diff --git a/sys/cam/ctl/README.ctl.txt b/sys/cam/ctl/README.ctl.txt index 27ebe49aec56..db8666ea99db 100644 --- a/sys/cam/ctl/README.ctl.txt +++ b/sys/cam/ctl/README.ctl.txt @@ -1,401 +1,401 @@ /* $FreeBSD$ */ CTL - CAM Target Layer Description Revision 1.4 (December 29th, 2011) Ken Merry Table of Contents: ================= Introduction Features Configuring and Running CTL Revision 1.N Changes To Do List Code Roadmap Userland Commands Introduction: ============ CTL is a disk, processor and cdrom device emulation subsystem originally written for Copan Systems under Linux starting in 2003. It has been shipping in Copan (now SGI) products since 2005. It was ported to FreeBSD in 2008, and thanks to an agreement between SGI (who acquired Copan's assets in 2010) and Spectra Logic in 2010, CTL is available under a BSD-style license. The intent behind the agreement was that Spectra would work to get CTL into the FreeBSD tree. Features: ======== - Disk, processor and cdrom device emulation. - Tagged queueing - SCSI task attribute support (ordered, head of queue, simple tags) - SCSI implicit command ordering support. (e.g. if a read follows a mode select, the read will be blocked until the mode select completes.) - Full task management support (abort, LUN reset, target reset, etc.) - Support for multiple ports - Support for multiple simultaneous initiators - Support for multiple simultaneous backing stores - Support for VMWare VAAI: COMPARE AND WRITE, XCOPY, WRITE SAME and UNMAP commands - Support for Microsoft ODX: POPULATE TOKEN/WRITE USING TOKEN, WRITE SAME and UNMAP commands - Persistent reservation support - Mode sense/select support - Error injection support - High Availability clustering support with ALUA - All I/O handled in-kernel, no userland context switch overhead. Configuring and Running CTL: =========================== - Add 'device ctl' to your kernel configuration file or load the module. - If you're running with a 8Gb or 4Gb Qlogic FC board, add 'options ISP_TARGET_MODE' to your kernel config file. 'device ispfw' or loading the ispfw module is also recommended. - Rebuild and install a new kernel. - Reboot with the new kernel. - To add a LUN with the RAM disk backend: ctladm create -b ramdisk -s 10485760000000000000 ctladm port -o on - You should now see the CTL disk LUN through camcontrol devlist: scbus6 on ctl2cam0 bus 0: at scbus6 target 1 lun 0 (da24,pass32) <> at scbus6 target -1 lun -1 () This is visible through the CTL CAM SIM. This allows using CTL without any physical hardware. You should be able to issue any normal SCSI commands to the device via the pass(4)/da(4) devices. If any target-capable HBAs are in the system (e.g. isp(4)), and have target mode enabled, you should now also be able to see the CTL LUNs via that target interface. Note that all CTL LUNs are presented to all frontends. There is no LUN masking, or separate, per-port configuration. - Note that the ramdisk backend is a "fake" ramdisk. That is, it is backed by a small amount of RAM that is used for all I/O requests. This is useful for performance testing, but not for any data integrity tests. - To add a LUN with the block/file backend: truncate -s +1T myfile ctladm create -b block -o file=myfile ctladm port -o on - You can also see a list of LUNs and their backends like this: # ctladm devlist LUN Backend Size (Blocks) BS Serial Number Device ID 0 block 2147483648 512 MYSERIAL 0 MYDEVID 0 1 block 2147483648 512 MYSERIAL 1 MYDEVID 1 2 block 2147483648 512 MYSERIAL 2 MYDEVID 2 3 block 2147483648 512 MYSERIAL 3 MYDEVID 3 4 block 2147483648 512 MYSERIAL 4 MYDEVID 4 5 block 2147483648 512 MYSERIAL 5 MYDEVID 5 6 block 2147483648 512 MYSERIAL 6 MYDEVID 6 7 block 2147483648 512 MYSERIAL 7 MYDEVID 7 8 block 2147483648 512 MYSERIAL 8 MYDEVID 8 9 block 2147483648 512 MYSERIAL 9 MYDEVID 9 10 block 2147483648 512 MYSERIAL 10 MYDEVID 10 11 block 2147483648 512 MYSERIAL 11 MYDEVID 11 - You can see the LUN type and backing store for block/file backend LUNs like this: # ctladm devlist -v LUN Backend Size (Blocks) BS Serial Number Device ID 0 block 2147483648 512 MYSERIAL 0 MYDEVID 0 lun_type=0 num_threads=14 file=testdisk0 1 block 2147483648 512 MYSERIAL 1 MYDEVID 1 lun_type=0 num_threads=14 file=testdisk1 2 block 2147483648 512 MYSERIAL 2 MYDEVID 2 lun_type=0 num_threads=14 file=testdisk2 3 block 2147483648 512 MYSERIAL 3 MYDEVID 3 lun_type=0 num_threads=14 file=testdisk3 4 block 2147483648 512 MYSERIAL 4 MYDEVID 4 lun_type=0 num_threads=14 file=testdisk4 5 block 2147483648 512 MYSERIAL 5 MYDEVID 5 lun_type=0 num_threads=14 file=testdisk5 6 block 2147483648 512 MYSERIAL 6 MYDEVID 6 lun_type=0 num_threads=14 file=testdisk6 7 block 2147483648 512 MYSERIAL 7 MYDEVID 7 lun_type=0 num_threads=14 file=testdisk7 8 block 2147483648 512 MYSERIAL 8 MYDEVID 8 lun_type=0 num_threads=14 file=testdisk8 9 block 2147483648 512 MYSERIAL 9 MYDEVID 9 lun_type=0 num_threads=14 file=testdisk9 10 ramdisk 0 0 MYSERIAL 0 MYDEVID 0 lun_type=3 11 ramdisk 204800000000000 512 MYSERIAL 1 MYDEVID 1 lun_type=0 Revision 1.4 Changes ==================== - Added in the second HA mode (where CTL does the data transfers instead of having data transfers done below CTL), and abstracted out the Copan HA API. - Fixed the phantom device problem in the CTL CAM SIM and improved the CAM SIM to automatically trigger a rescan when the port is enabled and disabled. - Made the number of threads in the block backend configurable via sysctl, loader tunable and the ctladm command line. (You can now specify -o num_threads=4 when creating a LUN with ctladm create.) - Fixed some LUN selection issues in ctlstat(8) and allowed for selection of LUN numbers up to 1023. - General cleanup. - This version intended for public release. Revision 1.3 Changes ==================== - Added descriptor sense support to CTL. It can be enabled through the control mode page (10), but is disabled by default. - Improved error injection support. The number of errors that can be injected with 'ctladm inject' has been increased, and any arbitrary sense data may now be injected as well. - The port infrastructure has been revamped. Individual ports and types of ports may now be enabled and disabled from the command line. ctladm now has the ability to set the WWNN and WWPN for each port. - The block backend can now send multiple I/Os to backing files. Multiple writes are only allowed for ZFS, but multiple readers are allowed for any filesystem. - The block and ramdisk backends now support setting the LUN blocksize. There are some restrictions when the backing device is a block device, but otherwise the blocksize may be set to anything. Revision 1.2 Changes ==================== - CTL initialization process has been revamped. Instead of using an ad-hoc method, it is now sequenced through SYSINIT() calls. - A block/file backend has been added. This allows using arbitrary files or block devices as a backing store. - The userland LUN configuration interface has been completely rewritten. Configuration is now done out of band. - The ctladm(8) command line interface has been revamped, and is now similar to camcontrol(8). To Do List: ========== - Use devstat(9) for CTL's statistics collection. CTL uses a home-grown statistics collection system that is similar to devstat(9). ctlstat should be retired in favor of iostat, etc., once aggregation modes are available in iostat to match the behavior of ctlstat -t and dump modes are available to match the behavior of ctlstat -d/ctlstat -J. - ZFS ARC backend for CTL. Since ZFS copies all I/O into the ARC (Adaptive Replacement Cache), running the block/file backend on top of a ZFS-backed zdev or file will involve an extra set of copies. The optimal solution for backing targets served by CTL with ZFS would be to allocate buffers out of the ARC directly, and DMA to/from them directly. That would eliminate an extra data buffer allocation and copy. - Switch CTL over to using CAM CCBs instead of its own union ctl_io. This will likely require a significant amount of work, but will eliminate another data structure in the stack, more memory allocations, etc. This will also require changes to the CAM CCB structure to support CTL. Code Roadmap: ============ CTL has the concept of pluggable frontend ports and backends. All frontends and backends can be active at the same time. You can have a ramdisk-backed LUN present along side a file backed LUN. ctl.c: ----- This is the core of CTL, where all of the command handlers and a lot of other things live. Yes, it is large. It started off small and grew to its current size over time. Perhaps it can be split into more files at some point. Here is a roadmap of some of the primary functions in ctl.c. Starting here and following the various leaf functions will show the command flow. -ctl_queue() This is where commands from the frontend ports come +ctl_queue() / ctl_run() This is where commands from the frontend ports come in. ctl_queue_sense() This is only used for non-packetized SCSI. i.e. parallel SCSI prior to U320 and perhaps U160. ctl_work_thread() This is the primary work thread, and everything gets executed from there. ctl_scsiio_precheck() This where all of the initial checks are done, and I/O is either queued for execution or blocked. ctl_scsiio() This is where the command handler is actually executed. (See ctl_cmd_table.c for the mapping of SCSI opcode to command handler function.) ctl_done() This is the routine called (or ctl_done_lock()) to initiate the command completion process. ctl_process_done() This is where command completion actually happens. ctl.h: ----- Basic function declarations and data structures. ctl_backend.c, ctl_backend.h: ------------- These files define the basic CTL backend API. The comments in the header explain the API. ctl_backend_block.c ------------------- The block and file backend. This allows for using a disk or a file as the backing store for a LUN. Multiple threads are started to do I/O to the backing device, primarily because the VFS API requires that to get any concurrency. ctl_backend_ramdisk.c: --------------------- A "fake" ramdisk backend. It only allocates a small amount of memory to act as a source and sink for reads and writes from an initiator. Therefore it cannot be used for any real data, but it can be used to test for throughput. It can also be used to test initiators' support for extremely large LUNs. ctl_cmd_table.c: --------------- This is a table with all 256 possible SCSI opcodes, and command handler functions defined for supported opcodes. It is included in ctl.c. ctl_debug.h: ----------- Simplistic debugging support. ctl_error.c, ctl_error.h: ----------- CTL-specific wrappers around the CAM sense building functions. ctl_frontend.c, ctl_frontend.h: -------------- These files define the basic CTL frontend port API. The comments in the header explain the API. ctl_frontend_cam_sim.c: ---------------------- This is a CTL frontend port that is also a CAM SIM. The idea is that this frontend allows for using CTL without any target-capable hardware. So any LUNs you create in CTL are visible via this port. ctl_ha.c: ctl_ha.h: -------- This is a High Availability API and TCP-based interlink implementation. ctl_io.h: -------- This defines most of the core CTL I/O structures. union ctl_io is conceptually very similar to CAM's union ccb. ctl_ioctl.h: ----------- This defines all ioctls available through the CTL character device, and the data structures needed for those ioctls. ctl_private.h: ------------- Private data structres (e.g. CTL softc) and function prototypes. This also includes the SCSI vendor and product names used by CTL. ctl_scsi_all.c ctl_scsi_all.h: -------------- CTL wrappers around CAM sense printing functions. ctl_ser_table.c: --------------- Command serialization table. This defines what happens when one type of command is followed by another type of command. e.g., what do you do when you have a mode select followed by a write? You block the write until the mode select is complete. That is defined in this table. ctl_util.c ctl_util.h: ---------- CTL utility functions, primarily designed to be used from userland. See ctladm for the primary consumer of these functions. These include CDB building functions. scsi_ctl.c: ---------- CAM target peripheral driver and CTL frontend port. This is the path into CTL for commands from target-capable hardware/SIMs. Userland Commands: ================= ctladm(8) fills a role similar to camcontrol(8). It allow configuring LUNs, issuing commands, injecting errors and various other control functions. ctlstat(8) fills a role similar to iostat(8). It reports I/O statistics for CTL. diff --git a/sys/cam/ctl/ctl.c b/sys/cam/ctl/ctl.c index bb8fbf910857..ee36e6b01f52 100644 --- a/sys/cam/ctl/ctl.c +++ b/sys/cam/ctl/ctl.c @@ -1,13568 +1,13601 @@ /*- * SPDX-License-Identifier: BSD-2-Clause-FreeBSD * * Copyright (c) 2003-2009 Silicon Graphics International Corp. * Copyright (c) 2012 The FreeBSD Foundation * Copyright (c) 2014-2017 Alexander Motin * Copyright (c) 2017 Jakub Wojciech Klama * Copyright (c) 2018 Marcelo Araujo * All rights reserved. * * Portions of this software were developed by Edward Tomasz Napierala * under sponsorship from the FreeBSD Foundation. * * 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, * without modification. * 2. Redistributions in binary form must reproduce at minimum a disclaimer * substantially similar to the "NO WARRANTY" disclaimer below * ("Disclaimer") and any redistribution must be conditioned upon * including a substantially similar Disclaimer requirement for further * binary redistribution. * * NO WARRANTY * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTIBILITY AND FITNESS FOR * A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT * HOLDERS OR CONTRIBUTORS BE LIABLE FOR 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 DAMAGES. * * $Id$ */ /* * CAM Target Layer, a SCSI device emulation subsystem. * * Author: Ken Merry */ #include __FBSDID("$FreeBSD$"); #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 #include #include #include #include #include #include #include #include #include #include #include struct ctl_softc *control_softc = NULL; /* * Template mode pages. */ /* * Note that these are default values only. The actual values will be * filled in when the user does a mode sense. */ const static struct scsi_da_rw_recovery_page rw_er_page_default = { /*page_code*/SMS_RW_ERROR_RECOVERY_PAGE, /*page_length*/sizeof(struct scsi_da_rw_recovery_page) - 2, /*byte3*/SMS_RWER_AWRE|SMS_RWER_ARRE, /*read_retry_count*/0, /*correction_span*/0, /*head_offset_count*/0, /*data_strobe_offset_cnt*/0, /*byte8*/SMS_RWER_LBPERE, /*write_retry_count*/0, /*reserved2*/0, /*recovery_time_limit*/{0, 0}, }; const static struct scsi_da_rw_recovery_page rw_er_page_changeable = { /*page_code*/SMS_RW_ERROR_RECOVERY_PAGE, /*page_length*/sizeof(struct scsi_da_rw_recovery_page) - 2, /*byte3*/SMS_RWER_PER, /*read_retry_count*/0, /*correction_span*/0, /*head_offset_count*/0, /*data_strobe_offset_cnt*/0, /*byte8*/SMS_RWER_LBPERE, /*write_retry_count*/0, /*reserved2*/0, /*recovery_time_limit*/{0, 0}, }; const static struct scsi_format_page format_page_default = { /*page_code*/SMS_FORMAT_DEVICE_PAGE, /*page_length*/sizeof(struct scsi_format_page) - 2, /*tracks_per_zone*/ {0, 0}, /*alt_sectors_per_zone*/ {0, 0}, /*alt_tracks_per_zone*/ {0, 0}, /*alt_tracks_per_lun*/ {0, 0}, /*sectors_per_track*/ {(CTL_DEFAULT_SECTORS_PER_TRACK >> 8) & 0xff, CTL_DEFAULT_SECTORS_PER_TRACK & 0xff}, /*bytes_per_sector*/ {0, 0}, /*interleave*/ {0, 0}, /*track_skew*/ {0, 0}, /*cylinder_skew*/ {0, 0}, /*flags*/ SFP_HSEC, /*reserved*/ {0, 0, 0} }; const static struct scsi_format_page format_page_changeable = { /*page_code*/SMS_FORMAT_DEVICE_PAGE, /*page_length*/sizeof(struct scsi_format_page) - 2, /*tracks_per_zone*/ {0, 0}, /*alt_sectors_per_zone*/ {0, 0}, /*alt_tracks_per_zone*/ {0, 0}, /*alt_tracks_per_lun*/ {0, 0}, /*sectors_per_track*/ {0, 0}, /*bytes_per_sector*/ {0, 0}, /*interleave*/ {0, 0}, /*track_skew*/ {0, 0}, /*cylinder_skew*/ {0, 0}, /*flags*/ 0, /*reserved*/ {0, 0, 0} }; const static struct scsi_rigid_disk_page rigid_disk_page_default = { /*page_code*/SMS_RIGID_DISK_PAGE, /*page_length*/sizeof(struct scsi_rigid_disk_page) - 2, /*cylinders*/ {0, 0, 0}, /*heads*/ CTL_DEFAULT_HEADS, /*start_write_precomp*/ {0, 0, 0}, /*start_reduced_current*/ {0, 0, 0}, /*step_rate*/ {0, 0}, /*landing_zone_cylinder*/ {0, 0, 0}, /*rpl*/ SRDP_RPL_DISABLED, /*rotational_offset*/ 0, /*reserved1*/ 0, /*rotation_rate*/ {(CTL_DEFAULT_ROTATION_RATE >> 8) & 0xff, CTL_DEFAULT_ROTATION_RATE & 0xff}, /*reserved2*/ {0, 0} }; const static struct scsi_rigid_disk_page rigid_disk_page_changeable = { /*page_code*/SMS_RIGID_DISK_PAGE, /*page_length*/sizeof(struct scsi_rigid_disk_page) - 2, /*cylinders*/ {0, 0, 0}, /*heads*/ 0, /*start_write_precomp*/ {0, 0, 0}, /*start_reduced_current*/ {0, 0, 0}, /*step_rate*/ {0, 0}, /*landing_zone_cylinder*/ {0, 0, 0}, /*rpl*/ 0, /*rotational_offset*/ 0, /*reserved1*/ 0, /*rotation_rate*/ {0, 0}, /*reserved2*/ {0, 0} }; const static struct scsi_da_verify_recovery_page verify_er_page_default = { /*page_code*/SMS_VERIFY_ERROR_RECOVERY_PAGE, /*page_length*/sizeof(struct scsi_da_verify_recovery_page) - 2, /*byte3*/0, /*read_retry_count*/0, /*reserved*/{ 0, 0, 0, 0, 0, 0 }, /*recovery_time_limit*/{0, 0}, }; const static struct scsi_da_verify_recovery_page verify_er_page_changeable = { /*page_code*/SMS_VERIFY_ERROR_RECOVERY_PAGE, /*page_length*/sizeof(struct scsi_da_verify_recovery_page) - 2, /*byte3*/SMS_VER_PER, /*read_retry_count*/0, /*reserved*/{ 0, 0, 0, 0, 0, 0 }, /*recovery_time_limit*/{0, 0}, }; const static struct scsi_caching_page caching_page_default = { /*page_code*/SMS_CACHING_PAGE, /*page_length*/sizeof(struct scsi_caching_page) - 2, /*flags1*/ SCP_DISC | SCP_WCE, /*ret_priority*/ 0, /*disable_pf_transfer_len*/ {0xff, 0xff}, /*min_prefetch*/ {0, 0}, /*max_prefetch*/ {0xff, 0xff}, /*max_pf_ceiling*/ {0xff, 0xff}, /*flags2*/ 0, /*cache_segments*/ 0, /*cache_seg_size*/ {0, 0}, /*reserved*/ 0, /*non_cache_seg_size*/ {0, 0, 0} }; const static struct scsi_caching_page caching_page_changeable = { /*page_code*/SMS_CACHING_PAGE, /*page_length*/sizeof(struct scsi_caching_page) - 2, /*flags1*/ SCP_WCE | SCP_RCD, /*ret_priority*/ 0, /*disable_pf_transfer_len*/ {0, 0}, /*min_prefetch*/ {0, 0}, /*max_prefetch*/ {0, 0}, /*max_pf_ceiling*/ {0, 0}, /*flags2*/ 0, /*cache_segments*/ 0, /*cache_seg_size*/ {0, 0}, /*reserved*/ 0, /*non_cache_seg_size*/ {0, 0, 0} }; const static struct scsi_control_page control_page_default = { /*page_code*/SMS_CONTROL_MODE_PAGE, /*page_length*/sizeof(struct scsi_control_page) - 2, /*rlec*/0, /*queue_flags*/SCP_QUEUE_ALG_RESTRICTED, /*eca_and_aen*/0, /*flags4*/SCP_TAS, /*aen_holdoff_period*/{0, 0}, /*busy_timeout_period*/{0, 0}, /*extended_selftest_completion_time*/{0, 0} }; const static struct scsi_control_page control_page_changeable = { /*page_code*/SMS_CONTROL_MODE_PAGE, /*page_length*/sizeof(struct scsi_control_page) - 2, /*rlec*/SCP_DSENSE, /*queue_flags*/SCP_QUEUE_ALG_MASK | SCP_NUAR, /*eca_and_aen*/SCP_SWP, /*flags4*/0, /*aen_holdoff_period*/{0, 0}, /*busy_timeout_period*/{0, 0}, /*extended_selftest_completion_time*/{0, 0} }; #define CTL_CEM_LEN (sizeof(struct scsi_control_ext_page) - 4) const static struct scsi_control_ext_page control_ext_page_default = { /*page_code*/SMS_CONTROL_MODE_PAGE | SMPH_SPF, /*subpage_code*/0x01, /*page_length*/{CTL_CEM_LEN >> 8, CTL_CEM_LEN}, /*flags*/0, /*prio*/0, /*max_sense*/0 }; const static struct scsi_control_ext_page control_ext_page_changeable = { /*page_code*/SMS_CONTROL_MODE_PAGE | SMPH_SPF, /*subpage_code*/0x01, /*page_length*/{CTL_CEM_LEN >> 8, CTL_CEM_LEN}, /*flags*/0, /*prio*/0, /*max_sense*/0xff }; const static struct scsi_info_exceptions_page ie_page_default = { /*page_code*/SMS_INFO_EXCEPTIONS_PAGE, /*page_length*/sizeof(struct scsi_info_exceptions_page) - 2, /*info_flags*/SIEP_FLAGS_EWASC, /*mrie*/SIEP_MRIE_NO, /*interval_timer*/{0, 0, 0, 0}, /*report_count*/{0, 0, 0, 1} }; const static struct scsi_info_exceptions_page ie_page_changeable = { /*page_code*/SMS_INFO_EXCEPTIONS_PAGE, /*page_length*/sizeof(struct scsi_info_exceptions_page) - 2, /*info_flags*/SIEP_FLAGS_EWASC | SIEP_FLAGS_DEXCPT | SIEP_FLAGS_TEST | SIEP_FLAGS_LOGERR, /*mrie*/0x0f, /*interval_timer*/{0xff, 0xff, 0xff, 0xff}, /*report_count*/{0xff, 0xff, 0xff, 0xff} }; #define CTL_LBPM_LEN (sizeof(struct ctl_logical_block_provisioning_page) - 4) const static struct ctl_logical_block_provisioning_page lbp_page_default = {{ /*page_code*/SMS_INFO_EXCEPTIONS_PAGE | SMPH_SPF, /*subpage_code*/0x02, /*page_length*/{CTL_LBPM_LEN >> 8, CTL_LBPM_LEN}, /*flags*/0, /*reserved*/{0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0}, /*descr*/{}}, {{/*flags*/0, /*resource*/0x01, /*reserved*/{0, 0}, /*count*/{0, 0, 0, 0}}, {/*flags*/0, /*resource*/0x02, /*reserved*/{0, 0}, /*count*/{0, 0, 0, 0}}, {/*flags*/0, /*resource*/0xf1, /*reserved*/{0, 0}, /*count*/{0, 0, 0, 0}}, {/*flags*/0, /*resource*/0xf2, /*reserved*/{0, 0}, /*count*/{0, 0, 0, 0}} } }; const static struct ctl_logical_block_provisioning_page lbp_page_changeable = {{ /*page_code*/SMS_INFO_EXCEPTIONS_PAGE | SMPH_SPF, /*subpage_code*/0x02, /*page_length*/{CTL_LBPM_LEN >> 8, CTL_LBPM_LEN}, /*flags*/SLBPP_SITUA, /*reserved*/{0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0}, /*descr*/{}}, {{/*flags*/0, /*resource*/0, /*reserved*/{0, 0}, /*count*/{0, 0, 0, 0}}, {/*flags*/0, /*resource*/0, /*reserved*/{0, 0}, /*count*/{0, 0, 0, 0}}, {/*flags*/0, /*resource*/0, /*reserved*/{0, 0}, /*count*/{0, 0, 0, 0}}, {/*flags*/0, /*resource*/0, /*reserved*/{0, 0}, /*count*/{0, 0, 0, 0}} } }; const static struct scsi_cddvd_capabilities_page cddvd_page_default = { /*page_code*/SMS_CDDVD_CAPS_PAGE, /*page_length*/sizeof(struct scsi_cddvd_capabilities_page) - 2, /*caps1*/0x3f, /*caps2*/0x00, /*caps3*/0xf0, /*caps4*/0x00, /*caps5*/0x29, /*caps6*/0x00, /*obsolete*/{0, 0}, /*nvol_levels*/{0, 0}, /*buffer_size*/{8, 0}, /*obsolete2*/{0, 0}, /*reserved*/0, /*digital*/0, /*obsolete3*/0, /*copy_management*/0, /*reserved2*/0, /*rotation_control*/0, /*cur_write_speed*/0, /*num_speed_descr*/0, }; const static struct scsi_cddvd_capabilities_page cddvd_page_changeable = { /*page_code*/SMS_CDDVD_CAPS_PAGE, /*page_length*/sizeof(struct scsi_cddvd_capabilities_page) - 2, /*caps1*/0, /*caps2*/0, /*caps3*/0, /*caps4*/0, /*caps5*/0, /*caps6*/0, /*obsolete*/{0, 0}, /*nvol_levels*/{0, 0}, /*buffer_size*/{0, 0}, /*obsolete2*/{0, 0}, /*reserved*/0, /*digital*/0, /*obsolete3*/0, /*copy_management*/0, /*reserved2*/0, /*rotation_control*/0, /*cur_write_speed*/0, /*num_speed_descr*/0, }; SYSCTL_NODE(_kern_cam, OID_AUTO, ctl, CTLFLAG_RD | CTLFLAG_MPSAFE, 0, "CAM Target Layer"); static int worker_threads = -1; SYSCTL_INT(_kern_cam_ctl, OID_AUTO, worker_threads, CTLFLAG_RDTUN, &worker_threads, 1, "Number of worker threads"); static int ctl_debug = CTL_DEBUG_NONE; SYSCTL_INT(_kern_cam_ctl, OID_AUTO, debug, CTLFLAG_RWTUN, &ctl_debug, 0, "Enabled debug flags"); static int ctl_lun_map_size = 1024; SYSCTL_INT(_kern_cam_ctl, OID_AUTO, lun_map_size, CTLFLAG_RWTUN, &ctl_lun_map_size, 0, "Size of per-port LUN map (max LUN + 1)"); #ifdef CTL_TIME_IO static int ctl_time_io_secs = CTL_TIME_IO_DEFAULT_SECS; SYSCTL_INT(_kern_cam_ctl, OID_AUTO, time_io_secs, CTLFLAG_RWTUN, &ctl_time_io_secs, 0, "Log requests taking more seconds"); #endif /* * Maximum number of LUNs we support. MUST be a power of 2. */ #define CTL_DEFAULT_MAX_LUNS 1024 static int ctl_max_luns = CTL_DEFAULT_MAX_LUNS; TUNABLE_INT("kern.cam.ctl.max_luns", &ctl_max_luns); SYSCTL_INT(_kern_cam_ctl, OID_AUTO, max_luns, CTLFLAG_RDTUN, &ctl_max_luns, CTL_DEFAULT_MAX_LUNS, "Maximum number of LUNs"); /* * Maximum number of ports registered at one time. */ #define CTL_DEFAULT_MAX_PORTS 256 static int ctl_max_ports = CTL_DEFAULT_MAX_PORTS; TUNABLE_INT("kern.cam.ctl.max_ports", &ctl_max_ports); SYSCTL_INT(_kern_cam_ctl, OID_AUTO, max_ports, CTLFLAG_RDTUN, &ctl_max_ports, CTL_DEFAULT_MAX_LUNS, "Maximum number of ports"); /* * Maximum number of initiators we support. */ #define CTL_MAX_INITIATORS (CTL_MAX_INIT_PER_PORT * ctl_max_ports) /* * Supported pages (0x00), Serial number (0x80), Device ID (0x83), * Extended INQUIRY Data (0x86), Mode Page Policy (0x87), * SCSI Ports (0x88), Third-party Copy (0x8F), SCSI Feature Sets (0x92), * Block limits (0xB0), Block Device Characteristics (0xB1) and * Logical Block Provisioning (0xB2) */ #define SCSI_EVPD_NUM_SUPPORTED_PAGES 11 static void ctl_isc_event_handler(ctl_ha_channel chanel, ctl_ha_event event, int param); static void ctl_copy_sense_data(union ctl_ha_msg *src, union ctl_io *dest); static void ctl_copy_sense_data_back(union ctl_io *src, union ctl_ha_msg *dest); static int ctl_init(void); static int ctl_shutdown(void); static int ctl_open(struct cdev *dev, int flags, int fmt, struct thread *td); static int ctl_close(struct cdev *dev, int flags, int fmt, struct thread *td); static void ctl_serialize_other_sc_cmd(struct ctl_scsiio *ctsio); static void ctl_ioctl_fill_ooa(struct ctl_lun *lun, uint32_t *cur_fill_num, struct ctl_ooa *ooa_hdr, struct ctl_ooa_entry *kern_entries); static int ctl_ioctl(struct cdev *dev, u_long cmd, caddr_t addr, int flag, struct thread *td); static int ctl_enable_lun(struct ctl_lun *lun); static int ctl_disable_lun(struct ctl_lun *lun); static int ctl_free_lun(struct ctl_lun *lun); static int ctl_do_mode_select(union ctl_io *io); static int ctl_pro_preempt(struct ctl_softc *softc, struct ctl_lun *lun, uint64_t res_key, uint64_t sa_res_key, uint8_t type, uint32_t residx, struct ctl_scsiio *ctsio, struct scsi_per_res_out *cdb, struct scsi_per_res_out_parms* param); static void ctl_pro_preempt_other(struct ctl_lun *lun, union ctl_ha_msg *msg); static void ctl_hndl_per_res_out_on_other_sc(union ctl_io *io); static int ctl_inquiry_evpd_supported(struct ctl_scsiio *ctsio, int alloc_len); static int ctl_inquiry_evpd_serial(struct ctl_scsiio *ctsio, int alloc_len); static int ctl_inquiry_evpd_devid(struct ctl_scsiio *ctsio, int alloc_len); static int ctl_inquiry_evpd_eid(struct ctl_scsiio *ctsio, int alloc_len); static int ctl_inquiry_evpd_mpp(struct ctl_scsiio *ctsio, int alloc_len); static int ctl_inquiry_evpd_scsi_ports(struct ctl_scsiio *ctsio, int alloc_len); static int ctl_inquiry_evpd_sfs(struct ctl_scsiio *ctsio, int alloc_len); static int ctl_inquiry_evpd_block_limits(struct ctl_scsiio *ctsio, int alloc_len); static int ctl_inquiry_evpd_bdc(struct ctl_scsiio *ctsio, int alloc_len); static int ctl_inquiry_evpd_lbp(struct ctl_scsiio *ctsio, int alloc_len); static int ctl_inquiry_evpd(struct ctl_scsiio *ctsio); static int ctl_inquiry_std(struct ctl_scsiio *ctsio); static int ctl_get_lba_len(union ctl_io *io, uint64_t *lba, uint64_t *len); static ctl_action ctl_extent_check(union ctl_io *io1, union ctl_io *io2, bool seq); static ctl_action ctl_extent_check_seq(union ctl_io *io1, union ctl_io *io2); static ctl_action ctl_check_for_blockage(struct ctl_lun *lun, union ctl_io *pending_io, union ctl_io *ooa_io); static ctl_action ctl_check_ooa(struct ctl_lun *lun, union ctl_io *pending_io, union ctl_io **starting_io); static void ctl_try_unblock_io(struct ctl_lun *lun, union ctl_io *io, bool skip); static void ctl_try_unblock_others(struct ctl_lun *lun, union ctl_io *io, bool skip); static int ctl_scsiio_lun_check(struct ctl_lun *lun, const struct ctl_cmd_entry *entry, struct ctl_scsiio *ctsio); static void ctl_failover_lun(union ctl_io *io); -static int ctl_scsiio_precheck(struct ctl_softc *ctl_softc, - struct ctl_scsiio *ctsio); +static void ctl_scsiio_precheck(struct ctl_scsiio *ctsio); static int ctl_scsiio(struct ctl_scsiio *ctsio); static int ctl_target_reset(union ctl_io *io); static void ctl_do_lun_reset(struct ctl_lun *lun, uint32_t initidx, ctl_ua_type ua_type); static int ctl_lun_reset(union ctl_io *io); static int ctl_abort_task(union ctl_io *io); static int ctl_abort_task_set(union ctl_io *io); static int ctl_query_task(union ctl_io *io, int task_set); static void ctl_i_t_nexus_loss(struct ctl_softc *softc, uint32_t initidx, ctl_ua_type ua_type); static int ctl_i_t_nexus_reset(union ctl_io *io); static int ctl_query_async_event(union ctl_io *io); static void ctl_run_task(union ctl_io *io); #ifdef CTL_IO_DELAY static void ctl_datamove_timer_wakeup(void *arg); static void ctl_done_timer_wakeup(void *arg); #endif /* CTL_IO_DELAY */ static void ctl_send_datamove_done(union ctl_io *io, int have_lock); static void ctl_datamove_remote_write_cb(struct ctl_ha_dt_req *rq); static int ctl_datamove_remote_dm_write_cb(union ctl_io *io); static void ctl_datamove_remote_write(union ctl_io *io); static int ctl_datamove_remote_dm_read_cb(union ctl_io *io); static void ctl_datamove_remote_read_cb(struct ctl_ha_dt_req *rq); static int ctl_datamove_remote_sgl_setup(union ctl_io *io); static int ctl_datamove_remote_xfer(union ctl_io *io, unsigned command, ctl_ha_dt_cb callback); static void ctl_datamove_remote_read(union ctl_io *io); static void ctl_datamove_remote(union ctl_io *io); static void ctl_process_done(union ctl_io *io); static void ctl_thresh_thread(void *arg); static void ctl_work_thread(void *arg); static void ctl_enqueue_incoming(union ctl_io *io); static void ctl_enqueue_rtr(union ctl_io *io); static void ctl_enqueue_done(union ctl_io *io); static void ctl_enqueue_isc(union ctl_io *io); static const struct ctl_cmd_entry * ctl_get_cmd_entry(struct ctl_scsiio *ctsio, int *sa); static const struct ctl_cmd_entry * ctl_validate_command(struct ctl_scsiio *ctsio); static int ctl_cmd_applicable(uint8_t lun_type, const struct ctl_cmd_entry *entry); static int ctl_ha_init(void); static int ctl_ha_shutdown(void); static uint64_t ctl_get_prkey(struct ctl_lun *lun, uint32_t residx); static void ctl_clr_prkey(struct ctl_lun *lun, uint32_t residx); static void ctl_alloc_prkey(struct ctl_lun *lun, uint32_t residx); static void ctl_set_prkey(struct ctl_lun *lun, uint32_t residx, uint64_t key); /* * Load the serialization table. This isn't very pretty, but is probably * the easiest way to do it. */ #include "ctl_ser_table.c" /* * We only need to define open, close and ioctl routines for this driver. */ static struct cdevsw ctl_cdevsw = { .d_version = D_VERSION, .d_flags = 0, .d_open = ctl_open, .d_close = ctl_close, .d_ioctl = ctl_ioctl, .d_name = "ctl", }; MALLOC_DEFINE(M_CTL, "ctlmem", "Memory used for CTL"); static int ctl_module_event_handler(module_t, int /*modeventtype_t*/, void *); static moduledata_t ctl_moduledata = { "ctl", ctl_module_event_handler, NULL }; DECLARE_MODULE(ctl, ctl_moduledata, SI_SUB_CONFIGURE, SI_ORDER_THIRD); MODULE_VERSION(ctl, 1); static struct ctl_frontend ha_frontend = { .name = "ha", .init = ctl_ha_init, .shutdown = ctl_ha_shutdown, }; static int ctl_ha_init(void) { struct ctl_softc *softc = control_softc; if (ctl_pool_create(softc, "othersc", CTL_POOL_ENTRIES_OTHER_SC, &softc->othersc_pool) != 0) return (ENOMEM); if (ctl_ha_msg_init(softc) != CTL_HA_STATUS_SUCCESS) { ctl_pool_free(softc->othersc_pool); return (EIO); } if (ctl_ha_msg_register(CTL_HA_CHAN_CTL, ctl_isc_event_handler) != CTL_HA_STATUS_SUCCESS) { ctl_ha_msg_destroy(softc); ctl_pool_free(softc->othersc_pool); return (EIO); } return (0); }; static int ctl_ha_shutdown(void) { struct ctl_softc *softc = control_softc; struct ctl_port *port; ctl_ha_msg_shutdown(softc); if (ctl_ha_msg_deregister(CTL_HA_CHAN_CTL) != CTL_HA_STATUS_SUCCESS) return (EIO); if (ctl_ha_msg_destroy(softc) != CTL_HA_STATUS_SUCCESS) return (EIO); ctl_pool_free(softc->othersc_pool); while ((port = STAILQ_FIRST(&ha_frontend.port_list)) != NULL) { ctl_port_deregister(port); free(port->port_name, M_CTL); free(port, M_CTL); } return (0); }; static void ctl_ha_datamove(union ctl_io *io) { struct ctl_lun *lun = CTL_LUN(io); struct ctl_sg_entry *sgl; union ctl_ha_msg msg; uint32_t sg_entries_sent; int do_sg_copy, i, j; memset(&msg.dt, 0, sizeof(msg.dt)); msg.hdr.msg_type = CTL_MSG_DATAMOVE; msg.hdr.original_sc = io->io_hdr.remote_io; msg.hdr.serializing_sc = io; msg.hdr.nexus = io->io_hdr.nexus; msg.hdr.status = io->io_hdr.status; msg.dt.flags = io->io_hdr.flags; /* * We convert everything into a S/G list here. We can't * pass by reference, only by value between controllers. * So we can't pass a pointer to the S/G list, only as many * S/G entries as we can fit in here. If it's possible for * us to get more than CTL_HA_MAX_SG_ENTRIES S/G entries, * then we need to break this up into multiple transfers. */ if (io->scsiio.kern_sg_entries == 0) { msg.dt.kern_sg_entries = 1; #if 0 if (io->io_hdr.flags & CTL_FLAG_BUS_ADDR) { msg.dt.sg_list[0].addr = io->scsiio.kern_data_ptr; } else { /* XXX KDM use busdma here! */ msg.dt.sg_list[0].addr = (void *)vtophys(io->scsiio.kern_data_ptr); } #else KASSERT((io->io_hdr.flags & CTL_FLAG_BUS_ADDR) == 0, ("HA does not support BUS_ADDR")); msg.dt.sg_list[0].addr = io->scsiio.kern_data_ptr; #endif msg.dt.sg_list[0].len = io->scsiio.kern_data_len; do_sg_copy = 0; } else { msg.dt.kern_sg_entries = io->scsiio.kern_sg_entries; do_sg_copy = 1; } msg.dt.kern_data_len = io->scsiio.kern_data_len; msg.dt.kern_total_len = io->scsiio.kern_total_len; msg.dt.kern_data_resid = io->scsiio.kern_data_resid; msg.dt.kern_rel_offset = io->scsiio.kern_rel_offset; msg.dt.sg_sequence = 0; /* * Loop until we've sent all of the S/G entries. On the * other end, we'll recompose these S/G entries into one * contiguous list before processing. */ for (sg_entries_sent = 0; sg_entries_sent < msg.dt.kern_sg_entries; msg.dt.sg_sequence++) { msg.dt.cur_sg_entries = MIN((sizeof(msg.dt.sg_list) / sizeof(msg.dt.sg_list[0])), msg.dt.kern_sg_entries - sg_entries_sent); if (do_sg_copy != 0) { sgl = (struct ctl_sg_entry *)io->scsiio.kern_data_ptr; for (i = sg_entries_sent, j = 0; i < msg.dt.cur_sg_entries; i++, j++) { #if 0 if (io->io_hdr.flags & CTL_FLAG_BUS_ADDR) { msg.dt.sg_list[j].addr = sgl[i].addr; } else { /* XXX KDM use busdma here! */ msg.dt.sg_list[j].addr = (void *)vtophys(sgl[i].addr); } #else KASSERT((io->io_hdr.flags & CTL_FLAG_BUS_ADDR) == 0, ("HA does not support BUS_ADDR")); msg.dt.sg_list[j].addr = sgl[i].addr; #endif msg.dt.sg_list[j].len = sgl[i].len; } } sg_entries_sent += msg.dt.cur_sg_entries; msg.dt.sg_last = (sg_entries_sent >= msg.dt.kern_sg_entries); if (ctl_ha_msg_send(CTL_HA_CHAN_CTL, &msg, sizeof(msg.dt) - sizeof(msg.dt.sg_list) + sizeof(struct ctl_sg_entry) * msg.dt.cur_sg_entries, M_WAITOK) > CTL_HA_STATUS_SUCCESS) { io->io_hdr.port_status = 31341; io->scsiio.be_move_done(io); return; } msg.dt.sent_sg_entries = sg_entries_sent; } /* * Officially handover the request from us to peer. * If failover has just happened, then we must return error. * If failover happen just after, then it is not our problem. */ if (lun) mtx_lock(&lun->lun_lock); if (io->io_hdr.flags & CTL_FLAG_FAILOVER) { if (lun) mtx_unlock(&lun->lun_lock); io->io_hdr.port_status = 31342; io->scsiio.be_move_done(io); return; } io->io_hdr.flags &= ~CTL_FLAG_IO_ACTIVE; io->io_hdr.flags |= CTL_FLAG_DMA_INPROG; if (lun) mtx_unlock(&lun->lun_lock); } static void ctl_ha_done(union ctl_io *io) { union ctl_ha_msg msg; if (io->io_hdr.io_type == CTL_IO_SCSI) { memset(&msg, 0, sizeof(msg)); msg.hdr.msg_type = CTL_MSG_FINISH_IO; msg.hdr.original_sc = io->io_hdr.remote_io; msg.hdr.nexus = io->io_hdr.nexus; msg.hdr.status = io->io_hdr.status; msg.scsi.scsi_status = io->scsiio.scsi_status; msg.scsi.tag_num = io->scsiio.tag_num; msg.scsi.tag_type = io->scsiio.tag_type; msg.scsi.sense_len = io->scsiio.sense_len; memcpy(&msg.scsi.sense_data, &io->scsiio.sense_data, io->scsiio.sense_len); ctl_ha_msg_send(CTL_HA_CHAN_CTL, &msg, sizeof(msg.scsi) - sizeof(msg.scsi.sense_data) + msg.scsi.sense_len, M_WAITOK); } ctl_free_io(io); } static void ctl_isc_handler_finish_xfer(struct ctl_softc *ctl_softc, union ctl_ha_msg *msg_info) { struct ctl_scsiio *ctsio; if (msg_info->hdr.original_sc == NULL) { printf("%s: original_sc == NULL!\n", __func__); /* XXX KDM now what? */ return; } ctsio = &msg_info->hdr.original_sc->scsiio; ctsio->io_hdr.flags |= CTL_FLAG_IO_ACTIVE; ctsio->io_hdr.msg_type = CTL_MSG_FINISH_IO; ctsio->io_hdr.status = msg_info->hdr.status; ctsio->scsi_status = msg_info->scsi.scsi_status; ctsio->sense_len = msg_info->scsi.sense_len; memcpy(&ctsio->sense_data, &msg_info->scsi.sense_data, msg_info->scsi.sense_len); ctl_enqueue_isc((union ctl_io *)ctsio); } static void ctl_isc_handler_finish_ser_only(struct ctl_softc *ctl_softc, union ctl_ha_msg *msg_info) { struct ctl_scsiio *ctsio; if (msg_info->hdr.serializing_sc == NULL) { printf("%s: serializing_sc == NULL!\n", __func__); /* XXX KDM now what? */ return; } ctsio = &msg_info->hdr.serializing_sc->scsiio; ctsio->io_hdr.msg_type = CTL_MSG_FINISH_IO; ctl_enqueue_isc((union ctl_io *)ctsio); } void ctl_isc_announce_lun(struct ctl_lun *lun) { struct ctl_softc *softc = lun->ctl_softc; union ctl_ha_msg *msg; struct ctl_ha_msg_lun_pr_key pr_key; int i, k; if (softc->ha_link != CTL_HA_LINK_ONLINE) return; mtx_lock(&lun->lun_lock); i = sizeof(msg->lun); if (lun->lun_devid) i += lun->lun_devid->len; i += sizeof(pr_key) * lun->pr_key_count; alloc: mtx_unlock(&lun->lun_lock); msg = malloc(i, M_CTL, M_WAITOK); mtx_lock(&lun->lun_lock); k = sizeof(msg->lun); if (lun->lun_devid) k += lun->lun_devid->len; k += sizeof(pr_key) * lun->pr_key_count; if (i < k) { free(msg, M_CTL); i = k; goto alloc; } bzero(&msg->lun, sizeof(msg->lun)); msg->hdr.msg_type = CTL_MSG_LUN_SYNC; msg->hdr.nexus.targ_lun = lun->lun; msg->hdr.nexus.targ_mapped_lun = lun->lun; msg->lun.flags = lun->flags; msg->lun.pr_generation = lun->pr_generation; msg->lun.pr_res_idx = lun->pr_res_idx; msg->lun.pr_res_type = lun->pr_res_type; msg->lun.pr_key_count = lun->pr_key_count; i = 0; if (lun->lun_devid) { msg->lun.lun_devid_len = lun->lun_devid->len; memcpy(&msg->lun.data[i], lun->lun_devid->data, msg->lun.lun_devid_len); i += msg->lun.lun_devid_len; } for (k = 0; k < CTL_MAX_INITIATORS; k++) { if ((pr_key.pr_key = ctl_get_prkey(lun, k)) == 0) continue; pr_key.pr_iid = k; memcpy(&msg->lun.data[i], &pr_key, sizeof(pr_key)); i += sizeof(pr_key); } mtx_unlock(&lun->lun_lock); ctl_ha_msg_send(CTL_HA_CHAN_CTL, &msg->port, sizeof(msg->port) + i, M_WAITOK); free(msg, M_CTL); if (lun->flags & CTL_LUN_PRIMARY_SC) { for (i = 0; i < CTL_NUM_MODE_PAGES; i++) { ctl_isc_announce_mode(lun, -1, lun->mode_pages.index[i].page_code & SMPH_PC_MASK, lun->mode_pages.index[i].subpage); } } } void ctl_isc_announce_port(struct ctl_port *port) { struct ctl_softc *softc = port->ctl_softc; union ctl_ha_msg *msg; int i; if (port->targ_port < softc->port_min || port->targ_port >= softc->port_max || softc->ha_link != CTL_HA_LINK_ONLINE) return; i = sizeof(msg->port) + strlen(port->port_name) + 1; if (port->lun_map) i += port->lun_map_size * sizeof(uint32_t); if (port->port_devid) i += port->port_devid->len; if (port->target_devid) i += port->target_devid->len; if (port->init_devid) i += port->init_devid->len; msg = malloc(i, M_CTL, M_WAITOK); bzero(&msg->port, sizeof(msg->port)); msg->hdr.msg_type = CTL_MSG_PORT_SYNC; msg->hdr.nexus.targ_port = port->targ_port; msg->port.port_type = port->port_type; msg->port.physical_port = port->physical_port; msg->port.virtual_port = port->virtual_port; msg->port.status = port->status; i = 0; msg->port.name_len = sprintf(&msg->port.data[i], "%d:%s", softc->ha_id, port->port_name) + 1; i += msg->port.name_len; if (port->lun_map) { msg->port.lun_map_len = port->lun_map_size * sizeof(uint32_t); memcpy(&msg->port.data[i], port->lun_map, msg->port.lun_map_len); i += msg->port.lun_map_len; } if (port->port_devid) { msg->port.port_devid_len = port->port_devid->len; memcpy(&msg->port.data[i], port->port_devid->data, msg->port.port_devid_len); i += msg->port.port_devid_len; } if (port->target_devid) { msg->port.target_devid_len = port->target_devid->len; memcpy(&msg->port.data[i], port->target_devid->data, msg->port.target_devid_len); i += msg->port.target_devid_len; } if (port->init_devid) { msg->port.init_devid_len = port->init_devid->len; memcpy(&msg->port.data[i], port->init_devid->data, msg->port.init_devid_len); i += msg->port.init_devid_len; } ctl_ha_msg_send(CTL_HA_CHAN_CTL, &msg->port, sizeof(msg->port) + i, M_WAITOK); free(msg, M_CTL); } void ctl_isc_announce_iid(struct ctl_port *port, int iid) { struct ctl_softc *softc = port->ctl_softc; union ctl_ha_msg *msg; int i, l; if (port->targ_port < softc->port_min || port->targ_port >= softc->port_max || softc->ha_link != CTL_HA_LINK_ONLINE) return; mtx_lock(&softc->ctl_lock); i = sizeof(msg->iid); l = 0; if (port->wwpn_iid[iid].name) l = strlen(port->wwpn_iid[iid].name) + 1; i += l; msg = malloc(i, M_CTL, M_NOWAIT); if (msg == NULL) { mtx_unlock(&softc->ctl_lock); return; } bzero(&msg->iid, sizeof(msg->iid)); msg->hdr.msg_type = CTL_MSG_IID_SYNC; msg->hdr.nexus.targ_port = port->targ_port; msg->hdr.nexus.initid = iid; msg->iid.in_use = port->wwpn_iid[iid].in_use; msg->iid.name_len = l; msg->iid.wwpn = port->wwpn_iid[iid].wwpn; if (port->wwpn_iid[iid].name) strlcpy(msg->iid.data, port->wwpn_iid[iid].name, l); mtx_unlock(&softc->ctl_lock); ctl_ha_msg_send(CTL_HA_CHAN_CTL, &msg->iid, i, M_NOWAIT); free(msg, M_CTL); } void ctl_isc_announce_mode(struct ctl_lun *lun, uint32_t initidx, uint8_t page, uint8_t subpage) { struct ctl_softc *softc = lun->ctl_softc; union ctl_ha_msg msg; u_int i; if (softc->ha_link != CTL_HA_LINK_ONLINE) return; for (i = 0; i < CTL_NUM_MODE_PAGES; i++) { if ((lun->mode_pages.index[i].page_code & SMPH_PC_MASK) == page && lun->mode_pages.index[i].subpage == subpage) break; } if (i == CTL_NUM_MODE_PAGES) return; /* Don't try to replicate pages not present on this device. */ if (lun->mode_pages.index[i].page_data == NULL) return; bzero(&msg.mode, sizeof(msg.mode)); msg.hdr.msg_type = CTL_MSG_MODE_SYNC; msg.hdr.nexus.targ_port = initidx / CTL_MAX_INIT_PER_PORT; msg.hdr.nexus.initid = initidx % CTL_MAX_INIT_PER_PORT; msg.hdr.nexus.targ_lun = lun->lun; msg.hdr.nexus.targ_mapped_lun = lun->lun; msg.mode.page_code = page; msg.mode.subpage = subpage; msg.mode.page_len = lun->mode_pages.index[i].page_len; memcpy(msg.mode.data, lun->mode_pages.index[i].page_data, msg.mode.page_len); ctl_ha_msg_send(CTL_HA_CHAN_CTL, &msg.mode, sizeof(msg.mode), M_WAITOK); } static void ctl_isc_ha_link_up(struct ctl_softc *softc) { struct ctl_port *port; struct ctl_lun *lun; union ctl_ha_msg msg; int i; /* Announce this node parameters to peer for validation. */ msg.login.msg_type = CTL_MSG_LOGIN; msg.login.version = CTL_HA_VERSION; msg.login.ha_mode = softc->ha_mode; msg.login.ha_id = softc->ha_id; msg.login.max_luns = ctl_max_luns; msg.login.max_ports = ctl_max_ports; msg.login.max_init_per_port = CTL_MAX_INIT_PER_PORT; ctl_ha_msg_send(CTL_HA_CHAN_CTL, &msg.login, sizeof(msg.login), M_WAITOK); STAILQ_FOREACH(port, &softc->port_list, links) { ctl_isc_announce_port(port); for (i = 0; i < CTL_MAX_INIT_PER_PORT; i++) { if (port->wwpn_iid[i].in_use) ctl_isc_announce_iid(port, i); } } STAILQ_FOREACH(lun, &softc->lun_list, links) ctl_isc_announce_lun(lun); } static void ctl_isc_ha_link_down(struct ctl_softc *softc) { struct ctl_port *port; struct ctl_lun *lun; union ctl_io *io; int i; mtx_lock(&softc->ctl_lock); STAILQ_FOREACH(lun, &softc->lun_list, links) { mtx_lock(&lun->lun_lock); if (lun->flags & CTL_LUN_PEER_SC_PRIMARY) { lun->flags &= ~CTL_LUN_PEER_SC_PRIMARY; ctl_est_ua_all(lun, -1, CTL_UA_ASYM_ACC_CHANGE); } mtx_unlock(&lun->lun_lock); mtx_unlock(&softc->ctl_lock); io = ctl_alloc_io(softc->othersc_pool); mtx_lock(&softc->ctl_lock); ctl_zero_io(io); io->io_hdr.msg_type = CTL_MSG_FAILOVER; io->io_hdr.nexus.targ_mapped_lun = lun->lun; ctl_enqueue_isc(io); } STAILQ_FOREACH(port, &softc->port_list, links) { if (port->targ_port >= softc->port_min && port->targ_port < softc->port_max) continue; port->status &= ~CTL_PORT_STATUS_ONLINE; for (i = 0; i < CTL_MAX_INIT_PER_PORT; i++) { port->wwpn_iid[i].in_use = 0; free(port->wwpn_iid[i].name, M_CTL); port->wwpn_iid[i].name = NULL; } } mtx_unlock(&softc->ctl_lock); } static void ctl_isc_ua(struct ctl_softc *softc, union ctl_ha_msg *msg, int len) { struct ctl_lun *lun; uint32_t iid = ctl_get_initindex(&msg->hdr.nexus); mtx_lock(&softc->ctl_lock); if (msg->hdr.nexus.targ_mapped_lun >= ctl_max_luns || (lun = softc->ctl_luns[msg->hdr.nexus.targ_mapped_lun]) == NULL) { mtx_unlock(&softc->ctl_lock); return; } mtx_lock(&lun->lun_lock); mtx_unlock(&softc->ctl_lock); if (msg->ua.ua_type == CTL_UA_THIN_PROV_THRES && msg->ua.ua_set) memcpy(lun->ua_tpt_info, msg->ua.ua_info, 8); if (msg->ua.ua_all) { if (msg->ua.ua_set) ctl_est_ua_all(lun, iid, msg->ua.ua_type); else ctl_clr_ua_all(lun, iid, msg->ua.ua_type); } else { if (msg->ua.ua_set) ctl_est_ua(lun, iid, msg->ua.ua_type); else ctl_clr_ua(lun, iid, msg->ua.ua_type); } mtx_unlock(&lun->lun_lock); } static void ctl_isc_lun_sync(struct ctl_softc *softc, union ctl_ha_msg *msg, int len) { struct ctl_lun *lun; struct ctl_ha_msg_lun_pr_key pr_key; int i, k; ctl_lun_flags oflags; uint32_t targ_lun; targ_lun = msg->hdr.nexus.targ_mapped_lun; mtx_lock(&softc->ctl_lock); if (targ_lun >= ctl_max_luns || (lun = softc->ctl_luns[targ_lun]) == NULL) { mtx_unlock(&softc->ctl_lock); return; } mtx_lock(&lun->lun_lock); mtx_unlock(&softc->ctl_lock); if (lun->flags & CTL_LUN_DISABLED) { mtx_unlock(&lun->lun_lock); return; } i = (lun->lun_devid != NULL) ? lun->lun_devid->len : 0; if (msg->lun.lun_devid_len != i || (i > 0 && memcmp(&msg->lun.data[0], lun->lun_devid->data, i) != 0)) { mtx_unlock(&lun->lun_lock); printf("%s: Received conflicting HA LUN %d\n", __func__, targ_lun); return; } else { /* Record whether peer is primary. */ oflags = lun->flags; if ((msg->lun.flags & CTL_LUN_PRIMARY_SC) && (msg->lun.flags & CTL_LUN_DISABLED) == 0) lun->flags |= CTL_LUN_PEER_SC_PRIMARY; else lun->flags &= ~CTL_LUN_PEER_SC_PRIMARY; if (oflags != lun->flags) ctl_est_ua_all(lun, -1, CTL_UA_ASYM_ACC_CHANGE); /* If peer is primary and we are not -- use data */ if ((lun->flags & CTL_LUN_PRIMARY_SC) == 0 && (lun->flags & CTL_LUN_PEER_SC_PRIMARY)) { lun->pr_generation = msg->lun.pr_generation; lun->pr_res_idx = msg->lun.pr_res_idx; lun->pr_res_type = msg->lun.pr_res_type; lun->pr_key_count = msg->lun.pr_key_count; for (k = 0; k < CTL_MAX_INITIATORS; k++) ctl_clr_prkey(lun, k); for (k = 0; k < msg->lun.pr_key_count; k++) { memcpy(&pr_key, &msg->lun.data[i], sizeof(pr_key)); ctl_alloc_prkey(lun, pr_key.pr_iid); ctl_set_prkey(lun, pr_key.pr_iid, pr_key.pr_key); i += sizeof(pr_key); } } mtx_unlock(&lun->lun_lock); CTL_DEBUG_PRINT(("%s: Known LUN %d, peer is %s\n", __func__, targ_lun, (msg->lun.flags & CTL_LUN_PRIMARY_SC) ? "primary" : "secondary")); /* If we are primary but peer doesn't know -- notify */ if ((lun->flags & CTL_LUN_PRIMARY_SC) && (msg->lun.flags & CTL_LUN_PEER_SC_PRIMARY) == 0) ctl_isc_announce_lun(lun); } } static void ctl_isc_port_sync(struct ctl_softc *softc, union ctl_ha_msg *msg, int len) { struct ctl_port *port; struct ctl_lun *lun; int i, new; port = softc->ctl_ports[msg->hdr.nexus.targ_port]; if (port == NULL) { CTL_DEBUG_PRINT(("%s: New port %d\n", __func__, msg->hdr.nexus.targ_port)); new = 1; port = malloc(sizeof(*port), M_CTL, M_WAITOK | M_ZERO); port->frontend = &ha_frontend; port->targ_port = msg->hdr.nexus.targ_port; port->fe_datamove = ctl_ha_datamove; port->fe_done = ctl_ha_done; } else if (port->frontend == &ha_frontend) { CTL_DEBUG_PRINT(("%s: Updated port %d\n", __func__, msg->hdr.nexus.targ_port)); new = 0; } else { printf("%s: Received conflicting HA port %d\n", __func__, msg->hdr.nexus.targ_port); return; } port->port_type = msg->port.port_type; port->physical_port = msg->port.physical_port; port->virtual_port = msg->port.virtual_port; port->status = msg->port.status; i = 0; free(port->port_name, M_CTL); port->port_name = strndup(&msg->port.data[i], msg->port.name_len, M_CTL); i += msg->port.name_len; if (msg->port.lun_map_len != 0) { if (port->lun_map == NULL || port->lun_map_size * sizeof(uint32_t) < msg->port.lun_map_len) { port->lun_map_size = 0; free(port->lun_map, M_CTL); port->lun_map = malloc(msg->port.lun_map_len, M_CTL, M_WAITOK); } memcpy(port->lun_map, &msg->port.data[i], msg->port.lun_map_len); port->lun_map_size = msg->port.lun_map_len / sizeof(uint32_t); i += msg->port.lun_map_len; } else { port->lun_map_size = 0; free(port->lun_map, M_CTL); port->lun_map = NULL; } if (msg->port.port_devid_len != 0) { if (port->port_devid == NULL || port->port_devid->len < msg->port.port_devid_len) { free(port->port_devid, M_CTL); port->port_devid = malloc(sizeof(struct ctl_devid) + msg->port.port_devid_len, M_CTL, M_WAITOK); } memcpy(port->port_devid->data, &msg->port.data[i], msg->port.port_devid_len); port->port_devid->len = msg->port.port_devid_len; i += msg->port.port_devid_len; } else { free(port->port_devid, M_CTL); port->port_devid = NULL; } if (msg->port.target_devid_len != 0) { if (port->target_devid == NULL || port->target_devid->len < msg->port.target_devid_len) { free(port->target_devid, M_CTL); port->target_devid = malloc(sizeof(struct ctl_devid) + msg->port.target_devid_len, M_CTL, M_WAITOK); } memcpy(port->target_devid->data, &msg->port.data[i], msg->port.target_devid_len); port->target_devid->len = msg->port.target_devid_len; i += msg->port.target_devid_len; } else { free(port->target_devid, M_CTL); port->target_devid = NULL; } if (msg->port.init_devid_len != 0) { if (port->init_devid == NULL || port->init_devid->len < msg->port.init_devid_len) { free(port->init_devid, M_CTL); port->init_devid = malloc(sizeof(struct ctl_devid) + msg->port.init_devid_len, M_CTL, M_WAITOK); } memcpy(port->init_devid->data, &msg->port.data[i], msg->port.init_devid_len); port->init_devid->len = msg->port.init_devid_len; i += msg->port.init_devid_len; } else { free(port->init_devid, M_CTL); port->init_devid = NULL; } if (new) { if (ctl_port_register(port) != 0) { printf("%s: ctl_port_register() failed with error\n", __func__); } } mtx_lock(&softc->ctl_lock); STAILQ_FOREACH(lun, &softc->lun_list, links) { if (ctl_lun_map_to_port(port, lun->lun) == UINT32_MAX) continue; mtx_lock(&lun->lun_lock); ctl_est_ua_all(lun, -1, CTL_UA_INQ_CHANGE); mtx_unlock(&lun->lun_lock); } mtx_unlock(&softc->ctl_lock); } static void ctl_isc_iid_sync(struct ctl_softc *softc, union ctl_ha_msg *msg, int len) { struct ctl_port *port; int iid; port = softc->ctl_ports[msg->hdr.nexus.targ_port]; if (port == NULL) { printf("%s: Received IID for unknown port %d\n", __func__, msg->hdr.nexus.targ_port); return; } iid = msg->hdr.nexus.initid; if (port->wwpn_iid[iid].in_use != 0 && msg->iid.in_use == 0) ctl_i_t_nexus_loss(softc, iid, CTL_UA_POWERON); port->wwpn_iid[iid].in_use = msg->iid.in_use; port->wwpn_iid[iid].wwpn = msg->iid.wwpn; free(port->wwpn_iid[iid].name, M_CTL); if (msg->iid.name_len) { port->wwpn_iid[iid].name = strndup(&msg->iid.data[0], msg->iid.name_len, M_CTL); } else port->wwpn_iid[iid].name = NULL; } static void ctl_isc_login(struct ctl_softc *softc, union ctl_ha_msg *msg, int len) { if (msg->login.version != CTL_HA_VERSION) { printf("CTL HA peers have different versions %d != %d\n", msg->login.version, CTL_HA_VERSION); ctl_ha_msg_abort(CTL_HA_CHAN_CTL); return; } if (msg->login.ha_mode != softc->ha_mode) { printf("CTL HA peers have different ha_mode %d != %d\n", msg->login.ha_mode, softc->ha_mode); ctl_ha_msg_abort(CTL_HA_CHAN_CTL); return; } if (msg->login.ha_id == softc->ha_id) { printf("CTL HA peers have same ha_id %d\n", msg->login.ha_id); ctl_ha_msg_abort(CTL_HA_CHAN_CTL); return; } if (msg->login.max_luns != ctl_max_luns || msg->login.max_ports != ctl_max_ports || msg->login.max_init_per_port != CTL_MAX_INIT_PER_PORT) { printf("CTL HA peers have different limits\n"); ctl_ha_msg_abort(CTL_HA_CHAN_CTL); return; } } static void ctl_isc_mode_sync(struct ctl_softc *softc, union ctl_ha_msg *msg, int len) { struct ctl_lun *lun; u_int i; uint32_t initidx, targ_lun; targ_lun = msg->hdr.nexus.targ_mapped_lun; mtx_lock(&softc->ctl_lock); if (targ_lun >= ctl_max_luns || (lun = softc->ctl_luns[targ_lun]) == NULL) { mtx_unlock(&softc->ctl_lock); return; } mtx_lock(&lun->lun_lock); mtx_unlock(&softc->ctl_lock); if (lun->flags & CTL_LUN_DISABLED) { mtx_unlock(&lun->lun_lock); return; } for (i = 0; i < CTL_NUM_MODE_PAGES; i++) { if ((lun->mode_pages.index[i].page_code & SMPH_PC_MASK) == msg->mode.page_code && lun->mode_pages.index[i].subpage == msg->mode.subpage) break; } if (i == CTL_NUM_MODE_PAGES) { mtx_unlock(&lun->lun_lock); return; } memcpy(lun->mode_pages.index[i].page_data, msg->mode.data, lun->mode_pages.index[i].page_len); initidx = ctl_get_initindex(&msg->hdr.nexus); if (initidx != -1) ctl_est_ua_all(lun, initidx, CTL_UA_MODE_CHANGE); mtx_unlock(&lun->lun_lock); } /* * ISC (Inter Shelf Communication) event handler. Events from the HA * subsystem come in here. */ static void ctl_isc_event_handler(ctl_ha_channel channel, ctl_ha_event event, int param) { struct ctl_softc *softc = control_softc; union ctl_io *io; struct ctl_prio *presio; ctl_ha_status isc_status; CTL_DEBUG_PRINT(("CTL: Isc Msg event %d\n", event)); if (event == CTL_HA_EVT_MSG_RECV) { union ctl_ha_msg *msg, msgbuf; if (param > sizeof(msgbuf)) msg = malloc(param, M_CTL, M_WAITOK); else msg = &msgbuf; isc_status = ctl_ha_msg_recv(CTL_HA_CHAN_CTL, msg, param, M_WAITOK); if (isc_status != CTL_HA_STATUS_SUCCESS) { printf("%s: Error receiving message: %d\n", __func__, isc_status); if (msg != &msgbuf) free(msg, M_CTL); return; } CTL_DEBUG_PRINT(("CTL: msg_type %d\n", msg->hdr.msg_type)); switch (msg->hdr.msg_type) { case CTL_MSG_SERIALIZE: io = ctl_alloc_io(softc->othersc_pool); ctl_zero_io(io); // populate ctsio from msg io->io_hdr.io_type = CTL_IO_SCSI; io->io_hdr.msg_type = CTL_MSG_SERIALIZE; io->io_hdr.remote_io = msg->hdr.original_sc; io->io_hdr.flags |= CTL_FLAG_FROM_OTHER_SC | CTL_FLAG_IO_ACTIVE; /* * If we're in serialization-only mode, we don't * want to go through full done processing. Thus * the COPY flag. * * XXX KDM add another flag that is more specific. */ if (softc->ha_mode != CTL_HA_MODE_XFER) io->io_hdr.flags |= CTL_FLAG_INT_COPY; io->io_hdr.nexus = msg->hdr.nexus; io->scsiio.priority = msg->scsi.priority; io->scsiio.tag_num = msg->scsi.tag_num; io->scsiio.tag_type = msg->scsi.tag_type; #ifdef CTL_TIME_IO io->io_hdr.start_time = time_uptime; getbinuptime(&io->io_hdr.start_bt); #endif /* CTL_TIME_IO */ io->scsiio.cdb_len = msg->scsi.cdb_len; memcpy(io->scsiio.cdb, msg->scsi.cdb, CTL_MAX_CDBLEN); if (softc->ha_mode == CTL_HA_MODE_XFER) { const struct ctl_cmd_entry *entry; entry = ctl_get_cmd_entry(&io->scsiio, NULL); io->io_hdr.flags &= ~CTL_FLAG_DATA_MASK; io->io_hdr.flags |= entry->flags & CTL_FLAG_DATA_MASK; } ctl_enqueue_isc(io); break; /* Performed on the Originating SC, XFER mode only */ case CTL_MSG_DATAMOVE: { struct ctl_sg_entry *sgl; int i, j; io = msg->hdr.original_sc; if (io == NULL) { printf("%s: original_sc == NULL!\n", __func__); /* XXX KDM do something here */ break; } io->io_hdr.msg_type = CTL_MSG_DATAMOVE; io->io_hdr.flags |= CTL_FLAG_IO_ACTIVE; /* * Keep track of this, we need to send it back over * when the datamove is complete. */ io->io_hdr.remote_io = msg->hdr.serializing_sc; if (msg->hdr.status == CTL_SUCCESS) io->io_hdr.status = msg->hdr.status; if (msg->dt.sg_sequence == 0) { #ifdef CTL_TIME_IO getbinuptime(&io->io_hdr.dma_start_bt); #endif i = msg->dt.kern_sg_entries + msg->dt.kern_data_len / CTL_HA_DATAMOVE_SEGMENT + 1; sgl = malloc(sizeof(*sgl) * i, M_CTL, M_WAITOK | M_ZERO); CTL_RSGL(io) = sgl; CTL_LSGL(io) = &sgl[msg->dt.kern_sg_entries]; io->scsiio.kern_data_ptr = (uint8_t *)sgl; io->scsiio.kern_sg_entries = msg->dt.kern_sg_entries; io->scsiio.rem_sg_entries = msg->dt.kern_sg_entries; io->scsiio.kern_data_len = msg->dt.kern_data_len; io->scsiio.kern_total_len = msg->dt.kern_total_len; io->scsiio.kern_data_resid = msg->dt.kern_data_resid; io->scsiio.kern_rel_offset = msg->dt.kern_rel_offset; io->io_hdr.flags &= ~CTL_FLAG_BUS_ADDR; io->io_hdr.flags |= msg->dt.flags & CTL_FLAG_BUS_ADDR; } else sgl = (struct ctl_sg_entry *) io->scsiio.kern_data_ptr; for (i = msg->dt.sent_sg_entries, j = 0; i < (msg->dt.sent_sg_entries + msg->dt.cur_sg_entries); i++, j++) { sgl[i].addr = msg->dt.sg_list[j].addr; sgl[i].len = msg->dt.sg_list[j].len; } /* * If this is the last piece of the I/O, we've got * the full S/G list. Queue processing in the thread. * Otherwise wait for the next piece. */ if (msg->dt.sg_last != 0) ctl_enqueue_isc(io); break; } /* Performed on the Serializing (primary) SC, XFER mode only */ case CTL_MSG_DATAMOVE_DONE: { if (msg->hdr.serializing_sc == NULL) { printf("%s: serializing_sc == NULL!\n", __func__); /* XXX KDM now what? */ break; } /* * We grab the sense information here in case * there was a failure, so we can return status * back to the initiator. */ io = msg->hdr.serializing_sc; io->io_hdr.msg_type = CTL_MSG_DATAMOVE_DONE; io->io_hdr.flags &= ~CTL_FLAG_DMA_INPROG; io->io_hdr.flags |= CTL_FLAG_IO_ACTIVE; io->io_hdr.port_status = msg->scsi.port_status; io->scsiio.kern_data_resid = msg->scsi.kern_data_resid; if (msg->hdr.status != CTL_STATUS_NONE) { io->io_hdr.status = msg->hdr.status; io->scsiio.scsi_status = msg->scsi.scsi_status; io->scsiio.sense_len = msg->scsi.sense_len; memcpy(&io->scsiio.sense_data, &msg->scsi.sense_data, msg->scsi.sense_len); if (msg->hdr.status == CTL_SUCCESS) io->io_hdr.flags |= CTL_FLAG_STATUS_SENT; } ctl_enqueue_isc(io); break; } /* Preformed on Originating SC, SER_ONLY mode */ case CTL_MSG_R2R: io = msg->hdr.original_sc; if (io == NULL) { printf("%s: original_sc == NULL!\n", __func__); break; } io->io_hdr.flags |= CTL_FLAG_IO_ACTIVE; io->io_hdr.msg_type = CTL_MSG_R2R; io->io_hdr.remote_io = msg->hdr.serializing_sc; ctl_enqueue_isc(io); break; /* * Performed on Serializing(i.e. primary SC) SC in SER_ONLY * mode. * Performed on the Originating (i.e. secondary) SC in XFER * mode */ case CTL_MSG_FINISH_IO: if (softc->ha_mode == CTL_HA_MODE_XFER) ctl_isc_handler_finish_xfer(softc, msg); else ctl_isc_handler_finish_ser_only(softc, msg); break; /* Preformed on Originating SC */ case CTL_MSG_BAD_JUJU: io = msg->hdr.original_sc; if (io == NULL) { printf("%s: Bad JUJU!, original_sc is NULL!\n", __func__); break; } ctl_copy_sense_data(msg, io); /* * IO should have already been cleaned up on other * SC so clear this flag so we won't send a message * back to finish the IO there. */ io->io_hdr.flags &= ~CTL_FLAG_SENT_2OTHER_SC; io->io_hdr.flags |= CTL_FLAG_IO_ACTIVE; /* io = msg->hdr.serializing_sc; */ io->io_hdr.msg_type = CTL_MSG_BAD_JUJU; ctl_enqueue_isc(io); break; /* Handle resets sent from the other side */ case CTL_MSG_MANAGE_TASKS: { struct ctl_taskio *taskio; taskio = (struct ctl_taskio *)ctl_alloc_io( softc->othersc_pool); ctl_zero_io((union ctl_io *)taskio); taskio->io_hdr.io_type = CTL_IO_TASK; taskio->io_hdr.flags |= CTL_FLAG_FROM_OTHER_SC; taskio->io_hdr.nexus = msg->hdr.nexus; taskio->task_action = msg->task.task_action; taskio->tag_num = msg->task.tag_num; taskio->tag_type = msg->task.tag_type; #ifdef CTL_TIME_IO taskio->io_hdr.start_time = time_uptime; getbinuptime(&taskio->io_hdr.start_bt); #endif /* CTL_TIME_IO */ ctl_run_task((union ctl_io *)taskio); break; } /* Persistent Reserve action which needs attention */ case CTL_MSG_PERS_ACTION: presio = (struct ctl_prio *)ctl_alloc_io( softc->othersc_pool); ctl_zero_io((union ctl_io *)presio); presio->io_hdr.msg_type = CTL_MSG_PERS_ACTION; presio->io_hdr.flags |= CTL_FLAG_FROM_OTHER_SC; presio->io_hdr.nexus = msg->hdr.nexus; presio->pr_msg = msg->pr; ctl_enqueue_isc((union ctl_io *)presio); break; case CTL_MSG_UA: ctl_isc_ua(softc, msg, param); break; case CTL_MSG_PORT_SYNC: ctl_isc_port_sync(softc, msg, param); break; case CTL_MSG_LUN_SYNC: ctl_isc_lun_sync(softc, msg, param); break; case CTL_MSG_IID_SYNC: ctl_isc_iid_sync(softc, msg, param); break; case CTL_MSG_LOGIN: ctl_isc_login(softc, msg, param); break; case CTL_MSG_MODE_SYNC: ctl_isc_mode_sync(softc, msg, param); break; default: printf("Received HA message of unknown type %d\n", msg->hdr.msg_type); ctl_ha_msg_abort(CTL_HA_CHAN_CTL); break; } if (msg != &msgbuf) free(msg, M_CTL); } else if (event == CTL_HA_EVT_LINK_CHANGE) { printf("CTL: HA link status changed from %d to %d\n", softc->ha_link, param); if (param == softc->ha_link) return; if (softc->ha_link == CTL_HA_LINK_ONLINE) { softc->ha_link = param; ctl_isc_ha_link_down(softc); } else { softc->ha_link = param; if (softc->ha_link == CTL_HA_LINK_ONLINE) ctl_isc_ha_link_up(softc); } return; } else { printf("ctl_isc_event_handler: Unknown event %d\n", event); return; } } static void ctl_copy_sense_data(union ctl_ha_msg *src, union ctl_io *dest) { memcpy(&dest->scsiio.sense_data, &src->scsi.sense_data, src->scsi.sense_len); dest->scsiio.scsi_status = src->scsi.scsi_status; dest->scsiio.sense_len = src->scsi.sense_len; dest->io_hdr.status = src->hdr.status; } static void ctl_copy_sense_data_back(union ctl_io *src, union ctl_ha_msg *dest) { memcpy(&dest->scsi.sense_data, &src->scsiio.sense_data, src->scsiio.sense_len); dest->scsi.scsi_status = src->scsiio.scsi_status; dest->scsi.sense_len = src->scsiio.sense_len; dest->hdr.status = src->io_hdr.status; } void ctl_est_ua(struct ctl_lun *lun, uint32_t initidx, ctl_ua_type ua) { struct ctl_softc *softc = lun->ctl_softc; ctl_ua_type *pu; if (initidx < softc->init_min || initidx >= softc->init_max) return; mtx_assert(&lun->lun_lock, MA_OWNED); pu = lun->pending_ua[initidx / CTL_MAX_INIT_PER_PORT]; if (pu == NULL) return; pu[initidx % CTL_MAX_INIT_PER_PORT] |= ua; } void ctl_est_ua_port(struct ctl_lun *lun, int port, uint32_t except, ctl_ua_type ua) { int i; mtx_assert(&lun->lun_lock, MA_OWNED); if (lun->pending_ua[port] == NULL) return; for (i = 0; i < CTL_MAX_INIT_PER_PORT; i++) { if (port * CTL_MAX_INIT_PER_PORT + i == except) continue; lun->pending_ua[port][i] |= ua; } } void ctl_est_ua_all(struct ctl_lun *lun, uint32_t except, ctl_ua_type ua) { struct ctl_softc *softc = lun->ctl_softc; int i; mtx_assert(&lun->lun_lock, MA_OWNED); for (i = softc->port_min; i < softc->port_max; i++) ctl_est_ua_port(lun, i, except, ua); } void ctl_clr_ua(struct ctl_lun *lun, uint32_t initidx, ctl_ua_type ua) { struct ctl_softc *softc = lun->ctl_softc; ctl_ua_type *pu; if (initidx < softc->init_min || initidx >= softc->init_max) return; mtx_assert(&lun->lun_lock, MA_OWNED); pu = lun->pending_ua[initidx / CTL_MAX_INIT_PER_PORT]; if (pu == NULL) return; pu[initidx % CTL_MAX_INIT_PER_PORT] &= ~ua; } void ctl_clr_ua_all(struct ctl_lun *lun, uint32_t except, ctl_ua_type ua) { struct ctl_softc *softc = lun->ctl_softc; int i, j; mtx_assert(&lun->lun_lock, MA_OWNED); for (i = softc->port_min; i < softc->port_max; i++) { if (lun->pending_ua[i] == NULL) continue; for (j = 0; j < CTL_MAX_INIT_PER_PORT; j++) { if (i * CTL_MAX_INIT_PER_PORT + j == except) continue; lun->pending_ua[i][j] &= ~ua; } } } void ctl_clr_ua_allluns(struct ctl_softc *ctl_softc, uint32_t initidx, ctl_ua_type ua_type) { struct ctl_lun *lun; mtx_assert(&ctl_softc->ctl_lock, MA_OWNED); STAILQ_FOREACH(lun, &ctl_softc->lun_list, links) { mtx_lock(&lun->lun_lock); ctl_clr_ua(lun, initidx, ua_type); mtx_unlock(&lun->lun_lock); } } static int ctl_ha_role_sysctl(SYSCTL_HANDLER_ARGS) { struct ctl_softc *softc = (struct ctl_softc *)arg1; struct ctl_lun *lun; struct ctl_lun_req ireq; int error, value; value = (softc->flags & CTL_FLAG_ACTIVE_SHELF) ? 0 : 1; error = sysctl_handle_int(oidp, &value, 0, req); if ((error != 0) || (req->newptr == NULL)) return (error); mtx_lock(&softc->ctl_lock); if (value == 0) softc->flags |= CTL_FLAG_ACTIVE_SHELF; else softc->flags &= ~CTL_FLAG_ACTIVE_SHELF; STAILQ_FOREACH(lun, &softc->lun_list, links) { mtx_unlock(&softc->ctl_lock); bzero(&ireq, sizeof(ireq)); ireq.reqtype = CTL_LUNREQ_MODIFY; ireq.reqdata.modify.lun_id = lun->lun; lun->backend->ioctl(NULL, CTL_LUN_REQ, (caddr_t)&ireq, 0, curthread); if (ireq.status != CTL_LUN_OK) { printf("%s: CTL_LUNREQ_MODIFY returned %d '%s'\n", __func__, ireq.status, ireq.error_str); } mtx_lock(&softc->ctl_lock); } mtx_unlock(&softc->ctl_lock); return (0); } static int ctl_init(void) { struct make_dev_args args; struct ctl_softc *softc; int i, error; softc = control_softc = malloc(sizeof(*control_softc), M_DEVBUF, M_WAITOK | M_ZERO); make_dev_args_init(&args); args.mda_devsw = &ctl_cdevsw; args.mda_uid = UID_ROOT; args.mda_gid = GID_OPERATOR; args.mda_mode = 0600; args.mda_si_drv1 = softc; args.mda_si_drv2 = NULL; error = make_dev_s(&args, &softc->dev, "cam/ctl"); if (error != 0) { free(softc, M_DEVBUF); control_softc = NULL; return (error); } sysctl_ctx_init(&softc->sysctl_ctx); softc->sysctl_tree = SYSCTL_ADD_NODE(&softc->sysctl_ctx, SYSCTL_STATIC_CHILDREN(_kern_cam), OID_AUTO, "ctl", CTLFLAG_RD | CTLFLAG_MPSAFE, 0, "CAM Target Layer"); if (softc->sysctl_tree == NULL) { printf("%s: unable to allocate sysctl tree\n", __func__); destroy_dev(softc->dev); free(softc, M_DEVBUF); control_softc = NULL; return (ENOMEM); } mtx_init(&softc->ctl_lock, "CTL mutex", NULL, MTX_DEF); softc->io_zone = uma_zcreate("CTL IO", sizeof(union ctl_io), NULL, NULL, NULL, NULL, UMA_ALIGN_PTR, 0); softc->flags = 0; SYSCTL_ADD_INT(&softc->sysctl_ctx, SYSCTL_CHILDREN(softc->sysctl_tree), OID_AUTO, "ha_mode", CTLFLAG_RDTUN, (int *)&softc->ha_mode, 0, "HA mode (0 - act/stby, 1 - serialize only, 2 - xfer)"); if (ctl_max_luns <= 0 || powerof2(ctl_max_luns) == 0) { printf("Bad value %d for kern.cam.ctl.max_luns, must be a power of two, using %d\n", ctl_max_luns, CTL_DEFAULT_MAX_LUNS); ctl_max_luns = CTL_DEFAULT_MAX_LUNS; } softc->ctl_luns = malloc(sizeof(struct ctl_lun *) * ctl_max_luns, M_DEVBUF, M_WAITOK | M_ZERO); softc->ctl_lun_mask = malloc(sizeof(uint32_t) * ((ctl_max_luns + 31) / 32), M_DEVBUF, M_WAITOK | M_ZERO); if (ctl_max_ports <= 0 || powerof2(ctl_max_ports) == 0) { printf("Bad value %d for kern.cam.ctl.max_ports, must be a power of two, using %d\n", ctl_max_ports, CTL_DEFAULT_MAX_PORTS); ctl_max_ports = CTL_DEFAULT_MAX_PORTS; } softc->ctl_port_mask = malloc(sizeof(uint32_t) * ((ctl_max_ports + 31) / 32), M_DEVBUF, M_WAITOK | M_ZERO); softc->ctl_ports = malloc(sizeof(struct ctl_port *) * ctl_max_ports, M_DEVBUF, M_WAITOK | M_ZERO); /* * In Copan's HA scheme, the "master" and "slave" roles are * figured out through the slot the controller is in. Although it * is an active/active system, someone has to be in charge. */ SYSCTL_ADD_INT(&softc->sysctl_ctx, SYSCTL_CHILDREN(softc->sysctl_tree), OID_AUTO, "ha_id", CTLFLAG_RDTUN, &softc->ha_id, 0, "HA head ID (0 - no HA)"); if (softc->ha_id == 0 || softc->ha_id > NUM_HA_SHELVES) { softc->flags |= CTL_FLAG_ACTIVE_SHELF; softc->is_single = 1; softc->port_cnt = ctl_max_ports; softc->port_min = 0; } else { softc->port_cnt = ctl_max_ports / NUM_HA_SHELVES; softc->port_min = (softc->ha_id - 1) * softc->port_cnt; } softc->port_max = softc->port_min + softc->port_cnt; softc->init_min = softc->port_min * CTL_MAX_INIT_PER_PORT; softc->init_max = softc->port_max * CTL_MAX_INIT_PER_PORT; SYSCTL_ADD_INT(&softc->sysctl_ctx, SYSCTL_CHILDREN(softc->sysctl_tree), OID_AUTO, "ha_link", CTLFLAG_RD, (int *)&softc->ha_link, 0, "HA link state (0 - offline, 1 - unknown, 2 - online)"); STAILQ_INIT(&softc->lun_list); STAILQ_INIT(&softc->fe_list); STAILQ_INIT(&softc->port_list); STAILQ_INIT(&softc->be_list); ctl_tpc_init(softc); if (worker_threads <= 0) worker_threads = max(1, mp_ncpus / 4); if (worker_threads > CTL_MAX_THREADS) worker_threads = CTL_MAX_THREADS; for (i = 0; i < worker_threads; i++) { struct ctl_thread *thr = &softc->threads[i]; mtx_init(&thr->queue_lock, "CTL queue mutex", NULL, MTX_DEF); thr->ctl_softc = softc; STAILQ_INIT(&thr->incoming_queue); STAILQ_INIT(&thr->rtr_queue); STAILQ_INIT(&thr->done_queue); STAILQ_INIT(&thr->isc_queue); error = kproc_kthread_add(ctl_work_thread, thr, &softc->ctl_proc, &thr->thread, 0, 0, "ctl", "work%d", i); if (error != 0) { printf("error creating CTL work thread!