diff --git a/sys/dev/mana/mana.h b/sys/dev/mana/mana.h index cb5ee66c2331..8784044d0cf0 100644 --- a/sys/dev/mana/mana.h +++ b/sys/dev/mana/mana.h @@ -1,715 +1,715 @@ /*- * SPDX-License-Identifier: BSD-2-Clause * * Copyright (c) 2021 Microsoft Corp. * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS 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 COPYRIGHT * OWNER 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. * * $FreeBSD$ * */ #ifndef _MANA_H #define _MANA_H #include #include #include #include #include #include #include #include #include #include #include "gdma.h" #include "hw_channel.h" /* Microsoft Azure Network Adapter (MANA)'s definitions * * Structures labeled with "HW DATA" are exchanged with the hardware. All of * them are naturally aligned and hence don't need __packed. */ /* MANA protocol version */ #define MANA_MAJOR_VERSION 0 #define MANA_MINOR_VERSION 1 #define MANA_MICRO_VERSION 1 #define DRV_MODULE_NAME "mana" #ifndef DRV_MODULE_VERSION #define DRV_MODULE_VERSION \ __XSTRING(MANA_MAJOR_VERSION) "." \ __XSTRING(MANA_MINOR_VERSION) "." \ __XSTRING(MANA_MICRO_VERSION) #endif #define DEVICE_NAME "Microsoft Azure Network Adapter (MANA)" #define DEVICE_DESC "MANA adapter" /* * Supported PCI vendor and devices IDs */ #ifndef PCI_VENDOR_ID_MICROSOFT #define PCI_VENDOR_ID_MICROSOFT 0x1414 #endif #define PCI_DEV_ID_MANA_VF 0x00ba typedef struct _mana_vendor_id_t { uint16_t vendor_id; uint16_t device_id; } mana_vendor_id_t; typedef uint64_t mana_handle_t; #define INVALID_MANA_HANDLE ((mana_handle_t)-1) enum TRI_STATE { TRI_STATE_UNKNOWN = -1, TRI_STATE_FALSE = 0, TRI_STATE_TRUE = 1 }; /* Number of entries for hardware indirection table must be in power of 2 */ #define MANA_INDIRECT_TABLE_SIZE 64 #define MANA_INDIRECT_TABLE_MASK (MANA_INDIRECT_TABLE_SIZE - 1) /* The Toeplitz hash key's length in bytes: should be multiple of 8 */ #define MANA_HASH_KEY_SIZE 40 #define COMP_ENTRY_SIZE 64 #define MIN_FRAME_SIZE 146 #define ADAPTER_MTU_SIZE 1500 #define DEFAULT_FRAME_SIZE (ADAPTER_MTU_SIZE + 14) #define MAX_FRAME_SIZE 4096 #define RX_BUFFERS_PER_QUEUE 512 #define MAX_SEND_BUFFERS_PER_QUEUE 256 #define EQ_SIZE (8 * PAGE_SIZE) #define LOG2_EQ_THROTTLE 3 #define MAX_PORTS_IN_MANA_DEV 8 struct mana_send_buf_info { struct mbuf *mbuf; bus_dmamap_t dma_map; /* Required to store the result of mana_gd_post_work_request. * gdma_posted_wqe_info.wqe_size_in_bu is required for progressing the * work queue when the WQE is consumed. */ struct gdma_posted_wqe_info wqe_inf; }; struct mana_stats { counter_u64_t packets; /* rx, tx */ counter_u64_t bytes; /* rx, tx */ counter_u64_t stop; /* tx */ counter_u64_t wakeup; /* tx */ counter_u64_t collapse; /* tx */ counter_u64_t collapse_err; /* tx */ counter_u64_t dma_mapping_err; /* rx, tx */ counter_u64_t mbuf_alloc_fail; /* rx */ counter_u64_t alt_chg; /* tx */ counter_u64_t alt_reset; /* tx */ }; struct mana_txq { struct gdma_queue *gdma_sq; union { uint32_t gdma_txq_id; struct { uint32_t reserved1 :10; uint32_t vsq_frame :14; uint32_t reserved2 :8; }; }; uint16_t vp_offset; - struct ifnet *ndev; + if_t ndev; /* Store index to the array of tx_qp in port structure */ int idx; /* The alternative txq idx when this txq is under heavy load */ int alt_txq_idx; /* The mbufs are sent to the HW and we are waiting for the CQEs. */ struct mana_send_buf_info *tx_buf_info; uint16_t next_to_use; uint16_t next_to_complete; atomic_t pending_sends; struct buf_ring *txq_br; struct mtx txq_mtx; char txq_mtx_name[16]; struct task enqueue_task; struct taskqueue *enqueue_tq; struct mana_stats stats; }; /* * Max WQE size is 512B. The first 8B is for GDMA Out of Band (OOB), * next is the Client OOB can be either 8B or 24B. Thus, the max * space for SGL entries in a singel WQE is 512 - 8 - 8 = 496B. Since each * SGL is 16B in size, the max number of SGLs in a WQE is 496/16 = 31. * Save one for emergency use, set the MAX_MBUF_FRAGS allowed to 30. */ #define MAX_MBUF_FRAGS 30 #define MANA_TSO_MAXSEG_SZ PAGE_SIZE /* mbuf data and frags dma mappings */ struct mana_mbuf_head { bus_addr_t dma_handle[MAX_MBUF_FRAGS + 1]; uint32_t size[MAX_MBUF_FRAGS + 1]; }; #define MANA_HEADROOM sizeof(struct mana_mbuf_head) enum mana_tx_pkt_format { MANA_SHORT_PKT_FMT = 0, MANA_LONG_PKT_FMT = 1, }; struct mana_tx_short_oob { uint32_t pkt_fmt :2; uint32_t is_outer_ipv4 :1; uint32_t is_outer_ipv6 :1; uint32_t comp_iphdr_csum :1; uint32_t comp_tcp_csum :1; uint32_t comp_udp_csum :1; uint32_t supress_txcqe_gen :1; uint32_t vcq_num :24; uint32_t trans_off :10; /* Transport header offset */ uint32_t vsq_frame :14; uint32_t short_vp_offset :8; }; /* HW DATA */ struct mana_tx_long_oob { uint32_t is_encap :1; uint32_t inner_is_ipv6 :1; uint32_t inner_tcp_opt :1; uint32_t inject_vlan_pri_tag :1; uint32_t reserved1 :12; uint32_t pcp :3; /* 802.1Q */ uint32_t dei :1; /* 802.1Q */ uint32_t vlan_id :12; /* 802.1Q */ uint32_t inner_frame_offset :10; uint32_t inner_ip_rel_offset :6; uint32_t long_vp_offset :12; uint32_t reserved2 :4; uint32_t reserved3; uint32_t reserved4; }; /* HW DATA */ struct mana_tx_oob { struct mana_tx_short_oob s_oob; struct mana_tx_long_oob l_oob; }; /* HW DATA */ enum mana_cq_type { MANA_CQ_TYPE_RX, MANA_CQ_TYPE_TX, }; enum mana_cqe_type { CQE_INVALID = 0, CQE_RX_OKAY = 1, CQE_RX_COALESCED_4 = 2, CQE_RX_OBJECT_FENCE = 3, CQE_RX_TRUNCATED = 4, CQE_TX_OKAY = 32, CQE_TX_SA_DROP = 33, CQE_TX_MTU_DROP = 34, CQE_TX_INVALID_OOB = 35, CQE_TX_INVALID_ETH_TYPE = 36, CQE_TX_HDR_PROCESSING_ERROR = 37, CQE_TX_VF_DISABLED = 38, CQE_TX_VPORT_IDX_OUT_OF_RANGE = 39, CQE_TX_VPORT_DISABLED = 40, CQE_TX_VLAN_TAGGING_VIOLATION = 41, }; #define MANA_CQE_COMPLETION 1 struct mana_cqe_header { uint32_t cqe_type :6; uint32_t client_type :2; uint32_t vendor_err :24; }; /* HW DATA */ /* NDIS HASH Types */ #define NDIS_HASH_IPV4 BIT(0) #define NDIS_HASH_TCP_IPV4 BIT(1) #define NDIS_HASH_UDP_IPV4 BIT(2) #define NDIS_HASH_IPV6 BIT(3) #define NDIS_HASH_TCP_IPV6 BIT(4) #define NDIS_HASH_UDP_IPV6 BIT(5) #define NDIS_HASH_IPV6_EX BIT(6) #define NDIS_HASH_TCP_IPV6_EX BIT(7) #define NDIS_HASH_UDP_IPV6_EX BIT(8) #define MANA_HASH_L3 (NDIS_HASH_IPV4 | NDIS_HASH_IPV6 | NDIS_HASH_IPV6_EX) #define MANA_HASH_L4 \ (NDIS_HASH_TCP_IPV4 | NDIS_HASH_UDP_IPV4 | NDIS_HASH_TCP_IPV6 | \ NDIS_HASH_UDP_IPV6 | NDIS_HASH_TCP_IPV6_EX | NDIS_HASH_UDP_IPV6_EX) #define NDIS_HASH_IPV4_L3_MASK (NDIS_HASH_IPV4) #define NDIS_HASH_IPV4_L4_MASK (NDIS_HASH_TCP_IPV4 | NDIS_HASH_UDP_IPV4) #define NDIS_HASH_IPV6_L3_MASK (NDIS_HASH_IPV6 | NDIS_HASH_IPV6_EX) #define NDIS_HASH_IPV6_L4_MASK \ (NDIS_HASH_TCP_IPV6 | NDIS_HASH_UDP_IPV6 | \ NDIS_HASH_TCP_IPV6_EX | NDIS_HASH_UDP_IPV6_EX) #define