), * and 1024 threads performing sync writes. */ goto out; } ZIL_STAT_BUMP(zilog, zil_commit_writer_count); wtxg = zil_get_commit_list(zilog); zil_prune_commit_list(zilog); zil_process_commit_list(zilog, zcw, &ilwbs); out: mutex_exit(&zilog->zl_issuer_lock); while ((lwb = list_remove_head(&ilwbs)) != NULL) zil_lwb_write_issue(zilog, lwb); list_destroy(&ilwbs); return (wtxg); } static void zil_commit_waiter_timeout(zilog_t *zilog, zil_commit_waiter_t *zcw) { ASSERT(!MUTEX_HELD(&zilog->zl_issuer_lock)); ASSERT(MUTEX_HELD(&zcw->zcw_lock)); ASSERT3B(zcw->zcw_done, ==, B_FALSE); lwb_t *lwb = zcw->zcw_lwb; ASSERT3P(lwb, !=, NULL); ASSERT3S(lwb->lwb_state, !=, LWB_STATE_NEW); /* * If the lwb has already been issued by another thread, we can * immediately return since there's no work to be done (the * point of this function is to issue the lwb). Additionally, we * do this prior to acquiring the zl_issuer_lock, to avoid * acquiring it when it's not necessary to do so. */ if (lwb->lwb_state != LWB_STATE_OPENED) return; /* * In order to call zil_lwb_write_close() we must hold the * zilog's "zl_issuer_lock". We can't simply acquire that lock, * since we're already holding the commit waiter's "zcw_lock", * and those two locks are acquired in the opposite order * elsewhere. */ mutex_exit(&zcw->zcw_lock); mutex_enter(&zilog->zl_issuer_lock); mutex_enter(&zcw->zcw_lock); /* * Since we just dropped and re-acquired the commit waiter's * lock, we have to re-check to see if the waiter was marked * "done" during that process. If the waiter was marked "done", * the "lwb" pointer is no longer valid (it can be free'd after * the waiter is marked "done"), so without this check we could * wind up with a use-after-free error below. */ if (zcw->zcw_done) { mutex_exit(&zilog->zl_issuer_lock); return; } ASSERT3P(lwb, ==, zcw->zcw_lwb); /* * We've already checked this above, but since we hadn't acquired * the zilog's zl_issuer_lock, we have to perform this check a * second time while holding the lock. * * We don't need to hold the zl_lock since the lwb cannot transition * from OPENED to CLOSED while we hold the zl_issuer_lock. The lwb * _can_ transition from CLOSED to DONE, but it's OK to race with * that transition since we treat the lwb the same, whether it's in * the CLOSED, ISSUED or DONE states. * * The important thing, is we treat the lwb differently depending on * if it's OPENED or CLOSED, and block any other threads that might * attempt to close/issue this lwb. For that reason we hold the * zl_issuer_lock when checking the lwb_state; we must not call * zil_lwb_write_close() if the lwb had already been closed/issued. * * See the comment above the lwb_state_t structure definition for * more details on the lwb states, and locking requirements. */ if (lwb->lwb_state != LWB_STATE_OPENED) { mutex_exit(&zilog->zl_issuer_lock); return; } /* * We do not need zcw_lock once we hold zl_issuer_lock and know lwb * is still open. But we have to drop it to avoid a deadlock in case * callback of zio issued by zil_lwb_write_issue() try to get it, * while zil_lwb_write_issue() is blocked on attempt to issue next * lwb it found in LWB_STATE_READY state. */ mutex_exit(&zcw->zcw_lock); /* * As described in the comments above zil_commit_waiter() and * zil_process_commit_list(), we need to issue this lwb's zio * since we've reached the commit waiter's timeout and it still * hasn't been issued. */ lwb_t *nlwb = zil_lwb_write_close(zilog, lwb, LWB_STATE_NEW); ASSERT3S(lwb->lwb_state, ==, LWB_STATE_CLOSED); /* * Since the lwb's zio hadn't been issued by the time this thread * reached its timeout, we reset the zilog's "zl_cur_used" field * to influence the zil block size selection algorithm. * * By having to issue the lwb's zio here, it means the size of the * lwb was too large, given the incoming throughput of itxs. By * setting "zl_cur_used" to zero, we communicate this fact to the * block size selection algorithm, so it can take this information * into account, and potentially select a smaller size for the * next lwb block that is allocated. */ zilog->zl_cur_used = 0; if (nlwb == NULL) { /* * When zil_lwb_write_close() returns NULL, this * indicates zio_alloc_zil() failed to allocate the * "next" lwb on-disk. When this occurs, the ZIL write * pipeline must be stalled; see the comment within the * zil_commit_writer_stall() function for more details. */ zil_lwb_write_issue(zilog, lwb); zil_commit_writer_stall(zilog); mutex_exit(&zilog->zl_issuer_lock); } else { mutex_exit(&zilog->zl_issuer_lock); zil_lwb_write_issue(zilog, lwb); } mutex_enter(&zcw->zcw_lock); } /* * This function is responsible for performing the following two tasks: * * 1. its primary responsibility is to block until the given "commit * waiter" is considered "done". * * 2. its secondary responsibility is to issue the zio for the lwb that * the given "commit waiter" is waiting on, if this function has * waited "long enough" and the lwb is still in the "open" state. * * Given a sufficient amount of itxs being generated and written using * the ZIL, the lwb's zio will be issued via the zil_lwb_assign() * function. If this does not occur, this secondary responsibility will * ensure the lwb is issued even if there is not other synchronous * activity on the system. * * For more details, see zil_process_commit_list(); more specifically, * the comment at the bottom of that function. */ static void zil_commit_waiter(zilog_t *zilog, zil_commit_waiter_t *zcw) { ASSERT(!MUTEX_HELD(&zilog->zl_lock)); ASSERT(!MUTEX_HELD(&zilog->zl_issuer_lock)); ASSERT(spa_writeable(zilog->zl_spa)); mutex_enter(&zcw->zcw_lock); /* * The timeout is scaled based on the lwb latency to avoid * significantly impacting the latency of each individual itx. * For more details, see the comment at the bottom of the * zil_process_commit_list() function. */ int pct = MAX(zfs_commit_timeout_pct, 1); hrtime_t sleep = (zilog->zl_last_lwb_latency * pct) / 100; hrtime_t wakeup = gethrtime() + sleep; boolean_t timedout = B_FALSE; while (!zcw->zcw_done) { ASSERT(MUTEX_HELD(&zcw->zcw_lock)); lwb_t *lwb = zcw->zcw_lwb; /* * Usually, the waiter will have a non-NULL lwb field here, * but it's possible for it to be NULL as a result of * zil_commit() racing with spa_sync(). * * When zil_clean() is called, it's possible for the itxg * list (which may be cleaned via a taskq) to contain * commit itxs. When this occurs, the commit waiters linked * off of these commit itxs will not be committed to an * lwb. Additionally, these commit waiters will not be * marked done until zil_commit_waiter_skip() is called via * zil_itxg_clean(). * * Thus, it's possible for this commit waiter (i.e. the * "zcw" variable) to be found in this "in between" state; * where it's "zcw_lwb" field is NULL, and it hasn't yet * been skipped, so it's "zcw_done" field is still B_FALSE. */ IMPLY(lwb != NULL, lwb->lwb_state != LWB_STATE_NEW); if (lwb != NULL && lwb->lwb_state == LWB_STATE_OPENED) { ASSERT3B(timedout, ==, B_FALSE); /* * If the lwb hasn't been issued yet, then we * need to wait with a timeout, in case this * function needs to issue the lwb after the * timeout is reached; responsibility (2) from * the comment above this function. */ int rc = cv_timedwait_hires(&zcw->zcw_cv, &zcw->zcw_lock, wakeup, USEC2NSEC(1), CALLOUT_FLAG_ABSOLUTE); if (rc != -1 || zcw->zcw_done) continue; timedout = B_TRUE; zil_commit_waiter_timeout(zilog, zcw); if (!zcw->zcw_done) { /* * If the commit waiter has already been * marked "done", it's possible for the * waiter's lwb structure to have already * been freed. Thus, we can only reliably * make these assertions if the waiter * isn't done. */ ASSERT3P(lwb, ==, zcw->zcw_lwb); ASSERT3S(lwb->lwb_state, !=, LWB_STATE_OPENED); } } else { /* * If the lwb isn't open, then it must have already * been issued. In that case, there's no need to * use a timeout when waiting for the lwb to * complete. * * Additionally, if the lwb is NULL, the waiter * will soon be signaled and marked done via * zil_clean() and zil_itxg_clean(), so no timeout * is required. */ IMPLY(lwb != NULL, lwb->lwb_state == LWB_STATE_CLOSED || lwb->lwb_state == LWB_STATE_READY || lwb->lwb_state == LWB_STATE_ISSUED || lwb->lwb_state == LWB_STATE_WRITE_DONE || lwb->lwb_state == LWB_STATE_FLUSH_DONE); cv_wait(&zcw->zcw_cv, &zcw->zcw_lock); } } mutex_exit(&zcw->zcw_lock); } static zil_commit_waiter_t * zil_alloc_commit_waiter(void) { zil_commit_waiter_t *zcw = kmem_cache_alloc(zil_zcw_cache, KM_SLEEP); cv_init(&zcw->zcw_cv, NULL, CV_DEFAULT, NULL); mutex_init(&zcw->zcw_lock, NULL, MUTEX_DEFAULT, NULL); list_link_init(&zcw->zcw_node); zcw->zcw_lwb = NULL; zcw->zcw_done = B_FALSE; zcw->zcw_zio_error = 0; return (zcw); } static void zil_free_commit_waiter(zil_commit_waiter_t *zcw) { ASSERT(!list_link_active(&zcw->zcw_node)); ASSERT3P(zcw->zcw_lwb, ==, NULL); ASSERT3B(zcw->zcw_done, ==, B_TRUE); mutex_destroy(&zcw->zcw_lock); cv_destroy(&zcw->zcw_cv); kmem_cache_free(zil_zcw_cache, zcw); } /* * This function is used to create a TX_COMMIT itx and assign it. This * way, it will be linked into the ZIL's list of synchronous itxs, and * then later committed to an lwb (or skipped) when * zil_process_commit_list() is called. */ static void zil_commit_itx_assign(zilog_t *zilog, zil_commit_waiter_t *zcw) { dmu_tx_t *tx = dmu_tx_create(zilog->zl_os); /* * Since we are not going to create any new dirty data, and we * can even help with clearing the existing dirty data, we * should not be subject to the dirty data based delays. We * use TXG_NOTHROTTLE to bypass the delay mechanism. */ VERIFY0(dmu_tx_assign(tx, TXG_WAIT | TXG_NOTHROTTLE)); itx_t *itx = zil_itx_create(TX_COMMIT, sizeof (lr_t)); itx->itx_sync = B_TRUE; itx->itx_private = zcw; zil_itx_assign(zilog, itx, tx); dmu_tx_commit(tx); } /* * Commit ZFS Intent Log transactions (itxs) to stable storage. * * When writing ZIL transactions to the on-disk representation of the * ZIL, the itxs are committed to a Log Write Block (lwb). Multiple * itxs can be committed to a single lwb. Once a lwb is written and * committed to stable storage (i.e. the lwb is written, and vdevs have * been flushed), each itx that was committed to that lwb is also * considered to be committed to stable storage. * * When an itx is committed to an lwb, the log record (lr_t) contained * by the itx is copied into the lwb's zio buffer, and once this buffer * is written to disk, it becomes an on-disk ZIL block. * * As itxs are generated, they're inserted into the ZIL's queue of * uncommitted itxs. The semantics of zil_commit() are such that it will * block until all itxs that were in the queue when it was called, are * committed to stable storage. * * If "foid" is zero, this means all "synchronous" and "asynchronous" * itxs, for all objects in the dataset, will be committed to stable * storage prior to zil_commit() returning. If "foid" is non-zero, all * "synchronous" itxs for all objects, but only "asynchronous" itxs * that correspond to the foid passed in, will be committed to stable * storage prior to zil_commit() returning. * * Generally speaking, when zil_commit() is called, the consumer doesn't * actually care about _all_ of the uncommitted itxs. Instead, they're * simply trying to waiting for a specific itx to be committed to disk, * but the interface(s) for interacting with the ZIL don't allow such * fine-grained communication. A better interface would allow a consumer * to create and assign an itx, and then pass a reference to this itx to * zil_commit(); such that zil_commit() would return as soon as that * specific itx was committed to disk (instead of waiting for _all_ * itxs to be committed). * * When a thread calls zil_commit() a special "commit itx" will be * generated, along with a corresponding "waiter" for this commit itx. * zil_commit() will wait on this waiter's CV, such that when the waiter * is marked done, and signaled, zil_commit() will return. * * This commit itx is inserted into the queue of uncommitted itxs. This * provides an easy mechanism for determining which itxs were in the * queue prior to zil_commit() having been called, and which itxs were * added after zil_commit() was called. * * The commit itx is special; it doesn't have any on-disk representation. * When a commit itx is "committed" to an lwb, the waiter associated * with it is linked onto the lwb's list of waiters. Then, when that lwb * completes, each waiter on the lwb's list is marked done and signaled * -- allowing the thread waiting on the waiter to return from zil_commit(). * * It's important to point out a few critical factors that allow us * to make use of the commit itxs, commit waiters, per-lwb lists of * commit waiters, and zio completion callbacks like we're doing: * * 1. The list of waiters for each lwb is traversed, and each commit * waiter is marked "done" and signaled, in the zio completion * callback of the lwb's zio[*]. * * * Actually, the waiters are signaled in the zio completion * callback of the root zio for the DKIOCFLUSHWRITECACHE commands * that are sent to the vdevs upon completion of the lwb zio. * * 2. When the itxs are inserted into the ZIL's queue of uncommitted * itxs, the order in which they are inserted is preserved[*]; as * itxs are added to the queue, they are added to the tail of * in-memory linked lists. * * When committing the itxs to lwbs (to be written to disk), they * are committed in the same order in which the itxs were added to * the uncommitted queue's linked list(s); i.e. the linked list of * itxs to commit is traversed from head to tail, and each itx is * committed to an lwb in that order. * * * To clarify: * * - the order of "sync" itxs is preserved w.r.t. other * "sync" itxs, regardless of the corresponding objects. * - the order of "async" itxs is preserved w.r.t. other * "async" itxs corresponding to the same object. * - the order of "async" itxs is *not* preserved w.r.t. other * "async" itxs corresponding to different objects. * - the order of "sync" itxs w.r.t. "async" itxs (or vice * versa) is *not* preserved, even for itxs that correspond * to the same object. * * For more details, see: zil_itx_assign(), zil_async_to_sync(), * zil_get_commit_list(), and zil_process_commit_list(). * * 3. The lwbs represent a linked list of blocks on disk. Thus, any * lwb cannot be considered committed to stable storage, until its * "previous" lwb is also committed to stable storage. This fact, * coupled with the fact described above, means that itxs are * committed in (roughly) the order in which they were generated. * This is essential because itxs are dependent on prior itxs. * Thus, we *must not* deem an itx as being committed to stable * storage, until *all* prior itxs have also been committed to * stable storage. * * To enforce this ordering of lwb zio's, while still leveraging as * much of the underlying storage performance as possible, we rely * on two fundamental concepts: * * 1. The creation and issuance of lwb zio's is protected by * the zilog's "zl_issuer_lock", which ensures only a single * thread is creating and/or issuing lwb's at a time * 2. The "previous" lwb is a child of the "current" lwb * (leveraging the zio parent-child dependency graph) * * By relying on this parent-child zio relationship, we can have * many lwb zio's concurrently issued to the underlying storage, * but the order in which they complete will be the same order in * which they were created. */ void zil_commit(zilog_t *zilog, uint64_t foid) { /* * We should never attempt to call zil_commit on a snapshot for * a couple of reasons: * * 1. A snapshot may never be modified, thus it cannot have any * in-flight itxs that would have modified the dataset. * * 2. By design, when zil_commit() is called, a commit itx will * be assigned to this zilog; as a result, the zilog will be * dirtied. We must not dirty the zilog of a snapshot; there's * checks in the code that enforce this invariant, and will * cause a panic if it's not upheld. */ ASSERT3B(dmu_objset_is_snapshot(zilog->zl_os), ==, B_FALSE); if (zilog->zl_sync == ZFS_SYNC_DISABLED) return; if (!spa_writeable(zilog->zl_spa)) { /* * If the SPA is not writable, there should never be any * pending itxs waiting to be committed to disk. If that * weren't true, we'd skip writing those itxs out, and * would break the semantics of zil_commit(); thus, we're * verifying that truth before we return to the caller. */ ASSERT(list_is_empty(&zilog->zl_lwb_list)); ASSERT3P(zilog->zl_last_lwb_opened, ==, NULL); for (int i = 0; i < TXG_SIZE; i++) ASSERT3P(zilog->zl_itxg[i].itxg_itxs, ==, NULL); return; } /* * If the ZIL is suspended, we don't want to dirty it by calling * zil_commit_itx_assign() below, nor can we write out * lwbs like would be done in zil_commit_write(). Thus, we * simply rely on txg_wait_synced() to maintain the necessary * semantics, and avoid calling those functions altogether. */ if (zilog->zl_suspend > 0) { txg_wait_synced(zilog->zl_dmu_pool, 0); return; } zil_commit_impl(zilog, foid); } void zil_commit_impl(zilog_t *zilog, uint64_t foid) { ZIL_STAT_BUMP(zilog, zil_commit_count); /* * Move the "async" itxs for the specified foid to the "sync" * queues, such that they will be later committed (or skipped) * to an lwb when zil_process_commit_list() is called. * * Since these "async" itxs must be committed prior to this * call to zil_commit returning, we must perform this operation * before we call zil_commit_itx_assign(). */ zil_async_to_sync(zilog, foid); /* * We allocate a new "waiter" structure which will initially be * linked to the commit itx using the itx's "itx_private" field. * Since the commit itx doesn't represent any on-disk state, * when it's committed to an lwb, rather than copying the its * lr_t into the lwb's buffer, the commit itx's "waiter" will be * added to the lwb's list of waiters. Then, when the lwb is * committed to stable storage, each waiter in the lwb's list of * waiters will be marked "done", and signalled. * * We must create the waiter and assign the commit itx prior to * calling zil_commit_writer(), or else our specific commit itx * is not guaranteed to be committed to an lwb prior to calling * zil_commit_waiter(). */ zil_commit_waiter_t *zcw = zil_alloc_commit_waiter(); zil_commit_itx_assign(zilog, zcw); uint64_t wtxg = zil_commit_writer(zilog, zcw); zil_commit_waiter(zilog, zcw); if (zcw->zcw_zio_error != 0) { /* * If there was an error writing out the ZIL blocks that * this thread is waiting on, then we fallback to * relying on spa_sync() to write out the data this * thread is waiting on. Obviously this has performance * implications, but the expectation is for this to be * an exceptional case, and shouldn't occur often. */ DTRACE_PROBE2(zil__commit__io__error, zilog_t *, zilog, zil_commit_waiter_t *, zcw); txg_wait_synced(zilog->zl_dmu_pool, 0); } else if (wtxg != 0) { txg_wait_synced(zilog->zl_dmu_pool, wtxg); } zil_free_commit_waiter(zcw); } /* * Called in syncing context to free committed log blocks and update log header. */ void zil_sync(zilog_t *zilog, dmu_tx_t *tx) { zil_header_t *zh = zil_header_in_syncing_context(zilog); uint64_t txg = dmu_tx_get_txg(tx); spa_t *spa = zilog->zl_spa; uint64_t *replayed_seq = &zilog->zl_replayed_seq[txg & TXG_MASK]; lwb_t *lwb; /* * We don't zero out zl_destroy_txg, so make sure we don't try * to destroy it twice. */ if (spa_sync_pass(spa) != 1) return; zil_lwb_flush_wait_all(zilog, txg); mutex_enter(&zilog->zl_lock); ASSERT(zilog->zl_stop_sync == 0); if (*replayed_seq != 0) { ASSERT(zh->zh_replay_seq < *replayed_seq); zh->zh_replay_seq = *replayed_seq; *replayed_seq = 0; } if (zilog->zl_destroy_txg == txg) { blkptr_t blk = zh->zh_log; dsl_dataset_t *ds = dmu_objset_ds(zilog->zl_os); ASSERT(list_is_empty(&zilog->zl_lwb_list)); memset(zh, 0, sizeof (zil_header_t)); memset(zilog->zl_replayed_seq, 0, sizeof (zilog->zl_replayed_seq)); if (zilog->zl_keep_first) { /* * If this block was part of log chain that couldn't * be claimed because a device was missing during * zil_claim(), but that device later returns, * then this block could erroneously appear valid. * To guard against this, assign a new GUID to the new * log chain so it doesn't matter what blk points to. */ zil_init_log_chain(zilog, &blk); zh->zh_log = blk; } else { /* * A destroyed ZIL chain can't contain any TX_SETSAXATTR * records. So, deactivate the feature for this dataset. * We activate it again when we start a new ZIL chain. */ if (dsl_dataset_feature_is_active(ds, SPA_FEATURE_ZILSAXATTR)) dsl_dataset_deactivate_feature(ds, SPA_FEATURE_ZILSAXATTR, tx); } } while ((lwb = list_head(&zilog->zl_lwb_list)) != NULL) { zh->zh_log = lwb->lwb_blk; if (lwb->lwb_state != LWB_STATE_FLUSH_DONE || lwb->lwb_alloc_txg > txg || lwb->lwb_max_txg > txg) break; list_remove(&zilog->zl_lwb_list, lwb); if (!BP_IS_HOLE(&lwb->lwb_blk)) zio_free(spa, txg, &lwb->lwb_blk); zil_free_lwb(zilog, lwb); /* * If we don't have anything left in the lwb list then * we've had an allocation failure and we need to zero * out the zil_header blkptr so that we don't end * up freeing the same block twice. */ if (list_is_empty(&zilog->zl_lwb_list)) BP_ZERO(&zh->zh_log); } mutex_exit(&zilog->zl_lock); } static int zil_lwb_cons(void *vbuf, void *unused, int kmflag) { (void) unused, (void) kmflag; lwb_t *lwb = vbuf; list_create(&lwb->lwb_itxs, sizeof (itx_t), offsetof(itx_t, itx_node)); list_create(&lwb->lwb_waiters, sizeof (zil_commit_waiter_t), offsetof(zil_commit_waiter_t, zcw_node)); avl_create(&lwb->lwb_vdev_tree, zil_lwb_vdev_compare, sizeof (zil_vdev_node_t), offsetof(zil_vdev_node_t, zv_node)); mutex_init(&lwb->lwb_vdev_lock, NULL, MUTEX_DEFAULT, NULL); return (0); } static void zil_lwb_dest(void *vbuf, void *unused) { (void) unused; lwb_t *lwb = vbuf; mutex_destroy(&lwb->lwb_vdev_lock); avl_destroy(&lwb->lwb_vdev_tree); list_destroy(&lwb->lwb_waiters); list_destroy(&lwb->lwb_itxs); } void zil_init(void) { zil_lwb_cache = kmem_cache_create("zil_lwb_cache", sizeof (lwb_t), 0, zil_lwb_cons, zil_lwb_dest, NULL, NULL, NULL, 0); zil_zcw_cache = kmem_cache_create("zil_zcw_cache", sizeof (zil_commit_waiter_t), 0, NULL, NULL, NULL, NULL, NULL, 0); zil_sums_init(&zil_sums_global); zil_kstats_global = kstat_create("zfs", 0, "zil", "misc", KSTAT_TYPE_NAMED, sizeof (zil_stats) / sizeof (kstat_named_t), KSTAT_FLAG_VIRTUAL); if (zil_kstats_global != NULL) { zil_kstats_global->ks_data = &zil_stats; zil_kstats_global->ks_update = zil_kstats_global_update; zil_kstats_global->ks_private = NULL; kstat_install(zil_kstats_global); } } void zil_fini(void) { kmem_cache_destroy(zil_zcw_cache); kmem_cache_destroy(zil_lwb_cache); if (zil_kstats_global != NULL) { kstat_delete(zil_kstats_global); zil_kstats_global = NULL; } zil_sums_fini(&zil_sums_global); } void zil_set_sync(zilog_t *zilog, uint64_t sync) { zilog->zl_sync = sync; } void zil_set_logbias(zilog_t *zilog, uint64_t logbias) { zilog->zl_logbias = logbias; } zilog_t * zil_alloc(objset_t *os, zil_header_t *zh_phys) { zilog_t *zilog; zilog = kmem_zalloc(sizeof (zilog_t), KM_SLEEP); zilog->zl_header = zh_phys; zilog->zl_os = os; zilog->zl_spa = dmu_objset_spa(os); zilog->zl_dmu_pool = dmu_objset_pool(os); zilog->zl_destroy_txg = TXG_INITIAL - 1; zilog->zl_logbias = dmu_objset_logbias(os); zilog->zl_sync = dmu_objset_syncprop(os); zilog->zl_dirty_max_txg = 0; zilog->zl_last_lwb_opened = NULL; zilog->zl_last_lwb_latency = 0; zilog->zl_max_block_size = zil_maxblocksize; mutex_init(&zilog->zl_lock, NULL, MUTEX_DEFAULT, NULL); mutex_init(&zilog->zl_issuer_lock, NULL, MUTEX_DEFAULT, NULL); mutex_init(&zilog->zl_lwb_io_lock, NULL, MUTEX_DEFAULT, NULL); for (int i = 0; i < TXG_SIZE; i++) { mutex_init(&zilog->zl_itxg[i].itxg_lock, NULL, MUTEX_DEFAULT, NULL); } list_create(&zilog->zl_lwb_list, sizeof (lwb_t), offsetof(lwb_t, lwb_node)); list_create(&zilog->zl_itx_commit_list, sizeof (itx_t), offsetof(itx_t, itx_node)); cv_init(&zilog->zl_cv_suspend, NULL, CV_DEFAULT, NULL); cv_init(&zilog->zl_lwb_io_cv, NULL, CV_DEFAULT, NULL); return (zilog); } void zil_free(zilog_t *zilog) { int i; zilog->zl_stop_sync = 1; ASSERT0(zilog->zl_suspend); ASSERT0(zilog->zl_suspending); ASSERT(list_is_empty(&zilog->zl_lwb_list)); list_destroy(&zilog->zl_lwb_list); ASSERT(list_is_empty(&zilog->zl_itx_commit_list)); list_destroy(&zilog->zl_itx_commit_list); for (i = 0; i < TXG_SIZE; i++) { /* * It's possible for an itx to be generated that doesn't dirty * a txg (e.g. ztest TX_TRUNCATE). So there's no zil_clean() * callback to remove the entry. We remove those here. * * Also free up the ziltest itxs. */ if (zilog->zl_itxg[i].itxg_itxs) zil_itxg_clean(zilog->zl_itxg[i].itxg_itxs); mutex_destroy(&zilog->zl_itxg[i].itxg_lock); } mutex_destroy(&zilog->zl_issuer_lock); mutex_destroy(&zilog->zl_lock); mutex_destroy(&zilog->zl_lwb_io_lock); cv_destroy(&zilog->zl_cv_suspend); cv_destroy(&zilog->zl_lwb_io_cv); kmem_free(zilog, sizeof (zilog_t)); } /* * Open an intent log. */ zilog_t * zil_open(objset_t *os, zil_get_data_t *get_data, zil_sums_t *zil_sums) { zilog_t *zilog = dmu_objset_zil(os); ASSERT3P(zilog->zl_get_data, ==, NULL); ASSERT3P(zilog->zl_last_lwb_opened, ==, NULL); ASSERT(list_is_empty(&zilog->zl_lwb_list)); zilog->zl_get_data = get_data; zilog->zl_sums = zil_sums; return (zilog); } /* * Close an intent log. */ void zil_close(zilog_t *zilog) { lwb_t *lwb; uint64_t txg; if (!dmu_objset_is_snapshot(zilog->zl_os)) { zil_commit(zilog, 0); } else { ASSERT(list_is_empty(&zilog->zl_lwb_list)); ASSERT0(zilog->zl_dirty_max_txg); ASSERT3B(zilog_is_dirty(zilog), ==, B_FALSE); } mutex_enter(&zilog->zl_lock); txg = zilog->zl_dirty_max_txg; lwb = list_tail(&zilog->zl_lwb_list); if (lwb != NULL) { txg = MAX(txg, lwb->lwb_alloc_txg); txg = MAX(txg, lwb->lwb_max_txg); } mutex_exit(&zilog->zl_lock); /* * zl_lwb_max_issued_txg may be larger than lwb_max_txg. It depends * on the time when the dmu_tx transaction is assigned in * zil_lwb_write_issue(). */ mutex_enter(&zilog->zl_lwb_io_lock); txg = MAX(zilog->zl_lwb_max_issued_txg, txg); mutex_exit(&zilog->zl_lwb_io_lock); /* * We need to use txg_wait_synced() to wait until that txg is synced. * zil_sync() will guarantee all lwbs up to that txg have been * written out, flushed, and cleaned. */ if (txg != 0) txg_wait_synced(zilog->zl_dmu_pool, txg); if (zilog_is_dirty(zilog)) zfs_dbgmsg("zil (%px) is dirty, txg %llu", zilog, (u_longlong_t)txg); if (txg < spa_freeze_txg(zilog->zl_spa)) VERIFY(!zilog_is_dirty(zilog)); zilog->zl_get_data = NULL; /* * We should have only one lwb left on the list; remove it now. */ mutex_enter(&zilog->zl_lock); lwb = list_remove_head(&zilog->zl_lwb_list); if (lwb != NULL) { ASSERT(list_is_empty(&zilog->zl_lwb_list)); ASSERT3S(lwb->lwb_state, ==, LWB_STATE_NEW); zio_buf_free(lwb->lwb_buf, lwb->lwb_sz); zil_free_lwb(zilog, lwb); } mutex_exit(&zilog->zl_lock); } static const char *suspend_tag = "zil suspending"; /* * Suspend an intent log. While in suspended mode, we still honor * synchronous semantics, but we rely on txg_wait_synced() to do it. * On old version pools, we suspend the log briefly when taking a * snapshot so that it will have an empty intent log. * * Long holds are not really intended to be used