\n"); return (error); } } error = kproc_kthread_add(ctl_thresh_thread, softc, &softc->ctl_proc, &softc->thresh_thread, 0, 0, "ctl", "thresh"); if (error != 0) { printf("error creating CTL threshold thread!\n"); return (error); } SYSCTL_ADD_PROC(&softc->sysctl_ctx,SYSCTL_CHILDREN(softc->sysctl_tree), OID_AUTO, "ha_role", CTLTYPE_INT | CTLFLAG_RWTUN | CTLFLAG_NEEDGIANT, softc, 0, ctl_ha_role_sysctl, "I", "HA role for this head"); if (softc->is_single == 0) { if (ctl_frontend_register(&ha_frontend) != 0) softc->is_single = 1; } return (0); } static int ctl_shutdown(void) { struct ctl_softc *softc = control_softc; int i; if (softc->is_single == 0) ctl_frontend_deregister(&ha_frontend); destroy_dev(softc->dev); /* Shutdown CTL threads. */ softc->shutdown = 1; for (i = 0; i < worker_threads; i++) { struct ctl_thread *thr = &softc->threads[i]; while (thr->thread != NULL) { wakeup(thr); if (thr->thread != NULL) pause("CTL thr shutdown", 1); } mtx_destroy(&thr->queue_lock); } while (softc->thresh_thread != NULL) { wakeup(softc->thresh_thread); if (softc->thresh_thread != NULL) pause("CTL thr shutdown", 1); } ctl_tpc_shutdown(softc); uma_zdestroy(softc->io_zone); mtx_destroy(&softc->ctl_lock); free(softc->ctl_luns, M_DEVBUF); free(softc->ctl_lun_mask, M_DEVBUF); free(softc->ctl_port_mask, M_DEVBUF); free(softc->ctl_ports, M_DEVBUF); sysctl_ctx_free(&softc->sysctl_ctx); free(softc, M_DEVBUF); control_softc = NULL; return (0); } static int ctl_module_event_handler(module_t mod, int what, void *arg) { switch (what) { case MOD_LOAD: return (ctl_init()); case MOD_UNLOAD: return (ctl_shutdown()); default: return (EOPNOTSUPP); } } /* * XXX KDM should we do some access checks here? Bump a reference count to * prevent a CTL module from being unloaded while someone has it open? */ static int ctl_open(struct cdev *dev, int flags, int fmt, struct thread *td) { return (0); } static int ctl_close(struct cdev *dev, int flags, int fmt, struct thread *td) { return (0); } /* * Remove an initiator by port number and initiator ID. * Returns 0 for success, -1 for failure. */ int ctl_remove_initiator(struct ctl_port *port, int iid) { struct ctl_softc *softc = port->ctl_softc; int last; mtx_assert(&softc->ctl_lock, MA_NOTOWNED); if (iid > CTL_MAX_INIT_PER_PORT) { printf("%s: initiator ID %u > maximun %u!\n", __func__, iid, CTL_MAX_INIT_PER_PORT); return (-1); } mtx_lock(&softc->ctl_lock); last = (--port->wwpn_iid[iid].in_use == 0); port->wwpn_iid[iid].last_use = time_uptime; mtx_unlock(&softc->ctl_lock); if (last) ctl_i_t_nexus_loss(softc, iid, CTL_UA_POWERON); ctl_isc_announce_iid(port, iid); return (0); } /* * Add an initiator to the initiator map. * Returns iid for success, < 0 for failure. */ int ctl_add_initiator(struct ctl_port *port, int iid, uint64_t wwpn, char *name) { struct ctl_softc *softc = port->ctl_softc; time_t best_time; int i, best; mtx_assert(&softc->ctl_lock, MA_NOTOWNED); if (iid >= CTL_MAX_INIT_PER_PORT) { printf("%s: WWPN %#jx initiator ID %u > maximum %u!\n", __func__, wwpn, iid, CTL_MAX_INIT_PER_PORT); free(name, M_CTL); return (-1); } mtx_lock(&softc->ctl_lock); if (iid < 0 && (wwpn != 0 || name != NULL)) { for (i = 0; i < CTL_MAX_INIT_PER_PORT; i++) { if (wwpn != 0 && wwpn == port->wwpn_iid[i].wwpn) { iid = i; break; } if (name != NULL && port->wwpn_iid[i].name != NULL && strcmp(name, port->wwpn_iid[i].name) == 0) { iid = i; break; } } } if (iid < 0) { for (i = 0; i < CTL_MAX_INIT_PER_PORT; i++) { if (port->wwpn_iid[i].in_use == 0 && port->wwpn_iid[i].wwpn == 0 && port->wwpn_iid[i].name == NULL) { iid = i; break; } } } if (iid < 0) { best = -1; best_time = INT32_MAX; for (i = 0; i < CTL_MAX_INIT_PER_PORT; i++) { if (port->wwpn_iid[i].in_use == 0) { if (port->wwpn_iid[i].last_use < best_time) { best = i; best_time = port->wwpn_iid[i].last_use; } } } iid = best; } if (iid < 0) { mtx_unlock(&softc->ctl_lock); free(name, M_CTL); return (-2); } if (port->wwpn_iid[iid].in_use > 0 && (wwpn != 0 || name != NULL)) { /* * This is not an error yet. */ if (wwpn != 0 && wwpn == port->wwpn_iid[iid].wwpn) { #if 0 printf("%s: port %d iid %u WWPN %#jx arrived" " again\n", __func__, port->targ_port, iid, (uintmax_t)wwpn); #endif goto take; } if (name != NULL && port->wwpn_iid[iid].name != NULL && strcmp(name, port->wwpn_iid[iid].name) == 0) { #if 0 printf("%s: port %d iid %u name '%s' arrived" " again\n", __func__, port->targ_port, iid, name); #endif goto take; } /* * This is an error, but what do we do about it? The * driver is telling us we have a new WWPN for this * initiator ID, so we pretty much need to use it. */ printf("%s: port %d iid %u WWPN %#jx '%s' arrived," " but WWPN %#jx '%s' is still at that address\n", __func__, port->targ_port, iid, wwpn, name, (uintmax_t)port->wwpn_iid[iid].wwpn, port->wwpn_iid[iid].name); } take: free(port->wwpn_iid[iid].name, M_CTL); port->wwpn_iid[iid].name = name; port->wwpn_iid[iid].wwpn = wwpn; port->wwpn_iid[iid].in_use++; mtx_unlock(&softc->ctl_lock); ctl_isc_announce_iid(port, iid); return (iid); } static int ctl_create_iid(struct ctl_port *port, int iid, uint8_t *buf) { int len; switch (port->port_type) { case CTL_PORT_FC: { struct scsi_transportid_fcp *id = (struct scsi_transportid_fcp *)buf; if (port->wwpn_iid[iid].wwpn == 0) return (0); memset(id, 0, sizeof(*id)); id->format_protocol = SCSI_PROTO_FC; scsi_u64to8b(port->wwpn_iid[iid].wwpn, id->n_port_name); return (sizeof(*id)); } case CTL_PORT_ISCSI: { struct scsi_transportid_iscsi_port *id = (struct scsi_transportid_iscsi_port *)buf; if (port->wwpn_iid[iid].name == NULL) return (0); memset(id, 0, 256); id->format_protocol = SCSI_TRN_ISCSI_FORMAT_PORT | SCSI_PROTO_ISCSI; len = strlcpy(id->iscsi_name, port->wwpn_iid[iid].name, 252) + 1; len = roundup2(min(len, 252), 4); scsi_ulto2b(len, id->additional_length); return (sizeof(*id) + len); } case CTL_PORT_SAS: { struct scsi_transportid_sas *id = (struct scsi_transportid_sas *)buf; if (port->wwpn_iid[iid].wwpn == 0) return (0); memset(id, 0, sizeof(*id)); id->format_protocol = SCSI_PROTO_SAS; scsi_u64to8b(port->wwpn_iid[iid].wwpn, id->sas_address); return (sizeof(*id)); } default: { struct scsi_transportid_spi *id = (struct scsi_transportid_spi *)buf; memset(id, 0, sizeof(*id)); id->format_protocol = SCSI_PROTO_SPI; scsi_ulto2b(iid, id->scsi_addr); scsi_ulto2b(port->targ_port, id->rel_trgt_port_id); return (sizeof(*id)); } } } /* * Serialize a command that went down the "wrong" side, and so was sent to * this controller for execution. The logic is a little different than the * standard case in ctl_scsiio_precheck(). Errors in this case need to get * sent back to the other side, but in the success case, we execute the * command on this side (XFER mode) or tell the other side to execute it * (SER_ONLY mode). */ static void ctl_serialize_other_sc_cmd(struct ctl_scsiio *ctsio) { struct ctl_softc *softc = CTL_SOFTC(ctsio); struct ctl_port *port = CTL_PORT(ctsio); union ctl_ha_msg msg_info; struct ctl_lun *lun; const struct ctl_cmd_entry *entry; union ctl_io *bio; uint32_t targ_lun; targ_lun = ctsio->io_hdr.nexus.targ_mapped_lun; /* Make sure that we know about this port. */ if (port == NULL || (port->status & CTL_PORT_STATUS_ONLINE) == 0) { ctl_set_internal_failure(ctsio, /*sks_valid*/ 0, /*retry_count*/ 1); goto badjuju; } /* Make sure that we know about this LUN. */ mtx_lock(&softc->ctl_lock); if (targ_lun >= ctl_max_luns || (lun = softc->ctl_luns[targ_lun]) == NULL) { mtx_unlock(&softc->ctl_lock); /* * The other node would not send this request to us unless * received announce that we are primary node for this LUN. * If this LUN does not exist now, it is probably result of * a race, so respond to initiator in the most opaque way. */ ctl_set_busy(ctsio); goto badjuju; } mtx_lock(&lun->lun_lock); mtx_unlock(&softc->ctl_lock); /* * If the LUN is invalid, pretend that it doesn't exist. * It will go away as soon as all pending I/Os completed. */ if (lun->flags & CTL_LUN_DISABLED) { mtx_unlock(&lun->lun_lock); ctl_set_busy(ctsio); goto badjuju; } entry = ctl_get_cmd_entry(ctsio, NULL); if (ctl_scsiio_lun_check(lun, entry, ctsio) != 0) { mtx_unlock(&lun->lun_lock); goto badjuju; } CTL_LUN(ctsio) = lun; CTL_BACKEND_LUN(ctsio) = lun->be_lun; /* * Every I/O goes into the OOA queue for a * particular LUN, and stays there until completion. */ #ifdef CTL_TIME_IO if (TAILQ_EMPTY(&lun->ooa_queue)) lun->idle_time += getsbinuptime() - lun->last_busy; #endif TAILQ_INSERT_TAIL(&lun->ooa_queue, &ctsio->io_hdr, ooa_links); bio = (union ctl_io *)TAILQ_PREV(&ctsio->io_hdr, ctl_ooaq, ooa_links); switch (ctl_check_ooa(lun, (union ctl_io *)ctsio, &bio)) { case CTL_ACTION_BLOCK: ctsio->io_hdr.blocker = bio; TAILQ_INSERT_TAIL(&bio->io_hdr.blocked_queue, &ctsio->io_hdr, blocked_links); mtx_unlock(&lun->lun_lock); break; case CTL_ACTION_PASS: case CTL_ACTION_SKIP: if (softc->ha_mode == CTL_HA_MODE_XFER) { ctsio->io_hdr.flags |= CTL_FLAG_IS_WAS_ON_RTR; ctl_enqueue_rtr((union ctl_io *)ctsio); mtx_unlock(&lun->lun_lock); } else { ctsio->io_hdr.flags &= ~CTL_FLAG_IO_ACTIVE; mtx_unlock(&lun->lun_lock); /* send msg back to other side */ msg_info.hdr.original_sc = ctsio->io_hdr.remote_io; msg_info.hdr.serializing_sc = (union ctl_io *)ctsio; msg_info.hdr.msg_type = CTL_MSG_R2R; ctl_ha_msg_send(CTL_HA_CHAN_CTL, &msg_info, sizeof(msg_info.hdr), M_WAITOK); } break; case CTL_ACTION_OVERLAP: TAILQ_REMOVE(&lun->ooa_queue, &ctsio->io_hdr, ooa_links); mtx_unlock(&lun->lun_lock); ctl_set_overlapped_cmd(ctsio); goto badjuju; case CTL_ACTION_OVERLAP_TAG: TAILQ_REMOVE(&lun->ooa_queue, &ctsio->io_hdr, ooa_links); mtx_unlock(&lun->lun_lock); ctl_set_overlapped_tag(ctsio, ctsio->tag_num); goto badjuju; case CTL_ACTION_ERROR: default: TAILQ_REMOVE(&lun->ooa_queue, &ctsio->io_hdr, ooa_links); mtx_unlock(&lun->lun_lock); ctl_set_internal_failure(ctsio, /*sks_valid*/ 0, /*retry_count*/ 0); badjuju: ctl_copy_sense_data_back((union ctl_io *)ctsio, &msg_info); msg_info.hdr.original_sc = ctsio->io_hdr.remote_io; msg_info.hdr.serializing_sc = NULL; msg_info.hdr.msg_type = CTL_MSG_BAD_JUJU; ctl_ha_msg_send(CTL_HA_CHAN_CTL, &msg_info, sizeof(msg_info.scsi), M_WAITOK); ctl_free_io((union ctl_io *)ctsio); break; } } /* * Returns 0 for success, errno for failure. */ static void ctl_ioctl_fill_ooa(struct ctl_lun *lun, uint32_t *cur_fill_num, struct ctl_ooa *ooa_hdr, struct ctl_ooa_entry *kern_entries) { union ctl_io *io; mtx_lock(&lun->lun_lock); for (io = (union ctl_io *)TAILQ_FIRST(&lun->ooa_queue); (io != NULL); (*cur_fill_num)++, io = (union ctl_io *)TAILQ_NEXT(&io->io_hdr, ooa_links)) { struct ctl_ooa_entry *entry; /* * If we've got more than we can fit, just count the * remaining entries. */ if (*cur_fill_num >= ooa_hdr->alloc_num) continue; entry = &kern_entries[*cur_fill_num]; entry->tag_num = io->scsiio.tag_num; entry->lun_num = lun->lun; #ifdef CTL_TIME_IO entry->start_bt = io->io_hdr.start_bt; #endif bcopy(io->scsiio.cdb, entry->cdb, io->scsiio.cdb_len); entry->cdb_len = io->scsiio.cdb_len; if (io->io_hdr.blocker != NULL) entry->cmd_flags |= CTL_OOACMD_FLAG_BLOCKED; if (io->io_hdr.flags & CTL_FLAG_DMA_INPROG) entry->cmd_flags |= CTL_OOACMD_FLAG_DMA; if (io->io_hdr.flags & CTL_FLAG_ABORT) entry->cmd_flags |= CTL_OOACMD_FLAG_ABORT; if (io->io_hdr.flags & CTL_FLAG_IS_WAS_ON_RTR) entry->cmd_flags |= CTL_OOACMD_FLAG_RTR; if (io->io_hdr.flags & CTL_FLAG_DMA_QUEUED) entry->cmd_flags |= CTL_OOACMD_FLAG_DMA_QUEUED; if (io->io_hdr.flags & CTL_FLAG_STATUS_QUEUED) entry->cmd_flags |= CTL_OOACMD_FLAG_STATUS_QUEUED; if (io->io_hdr.flags & CTL_FLAG_STATUS_SENT) entry->cmd_flags |= CTL_OOACMD_FLAG_STATUS_SENT; } mtx_unlock(&lun->lun_lock); } /* * Escape characters that are illegal or not recommended in XML. */ int ctl_sbuf_printf_esc(struct sbuf *sb, char *str, int size) { char *end = str + size; int retval; retval = 0; for (; *str && str < end; str++) { switch (*str) { case '&': retval = sbuf_printf(sb, "&"); break; case '>': retval = sbuf_printf(sb, ">"); break; case '<': retval = sbuf_printf(sb, "<"); break; default: retval = sbuf_putc(sb, *str); break; } if (retval != 0) break; } return (retval); } static void ctl_id_sbuf(struct ctl_devid *id, struct sbuf *sb) { struct scsi_vpd_id_descriptor *desc; int i; if (id == NULL || id->len < 4) return; desc = (struct scsi_vpd_id_descriptor *)id->data; switch (desc->id_type & SVPD_ID_TYPE_MASK) { case SVPD_ID_TYPE_T10: sbuf_printf(sb, "t10."); break; case SVPD_ID_TYPE_EUI64: sbuf_printf(sb, "eui."); break; case SVPD_ID_TYPE_NAA: sbuf_printf(sb, "naa."); break; case SVPD_ID_TYPE_SCSI_NAME: break; } switch (desc->proto_codeset & SVPD_ID_CODESET_MASK) { case SVPD_ID_CODESET_BINARY: for (i = 0; i < desc->length; i++) sbuf_printf(sb, "%02x", desc->identifier[i]); break; case SVPD_ID_CODESET_ASCII: sbuf_printf(sb, "%.*s", (int)desc->length, (char *)desc->identifier); break; case SVPD_ID_CODESET_UTF8: sbuf_printf(sb, "%s", (char *)desc->identifier); break; } } static int ctl_ioctl(struct cdev *dev, u_long cmd, caddr_t addr, int flag, struct thread *td) { struct ctl_softc *softc = dev->si_drv1; struct ctl_port *port; struct ctl_lun *lun; int retval; retval = 0; switch (cmd) { case CTL_IO: retval = ctl_ioctl_io(dev, cmd, addr, flag, td); break; case CTL_ENABLE_PORT: case CTL_DISABLE_PORT: case CTL_SET_PORT_WWNS: { struct ctl_port *port; struct ctl_port_entry *entry; entry = (struct ctl_port_entry *)addr; mtx_lock(&softc->ctl_lock); STAILQ_FOREACH(port, &softc->port_list, links) { int action, done; if (port->targ_port < softc->port_min || port->targ_port >= softc->port_max) continue; action = 0; done = 0; if ((entry->port_type == CTL_PORT_NONE) && (entry->targ_port == port->targ_port)) { /* * If the user only wants to enable or * disable or set WWNs on a specific port, * do the operation and we're done. */ action = 1; done = 1; } else if (entry->port_type & port->port_type) { /* * Compare the user's type mask with the * particular frontend type to see if we * have a match. */ action = 1; done = 0; /* * Make sure the user isn't trying to set * WWNs on multiple ports at the same time. */ if (cmd == CTL_SET_PORT_WWNS) { printf("%s: Can't set WWNs on " "multiple ports\n", __func__); retval = EINVAL; break; } } if (action == 0) continue; /* * XXX KDM we have to drop the lock here, because * the online/offline operations can potentially * block. We need to reference count the frontends * so they can't go away, */ if (cmd == CTL_ENABLE_PORT) { mtx_unlock(&softc->ctl_lock); ctl_port_online(port); mtx_lock(&softc->ctl_lock); } else if (cmd == CTL_DISABLE_PORT) { mtx_unlock(&softc->ctl_lock); ctl_port_offline(port); mtx_lock(&softc->ctl_lock); } else if (cmd == CTL_SET_PORT_WWNS) { ctl_port_set_wwns(port, (entry->flags & CTL_PORT_WWNN_VALID) ? 1 : 0, entry->wwnn, (entry->flags & CTL_PORT_WWPN_VALID) ? 1 : 0, entry->wwpn); } if (done != 0) break; } mtx_unlock(&softc->ctl_lock); break; } case CTL_GET_OOA: { struct ctl_ooa *ooa_hdr; struct ctl_ooa_entry *entries; uint32_t cur_fill_num; ooa_hdr = (struct ctl_ooa *)addr; if ((ooa_hdr->alloc_len == 0) || (ooa_hdr->alloc_num == 0)) { printf("%s: CTL_GET_OOA: alloc len %u and alloc num %u " "must be non-zero\n", __func__, ooa_hdr->alloc_len, ooa_hdr->alloc_num); retval = EINVAL; break; } if (ooa_hdr->alloc_len != (ooa_hdr->alloc_num * sizeof(struct ctl_ooa_entry))) { printf("%s: CTL_GET_OOA: alloc len %u must be alloc " "num %d * sizeof(struct ctl_ooa_entry) %zd\n", __func__, ooa_hdr->alloc_len, ooa_hdr->alloc_num,sizeof(struct ctl_ooa_entry)); retval = EINVAL; break; } entries = malloc(ooa_hdr->alloc_len, M_CTL, M_WAITOK | M_ZERO); if (entries == NULL) { printf("%s: could not allocate %d bytes for OOA " "dump\n", __func__, ooa_hdr->alloc_len); retval = ENOMEM; break; } mtx_lock(&softc->ctl_lock); if ((ooa_hdr->flags & CTL_OOA_FLAG_ALL_LUNS) == 0 && (ooa_hdr->lun_num >= ctl_max_luns || softc->ctl_luns[ooa_hdr->lun_num] == NULL)) { mtx_unlock(&softc->ctl_lock); free(entries, M_CTL); printf("%s: CTL_GET_OOA: invalid LUN %ju\n", __func__, (uintmax_t)ooa_hdr->lun_num); retval = EINVAL; break; } cur_fill_num = 0; if (ooa_hdr->flags & CTL_OOA_FLAG_ALL_LUNS) { STAILQ_FOREACH(lun, &softc->lun_list, links) { ctl_ioctl_fill_ooa(lun, &cur_fill_num, ooa_hdr, entries); } } else { lun = softc->ctl_luns[ooa_hdr->lun_num]; ctl_ioctl_fill_ooa(lun, &cur_fill_num, ooa_hdr, entries); } mtx_unlock(&softc->ctl_lock); ooa_hdr->fill_num = min(cur_fill_num, ooa_hdr->alloc_num); ooa_hdr->fill_len = ooa_hdr->fill_num * sizeof(struct ctl_ooa_entry); retval = copyout(entries, ooa_hdr->entries, ooa_hdr->fill_len); if (retval != 0) { printf("%s: error copying out %d bytes for OOA dump\n", __func__, ooa_hdr->fill_len); } getbinuptime(&ooa_hdr->cur_bt); if (cur_fill_num > ooa_hdr->alloc_num) { ooa_hdr->dropped_num = cur_fill_num -ooa_hdr->alloc_num; ooa_hdr->status = CTL_OOA_NEED_MORE_SPACE; } else { ooa_hdr->dropped_num = 0; ooa_hdr->status = CTL_OOA_OK; } free(entries, M_CTL); break; } case CTL_DELAY_IO: { struct ctl_io_delay_info *delay_info; delay_info = (struct ctl_io_delay_info *)addr; #ifdef CTL_IO_DELAY mtx_lock(&softc->ctl_lock); if (delay_info->lun_id >= ctl_max_luns || (lun = softc->ctl_luns[delay_info->lun_id]) == NULL) { mtx_unlock(&softc->ctl_lock); delay_info->status = CTL_DELAY_STATUS_INVALID_LUN; break; } mtx_lock(&lun->lun_lock); mtx_unlock(&softc->ctl_lock); delay_info->status = CTL_DELAY_STATUS_OK; switch (delay_info->delay_type) { case CTL_DELAY_TYPE_CONT: case CTL_DELAY_TYPE_ONESHOT: break; default: delay_info->status = CTL_DELAY_STATUS_INVALID_TYPE; break; } switch (delay_info->delay_loc) { case CTL_DELAY_LOC_DATAMOVE: lun->delay_info.datamove_type = delay_info->delay_type; lun->delay_info.datamove_delay = delay_info->delay_secs; break; case CTL_DELAY_LOC_DONE: lun->delay_info.done_type = delay_info->delay_type; lun->delay_info.done_delay = delay_info->delay_secs; break; default: delay_info->status = CTL_DELAY_STATUS_INVALID_LOC; break; } mtx_unlock(&lun->lun_lock); #else delay_info->status = CTL_DELAY_STATUS_NOT_IMPLEMENTED; #endif /* CTL_IO_DELAY */ break; } case CTL_ERROR_INJECT: { struct ctl_error_desc *err_desc, *new_err_desc; err_desc = (struct ctl_error_desc *)addr; new_err_desc = malloc(sizeof(*new_err_desc), M_CTL, M_WAITOK | M_ZERO); bcopy(err_desc, new_err_desc, sizeof(*new_err_desc)); mtx_lock(&softc->ctl_lock); if (err_desc->lun_id >= ctl_max_luns || (lun = softc->ctl_luns[err_desc->lun_id]) == NULL) { mtx_unlock(&softc->ctl_lock); free(new_err_desc, M_CTL); printf("%s: CTL_ERROR_INJECT: invalid LUN %ju\n", __func__, (uintmax_t)err_desc->lun_id); retval = EINVAL; break; } mtx_lock(&lun->lun_lock); mtx_unlock(&softc->ctl_lock); /* * We could do some checking here to verify the validity * of the request, but given the complexity of error * injection requests, the checking logic would be fairly * complex. * * For now, if the request is invalid, it just won't get * executed and might get deleted. */ STAILQ_INSERT_TAIL(&lun->error_list, new_err_desc, links); /* * XXX KDM check to make sure the serial number is unique, * in case we somehow manage to wrap. That shouldn't * happen for a very long time, but it's the right thing to * do. */ new_err_desc->serial = lun->error_serial; err_desc->serial = lun->error_serial; lun->error_serial++; mtx_unlock(&lun->lun_lock); break; } case CTL_ERROR_INJECT_DELETE: { struct ctl_error_desc *delete_desc, *desc, *desc2; int delete_done; delete_desc = (struct ctl_error_desc *)addr; delete_done = 0; mtx_lock(&softc->ctl_lock); if (delete_desc->lun_id >= ctl_max_luns || (lun = softc->ctl_luns[delete_desc->lun_id]) == NULL) { mtx_unlock(&softc->ctl_lock); printf("%s: CTL_ERROR_INJECT_DELETE: invalid LUN %ju\n", __func__, (uintmax_t)delete_desc->lun_id); retval = EINVAL; break; } mtx_lock(&lun->lun_lock); mtx_unlock(&softc->ctl_lock); STAILQ_FOREACH_SAFE(desc, &lun->error_list, links, desc2) { if (desc->serial != delete_desc->serial) continue; STAILQ_REMOVE(&lun->error_list, desc, ctl_error_desc, links); free(desc, M_CTL); delete_done = 1; } mtx_unlock(&lun->lun_lock); if (delete_done == 0) { printf("%s: CTL_ERROR_INJECT_DELETE: can't find " "error serial %ju on LUN %u\n", __func__, delete_desc->serial, delete_desc->lun_id); retval = EINVAL; break; } break; } case CTL_DUMP_STRUCTS: { int j, k; struct ctl_port *port; struct ctl_frontend *fe; mtx_lock(&softc->ctl_lock); printf("CTL Persistent Reservation information start:\n"); STAILQ_FOREACH(lun, &softc->lun_list, links) { mtx_lock(&lun->lun_lock); if ((lun->flags & CTL_LUN_DISABLED) != 0) { mtx_unlock(&lun->lun_lock); continue; } for (j = 0; j < ctl_max_ports; j++) { if (lun->pr_keys[j] == NULL) continue; for (k = 0; k < CTL_MAX_INIT_PER_PORT; k++){ if (lun->pr_keys[j][k] == 0) continue; printf(" LUN %ju port %d iid %d key " "%#jx\n", lun->lun, j, k, (uintmax_t)lun->pr_keys[j][k]); } } mtx_unlock(&lun->lun_lock); } printf("CTL Persistent Reservation information end\n"); printf("CTL Ports:\n"); STAILQ_FOREACH(port, &softc->port_list, links) { printf(" Port %d '%s' Frontend '%s' Type %u pp %d vp %d WWNN " "%#jx WWPN %#jx\n", port->targ_port, port->port_name, port->frontend->name, port->port_type, port->physical_port, port->virtual_port, (uintmax_t)port->wwnn, (uintmax_t)port->wwpn); for (j = 0; j < CTL_MAX_INIT_PER_PORT; j++) { if (port->wwpn_iid[j].in_use == 0 && port->wwpn_iid[j].wwpn == 0 && port->wwpn_iid[j].name == NULL) continue; printf(" iid %u use %d WWPN %#jx '%s'\n", j, port->wwpn_iid[j].in_use, (uintmax_t)port->wwpn_iid[j].wwpn, port->wwpn_iid[j].name); } } printf("CTL Port information end\n"); mtx_unlock(&softc->ctl_lock); /* * XXX KDM calling this without a lock. We'd likely want * to drop the lock before calling the frontend's dump * routine anyway. */ printf("CTL Frontends:\n"); STAILQ_FOREACH(fe, &softc->fe_list, links) { printf(" Frontend '%s'\n", fe->name); if (fe->fe_dump != NULL) fe->fe_dump(); } printf("CTL Frontend information end\n"); break; } case CTL_LUN_REQ: { struct ctl_lun_req *lun_req; struct ctl_backend_driver *backend; void *packed; nvlist_t *tmp_args_nvl; size_t packed_len; lun_req = (struct ctl_lun_req *)addr; tmp_args_nvl = lun_req->args_nvl; backend = ctl_backend_find(lun_req->backend); if (backend == NULL) { lun_req->status = CTL_LUN_ERROR; snprintf(lun_req->error_str, sizeof(lun_req->error_str), "Backend \"%s\" not found.", lun_req->backend); break; } if (lun_req->args != NULL) { packed = malloc(lun_req->args_len, M_CTL, M_WAITOK); if (copyin(lun_req->args, packed, lun_req->args_len) != 0) { free(packed, M_CTL); lun_req->status = CTL_LUN_ERROR; snprintf(lun_req->error_str, sizeof(lun_req->error_str), "Cannot copyin args."); break; } lun_req->args_nvl = nvlist_unpack(packed, lun_req->args_len, 0); free(packed, M_CTL); if (lun_req->args_nvl == NULL) { lun_req->status = CTL_LUN_ERROR; snprintf(lun_req->error_str, sizeof(lun_req->error_str), "Cannot unpack args nvlist."); break; } } else lun_req->args_nvl = nvlist_create(0); retval = backend->ioctl(dev, cmd, addr, flag, td); nvlist_destroy(lun_req->args_nvl); lun_req->args_nvl = tmp_args_nvl; if (lun_req->result_nvl != NULL) { if (lun_req->result != NULL) { packed = nvlist_pack(lun_req->result_nvl, &packed_len); if (packed == NULL) { lun_req->status = CTL_LUN_ERROR; snprintf(lun_req->error_str, sizeof(lun_req->error_str), "Cannot pack result nvlist."); break; } if (packed_len > lun_req->result_len) { lun_req->status = CTL_LUN_ERROR; snprintf(lun_req->error_str, sizeof(lun_req->error_str), "Result nvlist too large."); free(packed, M_NVLIST); break; } if (copyout(packed, lun_req->result, packed_len)) { lun_req->status = CTL_LUN_ERROR; snprintf(lun_req->error_str, sizeof(lun_req->error_str), "Cannot copyout() the result."); free(packed, M_NVLIST); break; } lun_req->result_len = packed_len; free(packed, M_NVLIST); } nvlist_destroy(lun_req->result_nvl); } break; } case CTL_LUN_LIST: { struct sbuf *sb; struct ctl_lun_list *list; const char *name, *value; void *cookie; int type; list = (struct ctl_lun_list *)addr; /* * Allocate a fixed length sbuf here, based on the length * of the user's buffer. We could allocate an auto-extending * buffer, and then tell the user how much larger our * amount of data is than his buffer, but that presents * some problems: * * 1. The sbuf(9) routines use a blocking malloc, and so * we can't hold a lock while calling them with an * auto-extending buffer. * * 2. There is not currently a LUN reference counting * mechanism, outside of outstanding transactions on * the LUN's OOA queue. So a LUN could go away on us * while we're getting the LUN number, backend-specific * information, etc. Thus, given the way things * currently work, we need to hold the CTL lock while * grabbing LUN information. * * So, from the user's standpoint, the best thing to do is * allocate what he thinks is a reasonable buffer length, * and then if he gets a CTL_LUN_LIST_NEED_MORE_SPACE error, * double the buffer length and try again. (And repeat * that until he succeeds.) */ sb = sbuf_new(NULL, NULL, list->alloc_len, SBUF_FIXEDLEN); if (sb == NULL) { list->status = CTL_LUN_LIST_ERROR; snprintf(list->error_str, sizeof(list->error_str), "Unable to allocate %d bytes for LUN list", list->alloc_len); break; } sbuf_printf(sb, "\n"); mtx_lock(&softc->ctl_lock); STAILQ_FOREACH(lun, &softc->lun_list, links) { mtx_lock(&lun->lun_lock); retval = sbuf_printf(sb, "\n", (uintmax_t)lun->lun); /* * Bail out as soon as we see that we've overfilled * the buffer. */ if (retval != 0) break; retval = sbuf_printf(sb, "\t%s" "\n", (lun->backend == NULL) ? "none" : lun->backend->name); if (retval != 0) break; retval = sbuf_printf(sb, "\t%d\n", lun->be_lun->lun_type); if (retval != 0) break; if (lun->backend == NULL) { retval = sbuf_printf(sb, "\n"); if (retval != 0) break; continue; } retval = sbuf_printf(sb, "\t%ju\n", (lun->be_lun->maxlba > 0) ? lun->be_lun->maxlba + 1 : 0); if (retval != 0) break; retval = sbuf_printf(sb, "\t%u\n", lun->be_lun->blocksize); if (retval != 0) break; retval = sbuf_printf(sb, "\t"); if (retval != 0) break; retval = ctl_sbuf_printf_esc(sb, lun->be_lun->serial_num, sizeof(lun->be_lun->serial_num)); if (retval != 0) break; retval = sbuf_printf(sb, "\n"); if (retval != 0) break; retval = sbuf_printf(sb, "\t"); if (retval != 0) break; retval = ctl_sbuf_printf_esc(sb, lun->be_lun->device_id, sizeof(lun->be_lun->device_id)); if (retval != 0) break; retval = sbuf_printf(sb, "\n"); if (retval != 0) break; if (lun->backend->lun_info != NULL) { retval = lun->backend->lun_info(lun->be_lun, sb); if (retval != 0) break; } cookie = NULL; while ((name = nvlist_next(lun->be_lun->options, &type, &cookie)) != NULL) { sbuf_printf(sb, "\t<%s>", name); if (type == NV_TYPE_STRING) { value = dnvlist_get_string( lun->be_lun->options, name, NULL); if (value != NULL) sbuf_printf(sb, "%s", value); } sbuf_printf(sb, "\n", name); } retval = sbuf_printf(sb, "\n"); if (retval != 0) break; mtx_unlock(&lun->lun_lock); } if (lun != NULL) mtx_unlock(&lun->lun_lock); mtx_unlock(&softc->ctl_lock); if ((retval != 0) || ((retval = sbuf_printf(sb, "\n")) != 0)) { retval = 0; sbuf_delete(sb); list->status = CTL_LUN_LIST_NEED_MORE_SPACE; snprintf(list->error_str, sizeof(list->error_str), "Out of space, %d bytes is too small", list->alloc_len); break; } sbuf_finish(sb); retval = copyout(sbuf_data(sb), list->lun_xml, sbuf_len(sb) + 1); list->fill_len = sbuf_len(sb) + 1; list->status = CTL_LUN_LIST_OK; sbuf_delete(sb); break; } case CTL_ISCSI: { struct ctl_iscsi *ci; struct ctl_frontend *fe; ci = (struct ctl_iscsi *)addr; fe = ctl_frontend_find("iscsi"); if (fe == NULL) { ci->status = CTL_ISCSI_ERROR; snprintf(ci->error_str, sizeof(ci->error_str), "Frontend \"iscsi\" not found."); break; } retval = fe->ioctl(dev, cmd, addr, flag, td); break; } case CTL_PORT_REQ: { struct ctl_req *req; struct ctl_frontend *fe; void *packed; nvlist_t *tmp_args_nvl; size_t packed_len; req = (struct ctl_req *)addr; tmp_args_nvl = req->args_nvl; fe = ctl_frontend_find(req->driver); if (fe == NULL) { req->status = CTL_LUN_ERROR; snprintf(req->error_str, sizeof(req->error_str), "Frontend \"%s\" not found.", req->driver); break; } if (req->args != NULL) { packed = malloc(req->args_len, M_CTL, M_WAITOK); if (copyin(req->args, packed, req->args_len) != 0) { free(packed, M_CTL); req->status = CTL_LUN_ERROR; snprintf(req->error_str, sizeof(req->error_str), "Cannot copyin args."); break; } req->args_nvl = nvlist_unpack(packed, req->args_len, 0); free(packed, M_CTL); if (req->args_nvl == NULL) { req->status = CTL_LUN_ERROR; snprintf(req->error_str, sizeof(req->error_str), "Cannot unpack args nvlist."); break; } } else req->args_nvl = nvlist_create(0); if (fe->ioctl) retval = fe->ioctl(dev, cmd, addr, flag, td); else retval = ENODEV; nvlist_destroy(req->args_nvl); req->args_nvl = tmp_args_nvl; if (req->result_nvl != NULL) { if (req->result != NULL) { packed = nvlist_pack(req->result_nvl, &packed_len); if (packed == NULL) { req->status = CTL_LUN_ERROR; snprintf(req->error_str, sizeof(req->error_str), "Cannot pack result nvlist."); break; } if (packed_len > req->result_len) { req->status = CTL_LUN_ERROR; snprintf(req->error_str, sizeof(req->error_str), "Result nvlist too large."); free(packed, M_NVLIST); break; } if (copyout(packed, req->result, packed_len)) { req->status = CTL_LUN_ERROR; snprintf(req->error_str, sizeof(req->error_str), "Cannot copyout() the result."); free(packed, M_NVLIST); break; } req->result_len = packed_len; free(packed, M_NVLIST); } nvlist_destroy(req->result_nvl); } break; } case CTL_PORT_LIST: { struct sbuf *sb; struct ctl_port *port; struct ctl_lun_list *list; const char *name, *value; void *cookie; int j, type; uint32_t plun; list = (struct ctl_lun_list *)addr; sb = sbuf_new(NULL, NULL, list->alloc_len, SBUF_FIXEDLEN); if (sb == NULL) { list->status = CTL_LUN_LIST_ERROR; snprintf(list->error_str, sizeof(list->error_str), "Unable to allocate %d bytes for LUN list", list->alloc_len); break; } sbuf_printf(sb, "\n"); mtx_lock(&softc->ctl_lock); STAILQ_FOREACH(port, &softc->port_list, links) { retval = sbuf_printf(sb, "\n", (uintmax_t)port->targ_port); /* * Bail out as soon as we see that we've overfilled * the buffer. */ if (retval != 0) break; retval = sbuf_printf(sb, "\t%s" "\n", port->frontend->name); if (retval != 0) break; retval = sbuf_printf(sb, "\t%d\n", port->port_type); if (retval != 0) break; retval = sbuf_printf(sb, "\t%s\n", (port->status & CTL_PORT_STATUS_ONLINE) ? "YES" : "NO"); if (retval != 0) break; retval = sbuf_printf(sb, "\t%s\n", port->port_name); if (retval != 0) break; retval = sbuf_printf(sb, "\t%d\n", port->physical_port); if (retval != 0) break; retval = sbuf_printf(sb, "\t%d\n", port->virtual_port); if (retval != 0) break; if (port->target_devid != NULL) { sbuf_printf(sb, "\t"); ctl_id_sbuf(port->target_devid, sb); sbuf_printf(sb, "\n"); } if (port->port_devid != NULL) { sbuf_printf(sb, "\t"); ctl_id_sbuf(port->port_devid, sb); sbuf_printf(sb, "\n"); } if (port->port_info != NULL) { retval = port->port_info(port->onoff_arg, sb); if (retval != 0) break; } cookie = NULL; while ((name = nvlist_next(port->options, &type, &cookie)) != NULL) { sbuf_printf(sb, "\t<%s>", name); if (type == NV_TYPE_STRING) { value = dnvlist_get_string(port->options, name, NULL); if (value != NULL) sbuf_printf(sb, "%s", value); } sbuf_printf(sb, "\n", name); } if (port->lun_map != NULL) { sbuf_printf(sb, "\ton\n"); for (j = 0; j < port->lun_map_size; j++) { plun = ctl_lun_map_from_port(port, j); if (plun == UINT32_MAX) continue; sbuf_printf(sb, "\t%u\n", j, plun); } } for (j = 0; j < CTL_MAX_INIT_PER_PORT; j++) { if (port->wwpn_iid[j].in_use == 0 || (port->wwpn_iid[j].wwpn == 0 && port->wwpn_iid[j].name == NULL)) continue; if (port->wwpn_iid[j].name != NULL) retval = sbuf_printf(sb, "\t%s\n", j, port->wwpn_iid[j].name); else retval = sbuf_printf(sb, "\tnaa.%08jx\n", j, port->wwpn_iid[j].wwpn); if (retval != 0) break; } if (retval != 0) break; retval = sbuf_printf(sb, "\n"); if (retval != 0) break; } mtx_unlock(&softc->ctl_lock); if ((retval != 0) || ((retval = sbuf_printf(sb, "\n")) != 0)) { retval = 0; sbuf_delete(sb); list->status = CTL_LUN_LIST_NEED_MORE_SPACE; snprintf(list->error_str, sizeof(list->error_str), "Out of space, %d bytes is too small", list->alloc_len); break; } sbuf_finish(sb); retval = copyout(sbuf_data(sb), list->lun_xml, sbuf_len(sb) + 1); list->fill_len = sbuf_len(sb) + 1; list->status = CTL_LUN_LIST_OK; sbuf_delete(sb); break; } case CTL_LUN_MAP: { struct ctl_lun_map *lm = (struct ctl_lun_map *)addr; struct ctl_port *port; mtx_lock(&softc->ctl_lock); if (lm->port < softc->port_min || lm->port >= softc->port_max || (port = softc->ctl_ports[lm->port]) == NULL) { mtx_unlock(&softc->ctl_lock); return (ENXIO); } if (port->status & CTL_PORT_STATUS_ONLINE) { STAILQ_FOREACH(lun, &softc->lun_list, links) { if (ctl_lun_map_to_port(port, lun->lun) == UINT32_MAX) continue; mtx_lock(&lun->lun_lock); ctl_est_ua_port(lun, lm->port, -1, CTL_UA_LUN_CHANGE); mtx_unlock(&lun->lun_lock); } } mtx_unlock(&softc->ctl_lock); // XXX: port_enable sleeps if (lm->plun != UINT32_MAX) { if (lm->lun == UINT32_MAX) retval = ctl_lun_map_unset(port, lm->plun); else if (lm->lun < ctl_max_luns && softc->ctl_luns[lm->lun] != NULL) retval = ctl_lun_map_set(port, lm->plun, lm->lun); else return (ENXIO); } else { if (lm->lun == UINT32_MAX) retval = ctl_lun_map_deinit(port); else retval = ctl_lun_map_init(port); } if (port->status & CTL_PORT_STATUS_ONLINE) ctl_isc_announce_port(port); break; } case CTL_GET_LUN_STATS: { struct ctl_get_io_stats *stats = (struct ctl_get_io_stats *)addr; int i; /* * XXX KDM no locking here. If the LUN list changes, * things can blow up. */ i = 0; stats->status = CTL_SS_OK; stats->fill_len = 0; STAILQ_FOREACH(lun, &softc->lun_list, links) { if (lun->lun < stats->first_item) continue; if (stats->fill_len + sizeof(lun->stats) > stats->alloc_len) { stats->status = CTL_SS_NEED_MORE_SPACE; break; } retval = copyout(&lun->stats, &stats->stats[i++], sizeof(lun->stats)); if (retval != 0) break; stats->fill_len += sizeof(lun->stats); } stats->num_items = softc->num_luns; stats->flags = CTL_STATS_FLAG_NONE; #ifdef CTL_TIME_IO stats->flags |= CTL_STATS_FLAG_TIME_VALID; #endif getnanouptime(&stats->timestamp); break; } case CTL_GET_PORT_STATS: { struct ctl_get_io_stats *stats = (struct ctl_get_io_stats *)addr; int i; /* * XXX KDM no locking here. If the LUN list changes, * things can blow up. */ i = 0; stats->status = CTL_SS_OK; stats->fill_len = 0; STAILQ_FOREACH(port, &softc->port_list, links) { if (port->targ_port < stats->first_item) continue; if (stats->fill_len + sizeof(port->stats) > stats->alloc_len) { stats->status = CTL_SS_NEED_MORE_SPACE; break; } retval = copyout(&port->stats, &stats->stats[i++], sizeof(port->stats)); if (retval != 0) break; stats->fill_len += sizeof(port->stats); } stats->num_items = softc->num_ports; stats->flags = CTL_STATS_FLAG_NONE; #ifdef CTL_TIME_IO stats->flags |= CTL_STATS_FLAG_TIME_VALID; #endif getnanouptime(&stats->timestamp); break; } default: { /* XXX KDM should we fix this? */ #if 0 struct ctl_backend_driver *backend; unsigned int type; int found; found = 0; /* * We encode the backend type as the ioctl type for backend * ioctls. So parse it out here, and then search for a * backend of this type. */ type = _IOC_TYPE(cmd); STAILQ_FOREACH(backend, &softc->be_list, links) { if (backend->type == type) { found = 1; break; } } if (found == 0) { printf("ctl: unknown ioctl command %#lx or backend " "%d\n", cmd, type); retval = EINVAL; break; } retval = backend->ioctl(dev, cmd, addr, flag, td); #endif retval = ENOTTY; break; } } return (retval); } uint32_t ctl_get_initindex(struct ctl_nexus *nexus) { return (nexus->initid + (nexus->targ_port * CTL_MAX_INIT_PER_PORT)); } int ctl_lun_map_init(struct ctl_port *port) { struct ctl_softc *softc = port->ctl_softc; struct ctl_lun *lun; int size = ctl_lun_map_size; uint32_t i; if (port->lun_map == NULL || port->lun_map_size < size) { port->lun_map_size = 0; free(port->lun_map, M_CTL); port->lun_map = malloc(size * sizeof(uint32_t), M_CTL, M_NOWAIT); } if (port->lun_map == NULL) return (ENOMEM); for (i = 0; i < size; i++) port->lun_map[i] = UINT32_MAX; port->lun_map_size = size; if (port->status & CTL_PORT_STATUS_ONLINE) { if (port->lun_disable != NULL) { STAILQ_FOREACH(lun, &softc->lun_list, links) port->lun_disable(port->targ_lun_arg, lun->lun); } ctl_isc_announce_port(port); } return (0); } int ctl_lun_map_deinit(struct ctl_port *port) { struct ctl_softc *softc = port->ctl_softc; struct ctl_lun *lun; if (port->lun_map == NULL) return (0); port->lun_map_size = 0; free(port->lun_map, M_CTL); port->lun_map = NULL; if (port->status & CTL_PORT_STATUS_ONLINE) { if (port->lun_enable != NULL) { STAILQ_FOREACH(lun, &softc->lun_list, links) port->lun_enable(port->targ_lun_arg, lun->lun); } ctl_isc_announce_port(port); } return (0); } int ctl_lun_map_set(struct ctl_port *port, uint32_t plun, uint32_t glun) { int status; uint32_t old; if (port->lun_map == NULL) { status = ctl_lun_map_init(port); if (status != 0) return (status); } if (plun >= port->lun_map_size) return (EINVAL); old = port->lun_map[plun]; port->lun_map[plun] = glun; if ((port->status & CTL_PORT_STATUS_ONLINE) && old == UINT32_MAX) { if (port->lun_enable != NULL) port->lun_enable(port->targ_lun_arg, plun); ctl_isc_announce_port(port); } return (0); } int ctl_lun_map_unset(struct ctl_port *port, uint32_t plun) { uint32_t old; if (port->lun_map == NULL || plun >= port->lun_map_size) return (0); old = port->lun_map[plun]; port->lun_map[plun] = UINT32_MAX; if ((port->status & CTL_PORT_STATUS_ONLINE) && old != UINT32_MAX) { if (port->lun_disable != NULL) port->lun_disable(port->targ_lun_arg, plun); ctl_isc_announce_port(port); } return (0); } uint32_t ctl_lun_map_from_port(struct ctl_port *port, uint32_t lun_id) { if (port == NULL) return (UINT32_MAX); if (port->lun_map == NULL) return (lun_id); if (lun_id > port->lun_map_size) return (UINT32_MAX); return (port->lun_map[lun_id]); } uint32_t ctl_lun_map_to_port(struct ctl_port *port, uint32_t lun_id) { uint32_t i; if (port == NULL) return (UINT32_MAX); if (port->lun_map == NULL) return (lun_id); for (i = 0; i < port->lun_map_size; i++) { if (port->lun_map[i] == lun_id) return (i); } return (UINT32_MAX); } uint32_t ctl_decode_lun(uint64_t encoded) { uint8_t lun[8]; uint32_t result = 0xffffffff; be64enc(lun, encoded); switch (lun[0] & RPL_LUNDATA_ATYP_MASK) { case RPL_LUNDATA_ATYP_PERIPH: if ((lun[0] & 0x3f) == 0 && lun[2] == 0 && lun[3] == 0 && lun[4] == 0 && lun[5] == 0 && lun[6] == 0 && lun[7] == 0) result = lun[1]; break; case RPL_LUNDATA_ATYP_FLAT: if (lun[2] == 0 && lun[3] == 0 && lun[4] == 0 && lun[5] == 0 && lun[6] == 0 && lun[7] == 0) result = ((lun[0] & 0x3f) << 8) + lun[1]; break; case RPL_LUNDATA_ATYP_EXTLUN: switch (lun[0] & RPL_LUNDATA_EXT_EAM_MASK) { case 0x02: switch (lun[0] & RPL_LUNDATA_EXT_LEN_MASK) { case 0x00: result = lun[1]; break; case 0x10: result = (lun[1] << 16) + (lun[2] << 8) + lun[3]; break; case 0x20: if (lun[1] == 0 && lun[6] == 0 && lun[7] == 0) result = (lun[2] << 24) + (lun[3] << 16) + (lun[4] << 8) + lun[5]; break; } break; case RPL_LUNDATA_EXT_EAM_NOT_SPEC: result = 0xffffffff; break; } break; } return (result); } uint64_t ctl_encode_lun(uint32_t decoded) { uint64_t l = decoded; if (l <= 0xff) return (((uint64_t)RPL_LUNDATA_ATYP_PERIPH << 56) | (l << 48)); if (l <= 0x3fff) return (((uint64_t)RPL_LUNDATA_ATYP_FLAT << 56) | (l << 48)); if (l <= 0xffffff) return (((uint64_t)(RPL_LUNDATA_ATYP_EXTLUN | 0x12) << 56) | (l << 32)); return ((((uint64_t)RPL_LUNDATA_ATYP_EXTLUN | 0x22) << 56) | (l << 16)); } int ctl_ffz(uint32_t *mask, uint32_t first, uint32_t last) { int i; for (i = first; i < last; i++) { if ((mask[i / 32] & (1 << (i % 32))) == 0) return (i); } return (-1); } int ctl_set_mask(uint32_t *mask, uint32_t bit) { uint32_t chunk, piece; chunk = bit >> 5; piece = bit % (sizeof(uint32_t) * 8); if ((mask[chunk] & (1 << piece)) != 0) return (-1); else mask[chunk] |= (1 << piece); return (0); } int ctl_clear_mask(uint32_t *mask, uint32_t bit) { uint32_t chunk, piece; chunk = bit >> 5; piece = bit % (sizeof(uint32_t) * 8); if ((mask[chunk] & (1 << piece)) == 0) return (-1); else mask[chunk] &= ~(1 << piece); return (0); } int ctl_is_set(uint32_t *mask, uint32_t bit) { uint32_t chunk, piece; chunk = bit >> 5; piece = bit % (sizeof(uint32_t) * 8); if ((mask[chunk] & (1 << piece)) == 0) return (0); else return (1); } static uint64_t ctl_get_prkey(struct ctl_lun *lun, uint32_t residx) { uint64_t *t; t = lun->pr_keys[residx/CTL_MAX_INIT_PER_PORT]; if (t == NULL) return (0); return (t[residx % CTL_MAX_INIT_PER_PORT]); } static void ctl_clr_prkey(struct ctl_lun *lun, uint32_t residx) { uint64_t *t; t = lun->pr_keys[residx/CTL_MAX_INIT_PER_PORT]; if (t == NULL) return; t[residx % CTL_MAX_INIT_PER_PORT] = 0; } static void ctl_alloc_prkey(struct ctl_lun *lun, uint32_t residx) { uint64_t *p; u_int i; i = residx/CTL_MAX_INIT_PER_PORT; if (lun->pr_keys[i] != NULL) return; mtx_unlock(&lun->lun_lock); p = malloc(sizeof(uint64_t) * CTL_MAX_INIT_PER_PORT, M_CTL, M_WAITOK | M_ZERO); mtx_lock(&lun->lun_lock); if (lun->pr_keys[i] == NULL) lun->pr_keys[i] = p; else free(p, M_CTL); } static void ctl_set_prkey(struct ctl_lun *lun, uint32_t residx, uint64_t key) { uint64_t *t; t = lun->pr_keys[residx/CTL_MAX_INIT_PER_PORT]; KASSERT(t != NULL, ("prkey %d is not allocated", residx)); t[residx % CTL_MAX_INIT_PER_PORT] = key; } /* * ctl_softc, pool_name, total_ctl_io are passed in. * npool is passed out. */ int ctl_pool_create(struct ctl_softc *ctl_softc, const char *pool_name, uint32_t total_ctl_io, void **npool) { struct ctl_io_pool *pool; pool = (struct ctl_io_pool *)malloc(sizeof(*pool), M_CTL, M_NOWAIT | M_ZERO); if (pool == NULL) return (ENOMEM); snprintf(pool->name, sizeof(pool->name), "CTL IO %s", pool_name); pool->ctl_softc = ctl_softc; #ifdef IO_POOLS pool->zone = uma_zsecond_create(pool->name, NULL, NULL, NULL, NULL, ctl_softc->io_zone); /* uma_prealloc(pool->zone, total_ctl_io); */ #else pool->zone = ctl_softc->io_zone; #endif *npool = pool; return (0); } void ctl_pool_free(struct ctl_io_pool *pool) { if (pool == NULL) return; #ifdef IO_POOLS uma_zdestroy(pool->zone); #endif free(pool, M_CTL); } union ctl_io * ctl_alloc_io(void *pool_ref) { struct ctl_io_pool *pool = (struct ctl_io_pool *)pool_ref; union ctl_io *io; io = uma_zalloc(pool->zone, M_WAITOK); if (io != NULL) { io->io_hdr.pool = pool_ref; CTL_SOFTC(io) = pool->ctl_softc; TAILQ_INIT(&io->io_hdr.blocked_queue); } return (io); } union ctl_io * ctl_alloc_io_nowait(void *pool_ref) { struct ctl_io_pool *pool = (struct ctl_io_pool *)pool_ref; union ctl_io *io; io = uma_zalloc(pool->zone, M_NOWAIT); if (io != NULL) { io->io_hdr.pool = pool_ref; CTL_SOFTC(io) = pool->ctl_softc; TAILQ_INIT(&io->io_hdr.blocked_queue); } return (io); } void ctl_free_io(union ctl_io *io) { struct ctl_io_pool *pool; if (io == NULL) return; pool = (struct ctl_io_pool *)io->io_hdr.pool; uma_zfree(pool->zone, io); } void ctl_zero_io(union ctl_io *io) { struct ctl_io_pool *pool; if (io == NULL) return; /* * May need to preserve linked list pointers at some point too. */ pool = io->io_hdr.pool; memset(io, 0, sizeof(*io)); io->io_hdr.pool = pool; CTL_SOFTC(io) = pool->ctl_softc; TAILQ_INIT(&io->io_hdr.blocked_queue); } int ctl_expand_number(const char *buf, uint64_t *num) { char *endptr; uint64_t number; unsigned shift; number = strtoq(buf, &endptr, 0); switch (tolower((unsigned char)*endptr)) { case 'e': shift = 60; break; case 'p': shift = 50; break; case 't': shift = 40; break; case 'g': shift = 30; break; case 'm': shift = 20; break; case 'k': shift = 10; break; case 'b': case '\0': /* No unit. */ *num = number; return (0); default: /* Unrecognized unit. */ return (-1); } if ((number << shift) >> shift != number) { /* Overflow */ return (-1); } *num = number << shift; return (0); } /* * This routine could be used in the future to load default and/or saved * mode page parameters for a particuar lun. */ static int ctl_init_page_index(struct ctl_lun *lun) { int i, page_code; struct ctl_page_index *page_index; const char *value; uint64_t ival; memcpy(&lun->mode_pages.index, page_index_template, sizeof(page_index_template)); for (i = 0; i < CTL_NUM_MODE_PAGES; i++) { page_index = &lun->mode_pages.index[i]; if (lun->be_lun->lun_type == T_DIRECT && (page_index->page_flags & CTL_PAGE_FLAG_DIRECT) == 0) continue; if (lun->be_lun->lun_type == T_PROCESSOR && (page_index->page_flags & CTL_PAGE_FLAG_PROC) == 0) continue; if (lun->be_lun->lun_type == T_CDROM && (page_index->page_flags & CTL_PAGE_FLAG_CDROM) == 0) continue; page_code = page_index->page_code & SMPH_PC_MASK; switch (page_code) { case SMS_RW_ERROR_RECOVERY_PAGE: { KASSERT(page_index->subpage == SMS_SUBPAGE_PAGE_0, ("subpage %#x for page %#x is incorrect!", page_index->subpage, page_code)); memcpy(&lun->mode_pages.rw_er_page[CTL_PAGE_CURRENT], &rw_er_page_default, sizeof(rw_er_page_default)); memcpy(&lun->mode_pages.rw_er_page[CTL_PAGE_CHANGEABLE], &rw_er_page_changeable, sizeof(rw_er_page_changeable)); memcpy(&lun->mode_pages.rw_er_page[CTL_PAGE_DEFAULT], &rw_er_page_default, sizeof(rw_er_page_default)); memcpy(&lun->mode_pages.rw_er_page[CTL_PAGE_SAVED], &rw_er_page_default, sizeof(rw_er_page_default)); page_index->page_data = (uint8_t *)lun->mode_pages.rw_er_page; break; } case SMS_FORMAT_DEVICE_PAGE: { struct scsi_format_page *format_page; KASSERT(page_index->subpage == SMS_SUBPAGE_PAGE_0, ("subpage %#x for page %#x is incorrect!", page_index->subpage, page_code)); /* * Sectors per track are set above. Bytes per * sector need to be set here on a per-LUN basis. */ memcpy(&lun->mode_pages.format_page[CTL_PAGE_CURRENT], &format_page_default, sizeof(format_page_default)); memcpy(&lun->mode_pages.format_page[ CTL_PAGE_CHANGEABLE], &format_page_changeable, sizeof(format_page_changeable)); memcpy(&lun->mode_pages.format_page[CTL_PAGE_DEFAULT], &format_page_default, sizeof(format_page_default)); memcpy(&lun->mode_pages.format_page[CTL_PAGE_SAVED], &format_page_default, sizeof(format_page_default)); format_page = &lun->mode_pages.format_page[ CTL_PAGE_CURRENT]; scsi_ulto2b(lun->be_lun->blocksize, format_page->bytes_per_sector); format_page = &lun->mode_pages.format_page[ CTL_PAGE_DEFAULT]; scsi_ulto2b(lun->be_lun->blocksize, format_page->bytes_per_sector); format_page = &lun->mode_pages.format_page[ CTL_PAGE_SAVED]; scsi_ulto2b(lun->be_lun->blocksize, format_page->bytes_per_sector); page_index->page_data = (uint8_t *)lun->mode_pages.format_page; break; } case SMS_RIGID_DISK_PAGE: { struct scsi_rigid_disk_page *rigid_disk_page; uint32_t sectors_per_cylinder; uint64_t cylinders; #ifndef __XSCALE__ int shift; #endif /* !__XSCALE__ */ KASSERT(page_index->subpage == SMS_SUBPAGE_PAGE_0, ("subpage %#x for page %#x is incorrect!", page_index->subpage, page_code)); /* * Rotation rate and sectors per track are set * above. We calculate the cylinders here based on * capacity. Due to the number of heads and * sectors per track we're using, smaller arrays * may turn out to have 0 cylinders. Linux and * FreeBSD don't pay attention to these mode pages * to figure out capacity, but Solaris does. It * seems to deal with 0 cylinders just fine, and * works out a fake geometry based on the capacity. */ memcpy(&lun->mode_pages.rigid_disk_page[ CTL_PAGE_DEFAULT], &rigid_disk_page_default, sizeof(rigid_disk_page_default)); memcpy(&lun->mode_pages.rigid_disk_page[ CTL_PAGE_CHANGEABLE],&rigid_disk_page_changeable, sizeof(rigid_disk_page_changeable)); sectors_per_cylinder = CTL_DEFAULT_SECTORS_PER_TRACK * CTL_DEFAULT_HEADS; /* * The divide method here will be more accurate, * probably, but results in floating point being * used in the kernel on i386 (__udivdi3()). On the * XScale, though, __udivdi3() is implemented in * software. * * The shift method for cylinder calculation is * accurate if sectors_per_cylinder is a power of * 2. Otherwise it might be slightly off -- you * might have a bit of a truncation problem. */ #ifdef __XSCALE__ cylinders = (lun->be_lun->maxlba + 1) / sectors_per_cylinder; #else for (shift = 31; shift > 0; shift--) { if (sectors_per_cylinder & (1 << shift)) break; } cylinders = (lun->be_lun->maxlba + 1) >> shift; #endif /* * We've basically got 3 bytes, or 24 bits for the * cylinder size in the mode page. If we're over, * just round down to 2^24. */ if (cylinders > 0xffffff) cylinders = 0xffffff; rigid_disk_page = &lun->mode_pages.rigid_disk_page[ CTL_PAGE_DEFAULT]; scsi_ulto3b(cylinders, rigid_disk_page->cylinders); if ((value = dnvlist_get_string(lun->be_lun->options, "rpm", NULL)) != NULL) { scsi_ulto2b(strtol(value, NULL, 0), rigid_disk_page->rotation_rate); } memcpy(&lun->mode_pages.rigid_disk_page[CTL_PAGE_CURRENT], &lun->mode_pages.rigid_disk_page[CTL_PAGE_DEFAULT], sizeof(rigid_disk_page_default)); memcpy(&lun->mode_pages.rigid_disk_page[CTL_PAGE_SAVED], &lun->mode_pages.rigid_disk_page[CTL_PAGE_DEFAULT], sizeof(rigid_disk_page_default)); page_index->page_data = (uint8_t *)lun->mode_pages.rigid_disk_page; break; } case SMS_VERIFY_ERROR_RECOVERY_PAGE: { KASSERT(page_index->subpage == SMS_SUBPAGE_PAGE_0, ("subpage %#x for page %#x is incorrect!", page_index->subpage, page_code)); memcpy(&lun->mode_pages.verify_er_page[CTL_PAGE_CURRENT], &verify_er_page_default, sizeof(verify_er_page_default)); memcpy(&lun->mode_pages.verify_er_page[CTL_PAGE_CHANGEABLE], &verify_er_page_changeable, sizeof(verify_er_page_changeable)); memcpy(&lun->mode_pages.verify_er_page[CTL_PAGE_DEFAULT], &verify_er_page_default, sizeof(verify_er_page_default)); memcpy(&lun->mode_pages.verify_er_page[CTL_PAGE_SAVED], &verify_er_page_default, sizeof(verify_er_page_default)); page_index->page_data = (uint8_t *)lun->mode_pages.verify_er_page; break; } case SMS_CACHING_PAGE: { struct scsi_caching_page *caching_page; KASSERT(page_index->subpage == SMS_SUBPAGE_PAGE_0, ("subpage %#x for page %#x is incorrect!", page_index->subpage, page_code)); memcpy(&lun->mode_pages.caching_page[CTL_PAGE_DEFAULT], &caching_page_default, sizeof(caching_page_default)); memcpy(&lun->mode_pages.caching_page[ CTL_PAGE_CHANGEABLE], &caching_page_changeable, sizeof(caching_page_changeable)); memcpy(&lun->mode_pages.caching_page[CTL_PAGE_SAVED], &caching_page_default, sizeof(caching_page_default)); caching_page = &lun->mode_pages.caching_page[ CTL_PAGE_SAVED]; value = dnvlist_get_string(lun->be_lun->options, "writecache", NULL); if (value != NULL && strcmp(value, "off") == 0) caching_page->flags1 &= ~SCP_WCE; value = dnvlist_get_string(lun->be_lun->options, "readcache", NULL); if (value != NULL && strcmp(value, "off") == 0) caching_page->flags1 |= SCP_RCD; memcpy(&lun->mode_pages.caching_page[CTL_PAGE_CURRENT], &lun->mode_pages.caching_page[CTL_PAGE_SAVED], sizeof(caching_page_default)); page_index->page_data = (uint8_t *)lun->mode_pages.caching_page; break; } case SMS_CONTROL_MODE_PAGE: { switch (page_index->subpage) { case SMS_SUBPAGE_PAGE_0: { struct scsi_control_page *control_page; memcpy(&lun->mode_pages.control_page[ CTL_PAGE_DEFAULT], &control_page_default, sizeof(control_page_default)); memcpy(&lun->mode_pages.control_page[ CTL_PAGE_CHANGEABLE], &control_page_changeable, sizeof(control_page_changeable)); memcpy(&lun->mode_pages.control_page[ CTL_PAGE_SAVED], &control_page_default, sizeof(control_page_default)); control_page = &lun->mode_pages.control_page[ CTL_PAGE_SAVED]; value = dnvlist_get_string(lun->be_lun->options, "reordering", NULL); if (value != NULL && strcmp(value, "unrestricted") == 0) { control_page->queue_flags &= ~SCP_QUEUE_ALG_MASK; control_page->queue_flags |= SCP_QUEUE_ALG_UNRESTRICTED; } memcpy(&lun->mode_pages.control_page[ CTL_PAGE_CURRENT], &lun->mode_pages.control_page[ CTL_PAGE_SAVED], sizeof(control_page_default)); page_index->page_data = (uint8_t *)lun->mode_pages.control_page; break; } case 0x01: memcpy(&lun->mode_pages.control_ext_page[ CTL_PAGE_DEFAULT], &control_ext_page_default, sizeof(control_ext_page_default)); memcpy(&lun->mode_pages.control_ext_page[ CTL_PAGE_CHANGEABLE], &control_ext_page_changeable, sizeof(control_ext_page_changeable)); memcpy(&lun->mode_pages.control_ext_page[ CTL_PAGE_SAVED], &control_ext_page_default, sizeof(control_ext_page_default)); memcpy(&lun->mode_pages.control_ext_page[ CTL_PAGE_CURRENT], &lun->mode_pages.control_ext_page[ CTL_PAGE_SAVED], sizeof(control_ext_page_default)); page_index->page_data = (uint8_t *)lun->mode_pages.control_ext_page; break; default: panic("subpage %#x for page %#x is incorrect!", page_index->subpage, page_code); } break; } case SMS_INFO_EXCEPTIONS_PAGE: { switch (page_index->subpage) { case SMS_SUBPAGE_PAGE_0: memcpy(&lun->mode_pages.ie_page[CTL_PAGE_CURRENT], &ie_page_default, sizeof(ie_page_default)); memcpy(&lun->mode_pages.ie_page[ CTL_PAGE_CHANGEABLE], &ie_page_changeable, sizeof(ie_page_changeable)); memcpy(&lun->mode_pages.ie_page[CTL_PAGE_DEFAULT], &ie_page_default, sizeof(ie_page_default)); memcpy(&lun->mode_pages.ie_page[CTL_PAGE_SAVED], &ie_page_default, sizeof(ie_page_default)); page_index->page_data = (uint8_t *)lun->mode_pages.ie_page; break; case 0x02: { struct ctl_logical_block_provisioning_page *page; memcpy(&lun->mode_pages.lbp_page[CTL_PAGE_DEFAULT], &lbp_page_default, sizeof(lbp_page_default)); memcpy(&lun->mode_pages.lbp_page[ CTL_PAGE_CHANGEABLE], &lbp_page_changeable, sizeof(lbp_page_changeable)); memcpy(&lun->mode_pages.lbp_page[CTL_PAGE_SAVED], &lbp_page_default, sizeof(lbp_page_default)); page = &lun->mode_pages.lbp_page[CTL_PAGE_SAVED]; value = dnvlist_get_string(lun->be_lun->options, "avail-threshold", NULL); if (value != NULL && ctl_expand_number(value, &ival) == 0) { page->descr[0].flags |= SLBPPD_ENABLED | SLBPPD_ARMING_DEC; if (lun->be_lun->blocksize) ival /= lun->be_lun->blocksize; else ival /= 512; scsi_ulto4b(ival >> CTL_LBP_EXPONENT, page->descr[0].count); } value = dnvlist_get_string(lun->be_lun->options, "used-threshold", NULL); if (value != NULL && ctl_expand_number(value, &ival) == 0) { page->descr[1].flags |= SLBPPD_ENABLED | SLBPPD_ARMING_INC; if (lun->be_lun->blocksize) ival /= lun->be_lun->blocksize; else ival /= 512; scsi_ulto4b(ival >> CTL_LBP_EXPONENT, page->descr[1].count); } value = dnvlist_get_string(lun->be_lun->options, "pool-avail-threshold", NULL); if (value != NULL && ctl_expand_number(value, &ival) == 0) { page->descr[2].flags |= SLBPPD_ENABLED | SLBPPD_ARMING_DEC; if (lun->be_lun->blocksize) ival /= lun->be_lun->blocksize; else ival /= 512; scsi_ulto4b(ival >> CTL_LBP_EXPONENT, page->descr[2].count); } value = dnvlist_get_string(lun->be_lun->options, "pool-used-threshold", NULL); if (value != NULL && ctl_expand_number(value, &ival) == 0) { page->descr[3].flags |= SLBPPD_ENABLED | SLBPPD_ARMING_INC; if (lun->be_lun->blocksize) ival /= lun->be_lun->blocksize; else ival /= 512; scsi_ulto4b(ival >> CTL_LBP_EXPONENT, page->descr[3].count); } memcpy(&lun->mode_pages.lbp_page[CTL_PAGE_CURRENT], &lun->mode_pages.lbp_page[CTL_PAGE_SAVED], sizeof(lbp_page_default)); page_index->page_data = (uint8_t *)lun->mode_pages.lbp_page; break; } default: panic("subpage %#x for page %#x is incorrect!", page_index->subpage, page_code); } break; } case SMS_CDDVD_CAPS_PAGE:{ KASSERT(page_index->subpage == SMS_SUBPAGE_PAGE_0, ("subpage %#x for page %#x is incorrect!", page_index->subpage, page_code)); memcpy(&lun->mode_pages.cddvd_page[CTL_PAGE_DEFAULT], &cddvd_page_default, sizeof(cddvd_page_default)); memcpy(&lun->mode_pages.cddvd_page[ CTL_PAGE_CHANGEABLE], &cddvd_page_changeable, sizeof(cddvd_page_changeable)); memcpy(&lun->mode_pages.cddvd_page[CTL_PAGE_SAVED], &cddvd_page_default, sizeof(cddvd_page_default)); memcpy(&lun->mode_pages.cddvd_page[CTL_PAGE_CURRENT], &lun->mode_pages.cddvd_page[CTL_PAGE_SAVED], sizeof(cddvd_page_default)); page_index->page_data = (uint8_t *)lun->mode_pages.cddvd_page; break; } default: panic("invalid page code value %#x", page_code); } } return (CTL_RETVAL_COMPLETE); } static int ctl_init_log_page_index(struct ctl_lun *lun) { struct ctl_page_index *page_index; int i, j, k, prev; memcpy(&lun->log_pages.index, log_page_index_template, sizeof(log_page_index_template)); prev = -1; for (i = 0, j = 0, k = 0; i < CTL_NUM_LOG_PAGES; i++) { page_index = &lun->log_pages.index[i]; if (lun->be_lun->lun_type == T_DIRECT && (page_index->page_flags & CTL_PAGE_FLAG_DIRECT) == 0) continue; if (lun->be_lun->lun_type == T_PROCESSOR && (page_index->page_flags & CTL_PAGE_FLAG_PROC) == 0) continue; if (lun->be_lun->lun_type == T_CDROM && (page_index->page_flags & CTL_PAGE_FLAG_CDROM) == 0) continue; if (page_index->page_code == SLS_LOGICAL_BLOCK_PROVISIONING && lun->backend->lun_attr == NULL) continue; if (page_index->page_code != prev) { lun->log_pages.pages_page[j] = page_index->page_code; prev = page_index->page_code; j++; } lun->log_pages.subpages_page[k*2] = page_index->page_code; lun->log_pages.subpages_page[k*2+1] = page_index->subpage; k++; } lun->log_pages.index[0].page_data = &lun->log_pages.pages_page[0]; lun->log_pages.index[0].page_len = j; lun->log_pages.index[1].page_data = &lun->log_pages.subpages_page[0]; lun->log_pages.index[1].page_len = k * 2; lun->log_pages.index[2].page_data = (uint8_t *)&lun->log_pages.temp_page; lun->log_pages.index[2].page_len = sizeof(lun->log_pages.temp_page); lun->log_pages.index[3].page_data = &lun->log_pages.lbp_page[0]; lun->log_pages.index[3].page_len = 12*CTL_NUM_LBP_PARAMS; lun->log_pages.index[4].page_data = (uint8_t *)&lun->log_pages.stat_page; lun->log_pages.index[4].page_len = sizeof(lun->log_pages.stat_page); lun->log_pages.index[5].page_data = (uint8_t *)&lun->log_pages.ie_page; lun->log_pages.index[5].page_len = sizeof(lun->log_pages.ie_page); return (CTL_RETVAL_COMPLETE); } static int hex2bin(const char *str, uint8_t *buf, int buf_size) { int i; u_char c; memset(buf, 0, buf_size); while (isspace(str[0])) str++; if (str[0] == '0' && (str[1] == 'x' || str[1] == 'X')) str += 2; buf_size *= 2; for (i = 0; str[i] != 0 && i < buf_size; i++) { while (str[i] == '-') /* Skip dashes in UUIDs. */ str++; c = str[i]; if (isdigit(c)) c -= '0'; else if (isalpha(c)) c -= isupper(c) ? 'A' - 10 : 'a' - 10; else break; if (c >= 16) break; if ((i & 1) == 0) buf[i / 2] |= (c << 4); else buf[i / 2] |= c; } return ((i + 1) / 2); } /* * Add LUN. * * Returns 0 for success, non-zero (errno) for failure. */ int ctl_add_lun(struct ctl_be_lun *be_lun) { struct ctl_softc *ctl_softc = control_softc; struct ctl_lun *nlun, *lun; struct scsi_vpd_id_descriptor *desc; struct scsi_vpd_id_t10 *t10id; const char *eui, *naa, *scsiname, *uuid, *vendor, *value; int lun_number; int devidlen, idlen1, idlen2 = 0, len; /* * We support only Direct Access, CD-ROM or Processor LUN types. */ switch (be_lun->lun_type) { case T_DIRECT: case T_PROCESSOR: case T_CDROM: break; case T_SEQUENTIAL: case T_CHANGER: default: return (EINVAL); } lun = malloc(sizeof(*lun), M_CTL, M_WAITOK | M_ZERO); lun->pending_sense = malloc(sizeof(struct scsi_sense_data *) * ctl_max_ports, M_DEVBUF, M_WAITOK | M_ZERO); lun->pending_ua = malloc(sizeof(ctl_ua_type *) * ctl_max_ports, M_DEVBUF, M_WAITOK | M_ZERO); lun->pr_keys = malloc(sizeof(uint64_t *) * ctl_max_ports, M_DEVBUF, M_WAITOK | M_ZERO); /* Generate LUN ID. */ devidlen = max(CTL_DEVID_MIN_LEN, strnlen(be_lun->device_id, CTL_DEVID_LEN)); idlen1 = sizeof(*t10id) + devidlen; len = sizeof(struct scsi_vpd_id_descriptor) + idlen1; scsiname = dnvlist_get_string(be_lun->options, "scsiname", NULL); if (scsiname != NULL) { idlen2 = roundup2(strlen(scsiname) + 1, 4); len += sizeof(struct scsi_vpd_id_descriptor) + idlen2; } eui = dnvlist_get_string(be_lun->options, "eui", NULL); if (eui != NULL) { len += sizeof(struct scsi_vpd_id_descriptor) + 16; } naa = dnvlist_get_string(be_lun->options, "naa", NULL); if (naa != NULL) { len += sizeof(struct scsi_vpd_id_descriptor) + 16; } uuid = dnvlist_get_string(be_lun->options, "uuid", NULL); if (uuid != NULL) { len += sizeof(struct scsi_vpd_id_descriptor) + 18; } lun->lun_devid = malloc(sizeof(struct ctl_devid) + len, M_CTL, M_WAITOK | M_ZERO); desc = (struct scsi_vpd_id_descriptor *)lun->lun_devid->data; desc->proto_codeset = SVPD_ID_CODESET_ASCII; desc->id_type = SVPD_ID_PIV | SVPD_ID_ASSOC_LUN | SVPD_ID_TYPE_T10; desc->length = idlen1; t10id = (struct scsi_vpd_id_t10 *)&desc->identifier[0]; memset(t10id->vendor, ' ', sizeof(t10id->vendor)); if ((vendor = dnvlist_get_string(be_lun->options, "vendor", NULL)) == NULL) { strncpy((char *)t10id->vendor, CTL_VENDOR, sizeof(t10id->vendor)); } else { strncpy(t10id->vendor, vendor, min(sizeof(t10id->vendor), strlen(vendor))); } strncpy((char *)t10id->vendor_spec_id, (char *)be_lun->device_id, devidlen); if (scsiname != NULL) { desc = (struct scsi_vpd_id_descriptor *)(&desc->identifier[0] + desc->length); desc->proto_codeset = SVPD_ID_CODESET_UTF8; desc->id_type = SVPD_ID_PIV | SVPD_ID_ASSOC_LUN | SVPD_ID_TYPE_SCSI_NAME; desc->length = idlen2; strlcpy(desc->identifier, scsiname, idlen2); } if (eui != NULL) { desc = (struct scsi_vpd_id_descriptor *)(&desc->identifier[0] + desc->length); desc->proto_codeset = SVPD_ID_CODESET_BINARY; desc->id_type = SVPD_ID_PIV | SVPD_ID_ASSOC_LUN | SVPD_ID_TYPE_EUI64; desc->length = hex2bin(eui, desc->identifier, 16); desc->length = desc->length > 12 ? 16 : (desc->length > 8 ? 12 : 8); len -= 16 - desc->length; } if (naa != NULL) { desc = (struct scsi_vpd_id_descriptor *)(&desc->identifier[0] + desc->length); desc->proto_codeset = SVPD_ID_CODESET_BINARY; desc->id_type = SVPD_ID_PIV | SVPD_ID_ASSOC_LUN | SVPD_ID_TYPE_NAA; desc->length = hex2bin(naa, desc->identifier, 16); desc->length = desc->length > 8 ? 16 : 8; len -= 16 - desc->length; } if (uuid != NULL) { desc = (struct scsi_vpd_id_descriptor *)(&desc->identifier[0] + desc->length); desc->proto_codeset = SVPD_ID_CODESET_BINARY; desc->id_type = SVPD_ID_PIV | SVPD_ID_ASSOC_LUN | SVPD_ID_TYPE_UUID; desc->identifier[0] = 0x10; hex2bin(uuid, &desc->identifier[2], 16); desc->length = 18; } lun->lun_devid->len = len; mtx_lock(&ctl_softc->ctl_lock); /* * See if the caller requested a particular LUN number. If so, see * if it is available. Otherwise, allocate the first available LUN. */ if (be_lun->flags & CTL_LUN_FLAG_ID_REQ) { if ((be_lun->req_lun_id > (ctl_max_luns - 1)) || (ctl_is_set(ctl_softc->ctl_lun_mask, be_lun->req_lun_id))) { mtx_unlock(&ctl_softc->ctl_lock); if (be_lun->req_lun_id > (ctl_max_luns - 1)) { printf("ctl: requested LUN ID %d is higher " "than ctl_max_luns - 1 (%d)\n", be_lun->req_lun_id, ctl_max_luns - 1); } else { /* * XXX KDM return an error, or just assign * another LUN ID in this case?? */ printf("ctl: requested LUN ID %d is already " "in use\n", be_lun->req_lun_id); } fail: free(lun->lun_devid, M_CTL); free(lun, M_CTL); return (ENOSPC); } lun_number = be_lun->req_lun_id; } else { lun_number = ctl_ffz(ctl_softc->ctl_lun_mask, 0, ctl_max_luns); if (lun_number == -1) { mtx_unlock(&ctl_softc->ctl_lock); printf("ctl: can't allocate LUN, out of LUNs\n"); goto fail; } } ctl_set_mask(ctl_softc->ctl_lun_mask, lun_number); mtx_unlock(&ctl_softc->ctl_lock); mtx_init(&lun->lun_lock, "CTL LUN", NULL, MTX_DEF); lun->lun = lun_number; lun->be_lun = be_lun; /* * The processor LUN is always enabled. Disk LUNs come on line * disabled, and must be enabled by the backend. */ lun->flags |= CTL_LUN_DISABLED; lun->backend = be_lun->be; be_lun->ctl_lun = lun; be_lun->lun_id = lun_number; if (be_lun->flags & CTL_LUN_FLAG_EJECTED) lun->flags |= CTL_LUN_EJECTED; if (be_lun->flags & CTL_LUN_FLAG_NO_MEDIA) lun->flags |= CTL_LUN_NO_MEDIA; if (be_lun->flags & CTL_LUN_FLAG_STOPPED) lun->flags |= CTL_LUN_STOPPED; if (be_lun->flags & CTL_LUN_FLAG_PRIMARY) lun->flags |= CTL_LUN_PRIMARY_SC; value = dnvlist_get_string(be_lun->options, "removable", NULL); if (value != NULL) { if (strcmp(value, "on") == 0) lun->flags |= CTL_LUN_REMOVABLE; } else if (be_lun->lun_type == T_CDROM) lun->flags |= CTL_LUN_REMOVABLE; lun->ctl_softc = ctl_softc; #ifdef CTL_TIME_IO lun->last_busy = getsbinuptime(); #endif TAILQ_INIT(&lun->ooa_queue); STAILQ_INIT(&lun->error_list); lun->ie_reported = 1; callout_init_mtx(&lun->ie_callout, &lun->lun_lock, 0); ctl_tpc_lun_init(lun); if (lun->flags & CTL_LUN_REMOVABLE) { lun->prevent = malloc((CTL_MAX_INITIATORS + 31) / 32 * 4, M_CTL, M_WAITOK); } /* * Initialize the mode and log page index. */ ctl_init_page_index(lun); ctl_init_log_page_index(lun); /* Setup statistics gathering */ lun->stats.item = lun_number; /* * Now, before we insert this lun on the lun list, set the lun * inventory changed UA for all other luns. */ mtx_lock(&ctl_softc->ctl_lock); STAILQ_FOREACH(nlun, &ctl_softc->lun_list, links) { mtx_lock(&nlun->lun_lock); ctl_est_ua_all(nlun, -1, CTL_UA_LUN_CHANGE); mtx_unlock(&nlun->lun_lock); } STAILQ_INSERT_TAIL(&ctl_softc->lun_list, lun, links); ctl_softc->ctl_luns[lun_number] = lun; ctl_softc->num_luns++; mtx_unlock(&ctl_softc->ctl_lock); /* * We successfully added the LUN, attempt to enable it. */ if (ctl_enable_lun(lun) != 0) { printf("%s: ctl_enable_lun() failed!\n", __func__); mtx_lock(&ctl_softc->ctl_lock); STAILQ_REMOVE(&ctl_softc->lun_list, lun, ctl_lun, links); ctl_clear_mask(ctl_softc->ctl_lun_mask, lun_number); ctl_softc->ctl_luns[lun_number] = NULL; ctl_softc->num_luns--; mtx_unlock(&ctl_softc->ctl_lock); free(lun->lun_devid, M_CTL); free(lun, M_CTL); return (EIO); } return (0); } /* * Free LUN that has no active requests. */ static int ctl_free_lun(struct ctl_lun *lun) { struct ctl_softc *softc = lun->ctl_softc; struct ctl_lun *nlun; int i; KASSERT(TAILQ_EMPTY(&lun->ooa_queue), ("Freeing a LUN %p with outstanding I/O!