NDIS_HASH_IPV4_MASK \ (NDIS_HASH_IPV4_L3_MASK | NDIS_HASH_IPV4_L4_MASK) #define NDIS_HASH_IPV6_MASK \ (NDIS_HASH_IPV6_L3_MASK | NDIS_HASH_IPV6_L4_MASK) struct mana_rxcomp_perpkt_info { uint32_t pkt_len :16; uint32_t reserved1 :16; uint32_t reserved2; uint32_t pkt_hash; }; /* HW DATA */ #define MANA_RXCOMP_OOB_NUM_PPI 4 /* Receive completion OOB */ struct mana_rxcomp_oob { struct mana_cqe_header cqe_hdr; uint32_t rx_vlan_id :12; uint32_t rx_vlantag_present :1; uint32_t rx_outer_iphdr_csum_succeed :1; uint32_t rx_outer_iphdr_csum_fail :1; uint32_t reserved1 :1; uint32_t rx_hashtype :9; uint32_t rx_iphdr_csum_succeed :1; uint32_t rx_iphdr_csum_fail :1; uint32_t rx_tcp_csum_succeed :1; uint32_t rx_tcp_csum_fail :1; uint32_t rx_udp_csum_succeed :1; uint32_t rx_udp_csum_fail :1; uint32_t reserved2 :1; struct mana_rxcomp_perpkt_info ppi[MANA_RXCOMP_OOB_NUM_PPI]; uint32_t rx_wqe_offset; }; /* HW DATA */ struct mana_tx_comp_oob { struct mana_cqe_header cqe_hdr; uint32_t tx_data_offset; uint32_t tx_sgl_offset :5; uint32_t tx_wqe_offset :27; uint32_t reserved[12]; }; /* HW DATA */ struct mana_rxq; #define CQE_POLLING_BUFFER 512 struct mana_cq { struct gdma_queue *gdma_cq; /* Cache the CQ id (used to verify if each CQE comes to the right CQ. */ uint32_t gdma_id; /* Type of the CQ: TX or RX */ enum mana_cq_type type; /* Pointer to the mana_rxq that is pushing RX CQEs to the queue. * Only and must be non-NULL if type is MANA_CQ_TYPE_RX. */ struct mana_rxq *rxq; /* Pointer to the mana_txq that is pushing TX CQEs to the queue. * Only and must be non-NULL if type is MANA_CQ_TYPE_TX. */ struct mana_txq *txq; /* Taskqueue and related structs */ struct task cleanup_task; struct taskqueue *cleanup_tq; int cpu; bool do_not_ring_db; /* Budget for one cleanup task */ int work_done; int budget; /* Buffer which the CQ handler can copy the CQE's into. */ struct gdma_comp gdma_comp_buf[CQE_POLLING_BUFFER]; }; struct mana_recv_buf_oob { /* A valid GDMA work request representing the data buffer. */ struct gdma_wqe_request wqe_req; struct mbuf *mbuf; bus_dmamap_t dma_map; /* SGL of the buffer going to be sent as part of the work request. */ uint32_t num_sge; struct gdma_sge sgl[MAX_RX_WQE_SGL_ENTRIES]; /* Required to store the result of mana_gd_post_work_request. * gdma_posted_wqe_info.wqe_size_in_bu is required for progressing the * work queue when the WQE is consumed. */ struct gdma_posted_wqe_info wqe_inf; }; struct mana_rxq { struct gdma_queue *gdma_rq; /* Cache the gdma receive queue id */ uint32_t gdma_id; /* Index of RQ in the vPort, not gdma receive queue id */ uint32_t rxq_idx; uint32_t datasize; mana_handle_t rxobj; struct completion fence_event; struct mana_cq rx_cq; - struct ifnet *ndev; + if_t ndev; struct lro_ctrl lro; /* Total number of receive buffers to be allocated */ uint32_t num_rx_buf; uint32_t buf_index; struct mana_stats stats; /* MUST BE THE LAST MEMBER: * Each receive buffer has an associated mana_recv_buf_oob. */ struct mana_recv_buf_oob rx_oobs[]; }; struct mana_tx_qp { struct mana_txq txq; struct mana_cq tx_cq; mana_handle_t tx_object; }; struct mana_port_stats { counter_u64_t rx_packets; counter_u64_t tx_packets; counter_u64_t rx_bytes; counter_u64_t tx_bytes; counter_u64_t rx_drops; counter_u64_t tx_drops; counter_u64_t stop_queue; counter_u64_t wake_queue; }; struct