the way we do here -- * held for such a short time. A concurrent caller of dsl_dataset_long_held() * could fail. Therefore we take pains to only put a long hold if it is * actually necessary. Fortunately, it will only be necessary if the * objset is currently mounted (or the ZVOL equivalent). In that case it * will already have a long hold, so we are not really making things any worse. * * Ideally, we would locate the existing long-holder (i.e. the zfsvfs_t or * zvol_state_t), and use their mechanism to prevent their hold from being * dropped (e.g. VFS_HOLD()). However, that would be even more pain for * very little gain. * * if cookiep == NULL, this does both the suspend & resume. * Otherwise, it returns with the dataset "long held", and the cookie * should be passed into zil_resume(). */ int zil_suspend(const char *osname, void **cookiep) { objset_t *os; zilog_t *zilog; const zil_header_t *zh; int error; error = dmu_objset_hold(osname, suspend_tag, &os); if (error != 0) return (error); zilog = dmu_objset_zil(os); mutex_enter(&zilog->zl_lock); zh = zilog->zl_header; if (zh->zh_flags & ZIL_REPLAY_NEEDED) { /* unplayed log */ mutex_exit(&zilog->zl_lock); dmu_objset_rele(os, suspend_tag); return (SET_ERROR(EBUSY)); } /* * Don't put a long hold in the cases where we can avoid it. This * is when there is no cookie so we are doing a suspend & resume * (i.e. called from zil_vdev_offline()), and there's nothing to do * for the suspend because it's already suspended, or there's no ZIL. */ if (cookiep == NULL && !zilog->zl_suspending && (zilog->zl_suspend > 0 || BP_IS_HOLE(&zh->zh_log))) { mutex_exit(&zilog->zl_lock); dmu_objset_rele(os, suspend_tag); return (0); } dsl_dataset_long_hold(dmu_objset_ds(os), suspend_tag); dsl_pool_rele(dmu_objset_pool(os), suspend_tag); zilog->zl_suspend++; if (zilog->zl_suspend > 1) { /* * Someone else is already suspending it. * Just wait for them to finish. */ while (zilog->zl_suspending) cv_wait(&zilog->zl_cv_suspend, &zilog->zl_lock); mutex_exit(&zilog->zl_lock); if (cookiep == NULL) zil_resume(os); else *cookiep = os; return (0); } /* * If there is no pointer to an on-disk block, this ZIL must not * be active (e.g. filesystem not mounted), so there's nothing * to clean up. */ if (BP_IS_HOLE(&zh->zh_log)) { ASSERT(cookiep != NULL); /* fast path already handled */ *cookiep = os; mutex_exit(&zilog->zl_lock); return (0); } /* * The ZIL has work to do. Ensure that the associated encryption * key will remain mapped while we are committing the log by * grabbing a reference to it. If the key isn't loaded we have no * choice but to return an error until the wrapping key is loaded. */ if (os->os_encrypted && dsl_dataset_create_key_mapping(dmu_objset_ds(os)) != 0) { zilog->zl_suspend--; mutex_exit(&zilog->zl_lock); dsl_dataset_long_rele(dmu_objset_ds(os), suspend_tag); dsl_dataset_rele(dmu_objset_ds(os), suspend_tag); return (SET_ERROR(EACCES)); } zilog->zl_suspending = B_TRUE; mutex_exit(&zilog->zl_lock); /* * We need to use zil_commit_impl to ensure we wait for all * LWB_STATE_OPENED, _CLOSED and _READY lwbs to be committed * to disk before proceeding. If we used zil_commit instead, it * would just call txg_wait_synced(), because zl_suspend is set. * txg_wait_synced() doesn't wait for these lwb's to be * LWB_STATE_FLUSH_DONE before returning. */ zil_commit_impl(zilog, 0); /* * Now that we've ensured all lwb's are LWB_STATE_FLUSH_DONE, we * use txg_wait_synced() to ensure the data from the zilog has * migrated to the main pool before calling zil_destroy(). */ txg_wait_synced(zilog->zl_dmu_pool, 0); zil_destroy(zilog, B_FALSE); mutex_enter(&zilog->zl_lock); zilog->zl_suspending = B_FALSE; cv_broadcast(&zilog->zl_cv_suspend); mutex_exit(&zilog->zl_lock); if (os->os_encrypted) dsl_dataset_remove_key_mapping(dmu_objset_ds(os)); if (cookiep == NULL) zil_resume(os); else *cookiep = os; return (0); } void zil_resume(void *cookie) { objset_t *os = cookie; zilog_t *zilog = dmu_objset_zil(os); mutex_enter(&zilog->zl_lock); ASSERT(zilog->zl_suspend != 0); zilog->zl_suspend--; mutex_exit(&zilog->zl_lock); dsl_dataset_long_rele(dmu_objset_ds(os), suspend_tag); dsl_dataset_rele(dmu_objset_ds(os), suspend_tag); } typedef struct zil_replay_arg { zil_replay_func_t *const *zr_replay; void *zr_arg; boolean_t zr_byteswap; char *zr_lr; } zil_replay_arg_t; static int zil_replay_error(zilog_t *zilog, const lr_t *lr, int error) { char name[ZFS_MAX_DATASET_NAME_LEN]; zilog->zl_replaying_seq--; /* didn't actually replay this one */ dmu_objset_name(zilog->zl_os, name); cmn_err(CE_WARN, "ZFS replay transaction error %d, " "dataset %s, seq 0x%llx, txtype %llu %s\n", error, name, (u_longlong_t)lr->lrc_seq, (u_longlong_t)(lr->lrc_txtype & ~TX_CI), (lr->lrc_txtype & TX_CI) ? "CI" : ""); return (error); } static int zil_replay_log_record(zilog_t *zilog, const lr_t *lr, void *zra, uint64_t claim_txg) { zil_replay_arg_t *zr = zra; const zil_header_t *zh = zilog->zl_header; uint64_t reclen = lr->lrc_reclen; uint64_t txtype = lr->lrc_txtype; int error = 0; zilog->zl_replaying_seq = lr->lrc_seq; if (lr->lrc_seq <= zh->zh_replay_seq) /* already replayed */ return (0); if (lr->lrc_txg < claim_txg) /* already committed */ return (0); /* Strip case-insensitive bit, still present in log record */ txtype &= ~TX_CI; if (txtype == 0 || txtype >= TX_MAX_TYPE) return (zil_replay_error(zilog, lr, EINVAL)); /* * If this record type can be logged out of order, the object * (lr_foid) may no longer exist. That's legitimate, not an error. */ if (TX_OOO(txtype)) { error = dmu_object_info(zilog->zl_os, LR_FOID_GET_OBJ(((lr_ooo_t *)lr)->lr_foid), NULL); if (error == ENOENT || error == EEXIST) return (0); } /* * Make a copy of the data so we can revise and extend it. */ memcpy(zr->zr_lr, lr, reclen); /* * If this is a TX_WRITE with a blkptr, suck in the data. */ if (txtype == TX_WRITE && reclen == sizeof (lr_write_t)) { error = zil_read_log_data(zilog, (lr_write_t *)lr, zr->zr_lr + reclen); if (error != 0) return (zil_replay_error(zilog, lr, error)); } /* * The log block containing this lr may have been byteswapped * so that we can easily examine common fields like lrc_txtype. * However, the log is a mix of different record types, and only the * replay vectors know how to byteswap their records. Therefore, if * the lr was byteswapped, undo it before invoking the replay vector. */ if (zr->zr_byteswap) byteswap_uint64_array(zr->zr_lr, reclen); /* * We must now do two things atomically: replay this log record, * and update the log header sequence number to reflect the fact that * we did so. At the end of each replay function the sequence number * is updated if we are in replay mode. */ error = zr->zr_replay[txtype](zr->zr_arg, zr->zr_lr, zr->zr_byteswap); if (error != 0) { /* * The DMU's dnode layer doesn't see removes until the txg * commits, so a subsequent claim can spuriously fail with * EEXIST. So if we receive any error we try syncing out * any removes then retry the transaction. Note that we * specify B_FALSE for byteswap now, so we don't do it twice. */ txg_wait_synced(spa_get_dsl(zilog->zl_spa), 0); error = zr->zr_replay[txtype](zr->zr_arg, zr->zr_lr, B_FALSE); if (error != 0) return (zil_replay_error(zilog, lr, error)); } return (0); } static int zil_incr_blks(zilog_t *zilog, const blkptr_t *bp, void *arg, uint64_t claim_txg) { (void) bp, (void) arg, (void) claim_txg; zilog->zl_replay_blks++; return (0); } /* * If this dataset has a non-empty intent log, replay it and destroy it. * Return B_TRUE if there were any entries to replay. */ boolean_t zil_replay(objset_t *os, void *arg, zil_replay_func_t *const replay_func[TX_MAX_TYPE]) { zilog_t *zilog = dmu_objset_zil(os); const zil_header_t *zh = zilog->zl_header; zil_replay_arg_t zr; if ((zh->zh_flags & ZIL_REPLAY_NEEDED) == 0) { return (zil_destroy(zilog, B_TRUE)); } zr.zr_replay = replay_func; zr.zr_arg = arg; zr.zr_byteswap = BP_SHOULD_BYTESWAP(&zh->zh_log); zr.zr_lr = vmem_alloc(2 * SPA_MAXBLOCKSIZE, KM_SLEEP); /* * Wait for in-progress removes to sync before starting replay. */ txg_wait_synced(zilog->zl_dmu_pool, 0); zilog->zl_replay = B_TRUE; zilog->zl_replay_time = ddi_get_lbolt(); ASSERT(zilog->zl_replay_blks == 0); (void) zil_parse(zilog, zil_incr_blks, zil_replay_log_record, &zr, zh->zh_claim_txg, B_TRUE); vmem_free(zr.zr_lr, 2 * SPA_MAXBLOCKSIZE); zil_destroy(zilog, B_FALSE); txg_wait_synced(zilog->zl_dmu_pool, zilog->zl_destroy_txg); zilog->zl_replay = B_FALSE; return (B_TRUE); } boolean_t zil_replaying(zilog_t *zilog, dmu_tx_t *tx) { if (zilog->zl_sync == ZFS_SYNC_DISABLED) return (B_TRUE); if (zilog->zl_replay) { dsl_dataset_dirty(dmu_objset_ds(zilog->zl_os), tx); zilog->zl_replayed_seq[dmu_tx_get_txg(tx) & TXG_MASK] = zilog->zl_replaying_seq; return (B_TRUE); } return (B_FALSE); } int zil_reset(const char *osname, void *arg) { (void) arg; int error = zil_suspend(osname, NULL); /* EACCES means crypto key not loaded */ if ((error == EACCES) || (error == EBUSY)) return (SET_ERROR(error)); if (error != 0) return (SET_ERROR(EEXIST)); return (0); } EXPORT_SYMBOL(zil_alloc); EXPORT_SYMBOL(zil_free); EXPORT_SYMBOL(zil_open); EXPORT_SYMBOL(zil_close); EXPORT_SYMBOL(zil_replay); EXPORT_SYMBOL(zil_replaying); EXPORT_SYMBOL(zil_destroy); EXPORT_SYMBOL(zil_destroy_sync); EXPORT_SYMBOL(zil_itx_create); EXPORT_SYMBOL(zil_itx_destroy); EXPORT_SYMBOL(zil_itx_assign); EXPORT_SYMBOL(zil_commit); EXPORT_SYMBOL(zil_claim); EXPORT_SYMBOL(zil_check_log_chain); EXPORT_SYMBOL(zil_sync); EXPORT_SYMBOL(zil_clean); EXPORT_SYMBOL(zil_suspend); EXPORT_SYMBOL(zil_resume); EXPORT_SYMBOL(zil_lwb_add_block); EXPORT_SYMBOL(zil_bp_tree_add); EXPORT_SYMBOL(zil_set_sync); EXPORT_SYMBOL(zil_set_logbias); EXPORT_SYMBOL(zil_sums_init); EXPORT_SYMBOL(zil_sums_fini); EXPORT_SYMBOL(zil_kstat_values_update); ZFS_MODULE_PARAM(zfs, zfs_, commit_timeout_pct, UINT, ZMOD_RW, "ZIL block open timeout percentage"); ZFS_MODULE_PARAM(zfs_zil, zil_, min_commit_timeout, U64, ZMOD_RW, "Minimum delay we care for ZIL block commit"); ZFS_MODULE_PARAM(zfs_zil, zil_, replay_disable, INT, ZMOD_RW, "Disable intent logging replay"); ZFS_MODULE_PARAM(zfs_zil, zil_, nocacheflush, INT, ZMOD_RW, "Disable ZIL cache flushes"); ZFS_MODULE_PARAM(zfs_zil, zil_, slog_bulk, U64, ZMOD_RW, "Limit in bytes slog sync writes per commit"); ZFS_MODULE_PARAM(zfs_zil, zil_, maxblocksize, UINT, ZMOD_RW, "Limit in bytes of ZIL log block size"); ZFS_MODULE_PARAM(zfs_zil, zil_, maxcopied, UINT, ZMOD_RW, "Limit in bytes WR_COPIED size"); diff --git a/sys/contrib/openzfs/tests/runfiles/linux.run b/sys/contrib/openzfs/tests/runfiles/linux.run index 2252e46df3a8..8bc55a1b4b47 100644 --- a/sys/contrib/openzfs/tests/runfiles/linux.run +++ b/sys/contrib/openzfs/tests/runfiles/linux.run @@ -1,228 +1,228 @@ # # This file and its contents are supplied under the terms of the # Common Development and Distribution License ("CDDL"), version 1.0. # You may only use this file in accordance with the terms of version # 1.0 of the CDDL. # # A full copy of the text of the CDDL should have accompanied this # source. A copy of the CDDL is also available via the Internet at # http://www.illumos.org/license/CDDL. # [DEFAULT] pre = setup quiet = False pre_user = root user = root timeout = 600 post_user = root post = cleanup failsafe_user = root failsafe = callbacks/zfs_failsafe outputdir = /var/tmp/test_results tags = ['functional'] [tests/functional/acl/posix:Linux] tests = ['posix_001_pos', 'posix_002_pos', 'posix_003_pos', 'posix_004_pos'] tags = ['functional', 'acl', 'posix'] [tests/functional/acl/posix-sa:Linux] tests = ['posix_001_pos', 'posix_002_pos', 'posix_003_pos', 'posix_004_pos'] tags = ['functional', 'acl', 'posix-sa'] [tests/functional/atime:Linux] tests = ['atime_003_pos', 'root_relatime_on'] tags = ['functional', 'atime'] [tests/functional/block_cloning:Linux] tests = ['block_cloning_copyfilerange', 'block_cloning_copyfilerange_partial', 'block_cloning_copyfilerange_fallback', 'block_cloning_ficlone', 'block_cloning_ficlonerange', 'block_cloning_ficlonerange_partial', 'block_cloning_disabled_copyfilerange', 'block_cloning_disabled_ficlone', 'block_cloning_disabled_ficlonerange', 'block_cloning_copyfilerange_cross_dataset', 'block_cloning_copyfilerange_fallback_same_txg'] tags = ['functional', 'block_cloning'] [tests/functional/chattr:Linux] tests = ['chattr_001_pos', 'chattr_002_neg'] tags = ['functional', 'chattr'] [tests/functional/cli_root/zfs:Linux] tests = ['zfs_003_neg'] tags = ['functional', 'cli_root', 'zfs'] [tests/functional/cli_root/zfs_mount:Linux] tests = ['zfs_mount_006_pos', 'zfs_mount_008_pos', 'zfs_mount_013_pos', 'zfs_mount_014_neg', 'zfs_multi_mount'] tags = ['functional', 'cli_root', 'zfs_mount'] [tests/functional/cli_root/zfs_share:Linux] tests = ['zfs_share_005_pos', 'zfs_share_007_neg', 'zfs_share_009_neg', 'zfs_share_012_pos', 'zfs_share_013_pos'] tags = ['functional', 'cli_root', 'zfs_share'] [tests/functional/cli_root/zfs_unshare:Linux] tests = ['zfs_unshare_008_pos'] tags = ['functional', 'cli_root', 'zfs_unshare'] [tests/functional/cli_root/zfs_sysfs:Linux] tests = ['zfeature_set_unsupported', 'zfs_get_unsupported', 'zfs_set_unsupported', 'zfs_sysfs_live', 'zpool_get_unsupported', 'zpool_set_unsupported'] tags = ['functional', 'cli_root', 'zfs_sysfs'] [tests/functional/cli_root/zpool_add:Linux] tests = ['add_nested_replacing_spare'] tags = ['functional', 'cli_root', 'zpool_add'] [tests/functional/cli_root/zpool_expand:Linux] tests = ['zpool_expand_001_pos', 'zpool_expand_002_pos', 'zpool_expand_003_neg', 'zpool_expand_004_pos', 'zpool_expand_005_pos'] tags = ['functional', 'cli_root', 'zpool_expand'] [tests/functional/cli_root/zpool_import:Linux] tests = ['zpool_import_hostid_changed', 'zpool_import_hostid_changed_unclean_export', 'zpool_import_hostid_changed_cachefile', 'zpool_import_hostid_changed_cachefile_unclean_export'] tags = ['functional', 'cli_root', 'zpool_import'] [tests/functional/cli_root/zpool_reopen:Linux] tests = ['zpool_reopen_001_pos', 'zpool_reopen_002_pos', 'zpool_reopen_003_pos', 'zpool_reopen_004_pos', 'zpool_reopen_005_pos', 'zpool_reopen_006_neg', 'zpool_reopen_007_pos'] tags = ['functional', 'cli_root', 'zpool_reopen'] [tests/functional/cli_root/zpool_split:Linux] tests = ['zpool_split_wholedisk'] tags = ['functional', 'cli_root', 'zpool_split'] [tests/functional/compression:Linux] tests = ['compress_004_pos'] tags = ['functional', 'compression'] [tests/functional/devices:Linux] tests = ['devices_001_pos', 'devices_002_neg', 'devices_003_pos'] tags = ['functional', 'devices'] [tests/functional/events:Linux] tests = ['events_001_pos', 'events_002_pos', 'zed_rc_filter', 'zed_fd_spill', 'zed_cksum_reported', 'zed_cksum_config', 'zed_io_config'] tags = ['functional', 'events'] [tests/functional/fadvise:Linux] tests = ['fadvise_sequential'] tags = ['functional', 'fadvise'] [tests/functional/fallocate:Linux] tests = ['fallocate_prealloc', 'fallocate_zero-range'] tags = ['functional', 'fallocate'] [tests/functional/fault:Linux] tests = ['auto_offline_001_pos', 'auto_online_001_pos', 'auto_online_002_pos', - 'auto_replace_001_pos', 'auto_spare_001_pos', 'auto_spare_002_pos', - 'auto_spare_multiple', 'auto_spare_ashift', 'auto_spare_shared', - 'decrypt_fault', 'decompress_fault', 'scrub_after_resilver', - 'zpool_status_-s'] + 'auto_replace_001_pos', 'auto_replace_002_pos', 'auto_spare_001_pos', + 'auto_spare_002_pos', 'auto_spare_multiple', 'auto_spare_ashift', + 'auto_spare_shared', 'decrypt_fault', 'decompress_fault', + 'scrub_after_resilver', 'zpool_status_-s'] tags = ['functional', 'fault'] [tests/functional/features/large_dnode:Linux] tests = ['large_dnode_002_pos', 'large_dnode_006_pos', 'large_dnode_008_pos'] tags = ['functional', 'features', 'large_dnode'] [tests/functional/io:Linux] tests = ['libaio', 'io_uring'] tags = ['functional', 'io'] [tests/functional/largest_pool:Linux] tests = ['largest_pool_001_pos'] pre = post = tags = ['functional', 'largest_pool'] [tests/functional/mmap:Linux] tests = ['mmap_libaio_001_pos', 'mmap_sync_001_pos'] tags = ['functional', 'mmap'] [tests/functional/mmp:Linux] tests = ['mmp_on_thread', 'mmp_on_uberblocks', 'mmp_on_off', 'mmp_interval', 'mmp_active_import', 'mmp_inactive_import', 'mmp_exported_import', 'mmp_write_uberblocks', 'mmp_reset_interval', 'multihost_history', 'mmp_on_zdb', 'mmp_write_distribution', 'mmp_hostid'] tags = ['functional', 'mmp'] [tests/functional/mount:Linux] tests = ['umount_unlinked_drain'] tags = ['functional', 'mount'] [tests/functional/pam:Linux] tests = ['pam_basic', 'pam_change_unmounted', 'pam_nounmount', 'pam_recursive', 'pam_short_password'] tags = ['functional', 'pam'] [tests/functional/procfs:Linux] tests = ['procfs_list_basic', 'procfs_list_concurrent_readers', 'procfs_list_stale_read', 'pool_state'] tags = ['functional', 'procfs'] [tests/functional/projectquota:Linux] tests = ['projectid_001_pos', 'projectid_002_pos', 'projectid_003_pos', 'projectquota_001_pos', 'projectquota_002_pos', 'projectquota_003_pos', 'projectquota_004_neg', 'projectquota_005_pos', 'projectquota_006_pos', 'projectquota_007_pos', 'projectquota_008_pos', 'projectquota_009_pos', 'projectspace_001_pos', 'projectspace_002_pos', 'projectspace_003_pos', 'projectspace_004_pos', 'projecttree_001_pos', 'projecttree_002_pos', 'projecttree_003_neg'] tags = ['functional', 'projectquota'] [tests/functional/dos_attributes:Linux] tests = ['read_dos_attrs_001', 'write_dos_attrs_001'] tags = ['functional', 'dos_attributes'] [tests/functional/renameat2:Linux] tests = ['renameat2_noreplace', 'renameat2_exchange', 'renameat2_whiteout'] tags = ['functional', 'renameat2'] [tests/functional/rsend:Linux] tests = ['send_realloc_dnode_size', 'send_encrypted_files'] tags = ['functional', 'rsend'] [tests/functional/simd:Linux] pre = post = tests = ['simd_supported'] tags = ['functional', 'simd'] [tests/functional/snapshot:Linux] tests = ['snapshot_015_pos', 'snapshot_016_pos'] tags = ['functional', 'snapshot'] [tests/functional/tmpfile:Linux] tests = ['tmpfile_001_pos', 'tmpfile_002_pos', 'tmpfile_003_pos', 'tmpfile_stat_mode'] tags = ['functional', 'tmpfile'] [tests/functional/upgrade:Linux] tests = ['upgrade_projectquota_001_pos'] tags = ['functional', 'upgrade'] [tests/functional/user_namespace:Linux] tests = ['user_namespace_001', 'user_namespace_002', 'user_namespace_003', 'user_namespace_004'] tags = ['functional', 'user_namespace'] [tests/functional/userquota:Linux] tests = ['groupspace_001_pos', 'groupspace_002_pos', 'groupspace_003_pos', 'userquota_013_pos', 'userspace_003_pos'] tags = ['functional', 'userquota'] [tests/functional/zvol/zvol_misc:Linux] tests = ['zvol_misc_fua'] tags = ['functional', 'zvol', 'zvol_misc'] [tests/functional/idmap_mount:Linux] tests = ['idmap_mount_001', 'idmap_mount_002', 'idmap_mount_003', 'idmap_mount_004', 'idmap_mount_005'] tags = ['functional', 'idmap_mount'] diff --git a/sys/contrib/openzfs/tests/test-runner/bin/zts-report.py.in b/sys/contrib/openzfs/tests/test-runner/bin/zts-report.py.in index 5d1360380de5..4608e87522a3 100755 --- a/sys/contrib/openzfs/tests/test-runner/bin/zts-report.py.in +++ b/sys/contrib/openzfs/tests/test-runner/bin/zts-report.py.in @@ -1,475 +1,476 @@ #!/usr/bin/env @PYTHON_SHEBANG@ # # This file and its contents are supplied under the terms of the # Common Development and Distribution License ("CDDL"), version 1.0. # You may only use this file in accordance with the terms of version # 1.0 of the CDDL. # # A full copy of the text of the CDDL should have accompanied this # source. A copy of the CDDL is also available via the Internet at # http://www.illumos.org/license/CDDL. # # # Copyright (c) 2017 by Delphix. All rights reserved. # Copyright (c) 2018 by Lawrence Livermore National Security, LLC. # # This script must remain compatible with Python 3.6+. # import os import re import sys import argparse # # This script parses the stdout of zfstest, which has this format: # # Test: /path/to/testa (run as root) [00:00] [PASS] # Test: /path/to/testb (run as jkennedy) [00:00] [PASS] # Test: /path/to/testc (run as root) [00:00] [FAIL] # [...many more results...] # # Results Summary # FAIL 22 # SKIP 32 # PASS 1156 # # Running Time: 02:50:31 # Percent passed: 95.5% # Log directory: /var/tmp/test_results/20180615T205926 # # # Common generic reasons for a test or test group to be skipped. # # Some test cases are known to fail in ways which are not harmful or dangerous. # In these cases simply mark the test as a known failure until it can be # updated and the issue resolved. Note that it's preferable to open a unique # issue on the GitHub issue tracker for each test case failure. # known_reason = 'Known issue' # # Some tests require that a test user be able to execute the zfs utilities. # This may not be possible when testing in-tree due to the default permissions # on the user's home directory. When testing this can be resolved by granting # group read access. # # chmod 0750 $HOME # exec_reason = 'Test user execute permissions required for utilities' # # Some tests require that the kernel supports renameat2 syscall. # renameat2_reason = 'Kernel renameat2 support required' # # Some tests require the O_TMPFILE flag which was first introduced in the # 3.11 kernel. # tmpfile_reason = 'Kernel O_TMPFILE support required' # # Some tests require the statx(2) system call on Linux which was first # introduced in the 4.11 kernel. # statx_reason = 'Kernel statx(2) system call required on Linux' # # Some tests require that the lsattr utility support the project id feature. # project_id_reason = 'lsattr with set/show project ID required' # # Some tests require that the kernel support user namespaces. # user_ns_reason = 'Kernel user namespace support required' # # Some rewind tests can fail since nothing guarantees that old MOS blocks # are not overwritten. Snapshots protect datasets and data files but not # the MOS. Reasonable efforts are made in the test case to increase the # odds that some txgs will have their MOS data left untouched, but it is # never a sure thing. # rewind_reason = 'Arbitrary pool rewind is not guaranteed' # # Some tests require a minimum version of the fio benchmark utility. # Older distributions such as CentOS 6.x only provide fio-2.0.13. # fio_reason = 'Fio v2.3 or newer required' # # Some tests require that the DISKS provided support the discard operation. # Normally this is not an issue because loop back devices are used for DISKS # and they support discard (TRIM/UNMAP). # trim_reason = 'DISKS must support discard (TRIM/UNMAP)' # # Some tests on FreeBSD require the fspacectl(2) system call and the # truncate(1) utility supporting the -d option. The system call was first # introduced in FreeBSD version 1400032. # fspacectl_reason = 'fspacectl(2) and truncate -d support required' # # Some tests are not applicable to a platform or need to be updated to operate # in the manor required by the platform. Any tests which are skipped for this # reason will be suppressed in the final analysis output. # na_reason = "Not applicable" # # Some test cases doesn't have all requirements to run on Github actions CI. # ci_reason = 'CI runner doesn\'t have all requirements' # # Idmapped mount is only supported in kernel version >= 5.12 # idmap_reason = 'Idmapped mount needs kernel 5.12+' # # copy_file_range() is not supported by all kernels # cfr_reason = 'Kernel copy_file_range support required' cfr_cross_reason = 'copy_file_range(2) cross-filesystem needs kernel 5.3+' # # These tests are known to fail, thus we use this list to prevent these # failures from failing the job as a whole; only unexpected failures # bubble up to cause this script to exit with a non-zero exit status. # # Format: { 'test-name': ['expected result', 'issue-number | reason'] } # # For each known failure it is recommended to link to a GitHub issue by # setting the reason to the issue number. Alternately, one of the generic # reasons listed above can be used. # known = { 'casenorm/mixed_none_lookup_ci': ['FAIL', 7633], 'casenorm/mixed_formd_lookup_ci': ['FAIL', 7633], 'cli_root/zpool_import/import_rewind_device_replaced': ['FAIL', rewind_reason], 'cli_user/misc/zfs_share_001_neg': ['SKIP', na_reason], 'cli_user/misc/zfs_unshare_001_neg': ['SKIP', na_reason], 'pool_checkpoint/checkpoint_discard_busy': ['SKIP', 12053], 'privilege/setup': ['SKIP', na_reason], 'refreserv/refreserv_004_pos': ['FAIL', known_reason], 'rootpool/setup': ['SKIP', na_reason], 'rsend/rsend_008_pos': ['SKIP', 6066], 'vdev_zaps/vdev_zaps_007_pos': ['FAIL', known_reason], } if sys.platform.startswith('freebsd'): known.update({ 'cli_root/zfs_receive/receive-o-x_props_override': ['FAIL', known_reason], 'cli_root/zpool_resilver/zpool_resilver_concurrent': ['SKIP', na_reason], 'cli_root/zpool_wait/zpool_wait_trim_basic': ['SKIP', trim_reason], 'cli_root/zpool_wait/zpool_wait_trim_cancel': ['SKIP', trim_reason], 'cli_root/zpool_wait/zpool_wait_trim_flag': ['SKIP', trim_reason], 'cli_root/zfs_unshare/zfs_unshare_008_pos': ['SKIP', na_reason], 'link_count/link_count_001': ['SKIP', na_reason], 'casenorm/mixed_create_failure': ['FAIL', 13215], 'mmap/mmap_sync_001_pos': ['SKIP', na_reason], 'rsend/send_raw_ashift': ['SKIP', 14961], }) elif sys.platform.startswith('linux'): known.update({ 'casenorm/mixed_formd_lookup': ['FAIL', 7633], 'casenorm/mixed_formd_delete': ['FAIL', 7633], 'casenorm/sensitive_formd_lookup': ['FAIL', 7633], 'casenorm/sensitive_formd_delete': ['FAIL', 7633], 'removal/removal_with_zdb': ['SKIP', known_reason], 'cli_root/zfs_unshare/zfs_unshare_002_pos': ['SKIP', na_reason], }) # # These tests may occasionally fail or be skipped. We want there failures # to be reported but only unexpected failures should bubble up to cause # this script to exit with a non-zero exit status. # # Format: { 'test-name': ['expected result', 'issue-number | reason'] } # # For each known failure it is recommended to link to a GitHub issue by # setting the reason to the issue number. Alternately, one of the generic # reasons listed above can be used. # maybe = { 'append/threadsappend_001_pos': ['FAIL', 6136], 'chattr/setup': ['SKIP', exec_reason], 'crtime/crtime_001_pos': ['SKIP', statx_reason], 'cli_root/zdb/zdb_006_pos': ['FAIL', known_reason], 'cli_root/zfs_destroy/zfs_destroy_dev_removal_condense': ['FAIL', known_reason], 'cli_root/zfs_get/zfs_get_004_pos': ['FAIL', known_reason], 'cli_root/zfs_get/zfs_get_009_pos': ['SKIP', 5479], 'cli_root/zfs_rollback/zfs_rollback_001_pos': ['FAIL', known_reason], 'cli_root/zfs_rollback/zfs_rollback_002_pos': ['FAIL', known_reason], 'cli_root/zfs_share/zfs_share_concurrent_shares': ['FAIL', known_reason], 'cli_root/zfs_snapshot/zfs_snapshot_002_neg': ['FAIL', known_reason], 'cli_root/zfs_unshare/zfs_unshare_006_pos': ['SKIP', na_reason], 'cli_root/zpool_add/zpool_add_004_pos': ['FAIL', known_reason], 'cli_root/zpool_destroy/zpool_destroy_001_pos': ['SKIP', 6145], 'cli_root/zpool_import/zpool_import_missing_003_pos': ['SKIP', 6839], 'cli_root/zpool_initialize/zpool_initialize_import_export': ['FAIL', 11948], 'cli_root/zpool_labelclear/zpool_labelclear_removed': ['FAIL', known_reason], 'cli_root/zpool_trim/setup': ['SKIP', trim_reason], 