\n", lun)); mtx_lock(&softc->ctl_lock); STAILQ_REMOVE(&softc->lun_list, lun, ctl_lun, links); ctl_clear_mask(softc->ctl_lun_mask, lun->lun); softc->ctl_luns[lun->lun] = NULL; softc->num_luns--; STAILQ_FOREACH(nlun, &softc->lun_list, links) { mtx_lock(&nlun->lun_lock); ctl_est_ua_all(nlun, -1, CTL_UA_LUN_CHANGE); mtx_unlock(&nlun->lun_lock); } mtx_unlock(&softc->ctl_lock); /* * Tell the backend to free resources, if this LUN has a backend. */ lun->be_lun->lun_shutdown(lun->be_lun); lun->ie_reportcnt = UINT32_MAX; callout_drain(&lun->ie_callout); ctl_tpc_lun_shutdown(lun); mtx_destroy(&lun->lun_lock); free(lun->lun_devid, M_CTL); for (i = 0; i < ctl_max_ports; i++) free(lun->pending_ua[i], M_CTL); free(lun->pending_ua, M_DEVBUF); for (i = 0; i < ctl_max_ports; i++) free(lun->pr_keys[i], M_CTL); free(lun->pr_keys, M_DEVBUF); free(lun->write_buffer, M_CTL); free(lun->prevent, M_CTL); free(lun, M_CTL); return (0); } static int ctl_enable_lun(struct ctl_lun *lun) { struct ctl_softc *softc; struct ctl_port *port, *nport; int retval; softc = lun->ctl_softc; mtx_lock(&softc->ctl_lock); mtx_lock(&lun->lun_lock); KASSERT((lun->flags & CTL_LUN_DISABLED) != 0, ("%s: LUN not disabled", __func__)); lun->flags &= ~CTL_LUN_DISABLED; mtx_unlock(&lun->lun_lock); STAILQ_FOREACH_SAFE(port, &softc->port_list, links, nport) { if ((port->status & CTL_PORT_STATUS_ONLINE) == 0 || port->lun_map != NULL || port->lun_enable == NULL) continue; /* * Drop the lock while we call the FETD's enable routine. * This can lead to a callback into CTL (at least in the * case of the internal initiator frontend. */ mtx_unlock(&softc->ctl_lock); retval = port->lun_enable(port->targ_lun_arg, lun->lun); mtx_lock(&softc->ctl_lock); if (retval != 0) { printf("%s: FETD %s port %d returned error " "%d for lun_enable on lun %jd\n", __func__, port->port_name, port->targ_port, retval, (intmax_t)lun->lun); } } mtx_unlock(&softc->ctl_lock); ctl_isc_announce_lun(lun); return (0); } static int ctl_disable_lun(struct ctl_lun *lun) { struct ctl_softc *softc; struct ctl_port *port; int retval; softc = lun->ctl_softc; mtx_lock(&softc->ctl_lock); mtx_lock(&lun->lun_lock); KASSERT((lun->flags & CTL_LUN_DISABLED) == 0, ("%s: LUN not enabled", __func__)); lun->flags |= CTL_LUN_DISABLED; mtx_unlock(&lun->lun_lock); STAILQ_FOREACH(port, &softc->port_list, links) { if ((port->status & CTL_PORT_STATUS_ONLINE) == 0 || port->lun_map != NULL || port->lun_disable == NULL) continue; /* * Drop the lock before we call the frontend's disable * routine, to avoid lock order reversals. * * XXX KDM what happens if the frontend list changes while * we're traversing it? It's unlikely, but should be handled. */ mtx_unlock(&softc->ctl_lock); retval = port->lun_disable(port->targ_lun_arg, lun->lun); mtx_lock(&softc->ctl_lock); if (retval != 0) { printf("%s: FETD %s port %d returned error " "%d for lun_disable on lun %jd\n", __func__, port->port_name, port->targ_port, retval, (intmax_t)lun->lun); } } mtx_unlock(&softc->ctl_lock); ctl_isc_announce_lun(lun); return (0); } int ctl_start_lun(struct ctl_be_lun *be_lun) { struct ctl_lun *lun = (struct ctl_lun *)be_lun->ctl_lun; mtx_lock(&lun->lun_lock); lun->flags &= ~CTL_LUN_STOPPED; mtx_unlock(&lun->lun_lock); return (0); } int ctl_stop_lun(struct ctl_be_lun *be_lun) { struct ctl_lun *lun = (struct ctl_lun *)be_lun->ctl_lun; mtx_lock(&lun->lun_lock); lun->flags |= CTL_LUN_STOPPED; mtx_unlock(&lun->lun_lock); return (0); } int ctl_lun_no_media(struct ctl_be_lun *be_lun) { struct ctl_lun *lun = (struct ctl_lun *)be_lun->ctl_lun; mtx_lock(&lun->lun_lock); lun->flags |= CTL_LUN_NO_MEDIA; mtx_unlock(&lun->lun_lock); return (0); } int ctl_lun_has_media(struct ctl_be_lun *be_lun) { struct ctl_lun *lun = (struct ctl_lun *)be_lun->ctl_lun; union ctl_ha_msg msg; mtx_lock(&lun->lun_lock); lun->flags &= ~(CTL_LUN_NO_MEDIA | CTL_LUN_EJECTED); if (lun->flags & CTL_LUN_REMOVABLE) ctl_est_ua_all(lun, -1, CTL_UA_MEDIUM_CHANGE); mtx_unlock(&lun->lun_lock); if ((lun->flags & CTL_LUN_REMOVABLE) && lun->ctl_softc->ha_mode == CTL_HA_MODE_XFER) { bzero(&msg.ua, sizeof(msg.ua)); msg.hdr.msg_type = CTL_MSG_UA; msg.hdr.nexus.initid = -1; msg.hdr.nexus.targ_port = -1; msg.hdr.nexus.targ_lun = lun->lun; msg.hdr.nexus.targ_mapped_lun = lun->lun; msg.ua.ua_all = 1; msg.ua.ua_set = 1; msg.ua.ua_type = CTL_UA_MEDIUM_CHANGE; ctl_ha_msg_send(CTL_HA_CHAN_CTL, &msg, sizeof(msg.ua), M_WAITOK); } return (0); } int ctl_lun_ejected(struct ctl_be_lun *be_lun) { struct ctl_lun *lun = (struct ctl_lun *)be_lun->ctl_lun; mtx_lock(&lun->lun_lock); lun->flags |= CTL_LUN_EJECTED; mtx_unlock(&lun->lun_lock); return (0); } int ctl_lun_primary(struct ctl_be_lun *be_lun) { struct ctl_lun *lun = (struct ctl_lun *)be_lun->ctl_lun; mtx_lock(&lun->lun_lock); lun->flags |= CTL_LUN_PRIMARY_SC; ctl_est_ua_all(lun, -1, CTL_UA_ASYM_ACC_CHANGE); mtx_unlock(&lun->lun_lock); ctl_isc_announce_lun(lun); return (0); } int ctl_lun_secondary(struct ctl_be_lun *be_lun) { struct ctl_lun *lun = (struct ctl_lun *)be_lun->ctl_lun; mtx_lock(&lun->lun_lock); lun->flags &= ~CTL_LUN_PRIMARY_SC; ctl_est_ua_all(lun, -1, CTL_UA_ASYM_ACC_CHANGE); mtx_unlock(&lun->lun_lock); ctl_isc_announce_lun(lun); return (0); } /* * Remove LUN. If there are active requests, wait for completion. * * Returns 0 for success, non-zero (errno) for failure. * Completion is reported to backed via the lun_shutdown() method. */ int ctl_remove_lun(struct ctl_be_lun *be_lun) { struct ctl_lun *lun; lun = (struct ctl_lun *)be_lun->ctl_lun; ctl_disable_lun(lun); mtx_lock(&lun->lun_lock); lun->flags |= CTL_LUN_INVALID; /* * If there is nothing in the OOA queue, go ahead and free the LUN. * If we have something in the OOA queue, we'll free it when the * last I/O completes. */ if (TAILQ_EMPTY(&lun->ooa_queue)) { mtx_unlock(&lun->lun_lock); ctl_free_lun(lun); } else mtx_unlock(&lun->lun_lock); return (0); } void ctl_lun_capacity_changed(struct ctl_be_lun *be_lun) { struct ctl_lun *lun = (struct ctl_lun *)be_lun->ctl_lun; union ctl_ha_msg msg; mtx_lock(&lun->lun_lock); ctl_est_ua_all(lun, -1, CTL_UA_CAPACITY_CHANGE); mtx_unlock(&lun->lun_lock); if (lun->ctl_softc->ha_mode == CTL_HA_MODE_XFER) { /* Send msg to other side. */ bzero(&msg.ua, sizeof(msg.ua)); msg.hdr.msg_type = CTL_MSG_UA; msg.hdr.nexus.initid = -1; msg.hdr.nexus.targ_port = -1; msg.hdr.nexus.targ_lun = lun->lun; msg.hdr.nexus.targ_mapped_lun = lun->lun; msg.ua.ua_all = 1; msg.ua.ua_set = 1; msg.ua.ua_type = CTL_UA_CAPACITY_CHANGE; ctl_ha_msg_send(CTL_HA_CHAN_CTL, &msg, sizeof(msg.ua), M_WAITOK); } } /* * Backend "memory move is complete" callback for requests that never * make it down to say RAIDCore's configuration code. */ int ctl_config_move_done(union ctl_io *io) { int retval; CTL_DEBUG_PRINT(("ctl_config_move_done\n")); KASSERT(io->io_hdr.io_type == CTL_IO_SCSI, ("Config I/O type isn't CTL_IO_SCSI (%d)!", io->io_hdr.io_type)); if ((io->io_hdr.port_status != 0) && ((io->io_hdr.status & CTL_STATUS_MASK) == CTL_STATUS_NONE || (io->io_hdr.status & CTL_STATUS_MASK) == CTL_SUCCESS)) { ctl_set_internal_failure(&io->scsiio, /*sks_valid*/ 1, /*retry_count*/ io->io_hdr.port_status); } else if (io->scsiio.kern_data_resid != 0 && (io->io_hdr.flags & CTL_FLAG_DATA_MASK) == CTL_FLAG_DATA_OUT && ((io->io_hdr.status & CTL_STATUS_MASK) == CTL_STATUS_NONE || (io->io_hdr.status & CTL_STATUS_MASK) == CTL_SUCCESS)) { ctl_set_invalid_field_ciu(&io->scsiio); } if (ctl_debug & CTL_DEBUG_CDB_DATA) ctl_data_print(io); if (((io->io_hdr.flags & CTL_FLAG_DATA_MASK) == CTL_FLAG_DATA_IN) || ((io->io_hdr.status & CTL_STATUS_MASK) != CTL_STATUS_NONE && (io->io_hdr.status & CTL_STATUS_MASK) != CTL_SUCCESS) || ((io->io_hdr.flags & CTL_FLAG_ABORT) != 0)) { /* * XXX KDM just assuming a single pointer here, and not a * S/G list. If we start using S/G lists for config data, * we'll need to know how to clean them up here as well. */ if (io->io_hdr.flags & CTL_FLAG_ALLOCATED) free(io->scsiio.kern_data_ptr, M_CTL); ctl_done(io); retval = CTL_RETVAL_COMPLETE; } else { /* * XXX KDM now we need to continue data movement. Some * options: * - call ctl_scsiio() again? We don't do this for data * writes, because for those at least we know ahead of * time where the write will go and how long it is. For * config writes, though, that information is largely * contained within the write itself, thus we need to * parse out the data again. * * - Call some other function once the data is in? */ /* * XXX KDM call ctl_scsiio() again for now, and check flag * bits to see whether we're allocated or not. */ retval = ctl_scsiio(&io->scsiio); } return (retval); } /* * This gets called by a backend driver when it is done with a * data_submit method. */ void ctl_data_submit_done(union ctl_io *io) { /* * If the IO_CONT flag is set, we need to call the supplied * function to continue processing the I/O, instead of completing * the I/O just yet. * * If there is an error, though, we don't want to keep processing. * Instead, just send status back to the initiator. */ if ((io->io_hdr.flags & CTL_FLAG_IO_CONT) && (io->io_hdr.flags & CTL_FLAG_ABORT) == 0 && ((io->io_hdr.status & CTL_STATUS_MASK) == CTL_STATUS_NONE || (io->io_hdr.status & CTL_STATUS_MASK) == CTL_SUCCESS)) { io->scsiio.io_cont(io); return; } ctl_done(io); } /* * This gets called by a backend driver when it is done with a * configuration write. */ void ctl_config_write_done(union ctl_io *io) { uint8_t *buf; /* * If the IO_CONT flag is set, we need to call the supplied * function to continue processing the I/O, instead of completing * the I/O just yet. * * If there is an error, though, we don't want to keep processing. * Instead, just send status back to the initiator. */ if ((io->io_hdr.flags & CTL_FLAG_IO_CONT) && (io->io_hdr.flags & CTL_FLAG_ABORT) == 0 && ((io->io_hdr.status & CTL_STATUS_MASK) == CTL_STATUS_NONE || (io->io_hdr.status & CTL_STATUS_MASK) == CTL_SUCCESS)) { io->scsiio.io_cont(io); return; } /* * Since a configuration write can be done for commands that actually * have data allocated, like write buffer, and commands that have * no data, like start/stop unit, we need to check here. */ if (io->io_hdr.flags & CTL_FLAG_ALLOCATED) buf = io->scsiio.kern_data_ptr; else buf = NULL; ctl_done(io); if (buf) free(buf, M_CTL); } void ctl_config_read_done(union ctl_io *io) { uint8_t *buf; /* * If there is some error -- we are done, skip data transfer. */ if ((io->io_hdr.flags & CTL_FLAG_ABORT) != 0 || ((io->io_hdr.status & CTL_STATUS_MASK) != CTL_STATUS_NONE && (io->io_hdr.status & CTL_STATUS_MASK) != CTL_SUCCESS)) { if (io->io_hdr.flags & CTL_FLAG_ALLOCATED) buf = io->scsiio.kern_data_ptr; else buf = NULL; ctl_done(io); if (buf) free(buf, M_CTL); return; } /* * If the IO_CONT flag is set, we need to call the supplied * function to continue processing the I/O, instead of completing * the I/O just yet. */ if (io->io_hdr.flags & CTL_FLAG_IO_CONT) { io->scsiio.io_cont(io); return; } ctl_datamove(io); } /* * SCSI release command. */ int ctl_scsi_release(struct ctl_scsiio *ctsio) { struct ctl_lun *lun = CTL_LUN(ctsio); uint32_t residx; CTL_DEBUG_PRINT(("ctl_scsi_release\n")); residx = ctl_get_initindex(&ctsio->io_hdr.nexus); /* * XXX KDM right now, we only support LUN reservation. We don't * support 3rd party reservations, or extent reservations, which * might actually need the parameter list. If we've gotten this * far, we've got a LUN reservation. Anything else got kicked out * above. So, according to SPC, ignore the length. */ mtx_lock(&lun->lun_lock); /* * According to SPC, it is not an error for an intiator to attempt * to release a reservation on a LUN that isn't reserved, or that * is reserved by another initiator. The reservation can only be * released, though, by the initiator who made it or by one of * several reset type events. */ if ((lun->flags & CTL_LUN_RESERVED) && (lun->res_idx == residx)) lun->flags &= ~CTL_LUN_RESERVED; mtx_unlock(&lun->lun_lock); ctl_set_success(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } int ctl_scsi_reserve(struct ctl_scsiio *ctsio) { struct ctl_lun *lun = CTL_LUN(ctsio); uint32_t residx; CTL_DEBUG_PRINT(("ctl_reserve\n")); residx = ctl_get_initindex(&ctsio->io_hdr.nexus); /* * XXX KDM right now, we only support LUN reservation. We don't * support 3rd party reservations, or extent reservations, which * might actually need the parameter list. If we've gotten this * far, we've got a LUN reservation. Anything else got kicked out * above. So, according to SPC, ignore the length. */ mtx_lock(&lun->lun_lock); if ((lun->flags & CTL_LUN_RESERVED) && (lun->res_idx != residx)) { ctl_set_reservation_conflict(ctsio); goto bailout; } /* SPC-3 exceptions to SPC-2 RESERVE and RELEASE behavior. */ if (lun->flags & CTL_LUN_PR_RESERVED) { ctl_set_success(ctsio); goto bailout; } lun->flags |= CTL_LUN_RESERVED; lun->res_idx = residx; ctl_set_success(ctsio); bailout: mtx_unlock(&lun->lun_lock); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } int ctl_start_stop(struct ctl_scsiio *ctsio) { struct ctl_lun *lun = CTL_LUN(ctsio); struct scsi_start_stop_unit *cdb; int retval; CTL_DEBUG_PRINT(("ctl_start_stop\n")); cdb = (struct scsi_start_stop_unit *)ctsio->cdb; if ((cdb->how & SSS_PC_MASK) == 0) { if ((lun->flags & CTL_LUN_PR_RESERVED) && (cdb->how & SSS_START) == 0) { uint32_t residx; residx = ctl_get_initindex(&ctsio->io_hdr.nexus); if (ctl_get_prkey(lun, residx) == 0 || (lun->pr_res_idx != residx && lun->pr_res_type < 4)) { ctl_set_reservation_conflict(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } } if ((cdb->how & SSS_LOEJ) && (lun->flags & CTL_LUN_REMOVABLE) == 0) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 4, /*bit_valid*/ 1, /*bit*/ 1); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } if ((cdb->how & SSS_START) == 0 && (cdb->how & SSS_LOEJ) && lun->prevent_count > 0) { /* "Medium removal prevented" */ ctl_set_sense(ctsio, /*current_error*/ 1, /*sense_key*/(lun->flags & CTL_LUN_NO_MEDIA) ? SSD_KEY_NOT_READY : SSD_KEY_ILLEGAL_REQUEST, /*asc*/ 0x53, /*ascq*/ 0x02, SSD_ELEM_NONE); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } } retval = lun->backend->config_write((union ctl_io *)ctsio); return (retval); } int ctl_prevent_allow(struct ctl_scsiio *ctsio) { struct ctl_lun *lun = CTL_LUN(ctsio); struct scsi_prevent *cdb; int retval; uint32_t initidx; CTL_DEBUG_PRINT(("ctl_prevent_allow\n")); cdb = (struct scsi_prevent *)ctsio->cdb; if ((lun->flags & CTL_LUN_REMOVABLE) == 0 || lun->prevent == NULL) { ctl_set_invalid_opcode(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } initidx = ctl_get_initindex(&ctsio->io_hdr.nexus); mtx_lock(&lun->lun_lock); if ((cdb->how & PR_PREVENT) && ctl_is_set(lun->prevent, initidx) == 0) { ctl_set_mask(lun->prevent, initidx); lun->prevent_count++; } else if ((cdb->how & PR_PREVENT) == 0 && ctl_is_set(lun->prevent, initidx)) { ctl_clear_mask(lun->prevent, initidx); lun->prevent_count--; } mtx_unlock(&lun->lun_lock); retval = lun->backend->config_write((union ctl_io *)ctsio); return (retval); } /* * We support the SYNCHRONIZE CACHE command (10 and 16 byte versions), but * we don't really do anything with the LBA and length fields if the user * passes them in. Instead we'll just flush out the cache for the entire * LUN. */ int ctl_sync_cache(struct ctl_scsiio *ctsio) { struct ctl_lun *lun = CTL_LUN(ctsio); struct ctl_lba_len_flags *lbalen; uint64_t starting_lba; uint32_t block_count; int retval; uint8_t byte2; CTL_DEBUG_PRINT(("ctl_sync_cache\n")); retval = 0; switch (ctsio->cdb[0]) { case SYNCHRONIZE_CACHE: { struct scsi_sync_cache *cdb; cdb = (struct scsi_sync_cache *)ctsio->cdb; starting_lba = scsi_4btoul(cdb->begin_lba); block_count = scsi_2btoul(cdb->lb_count); byte2 = cdb->byte2; break; } case SYNCHRONIZE_CACHE_16: { struct scsi_sync_cache_16 *cdb; cdb = (struct scsi_sync_cache_16 *)ctsio->cdb; starting_lba = scsi_8btou64(cdb->begin_lba); block_count = scsi_4btoul(cdb->lb_count); byte2 = cdb->byte2; break; } default: ctl_set_invalid_opcode(ctsio); ctl_done((union ctl_io *)ctsio); goto bailout; break; /* NOTREACHED */ } /* * We check the LBA and length, but don't do anything with them. * A SYNCHRONIZE CACHE will cause the entire cache for this lun to * get flushed. This check will just help satisfy anyone who wants * to see an error for an out of range LBA. */ if ((starting_lba + block_count) > (lun->be_lun->maxlba + 1)) { ctl_set_lba_out_of_range(ctsio, MAX(starting_lba, lun->be_lun->maxlba + 1)); ctl_done((union ctl_io *)ctsio); goto bailout; } lbalen = (struct ctl_lba_len_flags *)&ctsio->io_hdr.ctl_private[CTL_PRIV_LBA_LEN]; lbalen->lba = starting_lba; lbalen->len = block_count; lbalen->flags = byte2; retval = lun->backend->config_write((union ctl_io *)ctsio); bailout: return (retval); } int ctl_format(struct ctl_scsiio *ctsio) { struct scsi_format *cdb; int length, defect_list_len; CTL_DEBUG_PRINT(("ctl_format\n")); cdb = (struct scsi_format *)ctsio->cdb; length = 0; if (cdb->byte2 & SF_FMTDATA) { if (cdb->byte2 & SF_LONGLIST) length = sizeof(struct scsi_format_header_long); else length = sizeof(struct scsi_format_header_short); } if (((ctsio->io_hdr.flags & CTL_FLAG_ALLOCATED) == 0) && (length > 0)) { ctsio->kern_data_ptr = malloc(length, M_CTL, M_WAITOK); ctsio->kern_data_len = length; ctsio->kern_total_len = length; ctsio->kern_rel_offset = 0; ctsio->kern_sg_entries = 0; ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } defect_list_len = 0; if (cdb->byte2 & SF_FMTDATA) { if (cdb->byte2 & SF_LONGLIST) { struct scsi_format_header_long *header; header = (struct scsi_format_header_long *) ctsio->kern_data_ptr; defect_list_len = scsi_4btoul(header->defect_list_len); if (defect_list_len != 0) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 0, /*field*/ 2, /*bit_valid*/ 0, /*bit*/ 0); goto bailout; } } else { struct scsi_format_header_short *header; header = (struct scsi_format_header_short *) ctsio->kern_data_ptr; defect_list_len = scsi_2btoul(header->defect_list_len); if (defect_list_len != 0) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 0, /*field*/ 2, /*bit_valid*/ 0, /*bit*/ 0); goto bailout; } } } ctl_set_success(ctsio); bailout: if (ctsio->io_hdr.flags & CTL_FLAG_ALLOCATED) { free(ctsio->kern_data_ptr, M_CTL); ctsio->io_hdr.flags &= ~CTL_FLAG_ALLOCATED; } ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } int ctl_read_buffer(struct ctl_scsiio *ctsio) { struct ctl_lun *lun = CTL_LUN(ctsio); uint64_t buffer_offset; uint32_t len; uint8_t byte2; static uint8_t descr[4]; static uint8_t echo_descr[4] = { 0 }; CTL_DEBUG_PRINT(("ctl_read_buffer\n")); switch (ctsio->cdb[0]) { case READ_BUFFER: { struct scsi_read_buffer *cdb; cdb = (struct scsi_read_buffer *)ctsio->cdb; buffer_offset = scsi_3btoul(cdb->offset); len = scsi_3btoul(cdb->length); byte2 = cdb->byte2; break; } case READ_BUFFER_16: { struct scsi_read_buffer_16 *cdb; cdb = (struct scsi_read_buffer_16 *)ctsio->cdb; buffer_offset = scsi_8btou64(cdb->offset); len = scsi_4btoul(cdb->length); byte2 = cdb->byte2; break; } default: /* This shouldn't happen. */ ctl_set_invalid_opcode(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } if (buffer_offset > CTL_WRITE_BUFFER_SIZE || buffer_offset + len > CTL_WRITE_BUFFER_SIZE) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 6, /*bit_valid*/ 0, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } if ((byte2 & RWB_MODE) == RWB_MODE_DESCR) { descr[0] = 0; scsi_ulto3b(CTL_WRITE_BUFFER_SIZE, &descr[1]); ctsio->kern_data_ptr = descr; len = min(len, sizeof(descr)); } else if ((byte2 & RWB_MODE) == RWB_MODE_ECHO_DESCR) { ctsio->kern_data_ptr = echo_descr; len = min(len, sizeof(echo_descr)); } else { if (lun->write_buffer == NULL) { lun->write_buffer = malloc(CTL_WRITE_BUFFER_SIZE, M_CTL, M_WAITOK); } ctsio->kern_data_ptr = lun->write_buffer + buffer_offset; } ctsio->kern_data_len = len; ctsio->kern_total_len = len; ctsio->kern_rel_offset = 0; ctsio->kern_sg_entries = 0; ctl_set_success(ctsio); ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } int ctl_write_buffer(struct ctl_scsiio *ctsio) { struct ctl_lun *lun = CTL_LUN(ctsio); struct scsi_write_buffer *cdb; int buffer_offset, len; CTL_DEBUG_PRINT(("ctl_write_buffer\n")); cdb = (struct scsi_write_buffer *)ctsio->cdb; len = scsi_3btoul(cdb->length); buffer_offset = scsi_3btoul(cdb->offset); if (buffer_offset + len > CTL_WRITE_BUFFER_SIZE) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 6, /*bit_valid*/ 0, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } /* * If we've got a kernel request that hasn't been malloced yet, * malloc it and tell the caller the data buffer is here. */ if ((ctsio->io_hdr.flags & CTL_FLAG_ALLOCATED) == 0) { if (lun->write_buffer == NULL) { lun->write_buffer = malloc(CTL_WRITE_BUFFER_SIZE, M_CTL, M_WAITOK); } ctsio->kern_data_ptr = lun->write_buffer + buffer_offset; ctsio->kern_data_len = len; ctsio->kern_total_len = len; ctsio->kern_rel_offset = 0; ctsio->kern_sg_entries = 0; ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } ctl_set_success(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } static int ctl_write_same_cont(union ctl_io *io) { struct ctl_lun *lun = CTL_LUN(io); struct ctl_scsiio *ctsio; struct ctl_lba_len_flags *lbalen; int retval; ctsio = &io->scsiio; ctsio->io_hdr.status = CTL_STATUS_NONE; lbalen = (struct ctl_lba_len_flags *) &ctsio->io_hdr.ctl_private[CTL_PRIV_LBA_LEN]; lbalen->lba += lbalen->len; if ((lun->be_lun->maxlba + 1) - lbalen->lba <= UINT32_MAX) { ctsio->io_hdr.flags &= ~CTL_FLAG_IO_CONT; lbalen->len = (lun->be_lun->maxlba + 1) - lbalen->lba; } CTL_DEBUG_PRINT(("ctl_write_same_cont: calling config_write()\n")); retval = lun->backend->config_write((union ctl_io *)ctsio); return (retval); } int ctl_write_same(struct ctl_scsiio *ctsio) { struct ctl_lun *lun = CTL_LUN(ctsio); struct ctl_lba_len_flags *lbalen; const char *val; uint64_t lba, ival; uint32_t num_blocks; int len, retval; uint8_t byte2; CTL_DEBUG_PRINT(("ctl_write_same\n")); switch (ctsio->cdb[0]) { case WRITE_SAME_10: { struct scsi_write_same_10 *cdb; cdb = (struct scsi_write_same_10 *)ctsio->cdb; lba = scsi_4btoul(cdb->addr); num_blocks = scsi_2btoul(cdb->length); byte2 = cdb->byte2; break; } case WRITE_SAME_16: { struct scsi_write_same_16 *cdb; cdb = (struct scsi_write_same_16 *)ctsio->cdb; lba = scsi_8btou64(cdb->addr); num_blocks = scsi_4btoul(cdb->length); byte2 = cdb->byte2; break; } default: /* * We got a command we don't support. This shouldn't * happen, commands should be filtered out above us. */ ctl_set_invalid_opcode(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); break; /* NOTREACHED */ } /* ANCHOR flag can be used only together with UNMAP */ if ((byte2 & SWS_UNMAP) == 0 && (byte2 & SWS_ANCHOR) != 0) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 1, /*bit_valid*/ 1, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } /* * The first check is to make sure we're in bounds, the second * check is to catch wrap-around problems. If the lba + num blocks * is less than the lba, then we've wrapped around and the block * range is invalid anyway. */ if (((lba + num_blocks) > (lun->be_lun->maxlba + 1)) || ((lba + num_blocks) < lba)) { ctl_set_lba_out_of_range(ctsio, MAX(lba, lun->be_lun->maxlba + 1)); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } /* Zero number of blocks means "to the last logical block" */ if (num_blocks == 0) { ival = UINT64_MAX; val = dnvlist_get_string(lun->be_lun->options, "write_same_max_lba", NULL); if (val != NULL) ctl_expand_number(val, &ival); if ((lun->be_lun->maxlba + 1) - lba > ival) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ ctsio->cdb[0] == WRITE_SAME_10 ? 7 : 10, /*bit_valid*/ 0, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } if ((lun->be_lun->maxlba + 1) - lba > UINT32_MAX) { ctsio->io_hdr.flags |= CTL_FLAG_IO_CONT; ctsio->io_cont = ctl_write_same_cont; num_blocks = 1 << 31; } else num_blocks = (lun->be_lun->maxlba + 1) - lba; } len = lun->be_lun->blocksize; /* * If we've got a kernel request that hasn't been malloced yet, * malloc it and tell the caller the data buffer is here. */ if ((byte2 & SWS_NDOB) == 0 && (ctsio->io_hdr.flags & CTL_FLAG_ALLOCATED) == 0) { ctsio->kern_data_ptr = malloc(len, M_CTL, M_WAITOK); ctsio->kern_data_len = len; ctsio->kern_total_len = len; ctsio->kern_rel_offset = 0; ctsio->kern_sg_entries = 0; ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } lbalen = (struct ctl_lba_len_flags *)&ctsio->io_hdr.ctl_private[CTL_PRIV_LBA_LEN]; lbalen->lba = lba; lbalen->len = num_blocks; lbalen->flags = byte2; retval = lun->backend->config_write((union ctl_io *)ctsio); return (retval); } int ctl_unmap(struct ctl_scsiio *ctsio) { struct ctl_lun *lun = CTL_LUN(ctsio); struct scsi_unmap *cdb; struct ctl_ptr_len_flags *ptrlen; struct scsi_unmap_header *hdr; struct scsi_unmap_desc *buf, *end, *endnz, *range; uint64_t lba; uint32_t num_blocks; int len, retval; uint8_t byte2; CTL_DEBUG_PRINT(("ctl_unmap\n")); cdb = (struct scsi_unmap *)ctsio->cdb; len = scsi_2btoul(cdb->length); byte2 = cdb->byte2; /* * If we've got a kernel request that hasn't been malloced yet, * malloc it and tell the caller the data buffer is here. */ if ((ctsio->io_hdr.flags & CTL_FLAG_ALLOCATED) == 0) { ctsio->kern_data_ptr = malloc(len, M_CTL, M_WAITOK); ctsio->kern_data_len = len; ctsio->kern_total_len = len; ctsio->kern_rel_offset = 0; ctsio->kern_sg_entries = 0; ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } len = ctsio->kern_total_len - ctsio->kern_data_resid; hdr = (struct scsi_unmap_header *)ctsio->kern_data_ptr; if (len < sizeof (*hdr) || len < (scsi_2btoul(hdr->length) + sizeof(hdr->length)) || len < (scsi_2btoul(hdr->desc_length) + sizeof (*hdr)) || scsi_2btoul(hdr->desc_length) % sizeof(*buf) != 0) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 0, /*command*/ 0, /*field*/ 0, /*bit_valid*/ 0, /*bit*/ 0); goto done; } len = scsi_2btoul(hdr->desc_length); buf = (struct scsi_unmap_desc *)(hdr + 1); end = buf + len / sizeof(*buf); endnz = buf; for (range = buf; range < end; range++) { lba = scsi_8btou64(range->lba); num_blocks = scsi_4btoul(range->length); if (((lba + num_blocks) > (lun->be_lun->maxlba + 1)) || ((lba + num_blocks) < lba)) { ctl_set_lba_out_of_range(ctsio, MAX(lba, lun->be_lun->maxlba + 1)); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } if (num_blocks != 0) endnz = range + 1; } /* * Block backend can not handle zero last range. * Filter it out and return if there is nothing left. */ len = (uint8_t *)endnz - (uint8_t *)buf; if (len == 0) { ctl_set_success(ctsio); goto done; } mtx_lock(&lun->lun_lock); ptrlen = (struct ctl_ptr_len_flags *) &ctsio->io_hdr.ctl_private[CTL_PRIV_LBA_LEN]; ptrlen->ptr = (void *)buf; ptrlen->len = len; ptrlen->flags = byte2; ctl_try_unblock_others(lun, (union ctl_io *)ctsio, FALSE); mtx_unlock(&lun->lun_lock); retval = lun->backend->config_write((union ctl_io *)ctsio); return (retval); done: if (ctsio->io_hdr.flags & CTL_FLAG_ALLOCATED) { free(ctsio->kern_data_ptr, M_CTL); ctsio->io_hdr.flags &= ~CTL_FLAG_ALLOCATED; } ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } int ctl_default_page_handler(struct ctl_scsiio *ctsio, struct ctl_page_index *page_index, uint8_t *page_ptr) { struct ctl_lun *lun = CTL_LUN(ctsio); uint8_t *current_cp; int set_ua; uint32_t initidx; initidx = ctl_get_initindex(&ctsio->io_hdr.nexus); set_ua = 0; current_cp = (page_index->page_data + (page_index->page_len * CTL_PAGE_CURRENT)); mtx_lock(&lun->lun_lock); if (memcmp(current_cp, page_ptr, page_index->page_len)) { memcpy(current_cp, page_ptr, page_index->page_len); set_ua = 1; } if (set_ua != 0) ctl_est_ua_all(lun, initidx, CTL_UA_MODE_CHANGE); mtx_unlock(&lun->lun_lock); if (set_ua) { ctl_isc_announce_mode(lun, ctl_get_initindex(&ctsio->io_hdr.nexus), page_index->page_code, page_index->subpage); } return (CTL_RETVAL_COMPLETE); } static void ctl_ie_timer(void *arg) { struct ctl_lun *lun = arg; uint64_t t; if (lun->ie_asc == 0) return; if (lun->MODE_IE.mrie == SIEP_MRIE_UA) ctl_est_ua_all(lun, -1, CTL_UA_IE); else lun->ie_reported = 0; if (lun->ie_reportcnt < scsi_4btoul(lun->MODE_IE.report_count)) { lun->ie_reportcnt++; t = scsi_4btoul(lun->MODE_IE.interval_timer); if (t == 0 || t == UINT32_MAX) t = 3000; /* 5 min */ callout_schedule(&lun->ie_callout, t * hz / 10); } } int ctl_ie_page_handler(struct ctl_scsiio *ctsio, struct ctl_page_index *page_index, uint8_t *page_ptr) { struct ctl_lun *lun = CTL_LUN(ctsio); struct scsi_info_exceptions_page *pg; uint64_t t; (void)ctl_default_page_handler(ctsio, page_index, page_ptr); pg = (struct scsi_info_exceptions_page *)page_ptr; mtx_lock(&lun->lun_lock); if (pg->info_flags & SIEP_FLAGS_TEST) { lun->ie_asc = 0x5d; lun->ie_ascq = 0xff; if (pg->mrie == SIEP_MRIE_UA) { ctl_est_ua_all(lun, -1, CTL_UA_IE); lun->ie_reported = 1; } else { ctl_clr_ua_all(lun, -1, CTL_UA_IE); lun->ie_reported = -1; } lun->ie_reportcnt = 1; if (lun->ie_reportcnt < scsi_4btoul(pg->report_count)) { lun->ie_reportcnt++; t = scsi_4btoul(pg->interval_timer); if (t == 0 || t == UINT32_MAX) t = 3000; /* 5 min */ callout_reset(&lun->ie_callout, t * hz / 10, ctl_ie_timer, lun); } } else { lun->ie_asc = 0; lun->ie_ascq = 0; lun->ie_reported = 1; ctl_clr_ua_all(lun, -1, CTL_UA_IE); lun->ie_reportcnt = UINT32_MAX; callout_stop(&lun->ie_callout); } mtx_unlock(&lun->lun_lock); return (CTL_RETVAL_COMPLETE); } static int ctl_do_mode_select(union ctl_io *io) { struct ctl_lun *lun = CTL_LUN(io); struct scsi_mode_page_header *page_header; struct ctl_page_index *page_index; struct ctl_scsiio *ctsio; int page_len, page_len_offset, page_len_size; union ctl_modepage_info *modepage_info; uint16_t *len_left, *len_used; int retval, i; ctsio = &io->scsiio; page_index = NULL; page_len = 0; modepage_info = (union ctl_modepage_info *) ctsio->io_hdr.ctl_private[CTL_PRIV_MODEPAGE].bytes; len_left = &modepage_info->header.len_left; len_used = &modepage_info->header.len_used; do_next_page: page_header = (struct scsi_mode_page_header *) (ctsio->kern_data_ptr + *len_used); if (*len_left == 0) { free(ctsio->kern_data_ptr, M_CTL); ctl_set_success(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } else if (*len_left < sizeof(struct scsi_mode_page_header)) { free(ctsio->kern_data_ptr, M_CTL); ctl_set_param_len_error(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } else if ((page_header->page_code & SMPH_SPF) && (*len_left < sizeof(struct scsi_mode_page_header_sp))) { free(ctsio->kern_data_ptr, M_CTL); ctl_set_param_len_error(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } /* * XXX KDM should we do something with the block descriptor? */ for (i = 0; i < CTL_NUM_MODE_PAGES; i++) { page_index = &lun->mode_pages.index[i]; if (lun->be_lun->lun_type == T_DIRECT && (page_index->page_flags & CTL_PAGE_FLAG_DIRECT) == 0) continue; if (lun->be_lun->lun_type == T_PROCESSOR && (page_index->page_flags & CTL_PAGE_FLAG_PROC) == 0) continue; if (lun->be_lun->lun_type == T_CDROM && (page_index->page_flags & CTL_PAGE_FLAG_CDROM) == 0) continue; if ((page_index->page_code & SMPH_PC_MASK) != (page_header->page_code & SMPH_PC_MASK)) continue; /* * If neither page has a subpage code, then we've got a * match. */ if (((page_index->page_code & SMPH_SPF) == 0) && ((page_header->page_code & SMPH_SPF) == 0)) { page_len = page_header->page_length; break; } /* * If both pages have subpages, then the subpage numbers * have to match. */ if ((page_index->page_code & SMPH_SPF) && (page_header->page_code & SMPH_SPF)) { struct scsi_mode_page_header_sp *sph; sph = (struct scsi_mode_page_header_sp *)page_header; if (page_index->subpage == sph->subpage) { page_len = scsi_2btoul(sph->page_length); break; } } } /* * If we couldn't find the page, or if we don't have a mode select * handler for it, send back an error to the user. */ if ((i >= CTL_NUM_MODE_PAGES) || (page_index->select_handler == NULL)) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 0, /*field*/ *len_used, /*bit_valid*/ 0, /*bit*/ 0); free(ctsio->kern_data_ptr, M_CTL); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } if (page_index->page_code & SMPH_SPF) { page_len_offset = 2; page_len_size = 2; } else { page_len_size = 1; page_len_offset = 1; } /* * If the length the initiator gives us isn't the one we specify in * the mode page header, or if they didn't specify enough data in * the CDB to avoid truncating this page, kick out the request. */ if (page_len != page_index->page_len - page_len_offset - page_len_size) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 0, /*field*/ *len_used + page_len_offset, /*bit_valid*/ 0, /*bit*/ 0); free(ctsio->kern_data_ptr, M_CTL); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } if (*len_left < page_index->page_len) { free(ctsio->kern_data_ptr, M_CTL); ctl_set_param_len_error(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } /* * Run through the mode page, checking to make sure that the bits * the user changed are actually legal for him to change. */ for (i = 0; i < page_index->page_len; i++) { uint8_t *user_byte, *change_mask, *current_byte; int bad_bit; int j; user_byte = (uint8_t *)page_header + i; change_mask = page_index->page_data + (page_index->page_len * CTL_PAGE_CHANGEABLE) + i; current_byte = page_index->page_data + (page_index->page_len * CTL_PAGE_CURRENT) + i; /* * Check to see whether the user set any bits in this byte * that he is not allowed to set. */ if ((*user_byte & ~(*change_mask)) == (*current_byte & ~(*change_mask))) continue; /* * Go through bit by bit to determine which one is illegal. */ bad_bit = 0; for (j = 7; j >= 0; j--) { if ((((1 << i) & ~(*change_mask)) & *user_byte) != (((1 << i) & ~(*change_mask)) & *current_byte)) { bad_bit = i; break; } } ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 0, /*field*/ *len_used + i, /*bit_valid*/ 1, /*bit*/ bad_bit); free(ctsio->kern_data_ptr, M_CTL); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } /* * Decrement these before we call the page handler, since we may * end up getting called back one way or another before the handler * returns to this context. */ *len_left -= page_index->page_len; *len_used += page_index->page_len; retval = page_index->select_handler(ctsio, page_index, (uint8_t *)page_header); /* * If the page handler returns CTL_RETVAL_QUEUED, then we need to * wait until this queued command completes to finish processing * the mode page. If it returns anything other than * CTL_RETVAL_COMPLETE (e.g. CTL_RETVAL_ERROR), then it should have * already set the sense information, freed the data pointer, and * completed the io for us. */ if (retval != CTL_RETVAL_COMPLETE) goto bailout_no_done; /* * If the initiator sent us more than one page, parse the next one. */ if (*len_left > 0) goto do_next_page; ctl_set_success(ctsio); free(ctsio->kern_data_ptr, M_CTL); ctl_done((union ctl_io *)ctsio); bailout_no_done: return (CTL_RETVAL_COMPLETE); } int ctl_mode_select(struct ctl_scsiio *ctsio) { struct ctl_lun *lun = CTL_LUN(ctsio); union ctl_modepage_info *modepage_info; int bd_len, i, header_size, param_len, rtd; uint32_t initidx; initidx = ctl_get_initindex(&ctsio->io_hdr.nexus); switch (ctsio->cdb[0]) { case MODE_SELECT_6: { struct scsi_mode_select_6 *cdb; cdb = (struct scsi_mode_select_6 *)ctsio->cdb; rtd = (cdb->byte2 & SMS_RTD) ? 1 : 0; param_len = cdb->length; header_size = sizeof(struct scsi_mode_header_6); break; } case MODE_SELECT_10: { struct scsi_mode_select_10 *cdb; cdb = (struct scsi_mode_select_10 *)ctsio->cdb; rtd = (cdb->byte2 & SMS_RTD) ? 1 : 0; param_len = scsi_2btoul(cdb->length); header_size = sizeof(struct scsi_mode_header_10); break; } default: ctl_set_invalid_opcode(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } if (rtd) { if (param_len != 0) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 0, /*command*/ 1, /*field*/ 0, /*bit_valid*/ 0, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } /* Revert to defaults. */ ctl_init_page_index(lun); mtx_lock(&lun->lun_lock); ctl_est_ua_all(lun, initidx, CTL_UA_MODE_CHANGE); mtx_unlock(&lun->lun_lock); for (i = 0; i < CTL_NUM_MODE_PAGES; i++) { ctl_isc_announce_mode(lun, -1, lun->mode_pages.index[i].page_code & SMPH_PC_MASK, lun->mode_pages.index[i].subpage); } ctl_set_success(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } /* * From SPC-3: * "A parameter list length of zero indicates that the Data-Out Buffer * shall be empty. This condition shall not be considered as an error." */ if (param_len == 0) { ctl_set_success(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } /* * Since we'll hit this the first time through, prior to * allocation, we don't need to free a data buffer here. */ if (param_len < header_size) { ctl_set_param_len_error(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } /* * Allocate the data buffer and grab the user's data. In theory, * we shouldn't have to sanity check the parameter list length here * because the maximum size is 64K. We should be able to malloc * that much without too many problems. */ if ((ctsio->io_hdr.flags & CTL_FLAG_ALLOCATED) == 0) { ctsio->kern_data_ptr = malloc(param_len, M_CTL, M_WAITOK); ctsio->kern_data_len = param_len; ctsio->kern_total_len = param_len; ctsio->kern_rel_offset = 0; ctsio->kern_sg_entries = 0; ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } switch (ctsio->cdb[0]) { case MODE_SELECT_6: { struct scsi_mode_header_6 *mh6; mh6 = (struct scsi_mode_header_6 *)ctsio->kern_data_ptr; bd_len = mh6->blk_desc_len; break; } case MODE_SELECT_10: { struct scsi_mode_header_10 *mh10; mh10 = (struct scsi_mode_header_10 *)ctsio->kern_data_ptr; bd_len = scsi_2btoul(mh10->blk_desc_len); break; } default: panic("%s: Invalid CDB type %#x", __func__, ctsio->cdb[0]); } if (param_len < (header_size + bd_len)) { free(ctsio->kern_data_ptr, M_CTL); ctl_set_param_len_error(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } /* * Set the IO_CONT flag, so that if this I/O gets passed to * ctl_config_write_done(), it'll get passed back to * ctl_do_mode_select() for further processing, or completion if * we're all done. */ ctsio->io_hdr.flags |= CTL_FLAG_IO_CONT; ctsio->io_cont = ctl_do_mode_select; modepage_info = (union ctl_modepage_info *) ctsio->io_hdr.ctl_private[CTL_PRIV_MODEPAGE].bytes; memset(modepage_info, 0, sizeof(*modepage_info)); modepage_info->header.len_left = param_len - header_size - bd_len; modepage_info->header.len_used = header_size + bd_len; return (ctl_do_mode_select((union ctl_io *)ctsio)); } int ctl_mode_sense(struct ctl_scsiio *ctsio) { struct ctl_lun *lun = CTL_LUN(ctsio); int pc, page_code, llba, subpage; int alloc_len, page_len, header_len, bd_len, total_len; void *block_desc; struct ctl_page_index *page_index; llba = 0; CTL_DEBUG_PRINT(("ctl_mode_sense\n")); switch (ctsio->cdb[0]) { case MODE_SENSE_6: { struct scsi_mode_sense_6 *cdb; cdb = (struct scsi_mode_sense_6 *)ctsio->cdb; header_len = sizeof(struct scsi_mode_hdr_6); if (cdb->byte2 & SMS_DBD) bd_len = 0; else bd_len = sizeof(struct scsi_mode_block_descr); header_len += bd_len; pc = (cdb->page & SMS_PAGE_CTRL_MASK) >> 6; page_code = cdb->page & SMS_PAGE_CODE; subpage = cdb->subpage; alloc_len = cdb->length; break; } case MODE_SENSE_10: { struct scsi_mode_sense_10 *cdb; cdb = (struct scsi_mode_sense_10 *)ctsio->cdb; header_len = sizeof(struct scsi_mode_hdr_10); if (cdb->byte2 & SMS_DBD) { bd_len = 0; } else if (lun->be_lun->lun_type == T_DIRECT) { if (cdb->byte2 & SMS10_LLBAA) { llba = 1; bd_len = sizeof(struct scsi_mode_block_descr_dlong); } else bd_len = sizeof(struct scsi_mode_block_descr_dshort); } else bd_len = sizeof(struct scsi_mode_block_descr); header_len += bd_len; pc = (cdb->page & SMS_PAGE_CTRL_MASK) >> 6; page_code = cdb->page & SMS_PAGE_CODE; subpage = cdb->subpage; alloc_len = scsi_2btoul(cdb->length); break; } default: ctl_set_invalid_opcode(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); break; /* NOTREACHED */ } /* * We have to make a first pass through to calculate the size of * the pages that match the user's query. Then we allocate enough * memory to hold it, and actually copy the data into the buffer. */ switch (page_code) { case SMS_ALL_PAGES_PAGE: { u_int i; page_len = 0; /* * At the moment, values other than 0 and 0xff here are * reserved according to SPC-3. */ if ((subpage != SMS_SUBPAGE_PAGE_0) && (subpage != SMS_SUBPAGE_ALL)) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 3, /*bit_valid*/ 0, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } for (i = 0; i < CTL_NUM_MODE_PAGES; i++) { page_index = &lun->mode_pages.index[i]; /* Make sure the page is supported for this dev type */ if (lun->be_lun->lun_type == T_DIRECT && (page_index->page_flags & CTL_PAGE_FLAG_DIRECT) == 0) continue; if (lun->be_lun->lun_type == T_PROCESSOR && (page_index->page_flags & CTL_PAGE_FLAG_PROC) == 0) continue; if (lun->be_lun->lun_type == T_CDROM && (page_index->page_flags & CTL_PAGE_FLAG_CDROM) == 0) continue; /* * We don't use this subpage if the user didn't * request all subpages. */ if ((page_index->subpage != 0) && (subpage == SMS_SUBPAGE_PAGE_0)) continue; page_len += page_index->page_len; } break; } default: { u_int i; page_len = 0; for (i = 0; i < CTL_NUM_MODE_PAGES; i++) { page_index = &lun->mode_pages.index[i]; /* Make sure the page is supported for this dev type */ if (lun->be_lun->lun_type == T_DIRECT && (page_index->page_flags & CTL_PAGE_FLAG_DIRECT) == 0) continue; if (lun->be_lun->lun_type == T_PROCESSOR && (page_index->page_flags & CTL_PAGE_FLAG_PROC) == 0) continue; if (lun->be_lun->lun_type == T_CDROM && (page_index->page_flags & CTL_PAGE_FLAG_CDROM) == 0) continue; /* Look for the right page code */ if ((page_index->page_code & SMPH_PC_MASK) != page_code) continue; /* Look for the right subpage or the subpage wildcard*/ if ((page_index->subpage != subpage) && (subpage != SMS_SUBPAGE_ALL)) continue; page_len += page_index->page_len; } if (page_len == 0) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 2, /*bit_valid*/ 1, /*bit*/ 5); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } break; } } total_len = header_len + page_len; ctsio->kern_data_ptr = malloc(total_len, M_CTL, M_WAITOK | M_ZERO); ctsio->kern_sg_entries = 0; ctsio->kern_rel_offset = 0; ctsio->kern_data_len = min(total_len, alloc_len); ctsio->kern_total_len = ctsio->kern_data_len; switch (ctsio->cdb[0]) { case MODE_SENSE_6: { struct scsi_mode_hdr_6 *header; header = (struct scsi_mode_hdr_6 *)ctsio->kern_data_ptr; header->datalen = MIN(total_len - 1, 254); if (lun->be_lun->lun_type == T_DIRECT) { header->dev_specific = 0x10; /* DPOFUA */ if ((lun->be_lun->flags & CTL_LUN_FLAG_READONLY) || (lun->MODE_CTRL.eca_and_aen & SCP_SWP) != 0) header->dev_specific |= 0x80; /* WP */ } header->block_descr_len = bd_len; block_desc = &header[1]; break; } case MODE_SENSE_10: { struct scsi_mode_hdr_10 *header; int datalen; header = (struct scsi_mode_hdr_10 *)ctsio->kern_data_ptr; datalen = MIN(total_len - 2, 65533); scsi_ulto2b(datalen, header->datalen); if (lun->be_lun->lun_type == T_DIRECT) { header->dev_specific = 0x10; /* DPOFUA */ if ((lun->be_lun->flags & CTL_LUN_FLAG_READONLY) || (lun->MODE_CTRL.eca_and_aen & SCP_SWP) != 0) header->dev_specific |= 0x80; /* WP */ } if (llba) header->flags |= SMH_LONGLBA; scsi_ulto2b(bd_len, header->block_descr_len); block_desc = &header[1]; break; } default: panic("%s: Invalid CDB type %#x", __func__, ctsio->cdb[0]); } /* * If we've got a disk, use its blocksize in the block * descriptor. Otherwise, just set it to 0. */ if (bd_len > 0) { if (lun->be_lun->lun_type == T_DIRECT) { if (llba) { struct scsi_mode_block_descr_dlong *bd = block_desc; if (lun->be_lun->maxlba != 0) scsi_u64to8b(lun->be_lun->maxlba + 1, bd->num_blocks); scsi_ulto4b(lun->be_lun->blocksize, bd->block_len); } else { struct scsi_mode_block_descr_dshort *bd = block_desc; if (lun->be_lun->maxlba != 0) scsi_ulto4b(MIN(lun->be_lun->maxlba+1, UINT32_MAX), bd->num_blocks); scsi_ulto3b(lun->be_lun->blocksize, bd->block_len); } } else { struct scsi_mode_block_descr *bd = block_desc; scsi_ulto3b(0, bd->block_len); } } switch (page_code) { case SMS_ALL_PAGES_PAGE: { int i, data_used; data_used = header_len; for (i = 0; i < CTL_NUM_MODE_PAGES; i++) { struct ctl_page_index *page_index; page_index = &lun->mode_pages.index[i]; if (lun->be_lun->lun_type == T_DIRECT && (page_index->page_flags & CTL_PAGE_FLAG_DIRECT) == 0) continue; if (lun->be_lun->lun_type == T_PROCESSOR && (page_index->page_flags & CTL_PAGE_FLAG_PROC) == 0) continue; if (lun->be_lun->lun_type == T_CDROM && (page_index->page_flags & CTL_PAGE_FLAG_CDROM) == 0) continue; /* * We don't use this subpage if the user didn't * request all subpages. We already checked (above) * to make sure the user only specified a subpage * of 0 or 0xff in the SMS_ALL_PAGES_PAGE case. */ if ((page_index->subpage != 0) && (subpage == SMS_SUBPAGE_PAGE_0)) continue; /* * Call the handler, if it exists, to update the * page to the latest values. */ if (page_index->sense_handler != NULL) page_index->sense_handler(ctsio, page_index,pc); memcpy(ctsio->kern_data_ptr + data_used, page_index->page_data + (page_index->page_len * pc), page_index->page_len); data_used += page_index->page_len; } break; } default: { int i, data_used; data_used = header_len; for (i = 0; i < CTL_NUM_MODE_PAGES; i++) { struct ctl_page_index *page_index; page_index = &lun->mode_pages.index[i]; /* Look for the right page code */ if ((page_index->page_code & SMPH_PC_MASK) != page_code) continue; /* Look for the right subpage or the subpage wildcard*/ if ((page_index->subpage != subpage) && (subpage != SMS_SUBPAGE_ALL)) continue; /* Make sure the page is supported for this dev type */ if (lun->be_lun->lun_type == T_DIRECT && (page_index->page_flags & CTL_PAGE_FLAG_DIRECT) == 0) continue; if (lun->be_lun->lun_type == T_PROCESSOR && (page_index->page_flags & CTL_PAGE_FLAG_PROC) == 0) continue; if (lun->be_lun->lun_type == T_CDROM && (page_index->page_flags & CTL_PAGE_FLAG_CDROM) == 0) continue; /* * Call the handler, if it exists, to update the * page to the latest values. */ if (page_index->sense_handler != NULL) page_index->sense_handler(ctsio, page_index,pc); memcpy(ctsio->kern_data_ptr + data_used, page_index->page_data + (page_index->page_len * pc), page_index->page_len); data_used += page_index->page_len; } break; } } ctl_set_success(ctsio); ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } int ctl_temp_log_sense_handler(struct ctl_scsiio *ctsio, struct ctl_page_index *page_index, int pc) { struct ctl_lun *lun = CTL_LUN(ctsio); struct scsi_log_temperature *data; const char *value; data = (struct scsi_log_temperature *)page_index->page_data; scsi_ulto2b(SLP_TEMPERATURE, data->hdr.param_code); data->hdr.param_control = SLP_LBIN; data->hdr.param_len = sizeof(struct scsi_log_temperature) - sizeof(struct scsi_log_param_header); if ((value = dnvlist_get_string(lun->be_lun->options, "temperature", NULL)) != NULL) data->temperature = strtol(value, NULL, 0); else data->temperature = 0xff; data++; scsi_ulto2b(SLP_REFTEMPERATURE, data->hdr.param_code); data->hdr.param_control = SLP_LBIN; data->hdr.param_len = sizeof(struct scsi_log_temperature) - sizeof(struct scsi_log_param_header); if ((value = dnvlist_get_string(lun->be_lun->options, "reftemperature", NULL)) != NULL) data->temperature = strtol(value, NULL, 0); else data->temperature = 0xff; return (0); } int ctl_lbp_log_sense_handler(struct ctl_scsiio *ctsio, struct ctl_page_index *page_index, int pc) { struct ctl_lun *lun = CTL_LUN(ctsio); struct scsi_log_param_header *phdr; uint8_t *data; uint64_t val; data = page_index->page_data; if (lun->backend->lun_attr != NULL && (val = lun->backend->lun_attr(lun->be_lun, "blocksavail")) != UINT64_MAX) { phdr = (struct scsi_log_param_header *)data; scsi_ulto2b(0x0001, phdr->param_code); phdr->param_control = SLP_LBIN | SLP_LP; phdr->param_len = 8; data = (uint8_t *)(phdr + 1); scsi_ulto4b(val >> CTL_LBP_EXPONENT, data); data[4] = 0x02; /* per-pool */ data += phdr->param_len; } if (lun->backend->lun_attr != NULL && (val = lun->backend->lun_attr(lun->be_lun, "blocksused")) != UINT64_MAX) { phdr = (struct scsi_log_param_header *)data; scsi_ulto2b(0x0002, phdr->param_code); phdr->param_control = SLP_LBIN | SLP_LP; phdr->param_len = 8; data = (uint8_t *)(phdr + 1); scsi_ulto4b(val >> CTL_LBP_EXPONENT, data); data[4] = 0x01; /* per-LUN */ data += phdr->param_len; } if (lun->backend->lun_attr != NULL && (val = lun->backend->lun_attr(lun->be_lun, "poolblocksavail")) != UINT64_MAX) { phdr = (struct scsi_log_param_header *)data; scsi_ulto2b(0x00f1, phdr->param_code); phdr->param_control = SLP_LBIN | SLP_LP; phdr->param_len = 8; data = (uint8_t *)(phdr + 1); scsi_ulto4b(val >> CTL_LBP_EXPONENT, data); data[4] = 0x02; /* per-pool */ data += phdr->param_len; } if (lun->backend->lun_attr != NULL && (val = lun->backend->lun_attr(lun->be_lun, "poolblocksused")) != UINT64_MAX) { phdr = (struct scsi_log_param_header *)data; scsi_ulto2b(0x00f2, phdr->param_code); phdr->param_control = SLP_LBIN | SLP_LP; phdr->param_len = 8; data = (uint8_t *)(phdr + 1); scsi_ulto4b(val >> CTL_LBP_EXPONENT, data); data[4] = 0x02; /* per-pool */ data += phdr->param_len; } page_index->page_len = data - page_index->page_data; return (0); } int ctl_sap_log_sense_handler(struct ctl_scsiio *ctsio, struct ctl_page_index *page_index, int pc) { struct ctl_lun *lun = CTL_LUN(ctsio); struct stat_page *data; struct bintime *t; data = (struct stat_page *)page_index->page_data; scsi_ulto2b(SLP_SAP, data->sap.hdr.param_code); data->sap.hdr.param_control = SLP_LBIN; data->sap.hdr.param_len = sizeof(struct scsi_log_stat_and_perf) - sizeof(struct scsi_log_param_header); scsi_u64to8b(lun->stats.operations[CTL_STATS_READ], data->sap.read_num); scsi_u64to8b(lun->stats.operations[CTL_STATS_WRITE], data->sap.write_num); if (lun->be_lun->blocksize > 0) { scsi_u64to8b(lun->stats.bytes[CTL_STATS_WRITE] / lun->be_lun->blocksize, data->sap.recvieved_lba); scsi_u64to8b(lun->stats.bytes[CTL_STATS_READ] / lun->be_lun->blocksize, data->sap.transmitted_lba); } t = &lun->stats.time[CTL_STATS_READ]; scsi_u64to8b((uint64_t)t->sec * 1000 + t->frac / (UINT64_MAX / 1000), data->sap.read_int); t = &lun->stats.time[CTL_STATS_WRITE]; scsi_u64to8b((uint64_t)t->sec * 1000 + t->frac / (UINT64_MAX / 1000), data->sap.write_int); scsi_u64to8b(0, data->sap.weighted_num); scsi_u64to8b(0, data->sap.weighted_int); scsi_ulto2b(SLP_IT, data->it.hdr.param_code); data->it.hdr.param_control = SLP_LBIN; data->it.hdr.param_len = sizeof(struct scsi_log_idle_time) - sizeof(struct scsi_log_param_header); #ifdef CTL_TIME_IO scsi_u64to8b(lun->idle_time / SBT_1MS, data->it.idle_int); #endif scsi_ulto2b(SLP_TI, data->ti.hdr.param_code); data->it.hdr.param_control = SLP_LBIN; data->ti.hdr.param_len = sizeof(struct scsi_log_time_interval) - sizeof(struct scsi_log_param_header); scsi_ulto4b(3, data->ti.exponent); scsi_ulto4b(1, data->ti.integer); return (0); } int ctl_ie_log_sense_handler(struct ctl_scsiio *ctsio, struct ctl_page_index *page_index, int pc) { struct ctl_lun *lun = CTL_LUN(ctsio); struct scsi_log_informational_exceptions *data; const char *value; data = (struct scsi_log_informational_exceptions *)page_index->page_data; scsi_ulto2b(SLP_IE_GEN, data->hdr.param_code); data->hdr.param_control = SLP_LBIN; data->hdr.param_len = sizeof(struct scsi_log_informational_exceptions) - sizeof(struct scsi_log_param_header); data->ie_asc = lun->ie_asc; data->ie_ascq = lun->ie_ascq; if ((value = dnvlist_get_string(lun->be_lun->options, "temperature", NULL)) != NULL) data->temperature = strtol(value, NULL, 0); else data->temperature = 0xff; return (0); } int ctl_log_sense(struct ctl_scsiio *ctsio) { struct ctl_lun *lun = CTL_LUN(ctsio); int i, pc, page_code, subpage; int alloc_len, total_len; struct ctl_page_index *page_index; struct scsi_log_sense *cdb; struct scsi_log_header *header; CTL_DEBUG_PRINT(("ctl_log_sense\n")); cdb = (struct scsi_log_sense *)ctsio->cdb; pc = (cdb->page & SLS_PAGE_CTRL_MASK) >> 6; page_code = cdb->page & SLS_PAGE_CODE; subpage = cdb->subpage; alloc_len = scsi_2btoul(cdb->length); page_index = NULL; for (i = 0; i < CTL_NUM_LOG_PAGES; i++) { page_index = &lun->log_pages.index[i]; /* Look for the right page code */ if ((page_index->page_code & SL_PAGE_CODE) != page_code) continue; /* Look for the right subpage or the subpage wildcard*/ if (page_index->subpage != subpage) continue; break; } if (i >= CTL_NUM_LOG_PAGES) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 2, /*bit_valid*/ 0, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } total_len = sizeof(struct scsi_log_header) + page_index->page_len; ctsio->kern_data_ptr = malloc(total_len, M_CTL, M_WAITOK | M_ZERO); ctsio->kern_sg_entries = 0; ctsio->kern_rel_offset = 0; ctsio->kern_data_len = min(total_len, alloc_len); ctsio->kern_total_len = ctsio->kern_data_len; header = (struct scsi_log_header *)ctsio->kern_data_ptr; header->page = page_index->page_code; if (page_index->page_code == SLS_LOGICAL_BLOCK_PROVISIONING) header->page |= SL_DS; if (page_index->subpage) { header->page |= SL_SPF; header->subpage = page_index->subpage; } scsi_ulto2b(page_index->page_len, header->datalen); /* * Call the handler, if it exists, to update the * page to the latest values. */ if (page_index->sense_handler != NULL) page_index->sense_handler(ctsio, page_index, pc); memcpy(header + 1, page_index->page_data, page_index->page_len); ctl_set_success(ctsio); ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } int ctl_read_capacity(struct ctl_scsiio *ctsio) { struct ctl_lun *lun = CTL_LUN(ctsio); struct scsi_read_capacity *cdb; struct scsi_read_capacity_data *data; uint32_t lba; CTL_DEBUG_PRINT(("ctl_read_capacity\n")); cdb = (struct scsi_read_capacity *)ctsio->cdb; lba = scsi_4btoul(cdb->addr); if (((cdb->pmi & SRC_PMI) == 0) && (lba != 0)) { ctl_set_invalid_field(/*ctsio*/ ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 2, /*bit_valid*/ 0, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } ctsio->kern_data_ptr = malloc(sizeof(*data), M_CTL, M_WAITOK | M_ZERO); data = (struct scsi_read_capacity_data *)ctsio->kern_data_ptr; ctsio->kern_data_len = sizeof(*data); ctsio->kern_total_len = sizeof(*data); ctsio->kern_rel_offset = 0; ctsio->kern_sg_entries = 0; /* * If the maximum LBA is greater than 0xfffffffe, the user must * issue a SERVICE ACTION IN (16) command, with the read capacity * serivce action set. */ if (lun->be_lun->maxlba > 0xfffffffe) scsi_ulto4b(0xffffffff, data->addr); else scsi_ulto4b(lun->be_lun->maxlba, data->addr); /* * XXX KDM this may not be 512 bytes... */ scsi_ulto4b(lun->be_lun->blocksize, data->length); ctl_set_success(ctsio); ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } int ctl_read_capacity_16(struct ctl_scsiio *ctsio) { struct ctl_lun *lun = CTL_LUN(ctsio); struct scsi_read_capacity_16 *cdb; struct scsi_read_capacity_data_long *data; uint64_t lba; uint32_t alloc_len; CTL_DEBUG_PRINT(("ctl_read_capacity_16\n")); cdb = (struct scsi_read_capacity_16 *)ctsio->cdb; alloc_len = scsi_4btoul(cdb->alloc_len); lba = scsi_8btou64(cdb->addr); if ((cdb->reladr & SRC16_PMI) && (lba != 0)) { ctl_set_invalid_field(/*ctsio*/ ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 2, /*bit_valid*/ 0, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } ctsio->kern_data_ptr = malloc(sizeof(*data), M_CTL, M_WAITOK | M_ZERO); data = (struct scsi_read_capacity_data_long *)ctsio->kern_data_ptr; ctsio->kern_rel_offset = 0; ctsio->kern_sg_entries = 0; ctsio->kern_data_len = min(sizeof(*data), alloc_len); ctsio->kern_total_len = ctsio->kern_data_len; scsi_u64to8b(lun->be_lun->maxlba, data->addr); /* XXX KDM this may not be 512 bytes... */ scsi_ulto4b(lun->be_lun->blocksize, data->length); data->prot_lbppbe = lun->be_lun->pblockexp & SRC16_LBPPBE; scsi_ulto2b(lun->be_lun->pblockoff & SRC16_LALBA_A, data->lalba_lbp); if (lun->be_lun->flags & CTL_LUN_FLAG_UNMAP) data->lalba_lbp[0] |= SRC16_LBPME | SRC16_LBPRZ; ctl_set_success(ctsio); ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } int ctl_get_lba_status(struct ctl_scsiio *ctsio) { struct ctl_lun *lun = CTL_LUN(ctsio); struct scsi_get_lba_status *cdb; struct scsi_get_lba_status_data *data; struct ctl_lba_len_flags *lbalen; uint64_t lba; uint32_t alloc_len, total_len; int retval; CTL_DEBUG_PRINT(("ctl_get_lba_status\n")); cdb = (struct scsi_get_lba_status *)ctsio->cdb; lba = scsi_8btou64(cdb->addr); alloc_len = scsi_4btoul(cdb->alloc_len); if (lba > lun->be_lun->maxlba) { ctl_set_lba_out_of_range(ctsio, lba); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } total_len = sizeof(*data) + sizeof(data->descr[0]); ctsio->kern_data_ptr = malloc(total_len, M_CTL, M_WAITOK | M_ZERO); data = (struct scsi_get_lba_status_data *)ctsio->kern_data_ptr; ctsio->kern_rel_offset = 0; ctsio->kern_sg_entries = 0; ctsio->kern_data_len = min(total_len, alloc_len); ctsio->kern_total_len = ctsio->kern_data_len; /* Fill dummy data in case backend can't tell anything. */ scsi_ulto4b(4 + sizeof(data->descr[0]), data->length); scsi_u64to8b(lba, data->descr[0].addr); scsi_ulto4b(MIN(UINT32_MAX, lun->be_lun->maxlba + 1 - lba), data->descr[0].length); data->descr[0].status = 0; /* Mapped or unknown. */ ctl_set_success(ctsio); ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; lbalen = (struct ctl_lba_len_flags *)&ctsio->io_hdr.ctl_private[CTL_PRIV_LBA_LEN]; lbalen->lba = lba; lbalen->len = total_len; lbalen->flags = 0; retval = lun->backend->config_read((union ctl_io *)ctsio); return (retval); } int ctl_read_defect(struct ctl_scsiio *ctsio) { struct scsi_read_defect_data_10 *ccb10; struct scsi_read_defect_data_12 *ccb12; struct scsi_read_defect_data_hdr_10 *data10; struct scsi_read_defect_data_hdr_12 *data12; uint32_t alloc_len, data_len; uint8_t format; CTL_DEBUG_PRINT(("ctl_read_defect\n")); if (ctsio->cdb[0] == READ_DEFECT_DATA_10) { ccb10 = (struct scsi_read_defect_data_10 *)&ctsio->cdb; format = ccb10->format; alloc_len = scsi_2btoul(ccb10->alloc_length); data_len = sizeof(*data10); } else { ccb12 = (struct scsi_read_defect_data_12 *)&ctsio->cdb; format = ccb12->format; alloc_len = scsi_4btoul(ccb12->alloc_length); data_len = sizeof(*data12); } if (alloc_len == 0) { ctl_set_success(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } ctsio->kern_data_ptr = malloc(data_len, M_CTL, M_WAITOK | M_ZERO); ctsio->kern_rel_offset = 0; ctsio->kern_sg_entries = 0; ctsio->kern_data_len = min(data_len, alloc_len); ctsio->kern_total_len = ctsio->kern_data_len; if (ctsio->cdb[0] == READ_DEFECT_DATA_10) { data10 = (struct scsi_read_defect_data_hdr_10 *) ctsio->kern_data_ptr; data10->format = format; scsi_ulto2b(0, data10->length); } else { data12 = (struct scsi_read_defect_data_hdr_12 *) ctsio->kern_data_ptr; data12->format = format; scsi_ulto2b(0, data12->generation); scsi_ulto4b(0, data12->length); } ctl_set_success(ctsio); ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } int ctl_report_ident_info(struct ctl_scsiio *ctsio) { struct ctl_lun *lun = CTL_LUN(ctsio); struct scsi_report_ident_info *cdb; struct scsi_report_ident_info_data *rii_ptr; struct scsi_report_ident_info_descr *riid_ptr; const char *oii, *otii; int retval, alloc_len, total_len = 0, len = 0; CTL_DEBUG_PRINT(("ctl_report_ident_info\n")); cdb = (struct scsi_report_ident_info *)ctsio->cdb; retval = CTL_RETVAL_COMPLETE; total_len = sizeof(struct scsi_report_ident_info_data); switch (cdb->type) { case RII_LUII: oii = dnvlist_get_string(lun->be_lun->options, "ident_info", NULL); if (oii) len = strlen(oii); /* Approximately */ break; case RII_LUTII: otii = dnvlist_get_string(lun->be_lun->options, "text_ident_info", NULL); if (otii) len = strlen(otii) + 1; /* NULL-terminated */ break; case RII_IIS: len = 2 * sizeof(struct scsi_report_ident_info_descr); break; default: ctl_set_invalid_field(/*ctsio*/ ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 11, /*bit_valid*/ 1, /*bit*/ 2); ctl_done((union ctl_io *)ctsio); return(retval); } total_len += len; alloc_len = scsi_4btoul(cdb->length); ctsio->kern_data_ptr = malloc(total_len, M_CTL, M_WAITOK | M_ZERO); ctsio->kern_sg_entries = 0; ctsio->kern_rel_offset = 0; ctsio->kern_data_len = min(total_len, alloc_len); ctsio->kern_total_len = ctsio->kern_data_len; rii_ptr = (struct scsi_report_ident_info_data *)ctsio->kern_data_ptr; switch (cdb->type) { case RII_LUII: if (oii) { if (oii[0] == '0' && oii[1] == 'x') len = hex2bin(oii, (uint8_t *)(rii_ptr + 1), len); else strncpy((uint8_t *)(rii_ptr + 1), oii, len); } break; case RII_LUTII: if (otii) strlcpy((uint8_t *)(rii_ptr + 1), otii, len); break; case RII_IIS: riid_ptr = (struct scsi_report_ident_info_descr *)(rii_ptr + 1); riid_ptr->type = RII_LUII; scsi_ulto2b(0xffff, riid_ptr->length); riid_ptr++; riid_ptr->type = RII_LUTII; scsi_ulto2b(0xffff, riid_ptr->length); } scsi_ulto2b(len, rii_ptr->length); ctl_set_success(ctsio); ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return(retval); } int ctl_report_tagret_port_groups(struct ctl_scsiio *ctsio) { struct ctl_softc *softc = CTL_SOFTC(ctsio); struct ctl_lun *lun = CTL_LUN(ctsio); struct scsi_maintenance_in *cdb; int retval; int alloc_len, ext, total_len = 0, g, pc, pg, ts, os; int num_ha_groups, num_target_ports, shared_group; struct ctl_port *port; struct scsi_target_group_data *rtg_ptr; struct scsi_target_group_data_extended *rtg_ext_ptr; struct scsi_target_port_group_descriptor *tpg_desc; CTL_DEBUG_PRINT(("ctl_report_tagret_port_groups\n")); cdb = (struct scsi_maintenance_in *)ctsio->cdb; retval = CTL_RETVAL_COMPLETE; switch (cdb->byte2 & STG_PDF_MASK) { case STG_PDF_LENGTH: ext = 0; break; case STG_PDF_EXTENDED: ext = 1; break; default: ctl_set_invalid_field(/*ctsio*/ ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 2, /*bit_valid*/ 1, /*bit*/ 5); ctl_done((union ctl_io *)ctsio); return(retval); } num_target_ports = 0; shared_group = (softc->is_single != 0); mtx_lock(&softc->ctl_lock); STAILQ_FOREACH(port, &softc->port_list, links) { if ((port->status & CTL_PORT_STATUS_ONLINE) == 0) continue; if (ctl_lun_map_to_port(port, lun->lun) == UINT32_MAX) continue; num_target_ports++; if (port->status & CTL_PORT_STATUS_HA_SHARED) shared_group = 1; } mtx_unlock(&softc->ctl_lock); num_ha_groups = (softc->is_single) ? 