mana_context { struct gdma_dev *gdma_dev; uint16_t num_ports; struct mana_eq *eqs; - struct ifnet *ports[MAX_PORTS_IN_MANA_DEV]; + if_t ports[MAX_PORTS_IN_MANA_DEV]; }; struct mana_port_context { struct mana_context *ac; - struct ifnet *ndev; + if_t ndev; struct ifmedia media; struct sx apc_lock; /* DMA tag used for queue bufs of the entire port */ bus_dma_tag_t rx_buf_tag; bus_dma_tag_t tx_buf_tag; uint8_t mac_addr[ETHER_ADDR_LEN]; enum TRI_STATE rss_state; mana_handle_t default_rxobj; bool tx_shortform_allowed; uint16_t tx_vp_offset; struct mana_tx_qp *tx_qp; /* Indirection Table for RX & TX. The values are queue indexes */ uint32_t indir_table[MANA_INDIRECT_TABLE_SIZE]; /* Indirection table containing RxObject Handles */ mana_handle_t rxobj_table[MANA_INDIRECT_TABLE_SIZE]; /* Hash key used by the NIC */ uint8_t hashkey[MANA_HASH_KEY_SIZE]; /* This points to an array of num_queues of RQ pointers. */ struct mana_rxq **rxqs; /* Create num_queues EQs, SQs, SQ-CQs, RQs and RQ-CQs, respectively. */ unsigned int max_queues; unsigned int num_queues; mana_handle_t port_handle; int vport_use_count; uint16_t port_idx; uint16_t frame_size; bool port_is_up; bool port_st_save; /* Saved port state */ bool enable_tx_altq; bool bind_cleanup_thread_cpu; int last_tx_cq_bind_cpu; int last_rx_cq_bind_cpu; struct mana_port_stats port_stats; struct sysctl_oid_list *port_list; struct sysctl_ctx_list que_sysctl_ctx; }; #define MANA_APC_LOCK_INIT(apc) \ sx_init(&(apc)->apc_lock, "MANA port lock") #define MANA_APC_LOCK_DESTROY(apc) sx_destroy(&(apc)->apc_lock) #define MANA_APC_LOCK_LOCK(apc) sx_xlock(&(apc)->apc_lock) #define MANA_APC_LOCK_UNLOCK(apc) sx_unlock(&(apc)->apc_lock) int mana_config_rss(struct mana_port_context *ac, enum TRI_STATE rx, bool update_hash, bool update_tab); -int mana_alloc_queues(struct ifnet *ndev); -int mana_attach(struct ifnet *ndev); -int mana_detach(struct ifnet *ndev); +int mana_alloc_queues(if_t ndev); +int mana_attach(if_t ndev); +int mana_detach(if_t ndev); int mana_probe(struct gdma_dev *gd); void mana_remove(struct gdma_dev *gd); struct mana_obj_spec { uint32_t queue_index; uint64_t gdma_region; uint32_t queue_size; uint32_t attached_eq; uint32_t modr_ctx_id; }; enum mana_command_code { MANA_QUERY_DEV_CONFIG = 0x20001, MANA_QUERY_GF_STAT = 0x20002, MANA_CONFIG_VPORT_TX = 0x20003, MANA_CREATE_WQ_OBJ = 0x20004, MANA_DESTROY_WQ_OBJ = 0x20005, MANA_FENCE_RQ = 0x20006, MANA_CONFIG_VPORT_RX = 0x20007, MANA_QUERY_VPORT_CONFIG = 0x20008, }; /* Query Device Configuration */ struct mana_query_device_cfg_req { struct gdma_req_hdr hdr; /* Driver Capability flags */ uint64_t drv_cap_flags1; uint64_t drv_cap_flags2; uint64_t drv_cap_flags3; uint64_t drv_cap_flags4; uint32_t proto_major_ver; uint32_t proto_minor_ver; uint32_t proto_micro_ver; uint32_t reserved; }; /* HW DATA */ struct mana_query_device_cfg_resp { struct gdma_resp_hdr hdr; uint64_t pf_cap_flags1; uint64_t pf_cap_flags2; uint64_t pf_cap_flags3; uint64_t pf_cap_flags4; uint16_t max_num_vports; uint16_t reserved; uint32_t max_num_eqs; }; /* HW DATA */ /* Query vPort Configuration */ struct mana_query_vport_cfg_req { struct gdma_req_hdr hdr; uint32_t vport_index; }; /* HW DATA */ struct mana_query_vport_cfg_resp { struct gdma_resp_hdr hdr; uint32_t max_num_sq; uint32_t max_num_rq; uint32_t num_indirection_ent; uint32_t