'cli_root/zpool_upgrade/zpool_upgrade_004_pos': ['FAIL', 6141], 'delegate/setup': ['SKIP', exec_reason], 'fallocate/fallocate_punch-hole': ['SKIP', fspacectl_reason], 'history/history_004_pos': ['FAIL', 7026], 'history/history_005_neg': ['FAIL', 6680], 'history/history_006_neg': ['FAIL', 5657], 'history/history_008_pos': ['FAIL', known_reason], 'history/history_010_pos': ['SKIP', exec_reason], 'io/mmap': ['SKIP', fio_reason], 'largest_pool/largest_pool_001_pos': ['FAIL', known_reason], 'mmp/mmp_on_uberblocks': ['FAIL', known_reason], 'pam/setup': ['SKIP', "pamtester might be not available"], 'pool_checkpoint/checkpoint_discard_busy': ['FAIL', 11946], 'projectquota/setup': ['SKIP', exec_reason], 'removal/removal_condense_export': ['FAIL', known_reason], 'renameat2/setup': ['SKIP', renameat2_reason], 'reservation/reservation_008_pos': ['FAIL', 7741], 'reservation/reservation_018_pos': ['FAIL', 5642], 'snapshot/clone_001_pos': ['FAIL', known_reason], 'snapshot/snapshot_009_pos': ['FAIL', 7961], 'snapshot/snapshot_010_pos': ['FAIL', 7961], 'snapused/snapused_004_pos': ['FAIL', 5513], 'tmpfile/setup': ['SKIP', tmpfile_reason], 'trim/setup': ['SKIP', trim_reason], 'upgrade/upgrade_projectquota_001_pos': ['SKIP', project_id_reason], 'user_namespace/setup': ['SKIP', user_ns_reason], 'userquota/setup': ['SKIP', exec_reason], 'vdev_zaps/vdev_zaps_004_pos': ['FAIL', known_reason], 'zvol/zvol_ENOSPC/zvol_ENOSPC_001_pos': ['FAIL', 5848], } if sys.platform.startswith('freebsd'): maybe.update({ 'cli_root/zfs_copies/zfs_copies_002_pos': ['FAIL', known_reason], 'cli_root/zfs_inherit/zfs_inherit_001_neg': ['FAIL', known_reason], 'cli_root/zpool_import/zpool_import_012_pos': ['FAIL', known_reason], 'delegate/zfs_allow_003_pos': ['FAIL', known_reason], 'inheritance/inherit_001_pos': ['FAIL', 11829], 'resilver/resilver_restart_001': ['FAIL', known_reason], 'pool_checkpoint/checkpoint_big_rewind': ['FAIL', 12622], 'pool_checkpoint/checkpoint_indirect': ['FAIL', 12623], 'snapshot/snapshot_002_pos': ['FAIL', '14831'], }) elif sys.platform.startswith('linux'): maybe.update({ 'cli_root/zfs_rename/zfs_rename_002_pos': ['FAIL', known_reason], 'cli_root/zpool_reopen/zpool_reopen_003_pos': ['FAIL', known_reason], 'fault/auto_online_002_pos': ['FAIL', 11889], 'fault/auto_replace_001_pos': ['FAIL', 14851], 'fault/auto_spare_002_pos': ['FAIL', 11889], 'fault/auto_spare_multiple': ['FAIL', 11889], 'fault/auto_spare_shared': ['FAIL', 11889], 'fault/decompress_fault': ['FAIL', 11889], 'io/io_uring': ['SKIP', 'io_uring support required'], 'limits/filesystem_limit': ['SKIP', known_reason], 'limits/snapshot_limit': ['SKIP', known_reason], 'mmp/mmp_active_import': ['FAIL', known_reason], 'mmp/mmp_exported_import': ['FAIL', known_reason], 'mmp/mmp_inactive_import': ['FAIL', known_reason], 'zvol/zvol_misc/zvol_misc_snapdev': ['FAIL', 12621], 'zvol/zvol_misc/zvol_misc_volmode': ['FAIL', known_reason], 'zvol/zvol_misc/zvol_misc_fua': ['SKIP', 14872], 'zvol/zvol_misc/zvol_misc_trim': ['SKIP', 14872], 'idmap_mount/idmap_mount_001': ['SKIP', idmap_reason], 'idmap_mount/idmap_mount_002': ['SKIP', idmap_reason], 'idmap_mount/idmap_mount_003': ['SKIP', idmap_reason], 'idmap_mount/idmap_mount_004': ['SKIP', idmap_reason], 'idmap_mount/idmap_mount_005': ['SKIP', idmap_reason], 'block_cloning/block_cloning_disabled_copyfilerange': ['SKIP', cfr_reason], 'block_cloning/block_cloning_copyfilerange': ['SKIP', cfr_reason], 'block_cloning/block_cloning_copyfilerange_partial': ['SKIP', cfr_reason], 'block_cloning/block_cloning_copyfilerange_fallback': ['SKIP', cfr_reason], 'block_cloning/block_cloning_copyfilerange_cross_dataset': ['SKIP', cfr_cross_reason], 'block_cloning/block_cloning_copyfilerange_fallback_same_txg': ['SKIP', cfr_cross_reason], }) # Not all Github actions runners have scsi_debug module, so we may skip # some tests which use it. if os.environ.get('CI') == 'true': known.update({ 'cli_root/zpool_expand/zpool_expand_001_pos': ['SKIP', ci_reason], 'cli_root/zpool_expand/zpool_expand_003_neg': ['SKIP', ci_reason], 'cli_root/zpool_expand/zpool_expand_005_pos': ['SKIP', ci_reason], 'cli_root/zpool_reopen/setup': ['SKIP', ci_reason], 'cli_root/zpool_reopen/zpool_reopen_001_pos': ['SKIP', ci_reason], 'cli_root/zpool_reopen/zpool_reopen_002_pos': ['SKIP', ci_reason], 'cli_root/zpool_reopen/zpool_reopen_003_pos': ['SKIP', ci_reason], 'cli_root/zpool_reopen/zpool_reopen_004_pos': ['SKIP', ci_reason], 'cli_root/zpool_reopen/zpool_reopen_005_pos': ['SKIP', ci_reason], 'cli_root/zpool_reopen/zpool_reopen_006_neg': ['SKIP', ci_reason], 'cli_root/zpool_reopen/zpool_reopen_007_pos': ['SKIP', ci_reason], 'cli_root/zpool_split/zpool_split_wholedisk': ['SKIP', ci_reason], 'fault/auto_offline_001_pos': ['SKIP', ci_reason], 'fault/auto_online_001_pos': ['SKIP', ci_reason], 'fault/auto_online_002_pos': ['SKIP', ci_reason], 'fault/auto_replace_001_pos': ['SKIP', ci_reason], + 'fault/auto_replace_002_pos': ['SKIP', ci_reason], 'fault/auto_spare_ashift': ['SKIP', ci_reason], 'fault/auto_spare_shared': ['SKIP', ci_reason], 'procfs/pool_state': ['SKIP', ci_reason], }) maybe.update({ 'events/events_002_pos': ['FAIL', 11546], }) def process_results(pathname): try: f = open(pathname) except IOError as e: print('Error opening file:', e) sys.exit(1) prefix = '/zfs-tests/tests/(?:functional|perf/regression)/' pattern = \ r'^Test(?:\s+\(\S+\))?:' + \ rf'\s*\S*{prefix}(\S+)' + \ r'\s*\(run as (\S+)\)\s*\[(\S+)\]\s*\[(\S+)\]' pattern_log = r'^\s*Log directory:\s*(\S*)' d = {} logdir = 'Could not determine log directory.' for line in f.readlines(): m = re.match(pattern, line) if m and len(m.groups()) == 4: d[m.group(1)] = m.group(4) continue m = re.match(pattern_log, line) if m: logdir = m.group(1) return d, logdir class ListMaybesAction(argparse.Action): def __init__(self, option_strings, dest="SUPPRESS", default="SUPPRESS", help="list flaky tests and exit"): super(ListMaybesAction, self).__init__( option_strings=option_strings, dest=dest, default=default, nargs=0, help=help) def __call__(self, parser, namespace, values, option_string=None): for test in maybe: print(test) sys.exit(0) if __name__ == "__main__": parser = argparse.ArgumentParser(description='Analyze ZTS logs') parser.add_argument('logfile') parser.add_argument('--list-maybes', action=ListMaybesAction) parser.add_argument('--no-maybes', action='store_false', dest='maybes') args = parser.parse_args() results, logdir = process_results(args.logfile) if not results: print("\n\nNo test results were found.") print("Log directory:", logdir) sys.exit(0) expected = [] unexpected = [] all_maybes = True for test in list(results.keys()): if results[test] == "PASS": continue setup = test.replace(os.path.basename(test), "setup") if results[test] == "SKIP" and test != setup: if setup in known and known[setup][0] == "SKIP": continue if setup in maybe and maybe[setup][0] == "SKIP": continue if (test in known and results[test] in known[test][0]): expected.append(test) elif test in maybe and results[test] in maybe[test][0]: if results[test] == 'SKIP' or args.maybes: expected.append(test) elif not args.maybes: unexpected.append(test) else: unexpected.append(test) all_maybes = False print("\nTests with results other than PASS that are expected:") for test in sorted(expected): issue_url = 'https://github.com/openzfs/zfs/issues/' # Include the reason why the result is expected, given the following: # 1. Suppress test results which set the "Not applicable" reason. # 2. Numerical reasons are assumed to be GitHub issue numbers. # 3. When an entire test group is skipped only report the setup reason. if test in known: if known[test][1] == na_reason: continue elif isinstance(known[test][1], int): expect = f"{issue_url}{known[test][1]}" else: expect = known[test][1] elif test in maybe: if isinstance(maybe[test][1], int): expect = f"{issue_url}{maybe[test][1]}" else: expect = maybe[test][1] elif setup in known and known[setup][0] == "SKIP" and setup != test: continue elif setup in maybe and maybe[setup][0] == "SKIP" and setup != test: continue else: expect = "UNKNOWN REASON" print(f" {results[test]} {test} ({expect})") print("\nTests with result of PASS that are unexpected:") for test in sorted(known.keys()): # We probably should not be silently ignoring the case # where "test" is not in "results". if test not in results or results[test] != "PASS": continue print(f" {results[test]} {test} (expected {known[test][0]})") print("\nTests with results other than PASS that are unexpected:") for test in sorted(unexpected): expect = "PASS" if test not in known else known[test][0] print(f" {results[test]} {test} (expected {expect})") if len(unexpected) == 0: sys.exit(0) elif not args.maybes and all_maybes: sys.exit(2) else: sys.exit(1) diff --git a/sys/contrib/openzfs/tests/zfs-tests/include/commands.cfg b/sys/contrib/openzfs/tests/zfs-tests/include/commands.cfg index fa545e06bbf3..648f2203dfba 100644 --- a/sys/contrib/openzfs/tests/zfs-tests/include/commands.cfg +++ b/sys/contrib/openzfs/tests/zfs-tests/include/commands.cfg @@ -1,233 +1,234 @@ # # Copyright (c) 2016, 2019 by Delphix. All rights reserved. # These variables are used by zfs-tests.sh to constrain which utilities # may be used by the suite. The suite will create a directory which is # the only element of $PATH and create symlinks from that dir to the # binaries listed below. # # Please keep the contents of each variable sorted for ease of reading # and maintenance. # export SYSTEM_FILES_COMMON='awk basename bc bunzip2 bzcat cat chgrp chmod chown cksum cmp cp cpio cut date dd df diff dirname dmesg du echo env expr false file find fio getconf getent getfacl grep gunzip gzip head hostname id iostat kill ksh ldd ln ls mkdir mknod mkfifo mktemp mount mv net od openssl pamtester pax pgrep ping pkill printf ps python3 readlink rm rmdir rsync scp script sed seq setfacl sh sleep sort ssh stat strings sudo swapoff swapon sync tail tar timeout touch tr true truncate umount uname uniq vmstat wc' export SYSTEM_FILES_FREEBSD='chflags compress diskinfo fsck getextattr gpart jail jexec jls lsextattr md5 mdconfig newfs pw rmextattr setextattr sha256 showmount swapctl sysctl trim uncompress' export SYSTEM_FILES_LINUX='attr blkid blkdiscard blockdev chattr exportfs fallocate + flock free getfattr groupadd groupdel groupmod hostid + logger losetup lsattr lsblk lscpu lsmod lsscsi md5sum mkswap modprobe + mountpoint mpstat nsenter parted perf setfattr + setpriv sha256sum udevadm unshare useradd userdel usermod - setpriv - mountpoint - flock - logger' + wipefs' export ZFS_FILES='zdb zfs zhack zinject zpool ztest raidz_test arc_summary arcstat zilstat dbufstat mount.zfs zed zgenhostid zstream zfs_ids_to_path zpool_influxdb' export ZFSTEST_FILES='badsend btree_test chg_usr_exec clonefile devname2devid dir_rd_update draid file_fadvise file_append file_check file_trunc file_write get_diff getversion largest_file libzfs_input_check mkbusy mkfile mkfiles mktree mmap_exec mmap_libaio mmap_seek mmap_sync mmapwrite nvlist_to_lua randfree_file randwritecomp readmmap read_dos_attributes renameat2 rename_dir rm_lnkcnt_zero_file send_doall threadsappend user_ns_exec write_dos_attributes xattrtest stride_dd zed_fd_spill-zedlet suid_write_to_file cp_files blake3_test edonr_test skein_test sha2_test ctime truncate_test ereports zfs_diff-socket dosmode_readonly_write idmap_util' diff --git a/sys/contrib/openzfs/tests/zfs-tests/tests/Makefile.am b/sys/contrib/openzfs/tests/zfs-tests/tests/Makefile.am index 158401e078aa..87b50f59ca7a 100644 --- a/sys/contrib/openzfs/tests/zfs-tests/tests/Makefile.am +++ b/sys/contrib/openzfs/tests/zfs-tests/tests/Makefile.am @@ -1,2073 +1,2074 @@ CLEANFILES = dist_noinst_DATA = include $(top_srcdir)/config/Substfiles.am datadir_zfs_tests_testsdir = $(datadir)/$(PACKAGE)/zfs-tests/tests nobase_dist_datadir_zfs_tests_tests_DATA = \ perf/nfs-sample.cfg \ perf/perf.shlib \ \ perf/fio/mkfiles.fio \ perf/fio/random_reads.fio \ perf/fio/random_readwrite.fio \ perf/fio/random_readwrite_fixed.fio \ perf/fio/random_writes.fio \ perf/fio/sequential_reads.fio \ perf/fio/sequential_readwrite.fio \ perf/fio/sequential_writes.fio nobase_dist_datadir_zfs_tests_tests_SCRIPTS = \ perf/regression/random_reads.ksh \ perf/regression/random_readwrite.ksh \ perf/regression/random_readwrite_fixed.ksh \ perf/regression/random_writes.ksh \ perf/regression/random_writes_zil.ksh \ perf/regression/sequential_reads_arc_cached_clone.ksh \ perf/regression/sequential_reads_arc_cached.ksh \ perf/regression/sequential_reads_dbuf_cached.ksh \ perf/regression/sequential_reads.ksh \ perf/regression/sequential_writes.ksh \ perf/regression/setup.ksh \ \ perf/scripts/prefetch_io.sh # These lists can be regenerated by running make regen-tests at the root, or, on a *clean* source: # find functional/ ! -type d ! -name .gitignore ! -name .dirstamp ! -name '*.Po' ! -executable -name '*.in' | sort | sed 's/\.in$//;s/^/\t/;$!s/$/ \\/' # find functional/ ! -type d ! -name .gitignore ! -name .dirstamp ! -name '*.Po' -executable -name '*.in' | sort | sed 's/\.in$//;s/^/\t/;$!s/$/ \\/' # find functional/ ! -type d ! -name .gitignore ! -name .dirstamp ! -name '*.Po' ! -name '*.in' ! -name '*.c' | grep -Fe /simd -e /tmpfile | sort | sed 's/^/\t/;$!s/$/ \\/' # find functional/ ! -type d ! -name .gitignore ! -name .dirstamp ! -name '*.Po' ! -executable ! -name '*.in' ! -name '*.c' | grep -vFe /simd -e /tmpfile | sort | sed 's/^/\t/;$!s/$/ \\/' # find functional/ ! -type d ! -name .gitignore ! -name .dirstamp ! -name '*.Po' -executable ! -name '*.in' ! -name '*.c' | grep -vFe /simd -e /tmpfile | sort | sed 's/^/\t/;$!s/$/ \\/' # # simd and tmpfile are Linux-only and not installed elsewhere # # C programs are specced in ../Makefile.am above as part of the main Makefile find_common := find functional/ ! -type d ! -name .gitignore ! -name .dirstamp ! -name '*.Po' regen: @$(MAKE) -C $(top_builddir) clean @$(MAKE) clean $(SED) $(ac_inplace) '/^# -- >8 --/q' Makefile.am echo >> Makefile.am echo 'nobase_nodist_datadir_zfs_tests_tests_DATA = \' >> Makefile.am $(find_common) ! -executable -name '*.in' | sort | sed 's/\.in$$//;s/^/\t/;$$!s/$$/ \\/' >> Makefile.am echo 'nobase_nodist_datadir_zfs_tests_tests_SCRIPTS = \' >> Makefile.am $(find_common) -executable -name '*.in' | sort | sed 's/\.in$$//;s/^/\t/;$$!s/$$/ \\/' >> Makefile.am echo >> Makefile.am echo 'SUBSTFILES += $$(nobase_nodist_datadir_zfs_tests_tests_DATA) $$(nobase_nodist_datadir_zfs_tests_tests_SCRIPTS)' >> Makefile.am echo >> Makefile.am echo 'if BUILD_LINUX' >> Makefile.am echo 'nobase_dist_datadir_zfs_tests_tests_SCRIPTS += \' >> Makefile.am $(find_common) ! -name '*.in' ! -name '*.c' | grep -Fe /simd -e /tmpfile | sort | sed 's/^/\t/;$$!s/$$/ \\/' >> Makefile.am echo 'endif' >> Makefile.am echo >> Makefile.am echo 'nobase_dist_datadir_zfs_tests_tests_DATA += \' >> Makefile.am $(find_common) ! -executable ! -name '*.in' ! -name '*.c' | grep -vFe /simd -e /tmpfile | sort | sed 's/^/\t/;$$!s/$$/ \\/' >> Makefile.am echo >> Makefile.am echo 'nobase_dist_datadir_zfs_tests_tests_SCRIPTS += \' >> Makefile.am $(find_common) -executable ! -name '*.in' ! -name '*.c' | grep -vFe /simd -e /tmpfile | sort | sed 's/^/\t/;$$!s/$$/ \\/' >> Makefile.am # -- >8 -- nobase_nodist_datadir_zfs_tests_tests_DATA = \ functional/pam/utilities.kshlib nobase_nodist_datadir_zfs_tests_tests_SCRIPTS = \ functional/pyzfs/pyzfs_unittest.ksh SUBSTFILES += $(nobase_nodist_datadir_zfs_tests_tests_DATA) $(nobase_nodist_datadir_zfs_tests_tests_SCRIPTS) if BUILD_LINUX nobase_dist_datadir_zfs_tests_tests_SCRIPTS += \ functional/simd/simd_supported.ksh \ functional/tmpfile/cleanup.ksh \ functional/tmpfile/setup.ksh endif nobase_dist_datadir_zfs_tests_tests_DATA += \ functional/acl/acl.cfg \ functional/acl/acl_common.kshlib \ functional/alloc_class/alloc_class.cfg \ functional/alloc_class/alloc_class.kshlib \ functional/atime/atime.cfg \ functional/atime/atime_common.kshlib \ functional/block_cloning/block_cloning.kshlib \ functional/cache/cache.cfg \ functional/cache/cache.kshlib \ functional/cachefile/cachefile.cfg \ functional/cachefile/cachefile.kshlib \ functional/casenorm/casenorm.cfg \ functional/casenorm/casenorm.kshlib \ functional/channel_program/channel_common.kshlib \ functional/channel_program/lua_core/tst.args_to_lua.out \ functional/channel_program/lua_core/tst.args_to_lua.zcp \ functional/channel_program/lua_core/tst.divide_by_zero.err \ functional/channel_program/lua_core/tst.divide_by_zero.zcp \ functional/channel_program/lua_core/tst.exists.zcp \ functional/channel_program/lua_core/tst.large_prog.out \ functional/channel_program/lua_core/tst.large_prog.zcp \ functional/channel_program/lua_core/tst.lib_base.lua \ functional/channel_program/lua_core/tst.lib_coroutine.lua \ functional/channel_program/lua_core/tst.lib_strings.lua \ functional/channel_program/lua_core/tst.lib_table.lua \ functional/channel_program/lua_core/tst.nested_neg.zcp \ functional/channel_program/lua_core/tst.nested_pos.zcp \ functional/channel_program/lua_core/tst.recursive.zcp \ functional/channel_program/lua_core/tst.return_large.zcp \ functional/channel_program/lua_core/tst.return_recursive_table.zcp \ functional/channel_program/lua_core/tst.stack_gsub.err \ functional/channel_program/lua_core/tst.stack_gsub.zcp \ functional/channel_program/lua_core/tst.timeout.zcp \ functional/channel_program/synctask_core/tst.bookmark.copy.zcp \ functional/channel_program/synctask_core/tst.bookmark.create.zcp \ functional/channel_program/synctask_core/tst.get_index_props.out \ functional/channel_program/synctask_core/tst.get_index_props.zcp \ functional/channel_program/synctask_core/tst.get_number_props.out \ functional/channel_program/synctask_core/tst.get_number_props.zcp \ functional/channel_program/synctask_core/tst.get_string_props.out \ functional/channel_program/synctask_core/tst.get_string_props.zcp \ functional/channel_program/synctask_core/tst.promote_conflict.zcp \ functional/channel_program/synctask_core/tst.set_props.zcp \ functional/channel_program/synctask_core/tst.snapshot_destroy.zcp \ functional/channel_program/synctask_core/tst.snapshot_neg.zcp \ functional/channel_program/synctask_core/tst.snapshot_recursive.zcp \ functional/channel_program/synctask_core/tst.snapshot_rename.zcp \ functional/channel_program/synctask_core/tst.snapshot_simple.zcp \ functional/checksum/default.cfg \ functional/clean_mirror/clean_mirror_common.kshlib \ functional/clean_mirror/default.cfg \ functional/cli_root/cli_common.kshlib \ functional/cli_root/zfs_copies/zfs_copies.cfg \ functional/cli_root/zfs_copies/zfs_copies.kshlib \ functional/cli_root/zfs_create/properties.kshlib \ functional/cli_root/zfs_create/zfs_create.cfg \ functional/cli_root/zfs_create/zfs_create_common.kshlib \ functional/cli_root/zfs_destroy/zfs_destroy.cfg \ functional/cli_root/zfs_destroy/zfs_destroy_common.kshlib \ functional/cli_root/zfs_get/zfs_get_common.kshlib \ functional/cli_root/zfs_get/zfs_get_list_d.kshlib \ functional/cli_root/zfs_jail/jail.conf \ functional/cli_root/zfs_load-key/HEXKEY \ functional/cli_root/zfs_load-key/PASSPHRASE \ functional/cli_root/zfs_load-key/RAWKEY \ functional/cli_root/zfs_load-key/zfs_load-key.cfg \ functional/cli_root/zfs_load-key/zfs_load-key_common.kshlib \ functional/cli_root/zfs_mount/zfs_mount.cfg \ functional/cli_root/zfs_mount/zfs_mount.kshlib \ functional/cli_root/zfs_promote/zfs_promote.cfg \ functional/cli_root/zfs_receive/zstd_test_data.txt \ functional/cli_root/zfs_rename/zfs_rename.cfg \ functional/cli_root/zfs_rename/zfs_rename.kshlib \ functional/cli_root/zfs_rollback/zfs_rollback.cfg \ functional/cli_root/zfs_rollback/zfs_rollback_common.kshlib \ functional/cli_root/zfs_send/zfs_send.cfg \ functional/cli_root/zfs_set/zfs_set_common.kshlib \ functional/cli_root/zfs_share/zfs_share.cfg \ functional/cli_root/zfs_snapshot/zfs_snapshot.cfg \ functional/cli_root/zfs_unmount/zfs_unmount.cfg \ functional/cli_root/zfs_unmount/zfs_unmount.kshlib \ functional/cli_root/zfs_upgrade/zfs_upgrade.kshlib \ functional/cli_root/zfs_wait/zfs_wait.kshlib \ functional/cli_root/zpool_add/zpool_add.cfg \ functional/cli_root/zpool_add/zpool_add.kshlib \ functional/cli_root/zpool_clear/zpool_clear.cfg \ functional/cli_root/zpool_create/draidcfg.gz \ functional/cli_root/zpool_create/zpool_create.cfg \ functional/cli_root/zpool_create/zpool_create.shlib \ functional/cli_root/zpool_destroy/zpool_destroy.cfg \ functional/cli_root/zpool_events/zpool_events.cfg \ functional/cli_root/zpool_events/zpool_events.kshlib \ functional/cli_root/zpool_expand/zpool_expand.cfg \ functional/cli_root/zpool_export/zpool_export.cfg \ functional/cli_root/zpool_export/zpool_export.kshlib \ functional/cli_root/zpool_get/vdev_get.cfg \ functional/cli_root/zpool_get/zpool_get.cfg \ functional/cli_root/zpool_get/zpool_get_parsable.cfg \ functional/cli_root/zpool_import/blockfiles/cryptv0.dat.bz2 \ functional/cli_root/zpool_import/blockfiles/missing_ivset.dat.bz2 \ functional/cli_root/zpool_import/blockfiles/unclean_export.dat.bz2 \ functional/cli_root/zpool_import/zpool_import.cfg \ functional/cli_root/zpool_import/zpool_import.kshlib \ functional/cli_root/zpool_initialize/zpool_initialize.kshlib \ functional/cli_root/zpool_labelclear/labelclear.cfg \ functional/cli_root/zpool_remove/zpool_remove.cfg \ functional/cli_root/zpool_reopen/zpool_reopen.cfg \ functional/cli_root/zpool_reopen/zpool_reopen.shlib \ functional/cli_root/zpool_resilver/zpool_resilver.cfg \ functional/cli_root/zpool_scrub/zpool_scrub.cfg \ functional/cli_root/zpool_split/zpool_split.cfg \ functional/cli_root/zpool_trim/zpool_trim.kshlib \ functional/cli_root/zpool_upgrade/blockfiles/zfs-broken-mirror1.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-broken-mirror2.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v10.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v11.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v12.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v13.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v14.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v15.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v1.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v1mirror1.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v1mirror2.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v1mirror3.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v1raidz1.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v1raidz2.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v1raidz3.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v1stripe1.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v1stripe2.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v1stripe3.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v2.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v2mirror1.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v2mirror2.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v2mirror3.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v2raidz1.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v2raidz2.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v2raidz3.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v2stripe1.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v2stripe2.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v2stripe3.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v3.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v3hotspare1.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v3hotspare2.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v3hotspare3.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v3mirror1.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v3mirror2.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v3mirror3.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v3raidz1.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v3raidz21.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v3raidz22.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v3raidz23.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v3raidz2.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v3raidz3.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v3stripe1.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v3stripe2.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v3stripe3.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v4.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v5.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v6.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v7.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v8.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v999.