0 : NUM_HA_SHELVES; if (ext) total_len = sizeof(struct scsi_target_group_data_extended); else total_len = sizeof(struct scsi_target_group_data); total_len += sizeof(struct scsi_target_port_group_descriptor) * (shared_group + num_ha_groups) + sizeof(struct scsi_target_port_descriptor) * num_target_ports; alloc_len = scsi_4btoul(cdb->length); ctsio->kern_data_ptr = malloc(total_len, M_CTL, M_WAITOK | M_ZERO); ctsio->kern_sg_entries = 0; ctsio->kern_rel_offset = 0; ctsio->kern_data_len = min(total_len, alloc_len); ctsio->kern_total_len = ctsio->kern_data_len; if (ext) { rtg_ext_ptr = (struct scsi_target_group_data_extended *) ctsio->kern_data_ptr; scsi_ulto4b(total_len - 4, rtg_ext_ptr->length); rtg_ext_ptr->format_type = 0x10; rtg_ext_ptr->implicit_transition_time = 0; tpg_desc = &rtg_ext_ptr->groups[0]; } else { rtg_ptr = (struct scsi_target_group_data *) ctsio->kern_data_ptr; scsi_ulto4b(total_len - 4, rtg_ptr->length); tpg_desc = &rtg_ptr->groups[0]; } mtx_lock(&softc->ctl_lock); pg = softc->port_min / softc->port_cnt; if (lun->flags & (CTL_LUN_PRIMARY_SC | CTL_LUN_PEER_SC_PRIMARY)) { /* Some shelf is known to be primary. */ if (softc->ha_link == CTL_HA_LINK_OFFLINE) os = TPG_ASYMMETRIC_ACCESS_UNAVAILABLE; else if (softc->ha_link == CTL_HA_LINK_UNKNOWN) os = TPG_ASYMMETRIC_ACCESS_TRANSITIONING; else if (softc->ha_mode == CTL_HA_MODE_ACT_STBY) os = TPG_ASYMMETRIC_ACCESS_STANDBY; else os = TPG_ASYMMETRIC_ACCESS_NONOPTIMIZED; if (lun->flags & CTL_LUN_PRIMARY_SC) { ts = TPG_ASYMMETRIC_ACCESS_OPTIMIZED; } else { ts = os; os = TPG_ASYMMETRIC_ACCESS_OPTIMIZED; } } else { /* No known primary shelf. */ if (softc->ha_link == CTL_HA_LINK_OFFLINE) { ts = TPG_ASYMMETRIC_ACCESS_UNAVAILABLE; os = TPG_ASYMMETRIC_ACCESS_OPTIMIZED; } else if (softc->ha_link == CTL_HA_LINK_UNKNOWN) { ts = TPG_ASYMMETRIC_ACCESS_TRANSITIONING; os = TPG_ASYMMETRIC_ACCESS_OPTIMIZED; } else { ts = os = TPG_ASYMMETRIC_ACCESS_TRANSITIONING; } } if (shared_group) { tpg_desc->pref_state = ts; tpg_desc->support = TPG_AO_SUP | TPG_AN_SUP | TPG_S_SUP | TPG_U_SUP | TPG_T_SUP; scsi_ulto2b(1, tpg_desc->target_port_group); tpg_desc->status = TPG_IMPLICIT; pc = 0; STAILQ_FOREACH(port, &softc->port_list, links) { if ((port->status & CTL_PORT_STATUS_ONLINE) == 0) continue; if (!softc->is_single && (port->status & CTL_PORT_STATUS_HA_SHARED) == 0) continue; if (ctl_lun_map_to_port(port, lun->lun) == UINT32_MAX) continue; scsi_ulto2b(port->targ_port, tpg_desc->descriptors[pc]. relative_target_port_identifier); pc++; } tpg_desc->target_port_count = pc; tpg_desc = (struct scsi_target_port_group_descriptor *) &tpg_desc->descriptors[pc]; } for (g = 0; g < num_ha_groups; g++) { tpg_desc->pref_state = (g == pg) ? ts : os; tpg_desc->support = TPG_AO_SUP | TPG_AN_SUP | TPG_S_SUP | TPG_U_SUP | TPG_T_SUP; scsi_ulto2b(2 + g, tpg_desc->target_port_group); tpg_desc->status = TPG_IMPLICIT; pc = 0; STAILQ_FOREACH(port, &softc->port_list, links) { if (port->targ_port < g * softc->port_cnt || port->targ_port >= (g + 1) * softc->port_cnt) continue; if ((port->status & CTL_PORT_STATUS_ONLINE) == 0) continue; if (port->status & CTL_PORT_STATUS_HA_SHARED) continue; if (ctl_lun_map_to_port(port, lun->lun) == UINT32_MAX) continue; scsi_ulto2b(port->targ_port, tpg_desc->descriptors[pc]. relative_target_port_identifier); pc++; } tpg_desc->target_port_count = pc; tpg_desc = (struct scsi_target_port_group_descriptor *) &tpg_desc->descriptors[pc]; } mtx_unlock(&softc->ctl_lock); ctl_set_success(ctsio); ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return(retval); } int ctl_report_supported_opcodes(struct ctl_scsiio *ctsio) { struct ctl_lun *lun = CTL_LUN(ctsio); struct scsi_report_supported_opcodes *cdb; const struct ctl_cmd_entry *entry, *sentry; struct scsi_report_supported_opcodes_all *all; struct scsi_report_supported_opcodes_descr *descr; struct scsi_report_supported_opcodes_one *one; int retval; int alloc_len, total_len; int opcode, service_action, i, j, num; CTL_DEBUG_PRINT(("ctl_report_supported_opcodes\n")); cdb = (struct scsi_report_supported_opcodes *)ctsio->cdb; retval = CTL_RETVAL_COMPLETE; opcode = cdb->requested_opcode; service_action = scsi_2btoul(cdb->requested_service_action); switch (cdb->options & RSO_OPTIONS_MASK) { case RSO_OPTIONS_ALL: num = 0; for (i = 0; i < 256; i++) { entry = &ctl_cmd_table[i]; if (entry->flags & CTL_CMD_FLAG_SA5) { for (j = 0; j < 32; j++) { sentry = &((const struct ctl_cmd_entry *) entry->execute)[j]; if (ctl_cmd_applicable( lun->be_lun->lun_type, sentry)) num++; } } else { if (ctl_cmd_applicable(lun->be_lun->lun_type, entry)) num++; } } total_len = sizeof(struct scsi_report_supported_opcodes_all) + num * sizeof(struct scsi_report_supported_opcodes_descr); break; case RSO_OPTIONS_OC: if (ctl_cmd_table[opcode].flags & CTL_CMD_FLAG_SA5) { ctl_set_invalid_field(/*ctsio*/ ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 2, /*bit_valid*/ 1, /*bit*/ 2); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } total_len = sizeof(struct scsi_report_supported_opcodes_one) + 32; break; case RSO_OPTIONS_OC_SA: if ((ctl_cmd_table[opcode].flags & CTL_CMD_FLAG_SA5) == 0 || service_action >= 32) { ctl_set_invalid_field(/*ctsio*/ ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 2, /*bit_valid*/ 1, /*bit*/ 2); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } /* FALLTHROUGH */ case RSO_OPTIONS_OC_ASA: total_len = sizeof(struct scsi_report_supported_opcodes_one) + 32; break; default: ctl_set_invalid_field(/*ctsio*/ ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 2, /*bit_valid*/ 1, /*bit*/ 2); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } alloc_len = scsi_4btoul(cdb->length); ctsio->kern_data_ptr = malloc(total_len, M_CTL, M_WAITOK | M_ZERO); ctsio->kern_sg_entries = 0; ctsio->kern_rel_offset = 0; ctsio->kern_data_len = min(total_len, alloc_len); ctsio->kern_total_len = ctsio->kern_data_len; switch (cdb->options & RSO_OPTIONS_MASK) { case RSO_OPTIONS_ALL: all = (struct scsi_report_supported_opcodes_all *) ctsio->kern_data_ptr; num = 0; for (i = 0; i < 256; i++) { entry = &ctl_cmd_table[i]; if (entry->flags & CTL_CMD_FLAG_SA5) { for (j = 0; j < 32; j++) { sentry = &((const struct ctl_cmd_entry *) entry->execute)[j]; if (!ctl_cmd_applicable( lun->be_lun->lun_type, sentry)) continue; descr = &all->descr[num++]; descr->opcode = i; scsi_ulto2b(j, descr->service_action); descr->flags = RSO_SERVACTV; scsi_ulto2b(sentry->length, descr->cdb_length); } } else { if (!ctl_cmd_applicable(lun->be_lun->lun_type, entry)) continue; descr = &all->descr[num++]; descr->opcode = i; scsi_ulto2b(0, descr->service_action); descr->flags = 0; scsi_ulto2b(entry->length, descr->cdb_length); } } scsi_ulto4b( num * sizeof(struct scsi_report_supported_opcodes_descr), all->length); break; case RSO_OPTIONS_OC: one = (struct scsi_report_supported_opcodes_one *) ctsio->kern_data_ptr; entry = &ctl_cmd_table[opcode]; goto fill_one; case RSO_OPTIONS_OC_SA: one = (struct scsi_report_supported_opcodes_one *) ctsio->kern_data_ptr; entry = &ctl_cmd_table[opcode]; entry = &((const struct ctl_cmd_entry *) entry->execute)[service_action]; fill_one: if (ctl_cmd_applicable(lun->be_lun->lun_type, entry)) { one->support = 3; scsi_ulto2b(entry->length, one->cdb_length); one->cdb_usage[0] = opcode; memcpy(&one->cdb_usage[1], entry->usage, entry->length - 1); } else one->support = 1; break; case RSO_OPTIONS_OC_ASA: one = (struct scsi_report_supported_opcodes_one *) ctsio->kern_data_ptr; entry = &ctl_cmd_table[opcode]; if (entry->flags & CTL_CMD_FLAG_SA5) { entry = &((const struct ctl_cmd_entry *) entry->execute)[service_action]; } else if (service_action != 0) { one->support = 1; break; } goto fill_one; } ctl_set_success(ctsio); ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return(retval); } int ctl_report_supported_tmf(struct ctl_scsiio *ctsio) { struct scsi_report_supported_tmf *cdb; struct scsi_report_supported_tmf_ext_data *data; int retval; int alloc_len, total_len; CTL_DEBUG_PRINT(("ctl_report_supported_tmf\n")); cdb = (struct scsi_report_supported_tmf *)ctsio->cdb; retval = CTL_RETVAL_COMPLETE; if (cdb->options & RST_REPD) total_len = sizeof(struct scsi_report_supported_tmf_ext_data); else total_len = sizeof(struct scsi_report_supported_tmf_data); alloc_len = scsi_4btoul(cdb->length); ctsio->kern_data_ptr = malloc(total_len, M_CTL, M_WAITOK | M_ZERO); ctsio->kern_sg_entries = 0; ctsio->kern_rel_offset = 0; ctsio->kern_data_len = min(total_len, alloc_len); ctsio->kern_total_len = ctsio->kern_data_len; data = (struct scsi_report_supported_tmf_ext_data *)ctsio->kern_data_ptr; data->byte1 |= RST_ATS | RST_ATSS | RST_CTSS | RST_LURS | RST_QTS | RST_TRS; data->byte2 |= RST_QAES | RST_QTSS | RST_ITNRS; data->length = total_len - 4; ctl_set_success(ctsio); ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (retval); } int ctl_report_timestamp(struct ctl_scsiio *ctsio) { struct scsi_report_timestamp *cdb; struct scsi_report_timestamp_data *data; struct timeval tv; int64_t timestamp; int retval; int alloc_len, total_len; CTL_DEBUG_PRINT(("ctl_report_timestamp\n")); cdb = (struct scsi_report_timestamp *)ctsio->cdb; retval = CTL_RETVAL_COMPLETE; total_len = sizeof(struct scsi_report_timestamp_data); alloc_len = scsi_4btoul(cdb->length); ctsio->kern_data_ptr = malloc(total_len, M_CTL, M_WAITOK | M_ZERO); ctsio->kern_sg_entries = 0; ctsio->kern_rel_offset = 0; ctsio->kern_data_len = min(total_len, alloc_len); ctsio->kern_total_len = ctsio->kern_data_len; data = (struct scsi_report_timestamp_data *)ctsio->kern_data_ptr; scsi_ulto2b(sizeof(*data) - 2, data->length); data->origin = RTS_ORIG_OUTSIDE; getmicrotime(&tv); timestamp = (int64_t)tv.tv_sec * 1000 + tv.tv_usec / 1000; scsi_ulto4b(timestamp >> 16, data->timestamp); scsi_ulto2b(timestamp & 0xffff, &data->timestamp[4]); ctl_set_success(ctsio); ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (retval); } int ctl_persistent_reserve_in(struct ctl_scsiio *ctsio) { struct ctl_softc *softc = CTL_SOFTC(ctsio); struct ctl_lun *lun = CTL_LUN(ctsio); struct scsi_per_res_in *cdb; int alloc_len, total_len = 0; /* struct scsi_per_res_in_rsrv in_data; */ uint64_t key; CTL_DEBUG_PRINT(("ctl_persistent_reserve_in\n")); cdb = (struct scsi_per_res_in *)ctsio->cdb; alloc_len = scsi_2btoul(cdb->length); retry: mtx_lock(&lun->lun_lock); switch (cdb->action) { case SPRI_RK: /* read keys */ total_len = sizeof(struct scsi_per_res_in_keys) + lun->pr_key_count * sizeof(struct scsi_per_res_key); break; case SPRI_RR: /* read reservation */ if (lun->flags & CTL_LUN_PR_RESERVED) total_len = sizeof(struct scsi_per_res_in_rsrv); else total_len = sizeof(struct scsi_per_res_in_header); break; case SPRI_RC: /* report capabilities */ total_len = sizeof(struct scsi_per_res_cap); break; case SPRI_RS: /* read full status */ total_len = sizeof(struct scsi_per_res_in_header) + (sizeof(struct scsi_per_res_in_full_desc) + 256) * lun->pr_key_count; break; default: panic("%s: Invalid PR type %#x", __func__, cdb->action); } mtx_unlock(&lun->lun_lock); ctsio->kern_data_ptr = malloc(total_len, M_CTL, M_WAITOK | M_ZERO); ctsio->kern_rel_offset = 0; ctsio->kern_sg_entries = 0; ctsio->kern_data_len = min(total_len, alloc_len); ctsio->kern_total_len = ctsio->kern_data_len; mtx_lock(&lun->lun_lock); switch (cdb->action) { case SPRI_RK: { // read keys struct scsi_per_res_in_keys *res_keys; int i, key_count; res_keys = (struct scsi_per_res_in_keys*)ctsio->kern_data_ptr; /* * We had to drop the lock to allocate our buffer, which * leaves time for someone to come in with another * persistent reservation. (That is unlikely, though, * since this should be the only persistent reservation * command active right now.) */ if (total_len != (sizeof(struct scsi_per_res_in_keys) + (lun->pr_key_count * sizeof(struct scsi_per_res_key)))){ mtx_unlock(&lun->lun_lock); free(ctsio->kern_data_ptr, M_CTL); printf("%s: reservation length changed, retrying\n", __func__); goto retry; } scsi_ulto4b(lun->pr_generation, res_keys->header.generation); scsi_ulto4b(sizeof(struct scsi_per_res_key) * lun->pr_key_count, res_keys->header.length); for (i = 0, key_count = 0; i < CTL_MAX_INITIATORS; i++) { if ((key = ctl_get_prkey(lun, i)) == 0) continue; /* * We used lun->pr_key_count to calculate the * size to allocate. If it turns out the number of * initiators with the registered flag set is * larger than that (i.e. they haven't been kept in * sync), we've got a problem. */ if (key_count >= lun->pr_key_count) { key_count++; continue; } scsi_u64to8b(key, res_keys->keys[key_count].key); key_count++; } break; } case SPRI_RR: { // read reservation struct scsi_per_res_in_rsrv *res; int tmp_len, header_only; res = (struct scsi_per_res_in_rsrv *)ctsio->kern_data_ptr; scsi_ulto4b(lun->pr_generation, res->header.generation); if (lun->flags & CTL_LUN_PR_RESERVED) { tmp_len = sizeof(struct scsi_per_res_in_rsrv); scsi_ulto4b(sizeof(struct scsi_per_res_in_rsrv_data), res->header.length); header_only = 0; } else { tmp_len = sizeof(struct scsi_per_res_in_header); scsi_ulto4b(0, res->header.length); header_only = 1; } /* * We had to drop the lock to allocate our buffer, which * leaves time for someone to come in with another * persistent reservation. (That is unlikely, though, * since this should be the only persistent reservation * command active right now.) */ if (tmp_len != total_len) { mtx_unlock(&lun->lun_lock); free(ctsio->kern_data_ptr, M_CTL); printf("%s: reservation status changed, retrying\n", __func__); goto retry; } /* * No reservation held, so we're done. */ if (header_only != 0) break; /* * If the registration is an All Registrants type, the key * is 0, since it doesn't really matter. */ if (lun->pr_res_idx != CTL_PR_ALL_REGISTRANTS) { scsi_u64to8b(ctl_get_prkey(lun, lun->pr_res_idx), res->data.reservation); } res->data.scopetype = lun->pr_res_type; break; } case SPRI_RC: //report capabilities { struct scsi_per_res_cap *res_cap; uint16_t type_mask; res_cap = (struct scsi_per_res_cap *)ctsio->kern_data_ptr; scsi_ulto2b(sizeof(*res_cap), res_cap->length); res_cap->flags1 = SPRI_CRH; res_cap->flags2 = SPRI_TMV | SPRI_ALLOW_5; type_mask = SPRI_TM_WR_EX_AR | SPRI_TM_EX_AC_RO | SPRI_TM_WR_EX_RO | SPRI_TM_EX_AC | SPRI_TM_WR_EX | SPRI_TM_EX_AC_AR; scsi_ulto2b(type_mask, res_cap->type_mask); break; } case SPRI_RS: { // read full status struct scsi_per_res_in_full *res_status; struct scsi_per_res_in_full_desc *res_desc; struct ctl_port *port; int i, len; res_status = (struct scsi_per_res_in_full*)ctsio->kern_data_ptr; /* * We had to drop the lock to allocate our buffer, which * leaves time for someone to come in with another * persistent reservation. (That is unlikely, though, * since this should be the only persistent reservation * command active right now.) */ if (total_len < (sizeof(struct scsi_per_res_in_header) + (sizeof(struct scsi_per_res_in_full_desc) + 256) * lun->pr_key_count)){ mtx_unlock(&lun->lun_lock); free(ctsio->kern_data_ptr, M_CTL); printf("%s: reservation length changed, retrying\n", __func__); goto retry; } scsi_ulto4b(lun->pr_generation, res_status->header.generation); res_desc = &res_status->desc[0]; for (i = 0; i < CTL_MAX_INITIATORS; i++) { if ((key = ctl_get_prkey(lun, i)) == 0) continue; scsi_u64to8b(key, res_desc->res_key.key); if ((lun->flags & CTL_LUN_PR_RESERVED) && (lun->pr_res_idx == i || lun->pr_res_idx == CTL_PR_ALL_REGISTRANTS)) { res_desc->flags = SPRI_FULL_R_HOLDER; res_desc->scopetype = lun->pr_res_type; } scsi_ulto2b(i / CTL_MAX_INIT_PER_PORT, res_desc->rel_trgt_port_id); len = 0; port = softc->ctl_ports[i / CTL_MAX_INIT_PER_PORT]; if (port != NULL) len = ctl_create_iid(port, i % CTL_MAX_INIT_PER_PORT, res_desc->transport_id); scsi_ulto4b(len, res_desc->additional_length); res_desc = (struct scsi_per_res_in_full_desc *) &res_desc->transport_id[len]; } scsi_ulto4b((uint8_t *)res_desc - (uint8_t *)&res_status->desc[0], res_status->header.length); break; } default: panic("%s: Invalid PR type %#x", __func__, cdb->action); } mtx_unlock(&lun->lun_lock); ctl_set_success(ctsio); ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } /* * Returns 0 if ctl_persistent_reserve_out() should continue, non-zero if * it should return. */ static int ctl_pro_preempt(struct ctl_softc *softc, struct ctl_lun *lun, uint64_t res_key, uint64_t sa_res_key, uint8_t type, uint32_t residx, struct ctl_scsiio *ctsio, struct scsi_per_res_out *cdb, struct scsi_per_res_out_parms* param) { union ctl_ha_msg persis_io; int i; mtx_lock(&lun->lun_lock); if (sa_res_key == 0) { if (lun->pr_res_idx == CTL_PR_ALL_REGISTRANTS) { /* validate scope and type */ if ((cdb->scope_type & SPR_SCOPE_MASK) != SPR_LU_SCOPE) { mtx_unlock(&lun->lun_lock); ctl_set_invalid_field(/*ctsio*/ ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 2, /*bit_valid*/ 1, /*bit*/ 4); ctl_done((union ctl_io *)ctsio); return (1); } if (type>8 || type==2 || type==4 || type==0) { mtx_unlock(&lun->lun_lock); ctl_set_invalid_field(/*ctsio*/ ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 2, /*bit_valid*/ 1, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); return (1); } /* * Unregister everybody else and build UA for * them */ for(i = 0; i < CTL_MAX_INITIATORS; i++) { if (i == residx || ctl_get_prkey(lun, i) == 0) continue; ctl_clr_prkey(lun, i); ctl_est_ua(lun, i, CTL_UA_REG_PREEMPT); } lun->pr_key_count = 1; lun->pr_res_type = type; if (lun->pr_res_type != SPR_TYPE_WR_EX_AR && lun->pr_res_type != SPR_TYPE_EX_AC_AR) lun->pr_res_idx = residx; lun->pr_generation++; mtx_unlock(&lun->lun_lock); /* send msg to other side */ persis_io.hdr.nexus = ctsio->io_hdr.nexus; persis_io.hdr.msg_type = CTL_MSG_PERS_ACTION; persis_io.pr.pr_info.action = CTL_PR_PREEMPT; persis_io.pr.pr_info.residx = lun->pr_res_idx; persis_io.pr.pr_info.res_type = type; memcpy(persis_io.pr.pr_info.sa_res_key, param->serv_act_res_key, sizeof(param->serv_act_res_key)); ctl_ha_msg_send(CTL_HA_CHAN_CTL, &persis_io, sizeof(persis_io.pr), M_WAITOK); } else { /* not all registrants */ mtx_unlock(&lun->lun_lock); free(ctsio->kern_data_ptr, M_CTL); ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 0, /*field*/ 8, /*bit_valid*/ 0, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); return (1); } } else if (lun->pr_res_idx == CTL_PR_ALL_REGISTRANTS || !(lun->flags & CTL_LUN_PR_RESERVED)) { int found = 0; if (res_key == sa_res_key) { /* special case */ /* * The spec implies this is not good but doesn't * say what to do. There are two choices either * generate a res conflict or check condition * with illegal field in parameter data. Since * that is what is done when the sa_res_key is * zero I'll take that approach since this has * to do with the sa_res_key. */ mtx_unlock(&lun->lun_lock); free(ctsio->kern_data_ptr, M_CTL); ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 0, /*field*/ 8, /*bit_valid*/ 0, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); return (1); } for (i = 0; i < CTL_MAX_INITIATORS; i++) { if (ctl_get_prkey(lun, i) != sa_res_key) continue; found = 1; ctl_clr_prkey(lun, i); lun->pr_key_count--; ctl_est_ua(lun, i, CTL_UA_REG_PREEMPT); } if (!found) { mtx_unlock(&lun->lun_lock); free(ctsio->kern_data_ptr, M_CTL); ctl_set_reservation_conflict(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } lun->pr_generation++; mtx_unlock(&lun->lun_lock); /* send msg to other side */ persis_io.hdr.nexus = ctsio->io_hdr.nexus; persis_io.hdr.msg_type = CTL_MSG_PERS_ACTION; persis_io.pr.pr_info.action = CTL_PR_PREEMPT; persis_io.pr.pr_info.residx = lun->pr_res_idx; persis_io.pr.pr_info.res_type = type; memcpy(persis_io.pr.pr_info.sa_res_key, param->serv_act_res_key, sizeof(param->serv_act_res_key)); ctl_ha_msg_send(CTL_HA_CHAN_CTL, &persis_io, sizeof(persis_io.pr), M_WAITOK); } else { /* Reserved but not all registrants */ /* sa_res_key is res holder */ if (sa_res_key == ctl_get_prkey(lun, lun->pr_res_idx)) { /* validate scope and type */ if ((cdb->scope_type & SPR_SCOPE_MASK) != SPR_LU_SCOPE) { mtx_unlock(&lun->lun_lock); ctl_set_invalid_field(/*ctsio*/ ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 2, /*bit_valid*/ 1, /*bit*/ 4); ctl_done((union ctl_io *)ctsio); return (1); } if (type>8 || type==2 || type==4 || type==0) { mtx_unlock(&lun->lun_lock); ctl_set_invalid_field(/*ctsio*/ ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 2, /*bit_valid*/ 1, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); return (1); } /* * Do the following: * if sa_res_key != res_key remove all * registrants w/sa_res_key and generate UA * for these registrants(Registrations * Preempted) if it wasn't an exclusive * reservation generate UA(Reservations * Preempted) for all other registered nexuses * if the type has changed. Establish the new * reservation and holder. If res_key and * sa_res_key are the same do the above * except don't unregister the res holder. */ for(i = 0; i < CTL_MAX_INITIATORS; i++) { if (i == residx || ctl_get_prkey(lun, i) == 0) continue; if (sa_res_key == ctl_get_prkey(lun, i)) { ctl_clr_prkey(lun, i); lun->pr_key_count--; ctl_est_ua(lun, i, CTL_UA_REG_PREEMPT); } else if (type != lun->pr_res_type && (lun->pr_res_type == SPR_TYPE_WR_EX_RO || lun->pr_res_type == SPR_TYPE_EX_AC_RO)) { ctl_est_ua(lun, i, CTL_UA_RES_RELEASE); } } lun->pr_res_type = type; if (lun->pr_res_type != SPR_TYPE_WR_EX_AR && lun->pr_res_type != SPR_TYPE_EX_AC_AR) lun->pr_res_idx = residx; else lun->pr_res_idx = CTL_PR_ALL_REGISTRANTS; lun->pr_generation++; mtx_unlock(&lun->lun_lock); persis_io.hdr.nexus = ctsio->io_hdr.nexus; persis_io.hdr.msg_type = CTL_MSG_PERS_ACTION; persis_io.pr.pr_info.action = CTL_PR_PREEMPT; persis_io.pr.pr_info.residx = lun->pr_res_idx; persis_io.pr.pr_info.res_type = type; memcpy(persis_io.pr.pr_info.sa_res_key, param->serv_act_res_key, sizeof(param->serv_act_res_key)); ctl_ha_msg_send(CTL_HA_CHAN_CTL, &persis_io, sizeof(persis_io.pr), M_WAITOK); } else { /* * sa_res_key is not the res holder just * remove registrants */ int found=0; for (i = 0; i < CTL_MAX_INITIATORS; i++) { if (sa_res_key != ctl_get_prkey(lun, i)) continue; found = 1; ctl_clr_prkey(lun, i); lun->pr_key_count--; ctl_est_ua(lun, i, CTL_UA_REG_PREEMPT); } if (!found) { mtx_unlock(&lun->lun_lock); free(ctsio->kern_data_ptr, M_CTL); ctl_set_reservation_conflict(ctsio); ctl_done((union ctl_io *)ctsio); return (1); } lun->pr_generation++; mtx_unlock(&lun->lun_lock); persis_io.hdr.nexus = ctsio->io_hdr.nexus; persis_io.hdr.msg_type = CTL_MSG_PERS_ACTION; persis_io.pr.pr_info.action = CTL_PR_PREEMPT; persis_io.pr.pr_info.residx = lun->pr_res_idx; persis_io.pr.pr_info.res_type = type; memcpy(persis_io.pr.pr_info.sa_res_key, param->serv_act_res_key, sizeof(param->serv_act_res_key)); ctl_ha_msg_send(CTL_HA_CHAN_CTL, &persis_io, sizeof(persis_io.pr), M_WAITOK); } } return (0); } static void ctl_pro_preempt_other(struct ctl_lun *lun, union ctl_ha_msg *msg) { uint64_t sa_res_key; int i; sa_res_key = scsi_8btou64(msg->pr.pr_info.sa_res_key); if (lun->pr_res_idx == CTL_PR_ALL_REGISTRANTS || lun->pr_res_idx == CTL_PR_NO_RESERVATION || sa_res_key != ctl_get_prkey(lun, lun->pr_res_idx)) { if (sa_res_key == 0) { /* * Unregister everybody else and build UA for * them */ for(i = 0; i < CTL_MAX_INITIATORS; i++) { if (i == msg->pr.pr_info.residx || ctl_get_prkey(lun, i) == 0) continue; ctl_clr_prkey(lun, i); ctl_est_ua(lun, i, CTL_UA_REG_PREEMPT); } lun->pr_key_count = 1; lun->pr_res_type = msg->pr.pr_info.res_type; if (lun->pr_res_type != SPR_TYPE_WR_EX_AR && lun->pr_res_type != SPR_TYPE_EX_AC_AR) lun->pr_res_idx = msg->pr.pr_info.residx; } else { for (i = 0; i < CTL_MAX_INITIATORS; i++) { if (sa_res_key == ctl_get_prkey(lun, i)) continue; ctl_clr_prkey(lun, i); lun->pr_key_count--; ctl_est_ua(lun, i, CTL_UA_REG_PREEMPT); } } } else { for (i = 0; i < CTL_MAX_INITIATORS; i++) { if (i == msg->pr.pr_info.residx || ctl_get_prkey(lun, i) == 0) continue; if (sa_res_key == ctl_get_prkey(lun, i)) { ctl_clr_prkey(lun, i); lun->pr_key_count--; ctl_est_ua(lun, i, CTL_UA_REG_PREEMPT); } else if (msg->pr.pr_info.res_type != lun->pr_res_type && (lun->pr_res_type == SPR_TYPE_WR_EX_RO || lun->pr_res_type == SPR_TYPE_EX_AC_RO)) { ctl_est_ua(lun, i, CTL_UA_RES_RELEASE); } } lun->pr_res_type = msg->pr.pr_info.res_type; if (lun->pr_res_type != SPR_TYPE_WR_EX_AR && lun->pr_res_type != SPR_TYPE_EX_AC_AR) lun->pr_res_idx = msg->pr.pr_info.residx; else lun->pr_res_idx = CTL_PR_ALL_REGISTRANTS; } lun->pr_generation++; } int ctl_persistent_reserve_out(struct ctl_scsiio *ctsio) { struct ctl_softc *softc = CTL_SOFTC(ctsio); struct ctl_lun *lun = CTL_LUN(ctsio); int retval; u_int32_t param_len; struct scsi_per_res_out *cdb; struct scsi_per_res_out_parms* param; uint32_t residx; uint64_t res_key, sa_res_key, key; uint8_t type; union ctl_ha_msg persis_io; int i; CTL_DEBUG_PRINT(("ctl_persistent_reserve_out\n")); cdb = (struct scsi_per_res_out *)ctsio->cdb; retval = CTL_RETVAL_COMPLETE; /* * We only support whole-LUN scope. The scope & type are ignored for * register, register and ignore existing key and clear. * We sometimes ignore scope and type on preempts too!! * Verify reservation type here as well. */ type = cdb->scope_type & SPR_TYPE_MASK; if ((cdb->action == SPRO_RESERVE) || (cdb->action == SPRO_RELEASE)) { if ((cdb->scope_type & SPR_SCOPE_MASK) != SPR_LU_SCOPE) { ctl_set_invalid_field(/*ctsio*/ ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 2, /*bit_valid*/ 1, /*bit*/ 4); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } if (type>8 || type==2 || type==4 || type==0) { ctl_set_invalid_field(/*ctsio*/ ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 2, /*bit_valid*/ 1, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } } param_len = scsi_4btoul(cdb->length); if ((ctsio->io_hdr.flags & CTL_FLAG_ALLOCATED) == 0) { ctsio->kern_data_ptr = malloc(param_len, M_CTL, M_WAITOK); ctsio->kern_data_len = param_len; ctsio->kern_total_len = param_len; ctsio->kern_rel_offset = 0; ctsio->kern_sg_entries = 0; ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } param = (struct scsi_per_res_out_parms *)ctsio->kern_data_ptr; residx = ctl_get_initindex(&ctsio->io_hdr.nexus); res_key = scsi_8btou64(param->res_key.key); sa_res_key = scsi_8btou64(param->serv_act_res_key); /* * Validate the reservation key here except for SPRO_REG_IGNO * This must be done for all other service actions */ if ((cdb->action & SPRO_ACTION_MASK) != SPRO_REG_IGNO) { mtx_lock(&lun->lun_lock); if ((key = ctl_get_prkey(lun, residx)) != 0) { if (res_key != key) { /* * The current key passed in doesn't match * the one the initiator previously * registered. */ mtx_unlock(&lun->lun_lock); free(ctsio->kern_data_ptr, M_CTL); ctl_set_reservation_conflict(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } } else if ((cdb->action & SPRO_ACTION_MASK) != SPRO_REGISTER) { /* * We are not registered */ mtx_unlock(&lun->lun_lock); free(ctsio->kern_data_ptr, M_CTL); ctl_set_reservation_conflict(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } else if (res_key != 0) { /* * We are not registered and trying to register but * the register key isn't zero. */ mtx_unlock(&lun->lun_lock); free(ctsio->kern_data_ptr, M_CTL); ctl_set_reservation_conflict(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } mtx_unlock(&lun->lun_lock); } switch (cdb->action & SPRO_ACTION_MASK) { case SPRO_REGISTER: case SPRO_REG_IGNO: { /* * We don't support any of these options, as we report in * the read capabilities request (see * ctl_persistent_reserve_in(), above). */ if ((param->flags & SPR_SPEC_I_PT) || (param->flags & SPR_ALL_TG_PT) || (param->flags & SPR_APTPL)) { int bit_ptr; if (param->flags & SPR_APTPL) bit_ptr = 0; else if (param->flags & SPR_ALL_TG_PT) bit_ptr = 2; else /* SPR_SPEC_I_PT */ bit_ptr = 3; free(ctsio->kern_data_ptr, M_CTL); ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 0, /*field*/ 20, /*bit_valid*/ 1, /*bit*/ bit_ptr); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } mtx_lock(&lun->lun_lock); /* * The initiator wants to clear the * key/unregister. */ if (sa_res_key == 0) { if ((res_key == 0 && (cdb->action & SPRO_ACTION_MASK) == SPRO_REGISTER) || ((cdb->action & SPRO_ACTION_MASK) == SPRO_REG_IGNO && ctl_get_prkey(lun, residx) == 0)) { mtx_unlock(&lun->lun_lock); goto done; } ctl_clr_prkey(lun, residx); lun->pr_key_count--; if (residx == lun->pr_res_idx) { lun->flags &= ~CTL_LUN_PR_RESERVED; lun->pr_res_idx = CTL_PR_NO_RESERVATION; if ((lun->pr_res_type == SPR_TYPE_WR_EX_RO || lun->pr_res_type == SPR_TYPE_EX_AC_RO) && lun->pr_key_count) { /* * If the reservation is a registrants * only type we need to generate a UA * for other registered inits. The * sense code should be RESERVATIONS * RELEASED */ for (i = softc->init_min; i < softc->init_max; i++){ if (ctl_get_prkey(lun, i) == 0) continue; ctl_est_ua(lun, i, CTL_UA_RES_RELEASE); } } lun->pr_res_type = 0; } else if (lun->pr_res_idx == CTL_PR_ALL_REGISTRANTS) { if (lun->pr_key_count==0) { lun->flags &= ~CTL_LUN_PR_RESERVED; lun->pr_res_type = 0; lun->pr_res_idx = CTL_PR_NO_RESERVATION; } } lun->pr_generation++; mtx_unlock(&lun->lun_lock); persis_io.hdr.nexus = ctsio->io_hdr.nexus; persis_io.hdr.msg_type = CTL_MSG_PERS_ACTION; persis_io.pr.pr_info.action = CTL_PR_UNREG_KEY; persis_io.pr.pr_info.residx = residx; ctl_ha_msg_send(CTL_HA_CHAN_CTL, &persis_io, sizeof(persis_io.pr), M_WAITOK); } else /* sa_res_key != 0 */ { /* * If we aren't registered currently then increment * the key count and set the registered flag. */ ctl_alloc_prkey(lun, residx); if (ctl_get_prkey(lun, residx) == 0) lun->pr_key_count++; ctl_set_prkey(lun, residx, sa_res_key); lun->pr_generation++; mtx_unlock(&lun->lun_lock); persis_io.hdr.nexus = ctsio->io_hdr.nexus; persis_io.hdr.msg_type = CTL_MSG_PERS_ACTION; persis_io.pr.pr_info.action = CTL_PR_REG_KEY; persis_io.pr.pr_info.residx = residx; memcpy(persis_io.pr.pr_info.sa_res_key, param->serv_act_res_key, sizeof(param->serv_act_res_key)); ctl_ha_msg_send(CTL_HA_CHAN_CTL, &persis_io, sizeof(persis_io.pr), M_WAITOK); } break; } case SPRO_RESERVE: mtx_lock(&lun->lun_lock); if (lun->flags & CTL_LUN_PR_RESERVED) { /* * if this isn't the reservation holder and it's * not a "all registrants" type or if the type is * different then we have a conflict */ if ((lun->pr_res_idx != residx && lun->pr_res_idx != CTL_PR_ALL_REGISTRANTS) || lun->pr_res_type != type) { mtx_unlock(&lun->lun_lock); free(ctsio->kern_data_ptr, M_CTL); ctl_set_reservation_conflict(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } mtx_unlock(&lun->lun_lock); } else /* create a reservation */ { /* * If it's not an "all registrants" type record * reservation holder */ if (type != SPR_TYPE_WR_EX_AR && type != SPR_TYPE_EX_AC_AR) lun->pr_res_idx = residx; /* Res holder */ else lun->pr_res_idx = CTL_PR_ALL_REGISTRANTS; lun->flags |= CTL_LUN_PR_RESERVED; lun->pr_res_type = type; mtx_unlock(&lun->lun_lock); /* send msg to other side */ persis_io.hdr.nexus = ctsio->io_hdr.nexus; persis_io.hdr.msg_type = CTL_MSG_PERS_ACTION; persis_io.pr.pr_info.action = CTL_PR_RESERVE; persis_io.pr.pr_info.residx = lun->pr_res_idx; persis_io.pr.pr_info.res_type = type; ctl_ha_msg_send(CTL_HA_CHAN_CTL, &persis_io, sizeof(persis_io.pr), M_WAITOK); } break; case SPRO_RELEASE: mtx_lock(&lun->lun_lock); if ((lun->flags & CTL_LUN_PR_RESERVED) == 0) { /* No reservation exists return good status */ mtx_unlock(&lun->lun_lock); goto done; } /* * Is this nexus a reservation holder? */ if (lun->pr_res_idx != residx && lun->pr_res_idx != CTL_PR_ALL_REGISTRANTS) { /* * not a res holder return good status but * do nothing */ mtx_unlock(&lun->lun_lock); goto done; } if (lun->pr_res_type != type) { mtx_unlock(&lun->lun_lock); free(ctsio->kern_data_ptr, M_CTL); ctl_set_illegal_pr_release(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } /* okay to release */ lun->flags &= ~CTL_LUN_PR_RESERVED; lun->pr_res_idx = CTL_PR_NO_RESERVATION; lun->pr_res_type = 0; /* * If this isn't an exclusive access reservation and NUAR * is not set, generate UA for all other registrants. */ if (type != SPR_TYPE_EX_AC && type != SPR_TYPE_WR_EX && (lun->MODE_CTRL.queue_flags & SCP_NUAR) == 0) { for (i = softc->init_min; i < softc->init_max; i++) { if (i == residx || ctl_get_prkey(lun, i) == 0) continue; ctl_est_ua(lun, i, CTL_UA_RES_RELEASE); } } mtx_unlock(&lun->lun_lock); /* Send msg to other side */ persis_io.hdr.nexus = ctsio->io_hdr.nexus; persis_io.hdr.msg_type = CTL_MSG_PERS_ACTION; persis_io.pr.pr_info.action = CTL_PR_RELEASE; ctl_ha_msg_send(CTL_HA_CHAN_CTL, &persis_io, sizeof(persis_io.pr), M_WAITOK); break; case SPRO_CLEAR: /* send msg to other side */ mtx_lock(&lun->lun_lock); lun->flags &= ~CTL_LUN_PR_RESERVED; lun->pr_res_type = 0; lun->pr_key_count = 0; lun->pr_res_idx = CTL_PR_NO_RESERVATION; ctl_clr_prkey(lun, residx); for (i = 0; i < CTL_MAX_INITIATORS; i++) if (ctl_get_prkey(lun, i) != 0) { ctl_clr_prkey(lun, i); ctl_est_ua(lun, i, CTL_UA_REG_PREEMPT); } lun->pr_generation++; mtx_unlock(&lun->lun_lock); persis_io.hdr.nexus = ctsio->io_hdr.nexus; persis_io.hdr.msg_type = CTL_MSG_PERS_ACTION; persis_io.pr.pr_info.action = CTL_PR_CLEAR; ctl_ha_msg_send(CTL_HA_CHAN_CTL, &persis_io, sizeof(persis_io.pr), M_WAITOK); break; case SPRO_PREEMPT: case SPRO_PRE_ABO: { int nretval; nretval = ctl_pro_preempt(softc, lun, res_key, sa_res_key, type, residx, ctsio, cdb, param); if (nretval != 0) return (CTL_RETVAL_COMPLETE); break; } default: panic("%s: Invalid PR type %#x", __func__, cdb->action); } done: free(ctsio->kern_data_ptr, M_CTL); ctl_set_success(ctsio); ctl_done((union ctl_io *)ctsio); return (retval); } /* * This routine is for handling a message from the other SC pertaining to * persistent reserve out. All the error checking will have been done * so only perorming the action need be done here to keep the two * in sync. */ static void ctl_hndl_per_res_out_on_other_sc(union ctl_io *io) { struct ctl_softc *softc = CTL_SOFTC(io); union ctl_ha_msg *msg = (union ctl_ha_msg *)&io->presio.pr_msg; struct ctl_lun *lun; int i; uint32_t residx, targ_lun; targ_lun = msg->hdr.nexus.targ_mapped_lun; mtx_lock(&softc->ctl_lock); if (targ_lun >= ctl_max_luns || (lun = softc->ctl_luns[targ_lun]) == NULL) { mtx_unlock(&softc->ctl_lock); return; } mtx_lock(&lun->lun_lock); mtx_unlock(&softc->ctl_lock); if (lun->flags & CTL_LUN_DISABLED) { mtx_unlock(&lun->lun_lock); return; } residx = ctl_get_initindex(&msg->hdr.nexus); switch(msg->pr.pr_info.action) { case CTL_PR_REG_KEY: ctl_alloc_prkey(lun, msg->pr.pr_info.residx); if (ctl_get_prkey(lun, msg->pr.pr_info.residx) == 0) lun->pr_key_count++; ctl_set_prkey(lun, msg->pr.pr_info.residx, scsi_8btou64(msg->pr.pr_info.sa_res_key)); lun->pr_generation++; break; case CTL_PR_UNREG_KEY: ctl_clr_prkey(lun, msg->pr.pr_info.residx); lun->pr_key_count--; /* XXX Need to see if the reservation has been released */ /* if so do we need to generate UA? */ if (msg->pr.pr_info.residx == lun->pr_res_idx) { lun->flags &= ~CTL_LUN_PR_RESERVED; lun->pr_res_idx = CTL_PR_NO_RESERVATION; if ((lun->pr_res_type == SPR_TYPE_WR_EX_RO || lun->pr_res_type == SPR_TYPE_EX_AC_RO) && lun->pr_key_count) { /* * If the reservation is a registrants * only type we need to generate a UA * for other registered inits. The * sense code should be RESERVATIONS * RELEASED */ for (i = softc->init_min; i < softc->init_max; i++) { if (ctl_get_prkey(lun, i) == 0) continue; ctl_est_ua(lun, i, CTL_UA_RES_RELEASE); } } lun->pr_res_type = 0; } else if (lun->pr_res_idx == CTL_PR_ALL_REGISTRANTS) { if (lun->pr_key_count==0) { lun->flags &= ~CTL_LUN_PR_RESERVED; lun->pr_res_type = 0; lun->pr_res_idx = CTL_PR_NO_RESERVATION; } } lun->pr_generation++; break; case CTL_PR_RESERVE: lun->flags |= CTL_LUN_PR_RESERVED; lun->pr_res_type = msg->pr.pr_info.res_type; lun->pr_res_idx = msg->pr.pr_info.residx; break; case CTL_PR_RELEASE: /* * If this isn't an exclusive access reservation and NUAR * is not set, generate UA for all other registrants. */ if (lun->pr_res_type != SPR_TYPE_EX_AC && lun->pr_res_type != SPR_TYPE_WR_EX && (lun->MODE_CTRL.queue_flags & SCP_NUAR) == 0) { for (i = softc->init_min; i < softc->init_max; i++) { if (i == residx || ctl_get_prkey(lun, i) == 0) continue; ctl_est_ua(lun, i, CTL_UA_RES_RELEASE); } } lun->flags &= ~CTL_LUN_PR_RESERVED; lun->pr_res_idx = CTL_PR_NO_RESERVATION; lun->pr_res_type = 0; break; case CTL_PR_PREEMPT: ctl_pro_preempt_other(lun, msg); break; case CTL_PR_CLEAR: lun->flags &= ~CTL_LUN_PR_RESERVED; lun->pr_res_type = 0; lun->pr_key_count = 0; lun->pr_res_idx = CTL_PR_NO_RESERVATION; for (i=0; i < CTL_MAX_INITIATORS; i++) { if (ctl_get_prkey(lun, i) == 0) continue; ctl_clr_prkey(lun, i); ctl_est_ua(lun, i, CTL_UA_REG_PREEMPT); } lun->pr_generation++; break; } mtx_unlock(&lun->lun_lock); } int ctl_read_write(struct ctl_scsiio *ctsio) { struct ctl_lun *lun = CTL_LUN(ctsio); struct ctl_lba_len_flags *lbalen; uint64_t lba; uint32_t num_blocks; int flags, retval; int isread; CTL_DEBUG_PRINT(("ctl_read_write: command: %#x\n", ctsio->cdb[0])); flags = 0; isread = ctsio->cdb[0] == READ_6 || ctsio->cdb[0] == READ_10 || ctsio->cdb[0] == READ_12 || ctsio->cdb[0] == READ_16; switch (ctsio->cdb[0]) { case READ_6: case WRITE_6: { struct scsi_rw_6 *cdb; cdb = (struct scsi_rw_6 *)ctsio->cdb; lba = scsi_3btoul(cdb->addr); /* only 5 bits are valid in the most significant address byte */ lba &= 0x1fffff; num_blocks = cdb->length; /* * This is correct according to SBC-2. */ if (num_blocks == 0) num_blocks = 256; break; } case READ_10: case WRITE_10: { struct scsi_rw_10 *cdb; cdb = (struct scsi_rw_10 *)ctsio->cdb; if (cdb->byte2 & SRW10_FUA) flags |= CTL_LLF_FUA; if (cdb->byte2 & SRW10_DPO) flags |= CTL_LLF_DPO; lba = scsi_4btoul(cdb->addr); num_blocks = scsi_2btoul(cdb->length); break; } case WRITE_VERIFY_10: { struct scsi_write_verify_10 *cdb; cdb = (struct scsi_write_verify_10 *)ctsio->cdb; flags |= CTL_LLF_FUA; if (cdb->byte2 & SWV_DPO) flags |= CTL_LLF_DPO; lba = scsi_4btoul(cdb->addr); num_blocks = scsi_2btoul(cdb->length); break; } case READ_12: case WRITE_12: { struct scsi_rw_12 *cdb; cdb = (struct scsi_rw_12 *)ctsio->cdb; if (cdb->byte2 & SRW12_FUA) flags |= CTL_LLF_FUA; if (cdb->byte2 & SRW12_DPO) flags |= CTL_LLF_DPO; lba = scsi_4btoul(cdb->addr); num_blocks = scsi_4btoul(cdb->length); break; } case WRITE_VERIFY_12: { struct scsi_write_verify_12 *cdb; cdb = (struct scsi_write_verify_12 *)ctsio->cdb; flags |= CTL_LLF_FUA; if (cdb->byte2 & SWV_DPO) flags |= CTL_LLF_DPO; lba = scsi_4btoul(cdb->addr); num_blocks = scsi_4btoul(cdb->length); break; } case READ_16: case WRITE_16: { struct scsi_rw_16 *cdb; cdb = (struct scsi_rw_16 *)ctsio->cdb; if (cdb->byte2 & SRW12_FUA) flags |= CTL_LLF_FUA; if (cdb->byte2 & SRW12_DPO) flags |= CTL_LLF_DPO; lba = scsi_8btou64(cdb->addr); num_blocks = scsi_4btoul(cdb->length); break; } case WRITE_ATOMIC_16: { struct scsi_write_atomic_16 *cdb; if (lun->be_lun->atomicblock == 0) { ctl_set_invalid_opcode(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } cdb = (struct scsi_write_atomic_16 *)ctsio->cdb; if (cdb->byte2 & SRW12_FUA) flags |= CTL_LLF_FUA; if (cdb->byte2 & SRW12_DPO) flags |= CTL_LLF_DPO; lba = scsi_8btou64(cdb->addr); num_blocks = scsi_2btoul(cdb->length); if (num_blocks > lun->be_lun->atomicblock) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 12, /*bit_valid*/ 0, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } break; } case WRITE_VERIFY_16: { struct scsi_write_verify_16 *cdb; cdb = (struct scsi_write_verify_16 *)ctsio->cdb; flags |= CTL_LLF_FUA; if (cdb->byte2 & SWV_DPO) flags |= CTL_LLF_DPO; lba = scsi_8btou64(cdb->addr); num_blocks = scsi_4btoul(cdb->length); break; } default: /* * We got a command we don't support. This shouldn't * happen, commands should be filtered out above us. */ ctl_set_invalid_opcode(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); break; /* NOTREACHED */ } /* * The first check is to make sure we're in bounds, the second * check is to catch wrap-around problems. If the lba + num blocks * is less than the lba, then we've wrapped around and the block * range is invalid anyway. */ if (((lba + num_blocks) > (lun->be_lun->maxlba + 1)) || ((lba + num_blocks) < lba)) { ctl_set_lba_out_of_range(ctsio, MAX(lba, lun->be_lun->maxlba + 1)); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } /* * According to SBC-3, a transfer length of 0 is not an error. * Note that this cannot happen with WRITE(6) or READ(6), since 0 * translates to 256 blocks for those commands. */ if (num_blocks == 0) { ctl_set_success(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } /* Set FUA and/or DPO if caches are disabled. */ if (isread) { if ((lun->MODE_CACHING.flags1 & SCP_RCD) != 0) flags |= CTL_LLF_FUA | CTL_LLF_DPO; } else { if ((lun->MODE_CACHING.flags1 & SCP_WCE) == 0) flags |= CTL_LLF_FUA; } lbalen = (struct ctl_lba_len_flags *) &ctsio->io_hdr.ctl_private[CTL_PRIV_LBA_LEN]; lbalen->lba = lba; lbalen->len = num_blocks; lbalen->flags = (isread ? CTL_LLF_READ : CTL_LLF_WRITE) | flags; ctsio->kern_total_len = num_blocks * lun->be_lun->blocksize; ctsio->kern_rel_offset = 0; CTL_DEBUG_PRINT(("ctl_read_write: calling data_submit()\n")); retval = lun->backend->data_submit((union ctl_io *)ctsio); return (retval); } static int ctl_cnw_cont(union ctl_io *io) { struct ctl_lun *lun = CTL_LUN(io); struct ctl_scsiio *ctsio; struct ctl_lba_len_flags *lbalen; int retval; ctsio = &io->scsiio; ctsio->io_hdr.status = CTL_STATUS_NONE; ctsio->io_hdr.flags &= ~CTL_FLAG_IO_CONT; lbalen = (struct ctl_lba_len_flags *) &ctsio->io_hdr.ctl_private[CTL_PRIV_LBA_LEN]; lbalen->flags &= ~CTL_LLF_COMPARE; lbalen->flags |= CTL_LLF_WRITE; CTL_DEBUG_PRINT(("ctl_cnw_cont: calling data_submit()\n")); retval = lun->backend->data_submit((union ctl_io *)ctsio); return (retval); } int ctl_cnw(struct ctl_scsiio *ctsio) { struct ctl_lun *lun = CTL_LUN(ctsio); struct ctl_lba_len_flags *lbalen; uint64_t lba; uint32_t num_blocks; int flags, retval; CTL_DEBUG_PRINT(("ctl_cnw: command: %#x\n", ctsio->cdb[0])); flags = 0; switch (ctsio->cdb[0]) { case COMPARE_AND_WRITE: { struct scsi_compare_and_write *cdb; cdb = (struct scsi_compare_and_write *)ctsio->cdb; if (cdb->byte2 & SRW10_FUA) flags |= CTL_LLF_FUA; if (cdb->byte2 & SRW10_DPO) flags |= CTL_LLF_DPO; lba = scsi_8btou64(cdb->addr); num_blocks = cdb->length; break; } default: /* * We got a command we don't support. This shouldn't * happen, commands should be filtered out above us. */ ctl_set_invalid_opcode(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); break; /* NOTREACHED */ } /* * The first check is to make sure we're in bounds, the second * check is to catch wrap-around problems. If the lba + num blocks * is less than the lba, then we've wrapped around and the block * range is invalid anyway. */ if (((lba + num_blocks) > (lun->be_lun->maxlba + 1)) || ((lba + num_blocks) < lba)) { ctl_set_lba_out_of_range(ctsio, MAX(lba, lun->be_lun->maxlba + 1)); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } /* * According to SBC-3, a transfer length of 0 is not an error. */ if (num_blocks == 0) { ctl_set_success(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } /* Set FUA if write cache is disabled. */ if ((lun->MODE_CACHING.flags1 & SCP_WCE) == 0) flags |= CTL_LLF_FUA; ctsio->kern_total_len = 2 * num_blocks * lun->be_lun->blocksize; ctsio->kern_rel_offset = 0; /* * Set the IO_CONT flag, so that if this I/O gets passed to * ctl_data_submit_done(), it'll get passed back to * ctl_ctl_cnw_cont() for further processing. */ ctsio->io_hdr.flags |= CTL_FLAG_IO_CONT; ctsio->io_cont = ctl_cnw_cont; lbalen = (struct ctl_lba_len_flags *) &ctsio->io_hdr.ctl_private[CTL_PRIV_LBA_LEN]; lbalen->lba = lba; lbalen->len = num_blocks; lbalen->flags = CTL_LLF_COMPARE | flags; CTL_DEBUG_PRINT(("ctl_cnw: calling data_submit()\n")); retval = lun->backend->data_submit((union ctl_io *)ctsio); return (retval); } int ctl_verify(struct ctl_scsiio *ctsio) { struct ctl_lun *lun = CTL_LUN(ctsio); struct ctl_lba_len_flags *lbalen; uint64_t lba; uint32_t num_blocks; int bytchk, flags; int retval; CTL_DEBUG_PRINT(("ctl_verify: command: %#x\n", ctsio->cdb[0])); bytchk = 0; flags = CTL_LLF_FUA; switch (ctsio->cdb[0]) { case VERIFY_10: { struct scsi_verify_10 *cdb; cdb = (struct scsi_verify_10 *)ctsio->cdb; if (cdb->byte2 & SVFY_BYTCHK) bytchk = 1; if (cdb->byte2 & SVFY_DPO) flags |= CTL_LLF_DPO; lba = scsi_4btoul(cdb->addr); num_blocks = scsi_2btoul(cdb->length); break; } case VERIFY_12: { struct scsi_verify_12 *cdb; cdb = (struct scsi_verify_12 *)ctsio->cdb; if (cdb->byte2 & SVFY_BYTCHK) bytchk = 1; if (cdb->byte2 & SVFY_DPO) flags |= CTL_LLF_DPO; lba = scsi_4btoul(cdb->addr); num_blocks = scsi_4btoul(cdb->length); break; } case VERIFY_16: { struct scsi_rw_16 *cdb; cdb = (struct scsi_rw_16 *)ctsio->cdb; if (cdb->byte2 & SVFY_BYTCHK) bytchk = 1; if (cdb->byte2 & SVFY_DPO) flags |= CTL_LLF_DPO; lba = scsi_8btou64(cdb->addr); num_blocks = scsi_4btoul(cdb->length); break; } default: /* * We got a command we don't support. This shouldn't * happen, commands should be filtered out above us. */ ctl_set_invalid_opcode(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } /* * The first check is to make sure we're in bounds, the second * check is to catch wrap-around problems. If the lba + num blocks * is less than the lba, then we've wrapped around and the block * range is invalid anyway. */ if (((lba + num_blocks) > (lun->be_lun->maxlba + 1)) || ((lba + num_blocks) < lba)) { ctl_set_lba_out_of_range(ctsio, MAX(lba, lun->be_lun->maxlba + 1)); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } /* * According to SBC-3, a transfer length of 0 is not an error. */ if (num_blocks == 0) { ctl_set_success(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } lbalen = (struct ctl_lba_len_flags *) &ctsio->io_hdr.ctl_private[CTL_PRIV_LBA_LEN]; lbalen->lba = lba; lbalen->len = num_blocks; if (bytchk) { lbalen->flags = CTL_LLF_COMPARE | flags; ctsio->kern_total_len = num_blocks * lun->be_lun->blocksize; } else { lbalen->flags = CTL_LLF_VERIFY | flags; ctsio->kern_total_len = 0; } ctsio->kern_rel_offset = 0; CTL_DEBUG_PRINT(("ctl_verify: calling data_submit()\n")); retval = lun->backend->data_submit((union ctl_io *)ctsio); return (retval); } int ctl_report_luns(struct ctl_scsiio *ctsio) { struct ctl_softc *softc = CTL_SOFTC(ctsio); struct ctl_port *port = CTL_PORT(ctsio); struct ctl_lun *lun, *request_lun = CTL_LUN(ctsio); struct scsi_report_luns *cdb; struct scsi_report_luns_data *lun_data; int num_filled, num_luns, num_port_luns, retval; uint32_t alloc_len, lun_datalen; uint32_t initidx, targ_lun_id, lun_id; retval = CTL_RETVAL_COMPLETE; cdb = (struct scsi_report_luns *)ctsio->cdb; CTL_DEBUG_PRINT(("ctl_report_luns\n")); num_luns = 0; num_port_luns = port->lun_map ? port->lun_map_size : ctl_max_luns; mtx_lock(&softc->ctl_lock); for (targ_lun_id = 0; targ_lun_id < num_port_luns; targ_lun_id++) { if (ctl_lun_map_from_port(port, targ_lun_id) != UINT32_MAX) num_luns++; } mtx_unlock(&softc->ctl_lock); switch (cdb->select_report) { case RPL_REPORT_DEFAULT: case RPL_REPORT_ALL: case RPL_REPORT_NONSUBSID: break; case RPL_REPORT_WELLKNOWN: case RPL_REPORT_ADMIN: case RPL_REPORT_CONGLOM: num_luns = 0; break; default: ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 2, /*bit_valid*/ 0, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); return (retval); break; /* NOTREACHED */ } alloc_len = scsi_4btoul(cdb->length); /* * The initiator has to allocate at least 16 bytes for this request, * so he can at least get the header and the first LUN. Otherwise * we reject the request (per SPC-3 rev 14, section 6.21). */ if (alloc_len < (sizeof(struct scsi_report_luns_data) + sizeof(struct scsi_report_luns_lundata))) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 6, /*bit_valid*/ 0, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); return (retval); } lun_datalen = sizeof(*lun_data) + (num_luns * sizeof(struct scsi_report_luns_lundata)); ctsio->kern_data_ptr = malloc(lun_datalen, M_CTL, M_WAITOK | M_ZERO); lun_data = (struct scsi_report_luns_data *)ctsio->kern_data_ptr; ctsio->kern_sg_entries = 0; initidx = ctl_get_initindex(&ctsio->io_hdr.nexus); mtx_lock(&softc->ctl_lock); for (targ_lun_id = 0, num_filled = 0; targ_lun_id < num_port_luns && num_filled < num_luns; targ_lun_id++) { lun_id = ctl_lun_map_from_port(port, targ_lun_id); if (lun_id == UINT32_MAX) continue; lun = softc->ctl_luns[lun_id]; if (lun == NULL) continue; be64enc(lun_data->luns[num_filled++].lundata, ctl_encode_lun(targ_lun_id)); /* * According to SPC-3, rev 14 section 6.21: * * "The execution of a REPORT LUNS command to any valid and * installed logical unit shall clear the REPORTED LUNS DATA * HAS CHANGED unit attention condition for all logical * units of that target with respect to the requesting * initiator. A valid and installed logical unit is one * having a PERIPHERAL QUALIFIER of 000b in the standard * INQUIRY data (see 6.4.2)." * * If request_lun is NULL, the LUN this report luns command * was issued to is either disabled or doesn't exist. In that * case, we shouldn't clear any pending lun change unit * attention. */ if (request_lun != NULL) { mtx_lock(&lun->lun_lock); ctl_clr_ua(lun, initidx, CTL_UA_LUN_CHANGE); mtx_unlock(&lun->lun_lock); } } mtx_unlock(&softc->ctl_lock); /* * It's quite possible that we've returned fewer LUNs than we allocated * space for. Trim it. */ lun_datalen = sizeof(*lun_data) + (num_filled * sizeof(struct scsi_report_luns_lundata)); ctsio->kern_rel_offset = 0; ctsio->kern_sg_entries = 0; ctsio->kern_data_len = min(lun_datalen, alloc_len); ctsio->kern_total_len = ctsio->kern_data_len; /* * We set this to the actual data length, regardless of how much * space we actually have to return results. If the user looks at * this value, he'll know whether or not he allocated enough space * and reissue the command if necessary. We don't support well * known logical units, so if the user asks for that, return none. */ scsi_ulto4b(lun_datalen - 8, lun_data->length); /* * We can only return SCSI_STATUS_CHECK_COND when we can't satisfy * this request. */ ctl_set_success(ctsio); ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (retval); } int ctl_request_sense(struct ctl_scsiio *ctsio) { struct ctl_softc *softc = CTL_SOFTC(ctsio); struct ctl_lun *lun = CTL_LUN(ctsio); struct scsi_request_sense *cdb; struct scsi_sense_data *sense_ptr, *ps; uint32_t initidx; int have_error; u_int sense_len = SSD_FULL_SIZE; scsi_sense_data_type sense_format; ctl_ua_type ua_type; uint8_t asc = 0, ascq = 0; cdb = (struct scsi_request_sense *)ctsio->cdb; CTL_DEBUG_PRINT(("ctl_request_sense\n")); /* * Determine which sense format the user wants. */ if (cdb->byte2 & SRS_DESC) sense_format = SSD_TYPE_DESC; else sense_format = SSD_TYPE_FIXED; ctsio->kern_data_ptr = malloc(sizeof(*sense_ptr), M_CTL, M_WAITOK); sense_ptr = (struct scsi_sense_data *)ctsio->kern_data_ptr; ctsio->kern_sg_entries = 0; ctsio->kern_rel_offset = 0; /* * struct scsi_sense_data, which is currently set to 256 bytes, is * larger than the largest allowed value for the length field in the * REQUEST SENSE CDB, which is 252 bytes as of SPC-4. */ ctsio->kern_data_len = cdb->length; ctsio->kern_total_len = cdb->length; /* * If we don't have a LUN, we don't have any pending sense. */ if (lun == NULL || ((lun->flags & CTL_LUN_PRIMARY_SC) == 0 && softc->ha_link < CTL_HA_LINK_UNKNOWN)) { /* "Logical unit not supported" */ ctl_set_sense_data(sense_ptr, &sense_len, NULL, sense_format, /*current_error*/ 1, /*sense_key*/ SSD_KEY_ILLEGAL_REQUEST, /*asc*/ 0x25, /*ascq*/ 0x00, SSD_ELEM_NONE); goto send; } have_error = 0; initidx = ctl_get_initindex(&ctsio->io_hdr.nexus); /* * Check for pending sense, and then for pending unit attentions. * Pending sense gets returned first, then pending unit attentions. */ mtx_lock(&lun->lun_lock); ps = lun->pending_sense[initidx / CTL_MAX_INIT_PER_PORT]; if (ps != NULL) ps += initidx % CTL_MAX_INIT_PER_PORT; if (ps != NULL && ps->error_code != 0) { scsi_sense_data_type stored_format; /* * Check to see which sense format was used for the stored * sense data. */ stored_format = scsi_sense_type(ps); /* * If the user requested a different sense format than the * one we stored, then we need to convert it to the other * format. If we're going from descriptor to fixed format * sense data, we may lose things in translation, depending * on what options were used. * * If the stored format is SSD_TYPE_NONE (i.e. invalid), * for some reason we'll just copy it out as-is. */ if ((stored_format == SSD_TYPE_FIXED) && (sense_format == SSD_TYPE_DESC)) ctl_sense_to_desc((struct scsi_sense_data_fixed *) ps, (struct scsi_sense_data_desc *)sense_ptr); else if ((stored_format == SSD_TYPE_DESC) && (sense_format == SSD_TYPE_FIXED)) ctl_sense_to_fixed((struct scsi_sense_data_desc *) ps, (struct scsi_sense_data_fixed *)sense_ptr); else memcpy(sense_ptr, ps, sizeof(*sense_ptr)); ps->error_code = 0; have_error = 1; } else { ua_type = ctl_build_ua(lun, initidx, sense_ptr, &sense_len, sense_format); if (ua_type != CTL_UA_NONE) have_error = 1; } if (have_error == 0) { /* * Report informational exception if have one and allowed. */ if (lun->MODE_IE.mrie != SIEP_MRIE_NO) { asc = lun->ie_asc; ascq = lun->ie_ascq; } ctl_set_sense_data(sense_ptr, &sense_len, lun, sense_format, /*current_error*/ 1, /*sense_key*/ SSD_KEY_NO_SENSE, /*asc*/ asc, /*ascq*/ ascq, SSD_ELEM_NONE); } mtx_unlock(&lun->lun_lock); send: /* * We report the SCSI status as OK, since the status of the command * itself is OK. We're reporting sense as parameter data. */ ctl_set_success(ctsio); ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } int ctl_tur(struct ctl_scsiio *ctsio) { CTL_DEBUG_PRINT(("ctl_tur\n")); ctl_set_success(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } /* * SCSI VPD page 0x00, the Supported VPD Pages page. */ static int ctl_inquiry_evpd_supported(struct ctl_scsiio *ctsio, int alloc_len) { struct ctl_lun *lun = CTL_LUN(ctsio); struct scsi_vpd_supported_pages *pages; int sup_page_size; int p; sup_page_size = sizeof(struct scsi_vpd_supported_pages) * SCSI_EVPD_NUM_SUPPORTED_PAGES; ctsio->kern_data_ptr = malloc(sup_page_size, M_CTL, M_WAITOK | M_ZERO); pages = (struct scsi_vpd_supported_pages *)ctsio->kern_data_ptr; ctsio->kern_rel_offset = 0; ctsio->kern_sg_entries = 0; ctsio->kern_data_len = min(sup_page_size, alloc_len); ctsio->kern_total_len = ctsio->kern_data_len; /* * The control device is always connected. The disk device, on the * other hand, may not be online all the time. Need to change this * to figure out whether the disk device is actually online or not. */ if (lun != NULL) pages->device = (SID_QUAL_LU_CONNECTED << 5) | lun->be_lun->lun_type; else pages->device = (SID_QUAL_LU_OFFLINE << 5) | T_DIRECT; p = 0; /* Supported VPD pages */ pages->page_list[p++] = SVPD_SUPPORTED_PAGES; /* Serial Number */ pages->page_list[p++] = SVPD_UNIT_SERIAL_NUMBER; /* Device Identification */ pages->page_list[p++] = SVPD_DEVICE_ID; /* Extended INQUIRY Data */ pages->page_list[p++] = SVPD_EXTENDED_INQUIRY_DATA; /* Mode Page Policy */ pages->page_list[p++] = SVPD_MODE_PAGE_POLICY; /* SCSI Ports */ pages->page_list[p++] = SVPD_SCSI_PORTS; /* Third-party Copy */ pages->page_list[p++] = SVPD_SCSI_TPC; /* SCSI Feature Sets */ pages->page_list[p++] = SVPD_SCSI_SFS; if (lun != NULL && lun->be_lun->lun_type == T_DIRECT) { /* Block limits */ pages->page_list[p++] = SVPD_BLOCK_LIMITS; /* Block Device Characteristics */ pages->page_list[p++] = SVPD_BDC; /* Logical Block Provisioning */ pages->page_list[p++] = SVPD_LBP; } pages->length = p; ctl_set_success(ctsio); ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } /* * SCSI VPD page 0x80, the Unit Serial Number page. */ static int ctl_inquiry_evpd_serial(struct ctl_scsiio *ctsio, int alloc_len) { struct ctl_lun *lun = CTL_LUN(ctsio); struct scsi_vpd_unit_serial_number *sn_ptr; int data_len; data_len = 4 + CTL_SN_LEN; ctsio->kern_data_ptr = malloc(data_len, M_CTL, M_WAITOK | M_ZERO); sn_ptr = (struct scsi_vpd_unit_serial_number *)ctsio->kern_data_ptr; ctsio->kern_rel_offset = 0; ctsio->kern_sg_entries = 0; ctsio->kern_data_len = min(data_len, alloc_len); ctsio->kern_total_len = ctsio->kern_data_len; /* * The control device is always connected. The disk device, on the * other hand, may not be online all the time. Need to change this * to figure out whether the disk device is actually online or not. */ if (lun != NULL) sn_ptr->device = (SID_QUAL_LU_CONNECTED << 5) | lun->be_lun->lun_type; else sn_ptr->device = (SID_QUAL_LU_OFFLINE << 5) | T_DIRECT; sn_ptr->page_code = SVPD_UNIT_SERIAL_NUMBER; sn_ptr->length = CTL_SN_LEN; /* * If we don't have a LUN, we just leave the serial number as * all spaces. */ if (lun != NULL) { strncpy((char *)sn_ptr->serial_num, (char *)lun->be_lun->serial_num, CTL_SN_LEN); } else memset(sn_ptr->serial_num, 0x20, CTL_SN_LEN); ctl_set_success(ctsio); ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } /* * SCSI VPD page 0x86, the Extended INQUIRY Data page. */ static int ctl_inquiry_evpd_eid(struct ctl_scsiio *ctsio, int alloc_len) { struct ctl_lun *lun = CTL_LUN(ctsio); struct scsi_vpd_extended_inquiry_data *eid_ptr; int data_len; data_len = sizeof(struct scsi_vpd_extended_inquiry_data); ctsio->kern_data_ptr = malloc(data_len, M_CTL, M_WAITOK | M_ZERO); eid_ptr = (struct scsi_vpd_extended_inquiry_data *)ctsio->kern_data_ptr; ctsio->kern_sg_entries = 0; ctsio->kern_rel_offset = 0; ctsio->kern_data_len = min(data_len, alloc_len); ctsio->kern_total_len = ctsio->kern_data_len; /* * The control device is always connected. The disk device, on the * other hand, may not be online all the time. */ if (lun != NULL) eid_ptr->device = (SID_QUAL_LU_CONNECTED << 5) | lun->be_lun->lun_type; else eid_ptr->device = (SID_QUAL_LU_OFFLINE << 5) | T_DIRECT; eid_ptr->page_code = SVPD_EXTENDED_INQUIRY_DATA; scsi_ulto2b(data_len - 4, eid_ptr->page_length); /* * We support head of queue, ordered and simple tags. */ eid_ptr->flags2 = SVPD_EID_HEADSUP | SVPD_EID_ORDSUP | SVPD_EID_SIMPSUP; /* * Volatile cache supported. */ eid_ptr->flags3 = SVPD_EID_V_SUP; /* * This means that we clear the REPORTED LUNS DATA HAS CHANGED unit * attention for a particular IT nexus on all LUNs once we report * it to that nexus once. This bit is required as of SPC-4. */ eid_ptr->flags4 = SVPD_EID_LUICLR; /* * We support revert to defaults (RTD) bit in MODE SELECT. */ eid_ptr->flags5 = SVPD_EID_RTD_SUP; /* * XXX KDM in order to correctly answer this, we would need * information from the SIM to determine how much sense data it * can send. So this would really be a path inquiry field, most * likely. This can be set to a maximum of 252 according to SPC-4, * but the hardware may or may not be able to support that much. * 0 just means that the maximum sense data length is not reported. */ eid_ptr->max_sense_length = 0; ctl_set_success(ctsio); ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } static int ctl_inquiry_evpd_mpp(struct ctl_scsiio *ctsio, int alloc_len) { struct ctl_lun *lun = CTL_LUN(ctsio); struct scsi_vpd_mode_page_policy *mpp_ptr; int data_len; data_len = sizeof(struct scsi_vpd_mode_page_policy) + sizeof(struct scsi_vpd_mode_page_policy_descr); ctsio->kern_data_ptr = malloc(data_len, M_CTL, M_WAITOK | M_ZERO); mpp_ptr = (struct scsi_vpd_mode_page_policy *)ctsio->kern_data_ptr; ctsio->kern_rel_offset = 0; ctsio->kern_sg_entries = 0; ctsio->kern_data_len = min(data_len, alloc_len); ctsio->kern_total_len = ctsio->kern_data_len; /* * The control device is always connected. The disk device, on the * other hand, may not be online all the time. */ if (lun != NULL) mpp_ptr->device = (SID_QUAL_LU_CONNECTED << 5) | lun->be_lun->lun_type; else mpp_ptr->device = (SID_QUAL_LU_OFFLINE << 5) | T_DIRECT; mpp_ptr->page_code = SVPD_MODE_PAGE_POLICY; scsi_ulto2b(data_len - 4, mpp_ptr->page_length); mpp_ptr->descr[0].page_code = 0x3f; mpp_ptr->descr[0].subpage_code = 0xff; mpp_ptr->descr[0].policy = SVPD_MPP_SHARED; ctl_set_success(ctsio); ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } /* * SCSI VPD page 0x83, the Device Identification page. */ static int ctl_inquiry_evpd_devid(struct ctl_scsiio *ctsio, int alloc_len) { struct ctl_softc *softc = CTL_SOFTC(ctsio); struct ctl_port *port = CTL_PORT(ctsio); struct ctl_lun *lun = CTL_LUN(ctsio); struct scsi_vpd_device_id *devid_ptr; struct scsi_vpd_id_descriptor *desc; int data_len, g; uint8_t proto; data_len = sizeof(struct scsi_vpd_device_id) + sizeof(struct scsi_vpd_id_descriptor) + sizeof(struct scsi_vpd_id_rel_trgt_port_id) + sizeof(struct scsi_vpd_id_descriptor) + sizeof(struct scsi_vpd_id_trgt_port_grp_id); if (lun && lun->lun_devid) data_len += lun->lun_devid->len; if (port && port->port_devid) data_len += port->port_devid->len; if (port && port->target_devid) data_len += port->target_devid->len; ctsio->kern_data_ptr = malloc(data_len, M_CTL, M_WAITOK | M_ZERO); devid_ptr = (struct scsi_vpd_device_id *)ctsio->kern_data_ptr; ctsio->kern_sg_entries = 0; ctsio->kern_rel_offset = 0; ctsio->kern_sg_entries = 0; ctsio->kern_data_len = min(data_len, alloc_len); ctsio->kern_total_len = ctsio->kern_data_len; /* * The control device is always connected. The disk device, on the * other hand, may not be online all the time. */ if (lun != NULL) devid_ptr->device = (SID_QUAL_LU_CONNECTED << 5) | lun->be_lun->lun_type; else devid_ptr->device = (SID_QUAL_LU_OFFLINE << 5) | T_DIRECT; devid_ptr->page_code = SVPD_DEVICE_ID; scsi_ulto2b(data_len - 4, devid_ptr->length); if (port && port->port_type == CTL_PORT_FC) proto = SCSI_PROTO_FC << 4; else if (port && port->port_type == CTL_PORT_SAS) proto = SCSI_PROTO_SAS << 4; else if (port && port->port_type == CTL_PORT_ISCSI) proto = SCSI_PROTO_ISCSI << 4; else proto = SCSI_PROTO_SPI << 4; desc = (struct scsi_vpd_id_descriptor *)devid_ptr->desc_list; /* * We're using a LUN association here. i.e., this device ID is a * per-LUN identifier. */ if (lun && lun->lun_devid) { memcpy(desc, lun->lun_devid->data, lun->lun_devid->len); desc = (struct scsi_vpd_id_descriptor *)((uint8_t *)desc + lun->lun_devid->len); } /* * This is for the WWPN which is a port association. */ if (port && port->port_devid) { memcpy(desc, port->port_devid->data, port->port_devid->len); desc = (struct scsi_vpd_id_descriptor *)((uint8_t *)desc + port->port_devid->len); } /* * This is for the Relative Target Port(type 4h) identifier */ desc->proto_codeset = proto | SVPD_ID_CODESET_BINARY; desc->id_type = SVPD_ID_PIV | SVPD_ID_ASSOC_PORT | SVPD_ID_TYPE_RELTARG; desc->length = 4; scsi_ulto2b(ctsio->io_hdr.nexus.targ_port, &desc->identifier[2]); desc = (struct scsi_vpd_id_descriptor *)(&desc->identifier[0] + sizeof(struct scsi_vpd_id_rel_trgt_port_id)); /* * This is for the Target Port Group(type 5h) identifier */ desc->proto_codeset = proto | SVPD_ID_CODESET_BINARY; desc->id_type = SVPD_ID_PIV | SVPD_ID_ASSOC_PORT | SVPD_ID_TYPE_TPORTGRP; desc->length = 4; if (softc->is_single || (port && port->status & CTL_PORT_STATUS_HA_SHARED)) g = 1; else g = 2 + ctsio->io_hdr.nexus.targ_port / softc->port_cnt; scsi_ulto2b(g, &desc->identifier[2]); desc = (struct scsi_vpd_id_descriptor *)(&desc->identifier[0] + sizeof(struct scsi_vpd_id_trgt_port_grp_id)); /* * This is for the Target identifier */ if (port && port->target_devid) { memcpy(desc, port->target_devid->data, port->target_devid->len); } ctl_set_success(ctsio); ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } static int ctl_inquiry_evpd_scsi_ports(struct ctl_scsiio *ctsio, int alloc_len) { struct ctl_softc *softc = CTL_SOFTC(ctsio); struct ctl_lun *lun = CTL_LUN(ctsio); struct scsi_vpd_scsi_ports *sp; struct scsi_vpd_port_designation *pd; struct scsi_vpd_port_designation_cont *pdc; struct ctl_port *port; int data_len, num_target_ports, iid_len, id_len; num_target_ports = 0; iid_len = 0; id_len = 0; mtx_lock(&softc->ctl_lock); STAILQ_FOREACH(port, &softc->port_list, links) { if ((port->status & CTL_PORT_STATUS_ONLINE) == 0) continue; if (lun != NULL && ctl_lun_map_to_port(port, lun->lun) == UINT32_MAX) continue; num_target_ports++; if (port->init_devid) iid_len += port->init_devid->len; if (port->port_devid) id_len += port->port_devid->len; } mtx_unlock(&softc->ctl_lock); data_len = sizeof(struct scsi_vpd_scsi_ports) + num_target_ports * (sizeof(struct scsi_vpd_port_designation) + sizeof(struct scsi_vpd_port_designation_cont)) + iid_len + id_len; ctsio->kern_data_ptr = malloc(data_len, M_CTL, M_WAITOK | M_ZERO); sp = (struct scsi_vpd_scsi_ports *)ctsio->kern_data_ptr; ctsio->kern_sg_entries = 0; ctsio->kern_rel_offset = 0; ctsio->kern_sg_entries = 0; ctsio->kern_data_len = min(data_len, alloc_len); ctsio->kern_total_len = ctsio->kern_data_len; /* * The control device is always connected. The disk device, on the * other hand, may not be online all the time. Need to change this * to figure out whether the disk device is actually online or not. */ if (lun != NULL) sp->device = (SID_QUAL_LU_CONNECTED << 5) | lun->be_lun->lun_type; else sp->device = (SID_QUAL_LU_OFFLINE << 5) | T_DIRECT; sp->page_code = SVPD_SCSI_PORTS; scsi_ulto2b(data_len - sizeof(struct scsi_vpd_scsi_ports), sp->page_length); pd = &sp->design[0]; mtx_lock(&softc->ctl_lock); STAILQ_FOREACH(port, &softc->port_list, links) { if ((port->status & CTL_PORT_STATUS_ONLINE) == 0) continue; if (lun != NULL && ctl_lun_map_to_port(port, lun->lun) == UINT32_MAX) continue; scsi_ulto2b(port->targ_port, pd->relative_port_id); if (port->init_devid) { iid_len = port->init_devid->len; memcpy(pd->initiator_transportid, port->init_devid->data, port->init_devid->len); } else iid_len = 0; scsi_ulto2b(iid_len, pd->initiator_transportid_length); pdc = (struct scsi_vpd_port_designation_cont *) (&pd->initiator_transportid[iid_len]); if (port->port_devid) { id_len = port->port_devid->len; memcpy(pdc->target_port_descriptors, port->port_devid->data, port->port_devid->len); } else id_len = 0; scsi_ulto2b(id_len, pdc->target_port_descriptors_length); pd = (struct scsi_vpd_port_designation *) ((uint8_t *)pdc->target_port_descriptors + id_len); } mtx_unlock(&softc->ctl_lock); ctl_set_success(ctsio); ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } static int ctl_inquiry_evpd_sfs(struct ctl_scsiio *ctsio, int alloc_len) { struct ctl_lun *lun = CTL_LUN(ctsio); struct scsi_vpd_sfs *sfs_ptr; int sfs_page_size, n; sfs_page_size = sizeof(*sfs_ptr) + 5 * 2; ctsio->kern_data_ptr = malloc(sfs_page_size, M_CTL, M_WAITOK | M_ZERO); sfs_ptr = (struct scsi_vpd_sfs *)ctsio->kern_data_ptr; ctsio->kern_sg_entries = 0; ctsio->kern_rel_offset = 0; ctsio->kern_sg_entries = 0; ctsio->kern_data_len = min(sfs_page_size, alloc_len); ctsio->kern_total_len = ctsio->kern_data_len; /* * The control device is always connected. The disk device, on the * other hand, may not be online all the time. Need to change this * to figure out whether the disk device is actually online or not. */ if (lun != NULL) sfs_ptr->device = (SID_QUAL_LU_CONNECTED << 5) | lun->be_lun->lun_type; else sfs_ptr->device = (SID_QUAL_LU_OFFLINE << 5) | T_DIRECT; sfs_ptr->page_code = SVPD_SCSI_SFS; n = 0; /* Discovery 2016 */ scsi_ulto2b(0x0001, &sfs_ptr->codes[2 * n++]); if (lun != NULL && lun->be_lun->lun_type == T_DIRECT) { /* SBC Base 2016 */ scsi_ulto2b(0x0101, &sfs_ptr->codes[2 * n++]); /* SBC Base 2010 */ scsi_ulto2b(0x0102, &sfs_ptr->codes[2 * n++]); if (lun->be_lun->flags & CTL_LUN_FLAG_UNMAP) { /* Basic Provisioning 2016 */ scsi_ulto2b(0x0103, &sfs_ptr->codes[2 * n++]); } /* Drive Maintenance 2016 */ //scsi_ulto2b(0x0104, &sfs_ptr->codes[2 * n++]); } scsi_ulto2b(4 + 2 * n, sfs_ptr->page_length); ctl_set_success(ctsio); ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } static int ctl_inquiry_evpd_block_limits(struct ctl_scsiio *ctsio, int alloc_len) { struct ctl_lun *lun = CTL_LUN(ctsio); struct scsi_vpd_block_limits *bl_ptr; const char *val; uint64_t ival; ctsio->kern_data_ptr = malloc(sizeof(*bl_ptr), M_CTL, M_WAITOK | M_ZERO); bl_ptr = (struct scsi_vpd_block_limits *)ctsio->kern_data_ptr; ctsio->kern_sg_entries = 0; ctsio->kern_rel_offset = 0; ctsio->kern_sg_entries = 0; ctsio->kern_data_len = min(sizeof(*bl_ptr), alloc_len); ctsio->kern_total_len = ctsio->kern_data_len; /* * The control device is always connected. The disk device, on the * other hand, may not be online all the time. Need to change this * to figure out whether the disk device is actually online or not. */ if (lun != NULL) bl_ptr->device = (SID_QUAL_LU_CONNECTED << 5) | lun->be_lun->lun_type; else bl_ptr->device = (SID_QUAL_LU_OFFLINE << 5) | T_DIRECT; bl_ptr->page_code = SVPD_BLOCK_LIMITS; scsi_ulto2b(sizeof(*bl_ptr) - 4, bl_ptr->page_length); bl_ptr->max_cmp_write_len = 0xff; scsi_ulto4b(0xffffffff, bl_ptr->max_txfer_len); if (lun != NULL) { scsi_ulto4b(lun->be_lun->opttxferlen, bl_ptr->opt_txfer_len); if (lun->be_lun->flags & CTL_LUN_FLAG_UNMAP) { ival = 0xffffffff; val = dnvlist_get_string(lun->be_lun->options, "unmap_max_lba", NULL); if (val != NULL) ctl_expand_number(val, &ival); scsi_ulto4b(ival, bl_ptr->max_unmap_lba_cnt); ival = 0xffffffff; val = dnvlist_get_string(lun->be_lun->options, "unmap_max_descr", NULL); if (val != NULL) ctl_expand_number(val, &ival); scsi_ulto4b(ival, bl_ptr->max_unmap_blk_cnt); if (lun->be_lun->ublockexp != 0) { scsi_ulto4b((1 << lun->be_lun->ublockexp), bl_ptr->opt_unmap_grain); scsi_ulto4b(0x80000000 | lun->be_lun->ublockoff, bl_ptr->unmap_grain_align); } } scsi_ulto4b(lun->be_lun->atomicblock, bl_ptr->max_atomic_transfer_length); scsi_ulto4b(0, bl_ptr->atomic_alignment); scsi_ulto4b(0, bl_ptr->atomic_transfer_length_granularity); scsi_ulto4b(0, bl_ptr->max_atomic_transfer_length_with_atomic_boundary); scsi_ulto4b(0, bl_ptr->max_atomic_boundary_size); ival = UINT64_MAX; val = dnvlist_get_string(lun->be_lun->options, "write_same_max_lba", NULL); if (val != NULL) ctl_expand_number(val, &ival); scsi_u64to8b(ival, bl_ptr->max_write_same_length); if (lun->be_lun->maxlba + 1 > ival) bl_ptr->flags |= SVPD_BL_WSNZ; } ctl_set_success(ctsio); ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } static int ctl_inquiry_evpd_bdc(struct ctl_scsiio *ctsio, int alloc_len) { struct ctl_lun *lun = CTL_LUN(ctsio); struct scsi_vpd_block_device_characteristics *bdc_ptr; const char *value; u_int i; ctsio->kern_data_ptr = malloc(sizeof(*bdc_ptr), M_CTL, M_WAITOK | M_ZERO); bdc_ptr = (struct scsi_vpd_block_device_characteristics *)ctsio->kern_data_ptr; ctsio->kern_sg_entries = 0; ctsio->kern_rel_offset = 0; ctsio->kern_data_len = min(sizeof(*bdc_ptr), alloc_len); ctsio->kern_total_len = ctsio->kern_data_len; /* * The control device is always connected. The disk device, on the * other hand, may not be online all the time. Need to change this * to figure out whether the disk device is actually online or not. */ if (lun != NULL) bdc_ptr->device = (SID_QUAL_LU_CONNECTED << 5) | lun->be_lun->lun_type; else bdc_ptr->device = (SID_QUAL_LU_OFFLINE << 5) | T_DIRECT; bdc_ptr->page_code = SVPD_BDC; scsi_ulto2b(sizeof(*bdc_ptr) - 4, bdc_ptr->page_length); if (lun != NULL && (value = dnvlist_get_string(lun->be_lun->options, "rpm", NULL)) != NULL) i = strtol(value, NULL, 0); else i = CTL_DEFAULT_ROTATION_RATE; scsi_ulto2b(i, bdc_ptr->medium_rotation_rate); if (lun != NULL && (value = dnvlist_get_string(lun->be_lun->options, "formfactor", NULL)) != NULL) i = strtol(value, NULL, 0); else i = 0; bdc_ptr->wab_wac_ff = (i & 0x0f); bdc_ptr->flags = SVPD_RBWZ | SVPD_FUAB | SVPD_VBULS; ctl_set_success(ctsio); ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } static int ctl_inquiry_evpd_lbp(struct ctl_scsiio *ctsio, int alloc_len) { struct ctl_lun *lun = CTL_LUN(ctsio); struct scsi_vpd_logical_block_prov *lbp_ptr; const char *value; ctsio->kern_data_ptr = malloc(sizeof(*lbp_ptr), M_CTL, M_WAITOK | M_ZERO); lbp_ptr = (struct scsi_vpd_logical_block_prov *)ctsio->kern_data_ptr; ctsio->kern_sg_entries = 0; ctsio->kern_rel_offset = 0; ctsio->kern_data_len = min(sizeof(*lbp_ptr), alloc_len); ctsio->kern_total_len = ctsio->kern_data_len; /* * The control device is always connected. The disk device, on the * other hand, may not be online all the time. Need to change this * to figure out whether the disk device is actually online or not. */ if (lun != NULL) lbp_ptr->device = (SID_QUAL_LU_CONNECTED << 5) | lun->be_lun->lun_type; else lbp_ptr->device = (SID_QUAL_LU_OFFLINE << 5) | T_DIRECT; lbp_ptr->page_code = SVPD_LBP; scsi_ulto2b(sizeof(*lbp_ptr) - 4, lbp_ptr->page_length); lbp_ptr->threshold_exponent = CTL_LBP_EXPONENT; if (lun != NULL && lun->be_lun->flags & CTL_LUN_FLAG_UNMAP) { lbp_ptr->flags = SVPD_LBP_UNMAP | SVPD_LBP_WS16 | SVPD_LBP_WS10 | SVPD_LBP_RZ | SVPD_LBP_ANC_SUP; value = dnvlist_get_string(lun->be_lun->options, "provisioning_type", NULL); if (value != NULL) { if (strcmp(value, "resource") == 0) lbp_ptr->prov_type = SVPD_LBP_RESOURCE; else if (strcmp(value, "thin") == 0) lbp_ptr->prov_type = SVPD_LBP_THIN; } else lbp_ptr->prov_type = SVPD_LBP_THIN; } ctl_set_success(ctsio); ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } /* * INQUIRY with the EVPD bit set. */ static int ctl_inquiry_evpd(struct ctl_scsiio *ctsio) { struct ctl_lun *lun = CTL_LUN(ctsio); struct scsi_inquiry *cdb; int alloc_len, retval; cdb = (struct scsi_inquiry *)ctsio->cdb; alloc_len = scsi_2btoul(cdb->length); switch (cdb->page_code) { case SVPD_SUPPORTED_PAGES: retval = ctl_inquiry_evpd_supported(ctsio, alloc_len); break; case SVPD_UNIT_SERIAL_NUMBER: retval = ctl_inquiry_evpd_serial(ctsio, alloc_len); break; case SVPD_DEVICE_ID: retval = ctl_inquiry_evpd_devid(ctsio, alloc_len); break; case SVPD_EXTENDED_INQUIRY_DATA: retval = ctl_inquiry_evpd_eid(ctsio, alloc_len); break; case SVPD_MODE_PAGE_POLICY: retval = ctl_inquiry_evpd_mpp(ctsio, alloc_len); break; case SVPD_SCSI_PORTS: retval = ctl_inquiry_evpd_scsi_ports(ctsio, alloc_len); break; case SVPD_SCSI_TPC: retval = ctl_inquiry_evpd_tpc(ctsio, alloc_len); break; case SVPD_SCSI_SFS: retval = ctl_inquiry_evpd_sfs(ctsio, alloc_len); break; case SVPD_BLOCK_LIMITS: if (lun == NULL || lun->be_lun->lun_type != T_DIRECT) goto err; retval = ctl_inquiry_evpd_block_limits(ctsio, alloc_len); break; case SVPD_BDC: if (lun == NULL || lun->be_lun->lun_type != T_DIRECT) goto err; retval = ctl_inquiry_evpd_bdc(ctsio, alloc_len); break; case SVPD_LBP: if (lun == NULL || lun->be_lun->lun_type != T_DIRECT) goto err; retval = ctl_inquiry_evpd_lbp(ctsio, alloc_len); break; default: err: ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 2, /*bit_valid*/ 0, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); retval = CTL_RETVAL_COMPLETE; break; } return (retval); } /* * Standard INQUIRY data. */ static int ctl_inquiry_std(struct ctl_scsiio *ctsio) { struct ctl_softc *softc = CTL_SOFTC(ctsio); struct ctl_port *port = CTL_PORT(ctsio); struct ctl_lun *lun = CTL_LUN(ctsio); struct scsi_inquiry_data *inq_ptr; struct scsi_inquiry *cdb; const char *val; uint32_t alloc_len, data_len; ctl_port_type port_type; port_type = port->port_type; if (port_type == CTL_PORT_IOCTL || port_type == CTL_PORT_INTERNAL) port_type = CTL_PORT_SCSI; cdb = (struct scsi_inquiry *)ctsio->cdb; alloc_len = scsi_2btoul(cdb->length); /* * We malloc the full inquiry data size here and fill it * in. If the user only asks for less, we'll give him * that much. */ data_len = offsetof(struct scsi_inquiry_data, vendor_specific1); ctsio->kern_data_ptr = malloc(data_len, M_CTL, M_WAITOK | M_ZERO); inq_ptr = (struct scsi_inquiry_data *)ctsio->kern_data_ptr; ctsio->kern_sg_entries = 0; ctsio->kern_rel_offset = 0; ctsio->kern_data_len = min(data_len, alloc_len); ctsio->kern_total_len = ctsio->kern_data_len; if (lun != NULL) { if ((lun->flags & CTL_LUN_PRIMARY_SC) || softc->ha_link >= CTL_HA_LINK_UNKNOWN) { inq_ptr->device = (SID_QUAL_LU_CONNECTED << 5) | lun->be_lun->lun_type; } else { inq_ptr->device = (SID_QUAL_LU_OFFLINE << 5) | lun->be_lun->lun_type; } if (lun->flags & CTL_LUN_REMOVABLE) inq_ptr->dev_qual2 |= SID_RMB; } else inq_ptr->device = (SID_QUAL_BAD_LU << 5) | T_NODEVICE; /* RMB in byte 2 is 0 */ inq_ptr->version = SCSI_REV_SPC5; /* * According to SAM-3, even if a device only supports a single * level of LUN addressing, it should still set the HISUP bit: * * 4.9.1 Logical unit numbers overview * * All logical unit number formats described in this standard are * hierarchical in structure even when only a single level in that * hierarchy is used. The HISUP bit shall be set to one in the * standard INQUIRY data (see SPC-2) when any logical unit number * format described in this standard is used. Non-hierarchical * formats are outside the scope of this standard. * * Therefore we set the HiSup bit here. * * The response format is 2, per SPC-3. */ inq_ptr->response_format = SID_HiSup | 2; inq_ptr->additional_length = data_len - (offsetof(struct scsi_inquiry_data, additional_length) + 1); CTL_DEBUG_PRINT(("additional_length = %d\n", inq_ptr->additional_length)); inq_ptr->spc3_flags = SPC3_SID_3PC | SPC3_SID_TPGS_IMPLICIT; if (port_type == CTL_PORT_SCSI) inq_ptr->spc2_flags = SPC2_SID_ADDR16; inq_ptr->spc2_flags |= SPC2_SID_MultiP; inq_ptr->flags = SID_CmdQue; if (port_type == CTL_PORT_SCSI) inq_ptr->flags |= SID_WBus16 | SID_Sync; /* * Per SPC-3, unused bytes in ASCII strings are filled with spaces. * We have 8 bytes for the vendor name, and 16 bytes for the device * name and 4 bytes for the revision. */ if (lun == NULL || (val = dnvlist_get_string(lun->be_lun->options, "vendor", NULL)) == NULL) { strncpy(inq_ptr->vendor, CTL_VENDOR, sizeof(inq_ptr->vendor)); } else { memset(inq_ptr->vendor, ' ', sizeof(inq_ptr->vendor)); strncpy(inq_ptr->vendor, val, min(sizeof(inq_ptr->vendor), strlen(val))); } if (lun == NULL) { strncpy(inq_ptr->product, CTL_DIRECT_PRODUCT, sizeof(inq_ptr->product)); } else if ((val = dnvlist_get_string(lun->be_lun->options, "product", NULL)) == NULL) { switch (lun->be_lun->lun_type) { case T_DIRECT: strncpy(inq_ptr->product, CTL_DIRECT_PRODUCT, sizeof(inq_ptr->product)); break; case T_PROCESSOR: strncpy(inq_ptr->product, CTL_PROCESSOR_PRODUCT, sizeof(inq_ptr->product)); break; case T_CDROM: strncpy(inq_ptr->product, CTL_CDROM_PRODUCT, sizeof(inq_ptr->product)); break; default: strncpy(inq_ptr->product, CTL_UNKNOWN_PRODUCT, sizeof(inq_ptr->product)); break; } } else { memset(inq_ptr->product, ' ', sizeof(inq_ptr->product)); strncpy(inq_ptr->product, val, min(sizeof(inq_ptr->product), strlen(val))); } /* * XXX make this a macro somewhere so it automatically gets * incremented when we make changes. */ if (lun == NULL || (val = dnvlist_get_string(lun->be_lun->options, "revision", NULL)) == NULL) { strncpy(inq_ptr->revision, "0001", sizeof(inq_ptr->revision)); } else { memset(inq_ptr->revision, ' ', sizeof(inq_ptr->revision)); strncpy(inq_ptr->revision, val, min(sizeof(inq_ptr->revision), strlen(val))); } /* * For parallel SCSI, we support double transition and single * transition clocking. We also support QAS (Quick Arbitration * and Selection) and Information Unit transfers on both the * control and array devices. */ if (port_type == CTL_PORT_SCSI) inq_ptr->spi3data = SID_SPI_CLOCK_DT_ST | SID_SPI_QAS | SID_SPI_IUS; /* SAM-6 (no version claimed) */ scsi_ulto2b(0x00C0, inq_ptr->version1); /* SPC-5 (no version claimed) */ scsi_ulto2b(0x05C0, inq_ptr->version2); if (port_type == CTL_PORT_FC) { /* FCP-2 ANSI INCITS.350:2003 */ scsi_ulto2b(0x0917, inq_ptr->version3); } else if (port_type == CTL_PORT_SCSI) { /* SPI-4 ANSI INCITS.362:200x */ scsi_ulto2b(0x0B56, inq_ptr->version3); } else if (port_type == CTL_PORT_ISCSI) { /* iSCSI (no version claimed) */ scsi_ulto2b(0x0960, inq_ptr->version3); } else if (port_type == CTL_PORT_SAS) { /* SAS (no version claimed) */ scsi_ulto2b(0x0BE0, inq_ptr->version3); } else if (port_type == CTL_PORT_UMASS) { /* USB Mass Storage Class Bulk-Only Transport, Revision 1.0 */ scsi_ulto2b(0x1730, inq_ptr->version3); } if (lun == NULL) { /* SBC-4 (no version claimed) */ scsi_ulto2b(0x0600, inq_ptr->version4); } else { switch (lun->be_lun->lun_type) { case T_DIRECT: /* SBC-4 (no version claimed) */ scsi_ulto2b(0x0600, inq_ptr->version4); break; case T_PROCESSOR: break; case T_CDROM: /* MMC-6 (no version claimed) */ scsi_ulto2b(0x04E0, inq_ptr->version4); break; default: break; } } ctl_set_success(ctsio); ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } int ctl_inquiry(struct ctl_scsiio *ctsio) { struct scsi_inquiry *cdb; int retval; CTL_DEBUG_PRINT(("ctl_inquiry\n")); cdb = (struct scsi_inquiry *)ctsio->cdb; if (cdb->byte2 & SI_EVPD) retval = ctl_inquiry_evpd(ctsio); else if (cdb->page_code == 0) retval = ctl_inquiry_std(ctsio); else { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 2, /*bit_valid*/ 0, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } return (retval); } int ctl_get_config(struct ctl_scsiio *ctsio) { struct ctl_lun *lun = CTL_LUN(ctsio); struct scsi_get_config_header *hdr; struct scsi_get_config_feature *feature; struct scsi_get_config *cdb; uint32_t alloc_len, data_len; int rt, starting; cdb = (struct scsi_get_config *)ctsio->cdb; rt = (cdb->rt & SGC_RT_MASK); starting = scsi_2btoul(cdb->starting_feature); alloc_len = scsi_2btoul(cdb->length); data_len = sizeof(struct scsi_get_config_header) + sizeof(struct scsi_get_config_feature) + 8 + sizeof(struct scsi_get_config_feature) + 8 + sizeof(struct scsi_get_config_feature) + 4 + sizeof(struct scsi_get_config_feature) + 4 + sizeof(struct scsi_get_config_feature) + 8 + sizeof(struct scsi_get_config_feature) + sizeof(struct scsi_get_config_feature) + 4 + sizeof(struct scsi_get_config_feature) + 4 + sizeof(struct scsi_get_config_feature) + 4 + sizeof(struct scsi_get_config_feature) + 4 + sizeof(struct scsi_get_config_feature) + 4 + sizeof(struct scsi_get_config_feature) + 4; ctsio->kern_data_ptr = malloc(data_len, M_CTL, M_WAITOK | M_ZERO); ctsio->kern_sg_entries = 0; ctsio->kern_rel_offset = 0; hdr = (struct scsi_get_config_header *)ctsio->kern_data_ptr; if (lun->flags & CTL_LUN_NO_MEDIA) scsi_ulto2b(0x0000, hdr->current_profile); else scsi_ulto2b(0x0010, hdr->current_profile); feature = (struct scsi_get_config_feature *)(hdr + 1); if (starting > 0x003b) goto done; if (starting > 0x003a) goto f3b; if (starting > 0x002b) goto f3a; if (starting > 0x002a) goto f2b; if (starting > 0x001f) goto f2a; if (starting > 0x001e) goto f1f; if (starting > 0x001d) goto f1e; if (starting > 0x0010) goto f1d; if (starting > 0x0003) goto f10; if (starting > 0x0002) goto f3; if (starting > 0x0001) goto f2; if (starting > 0x0000) goto f1; /* Profile List */ scsi_ulto2b(0x0000, feature->feature_code); feature->flags = SGC_F_PERSISTENT | SGC_F_CURRENT; feature->add_length = 8; scsi_ulto2b(0x0008, &feature->feature_data[0]); /* CD-ROM */ feature->feature_data[2] = 0x00; scsi_ulto2b(0x0010, &feature->feature_data[4]); /* DVD-ROM */ feature->feature_data[6] = 0x01; feature = (struct scsi_get_config_feature *) &feature->feature_data[feature->add_length]; f1: /* Core */ scsi_ulto2b(0x0001, feature->feature_code); feature->flags = 0x08 | SGC_F_PERSISTENT | SGC_F_CURRENT; feature->add_length = 8; scsi_ulto4b(0x00000000, &feature->feature_data[0]); feature->feature_data[4] = 0x03; feature = (struct scsi_get_config_feature *) &feature->feature_data[feature->add_length]; f2: /* Morphing */ scsi_ulto2b(0x0002, feature->feature_code); feature->flags = 0x04 | SGC_F_PERSISTENT | SGC_F_CURRENT; feature->add_length = 4; feature->feature_data[0] = 0x02; feature = (struct scsi_get_config_feature *) &feature->feature_data[feature->add_length]; f3: /* Removable Medium */ scsi_ulto2b(0x0003, feature->feature_code); feature->flags = 0x04 | SGC_F_PERSISTENT | SGC_F_CURRENT; feature->add_length = 4; feature->feature_data[0] = 0x39; feature = (struct scsi_get_config_feature *) &feature->feature_data[feature->add_length]; if (rt == SGC_RT_CURRENT && (lun->flags & CTL_LUN_NO_MEDIA)) goto done; f10: /* Random Read */ scsi_ulto2b(0x0010, feature->feature_code); feature->flags = 0x00; if ((lun->flags & CTL_LUN_NO_MEDIA) == 0) feature->flags |= SGC_F_CURRENT; feature->add_length = 8; scsi_ulto4b(lun->be_lun->blocksize, &feature->feature_data[0]); scsi_ulto2b(1, &feature->feature_data[4]); feature->feature_data[6] = 0x00; feature = (struct scsi_get_config_feature *) &feature->feature_data[feature->add_length]; f1d: /* Multi-Read */ scsi_ulto2b(0x001D, feature->feature_code); feature->flags = 0x00; if ((lun->flags & CTL_LUN_NO_MEDIA) == 0) feature->flags |= SGC_F_CURRENT; feature->add_length = 0; feature = (struct scsi_get_config_feature *) &feature->feature_data[feature->add_length]; f1e: /* CD Read */ scsi_ulto2b(0x001E, feature->feature_code); feature->flags = 0x00; if ((lun->flags & CTL_LUN_NO_MEDIA) == 0) feature->flags |= SGC_F_CURRENT; feature->add_length = 4; feature->feature_data[0] = 0x00; feature = (struct scsi_get_config_feature *) &feature->feature_data[feature->add_length]; f1f: /* DVD Read */ scsi_ulto2b(0x001F, feature->feature_code); feature->flags = 0x08; if ((lun->flags & CTL_LUN_NO_MEDIA) == 0) feature->flags |= SGC_F_CURRENT; feature->add_length = 4; feature->feature_data[0] = 0x01; feature->feature_data[2] = 0x03; feature = (struct scsi_get_config_feature *) &feature->feature_data[feature->add_length]; f2a: /* DVD+RW */ scsi_ulto2b(0x002A, feature->feature_code); feature->flags = 0x04; if ((lun->flags & CTL_LUN_NO_MEDIA) == 0) feature->flags |= SGC_F_CURRENT; feature->add_length = 4; feature->feature_data[0] = 0x00; feature->feature_data[1] = 0x00; feature = (struct scsi_get_config_feature *) &feature->feature_data[feature->add_length]; f2b: /* DVD+R */ scsi_ulto2b(0x002B, feature->feature_code); feature->flags = 0x00; if ((lun->flags & CTL_LUN_NO_MEDIA) == 0) feature->flags |= SGC_F_CURRENT; feature->add_length = 4; feature->feature_data[0] = 0x00; feature = (struct scsi_get_config_feature *) &feature->feature_data[feature->add_length]; f3a: /* DVD+RW Dual Layer */ scsi_ulto2b(0x003A, feature->feature_code); feature->flags = 0x00; if ((lun->flags & CTL_LUN_NO_MEDIA) == 0) feature->flags |= SGC_F_CURRENT; feature->add_length = 4; feature->feature_data[0] = 0x00; feature->feature_data[1] = 0x00; feature = (struct scsi_get_config_feature *) &feature->feature_data[feature->add_length]; f3b: /* DVD+R Dual Layer */ scsi_ulto2b(0x003B, feature->feature_code); feature->flags = 0x00; if ((lun->flags & CTL_LUN_NO_MEDIA) == 0) feature->flags |= SGC_F_CURRENT; feature->add_length = 4; feature->feature_data[0] = 0x00; feature = (struct scsi_get_config_feature *) &feature->feature_data[feature->add_length]; done: data_len = (uint8_t *)feature - (uint8_t *)hdr; if (rt == SGC_RT_SPECIFIC && data_len > 4) { feature = (struct scsi_get_config_feature *)(hdr + 1); if (scsi_2btoul(feature->feature_code) == starting) feature = (struct scsi_get_config_feature *) &feature->feature_data[feature->add_length]; data_len = (uint8_t *)feature - (uint8_t *)hdr; } scsi_ulto4b(data_len - 4, hdr->data_length); ctsio->kern_data_len = min(data_len, alloc_len); ctsio->kern_total_len = ctsio->kern_data_len; ctl_set_success(ctsio); ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } int ctl_get_event_status(struct ctl_scsiio *ctsio) { struct scsi_get_event_status_header *hdr; struct scsi_get_event_status *cdb; uint32_t alloc_len, data_len; cdb = (struct scsi_get_event_status *)ctsio->cdb; if ((cdb->byte2 & SGESN_POLLED) == 0) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 1, /*bit_valid*/ 1, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } alloc_len = scsi_2btoul(cdb->length); data_len = sizeof(struct scsi_get_event_status_header); ctsio->kern_data_ptr = malloc(data_len, M_CTL, M_WAITOK | M_ZERO); ctsio->kern_sg_entries = 0; ctsio->kern_rel_offset = 0; ctsio->kern_data_len = min(data_len, alloc_len); ctsio->kern_total_len = ctsio->kern_data_len; hdr = (struct scsi_get_event_status_header *)ctsio->kern_data_ptr; scsi_ulto2b(0, hdr->descr_length); hdr->nea_class = SGESN_NEA; hdr->supported_class = 0; ctl_set_success(ctsio); ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } int ctl_mechanism_status(struct ctl_scsiio *ctsio) { struct scsi_mechanism_status_header *hdr; struct scsi_mechanism_status *cdb; uint32_t alloc_len, data_len; cdb = (struct scsi_mechanism_status *)ctsio->cdb; alloc_len = scsi_2btoul(cdb->length); data_len = sizeof(struct scsi_mechanism_status_header); ctsio->kern_data_ptr = malloc(data_len, M_CTL, M_WAITOK | M_ZERO); ctsio->kern_sg_entries = 0; ctsio->kern_rel_offset = 0; ctsio->kern_data_len = min(data_len, alloc_len); ctsio->kern_total_len = ctsio->kern_data_len; hdr = (struct scsi_mechanism_status_header *)ctsio->kern_data_ptr; hdr->state1 = 0x00; hdr->state2 = 0xe0; scsi_ulto3b(0, hdr->lba); hdr->slots_num = 0; scsi_ulto2b(0, hdr->slots_length); ctl_set_success(ctsio); ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } static void ctl_ultomsf(uint32_t lba, uint8_t *buf) { lba += 150; buf[0] = 0; buf[1] = bin2bcd((lba / 75) / 60); buf[2] = bin2bcd((lba / 75) % 60); buf[3] = bin2bcd(lba % 75); } int ctl_read_toc(struct ctl_scsiio *ctsio) { struct ctl_lun *lun = CTL_LUN(ctsio); struct scsi_read_toc_hdr *hdr; struct scsi_read_toc_type01_descr *descr; struct scsi_read_toc *cdb; uint32_t alloc_len, data_len; int format, msf; cdb = (struct scsi_read_toc *)ctsio->cdb; msf = (cdb->byte2 & CD_MSF) != 0; format = cdb->format; alloc_len = scsi_2btoul(cdb->data_len); data_len = sizeof(struct scsi_read_toc_hdr); if (format == 0) data_len += 2 * sizeof(struct scsi_read_toc_type01_descr); else data_len += sizeof(struct scsi_read_toc_type01_descr); ctsio->kern_data_ptr = malloc(data_len, M_CTL, M_WAITOK | M_ZERO); ctsio->kern_sg_entries = 0; ctsio->kern_rel_offset = 0; ctsio->kern_data_len = min(data_len, alloc_len); ctsio->kern_total_len = ctsio->kern_data_len; hdr = (struct scsi_read_toc_hdr *)ctsio->kern_data_ptr; if (format == 0) { scsi_ulto2b(0x12, hdr->data_length); hdr->first = 1; hdr->last = 1; descr = (struct scsi_read_toc_type01_descr *)(hdr + 1); descr->addr_ctl = 0x14; descr->track_number = 1; if (msf) ctl_ultomsf(0, descr->track_start); else scsi_ulto4b(0, descr->track_start); descr++; descr->addr_ctl = 0x14; descr->track_number = 0xaa; if (msf) ctl_ultomsf(lun->be_lun->maxlba+1, descr->track_start); else scsi_ulto4b(lun->be_lun->maxlba+1, descr->track_start); } else { scsi_ulto2b(0x0a, hdr->data_length); hdr->first = 1; hdr->last = 1; descr = (struct scsi_read_toc_type01_descr *)(hdr + 1); descr->addr_ctl = 0x14; descr->track_number = 1; if (msf) ctl_ultomsf(0, descr->track_start); else scsi_ulto4b(0, descr->track_start); } ctl_set_success(ctsio); ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } /* * For known CDB types, parse the LBA and length. */ static int ctl_get_lba_len(union ctl_io *io, uint64_t *lba, uint64_t *len) { if (io->io_hdr.io_type != CTL_IO_SCSI) return (1); switch (io->scsiio.cdb[0]) { case COMPARE_AND_WRITE: { struct scsi_compare_and_write *cdb; cdb = (struct scsi_compare_and_write *)io->scsiio.cdb; *lba = scsi_8btou64(cdb->addr); *len = cdb->length; break; } case READ_6: case WRITE_6: { struct scsi_rw_6 *cdb; cdb = (struct scsi_rw_6 *)io->scsiio.cdb; *lba = scsi_3btoul(cdb->addr); /* only 5 bits are valid in the most significant address byte */ *lba &= 0x1fffff; *len = cdb->length; break; } case READ_10: case WRITE_10: { struct scsi_rw_10 *cdb; cdb = (struct scsi_rw_10 *)io->scsiio.cdb; *lba = scsi_4btoul(cdb->addr); *len = scsi_2btoul(cdb->length); break; } case WRITE_VERIFY_10: { struct scsi_write_verify_10 *cdb; cdb = (struct scsi_write_verify_10 *)io->scsiio.cdb; *lba = scsi_4btoul(cdb->addr); *len = scsi_2btoul(cdb->length); break; } case READ_12: case WRITE_12: { struct scsi_rw_12 *cdb; cdb = (struct scsi_rw_12 *)io->scsiio.cdb; *lba = scsi_4btoul(cdb->addr); *len = scsi_4btoul(cdb->length); break; } case WRITE_VERIFY_12: { struct scsi_write_verify_12 *cdb; cdb = (struct scsi_write_verify_12 *)io->scsiio.cdb; *lba = scsi_4btoul(cdb->addr); *len = scsi_4btoul(cdb->length); break; } case READ_16: case WRITE_16: { struct scsi_rw_16 *cdb; cdb = (struct scsi_rw_16 *)io->scsiio.cdb; *lba = scsi_8btou64(cdb->addr); *len = scsi_4btoul(cdb->length); break; } case WRITE_ATOMIC_16: { struct scsi_write_atomic_16 *cdb; cdb = (struct scsi_write_atomic_16 *)io->scsiio.cdb; *lba = scsi_8btou64(cdb->addr); *len = scsi_2btoul(cdb->length); break; } case WRITE_VERIFY_16: { struct scsi_write_verify_16 *cdb; cdb = (struct scsi_write_verify_16 *)io->scsiio.cdb; *lba = scsi_8btou64(cdb->addr); *len = scsi_4btoul(cdb->length); break; } case WRITE_SAME_10: { struct scsi_write_same_10 *cdb; cdb = (struct scsi_write_same_10 *)io->scsiio.cdb; *lba = scsi_4btoul(cdb->addr); *len = scsi_2btoul(cdb->length); break; } case WRITE_SAME_16: { struct scsi_write_same_16 *cdb; cdb = (struct scsi_write_same_16 *)io->scsiio.cdb; *lba = scsi_8btou64(cdb->addr); *len = scsi_4btoul(cdb->length); break; } case VERIFY_10: { struct scsi_verify_10 *cdb; cdb = (struct scsi_verify_10 *)io->scsiio.cdb; *lba = scsi_4btoul(cdb->addr); *len = scsi_2btoul(cdb->length); break; } case VERIFY_12: { struct scsi_verify_12 *cdb; cdb = (struct scsi_verify_12 *)io->scsiio.cdb; *lba = scsi_4btoul(cdb->addr); *len = scsi_4btoul(cdb->length); break; } case VERIFY_16: { struct scsi_verify_16 *cdb; cdb = (struct scsi_verify_16 *)io->scsiio.cdb; *lba = scsi_8btou64(cdb->addr); *len = scsi_4btoul(cdb->length); break; } case UNMAP: { *lba = 0; *len = UINT64_MAX; break; } case SERVICE_ACTION_IN: { /* GET LBA STATUS */ struct scsi_get_lba_status *cdb; cdb = (struct scsi_get_lba_status *)io->scsiio.cdb; *lba = scsi_8btou64(cdb->addr); *len = UINT32_MAX; break; } default: return (1); break; /* NOTREACHED */ } return (0); } static ctl_action ctl_extent_check_lba(uint64_t lba1, uint64_t len1, uint64_t lba2, uint64_t len2, bool seq) { uint64_t endlba1, endlba2; endlba1 = lba1 + len1 - (seq ? 0 : 1); endlba2 = lba2 + len2 - 1; if ((endlba1 < lba2) || (endlba2 < lba1)) return (CTL_ACTION_PASS); else return (CTL_ACTION_BLOCK); } static int ctl_extent_check_unmap(union ctl_io *io, uint64_t lba2, uint64_t len2) { struct ctl_ptr_len_flags *ptrlen; struct scsi_unmap_desc *buf, *end, *range; uint64_t lba; uint32_t len; /* If not UNMAP -- go other way. */ if (io->io_hdr.io_type != CTL_IO_SCSI || io->scsiio.cdb[0] != UNMAP) return (CTL_ACTION_ERROR); /* If UNMAP without data -- block and wait for data. */ ptrlen = (struct ctl_ptr_len_flags *) &io->io_hdr.ctl_private[CTL_PRIV_LBA_LEN]; if ((io->io_hdr.flags & CTL_FLAG_ALLOCATED) == 0 || ptrlen->ptr == NULL) return (CTL_ACTION_BLOCK); /* UNMAP with data -- check for collision. */ buf = (struct scsi_unmap_desc *)ptrlen->ptr; end = buf + ptrlen->len / sizeof(*buf); for (range = buf; range < end; range++) { lba = scsi_8btou64(range->lba); len = scsi_4btoul(range->length); if ((lba < lba2 + len2) && (lba + len > lba2)) return (CTL_ACTION_BLOCK); } return (CTL_ACTION_PASS); } static ctl_action ctl_extent_check(union ctl_io *io1, union ctl_io *io2, bool seq) { uint64_t lba1, lba2; uint64_t len1, len2; int retval; if (ctl_get_lba_len(io2, &lba2, &len2) != 0) return (CTL_ACTION_ERROR); retval = ctl_extent_check_unmap(io1, lba2, len2); if (retval != CTL_ACTION_ERROR) return (retval); if (ctl_get_lba_len(io1, &lba1, &len1) != 0) return (CTL_ACTION_ERROR); if (io1->io_hdr.flags & CTL_FLAG_SERSEQ_DONE) seq = FALSE; return (ctl_extent_check_lba(lba1, len1, lba2, len2, seq)); } static ctl_action ctl_extent_check_seq(union ctl_io *io1, union ctl_io *io2) { uint64_t lba1, lba2; uint64_t len1, len2; if (io1->io_hdr.flags & CTL_FLAG_SERSEQ_DONE) return (CTL_ACTION_PASS); if (ctl_get_lba_len(io1, &lba1, &len1) != 0) return (CTL_ACTION_ERROR); if (ctl_get_lba_len(io2, &lba2, &len2) != 0) return (CTL_ACTION_ERROR); if (lba1 + len1 == lba2) return (CTL_ACTION_BLOCK); return (CTL_ACTION_PASS); } static ctl_action ctl_check_for_blockage(struct ctl_lun *lun, union ctl_io *pending_io, union ctl_io *ooa_io) { const struct ctl_cmd_entry *pending_entry, *ooa_entry; const ctl_serialize_action *serialize_row; /* * Aborted commands are not going to be executed and may even * not report completion, so we don't care about their order. * Let them complete ASAP to clean the OOA queue. */ if (pending_io->io_hdr.flags & CTL_FLAG_ABORT) return (CTL_ACTION_SKIP); /* * The initiator attempted multiple untagged commands at the same * time. Can't do that. */ if ((pending_io->scsiio.tag_type == CTL_TAG_UNTAGGED) && (ooa_io->scsiio.tag_type == CTL_TAG_UNTAGGED) && ((pending_io->io_hdr.nexus.targ_port == ooa_io->io_hdr.nexus.targ_port) && (pending_io->io_hdr.nexus.initid == ooa_io->io_hdr.nexus.initid)) && ((ooa_io->io_hdr.flags & (CTL_FLAG_ABORT | CTL_FLAG_STATUS_SENT)) == 0)) return (CTL_ACTION_OVERLAP); /* * The initiator attempted to send multiple tagged commands with * the same ID. (It's fine if different initiators have the same * tag ID.) * * Even if all of those conditions are true, we don't kill the I/O * if the command ahead of us has been aborted. We won't end up * sending it to the FETD, and it's perfectly legal to resend a * command with the same tag number as long as the previous * instance of this tag number has been aborted somehow. */ if ((pending_io->scsiio.tag_type != CTL_TAG_UNTAGGED) && (ooa_io->scsiio.tag_type != CTL_TAG_UNTAGGED) && (pending_io->scsiio.tag_num == ooa_io->scsiio.tag_num) && ((pending_io->io_hdr.nexus.targ_port == ooa_io->io_hdr.nexus.targ_port) && (pending_io->io_hdr.nexus.initid == ooa_io->io_hdr.nexus.initid)) && ((ooa_io->io_hdr.flags & (CTL_FLAG_ABORT | CTL_FLAG_STATUS_SENT)) == 0)) return (CTL_ACTION_OVERLAP_TAG); /* * If we get a head of queue tag, SAM-3 says that we should * immediately execute it. * * What happens if this command would normally block for some other * reason? e.g. a request sense with a head of queue tag * immediately after a write. Normally that would block, but this * will result in its getting executed immediately... * * We currently return "pass" instead of "skip", so we'll end up * going through the rest of the queue to check for overlapped tags. * * XXX KDM check for other types of blockage first?? */ if (pending_io->scsiio.tag_type == CTL_TAG_HEAD_OF_QUEUE) return (CTL_ACTION_PASS); /* * Ordered tags have to block until all items ahead of them * have completed. If we get called with an ordered tag, we always * block, if something else is ahead of us in the queue. */ if (pending_io->scsiio.tag_type == CTL_TAG_ORDERED) return (CTL_ACTION_BLOCK); /* * Simple tags get blocked until all head of queue and ordered tags * ahead of them have completed. I'm lumping untagged commands in * with simple tags here. XXX KDM is that the right thing to do? */ if (((pending_io->scsiio.tag_type == CTL_TAG_UNTAGGED) || (pending_io->scsiio.tag_type == CTL_TAG_SIMPLE)) && ((ooa_io->scsiio.tag_type == CTL_TAG_HEAD_OF_QUEUE) || (ooa_io->scsiio.tag_type == CTL_TAG_ORDERED))) return (CTL_ACTION_BLOCK); pending_entry = ctl_get_cmd_entry(&pending_io->scsiio, NULL); KASSERT(pending_entry->seridx < CTL_SERIDX_COUNT, ("%s: Invalid seridx %d for pending CDB %02x %02x @ %p", __func__, pending_entry->seridx, pending_io->scsiio.cdb[0], pending_io->scsiio.cdb[1], pending_io)); ooa_entry = ctl_get_cmd_entry(&ooa_io->scsiio, NULL); if (ooa_entry->seridx == CTL_SERIDX_INVLD) return (CTL_ACTION_PASS); /* Unsupported command in OOA queue */ KASSERT(ooa_entry->seridx < CTL_SERIDX_COUNT, ("%s: Invalid seridx %d for ooa CDB %02x %02x @ %p", __func__, ooa_entry->seridx, ooa_io->scsiio.cdb[0], ooa_io->scsiio.cdb[1], ooa_io)); serialize_row = ctl_serialize_table[ooa_entry->seridx]; switch (serialize_row[pending_entry->seridx]) { case CTL_SER_BLOCK: return (CTL_ACTION_BLOCK); case CTL_SER_EXTENT: return (ctl_extent_check(ooa_io, pending_io, (lun->be_lun->serseq == CTL_LUN_SERSEQ_ON))); case CTL_SER_EXTENTOPT: if ((lun->MODE_CTRL.queue_flags & SCP_QUEUE_ALG_MASK) != SCP_QUEUE_ALG_UNRESTRICTED) return (ctl_extent_check(ooa_io, pending_io, (lun->be_lun->serseq == CTL_LUN_SERSEQ_ON))); return (CTL_ACTION_PASS); case CTL_SER_EXTENTSEQ: if (lun->be_lun->serseq != CTL_LUN_SERSEQ_OFF) return (ctl_extent_check_seq(ooa_io, pending_io)); return (CTL_ACTION_PASS); case CTL_SER_PASS: return (CTL_ACTION_PASS); case CTL_SER_BLOCKOPT: if ((lun->MODE_CTRL.queue_flags & SCP_QUEUE_ALG_MASK) != SCP_QUEUE_ALG_UNRESTRICTED) return (CTL_ACTION_BLOCK); return (CTL_ACTION_PASS); case CTL_SER_SKIP: return (CTL_ACTION_SKIP); default: panic("%s: Invalid serialization value %d for %d => %d", __func__, serialize_row[pending_entry->seridx], pending_entry->seridx, ooa_entry->seridx); } return (CTL_ACTION_ERROR); } /* * Check for blockage or overlaps against the OOA (Order Of Arrival) queue. * Assumptions: * - pending_io is generally either incoming, or on the blocked queue * - starting I/O is the I/O we want to start the check with. */ static ctl_action ctl_check_ooa(struct ctl_lun *lun, union ctl_io *pending_io, union ctl_io **starting_io) { union ctl_io *ooa_io; ctl_action action; mtx_assert(&lun->lun_lock, MA_OWNED); /* * Run back along the OOA queue, starting with the current * blocked I/O and going through every I/O before it on the * queue. If starting_io is NULL, we'll just end up returning * CTL_ACTION_PASS. */ for (ooa_io = *starting_io; ooa_io != NULL; ooa_io = (union ctl_io *)TAILQ_PREV(&ooa_io->io_hdr, ctl_ooaq, ooa_links)){ action = ctl_check_for_blockage(lun, pending_io, ooa_io); if (action != CTL_ACTION_PASS) { *starting_io = ooa_io; return (action); } } *starting_io = NULL; return (CTL_ACTION_PASS); } /* * Try to unblock the specified I/O. * * skip parameter allows explicitly skip present blocker of the I/O, * starting from the previous one on OOA queue. It can be used when * we know for sure that the blocker I/O does no longer count. */ static void ctl_try_unblock_io(struct ctl_lun *lun, union ctl_io *io, bool skip) { struct ctl_softc *softc = lun->ctl_softc; union ctl_io *bio, *obio; const struct ctl_cmd_entry *entry; union ctl_ha_msg msg_info; ctl_action action; mtx_assert(&lun->lun_lock, MA_OWNED); if (io->io_hdr.blocker == NULL) return; obio = bio = io->io_hdr.blocker; if (skip) bio = (union ctl_io *)TAILQ_PREV(&bio->io_hdr, ctl_ooaq, ooa_links); action = ctl_check_ooa(lun, io, &bio); if (action == CTL_ACTION_BLOCK) { /* Still blocked, but may be by different I/O now. */ if (bio != obio) { TAILQ_REMOVE(&obio->io_hdr.blocked_queue, &io->io_hdr, blocked_links); TAILQ_INSERT_TAIL(&bio->io_hdr.blocked_queue, &io->io_hdr, blocked_links); io->io_hdr.blocker = bio; } return; } /* No longer blocked, one way or another. */ TAILQ_REMOVE(&obio->io_hdr.blocked_queue, &io->io_hdr, blocked_links); io->io_hdr.blocker = NULL; switch (action) { case CTL_ACTION_OVERLAP: ctl_set_overlapped_cmd(&io->scsiio); goto error; case CTL_ACTION_OVERLAP_TAG: ctl_set_overlapped_tag(&io->scsiio, io->scsiio.tag_num & 0xff); goto error; case CTL_ACTION_PASS: case CTL_ACTION_SKIP: /* Serializing commands from the other SC retire there. */ if ((io->io_hdr.flags & CTL_FLAG_FROM_OTHER_SC) && (softc->ha_mode != CTL_HA_MODE_XFER)) { io->io_hdr.flags &= ~CTL_FLAG_IO_ACTIVE; msg_info.hdr.original_sc = io->io_hdr.remote_io; msg_info.hdr.serializing_sc = io; msg_info.hdr.msg_type = CTL_MSG_R2R; ctl_ha_msg_send(CTL_HA_CHAN_CTL, &msg_info, sizeof(msg_info.hdr), M_NOWAIT); break; } /* * Check this I/O for LUN state changes that may have happened * while this command was blocked. The LUN state may have been * changed by a command ahead of us in the queue. */ entry = ctl_get_cmd_entry(&io->scsiio, NULL); if (ctl_scsiio_lun_check(lun, entry, &io->scsiio) != 0) { ctl_done(io); break; } io->io_hdr.flags |= CTL_FLAG_IS_WAS_ON_RTR; ctl_enqueue_rtr(io); break; case CTL_ACTION_ERROR: default: ctl_set_internal_failure(&io->scsiio, /*sks_valid*/ 0, /*retry_count*/ 0); error: /* Serializing commands from the other SC are done here. */ if ((io->io_hdr.flags & CTL_FLAG_FROM_OTHER_SC) && (softc->ha_mode != CTL_HA_MODE_XFER)) { ctl_try_unblock_others(lun, io, TRUE); TAILQ_REMOVE(&lun->ooa_queue, &io->io_hdr, ooa_links); ctl_copy_sense_data_back(io, &msg_info); msg_info.hdr.original_sc = io->io_hdr.remote_io; msg_info.hdr.serializing_sc = NULL; msg_info.hdr.msg_type = CTL_MSG_BAD_JUJU; ctl_ha_msg_send(CTL_HA_CHAN_CTL, &msg_info, sizeof(msg_info.scsi), M_WAITOK); ctl_free_io(io); break; } ctl_done(io); break; } } /* * Try to unblock I/Os blocked by the specified I/O. * * skip parameter allows explicitly skip the specified I/O as blocker, * starting from the previous one on the OOA queue. It can be used when * we know for sure that the specified I/O does no longer count (done). * It has to be still on OOA queue though so that we know where to start. */ static void ctl_try_unblock_others(struct ctl_lun *lun, union ctl_io *bio, bool skip) { union ctl_io *io, *next_io; mtx_assert(&lun->lun_lock, MA_OWNED); for (io = (union ctl_io *)TAILQ_FIRST(&bio->io_hdr.blocked_queue); io != NULL; io = next_io) { next_io = (union ctl_io *)TAILQ_NEXT(&io->io_hdr, blocked_links); KASSERT(io->io_hdr.blocker != NULL, ("I/O %p on blocked list without blocker", io)); ctl_try_unblock_io(lun, io, skip); } KASSERT(!skip || TAILQ_EMPTY(&bio->io_hdr.blocked_queue), ("blocked_queue is not empty after skipping %p", bio)); } /* * This routine (with one exception) checks LUN flags that can be set by * commands ahead of us in the OOA queue. These flags have to be checked * when a command initially comes in, and when we pull a command off the * blocked queue and are preparing to execute it. The reason we have to * check these flags for commands on the blocked queue is that the LUN * state may have been changed by a command ahead of us while we're on the * blocked queue. * * Ordering is somewhat important with these checks, so please pay * careful attention to the placement of any new checks. */ static int ctl_scsiio_lun_check(struct ctl_lun *lun, const struct ctl_cmd_entry *entry, struct ctl_scsiio *ctsio) { struct ctl_softc *softc = lun->ctl_softc; int retval; uint32_t residx; retval = 0; mtx_assert(&lun->lun_lock, MA_OWNED); /* * If this shelf is a secondary shelf controller, we may have to * reject some commands disallowed by HA mode and link state. */ if ((lun->flags & CTL_LUN_PRIMARY_SC) == 0) { if (softc->ha_link == CTL_HA_LINK_OFFLINE && (entry->flags & CTL_CMD_FLAG_OK_ON_UNAVAIL) == 0) { ctl_set_lun_unavail(ctsio); retval = 1; goto bailout; } if ((lun->flags & CTL_LUN_PEER_SC_PRIMARY) == 0 && (entry->flags & CTL_CMD_FLAG_OK_ON_UNAVAIL) == 0) { ctl_set_lun_transit(ctsio); retval = 1; goto bailout; } if (softc->ha_mode == CTL_HA_MODE_ACT_STBY && (entry->flags & CTL_CMD_FLAG_OK_ON_STANDBY) == 0) { ctl_set_lun_standby(ctsio); retval = 1; goto bailout; } /* The rest of checks are only done on executing side */ if (softc->ha_mode == CTL_HA_MODE_XFER) goto bailout; } if (entry->pattern & CTL_LUN_PAT_WRITE) { if (lun->be_lun->flags & CTL_LUN_FLAG_READONLY) { ctl_set_hw_write_protected(ctsio); retval = 1; goto bailout; } if ((lun->MODE_CTRL.eca_and_aen & SCP_SWP) != 0) { ctl_set_sense(ctsio, /*current_error*/ 1, /*sense_key*/ SSD_KEY_DATA_PROTECT, /*asc*/ 0x27, /*ascq*/ 0x02, SSD_ELEM_NONE); retval = 1; goto bailout; } } /* * Check for a reservation conflict. If this command isn't allowed * even on reserved LUNs, and if this initiator isn't the one who * reserved us, reject the command with a reservation conflict. */ residx = ctl_get_initindex(&ctsio->io_hdr.nexus); if ((lun->flags & CTL_LUN_RESERVED) && ((entry->flags & CTL_CMD_FLAG_ALLOW_ON_RESV) == 0)) { if (lun->res_idx != residx) { ctl_set_reservation_conflict(ctsio); retval = 1; goto bailout; } } if ((lun->flags & CTL_LUN_PR_RESERVED) == 0 || (entry->flags & CTL_CMD_FLAG_ALLOW_ON_PR_RESV)) { /* No reservation or command is allowed. */; } else if ((entry->flags & CTL_CMD_FLAG_ALLOW_ON_PR_WRESV) && (lun->pr_res_type == SPR_TYPE_WR_EX || lun->pr_res_type == SPR_TYPE_WR_EX_RO || lun->pr_res_type == SPR_TYPE_WR_EX_AR)) { /* The command is allowed for Write Exclusive resv. */; } else { /* * if we aren't registered or it's a res holder type * reservation and this isn't the res holder then set a * conflict. */ if (ctl_get_prkey(lun, residx) == 0 || (residx != lun->pr_res_idx && lun->pr_res_type < 4)) { ctl_set_reservation_conflict(ctsio); retval = 1; goto bailout; } } if ((entry->flags & CTL_CMD_FLAG_OK_ON_NO_MEDIA) == 0) { if (lun->flags & CTL_LUN_EJECTED) ctl_set_lun_ejected(ctsio); else if (lun->flags & CTL_LUN_NO_MEDIA) { if (lun->flags & CTL_LUN_REMOVABLE) ctl_set_lun_no_media(ctsio); else ctl_set_lun_int_reqd(ctsio); } else if (lun->flags & CTL_LUN_STOPPED) ctl_set_lun_stopped(ctsio); else goto bailout; retval = 1; goto bailout; } bailout: return (retval); } static void ctl_failover_io(union ctl_io *io, int have_lock) { ctl_set_busy(&io->scsiio); ctl_done(io); } static void ctl_failover_lun(union ctl_io *rio) { struct ctl_softc *softc = CTL_SOFTC(rio); struct ctl_lun *lun; struct ctl_io_hdr *io, *next_io; uint32_t targ_lun; targ_lun = rio->io_hdr.nexus.targ_mapped_lun; CTL_DEBUG_PRINT(("FAILOVER for lun %u\n", targ_lun)); /* Find and lock the LUN. */ mtx_lock(&softc->ctl_lock); if (targ_lun > ctl_max_luns || (lun = softc->ctl_luns[targ_lun]) == NULL) { mtx_unlock(&softc->ctl_lock); return; } mtx_lock(&lun->lun_lock); mtx_unlock(&softc->ctl_lock); if (lun->flags & CTL_LUN_DISABLED) { mtx_unlock(&lun->lun_lock); return; } if (softc->ha_mode == CTL_HA_MODE_XFER) { TAILQ_FOREACH_SAFE(io, &lun->ooa_queue, ooa_links, next_io) { /* We are master */ if (io->flags & CTL_FLAG_FROM_OTHER_SC) { if (io->flags & CTL_FLAG_IO_ACTIVE) { io->flags |= CTL_FLAG_ABORT; io->flags |= CTL_FLAG_FAILOVER; ctl_try_unblock_io(lun, (union ctl_io *)io, FALSE); } else { /* This can be only due to DATAMOVE */ io->msg_type = CTL_MSG_DATAMOVE_DONE; io->flags &= ~CTL_FLAG_DMA_INPROG; io->flags |= CTL_FLAG_IO_ACTIVE; io->port_status = 31340; ctl_enqueue_isc((union ctl_io *)io); } } else /* We are slave */ if (io->flags & CTL_FLAG_SENT_2OTHER_SC) { io->flags &= ~CTL_FLAG_SENT_2OTHER_SC; if (io->flags & CTL_FLAG_IO_ACTIVE) { io->flags |= CTL_FLAG_FAILOVER; } else { ctl_set_busy(&((union ctl_io *)io)-> scsiio); ctl_done((union ctl_io *)io); } } } } else { /* SERIALIZE modes */ TAILQ_FOREACH_SAFE(io, &lun->ooa_queue, ooa_links, next_io) { /* We are master */ if (io->flags & CTL_FLAG_FROM_OTHER_SC) { if (io->blocker != NULL) { TAILQ_REMOVE(&io->blocker->io_hdr.blocked_queue, io, blocked_links); io->blocker = NULL; } ctl_try_unblock_others(lun, (union ctl_io *)io, TRUE); TAILQ_REMOVE(&lun->ooa_queue, io, ooa_links); ctl_free_io((union ctl_io *)io); } else /* We are slave */ if (io->flags & CTL_FLAG_SENT_2OTHER_SC) { io->flags &= ~CTL_FLAG_SENT_2OTHER_SC; if (!(io->flags & CTL_FLAG_IO_ACTIVE)) { ctl_set_busy(&((union ctl_io *)io)-> scsiio); ctl_done((union ctl_io *)io); } } } } mtx_unlock(&lun->lun_lock); } -static int -ctl_scsiio_precheck(struct ctl_softc *softc, struct ctl_scsiio *ctsio) +static void +ctl_scsiio_precheck(struct ctl_scsiio *ctsio) { + struct ctl_softc *softc = CTL_SOFTC(ctsio); struct ctl_lun *lun; const struct ctl_cmd_entry *entry; union ctl_io *bio; uint32_t initidx, targ_lun; - int retval = 0; lun = NULL; targ_lun = ctsio->io_hdr.nexus.targ_mapped_lun; if (targ_lun < ctl_max_luns) lun = softc->ctl_luns[targ_lun]; if (lun) { /* * If the LUN is invalid, pretend that it doesn't exist. * It will go away as soon as all pending I/O has been * completed. */ mtx_lock(&lun->lun_lock); if (lun->flags & CTL_LUN_DISABLED) { mtx_unlock(&lun->lun_lock); lun = NULL; } } CTL_LUN(ctsio) = lun; if (lun) { CTL_BACKEND_LUN(ctsio) = lun->be_lun; /* * Every I/O goes into the OOA queue for a particular LUN, * and stays there until completion. */ #ifdef CTL_TIME_IO if (TAILQ_EMPTY(&lun->ooa_queue)) lun->idle_time += getsbinuptime() - lun->last_busy; #endif TAILQ_INSERT_TAIL(&lun->ooa_queue, &ctsio->io_hdr, ooa_links); } /* Get command entry and return error if it is unsuppotyed. */ entry = ctl_validate_command(ctsio); if (entry == NULL) { if (lun) mtx_unlock(&lun->lun_lock); - return (retval); + return; } ctsio->io_hdr.flags &= ~CTL_FLAG_DATA_MASK; ctsio->io_hdr.flags |= entry->flags & CTL_FLAG_DATA_MASK; /* * Check to see whether we can send this command to LUNs that don't * exist. This should pretty much only be the case for inquiry * and request sense. Further checks, below, really require having * a LUN, so we can't really check the command anymore. Just put * it on the rtr queue. */ if (lun == NULL) { if (entry->flags & CTL_CMD_FLAG_OK_ON_NO_LUN) { ctsio->io_hdr.flags |= CTL_FLAG_IS_WAS_ON_RTR; ctl_enqueue_rtr((union ctl_io *)ctsio); - return (retval); + return; } ctl_set_unsupported_lun(ctsio); ctl_done((union ctl_io *)ctsio); CTL_DEBUG_PRINT(("ctl_scsiio_precheck: bailing out due to invalid LUN\n")); - return (retval); + return; } else { /* * Make sure we support this particular command on this LUN. * e.g., we don't support writes to the control LUN. */ if (!ctl_cmd_applicable(lun->be_lun->lun_type, entry)) { mtx_unlock(&lun->lun_lock); ctl_set_invalid_opcode(ctsio); ctl_done((union ctl_io *)ctsio); - return (retval); + return; } } initidx = ctl_get_initindex(&ctsio->io_hdr.nexus); /* * If we've got a request sense, it'll clear the contingent * allegiance condition. Otherwise, if we have a CA condition for * this initiator, clear it, because it sent down a command other * than request sense. */ if (ctsio->cdb[0] != REQUEST_SENSE) { struct scsi_sense_data *ps; ps = lun->pending_sense[initidx / CTL_MAX_INIT_PER_PORT]; if (ps != NULL) ps[initidx % CTL_MAX_INIT_PER_PORT].error_code = 0; } /* * If the command has this flag set, it handles its own unit * attention reporting, we shouldn't do anything. Otherwise we * check for any pending unit attentions, and send them back to the * initiator. We only do this when a command initially comes in, * not when we pull it off the blocked queue. * * According to SAM-3, section 5.3.2, the order that things get * presented back to the host is basically unit attentions caused * by some sort of reset event, busy status, reservation conflicts * or task set full, and finally any other status. * * One issue here is that some of the unit attentions we report * don't fall into the "reset" category (e.g. "reported luns data * has changed"). So reporting it here, before the reservation * check, may be technically wrong. I guess the only thing to do * would be to check for and report the reset events here, and then * check for the other unit attention types after we check for a * reservation conflict. * * XXX KDM need to fix this */ if ((entry->flags & CTL_CMD_FLAG_NO_SENSE) == 0) { ctl_ua_type ua_type; u_int sense_len = 0; ua_type = ctl_build_ua(lun, initidx, &ctsio->sense_data, &sense_len, SSD_TYPE_NONE); if (ua_type != CTL_UA_NONE) { mtx_unlock(&lun->lun_lock); ctsio->scsi_status = SCSI_STATUS_CHECK_COND; ctsio->io_hdr.status = CTL_SCSI_ERROR | CTL_AUTOSENSE; ctsio->sense_len = sense_len; ctl_done((union ctl_io *)ctsio); - return (retval); + return; } } if (ctl_scsiio_lun_check(lun, entry, ctsio) != 0) { mtx_unlock(&lun->lun_lock); ctl_done((union ctl_io *)ctsio); - return (retval); + return; } /* * XXX CHD this is where we want to send IO to other side if * this LUN is secondary on this SC. We will need to make a copy * of the IO and flag the IO on this side as SENT_2OTHER and the flag * the copy we send as FROM_OTHER. * We also need to stuff the address of the original IO so we can * find it easily. Something similar will need be done on the other * side so when we are done we can find the copy. */ if ((lun->flags & CTL_LUN_PRIMARY_SC) == 0 && (lun->flags & CTL_LUN_PEER_SC_PRIMARY) != 0 && (entry->flags & CTL_CMD_FLAG_RUN_HERE) == 0) { union ctl_ha_msg msg_info; int isc_retval; ctsio->io_hdr.flags |= CTL_FLAG_SENT_2OTHER_SC; ctsio->io_hdr.flags &= ~CTL_FLAG_IO_ACTIVE; mtx_unlock(&lun->lun_lock); msg_info.hdr.msg_type = CTL_MSG_SERIALIZE; msg_info.hdr.original_sc = (union ctl_io *)ctsio; msg_info.hdr.serializing_sc = NULL; msg_info.hdr.nexus = ctsio->io_hdr.nexus; msg_info.scsi.tag_num = ctsio->tag_num; msg_info.scsi.tag_type = ctsio->tag_type; memcpy(msg_info.scsi.cdb, ctsio->cdb, CTL_MAX_CDBLEN); msg_info.scsi.cdb_len = ctsio->cdb_len; msg_info.scsi.priority = ctsio->priority; if ((isc_retval = ctl_ha_msg_send(CTL_HA_CHAN_CTL, &msg_info, sizeof(msg_info.scsi) - sizeof(msg_info.scsi.sense_data), M_WAITOK)) > CTL_HA_STATUS_SUCCESS) { ctl_set_busy(ctsio); ctl_done((union ctl_io *)ctsio); - return (retval); + return; } - return (retval); + return; } bio = (union ctl_io *)TAILQ_PREV(&ctsio->io_hdr, ctl_ooaq, ooa_links); switch (ctl_check_ooa(lun, (union ctl_io *)ctsio, &bio)) { case CTL_ACTION_BLOCK: ctsio->io_hdr.blocker = bio; TAILQ_INSERT_TAIL(&bio->io_hdr.blocked_queue, &ctsio->io_hdr, blocked_links); mtx_unlock(&lun->lun_lock); - return (retval); + break; case CTL_ACTION_PASS: case CTL_ACTION_SKIP: ctsio->io_hdr.flags |= CTL_FLAG_IS_WAS_ON_RTR; mtx_unlock(&lun->lun_lock); ctl_enqueue_rtr((union ctl_io *)ctsio); break; case CTL_ACTION_OVERLAP: mtx_unlock(&lun->lun_lock); ctl_set_overlapped_cmd(ctsio); ctl_done((union ctl_io *)ctsio); break; case CTL_ACTION_OVERLAP_TAG: mtx_unlock(&lun->lun_lock); ctl_set_overlapped_tag(ctsio, ctsio->tag_num & 0xff); ctl_done((union ctl_io *)ctsio); break; case CTL_ACTION_ERROR: default: mtx_unlock(&lun->lun_lock); ctl_set_internal_failure(ctsio, /*sks_valid*/ 0, /*retry_count*/ 0); ctl_done((union ctl_io *)ctsio); break; } - return (retval); } const struct ctl_cmd_entry * ctl_get_cmd_entry(struct ctl_scsiio *ctsio, int *sa) { const struct ctl_cmd_entry *entry; int service_action; entry = &ctl_cmd_table[ctsio->cdb[0]]; if (sa) *sa = ((entry->flags & CTL_CMD_FLAG_SA5) != 0); if (entry->flags & CTL_CMD_FLAG_SA5) { service_action = ctsio->cdb[1] & SERVICE_ACTION_MASK; entry = &((const struct ctl_cmd_entry *) entry->execute)[service_action]; } return (entry); } const struct ctl_cmd_entry * ctl_validate_command(struct ctl_scsiio *ctsio) { const struct ctl_cmd_entry *entry; int i, sa; uint8_t diff; entry = ctl_get_cmd_entry(ctsio, &sa); if (entry->execute == NULL) { if (sa) ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 1, /*bit_valid*/ 1, /*bit*/ 4); else ctl_set_invalid_opcode(ctsio); ctl_done((union ctl_io *)ctsio); return (NULL); } KASSERT(entry->length > 0, ("Not defined length for command 0x%02x/0x%02x", ctsio->cdb[0], ctsio->cdb[1])); for (i = 1; i < entry->length; i++) { diff = ctsio->cdb[i] & ~entry->usage[i - 1]; if (diff == 0) continue; ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ i, /*bit_valid*/ 1, /*bit*/ fls(diff) - 1); ctl_done((union ctl_io *)ctsio); return (NULL); } return (entry); } static int ctl_cmd_applicable(uint8_t lun_type, const struct ctl_cmd_entry *entry) { switch (lun_type) { case T_DIRECT: if ((entry->flags & CTL_CMD_FLAG_OK_ON_DIRECT) == 0) return (0); break; case T_PROCESSOR: if ((entry->flags & CTL_CMD_FLAG_OK_ON_PROC) == 0) return (0); break; case T_CDROM: if ((entry->flags & CTL_CMD_FLAG_OK_ON_CDROM) == 0) return (0); break; default: return (0); } return (1); } static int ctl_scsiio(struct ctl_scsiio *ctsio) { int retval; const struct ctl_cmd_entry *entry; retval = CTL_RETVAL_COMPLETE; CTL_DEBUG_PRINT(("ctl_scsiio cdb[0]=%02X\n", ctsio->cdb[0])); entry = ctl_get_cmd_entry(ctsio, NULL); /* * If this I/O has been aborted, just send it straight to * ctl_done() without executing it. */ if (ctsio->io_hdr.flags & CTL_FLAG_ABORT) { ctl_done((union ctl_io *)ctsio); goto bailout; } /* * All the checks should have been handled by ctl_scsiio_precheck(). * We should be clear now to just execute the I/O. */ retval = entry->execute(ctsio); bailout: return (retval); } static int ctl_target_reset(union ctl_io *io) { struct ctl_softc *softc = CTL_SOFTC(io); struct ctl_port *port = CTL_PORT(io); struct ctl_lun *lun; uint32_t initidx; ctl_ua_type ua_type; if (!(io->io_hdr.flags & CTL_FLAG_FROM_OTHER_SC)) { union ctl_ha_msg msg_info; msg_info.hdr.nexus = io->io_hdr.nexus; msg_info.task.task_action = io->taskio.task_action; msg_info.hdr.msg_type = CTL_MSG_MANAGE_TASKS; msg_info.hdr.original_sc = NULL; msg_info.hdr.serializing_sc = NULL; ctl_ha_msg_send(CTL_HA_CHAN_CTL, &msg_info, sizeof(msg_info.task), M_WAITOK); } initidx = ctl_get_initindex(&io->io_hdr.nexus); if (io->taskio.task_action == CTL_TASK_TARGET_RESET) ua_type = CTL_UA_TARG_RESET; else ua_type = CTL_UA_BUS_RESET; mtx_lock(&softc->ctl_lock); STAILQ_FOREACH(lun, &softc->lun_list, links) { if (port != NULL && ctl_lun_map_to_port(port, lun->lun) == UINT32_MAX) continue; ctl_do_lun_reset(lun, initidx, ua_type); } mtx_unlock(&softc->ctl_lock); io->taskio.task_status = CTL_TASK_FUNCTION_COMPLETE; return (0); } /* * The LUN should always be set. The I/O is optional, and is used to * distinguish between I/Os sent by this initiator, and by other * initiators. We set unit attention for initiators other than this one. * SAM-3 is vague on this point. It does say that a unit attention should * be established for other initiators when a LUN is reset (see section * 5.7.3), but it doesn't specifically say that the unit attention should * be established for this particular initiator when a LUN is reset. Here * is the relevant text, from SAM-3 rev 8: * * 5.7.2 When a SCSI initiator port aborts its own tasks * * When a SCSI initiator port causes its own task(s) to be aborted, no * notification that the task(s) have been aborted shall be returned to * the SCSI initiator port other than the completion response for the * command or task management function action that caused the task(s) to * be aborted and notification(s) associated with related effects of the * action (e.g., a reset unit attention condition). * * XXX KDM for now, we're setting unit attention for all initiators. */ static void ctl_do_lun_reset(struct ctl_lun *lun, uint32_t initidx, ctl_ua_type ua_type) { union ctl_io *xio; int i; mtx_lock(&lun->lun_lock); /* Abort tasks. */ for (xio = (union ctl_io *)TAILQ_FIRST(&lun->ooa_queue); xio != NULL; xio = (union ctl_io *)TAILQ_NEXT(&xio->io_hdr, ooa_links)) { xio->io_hdr.flags |= CTL_FLAG_ABORT | CTL_FLAG_ABORT_STATUS; ctl_try_unblock_io(lun, xio, FALSE); } /* Clear CA. */ for (i = 0; i < ctl_max_ports; i++) { free(lun->pending_sense[i], M_CTL); lun->pending_sense[i] = NULL; } /* Clear reservation. */ lun->flags &= ~CTL_LUN_RESERVED; /* Clear prevent media removal. */ if (lun->prevent) { for (i = 0; i < CTL_MAX_INITIATORS; i++) ctl_clear_mask(lun->prevent, i); lun->prevent_count = 0; } /* Clear TPC status */ ctl_tpc_lun_clear(lun, -1); /* Establish UA. */ #if 0 ctl_est_ua_all(lun, initidx, ua_type); #else ctl_est_ua_all(lun, -1, ua_type); #endif mtx_unlock(&lun->lun_lock); } static int ctl_lun_reset(union ctl_io *io) { struct ctl_softc *softc = CTL_SOFTC(io); struct ctl_lun *lun; uint32_t targ_lun, initidx; targ_lun = io->io_hdr.nexus.targ_mapped_lun; initidx = ctl_get_initindex(&io->io_hdr.nexus); mtx_lock(&softc->ctl_lock); if (targ_lun >= ctl_max_luns || (lun = softc->ctl_luns[targ_lun]) == NULL) { mtx_unlock(&softc->ctl_lock); io->taskio.task_status = CTL_TASK_LUN_DOES_NOT_EXIST; return (1); } ctl_do_lun_reset(lun, initidx, CTL_UA_LUN_RESET); mtx_unlock(&softc->ctl_lock); io->taskio.task_status = CTL_TASK_FUNCTION_COMPLETE; if ((io->io_hdr.flags & CTL_FLAG_FROM_OTHER_SC) == 0) { union ctl_ha_msg msg_info; msg_info.hdr.msg_type = CTL_MSG_MANAGE_TASKS; msg_info.hdr.nexus = io->io_hdr.nexus; msg_info.task.task_action = CTL_TASK_LUN_RESET; msg_info.hdr.original_sc = NULL; msg_info.hdr.serializing_sc = NULL; ctl_ha_msg_send(CTL_HA_CHAN_CTL, &msg_info, sizeof(msg_info.task), M_WAITOK); } return (0); } static void ctl_abort_tasks_lun(struct ctl_lun *lun, uint32_t targ_port, uint32_t init_id, int other_sc) { union ctl_io *xio; mtx_assert(&lun->lun_lock, MA_OWNED); /* * Run through the OOA queue and attempt to find the given I/O. * The target port, initiator ID, tag type and tag number have to * match the values that we got from the initiator. If we have an * untagged command to abort, simply abort the first untagged command * we come to. We only allow one untagged command at a time of course. */ for (xio = (union ctl_io *)TAILQ_FIRST(&lun->ooa_queue); xio != NULL; xio = (union ctl_io *)TAILQ_NEXT(&xio->io_hdr, ooa_links)) { if ((targ_port == UINT32_MAX || targ_port == xio->io_hdr.nexus.targ_port) && (init_id == UINT32_MAX || init_id == xio->io_hdr.nexus.initid)) { if (targ_port != xio->io_hdr.nexus.targ_port || init_id != xio->io_hdr.nexus.initid) xio->io_hdr.flags |= CTL_FLAG_ABORT_STATUS; xio->io_hdr.flags |= CTL_FLAG_ABORT; if (!other_sc && !(lun->flags & CTL_LUN_PRIMARY_SC)) { union ctl_ha_msg msg_info; msg_info.hdr.nexus = xio->io_hdr.nexus; msg_info.task.task_action = CTL_TASK_ABORT_TASK; msg_info.task.tag_num = xio->scsiio.tag_num; msg_info.task.tag_type = xio->scsiio.tag_type; msg_info.hdr.msg_type = CTL_MSG_MANAGE_TASKS; msg_info.hdr.original_sc = NULL; msg_info.hdr.serializing_sc = NULL; ctl_ha_msg_send(CTL_HA_CHAN_CTL, &msg_info, sizeof(msg_info.task), M_NOWAIT); } ctl_try_unblock_io(lun, xio, FALSE); } } } static int ctl_abort_task_set(union ctl_io *io) { struct ctl_softc *softc = CTL_SOFTC(io); struct ctl_lun *lun; uint32_t targ_lun; /* * Look up the LUN. */ targ_lun = io->io_hdr.nexus.targ_mapped_lun; mtx_lock(&softc->ctl_lock); if (targ_lun >= ctl_max_luns || (lun = softc->ctl_luns[targ_lun]) == NULL) { mtx_unlock(&softc->ctl_lock); io->taskio.task_status = CTL_TASK_LUN_DOES_NOT_EXIST; return (1); } mtx_lock(&lun->lun_lock); mtx_unlock(&softc->ctl_lock); if (io->taskio.task_action == CTL_TASK_ABORT_TASK_SET) { ctl_abort_tasks_lun(lun, io->io_hdr.nexus.targ_port, io->io_hdr.nexus.initid, (io->io_hdr.flags & CTL_FLAG_FROM_OTHER_SC) != 0); } else { /* CTL_TASK_CLEAR_TASK_SET */ ctl_abort_tasks_lun(lun, UINT32_MAX, UINT32_MAX, (io->io_hdr.flags & CTL_FLAG_FROM_OTHER_SC) != 0); } mtx_unlock(&lun->lun_lock); io->taskio.task_status = CTL_TASK_FUNCTION_COMPLETE; return (0); } static void ctl_i_t_nexus_loss(struct ctl_softc *softc, uint32_t initidx, ctl_ua_type ua_type) { struct ctl_lun *lun; struct scsi_sense_data *ps; uint32_t p, i; p = initidx / CTL_MAX_INIT_PER_PORT; i = initidx % CTL_MAX_INIT_PER_PORT; mtx_lock(&softc->ctl_lock); STAILQ_FOREACH(lun, &softc->lun_list, links) { mtx_lock(&lun->lun_lock); /* Abort tasks. */ ctl_abort_tasks_lun(lun, p, i, 1); /* Clear CA. */ ps = lun->pending_sense[p]; if (ps != NULL) ps[i].error_code = 0; /* Clear reservation. */ if ((lun->flags & CTL_LUN_RESERVED) && (lun->res_idx == initidx)) lun->flags &= ~CTL_LUN_RESERVED; /* Clear prevent media removal. */ if (lun->prevent && ctl_is_set(lun->prevent, initidx)) { ctl_clear_mask(lun->prevent, initidx); lun->prevent_count--; } /* Clear TPC status */ ctl_tpc_lun_clear(lun, initidx); /* Establish UA. */ ctl_est_ua(lun, initidx, ua_type); mtx_unlock(&lun->lun_lock); } mtx_unlock(&softc->ctl_lock); } static int ctl_i_t_nexus_reset(union ctl_io *io) { struct ctl_softc *softc = CTL_SOFTC(io); uint32_t initidx; if (!(io->io_hdr.flags & CTL_FLAG_FROM_OTHER_SC)) { union ctl_ha_msg msg_info; msg_info.hdr.nexus = io->io_hdr.nexus; msg_info.task.task_action = CTL_TASK_I_T_NEXUS_RESET; msg_info.hdr.msg_type = CTL_MSG_MANAGE_TASKS; msg_info.hdr.original_sc = NULL; msg_info.hdr.serializing_sc = NULL; ctl_ha_msg_send(CTL_HA_CHAN_CTL, &msg_info, sizeof(msg_info.task), M_WAITOK); } initidx = ctl_get_initindex(&io->io_hdr.nexus); ctl_i_t_nexus_loss(softc, initidx, CTL_UA_I_T_NEXUS_LOSS); io->taskio.task_status = CTL_TASK_FUNCTION_COMPLETE; return (0); } static int ctl_abort_task(union ctl_io *io) { struct ctl_softc *softc = CTL_SOFTC(io); union ctl_io *xio; struct ctl_lun *lun; uint32_t targ_lun; /* * Look up the LUN. */ targ_lun = io->io_hdr.nexus.targ_mapped_lun; mtx_lock(&softc->ctl_lock); if (targ_lun >= ctl_max_luns || (lun = softc->ctl_luns[targ_lun]) == NULL) { mtx_unlock(&softc->ctl_lock); io->taskio.task_status = CTL_TASK_LUN_DOES_NOT_EXIST; return (1); } mtx_lock(&lun->lun_lock); mtx_unlock(&softc->ctl_lock); /* * Run through the OOA queue and attempt to find the given I/O. * The target port, initiator ID, tag type and tag number have to * match the values that we got from the initiator. If we have an * untagged command to abort, simply abort the first untagged command * we come to. We only allow one untagged command at a time of course. */ for (xio = (union ctl_io *)TAILQ_FIRST(&lun->ooa_queue); xio != NULL; xio = (union ctl_io *)TAILQ_NEXT(&xio->io_hdr, ooa_links)) { if ((xio->io_hdr.nexus.targ_port != io->io_hdr.nexus.targ_port) || (xio->io_hdr.nexus.initid != io->io_hdr.nexus.initid) || (xio->io_hdr.flags & CTL_FLAG_ABORT)) continue; /* * If the abort says that the task is untagged, the * task in the queue must be untagged. Otherwise, * we just check to see whether the tag numbers * match. This is because the QLogic firmware * doesn't pass back the tag type in an abort * request. */ #if 0 if (((xio->scsiio.tag_type == CTL_TAG_UNTAGGED) && (io->taskio.tag_type == CTL_TAG_UNTAGGED)) || (xio->scsiio.tag_num == io->taskio.tag_num)) { #else /* * XXX KDM we've got problems with FC, because it * doesn't send down a tag type with aborts. So we * can only really go by the tag number... * This may cause problems with parallel SCSI. * Need to figure that out!! */ if (xio->scsiio.tag_num == io->taskio.tag_num) { #endif xio->io_hdr.flags |= CTL_FLAG_ABORT; if ((io->io_hdr.flags & CTL_FLAG_FROM_OTHER_SC) == 0 && !