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-v9.dat.bz2 \ functional/cli_root/zpool_upgrade/blockfiles/zfs-pool-vBROKEN.dat.bz2 \ functional/cli_root/zpool_upgrade/zpool_upgrade.cfg \ functional/cli_root/zpool_upgrade/zpool_upgrade.kshlib \ functional/cli_root/zpool_wait/zpool_wait.kshlib \ functional/cli_root/zhack/library.kshlib \ functional/cli_user/misc/misc.cfg \ functional/cli_user/zfs_list/zfs_list.cfg \ functional/cli_user/zfs_list/zfs_list.kshlib \ functional/compression/compress.cfg \ functional/compression/testpool_zstd.tar.gz \ functional/deadman/deadman.cfg \ functional/delegate/delegate.cfg \ functional/delegate/delegate_common.kshlib \ functional/devices/devices.cfg \ functional/devices/devices_common.kshlib \ functional/events/events.cfg \ functional/events/events_common.kshlib \ functional/fault/fault.cfg \ functional/grow/grow.cfg \ functional/history/history.cfg \ functional/history/history_common.kshlib \ functional/history/i386.migratedpool.DAT.Z \ functional/history/i386.orig_history.txt \ functional/history/sparc.migratedpool.DAT.Z \ functional/history/sparc.orig_history.txt \ functional/history/zfs-pool-v4.dat.Z \ functional/inheritance/config001.cfg \ functional/inheritance/config002.cfg \ functional/inheritance/config003.cfg \ functional/inheritance/config004.cfg \ functional/inheritance/config005.cfg \ functional/inheritance/config006.cfg \ functional/inheritance/config007.cfg \ functional/inheritance/config008.cfg \ functional/inheritance/config009.cfg \ functional/inheritance/config010.cfg \ functional/inheritance/config011.cfg \ functional/inheritance/config012.cfg \ functional/inheritance/config013.cfg \ functional/inheritance/config014.cfg \ functional/inheritance/config015.cfg \ functional/inheritance/config016.cfg \ functional/inheritance/config017.cfg \ functional/inheritance/config018.cfg \ functional/inheritance/config019.cfg \ functional/inheritance/config020.cfg \ functional/inheritance/config021.cfg \ functional/inheritance/config022.cfg \ functional/inheritance/config023.cfg \ functional/inheritance/config024.cfg \ functional/inheritance/inherit.kshlib \ functional/inheritance/README.config \ functional/inheritance/README.state \ functional/inheritance/state001.cfg \ functional/inheritance/state002.cfg \ functional/inheritance/state003.cfg \ functional/inheritance/state004.cfg \ functional/inheritance/state005.cfg \ functional/inheritance/state006.cfg \ functional/inheritance/state007.cfg \ functional/inheritance/state008.cfg \ functional/inheritance/state009.cfg \ functional/inheritance/state010.cfg \ functional/inheritance/state011.cfg \ functional/inheritance/state012.cfg \ functional/inheritance/state013.cfg \ functional/inheritance/state014.cfg \ functional/inheritance/state015.cfg \ functional/inheritance/state016.cfg \ functional/inheritance/state017.cfg \ functional/inheritance/state018.cfg \ functional/inheritance/state019.cfg \ functional/inheritance/state020.cfg \ functional/inheritance/state021.cfg \ functional/inheritance/state022.cfg \ functional/inheritance/state023.cfg \ functional/inheritance/state024.cfg \ functional/inuse/inuse.cfg \ functional/io/io.cfg \ functional/l2arc/l2arc.cfg \ functional/largest_pool/largest_pool.cfg \ functional/migration/migration.cfg \ functional/migration/migration.kshlib \ functional/mmap/mmap.cfg \ functional/mmp/mmp.cfg \ functional/mmp/mmp.kshlib \ functional/mv_files/mv_files.cfg \ functional/mv_files/mv_files_common.kshlib \ functional/nopwrite/nopwrite.shlib \ functional/no_space/enospc.cfg \ functional/online_offline/online_offline.cfg \ functional/pool_checkpoint/pool_checkpoint.kshlib \ functional/projectquota/projectquota.cfg \ functional/projectquota/projectquota_common.kshlib \ functional/quota/quota.cfg \ functional/quota/quota.kshlib \ functional/redacted_send/redacted.cfg \ functional/redacted_send/redacted.kshlib \ functional/redundancy/redundancy.cfg \ functional/redundancy/redundancy.kshlib \ functional/refreserv/refreserv.cfg \ functional/removal/removal.kshlib \ functional/replacement/replacement.cfg \ functional/reservation/reservation.cfg \ functional/reservation/reservation.shlib \ functional/rsend/dedup_encrypted_zvol.bz2 \ functional/rsend/dedup_encrypted_zvol.zsend.bz2 \ functional/rsend/dedup.zsend.bz2 \ functional/rsend/fs.tar.gz \ functional/rsend/rsend.cfg \ functional/rsend/rsend.kshlib \ functional/scrub_mirror/default.cfg \ functional/scrub_mirror/scrub_mirror_common.kshlib \ functional/slog/slog.cfg \ functional/slog/slog.kshlib \ functional/snapshot/snapshot.cfg \ functional/snapused/snapused.kshlib \ functional/sparse/sparse.cfg \ functional/trim/trim.cfg \ functional/trim/trim.kshlib \ functional/truncate/truncate.cfg \ functional/upgrade/upgrade_common.kshlib \ functional/user_namespace/user_namespace.cfg \ functional/user_namespace/user_namespace_common.kshlib \ functional/userquota/13709_reproducer.bz2 \ functional/userquota/userquota.cfg \ functional/userquota/userquota_common.kshlib \ functional/vdev_zaps/vdev_zaps.kshlib \ functional/xattr/xattr.cfg \ functional/xattr/xattr_common.kshlib \ functional/zvol/zvol.cfg \ functional/zvol/zvol_cli/zvol_cli.cfg \ functional/zvol/zvol_common.shlib \ functional/zvol/zvol_ENOSPC/zvol_ENOSPC.cfg \ functional/zvol/zvol_misc/zvol_misc_common.kshlib \ functional/zvol/zvol_swap/zvol_swap.cfg \ functional/idmap_mount/idmap_mount.cfg \ functional/idmap_mount/idmap_mount_common.kshlib nobase_dist_datadir_zfs_tests_tests_SCRIPTS += \ functional/acl/off/cleanup.ksh \ functional/acl/off/dosmode.ksh \ functional/acl/off/posixmode.ksh \ functional/acl/off/setup.ksh \ functional/acl/posix/cleanup.ksh \ functional/acl/posix/posix_001_pos.ksh \ functional/acl/posix/posix_002_pos.ksh \ functional/acl/posix/posix_003_pos.ksh \ functional/acl/posix/posix_004_pos.ksh \ functional/acl/posix-sa/cleanup.ksh \ functional/acl/posix-sa/posix_001_pos.ksh \ functional/acl/posix-sa/posix_002_pos.ksh \ functional/acl/posix-sa/posix_003_pos.ksh \ functional/acl/posix-sa/posix_004_pos.ksh \ functional/acl/posix-sa/setup.ksh \ functional/acl/posix/setup.ksh \ functional/alloc_class/alloc_class_001_pos.ksh \ functional/alloc_class/alloc_class_002_neg.ksh \ functional/alloc_class/alloc_class_003_pos.ksh \ functional/alloc_class/alloc_class_004_pos.ksh \ functional/alloc_class/alloc_class_005_pos.ksh \ functional/alloc_class/alloc_class_006_pos.ksh \ functional/alloc_class/alloc_class_007_pos.ksh \ functional/alloc_class/alloc_class_008_pos.ksh \ functional/alloc_class/alloc_class_009_pos.ksh \ functional/alloc_class/alloc_class_010_pos.ksh \ functional/alloc_class/alloc_class_011_neg.ksh \ functional/alloc_class/alloc_class_012_pos.ksh \ functional/alloc_class/alloc_class_013_pos.ksh \ functional/alloc_class/alloc_class_014_neg.ksh \ functional/alloc_class/alloc_class_015_pos.ksh \ functional/alloc_class/cleanup.ksh \ functional/alloc_class/setup.ksh \ functional/append/file_append.ksh \ functional/append/threadsappend_001_pos.ksh \ functional/append/cleanup.ksh \ functional/append/setup.ksh \ functional/arc/arcstats_runtime_tuning.ksh \ functional/arc/cleanup.ksh \ functional/arc/dbufstats_001_pos.ksh \ functional/arc/dbufstats_002_pos.ksh \ functional/arc/dbufstats_003_pos.ksh \ functional/arc/setup.ksh \ functional/atime/atime_001_pos.ksh \ functional/atime/atime_002_neg.ksh \ functional/atime/atime_003_pos.ksh \ functional/atime/cleanup.ksh \ functional/atime/root_atime_off.ksh \ functional/atime/root_atime_on.ksh \ functional/atime/root_relatime_on.ksh \ functional/atime/setup.ksh \ functional/block_cloning/cleanup.ksh \ functional/block_cloning/setup.ksh \ functional/block_cloning/block_cloning_copyfilerange_cross_dataset.ksh \ functional/block_cloning/block_cloning_copyfilerange_fallback.ksh \ functional/block_cloning/block_cloning_copyfilerange_fallback_same_txg.ksh \ functional/block_cloning/block_cloning_copyfilerange.ksh \ functional/block_cloning/block_cloning_copyfilerange_partial.ksh \ functional/block_cloning/block_cloning_disabled_copyfilerange.ksh \ functional/block_cloning/block_cloning_disabled_ficlone.ksh \ functional/block_cloning/block_cloning_disabled_ficlonerange.ksh \ functional/block_cloning/block_cloning_ficlone.ksh \ functional/block_cloning/block_cloning_ficlonerange.ksh \ functional/block_cloning/block_cloning_ficlonerange_partial.ksh \ functional/bootfs/bootfs_001_pos.ksh \ functional/bootfs/bootfs_002_neg.ksh \ functional/bootfs/bootfs_003_pos.ksh \ functional/bootfs/bootfs_004_neg.ksh \ functional/bootfs/bootfs_005_neg.ksh \ functional/bootfs/bootfs_006_pos.ksh \ functional/bootfs/bootfs_007_pos.ksh \ functional/bootfs/bootfs_008_pos.ksh \ functional/bootfs/cleanup.ksh \ functional/bootfs/setup.ksh \ functional/btree/btree_negative.ksh \ functional/btree/btree_positive.ksh \ functional/cache/cache_001_pos.ksh \ functional/cache/cache_002_pos.ksh \ functional/cache/cache_003_pos.ksh \ functional/cache/cache_004_neg.ksh \ functional/cache/cache_005_neg.ksh \ functional/cache/cache_006_pos.ksh \ functional/cache/cache_007_neg.ksh \ functional/cache/cache_008_neg.ksh \ functional/cache/cache_009_pos.ksh \ functional/cache/cache_010_pos.ksh \ functional/cache/cache_011_pos.ksh \ functional/cache/cache_012_pos.ksh \ functional/cache/cleanup.ksh \ functional/cachefile/cachefile_001_pos.ksh \ functional/cachefile/cachefile_002_pos.ksh \ functional/cachefile/cachefile_003_pos.ksh \ functional/cachefile/cachefile_004_pos.ksh \ functional/cachefile/cleanup.ksh \ functional/cachefile/setup.ksh \ functional/cache/setup.ksh \ functional/casenorm/case_all_values.ksh \ functional/casenorm/cleanup.ksh \ functional/casenorm/insensitive_formd_delete.ksh \ functional/casenorm/insensitive_formd_lookup.ksh \ functional/casenorm/insensitive_none_delete.ksh \ functional/casenorm/insensitive_none_lookup.ksh \ functional/casenorm/mixed_create_failure.ksh \ functional/casenorm/mixed_formd_delete.ksh \ functional/casenorm/mixed_formd_lookup_ci.ksh \ functional/casenorm/mixed_formd_lookup.ksh \ functional/casenorm/mixed_none_delete.ksh \ functional/casenorm/mixed_none_lookup_ci.ksh \ functional/casenorm/mixed_none_lookup.ksh \ functional/casenorm/norm_all_values.ksh \ functional/casenorm/sensitive_formd_delete.ksh \ functional/casenorm/sensitive_formd_lookup.ksh \ functional/casenorm/sensitive_none_delete.ksh \ functional/casenorm/sensitive_none_lookup.ksh \ functional/casenorm/setup.ksh \ functional/channel_program/lua_core/cleanup.ksh \ functional/channel_program/lua_core/setup.ksh \ functional/channel_program/lua_core/tst.args_to_lua.ksh \ functional/channel_program/lua_core/tst.divide_by_zero.ksh \ functional/channel_program/lua_core/tst.exists.ksh \ functional/channel_program/lua_core/tst.integer_illegal.ksh \ functional/channel_program/lua_core/tst.integer_overflow.ksh \ functional/channel_program/lua_core/tst.language_functions_neg.ksh \ functional/channel_program/lua_core/tst.language_functions_pos.ksh \ functional/channel_program/lua_core/tst.large_prog.ksh \ functional/channel_program/lua_core/tst.libraries.ksh \ functional/channel_program/lua_core/tst.memory_limit.ksh \ functional/channel_program/lua_core/tst.nested_neg.ksh \ functional/channel_program/lua_core/tst.nested_pos.ksh \ functional/channel_program/lua_core/tst.nvlist_to_lua.ksh \ functional/channel_program/lua_core/tst.recursive_neg.ksh \ functional/channel_program/lua_core/tst.recursive_pos.ksh \ functional/channel_program/lua_core/tst.return_large.ksh \ functional/channel_program/lua_core/tst.return_nvlist_neg.ksh \ functional/channel_program/lua_core/tst.return_nvlist_pos.ksh \ functional/channel_program/lua_core/tst.return_recursive_table.ksh \ functional/channel_program/lua_core/tst.stack_gsub.ksh \ functional/channel_program/lua_core/tst.timeout.ksh \ functional/channel_program/synctask_core/cleanup.ksh \ functional/channel_program/synctask_core/setup.ksh \ functional/channel_program/synctask_core/tst.bookmark.copy.ksh \ functional/channel_program/synctask_core/tst.bookmark.create.ksh \ functional/channel_program/synctask_core/tst.destroy_fs.ksh \ functional/channel_program/synctask_core/tst.destroy_snap.ksh \ functional/channel_program/synctask_core/tst.get_count_and_limit.ksh \ functional/channel_program/synctask_core/tst.get_index_props.ksh \ functional/channel_program/synctask_core/tst.get_mountpoint.ksh \ functional/channel_program/synctask_core/tst.get_neg.ksh \ functional/channel_program/synctask_core/tst.get_number_props.ksh \ functional/channel_program/synctask_core/tst.get_string_props.ksh \ functional/channel_program/synctask_core/tst.get_type.ksh \ functional/channel_program/synctask_core/tst.get_userquota.ksh \ functional/channel_program/synctask_core/tst.get_written.ksh \ functional/channel_program/synctask_core/tst.inherit.ksh \ functional/channel_program/synctask_core/tst.list_bookmarks.ksh \ functional/channel_program/synctask_core/tst.list_children.ksh \ functional/channel_program/synctask_core/tst.list_clones.ksh \ functional/channel_program/synctask_core/tst.list_holds.ksh \ functional/channel_program/synctask_core/tst.list_snapshots.ksh \ functional/channel_program/synctask_core/tst.list_system_props.ksh \ functional/channel_program/synctask_core/tst.list_user_props.ksh \ functional/channel_program/synctask_core/tst.parse_args_neg.ksh \ functional/channel_program/synctask_core/tst.promote_conflict.ksh \ functional/channel_program/synctask_core/tst.promote_multiple.ksh \ functional/channel_program/synctask_core/tst.promote_simple.ksh \ functional/channel_program/synctask_core/tst.rollback_mult.ksh \ functional/channel_program/synctask_core/tst.rollback_one.ksh \ functional/channel_program/synctask_core/tst.set_props.ksh \ functional/channel_program/synctask_core/tst.snapshot_destroy.ksh \ functional/channel_program/synctask_core/tst.snapshot_neg.ksh \ functional/channel_program/synctask_core/tst.snapshot_recursive.ksh \ functional/channel_program/synctask_core/tst.snapshot_rename.ksh \ functional/channel_program/synctask_core/tst.snapshot_simple.ksh \ functional/channel_program/synctask_core/tst.terminate_by_signal.ksh \ functional/chattr/chattr_001_pos.ksh \ functional/chattr/chattr_002_neg.ksh \ functional/chattr/cleanup.ksh \ functional/chattr/setup.ksh \ functional/checksum/cleanup.ksh \ functional/checksum/filetest_001_pos.ksh \ functional/checksum/filetest_002_pos.ksh \ functional/checksum/run_blake3_test.ksh \ functional/checksum/run_edonr_test.ksh \ functional/checksum/run_sha2_test.ksh \ functional/checksum/run_skein_test.ksh \ functional/checksum/setup.ksh \ functional/clean_mirror/clean_mirror_001_pos.ksh \ functional/clean_mirror/clean_mirror_002_pos.ksh \ functional/clean_mirror/clean_mirror_003_pos.ksh \ functional/clean_mirror/clean_mirror_004_pos.ksh \ functional/clean_mirror/cleanup.ksh \ functional/clean_mirror/setup.ksh \ functional/cli_root/zdb/zdb_002_pos.ksh \ functional/cli_root/zdb/zdb_003_pos.ksh \ functional/cli_root/zdb/zdb_004_pos.ksh \ functional/cli_root/zdb/zdb_005_pos.ksh \ functional/cli_root/zdb/zdb_006_pos.ksh \ functional/cli_root/zdb/zdb_args_neg.ksh \ functional/cli_root/zdb/zdb_args_pos.ksh \ functional/cli_root/zdb/zdb_backup.ksh \ functional/cli_root/zdb/zdb_block_size_histogram.ksh \ functional/cli_root/zdb/zdb_checksum.ksh \ functional/cli_root/zdb/zdb_decompress.ksh \ functional/cli_root/zdb/zdb_decompress_zstd.ksh \ functional/cli_root/zdb/zdb_display_block.ksh \ functional/cli_root/zdb/zdb_encrypted.ksh \ functional/cli_root/zdb/zdb_label_checksum.ksh \ functional/cli_root/zdb/zdb_object_range_neg.ksh \ functional/cli_root/zdb/zdb_object_range_pos.ksh \ functional/cli_root/zdb/zdb_objset_id.ksh \ functional/cli_root/zdb/zdb_recover_2.ksh \ functional/cli_root/zdb/zdb_recover.ksh \ functional/cli_root/zfs_bookmark/cleanup.ksh \ functional/cli_root/zfs_bookmark/setup.ksh \ functional/cli_root/zfs_bookmark/zfs_bookmark_cliargs.ksh \ functional/cli_root/zfs_change-key/cleanup.ksh \ functional/cli_root/zfs_change-key/setup.ksh \ functional/cli_root/zfs_change-key/zfs_change-key_child.ksh \ functional/cli_root/zfs_change-key/zfs_change-key_clones.ksh \ functional/cli_root/zfs_change-key/zfs_change-key_format.ksh \ functional/cli_root/zfs_change-key/zfs_change-key_inherit.ksh \ functional/cli_root/zfs_change-key/zfs_change-key.ksh \ functional/cli_root/zfs_change-key/zfs_change-key_load.ksh \ functional/cli_root/zfs_change-key/zfs_change-key_location.ksh \ functional/cli_root/zfs_change-key/zfs_change-key_pbkdf2iters.ksh \ functional/cli_root/zfs/cleanup.ksh \ functional/cli_root/zfs_clone/cleanup.ksh \ functional/cli_root/zfs_clone/setup.ksh \ functional/cli_root/zfs_clone/zfs_clone_001_neg.ksh \ functional/cli_root/zfs_clone/zfs_clone_002_pos.ksh \ functional/cli_root/zfs_clone/zfs_clone_003_pos.ksh \ functional/cli_root/zfs_clone/zfs_clone_004_pos.ksh \ functional/cli_root/zfs_clone/zfs_clone_005_pos.ksh \ functional/cli_root/zfs_clone/zfs_clone_006_pos.ksh \ functional/cli_root/zfs_clone/zfs_clone_007_pos.ksh \ functional/cli_root/zfs_clone/zfs_clone_008_neg.ksh \ functional/cli_root/zfs_clone/zfs_clone_009_neg.ksh \ functional/cli_root/zfs_clone/zfs_clone_010_pos.ksh \ functional/cli_root/zfs_clone/zfs_clone_deeply_nested.ksh \ functional/cli_root/zfs_clone/zfs_clone_encrypted.ksh \ functional/cli_root/zfs_clone/zfs_clone_rm_nested.ksh \ functional/cli_root/zfs_copies/cleanup.ksh \ functional/cli_root/zfs_copies/setup.ksh \ functional/cli_root/zfs_copies/zfs_copies_001_pos.ksh \ functional/cli_root/zfs_copies/zfs_copies_002_pos.ksh \ functional/cli_root/zfs_copies/zfs_copies_003_pos.ksh \ functional/cli_root/zfs_copies/zfs_copies_004_neg.ksh \ functional/cli_root/zfs_copies/zfs_copies_005_neg.ksh \ functional/cli_root/zfs_copies/zfs_copies_006_pos.ksh \ functional/cli_root/zfs_create/cleanup.ksh \ functional/cli_root/zfs_create/setup.ksh \ functional/cli_root/zfs_create/zfs_create_001_pos.ksh \ functional/cli_root/zfs_create/zfs_create_002_pos.ksh \ functional/cli_root/zfs_create/zfs_create_003_pos.ksh \ functional/cli_root/zfs_create/zfs_create_004_pos.ksh \ functional/cli_root/zfs_create/zfs_create_005_pos.ksh \ functional/cli_root/zfs_create/zfs_create_006_pos.ksh \ functional/cli_root/zfs_create/zfs_create_007_pos.ksh \ functional/cli_root/zfs_create/zfs_create_008_neg.ksh \ functional/cli_root/zfs_create/zfs_create_009_neg.ksh \ functional/cli_root/zfs_create/zfs_create_010_neg.ksh \ functional/cli_root/zfs_create/zfs_create_011_pos.ksh \ functional/cli_root/zfs_create/zfs_create_012_pos.ksh \ functional/cli_root/zfs_create/zfs_create_013_pos.ksh \ functional/cli_root/zfs_create/zfs_create_014_pos.ksh \ functional/cli_root/zfs_create/zfs_create_crypt_combos.ksh \ functional/cli_root/zfs_create/zfs_create_dryrun.ksh \ functional/cli_root/zfs_create/zfs_create_encrypted.ksh \ functional/cli_root/zfs_create/zfs_create_nomount.ksh \ functional/cli_root/zfs_create/zfs_create_verbose.ksh \ functional/cli_root/zfs_destroy/cleanup.ksh \ functional/cli_root/zfs_destroy/setup.ksh \ functional/cli_root/zfs_destroy/zfs_clone_livelist_condense_and_disable.ksh \ functional/cli_root/zfs_destroy/zfs_clone_livelist_condense_races.ksh \ functional/cli_root/zfs_destroy/zfs_clone_livelist_dedup.ksh \ functional/cli_root/zfs_destroy/zfs_destroy_001_pos.ksh \ functional/cli_root/zfs_destroy/zfs_destroy_002_pos.ksh \ functional/cli_root/zfs_destroy/zfs_destroy_003_pos.ksh \ functional/cli_root/zfs_destroy/zfs_destroy_004_pos.ksh \ functional/cli_root/zfs_destroy/zfs_destroy_005_neg.ksh \ functional/cli_root/zfs_destroy/zfs_destroy_006_neg.ksh \ functional/cli_root/zfs_destroy/zfs_destroy_007_neg.ksh \ functional/cli_root/zfs_destroy/zfs_destroy_008_pos.ksh \ functional/cli_root/zfs_destroy/zfs_destroy_009_pos.ksh \ functional/cli_root/zfs_destroy/zfs_destroy_010_pos.ksh \ functional/cli_root/zfs_destroy/zfs_destroy_011_pos.ksh \ functional/cli_root/zfs_destroy/zfs_destroy_012_pos.ksh \ functional/cli_root/zfs_destroy/zfs_destroy_013_neg.ksh \ functional/cli_root/zfs_destroy/zfs_destroy_014_pos.ksh \ functional/cli_root/zfs_destroy/zfs_destroy_015_pos.ksh \ functional/cli_root/zfs_destroy/zfs_destroy_016_pos.ksh \ functional/cli_root/zfs_destroy/zfs_destroy_clone_livelist.ksh \ functional/cli_root/zfs_destroy/zfs_destroy_dev_removal_condense.ksh \ functional/cli_root/zfs_destroy/zfs_destroy_dev_removal.ksh \ functional/cli_root/zfs_diff/cleanup.ksh \ functional/cli_root/zfs_diff/setup.ksh \ functional/cli_root/zfs_diff/zfs_diff_changes.ksh \ functional/cli_root/zfs_diff/zfs_diff_cliargs.ksh \ functional/cli_root/zfs_diff/zfs_diff_encrypted.ksh \ functional/cli_root/zfs_diff/zfs_diff_mangle.ksh \ functional/cli_root/zfs_diff/zfs_diff_timestamp.ksh \ functional/cli_root/zfs_diff/zfs_diff_types.ksh \ functional/cli_root/zfs_get/cleanup.ksh \ functional/cli_root/zfs_get/setup.ksh \ functional/cli_root/zfs_get/zfs_get_001_pos.ksh \ functional/cli_root/zfs_get/zfs_get_002_pos.ksh \ functional/cli_root/zfs_get/zfs_get_003_pos.ksh \ functional/cli_root/zfs_get/zfs_get_004_pos.ksh \ functional/cli_root/zfs_get/zfs_get_005_neg.ksh \ functional/cli_root/zfs_get/zfs_get_006_neg.ksh \ functional/cli_root/zfs_get/zfs_get_007_neg.ksh \ functional/cli_root/zfs_get/zfs_get_008_pos.ksh \ functional/cli_root/zfs_get/zfs_get_009_pos.ksh \ functional/cli_root/zfs_get/zfs_get_010_neg.ksh \ functional/cli_root/zfs_ids_to_path/cleanup.ksh \ functional/cli_root/zfs_ids_to_path/setup.ksh \ functional/cli_root/zfs_ids_to_path/zfs_ids_to_path_001_pos.ksh \ functional/cli_root/zfs_inherit/cleanup.ksh \ functional/cli_root/zfs_inherit/setup.ksh \ functional/cli_root/zfs_inherit/zfs_inherit_001_neg.ksh \ functional/cli_root/zfs_inherit/zfs_inherit_002_neg.ksh \ functional/cli_root/zfs_inherit/zfs_inherit_003_pos.ksh \ functional/cli_root/zfs_inherit/zfs_inherit_mountpoint.ksh \ functional/cli_root/zfs_jail/cleanup.ksh \ functional/cli_root/zfs_jail/setup.ksh \ functional/cli_root/zfs_jail/zfs_jail_001_pos.ksh \ functional/cli_root/zfs_load-key/cleanup.ksh \ functional/cli_root/zfs_load-key/setup.ksh \ functional/cli_root/zfs_load-key/zfs_load-key_all.ksh \ functional/cli_root/zfs_load-key/zfs_load-key_file.ksh \ functional/cli_root/zfs_load-key/zfs_load-key_https.ksh \ functional/cli_root/zfs_load-key/zfs_load-key.ksh \ functional/cli_root/zfs_load-key/zfs_load-key_location.ksh \ functional/cli_root/zfs_load-key/zfs_load-key_noop.ksh \ functional/cli_root/zfs_load-key/zfs_load-key_recursive.ksh \ functional/cli_root/zfs_mount/cleanup.ksh \ functional/cli_root/zfs_mount/setup.ksh \ functional/cli_root/zfs_mount/zfs_mount_001_pos.ksh \ functional/cli_root/zfs_mount/zfs_mount_002_pos.ksh \ functional/cli_root/zfs_mount/zfs_mount_003_pos.ksh \ functional/cli_root/zfs_mount/zfs_mount_004_pos.ksh \ functional/cli_root/zfs_mount/zfs_mount_005_pos.ksh \ functional/cli_root/zfs_mount/zfs_mount_006_pos.ksh \ functional/cli_root/zfs_mount/zfs_mount_007_pos.ksh \ functional/cli_root/zfs_mount/zfs_mount_008_pos.ksh \ functional/cli_root/zfs_mount/zfs_mount_009_neg.ksh \ functional/cli_root/zfs_mount/zfs_mount_010_neg.ksh \ functional/cli_root/zfs_mount/zfs_mount_011_neg.ksh \ functional/cli_root/zfs_mount/zfs_mount_012_pos.ksh \ functional/cli_root/zfs_mount/zfs_mount_013_pos.ksh \ functional/cli_root/zfs_mount/zfs_mount_014_neg.ksh \ functional/cli_root/zfs_mount/zfs_mount_all_001_pos.ksh \ functional/cli_root/zfs_mount/zfs_mount_all_fail.ksh \ functional/cli_root/zfs_mount/zfs_mount_all_mountpoints.ksh \ functional/cli_root/zfs_mount/zfs_mount_encrypted.ksh \ functional/cli_root/zfs_mount/zfs_mount_remount.ksh \ functional/cli_root/zfs_mount/zfs_mount_test_race.ksh \ functional/cli_root/zfs_mount/zfs_multi_mount.ksh \ functional/cli_root/zfs_program/cleanup.ksh \ functional/cli_root/zfs_program/setup.ksh \ functional/cli_root/zfs_program/zfs_program_json.ksh \ functional/cli_root/zfs_promote/cleanup.ksh \ functional/cli_root/zfs_promote/setup.ksh \ functional/cli_root/zfs_promote/zfs_promote_001_pos.ksh \ functional/cli_root/zfs_promote/zfs_promote_002_pos.ksh \ functional/cli_root/zfs_promote/zfs_promote_003_pos.ksh \ functional/cli_root/zfs_promote/zfs_promote_004_pos.ksh \ functional/cli_root/zfs_promote/zfs_promote_005_pos.ksh \ functional/cli_root/zfs_promote/zfs_promote_006_neg.ksh \ functional/cli_root/zfs_promote/zfs_promote_007_neg.ksh \ functional/cli_root/zfs_promote/zfs_promote_008_pos.ksh \ functional/cli_root/zfs_promote/zfs_promote_encryptionroot.ksh \ functional/cli_root/zfs_property/cleanup.ksh \ functional/cli_root/zfs_property/setup.ksh \ functional/cli_root/zfs_property/zfs_written_property_001_pos.ksh \ functional/cli_root/zfs_receive/cleanup.ksh \ functional/cli_root/zfs_receive/receive-o-x_props_aliases.ksh \ functional/cli_root/zfs_receive/receive-o-x_props_override.ksh \ functional/cli_root/zfs_receive/setup.ksh \ functional/cli_root/zfs_receive/zfs_receive_001_pos.ksh \ functional/cli_root/zfs_receive/zfs_receive_002_pos.ksh \ functional/cli_root/zfs_receive/zfs_receive_003_pos.ksh \ functional/cli_root/zfs_receive/zfs_receive_004_neg.ksh \ functional/cli_root/zfs_receive/zfs_receive_005_neg.ksh \ functional/cli_root/zfs_receive/zfs_receive_006_pos.ksh \ functional/cli_root/zfs_receive/zfs_receive_007_neg.ksh \ functional/cli_root/zfs_receive/zfs_receive_008_pos.ksh \ functional/cli_root/zfs_receive/zfs_receive_009_neg.ksh \ functional/cli_root/zfs_receive/zfs_receive_010_pos.ksh \ functional/cli_root/zfs_receive/zfs_receive_011_pos.ksh \ functional/cli_root/zfs_receive/zfs_receive_012_pos.ksh \ functional/cli_root/zfs_receive/zfs_receive_013_pos.ksh \ functional/cli_root/zfs_receive/zfs_receive_014_pos.ksh \ functional/cli_root/zfs_receive/zfs_receive_015_pos.ksh \ functional/cli_root/zfs_receive/zfs_receive_016_pos.ksh \ functional/cli_root/zfs_receive/zfs_receive_-e.ksh \ functional/cli_root/zfs_receive/zfs_receive_from_encrypted.ksh \ functional/cli_root/zfs_receive/zfs_receive_from_zstd.ksh \ functional/cli_root/zfs_receive/zfs_receive_new_props.ksh \ functional/cli_root/zfs_receive/zfs_receive_raw_-d.ksh \ functional/cli_root/zfs_receive/zfs_receive_raw_incremental.ksh \ functional/cli_root/zfs_receive/zfs_receive_raw.ksh \ functional/cli_root/zfs_receive/zfs_receive_to_encrypted.ksh \ functional/cli_root/zfs_receive/zfs_receive_-wR-encrypted-mix.ksh \ functional/cli_root/zfs_receive/zfs_receive_corrective.ksh \ functional/cli_root/zfs_receive/zfs_receive_compressed_corrective.ksh \ functional/cli_root/zfs_receive/zfs_receive_large_block_corrective.ksh \ functional/cli_root/zfs_rename/cleanup.ksh \ functional/cli_root/zfs_rename/setup.ksh \ functional/cli_root/zfs_rename/zfs_rename_001_pos.ksh \ functional/cli_root/zfs_rename/zfs_rename_002_pos.ksh \ functional/cli_root/zfs_rename/zfs_rename_003_pos.ksh \ functional/cli_root/zfs_rename/zfs_rename_004_neg.ksh \ functional/cli_root/zfs_rename/zfs_rename_005_neg.ksh \ functional/cli_root/zfs_rename/zfs_rename_006_pos.ksh \ functional/cli_root/zfs_rename/zfs_rename_007_pos.ksh \ functional/cli_root/zfs_rename/zfs_rename_008_pos.ksh \ functional/cli_root/zfs_rename/zfs_rename_009_neg.ksh \ functional/cli_root/zfs_rename/zfs_rename_010_neg.ksh \ functional/cli_root/zfs_rename/zfs_rename_011_pos.ksh \ functional/cli_root/zfs_rename/zfs_rename_012_neg.ksh \ functional/cli_root/zfs_rename/zfs_rename_013_pos.ksh \ functional/cli_root/zfs_rename/zfs_rename_014_neg.ksh \ functional/cli_root/zfs_rename/zfs_rename_encrypted_child.ksh \ functional/cli_root/zfs_rename/zfs_rename_mountpoint.ksh \ functional/cli_root/zfs_rename/zfs_rename_nounmount.ksh \ functional/cli_root/zfs_rename/zfs_rename_to_encrypted.ksh \ functional/cli_root/zfs_reservation/cleanup.ksh \ functional/cli_root/zfs_reservation/setup.ksh \ functional/cli_root/zfs_reservation/zfs_reservation_001_pos.ksh \ functional/cli_root/zfs_reservation/zfs_reservation_002_pos.ksh \ functional/cli_root/zfs_rollback/cleanup.ksh \ functional/cli_root/zfs_rollback/setup.ksh \ functional/cli_root/zfs_rollback/zfs_rollback_001_pos.ksh \ functional/cli_root/zfs_rollback/zfs_rollback_002_pos.ksh \ functional/cli_root/zfs_rollback/zfs_rollback_003_neg.ksh \ functional/cli_root/zfs_rollback/zfs_rollback_004_neg.ksh \ functional/cli_root/zfs_send/cleanup.ksh \ functional/cli_root/zfs_send/setup.ksh \ functional/cli_root/zfs_send/zfs_send_001_pos.ksh \ functional/cli_root/zfs_send/zfs_send_002_pos.ksh \ functional/cli_root/zfs_send/zfs_send_003_pos.ksh \ functional/cli_root/zfs_send/zfs_send_004_neg.ksh \ functional/cli_root/zfs_send/zfs_send_005_pos.ksh \ functional/cli_root/zfs_send/zfs_send_006_pos.ksh \ functional/cli_root/zfs_send/zfs_send_007_pos.ksh \ functional/cli_root/zfs_send/zfs_send-b.ksh \ functional/cli_root/zfs_send/zfs_send_encrypted.ksh \ functional/cli_root/zfs_send/zfs_send_encrypted_unloaded.ksh \ functional/cli_root/zfs_send/zfs_send_raw.ksh \ functional/cli_root/zfs_send/zfs_send_skip_missing.ksh \ functional/cli_root/zfs_send/zfs_send_sparse.ksh \ functional/cli_root/zfs_set/cache_001_pos.ksh \ functional/cli_root/zfs_set/cache_002_neg.ksh \ functional/cli_root/zfs_set/canmount_001_pos.ksh \ functional/cli_root/zfs_set/canmount_002_pos.ksh \ functional/cli_root/zfs_set/canmount_003_pos.ksh \ functional/cli_root/zfs_set/canmount_004_pos.ksh \ functional/cli_root/zfs_set/checksum_001_pos.ksh \ functional/cli_root/zfs_set/cleanup.ksh \ functional/cli_root/zfs_set/compression_001_pos.ksh \ functional/cli_root/zfs_set/mountpoint_001_pos.ksh \ functional/cli_root/zfs_set/mountpoint_002_pos.ksh \ functional/cli_root/zfs_set/mountpoint_003_pos.ksh \ functional/cli_root/zfs_set/onoffs_001_pos.ksh \ functional/cli_root/zfs_set/property_alias_001_pos.ksh \ functional/cli_root/zfs_set/readonly_001_pos.ksh \ functional/cli_root/zfs_set/reservation_001_neg.ksh \ functional/cli_root/zfs_set/ro_props_001_pos.ksh \ functional/cli_root/zfs_set/setup.ksh \ functional/cli_root/zfs_set/share_mount_001_neg.ksh \ functional/cli_root/zfs_set/snapdir_001_pos.ksh \ functional/cli_root/zfs/setup.ksh \ functional/cli_root/zfs_set/user_property_001_pos.ksh \ functional/cli_root/zfs_set/user_property_002_pos.ksh \ functional/cli_root/zfs_set/user_property_003_neg.ksh \ functional/cli_root/zfs_set/user_property_004_pos.ksh \ functional/cli_root/zfs_set/version_001_neg.ksh \ functional/cli_root/zfs_set/zfs_set_001_neg.ksh \ functional/cli_root/zfs_set/zfs_set_002_neg.ksh \ functional/cli_root/zfs_set/zfs_set_003_neg.ksh \ functional/cli_root/zfs_set/zfs_set_feature_activation.ksh \ functional/cli_root/zfs_set/zfs_set_keylocation.ksh \ functional/cli_root/zfs_set/zfs_set_nomount.ksh \ functional/cli_root/zfs_share/cleanup.ksh \ functional/cli_root/zfs_share/setup.ksh \ functional/cli_root/zfs_share/zfs_share_001_pos.ksh \ functional/cli_root/zfs_share/zfs_share_002_pos.ksh \ functional/cli_root/zfs_share/zfs_share_003_pos.ksh \ functional/cli_root/zfs_share/zfs_share_004_pos.ksh \ functional/cli_root/zfs_share/zfs_share_005_pos.ksh \ functional/cli_root/zfs_share/zfs_share_006_pos.ksh \ functional/cli_root/zfs_share/zfs_share_007_neg.ksh \ functional/cli_root/zfs_share/zfs_share_008_neg.ksh \ functional/cli_root/zfs_share/zfs_share_009_neg.ksh \ functional/cli_root/zfs_share/zfs_share_010_neg.ksh \ functional/cli_root/zfs_share/zfs_share_011_pos.ksh \ functional/cli_root/zfs_share/zfs_share_012_pos.ksh \ functional/cli_root/zfs_share/zfs_share_013_pos.ksh \ functional/cli_root/zfs_share/zfs_share_concurrent_shares.ksh \ functional/cli_root/zfs_snapshot/cleanup.ksh \ functional/cli_root/zfs_snapshot/setup.ksh \ functional/cli_root/zfs_snapshot/zfs_snapshot_001_neg.ksh \ functional/cli_root/zfs_snapshot/zfs_snapshot_002_neg.ksh \ functional/cli_root/zfs_snapshot/zfs_snapshot_003_neg.ksh \ functional/cli_root/zfs_snapshot/zfs_snapshot_004_neg.ksh \ functional/cli_root/zfs_snapshot/zfs_snapshot_005_neg.ksh \ functional/cli_root/zfs_snapshot/zfs_snapshot_006_pos.ksh \ functional/cli_root/zfs_snapshot/zfs_snapshot_007_neg.ksh \ functional/cli_root/zfs_snapshot/zfs_snapshot_008_neg.ksh \ functional/cli_root/zfs_snapshot/zfs_snapshot_009_pos.ksh \ functional/cli_root/zfs_sysfs/cleanup.ksh \ functional/cli_root/zfs_sysfs/setup.ksh \ functional/cli_root/zfs_sysfs/zfeature_set_unsupported.ksh \ functional/cli_root/zfs_sysfs/zfs_get_unsupported.ksh \ functional/cli_root/zfs_sysfs/zfs_set_unsupported.ksh \ functional/cli_root/zfs_sysfs/zfs_sysfs_live.ksh \ functional/cli_root/zfs_sysfs/zpool_get_unsupported.ksh \ functional/cli_root/zfs_sysfs/zpool_set_unsupported.ksh \ functional/cli_root/zfs_unload-key/cleanup.ksh \ functional/cli_root/zfs_unload-key/setup.ksh \ functional/cli_root/zfs_unload-key/zfs_unload-key_all.ksh \ functional/cli_root/zfs_unload-key/zfs_unload-key.ksh \ functional/cli_root/zfs_unload-key/zfs_unload-key_recursive.ksh \ functional/cli_root/zfs_unmount/cleanup.ksh \ functional/cli_root/zfs_unmount/setup.ksh \ functional/cli_root/zfs_unmount/zfs_unmount_001_pos.ksh \ functional/cli_root/zfs_unmount/zfs_unmount_002_pos.ksh \ functional/cli_root/zfs_unmount/zfs_unmount_003_pos.ksh \ functional/cli_root/zfs_unmount/zfs_unmount_004_pos.ksh \ functional/cli_root/zfs_unmount/zfs_unmount_005_pos.ksh \ functional/cli_root/zfs_unmount/zfs_unmount_006_pos.ksh \ functional/cli_root/zfs_unmount/zfs_unmount_007_neg.ksh \ functional/cli_root/zfs_unmount/zfs_unmount_008_neg.ksh \ functional/cli_root/zfs_unmount/zfs_unmount_009_pos.ksh \ functional/cli_root/zfs_unmount/zfs_unmount_all_001_pos.ksh \ functional/cli_root/zfs_unmount/zfs_unmount_nested.ksh \ functional/cli_root/zfs_unmount/zfs_unmount_unload_keys.ksh \ functional/cli_root/zfs_unshare/cleanup.ksh \ functional/cli_root/zfs_unshare/setup.ksh \ functional/cli_root/zfs_unshare/zfs_unshare_001_pos.ksh \ functional/cli_root/zfs_unshare/zfs_unshare_002_pos.ksh \ functional/cli_root/zfs_unshare/zfs_unshare_003_pos.ksh \ functional/cli_root/zfs_unshare/zfs_unshare_004_neg.ksh \ functional/cli_root/zfs_unshare/zfs_unshare_005_neg.ksh \ functional/cli_root/zfs_unshare/zfs_unshare_006_pos.ksh \ functional/cli_root/zfs_unshare/zfs_unshare_007_pos.ksh \ functional/cli_root/zfs_unshare/zfs_unshare_008_pos.ksh \ functional/cli_root/zfs_upgrade/cleanup.ksh \ functional/cli_root/zfs_upgrade/setup.ksh \ functional/cli_root/zfs_upgrade/zfs_upgrade_001_pos.ksh \ functional/cli_root/zfs_upgrade/zfs_upgrade_002_pos.ksh \ functional/cli_root/zfs_upgrade/zfs_upgrade_003_pos.ksh \ functional/cli_root/zfs_upgrade/zfs_upgrade_004_pos.ksh \ functional/cli_root/zfs_upgrade/zfs_upgrade_005_pos.ksh \ functional/cli_root/zfs_upgrade/zfs_upgrade_006_neg.ksh \ functional/cli_root/zfs_upgrade/zfs_upgrade_007_neg.ksh \ functional/cli_root/zfs_wait/cleanup.ksh \ functional/cli_root/zfs_wait/setup.ksh \ functional/cli_root/zfs_wait/zfs_wait_deleteq.ksh \ functional/cli_root/zfs_wait/zfs_wait_getsubopt.ksh \ functional/cli_root/zfs/zfs_001_neg.ksh \ functional/cli_root/zfs/zfs_002_pos.ksh \ functional/cli_root/zfs/zfs_003_neg.ksh \ functional/cli_root/zhack/zhack_label_repair_001.ksh \ functional/cli_root/zhack/zhack_label_repair_002.ksh \ functional/cli_root/zhack/zhack_label_repair_003.ksh \ functional/cli_root/zhack/zhack_label_repair_004.ksh \ functional/cli_root/zpool_add/add_nested_replacing_spare.ksh \ functional/cli_root/zpool_add/add-o_ashift.ksh \ functional/cli_root/zpool_add/add_prop_ashift.ksh \ functional/cli_root/zpool_add/cleanup.ksh \ functional/cli_root/zpool_add/setup.ksh \ functional/cli_root/zpool_add/zpool_add_001_pos.ksh \ functional/cli_root/zpool_add/zpool_add_002_pos.ksh \ functional/cli_root/zpool_add/zpool_add_003_pos.ksh \ functional/cli_root/zpool_add/zpool_add_004_pos.ksh \ functional/cli_root/zpool_add/zpool_add_005_pos.ksh \ functional/cli_root/zpool_add/zpool_add_006_pos.ksh \ functional/cli_root/zpool_add/zpool_add_007_neg.ksh \ functional/cli_root/zpool_add/zpool_add_008_neg.ksh \ functional/cli_root/zpool_add/zpool_add_009_neg.ksh \ functional/cli_root/zpool_add/zpool_add_010_pos.ksh \ functional/cli_root/zpool_add/zpool_add_dryrun_output.ksh \ functional/cli_root/zpool_attach/attach-o_ashift.ksh \ functional/cli_root/zpool_attach/cleanup.ksh \ functional/cli_root/zpool_attach/setup.ksh \ functional/cli_root/zpool_attach/zpool_attach_001_neg.ksh \ functional/cli_root/zpool/cleanup.ksh \ functional/cli_root/zpool_clear/cleanup.ksh \ functional/cli_root/zpool_clear/setup.ksh \ functional/cli_root/zpool_clear/zpool_clear_001_pos.ksh \ functional/cli_root/zpool_clear/zpool_clear_002_neg.ksh \ functional/cli_root/zpool_clear/zpool_clear_003_neg.ksh \ functional/cli_root/zpool_clear/zpool_clear_readonly.ksh \ functional/cli_root/zpool_create/cleanup.ksh \ functional/cli_root/zpool_create/create-o_ashift.ksh \ functional/cli_root/zpool_create/setup.ksh \ functional/cli_root/zpool_create/zpool_create_001_pos.ksh \ functional/cli_root/zpool_create/zpool_create_002_pos.ksh \ functional/cli_root/zpool_create/zpool_create_003_pos.ksh \ functional/cli_root/zpool_create/zpool_create_004_pos.ksh \ functional/cli_root/zpool_create/zpool_create_005_pos.ksh \ functional/cli_root/zpool_create/zpool_create_006_pos.ksh \ functional/cli_root/zpool_create/zpool_create_007_neg.ksh \ functional/cli_root/zpool_create/zpool_create_008_pos.ksh \ functional/cli_root/zpool_create/zpool_create_009_neg.ksh \ functional/cli_root/zpool_create/zpool_create_010_neg.ksh \ functional/cli_root/zpool_create/zpool_create_011_neg.ksh \ functional/cli_root/zpool_create/zpool_create_012_neg.ksh \ functional/cli_root/zpool_create/zpool_create_014_neg.ksh \ functional/cli_root/zpool_create/zpool_create_015_neg.ksh \ functional/cli_root/zpool_create/zpool_create_016_pos.ksh \ functional/cli_root/zpool_create/zpool_create_017_neg.ksh \ functional/cli_root/zpool_create/zpool_create_018_pos.ksh \ functional/cli_root/zpool_create/zpool_create_019_pos.ksh \ functional/cli_root/zpool_create/zpool_create_020_pos.ksh \ functional/cli_root/zpool_create/zpool_create_021_pos.ksh \ functional/cli_root/zpool_create/zpool_create_022_pos.ksh \ functional/cli_root/zpool_create/zpool_create_023_neg.ksh \ functional/cli_root/zpool_create/zpool_create_024_pos.ksh \ functional/cli_root/zpool_create/zpool_create_crypt_combos.ksh \ functional/cli_root/zpool_create/zpool_create_draid_001_pos.ksh \ functional/cli_root/zpool_create/zpool_create_draid_002_pos.ksh \ functional/cli_root/zpool_create/zpool_create_draid_003_pos.ksh \ functional/cli_root/zpool_create/zpool_create_draid_004_pos.ksh \ functional/cli_root/zpool_create/zpool_create_dryrun_output.ksh \ functional/cli_root/zpool_create/zpool_create_encrypted.ksh \ functional/cli_root/zpool_create/zpool_create_features_001_pos.ksh \ functional/cli_root/zpool_create/zpool_create_features_002_pos.ksh \ functional/cli_root/zpool_create/zpool_create_features_003_pos.ksh \ functional/cli_root/zpool_create/zpool_create_features_004_neg.ksh \ functional/cli_root/zpool_create/zpool_create_features_005_pos.ksh \ functional/cli_root/zpool_create/zpool_create_features_006_pos.ksh \ functional/cli_root/zpool_create/zpool_create_features_007_pos.ksh \ functional/cli_root/zpool_create/zpool_create_features_008_pos.ksh \ functional/cli_root/zpool_create/zpool_create_features_009_pos.ksh \ functional/cli_root/zpool_create/zpool_create_tempname.ksh \ functional/cli_root/zpool_destroy/zpool_destroy_001_pos.ksh \ functional/cli_root/zpool_destroy/zpool_destroy_002_pos.ksh \ functional/cli_root/zpool_destroy/zpool_destroy_003_neg.ksh \ functional/cli_root/zpool_detach/cleanup.ksh \ functional/cli_root/zpool_detach/setup.ksh \ functional/cli_root/zpool_detach/zpool_detach_001_neg.ksh \ functional/cli_root/zpool_events/cleanup.ksh \ functional/cli_root/zpool_events/setup.ksh \ functional/cli_root/zpool_events/zpool_events_clear.ksh \ functional/cli_root/zpool_events/zpool_events_clear_retained.ksh \ functional/cli_root/zpool_events/zpool_events_cliargs.ksh \ functional/cli_root/zpool_events/zpool_events_duplicates.ksh \ functional/cli_root/zpool_events/zpool_events_errors.ksh \ functional/cli_root/zpool_events/zpool_events_follow.ksh \ functional/cli_root/zpool_events/zpool_events_poolname.ksh \ functional/cli_root/zpool_expand/cleanup.ksh \ functional/cli_root/zpool_expand/setup.ksh \ functional/cli_root/zpool_expand/zpool_expand_001_pos.ksh \ functional/cli_root/zpool_expand/zpool_expand_002_pos.ksh \ functional/cli_root/zpool_expand/zpool_expand_003_neg.ksh \ functional/cli_root/zpool_expand/zpool_expand_004_pos.ksh \ functional/cli_root/zpool_expand/zpool_expand_005_pos.ksh \ functional/cli_root/zpool_export/cleanup.ksh \ functional/cli_root/zpool_export/setup.ksh \ functional/cli_root/zpool_export/zpool_export_001_pos.ksh \ functional/cli_root/zpool_export/zpool_export_002_pos.ksh \ functional/cli_root/zpool_export/zpool_export_003_neg.ksh \ functional/cli_root/zpool_export/zpool_export_004_pos.ksh \ functional/cli_root/zpool_get/cleanup.ksh \ functional/cli_root/zpool_get/setup.ksh \ functional/cli_root/zpool_get/vdev_get_001_pos.ksh \ functional/cli_root/zpool_get/zpool_get_001_pos.ksh \ functional/cli_root/zpool_get/zpool_get_002_pos.ksh \ functional/cli_root/zpool_get/zpool_get_003_pos.ksh \ functional/cli_root/zpool_get/zpool_get_004_neg.ksh \ functional/cli_root/zpool_get/zpool_get_005_pos.ksh \ functional/cli_root/zpool_history/cleanup.ksh \ functional/cli_root/zpool_history/setup.ksh \ functional/cli_root/zpool_history/zpool_history_001_neg.ksh \ functional/cli_root/zpool_history/zpool_history_002_pos.ksh \ functional/cli_root/zpool_import/cleanup.ksh \ functional/cli_root/zpool_import/import_cachefile_device_added.ksh \ functional/cli_root/zpool_import/import_cachefile_device_removed.ksh \ functional/cli_root/zpool_import/import_cachefile_device_replaced.ksh \ functional/cli_root/zpool_import/import_cachefile_mirror_attached.ksh \ functional/cli_root/zpool_import/import_cachefile_mirror_detached.ksh \ functional/cli_root/zpool_import/import_cachefile_paths_changed.ksh \ functional/cli_root/zpool_import/import_cachefile_shared_device.ksh \ functional/cli_root/zpool_import/import_devices_missing.ksh \ functional/cli_root/zpool_import/import_log_missing.ksh \ functional/cli_root/zpool_import/import_paths_changed.ksh \ functional/cli_root/zpool_import/import_rewind_config_changed.ksh \ functional/cli_root/zpool_import/import_rewind_device_replaced.ksh \ functional/cli_root/zpool_import/setup.ksh \ functional/cli_root/zpool_import/zpool_import_001_pos.ksh \ functional/cli_root/zpool_import/zpool_import_002_pos.ksh \ functional/cli_root/zpool_import/zpool_import_003_pos.ksh \ functional/cli_root/zpool_import/zpool_import_004_pos.ksh \ functional/cli_root/zpool_import/zpool_import_005_pos.ksh \ functional/cli_root/zpool_import/zpool_import_006_pos.ksh \ functional/cli_root/zpool_import/zpool_import_007_pos.ksh \ functional/cli_root/zpool_import/zpool_import_008_pos.ksh \ functional/cli_root/zpool_import/zpool_import_009_neg.ksh \ functional/cli_root/zpool_import/zpool_import_010_pos.ksh \ functional/cli_root/zpool_import/zpool_import_011_neg.ksh \ functional/cli_root/zpool_import/zpool_import_012_pos.ksh \ functional/cli_root/zpool_import/zpool_import_013_neg.ksh \ functional/cli_root/zpool_import/zpool_import_014_pos.ksh \ functional/cli_root/zpool_import/zpool_import_015_pos.ksh \ functional/cli_root/zpool_import/zpool_import_016_pos.ksh \ functional/cli_root/zpool_import/zpool_import_017_pos.ksh \ functional/cli_root/zpool_import/zpool_import_all_001_pos.ksh \ functional/cli_root/zpool_import/zpool_import_encrypted.ksh \ functional/cli_root/zpool_import/zpool_import_encrypted_load.ksh \ functional/cli_root/zpool_import/zpool_import_errata3.ksh \ functional/cli_root/zpool_import/zpool_import_errata4.ksh \ functional/cli_root/zpool_import/zpool_import_features_001_pos.ksh \ functional/cli_root/zpool_import/zpool_import_features_002_neg.ksh \ functional/cli_root/zpool_import/zpool_import_features_003_pos.ksh \ functional/cli_root/zpool_import/zpool_import_hostid_changed.ksh \ functional/cli_root/zpool_import/zpool_import_hostid_changed_unclean_export.ksh \ functional/cli_root/zpool_import/zpool_import_hostid_changed_cachefile.ksh \ functional/cli_root/zpool_import/zpool_import_hostid_changed_cachefile_unclean_export.ksh \ functional/cli_root/zpool_import/zpool_import_missing_001_pos.ksh \ functional/cli_root/zpool_import/zpool_import_missing_002_pos.ksh \ functional/cli_root/zpool_import/zpool_import_missing_003_pos.ksh \ functional/cli_root/zpool_import/zpool_import_rename_001_pos.ksh \ functional/cli_root/zpool_initialize/cleanup.ksh \ functional/cli_root/zpool_initialize/zpool_initialize_attach_detach_add_remove.ksh \ functional/cli_root/zpool_initialize/zpool_initialize_fault_export_import_online.ksh \ functional/cli_root/zpool_initialize/zpool_initialize_import_export.ksh \ functional/cli_root/zpool_initialize/zpool_initialize_offline_export_import_online.ksh \ functional/cli_root/zpool_initialize/zpool_initialize_online_offline.ksh \ functional/cli_root/zpool_initialize/zpool_initialize_split.ksh \ functional/cli_root/zpool_initialize/zpool_initialize_start_and_cancel_neg.ksh \ functional/cli_root/zpool_initialize/zpool_initialize_start_and_cancel_pos.ksh \ functional/cli_root/zpool_initialize/zpool_initialize_suspend_resume.ksh \ functional/cli_root/zpool_initialize/zpool_initialize_uninit.ksh \ functional/cli_root/zpool_initialize/zpool_initialize_unsupported_vdevs.ksh \ functional/cli_root/zpool_initialize/zpool_initialize_verify_checksums.ksh \ functional/cli_root/zpool_initialize/zpool_initialize_verify_initialized.ksh \ functional/cli_root/zpool_labelclear/zpool_labelclear_active.ksh \ functional/cli_root/zpool_labelclear/zpool_labelclear_exported.ksh \ functional/cli_root/zpool_labelclear/zpool_labelclear_removed.ksh \ functional/cli_root/zpool_labelclear/zpool_labelclear_valid.ksh \ functional/cli_root/zpool_offline/cleanup.ksh \ functional/cli_root/zpool_offline/setup.ksh \ functional/cli_root/zpool_offline/zpool_offline_001_pos.ksh \ functional/cli_root/zpool_offline/zpool_offline_002_neg.ksh \ functional/cli_root/zpool_offline/zpool_offline_003_pos.ksh \ functional/cli_root/zpool_online/cleanup.ksh \ functional/cli_root/zpool_online/setup.ksh \ functional/cli_root/zpool_online/zpool_online_001_pos.ksh \ functional/cli_root/zpool_online/zpool_online_002_neg.ksh \ functional/cli_root/zpool_remove/cleanup.ksh \ functional/cli_root/zpool_remove/setup.ksh \ functional/cli_root/zpool_remove/zpool_remove_001_neg.ksh \ functional/cli_root/zpool_remove/zpool_remove_002_pos.ksh \ functional/cli_root/zpool_remove/zpool_remove_003_pos.ksh \ functional/cli_root/zpool_reopen/cleanup.ksh \ functional/cli_root/zpool_reopen/setup.ksh \ functional/cli_root/zpool_reopen/zpool_reopen_001_pos.ksh \ functional/cli_root/zpool_reopen/zpool_reopen_002_pos.ksh \ functional/cli_root/zpool_reopen/zpool_reopen_003_pos.ksh \ functional/cli_root/zpool_reopen/zpool_reopen_004_pos.ksh \ functional/cli_root/zpool_reopen/zpool_reopen_005_pos.ksh \ functional/cli_root/zpool_reopen/zpool_reopen_006_neg.ksh \ functional/cli_root/zpool_reopen/zpool_reopen_007_pos.ksh \ functional/cli_root/zpool_replace/cleanup.ksh \ functional/cli_root/zpool_replace/replace-o_ashift.ksh \ functional/cli_root/zpool_replace/replace_prop_ashift.ksh \ functional/cli_root/zpool_replace/setup.ksh \ functional/cli_root/zpool_replace/zpool_replace_001_neg.ksh \ functional/cli_root/zpool_resilver/cleanup.ksh \ functional/cli_root/zpool_resilver/setup.ksh \ functional/cli_root/zpool_resilver/zpool_resilver_bad_args.ksh \ functional/cli_root/zpool_resilver/zpool_resilver_restart.ksh \ functional/cli_root/zpool_resilver/zpool_resilver_concurrent.ksh \ functional/cli_root/zpool_scrub/cleanup.ksh \ functional/cli_root/zpool_scrub/setup.ksh \ functional/cli_root/zpool_scrub/zpool_scrub_001_neg.ksh \ functional/cli_root/zpool_scrub/zpool_scrub_002_pos.ksh \ functional/cli_root/zpool_scrub/zpool_scrub_003_pos.ksh \ functional/cli_root/zpool_scrub/zpool_scrub_004_pos.ksh \ functional/cli_root/zpool_scrub/zpool_scrub_005_pos.ksh \ functional/cli_root/zpool_scrub/zpool_scrub_encrypted_unloaded.ksh \ functional/cli_root/zpool_scrub/zpool_scrub_multiple_copies.ksh \ functional/cli_root/zpool_scrub/zpool_scrub_offline_device.ksh \ functional/cli_root/zpool_scrub/zpool_scrub_print_repairing.ksh \ functional/cli_root/zpool_scrub/zpool_error_scrub_001_pos.ksh \ functional/cli_root/zpool_scrub/zpool_error_scrub_002_pos.ksh \ functional/cli_root/zpool_scrub/zpool_error_scrub_003_pos.ksh \ functional/cli_root/zpool_scrub/zpool_error_scrub_004_pos.ksh \ functional/cli_root/zpool_set/cleanup.ksh \ functional/cli_root/zpool_set/setup.ksh \ functional/cli_root/zpool/setup.ksh \ functional/cli_root/zpool_set/vdev_set_001_pos.ksh \ functional/cli_root/zpool_set/zpool_set_common.kshlib \ functional/cli_root/zpool_set/zpool_set_001_pos.ksh \ functional/cli_root/zpool_set/zpool_set_002_neg.ksh \ functional/cli_root/zpool_set/zpool_set_003_neg.ksh \ functional/cli_root/zpool_set/zpool_set_ashift.ksh \ functional/cli_root/zpool_set/user_property_001_pos.ksh \ functional/cli_root/zpool_set/user_property_002_neg.ksh \ functional/cli_root/zpool_set/zpool_set_features.ksh \ functional/cli_root/zpool_split/cleanup.ksh \ functional/cli_root/zpool_split/setup.ksh \ functional/cli_root/zpool_split/zpool_split_cliargs.ksh \ functional/cli_root/zpool_split/zpool_split_devices.ksh \ functional/cli_root/zpool_split/zpool_split_dryrun_output.ksh \ functional/cli_root/zpool_split/zpool_split_encryption.ksh \ functional/cli_root/zpool_split/zpool_split_indirect.ksh \ functional/cli_root/zpool_split/zpool_split_props.ksh \ functional/cli_root/zpool_split/zpool_split_resilver.ksh \ functional/cli_root/zpool_split/zpool_split_vdevs.ksh \ functional/cli_root/zpool_split/zpool_split_wholedisk.ksh \ functional/cli_root/zpool_status/cleanup.ksh \ functional/cli_root/zpool_status/setup.ksh \ functional/cli_root/zpool_status/zpool_status_001_pos.ksh \ functional/cli_root/zpool_status/zpool_status_002_pos.ksh \ functional/cli_root/zpool_status/zpool_status_003_pos.ksh \ functional/cli_root/zpool_status/zpool_status_004_pos.ksh \ functional/cli_root/zpool_status/zpool_status_005_pos.ksh \ functional/cli_root/zpool_status/zpool_status_006_pos.ksh \ functional/cli_root/zpool_status/zpool_status_007_pos.ksh \ functional/cli_root/zpool_status/zpool_status_features_001_pos.ksh \ functional/cli_root/zpool_sync/cleanup.ksh \ functional/cli_root/zpool_sync/setup.ksh \ functional/cli_root/zpool_sync/zpool_sync_001_pos.ksh \ functional/cli_root/zpool_sync/zpool_sync_002_neg.ksh \ functional/cli_root/zpool_trim/cleanup.ksh \ functional/cli_root/zpool_trim/setup.ksh \ functional/cli_root/zpool_trim/zpool_trim_attach_detach_add_remove.ksh \ functional/cli_root/zpool_trim/zpool_trim_fault_export_import_online.ksh \ functional/cli_root/zpool_trim/zpool_trim_import_export.ksh \ functional/cli_root/zpool_trim/zpool_trim_multiple.ksh \ functional/cli_root/zpool_trim/zpool_trim_neg.ksh \ functional/cli_root/zpool_trim/zpool_trim_offline_export_import_online.ksh \ functional/cli_root/zpool_trim/zpool_trim_online_offline.ksh \ functional/cli_root/zpool_trim/zpool_trim_partial.ksh \ functional/cli_root/zpool_trim/zpool_trim_rate.ksh \ functional/cli_root/zpool_trim/zpool_trim_rate_neg.ksh \ functional/cli_root/zpool_trim/zpool_trim_secure.ksh \ functional/cli_root/zpool_trim/zpool_trim_split.ksh \ functional/cli_root/zpool_trim/zpool_trim_start_and_cancel_neg.ksh \ functional/cli_root/zpool_trim/zpool_trim_start_and_cancel_pos.ksh \ functional/cli_root/zpool_trim/zpool_trim_suspend_resume.ksh \ functional/cli_root/zpool_trim/zpool_trim_unsupported_vdevs.ksh \ functional/cli_root/zpool_trim/zpool_trim_verify_checksums.ksh \ functional/cli_root/zpool_trim/zpool_trim_verify_trimmed.ksh \ functional/cli_root/zpool_upgrade/cleanup.ksh \ functional/cli_root/zpool_upgrade/setup.ksh \ functional/cli_root/zpool_upgrade/zpool_upgrade_001_pos.ksh \ functional/cli_root/zpool_upgrade/zpool_upgrade_002_pos.ksh \ functional/cli_root/zpool_upgrade/zpool_upgrade_003_pos.ksh \ functional/cli_root/zpool_upgrade/zpool_upgrade_004_pos.ksh \ functional/cli_root/zpool_upgrade/zpool_upgrade_005_neg.ksh \ functional/cli_root/zpool_upgrade/zpool_upgrade_006_neg.ksh \ functional/cli_root/zpool_upgrade/zpool_upgrade_007_pos.ksh \ functional/cli_root/zpool_upgrade/zpool_upgrade_008_pos.ksh \ functional/cli_root/zpool_upgrade/zpool_upgrade_009_neg.ksh \ functional/cli_root/zpool_upgrade/zpool_upgrade_features_001_pos.ksh \ functional/cli_root/zpool_wait/cleanup.ksh \ functional/cli_root/zpool_wait/scan/cleanup.ksh \ functional/cli_root/zpool_wait/scan/setup.ksh \ functional/cli_root/zpool_wait/scan/zpool_wait_rebuild.ksh \ functional/cli_root/zpool_wait/scan/zpool_wait_replace_cancel.ksh \ functional/cli_root/zpool_wait/scan/zpool_wait_replace.ksh \ functional/cli_root/zpool_wait/scan/zpool_wait_resilver.ksh \ functional/cli_root/zpool_wait/scan/zpool_wait_scrub_basic.ksh \ functional/cli_root/zpool_wait/scan/zpool_wait_scrub_cancel.ksh \ functional/cli_root/zpool_wait/scan/zpool_wait_scrub_flag.ksh \ functional/cli_root/zpool_wait/setup.ksh \ functional/cli_root/zpool_wait/zpool_wait_discard.ksh \ functional/cli_root/zpool_wait/zpool_wait_freeing.ksh \ functional/cli_root/zpool_wait/zpool_wait_initialize_basic.ksh \ functional/cli_root/zpool_wait/zpool_wait_initialize_cancel.ksh \ functional/cli_root/zpool_wait/zpool_wait_initialize_flag.ksh \ functional/cli_root/zpool_wait/zpool_wait_multiple.ksh \ functional/cli_root/zpool_wait/zpool_wait_no_activity.ksh \ functional/cli_root/zpool_wait/zpool_wait_remove_cancel.ksh \ functional/cli_root/zpool_wait/zpool_wait_remove.ksh \ functional/cli_root/zpool_wait/zpool_wait_trim_basic.ksh \ functional/cli_root/zpool_wait/zpool_wait_trim_cancel.ksh \ functional/cli_root/zpool_wait/zpool_wait_trim_flag.ksh \ functional/cli_root/zpool_wait/zpool_wait_usage.ksh \ functional/cli_root/zpool/zpool_001_neg.ksh \ functional/cli_root/zpool/zpool_002_pos.ksh \ functional/cli_root/zpool/zpool_003_pos.ksh \ functional/cli_root/zpool/zpool_colors.ksh \ functional/cli_user/misc/arcstat_001_pos.ksh \ functional/cli_user/misc/arc_summary_001_pos.ksh \ functional/cli_user/misc/arc_summary_002_neg.ksh \ functional/cli_user/misc/zilstat_001_pos.ksh \ functional/cli_user/misc/cleanup.ksh \ functional/cli_user/misc/setup.ksh \ functional/cli_user/misc/zdb_001_neg.ksh \ functional/cli_user/misc/zfs_001_neg.ksh \ functional/cli_user/misc/zfs_allow_001_neg.ksh \ functional/cli_user/misc/zfs_clone_001_neg.ksh \ functional/cli_user/misc/zfs_create_001_neg.ksh \ functional/cli_user/misc/zfs_destroy_001_neg.ksh \ functional/cli_user/misc/zfs_get_001_neg.ksh \ functional/cli_user/misc/zfs_inherit_001_neg.ksh \ functional/cli_user/misc/zfs_mount_001_neg.ksh \ functional/cli_user/misc/zfs_promote_001_neg.ksh \ functional/cli_user/misc/zfs_receive_001_neg.ksh \ functional/cli_user/misc/zfs_rename_001_neg.ksh \ functional/cli_user/misc/zfs_rollback_001_neg.ksh \ functional/cli_user/misc/zfs_send_001_neg.ksh \ functional/cli_user/misc/zfs_set_001_neg.ksh \ functional/cli_user/misc/zfs_share_001_neg.ksh \ functional/cli_user/misc/zfs_snapshot_001_neg.ksh \ functional/cli_user/misc/zfs_unallow_001_neg.ksh \ functional/cli_user/misc/zfs_unmount_001_neg.ksh \ functional/cli_user/misc/zfs_unshare_001_neg.ksh \ functional/cli_user/misc/zfs_upgrade_001_neg.ksh \ functional/cli_user/misc/zpool_001_neg.ksh \ functional/cli_user/misc/zpool_add_001_neg.ksh \ functional/cli_user/misc/zpool_attach_001_neg.ksh \ functional/cli_user/misc/zpool_clear_001_neg.ksh \ functional/cli_user/misc/zpool_create_001_neg.ksh \ functional/cli_user/misc/zpool_destroy_001_neg.ksh \ functional/cli_user/misc/zpool_detach_001_neg.ksh \ functional/cli_user/misc/zpool_export_001_neg.ksh \ functional/cli_user/misc/zpool_get_001_neg.ksh \ functional/cli_user/misc/zpool_history_001_neg.ksh \ functional/cli_user/misc/zpool_import_001_neg.ksh \ functional/cli_user/misc/zpool_import_002_neg.ksh \ functional/cli_user/misc/zpool_offline_001_neg.ksh \ functional/cli_user/misc/zpool_online_001_neg.ksh \ functional/cli_user/misc/zpool_remove_001_neg.ksh \ functional/cli_user/misc/zpool_replace_001_neg.ksh \ functional/cli_user/misc/zpool_scrub_001_neg.ksh \ functional/cli_user/misc/zpool_set_001_neg.ksh \ functional/cli_user/misc/zpool_status_001_neg.ksh \ functional/cli_user/misc/zpool_upgrade_001_neg.ksh \ functional/cli_user/misc/zpool_wait_privilege.ksh \ functional/cli_user/zfs_list/cleanup.ksh \ functional/cli_user/zfs_list/setup.ksh \ functional/cli_user/zfs_list/zfs_list_001_pos.ksh \ functional/cli_user/zfs_list/zfs_list_002_pos.ksh \ functional/cli_user/zfs_list/zfs_list_003_pos.ksh \ functional/cli_user/zfs_list/zfs_list_004_neg.ksh \ functional/cli_user/zfs_list/zfs_list_005_neg.ksh \ functional/cli_user/zfs_list/zfs_list_007_pos.ksh \ functional/cli_user/zfs_list/zfs_list_008_neg.ksh \ functional/cli_user/zpool_iostat/cleanup.ksh \ functional/cli_user/zpool_iostat/setup.ksh \ functional/cli_user/zpool_iostat/zpool_iostat_001_neg.ksh \ functional/cli_user/zpool_iostat/zpool_iostat_002_pos.ksh \ functional/cli_user/zpool_iostat/zpool_iostat_003_neg.ksh \ functional/cli_user/zpool_iostat/zpool_iostat_004_pos.ksh \ functional/cli_user/zpool_iostat/zpool_iostat_005_pos.ksh \ functional/cli_user/zpool_iostat/zpool_iostat_-c_disable.ksh \ functional/cli_user/zpool_iostat/zpool_iostat_-c_homedir.ksh \ functional/cli_user/zpool_iostat/zpool_iostat_-c_searchpath.ksh \ functional/cli_user/zpool_list/cleanup.ksh \ functional/cli_user/zpool_list/setup.ksh \ functional/cli_user/zpool_list/zpool_list_001_pos.ksh \ functional/cli_user/zpool_list/zpool_list_002_neg.ksh \ functional/cli_user/zpool_status/cleanup.ksh \ functional/cli_user/zpool_status/setup.ksh \ functional/cli_user/zpool_status/zpool_status_003_pos.ksh \ functional/cli_user/zpool_status/zpool_status_-c_disable.ksh \ functional/cli_user/zpool_status/zpool_status_-c_homedir.ksh \ functional/cli_user/zpool_status/zpool_status_-c_searchpath.ksh \ functional/compression/cleanup.ksh \ functional/compression/compress_001_pos.ksh \ functional/compression/compress_002_pos.ksh \ functional/compression/compress_003_pos.ksh \ functional/compression/compress_004_pos.ksh \ functional/compression/compress_zstd_bswap.ksh \ functional/compression/l2arc_compressed_arc_disabled.ksh \ functional/compression/l2arc_compressed_arc.ksh \ functional/compression/l2arc_encrypted.ksh \ functional/compression/l2arc_encrypted_no_compressed_arc.ksh \ functional/compression/setup.ksh \ functional/cp_files/cleanup.ksh \ functional/cp_files/cp_files_001_pos.ksh \ functional/cp_files/setup.ksh \ functional/crtime/cleanup.ksh \ functional/crtime/crtime_001_pos.ksh \ functional/crtime/setup.ksh \ functional/ctime/cleanup.ksh \ functional/ctime/ctime_001_pos.ksh \ functional/ctime/setup.ksh \ functional/deadman/deadman_ratelimit.ksh \ functional/deadman/deadman_sync.ksh \ functional/deadman/deadman_zio.ksh \ functional/delegate/cleanup.ksh \ functional/delegate/setup.ksh \ functional/delegate/zfs_allow_001_pos.ksh \ functional/delegate/zfs_allow_002_pos.ksh \ functional/delegate/zfs_allow_003_pos.ksh \ functional/delegate/zfs_allow_004_pos.ksh \ functional/delegate/zfs_allow_005_pos.ksh \ functional/delegate/zfs_allow_006_pos.ksh \ functional/delegate/zfs_allow_007_pos.ksh \ functional/delegate/zfs_allow_008_pos.ksh \ functional/delegate/zfs_allow_009_neg.ksh \ functional/delegate/zfs_allow_010_pos.ksh \ functional/delegate/zfs_allow_011_neg.ksh \ functional/delegate/zfs_allow_012_neg.ksh \ functional/delegate/zfs_unallow_001_pos.ksh \ functional/delegate/zfs_unallow_002_pos.ksh \ functional/delegate/zfs_unallow_003_pos.ksh \ functional/delegate/zfs_unallow_004_pos.ksh \ functional/delegate/zfs_unallow_005_pos.ksh \ functional/delegate/zfs_unallow_006_pos.ksh \ functional/delegate/zfs_unallow_007_neg.ksh \ functional/delegate/zfs_unallow_008_neg.ksh \ functional/devices/cleanup.ksh \ functional/devices/devices_001_pos.ksh \ functional/devices/devices_002_neg.ksh \ functional/devices/devices_003_pos.ksh \ functional/devices/setup.ksh \ functional/dos_attributes/cleanup.ksh \ functional/dos_attributes/read_dos_attrs_001.ksh \ functional/dos_attributes/setup.ksh \ functional/dos_attributes/write_dos_attrs_001.ksh \ functional/events/cleanup.ksh \ functional/events/events_001_pos.ksh \ functional/events/events_002_pos.ksh \ functional/events/setup.ksh \ functional/events/zed_cksum_config.ksh \ functional/events/zed_cksum_reported.ksh \ functional/events/zed_fd_spill.ksh \ functional/events/zed_io_config.ksh \ functional/events/zed_rc_filter.ksh \ functional/exec/cleanup.ksh \ functional/exec/exec_001_pos.ksh \ functional/exec/exec_002_neg.ksh \ functional/exec/setup.ksh \ functional/fadvise/cleanup.ksh \ functional/fadvise/fadvise_sequential.ksh \ functional/fadvise/setup.ksh \ functional/fallocate/cleanup.ksh \ functional/fallocate/fallocate_prealloc.ksh \ functional/fallocate/fallocate_punch-hole.ksh \ functional/fallocate/fallocate_zero-range.ksh \ functional/fallocate/setup.ksh \ functional/fault/auto_offline_001_pos.ksh \ functional/fault/auto_online_001_pos.ksh \ functional/fault/auto_online_002_pos.ksh \ functional/fault/auto_replace_001_pos.ksh \ + functional/fault/auto_replace_002_pos.ksh \ functional/fault/auto_spare_001_pos.ksh \ functional/fault/auto_spare_002_pos.ksh \ functional/fault/auto_spare_ashift.ksh \ functional/fault/auto_spare_multiple.ksh \ functional/fault/auto_spare_shared.ksh \ functional/fault/cleanup.ksh \ functional/fault/decompress_fault.ksh \ functional/fault/decrypt_fault.ksh \ functional/fault/scrub_after_resilver.ksh \ functional/fault/setup.ksh \ functional/fault/zpool_status_-s.ksh \ functional/features/async_destroy/async_destroy_001_pos.ksh \ functional/features/async_destroy/cleanup.ksh \ functional/features/async_destroy/setup.ksh \ functional/features/large_dnode/cleanup.ksh \ functional/features/large_dnode/large_dnode_001_pos.ksh \ functional/features/large_dnode/large_dnode_002_pos.ksh \ functional/features/large_dnode/large_dnode_003_pos.ksh \ functional/features/large_dnode/large_dnode_004_neg.ksh \ functional/features/large_dnode/large_dnode_005_pos.ksh \ functional/features/large_dnode/large_dnode_006_pos.ksh \ functional/features/large_dnode/large_dnode_007_neg.ksh \ functional/features/large_dnode/large_dnode_008_pos.ksh \ functional/features/large_dnode/large_dnode_009_pos.ksh \ functional/features/large_dnode/setup.ksh \ functional/grow/grow_pool_001_pos.ksh \ functional/grow/grow_replicas_001_pos.ksh \ functional/history/cleanup.ksh \ functional/history/history_001_pos.ksh \ functional/history/history_002_pos.ksh \ functional/history/history_003_pos.ksh \ functional/history/history_004_pos.ksh \ functional/history/history_005_neg.ksh \ functional/history/history_006_neg.ksh \ functional/history/history_007_pos.ksh \ functional/history/history_008_pos.ksh \ functional/history/history_009_pos.ksh \ functional/history/history_010_pos.ksh \ functional/history/setup.ksh \ functional/inheritance/cleanup.ksh \ functional/inheritance/inherit_001_pos.ksh \ functional/inuse/inuse_001_pos.ksh \ functional/inuse/inuse_003_pos.ksh \ functional/inuse/inuse_004_pos.ksh \ functional/inuse/inuse_005_pos.ksh \ functional/inuse/inuse_006_pos.ksh \ functional/inuse/inuse_007_pos.ksh \ functional/inuse/inuse_008_pos.ksh \ functional/inuse/inuse_009_pos.ksh \ functional/inuse/setup.ksh \ functional/io/cleanup.ksh \ functional/io/io_uring.ksh \ functional/io/libaio.ksh \ functional/io/mmap.ksh \ functional/io/posixaio.ksh \ functional/io/psync.ksh \ functional/io/setup.ksh \ functional/io/sync.ksh \ functional/l2arc/cleanup.ksh \ functional/l2arc/l2arc_arcstats_pos.ksh \ functional/l2arc/l2arc_l2miss_pos.ksh \ functional/l2arc/l2arc_mfuonly_pos.ksh \ functional/l2arc/persist_l2arc_001_pos.ksh \ functional/l2arc/persist_l2arc_002_pos.ksh \ functional/l2arc/persist_l2arc_003_neg.ksh \ functional/l2arc/persist_l2arc_004_pos.ksh \ functional/l2arc/persist_l2arc_005_pos.ksh \ functional/l2arc/setup.ksh \ functional/large_files/cleanup.ksh \ functional/large_files/large_files_001_pos.ksh \ functional/large_files/large_files_002_pos.ksh \ functional/large_files/setup.ksh \ functional/largest_pool/largest_pool_001_pos.ksh \ functional/libzfs/cleanup.ksh \ functional/libzfs/libzfs_input.ksh \ functional/libzfs/setup.ksh \ functional/limits/cleanup.ksh \ functional/limits/filesystem_count.ksh \ functional/limits/filesystem_limit.ksh \ functional/limits/setup.ksh \ functional/limits/snapshot_count.ksh \ functional/limits/snapshot_limit.ksh \ functional/link_count/cleanup.ksh \ functional/link_count/link_count_001.ksh \ functional/link_count/link_count_root_inode.ksh \ functional/link_count/setup.ksh \ functional/log_spacemap/log_spacemap_import_logs.ksh \ functional/migration/cleanup.ksh \ functional/migration/migration_001_pos.ksh \ functional/migration/migration_002_pos.ksh \ functional/migration/migration_003_pos.ksh \ functional/migration/migration_004_pos.ksh \ functional/migration/migration_005_pos.ksh \ functional/migration/migration_006_pos.ksh \ functional/migration/migration_007_pos.ksh \ functional/migration/migration_008_pos.ksh \ functional/migration/migration_009_pos.ksh \ functional/migration/migration_010_pos.ksh \ functional/migration/migration_011_pos.ksh \ functional/migration/migration_012_pos.ksh \ functional/migration/setup.ksh \ functional/mmap/cleanup.ksh \ functional/mmap/mmap_libaio_001_pos.ksh \ functional/mmap/mmap_mixed.ksh \ functional/mmap/mmap_read_001_pos.ksh \ functional/mmap/mmap_seek_001_pos.ksh \ functional/mmap/mmap_sync_001_pos.ksh \ functional/mmap/mmap_write_001_pos.ksh \ functional/mmap/setup.ksh \ functional/mmp/cleanup.ksh \ functional/mmp/mmp_active_import.ksh \ functional/mmp/mmp_exported_import.ksh \ functional/mmp/mmp_hostid.ksh \ functional/mmp/mmp_inactive_import.ksh \ functional/mmp/mmp_interval.ksh \ functional/mmp/mmp_on_off.ksh \ functional/mmp/mmp_on_thread.ksh \ functional/mmp/mmp_on_uberblocks.ksh \ functional/mmp/mmp_on_zdb.ksh \ functional/mmp/mmp_reset_interval.ksh \ functional/mmp/mmp_write_distribution.ksh \ functional/mmp/mmp_write_uberblocks.ksh \ functional/mmp/multihost_history.ksh \ functional/mmp/setup.ksh \ functional/mount/cleanup.ksh \ functional/mount/setup.ksh \ functional/mount/umount_001.ksh \ functional/mount/umountall_001.ksh \ functional/mount/umount_unlinked_drain.ksh \ functional/mv_files/cleanup.ksh \ functional/mv_files/mv_files_001_pos.ksh \ functional/mv_files/mv_files_002_pos.ksh \ functional/mv_files/random_creation.ksh \ functional/mv_files/setup.ksh \ functional/nestedfs/cleanup.ksh \ functional/nestedfs/nestedfs_001_pos.ksh \ functional/nestedfs/setup.ksh \ functional/nopwrite/cleanup.ksh \ functional/nopwrite/nopwrite_copies.ksh \ functional/nopwrite/nopwrite_mtime.ksh \ functional/nopwrite/nopwrite_negative.ksh \ functional/nopwrite/nopwrite_promoted_clone.ksh \ functional/nopwrite/nopwrite_recsize.ksh \ functional/nopwrite/nopwrite_sync.ksh \ functional/nopwrite/nopwrite_varying_compression.ksh \ functional/nopwrite/nopwrite_volume.ksh \ functional/nopwrite/setup.ksh \ functional/no_space/cleanup.ksh \ functional/no_space/enospc_001_pos.ksh \ functional/no_space/enospc_002_pos.ksh \ functional/no_space/enospc_003_pos.ksh \ functional/no_space/enospc_df.ksh \ functional/no_space/enospc_ganging.ksh \ functional/no_space/enospc_rm.ksh \ functional/no_space/setup.ksh \ functional/online_offline/cleanup.ksh \ functional/online_offline/online_offline_001_pos.ksh \ functional/online_offline/online_offline_002_neg.ksh \ functional/online_offline/online_offline_003_neg.ksh \ functional/online_offline/setup.ksh \ functional/pam/cleanup.ksh \ functional/pam/pam_basic.ksh \ functional/pam/pam_change_unmounted.ksh \ functional/pam/pam_nounmount.ksh \ functional/pam/pam_recursive.ksh \ functional/pam/pam_short_password.ksh \ functional/pam/setup.ksh \ functional/pool_checkpoint/checkpoint_after_rewind.ksh \ functional/pool_checkpoint/checkpoint_big_rewind.ksh \ functional/pool_checkpoint/checkpoint_capacity.ksh \ functional/pool_checkpoint/checkpoint_conf_change.ksh \ functional/pool_checkpoint/checkpoint_discard_busy.ksh \ functional/pool_checkpoint/checkpoint_discard.ksh \ functional/pool_checkpoint/checkpoint_discard_many.ksh \ functional/pool_checkpoint/checkpoint_indirect.ksh \ functional/pool_checkpoint/checkpoint_invalid.ksh \ functional/pool_checkpoint/checkpoint_lun_expsz.ksh \ functional/pool_checkpoint/checkpoint_open.ksh \ functional/pool_checkpoint/checkpoint_removal.ksh \ functional/pool_checkpoint/checkpoint_rewind.ksh \ functional/pool_checkpoint/checkpoint_ro_rewind.ksh \ functional/pool_checkpoint/checkpoint_sm_scale.ksh \ functional/pool_checkpoint/checkpoint_twice.ksh \ functional/pool_checkpoint/checkpoint_vdev_add.ksh \ functional/pool_checkpoint/checkpoint_zdb.ksh \ functional/pool_checkpoint/checkpoint_zhack_feat.ksh \ functional/pool_checkpoint/cleanup.ksh \ functional/pool_checkpoint/setup.ksh \ functional/pool_names/pool_names_001_pos.ksh \ functional/pool_names/pool_names_002_neg.ksh \ functional/poolversion/cleanup.ksh \ functional/poolversion/poolversion_001_pos.ksh \ functional/poolversion/poolversion_002_pos.ksh \ functional/poolversion/setup.ksh \ functional/privilege/cleanup.ksh \ functional/privilege/privilege_001_pos.ksh \ functional/privilege/privilege_002_pos.ksh \ functional/privilege/setup.ksh \ functional/procfs/cleanup.ksh \ functional/procfs/pool_state.ksh \ functional/procfs/procfs_list_basic.ksh \ functional/procfs/procfs_list_concurrent_readers.ksh \ functional/procfs/procfs_list_stale_read.ksh \ functional/procfs/setup.ksh \ functional/projectquota/cleanup.ksh \ functional/projectquota/projectid_001_pos.ksh \ functional/projectquota/projectid_002_pos.ksh \ functional/projectquota/projectid_003_pos.ksh \ functional/projectquota/projectquota_001_pos.ksh \ functional/projectquota/projectquota_002_pos.ksh \ functional/projectquota/projectquota_003_pos.ksh \ functional/projectquota/projectquota_004_neg.ksh \ functional/projectquota/projectquota_005_pos.ksh \ functional/projectquota/projectquota_006_pos.ksh \ functional/projectquota/projectquota_007_pos.ksh \ functional/projectquota/projectquota_008_pos.ksh \ functional/projectquota/projectquota_009_pos.ksh \ functional/projectquota/projectspace_001_pos.ksh \ functional/projectquota/projectspace_002_pos.ksh \ functional/projectquota/projectspace_003_pos.ksh \ functional/projectquota/projectspace_004_pos.ksh \ functional/projectquota/projecttree_001_pos.ksh \ functional/projectquota/projecttree_002_pos.ksh \ functional/projectquota/projecttree_003_neg.ksh \ functional/projectquota/setup.ksh \ functional/quota/cleanup.ksh \ functional/quota/quota_001_pos.ksh \ functional/quota/quota_002_pos.ksh \ functional/quota/quota_003_pos.ksh \ functional/quota/quota_004_pos.ksh \ functional/quota/quota_005_pos.ksh \ functional/quota/quota_006_neg.ksh \ functional/quota/setup.ksh \ functional/raidz/cleanup.ksh \ functional/raidz/raidz_001_neg.ksh \ functional/raidz/raidz_002_pos.ksh \ functional/raidz/raidz_003_pos.ksh \ functional/raidz/raidz_004_pos.ksh \ functional/raidz/setup.ksh \ functional/redacted_send/cleanup.ksh \ functional/redacted_send/redacted_compressed.ksh \ functional/redacted_send/redacted_contents.ksh \ functional/redacted_send/redacted_deleted.ksh \ functional/redacted_send/redacted_disabled_feature.ksh \ functional/redacted_send/redacted_embedded.ksh \ functional/redacted_send/redacted_holes.ksh \ functional/redacted_send/redacted_incrementals.ksh \ functional/redacted_send/redacted_largeblocks.ksh \ functional/redacted_send/redacted_many_clones.ksh \ functional/redacted_send/redacted_mixed_recsize.ksh \ functional/redacted_send/redacted_mounts.ksh \ functional/redacted_send/redacted_negative.ksh \ functional/redacted_send/redacted_origin.ksh \ functional/redacted_send/redacted_panic.ksh \ functional/redacted_send/redacted_props.ksh \ functional/redacted_send/redacted_resume.ksh \ functional/redacted_send/redacted_size.ksh \ functional/redacted_send/redacted_volume.ksh \ functional/redacted_send/setup.ksh \ functional/redundancy/cleanup.ksh \ functional/redundancy/redundancy_draid1.ksh \ functional/redundancy/redundancy_draid2.ksh \ functional/redundancy/redundancy_draid3.ksh \ functional/redundancy/redundancy_draid_damaged1.ksh \ functional/redundancy/redundancy_draid_damaged2.ksh \ functional/redundancy/redundancy_draid.ksh \ functional/redundancy/redundancy_draid_spare1.ksh \ functional/redundancy/redundancy_draid_spare2.ksh \ functional/redundancy/redundancy_draid_spare3.ksh \ functional/redundancy/redundancy_mirror.ksh \ functional/redundancy/redundancy_raidz1.ksh \ functional/redundancy/redundancy_raidz2.ksh \ functional/redundancy/redundancy_raidz3.ksh \ functional/redundancy/redundancy_raidz.ksh \ functional/redundancy/redundancy_stripe.ksh \ functional/redundancy/setup.ksh \ functional/refquota/cleanup.ksh \ functional/refquota/refquota_001_pos.ksh \ functional/refquota/refquota_002_pos.ksh \ functional/refquota/refquota_003_pos.ksh \ functional/refquota/refquota_004_pos.ksh \ functional/refquota/refquota_005_pos.ksh \ functional/refquota/refquota_006_neg.ksh \ functional/refquota/refquota_007_neg.ksh \ functional/refquota/refquota_008_neg.ksh \ functional/refquota/setup.ksh \ functional/refreserv/cleanup.ksh \ functional/refreserv/refreserv_001_pos.ksh \ functional/refreserv/refreserv_002_pos.ksh \ functional/refreserv/refreserv_003_pos.ksh \ functional/refreserv/refreserv_004_pos.ksh \ functional/refreserv/refreserv_005_pos.ksh \ functional/refreserv/refreserv_multi_raidz.ksh \ functional/refreserv/refreserv_raidz.ksh \ functional/refreserv/setup.ksh \ functional/removal/cleanup.ksh \ functional/removal/removal_all_vdev.ksh \ functional/removal/removal_cancel.ksh \ functional/removal/removal_check_space.ksh \ functional/removal/removal_condense_export.ksh \ functional/removal/removal_multiple_indirection.ksh \ functional/removal/removal_nopwrite.ksh \ functional/removal/removal_remap_deadlists.ksh \ functional/removal/removal_reservation.ksh \ functional/removal/removal_resume_export.ksh \ functional/removal/removal_sanity.ksh \ functional/removal/removal_with_add.ksh \ functional/removal/removal_with_create_fs.ksh \ functional/removal/removal_with_dedup.ksh \ functional/removal/removal_with_errors.ksh \ functional/removal/removal_with_export.ksh \ functional/removal/removal_with_faulted.ksh \ functional/removal/removal_with_ganging.ksh \ functional/removal/removal_with_indirect.ksh \ functional/removal/removal_with_remove.ksh \ functional/removal/removal_with_scrub.ksh \ functional/removal/removal_with_send.ksh \ functional/removal/removal_with_send_recv.ksh \ functional/removal/removal_with_snapshot.ksh \ functional/removal/removal_with_write.ksh \ functional/removal/removal_with_zdb.ksh \ functional/removal/remove_attach_mirror.ksh \ functional/removal/remove_expanded.ksh \ functional/removal/remove_indirect.ksh \ functional/removal/remove_mirror.ksh \ functional/removal/remove_mirror_sanity.ksh \ functional/removal/remove_raidz.ksh \ functional/rename_dirs/cleanup.ksh \ functional/rename_dirs/rename_dirs_001_pos.ksh \ functional/rename_dirs/setup.ksh \ functional/renameat2/cleanup.ksh \ functional/renameat2/setup.ksh \ functional/renameat2/renameat2_exchange.ksh \ functional/renameat2/renameat2_noreplace.ksh \ functional/renameat2/renameat2_whiteout.ksh \ functional/replacement/attach_import.ksh \ functional/replacement/attach_multiple.ksh \ functional/replacement/attach_rebuild.ksh \ functional/replacement/attach_resilver.ksh \ functional/replacement/cleanup.ksh \ functional/replacement/detach.ksh \ functional/replacement/rebuild_disabled_feature.ksh \ functional/replacement/rebuild_multiple.ksh \ functional/replacement/rebuild_raidz.ksh \ functional/replacement/replace_import.ksh \ functional/replacement/replace_rebuild.ksh \ functional/replacement/replace_resilver.ksh \ functional/replacement/resilver_restart_001.ksh \ functional/replacement/resilver_restart_002.ksh \ functional/replacement/scrub_cancel.ksh \ functional/replacement/setup.ksh \ functional/reservation/cleanup.ksh \ functional/reservation/reservation_001_pos.ksh \ functional/reservation/reservation_002_pos.ksh \ functional/reservation/reservation_003_pos.ksh \ functional/reservation/reservation_004_pos.ksh \ functional/reservation/reservation_005_pos.ksh \ functional/reservation/reservation_006_pos.ksh \ functional/reservation/reservation_007_pos.ksh \ functional/reservation/reservation_008_pos.ksh \ functional/reservation/reservation_009_pos.ksh \ functional/reservation/reservation_010_pos.ksh \ functional/reservation/reservation_011_pos.ksh \ functional/reservation/reservation_012_pos.ksh \ functional/reservation/reservation_013_pos.ksh \ functional/reservation/reservation_014_pos.ksh \ functional/reservation/reservation_015_pos.ksh \ functional/reservation/reservation_016_pos.ksh \ functional/reservation/reservation_017_pos.ksh \ functional/reservation/reservation_018_pos.ksh \ functional/reservation/reservation_019_pos.ksh \ functional/reservation/reservation_020_pos.ksh \ functional/reservation/reservation_021_neg.ksh \ functional/reservation/reservation_022_pos.ksh \ functional/reservation/setup.ksh \ functional/rootpool/cleanup.ksh \ functional/rootpool/rootpool_002_neg.ksh \ functional/rootpool/rootpool_003_neg.ksh \ functional/rootpool/rootpool_007_pos.ksh \ functional/rootpool/setup.ksh \ functional/rsend/cleanup.ksh \ functional/rsend/recv_dedup_encrypted_zvol.ksh \ functional/rsend/recv_dedup.ksh \ functional/rsend/rsend_001_pos.ksh \ functional/rsend/rsend_002_pos.ksh \ functional/rsend/rsend_003_pos.ksh \ functional/rsend/rsend_004_pos.ksh \ functional/rsend/rsend_005_pos.ksh \ functional/rsend/rsend_006_pos.ksh \ functional/rsend/rsend_007_pos.ksh \ functional/rsend/rsend_008_pos.ksh \ functional/rsend/rsend_009_pos.ksh \ functional/rsend/rsend_010_pos.ksh \ functional/rsend/rsend_011_pos.ksh \ functional/rsend/rsend_012_pos.ksh \ functional/rsend/rsend_013_pos.ksh \ functional/rsend/rsend_014_pos.ksh \ functional/rsend/rsend_016_neg.ksh \ functional/rsend/rsend_019_pos.ksh \ functional/rsend/rsend_020_pos.ksh \ functional/rsend/rsend_021_pos.ksh \ functional/rsend/rsend_022_pos.ksh \ functional/rsend/rsend_024_pos.ksh \ functional/rsend/rsend_025_pos.ksh \ functional/rsend/rsend_026_neg.ksh \ functional/rsend/rsend_027_pos.ksh \ functional/rsend/rsend_028_neg.ksh \ functional/rsend/rsend_029_neg.ksh \ functional/rsend/rsend_030_pos.ksh \ functional/rsend/rsend_031_pos.ksh \ functional/rsend/send-c_embedded_blocks.ksh \ functional/rsend/send-c_incremental.ksh \ functional/rsend/send-c_lz4_disabled.ksh \ functional/rsend/send-c_mixed_compression.ksh \ functional/rsend/send-c_props.ksh \ functional/rsend/send-c_recv_dedup.ksh \ functional/rsend/send-c_recv_lz4_disabled.ksh \ functional/rsend/send-c_resume.ksh \ functional/rsend/send-c_stream_size_estimate.ksh \ functional/rsend/send-c_verify_contents.ksh \ functional/rsend/send-c_verify_ratio.ksh \ functional/rsend/send-c_volume.ksh \ functional/rsend/send-c_zstream_recompress.ksh \ functional/rsend/send-c_zstreamdump.ksh \ functional/rsend/send-cpL_varied_recsize.ksh \ functional/rsend/send_doall.ksh \ functional/rsend/send_encrypted_incremental.ksh \ functional/rsend/send_encrypted_files.ksh \ functional/rsend/send_encrypted_freeobjects.ksh \ functional/rsend/send_encrypted_hierarchy.ksh \ functional/rsend/send_encrypted_props.ksh \ functional/rsend/send_encrypted_truncated_files.ksh \ functional/rsend/send_freeobjects.ksh \ functional/rsend/send_holds.ksh \ functional/rsend/send_hole_birth.ksh \ functional/rsend/send_invalid.ksh \ functional/rsend/send-L_toggle.ksh \ functional/rsend/send_mixed_raw.ksh \ functional/rsend/send_partial_dataset.ksh \ functional/rsend/send_raw_ashift.ksh \ functional/rsend/send_raw_spill_block.ksh \ functional/rsend/send_raw_large_blocks.ksh \ functional/rsend/send_realloc_dnode_size.ksh \ functional/rsend/send_realloc_encrypted_files.ksh \ functional/rsend/send_realloc_files.ksh \ functional/rsend/send_spill_block.ksh \ functional/rsend/send-wR_encrypted_zvol.ksh \ functional/rsend/setup.ksh \ functional/scrub_mirror/cleanup.ksh \ functional/scrub_mirror/scrub_mirror_001_pos.ksh \ functional/scrub_mirror/scrub_mirror_002_pos.ksh \ functional/scrub_mirror/scrub_mirror_003_pos.ksh \ functional/scrub_mirror/scrub_mirror_004_pos.ksh \ functional/scrub_mirror/setup.ksh \ functional/slog/cleanup.ksh \ functional/slog/setup.ksh \ functional/slog/slog_001_pos.ksh \ functional/slog/slog_002_pos.ksh \ functional/slog/slog_003_pos.ksh \ functional/slog/slog_004_pos.ksh \ functional/slog/slog_005_pos.ksh \ functional/slog/slog_006_pos.ksh \ functional/slog/slog_007_pos.ksh \ functional/slog/slog_008_neg.ksh \ functional/slog/slog_009_neg.ksh \ functional/slog/slog_010_neg.ksh \ functional/slog/slog_011_neg.ksh \ functional/slog/slog_012_neg.ksh \ functional/slog/slog_013_pos.ksh \ functional/slog/slog_014_pos.ksh \ functional/slog/slog_015_neg.ksh \ functional/slog/slog_016_pos.ksh \ functional/slog/slog_replay_fs_001.ksh \ functional/slog/slog_replay_fs_002.ksh \ functional/slog/slog_replay_volume.ksh \ functional/snapshot/cleanup.ksh \ functional/snapshot/clone_001_pos.ksh \ functional/snapshot/rollback_001_pos.ksh \ functional/snapshot/rollback_002_pos.ksh \ functional/snapshot/rollback_003_pos.ksh \ functional/snapshot/setup.ksh \ functional/snapshot/snapshot_001_pos.ksh \ functional/snapshot/snapshot_002_pos.ksh \ functional/snapshot/snapshot_003_pos.ksh \ functional/snapshot/snapshot_004_pos.ksh \ functional/snapshot/snapshot_005_pos.ksh \ functional/snapshot/snapshot_006_pos.ksh \ functional/snapshot/snapshot_007_pos.ksh \ functional/snapshot/snapshot_008_pos.ksh \ functional/snapshot/snapshot_009_pos.ksh \ functional/snapshot/snapshot_010_pos.ksh \ functional/snapshot/snapshot_011_pos.ksh \ functional/snapshot/snapshot_012_pos.ksh \ functional/snapshot/snapshot_013_pos.ksh \ functional/snapshot/snapshot_014_pos.ksh \ functional/snapshot/snapshot_015_pos.ksh \ functional/snapshot/snapshot_016_pos.ksh \ functional/snapshot/snapshot_017_pos.ksh \ functional/snapshot/snapshot_018_pos.ksh \ functional/snapused/cleanup.ksh \ functional/snapused/setup.ksh \ functional/snapused/snapused_001_pos.ksh \ functional/snapused/snapused_002_pos.ksh \ functional/snapused/snapused_003_pos.ksh \ functional/snapused/snapused_004_pos.ksh \ functional/snapused/snapused_005_pos.ksh \ functional/sparse/cleanup.ksh \ functional/sparse/setup.ksh \ functional/sparse/sparse_001_pos.ksh \ functional/stat/cleanup.ksh \ functional/stat/setup.ksh \ functional/stat/stat_001_pos.ksh \ functional/suid/cleanup.ksh \ functional/suid/setup.ksh \ functional/suid/suid_write_to_none.ksh \ functional/suid/suid_write_to_sgid.ksh \ functional/suid/suid_write_to_suid.ksh \ functional/suid/suid_write_to_suid_sgid.ksh \ functional/suid/suid_write_zil_replay.ksh \ functional/trim/autotrim_config.ksh \ functional/trim/autotrim_integrity.ksh \ functional/trim/autotrim_trim_integrity.ksh \ functional/trim/cleanup.ksh \ functional/trim/setup.ksh \ functional/trim/trim_config.ksh \ functional/trim/trim_integrity.ksh \ functional/trim/trim_l2arc.ksh \ functional/truncate/cleanup.ksh \ functional/truncate/setup.ksh \ functional/truncate/truncate_001_pos.ksh \ functional/truncate/truncate_002_pos.ksh \ functional/truncate/truncate_timestamps.ksh \ functional/upgrade/cleanup.ksh \ functional/upgrade/setup.ksh \ functional/upgrade/upgrade_projectquota_001_pos.ksh \ functional/upgrade/upgrade_readonly_pool.ksh \ functional/upgrade/upgrade_userobj_001_pos.ksh \ functional/user_namespace/cleanup.ksh \ functional/user_namespace/setup.ksh \ functional/user_namespace/user_namespace_001.ksh \ functional/user_namespace/user_namespace_002.ksh \ functional/user_namespace/user_namespace_003.ksh \ functional/user_namespace/user_namespace_004.ksh \ functional/userquota/cleanup.ksh \ functional/userquota/groupspace_001_pos.ksh \ functional/userquota/groupspace_002_pos.ksh \ functional/userquota/groupspace_003_pos.ksh \ functional/userquota/setup.ksh \ functional/userquota/userquota_001_pos.ksh \ functional/userquota/userquota_002_pos.ksh \ functional/userquota/userquota_003_pos.ksh \ functional/userquota/userquota_004_pos.ksh \ functional/userquota/userquota_005_neg.ksh \ functional/userquota/userquota_006_pos.ksh \ functional/userquota/userquota_007_pos.ksh \ functional/userquota/userquota_008_pos.ksh \ functional/userquota/userquota_009_pos.ksh \ functional/userquota/userquota_010_pos.ksh \ functional/userquota/userquota_011_pos.ksh \ functional/userquota/userquota_012_neg.ksh \ functional/userquota/userquota_013_pos.ksh \ functional/userquota/userspace_001_pos.ksh \ functional/userquota/userspace_002_pos.ksh \ functional/userquota/userspace_003_pos.ksh \ functional/userquota/userspace_encrypted.ksh \ functional/userquota/userspace_send_encrypted.ksh \ functional/userquota/userspace_encrypted_13709.ksh \ functional/vdev_zaps/cleanup.ksh \ functional/vdev_zaps/setup.ksh \ functional/vdev_zaps/vdev_zaps_001_pos.ksh \ functional/vdev_zaps/vdev_zaps_002_pos.ksh \ functional/vdev_zaps/vdev_zaps_003_pos.ksh \ functional/vdev_zaps/vdev_zaps_004_pos.ksh \ functional/vdev_zaps/vdev_zaps_005_pos.ksh \ functional/vdev_zaps/vdev_zaps_006_pos.ksh \ functional/vdev_zaps/vdev_zaps_007_pos.ksh \ functional/write_dirs/cleanup.ksh \ functional/write_dirs/setup.ksh \ functional/write_dirs/write_dirs_001_pos.ksh \ functional/write_dirs/write_dirs_002_pos.ksh \ functional/xattr/cleanup.ksh \ functional/xattr/setup.ksh \ functional/xattr/xattr_001_pos.ksh \ functional/xattr/xattr_002_neg.ksh \ functional/xattr/xattr_003_neg.ksh \ functional/xattr/xattr_004_pos.ksh \ functional/xattr/xattr_005_pos.ksh \ functional/xattr/xattr_006_pos.ksh \ functional/xattr/xattr_007_neg.ksh \ functional/xattr/xattr_008_pos.ksh \ functional/xattr/xattr_009_neg.ksh \ functional/xattr/xattr_010_neg.ksh \ functional/xattr/xattr_011_pos.ksh \ functional/xattr/xattr_012_pos.ksh \ functional/xattr/xattr_013_pos.ksh \ functional/xattr/xattr_compat.ksh \ functional/zpool_influxdb/cleanup.ksh \ functional/zpool_influxdb/setup.ksh \ functional/zpool_influxdb/zpool_influxdb.ksh \ functional/zvol/zvol_cli/cleanup.ksh \ functional/zvol/zvol_cli/setup.ksh \ functional/zvol/zvol_cli/zvol_cli_001_pos.ksh \ functional/zvol/zvol_cli/zvol_cli_002_pos.ksh \ functional/zvol/zvol_cli/zvol_cli_003_neg.ksh \ functional/zvol/zvol_ENOSPC/cleanup.ksh \ functional/zvol/zvol_ENOSPC/setup.ksh \ functional/zvol/zvol_ENOSPC/zvol_ENOSPC_001_pos.ksh \ functional/zvol/zvol_misc/cleanup.ksh \ functional/zvol/zvol_misc/setup.ksh \ functional/zvol/zvol_misc/zvol_misc_001_neg.ksh \ functional/zvol/zvol_misc/zvol_misc_002_pos.ksh \ functional/zvol/zvol_misc/zvol_misc_003_neg.ksh \ functional/zvol/zvol_misc/zvol_misc_004_pos.ksh \ functional/zvol/zvol_misc/zvol_misc_005_neg.ksh \ functional/zvol/zvol_misc/zvol_misc_006_pos.ksh \ functional/zvol/zvol_misc/zvol_misc_fua.ksh \ functional/zvol/zvol_misc/zvol_misc_hierarchy.ksh \ functional/zvol/zvol_misc/zvol_misc_rename_inuse.ksh \ functional/zvol/zvol_misc/zvol_misc_snapdev.ksh \ functional/zvol/zvol_misc/zvol_misc_trim.ksh \ functional/zvol/zvol_misc/zvol_misc_volmode.ksh \ functional/zvol/zvol_misc/zvol_misc_zil.ksh \ functional/zvol/zvol_stress/cleanup.ksh \ functional/zvol/zvol_stress/setup.ksh \ functional/zvol/zvol_stress/zvol_stress.ksh \ functional/zvol/zvol_swap/cleanup.ksh \ functional/zvol/zvol_swap/setup.ksh \ functional/zvol/zvol_swap/zvol_swap_001_pos.ksh \ functional/zvol/zvol_swap/zvol_swap_002_pos.ksh \ functional/zvol/zvol_swap/zvol_swap_003_pos.ksh \ functional/zvol/zvol_swap/zvol_swap_004_pos.ksh \ functional/zvol/zvol_swap/zvol_swap_005_pos.ksh \ functional/zvol/zvol_swap/zvol_swap_006_pos.ksh \ functional/idmap_mount/cleanup.ksh \ functional/idmap_mount/setup.ksh \ functional/idmap_mount/idmap_mount_001.ksh \ functional/idmap_mount/idmap_mount_002.ksh \ functional/idmap_mount/idmap_mount_003.ksh \ functional/idmap_mount/idmap_mount_004.ksh \ functional/idmap_mount/idmap_mount_005.ksh diff --git a/sys/contrib/openzfs/tests/zfs-tests/tests/functional/cli_user/misc/misc.cfg b/sys/contrib/openzfs/tests/zfs-tests/tests/functional/cli_user/misc/misc.cfg index e98b5e8b2214..9c76a8780b4a 100644 --- a/sys/contrib/openzfs/tests/zfs-tests/tests/functional/cli_user/misc/misc.cfg +++ b/sys/contrib/openzfs/tests/zfs-tests/tests/functional/cli_user/misc/misc.cfg @@ -1,123 +1,123 @@ # # CDDL HEADER START # # The contents of this file are subject to the terms of the # Common Development and Distribution License (the "License"). # You may not use this file except in compliance with the License. # # You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE # or https://opensource.org/licenses/CDDL-1.0. # See the License for the specific language governing permissions # and limitations under the License. # # When distributing Covered Code, include this CDDL HEADER in each # file and include the License file at usr/src/OPENSOLARIS.LICENSE. # If applicable, add the following below this CDDL HEADER, with the # fields enclosed by brackets "[]" replaced with your own identifying # information: Portions Copyright [yyyy] [name of copyright owner] # # CDDL HEADER END # # # Copyright 2007 Sun Microsystems, Inc. All rights reserved. # Use is subject to license terms. # # # Copyright (c) 2013 by Delphix. All rights reserved. # if is_linux; then - # these are the set of setable ZFS properties + # these are the set of settable ZFS properties PROP_NAMES="\ acltype atime \ checksum compression devices \ exec mountpoint quota readonly \ recordsize reservation setuid \ snapdir" # these are a set of values we apply, for use when testing the # zfs get/set subcommands - ordered as per the list above so we # can iterate over both sets in an array PROP_VALS="\ posix on \ fletcher2 on on \ on legacy none on \ 128K none on \ visible" # these are an alternate set of property values PROP_ALTVALS="\ nfsv4 off \ fletcher4 lzjb off \ off /tmp/zfstest 100M off \ 512 10m off \ hidden" elif is_freebsd; then PROP_NAMES="\ acltype atime \ checksum compression devices \ exec mountpoint quota readonly \ recordsize reservation setuid \ snapdir" # these are a set of values we apply, for use when testing the # zfs get/set subcommands - ordered as per the list above so we # can iterate over both sets in an array PROP_VALS="\ posix on \ fletcher2 on on \ on legacy none on \ 128K none on \ visible" # these are an alternate set of property values PROP_ALTVALS="\ nfsv4 off \ fletcher4 lzjb off \ off /tmp/zfstest 100M off \ 512 10m off \ hidden" else - # these are the set of setable ZFS properties + # these are the set of settable ZFS properties PROP_NAMES="\ aclinherit aclmode atime \ checksum compression devices \ exec mountpoint quota readonly \ recordsize reservation setuid sharenfs \ snapdir" # these are a set of values we apply, for use when testing the # zfs get/set subcommands - ordered as per the list above so we # can iterate over both sets in an array PROP_VALS="\ passthrough discard on \ fletcher2 on on \ on legacy none on \ 128K none on on \ visible" # these are an alternate set of property values PROP_ALTVALS="\ passthrough-x groupmask off \ fletcher4 lzjb off \ off /tmp/zfstest 100M off \ 512 10m off off \ hidden" fi # additional properties to worry about: canmount copies xattr zoned version POOL_PROPS="\ failmode autoreplace" POOL_VALS="\ continue on" POOL_ALTVALS="\ panic off" export TESTSNAP=testsnap-misc export TESTCLCT=testclct-misc diff --git a/sys/contrib/openzfs/tests/zfs-tests/tests/functional/fault/auto_replace_001_pos.ksh b/sys/contrib/openzfs/tests/zfs-tests/tests/functional/fault/auto_replace_001_pos.ksh index 081e6c18430d..ae56ee9919bf 100755 --- a/sys/contrib/openzfs/tests/zfs-tests/tests/functional/fault/auto_replace_001_pos.ksh +++ b/sys/contrib/openzfs/tests/zfs-tests/tests/functional/fault/auto_replace_001_pos.ksh @@ -1,109 +1,140 @@ #!/bin/ksh -p # # CDDL HEADER START # # The contents of this file are subject to the terms of the # Common Development and Distribution License (the "License"). # You may not use this file except in compliance with the License. # # You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE # or https://opensource.org/licenses/CDDL-1.0. # See the License for the specific language governing permissions # and limitations under the License. # # When distributing Covered Code, include this CDDL HEADER in each # file and include the License file at usr/src/OPENSOLARIS.LICENSE. # If applicable, add the following below this CDDL HEADER, with the # fields enclosed by brackets "[]" replaced with your own identifying # information: Portions Copyright [yyyy] [name of copyright owner] # # CDDL HEADER END # # # Copyright (c) 2017 by Intel Corporation. All rights reserved. # . $STF_SUITE/include/libtest.shlib . $STF_SUITE/tests/functional/fault/fault.cfg # # DESCRIPTION: # Testing Fault Management Agent ZED Logic - Automated Auto-Replace Test. # # STRATEGY: # 1. Update /etc/zfs/vdev_id.conf with scsidebug alias for a persistent path. # This creates keys ID_VDEV and ID_VDEV_PATH and set phys_path="scsidebug". # 2. Create a pool and set autoreplace=on (auto-replace is opt-in) -# 3. Export a pool +# 3. Export the pool # 4. Wipe and offline the scsi_debug disk -# 5. Import pool with missing disk +# 5. Import the pool with missing disk # 6. Re-online the wiped scsi_debug disk -# 7. Verify the ZED detects the new unused disk and adds it back to the pool +# 7. Verify ZED detects the new blank disk and replaces the missing vdev +# 8. Verify that the scsi_debug disk was re-partitioned # -# Creates a raidz1 zpool using persistent disk path names +# Creates a raidz1 zpool using persistent /dev/disk/by-vdev path names # (ie not /dev/sdc) # # Auto-replace is opt in, and matches by phys_path. # verify_runnable "both" if ! is_physical_device $DISKS; then log_unsupported "Unsupported disks for this test." fi function cleanup { zpool status $TESTPOOL destroy_pool $TESTPOOL sed -i '/alias scsidebug/d' $VDEVID_CONF unload_scsi_debug } log_assert "Testing automated auto-replace FMA test" log_onexit cleanup load_scsi_debug $SDSIZE $SDHOSTS $SDTGTS $SDLUNS '512b' SD=$(get_debug_device) SD_DEVICE_ID=$(get_persistent_disk_name $SD) SD_HOST=$(get_scsi_host $SD) # Register vdev_id alias for scsi_debug device to create a persistent path echo "alias scsidebug /dev/disk/by-id/$SD_DEVICE_ID" >>$VDEVID_CONF block_device_wait SD_DEVICE=$(udevadm info -q all -n $DEV_DSKDIR/$SD | \ awk -F'=' '/ID_VDEV=/ {print $2; exit}') [ -z $SD_DEVICE ] && log_fail "vdev rule was not registered properly" log_must zpool events -c log_must zpool create -f $TESTPOOL raidz1 $SD_DEVICE $DISK1 $DISK2 $DISK3 # Auto-replace is opt-in so need to set property log_must zpool set autoreplace=on $TESTPOOL # Add some data to the pool -log_must mkfile $FSIZE /$TESTPOOL/data +log_must zfs create $TESTPOOL/fs +log_must fill_fs /$TESTPOOL/fs 4 100 4096 512 Z log_must zpool export $TESTPOOL +# Record the partition UUID for later comparison +part_uuid=$(udevadm info --query=property --property=ID_PART_TABLE_UUID \ + --value /dev/disk/by-id/$SD_DEVICE_ID) +[[ -z "$part_uuid" ]] || log_note original disk GPT uuid ${part_uuid} + +# # Wipe and offline the disk +# +# Note that it is not enough to zero the disk to expunge the partitions. +# You also need to inform the kernel (e.g., 'hdparm -z' or 'partprobe'). +# +# Using partprobe is overkill and hdparm is not as common as wipefs. So +# we use wipefs which lets the kernel know the partition was removed +# from the device (i.e., calls BLKRRPART ioctl). +# log_must dd if=/dev/zero of=/dev/disk/by-id/$SD_DEVICE_ID bs=1M count=$SDSIZE +log_must /usr/sbin/wipefs -a /dev/disk/by-id/$SD_DEVICE_ID remove_disk $SD block_device_wait # Re-import pool with drive missing log_must zpool import $TESTPOOL log_must check_state $TESTPOOL "" "DEGRADED" block_device_wait # Online an empty disk in the same physical location insert_disk $SD $SD_HOST # Wait for the new disk to be online and replaced log_must wait_vdev_state $TESTPOOL "scsidebug" "ONLINE" 60 log_must wait_replacing $TESTPOOL 60 # Validate auto-replace was successful log_must check_state $TESTPOOL "" "ONLINE" +# +# Confirm the partition UUID changed so we know the new disk was relabeled +# +# Note: some older versions of udevadm don't support "--property" option so +# we'll # skip this test when it is not supported +# +if [ ! -z "$part_uuid" ]; then + new_uuid=$(udevadm info --query=property --property=ID_PART_TABLE_UUID \ + --value /dev/disk/by-id/$SD_DEVICE_ID) + log_note new disk GPT uuid ${new_uuid} + [[ "$part_uuid" = "$new_uuid" ]] && \ + log_fail "The new disk was not relabeled as expected" +fi + log_pass "Auto-replace test successful" diff --git a/sys/contrib/openzfs/tests/zfs-tests/tests/functional/fault/auto_replace_002_pos.ksh b/sys/contrib/openzfs/tests/zfs-tests/tests/functional/fault/auto_replace_002_pos.ksh new file mode 100755 index 000000000000..2259e604317b --- /dev/null +++ b/sys/contrib/openzfs/tests/zfs-tests/tests/functional/fault/auto_replace_002_pos.ksh @@ -0,0 +1,192 @@ +#!/bin/ksh -p +# +# CDDL HEADER START +# +# The contents of this file are subject to the terms of the +# Common Development and Distribution License (the "License"). +# You may not use this file except in compliance with the License. +# +# You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE +# or https://opensource.org/licenses/CDDL-1.0. +# See the License for the specific language governing permissions +# and limitations under the License. +# +# When distributing Covered Code, include this CDDL HEADER in each +# file and include the License file at usr/src/OPENSOLARIS.LICENSE. +# If applicable, add the following below this CDDL HEADER, with the +# fields enclosed by brackets "[]" replaced with your own identifying +# information: Portions Copyright [yyyy] [name of copyright owner] +# +# CDDL HEADER END +# +# +# Copyright (c) 2017 by Intel Corporation. All rights reserved. +# Copyright (c) 2023 by Klara, Inc. All rights reserved. +# + +. $STF_SUITE/include/libtest.shlib +. $STF_SUITE/tests/functional/fault/fault.cfg + +# +# DESCRIPTION: +# Testing Fault Management Agent ZED Logic - Automated Auto-Replace Test. +# Verifys that auto-replace works with by-id paths. +# +# STRATEGY: +# 1. Update /etc/zfs/vdev_id.conf with scsidebug alias for a persistent path. +# This creates keys ID_VDEV and ID_VDEV_PATH and set phys_path="scsidebug". +# 2. Create a pool and set autoreplace=on (auto-replace is opt-in) +# 3. Export the pool +# 4. Wipe and offline the scsi_debug disk +# 5. Import the pool with missing disk +# 6. Re-online the wiped scsi_debug disk with a new serial number +# 7. Verify ZED detects the new blank disk and replaces the missing vdev +# 8. Verify that the scsi_debug disk was re-partitioned +# +# Creates a raidz1 zpool using persistent /dev/disk/by-id path names +# +# Auto-replace is opt in, and matches by phys_path. +# + +verify_runnable "both" + +if ! is_physical_device $DISKS; then + log_unsupported "Unsupported disks for this test." +fi + +function cleanup +{ + zpool status $TESTPOOL + destroy_pool $TESTPOOL + sed -i '/alias scsidebug/d' $VDEVID_CONF + unload_scsi_debug +} + +# +# Wait until a vdev transitions to its replacement vdev +# +# Return 0 when vdev reaches expected state, 1 on timeout. +# +# Note: index +2 is to skip over root and raidz-0 vdevs +# +function wait_vdev_online # pool index oldguid timeout +{ + typeset pool=$1 + typeset -i index=$2+2 + typeset guid=$3 + typeset timeout=${4:-60} + typeset -i i=0 + + while [[ $i -lt $timeout ]]; do + vdev_guids=( $(zpool get -H -o value guid $pool all-vdevs) ) + + if [ "${vdev_guids[$index]}" != "${guid}" ]; then + log_note "new vdev[$((index-2))]: ${vdev_guids[$index]}, replacing ${guid}" + return 0 + fi + + i=$((i+1)) + sleep 1 + done + + return 1 +} +log_assert "automated auto-replace with by-id paths" +log_onexit cleanup + +load_scsi_debug $SDSIZE $SDHOSTS $SDTGTS $SDLUNS '512b' +SD=$(get_debug_device) +SD_DEVICE_ID=$(get_persistent_disk_name $SD) +SD_HOST=$(get_scsi_host $SD) + +# Register vdev_id alias for scsi_debug device to create a persistent path +echo "alias scsidebug /dev/disk/by-id/$SD_DEVICE_ID" >>$VDEVID_CONF +block_device_wait + +SD_DEVICE=$(udevadm info -q all -n $DEV_DSKDIR/$SD | \ + awk -F'=' '/ID_VDEV=/ {print $2; exit}') +[ -z $SD_DEVICE ] && log_fail "vdev rule was not registered properly" + +log_must zpool events -c +log_must zpool create -f $TESTPOOL raidz1 $SD_DEVICE_ID $DISK1 $DISK2 $DISK3 + +vdev_guid=$(zpool get guid -H -o value $TESTPOOL $SD_DEVICE_ID) +log_note original vdev guid ${vdev_guid} + +# Auto-replace is opt-in so need to set property +log_must zpool set autoreplace=on $TESTPOOL + +# Add some data to the pool +log_must zfs create $TESTPOOL/fs +log_must fill_fs /$TESTPOOL/fs 4 100 4096 512 Z +log_must zpool export $TESTPOOL + +# Record the partition UUID for later comparison +part_uuid=$(udevadm info --query=property --property=ID_PART_TABLE_UUID \ + --value /dev/disk/by-id/$SD_DEVICE_ID) +[[ -z "$part_uuid" ]] || log_note original disk GPT uuid ${part_uuid} + +# +# Wipe and offline the disk +# +# Note that it is not enough to zero the disk to expunge the partitions. +# You also need to inform the kernel (e.g., 'hdparm -z' or 'partprobe'). +# +# Using partprobe is overkill and hdparm is not as common as wipefs. So +# we use wipefs which lets the kernel know the partition was removed +# from the device (i.e., calls BLKRRPART ioctl). +# +log_must dd if=/dev/zero of=/dev/disk/by-id/$SD_DEVICE_ID bs=1M count=$SDSIZE +log_must /usr/sbin/wipefs -a /dev/disk/by-id/$SD_DEVICE_ID +remove_disk $SD +block_device_wait + +# Re-import pool with drive missing +log_must zpool import $TESTPOOL +log_must check_state $TESTPOOL "" "DEGRADED" +block_device_wait + +# +# Online an empty disk in the same physical location, with a different by-id +# symlink. We use vpd_use_hostno to make sure the underlying serial number +# changes for the new disk which in turn gives us a different by-id path. +# +# The original names were something like: +# /dev/disk/by-id/scsi-SLinux_scsi_debug_16000-part1 +# /dev/disk/by-id/wwn-0x33333330000007d0-part1 +# +# This new inserted disk, will have different links like: +# /dev/disk/by-id/scsi-SLinux_scsi_debug_2000-part1 +# /dev/disk/by-id/wwn-0x0x3333333000003e80 -part1 +# +echo '0' > /sys/bus/pseudo/drivers/scsi_debug/vpd_use_hostno + +insert_disk $SD $SD_HOST + +# make sure the physical path points to the same scsi-debug device +SD_DEVICE_ID=$(get_persistent_disk_name $SD) +echo "alias scsidebug /dev/disk/by-id/$SD_DEVICE_ID" >>$VDEVID_CONF +block_device_wait + +# Wait for the new disk to be online and replaced +log_must wait_vdev_online $TESTPOOL 0 $vdev_guid 45 +log_must wait_replacing $TESTPOOL 45 + +# Validate auto-replace was successful +log_must check_state $TESTPOOL "" "ONLINE" + +# +# Confirm the partition UUID changed so we know the new disk was relabeled +# +# Note: some older versions of udevadm don't support "--property" option so +# we'll # skip this test when it is not supported +# +if [ ! -z "$part_uuid" ]; then + new_uuid=$(udevadm info --query=property --property=ID_PART_TABLE_UUID \ + --value /dev/disk/by-id/$SD_DEVICE_ID) + log_note new disk GPT uuid ${new_uuid} + [[ "$part_uuid" = "$new_uuid" ]] && \ + log_fail "The new disk was not relabeled as expected" +fi + +log_pass "automated auto-replace with by-id paths" diff --git a/sys/contrib/openzfs/tests/zfs-tests/tests/functional/procfs/pool_state.ksh b/sys/contrib/openzfs/tests/zfs-tests/tests/functional/procfs/pool_state.ksh index 7a02eb68abda..bae876379177 100755 --- a/sys/contrib/openzfs/tests/zfs-tests/tests/functional/procfs/pool_state.ksh +++ b/sys/contrib/openzfs/tests/zfs-tests/tests/functional/procfs/pool_state.ksh @@ -1,148 +1,152 @@ #!/bin/ksh -p # # CDDL HEADER START # # The contents of this file are subject to the terms of the # Common Development and Distribution License (the "License"). # You may not use this file except in compliance with the License. # # You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE # or https://opensource.org/licenses/CDDL-1.0. # See the License for the specific language governing permissions # and limitations under the License. # # When distributing Covered Code, include this CDDL HEADER in each # file and include the License file at usr/src/OPENSOLARIS.LICENSE. # If applicable, add the following below this CDDL HEADER, with the # fields enclosed by brackets "[]" replaced with your own identifying # information: Portions Copyright [yyyy] [name of copyright owner] # # CDDL HEADER END # # Copyright (c) 2018 by Lawrence Livermore National Security, LLC. # # # DESCRIPTION: # Test /proc/spl/kstat/zfs//state kstat # # STRATEGY: # 1. Create a mirrored pool # 2. Check that pool is ONLINE # 3. Fault one disk # 4. Check that pool is DEGRADED # 5. Create a new pool with a single scsi_debug disk # 6. Remove the disk # 7. Check that pool is SUSPENDED # 8. Add the disk back in # 9. Clear errors and destroy the pools . $STF_SUITE/include/libtest.shlib verify_runnable "both" function cleanup { # Destroy the scsi_debug pool if [ -n "$TESTPOOL2" ] ; then if [ -n "$host" ] ; then # Re-enable the disk scan_scsi_hosts $host # Device may have changed names after being inserted SDISK=$(get_debug_device) log_must ln $DEV_RDSKDIR/$SDISK $REALDISK fi # Restore our working pool image if [ -n "$BACKUP" ] ; then gunzip -c $BACKUP > $REALDISK log_must rm -f $BACKUP fi if poolexists $TESTPOOL2 ; then # Our disk is back. Now we can clear errors and destroy the # pool cleanly. log_must zpool clear $TESTPOOL2 # Now that the disk is back and errors cleared, wait for our # hung 'zpool scrub' to finish. wait destroy_pool $TESTPOOL2 fi log_must rm -f $REALDISK unload_scsi_debug fi } # Check that our pool state values match what's expected # # $1: pool name # $2: expected state ("ONLINE", "DEGRADED", "SUSPENDED", etc) function check_all { pool=$1 expected=$2 state1=$(zpool status $pool | awk '/state: /{print $2}'); state2=$(zpool list -H -o health $pool) state3=$(/state kstat" # Test that the initial pool is healthy check_all $TESTPOOL "ONLINE" # Fault one of the disks, and check that pool is degraded read -r DISK1 _ <<<"$DISKS" log_must zpool offline -tf $TESTPOOL $DISK1 check_all $TESTPOOL "DEGRADED" log_must zpool online $TESTPOOL $DISK1 log_must zpool clear $TESTPOOL # Create a new pool out of a scsi_debug disk TESTPOOL2=testpool2 MINVDEVSIZE_MB=$((MINVDEVSIZE / 1048576)) load_scsi_debug $MINVDEVSIZE_MB 1 1 1 '512b' SDISK=$(get_debug_device) host=$(get_scsi_host $SDISK) # Use $REALDISK instead of $SDISK in our pool because $SDISK can change names # as we remove/add the disk (i.e. /dev/sdf -> /dev/sdg). REALDISK=/dev/kstat-state-realdisk log_must [ ! -e $REALDISK ] ln $DEV_RDSKDIR/$SDISK $REALDISK log_must zpool create $TESTPOOL2 $REALDISK # Backup the contents of the disk image BACKUP=$TEST_BASE_DIR/kstat-state-realdisk.gz log_must [ ! -e $BACKUP ] gzip -c $REALDISK > $BACKUP # Yank out the disk from under the pool log_must rm $REALDISK remove_disk $SDISK # Run a 'zpool scrub' in the background to suspend the pool. We run it in the # background since the command will hang when the pool gets suspended. The # command will resume and exit after we restore the missing disk later on. zpool scrub $TESTPOOL2 & -sleep 3 # Give the scrub some time to run before we check if it fails +# Once we trigger the zpool scrub, all zpool/zfs command gets stuck for 180 seconds. +# Post 180 seconds zpool/zfs commands gets start executing however few more seconds(10s) +# it take to update the status. +# hence sleeping for 200 seconds so that we get the correct status. +sleep 200 # Give the scrub some time to run before we check if it fails log_must check_all $TESTPOOL2 "SUSPENDED" log_pass "/proc/spl/kstat/zfs//state test successful" diff --git a/sys/modules/zfs/zfs_config.h b/sys/modules/zfs/zfs_config.h index a41af071ec5d..e91cf5f22368 100644 --- a/sys/modules/zfs/zfs_config.h +++ b/sys/modules/zfs/zfs_config.h @@ -1,1149 +1,1149 @@ /* */ /* zfs_config.h. Generated from zfs_config.h.in by configure. */ /* zfs_config.h.in. Generated from configure.ac by autoheader. */ /* Define to 1 if translation of program messages to the user's native language is requested. */ /* #undef ENABLE_NLS */ /* bio_end_io_t wants 1 arg */ /* #undef HAVE_1ARG_BIO_END_IO_T */ /* lookup_bdev() wants 1 arg */ /* #undef HAVE_1ARG_LOOKUP_BDEV */ /* submit_bio() wants 1 arg */ /* #undef HAVE_1ARG_SUBMIT_BIO */ /* bdi_setup_and_register() wants 2 args */ /* #undef HAVE_2ARGS_BDI_SETUP_AND_REGISTER */ /* vfs_getattr wants 2 args */ /* #undef HAVE_2ARGS_VFS_GETATTR */ /* zlib_deflate_workspacesize() wants 2 args */ /* #undef HAVE_2ARGS_ZLIB_DEFLATE_WORKSPACESIZE */ /* bdi_setup_and_register() wants 3 args */ /* #undef HAVE_3ARGS_BDI_SETUP_AND_REGISTER */ /* vfs_getattr wants 3 args */ /* #undef HAVE_3ARGS_VFS_GETATTR */ /* vfs_getattr wants 4 args */ /* #undef HAVE_4ARGS_VFS_GETATTR */ /* kernel has access_ok with 'type' parameter */ /* #undef HAVE_ACCESS_OK_TYPE */ /* posix_acl has refcount_t */ /* #undef HAVE_ACL_REFCOUNT */ /* add_disk() returns int */ /* #undef HAVE_ADD_DISK_RET */ /* Define if host toolchain supports AES */ #define HAVE_AES 1 /* Define if you have [rt] */ #define HAVE_AIO_H 1 #ifdef __amd64__ #ifndef RESCUE /* Define if host toolchain supports AVX */ #define HAVE_AVX 1 #endif /* Define if host toolchain supports AVX2 */ #define HAVE_AVX2 1 /* Define if host toolchain supports AVX512BW */ #define HAVE_AVX512BW 1 /* Define if host toolchain supports AVX512CD */ #define HAVE_AVX512CD 1 /* Define if host toolchain supports AVX512DQ */ #define HAVE_AVX512DQ 1 /* Define if host toolchain supports AVX512ER */ #define HAVE_AVX512ER 1 /* Define if host toolchain supports AVX512F */ #define HAVE_AVX512F 1 /* Define if host toolchain supports AVX512IFMA */ #define HAVE_AVX512IFMA 1 /* Define if host toolchain supports AVX512PF */ #define HAVE_AVX512PF 1 /* Define if host toolchain supports AVX512VBMI */ #define HAVE_AVX512VBMI 1 /* Define if host toolchain supports AVX512VL */ #define HAVE_AVX512VL 1 #endif /* bdevname() is available */ /* #undef HAVE_BDEVNAME */ /* bdev_check_media_change() exists */ /* #undef HAVE_BDEV_CHECK_MEDIA_CHANGE */ /* bdev_*_io_acct() available */ /* #undef HAVE_BDEV_IO_ACCT_63 */ /* bdev_*_io_acct() available */ /* #undef HAVE_BDEV_IO_ACCT_OLD */ /* bdev_kobj() exists */ /* #undef HAVE_BDEV_KOBJ */ /* bdev_max_discard_sectors() is available */ /* #undef HAVE_BDEV_MAX_DISCARD_SECTORS */ /* bdev_max_secure_erase_sectors() is available */ /* #undef HAVE_BDEV_MAX_SECURE_ERASE_SECTORS */ /* block_device_operations->submit_bio() returns void */ /* #undef HAVE_BDEV_SUBMIT_BIO_RETURNS_VOID */ /* bdev_whole() is available */ /* #undef HAVE_BDEV_WHOLE */ /* bio_alloc() takes 4 arguments */ /* #undef HAVE_BIO_ALLOC_4ARG */ /* bio->bi_bdev->bd_disk exists */ /* #undef HAVE_BIO_BDEV_DISK */ /* bio->bi_opf is defined */ /* #undef HAVE_BIO_BI_OPF */ /* bio->bi_status exists */ /* #undef HAVE_BIO_BI_STATUS */ /* bio has bi_iter */ /* #undef HAVE_BIO_BVEC_ITER */ /* bio_*_io_acct() available */ /* #undef HAVE_BIO_IO_ACCT */ /* bio_max_segs() is implemented */ /* #undef HAVE_BIO_MAX_SEGS */ /* bio_set_dev() is available */ /* #undef HAVE_BIO_SET_DEV */ /* bio_set_dev() GPL-only */ /* #undef HAVE_BIO_SET_DEV_GPL_ONLY */ /* bio_set_dev() is a macro */ /* #undef HAVE_BIO_SET_DEV_MACRO */ /* bio_set_op_attrs is available */ /* #undef HAVE_BIO_SET_OP_ATTRS */ /* blkdev_get_by_path() exists and takes 4 args */ /* #undef HAVE_BLKDEV_GET_BY_PATH_4ARG */ /* blkdev_get_by_path() handles ERESTARTSYS */ /* #undef HAVE_BLKDEV_GET_ERESTARTSYS */ /* blkdev_issue_discard() is available */ /* #undef HAVE_BLKDEV_ISSUE_DISCARD */ /* blkdev_issue_secure_erase() is available */ /* #undef HAVE_BLKDEV_ISSUE_SECURE_ERASE */ /* blkdev_put() accepts void* as arg 2 */ /* #undef HAVE_BLKDEV_PUT_HOLDER */ /* blkdev_reread_part() exists */ /* #undef HAVE_BLKDEV_REREAD_PART */ /* blkg_tryget() is available */ /* #undef HAVE_BLKG_TRYGET */ /* blkg_tryget() GPL-only */ /* #undef HAVE_BLKG_TRYGET_GPL_ONLY */ /* blk_alloc_disk() exists */ /* #undef HAVE_BLK_ALLOC_DISK */ /* blk_alloc_queue() expects request function */ /* #undef HAVE_BLK_ALLOC_QUEUE_REQUEST_FN */ /* blk_alloc_queue_rh() expects request function */ /* #undef HAVE_BLK_ALLOC_QUEUE_REQUEST_FN_RH */ /* blk_cleanup_disk() exists */ /* #undef HAVE_BLK_CLEANUP_DISK */ /* blk_mode_t is defined */ /* #undef HAVE_BLK_MODE_T */ /* block multiqueue is available */ /* #undef HAVE_BLK_MQ */ /* blk queue backing_dev_info is dynamic */ /* #undef HAVE_BLK_QUEUE_BDI_DYNAMIC */ /* blk_queue_discard() is available */ /* #undef HAVE_BLK_QUEUE_DISCARD */ /* blk_queue_flag_clear() exists */ /* #undef HAVE_BLK_QUEUE_FLAG_CLEAR */ /* blk_queue_flag_set() exists */ /* #undef HAVE_BLK_QUEUE_FLAG_SET */ /* blk_queue_flush() is available */ /* #undef HAVE_BLK_QUEUE_FLUSH */ /* blk_queue_flush() is GPL-only */ /* #undef HAVE_BLK_QUEUE_FLUSH_GPL_ONLY */ /* blk_queue_secdiscard() is available */ /* #undef HAVE_BLK_QUEUE_SECDISCARD */ /* blk_queue_secure_erase() is available */ /* #undef HAVE_BLK_QUEUE_SECURE_ERASE */ /* blk_queue_update_readahead() exists */ /* #undef HAVE_BLK_QUEUE_UPDATE_READAHEAD */ /* blk_queue_write_cache() exists */ /* #undef HAVE_BLK_QUEUE_WRITE_CACHE */ /* blk_queue_write_cache() is GPL-only */ /* #undef HAVE_BLK_QUEUE_WRITE_CACHE_GPL_ONLY */ /* BLK_STS_RESV_CONFLICT is defined */ /* #undef HAVE_BLK_STS_RESV_CONFLICT */ /* Define if release() in block_device_operations takes 1 arg */ /* #undef HAVE_BLOCK_DEVICE_OPERATIONS_RELEASE_1ARG */ /* Define if revalidate_disk() in block_device_operations */ /* #undef HAVE_BLOCK_DEVICE_OPERATIONS_REVALIDATE_DISK */ /* Define to 1 if you have the Mac OS X function CFLocaleCopyCurrent in the CoreFoundation framework. */ /* #undef HAVE_CFLOCALECOPYCURRENT */ /* Define to 1 if you have the Mac OS X function CFLocaleCopyPreferredLanguages in the CoreFoundation framework. */ /* #undef HAVE_CFLOCALECOPYPREFERREDLANGUAGES */ /* Define to 1 if you have the Mac OS X function CFPreferencesCopyAppValue in the CoreFoundation framework. */ /* #undef HAVE_CFPREFERENCESCOPYAPPVALUE */ /* check_disk_change() exists */ /* #undef HAVE_CHECK_DISK_CHANGE */ /* clear_inode() is available */ /* #undef HAVE_CLEAR_INODE */ /* dentry uses const struct dentry_operations */ /* #undef HAVE_CONST_DENTRY_OPERATIONS */ /* copy_from_iter() is available */ /* #undef HAVE_COPY_FROM_ITER */ /* copy_splice_read exists */ /* #undef HAVE_COPY_SPLICE_READ */ /* copy_to_iter() is available */ /* #undef HAVE_COPY_TO_ITER */ /* cpu_has_feature() is GPL-only */ /* #undef HAVE_CPU_HAS_FEATURE_GPL_ONLY */ /* yes */ /* #undef HAVE_CPU_HOTPLUG */ /* current_time() exists */ /* #undef HAVE_CURRENT_TIME */ /* Define if the GNU dcgettext() function is already present or preinstalled. */ /* #undef HAVE_DCGETTEXT */ /* DECLARE_EVENT_CLASS() is available */ /* #undef HAVE_DECLARE_EVENT_CLASS */ /* dentry aliases are in d_u member */ /* #undef HAVE_DENTRY_D_U_ALIASES */ /* dequeue_signal() takes 4 arguments */ /* #undef HAVE_DEQUEUE_SIGNAL_4ARG */ /* lookup_bdev() wants dev_t arg */ /* #undef HAVE_DEVT_LOOKUP_BDEV */ /* sops->dirty_inode() wants flags */ /* #undef HAVE_DIRTY_INODE_WITH_FLAGS */ /* disk_check_media_change() exists */ /* #undef HAVE_DISK_CHECK_MEDIA_CHANGE */ /* disk_*_io_acct() available */ /* #undef HAVE_DISK_IO_ACCT */ /* disk_update_readahead() exists */ /* #undef HAVE_DISK_UPDATE_READAHEAD */ /* Define to 1 if you have the header file. */ #define HAVE_DLFCN_H 1 /* d_make_root() is available */ /* #undef HAVE_D_MAKE_ROOT */ /* d_prune_aliases() is available */ /* #undef HAVE_D_PRUNE_ALIASES */ /* dops->d_revalidate() operation takes nameidata */ /* #undef HAVE_D_REVALIDATE_NAMEIDATA */ /* eops->encode_fh() wants child and parent inodes */ /* #undef HAVE_ENCODE_FH_WITH_INODE */ /* sops->evict_inode() exists */ /* #undef HAVE_EVICT_INODE */ /* FALLOC_FL_ZERO_RANGE is defined */ /* #undef HAVE_FALLOC_FL_ZERO_RANGE */ /* fault_in_iov_iter_readable() is available */ /* #undef HAVE_FAULT_IN_IOV_ITER_READABLE */ /* filemap_range_has_page() is available */ /* #undef HAVE_FILEMAP_RANGE_HAS_PAGE */ /* fops->aio_fsync() exists */ /* #undef HAVE_FILE_AIO_FSYNC */ /* file_dentry() is available */ /* #undef HAVE_FILE_DENTRY */ /* fops->fadvise() exists */ /* #undef HAVE_FILE_FADVISE */ /* file_inode() is available */ /* #undef HAVE_FILE_INODE */ /* flush_dcache_page() is GPL-only */ /* #undef HAVE_FLUSH_DCACHE_PAGE_GPL_ONLY */ /* iops->follow_link() cookie */ /* #undef HAVE_FOLLOW_LINK_COOKIE */ /* iops->follow_link() nameidata */ /* #undef HAVE_FOLLOW_LINK_NAMEIDATA */ /* Define if compiler supports -Wformat-overflow */ /* #undef HAVE_FORMAT_OVERFLOW */ /* fsync_bdev() is declared in include/blkdev.h */ /* #undef HAVE_FSYNC_BDEV */ /* fops->fsync() with range */ /* #undef HAVE_FSYNC_RANGE */ /* fops->fsync() without dentry */ /* #undef HAVE_FSYNC_WITHOUT_DENTRY */ /* yes */ /* #undef HAVE_GENERIC_FADVISE */ /* generic_fillattr requires struct mnt_idmap* */ /* #undef HAVE_GENERIC_FILLATTR_IDMAP */ /* generic_fillattr requires struct mnt_idmap* and u32 request_mask */ /* #undef HAVE_GENERIC_FILLATTR_IDMAP_REQMASK */ /* generic_fillattr requires struct user_namespace* */ /* #undef HAVE_GENERIC_FILLATTR_USERNS */ /* generic_*_io_acct() 3 arg available */ /* #undef HAVE_GENERIC_IO_ACCT_3ARG */ /* generic_*_io_acct() 4 arg available */ /* #undef HAVE_GENERIC_IO_ACCT_4ARG */ /* generic_readlink is global */ /* #undef HAVE_GENERIC_READLINK */ /* generic_setxattr() exists */ /* #undef HAVE_GENERIC_SETXATTR */ /* generic_write_checks() takes kiocb */ /* #undef HAVE_GENERIC_WRITE_CHECKS_KIOCB */ /* Define if the GNU gettext() function is already present or preinstalled. */ /* #undef HAVE_GETTEXT */ /* iops->get_acl() exists */ /* #undef HAVE_GET_ACL */ /* iops->get_acl() takes rcu */ /* #undef HAVE_GET_ACL_RCU */ /* has iops->get_inode_acl() */ /* #undef HAVE_GET_INODE_ACL */ /* iops->get_link() cookie */ /* #undef HAVE_GET_LINK_COOKIE */ /* iops->get_link() delayed */ /* #undef HAVE_GET_LINK_DELAYED */ /* group_info->gid exists */ /* #undef HAVE_GROUP_INFO_GID */ /* has_capability() is available */ /* #undef HAVE_HAS_CAPABILITY */ /* iattr->ia_vfsuid and iattr->ia_vfsgid exist */ /* #undef HAVE_IATTR_VFSID */ /* Define if you have the iconv() function and it works. */ #define HAVE_ICONV 1 /* iops->getattr() takes struct mnt_idmap* */ /* #undef HAVE_IDMAP_IOPS_GETATTR */ /* iops->setattr() takes struct mnt_idmap* */ /* #undef HAVE_IDMAP_IOPS_SETATTR */ /* APIs for idmapped mount are present */ /* #undef HAVE_IDMAP_MNT_API */ /* Define if compiler supports -Wimplicit-fallthrough */ /* #undef HAVE_IMPLICIT_FALLTHROUGH */ /* Define if compiler supports -Winfinite-recursion */ /* #undef HAVE_INFINITE_RECURSION */ /* inode_get_ctime() exists in linux/fs.h */ /* #undef HAVE_INODE_GET_CTIME */ /* yes */ /* #undef HAVE_INODE_LOCK_SHARED */ /* inode_owner_or_capable() exists */ /* #undef HAVE_INODE_OWNER_OR_CAPABLE */ /* inode_owner_or_capable() takes mnt_idmap */ /* #undef HAVE_INODE_OWNER_OR_CAPABLE_IDMAP */ /* inode_owner_or_capable() takes user_ns */ /* #undef HAVE_INODE_OWNER_OR_CAPABLE_USERNS */ /* inode_set_ctime_to_ts() exists in linux/fs.h */ /* #undef HAVE_INODE_SET_CTIME_TO_TS */ /* inode_set_flags() exists */ /* #undef HAVE_INODE_SET_FLAGS */ /* inode_set_iversion() exists */ /* #undef HAVE_INODE_SET_IVERSION */ /* inode->i_*time's are timespec64 */ /* #undef HAVE_INODE_TIMESPEC64_TIMES */ /* timestamp_truncate() exists */ /* #undef HAVE_INODE_TIMESTAMP_TRUNCATE */ /* Define to 1 if you have the header file. */ #define HAVE_INTTYPES_H 1 /* in_compat_syscall() is available */ /* #undef HAVE_IN_COMPAT_SYSCALL */ /* iops->create() takes struct mnt_idmap* */ /* #undef HAVE_IOPS_CREATE_IDMAP */ /* iops->create() takes struct user_namespace* */ /* #undef HAVE_IOPS_CREATE_USERNS */ /* iops->mkdir() takes struct mnt_idmap* */ /* #undef HAVE_IOPS_MKDIR_IDMAP */ /* iops->mkdir() takes struct user_namespace* */ /* #undef HAVE_IOPS_MKDIR_USERNS */ /* iops->mknod() takes struct mnt_idmap* */ /* #undef HAVE_IOPS_MKNOD_IDMAP */ /* iops->mknod() takes struct user_namespace* */ /* #undef HAVE_IOPS_MKNOD_USERNS */ /* iops->permission() takes struct mnt_idmap* */ /* #undef HAVE_IOPS_PERMISSION_IDMAP */ /* iops->permission() takes struct user_namespace* */ /* #undef HAVE_IOPS_PERMISSION_USERNS */ /* iops->rename() takes struct mnt_idmap* */ /* #undef HAVE_IOPS_RENAME_IDMAP */ /* iops->rename() takes struct user_namespace* */ /* #undef HAVE_IOPS_RENAME_USERNS */ /* iops->setattr() exists */ /* #undef HAVE_IOPS_SETATTR */ /* iops->symlink() takes struct mnt_idmap* */ /* #undef HAVE_IOPS_SYMLINK_IDMAP */ /* iops->symlink() takes struct user_namespace* */ /* #undef HAVE_IOPS_SYMLINK_USERNS */ /* iov_iter_advance() is available */ /* #undef HAVE_IOV_ITER_ADVANCE */ /* iov_iter_count() is available */ /* #undef HAVE_IOV_ITER_COUNT */ /* iov_iter_fault_in_readable() is available */ /* #undef HAVE_IOV_ITER_FAULT_IN_READABLE */ /* iov_iter_revert() is available */ /* #undef HAVE_IOV_ITER_REVERT */ /* iov_iter_type() is available */ /* #undef HAVE_IOV_ITER_TYPE */ /* iov_iter types are available */ /* #undef HAVE_IOV_ITER_TYPES */ /* yes */ /* #undef HAVE_IO_SCHEDULE_TIMEOUT */ /* Define to 1 if you have the `issetugid' function. */ #define HAVE_ISSETUGID 1 /* iter_iov() is available */ /* #undef HAVE_ITER_IOV */ /* kernel has kernel_fpu_* functions */ /* #undef HAVE_KERNEL_FPU */ /* kernel has asm/fpu/api.h */ /* #undef HAVE_KERNEL_FPU_API_HEADER */ /* kernel fpu internal */ /* #undef HAVE_KERNEL_FPU_INTERNAL */ /* kernel has asm/fpu/internal.h */ /* #undef HAVE_KERNEL_FPU_INTERNAL_HEADER */ /* uncached_acl_sentinel() exists */ /* #undef HAVE_KERNEL_GET_ACL_HANDLE_CACHE */ /* Define if compiler supports -Winfinite-recursion */ /* #undef HAVE_KERNEL_INFINITE_RECURSION */ /* kernel does stack verification */ /* #undef HAVE_KERNEL_OBJTOOL */ /* kernel has linux/objtool.h */ /* #undef HAVE_KERNEL_OBJTOOL_HEADER */ /* kernel_read() take loff_t pointer */ /* #undef HAVE_KERNEL_READ_PPOS */ /* timer_list.function gets a timer_list */ /* #undef HAVE_KERNEL_TIMER_FUNCTION_TIMER_LIST */ /* struct timer_list has a flags member */ /* #undef HAVE_KERNEL_TIMER_LIST_FLAGS */ /* timer_setup() is available */ /* #undef HAVE_KERNEL_TIMER_SETUP */ /* kernel_write() take loff_t pointer */ /* #undef HAVE_KERNEL_WRITE_PPOS */ /* kmem_cache_create_usercopy() exists */ /* #undef HAVE_KMEM_CACHE_CREATE_USERCOPY */ /* kstrtoul() exists */ /* #undef HAVE_KSTRTOUL */ /* ktime_get_coarse_real_ts64() exists */ /* #undef HAVE_KTIME_GET_COARSE_REAL_TS64 */ /* ktime_get_raw_ts64() exists */ /* #undef HAVE_KTIME_GET_RAW_TS64 */ /* kvmalloc exists */ /* #undef HAVE_KVMALLOC */ /* Define if you have [aio] */ /* #undef HAVE_LIBAIO */ /* Define if you have [blkid] */ /* #undef HAVE_LIBBLKID */ /* Define if you have [crypto] */ #define HAVE_LIBCRYPTO 1 /* Define if you have [tirpc] */ /* #undef HAVE_LIBTIRPC */ /* Define if you have [udev] */ /* #undef HAVE_LIBUDEV */ /* Define if you have [uuid] */ /* #undef HAVE_LIBUUID */ /* linux/blk-cgroup.h exists */ /* #undef HAVE_LINUX_BLK_CGROUP_HEADER */ /* lseek_execute() is available */ /* #undef HAVE_LSEEK_EXECUTE */ /* makedev() is declared in sys/mkdev.h */ /* #undef HAVE_MAKEDEV_IN_MKDEV */ /* makedev() is declared in sys/sysmacros.h */ /* #undef HAVE_MAKEDEV_IN_SYSMACROS */ /* Noting that make_request_fn() returns blk_qc_t */ /* #undef HAVE_MAKE_REQUEST_FN_RET_QC */ /* Noting that make_request_fn() returns void */ /* #undef HAVE_MAKE_REQUEST_FN_RET_VOID */ /* iops->mkdir() takes umode_t */ /* #undef HAVE_MKDIR_UMODE_T */ /* Define to 1 if you have the `mlockall' function. */ #define HAVE_MLOCKALL 1 /* lookup_bdev() wants mode arg */ /* #undef HAVE_MODE_LOOKUP_BDEV */ /* Define if host toolchain supports MOVBE */ #define HAVE_MOVBE 1 /* new_sync_read()/new_sync_write() are available */ /* #undef HAVE_NEW_SYNC_READ */ /* folio_wait_bit() exists */ /* #undef HAVE_PAGEMAP_FOLIO_WAIT_BIT */ /* part_to_dev() exists */ /* #undef HAVE_PART_TO_DEV */ /* iops->getattr() takes a path */ /* #undef HAVE_PATH_IOPS_GETATTR */ /* Define if host toolchain supports PCLMULQDQ */ #define HAVE_PCLMULQDQ 1 /* percpu_counter_add_batch() is defined */ /* #undef HAVE_PERCPU_COUNTER_ADD_BATCH */ /* percpu_counter_init() wants gfp_t */ /* #undef HAVE_PERCPU_COUNTER_INIT_WITH_GFP */ /* posix_acl_chmod() exists */ /* #undef HAVE_POSIX_ACL_CHMOD */ /* posix_acl_from_xattr() needs user_ns */ /* #undef HAVE_POSIX_ACL_FROM_XATTR_USERNS */ /* posix_acl_release() is available */ /* #undef HAVE_POSIX_ACL_RELEASE */ /* posix_acl_release() is GPL-only */ /* #undef HAVE_POSIX_ACL_RELEASE_GPL_ONLY */ /* posix_acl_valid() wants user namespace */ /* #undef HAVE_POSIX_ACL_VALID_WITH_NS */ /* proc_ops structure exists */ /* #undef HAVE_PROC_OPS_STRUCT */ /* iops->put_link() cookie */ /* #undef HAVE_PUT_LINK_COOKIE */ /* iops->put_link() delayed */ /* #undef HAVE_PUT_LINK_DELAYED */ /* iops->put_link() nameidata */ /* #undef HAVE_PUT_LINK_NAMEIDATA */ /* If available, contains the Python version number currently in use. */ #define HAVE_PYTHON "3.7" /* qat is enabled and existed */ /* #undef HAVE_QAT */ /* struct reclaim_state has reclaimed */ /* #undef HAVE_RECLAIM_STATE_RECLAIMED */ /* register_shrinker is vararg */ /* #undef HAVE_REGISTER_SHRINKER_VARARG */ /* register_sysctl_table exists */ /* #undef HAVE_REGISTER_SYSCTL_TABLE */ /* iops->rename2() exists */ /* #undef HAVE_RENAME2 */ /* struct inode_operations_wrapper takes .rename2() */ /* #undef HAVE_RENAME2_OPERATIONS_WRAPPER */ /* iops->rename() wants flags */ /* #undef HAVE_RENAME_WANTS_FLAGS */ /* REQ_DISCARD is defined */ /* #undef HAVE_REQ_DISCARD */ /* REQ_FLUSH is defined */ /* #undef HAVE_REQ_FLUSH */ /* REQ_OP_DISCARD is defined */ /* #undef HAVE_REQ_OP_DISCARD */ /* REQ_OP_FLUSH is defined */ /* #undef HAVE_REQ_OP_FLUSH */ /* REQ_OP_SECURE_ERASE is defined */ /* #undef HAVE_REQ_OP_SECURE_ERASE */ /* REQ_PREFLUSH is defined */ /* #undef HAVE_REQ_PREFLUSH */ /* revalidate_disk() is available */ /* #undef HAVE_REVALIDATE_DISK */ /* revalidate_disk_size() is available */ /* #undef HAVE_REVALIDATE_DISK_SIZE */ /* struct rw_semaphore has member activity */ /* #undef HAVE_RWSEM_ACTIVITY */ /* struct rw_semaphore has atomic_long_t member count */ /* #undef HAVE_RWSEM_ATOMIC_LONG_COUNT */ /* linux/sched/signal.h exists */ /* #undef HAVE_SCHED_SIGNAL_HEADER */ /* Define to 1 if you have the header file. */ #define HAVE_SECURITY_PAM_MODULES_H 1 /* setattr_prepare() accepts mnt_idmap */ /* #undef HAVE_SETATTR_PREPARE_IDMAP */ /* setattr_prepare() is available, doesn't accept user_namespace */ /* #undef HAVE_SETATTR_PREPARE_NO_USERNS */ /* setattr_prepare() accepts user_namespace */ /* #undef HAVE_SETATTR_PREPARE_USERNS */ /* iops->set_acl() exists, takes 3 args */ /* #undef HAVE_SET_ACL */ /* iops->set_acl() takes 4 args, arg1 is struct mnt_idmap * */ /* #undef HAVE_SET_ACL_IDMAP_DENTRY */ /* iops->set_acl() takes 4 args */ /* #undef HAVE_SET_ACL_USERNS */ /* iops->set_acl() takes 4 args, arg2 is struct dentry * */ /* #undef HAVE_SET_ACL_USERNS_DENTRY_ARG2 */ /* set_cached_acl() is usable */ /* #undef HAVE_SET_CACHED_ACL_USABLE */ /* set_special_state() exists */ /* #undef HAVE_SET_SPECIAL_STATE */ /* struct shrink_control exists */ /* #undef HAVE_SHRINK_CONTROL_STRUCT */ /* kernel_siginfo_t exists */ /* #undef HAVE_SIGINFO */ /* signal_stop() exists */ /* #undef HAVE_SIGNAL_STOP */ /* new shrinker callback wants 2 args */ /* #undef HAVE_SINGLE_SHRINKER_CALLBACK */ /* cs->count_objects exists */ /* #undef HAVE_SPLIT_SHRINKER_CALLBACK */ #if defined(__amd64__) || defined(__i386__) /* Define if host toolchain supports SSE */ #define HAVE_SSE 1 /* Define if host toolchain supports SSE2 */ #define HAVE_SSE2 1 /* Define if host toolchain supports SSE3 */ #define HAVE_SSE3 1 /* Define if host toolchain supports SSE4.1 */ #define HAVE_SSE4_1 1 /* Define if host toolchain supports SSE4.2 */ #define HAVE_SSE4_2 1 /* Define if host toolchain supports SSSE3 */ #define HAVE_SSSE3 1 #endif /* STACK_FRAME_NON_STANDARD is defined */ /* #undef HAVE_STACK_FRAME_NON_STANDARD */ /* standalone exists */ /* #undef HAVE_STANDALONE_LINUX_STDARG */ /* Define to 1 if you have the header file. */ #define HAVE_STDINT_H 1 /* Define to 1 if you have the header file. */ #define HAVE_STDIO_H 1 /* Define to 1 if you have the header file. */ #define HAVE_STDLIB_H 1 /* Define to 1 if you have the header file. */ #define HAVE_STRINGS_H 1 /* Define to 1 if you have the header file. */ #define HAVE_STRING_H 1 /* Define to 1 if you have the `strlcat' function. */ #define HAVE_STRLCAT 1 /* Define to 1 if you have the `strlcpy' function. */ #define HAVE_STRLCPY 1 /* submit_bio is member of struct block_device_operations */ /* #undef HAVE_SUBMIT_BIO_IN_BLOCK_DEVICE_OPERATIONS */ /* super_setup_bdi_name() exits */ /* #undef HAVE_SUPER_SETUP_BDI_NAME */ /* super_block->s_user_ns exists */ /* #undef HAVE_SUPER_USER_NS */ /* sync_blockdev() is declared in include/blkdev.h */ /* #undef HAVE_SYNC_BLOCKDEV */ /* struct kobj_type has default_groups */ /* #undef HAVE_SYSFS_DEFAULT_GROUPS */ /* Define to 1 if you have the header file. */ #define HAVE_SYS_STAT_H 1 /* Define to 1 if you have the header file. */ #define HAVE_SYS_TYPES_H 1 /* i_op->tmpfile() exists */ /* #undef HAVE_TMPFILE */ /* i_op->tmpfile() uses old dentry signature */ /* #undef HAVE_TMPFILE_DENTRY */ /* i_op->tmpfile() has mnt_idmap */ /* #undef HAVE_TMPFILE_IDMAP */ /* i_op->tmpfile() has userns */ /* #undef HAVE_TMPFILE_USERNS */ /* totalhigh_pages() exists */ /* #undef HAVE_TOTALHIGH_PAGES */ /* kernel has totalram_pages() */ /* #undef HAVE_TOTALRAM_PAGES_FUNC */ /* Define to 1 if you have the `udev_device_get_is_initialized' function. */ /* #undef HAVE_UDEV_DEVICE_GET_IS_INITIALIZED */ /* kernel has __kernel_fpu_* functions */ /* #undef HAVE_UNDERSCORE_KERNEL_FPU */ /* Define to 1 if you have the header file. */ #define HAVE_UNISTD_H 1 /* iops->getattr() takes struct user_namespace* */ /* #undef HAVE_USERNS_IOPS_GETATTR */ /* iops->setattr() takes struct user_namespace* */ /* #undef HAVE_USERNS_IOPS_SETATTR */ /* user_namespace->ns.inum exists */ /* #undef HAVE_USER_NS_COMMON_INUM */ /* iops->getattr() takes a vfsmount */ /* #undef HAVE_VFSMOUNT_IOPS_GETATTR */ /* fops->clone_file_range() is available */ /* #undef HAVE_VFS_CLONE_FILE_RANGE */ /* fops->copy_file_range() is available */ /* #undef HAVE_VFS_COPY_FILE_RANGE */ /* fops->dedupe_file_range() is available */ /* #undef HAVE_VFS_DEDUPE_FILE_RANGE */ /* aops->direct_IO() uses iovec */ /* #undef HAVE_VFS_DIRECT_IO_IOVEC */ /* aops->direct_IO() uses iov_iter without rw */ /* #undef HAVE_VFS_DIRECT_IO_ITER */ /* aops->direct_IO() uses iov_iter with offset */ /* #undef HAVE_VFS_DIRECT_IO_ITER_OFFSET */ /* aops->direct_IO() uses iov_iter with rw and offset */ /* #undef HAVE_VFS_DIRECT_IO_ITER_RW_OFFSET */ /* filemap_dirty_folio exists */ /* #undef HAVE_VFS_FILEMAP_DIRTY_FOLIO */ /* file_operations_extend takes .copy_file_range() and .clone_file_range() */ /* #undef HAVE_VFS_FILE_OPERATIONS_EXTEND */ /* generic_copy_file_range() is available */ /* #undef HAVE_VFS_GENERIC_COPY_FILE_RANGE */ /* All required iov_iter interfaces are available */ /* #undef HAVE_VFS_IOV_ITER */ /* fops->iterate() is available */ /* #undef HAVE_VFS_ITERATE */ /* fops->iterate_shared() is available */ /* #undef HAVE_VFS_ITERATE_SHARED */ /* fops->readdir() is available */ /* #undef HAVE_VFS_READDIR */ /* address_space_operations->readpages exists */ /* #undef HAVE_VFS_READPAGES */ /* read_folio exists */ /* #undef HAVE_VFS_READ_FOLIO */ /* fops->remap_file_range() is available */ /* #undef HAVE_VFS_REMAP_FILE_RANGE */ /* fops->read/write_iter() are available */ /* #undef HAVE_VFS_RW_ITERATE */ /* __set_page_dirty_nobuffers exists */ /* #undef HAVE_VFS_SET_PAGE_DIRTY_NOBUFFERS */ /* __vmalloc page flags exists */ /* #undef HAVE_VMALLOC_PAGE_KERNEL */ /* yes */ /* #undef HAVE_WAIT_ON_BIT_ACTION */ /* wait_queue_entry_t exists */ /* #undef HAVE_WAIT_QUEUE_ENTRY_T */ /* wq_head->head and wq_entry->entry exist */ /* #undef HAVE_WAIT_QUEUE_HEAD_ENTRY */ /* int (*writepage_t)() takes struct folio* */ /* #undef HAVE_WRITEPAGE_T_FOLIO */ /* xattr_handler->get() wants dentry */ /* #undef HAVE_XATTR_GET_DENTRY */ /* xattr_handler->get() wants both dentry and inode */ /* #undef HAVE_XATTR_GET_DENTRY_INODE */ /* xattr_handler->get() wants dentry and inode and flags */ /* #undef HAVE_XATTR_GET_DENTRY_INODE_FLAGS */ /* xattr_handler->get() wants xattr_handler */ /* #undef HAVE_XATTR_GET_HANDLER */ /* xattr_handler has name */ /* #undef HAVE_XATTR_HANDLER_NAME */ /* xattr_handler->list() wants dentry */ /* #undef HAVE_XATTR_LIST_DENTRY */ /* xattr_handler->list() wants xattr_handler */ /* #undef HAVE_XATTR_LIST_HANDLER */ /* xattr_handler->list() wants simple */ /* #undef HAVE_XATTR_LIST_SIMPLE */ /* xattr_handler->set() wants dentry */ /* #undef HAVE_XATTR_SET_DENTRY */ /* xattr_handler->set() wants both dentry and inode */ /* #undef HAVE_XATTR_SET_DENTRY_INODE */ /* xattr_handler->set() wants xattr_handler */ /* #undef HAVE_XATTR_SET_HANDLER */ /* xattr_handler->set() takes mnt_idmap */ /* #undef HAVE_XATTR_SET_IDMAP */ /* xattr_handler->set() takes user_namespace */ /* #undef HAVE_XATTR_SET_USERNS */ /* Define if host toolchain supports XSAVE */ #define HAVE_XSAVE 1 /* Define if host toolchain supports XSAVEOPT */ #define HAVE_XSAVEOPT 1 /* Define if host toolchain supports XSAVES */ #define HAVE_XSAVES 1 /* ZERO_PAGE() is GPL-only */ /* #undef HAVE_ZERO_PAGE_GPL_ONLY */ /* Define if you have [z] */ #define HAVE_ZLIB 1 /* __posix_acl_chmod() exists */ /* #undef HAVE___POSIX_ACL_CHMOD */ /* kernel exports FPU functions */ /* #undef KERNEL_EXPORTS_X86_FPU */ /* TBD: fetch(3) support */ #if 0 /* whether the chosen libfetch is to be loaded at run-time */ #define LIBFETCH_DYNAMIC 1 /* libfetch is fetch(3) */ #define LIBFETCH_IS_FETCH 1 /* libfetch is libcurl */ #define LIBFETCH_IS_LIBCURL 0 /* soname of chosen libfetch */ #define LIBFETCH_SONAME "libfetch.so.6" #endif /* Define to the sub-directory where libtool stores uninstalled libraries. */ #define LT_OBJDIR ".libs/" /* make_request_fn() return type */ /* #undef MAKE_REQUEST_FN_RET */ /* struct shrink_control has nid */ /* #undef SHRINK_CONTROL_HAS_NID */ /* using complete_and_exit() instead */ /* #undef SPL_KTHREAD_COMPLETE_AND_EXIT */ /* Defined for legacy compatibility. */ #define SPL_META_ALIAS ZFS_META_ALIAS /* Defined for legacy compatibility. */ #define SPL_META_RELEASE ZFS_META_RELEASE /* Defined for legacy compatibility. */ #define SPL_META_VERSION ZFS_META_VERSION /* pde_data() is PDE_DATA() */ /* #undef SPL_PDE_DATA */ /* Define to 1 if all of the C90 standard headers exist (not just the ones required in a freestanding environment). This macro is provided for backward compatibility; new code need not use it. */ #define SYSTEM_FREEBSD 1 /* True if ZFS is to be compiled for a Linux system */ /* #undef SYSTEM_LINUX */ /* Version number of package */ /* #undef ZFS_DEBUG */ /* /dev/zfs minor */ /* #undef ZFS_DEVICE_MINOR */ /* enum node_stat_item contains NR_FILE_PAGES */ /* #undef ZFS_ENUM_NODE_STAT_ITEM_NR_FILE_PAGES */ /* enum node_stat_item contains NR_INACTIVE_ANON */ /* #undef ZFS_ENUM_NODE_STAT_ITEM_NR_INACTIVE_ANON */ /* enum node_stat_item contains NR_INACTIVE_FILE */ /* #undef ZFS_ENUM_NODE_STAT_ITEM_NR_INACTIVE_FILE */ /* enum zone_stat_item contains NR_FILE_PAGES */ /* #undef ZFS_ENUM_ZONE_STAT_ITEM_NR_FILE_PAGES */ /* enum zone_stat_item contains NR_INACTIVE_ANON */ /* #undef ZFS_ENUM_ZONE_STAT_ITEM_NR_INACTIVE_ANON */ /* enum zone_stat_item contains NR_INACTIVE_FILE */ /* #undef ZFS_ENUM_ZONE_STAT_ITEM_NR_INACTIVE_FILE */ /* GENHD_FL_EXT_DEVT flag is not available */ /* #undef ZFS_GENHD_FL_EXT_DEVT */ /* GENHD_FL_NO_PART_SCAN flag is available */ /* #undef ZFS_GENHD_FL_NO_PART */ /* global_node_page_state() exists */ /* #undef ZFS_GLOBAL_NODE_PAGE_STATE */ /* global_zone_page_state() exists */ /* #undef ZFS_GLOBAL_ZONE_PAGE_STATE */ /* Define to 1 if GPL-only symbols can be used */ /* #undef ZFS_IS_GPL_COMPATIBLE */ /* Define the project alias string. */ -#define ZFS_META_ALIAS "zfs-2.2.99-FreeBSD_g8a7407012" +#define ZFS_META_ALIAS "zfs-2.2.99-FreeBSD_g797f55ef1" /* Define the project author. */ #define ZFS_META_AUTHOR "OpenZFS" /* Define the project release date. */ /* #undef ZFS_META_DATA */ /* Define the maximum compatible kernel version. */ #define ZFS_META_KVER_MAX "6.5" /* Define the minimum compatible kernel version. */ #define ZFS_META_KVER_MIN "3.10" /* Define the project license. */ #define ZFS_META_LICENSE "CDDL" /* Define the libtool library 'age' version information. */ /* #undef ZFS_META_LT_AGE */ /* Define the libtool library 'current' version information. */ /* #undef ZFS_META_LT_CURRENT */ /* Define the libtool library 'revision' version information. */ /* #undef ZFS_META_LT_REVISION */ /* Define the project name. */ #define ZFS_META_NAME "zfs" /* Define the project release. */ -#define ZFS_META_RELEASE "FreeBSD_g8a7407012" +#define ZFS_META_RELEASE "FreeBSD_g797f55ef1" /* Define the project version. */ #define ZFS_META_VERSION "2.2.99" /* count is located in percpu_ref.data */ /* #undef ZFS_PERCPU_REF_COUNT_IN_DATA */ diff --git a/sys/modules/zfs/zfs_gitrev.h b/sys/modules/zfs/zfs_gitrev.h index 0dfff6b0c883..e88a5e8dbb37 100644 --- a/sys/modules/zfs/zfs_gitrev.h +++ b/sys/modules/zfs/zfs_gitrev.h @@ -1 +1 @@ -#define ZFS_META_GITREV "zfs-2.2.99-151-g8a7407012" +#define ZFS_META_GITREV "zfs-2.2.99-162-g797f55ef1"