(lun->flags & CTL_LUN_PRIMARY_SC)) { union ctl_ha_msg msg_info; msg_info.hdr.nexus = io->io_hdr.nexus; msg_info.task.task_action = CTL_TASK_ABORT_TASK; msg_info.task.tag_num = io->taskio.tag_num; msg_info.task.tag_type = io->taskio.tag_type; msg_info.hdr.msg_type = CTL_MSG_MANAGE_TASKS; msg_info.hdr.original_sc = NULL; msg_info.hdr.serializing_sc = NULL; ctl_ha_msg_send(CTL_HA_CHAN_CTL, &msg_info, sizeof(msg_info.task), M_NOWAIT); } ctl_try_unblock_io(lun, xio, FALSE); } } mtx_unlock(&lun->lun_lock); io->taskio.task_status = CTL_TASK_FUNCTION_COMPLETE; return (0); } static int ctl_query_task(union ctl_io *io, int task_set) { struct ctl_softc *softc = CTL_SOFTC(io); union ctl_io *xio; struct ctl_lun *lun; int found = 0; uint32_t targ_lun; targ_lun = io->io_hdr.nexus.targ_mapped_lun; mtx_lock(&softc->ctl_lock); if (targ_lun >= ctl_max_luns || (lun = softc->ctl_luns[targ_lun]) == NULL) { mtx_unlock(&softc->ctl_lock); io->taskio.task_status = CTL_TASK_LUN_DOES_NOT_EXIST; return (1); } mtx_lock(&lun->lun_lock); mtx_unlock(&softc->ctl_lock); for (xio = (union ctl_io *)TAILQ_FIRST(&lun->ooa_queue); xio != NULL; xio = (union ctl_io *)TAILQ_NEXT(&xio->io_hdr, ooa_links)) { if ((xio->io_hdr.nexus.targ_port != io->io_hdr.nexus.targ_port) || (xio->io_hdr.nexus.initid != io->io_hdr.nexus.initid) || (xio->io_hdr.flags & CTL_FLAG_ABORT)) continue; if (task_set || xio->scsiio.tag_num == io->taskio.tag_num) { found = 1; break; } } mtx_unlock(&lun->lun_lock); if (found) io->taskio.task_status = CTL_TASK_FUNCTION_SUCCEEDED; else io->taskio.task_status = CTL_TASK_FUNCTION_COMPLETE; return (0); } static int ctl_query_async_event(union ctl_io *io) { struct ctl_softc *softc = CTL_SOFTC(io); struct ctl_lun *lun; ctl_ua_type ua; uint32_t targ_lun, initidx; targ_lun = io->io_hdr.nexus.targ_mapped_lun; mtx_lock(&softc->ctl_lock); if (targ_lun >= ctl_max_luns || (lun = softc->ctl_luns[targ_lun]) == NULL) { mtx_unlock(&softc->ctl_lock); io->taskio.task_status = CTL_TASK_LUN_DOES_NOT_EXIST; return (1); } mtx_lock(&lun->lun_lock); mtx_unlock(&softc->ctl_lock); initidx = ctl_get_initindex(&io->io_hdr.nexus); ua = ctl_build_qae(lun, initidx, io->taskio.task_resp); mtx_unlock(&lun->lun_lock); if (ua != CTL_UA_NONE) io->taskio.task_status = CTL_TASK_FUNCTION_SUCCEEDED; else io->taskio.task_status = CTL_TASK_FUNCTION_COMPLETE; return (0); } static void ctl_run_task(union ctl_io *io) { int retval = 1; CTL_DEBUG_PRINT(("ctl_run_task\n")); KASSERT(io->io_hdr.io_type == CTL_IO_TASK, ("ctl_run_task: Unextected io_type %d\n", io->io_hdr.io_type)); io->taskio.task_status = CTL_TASK_FUNCTION_NOT_SUPPORTED; bzero(io->taskio.task_resp, sizeof(io->taskio.task_resp)); switch (io->taskio.task_action) { case CTL_TASK_ABORT_TASK: retval = ctl_abort_task(io); break; case CTL_TASK_ABORT_TASK_SET: case CTL_TASK_CLEAR_TASK_SET: retval = ctl_abort_task_set(io); break; case CTL_TASK_CLEAR_ACA: break; case CTL_TASK_I_T_NEXUS_RESET: retval = ctl_i_t_nexus_reset(io); break; case CTL_TASK_LUN_RESET: retval = ctl_lun_reset(io); break; case CTL_TASK_TARGET_RESET: case CTL_TASK_BUS_RESET: retval = ctl_target_reset(io); break; case CTL_TASK_PORT_LOGIN: break; case CTL_TASK_PORT_LOGOUT: break; case CTL_TASK_QUERY_TASK: retval = ctl_query_task(io, 0); break; case CTL_TASK_QUERY_TASK_SET: retval = ctl_query_task(io, 1); break; case CTL_TASK_QUERY_ASYNC_EVENT: retval = ctl_query_async_event(io); break; default: printf("%s: got unknown task management event %d\n", __func__, io->taskio.task_action); break; } if (retval == 0) io->io_hdr.status = CTL_SUCCESS; else io->io_hdr.status = CTL_ERROR; ctl_done(io); } /* * For HA operation. Handle commands that come in from the other * controller. */ static void ctl_handle_isc(union ctl_io *io) { struct ctl_softc *softc = CTL_SOFTC(io); struct ctl_lun *lun; const struct ctl_cmd_entry *entry; uint32_t targ_lun; targ_lun = io->io_hdr.nexus.targ_mapped_lun; switch (io->io_hdr.msg_type) { case CTL_MSG_SERIALIZE: ctl_serialize_other_sc_cmd(&io->scsiio); break; case CTL_MSG_R2R: /* Only used in SER_ONLY mode. */ entry = ctl_get_cmd_entry(&io->scsiio, NULL); if (targ_lun >= ctl_max_luns || (lun = softc->ctl_luns[targ_lun]) == NULL) { ctl_done(io); break; } mtx_lock(&lun->lun_lock); if (ctl_scsiio_lun_check(lun, entry, &io->scsiio) != 0) { mtx_unlock(&lun->lun_lock); ctl_done(io); break; } io->io_hdr.flags |= CTL_FLAG_IS_WAS_ON_RTR; mtx_unlock(&lun->lun_lock); ctl_enqueue_rtr(io); break; case CTL_MSG_FINISH_IO: if (softc->ha_mode == CTL_HA_MODE_XFER) { ctl_done(io); break; } if (targ_lun >= ctl_max_luns || (lun = softc->ctl_luns[targ_lun]) == NULL) { ctl_free_io(io); break; } mtx_lock(&lun->lun_lock); ctl_try_unblock_others(lun, io, TRUE); TAILQ_REMOVE(&lun->ooa_queue, &io->io_hdr, ooa_links); mtx_unlock(&lun->lun_lock); ctl_free_io(io); break; case CTL_MSG_PERS_ACTION: ctl_hndl_per_res_out_on_other_sc(io); ctl_free_io(io); break; case CTL_MSG_BAD_JUJU: ctl_done(io); break; case CTL_MSG_DATAMOVE: /* Only used in XFER mode */ ctl_datamove_remote(io); break; case CTL_MSG_DATAMOVE_DONE: /* Only used in XFER mode */ io->scsiio.be_move_done(io); break; case CTL_MSG_FAILOVER: ctl_failover_lun(io); ctl_free_io(io); break; default: printf("%s: Invalid message type %d\n", __func__, io->io_hdr.msg_type); ctl_free_io(io); break; } } /* * Returns the match type in the case of a match, or CTL_LUN_PAT_NONE if * there is no match. */ static ctl_lun_error_pattern ctl_cmd_pattern_match(struct ctl_scsiio *ctsio, struct ctl_error_desc *desc) { const struct ctl_cmd_entry *entry; ctl_lun_error_pattern filtered_pattern, pattern; pattern = desc->error_pattern; /* * XXX KDM we need more data passed into this function to match a * custom pattern, and we actually need to implement custom pattern * matching. */ if (pattern & CTL_LUN_PAT_CMD) return (CTL_LUN_PAT_CMD); if ((pattern & CTL_LUN_PAT_MASK) == CTL_LUN_PAT_ANY) return (CTL_LUN_PAT_ANY); entry = ctl_get_cmd_entry(ctsio, NULL); filtered_pattern = entry->pattern & pattern; /* * If the user requested specific flags in the pattern (e.g. * CTL_LUN_PAT_RANGE), make sure the command supports all of those * flags. * * If the user did not specify any flags, it doesn't matter whether * or not the command supports the flags. */ if ((filtered_pattern & ~CTL_LUN_PAT_MASK) != (pattern & ~CTL_LUN_PAT_MASK)) return (CTL_LUN_PAT_NONE); /* * If the user asked for a range check, see if the requested LBA * range overlaps with this command's LBA range. */ if (filtered_pattern & CTL_LUN_PAT_RANGE) { uint64_t lba1; uint64_t len1; ctl_action action; int retval; retval = ctl_get_lba_len((union ctl_io *)ctsio, &lba1, &len1); if (retval != 0) return (CTL_LUN_PAT_NONE); action = ctl_extent_check_lba(lba1, len1, desc->lba_range.lba, desc->lba_range.len, FALSE); /* * A "pass" means that the LBA ranges don't overlap, so * this doesn't match the user's range criteria. */ if (action == CTL_ACTION_PASS) return (CTL_LUN_PAT_NONE); } return (filtered_pattern); } static void ctl_inject_error(struct ctl_lun *lun, union ctl_io *io) { struct ctl_error_desc *desc, *desc2; mtx_assert(&lun->lun_lock, MA_OWNED); STAILQ_FOREACH_SAFE(desc, &lun->error_list, links, desc2) { ctl_lun_error_pattern pattern; /* * Check to see whether this particular command matches * the pattern in the descriptor. */ pattern = ctl_cmd_pattern_match(&io->scsiio, desc); if ((pattern & CTL_LUN_PAT_MASK) == CTL_LUN_PAT_NONE) continue; switch (desc->lun_error & CTL_LUN_INJ_TYPE) { case CTL_LUN_INJ_ABORTED: ctl_set_aborted(&io->scsiio); break; case CTL_LUN_INJ_MEDIUM_ERR: ctl_set_medium_error(&io->scsiio, (io->io_hdr.flags & CTL_FLAG_DATA_MASK) != CTL_FLAG_DATA_OUT); break; case CTL_LUN_INJ_UA: /* 29h/00h POWER ON, RESET, OR BUS DEVICE RESET * OCCURRED */ ctl_set_ua(&io->scsiio, 0x29, 0x00); break; case CTL_LUN_INJ_CUSTOM: /* * We're assuming the user knows what he is doing. * Just copy the sense information without doing * checks. */ bcopy(&desc->custom_sense, &io->scsiio.sense_data, MIN(sizeof(desc->custom_sense), sizeof(io->scsiio.sense_data))); io->scsiio.scsi_status = SCSI_STATUS_CHECK_COND; io->scsiio.sense_len = SSD_FULL_SIZE; io->io_hdr.status = CTL_SCSI_ERROR | CTL_AUTOSENSE; break; case CTL_LUN_INJ_NONE: default: /* * If this is an error injection type we don't know * about, clear the continuous flag (if it is set) * so it will get deleted below. */ desc->lun_error &= ~CTL_LUN_INJ_CONTINUOUS; break; } /* * By default, each error injection action is a one-shot */ if (desc->lun_error & CTL_LUN_INJ_CONTINUOUS) continue; STAILQ_REMOVE(&lun->error_list, desc, ctl_error_desc, links); free(desc, M_CTL); } } #ifdef CTL_IO_DELAY static void ctl_datamove_timer_wakeup(void *arg) { union ctl_io *io; io = (union ctl_io *)arg; ctl_datamove(io); } #endif /* CTL_IO_DELAY */ void ctl_datamove(union ctl_io *io) { void (*fe_datamove)(union ctl_io *io); mtx_assert(&((struct ctl_softc *)CTL_SOFTC(io))->ctl_lock, MA_NOTOWNED); CTL_DEBUG_PRINT(("ctl_datamove\n")); /* No data transferred yet. Frontend must update this when done. */ io->scsiio.kern_data_resid = io->scsiio.kern_data_len; #ifdef CTL_TIME_IO if ((time_uptime - io->io_hdr.start_time) > ctl_time_io_secs) { char str[256]; char path_str[64]; struct sbuf sb; ctl_scsi_path_string(io, path_str, sizeof(path_str)); sbuf_new(&sb, str, sizeof(str), SBUF_FIXEDLEN); sbuf_cat(&sb, path_str); switch (io->io_hdr.io_type) { case CTL_IO_SCSI: ctl_scsi_command_string(&io->scsiio, NULL, &sb); sbuf_printf(&sb, "\n"); sbuf_cat(&sb, path_str); sbuf_printf(&sb, "Tag: 0x%04x/%d, Prio: %d\n", io->scsiio.tag_num, io->scsiio.tag_type, io->scsiio.priority); break; case CTL_IO_TASK: sbuf_printf(&sb, "Task Action: %d Tag: 0x%04x/%d\n", io->taskio.task_action, io->taskio.tag_num, io->taskio.tag_type); break; default: panic("%s: Invalid CTL I/O type %d\n", __func__, io->io_hdr.io_type); } sbuf_cat(&sb, path_str); sbuf_printf(&sb, "ctl_datamove: %jd seconds\n", (intmax_t)time_uptime - io->io_hdr.start_time); sbuf_finish(&sb); printf("%s", sbuf_data(&sb)); } #endif /* CTL_TIME_IO */ #ifdef CTL_IO_DELAY if (io->io_hdr.flags & CTL_FLAG_DELAY_DONE) { io->io_hdr.flags &= ~CTL_FLAG_DELAY_DONE; } else { struct ctl_lun *lun; lun = CTL_LUN(io); if ((lun != NULL) && (lun->delay_info.datamove_delay > 0)) { callout_init(&io->io_hdr.delay_callout, /*mpsafe*/ 1); io->io_hdr.flags |= CTL_FLAG_DELAY_DONE; callout_reset(&io->io_hdr.delay_callout, lun->delay_info.datamove_delay * hz, ctl_datamove_timer_wakeup, io); if (lun->delay_info.datamove_type == CTL_DELAY_TYPE_ONESHOT) lun->delay_info.datamove_delay = 0; return; } } #endif /* * This command has been aborted. Set the port status, so we fail * the data move. */ if (io->io_hdr.flags & CTL_FLAG_ABORT) { printf("ctl_datamove: tag 0x%04x on (%u:%u:%u) aborted\n", io->scsiio.tag_num, io->io_hdr.nexus.initid, io->io_hdr.nexus.targ_port, io->io_hdr.nexus.targ_lun); io->io_hdr.port_status = 31337; /* * Note that the backend, in this case, will get the * callback in its context. In other cases it may get * called in the frontend's interrupt thread context. */ io->scsiio.be_move_done(io); return; } /* Don't confuse frontend with zero length data move. */ if (io->scsiio.kern_data_len == 0) { io->scsiio.be_move_done(io); return; } fe_datamove = CTL_PORT(io)->fe_datamove; fe_datamove(io); } static void ctl_send_datamove_done(union ctl_io *io, int have_lock) { union ctl_ha_msg msg; #ifdef CTL_TIME_IO struct bintime cur_bt; #endif memset(&msg, 0, sizeof(msg)); msg.hdr.msg_type = CTL_MSG_DATAMOVE_DONE; msg.hdr.original_sc = io; msg.hdr.serializing_sc = io->io_hdr.remote_io; msg.hdr.nexus = io->io_hdr.nexus; msg.hdr.status = io->io_hdr.status; msg.scsi.kern_data_resid = io->scsiio.kern_data_resid; msg.scsi.tag_num = io->scsiio.tag_num; msg.scsi.tag_type = io->scsiio.tag_type; msg.scsi.scsi_status = io->scsiio.scsi_status; memcpy(&msg.scsi.sense_data, &io->scsiio.sense_data, io->scsiio.sense_len); msg.scsi.sense_len = io->scsiio.sense_len; msg.scsi.port_status = io->io_hdr.port_status; io->io_hdr.flags &= ~CTL_FLAG_IO_ACTIVE; if (io->io_hdr.flags & CTL_FLAG_FAILOVER) { ctl_failover_io(io, /*have_lock*/ have_lock); return; } ctl_ha_msg_send(CTL_HA_CHAN_CTL, &msg, sizeof(msg.scsi) - sizeof(msg.scsi.sense_data) + msg.scsi.sense_len, M_WAITOK); #ifdef CTL_TIME_IO getbinuptime(&cur_bt); bintime_sub(&cur_bt, &io->io_hdr.dma_start_bt); bintime_add(&io->io_hdr.dma_bt, &cur_bt); #endif io->io_hdr.num_dmas++; } /* * The DMA to the remote side is done, now we need to tell the other side * we're done so it can continue with its data movement. */ static void ctl_datamove_remote_write_cb(struct ctl_ha_dt_req *rq) { union ctl_io *io; uint32_t i; io = rq->context; if (rq->ret != CTL_HA_STATUS_SUCCESS) { printf("%s: ISC DMA write failed with error %d", __func__, rq->ret); ctl_set_internal_failure(&io->scsiio, /*sks_valid*/ 1, /*retry_count*/ rq->ret); } ctl_dt_req_free(rq); for (i = 0; i < io->scsiio.kern_sg_entries; i++) free(CTL_LSGLT(io)[i].addr, M_CTL); free(CTL_RSGL(io), M_CTL); CTL_RSGL(io) = NULL; CTL_LSGL(io) = NULL; /* * The data is in local and remote memory, so now we need to send * status (good or back) back to the other side. */ ctl_send_datamove_done(io, /*have_lock*/ 0); } /* * We've moved the data from the host/controller into local memory. Now we * need to push it over to the remote controller's memory. */ static int ctl_datamove_remote_dm_write_cb(union ctl_io *io) { int retval; retval = ctl_datamove_remote_xfer(io, CTL_HA_DT_CMD_WRITE, ctl_datamove_remote_write_cb); return (retval); } static void ctl_datamove_remote_write(union ctl_io *io) { int retval; void (*fe_datamove)(union ctl_io *io); /* * - Get the data from the host/HBA into local memory. * - DMA memory from the local controller to the remote controller. * - Send status back to the remote controller. */ retval = ctl_datamove_remote_sgl_setup(io); if (retval != 0) return; /* Switch the pointer over so the FETD knows what to do */ io->scsiio.kern_data_ptr = (uint8_t *)CTL_LSGL(io); /* * Use a custom move done callback, since we need to send completion * back to the other controller, not to the backend on this side. */ io->scsiio.be_move_done = ctl_datamove_remote_dm_write_cb; fe_datamove = CTL_PORT(io)->fe_datamove; fe_datamove(io); } static int ctl_datamove_remote_dm_read_cb(union ctl_io *io) { uint32_t i; for (i = 0; i < io->scsiio.kern_sg_entries; i++) free(CTL_LSGLT(io)[i].addr, M_CTL); free(CTL_RSGL(io), M_CTL); CTL_RSGL(io) = NULL; CTL_LSGL(io) = NULL; /* * The read is done, now we need to send status (good or bad) back * to the other side. */ ctl_send_datamove_done(io, /*have_lock*/ 0); return (0); } static void ctl_datamove_remote_read_cb(struct ctl_ha_dt_req *rq) { union ctl_io *io; void (*fe_datamove)(union ctl_io *io); io = rq->context; if (rq->ret != CTL_HA_STATUS_SUCCESS) { printf("%s: ISC DMA read failed with error %d\n", __func__, rq->ret); ctl_set_internal_failure(&io->scsiio, /*sks_valid*/ 1, /*retry_count*/ rq->ret); } ctl_dt_req_free(rq); /* Switch the pointer over so the FETD knows what to do */ io->scsiio.kern_data_ptr = (uint8_t *)CTL_LSGL(io); /* * Use a custom move done callback, since we need to send completion * back to the other controller, not to the backend on this side. */ io->scsiio.be_move_done = ctl_datamove_remote_dm_read_cb; /* XXX KDM add checks like the ones in ctl_datamove? */ fe_datamove = CTL_PORT(io)->fe_datamove; fe_datamove(io); } static int ctl_datamove_remote_sgl_setup(union ctl_io *io) { struct ctl_sg_entry *local_sglist; uint32_t len_to_go; int retval; int i; retval = 0; local_sglist = CTL_LSGL(io); len_to_go = io->scsiio.kern_data_len; /* * The difficult thing here is that the size of the various * S/G segments may be different than the size from the * remote controller. That'll make it harder when DMAing * the data back to the other side. */ for (i = 0; len_to_go > 0; i++) { local_sglist[i].len = MIN(len_to_go, CTL_HA_DATAMOVE_SEGMENT); local_sglist[i].addr = malloc(local_sglist[i].len, M_CTL, M_WAITOK); len_to_go -= local_sglist[i].len; } /* * Reset the number of S/G entries accordingly. The original * number of S/G entries is available in rem_sg_entries. */ io->scsiio.kern_sg_entries = i; return (retval); } static int ctl_datamove_remote_xfer(union ctl_io *io, unsigned command, ctl_ha_dt_cb callback) { struct ctl_ha_dt_req *rq; struct ctl_sg_entry *remote_sglist, *local_sglist; uint32_t local_used, remote_used, total_used; int i, j, isc_ret; rq = ctl_dt_req_alloc(); /* * If we failed to allocate the request, and if the DMA didn't fail * anyway, set busy status. This is just a resource allocation * failure. */ if ((rq == NULL) && ((io->io_hdr.status & CTL_STATUS_MASK) != CTL_STATUS_NONE && (io->io_hdr.status & CTL_STATUS_MASK) != CTL_SUCCESS)) ctl_set_busy(&io->scsiio); if ((io->io_hdr.status & CTL_STATUS_MASK) != CTL_STATUS_NONE && (io->io_hdr.status & CTL_STATUS_MASK) != CTL_SUCCESS) { if (rq != NULL) ctl_dt_req_free(rq); /* * The data move failed. We need to return status back * to the other controller. No point in trying to DMA * data to the remote controller. */ ctl_send_datamove_done(io, /*have_lock*/ 0); return (1); } local_sglist = CTL_LSGL(io); remote_sglist = CTL_RSGL(io); local_used = 0; remote_used = 0; total_used = 0; /* * Pull/push the data over the wire from/to the other controller. * This takes into account the possibility that the local and * remote sglists may not be identical in terms of the size of * the elements and the number of elements. * * One fundamental assumption here is that the length allocated for * both the local and remote sglists is identical. Otherwise, we've * essentially got a coding error of some sort. */ isc_ret = CTL_HA_STATUS_SUCCESS; for (i = 0, j = 0; total_used < io->scsiio.kern_data_len; ) { uint32_t cur_len; uint8_t *tmp_ptr; rq->command = command; rq->context = io; /* * Both pointers should be aligned. But it is possible * that the allocation length is not. They should both * also have enough slack left over at the end, though, * to round up to the next 8 byte boundary. */ cur_len = MIN(local_sglist[i].len - local_used, remote_sglist[j].len - remote_used); rq->size = cur_len; tmp_ptr = (uint8_t *)local_sglist[i].addr; tmp_ptr += local_used; #if 0 /* Use physical addresses when talking to ISC hardware */ if ((io->io_hdr.flags & CTL_FLAG_BUS_ADDR) == 0) { /* XXX KDM use busdma */ rq->local = vtophys(tmp_ptr); } else rq->local = tmp_ptr; #else KASSERT((io->io_hdr.flags & CTL_FLAG_BUS_ADDR) == 0, ("HA does not support BUS_ADDR")); rq->local = tmp_ptr; #endif tmp_ptr = (uint8_t *)remote_sglist[j].addr; tmp_ptr += remote_used; rq->remote = tmp_ptr; rq->callback = NULL; local_used += cur_len; if (local_used >= local_sglist[i].len) { i++; local_used = 0; } remote_used += cur_len; if (remote_used >= remote_sglist[j].len) { j++; remote_used = 0; } total_used += cur_len; if (total_used >= io->scsiio.kern_data_len) rq->callback = callback; isc_ret = ctl_dt_single(rq); if (isc_ret > CTL_HA_STATUS_SUCCESS) break; } if (isc_ret != CTL_HA_STATUS_WAIT) { rq->ret = isc_ret; callback(rq); } return (0); } static void ctl_datamove_remote_read(union ctl_io *io) { int retval; uint32_t i; /* * This will send an error to the other controller in the case of a * failure. */ retval = ctl_datamove_remote_sgl_setup(io); if (retval != 0) return; retval = ctl_datamove_remote_xfer(io, CTL_HA_DT_CMD_READ, ctl_datamove_remote_read_cb); if (retval != 0) { /* * Make sure we free memory if there was an error.. The * ctl_datamove_remote_xfer() function will send the * datamove done message, or call the callback with an * error if there is a problem. */ for (i = 0; i < io->scsiio.kern_sg_entries; i++) free(CTL_LSGLT(io)[i].addr, M_CTL); free(CTL_RSGL(io), M_CTL); CTL_RSGL(io) = NULL; CTL_LSGL(io) = NULL; } } /* * Process a datamove request from the other controller. This is used for * XFER mode only, not SER_ONLY mode. For writes, we DMA into local memory * first. Once that is complete, the data gets DMAed into the remote * controller's memory. For reads, we DMA from the remote controller's * memory into our memory first, and then move it out to the FETD. */ static void ctl_datamove_remote(union ctl_io *io) { mtx_assert(&((struct ctl_softc *)CTL_SOFTC(io))->ctl_lock, MA_NOTOWNED); if (io->io_hdr.flags & CTL_FLAG_FAILOVER) { ctl_failover_io(io, /*have_lock*/ 0); return; } /* * Note that we look for an aborted I/O here, but don't do some of * the other checks that ctl_datamove() normally does. * We don't need to run the datamove delay code, since that should * have been done if need be on the other controller. */ if (io->io_hdr.flags & CTL_FLAG_ABORT) { printf("%s: tag 0x%04x on (%u:%u:%u) aborted\n", __func__, io->scsiio.tag_num, io->io_hdr.nexus.initid, io->io_hdr.nexus.targ_port, io->io_hdr.nexus.targ_lun); io->io_hdr.port_status = 31338; ctl_send_datamove_done(io, /*have_lock*/ 0); return; } if ((io->io_hdr.flags & CTL_FLAG_DATA_MASK) == CTL_FLAG_DATA_OUT) ctl_datamove_remote_write(io); else if ((io->io_hdr.flags & CTL_FLAG_DATA_MASK) == CTL_FLAG_DATA_IN) ctl_datamove_remote_read(io); else { io->io_hdr.port_status = 31339; ctl_send_datamove_done(io, /*have_lock*/ 0); } } static void ctl_process_done(union ctl_io *io) { struct ctl_softc *softc = CTL_SOFTC(io); struct ctl_port *port = CTL_PORT(io); struct ctl_lun *lun = CTL_LUN(io); void (*fe_done)(union ctl_io *io); union ctl_ha_msg msg; CTL_DEBUG_PRINT(("ctl_process_done\n")); fe_done = port->fe_done; #ifdef CTL_TIME_IO if ((time_uptime - io->io_hdr.start_time) > ctl_time_io_secs) { char str[256]; char path_str[64]; struct sbuf sb; ctl_scsi_path_string(io, path_str, sizeof(path_str)); sbuf_new(&sb, str, sizeof(str), SBUF_FIXEDLEN); sbuf_cat(&sb, path_str); switch (io->io_hdr.io_type) { case CTL_IO_SCSI: ctl_scsi_command_string(&io->scsiio, NULL, &sb); sbuf_printf(&sb, "\n"); sbuf_cat(&sb, path_str); sbuf_printf(&sb, "Tag: 0x%04x/%d, Prio: %d\n", io->scsiio.tag_num, io->scsiio.tag_type, io->scsiio.priority); break; case CTL_IO_TASK: sbuf_printf(&sb, "Task Action: %d Tag: 0x%04x/%d\n", io->taskio.task_action, io->taskio.tag_num, io->taskio.tag_type); break; default: panic("%s: Invalid CTL I/O type %d\n", __func__, io->io_hdr.io_type); } sbuf_cat(&sb, path_str); sbuf_printf(&sb, "ctl_process_done: %jd seconds\n", (intmax_t)time_uptime - io->io_hdr.start_time); sbuf_finish(&sb); printf("%s", sbuf_data(&sb)); } #endif /* CTL_TIME_IO */ switch (io->io_hdr.io_type) { case CTL_IO_SCSI: break; case CTL_IO_TASK: if (ctl_debug & CTL_DEBUG_INFO) ctl_io_error_print(io, NULL); fe_done(io); return; default: panic("%s: Invalid CTL I/O type %d\n", __func__, io->io_hdr.io_type); } if (lun == NULL) { CTL_DEBUG_PRINT(("NULL LUN for lun %d\n", io->io_hdr.nexus.targ_mapped_lun)); goto bailout; } mtx_lock(&lun->lun_lock); /* * Check to see if we have any informational exception and status * of this command can be modified to report it in form of either * RECOVERED ERROR or NO SENSE, depending on MRIE mode page field. */ if (lun->ie_reported == 0 && lun->ie_asc != 0 && io->io_hdr.status == CTL_SUCCESS && (io->io_hdr.flags & CTL_FLAG_STATUS_SENT) == 0) { uint8_t mrie = lun->MODE_IE.mrie; uint8_t per = ((lun->MODE_RWER.byte3 & SMS_RWER_PER) || (lun->MODE_VER.byte3 & SMS_VER_PER)); if (((mrie == SIEP_MRIE_REC_COND && per) || mrie == SIEP_MRIE_REC_UNCOND || mrie == SIEP_MRIE_NO_SENSE) && (ctl_get_cmd_entry(&io->scsiio, NULL)->flags & CTL_CMD_FLAG_NO_SENSE) == 0) { ctl_set_sense(&io->scsiio, /*current_error*/ 1, /*sense_key*/ (mrie == SIEP_MRIE_NO_SENSE) ? SSD_KEY_NO_SENSE : SSD_KEY_RECOVERED_ERROR, /*asc*/ lun->ie_asc, /*ascq*/ lun->ie_ascq, SSD_ELEM_NONE); lun->ie_reported = 1; } } else if (lun->ie_reported < 0) lun->ie_reported = 0; /* * Check to see if we have any errors to inject here. We only * inject errors for commands that don't already have errors set. */ if (!STAILQ_EMPTY(&lun->error_list) && ((io->io_hdr.status & CTL_STATUS_MASK) == CTL_SUCCESS) && ((io->io_hdr.flags & CTL_FLAG_STATUS_SENT) == 0)) ctl_inject_error(lun, io); /* * XXX KDM how do we treat commands that aren't completed * successfully? * * XXX KDM should we also track I/O latency? */ if ((io->io_hdr.status & CTL_STATUS_MASK) == CTL_SUCCESS && io->io_hdr.io_type == CTL_IO_SCSI) { int type; #ifdef CTL_TIME_IO struct bintime bt; getbinuptime(&bt); bintime_sub(&bt, &io->io_hdr.start_bt); #endif if ((io->io_hdr.flags & CTL_FLAG_DATA_MASK) == CTL_FLAG_DATA_IN) type = CTL_STATS_READ; else if ((io->io_hdr.flags & CTL_FLAG_DATA_MASK) == CTL_FLAG_DATA_OUT) type = CTL_STATS_WRITE; else type = CTL_STATS_NO_IO; lun->stats.bytes[type] += io->scsiio.kern_total_len; lun->stats.operations[type] ++; lun->stats.dmas[type] += io->io_hdr.num_dmas; #ifdef CTL_TIME_IO bintime_add(&lun->stats.dma_time[type], &io->io_hdr.dma_bt); bintime_add(&lun->stats.time[type], &bt); #endif mtx_lock(&port->port_lock); port->stats.bytes[type] += io->scsiio.kern_total_len; port->stats.operations[type] ++; port->stats.dmas[type] += io->io_hdr.num_dmas; #ifdef CTL_TIME_IO bintime_add(&port->stats.dma_time[type], &io->io_hdr.dma_bt); bintime_add(&port->stats.time[type], &bt); #endif mtx_unlock(&port->port_lock); } /* * Run through the blocked queue of this I/O and see if anything * can be unblocked, now that this I/O is done and will be removed. * We need to do it before removal to have OOA position to start. */ ctl_try_unblock_others(lun, io, TRUE); /* * Remove this from the OOA queue. */ TAILQ_REMOVE(&lun->ooa_queue, &io->io_hdr, ooa_links); #ifdef CTL_TIME_IO if (TAILQ_EMPTY(&lun->ooa_queue)) lun->last_busy = getsbinuptime(); #endif /* * If the LUN has been invalidated, free it if there is nothing * left on its OOA queue. */ if ((lun->flags & CTL_LUN_INVALID) && TAILQ_EMPTY(&lun->ooa_queue)) { mtx_unlock(&lun->lun_lock); ctl_free_lun(lun); } else mtx_unlock(&lun->lun_lock); bailout: /* * If this command has been aborted, make sure we set the status * properly. The FETD is responsible for freeing the I/O and doing * whatever it needs to do to clean up its state. */ if (io->io_hdr.flags & CTL_FLAG_ABORT) ctl_set_task_aborted(&io->scsiio); /* * If enabled, print command error status. */ if ((io->io_hdr.status & CTL_STATUS_MASK) != CTL_SUCCESS && (ctl_debug & CTL_DEBUG_INFO) != 0) ctl_io_error_print(io, NULL); /* * Tell the FETD or the other shelf controller we're done with this * command. Note that only SCSI commands get to this point. Task * management commands are completed above. */ if ((softc->ha_mode != CTL_HA_MODE_XFER) && (io->io_hdr.flags & CTL_FLAG_SENT_2OTHER_SC)) { memset(&msg, 0, sizeof(msg)); msg.hdr.msg_type = CTL_MSG_FINISH_IO; msg.hdr.serializing_sc = io->io_hdr.remote_io; msg.hdr.nexus = io->io_hdr.nexus; ctl_ha_msg_send(CTL_HA_CHAN_CTL, &msg, sizeof(msg.scsi) - sizeof(msg.scsi.sense_data), M_WAITOK); } fe_done(io); } /* * Front end should call this if it doesn't do autosense. When the request * sense comes back in from the initiator, we'll dequeue this and send it. */ int ctl_queue_sense(union ctl_io *io) { struct ctl_softc *softc = CTL_SOFTC(io); struct ctl_port *port = CTL_PORT(io); struct ctl_lun *lun; struct scsi_sense_data *ps; uint32_t initidx, p, targ_lun; CTL_DEBUG_PRINT(("ctl_queue_sense\n")); targ_lun = ctl_lun_map_from_port(port, io->io_hdr.nexus.targ_lun); /* * LUN lookup will likely move to the ctl_work_thread() once we * have our new queueing infrastructure (that doesn't put things on * a per-LUN queue initially). That is so that we can handle * things like an INQUIRY to a LUN that we don't have enabled. We * can't deal with that right now. * If we don't have a LUN for this, just toss the sense information. */ mtx_lock(&softc->ctl_lock); if (targ_lun >= ctl_max_luns || (lun = softc->ctl_luns[targ_lun]) == NULL) { mtx_unlock(&softc->ctl_lock); goto bailout; } mtx_lock(&lun->lun_lock); mtx_unlock(&softc->ctl_lock); initidx = ctl_get_initindex(&io->io_hdr.nexus); p = initidx / CTL_MAX_INIT_PER_PORT; if (lun->pending_sense[p] == NULL) { lun->pending_sense[p] = malloc(sizeof(*ps) * CTL_MAX_INIT_PER_PORT, M_CTL, M_NOWAIT | M_ZERO); } if ((ps = lun->pending_sense[p]) != NULL) { ps += initidx % CTL_MAX_INIT_PER_PORT; memset(ps, 0, sizeof(*ps)); memcpy(ps, &io->scsiio.sense_data, io->scsiio.sense_len); } mtx_unlock(&lun->lun_lock); bailout: ctl_free_io(io); return (CTL_RETVAL_COMPLETE); } /* * Primary command inlet from frontend ports. All SCSI and task I/O * requests must go through this function. */ int ctl_queue(union ctl_io *io) { struct ctl_port *port = CTL_PORT(io); CTL_DEBUG_PRINT(("ctl_queue cdb[0]=%02X\n", io->scsiio.cdb[0])); #ifdef CTL_TIME_IO io->io_hdr.start_time = time_uptime; getbinuptime(&io->io_hdr.start_bt); #endif /* CTL_TIME_IO */ /* Map FE-specific LUN ID into global one. */ io->io_hdr.nexus.targ_mapped_lun = ctl_lun_map_from_port(port, io->io_hdr.nexus.targ_lun); switch (io->io_hdr.io_type) { case CTL_IO_SCSI: case CTL_IO_TASK: if (ctl_debug & CTL_DEBUG_CDB) ctl_io_print(io); ctl_enqueue_incoming(io); break; default: printf("ctl_queue: unknown I/O type %d\n", io->io_hdr.io_type); return (EINVAL); } return (CTL_RETVAL_COMPLETE); } +int +ctl_run(union ctl_io *io) +{ + struct ctl_port *port = CTL_PORT(io); + + CTL_DEBUG_PRINT(("ctl_run cdb[0]=%02X\n", io->scsiio.cdb[0])); + +#ifdef CTL_TIME_IO + io->io_hdr.start_time = time_uptime; + getbinuptime(&io->io_hdr.start_bt); +#endif /* CTL_TIME_IO */ + + /* Map FE-specific LUN ID into global one. */ + io->io_hdr.nexus.targ_mapped_lun = + ctl_lun_map_from_port(port, io->io_hdr.nexus.targ_lun); + + switch (io->io_hdr.io_type) { + case CTL_IO_SCSI: + if (ctl_debug & CTL_DEBUG_CDB) + ctl_io_print(io); + ctl_scsiio_precheck(&io->scsiio); + break; + case CTL_IO_TASK: + if (ctl_debug & CTL_DEBUG_CDB) + ctl_io_print(io); + ctl_run_task(io); + break; + default: + printf("ctl_run: unknown I/O type %d\n", io->io_hdr.io_type); + return (EINVAL); + } + + return (CTL_RETVAL_COMPLETE); +} + #ifdef CTL_IO_DELAY static void ctl_done_timer_wakeup(void *arg) { union ctl_io *io; io = (union ctl_io *)arg; ctl_done(io); } #endif /* CTL_IO_DELAY */ void ctl_serseq_done(union ctl_io *io) { struct ctl_lun *lun = CTL_LUN(io); if (lun->be_lun->serseq == CTL_LUN_SERSEQ_OFF) return; mtx_lock(&lun->lun_lock); io->io_hdr.flags |= CTL_FLAG_SERSEQ_DONE; ctl_try_unblock_others(lun, io, FALSE); mtx_unlock(&lun->lun_lock); } void ctl_done(union ctl_io *io) { /* * Enable this to catch duplicate completion issues. */ #if 0 if (io->io_hdr.flags & CTL_FLAG_ALREADY_DONE) { printf("%s: type %d msg %d cdb %x iptl: " "%u:%u:%u tag 0x%04x " "flag %#x status %x\n", __func__, io->io_hdr.io_type, io->io_hdr.msg_type, io->scsiio.cdb[0], io->io_hdr.nexus.initid, io->io_hdr.nexus.targ_port, io->io_hdr.nexus.targ_lun, (io->io_hdr.io_type == CTL_IO_TASK) ? io->taskio.tag_num : io->scsiio.tag_num, io->io_hdr.flags, io->io_hdr.status); } else io->io_hdr.flags |= CTL_FLAG_ALREADY_DONE; #endif /* * This is an internal copy of an I/O, and should not go through * the normal done processing logic. */ if (io->io_hdr.flags & CTL_FLAG_INT_COPY) return; #ifdef CTL_IO_DELAY if (io->io_hdr.flags & CTL_FLAG_DELAY_DONE) { io->io_hdr.flags &= ~CTL_FLAG_DELAY_DONE; } else { struct ctl_lun *lun = CTL_LUN(io); if ((lun != NULL) && (lun->delay_info.done_delay > 0)) { callout_init(&io->io_hdr.delay_callout, /*mpsafe*/ 1); io->io_hdr.flags |= CTL_FLAG_DELAY_DONE; callout_reset(&io->io_hdr.delay_callout, lun->delay_info.done_delay * hz, ctl_done_timer_wakeup, io); if (lun->delay_info.done_type == CTL_DELAY_TYPE_ONESHOT) lun->delay_info.done_delay = 0; return; } } #endif /* CTL_IO_DELAY */ ctl_enqueue_done(io); } static void ctl_work_thread(void *arg) { struct ctl_thread *thr = (struct ctl_thread *)arg; struct ctl_softc *softc = thr->ctl_softc; union ctl_io *io; int retval; CTL_DEBUG_PRINT(("ctl_work_thread starting\n")); thread_lock(curthread); sched_prio(curthread, PUSER - 1); thread_unlock(curthread); while (!softc->shutdown) { /* * We handle the queues in this order: * - ISC * - done queue (to free up resources, unblock other commands) * - incoming queue * - RtR queue * * If those queues are empty, we break out of the loop and * go to sleep. */ mtx_lock(&thr->queue_lock); io = (union ctl_io *)STAILQ_FIRST(&thr->isc_queue); if (io != NULL) { STAILQ_REMOVE_HEAD(&thr->isc_queue, links); mtx_unlock(&thr->queue_lock); ctl_handle_isc(io); continue; } io = (union ctl_io *)STAILQ_FIRST(&thr->done_queue); if (io != NULL) { STAILQ_REMOVE_HEAD(&thr->done_queue, links); /* clear any blocked commands, call fe_done */ mtx_unlock(&thr->queue_lock); ctl_process_done(io); continue; } io = (union ctl_io *)STAILQ_FIRST(&thr->incoming_queue); if (io != NULL) { STAILQ_REMOVE_HEAD(&thr->incoming_queue, links); mtx_unlock(&thr->queue_lock); if (io->io_hdr.io_type == CTL_IO_TASK) ctl_run_task(io); else - ctl_scsiio_precheck(softc, &io->scsiio); + ctl_scsiio_precheck(&io->scsiio); continue; } io = (union ctl_io *)STAILQ_FIRST(&thr->rtr_queue); if (io != NULL) { STAILQ_REMOVE_HEAD(&thr->rtr_queue, links); mtx_unlock(&thr->queue_lock); retval = ctl_scsiio(&io->scsiio); if (retval != CTL_RETVAL_COMPLETE) CTL_DEBUG_PRINT(("ctl_scsiio failed\n")); continue; } /* Sleep until we have something to do. */ mtx_sleep(thr, &thr->queue_lock, PDROP, "-", 0); } thr->thread = NULL; kthread_exit(); } static void ctl_thresh_thread(void *arg) { struct ctl_softc *softc = (struct ctl_softc *)arg; struct ctl_lun *lun; struct ctl_logical_block_provisioning_page *page; const char *attr; union ctl_ha_msg msg; uint64_t thres, val; int i, e, set; CTL_DEBUG_PRINT(("ctl_thresh_thread starting\n")); thread_lock(curthread); sched_prio(curthread, PUSER - 1); thread_unlock(curthread); while (!softc->shutdown) { mtx_lock(&softc->ctl_lock); STAILQ_FOREACH(lun, &softc->lun_list, links) { if ((lun->flags & CTL_LUN_DISABLED) || (lun->flags & CTL_LUN_NO_MEDIA) || lun->backend->lun_attr == NULL) continue; if ((lun->flags & CTL_LUN_PRIMARY_SC) == 0 && softc->ha_mode == CTL_HA_MODE_XFER) continue; if ((lun->MODE_RWER.byte8 & SMS_RWER_LBPERE) == 0) continue; e = 0; page = &lun->MODE_LBP; for (i = 0; i < CTL_NUM_LBP_THRESH; i++) { if ((page->descr[i].flags & SLBPPD_ENABLED) == 0) continue; thres = scsi_4btoul(page->descr[i].count); thres <<= CTL_LBP_EXPONENT; switch (page->descr[i].resource) { case 0x01: attr = "blocksavail"; break; case 0x02: attr = "blocksused"; break; case 0xf1: attr = "poolblocksavail"; break; case 0xf2: attr = "poolblocksused"; break; default: continue; } mtx_unlock(&softc->ctl_lock); // XXX val = lun->backend->lun_attr(lun->be_lun, attr); mtx_lock(&softc->ctl_lock); if (val == UINT64_MAX) continue; if ((page->descr[i].flags & SLBPPD_ARMING_MASK) == SLBPPD_ARMING_INC) e = (val >= thres); else e = (val <= thres); if (e) break; } mtx_lock(&lun->lun_lock); if (e) { scsi_u64to8b((uint8_t *)&page->descr[i] - (uint8_t *)page, lun->ua_tpt_info); if (lun->lasttpt == 0 || time_uptime - lun->lasttpt >= CTL_LBP_UA_PERIOD) { lun->lasttpt = time_uptime; ctl_est_ua_all(lun, -1, CTL_UA_THIN_PROV_THRES); set = 1; } else set = 0; } else { lun->lasttpt = 0; ctl_clr_ua_all(lun, -1, CTL_UA_THIN_PROV_THRES); set = -1; } mtx_unlock(&lun->lun_lock); if (set != 0 && lun->ctl_softc->ha_mode == CTL_HA_MODE_XFER) { /* Send msg to other side. */ bzero(&msg.ua, sizeof(msg.ua)); msg.hdr.msg_type = CTL_MSG_UA; msg.hdr.nexus.initid = -1; msg.hdr.nexus.targ_port = -1; msg.hdr.nexus.targ_lun = lun->lun; msg.hdr.nexus.targ_mapped_lun = lun->lun; msg.ua.ua_all = 1; msg.ua.ua_set = (set > 0); msg.ua.ua_type = CTL_UA_THIN_PROV_THRES; memcpy(msg.ua.ua_info, lun->ua_tpt_info, 8); mtx_unlock(&softc->ctl_lock); // XXX ctl_ha_msg_send(CTL_HA_CHAN_CTL, &msg, sizeof(msg.ua), M_WAITOK); mtx_lock(&softc->ctl_lock); } } mtx_sleep(&softc->thresh_thread, &softc->ctl_lock, PDROP, "-", CTL_LBP_PERIOD * hz); } softc->thresh_thread = NULL; kthread_exit(); } static void ctl_enqueue_incoming(union ctl_io *io) { struct ctl_softc *softc = CTL_SOFTC(io); struct ctl_thread *thr; u_int idx; idx = (io->io_hdr.nexus.targ_port * 127 + io->io_hdr.nexus.initid) % worker_threads; thr = &softc->threads[idx]; mtx_lock(&thr->queue_lock); STAILQ_INSERT_TAIL(&thr->incoming_queue, &io->io_hdr, links); mtx_unlock(&thr->queue_lock); wakeup(thr); } static void ctl_enqueue_rtr(union ctl_io *io) { struct ctl_softc *softc = CTL_SOFTC(io); struct ctl_thread *thr; thr = &softc->threads[io->io_hdr.nexus.targ_mapped_lun % worker_threads]; mtx_lock(&thr->queue_lock); STAILQ_INSERT_TAIL(&thr->rtr_queue, &io->io_hdr, links); mtx_unlock(&thr->queue_lock); wakeup(thr); } static void ctl_enqueue_done(union ctl_io *io) { struct ctl_softc *softc = CTL_SOFTC(io); struct ctl_thread *thr; thr = &softc->threads[io->io_hdr.nexus.targ_mapped_lun % worker_threads]; mtx_lock(&thr->queue_lock); STAILQ_INSERT_TAIL(&thr->done_queue, &io->io_hdr, links); mtx_unlock(&thr->queue_lock); wakeup(thr); } static void ctl_enqueue_isc(union ctl_io *io) { struct ctl_softc *softc = CTL_SOFTC(io); struct ctl_thread *thr; thr = &softc->threads[io->io_hdr.nexus.targ_mapped_lun % worker_threads]; mtx_lock(&thr->queue_lock); STAILQ_INSERT_TAIL(&thr->isc_queue, &io->io_hdr, links); mtx_unlock(&thr->queue_lock); wakeup(thr); } /* * vim: ts=8 */ diff --git a/sys/cam/ctl/ctl_frontend.h b/sys/cam/ctl/ctl_frontend.h index bdcb7a2e1abd..c9ab255cdde4 100644 --- a/sys/cam/ctl/ctl_frontend.h +++ b/sys/cam/ctl/ctl_frontend.h @@ -1,339 +1,346 @@ /*- * SPDX-License-Identifier: BSD-2-Clause-FreeBSD * * Copyright (c) 2003 Silicon Graphics International Corp. * Copyright (c) 2014-2017 Alexander Motin * 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, * without modification. * 2. Redistributions in binary form must reproduce at minimum a disclaimer * substantially similar to the "NO WARRANTY" disclaimer below * ("Disclaimer") and any redistribution must be conditioned upon * including a substantially similar Disclaimer requirement for further * binary redistribution. * * NO WARRANTY * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTIBILITY AND FITNESS FOR * A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT * HOLDERS OR CONTRIBUTORS BE LIABLE FOR 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 DAMAGES. * * $Id: //depot/users/kenm/FreeBSD-test2/sys/cam/ctl/ctl_frontend.h#2 $ * $FreeBSD$ */ /* * CAM Target Layer front end registration hooks * * Author: Ken Merry */ #ifndef _CTL_FRONTEND_H_ #define _CTL_FRONTEND_H_ #include #include typedef enum { CTL_PORT_STATUS_NONE = 0x00, CTL_PORT_STATUS_ONLINE = 0x01, CTL_PORT_STATUS_HA_SHARED = 0x02 } ctl_port_status; typedef int (*fe_init_t)(void); typedef int (*fe_shutdown_t)(void); typedef void (*port_func_t)(void *onoff_arg); typedef int (*port_info_func_t)(void *onoff_arg, struct sbuf *sb); typedef int (*lun_func_t)(void *arg, int lun_id); typedef int (*fe_ioctl_t)(struct cdev *dev, u_long cmd, caddr_t addr, int flag, struct thread *td); #define CTL_FRONTEND_DECLARE(name, driver) \ static int name ## _modevent(module_t mod, int type, void *data) \ { \ switch (type) { \ case MOD_LOAD: \ return (ctl_frontend_register( \ (struct ctl_frontend *)data)); \ break; \ case MOD_UNLOAD: \ return (ctl_frontend_deregister( \ (struct ctl_frontend *)data)); \ break; \ default: \ return EOPNOTSUPP; \ } \ return 0; \ } \ static moduledata_t name ## _mod = { \ #name, \ name ## _modevent, \ (void *)&driver \ }; \ DECLARE_MODULE(name, name ## _mod, SI_SUB_CONFIGURE, SI_ORDER_FOURTH); \ MODULE_DEPEND(name, ctl, 1, 1, 1); \ MODULE_DEPEND(name, cam, 1, 1, 1) struct ctl_wwpn_iid { int in_use; time_t last_use; uint64_t wwpn; char *name; }; /* * The ctl_frontend structure is the registration mechanism between a FETD * (Front End Target Driver) and the CTL layer. Here is a description of * the fields: * * port_type: This field tells CTL what kind of front end it is * dealing with. This field serves two purposes. * The first is to let CTL know whether the frontend * in question is inside the main CTL module (i.e. * the ioctl front end), and therefore its module * reference count shouldn't be incremented. The * CTL ioctl front end should continue to use the * CTL_PORT_IOCTL argument as long as it is part of * the main CTL module. The second is to let CTL * know what kind of front end it is dealing with, so * it can return the proper inquiry data for that * particular port. * * num_requested_ctl_io: This is the number of ctl_io structures that the * front end needs for its pool. This should * generally be the maximum number of outstanding * transactions that the FETD can handle. The CTL * layer will add a few to this to account for * ctl_io buffers queued for pending sense data. * (Pending sense only gets queued if the FETD * doesn't support autosense. e.g. non-packetized * parallel SCSI doesn't support autosense.) * * port_name: A string describing the FETD. e.g. "LSI 1030T U320" * or whatever you want to use to describe the driver. * * physical_port: This is the physical port number of this * particular port within the driver/hardware. This * number is hardware/driver specific. * virtual_port: This is the virtual port number of this * particular port. This is for things like NP-IV. * * port_online(): This function is called, with onoff_arg as its * argument, by the CTL layer when it wants the FETD * to start responding to selections on the specified * target ID. * * port_offline(): This function is called, with onoff_arg as its * argument, by the CTL layer when it wants the FETD * to stop responding to selection on the specified * target ID. * * onoff_arg: This is supplied as an argument to port_online() * and port_offline(). This is specified by the * FETD. * * lun_enable(): This function is called, with targ_lun_arg, a target * ID and a LUN ID as its arguments, by CTL when it * wants the FETD to enable a particular LUN. If the * FETD doesn't really know about LUNs, it should * just ignore this call and return 0. If the FETD * cannot enable the requested LUN for some reason, the * FETD should return non-zero status. * * lun_disable(): This function is called, with targ_lun_arg, a target * ID and LUN ID as its arguments, by CTL when it * wants the FETD to disable a particular LUN. If the * FETD doesn't really know about LUNs, it should just * ignore this call and return 0. If the FETD cannot * disable the requested LUN for some reason, the * FETD should return non-zero status. * * targ_lun_arg: This is supplied as an argument to the targ/lun * enable/disable() functions. This is specified by * the FETD. * * fe_datamove(): This function is called one or more times per I/O * by the CTL layer to tell the FETD to initiate a * DMA to or from the data buffer(s) specified by * the passed-in ctl_io structure. * * fe_done(): This function is called by the CTL layer when a * particular SCSI I/O or task management command has * completed. For SCSI I/O requests (CTL_IO_SCSI), * sense data is always supplied if the status is * CTL_SCSI_ERROR and the SCSI status byte is * SCSI_STATUS_CHECK_COND. If the FETD doesn't * support autosense, the sense should be queued * back to the CTL layer via ctl_queue_sense(). * * fe_dump(): This function, if it exists, is called by CTL * to request a dump of any debugging information or * state to the console. * * targ_port: The CTL layer assigns a "port number" to every * FETD. This port number should be passed back in * in the header of every ctl_io that is queued to * the CTL layer. This enables us to determine * which bus the command came in on. * * ctl_pool_ref: Memory pool reference used by the FETD in calls to * ctl_alloc_io(). * * max_initiators: Maximum number of initiators that the FETD is * allowed to have. Initiators should be numbered * from 0 to max_initiators - 1. This value will * typically be 16, and thus not a problem for * parallel SCSI. This may present issues for Fibre * Channel. * * wwnn World Wide Node Name to be used by the FETD. * Note that this is set *after* registration. It * will be set prior to the online function getting * called. * * wwpn World Wide Port Name to be used by the FETD. * Note that this is set *after* registration. It * will be set prior to the online function getting * called. * * status: Used by CTL to keep track of per-FETD state. * * links: Linked list pointers, used by CTL. The FETD * shouldn't touch this field. */ struct ctl_port { struct ctl_softc *ctl_softc; struct ctl_frontend *frontend; ctl_port_type port_type; /* passed to CTL */ int num_requested_ctl_io; /* passed to CTL */ char *port_name; /* passed to CTL */ int physical_port; /* passed to CTL */ int virtual_port; /* passed to CTL */ port_func_t port_online; /* passed to CTL */ port_func_t port_offline; /* passed to CTL */ port_info_func_t port_info; /* passed to CTL */ void *onoff_arg; /* passed to CTL */ lun_func_t lun_enable; /* passed to CTL */ lun_func_t lun_disable; /* passed to CTL */ int lun_map_size; /* passed to CTL */ uint32_t *lun_map; /* passed to CTL */ void *targ_lun_arg; /* passed to CTL */ void (*fe_datamove)(union ctl_io *io); /* passed to CTL */ void (*fe_done)(union ctl_io *io); /* passed to CTL */ int32_t targ_port; /* passed back to FETD */ void *ctl_pool_ref; /* passed back to FETD */ uint32_t max_initiators; /* passed back to FETD */ struct ctl_wwpn_iid *wwpn_iid; /* used by CTL */ uint64_t wwnn; /* set by CTL before online */ uint64_t wwpn; /* set by CTL before online */ ctl_port_status status; /* used by CTL */ nvlist_t *options; /* passed to CTL */ struct ctl_devid *port_devid; /* passed to CTL */ struct ctl_devid *target_devid; /* passed to CTL */ struct ctl_devid *init_devid; /* passed to CTL */ struct ctl_io_stats stats; /* used by CTL */ struct mtx port_lock; /* used by CTL */ STAILQ_ENTRY(ctl_port) fe_links; /* used by CTL */ STAILQ_ENTRY(ctl_port) links; /* used by CTL */ }; struct ctl_frontend { char name[CTL_DRIVER_NAME_LEN]; /* passed to CTL */ fe_init_t init; /* passed to CTL */ fe_ioctl_t ioctl; /* passed to CTL */ void (*fe_dump)(void); /* passed to CTL */ fe_shutdown_t shutdown; /* passed to CTL */ STAILQ_HEAD(, ctl_port) port_list; /* used by CTL */ STAILQ_ENTRY(ctl_frontend) links; /* used by CTL */ }; /* * This may block until resources are allocated. Called at FETD module load * time. Returns 0 for success, non-zero for failure. */ int ctl_frontend_register(struct ctl_frontend *fe); /* * Called at FETD module unload time. * Returns 0 for success, non-zero for failure. */ int ctl_frontend_deregister(struct ctl_frontend *fe); /* * Find the frontend by its name. Returns NULL if not found. */ struct ctl_frontend * ctl_frontend_find(char *frontend_name); /* * This may block until resources are allocated. Called at FETD module load * time. Returns 0 for success, non-zero for failure. */ int ctl_port_register(struct ctl_port *port); /* * Called at FETD module unload time. * Returns 0 for success, non-zero for failure. */ int ctl_port_deregister(struct ctl_port *port); /* * Called to set the WWNN and WWPN for a particular frontend. */ void ctl_port_set_wwns(struct ctl_port *port, int wwnn_valid, uint64_t wwnn, int wwpn_valid, uint64_t wwpn); /* * Called to bring a particular frontend online. */ void ctl_port_online(struct ctl_port *fe); /* * Called to take a particular frontend offline. */ void ctl_port_offline(struct ctl_port *fe); /* * This routine queues I/O and task management requests from the FETD to the * CTL layer. Returns immediately. Returns 0 for success, non-zero for * failure. */ int ctl_queue(union ctl_io *io); +/* + * This routine starts execution of I/O and task management requests from + * the FETD to the CTL layer. May sleep. Returns 0 for success, non-zero + * for failure. + */ +int ctl_run(union ctl_io *io); + /* * This routine is used if the front end interface doesn't support * autosense (e.g. non-packetized parallel SCSI). This will queue the * scsiio structure back to a per-lun pending sense queue. This MUST be * called BEFORE any request sense can get queued to the CTL layer -- I * need it in the queue in order to service the request. The scsiio * structure passed in here will be freed by the CTL layer when sense is * retrieved by the initiator. Returns 0 for success, non-zero for failure. */ int ctl_queue_sense(union ctl_io *io); /* * This routine adds an initiator to CTL's port database. * The iid field should be the same as the iid passed in the nexus of each * ctl_io from this initiator. * The WWPN should be the FC WWPN, if available. */ int ctl_add_initiator(struct ctl_port *port, int iid, uint64_t wwpn, char *name); /* * This routine will remove an initiator from CTL's port database. * The iid field should be the same as the iid passed in the nexus of each * ctl_io from this initiator. */ int ctl_remove_initiator(struct ctl_port *port, int iid); #endif /* _CTL_FRONTEND_H_ */ diff --git a/sys/cam/ctl/ctl_frontend_ioctl.c b/sys/cam/ctl/ctl_frontend_ioctl.c index 370e553042c5..ef5e2bd22a86 100644 --- a/sys/cam/ctl/ctl_frontend_ioctl.c +++ b/sys/cam/ctl/ctl_frontend_ioctl.c @@ -1,645 +1,645 @@ /*- * SPDX-License-Identifier: BSD-2-Clause-FreeBSD * * Copyright (c) 2003-2009 Silicon Graphics International Corp. * Copyright (c) 2012 The FreeBSD Foundation * Copyright (c) 2015 Alexander Motin * Copyright (c) 2017 Jakub Wojciech Klama * 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, * without modification, immediately at the beginning of the file. * 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 AUTHOR ``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 AUTHOR 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 #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include typedef enum { CTL_IOCTL_INPROG, CTL_IOCTL_DATAMOVE, CTL_IOCTL_DONE } ctl_fe_ioctl_state; struct ctl_fe_ioctl_params { struct cv sem; struct mtx ioctl_mtx; ctl_fe_ioctl_state state; }; struct cfi_port { TAILQ_ENTRY(cfi_port) link; uint32_t cur_tag_num; struct cdev * dev; struct ctl_port port; }; struct cfi_softc { TAILQ_HEAD(, cfi_port) ports; }; static struct cfi_softc cfi_softc; static int cfi_init(void); static int cfi_shutdown(void); static void cfi_datamove(union ctl_io *io); static void cfi_done(union ctl_io *io); static int cfi_ioctl(struct cdev *dev, u_long cmd, caddr_t addr, int flag, struct thread *td); static void cfi_ioctl_port_create(struct ctl_req *req); static void cfi_ioctl_port_remove(struct ctl_req *req); static struct cdevsw cfi_cdevsw = { .d_version = D_VERSION, .d_flags = 0, .d_ioctl = ctl_ioctl_io }; static struct ctl_frontend cfi_frontend = { .name = "ioctl", .init = cfi_init, .ioctl = cfi_ioctl, .shutdown = cfi_shutdown, }; CTL_FRONTEND_DECLARE(ctlioctl, cfi_frontend); static int cfi_init(void) { struct cfi_softc *isoftc = &cfi_softc; struct cfi_port *cfi; struct ctl_port *port; int error = 0; memset(isoftc, 0, sizeof(*isoftc)); TAILQ_INIT(&isoftc->ports); cfi = malloc(sizeof(*cfi), M_CTL, M_WAITOK | M_ZERO); port = &cfi->port; port->frontend = &cfi_frontend; port->port_type = CTL_PORT_IOCTL; port->num_requested_ctl_io = 100; port->port_name = "ioctl"; port->fe_datamove = cfi_datamove; port->fe_done = cfi_done; port->physical_port = 0; port->targ_port = -1; if ((error = ctl_port_register(port)) != 0) { printf("%s: ioctl port registration failed\n", __func__); return (error); } ctl_port_online(port); TAILQ_INSERT_TAIL(&isoftc->ports, cfi, link); return (0); } static int cfi_shutdown(void) { struct cfi_softc *isoftc = &cfi_softc; struct cfi_port *cfi, *temp; struct ctl_port *port; int error; TAILQ_FOREACH_SAFE(cfi, &isoftc->ports, link, temp) { port = &cfi->port; ctl_port_offline(port); error = ctl_port_deregister(port); if (error != 0) { printf("%s: ctl_frontend_deregister() failed\n", __func__); return (error); } TAILQ_REMOVE(&isoftc->ports, cfi, link); free(cfi, M_CTL); } return (0); } static void cfi_ioctl_port_create(struct ctl_req *req) { struct cfi_softc *isoftc = &cfi_softc; struct cfi_port *cfi; struct ctl_port *port; struct make_dev_args args; const char *val; int retval; int pp = -1, vp = 0; val = dnvlist_get_string(req->args_nvl, "pp", NULL); if (val != NULL) pp = strtol(val, NULL, 10); val = dnvlist_get_string(req->args_nvl, "vp", NULL); if (val != NULL) vp = strtol(val, NULL, 10); if (pp != -1) { /* Check for duplicates */ TAILQ_FOREACH(cfi, &isoftc->ports, link) { if (pp == cfi->port.physical_port && vp == cfi->port.virtual_port) { req->status = CTL_LUN_ERROR; snprintf(req->error_str, sizeof(req->error_str), "port %d already exists", pp); return; } } } else { /* Find free port number */ TAILQ_FOREACH(cfi, &isoftc->ports, link) { pp = MAX(pp, cfi->port.physical_port); } pp++; } cfi = malloc(sizeof(*cfi), M_CTL, M_WAITOK | M_ZERO); port = &cfi->port; port->frontend = &cfi_frontend; port->port_type = CTL_PORT_IOCTL; port->num_requested_ctl_io = 100; port->port_name = "ioctl"; port->fe_datamove = cfi_datamove; port->fe_done = cfi_done; port->physical_port = pp; port->virtual_port = vp; port->targ_port = -1; retval = ctl_port_register(port); if (retval != 0) { req->status = CTL_LUN_ERROR; snprintf(req->error_str, sizeof(req->error_str), "ctl_port_register() failed with error %d", retval); free(cfi, M_CTL); return; } req->result_nvl = nvlist_create(0); nvlist_add_number(req->result_nvl, "port_id", port->targ_port); ctl_port_online(port); make_dev_args_init(&args); args.mda_devsw = &cfi_cdevsw; args.mda_uid = UID_ROOT; args.mda_gid = GID_OPERATOR; args.mda_mode = 0600; args.mda_si_drv1 = NULL; args.mda_si_drv2 = cfi; retval = make_dev_s(&args, &cfi->dev, "cam/ctl%d.%d", pp, vp); if (retval != 0) { req->status = CTL_LUN_ERROR; snprintf(req->error_str, sizeof(req->error_str), "make_dev_s() failed with error %d", retval); ctl_port_offline(port); ctl_port_deregister(port); free(cfi, M_CTL); return; } req->status = CTL_LUN_OK; TAILQ_INSERT_TAIL(&isoftc->ports, cfi, link); } static void cfi_ioctl_port_remove(struct ctl_req *req) { struct cfi_softc *isoftc = &cfi_softc; struct cfi_port *cfi = NULL; const char *val; int port_id = -1; val = dnvlist_get_string(req->args_nvl, "port_id", NULL); if (val != NULL) port_id = strtol(val, NULL, 10); if (port_id == -1) { req->status = CTL_LUN_ERROR; snprintf(req->error_str, sizeof(req->error_str), "port_id not provided"); return; } TAILQ_FOREACH(cfi, &isoftc->ports, link) { if (cfi->port.targ_port == port_id) break; } if (cfi == NULL) { req->status = CTL_LUN_ERROR; snprintf(req->error_str, sizeof(req->error_str), "cannot find port %d", port_id); return; } if (cfi->port.physical_port == 0 && cfi->port.virtual_port == 0) { req->status = CTL_LUN_ERROR; snprintf(req->error_str, sizeof(req->error_str), "cannot destroy default ioctl port"); return; } ctl_port_offline(&cfi->port); ctl_port_deregister(&cfi->port); TAILQ_REMOVE(&isoftc->ports, cfi, link); destroy_dev(cfi->dev); free(cfi, M_CTL); req->status = CTL_LUN_OK; } static int cfi_ioctl(struct cdev *dev, u_long cmd, caddr_t addr, int flag, struct thread *td) { struct ctl_req *req; if (cmd == CTL_PORT_REQ) { req = (struct ctl_req *)addr; switch (req->reqtype) { case CTL_REQ_CREATE: cfi_ioctl_port_create(req); break; case CTL_REQ_REMOVE: cfi_ioctl_port_remove(req); break; default: req->status = CTL_LUN_ERROR; snprintf(req->error_str, sizeof(req->error_str), "Unsupported request type %d", req->reqtype); } return (0); } return (ENOTTY); } /* * Data movement routine for the CTL ioctl frontend port. */ static int ctl_ioctl_do_datamove(struct ctl_scsiio *ctsio) { struct ctl_sg_entry *ext_sglist, *kern_sglist; struct ctl_sg_entry ext_entry, kern_entry; int ext_sglen, ext_sg_entries, kern_sg_entries; int ext_sg_start, ext_offset; int len_to_copy; int kern_watermark, ext_watermark; int ext_sglist_malloced; int i, j; CTL_DEBUG_PRINT(("ctl_ioctl_do_datamove\n")); /* * If this flag is set, fake the data transfer. */ if (ctsio->io_hdr.flags & CTL_FLAG_NO_DATAMOVE) { ext_sglist_malloced = 0; ctsio->ext_data_filled += ctsio->kern_data_len; ctsio->kern_data_resid = 0; goto bailout; } /* * To simplify things here, if we have a single buffer, stick it in * a S/G entry and just make it a single entry S/G list. */ if (ctsio->ext_sg_entries > 0) { int len_seen; ext_sglen = ctsio->ext_sg_entries * sizeof(*ext_sglist); ext_sglist = (struct ctl_sg_entry *)malloc(ext_sglen, M_CTL, M_WAITOK); ext_sglist_malloced = 1; if (copyin(ctsio->ext_data_ptr, ext_sglist, ext_sglen) != 0) { ctsio->io_hdr.port_status = 31343; goto bailout; } ext_sg_entries = ctsio->ext_sg_entries; ext_sg_start = ext_sg_entries; ext_offset = 0; len_seen = 0; for (i = 0; i < ext_sg_entries; i++) { if ((len_seen + ext_sglist[i].len) >= ctsio->ext_data_filled) { ext_sg_start = i; ext_offset = ctsio->ext_data_filled - len_seen; break; } len_seen += ext_sglist[i].len; } } else { ext_sglist = &ext_entry; ext_sglist_malloced = 0; ext_sglist->addr = ctsio->ext_data_ptr; ext_sglist->len = ctsio->ext_data_len; ext_sg_entries = 1; ext_sg_start = 0; ext_offset = ctsio->ext_data_filled; } if (ctsio->kern_sg_entries > 0) { kern_sglist = (struct ctl_sg_entry *)ctsio->kern_data_ptr; kern_sg_entries = ctsio->kern_sg_entries; } else { kern_sglist = &kern_entry; kern_sglist->addr = ctsio->kern_data_ptr; kern_sglist->len = ctsio->kern_data_len; kern_sg_entries = 1; } kern_watermark = 0; ext_watermark = ext_offset; for (i = ext_sg_start, j = 0; i < ext_sg_entries && j < kern_sg_entries;) { uint8_t *ext_ptr, *kern_ptr; len_to_copy = MIN(ext_sglist[i].len - ext_watermark, kern_sglist[j].len - kern_watermark); ext_ptr = (uint8_t *)ext_sglist[i].addr; ext_ptr = ext_ptr + ext_watermark; if (ctsio->io_hdr.flags & CTL_FLAG_BUS_ADDR) { /* * XXX KDM fix this! */ panic("need to implement bus address support"); #if 0 kern_ptr = bus_to_virt(kern_sglist[j].addr); #endif } else kern_ptr = (uint8_t *)kern_sglist[j].addr; kern_ptr = kern_ptr + kern_watermark; if ((ctsio->io_hdr.flags & CTL_FLAG_DATA_MASK) == CTL_FLAG_DATA_IN) { CTL_DEBUG_PRINT(("ctl_ioctl_do_datamove: copying %d " "bytes to user\n", len_to_copy)); CTL_DEBUG_PRINT(("ctl_ioctl_do_datamove: from %p " "to %p\n", kern_ptr, ext_ptr)); if (copyout(kern_ptr, ext_ptr, len_to_copy) != 0) { ctsio->io_hdr.port_status = 31344; goto bailout; } } else { CTL_DEBUG_PRINT(("ctl_ioctl_do_datamove: copying %d " "bytes from user\n", len_to_copy)); CTL_DEBUG_PRINT(("ctl_ioctl_do_datamove: from %p " "to %p\n", ext_ptr, kern_ptr)); if (copyin(ext_ptr, kern_ptr, len_to_copy)!= 0){ ctsio->io_hdr.port_status = 31345; goto bailout; } } ctsio->ext_data_filled += len_to_copy; ctsio->kern_data_resid -= len_to_copy; ext_watermark += len_to_copy; if (ext_sglist[i].len == ext_watermark) { i++; ext_watermark = 0; } kern_watermark += len_to_copy; if (kern_sglist[j].len == kern_watermark) { j++; kern_watermark = 0; } } CTL_DEBUG_PRINT(("ctl_ioctl_do_datamove: ext_sg_entries: %d, " "kern_sg_entries: %d\n", ext_sg_entries, kern_sg_entries)); CTL_DEBUG_PRINT(("ctl_ioctl_do_datamove: ext_data_len = %d, " "kern_data_len = %d\n", ctsio->ext_data_len, ctsio->kern_data_len)); bailout: if (ext_sglist_malloced != 0) free(ext_sglist, M_CTL); return (CTL_RETVAL_COMPLETE); } static void cfi_datamove(union ctl_io *io) { struct ctl_fe_ioctl_params *params; params = (struct ctl_fe_ioctl_params *) io->io_hdr.ctl_private[CTL_PRIV_FRONTEND].ptr; mtx_lock(¶ms->ioctl_mtx); params->state = CTL_IOCTL_DATAMOVE; cv_broadcast(¶ms->sem); mtx_unlock(¶ms->ioctl_mtx); } static void cfi_done(union ctl_io *io) { struct ctl_fe_ioctl_params *params; params = (struct ctl_fe_ioctl_params *) io->io_hdr.ctl_private[CTL_PRIV_FRONTEND].ptr; mtx_lock(¶ms->ioctl_mtx); params->state = CTL_IOCTL_DONE; cv_broadcast(¶ms->sem); mtx_unlock(¶ms->ioctl_mtx); } static int cfi_submit_wait(union ctl_io *io) { struct ctl_fe_ioctl_params params; ctl_fe_ioctl_state last_state; int done, retval; bzero(¶ms, sizeof(params)); mtx_init(¶ms.ioctl_mtx, "ctliocmtx", NULL, MTX_DEF); cv_init(¶ms.sem, "ctlioccv"); params.state = CTL_IOCTL_INPROG; last_state = params.state; io->io_hdr.ctl_private[CTL_PRIV_FRONTEND].ptr = ¶ms; CTL_DEBUG_PRINT(("cfi_submit_wait\n")); /* This shouldn't happen */ - if ((retval = ctl_queue(io)) != CTL_RETVAL_COMPLETE) + if ((retval = ctl_run(io)) != CTL_RETVAL_COMPLETE) return (retval); done = 0; do { mtx_lock(¶ms.ioctl_mtx); /* * Check the state here, and don't sleep if the state has * already changed (i.e. wakeup has already occurred, but we * weren't waiting yet). */ if (params.state == last_state) { /* XXX KDM cv_wait_sig instead? */ cv_wait(¶ms.sem, ¶ms.ioctl_mtx); } last_state = params.state; switch (params.state) { case CTL_IOCTL_INPROG: /* Why did we wake up? */ /* XXX KDM error here? */ mtx_unlock(¶ms.ioctl_mtx); break; case CTL_IOCTL_DATAMOVE: CTL_DEBUG_PRINT(("got CTL_IOCTL_DATAMOVE\n")); /* * change last_state back to INPROG to avoid * deadlock on subsequent data moves. */ params.state = last_state = CTL_IOCTL_INPROG; mtx_unlock(¶ms.ioctl_mtx); ctl_ioctl_do_datamove(&io->scsiio); /* * Note that in some cases, most notably writes, * this will queue the I/O and call us back later. * In other cases, generally reads, this routine * will immediately call back and wake us up, * probably using our own context. */ io->scsiio.be_move_done(io); break; case CTL_IOCTL_DONE: mtx_unlock(¶ms.ioctl_mtx); CTL_DEBUG_PRINT(("got CTL_IOCTL_DONE\n")); done = 1; break; default: mtx_unlock(¶ms.ioctl_mtx); /* XXX KDM error here? */ break; } } while (done == 0); mtx_destroy(¶ms.ioctl_mtx); cv_destroy(¶ms.sem); return (CTL_RETVAL_COMPLETE); } int ctl_ioctl_io(struct cdev *dev, u_long cmd, caddr_t addr, int flag, struct thread *td) { struct cfi_port *cfi; union ctl_io *io; void *pool_tmp, *sc_tmp; int retval = 0; if (cmd != CTL_IO) return (ENOTTY); cfi = dev->si_drv2 == NULL ? TAILQ_FIRST(&cfi_softc.ports) : dev->si_drv2; /* * If we haven't been "enabled", don't allow any SCSI I/O * to this FETD. */ if ((cfi->port.status & CTL_PORT_STATUS_ONLINE) == 0) return (EPERM); io = ctl_alloc_io(cfi->port.ctl_pool_ref); /* * Need to save the pool reference so it doesn't get * spammed by the user's ctl_io. */ pool_tmp = io->io_hdr.pool; sc_tmp = CTL_SOFTC(io); memcpy(io, (void *)addr, sizeof(*io)); io->io_hdr.pool = pool_tmp; CTL_SOFTC(io) = sc_tmp; TAILQ_INIT(&io->io_hdr.blocked_queue); /* * No status yet, so make sure the status is set properly. */ io->io_hdr.status = CTL_STATUS_NONE; /* * The user sets the initiator ID, target and LUN IDs. */ io->io_hdr.nexus.targ_port = cfi->port.targ_port; io->io_hdr.flags |= CTL_FLAG_USER_REQ; if ((io->io_hdr.io_type == CTL_IO_SCSI) && (io->scsiio.tag_type != CTL_TAG_UNTAGGED)) io->scsiio.tag_num = cfi->cur_tag_num++; retval = cfi_submit_wait(io); if (retval == 0) memcpy((void *)addr, io, sizeof(*io)); ctl_free_io(io); return (retval); } diff --git a/sys/cam/ctl/ctl_frontend_iscsi.c b/sys/cam/ctl/ctl_frontend_iscsi.c index 8b0effcaf393..73483fb155cc 100644 --- a/sys/cam/ctl/ctl_frontend_iscsi.c +++ b/sys/cam/ctl/ctl_frontend_iscsi.c @@ -1,3044 +1,3044 @@ /*- * SPDX-License-Identifier: BSD-2-Clause-FreeBSD * * Copyright (c) 2012 The FreeBSD Foundation * * This software was developed by Edward Tomasz Napierala under sponsorship * from the FreeBSD Foundation. * * 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 AUTHOR 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 AUTHOR 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. * * $FreeBSD$ */ /* * CTL frontend for the iSCSI protocol. */ #include __FBSDID("$FreeBSD$"); #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 #include #include #include #include #include #include #include #ifdef ICL_KERNEL_PROXY #include #endif #ifdef ICL_KERNEL_PROXY FEATURE(cfiscsi_kernel_proxy, "iSCSI target built with ICL_KERNEL_PROXY"); #endif static MALLOC_DEFINE(M_CFISCSI, "cfiscsi", "Memory used for CTL iSCSI frontend"); static uma_zone_t cfiscsi_data_wait_zone; SYSCTL_NODE(_kern_cam_ctl, OID_AUTO, iscsi, CTLFLAG_RD | CTLFLAG_MPSAFE, 0, "CAM Target Layer iSCSI Frontend"); static int debug = 1; SYSCTL_INT(_kern_cam_ctl_iscsi, OID_AUTO, debug, CTLFLAG_RWTUN, &debug, 1, "Enable debug messages"); static int ping_timeout = 5; SYSCTL_INT(_kern_cam_ctl_iscsi, OID_AUTO, ping_timeout, CTLFLAG_RWTUN, &ping_timeout, 5, "Interval between ping (NOP-Out) requests, in seconds"); static int login_timeout = 60; SYSCTL_INT(_kern_cam_ctl_iscsi, OID_AUTO, login_timeout, CTLFLAG_RWTUN, &login_timeout, 60, "Time to wait for ctld(8) to finish Login Phase, in seconds"); static int maxtags = 256; SYSCTL_INT(_kern_cam_ctl_iscsi, OID_AUTO, maxtags, CTLFLAG_RWTUN, &maxtags, 0, "Max number of requests queued by initiator"); #define CFISCSI_DEBUG(X, ...) \ do { \ if (debug > 1) { \ printf("%s: " X "\n", \ __func__, ## __VA_ARGS__); \ } \ } while (0) #define CFISCSI_WARN(X, ...) \ do { \ if (debug > 0) { \ printf("WARNING: %s: " X "\n", \ __func__, ## __VA_ARGS__); \ } \ } while (0) #define CFISCSI_SESSION_DEBUG(S, X, ...) \ do { \ if (debug > 1) { \ printf("%s: %s (%s): " X "\n", \ __func__, S->cs_initiator_addr, \ S->cs_initiator_name, ## __VA_ARGS__); \ } \ } while (0) #define CFISCSI_SESSION_WARN(S, X, ...) \ do { \ if (debug > 0) { \ printf("WARNING: %s (%s): " X "\n", \ S->cs_initiator_addr, \ S->cs_initiator_name, ## __VA_ARGS__); \ } \ } while (0) #define CFISCSI_SESSION_LOCK(X) mtx_lock(&X->cs_lock) #define CFISCSI_SESSION_UNLOCK(X) mtx_unlock(&X->cs_lock) #define CFISCSI_SESSION_LOCK_ASSERT(X) mtx_assert(&X->cs_lock, MA_OWNED) #define CONN_SESSION(X) ((struct cfiscsi_session *)(X)->ic_prv0) #define PDU_SESSION(X) CONN_SESSION((X)->ip_conn) struct cfiscsi_priv { void *request; uint32_t expdatasn; uint32_t r2tsn; }; #define PRIV(io) \ ((struct cfiscsi_priv *)&(io)->io_hdr.ctl_private[CTL_PRIV_FRONTEND]) #define PRIV_REQUEST(io) PRIV(io)->request #define PRIV_EXPDATASN(io) PRIV(io)->expdatasn #define PRIV_R2TSN(io) PRIV(io)->r2tsn static int cfiscsi_init(void); static int cfiscsi_shutdown(void); static void cfiscsi_online(void *arg); static void cfiscsi_offline(void *arg); static int cfiscsi_info(void *arg, struct sbuf *sb); static int cfiscsi_ioctl(struct cdev *dev, u_long cmd, caddr_t addr, int flag, struct thread *td); static void cfiscsi_datamove(union ctl_io *io); static void cfiscsi_datamove_in(union ctl_io *io); static void cfiscsi_datamove_out(union ctl_io *io); static void cfiscsi_done(union ctl_io *io); static bool cfiscsi_pdu_update_cmdsn(const struct icl_pdu *request); static void cfiscsi_pdu_handle_nop_out(struct icl_pdu *request); static void cfiscsi_pdu_handle_scsi_command(struct icl_pdu *request); static void cfiscsi_pdu_handle_task_request(struct icl_pdu *request); static void cfiscsi_pdu_handle_data_out(struct icl_pdu *request); static void cfiscsi_pdu_handle_logout_request(struct icl_pdu *request); static void cfiscsi_session_terminate(struct cfiscsi_session *cs); static struct cfiscsi_data_wait *cfiscsi_data_wait_new( struct cfiscsi_session *cs, union ctl_io *io, uint32_t initiator_task_tag, uint32_t *target_transfer_tagp); static void cfiscsi_data_wait_free(struct cfiscsi_session *cs, struct cfiscsi_data_wait *cdw); static struct cfiscsi_target *cfiscsi_target_find(struct cfiscsi_softc *softc, const char *name, uint16_t tag); static struct cfiscsi_target *cfiscsi_target_find_or_create( struct cfiscsi_softc *softc, const char *name, const char *alias, uint16_t tag); static void cfiscsi_target_release(struct cfiscsi_target *ct); static void cfiscsi_session_delete(struct cfiscsi_session *cs); static struct cfiscsi_softc cfiscsi_softc; static struct ctl_frontend cfiscsi_frontend = { .name = "iscsi", .init = cfiscsi_init, .ioctl = cfiscsi_ioctl, .shutdown = cfiscsi_shutdown, }; CTL_FRONTEND_DECLARE(cfiscsi, cfiscsi_frontend); MODULE_DEPEND(cfiscsi, icl, 1, 1, 1); static struct icl_pdu * cfiscsi_pdu_new_response(struct icl_pdu *request, int flags) { return (icl_pdu_new(request->ip_conn, flags)); } static bool cfiscsi_pdu_update_cmdsn(const struct icl_pdu *request) { const struct iscsi_bhs_scsi_command *bhssc; struct cfiscsi_session *cs; uint32_t cmdsn, curcmdsn; cs = PDU_SESSION(request); /* * Every incoming PDU - not just NOP-Out - resets the ping timer. * The purpose of the timeout is to reset the connection when it stalls; * we don't want this to happen when NOP-In or NOP-Out ends up delayed * in some queue. */ cs->cs_timeout = 0; /* * Immediate commands carry cmdsn, but it is neither incremented nor * verified. */ if (request->ip_bhs->bhs_opcode & ISCSI_BHS_OPCODE_IMMEDIATE) return (false); /* * Data-Out PDUs don't contain CmdSN. */ if (request->ip_bhs->bhs_opcode == ISCSI_BHS_OPCODE_SCSI_DATA_OUT) return (false); /* * We're only using fields common for all the request * (initiator -> target) PDUs. */ bhssc = (const struct iscsi_bhs_scsi_command *)request->ip_bhs; curcmdsn = cmdsn = ntohl(bhssc->bhssc_cmdsn); /* * Increment session cmdsn and exit if we received the expected value. */ do { if (atomic_fcmpset_32(&cs->cs_cmdsn, &curcmdsn, cmdsn + 1)) return (false); } while (curcmdsn == cmdsn); /* * The target MUST silently ignore any non-immediate command outside * of this range. */ if (ISCSI_SNLT(cmdsn, curcmdsn) || ISCSI_SNGT(cmdsn, curcmdsn - 1 + maxtags)) { CFISCSI_SESSION_WARN(cs, "received PDU with CmdSN %u, " "while expected %u", cmdsn, curcmdsn); return (true); } /* * We don't support multiple connections now, so any discontinuity in * CmdSN means lost PDUs. Since we don't support PDU retransmission -- * terminate the connection. */ CFISCSI_SESSION_WARN(cs, "received PDU with CmdSN %u, " "while expected %u; dropping connection", cmdsn, curcmdsn); cfiscsi_session_terminate(cs); return (true); } static void cfiscsi_pdu_handle(struct icl_pdu *request) { struct cfiscsi_session *cs; bool ignore; cs = PDU_SESSION(request); ignore = cfiscsi_pdu_update_cmdsn(request); if (ignore) { icl_pdu_free(request); return; } /* * Handle the PDU; this includes e.g. receiving the remaining * part of PDU and submitting the SCSI command to CTL * or queueing a reply. The handling routine is responsible * for freeing the PDU when it's no longer needed. */ switch (request->ip_bhs->bhs_opcode & ~ISCSI_BHS_OPCODE_IMMEDIATE) { case ISCSI_BHS_OPCODE_NOP_OUT: cfiscsi_pdu_handle_nop_out(request); break; case ISCSI_BHS_OPCODE_SCSI_COMMAND: cfiscsi_pdu_handle_scsi_command(request); break; case ISCSI_BHS_OPCODE_TASK_REQUEST: cfiscsi_pdu_handle_task_request(request); break; case ISCSI_BHS_OPCODE_SCSI_DATA_OUT: cfiscsi_pdu_handle_data_out(request); break; case ISCSI_BHS_OPCODE_LOGOUT_REQUEST: cfiscsi_pdu_handle_logout_request(request); break; default: CFISCSI_SESSION_WARN(cs, "received PDU with unsupported " "opcode 0x%x; dropping connection", request->ip_bhs->bhs_opcode); icl_pdu_free(request); cfiscsi_session_terminate(cs); } } static void cfiscsi_receive_callback(struct icl_pdu *request) { #ifdef ICL_KERNEL_PROXY struct cfiscsi_session *cs; cs = PDU_SESSION(request); if (cs->cs_waiting_for_ctld || cs->cs_login_phase) { if (cs->cs_login_pdu == NULL) cs->cs_login_pdu = request; else icl_pdu_free(request); cv_signal(&cs->cs_login_cv); return; } #endif cfiscsi_pdu_handle(request); } static void cfiscsi_error_callback(struct icl_conn *ic) { struct cfiscsi_session *cs; cs = CONN_SESSION(ic); CFISCSI_SESSION_WARN(cs, "connection error; dropping connection"); cfiscsi_session_terminate(cs); } static int cfiscsi_pdu_prepare(struct icl_pdu *response) { struct cfiscsi_session *cs; struct iscsi_bhs_scsi_response *bhssr; bool advance_statsn = true; uint32_t cmdsn; cs = PDU_SESSION(response); CFISCSI_SESSION_LOCK_ASSERT(cs); /* * We're only using fields common for all the response * (target -> initiator) PDUs. */ bhssr = (struct iscsi_bhs_scsi_response *)response->ip_bhs; /* * 10.8.3: "The StatSN for this connection is not advanced * after this PDU is sent." */ if (bhssr->bhssr_opcode == ISCSI_BHS_OPCODE_R2T) advance_statsn = false; /* * 10.19.2: "However, when the Initiator Task Tag is set to 0xffffffff, * StatSN for the connection is not advanced after this PDU is sent." */ if (bhssr->bhssr_opcode == ISCSI_BHS_OPCODE_NOP_IN && bhssr->bhssr_initiator_task_tag == 0xffffffff) advance_statsn = false; /* * See the comment below - StatSN is not meaningful and must * not be advanced. */ if (bhssr->bhssr_opcode == ISCSI_BHS_OPCODE_SCSI_DATA_IN && (bhssr->bhssr_flags & BHSDI_FLAGS_S) == 0) advance_statsn = false; /* * 10.7.3: "The fields StatSN, Status, and Residual Count * only have meaningful content if the S bit is set to 1." */ if (bhssr->bhssr_opcode != ISCSI_BHS_OPCODE_SCSI_DATA_IN || (bhssr->bhssr_flags & BHSDI_FLAGS_S)) bhssr->bhssr_statsn = htonl(cs->cs_statsn); cmdsn = cs->cs_cmdsn; bhssr->bhssr_expcmdsn = htonl(cmdsn); bhssr->bhssr_maxcmdsn = htonl(cmdsn - 1 + imax(0, maxtags - cs->cs_outstanding_ctl_pdus)); if (advance_statsn) cs->cs_statsn++; return (0); } static void cfiscsi_pdu_queue(struct icl_pdu *response) { struct cfiscsi_session *cs; cs = PDU_SESSION(response); CFISCSI_SESSION_LOCK(cs); cfiscsi_pdu_prepare(response); icl_pdu_queue(response); CFISCSI_SESSION_UNLOCK(cs); } static void cfiscsi_pdu_queue_cb(struct icl_pdu *response, icl_pdu_cb cb) { struct cfiscsi_session *cs = PDU_SESSION(response); CFISCSI_SESSION_LOCK(cs); cfiscsi_pdu_prepare(response); icl_pdu_queue_cb(response, cb); CFISCSI_SESSION_UNLOCK(cs); } static void cfiscsi_pdu_handle_nop_out(struct icl_pdu *request) { struct cfiscsi_session *cs; struct iscsi_bhs_nop_out *bhsno; struct iscsi_bhs_nop_in *bhsni; struct icl_pdu *response; void *data = NULL; size_t datasize; int error; cs = PDU_SESSION(request); bhsno = (struct iscsi_bhs_nop_out *)request->ip_bhs; if (bhsno->bhsno_initiator_task_tag == 0xffffffff) { /* * Nothing to do, iscsi_pdu_update_statsn() already * zeroed the timeout. */ icl_pdu_free(request); return; } datasize = icl_pdu_data_segment_length(request); if (datasize > 0) { data = malloc(datasize, M_CFISCSI, M_NOWAIT | M_ZERO); if (data == NULL) { CFISCSI_SESSION_WARN(cs, "failed to allocate memory; " "dropping connection"); icl_pdu_free(request); cfiscsi_session_terminate(cs); return; } icl_pdu_get_data(request, 0, data, datasize); } response = cfiscsi_pdu_new_response(request, M_NOWAIT); if (response == NULL) { CFISCSI_SESSION_WARN(cs, "failed to allocate memory; " "droppping connection"); free(data, M_CFISCSI); icl_pdu_free(request); cfiscsi_session_terminate(cs); return; } bhsni = (struct iscsi_bhs_nop_in *)response->ip_bhs; bhsni->bhsni_opcode = ISCSI_BHS_OPCODE_NOP_IN; bhsni->bhsni_flags = 0x80; bhsni->bhsni_initiator_task_tag = bhsno->bhsno_initiator_task_tag; bhsni->bhsni_target_transfer_tag = 0xffffffff; if (datasize > 0) { error = icl_pdu_append_data(response, data, datasize, M_NOWAIT); if (error != 0) { CFISCSI_SESSION_WARN(cs, "failed to allocate memory; " "dropping connection"); free(data, M_CFISCSI); icl_pdu_free(request); icl_pdu_free(response); cfiscsi_session_terminate(cs); return; } free(data, M_CFISCSI); } icl_pdu_free(request); cfiscsi_pdu_queue(response); } static void cfiscsi_pdu_handle_scsi_command(struct icl_pdu *request) { struct iscsi_bhs_scsi_command *bhssc; struct cfiscsi_session *cs; union ctl_io *io; int error; cs = PDU_SESSION(request); bhssc = (struct iscsi_bhs_scsi_command *)request->ip_bhs; //CFISCSI_SESSION_DEBUG(cs, "initiator task tag 0x%x", // bhssc->bhssc_initiator_task_tag); if (request->ip_data_len > 0 && cs->cs_immediate_data == false) { CFISCSI_SESSION_WARN(cs, "unsolicited data with " "ImmediateData=No; dropping connection"); icl_pdu_free(request); cfiscsi_session_terminate(cs); return; } io = ctl_alloc_io(cs->cs_target->ct_port.ctl_pool_ref); ctl_zero_io(io); PRIV_REQUEST(io) = request; io->io_hdr.io_type = CTL_IO_SCSI; io->io_hdr.nexus.initid = cs->cs_ctl_initid; io->io_hdr.nexus.targ_port = cs->cs_target->ct_port.targ_port; io->io_hdr.nexus.targ_lun = ctl_decode_lun(be64toh(bhssc->bhssc_lun)); io->scsiio.priority = (bhssc->bhssc_pri & BHSSC_PRI_MASK) >> BHSSC_PRI_SHIFT; io->scsiio.tag_num = bhssc->bhssc_initiator_task_tag; switch ((bhssc->bhssc_flags & BHSSC_FLAGS_ATTR)) { case BHSSC_FLAGS_ATTR_UNTAGGED: io->scsiio.tag_type = CTL_TAG_UNTAGGED; break; case BHSSC_FLAGS_ATTR_SIMPLE: io->scsiio.tag_type = CTL_TAG_SIMPLE; break; case BHSSC_FLAGS_ATTR_ORDERED: io->scsiio.tag_type = CTL_TAG_ORDERED; break; case BHSSC_FLAGS_ATTR_HOQ: io->scsiio.tag_type = CTL_TAG_HEAD_OF_QUEUE; break; case BHSSC_FLAGS_ATTR_ACA: io->scsiio.tag_type = CTL_TAG_ACA; break; default: io->scsiio.tag_type = CTL_TAG_UNTAGGED; CFISCSI_SESSION_WARN(cs, "unhandled tag type %d", bhssc->bhssc_flags & BHSSC_FLAGS_ATTR); break; } io->scsiio.cdb_len = sizeof(bhssc->bhssc_cdb); /* Which is 16. */ memcpy(io->scsiio.cdb, bhssc->bhssc_cdb, sizeof(bhssc->bhssc_cdb)); refcount_acquire(&cs->cs_outstanding_ctl_pdus); - error = ctl_queue(io); + error = ctl_run(io); if (error != CTL_RETVAL_COMPLETE) { - CFISCSI_SESSION_WARN(cs, "ctl_queue() failed; error %d; " + CFISCSI_SESSION_WARN(cs, "ctl_run() failed; error %d; " "dropping connection", error); ctl_free_io(io); refcount_release(&cs->cs_outstanding_ctl_pdus); icl_pdu_free(request); cfiscsi_session_terminate(cs); } } static void cfiscsi_pdu_handle_task_request(struct icl_pdu *request) { struct iscsi_bhs_task_management_request *bhstmr; struct iscsi_bhs_task_management_response *bhstmr2; struct icl_pdu *response; struct cfiscsi_session *cs; union ctl_io *io; int error; cs = PDU_SESSION(request); bhstmr = (struct iscsi_bhs_task_management_request *)request->ip_bhs; io = ctl_alloc_io(cs->cs_target->ct_port.ctl_pool_ref); ctl_zero_io(io); PRIV_REQUEST(io) = request; io->io_hdr.io_type = CTL_IO_TASK; io->io_hdr.nexus.initid = cs->cs_ctl_initid; io->io_hdr.nexus.targ_port = cs->cs_target->ct_port.targ_port; io->io_hdr.nexus.targ_lun = ctl_decode_lun(be64toh(bhstmr->bhstmr_lun)); io->taskio.tag_type = CTL_TAG_SIMPLE; /* XXX */ switch (bhstmr->bhstmr_function & ~0x80) { case BHSTMR_FUNCTION_ABORT_TASK: #if 0 CFISCSI_SESSION_DEBUG(cs, "BHSTMR_FUNCTION_ABORT_TASK"); #endif io->taskio.task_action = CTL_TASK_ABORT_TASK; io->taskio.tag_num = bhstmr->bhstmr_referenced_task_tag; break; case BHSTMR_FUNCTION_ABORT_TASK_SET: #if 0 CFISCSI_SESSION_DEBUG(cs, "BHSTMR_FUNCTION_ABORT_TASK_SET"); #endif io->taskio.task_action = CTL_TASK_ABORT_TASK_SET; break; case BHSTMR_FUNCTION_CLEAR_TASK_SET: #if 0 CFISCSI_SESSION_DEBUG(cs, "BHSTMR_FUNCTION_CLEAR_TASK_SET"); #endif io->taskio.task_action = CTL_TASK_CLEAR_TASK_SET; break; case BHSTMR_FUNCTION_LOGICAL_UNIT_RESET: #if 0 CFISCSI_SESSION_DEBUG(cs, "BHSTMR_FUNCTION_LOGICAL_UNIT_RESET"); #endif io->taskio.task_action = CTL_TASK_LUN_RESET; break; case BHSTMR_FUNCTION_TARGET_WARM_RESET: #if 0 CFISCSI_SESSION_DEBUG(cs, "BHSTMR_FUNCTION_TARGET_WARM_RESET"); #endif io->taskio.task_action = CTL_TASK_TARGET_RESET; break; case BHSTMR_FUNCTION_TARGET_COLD_RESET: #if 0 CFISCSI_SESSION_DEBUG(cs, "BHSTMR_FUNCTION_TARGET_COLD_RESET"); #endif io->taskio.task_action = CTL_TASK_TARGET_RESET; break; case BHSTMR_FUNCTION_QUERY_TASK: #if 0 CFISCSI_SESSION_DEBUG(cs, "BHSTMR_FUNCTION_QUERY_TASK"); #endif io->taskio.task_action = CTL_TASK_QUERY_TASK; io->taskio.tag_num = bhstmr->bhstmr_referenced_task_tag; break; case BHSTMR_FUNCTION_QUERY_TASK_SET: #if 0 CFISCSI_SESSION_DEBUG(cs, "BHSTMR_FUNCTION_QUERY_TASK_SET"); #endif io->taskio.task_action = CTL_TASK_QUERY_TASK_SET; break; case BHSTMR_FUNCTION_I_T_NEXUS_RESET: #if 0 CFISCSI_SESSION_DEBUG(cs, "BHSTMR_FUNCTION_I_T_NEXUS_RESET"); #endif io->taskio.task_action = CTL_TASK_I_T_NEXUS_RESET; break; case BHSTMR_FUNCTION_QUERY_ASYNC_EVENT: #if 0 CFISCSI_SESSION_DEBUG(cs, "BHSTMR_FUNCTION_QUERY_ASYNC_EVENT"); #endif io->taskio.task_action = CTL_TASK_QUERY_ASYNC_EVENT; break; default: CFISCSI_SESSION_DEBUG(cs, "unsupported function 0x%x", bhstmr->bhstmr_function & ~0x80); ctl_free_io(io); response = cfiscsi_pdu_new_response(request, M_NOWAIT); if (response == NULL) { CFISCSI_SESSION_WARN(cs, "failed to allocate memory; " "dropping connection"); icl_pdu_free(request); cfiscsi_session_terminate(cs); return; } bhstmr2 = (struct iscsi_bhs_task_management_response *) response->ip_bhs; bhstmr2->bhstmr_opcode = ISCSI_BHS_OPCODE_TASK_RESPONSE; bhstmr2->bhstmr_flags = 0x80; bhstmr2->bhstmr_response = BHSTMR_RESPONSE_FUNCTION_NOT_SUPPORTED; bhstmr2->bhstmr_initiator_task_tag = bhstmr->bhstmr_initiator_task_tag; icl_pdu_free(request); cfiscsi_pdu_queue(response); return; } refcount_acquire(&cs->cs_outstanding_ctl_pdus); - error = ctl_queue(io); + error = ctl_run(io); if (error != CTL_RETVAL_COMPLETE) { - CFISCSI_SESSION_WARN(cs, "ctl_queue() failed; error %d; " + CFISCSI_SESSION_WARN(cs, "ctl_run() failed; error %d; " "dropping connection", error); ctl_free_io(io); refcount_release(&cs->cs_outstanding_ctl_pdus); icl_pdu_free(request); cfiscsi_session_terminate(cs); } } static bool cfiscsi_handle_data_segment(struct icl_pdu *request, struct cfiscsi_data_wait *cdw) { struct iscsi_bhs_data_out *bhsdo; struct cfiscsi_session *cs; struct ctl_sg_entry ctl_sg_entry, *ctl_sglist; size_t copy_len, len, off, buffer_offset; int ctl_sg_count; union ctl_io *io; cs = PDU_SESSION(request); KASSERT((request->ip_bhs->bhs_opcode & ~ISCSI_BHS_OPCODE_IMMEDIATE) == ISCSI_BHS_OPCODE_SCSI_DATA_OUT || (request->ip_bhs->bhs_opcode & ~ISCSI_BHS_OPCODE_IMMEDIATE) == ISCSI_BHS_OPCODE_SCSI_COMMAND, ("bad opcode 0x%x", request->ip_bhs->bhs_opcode)); /* * We're only using fields common for Data-Out and SCSI Command PDUs. */ bhsdo = (struct iscsi_bhs_data_out *)request->ip_bhs; io = cdw->cdw_ctl_io; KASSERT((io->io_hdr.flags & CTL_FLAG_DATA_MASK) != CTL_FLAG_DATA_IN, ("CTL_FLAG_DATA_IN")); #if 0 CFISCSI_SESSION_DEBUG(cs, "received %zd bytes out of %d", request->ip_data_len, io->scsiio.kern_total_len); #endif if (io->scsiio.kern_sg_entries > 0) { ctl_sglist = (struct ctl_sg_entry *)io->scsiio.kern_data_ptr; ctl_sg_count = io->scsiio.kern_sg_entries; } else { ctl_sglist = &ctl_sg_entry; ctl_sglist->addr = io->scsiio.kern_data_ptr; ctl_sglist->len = io->scsiio.kern_data_len; ctl_sg_count = 1; } if ((request->ip_bhs->bhs_opcode & ~ISCSI_BHS_OPCODE_IMMEDIATE) == ISCSI_BHS_OPCODE_SCSI_DATA_OUT) buffer_offset = ntohl(bhsdo->bhsdo_buffer_offset); else buffer_offset = 0; len = icl_pdu_data_segment_length(request); /* * Make sure the offset, as sent by the initiator, matches the offset * we're supposed to be at in the scatter-gather list. */ if (buffer_offset > io->scsiio.kern_rel_offset + io->scsiio.ext_data_filled || buffer_offset + len <= io->scsiio.kern_rel_offset + io->scsiio.ext_data_filled) { CFISCSI_SESSION_WARN(cs, "received bad buffer offset %zd, " "expected %zd; dropping connection", buffer_offset, (size_t)io->scsiio.kern_rel_offset + (size_t)io->scsiio.ext_data_filled); ctl_set_data_phase_error(&io->scsiio); cfiscsi_session_terminate(cs); return (true); } /* * This is the offset within the PDU data segment, as opposed * to buffer_offset, which is the offset within the task (SCSI * command). */ off = io->scsiio.kern_rel_offset + io->scsiio.ext_data_filled - buffer_offset; /* * Iterate over the scatter/gather segments, filling them with data * from the PDU data segment. Note that this can get called multiple * times for one SCSI command; the cdw structure holds state for the * scatter/gather list. */ for (;;) { KASSERT(cdw->cdw_sg_index < ctl_sg_count, ("cdw->cdw_sg_index >= ctl_sg_count")); if (cdw->cdw_sg_len == 0) { cdw->cdw_sg_addr = ctl_sglist[cdw->cdw_sg_index].addr; cdw->cdw_sg_len = ctl_sglist[cdw->cdw_sg_index].len; } KASSERT(off <= len, ("len > off")); copy_len = len - off; if (copy_len > cdw->cdw_sg_len) copy_len = cdw->cdw_sg_len; icl_pdu_get_data(request, off, cdw->cdw_sg_addr, copy_len); cdw->cdw_sg_addr += copy_len; cdw->cdw_sg_len -= copy_len; off += copy_len; io->scsiio.ext_data_filled += copy_len; io->scsiio.kern_data_resid -= copy_len; if (cdw->cdw_sg_len == 0) { /* * End of current segment. */ if (cdw->cdw_sg_index == ctl_sg_count - 1) { /* * Last segment in scatter/gather list. */ break; } cdw->cdw_sg_index++; } if (off == len) { /* * End of PDU payload. */ break; } } if (len > off) { /* * In case of unsolicited data, it's possible that the buffer * provided by CTL is smaller than negotiated FirstBurstLength. * Just ignore the superfluous data; will ask for them with R2T * on next call to cfiscsi_datamove(). * * This obviously can only happen with SCSI Command PDU. */ if ((request->ip_bhs->bhs_opcode & ~ISCSI_BHS_OPCODE_IMMEDIATE) == ISCSI_BHS_OPCODE_SCSI_COMMAND) return (true); CFISCSI_SESSION_WARN(cs, "received too much data: got %zd bytes, " "expected %zd; dropping connection", icl_pdu_data_segment_length(request), off); ctl_set_data_phase_error(&io->scsiio); cfiscsi_session_terminate(cs); return (true); } if (io->scsiio.ext_data_filled == cdw->cdw_r2t_end && (bhsdo->bhsdo_flags & BHSDO_FLAGS_F) == 0) { CFISCSI_SESSION_WARN(cs, "got the final packet without " "the F flag; flags = 0x%x; dropping connection", bhsdo->bhsdo_flags); ctl_set_data_phase_error(&io->scsiio); cfiscsi_session_terminate(cs); return (true); } if (io->scsiio.ext_data_filled != cdw->cdw_r2t_end && (bhsdo->bhsdo_flags & BHSDO_FLAGS_F) != 0) { if ((request->ip_bhs->bhs_opcode & ~ISCSI_BHS_OPCODE_IMMEDIATE) == ISCSI_BHS_OPCODE_SCSI_DATA_OUT) { CFISCSI_SESSION_WARN(cs, "got the final packet, but the " "transmitted size was %zd bytes instead of %d; " "dropping connection", (size_t)io->scsiio.ext_data_filled, cdw->cdw_r2t_end); ctl_set_data_phase_error(&io->scsiio); cfiscsi_session_terminate(cs); return (true); } else { /* * For SCSI Command PDU, this just means we need to * solicit more data by sending R2T. */ return (false); } } if (io->scsiio.ext_data_filled == cdw->cdw_r2t_end) { #if 0 CFISCSI_SESSION_DEBUG(cs, "no longer expecting Data-Out with target " "transfer tag 0x%x", cdw->cdw_target_transfer_tag); #endif return (true); } return (false); } static void cfiscsi_pdu_handle_data_out(struct icl_pdu *request) { struct iscsi_bhs_data_out *bhsdo; struct cfiscsi_session *cs; struct cfiscsi_data_wait *cdw = NULL; union ctl_io *io; bool done; cs = PDU_SESSION(request); bhsdo = (struct iscsi_bhs_data_out *)request->ip_bhs; CFISCSI_SESSION_LOCK(cs); TAILQ_FOREACH(cdw, &cs->cs_waiting_for_data_out, cdw_next) { #if 0 CFISCSI_SESSION_DEBUG(cs, "have ttt 0x%x, itt 0x%x; looking for " "ttt 0x%x, itt 0x%x", bhsdo->bhsdo_target_transfer_tag, bhsdo->bhsdo_initiator_task_tag, cdw->cdw_target_transfer_tag, cdw->cdw_initiator_task_tag)); #endif if (bhsdo->bhsdo_target_transfer_tag == cdw->cdw_target_transfer_tag) break; } CFISCSI_SESSION_UNLOCK(cs); if (cdw == NULL) { CFISCSI_SESSION_WARN(cs, "data transfer tag 0x%x, initiator task tag " "0x%x, not found; dropping connection", bhsdo->bhsdo_target_transfer_tag, bhsdo->bhsdo_initiator_task_tag); icl_pdu_free(request); cfiscsi_session_terminate(cs); return; } if (cdw->cdw_datasn != ntohl(bhsdo->bhsdo_datasn)) { CFISCSI_SESSION_WARN(cs, "received Data-Out PDU with " "DataSN %u, while expected %u; dropping connection", ntohl(bhsdo->bhsdo_datasn), cdw->cdw_datasn); icl_pdu_free(request); cfiscsi_session_terminate(cs); return; } cdw->cdw_datasn++; io = cdw->cdw_ctl_io; KASSERT((io->io_hdr.flags & CTL_FLAG_DATA_MASK) != CTL_FLAG_DATA_IN, ("CTL_FLAG_DATA_IN")); done = cfiscsi_handle_data_segment(request, cdw); if (done) { CFISCSI_SESSION_LOCK(cs); TAILQ_REMOVE(&cs->cs_waiting_for_data_out, cdw, cdw_next); CFISCSI_SESSION_UNLOCK(cs); done = (io->scsiio.ext_data_filled != cdw->cdw_r2t_end || io->scsiio.ext_data_filled == io->scsiio.kern_data_len); cfiscsi_data_wait_free(cs, cdw); io->io_hdr.flags &= ~CTL_FLAG_DMA_INPROG; if (done) io->scsiio.be_move_done(io); else cfiscsi_datamove_out(io); } icl_pdu_free(request); } static void cfiscsi_pdu_handle_logout_request(struct icl_pdu *request) { struct iscsi_bhs_logout_request *bhslr; struct iscsi_bhs_logout_response *bhslr2; struct icl_pdu *response; struct cfiscsi_session *cs; cs = PDU_SESSION(request); bhslr = (struct iscsi_bhs_logout_request *)request->ip_bhs; switch (bhslr->bhslr_reason & 0x7f) { case BHSLR_REASON_CLOSE_SESSION: case BHSLR_REASON_CLOSE_CONNECTION: response = cfiscsi_pdu_new_response(request, M_NOWAIT); if (response == NULL) { CFISCSI_SESSION_DEBUG(cs, "failed to allocate memory"); icl_pdu_free(request); cfiscsi_session_terminate(cs); return; } bhslr2 = (struct iscsi_bhs_logout_response *)response->ip_bhs; bhslr2->bhslr_opcode = ISCSI_BHS_OPCODE_LOGOUT_RESPONSE; bhslr2->bhslr_flags = 0x80; bhslr2->bhslr_response = BHSLR_RESPONSE_CLOSED_SUCCESSFULLY; bhslr2->bhslr_initiator_task_tag = bhslr->bhslr_initiator_task_tag; icl_pdu_free(request); cfiscsi_pdu_queue(response); cfiscsi_session_terminate(cs); break; case BHSLR_REASON_REMOVE_FOR_RECOVERY: response = cfiscsi_pdu_new_response(request, M_NOWAIT); if (response == NULL) { CFISCSI_SESSION_WARN(cs, "failed to allocate memory; dropping connection"); icl_pdu_free(request); cfiscsi_session_terminate(cs); return; } bhslr2 = (struct iscsi_bhs_logout_response *)response->ip_bhs; bhslr2->bhslr_opcode = ISCSI_BHS_OPCODE_LOGOUT_RESPONSE; bhslr2->bhslr_flags = 0x80; bhslr2->bhslr_response = BHSLR_RESPONSE_RECOVERY_NOT_SUPPORTED; bhslr2->bhslr_initiator_task_tag = bhslr->bhslr_initiator_task_tag; icl_pdu_free(request); cfiscsi_pdu_queue(response); break; default: CFISCSI_SESSION_WARN(cs, "invalid reason 0%x; dropping connection", bhslr->bhslr_reason); icl_pdu_free(request); cfiscsi_session_terminate(cs); break; } } static void cfiscsi_callout(void *context) { struct icl_pdu *cp; struct iscsi_bhs_nop_in *bhsni; struct cfiscsi_session *cs; cs = context; if (cs->cs_terminating) return; callout_schedule(&cs->cs_callout, 1 * hz); atomic_add_int(&cs->cs_timeout, 1); #ifdef ICL_KERNEL_PROXY if (cs->cs_waiting_for_ctld || cs->cs_login_phase) { if (login_timeout > 0 && cs->cs_timeout > login_timeout) { CFISCSI_SESSION_WARN(cs, "login timed out after " "%d seconds; dropping connection", cs->cs_timeout); cfiscsi_session_terminate(cs); } return; } #endif if (ping_timeout <= 0) { /* * Pings are disabled. Don't send NOP-In in this case; * user might have disabled pings to work around problems * with certain initiators that can't properly handle * NOP-In, such as iPXE. Reset the timeout, to avoid * triggering reconnection, should the user decide to * reenable them. */ cs->cs_timeout = 0; return; } if (cs->cs_timeout >= ping_timeout) { CFISCSI_SESSION_WARN(cs, "no ping reply (NOP-Out) after %d seconds; " "dropping connection", ping_timeout); cfiscsi_session_terminate(cs); return; } /* * If the ping was reset less than one second ago - which means * that we've received some PDU during the last second - assume * the traffic flows correctly and don't bother sending a NOP-Out. * * (It's 2 - one for one second, and one for incrementing is_timeout * earlier in this routine.) */ if (cs->cs_timeout < 2) return; cp = icl_pdu_new(cs->cs_conn, M_NOWAIT); if (cp == NULL) { CFISCSI_SESSION_WARN(cs, "failed to allocate memory"); return; } bhsni = (struct iscsi_bhs_nop_in *)cp->ip_bhs; bhsni->bhsni_opcode = ISCSI_BHS_OPCODE_NOP_IN; bhsni->bhsni_flags = 0x80; bhsni->bhsni_initiator_task_tag = 0xffffffff; cfiscsi_pdu_queue(cp); } static struct cfiscsi_data_wait * cfiscsi_data_wait_new(struct cfiscsi_session *cs, union ctl_io *io, uint32_t initiator_task_tag, uint32_t *target_transfer_tagp) { struct cfiscsi_data_wait *cdw; int error; cdw = uma_zalloc(cfiscsi_data_wait_zone, M_NOWAIT | M_ZERO); if (cdw == NULL) { CFISCSI_SESSION_WARN(cs, "failed to allocate %zd bytes", sizeof(*cdw)); return (NULL); } error = icl_conn_transfer_setup(cs->cs_conn, io, target_transfer_tagp, &cdw->cdw_icl_prv); if (error != 0) { CFISCSI_SESSION_WARN(cs, "icl_conn_transfer_setup() failed with error %d", error); uma_zfree(cfiscsi_data_wait_zone, cdw); return (NULL); } cdw->cdw_ctl_io = io; cdw->cdw_target_transfer_tag = *target_transfer_tagp; cdw->cdw_initiator_task_tag = initiator_task_tag; return (cdw); } static void cfiscsi_data_wait_free(struct cfiscsi_session *cs, struct cfiscsi_data_wait *cdw) { icl_conn_transfer_done(cs->cs_conn, cdw->cdw_icl_prv); uma_zfree(cfiscsi_data_wait_zone, cdw); } static void cfiscsi_session_terminate_tasks(struct cfiscsi_session *cs) { struct cfiscsi_data_wait *cdw; union ctl_io *io; int error, last, wait; if (cs->cs_target == NULL) return; /* No target yet, so nothing to do. */ io = ctl_alloc_io(cs->cs_target->ct_port.ctl_pool_ref); ctl_zero_io(io); PRIV_REQUEST(io) = cs; io->io_hdr.io_type = CTL_IO_TASK; io->io_hdr.nexus.initid = cs->cs_ctl_initid; io->io_hdr.nexus.targ_port = cs->cs_target->ct_port.targ_port; io->io_hdr.nexus.targ_lun = 0; io->taskio.tag_type = CTL_TAG_SIMPLE; /* XXX */ io->taskio.task_action = CTL_TASK_I_T_NEXUS_RESET; wait = cs->cs_outstanding_ctl_pdus; refcount_acquire(&cs->cs_outstanding_ctl_pdus); - error = ctl_queue(io); + error = ctl_run(io); if (error != CTL_RETVAL_COMPLETE) { - CFISCSI_SESSION_WARN(cs, "ctl_queue() failed; error %d", error); + CFISCSI_SESSION_WARN(cs, "ctl_run() failed; error %d", error); refcount_release(&cs->cs_outstanding_ctl_pdus); ctl_free_io(io); } CFISCSI_SESSION_LOCK(cs); while ((cdw = TAILQ_FIRST(&cs->cs_waiting_for_data_out)) != NULL) { TAILQ_REMOVE(&cs->cs_waiting_for_data_out, cdw, cdw_next); CFISCSI_SESSION_UNLOCK(cs); /* * Set nonzero port status; this prevents backends from * assuming that the data transfer actually succeeded * and writing uninitialized data to disk. */ cdw->cdw_ctl_io->io_hdr.flags &= ~CTL_FLAG_DMA_INPROG; cdw->cdw_ctl_io->scsiio.io_hdr.port_status = 42; cdw->cdw_ctl_io->scsiio.be_move_done(cdw->cdw_ctl_io); cfiscsi_data_wait_free(cs, cdw); CFISCSI_SESSION_LOCK(cs); } CFISCSI_SESSION_UNLOCK(cs); /* * Wait for CTL to terminate all the tasks. */ if (wait > 0) CFISCSI_SESSION_WARN(cs, "waiting for CTL to terminate %d tasks", wait); for (;;) { refcount_acquire(&cs->cs_outstanding_ctl_pdus); last = refcount_release(&cs->cs_outstanding_ctl_pdus); if (last != 0) break; tsleep(__DEVOLATILE(void *, &cs->cs_outstanding_ctl_pdus), 0, "cfiscsi_terminate", hz / 100); } if (wait > 0) CFISCSI_SESSION_WARN(cs, "tasks terminated"); } static void cfiscsi_maintenance_thread(void *arg) { struct cfiscsi_session *cs; cs = arg; for (;;) { CFISCSI_SESSION_LOCK(cs); if (cs->cs_terminating == false || cs->cs_handoff_in_progress) cv_wait(&cs->cs_maintenance_cv, &cs->cs_lock); CFISCSI_SESSION_UNLOCK(cs); if (cs->cs_terminating && cs->cs_handoff_in_progress == false) { /* * We used to wait up to 30 seconds to deliver queued * PDUs to the initiator. We also tried hard to deliver * SCSI Responses for the aborted PDUs. We don't do * that anymore. We might need to revisit that. */ callout_drain(&cs->cs_callout); icl_conn_close(cs->cs_conn); /* * At this point ICL receive thread is no longer * running; no new tasks can be queued. */ cfiscsi_session_terminate_tasks(cs); cfiscsi_session_delete(cs); kthread_exit(); return; } CFISCSI_SESSION_DEBUG(cs, "nothing to do"); } } static void cfiscsi_session_terminate(struct cfiscsi_session *cs) { cs->cs_terminating = true; cv_signal(&cs->cs_maintenance_cv); #ifdef ICL_KERNEL_PROXY cv_signal(&cs->cs_login_cv); #endif } static int cfiscsi_session_register_initiator(struct cfiscsi_session *cs) { struct cfiscsi_target *ct; char *name; int i; KASSERT(cs->cs_ctl_initid == -1, ("already registered")); ct = cs->cs_target; name = strdup(cs->cs_initiator_id, M_CTL); i = ctl_add_initiator(&ct->ct_port, -1, 0, name); if (i < 0) { CFISCSI_SESSION_WARN(cs, "ctl_add_initiator failed with error %d", i); cs->cs_ctl_initid = -1; return (1); } cs->cs_ctl_initid = i; #if 0 CFISCSI_SESSION_DEBUG(cs, "added initiator id %d", i); #endif return (0); } static void cfiscsi_session_unregister_initiator(struct cfiscsi_session *cs) { int error; if (cs->cs_ctl_initid == -1) return; error = ctl_remove_initiator(&cs->cs_target->ct_port, cs->cs_ctl_initid); if (error != 0) { CFISCSI_SESSION_WARN(cs, "ctl_remove_initiator failed with error %d", error); } cs->cs_ctl_initid = -1; } static struct cfiscsi_session * cfiscsi_session_new(struct cfiscsi_softc *softc, const char *offload) { struct cfiscsi_session *cs; int error; cs = malloc(sizeof(*cs), M_CFISCSI, M_NOWAIT | M_ZERO); if (cs == NULL) { CFISCSI_WARN("malloc failed"); return (NULL); } cs->cs_ctl_initid = -1; refcount_init(&cs->cs_outstanding_ctl_pdus, 0); TAILQ_INIT(&cs->cs_waiting_for_data_out); mtx_init(&cs->cs_lock, "cfiscsi_lock", NULL, MTX_DEF); cv_init(&cs->cs_maintenance_cv, "cfiscsi_mt"); #ifdef ICL_KERNEL_PROXY cv_init(&cs->cs_login_cv, "cfiscsi_login"); #endif /* * The purpose of this is to avoid racing with session shutdown. * Otherwise we could have the maintenance thread call icl_conn_close() * before we call icl_conn_handoff(). */ cs->cs_handoff_in_progress = true; cs->cs_conn = icl_new_conn(offload, false, "cfiscsi", &cs->cs_lock); if (cs->cs_conn == NULL) { free(cs, M_CFISCSI); return (NULL); } cs->cs_conn->ic_receive = cfiscsi_receive_callback; cs->cs_conn->ic_error = cfiscsi_error_callback; cs->cs_conn->ic_prv0 = cs; error = kthread_add(cfiscsi_maintenance_thread, cs, NULL, NULL, 0, 0, "cfiscsimt"); if (error != 0) { CFISCSI_SESSION_WARN(cs, "kthread_add(9) failed with error %d", error); free(cs, M_CFISCSI); return (NULL); } mtx_lock(&softc->lock); cs->cs_id = ++softc->last_session_id; TAILQ_INSERT_TAIL(&softc->sessions, cs, cs_next); mtx_unlock(&softc->lock); /* * Start pinging the initiator. */ callout_init(&cs->cs_callout, 1); callout_reset(&cs->cs_callout, 1 * hz, cfiscsi_callout, cs); return (cs); } static void cfiscsi_session_delete(struct cfiscsi_session *cs) { struct cfiscsi_softc *softc; softc = &cfiscsi_softc; KASSERT(cs->cs_outstanding_ctl_pdus == 0, ("destroying session with outstanding CTL pdus")); KASSERT(TAILQ_EMPTY(&cs->cs_waiting_for_data_out), ("destroying session with non-empty queue")); mtx_lock(&softc->lock); TAILQ_REMOVE(&softc->sessions, cs, cs_next); mtx_unlock(&softc->lock); cfiscsi_session_unregister_initiator(cs); if (cs->cs_target != NULL) cfiscsi_target_release(cs->cs_target); icl_conn_close(cs->cs_conn); icl_conn_free(cs->cs_conn); free(cs, M_CFISCSI); cv_signal(&softc->sessions_cv); } static int cfiscsi_init(void) { struct cfiscsi_softc *softc; softc = &cfiscsi_softc; bzero(softc, sizeof(*softc)); mtx_init(&softc->lock, "cfiscsi", NULL, MTX_DEF); cv_init(&softc->sessions_cv, "cfiscsi_sessions"); #ifdef ICL_KERNEL_PROXY cv_init(&softc->accept_cv, "cfiscsi_accept"); #endif TAILQ_INIT(&softc->sessions); TAILQ_INIT(&softc->targets); cfiscsi_data_wait_zone = uma_zcreate("cfiscsi_data_wait", sizeof(struct cfiscsi_data_wait), NULL, NULL, NULL, NULL, UMA_ALIGN_PTR, 0); return (0); } static int cfiscsi_shutdown(void) { struct cfiscsi_softc *softc = &cfiscsi_softc; if (!TAILQ_EMPTY(&softc->sessions) || !TAILQ_EMPTY(&softc->targets)) return (EBUSY); uma_zdestroy(cfiscsi_data_wait_zone); #ifdef ICL_KERNEL_PROXY cv_destroy(&softc->accept_cv); #endif cv_destroy(&softc->sessions_cv); mtx_destroy(&softc->lock); return (0); } #ifdef ICL_KERNEL_PROXY static void cfiscsi_accept(struct socket *so, struct sockaddr *sa, int portal_id) { struct cfiscsi_session *cs; cs = cfiscsi_session_new(&cfiscsi_softc, NULL); if (cs == NULL) { CFISCSI_WARN("failed to create session"); return; } icl_conn_handoff_sock(cs->cs_conn, so); cs->cs_initiator_sa = sa; cs->cs_portal_id = portal_id; cs->cs_handoff_in_progress = false; cs->cs_waiting_for_ctld = true; cv_signal(&cfiscsi_softc.accept_cv); CFISCSI_SESSION_LOCK(cs); /* * Wake up the maintenance thread if we got scheduled for termination * somewhere between cfiscsi_session_new() and icl_conn_handoff_sock(). */ if (cs->cs_terminating) cfiscsi_session_terminate(cs); CFISCSI_SESSION_UNLOCK(cs); } #endif static void cfiscsi_online(void *arg) { struct cfiscsi_softc *softc; struct cfiscsi_target *ct; int online; ct = (struct cfiscsi_target *)arg; softc = ct->ct_softc; mtx_lock(&softc->lock); if (ct->ct_online) { mtx_unlock(&softc->lock); return; } ct->ct_online = 1; online = softc->online++; mtx_unlock(&softc->lock); if (online > 0) return; #ifdef ICL_KERNEL_PROXY if (softc->listener != NULL) icl_listen_free(softc->listener); softc->listener = icl_listen_new(cfiscsi_accept); #endif } static void cfiscsi_offline(void *arg) { struct cfiscsi_softc *softc; struct cfiscsi_target *ct; struct cfiscsi_session *cs; int error, online; ct = (struct cfiscsi_target *)arg; softc = ct->ct_softc; mtx_lock(&softc->lock); if (!ct->ct_online) { mtx_unlock(&softc->lock); return; } ct->ct_online = 0; online = --softc->online; do { TAILQ_FOREACH(cs, &softc->sessions, cs_next) { if (cs->cs_target == ct) cfiscsi_session_terminate(cs); } TAILQ_FOREACH(cs, &softc->sessions, cs_next) { if (cs->cs_target == ct) break; } if (cs != NULL) { error = cv_wait_sig(&softc->sessions_cv, &softc->lock); if (error != 0) { CFISCSI_SESSION_DEBUG(cs, "cv_wait failed with error %d\n", error); break; } } } while (cs != NULL && ct->ct_online == 0); mtx_unlock(&softc->lock); if (online > 0) return; #ifdef ICL_KERNEL_PROXY icl_listen_free(softc->listener); softc->listener = NULL; #endif } static int cfiscsi_info(void *arg, struct sbuf *sb) { struct cfiscsi_target *ct = (struct cfiscsi_target *)arg; int retval; retval = sbuf_printf(sb, "\t%d\n", ct->ct_state); return (retval); } static void cfiscsi_ioctl_handoff(struct ctl_iscsi *ci) { struct cfiscsi_softc *softc; struct cfiscsi_session *cs, *cs2; struct cfiscsi_target *ct; struct ctl_iscsi_handoff_params *cihp; int error; cihp = (struct ctl_iscsi_handoff_params *)&(ci->data); softc = &cfiscsi_softc; CFISCSI_DEBUG("new connection from %s (%s) to %s", cihp->initiator_name, cihp->initiator_addr, cihp->target_name); ct = cfiscsi_target_find(softc, cihp->target_name, cihp->portal_group_tag); if (ct == NULL) { ci->status = CTL_ISCSI_ERROR; snprintf(ci->error_str, sizeof(ci->error_str), "%s: target not found", __func__); return; } #ifdef ICL_KERNEL_PROXY if (cihp->socket > 0 && cihp->connection_id > 0) { snprintf(ci->error_str, sizeof(ci->error_str), "both socket and connection_id set"); ci->status = CTL_ISCSI_ERROR; cfiscsi_target_release(ct); return; } if (cihp->socket == 0) { mtx_lock(&cfiscsi_softc.lock); TAILQ_FOREACH(cs, &cfiscsi_softc.sessions, cs_next) { if (cs->cs_id == cihp->connection_id) break; } if (cs == NULL) { mtx_unlock(&cfiscsi_softc.lock); snprintf(ci->error_str, sizeof(ci->error_str), "connection not found"); ci->status = CTL_ISCSI_ERROR; cfiscsi_target_release(ct); return; } mtx_unlock(&cfiscsi_softc.lock); } else { #endif cs = cfiscsi_session_new(softc, cihp->offload); if (cs == NULL) { ci->status = CTL_ISCSI_ERROR; snprintf(ci->error_str, sizeof(ci->error_str), "%s: cfiscsi_session_new failed", __func__); cfiscsi_target_release(ct); return; } #ifdef ICL_KERNEL_PROXY } #endif /* * First PDU of Full Feature phase has the same CmdSN as the last * PDU from the Login Phase received from the initiator. Thus, * the -1 below. */ cs->cs_cmdsn = cihp->cmdsn; cs->cs_statsn = cihp->statsn; cs->cs_max_recv_data_segment_length = cihp->max_recv_data_segment_length; cs->cs_max_send_data_segment_length = cihp->max_send_data_segment_length; cs->cs_max_burst_length = cihp->max_burst_length; cs->cs_first_burst_length = cihp->first_burst_length; cs->cs_immediate_data = !!cihp->immediate_data; if (cihp->header_digest == CTL_ISCSI_DIGEST_CRC32C) cs->cs_conn->ic_header_crc32c = true; if (cihp->data_digest == CTL_ISCSI_DIGEST_CRC32C) cs->cs_conn->ic_data_crc32c = true; strlcpy(cs->cs_initiator_name, cihp->initiator_name, sizeof(cs->cs_initiator_name)); strlcpy(cs->cs_initiator_addr, cihp->initiator_addr, sizeof(cs->cs_initiator_addr)); strlcpy(cs->cs_initiator_alias, cihp->initiator_alias, sizeof(cs->cs_initiator_alias)); memcpy(cs->cs_initiator_isid, cihp->initiator_isid, sizeof(cs->cs_initiator_isid)); snprintf(cs->cs_initiator_id, sizeof(cs->cs_initiator_id), "%s,i,0x%02x%02x%02x%02x%02x%02x", cs->cs_initiator_name, cihp->initiator_isid[0], cihp->initiator_isid[1], cihp->initiator_isid[2], cihp->initiator_isid[3], cihp->initiator_isid[4], cihp->initiator_isid[5]); mtx_lock(&softc->lock); if (ct->ct_online == 0) { mtx_unlock(&softc->lock); CFISCSI_SESSION_LOCK(cs); cs->cs_handoff_in_progress = false; cfiscsi_session_terminate(cs); CFISCSI_SESSION_UNLOCK(cs); cfiscsi_target_release(ct); ci->status = CTL_ISCSI_ERROR; snprintf(ci->error_str, sizeof(ci->error_str), "%s: port offline", __func__); return; } cs->cs_target = ct; mtx_unlock(&softc->lock); restart: if (!cs->cs_terminating) { mtx_lock(&softc->lock); TAILQ_FOREACH(cs2, &softc->sessions, cs_next) { if (cs2 != cs && cs2->cs_tasks_aborted == false && cs->cs_target == cs2->cs_target && strcmp(cs->cs_initiator_id, cs2->cs_initiator_id) == 0) { if (strcmp(cs->cs_initiator_addr, cs2->cs_initiator_addr) != 0) { CFISCSI_SESSION_WARN(cs2, "session reinstatement from " "different address %s", cs->cs_initiator_addr); } else { CFISCSI_SESSION_DEBUG(cs2, "session reinstatement"); } cfiscsi_session_terminate(cs2); mtx_unlock(&softc->lock); pause("cfiscsi_reinstate", 1); goto restart; } } mtx_unlock(&softc->lock); } /* * Register initiator with CTL. */ cfiscsi_session_register_initiator(cs); #ifdef ICL_KERNEL_PROXY if (cihp->socket > 0) { #endif error = icl_conn_handoff(cs->cs_conn, cihp->socket); if (error != 0) { CFISCSI_SESSION_LOCK(cs); cs->cs_handoff_in_progress = false; cfiscsi_session_terminate(cs); CFISCSI_SESSION_UNLOCK(cs); ci->status = CTL_ISCSI_ERROR; snprintf(ci->error_str, sizeof(ci->error_str), "%s: icl_conn_handoff failed with error %d", __func__, error); return; } #ifdef ICL_KERNEL_PROXY } #endif #ifdef ICL_KERNEL_PROXY cs->cs_login_phase = false; /* * First PDU of the Full Feature phase has likely already arrived. * We have to pick it up and execute properly. */ if (cs->cs_login_pdu != NULL) { CFISCSI_SESSION_DEBUG(cs, "picking up first PDU"); cfiscsi_pdu_handle(cs->cs_login_pdu); cs->cs_login_pdu = NULL; } #endif CFISCSI_SESSION_LOCK(cs); cs->cs_handoff_in_progress = false; /* * Wake up the maintenance thread if we got scheduled for termination. */ if (cs->cs_terminating) cfiscsi_session_terminate(cs); CFISCSI_SESSION_UNLOCK(cs); ci->status = CTL_ISCSI_OK; } static void cfiscsi_ioctl_list(struct ctl_iscsi *ci) { struct ctl_iscsi_list_params *cilp; struct cfiscsi_session *cs; struct cfiscsi_softc *softc; struct sbuf *sb; int error; cilp = (struct ctl_iscsi_list_params *)&(ci->data); softc = &cfiscsi_softc; sb = sbuf_new(NULL, NULL, cilp->alloc_len, SBUF_FIXEDLEN); if (sb == NULL) { ci->status = CTL_ISCSI_ERROR; snprintf(ci->error_str, sizeof(ci->error_str), "Unable to allocate %d bytes for iSCSI session list", cilp->alloc_len); return; } sbuf_printf(sb, "\n"); mtx_lock(&softc->lock); TAILQ_FOREACH(cs, &softc->sessions, cs_next) { if (cs->cs_target == NULL) continue; error = sbuf_printf(sb, "" "%s" "%s" "%s" "%s" "%s" "%u" "%s" "%s" "%d" "%d" "%d" "%d" "%d" "%d" "%s" "\n", cs->cs_id, cs->cs_initiator_name, cs->cs_initiator_addr, cs->cs_initiator_alias, cs->cs_target->ct_name, cs->cs_target->ct_alias, cs->cs_target->ct_tag, cs->cs_conn->ic_header_crc32c ? "CRC32C" : "None", cs->cs_conn->ic_data_crc32c ? "CRC32C" : "None", cs->cs_max_recv_data_segment_length, cs->cs_max_send_data_segment_length, cs->cs_max_burst_length, cs->cs_first_burst_length, cs->cs_immediate_data, cs->cs_conn->ic_iser, cs->cs_conn->ic_offload); if (error != 0) break; } mtx_unlock(&softc->lock); error = sbuf_printf(sb, "\n"); if (error != 0) { sbuf_delete(sb); ci->status = CTL_ISCSI_LIST_NEED_MORE_SPACE; snprintf(ci->error_str, sizeof(ci->error_str), "Out of space, %d bytes is too small", cilp->alloc_len); return; } sbuf_finish(sb); error = copyout(sbuf_data(sb), cilp->conn_xml, sbuf_len(sb) + 1); if (error != 0) { sbuf_delete(sb); snprintf(ci->error_str, sizeof(ci->error_str), "copyout failed with error %d", error); ci->status = CTL_ISCSI_ERROR; return; } cilp->fill_len = sbuf_len(sb) + 1; ci->status = CTL_ISCSI_OK; sbuf_delete(sb); } static void cfiscsi_ioctl_logout(struct ctl_iscsi *ci) { struct icl_pdu *response; struct iscsi_bhs_asynchronous_message *bhsam; struct ctl_iscsi_logout_params *cilp; struct cfiscsi_session *cs; struct cfiscsi_softc *softc; int found = 0; cilp = (struct ctl_iscsi_logout_params *)&(ci->data); softc = &cfiscsi_softc; mtx_lock(&softc->lock); TAILQ_FOREACH(cs, &softc->sessions, cs_next) { if (cilp->all == 0 && cs->cs_id != cilp->connection_id && strcmp(cs->cs_initiator_name, cilp->initiator_name) != 0 && strcmp(cs->cs_initiator_addr, cilp->initiator_addr) != 0) continue; response = icl_pdu_new(cs->cs_conn, M_NOWAIT); if (response == NULL) { ci->status = CTL_ISCSI_ERROR; snprintf(ci->error_str, sizeof(ci->error_str), "Unable to allocate memory"); mtx_unlock(&softc->lock); return; } bhsam = (struct iscsi_bhs_asynchronous_message *)response->ip_bhs; bhsam->bhsam_opcode = ISCSI_BHS_OPCODE_ASYNC_MESSAGE; bhsam->bhsam_flags = 0x80; bhsam->bhsam_async_event = BHSAM_EVENT_TARGET_REQUESTS_LOGOUT; bhsam->bhsam_parameter3 = htons(10); cfiscsi_pdu_queue(response); found++; } mtx_unlock(&softc->lock); if (found == 0) { ci->status = CTL_ISCSI_SESSION_NOT_FOUND; snprintf(ci->error_str, sizeof(ci->error_str), "No matching connections found"); return; } ci->status = CTL_ISCSI_OK; } static void cfiscsi_ioctl_terminate(struct ctl_iscsi *ci) { struct icl_pdu *response; struct iscsi_bhs_asynchronous_message *bhsam; struct ctl_iscsi_terminate_params *citp; struct cfiscsi_session *cs; struct cfiscsi_softc *softc; int found = 0; citp = (struct ctl_iscsi_terminate_params *)&(ci->data); softc = &cfiscsi_softc; mtx_lock(&softc->lock); TAILQ_FOREACH(cs, &softc->sessions, cs_next) { if (citp->all == 0 && cs->cs_id != citp->connection_id && strcmp(cs->cs_initiator_name, citp->initiator_name) != 0 && strcmp(cs->cs_initiator_addr, citp->initiator_addr) != 0) continue; response = icl_pdu_new(cs->cs_conn, M_NOWAIT); if (response == NULL) { /* * Oh well. Just terminate the connection. */ } else { bhsam = (struct iscsi_bhs_asynchronous_message *) response->ip_bhs; bhsam->bhsam_opcode = ISCSI_BHS_OPCODE_ASYNC_MESSAGE; bhsam->bhsam_flags = 0x80; bhsam->bhsam_0xffffffff = 0xffffffff; bhsam->bhsam_async_event = BHSAM_EVENT_TARGET_TERMINATES_SESSION; cfiscsi_pdu_queue(response); } cfiscsi_session_terminate(cs); found++; } mtx_unlock(&softc->lock); if (found == 0) { ci->status = CTL_ISCSI_SESSION_NOT_FOUND; snprintf(ci->error_str, sizeof(ci->error_str), "No matching connections found"); return; } ci->status = CTL_ISCSI_OK; } static void cfiscsi_ioctl_limits(struct ctl_iscsi *ci) { struct ctl_iscsi_limits_params *cilp; struct icl_drv_limits idl; int error; cilp = (struct ctl_iscsi_limits_params *)&(ci->data); error = icl_limits(cilp->offload, false, &idl); if (error != 0) { ci->status = CTL_ISCSI_ERROR; snprintf(ci->error_str, sizeof(ci->error_str), "%s: icl_limits failed with error %d", __func__, error); return; } cilp->max_recv_data_segment_length = idl.idl_max_recv_data_segment_length; cilp->max_send_data_segment_length = idl.idl_max_send_data_segment_length; cilp->max_burst_length = idl.idl_max_burst_length; cilp->first_burst_length = idl.idl_first_burst_length; ci->status = CTL_ISCSI_OK; } #ifdef ICL_KERNEL_PROXY static void cfiscsi_ioctl_listen(struct ctl_iscsi *ci) { struct ctl_iscsi_listen_params *cilp; struct sockaddr *sa; int error; cilp = (struct ctl_iscsi_listen_params *)&(ci->data); if (cfiscsi_softc.listener == NULL) { CFISCSI_DEBUG("no listener"); snprintf(ci->error_str, sizeof(ci->error_str), "no listener"); ci->status = CTL_ISCSI_ERROR; return; } error = getsockaddr(&sa, (void *)cilp->addr, cilp->addrlen); if (error != 0) { CFISCSI_DEBUG("getsockaddr, error %d", error); snprintf(ci->error_str, sizeof(ci->error_str), "getsockaddr failed"); ci->status = CTL_ISCSI_ERROR; return; } error = icl_listen_add(cfiscsi_softc.listener, cilp->iser, cilp->domain, cilp->socktype, cilp->protocol, sa, cilp->portal_id); if (error != 0) { free(sa, M_SONAME); CFISCSI_DEBUG("icl_listen_add, error %d", error); snprintf(ci->error_str, sizeof(ci->error_str), "icl_listen_add failed, error %d", error); ci->status = CTL_ISCSI_ERROR; return; } ci->status = CTL_ISCSI_OK; } static void cfiscsi_ioctl_accept(struct ctl_iscsi *ci) { struct ctl_iscsi_accept_params *ciap; struct cfiscsi_session *cs; int error; ciap = (struct ctl_iscsi_accept_params *)&(ci->data); mtx_lock(&cfiscsi_softc.lock); for (;;) { TAILQ_FOREACH(cs, &cfiscsi_softc.sessions, cs_next) { if (cs->cs_waiting_for_ctld) break; } if (cs != NULL) break; error = cv_wait_sig(&cfiscsi_softc.accept_cv, &cfiscsi_softc.lock); if (error != 0) { mtx_unlock(&cfiscsi_softc.lock); snprintf(ci->error_str, sizeof(ci->error_str), "interrupted"); ci->status = CTL_ISCSI_ERROR; return; } } mtx_unlock(&cfiscsi_softc.lock); cs->cs_waiting_for_ctld = false; cs->cs_login_phase = true; ciap->connection_id = cs->cs_id; ciap->portal_id = cs->cs_portal_id; ciap->initiator_addrlen = cs->cs_initiator_sa->sa_len; error = copyout(cs->cs_initiator_sa, ciap->initiator_addr, cs->cs_initiator_sa->sa_len); if (error != 0) { snprintf(ci->error_str, sizeof(ci->error_str), "copyout failed with error %d", error); ci->status = CTL_ISCSI_ERROR; return; } ci->status = CTL_ISCSI_OK; } static void cfiscsi_ioctl_send(struct ctl_iscsi *ci) { struct ctl_iscsi_send_params *cisp; struct cfiscsi_session *cs; struct icl_pdu *ip; size_t datalen; void *data; int error; cisp = (struct ctl_iscsi_send_params *)&(ci->data); mtx_lock(&cfiscsi_softc.lock); TAILQ_FOREACH(cs, &cfiscsi_softc.sessions, cs_next) { if (cs->cs_id == cisp->connection_id) break; } if (cs == NULL) { mtx_unlock(&cfiscsi_softc.lock); snprintf(ci->error_str, sizeof(ci->error_str), "connection not found"); ci->status = CTL_ISCSI_ERROR; return; } mtx_unlock(&cfiscsi_softc.lock); #if 0 if (cs->cs_login_phase == false) return (EBUSY); #endif if (cs->cs_terminating) { snprintf(ci->error_str, sizeof(ci->error_str), "connection is terminating"); ci->status = CTL_ISCSI_ERROR; return; } datalen = cisp->data_segment_len; /* * XXX */ //if (datalen > CFISCSI_MAX_DATA_SEGMENT_LENGTH) { if (datalen > 65535) { snprintf(ci->error_str, sizeof(ci->error_str), "data segment too big"); ci->status = CTL_ISCSI_ERROR; return; } if (datalen > 0) { data = malloc(datalen, M_CFISCSI, M_WAITOK); error = copyin(cisp->data_segment, data, datalen); if (error != 0) { free(data, M_CFISCSI); snprintf(ci->error_str, sizeof(ci->error_str), "copyin error %d", error); ci->status = CTL_ISCSI_ERROR; return; } } ip = icl_pdu_new(cs->cs_conn, M_WAITOK); memcpy(ip->ip_bhs, cisp->bhs, sizeof(*ip->ip_bhs)); if (datalen > 0) { icl_pdu_append_data(ip, data, datalen, M_WAITOK); free(data, M_CFISCSI); } CFISCSI_SESSION_LOCK(cs); icl_pdu_queue(ip); CFISCSI_SESSION_UNLOCK(cs); ci->status = CTL_ISCSI_OK; } static void cfiscsi_ioctl_receive(struct ctl_iscsi *ci) { struct ctl_iscsi_receive_params *cirp; struct cfiscsi_session *cs; struct icl_pdu *ip; void *data; int error; cirp = (struct ctl_iscsi_receive_params *)&(ci->data); mtx_lock(&cfiscsi_softc.lock); TAILQ_FOREACH(cs, &cfiscsi_softc.sessions, cs_next) { if (cs->cs_id == cirp->connection_id) break; } if (cs == NULL) { mtx_unlock(&cfiscsi_softc.lock); snprintf(ci->error_str, sizeof(ci->error_str), "connection not found"); ci->status = CTL_ISCSI_ERROR; return; } mtx_unlock(&cfiscsi_softc.lock); #if 0 if (is->is_login_phase == false) return (EBUSY); #endif CFISCSI_SESSION_LOCK(cs); while (cs->cs_login_pdu == NULL && cs->cs_terminating == false) { error = cv_wait_sig(&cs->cs_login_cv, &cs->cs_lock); if (error != 0) { CFISCSI_SESSION_UNLOCK(cs); snprintf(ci->error_str, sizeof(ci->error_str), "interrupted by signal"); ci->status = CTL_ISCSI_ERROR; return; } } if (cs->cs_terminating) { CFISCSI_SESSION_UNLOCK(cs); snprintf(ci->error_str, sizeof(ci->error_str), "connection terminating"); ci->status = CTL_ISCSI_ERROR; return; } ip = cs->cs_login_pdu; cs->cs_login_pdu = NULL; CFISCSI_SESSION_UNLOCK(cs); if (ip->ip_data_len > cirp->data_segment_len) { icl_pdu_free(ip); snprintf(ci->error_str, sizeof(ci->error_str), "data segment too big"); ci->status = CTL_ISCSI_ERROR; return; } copyout(ip->ip_bhs, cirp->bhs, sizeof(*ip->ip_bhs)); if (ip->ip_data_len > 0) { data = malloc(ip->ip_data_len, M_CFISCSI, M_WAITOK); icl_pdu_get_data(ip, 0, data, ip->ip_data_len); copyout(data, cirp->data_segment, ip->ip_data_len); free(data, M_CFISCSI); } icl_pdu_free(ip); ci->status = CTL_ISCSI_OK; } #endif /* !ICL_KERNEL_PROXY */ static void cfiscsi_ioctl_port_create(struct ctl_req *req) { struct cfiscsi_target *ct; struct ctl_port *port; const char *target, *alias, *val; struct scsi_vpd_id_descriptor *desc; int retval, len, idlen; uint16_t tag; target = dnvlist_get_string(req->args_nvl, "cfiscsi_target", NULL); alias = dnvlist_get_string(req->args_nvl, "cfiscsi_target_alias", NULL); val = dnvlist_get_string(req->args_nvl, "cfiscsi_portal_group_tag", NULL); if (target == NULL || val == NULL) { req->status = CTL_LUN_ERROR; snprintf(req->error_str, sizeof(req->error_str), "Missing required argument"); return; } tag = strtoul(val, NULL, 0); ct = cfiscsi_target_find_or_create(&cfiscsi_softc, target, alias, tag); if (ct == NULL) { req->status = CTL_LUN_ERROR; snprintf(req->error_str, sizeof(req->error_str), "failed to create target \"%s\"", target); return; } if (ct->ct_state == CFISCSI_TARGET_STATE_ACTIVE) { req->status = CTL_LUN_ERROR; snprintf(req->error_str, sizeof(req->error_str), "target \"%s\" for portal group tag %u already exists", target, tag); cfiscsi_target_release(ct); return; } port = &ct->ct_port; // WAT if (ct->ct_state == CFISCSI_TARGET_STATE_DYING) goto done; port->frontend = &cfiscsi_frontend; port->port_type = CTL_PORT_ISCSI; /* XXX KDM what should the real number be here? */ port->num_requested_ctl_io = 4096; port->port_name = "iscsi"; port->physical_port = (int)tag; port->virtual_port = ct->ct_target_id; port->port_online = cfiscsi_online; port->port_offline = cfiscsi_offline; port->port_info = cfiscsi_info; port->onoff_arg = ct; port->fe_datamove = cfiscsi_datamove; port->fe_done = cfiscsi_done; port->targ_port = -1; port->options = nvlist_clone(req->args_nvl); /* Generate Port ID. */ idlen = strlen(target) + strlen(",t,0x0001") + 1; idlen = roundup2(idlen, 4); len = sizeof(struct scsi_vpd_device_id) + idlen; port->port_devid = malloc(sizeof(struct ctl_devid) + len, M_CTL, M_WAITOK | M_ZERO); port->port_devid->len = len; desc = (struct scsi_vpd_id_descriptor *)port->port_devid->data; desc->proto_codeset = (SCSI_PROTO_ISCSI << 4) | SVPD_ID_CODESET_UTF8; desc->id_type = SVPD_ID_PIV | SVPD_ID_ASSOC_PORT | SVPD_ID_TYPE_SCSI_NAME; desc->length = idlen; snprintf(desc->identifier, idlen, "%s,t,0x%4.4x", target, tag); /* Generate Target ID. */ idlen = strlen(target) + 1; idlen = roundup2(idlen, 4); len = sizeof(struct scsi_vpd_device_id) + idlen; port->target_devid = malloc(sizeof(struct ctl_devid) + len, M_CTL, M_WAITOK | M_ZERO); port->target_devid->len = len; desc = (struct scsi_vpd_id_descriptor *)port->target_devid->data; desc->proto_codeset = (SCSI_PROTO_ISCSI << 4) | SVPD_ID_CODESET_UTF8; desc->id_type = SVPD_ID_PIV | SVPD_ID_ASSOC_TARGET | SVPD_ID_TYPE_SCSI_NAME; desc->length = idlen; strlcpy(desc->identifier, target, idlen); retval = ctl_port_register(port); if (retval != 0) { free(port->port_devid, M_CFISCSI); free(port->target_devid, M_CFISCSI); cfiscsi_target_release(ct); req->status = CTL_LUN_ERROR; snprintf(req->error_str, sizeof(req->error_str), "ctl_port_register() failed with error %d", retval); return; } done: ct->ct_state = CFISCSI_TARGET_STATE_ACTIVE; req->status = CTL_LUN_OK; req->result_nvl = nvlist_create(0); nvlist_add_number(req->result_nvl, "port_id", port->targ_port); } static void cfiscsi_ioctl_port_remove(struct ctl_req *req) { struct cfiscsi_target *ct; const char *target, *val; uint16_t tag; target = dnvlist_get_string(req->args_nvl, "cfiscsi_target", NULL); val = dnvlist_get_string(req->args_nvl, "cfiscsi_portal_group_tag", NULL); if (target == NULL || val == NULL) { req->status = CTL_LUN_ERROR; snprintf(req->error_str, sizeof(req->error_str), "Missing required argument"); return; } tag = strtoul(val, NULL, 0); ct = cfiscsi_target_find(&cfiscsi_softc, target, tag); if (ct == NULL) { req->status = CTL_LUN_ERROR; snprintf(req->error_str, sizeof(req->error_str), "can't find target \"%s\"", target); return; } ct->ct_state = CFISCSI_TARGET_STATE_DYING; ctl_port_offline(&ct->ct_port); cfiscsi_target_release(ct); cfiscsi_target_release(ct); req->status = CTL_LUN_OK; } static int cfiscsi_ioctl(struct cdev *dev, u_long cmd, caddr_t addr, int flag, struct thread *td) { struct ctl_iscsi *ci; struct ctl_req *req; if (cmd == CTL_PORT_REQ) { req = (struct ctl_req *)addr; switch (req->reqtype) { case CTL_REQ_CREATE: cfiscsi_ioctl_port_create(req); break; case CTL_REQ_REMOVE: cfiscsi_ioctl_port_remove(req); break; default: req->status = CTL_LUN_ERROR; snprintf(req->error_str, sizeof(req->error_str), "Unsupported request type %d", req->reqtype); } return (0); } if (cmd != CTL_ISCSI) return (ENOTTY); ci = (struct ctl_iscsi *)addr; switch (ci->type) { case CTL_ISCSI_HANDOFF: cfiscsi_ioctl_handoff(ci); break; case CTL_ISCSI_LIST: cfiscsi_ioctl_list(ci); break; case CTL_ISCSI_LOGOUT: cfiscsi_ioctl_logout(ci); break; case CTL_ISCSI_TERMINATE: cfiscsi_ioctl_terminate(ci); break; case CTL_ISCSI_LIMITS: cfiscsi_ioctl_limits(ci); break; #ifdef ICL_KERNEL_PROXY case CTL_ISCSI_LISTEN: cfiscsi_ioctl_listen(ci); break; case CTL_ISCSI_ACCEPT: cfiscsi_ioctl_accept(ci); break; case CTL_ISCSI_SEND: cfiscsi_ioctl_send(ci); break; case CTL_ISCSI_RECEIVE: cfiscsi_ioctl_receive(ci); break; #else case CTL_ISCSI_LISTEN: case CTL_ISCSI_ACCEPT: case CTL_ISCSI_SEND: case CTL_ISCSI_RECEIVE: ci->status = CTL_ISCSI_ERROR; snprintf(ci->error_str, sizeof(ci->error_str), "%s: CTL compiled without ICL_KERNEL_PROXY", __func__); break; #endif /* !ICL_KERNEL_PROXY */ default: ci->status = CTL_ISCSI_ERROR; snprintf(ci->error_str, sizeof(ci->error_str), "%s: invalid iSCSI request type %d", __func__, ci->type); break; } return (0); } static void cfiscsi_target_hold(struct cfiscsi_target *ct) { refcount_acquire(&ct->ct_refcount); } static void cfiscsi_target_release(struct cfiscsi_target *ct) { struct cfiscsi_softc *softc; softc = ct->ct_softc; mtx_lock(&softc->lock); if (refcount_release(&ct->ct_refcount)) { TAILQ_REMOVE(&softc->targets, ct, ct_next); mtx_unlock(&softc->lock); if (ct->ct_state != CFISCSI_TARGET_STATE_INVALID) { ct->ct_state = CFISCSI_TARGET_STATE_INVALID; if (ctl_port_deregister(&ct->ct_port) != 0) printf("%s: ctl_port_deregister() failed\n", __func__); } free(ct, M_CFISCSI); return; } mtx_unlock(&softc->lock); } static struct cfiscsi_target * cfiscsi_target_find(struct cfiscsi_softc *softc, const char *name, uint16_t tag) { struct cfiscsi_target *ct; mtx_lock(&softc->lock); TAILQ_FOREACH(ct, &softc->targets, ct_next) { if (ct->ct_tag != tag || strcmp(name, ct->ct_name) != 0 || ct->ct_state != CFISCSI_TARGET_STATE_ACTIVE) continue; cfiscsi_target_hold(ct); mtx_unlock(&softc->lock); return (ct); } mtx_unlock(&softc->lock); return (NULL); } static struct cfiscsi_target * cfiscsi_target_find_or_create(struct cfiscsi_softc *softc, const char *name, const char *alias, uint16_t tag) { struct cfiscsi_target *ct, *newct; if (name[0] == '\0' || strlen(name) >= CTL_ISCSI_NAME_LEN) return (NULL); newct = malloc(sizeof(*newct), M_CFISCSI, M_WAITOK | M_ZERO); mtx_lock(&softc->lock); TAILQ_FOREACH(ct, &softc->targets, ct_next) { if (ct->ct_tag != tag || strcmp(name, ct->ct_name) != 0 || ct->ct_state == CFISCSI_TARGET_STATE_INVALID) continue; cfiscsi_target_hold(ct); mtx_unlock(&softc->lock); free(newct, M_CFISCSI); return (ct); } strlcpy(newct->ct_name, name, sizeof(newct->ct_name)); if (alias != NULL) strlcpy(newct->ct_alias, alias, sizeof(newct->ct_alias)); newct->ct_tag = tag; refcount_init(&newct->ct_refcount, 1); newct->ct_softc = softc; if (TAILQ_EMPTY(&softc->targets)) softc->last_target_id = 0; newct->ct_target_id = ++softc->last_target_id; TAILQ_INSERT_TAIL(&softc->targets, newct, ct_next); mtx_unlock(&softc->lock); return (newct); } static void cfiscsi_pdu_done(struct icl_pdu *ip, int error) { if (error != 0) ; // XXX: Do something on error? ((ctl_ref)ip->ip_prv0)(ip->ip_prv1, -1); } static void cfiscsi_datamove_in(union ctl_io *io) { struct cfiscsi_session *cs; struct icl_pdu *request, *response; const struct iscsi_bhs_scsi_command *bhssc; struct iscsi_bhs_data_in *bhsdi; struct ctl_sg_entry ctl_sg_entry, *ctl_sglist; size_t len, expected_len, sg_len, buffer_offset; const char *sg_addr; icl_pdu_cb cb; int ctl_sg_count, error, i; request = PRIV_REQUEST(io); cs = PDU_SESSION(request); bhssc = (const struct iscsi_bhs_scsi_command *)request->ip_bhs; KASSERT((bhssc->bhssc_opcode & ~ISCSI_BHS_OPCODE_IMMEDIATE) == ISCSI_BHS_OPCODE_SCSI_COMMAND, ("bhssc->bhssc_opcode != ISCSI_BHS_OPCODE_SCSI_COMMAND")); if (io->scsiio.kern_sg_entries > 0) { ctl_sglist = (struct ctl_sg_entry *)io->scsiio.kern_data_ptr; ctl_sg_count = io->scsiio.kern_sg_entries; } else { ctl_sglist = &ctl_sg_entry; ctl_sglist->addr = io->scsiio.kern_data_ptr; ctl_sglist->len = io->scsiio.kern_data_len; ctl_sg_count = 1; } /* * This is the offset within the current SCSI command; for the first * call to cfiscsi_datamove() it will be 0, and for subsequent ones * it will be the sum of lengths of previous ones. */ buffer_offset = io->scsiio.kern_rel_offset; /* * This is the transfer length expected by the initiator. It can be * different from the amount of data from the SCSI point of view. */ expected_len = ntohl(bhssc->bhssc_expected_data_transfer_length); /* * If the transfer is outside of expected length -- we are done. */ if (buffer_offset >= expected_len) { #if 0 CFISCSI_SESSION_DEBUG(cs, "buffer_offset = %zd, " "already sent the expected len", buffer_offset); #endif io->scsiio.be_move_done(io); return; } if (io->scsiio.kern_data_ref != NULL) cb = cfiscsi_pdu_done; else cb = NULL; i = 0; sg_addr = NULL; sg_len = 0; response = NULL; bhsdi = NULL; for (;;) { if (response == NULL) { response = cfiscsi_pdu_new_response(request, M_NOWAIT); if (response == NULL) { CFISCSI_SESSION_WARN(cs, "failed to " "allocate memory; dropping connection"); ctl_set_busy(&io->scsiio); io->scsiio.be_move_done(io); cfiscsi_session_terminate(cs); return; } bhsdi = (struct iscsi_bhs_data_in *)response->ip_bhs; bhsdi->bhsdi_opcode = ISCSI_BHS_OPCODE_SCSI_DATA_IN; bhsdi->bhsdi_initiator_task_tag = bhssc->bhssc_initiator_task_tag; bhsdi->bhsdi_target_transfer_tag = 0xffffffff; bhsdi->bhsdi_datasn = htonl(PRIV_EXPDATASN(io)++); bhsdi->bhsdi_buffer_offset = htonl(buffer_offset); } KASSERT(i < ctl_sg_count, ("i >= ctl_sg_count")); if (sg_len == 0) { sg_addr = ctl_sglist[i].addr; sg_len = ctl_sglist[i].len; KASSERT(sg_len > 0, ("sg_len <= 0")); } len = sg_len; /* * Truncate to maximum data segment length. */ KASSERT(response->ip_data_len < cs->cs_max_send_data_segment_length, ("ip_data_len %zd >= max_send_data_segment_length %d", response->ip_data_len, cs->cs_max_send_data_segment_length)); if (response->ip_data_len + len > cs->cs_max_send_data_segment_length) { len = cs->cs_max_send_data_segment_length - response->ip_data_len; KASSERT(len <= sg_len, ("len %zd > sg_len %zd", len, sg_len)); } /* * Truncate to expected data transfer length. */ KASSERT(buffer_offset + response->ip_data_len < expected_len, ("buffer_offset %zd + ip_data_len %zd >= expected_len %zd", buffer_offset, response->ip_data_len, expected_len)); if (buffer_offset + response->ip_data_len + len > expected_len) { CFISCSI_SESSION_DEBUG(cs, "truncating from %zd " "to expected data transfer length %zd", buffer_offset + response->ip_data_len + len, expected_len); len = expected_len - (buffer_offset + response->ip_data_len); KASSERT(len <= sg_len, ("len %zd > sg_len %zd", len, sg_len)); } error = icl_pdu_append_data(response, sg_addr, len, M_NOWAIT | (cb ? ICL_NOCOPY : 0)); if (error != 0) { CFISCSI_SESSION_WARN(cs, "failed to " "allocate memory; dropping connection"); icl_pdu_free(response); ctl_set_busy(&io->scsiio); io->scsiio.be_move_done(io); cfiscsi_session_terminate(cs); return; } sg_addr += len; sg_len -= len; io->scsiio.kern_data_resid -= len; KASSERT(buffer_offset + response->ip_data_len <= expected_len, ("buffer_offset %zd + ip_data_len %zd > expected_len %zd", buffer_offset, response->ip_data_len, expected_len)); if (buffer_offset + response->ip_data_len == expected_len) { /* * Already have the amount of data the initiator wanted. */ break; } if (sg_len == 0) { /* * End of scatter-gather segment; * proceed to the next one... */ if (i == ctl_sg_count - 1) { /* * ... unless this was the last one. */ break; } i++; } if (response->ip_data_len == cs->cs_max_send_data_segment_length) { /* * Can't stuff more data into the current PDU; * queue it. Note that's not enough to check * for kern_data_resid == 0 instead; there * may be several Data-In PDUs for the final * call to cfiscsi_datamove(), and we want * to set the F flag only on the last of them. */ buffer_offset += response->ip_data_len; if (buffer_offset == io->scsiio.kern_total_len || buffer_offset == expected_len) { buffer_offset -= response->ip_data_len; break; } if (cb != NULL) { response->ip_prv0 = io->scsiio.kern_data_ref; response->ip_prv1 = io->scsiio.kern_data_arg; io->scsiio.kern_data_ref(io->scsiio.kern_data_arg, 1); } cfiscsi_pdu_queue_cb(response, cb); response = NULL; bhsdi = NULL; } } if (response != NULL) { buffer_offset += response->ip_data_len; if (buffer_offset == io->scsiio.kern_total_len || buffer_offset == expected_len) { bhsdi->bhsdi_flags |= BHSDI_FLAGS_F; if (io->io_hdr.status == CTL_SUCCESS) { bhsdi->bhsdi_flags |= BHSDI_FLAGS_S; if (io->scsiio.kern_total_len < ntohl(bhssc->bhssc_expected_data_transfer_length)) { bhsdi->bhsdi_flags |= BHSSR_FLAGS_RESIDUAL_UNDERFLOW; bhsdi->bhsdi_residual_count = htonl(ntohl(bhssc->bhssc_expected_data_transfer_length) - io->scsiio.kern_total_len); } else if (io->scsiio.kern_total_len > ntohl(bhssc->bhssc_expected_data_transfer_length)) { bhsdi->bhsdi_flags |= BHSSR_FLAGS_RESIDUAL_OVERFLOW; bhsdi->bhsdi_residual_count = htonl(io->scsiio.kern_total_len - ntohl(bhssc->bhssc_expected_data_transfer_length)); } bhsdi->bhsdi_status = io->scsiio.scsi_status; io->io_hdr.flags |= CTL_FLAG_STATUS_SENT; } } KASSERT(response->ip_data_len > 0, ("sending empty Data-In")); if (cb != NULL) { response->ip_prv0 = io->scsiio.kern_data_ref; response->ip_prv1 = io->scsiio.kern_data_arg; io->scsiio.kern_data_ref(io->scsiio.kern_data_arg, 1); } cfiscsi_pdu_queue_cb(response, cb); } io->scsiio.be_move_done(io); } static void cfiscsi_datamove_out(union ctl_io *io) { struct cfiscsi_session *cs; struct icl_pdu *request, *response; const struct iscsi_bhs_scsi_command *bhssc; struct iscsi_bhs_r2t *bhsr2t; struct cfiscsi_data_wait *cdw; struct ctl_sg_entry ctl_sg_entry, *ctl_sglist; uint32_t expected_len, datamove_len, r2t_off, r2t_len; uint32_t target_transfer_tag; bool done; request = PRIV_REQUEST(io); cs = PDU_SESSION(request); bhssc = (const struct iscsi_bhs_scsi_command *)request->ip_bhs; KASSERT((bhssc->bhssc_opcode & ~ISCSI_BHS_OPCODE_IMMEDIATE) == ISCSI_BHS_OPCODE_SCSI_COMMAND, ("bhssc->bhssc_opcode != ISCSI_BHS_OPCODE_SCSI_COMMAND")); /* * Complete write underflow. Not a single byte to read. Return. */ expected_len = ntohl(bhssc->bhssc_expected_data_transfer_length); if (io->scsiio.kern_rel_offset >= expected_len) { io->scsiio.be_move_done(io); return; } datamove_len = MIN(io->scsiio.kern_data_len, expected_len - io->scsiio.kern_rel_offset); target_transfer_tag = atomic_fetchadd_32(&cs->cs_target_transfer_tag, 1); if (target_transfer_tag == 0xffffffff) { target_transfer_tag = atomic_fetchadd_32(&cs->cs_target_transfer_tag, 1); } cdw = cfiscsi_data_wait_new(cs, io, bhssc->bhssc_initiator_task_tag, &target_transfer_tag); if (cdw == NULL) { CFISCSI_SESSION_WARN(cs, "failed to " "allocate memory; dropping connection"); ctl_set_busy(&io->scsiio); io->scsiio.be_move_done(io); cfiscsi_session_terminate(cs); return; } #if 0 CFISCSI_SESSION_DEBUG(cs, "expecting Data-Out with initiator " "task tag 0x%x, target transfer tag 0x%x", bhssc->bhssc_initiator_task_tag, target_transfer_tag); #endif cdw->cdw_ctl_io = io; cdw->cdw_target_transfer_tag = target_transfer_tag; cdw->cdw_initiator_task_tag = bhssc->bhssc_initiator_task_tag; cdw->cdw_r2t_end = datamove_len; cdw->cdw_datasn = 0; /* Set initial data pointer for the CDW respecting ext_data_filled. */ if (io->scsiio.kern_sg_entries > 0) { ctl_sglist = (struct ctl_sg_entry *)io->scsiio.kern_data_ptr; } else { ctl_sglist = &ctl_sg_entry; ctl_sglist->addr = io->scsiio.kern_data_ptr; ctl_sglist->len = datamove_len; } cdw->cdw_sg_index = 0; cdw->cdw_sg_addr = ctl_sglist[cdw->cdw_sg_index].addr; cdw->cdw_sg_len = ctl_sglist[cdw->cdw_sg_index].len; r2t_off = io->scsiio.ext_data_filled; while (r2t_off > 0) { if (r2t_off >= cdw->cdw_sg_len) { r2t_off -= cdw->cdw_sg_len; cdw->cdw_sg_index++; cdw->cdw_sg_addr = ctl_sglist[cdw->cdw_sg_index].addr; cdw->cdw_sg_len = ctl_sglist[cdw->cdw_sg_index].len; continue; } cdw->cdw_sg_addr += r2t_off; cdw->cdw_sg_len -= r2t_off; r2t_off = 0; } if (cs->cs_immediate_data && io->scsiio.kern_rel_offset + io->scsiio.ext_data_filled < icl_pdu_data_segment_length(request)) { done = cfiscsi_handle_data_segment(request, cdw); if (done) { cfiscsi_data_wait_free(cs, cdw); io->scsiio.be_move_done(io); return; } } r2t_off = io->scsiio.kern_rel_offset + io->scsiio.ext_data_filled; r2t_len = MIN(datamove_len - io->scsiio.ext_data_filled, cs->cs_max_burst_length); cdw->cdw_r2t_end = io->scsiio.ext_data_filled + r2t_len; CFISCSI_SESSION_LOCK(cs); TAILQ_INSERT_TAIL(&cs->cs_waiting_for_data_out, cdw, cdw_next); CFISCSI_SESSION_UNLOCK(cs); /* * XXX: We should limit the number of outstanding R2T PDUs * per task to MaxOutstandingR2T. */ response = cfiscsi_pdu_new_response(request, M_NOWAIT); if (response == NULL) { CFISCSI_SESSION_WARN(cs, "failed to " "allocate memory; dropping connection"); ctl_set_busy(&io->scsiio); io->scsiio.be_move_done(io); cfiscsi_session_terminate(cs); return; } io->io_hdr.flags |= CTL_FLAG_DMA_INPROG; bhsr2t = (struct iscsi_bhs_r2t *)response->ip_bhs; bhsr2t->bhsr2t_opcode = ISCSI_BHS_OPCODE_R2T; bhsr2t->bhsr2t_flags = 0x80; bhsr2t->bhsr2t_lun = bhssc->bhssc_lun; bhsr2t->bhsr2t_initiator_task_tag = bhssc->bhssc_initiator_task_tag; bhsr2t->bhsr2t_target_transfer_tag = target_transfer_tag; /* * XXX: Here we assume that cfiscsi_datamove() won't ever * be running concurrently on several CPUs for a given * command. */ bhsr2t->bhsr2t_r2tsn = htonl(PRIV_R2TSN(io)++); /* * This is the offset within the current SCSI command; * i.e. for the first call of datamove(), it will be 0, * and for subsequent ones it will be the sum of lengths * of previous ones. * * The ext_data_filled is to account for unsolicited * (immediate) data that might have already arrived. */ bhsr2t->bhsr2t_buffer_offset = htonl(r2t_off); /* * This is the total length (sum of S/G lengths) this call * to cfiscsi_datamove() is supposed to handle, limited by * MaxBurstLength. */ bhsr2t->bhsr2t_desired_data_transfer_length = htonl(r2t_len); cfiscsi_pdu_queue(response); } static void cfiscsi_datamove(union ctl_io *io) { if ((io->io_hdr.flags & CTL_FLAG_DATA_MASK) == CTL_FLAG_DATA_IN) cfiscsi_datamove_in(io); else { /* We hadn't received anything during this datamove yet. */ io->scsiio.ext_data_filled = 0; cfiscsi_datamove_out(io); } } static void cfiscsi_scsi_command_done(union ctl_io *io) { struct icl_pdu *request, *response; struct iscsi_bhs_scsi_command *bhssc; struct iscsi_bhs_scsi_response *bhssr; #ifdef DIAGNOSTIC struct cfiscsi_data_wait *cdw; #endif struct cfiscsi_session *cs; uint16_t sense_length; request = PRIV_REQUEST(io); cs = PDU_SESSION(request); bhssc = (struct iscsi_bhs_scsi_command *)request->ip_bhs; KASSERT((bhssc->bhssc_opcode & ~ISCSI_BHS_OPCODE_IMMEDIATE) == ISCSI_BHS_OPCODE_SCSI_COMMAND, ("replying to wrong opcode 0x%x", bhssc->bhssc_opcode)); //CFISCSI_SESSION_DEBUG(cs, "initiator task tag 0x%x", // bhssc->bhssc_initiator_task_tag); #ifdef DIAGNOSTIC CFISCSI_SESSION_LOCK(cs); TAILQ_FOREACH(cdw, &cs->cs_waiting_for_data_out, cdw_next) KASSERT(bhssc->bhssc_initiator_task_tag != cdw->cdw_initiator_task_tag, ("dangling cdw")); CFISCSI_SESSION_UNLOCK(cs); #endif /* * Do not return status for aborted commands. * There are exceptions, but none supported by CTL yet. */ if (((io->io_hdr.flags & CTL_FLAG_ABORT) && (io->io_hdr.flags & CTL_FLAG_ABORT_STATUS) == 0) || (io->io_hdr.flags & CTL_FLAG_STATUS_SENT)) { ctl_free_io(io); icl_pdu_free(request); return; } response = cfiscsi_pdu_new_response(request, M_WAITOK); bhssr = (struct iscsi_bhs_scsi_response *)response->ip_bhs; bhssr->bhssr_opcode = ISCSI_BHS_OPCODE_SCSI_RESPONSE; bhssr->bhssr_flags = 0x80; /* * XXX: We don't deal with bidirectional under/overflows; * does anything actually support those? */ if (io->scsiio.kern_total_len < ntohl(bhssc->bhssc_expected_data_transfer_length)) { bhssr->bhssr_flags |= BHSSR_FLAGS_RESIDUAL_UNDERFLOW; bhssr->bhssr_residual_count = htonl(ntohl(bhssc->bhssc_expected_data_transfer_length) - io->scsiio.kern_total_len); //CFISCSI_SESSION_DEBUG(cs, "underflow; residual count %d", // ntohl(bhssr->bhssr_residual_count)); } else if (io->scsiio.kern_total_len > ntohl(bhssc->bhssc_expected_data_transfer_length)) { bhssr->bhssr_flags |= BHSSR_FLAGS_RESIDUAL_OVERFLOW; bhssr->bhssr_residual_count = htonl(io->scsiio.kern_total_len - ntohl(bhssc->bhssc_expected_data_transfer_length)); //CFISCSI_SESSION_DEBUG(cs, "overflow; residual count %d", // ntohl(bhssr->bhssr_residual_count)); } bhssr->bhssr_response = BHSSR_RESPONSE_COMMAND_COMPLETED; bhssr->bhssr_status = io->scsiio.scsi_status; bhssr->bhssr_initiator_task_tag = bhssc->bhssc_initiator_task_tag; bhssr->bhssr_expdatasn = htonl(PRIV_EXPDATASN(io)); if (io->scsiio.sense_len > 0) { #if 0 CFISCSI_SESSION_DEBUG(cs, "returning %d bytes of sense data", io->scsiio.sense_len); #endif sense_length = htons(io->scsiio.sense_len); icl_pdu_append_data(response, &sense_length, sizeof(sense_length), M_WAITOK); icl_pdu_append_data(response, &io->scsiio.sense_data, io->scsiio.sense_len, M_WAITOK); } ctl_free_io(io); icl_pdu_free(request); cfiscsi_pdu_queue(response); } static void cfiscsi_task_management_done(union ctl_io *io) { struct icl_pdu *request, *response; struct iscsi_bhs_task_management_request *bhstmr; struct iscsi_bhs_task_management_response *bhstmr2; struct cfiscsi_data_wait *cdw, *tmpcdw; struct cfiscsi_session *cs, *tcs; struct cfiscsi_softc *softc; int cold_reset = 0; request = PRIV_REQUEST(io); cs = PDU_SESSION(request); bhstmr = (struct iscsi_bhs_task_management_request *)request->ip_bhs; KASSERT((bhstmr->bhstmr_opcode & ~ISCSI_BHS_OPCODE_IMMEDIATE) == ISCSI_BHS_OPCODE_TASK_REQUEST, ("replying to wrong opcode 0x%x", bhstmr->bhstmr_opcode)); #if 0 CFISCSI_SESSION_DEBUG(cs, "initiator task tag 0x%x; referenced task tag 0x%x", bhstmr->bhstmr_initiator_task_tag, bhstmr->bhstmr_referenced_task_tag); #endif if ((bhstmr->bhstmr_function & ~0x80) == BHSTMR_FUNCTION_ABORT_TASK) { /* * Make sure we no longer wait for Data-Out for this command. */ CFISCSI_SESSION_LOCK(cs); TAILQ_FOREACH_SAFE(cdw, &cs->cs_waiting_for_data_out, cdw_next, tmpcdw) { if (bhstmr->bhstmr_referenced_task_tag != cdw->cdw_initiator_task_tag) continue; #if 0 CFISCSI_SESSION_DEBUG(cs, "removing csw for initiator task " "tag 0x%x", bhstmr->bhstmr_initiator_task_tag); #endif TAILQ_REMOVE(&cs->cs_waiting_for_data_out, cdw, cdw_next); io->io_hdr.flags &= ~CTL_FLAG_DMA_INPROG; cdw->cdw_ctl_io->scsiio.io_hdr.port_status = 43; cdw->cdw_ctl_io->scsiio.be_move_done(cdw->cdw_ctl_io); cfiscsi_data_wait_free(cs, cdw); } CFISCSI_SESSION_UNLOCK(cs); } if ((bhstmr->bhstmr_function & ~0x80) == BHSTMR_FUNCTION_TARGET_COLD_RESET && io->io_hdr.status == CTL_SUCCESS) cold_reset = 1; response = cfiscsi_pdu_new_response(request, M_WAITOK); bhstmr2 = (struct iscsi_bhs_task_management_response *) response->ip_bhs; bhstmr2->bhstmr_opcode = ISCSI_BHS_OPCODE_TASK_RESPONSE; bhstmr2->bhstmr_flags = 0x80; switch (io->taskio.task_status) { case CTL_TASK_FUNCTION_COMPLETE: bhstmr2->bhstmr_response = BHSTMR_RESPONSE_FUNCTION_COMPLETE; break; case CTL_TASK_FUNCTION_SUCCEEDED: bhstmr2->bhstmr_response = BHSTMR_RESPONSE_FUNCTION_SUCCEEDED; break; case CTL_TASK_LUN_DOES_NOT_EXIST: bhstmr2->bhstmr_response = BHSTMR_RESPONSE_LUN_DOES_NOT_EXIST; break; case CTL_TASK_FUNCTION_NOT_SUPPORTED: default: bhstmr2->bhstmr_response = BHSTMR_RESPONSE_FUNCTION_NOT_SUPPORTED; break; } memcpy(bhstmr2->bhstmr_additional_reponse_information, io->taskio.task_resp, sizeof(io->taskio.task_resp)); bhstmr2->bhstmr_initiator_task_tag = bhstmr->bhstmr_initiator_task_tag; ctl_free_io(io); icl_pdu_free(request); cfiscsi_pdu_queue(response); if (cold_reset) { softc = cs->cs_target->ct_softc; mtx_lock(&softc->lock); TAILQ_FOREACH(tcs, &softc->sessions, cs_next) { if (tcs->cs_target == cs->cs_target) cfiscsi_session_terminate(tcs); } mtx_unlock(&softc->lock); } } static void cfiscsi_done(union ctl_io *io) { struct icl_pdu *request; struct cfiscsi_session *cs; KASSERT(((io->io_hdr.status & CTL_STATUS_MASK) != CTL_STATUS_NONE), ("invalid CTL status %#x", io->io_hdr.status)); if (io->io_hdr.io_type == CTL_IO_TASK && io->taskio.task_action == CTL_TASK_I_T_NEXUS_RESET) { /* * Implicit task termination has just completed; nothing to do. */ cs = PRIV_REQUEST(io); cs->cs_tasks_aborted = true; refcount_release(&cs->cs_outstanding_ctl_pdus); wakeup(__DEVOLATILE(void *, &cs->cs_outstanding_ctl_pdus)); ctl_free_io(io); return; } request = PRIV_REQUEST(io); cs = PDU_SESSION(request); switch (request->ip_bhs->bhs_opcode & ~ISCSI_BHS_OPCODE_IMMEDIATE) { case ISCSI_BHS_OPCODE_SCSI_COMMAND: cfiscsi_scsi_command_done(io); break; case ISCSI_BHS_OPCODE_TASK_REQUEST: cfiscsi_task_management_done(io); break; default: panic("cfiscsi_done called with wrong opcode 0x%x", request->ip_bhs->bhs_opcode); } refcount_release(&cs->cs_outstanding_ctl_pdus); } diff --git a/sys/cam/ctl/ctl_tpc.c b/sys/cam/ctl/ctl_tpc.c index d63435b38762..de9e97b87a3e 100644 --- a/sys/cam/ctl/ctl_tpc.c +++ b/sys/cam/ctl/ctl_tpc.c @@ -1,2474 +1,2474 @@ /*- * SPDX-License-Identifier: BSD-2-Clause-FreeBSD * * Copyright (c) 2014 Alexander Motin * 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, * without modification, immediately at the beginning of the file. * 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 AUTHOR ``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 AUTHOR 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 #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #define TPC_MAX_CSCDS 64 #define TPC_MAX_SEGS 64 #define TPC_MAX_SEG 0 #define TPC_MAX_LIST 8192 #define TPC_MAX_INLINE 0 #define TPC_MAX_LISTS 255 #define TPC_MAX_IO_SIZE (1024 * 1024) #define TPC_MAX_IOCHUNK_SIZE (TPC_MAX_IO_SIZE * 16) #define TPC_MIN_TOKEN_TIMEOUT 1 #define TPC_DFL_TOKEN_TIMEOUT 60 #define TPC_MAX_TOKEN_TIMEOUT 600 MALLOC_DEFINE(M_CTL_TPC, "ctltpc", "CTL TPC"); typedef enum { TPC_ERR_RETRY = 0x000, TPC_ERR_FAIL = 0x001, TPC_ERR_MASK = 0x0ff, TPC_ERR_NO_DECREMENT = 0x100 } tpc_error_action; struct tpc_list; TAILQ_HEAD(runl, tpc_io); struct tpc_io { union ctl_io *io; uint8_t target; uint32_t cscd; uint64_t lun; uint8_t *buf; struct tpc_list *list; struct runl run; TAILQ_ENTRY(tpc_io) rlinks; TAILQ_ENTRY(tpc_io) links; }; struct tpc_token { uint8_t token[512]; uint64_t lun; uint32_t blocksize; uint8_t *params; struct scsi_range_desc *range; int nrange; int active; time_t last_active; uint32_t timeout; TAILQ_ENTRY(tpc_token) links; }; struct tpc_list { uint8_t service_action; int init_port; uint32_t init_idx; uint32_t list_id; uint8_t flags; uint8_t *params; struct scsi_ec_cscd *cscd; struct scsi_ec_segment *seg[TPC_MAX_SEGS]; uint8_t *inl; int ncscd; int nseg; int leninl; struct tpc_token *token; struct scsi_range_desc *range; int nrange; off_t offset_into_rod; int curseg; off_t cursectors; off_t curbytes; int curops; int stage; off_t segsectors; off_t segbytes; int tbdio; int error; int abort; int completed; time_t last_active; TAILQ_HEAD(, tpc_io) allio; struct scsi_sense_data fwd_sense_data; uint8_t fwd_sense_len; uint8_t fwd_scsi_status; uint8_t fwd_target; uint16_t fwd_cscd; struct scsi_sense_data sense_data; uint8_t sense_len; uint8_t scsi_status; struct ctl_scsiio *ctsio; struct ctl_lun *lun; int res_token_valid; uint8_t res_token[512]; TAILQ_ENTRY(tpc_list) links; }; static void tpc_timeout(void *arg) { struct ctl_softc *softc = arg; struct ctl_lun *lun; struct tpc_token *token, *ttoken; struct tpc_list *list, *tlist; /* Free completed lists with expired timeout. */ STAILQ_FOREACH(lun, &softc->lun_list, links) { mtx_lock(&lun->lun_lock); TAILQ_FOREACH_SAFE(list, &lun->tpc_lists, links, tlist) { if (!list->completed || time_uptime < list->last_active + TPC_DFL_TOKEN_TIMEOUT) continue; TAILQ_REMOVE(&lun->tpc_lists, list, links); free(list, M_CTL); } mtx_unlock(&lun->lun_lock); } /* Free inactive ROD tokens with expired timeout. */ mtx_lock(&softc->tpc_lock); TAILQ_FOREACH_SAFE(token, &softc->tpc_tokens, links, ttoken) { if (token->active || time_uptime < token->last_active + token->timeout + 1) continue; TAILQ_REMOVE(&softc->tpc_tokens, token, links); free(token->params, M_CTL); free(token, M_CTL); } mtx_unlock(&softc->tpc_lock); callout_schedule(&softc->tpc_timeout, hz); } void ctl_tpc_init(struct ctl_softc *softc) { mtx_init(&softc->tpc_lock, "CTL TPC mutex", NULL, MTX_DEF); TAILQ_INIT(&softc->tpc_tokens); callout_init_mtx(&softc->tpc_timeout, &softc->ctl_lock, 0); callout_reset(&softc->tpc_timeout, hz, tpc_timeout, softc); } void ctl_tpc_shutdown(struct ctl_softc *softc) { struct tpc_token *token; callout_drain(&softc->tpc_timeout); /* Free ROD tokens. */ mtx_lock(&softc->tpc_lock); while ((token = TAILQ_FIRST(&softc->tpc_tokens)) != NULL) { TAILQ_REMOVE(&softc->tpc_tokens, token, links); free(token->params, M_CTL); free(token, M_CTL); } mtx_unlock(&softc->tpc_lock); mtx_destroy(&softc->tpc_lock); } void ctl_tpc_lun_init(struct ctl_lun *lun) { TAILQ_INIT(&lun->tpc_lists); } void ctl_tpc_lun_clear(struct ctl_lun *lun, uint32_t initidx) { struct tpc_list *list, *tlist; TAILQ_FOREACH_SAFE(list, &lun->tpc_lists, links, tlist) { if (initidx != -1 && list->init_idx != initidx) continue; if (!list->completed) continue; TAILQ_REMOVE(&lun->tpc_lists, list, links); free(list, M_CTL); } } void ctl_tpc_lun_shutdown(struct ctl_lun *lun) { struct ctl_softc *softc = lun->ctl_softc; struct tpc_list *list; struct tpc_token *token, *ttoken; /* Free lists for this LUN. */ while ((list = TAILQ_FIRST(&lun->tpc_lists)) != NULL) { TAILQ_REMOVE(&lun->tpc_lists, list, links); KASSERT(list->completed, ("Not completed TPC (%p) on shutdown", list)); free(list, M_CTL); } /* Free ROD tokens for this LUN. */ mtx_lock(&softc->tpc_lock); TAILQ_FOREACH_SAFE(token, &softc->tpc_tokens, links, ttoken) { if (token->lun != lun->lun || token->active) continue; TAILQ_REMOVE(&softc->tpc_tokens, token, links); free(token->params, M_CTL); free(token, M_CTL); } mtx_unlock(&softc->tpc_lock); } int ctl_inquiry_evpd_tpc(struct ctl_scsiio *ctsio, int alloc_len) { struct ctl_lun *lun = CTL_LUN(ctsio); struct scsi_vpd_tpc *tpc_ptr; struct scsi_vpd_tpc_descriptor *d_ptr; struct scsi_vpd_tpc_descriptor_bdrl *bdrl_ptr; struct scsi_vpd_tpc_descriptor_sc *sc_ptr; struct scsi_vpd_tpc_descriptor_sc_descr *scd_ptr; struct scsi_vpd_tpc_descriptor_pd *pd_ptr; struct scsi_vpd_tpc_descriptor_sd *sd_ptr; struct scsi_vpd_tpc_descriptor_sdid *sdid_ptr; struct scsi_vpd_tpc_descriptor_rtf *rtf_ptr; struct scsi_vpd_tpc_descriptor_rtf_block *rtfb_ptr; struct scsi_vpd_tpc_descriptor_srt *srt_ptr; struct scsi_vpd_tpc_descriptor_srtd *srtd_ptr; struct scsi_vpd_tpc_descriptor_gco *gco_ptr; int data_len; data_len = sizeof(struct scsi_vpd_tpc) + sizeof(struct scsi_vpd_tpc_descriptor_bdrl) + roundup2(sizeof(struct scsi_vpd_tpc_descriptor_sc) + 2 * sizeof(struct scsi_vpd_tpc_descriptor_sc_descr) + 11, 4) + sizeof(struct scsi_vpd_tpc_descriptor_pd) + roundup2(sizeof(struct scsi_vpd_tpc_descriptor_sd) + 4, 4) + roundup2(sizeof(struct scsi_vpd_tpc_descriptor_sdid) + 2, 4) + sizeof(struct scsi_vpd_tpc_descriptor_rtf) + sizeof(struct scsi_vpd_tpc_descriptor_rtf_block) + sizeof(struct scsi_vpd_tpc_descriptor_srt) + 2*sizeof(struct scsi_vpd_tpc_descriptor_srtd) + sizeof(struct scsi_vpd_tpc_descriptor_gco); ctsio->kern_data_ptr = malloc(data_len, M_CTL, M_WAITOK | M_ZERO); tpc_ptr = (struct scsi_vpd_tpc *)ctsio->kern_data_ptr; ctsio->kern_rel_offset = 0; ctsio->kern_sg_entries = 0; ctsio->kern_data_len = min(data_len, alloc_len); ctsio->kern_total_len = ctsio->kern_data_len; /* * The control device is always connected. The disk device, on the * other hand, may not be online all the time. */ if (lun != NULL) tpc_ptr->device = (SID_QUAL_LU_CONNECTED << 5) | lun->be_lun->lun_type; else tpc_ptr->device = (SID_QUAL_LU_OFFLINE << 5) | T_DIRECT; tpc_ptr->page_code = SVPD_SCSI_TPC; scsi_ulto2b(data_len - 4, tpc_ptr->page_length); /* Block Device ROD Limits */ d_ptr = (struct scsi_vpd_tpc_descriptor *)&tpc_ptr->descr[0]; bdrl_ptr = (struct scsi_vpd_tpc_descriptor_bdrl *)d_ptr; scsi_ulto2b(SVPD_TPC_BDRL, bdrl_ptr->desc_type); scsi_ulto2b(sizeof(*bdrl_ptr) - 4, bdrl_ptr->desc_length); scsi_ulto2b(TPC_MAX_SEGS, bdrl_ptr->maximum_ranges); scsi_ulto4b(TPC_MAX_TOKEN_TIMEOUT, bdrl_ptr->maximum_inactivity_timeout); scsi_ulto4b(TPC_DFL_TOKEN_TIMEOUT, bdrl_ptr->default_inactivity_timeout); scsi_u64to8b(0, bdrl_ptr->maximum_token_transfer_size); scsi_u64to8b(0, bdrl_ptr->optimal_transfer_count); /* Supported commands */ d_ptr = (struct scsi_vpd_tpc_descriptor *) (&d_ptr->parameters[0] + scsi_2btoul(d_ptr->desc_length)); sc_ptr = (struct scsi_vpd_tpc_descriptor_sc *)d_ptr; scsi_ulto2b(SVPD_TPC_SC, sc_ptr->desc_type); sc_ptr->list_length = 2 * sizeof(*scd_ptr) + 11; scsi_ulto2b(roundup2(1 + sc_ptr->list_length, 4), sc_ptr->desc_length); scd_ptr = &sc_ptr->descr[0]; scd_ptr->opcode = EXTENDED_COPY; scd_ptr->sa_length = 5; scd_ptr->supported_service_actions[0] = EC_EC_LID1; scd_ptr->supported_service_actions[1] = EC_EC_LID4; scd_ptr->supported_service_actions[2] = EC_PT; scd_ptr->supported_service_actions[3] = EC_WUT; scd_ptr->supported_service_actions[4] = EC_COA; scd_ptr = (struct scsi_vpd_tpc_descriptor_sc_descr *) &scd_ptr->supported_service_actions[scd_ptr->sa_length]; scd_ptr->opcode = RECEIVE_COPY_STATUS; scd_ptr->sa_length = 6; scd_ptr->supported_service_actions[0] = RCS_RCS_LID1; scd_ptr->supported_service_actions[1] = RCS_RCFD; scd_ptr->supported_service_actions[2] = RCS_RCS_LID4; scd_ptr->supported_service_actions[3] = RCS_RCOP; scd_ptr->supported_service_actions[4] = RCS_RRTI; scd_ptr->supported_service_actions[5] = RCS_RART; /* Parameter data. */ d_ptr = (struct scsi_vpd_tpc_descriptor *) (&d_ptr->parameters[0] + scsi_2btoul(d_ptr->desc_length)); pd_ptr = (struct scsi_vpd_tpc_descriptor_pd *)d_ptr; scsi_ulto2b(SVPD_TPC_PD, pd_ptr->desc_type); scsi_ulto2b(sizeof(*pd_ptr) - 4, pd_ptr->desc_length); scsi_ulto2b(TPC_MAX_CSCDS, pd_ptr->maximum_cscd_descriptor_count); scsi_ulto2b(TPC_MAX_SEGS, pd_ptr->maximum_segment_descriptor_count); scsi_ulto4b(TPC_MAX_LIST, pd_ptr->maximum_descriptor_list_length); scsi_ulto4b(TPC_MAX_INLINE, pd_ptr->maximum_inline_data_length); /* Supported Descriptors */ d_ptr = (struct scsi_vpd_tpc_descriptor *) (&d_ptr->parameters[0] + scsi_2btoul(d_ptr->desc_length)); sd_ptr = (struct scsi_vpd_tpc_descriptor_sd *)d_ptr; scsi_ulto2b(SVPD_TPC_SD, sd_ptr->desc_type); scsi_ulto2b(roundup2(sizeof(*sd_ptr) - 4 + 4, 4), sd_ptr->desc_length); sd_ptr->list_length = 4; sd_ptr->supported_descriptor_codes[0] = EC_SEG_B2B; sd_ptr->supported_descriptor_codes[1] = EC_SEG_VERIFY; sd_ptr->supported_descriptor_codes[2] = EC_SEG_REGISTER_KEY; sd_ptr->supported_descriptor_codes[3] = EC_CSCD_ID; /* Supported CSCD Descriptor IDs */ d_ptr = (struct scsi_vpd_tpc_descriptor *) (&d_ptr->parameters[0] + scsi_2btoul(d_ptr->desc_length)); sdid_ptr = (struct scsi_vpd_tpc_descriptor_sdid *)d_ptr; scsi_ulto2b(SVPD_TPC_SDID, sdid_ptr->desc_type); scsi_ulto2b(roundup2(sizeof(*sdid_ptr) - 4 + 2, 4), sdid_ptr->desc_length); scsi_ulto2b(2, sdid_ptr->list_length); scsi_ulto2b(0xffff, &sdid_ptr->supported_descriptor_ids[0]); /* ROD Token Features */ d_ptr = (struct scsi_vpd_tpc_descriptor *) (&d_ptr->parameters[0] + scsi_2btoul(d_ptr->desc_length)); rtf_ptr = (struct scsi_vpd_tpc_descriptor_rtf *)d_ptr; scsi_ulto2b(SVPD_TPC_RTF, rtf_ptr->desc_type); scsi_ulto2b(sizeof(*rtf_ptr) - 4 + sizeof(*rtfb_ptr), rtf_ptr->desc_length); rtf_ptr->remote_tokens = 0; scsi_ulto4b(TPC_MIN_TOKEN_TIMEOUT, rtf_ptr->minimum_token_lifetime); scsi_ulto4b(UINT32_MAX, rtf_ptr->maximum_token_lifetime); scsi_ulto4b(TPC_MAX_TOKEN_TIMEOUT, rtf_ptr->maximum_token_inactivity_timeout); scsi_ulto2b(sizeof(*rtfb_ptr), rtf_ptr->type_specific_features_length); rtfb_ptr = (struct scsi_vpd_tpc_descriptor_rtf_block *) &rtf_ptr->type_specific_features; rtfb_ptr->type_format = SVPD_TPC_RTF_BLOCK; scsi_ulto2b(sizeof(*rtfb_ptr) - 4, rtfb_ptr->desc_length); scsi_ulto2b(0, rtfb_ptr->optimal_length_granularity); scsi_u64to8b(0, rtfb_ptr->maximum_bytes); scsi_u64to8b(0, rtfb_ptr->optimal_bytes); scsi_u64to8b(UINT64_MAX, rtfb_ptr->optimal_bytes_to_token_per_segment); scsi_u64to8b(TPC_MAX_IOCHUNK_SIZE, rtfb_ptr->optimal_bytes_from_token_per_segment); /* Supported ROD Tokens */ d_ptr = (struct scsi_vpd_tpc_descriptor *) (&d_ptr->parameters[0] + scsi_2btoul(d_ptr->desc_length)); srt_ptr = (struct scsi_vpd_tpc_descriptor_srt *)d_ptr; scsi_ulto2b(SVPD_TPC_SRT, srt_ptr->desc_type); scsi_ulto2b(sizeof(*srt_ptr) - 4 + 2*sizeof(*srtd_ptr), srt_ptr->desc_length); scsi_ulto2b(2*sizeof(*srtd_ptr), srt_ptr->rod_type_descriptors_length); srtd_ptr = (struct scsi_vpd_tpc_descriptor_srtd *) &srt_ptr->rod_type_descriptors; scsi_ulto4b(ROD_TYPE_AUR, srtd_ptr->rod_type); srtd_ptr->flags = SVPD_TPC_SRTD_TIN | SVPD_TPC_SRTD_TOUT; scsi_ulto2b(0, srtd_ptr->preference_indicator); srtd_ptr++; scsi_ulto4b(ROD_TYPE_BLOCK_ZERO, srtd_ptr->rod_type); srtd_ptr->flags = SVPD_TPC_SRTD_TIN; scsi_ulto2b(0, srtd_ptr->preference_indicator); /* General Copy Operations */ d_ptr = (struct scsi_vpd_tpc_descriptor *) (&d_ptr->parameters[0] + scsi_2btoul(d_ptr->desc_length)); gco_ptr = (struct scsi_vpd_tpc_descriptor_gco *)d_ptr; scsi_ulto2b(SVPD_TPC_GCO, gco_ptr->desc_type); scsi_ulto2b(sizeof(*gco_ptr) - 4, gco_ptr->desc_length); scsi_ulto4b(TPC_MAX_LISTS, gco_ptr->total_concurrent_copies); scsi_ulto4b(TPC_MAX_LISTS, gco_ptr->maximum_identified_concurrent_copies); scsi_ulto4b(TPC_MAX_SEG, gco_ptr->maximum_segment_length); gco_ptr->data_segment_granularity = 0; gco_ptr->inline_data_granularity = 0; ctl_set_success(ctsio); ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } int ctl_receive_copy_operating_parameters(struct ctl_scsiio *ctsio) { struct scsi_receive_copy_operating_parameters *cdb; struct scsi_receive_copy_operating_parameters_data *data; int retval; int alloc_len, total_len; CTL_DEBUG_PRINT(("ctl_report_supported_tmf\n")); cdb = (struct scsi_receive_copy_operating_parameters *)ctsio->cdb; retval = CTL_RETVAL_COMPLETE; total_len = sizeof(*data) + 4; alloc_len = scsi_4btoul(cdb->length); ctsio->kern_data_ptr = malloc(total_len, M_CTL, M_WAITOK | M_ZERO); ctsio->kern_sg_entries = 0; ctsio->kern_rel_offset = 0; ctsio->kern_data_len = min(total_len, alloc_len); ctsio->kern_total_len = ctsio->kern_data_len; data = (struct scsi_receive_copy_operating_parameters_data *)ctsio->kern_data_ptr; scsi_ulto4b(sizeof(*data) - 4 + 4, data->length); data->snlid = RCOP_SNLID; scsi_ulto2b(TPC_MAX_CSCDS, data->maximum_cscd_descriptor_count); scsi_ulto2b(TPC_MAX_SEGS, data->maximum_segment_descriptor_count); scsi_ulto4b(TPC_MAX_LIST, data->maximum_descriptor_list_length); scsi_ulto4b(TPC_MAX_SEG, data->maximum_segment_length); scsi_ulto4b(TPC_MAX_INLINE, data->maximum_inline_data_length); scsi_ulto4b(0, data->held_data_limit); scsi_ulto4b(0, data->maximum_stream_device_transfer_size); scsi_ulto2b(TPC_MAX_LISTS, data->total_concurrent_copies); data->maximum_concurrent_copies = TPC_MAX_LISTS; data->data_segment_granularity = 0; data->inline_data_granularity = 0; data->held_data_granularity = 0; data->implemented_descriptor_list_length = 4; data->list_of_implemented_descriptor_type_codes[0] = EC_SEG_B2B; data->list_of_implemented_descriptor_type_codes[1] = EC_SEG_VERIFY; data->list_of_implemented_descriptor_type_codes[2] = EC_SEG_REGISTER_KEY; data->list_of_implemented_descriptor_type_codes[3] = EC_CSCD_ID; ctl_set_success(ctsio); ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (retval); } static struct tpc_list * tpc_find_list(struct ctl_lun *lun, uint32_t list_id, uint32_t init_idx) { struct tpc_list *list; mtx_assert(&lun->lun_lock, MA_OWNED); TAILQ_FOREACH(list, &lun->tpc_lists, links) { if ((list->flags & EC_LIST_ID_USAGE_MASK) != EC_LIST_ID_USAGE_NONE && list->list_id == list_id && list->init_idx == init_idx) break; } return (list); } int ctl_receive_copy_status_lid1(struct ctl_scsiio *ctsio) { struct ctl_lun *lun = CTL_LUN(ctsio); struct scsi_receive_copy_status_lid1 *cdb; struct scsi_receive_copy_status_lid1_data *data; struct tpc_list *list; struct tpc_list list_copy; int retval; int alloc_len, total_len; uint32_t list_id; CTL_DEBUG_PRINT(("ctl_receive_copy_status_lid1\n")); cdb = (struct scsi_receive_copy_status_lid1 *)ctsio->cdb; retval = CTL_RETVAL_COMPLETE; list_id = cdb->list_identifier; mtx_lock(&lun->lun_lock); list = tpc_find_list(lun, list_id, ctl_get_initindex(&ctsio->io_hdr.nexus)); if (list == NULL) { mtx_unlock(&lun->lun_lock); ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 2, /*bit_valid*/ 0, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); return (retval); } list_copy = *list; if (list->completed) { TAILQ_REMOVE(&lun->tpc_lists, list, links); free(list, M_CTL); } mtx_unlock(&lun->lun_lock); total_len = sizeof(*data); alloc_len = scsi_4btoul(cdb->length); ctsio->kern_data_ptr = malloc(total_len, M_CTL, M_WAITOK | M_ZERO); ctsio->kern_sg_entries = 0; ctsio->kern_rel_offset = 0; ctsio->kern_data_len = min(total_len, alloc_len); ctsio->kern_total_len = ctsio->kern_data_len; data = (struct scsi_receive_copy_status_lid1_data *)ctsio->kern_data_ptr; scsi_ulto4b(sizeof(*data) - 4, data->available_data); if (list_copy.completed) { if (list_copy.error || list_copy.abort) data->copy_command_status = RCS_CCS_ERROR; else data->copy_command_status = RCS_CCS_COMPLETED; } else data->copy_command_status = RCS_CCS_INPROG; scsi_ulto2b(list_copy.curseg, data->segments_processed); if (list_copy.curbytes <= UINT32_MAX) { data->transfer_count_units = RCS_TC_BYTES; scsi_ulto4b(list_copy.curbytes, data->transfer_count); } else { data->transfer_count_units = RCS_TC_MBYTES; scsi_ulto4b(list_copy.curbytes >> 20, data->transfer_count); } ctl_set_success(ctsio); ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (retval); } int ctl_receive_copy_failure_details(struct ctl_scsiio *ctsio) { struct ctl_lun *lun = CTL_LUN(ctsio); struct scsi_receive_copy_failure_details *cdb; struct scsi_receive_copy_failure_details_data *data; struct tpc_list *list; struct tpc_list list_copy; int retval; int alloc_len, total_len; uint32_t list_id; CTL_DEBUG_PRINT(("ctl_receive_copy_failure_details\n")); cdb = (struct scsi_receive_copy_failure_details *)ctsio->cdb; retval = CTL_RETVAL_COMPLETE; list_id = cdb->list_identifier; mtx_lock(&lun->lun_lock); list = tpc_find_list(lun, list_id, ctl_get_initindex(&ctsio->io_hdr.nexus)); if (list == NULL || !list->completed) { mtx_unlock(&lun->lun_lock); ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 2, /*bit_valid*/ 0, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); return (retval); } list_copy = *list; TAILQ_REMOVE(&lun->tpc_lists, list, links); free(list, M_CTL); mtx_unlock(&lun->lun_lock); total_len = sizeof(*data) + list_copy.sense_len; alloc_len = scsi_4btoul(cdb->length); ctsio->kern_data_ptr = malloc(total_len, M_CTL, M_WAITOK | M_ZERO); ctsio->kern_sg_entries = 0; ctsio->kern_rel_offset = 0; ctsio->kern_data_len = min(total_len, alloc_len); ctsio->kern_total_len = ctsio->kern_data_len; data = (struct scsi_receive_copy_failure_details_data *)ctsio->kern_data_ptr; if (list_copy.completed && (list_copy.error || list_copy.abort)) { scsi_ulto4b(sizeof(*data) - 4 + list_copy.sense_len, data->available_data); data->copy_command_status = RCS_CCS_ERROR; } else scsi_ulto4b(0, data->available_data); scsi_ulto2b(list_copy.sense_len, data->sense_data_length); memcpy(data->sense_data, &list_copy.sense_data, list_copy.sense_len); ctl_set_success(ctsio); ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (retval); } int ctl_receive_copy_status_lid4(struct ctl_scsiio *ctsio) { struct ctl_lun *lun = CTL_LUN(ctsio); struct scsi_receive_copy_status_lid4 *cdb; struct scsi_receive_copy_status_lid4_data *data; struct tpc_list *list; struct tpc_list list_copy; int retval; int alloc_len, total_len; uint32_t list_id; CTL_DEBUG_PRINT(("ctl_receive_copy_status_lid4\n")); cdb = (struct scsi_receive_copy_status_lid4 *)ctsio->cdb; retval = CTL_RETVAL_COMPLETE; list_id = scsi_4btoul(cdb->list_identifier); mtx_lock(&lun->lun_lock); list = tpc_find_list(lun, list_id, ctl_get_initindex(&ctsio->io_hdr.nexus)); if (list == NULL) { mtx_unlock(&lun->lun_lock); ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 2, /*bit_valid*/ 0, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); return (retval); } list_copy = *list; if (list->completed) { TAILQ_REMOVE(&lun->tpc_lists, list, links); free(list, M_CTL); } mtx_unlock(&lun->lun_lock); total_len = sizeof(*data) + list_copy.sense_len; alloc_len = scsi_4btoul(cdb->length); ctsio->kern_data_ptr = malloc(total_len, M_CTL, M_WAITOK | M_ZERO); ctsio->kern_sg_entries = 0; ctsio->kern_rel_offset = 0; ctsio->kern_data_len = min(total_len, alloc_len); ctsio->kern_total_len = ctsio->kern_data_len; data = (struct scsi_receive_copy_status_lid4_data *)ctsio->kern_data_ptr; scsi_ulto4b(sizeof(*data) - 4 + list_copy.sense_len, data->available_data); data->response_to_service_action = list_copy.service_action; if (list_copy.completed) { if (list_copy.error) data->copy_command_status = RCS_CCS_ERROR; else if (list_copy.abort) data->copy_command_status = RCS_CCS_ABORTED; else data->copy_command_status = RCS_CCS_COMPLETED; } else data->copy_command_status = RCS_CCS_INPROG_FG; scsi_ulto2b(list_copy.curops, data->operation_counter); scsi_ulto4b(UINT32_MAX, data->estimated_status_update_delay); data->transfer_count_units = RCS_TC_BYTES; scsi_u64to8b(list_copy.curbytes, data->transfer_count); scsi_ulto2b(list_copy.curseg, data->segments_processed); data->length_of_the_sense_data_field = list_copy.sense_len; data->sense_data_length = list_copy.sense_len; memcpy(data->sense_data, &list_copy.sense_data, list_copy.sense_len); ctl_set_success(ctsio); ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (retval); } int ctl_copy_operation_abort(struct ctl_scsiio *ctsio) { struct ctl_lun *lun = CTL_LUN(ctsio); struct scsi_copy_operation_abort *cdb; struct tpc_list *list; int retval; uint32_t list_id; CTL_DEBUG_PRINT(("ctl_copy_operation_abort\n")); cdb = (struct scsi_copy_operation_abort *)ctsio->cdb; retval = CTL_RETVAL_COMPLETE; list_id = scsi_4btoul(cdb->list_identifier); mtx_lock(&lun->lun_lock); list = tpc_find_list(lun, list_id, ctl_get_initindex(&ctsio->io_hdr.nexus)); if (list == NULL) { mtx_unlock(&lun->lun_lock); ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 2, /*bit_valid*/ 0, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); return (retval); } list->abort = 1; mtx_unlock(&lun->lun_lock); ctl_set_success(ctsio); ctl_done((union ctl_io *)ctsio); return (retval); } static uint64_t tpc_resolve(struct tpc_list *list, uint16_t idx, uint32_t *ss, uint32_t *pb, uint32_t *pbo) { if (idx == 0xffff) { if (ss) *ss = list->lun->be_lun->blocksize; if (pb) *pb = list->lun->be_lun->blocksize << list->lun->be_lun->pblockexp; if (pbo) *pbo = list->lun->be_lun->blocksize * list->lun->be_lun->pblockoff; return (list->lun->lun); } if (idx >= list->ncscd) return (UINT64_MAX); return (tpcl_resolve(list->lun->ctl_softc, list->init_port, &list->cscd[idx], ss, pb, pbo)); } static void tpc_set_io_error_sense(struct tpc_list *list) { int flen; uint8_t csi[4]; uint8_t sks[3]; uint8_t fbuf[4 + 64]; scsi_ulto4b(list->curseg, csi); if (list->fwd_cscd <= 0x07ff) { sks[0] = SSD_SKS_SEGMENT_VALID; scsi_ulto2b((uint8_t *)&list->cscd[list->fwd_cscd] - list->params, &sks[1]); } else sks[0] = 0; if (list->fwd_scsi_status) { fbuf[0] = 0x0c; fbuf[2] = list->fwd_target; flen = list->fwd_sense_len; if (flen > 64) { flen = 64; fbuf[2] |= SSD_FORWARDED_FSDT; } fbuf[1] = 2 + flen; fbuf[3] = list->fwd_scsi_status; bcopy(&list->fwd_sense_data, &fbuf[4], flen); flen += 4; } else flen = 0; ctl_set_sense(list->ctsio, /*current_error*/ 1, /*sense_key*/ SSD_KEY_COPY_ABORTED, /*asc*/ 0x0d, /*ascq*/ 0x01, SSD_ELEM_COMMAND, sizeof(csi), csi, sks[0] ? SSD_ELEM_SKS : SSD_ELEM_SKIP, sizeof(sks), sks, flen ? SSD_ELEM_DESC : SSD_ELEM_SKIP, flen, fbuf, SSD_ELEM_NONE); } static int tpc_process_b2b(struct tpc_list *list) { struct scsi_ec_segment_b2b *seg; struct scsi_ec_cscd_dtsp *sdstp, *ddstp; struct tpc_io *tior, *tiow; struct runl run; uint64_t sl, dl; off_t srclba, dstlba, numbytes, donebytes, roundbytes; int numlba; uint32_t srcblock, dstblock, pb, pbo, adj; uint16_t scscd, dcscd; uint8_t csi[4]; scsi_ulto4b(list->curseg, csi); if (list->stage == 1) { while ((tior = TAILQ_FIRST(&list->allio)) != NULL) { TAILQ_REMOVE(&list->allio, tior, links); ctl_free_io(tior->io); free(tior->buf, M_CTL); free(tior, M_CTL); } if (list->abort) { ctl_set_task_aborted(list->ctsio); return (CTL_RETVAL_ERROR); } else if (list->error) { tpc_set_io_error_sense(list); return (CTL_RETVAL_ERROR); } list->cursectors += list->segsectors; list->curbytes += list->segbytes; return (CTL_RETVAL_COMPLETE); } TAILQ_INIT(&list->allio); seg = (struct scsi_ec_segment_b2b *)list->seg[list->curseg]; scscd = scsi_2btoul(seg->src_cscd); dcscd = scsi_2btoul(seg->dst_cscd); sl = tpc_resolve(list, scscd, &srcblock, NULL, NULL); dl = tpc_resolve(list, dcscd, &dstblock, &pb, &pbo); if (sl == UINT64_MAX || dl == UINT64_MAX) { ctl_set_sense(list->ctsio, /*current_error*/ 1, /*sense_key*/ SSD_KEY_COPY_ABORTED, /*asc*/ 0x08, /*ascq*/ 0x04, SSD_ELEM_COMMAND, sizeof(csi), csi, SSD_ELEM_NONE); return (CTL_RETVAL_ERROR); } if (pbo > 0) pbo = pb - pbo; sdstp = &list->cscd[scscd].dtsp; if (scsi_3btoul(sdstp->block_length) != 0) srcblock = scsi_3btoul(sdstp->block_length); ddstp = &list->cscd[dcscd].dtsp; if (scsi_3btoul(ddstp->block_length) != 0) dstblock = scsi_3btoul(ddstp->block_length); numlba = scsi_2btoul(seg->number_of_blocks); if (seg->flags & EC_SEG_DC) numbytes = (off_t)numlba * dstblock; else numbytes = (off_t)numlba * srcblock; srclba = scsi_8btou64(seg->src_lba); dstlba = scsi_8btou64(seg->dst_lba); // printf("Copy %ju bytes from %ju @ %ju to %ju @ %ju\n", // (uintmax_t)numbytes, sl, scsi_8btou64(seg->src_lba), // dl, scsi_8btou64(seg->dst_lba)); if (numbytes == 0) return (CTL_RETVAL_COMPLETE); if (numbytes % srcblock != 0 || numbytes % dstblock != 0) { ctl_set_sense(list->ctsio, /*current_error*/ 1, /*sense_key*/ SSD_KEY_COPY_ABORTED, /*asc*/ 0x26, /*ascq*/ 0x0A, SSD_ELEM_COMMAND, sizeof(csi), csi, SSD_ELEM_NONE); return (CTL_RETVAL_ERROR); } list->segbytes = numbytes; list->segsectors = numbytes / dstblock; donebytes = 0; TAILQ_INIT(&run); list->tbdio = 0; while (donebytes < numbytes) { roundbytes = numbytes - donebytes; if (roundbytes > TPC_MAX_IO_SIZE) { roundbytes = TPC_MAX_IO_SIZE; roundbytes -= roundbytes % dstblock; if (pb > dstblock) { adj = (dstlba * dstblock + roundbytes - pbo) % pb; if (roundbytes > adj) roundbytes -= adj; } } tior = malloc(sizeof(*tior), M_CTL, M_WAITOK | M_ZERO); TAILQ_INIT(&tior->run); tior->buf = malloc(roundbytes, M_CTL, M_WAITOK); tior->list = list; TAILQ_INSERT_TAIL(&list->allio, tior, links); tior->io = tpcl_alloc_io(); ctl_scsi_read_write(tior->io, /*data_ptr*/ tior->buf, /*data_len*/ roundbytes, /*read_op*/ 1, /*byte2*/ 0, /*minimum_cdb_size*/ 0, /*lba*/ srclba, /*num_blocks*/ roundbytes / srcblock, /*tag_type*/ CTL_TAG_SIMPLE, /*control*/ 0); tior->io->io_hdr.retries = 3; tior->target = SSD_FORWARDED_SDS_EXSRC; tior->cscd = scscd; tior->lun = sl; tior->io->io_hdr.ctl_private[CTL_PRIV_FRONTEND].ptr = tior; tiow = malloc(sizeof(*tior), M_CTL, M_WAITOK | M_ZERO); TAILQ_INIT(&tiow->run); tiow->list = list; TAILQ_INSERT_TAIL(&list->allio, tiow, links); tiow->io = tpcl_alloc_io(); ctl_scsi_read_write(tiow->io, /*data_ptr*/ tior->buf, /*data_len*/ roundbytes, /*read_op*/ 0, /*byte2*/ 0, /*minimum_cdb_size*/ 0, /*lba*/ dstlba, /*num_blocks*/ roundbytes / dstblock, /*tag_type*/ CTL_TAG_SIMPLE, /*control*/ 0); tiow->io->io_hdr.retries = 3; tiow->target = SSD_FORWARDED_SDS_EXDST; tiow->cscd = dcscd; tiow->lun = dl; tiow->io->io_hdr.ctl_private[CTL_PRIV_FRONTEND].ptr = tiow; TAILQ_INSERT_TAIL(&tior->run, tiow, rlinks); TAILQ_INSERT_TAIL(&run, tior, rlinks); list->tbdio++; donebytes += roundbytes; srclba += roundbytes / srcblock; dstlba += roundbytes / dstblock; } while ((tior = TAILQ_FIRST(&run)) != NULL) { TAILQ_REMOVE(&run, tior, rlinks); if (tpcl_queue(tior->io, tior->lun) != CTL_RETVAL_COMPLETE) panic("tpcl_queue() error"); } list->stage++; return (CTL_RETVAL_QUEUED); } static int tpc_process_verify(struct tpc_list *list) { struct scsi_ec_segment_verify *seg; struct tpc_io *tio; uint64_t sl; uint16_t cscd; uint8_t csi[4]; scsi_ulto4b(list->curseg, csi); if (list->stage == 1) { while ((tio = TAILQ_FIRST(&list->allio)) != NULL) { TAILQ_REMOVE(&list->allio, tio, links); ctl_free_io(tio->io); free(tio, M_CTL); } if (list->abort) { ctl_set_task_aborted(list->ctsio); return (CTL_RETVAL_ERROR); } else if (list->error) { tpc_set_io_error_sense(list); return (CTL_RETVAL_ERROR); } else return (CTL_RETVAL_COMPLETE); } TAILQ_INIT(&list->allio); seg = (struct scsi_ec_segment_verify *)list->seg[list->curseg]; cscd = scsi_2btoul(seg->src_cscd); sl = tpc_resolve(list, cscd, NULL, NULL, NULL); if (sl == UINT64_MAX) { ctl_set_sense(list->ctsio, /*current_error*/ 1, /*sense_key*/ SSD_KEY_COPY_ABORTED, /*asc*/ 0x08, /*ascq*/ 0x04, SSD_ELEM_COMMAND, sizeof(csi), csi, SSD_ELEM_NONE); return (CTL_RETVAL_ERROR); } // printf("Verify %ju\n", sl); if ((seg->tur & 0x01) == 0) return (CTL_RETVAL_COMPLETE); list->tbdio = 1; tio = malloc(sizeof(*tio), M_CTL, M_WAITOK | M_ZERO); TAILQ_INIT(&tio->run); tio->list = list; TAILQ_INSERT_TAIL(&list->allio, tio, links); tio->io = tpcl_alloc_io(); ctl_scsi_tur(tio->io, /*tag_type*/ CTL_TAG_SIMPLE, /*control*/ 0); tio->io->io_hdr.retries = 3; tio->target = SSD_FORWARDED_SDS_EXSRC; tio->cscd = cscd; tio->lun = sl; tio->io->io_hdr.ctl_private[CTL_PRIV_FRONTEND].ptr = tio; list->stage++; if (tpcl_queue(tio->io, tio->lun) != CTL_RETVAL_COMPLETE) panic("tpcl_queue() error"); return (CTL_RETVAL_QUEUED); } static int tpc_process_register_key(struct tpc_list *list) { struct scsi_ec_segment_register_key *seg; struct tpc_io *tio; uint64_t dl; int datalen; uint16_t cscd; uint8_t csi[4]; scsi_ulto4b(list->curseg, csi); if (list->stage == 1) { while ((tio = TAILQ_FIRST(&list->allio)) != NULL) { TAILQ_REMOVE(&list->allio, tio, links); ctl_free_io(tio->io); free(tio->buf, M_CTL); free(tio, M_CTL); } if (list->abort) { ctl_set_task_aborted(list->ctsio); return (CTL_RETVAL_ERROR); } else if (list->error) { tpc_set_io_error_sense(list); return (CTL_RETVAL_ERROR); } else return (CTL_RETVAL_COMPLETE); } TAILQ_INIT(&list->allio); seg = (struct scsi_ec_segment_register_key *)list->seg[list->curseg]; cscd = scsi_2btoul(seg->dst_cscd); dl = tpc_resolve(list, cscd, NULL, NULL, NULL); if (dl == UINT64_MAX) { ctl_set_sense(list->ctsio, /*current_error*/ 1, /*sense_key*/ SSD_KEY_COPY_ABORTED, /*asc*/ 0x08, /*ascq*/ 0x04, SSD_ELEM_COMMAND, sizeof(csi), csi, SSD_ELEM_NONE); return (CTL_RETVAL_ERROR); } // printf("Register Key %ju\n", dl); list->tbdio = 1; tio = malloc(sizeof(*tio), M_CTL, M_WAITOK | M_ZERO); TAILQ_INIT(&tio->run); tio->list = list; TAILQ_INSERT_TAIL(&list->allio, tio, links); tio->io = tpcl_alloc_io(); datalen = sizeof(struct scsi_per_res_out_parms); tio->buf = malloc(datalen, M_CTL, M_WAITOK); ctl_scsi_persistent_res_out(tio->io, tio->buf, datalen, SPRO_REGISTER, -1, scsi_8btou64(seg->res_key), scsi_8btou64(seg->sa_res_key), /*tag_type*/ CTL_TAG_SIMPLE, /*control*/ 0); tio->io->io_hdr.retries = 3; tio->target = SSD_FORWARDED_SDS_EXDST; tio->cscd = cscd; tio->lun = dl; tio->io->io_hdr.ctl_private[CTL_PRIV_FRONTEND].ptr = tio; list->stage++; if (tpcl_queue(tio->io, tio->lun) != CTL_RETVAL_COMPLETE) panic("tpcl_queue() error"); return (CTL_RETVAL_QUEUED); } static off_t tpc_ranges_length(struct scsi_range_desc *range, int nrange) { off_t length = 0; int r; for (r = 0; r < nrange; r++) length += scsi_4btoul(range[r].length); return (length); } static int tpc_check_ranges_l(struct scsi_range_desc *range, int nrange, uint64_t maxlba, uint64_t *lba) { uint64_t b1; uint32_t l1; int i; for (i = 0; i < nrange; i++) { b1 = scsi_8btou64(range[i].lba); l1 = scsi_4btoul(range[i].length); if (b1 + l1 < b1 || b1 + l1 > maxlba + 1) { *lba = MAX(b1, maxlba + 1); return (-1); } } return (0); } static int tpc_check_ranges_x(struct scsi_range_desc *range, int nrange) { uint64_t b1, b2; uint32_t l1, l2; int i, j; for (i = 0; i < nrange - 1; i++) { b1 = scsi_8btou64(range[i].lba); l1 = scsi_4btoul(range[i].length); for (j = i + 1; j < nrange; j++) { b2 = scsi_8btou64(range[j].lba); l2 = scsi_4btoul(range[j].length); if (b1 + l1 > b2 && b2 + l2 > b1) return (-1); } } return (0); } static int tpc_skip_ranges(struct scsi_range_desc *range, int nrange, off_t skip, int *srange, off_t *soffset) { off_t off; int r; r = 0; off = 0; while (r < nrange) { if (skip - off < scsi_4btoul(range[r].length)) { *srange = r; *soffset = skip - off; return (0); } off += scsi_4btoul(range[r].length); r++; } return (-1); } static int tpc_process_wut(struct tpc_list *list) { struct tpc_io *tio, *tior, *tiow; struct runl run; int drange, srange; off_t doffset, soffset; off_t srclba, dstlba, numbytes, donebytes, roundbytes; uint32_t srcblock, dstblock, pb, pbo, adj; if (list->stage > 0) { /* Cleanup after previous rounds. */ while ((tio = TAILQ_FIRST(&list->allio)) != NULL) { TAILQ_REMOVE(&list->allio, tio, links); ctl_free_io(tio->io); free(tio->buf, M_CTL); free(tio, M_CTL); } if (list->abort) { ctl_set_task_aborted(list->ctsio); return (CTL_RETVAL_ERROR); } else if (list->error) { if (list->fwd_scsi_status) { list->ctsio->io_hdr.status = CTL_SCSI_ERROR | CTL_AUTOSENSE; list->ctsio->scsi_status = list->fwd_scsi_status; list->ctsio->sense_data = list->fwd_sense_data; list->ctsio->sense_len = list->fwd_sense_len; } else { ctl_set_invalid_field(list->ctsio, /*sks_valid*/ 0, /*command*/ 0, /*field*/ 0, /*bit_valid*/ 0, /*bit*/ 0); } return (CTL_RETVAL_ERROR); } list->cursectors += list->segsectors; list->curbytes += list->segbytes; } /* Check where we are on destination ranges list. */ if (tpc_skip_ranges(list->range, list->nrange, list->cursectors, &drange, &doffset) != 0) return (CTL_RETVAL_COMPLETE); dstblock = list->lun->be_lun->blocksize; pb = dstblock << list->lun->be_lun->pblockexp; if (list->lun->be_lun->pblockoff > 0) pbo = pb - dstblock * list->lun->be_lun->pblockoff; else pbo = 0; /* Check where we are on source ranges list. */ srcblock = list->token->blocksize; if (tpc_skip_ranges(list->token->range, list->token->nrange, list->offset_into_rod + list->cursectors * dstblock / srcblock, &srange, &soffset) != 0) { ctl_set_invalid_field(list->ctsio, /*sks_valid*/ 0, /*command*/ 0, /*field*/ 0, /*bit_valid*/ 0, /*bit*/ 0); return (CTL_RETVAL_ERROR); } srclba = scsi_8btou64(list->token->range[srange].lba) + soffset; dstlba = scsi_8btou64(list->range[drange].lba) + doffset; numbytes = srcblock * (scsi_4btoul(list->token->range[srange].length) - soffset); numbytes = omin(numbytes, dstblock * (scsi_4btoul(list->range[drange].length) - doffset)); if (numbytes > TPC_MAX_IOCHUNK_SIZE) { numbytes = TPC_MAX_IOCHUNK_SIZE; numbytes -= numbytes % dstblock; if (pb > dstblock) { adj = (dstlba * dstblock + numbytes - pbo) % pb; if (numbytes > adj) numbytes -= adj; } } if (numbytes % srcblock != 0 || numbytes % dstblock != 0) { ctl_set_invalid_field(list->ctsio, /*sks_valid*/ 0, /*command*/ 0, /*field*/ 0, /*bit_valid*/ 0, /*bit*/ 0); return (CTL_RETVAL_ERROR); } list->segbytes = numbytes; list->segsectors = numbytes / dstblock; //printf("Copy chunk of %ju sectors from %ju to %ju\n", list->segsectors, // srclba, dstlba); donebytes = 0; TAILQ_INIT(&run); list->tbdio = 0; TAILQ_INIT(&list->allio); while (donebytes < numbytes) { roundbytes = numbytes - donebytes; if (roundbytes > TPC_MAX_IO_SIZE) { roundbytes = TPC_MAX_IO_SIZE; roundbytes -= roundbytes % dstblock; if (pb > dstblock) { adj = (dstlba * dstblock + roundbytes - pbo) % pb; if (roundbytes > adj) roundbytes -= adj; } } tior = malloc(sizeof(*tior), M_CTL, M_WAITOK | M_ZERO); TAILQ_INIT(&tior->run); tior->buf = malloc(roundbytes, M_CTL, M_WAITOK); tior->list = list; TAILQ_INSERT_TAIL(&list->allio, tior, links); tior->io = tpcl_alloc_io(); ctl_scsi_read_write(tior->io, /*data_ptr*/ tior->buf, /*data_len*/ roundbytes, /*read_op*/ 1, /*byte2*/ 0, /*minimum_cdb_size*/ 0, /*lba*/ srclba, /*num_blocks*/ roundbytes / srcblock, /*tag_type*/ CTL_TAG_SIMPLE, /*control*/ 0); tior->io->io_hdr.retries = 3; tior->lun = list->token->lun; tior->io->io_hdr.ctl_private[CTL_PRIV_FRONTEND].ptr = tior; tiow = malloc(sizeof(*tiow), M_CTL, M_WAITOK | M_ZERO); TAILQ_INIT(&tiow->run); tiow->list = list; TAILQ_INSERT_TAIL(&list->allio, tiow, links); tiow->io = tpcl_alloc_io(); ctl_scsi_read_write(tiow->io, /*data_ptr*/ tior->buf, /*data_len*/ roundbytes, /*read_op*/ 0, /*byte2*/ 0, /*minimum_cdb_size*/ 0, /*lba*/ dstlba, /*num_blocks*/ roundbytes / dstblock, /*tag_type*/ CTL_TAG_SIMPLE, /*control*/ 0); tiow->io->io_hdr.retries = 3; tiow->lun = list->lun->lun; tiow->io->io_hdr.ctl_private[CTL_PRIV_FRONTEND].ptr = tiow; TAILQ_INSERT_TAIL(&tior->run, tiow, rlinks); TAILQ_INSERT_TAIL(&run, tior, rlinks); list->tbdio++; donebytes += roundbytes; srclba += roundbytes / srcblock; dstlba += roundbytes / dstblock; } while ((tior = TAILQ_FIRST(&run)) != NULL) { TAILQ_REMOVE(&run, tior, rlinks); if (tpcl_queue(tior->io, tior->lun) != CTL_RETVAL_COMPLETE) panic("tpcl_queue() error"); } list->stage++; return (CTL_RETVAL_QUEUED); } static int tpc_process_zero_wut(struct tpc_list *list) { struct tpc_io *tio, *tiow; struct runl run, *prun; int r; uint32_t dstblock, len; if (list->stage > 0) { complete: /* Cleanup after previous rounds. */ while ((tio = TAILQ_FIRST(&list->allio)) != NULL) { TAILQ_REMOVE(&list->allio, tio, links); ctl_free_io(tio->io); free(tio, M_CTL); } if (list->abort) { ctl_set_task_aborted(list->ctsio); return (CTL_RETVAL_ERROR); } else if (list->error) { if (list->fwd_scsi_status) { list->ctsio->io_hdr.status = CTL_SCSI_ERROR | CTL_AUTOSENSE; list->ctsio->scsi_status = list->fwd_scsi_status; list->ctsio->sense_data = list->fwd_sense_data; list->ctsio->sense_len = list->fwd_sense_len; } else { ctl_set_invalid_field(list->ctsio, /*sks_valid*/ 0, /*command*/ 0, /*field*/ 0, /*bit_valid*/ 0, /*bit*/ 0); } return (CTL_RETVAL_ERROR); } list->cursectors += list->segsectors; list->curbytes += list->segbytes; return (CTL_RETVAL_COMPLETE); } dstblock = list->lun->be_lun->blocksize; TAILQ_INIT(&run); prun = &run; list->tbdio = 1; TAILQ_INIT(&list->allio); list->segsectors = 0; for (r = 0; r < list->nrange; r++) { len = scsi_4btoul(list->range[r].length); if (len == 0) continue; tiow = malloc(sizeof(*tiow), M_CTL, M_WAITOK | M_ZERO); TAILQ_INIT(&tiow->run); tiow->list = list; TAILQ_INSERT_TAIL(&list->allio, tiow, links); tiow->io = tpcl_alloc_io(); ctl_scsi_write_same(tiow->io, /*data_ptr*/ NULL, /*data_len*/ 0, /*byte2*/ SWS_NDOB, /*lba*/ scsi_8btou64(list->range[r].lba), /*num_blocks*/ len, /*tag_type*/ CTL_TAG_SIMPLE, /*control*/ 0); tiow->io->io_hdr.retries = 3; tiow->lun = list->lun->lun; tiow->io->io_hdr.ctl_private[CTL_PRIV_FRONTEND].ptr = tiow; TAILQ_INSERT_TAIL(prun, tiow, rlinks); prun = &tiow->run; list->segsectors += len; } list->segbytes = list->segsectors * dstblock; if (TAILQ_EMPTY(&run)) goto complete; while ((tiow = TAILQ_FIRST(&run)) != NULL) { TAILQ_REMOVE(&run, tiow, rlinks); if (tpcl_queue(tiow->io, tiow->lun) != CTL_RETVAL_COMPLETE) panic("tpcl_queue() error"); } list->stage++; return (CTL_RETVAL_QUEUED); } static void tpc_process(struct tpc_list *list) { struct ctl_lun *lun = list->lun; struct ctl_softc *softc = lun->ctl_softc; struct scsi_ec_segment *seg; struct ctl_scsiio *ctsio = list->ctsio; int retval = CTL_RETVAL_COMPLETE; uint8_t csi[4]; if (list->service_action == EC_WUT) { if (list->token != NULL) retval = tpc_process_wut(list); else retval = tpc_process_zero_wut(list); if (retval == CTL_RETVAL_QUEUED) return; if (retval == CTL_RETVAL_ERROR) { list->error = 1; goto done; } } else { //printf("ZZZ %d cscd, %d segs\n", list->ncscd, list->nseg); while (list->curseg < list->nseg) { seg = list->seg[list->curseg]; switch (seg->type_code) { case EC_SEG_B2B: retval = tpc_process_b2b(list); break; case EC_SEG_VERIFY: retval = tpc_process_verify(list); break; case EC_SEG_REGISTER_KEY: retval = tpc_process_register_key(list); break; default: scsi_ulto4b(list->curseg, csi); ctl_set_sense(ctsio, /*current_error*/ 1, /*sense_key*/ SSD_KEY_COPY_ABORTED, /*asc*/ 0x26, /*ascq*/ 0x09, SSD_ELEM_COMMAND, sizeof(csi), csi, SSD_ELEM_NONE); goto done; } if (retval == CTL_RETVAL_QUEUED) return; if (retval == CTL_RETVAL_ERROR) { list->error = 1; goto done; } list->curseg++; list->stage = 0; } } ctl_set_success(ctsio); done: //printf("ZZZ done\n"); free(list->params, M_CTL); list->params = NULL; if (list->token) { mtx_lock(&softc->tpc_lock); if (--list->token->active == 0) list->token->last_active = time_uptime; mtx_unlock(&softc->tpc_lock); list->token = NULL; } mtx_lock(&lun->lun_lock); if ((list->flags & EC_LIST_ID_USAGE_MASK) == EC_LIST_ID_USAGE_NONE) { TAILQ_REMOVE(&lun->tpc_lists, list, links); free(list, M_CTL); } else { list->completed = 1; list->last_active = time_uptime; list->sense_data = ctsio->sense_data; list->sense_len = ctsio->sense_len; list->scsi_status = ctsio->scsi_status; } mtx_unlock(&lun->lun_lock); ctl_done((union ctl_io *)ctsio); } /* * For any sort of check condition, busy, etc., we just retry. We do not * decrement the retry count for unit attention type errors. These are * normal, and we want to save the retry count for "real" errors. Otherwise, * we could end up with situations where a command will succeed in some * situations and fail in others, depending on whether a unit attention is * pending. Also, some of our error recovery actions, most notably the * LUN reset action, will cause a unit attention. * * We can add more detail here later if necessary. */ static tpc_error_action tpc_checkcond_parse(union ctl_io *io) { tpc_error_action error_action; int error_code, sense_key, asc, ascq; /* * Default to retrying the command. */ error_action = TPC_ERR_RETRY; scsi_extract_sense_len(&io->scsiio.sense_data, io->scsiio.sense_len, &error_code, &sense_key, &asc, &ascq, /*show_errors*/ 1); switch (error_code) { case SSD_DEFERRED_ERROR: case SSD_DESC_DEFERRED_ERROR: error_action |= TPC_ERR_NO_DECREMENT; break; case SSD_CURRENT_ERROR: case SSD_DESC_CURRENT_ERROR: default: switch (sense_key) { case SSD_KEY_UNIT_ATTENTION: error_action |= TPC_ERR_NO_DECREMENT; break; case SSD_KEY_HARDWARE_ERROR: /* * This is our generic "something bad happened" * error code. It often isn't recoverable. */ if ((asc == 0x44) && (ascq == 0x00)) error_action = TPC_ERR_FAIL; break; case SSD_KEY_NOT_READY: /* * If the LUN is powered down, there likely isn't * much point in retrying right now. */ if ((asc == 0x04) && (ascq == 0x02)) error_action = TPC_ERR_FAIL; /* * If the LUN is offline, there probably isn't much * point in retrying, either. */ if ((asc == 0x04) && (ascq == 0x03)) error_action = TPC_ERR_FAIL; break; } } return (error_action); } static tpc_error_action tpc_error_parse(union ctl_io *io) { tpc_error_action error_action = TPC_ERR_RETRY; switch (io->io_hdr.io_type) { case CTL_IO_SCSI: switch (io->io_hdr.status & CTL_STATUS_MASK) { case CTL_SCSI_ERROR: switch (io->scsiio.scsi_status) { case SCSI_STATUS_CHECK_COND: error_action = tpc_checkcond_parse(io); break; default: break; } break; default: break; } break; case CTL_IO_TASK: break; default: panic("%s: invalid ctl_io type %d\n", __func__, io->io_hdr.io_type); break; } return (error_action); } void tpc_done(union ctl_io *io) { struct tpc_io *tio, *tior; /* * Very minimal retry logic. We basically retry if we got an error * back, and the retry count is greater than 0. If we ever want * more sophisticated initiator type behavior, the CAM error * recovery code in ../common might be helpful. */ tio = io->io_hdr.ctl_private[CTL_PRIV_FRONTEND].ptr; if (((io->io_hdr.status & CTL_STATUS_MASK) != CTL_SUCCESS) && (io->io_hdr.retries > 0)) { ctl_io_status old_status; tpc_error_action error_action; error_action = tpc_error_parse(io); switch (error_action & TPC_ERR_MASK) { case TPC_ERR_FAIL: break; case TPC_ERR_RETRY: default: if ((error_action & TPC_ERR_NO_DECREMENT) == 0) io->io_hdr.retries--; old_status = io->io_hdr.status; io->io_hdr.status = CTL_STATUS_NONE; io->io_hdr.flags &= ~CTL_FLAG_ABORT; io->io_hdr.flags &= ~CTL_FLAG_SENT_2OTHER_SC; if (tpcl_queue(io, tio->lun) != CTL_RETVAL_COMPLETE) { - printf("%s: error returned from ctl_queue()!\n", + printf("%s: error returned from tpcl_queue()!\n", __func__); io->io_hdr.status = old_status; } else return; } } if ((io->io_hdr.status & CTL_STATUS_MASK) != CTL_SUCCESS) { tio->list->error = 1; if (io->io_hdr.io_type == CTL_IO_SCSI && (io->io_hdr.status & CTL_STATUS_MASK) == CTL_SCSI_ERROR) { tio->list->fwd_scsi_status = io->scsiio.scsi_status; tio->list->fwd_sense_data = io->scsiio.sense_data; tio->list->fwd_sense_len = io->scsiio.sense_len; tio->list->fwd_target = tio->target; tio->list->fwd_cscd = tio->cscd; } } else atomic_add_int(&tio->list->curops, 1); if (!tio->list->error && !tio->list->abort) { while ((tior = TAILQ_FIRST(&tio->run)) != NULL) { TAILQ_REMOVE(&tio->run, tior, rlinks); atomic_add_int(&tio->list->tbdio, 1); if (tpcl_queue(tior->io, tior->lun) != CTL_RETVAL_COMPLETE) panic("tpcl_queue() error"); } } if (atomic_fetchadd_int(&tio->list->tbdio, -1) == 1) tpc_process(tio->list); } int ctl_extended_copy_lid1(struct ctl_scsiio *ctsio) { struct ctl_lun *lun = CTL_LUN(ctsio); struct scsi_extended_copy *cdb; struct scsi_extended_copy_lid1_data *data; struct scsi_ec_cscd *cscd; struct scsi_ec_segment *seg; struct tpc_list *list, *tlist; uint8_t *ptr; const char *value; int len, off, lencscd, lenseg, leninl, nseg; CTL_DEBUG_PRINT(("ctl_extended_copy_lid1\n")); cdb = (struct scsi_extended_copy *)ctsio->cdb; len = scsi_4btoul(cdb->length); if (len == 0) { ctl_set_success(ctsio); goto done; } if (len < sizeof(struct scsi_extended_copy_lid1_data) || len > sizeof(struct scsi_extended_copy_lid1_data) + TPC_MAX_LIST + TPC_MAX_INLINE) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 9, /*bit_valid*/ 0, /*bit*/ 0); goto done; } /* * If we've got a kernel request that hasn't been malloced yet, * malloc it and tell the caller the data buffer is here. */ if ((ctsio->io_hdr.flags & CTL_FLAG_ALLOCATED) == 0) { ctsio->kern_data_ptr = malloc(len, M_CTL, M_WAITOK); ctsio->kern_data_len = len; ctsio->kern_total_len = len; ctsio->kern_rel_offset = 0; ctsio->kern_sg_entries = 0; ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } data = (struct scsi_extended_copy_lid1_data *)ctsio->kern_data_ptr; lencscd = scsi_2btoul(data->cscd_list_length); lenseg = scsi_4btoul(data->segment_list_length); leninl = scsi_4btoul(data->inline_data_length); if (lencscd > TPC_MAX_CSCDS * sizeof(struct scsi_ec_cscd)) { ctl_set_sense(ctsio, /*current_error*/ 1, /*sense_key*/ SSD_KEY_ILLEGAL_REQUEST, /*asc*/ 0x26, /*ascq*/ 0x06, SSD_ELEM_NONE); goto done; } if (lenseg > TPC_MAX_SEGS * sizeof(struct scsi_ec_segment)) { ctl_set_sense(ctsio, /*current_error*/ 1, /*sense_key*/ SSD_KEY_ILLEGAL_REQUEST, /*asc*/ 0x26, /*ascq*/ 0x08, SSD_ELEM_NONE); goto done; } if (lencscd + lenseg > TPC_MAX_LIST || leninl > TPC_MAX_INLINE || len < sizeof(struct scsi_extended_copy_lid1_data) + lencscd + lenseg + leninl) { ctl_set_param_len_error(ctsio); goto done; } list = malloc(sizeof(struct tpc_list), M_CTL, M_WAITOK | M_ZERO); list->service_action = cdb->service_action; value = dnvlist_get_string(lun->be_lun->options, "insecure_tpc", NULL); if (value != NULL && strcmp(value, "on") == 0) list->init_port = -1; else list->init_port = ctsio->io_hdr.nexus.targ_port; list->init_idx = ctl_get_initindex(&ctsio->io_hdr.nexus); list->list_id = data->list_identifier; list->flags = data->flags; list->params = ctsio->kern_data_ptr; list->cscd = (struct scsi_ec_cscd *)&data->data[0]; ptr = &data->data[0]; for (off = 0; off < lencscd; off += sizeof(struct scsi_ec_cscd)) { cscd = (struct scsi_ec_cscd *)(ptr + off); if (cscd->type_code != EC_CSCD_ID) { free(list, M_CTL); ctl_set_sense(ctsio, /*current_error*/ 1, /*sense_key*/ SSD_KEY_ILLEGAL_REQUEST, /*asc*/ 0x26, /*ascq*/ 0x07, SSD_ELEM_NONE); goto done; } } ptr = &data->data[lencscd]; for (nseg = 0, off = 0; off < lenseg; nseg++) { if (nseg >= TPC_MAX_SEGS) { free(list, M_CTL); ctl_set_sense(ctsio, /*current_error*/ 1, /*sense_key*/ SSD_KEY_ILLEGAL_REQUEST, /*asc*/ 0x26, /*ascq*/ 0x08, SSD_ELEM_NONE); goto done; } seg = (struct scsi_ec_segment *)(ptr + off); if (seg->type_code != EC_SEG_B2B && seg->type_code != EC_SEG_VERIFY && seg->type_code != EC_SEG_REGISTER_KEY) { free(list, M_CTL); ctl_set_sense(ctsio, /*current_error*/ 1, /*sense_key*/ SSD_KEY_ILLEGAL_REQUEST, /*asc*/ 0x26, /*ascq*/ 0x09, SSD_ELEM_NONE); goto done; } list->seg[nseg] = seg; off += sizeof(struct scsi_ec_segment) + scsi_2btoul(seg->descr_length); } list->inl = &data->data[lencscd + lenseg]; list->ncscd = lencscd / sizeof(struct scsi_ec_cscd); list->nseg = nseg; list->leninl = leninl; list->ctsio = ctsio; list->lun = lun; mtx_lock(&lun->lun_lock); if ((list->flags & EC_LIST_ID_USAGE_MASK) != EC_LIST_ID_USAGE_NONE) { tlist = tpc_find_list(lun, list->list_id, list->init_idx); if (tlist != NULL && !tlist->completed) { mtx_unlock(&lun->lun_lock); free(list, M_CTL); ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 0, /*field*/ 0, /*bit_valid*/ 0, /*bit*/ 0); goto done; } if (tlist != NULL) { TAILQ_REMOVE(&lun->tpc_lists, tlist, links); free(tlist, M_CTL); } } TAILQ_INSERT_TAIL(&lun->tpc_lists, list, links); mtx_unlock(&lun->lun_lock); tpc_process(list); return (CTL_RETVAL_COMPLETE); done: if (ctsio->io_hdr.flags & CTL_FLAG_ALLOCATED) { free(ctsio->kern_data_ptr, M_CTL); ctsio->io_hdr.flags &= ~CTL_FLAG_ALLOCATED; } ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } int ctl_extended_copy_lid4(struct ctl_scsiio *ctsio) { struct ctl_lun *lun = CTL_LUN(ctsio); struct scsi_extended_copy *cdb; struct scsi_extended_copy_lid4_data *data; struct scsi_ec_cscd *cscd; struct scsi_ec_segment *seg; struct tpc_list *list, *tlist; uint8_t *ptr; const char *value; int len, off, lencscd, lenseg, leninl, nseg; CTL_DEBUG_PRINT(("ctl_extended_copy_lid4\n")); cdb = (struct scsi_extended_copy *)ctsio->cdb; len = scsi_4btoul(cdb->length); if (len == 0) { ctl_set_success(ctsio); goto done; } if (len < sizeof(struct scsi_extended_copy_lid4_data) || len > sizeof(struct scsi_extended_copy_lid4_data) + TPC_MAX_LIST + TPC_MAX_INLINE) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 9, /*bit_valid*/ 0, /*bit*/ 0); goto done; } /* * If we've got a kernel request that hasn't been malloced yet, * malloc it and tell the caller the data buffer is here. */ if ((ctsio->io_hdr.flags & CTL_FLAG_ALLOCATED) == 0) { ctsio->kern_data_ptr = malloc(len, M_CTL, M_WAITOK); ctsio->kern_data_len = len; ctsio->kern_total_len = len; ctsio->kern_rel_offset = 0; ctsio->kern_sg_entries = 0; ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } data = (struct scsi_extended_copy_lid4_data *)ctsio->kern_data_ptr; lencscd = scsi_2btoul(data->cscd_list_length); lenseg = scsi_2btoul(data->segment_list_length); leninl = scsi_2btoul(data->inline_data_length); if (lencscd > TPC_MAX_CSCDS * sizeof(struct scsi_ec_cscd)) { ctl_set_sense(ctsio, /*current_error*/ 1, /*sense_key*/ SSD_KEY_ILLEGAL_REQUEST, /*asc*/ 0x26, /*ascq*/ 0x06, SSD_ELEM_NONE); goto done; } if (lenseg > TPC_MAX_SEGS * sizeof(struct scsi_ec_segment)) { ctl_set_sense(ctsio, /*current_error*/ 1, /*sense_key*/ SSD_KEY_ILLEGAL_REQUEST, /*asc*/ 0x26, /*ascq*/ 0x08, SSD_ELEM_NONE); goto done; } if (lencscd + lenseg > TPC_MAX_LIST || leninl > TPC_MAX_INLINE || len < sizeof(struct scsi_extended_copy_lid1_data) + lencscd + lenseg + leninl) { ctl_set_param_len_error(ctsio); goto done; } list = malloc(sizeof(struct tpc_list), M_CTL, M_WAITOK | M_ZERO); list->service_action = cdb->service_action; value = dnvlist_get_string(lun->be_lun->options, "insecure_tpc", NULL); if (value != NULL && strcmp(value, "on") == 0) list->init_port = -1; else list->init_port = ctsio->io_hdr.nexus.targ_port; list->init_idx = ctl_get_initindex(&ctsio->io_hdr.nexus); list->list_id = scsi_4btoul(data->list_identifier); list->flags = data->flags; list->params = ctsio->kern_data_ptr; list->cscd = (struct scsi_ec_cscd *)&data->data[0]; ptr = &data->data[0]; for (off = 0; off < lencscd; off += sizeof(struct scsi_ec_cscd)) { cscd = (struct scsi_ec_cscd *)(ptr + off); if (cscd->type_code != EC_CSCD_ID) { free(list, M_CTL); ctl_set_sense(ctsio, /*current_error*/ 1, /*sense_key*/ SSD_KEY_ILLEGAL_REQUEST, /*asc*/ 0x26, /*ascq*/ 0x07, SSD_ELEM_NONE); goto done; } } ptr = &data->data[lencscd]; for (nseg = 0, off = 0; off < lenseg; nseg++) { if (nseg >= TPC_MAX_SEGS) { free(list, M_CTL); ctl_set_sense(ctsio, /*current_error*/ 1, /*sense_key*/ SSD_KEY_ILLEGAL_REQUEST, /*asc*/ 0x26, /*ascq*/ 0x08, SSD_ELEM_NONE); goto done; } seg = (struct scsi_ec_segment *)(ptr + off); if (seg->type_code != EC_SEG_B2B && seg->type_code != EC_SEG_VERIFY && seg->type_code != EC_SEG_REGISTER_KEY) { free(list, M_CTL); ctl_set_sense(ctsio, /*current_error*/ 1, /*sense_key*/ SSD_KEY_ILLEGAL_REQUEST, /*asc*/ 0x26, /*ascq*/ 0x09, SSD_ELEM_NONE); goto done; } list->seg[nseg] = seg; off += sizeof(struct scsi_ec_segment) + scsi_2btoul(seg->descr_length); } list->inl = &data->data[lencscd + lenseg]; list->ncscd = lencscd / sizeof(struct scsi_ec_cscd); list->nseg = nseg; list->leninl = leninl; list->ctsio = ctsio; list->lun = lun; mtx_lock(&lun->lun_lock); if ((list->flags & EC_LIST_ID_USAGE_MASK) != EC_LIST_ID_USAGE_NONE) { tlist = tpc_find_list(lun, list->list_id, list->init_idx); if (tlist != NULL && !tlist->completed) { mtx_unlock(&lun->lun_lock); free(list, M_CTL); ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 0, /*field*/ 0, /*bit_valid*/ 0, /*bit*/ 0); goto done; } if (tlist != NULL) { TAILQ_REMOVE(&lun->tpc_lists, tlist, links); free(tlist, M_CTL); } } TAILQ_INSERT_TAIL(&lun->tpc_lists, list, links); mtx_unlock(&lun->lun_lock); tpc_process(list); return (CTL_RETVAL_COMPLETE); done: if (ctsio->io_hdr.flags & CTL_FLAG_ALLOCATED) { free(ctsio->kern_data_ptr, M_CTL); ctsio->io_hdr.flags &= ~CTL_FLAG_ALLOCATED; } ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } static void tpc_create_token(struct ctl_lun *lun, struct ctl_port *port, off_t len, struct scsi_token *token) { static int id = 0; struct scsi_vpd_id_descriptor *idd = NULL; struct scsi_ec_cscd_id *cscd; struct scsi_read_capacity_data_long *dtsd; int targid_len; scsi_ulto4b(ROD_TYPE_AUR, token->type); scsi_ulto2b(0x01f8, token->length); scsi_u64to8b(atomic_fetchadd_int(&id, 1), &token->body[0]); if (lun->lun_devid) idd = scsi_get_devid_desc((struct scsi_vpd_id_descriptor *) lun->lun_devid->data, lun->lun_devid->len, scsi_devid_is_lun_naa); if (idd == NULL && lun->lun_devid) idd = scsi_get_devid_desc((struct scsi_vpd_id_descriptor *) lun->lun_devid->data, lun->lun_devid->len, scsi_devid_is_lun_eui64); if (idd != NULL) { cscd = (struct scsi_ec_cscd_id *)&token->body[8]; cscd->type_code = EC_CSCD_ID; cscd->luidt_pdt = T_DIRECT; memcpy(&cscd->codeset, idd, 4 + idd->length); scsi_ulto3b(lun->be_lun->blocksize, cscd->dtsp.block_length); } scsi_u64to8b(0, &token->body[40]); /* XXX: Should be 128bit value. */ scsi_u64to8b(len, &token->body[48]); /* ROD token device type specific data (RC16 without first field) */ dtsd = (struct scsi_read_capacity_data_long *)&token->body[88 - 8]; scsi_ulto4b(lun->be_lun->blocksize, dtsd->length); dtsd->prot_lbppbe = lun->be_lun->pblockexp & SRC16_LBPPBE; scsi_ulto2b(lun->be_lun->pblockoff & SRC16_LALBA_A, dtsd->lalba_lbp); if (lun->be_lun->flags & CTL_LUN_FLAG_UNMAP) dtsd->lalba_lbp[0] |= SRC16_LBPME | SRC16_LBPRZ; if (port->target_devid) { targid_len = port->target_devid->len; memcpy(&token->body[120], port->target_devid->data, targid_len); } else targid_len = 32; arc4rand(&token->body[120 + targid_len], 384 - targid_len, 0); }; int ctl_populate_token(struct ctl_scsiio *ctsio) { struct ctl_softc *softc = CTL_SOFTC(ctsio); struct ctl_port *port = CTL_PORT(ctsio); struct ctl_lun *lun = CTL_LUN(ctsio); struct scsi_populate_token *cdb; struct scsi_populate_token_data *data; struct tpc_list *list, *tlist; struct tpc_token *token; uint64_t lba; int len, lendata, lendesc; CTL_DEBUG_PRINT(("ctl_populate_token\n")); cdb = (struct scsi_populate_token *)ctsio->cdb; len = scsi_4btoul(cdb->length); if (len < sizeof(struct scsi_populate_token_data) || len > sizeof(struct scsi_populate_token_data) + TPC_MAX_SEGS * sizeof(struct scsi_range_desc)) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 9, /*bit_valid*/ 0, /*bit*/ 0); goto done; } /* * If we've got a kernel request that hasn't been malloced yet, * malloc it and tell the caller the data buffer is here. */ if ((ctsio->io_hdr.flags & CTL_FLAG_ALLOCATED) == 0) { ctsio->kern_data_ptr = malloc(len, M_CTL, M_WAITOK); ctsio->kern_data_len = len; ctsio->kern_total_len = len; ctsio->kern_rel_offset = 0; ctsio->kern_sg_entries = 0; ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } data = (struct scsi_populate_token_data *)ctsio->kern_data_ptr; lendata = scsi_2btoul(data->length); if (lendata < sizeof(struct scsi_populate_token_data) - 2 + sizeof(struct scsi_range_desc)) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 0, /*field*/ 0, /*bit_valid*/ 0, /*bit*/ 0); goto done; } lendesc = scsi_2btoul(data->range_descriptor_length); if (lendesc < sizeof(struct scsi_range_desc) || len < sizeof(struct scsi_populate_token_data) + lendesc || lendata < sizeof(struct scsi_populate_token_data) - 2 + lendesc) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 0, /*field*/ 14, /*bit_valid*/ 0, /*bit*/ 0); goto done; } /* printf("PT(list=%u) flags=%x to=%d rt=%x len=%x\n", scsi_4btoul(cdb->list_identifier), data->flags, scsi_4btoul(data->inactivity_timeout), scsi_4btoul(data->rod_type), scsi_2btoul(data->range_descriptor_length)); */ /* Validate INACTIVITY TIMEOUT field */ if (scsi_4btoul(data->inactivity_timeout) > TPC_MAX_TOKEN_TIMEOUT) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 0, /*field*/ 4, /*bit_valid*/ 0, /*bit*/ 0); goto done; } /* Validate ROD TYPE field */ if ((data->flags & EC_PT_RTV) && scsi_4btoul(data->rod_type) != ROD_TYPE_AUR) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 0, /*field*/ 8, /*bit_valid*/ 0, /*bit*/ 0); goto done; } /* Validate list of ranges */ if (tpc_check_ranges_l(&data->desc[0], scsi_2btoul(data->range_descriptor_length) / sizeof(struct scsi_range_desc), lun->be_lun->maxlba, &lba) != 0) { ctl_set_lba_out_of_range(ctsio, lba); goto done; } if (tpc_check_ranges_x(&data->desc[0], scsi_2btoul(data->range_descriptor_length) / sizeof(struct scsi_range_desc)) != 0) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 0, /*command*/ 0, /*field*/ 0, /*bit_valid*/ 0, /*bit*/ 0); goto done; } list = malloc(sizeof(struct tpc_list), M_CTL, M_WAITOK | M_ZERO); list->service_action = cdb->service_action; list->init_port = ctsio->io_hdr.nexus.targ_port; list->init_idx = ctl_get_initindex(&ctsio->io_hdr.nexus); list->list_id = scsi_4btoul(cdb->list_identifier); list->flags = data->flags; list->ctsio = ctsio; list->lun = lun; mtx_lock(&lun->lun_lock); tlist = tpc_find_list(lun, list->list_id, list->init_idx); if (tlist != NULL && !tlist->completed) { mtx_unlock(&lun->lun_lock); free(list, M_CTL); ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 0, /*field*/ 0, /*bit_valid*/ 0, /*bit*/ 0); goto done; } if (tlist != NULL) { TAILQ_REMOVE(&lun->tpc_lists, tlist, links); free(tlist, M_CTL); } TAILQ_INSERT_TAIL(&lun->tpc_lists, list, links); mtx_unlock(&lun->lun_lock); token = malloc(sizeof(*token), M_CTL, M_WAITOK | M_ZERO); token->lun = lun->lun; token->blocksize = lun->be_lun->blocksize; token->params = ctsio->kern_data_ptr; token->range = &data->desc[0]; token->nrange = scsi_2btoul(data->range_descriptor_length) / sizeof(struct scsi_range_desc); list->cursectors = tpc_ranges_length(token->range, token->nrange); list->curbytes = (off_t)list->cursectors * lun->be_lun->blocksize; tpc_create_token(lun, port, list->curbytes, (struct scsi_token *)token->token); token->active = 0; token->last_active = time_uptime; token->timeout = scsi_4btoul(data->inactivity_timeout); if (token->timeout == 0) token->timeout = TPC_DFL_TOKEN_TIMEOUT; else if (token->timeout < TPC_MIN_TOKEN_TIMEOUT) token->timeout = TPC_MIN_TOKEN_TIMEOUT; memcpy(list->res_token, token->token, sizeof(list->res_token)); list->res_token_valid = 1; list->curseg = 0; list->completed = 1; list->last_active = time_uptime; mtx_lock(&softc->tpc_lock); TAILQ_INSERT_TAIL(&softc->tpc_tokens, token, links); mtx_unlock(&softc->tpc_lock); ctl_set_success(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); done: if (ctsio->io_hdr.flags & CTL_FLAG_ALLOCATED) { free(ctsio->kern_data_ptr, M_CTL); ctsio->io_hdr.flags &= ~CTL_FLAG_ALLOCATED; } ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } int ctl_write_using_token(struct ctl_scsiio *ctsio) { struct ctl_softc *softc = CTL_SOFTC(ctsio); struct ctl_lun *lun = CTL_LUN(ctsio); struct scsi_write_using_token *cdb; struct scsi_write_using_token_data *data; struct tpc_list *list, *tlist; struct tpc_token *token; uint64_t lba; int len, lendata, lendesc; CTL_DEBUG_PRINT(("ctl_write_using_token\n")); cdb = (struct scsi_write_using_token *)ctsio->cdb; len = scsi_4btoul(cdb->length); if (len < sizeof(struct scsi_write_using_token_data) || len > sizeof(struct scsi_write_using_token_data) + TPC_MAX_SEGS * sizeof(struct scsi_range_desc)) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 9, /*bit_valid*/ 0, /*bit*/ 0); goto done; } /* * If we've got a kernel request that hasn't been malloced yet, * malloc it and tell the caller the data buffer is here. */ if ((ctsio->io_hdr.flags & CTL_FLAG_ALLOCATED) == 0) { ctsio->kern_data_ptr = malloc(len, M_CTL, M_WAITOK); ctsio->kern_data_len = len; ctsio->kern_total_len = len; ctsio->kern_rel_offset = 0; ctsio->kern_sg_entries = 0; ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } data = (struct scsi_write_using_token_data *)ctsio->kern_data_ptr; lendata = scsi_2btoul(data->length); if (lendata < sizeof(struct scsi_write_using_token_data) - 2 + sizeof(struct scsi_range_desc)) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 0, /*field*/ 0, /*bit_valid*/ 0, /*bit*/ 0); goto done; } lendesc = scsi_2btoul(data->range_descriptor_length); if (lendesc < sizeof(struct scsi_range_desc) || len < sizeof(struct scsi_write_using_token_data) + lendesc || lendata < sizeof(struct scsi_write_using_token_data) - 2 + lendesc) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 0, /*field*/ 534, /*bit_valid*/ 0, /*bit*/ 0); goto done; } /* printf("WUT(list=%u) flags=%x off=%ju len=%x\n", scsi_4btoul(cdb->list_identifier), data->flags, scsi_8btou64(data->offset_into_rod), scsi_2btoul(data->range_descriptor_length)); */ /* Validate list of ranges */ if (tpc_check_ranges_l(&data->desc[0], scsi_2btoul(data->range_descriptor_length) / sizeof(struct scsi_range_desc), lun->be_lun->maxlba, &lba) != 0) { ctl_set_lba_out_of_range(ctsio, lba); goto done; } if (tpc_check_ranges_x(&data->desc[0], scsi_2btoul(data->range_descriptor_length) / sizeof(struct scsi_range_desc)) != 0) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 0, /*command*/ 0, /*field*/ 0, /*bit_valid*/ 0, /*bit*/ 0); goto done; } list = malloc(sizeof(struct tpc_list), M_CTL, M_WAITOK | M_ZERO); list->service_action = cdb->service_action; list->init_port = ctsio->io_hdr.nexus.targ_port; list->init_idx = ctl_get_initindex(&ctsio->io_hdr.nexus); list->list_id = scsi_4btoul(cdb->list_identifier); list->flags = data->flags; list->params = ctsio->kern_data_ptr; list->range = &data->desc[0]; list->nrange = scsi_2btoul(data->range_descriptor_length) / sizeof(struct scsi_range_desc); list->offset_into_rod = scsi_8btou64(data->offset_into_rod); list->ctsio = ctsio; list->lun = lun; mtx_lock(&lun->lun_lock); tlist = tpc_find_list(lun, list->list_id, list->init_idx); if (tlist != NULL && !tlist->completed) { mtx_unlock(&lun->lun_lock); free(list, M_CTL); ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 0, /*field*/ 0, /*bit_valid*/ 0, /*bit*/ 0); goto done; } if (tlist != NULL) { TAILQ_REMOVE(&lun->tpc_lists, tlist, links); free(tlist, M_CTL); } TAILQ_INSERT_TAIL(&lun->tpc_lists, list, links); mtx_unlock(&lun->lun_lock); /* Block device zero ROD token -> no token. */ if (scsi_4btoul(data->rod_token) == ROD_TYPE_BLOCK_ZERO) { tpc_process(list); return (CTL_RETVAL_COMPLETE); } mtx_lock(&softc->tpc_lock); TAILQ_FOREACH(token, &softc->tpc_tokens, links) { if (memcmp(token->token, data->rod_token, sizeof(data->rod_token)) == 0) break; } if (token != NULL) { token->active++; list->token = token; if (data->flags & EC_WUT_DEL_TKN) token->timeout = 0; } mtx_unlock(&softc->tpc_lock); if (token == NULL) { mtx_lock(&lun->lun_lock); TAILQ_REMOVE(&lun->tpc_lists, list, links); mtx_unlock(&lun->lun_lock); free(list, M_CTL); ctl_set_sense(ctsio, /*current_error*/ 1, /*sense_key*/ SSD_KEY_ILLEGAL_REQUEST, /*asc*/ 0x23, /*ascq*/ 0x04, SSD_ELEM_NONE); goto done; } tpc_process(list); return (CTL_RETVAL_COMPLETE); done: if (ctsio->io_hdr.flags & CTL_FLAG_ALLOCATED) { free(ctsio->kern_data_ptr, M_CTL); ctsio->io_hdr.flags &= ~CTL_FLAG_ALLOCATED; } ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } int ctl_receive_rod_token_information(struct ctl_scsiio *ctsio) { struct ctl_lun *lun = CTL_LUN(ctsio); struct scsi_receive_rod_token_information *cdb; struct scsi_receive_copy_status_lid4_data *data; struct tpc_list *list; struct tpc_list list_copy; uint8_t *ptr; int retval; int alloc_len, total_len, token_len; uint32_t list_id; CTL_DEBUG_PRINT(("ctl_receive_rod_token_information\n")); cdb = (struct scsi_receive_rod_token_information *)ctsio->cdb; retval = CTL_RETVAL_COMPLETE; list_id = scsi_4btoul(cdb->list_identifier); mtx_lock(&lun->lun_lock); list = tpc_find_list(lun, list_id, ctl_get_initindex(&ctsio->io_hdr.nexus)); if (list == NULL) { mtx_unlock(&lun->lun_lock); ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 2, /*bit_valid*/ 0, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); return (retval); } list_copy = *list; if (list->completed) { TAILQ_REMOVE(&lun->tpc_lists, list, links); free(list, M_CTL); } mtx_unlock(&lun->lun_lock); token_len = list_copy.res_token_valid ? 2 + sizeof(list_copy.res_token) : 0; total_len = sizeof(*data) + list_copy.sense_len + 4 + token_len; alloc_len = scsi_4btoul(cdb->length); ctsio->kern_data_ptr = malloc(total_len, M_CTL, M_WAITOK | M_ZERO); ctsio->kern_sg_entries = 0; ctsio->kern_rel_offset = 0; ctsio->kern_data_len = min(total_len, alloc_len); ctsio->kern_total_len = ctsio->kern_data_len; data = (struct scsi_receive_copy_status_lid4_data *)ctsio->kern_data_ptr; scsi_ulto4b(sizeof(*data) - 4 + list_copy.sense_len + 4 + token_len, data->available_data); data->response_to_service_action = list_copy.service_action; if (list_copy.completed) { if (list_copy.error) data->copy_command_status = RCS_CCS_ERROR; else if (list_copy.abort) data->copy_command_status = RCS_CCS_ABORTED; else data->copy_command_status = RCS_CCS_COMPLETED; } else data->copy_command_status = RCS_CCS_INPROG_FG; scsi_ulto2b(list_copy.curops, data->operation_counter); scsi_ulto4b(UINT32_MAX, data->estimated_status_update_delay); data->transfer_count_units = RCS_TC_LBAS; scsi_u64to8b(list_copy.cursectors, data->transfer_count); scsi_ulto2b(list_copy.curseg, data->segments_processed); data->length_of_the_sense_data_field = list_copy.sense_len; data->sense_data_length = list_copy.sense_len; memcpy(data->sense_data, &list_copy.sense_data, list_copy.sense_len); ptr = &data->sense_data[data->length_of_the_sense_data_field]; scsi_ulto4b(token_len, &ptr[0]); if (list_copy.res_token_valid) { scsi_ulto2b(0, &ptr[4]); memcpy(&ptr[6], list_copy.res_token, sizeof(list_copy.res_token)); } /* printf("RRTI(list=%u) valid=%d\n", scsi_4btoul(cdb->list_identifier), list_copy.res_token_valid); */ ctl_set_success(ctsio); ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (retval); } int ctl_report_all_rod_tokens(struct ctl_scsiio *ctsio) { struct ctl_softc *softc = CTL_SOFTC(ctsio); struct scsi_report_all_rod_tokens *cdb; struct scsi_report_all_rod_tokens_data *data; struct tpc_token *token; int retval; int alloc_len, total_len, tokens, i; CTL_DEBUG_PRINT(("ctl_receive_rod_token_information\n")); cdb = (struct scsi_report_all_rod_tokens *)ctsio->cdb; retval = CTL_RETVAL_COMPLETE; tokens = 0; mtx_lock(&softc->tpc_lock); TAILQ_FOREACH(token, &softc->tpc_tokens, links) tokens++; mtx_unlock(&softc->tpc_lock); if (tokens > 512) tokens = 512; total_len = sizeof(*data) + tokens * 96; alloc_len = scsi_4btoul(cdb->length); ctsio->kern_data_ptr = malloc(total_len, M_CTL, M_WAITOK | M_ZERO); ctsio->kern_sg_entries = 0; ctsio->kern_rel_offset = 0; ctsio->kern_data_len = min(total_len, alloc_len); ctsio->kern_total_len = ctsio->kern_data_len; data = (struct scsi_report_all_rod_tokens_data *)ctsio->kern_data_ptr; i = 0; mtx_lock(&softc->tpc_lock); TAILQ_FOREACH(token, &softc->tpc_tokens, links) { if (i >= tokens) break; memcpy(&data->rod_management_token_list[i * 96], token->token, 96); i++; } mtx_unlock(&softc->tpc_lock); scsi_ulto4b(sizeof(*data) - 4 + i * 96, data->available_data); /* printf("RART tokens=%d\n", i); */ ctl_set_success(ctsio); ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (retval); }