reserved1; uint8_t mac_addr[6]; uint8_t reserved2[2]; mana_handle_t vport; }; /* HW DATA */ /* Configure vPort */ struct mana_config_vport_req { struct gdma_req_hdr hdr; mana_handle_t vport; uint32_t pdid; uint32_t doorbell_pageid; }; /* HW DATA */ struct mana_config_vport_resp { struct gdma_resp_hdr hdr; uint16_t tx_vport_offset; uint8_t short_form_allowed; uint8_t reserved; }; /* HW DATA */ /* Create WQ Object */ struct mana_create_wqobj_req { struct gdma_req_hdr hdr; mana_handle_t vport; uint32_t wq_type; uint32_t reserved; uint64_t wq_gdma_region; uint64_t cq_gdma_region; uint32_t wq_size; uint32_t cq_size; uint32_t cq_moderation_ctx_id; uint32_t cq_parent_qid; }; /* HW DATA */ struct mana_create_wqobj_resp { struct gdma_resp_hdr hdr; uint32_t wq_id; uint32_t cq_id; mana_handle_t wq_obj; }; /* HW DATA */ /* Destroy WQ Object */ struct mana_destroy_wqobj_req { struct gdma_req_hdr hdr; uint32_t wq_type; uint32_t reserved; mana_handle_t wq_obj_handle; }; /* HW DATA */ struct mana_destroy_wqobj_resp { struct gdma_resp_hdr hdr; }; /* HW DATA */ /* Fence RQ */ struct mana_fence_rq_req { struct gdma_req_hdr hdr; mana_handle_t wq_obj_handle; }; /* HW DATA */ struct mana_fence_rq_resp { struct gdma_resp_hdr hdr; }; /* HW DATA */ /* Configure vPort Rx Steering */ struct mana_cfg_rx_steer_req { struct gdma_req_hdr hdr; mana_handle_t vport; uint16_t num_indir_entries; uint16_t indir_tab_offset; uint32_t rx_enable; uint32_t rss_enable; uint8_t update_default_rxobj; uint8_t update_hashkey; uint8_t update_indir_tab; uint8_t reserved; mana_handle_t default_rxobj; uint8_t hashkey[MANA_HASH_KEY_SIZE]; }; /* HW DATA */ struct mana_cfg_rx_steer_resp { struct gdma_resp_hdr hdr; }; /* HW DATA */ #define MANA_MAX_NUM_QUEUES 16 #define MANA_SHORT_VPORT_OFFSET_MAX ((1U << 8) - 1) struct mana_tx_package { struct gdma_wqe_request wqe_req; struct gdma_sge sgl_array[MAX_MBUF_FRAGS]; struct mana_tx_oob tx_oob; struct gdma_posted_wqe_info wqe_info; }; int mana_restart(struct mana_port_context *apc); int mana_create_wq_obj(struct mana_port_context *apc, mana_handle_t vport, uint32_t wq_type, struct mana_obj_spec *wq_spec, struct mana_obj_spec *cq_spec, mana_handle_t *wq_obj); void mana_destroy_wq_obj(struct mana_port_context *apc, uint32_t wq_type, mana_handle_t wq_obj); int mana_cfg_vport(struct mana_port_context *apc, uint32_t protection_dom_id, uint32_t doorbell_pg_id); void mana_uncfg_vport(struct mana_port_context *apc); #endif /* _MANA_H */ diff --git a/sys/dev/mana/mana_en.c b/sys/dev/mana/mana_en.c index 5a95eff66ab6..9d9a4084efe1 100644 --- a/sys/dev/mana/mana_en.c +++ b/sys/dev/mana/mana_en.c @@ -1,2888 +1,2888 @@ /*- * SPDX-License-Identifier: BSD-2-Clause * * Copyright (c) 2021 Microsoft Corp. * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS 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 COPYRIGHT * OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT * LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #include __FBSDID("$FreeBSD$"); #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifdef RSS #include #endif #include #include #include #include #include #include #include #include "mana.h" #include "mana_sysctl.h" static int mana_up(struct mana_port_context *apc); static int mana_down(struct mana_port_context *apc); static void mana_rss_key_fill(void *k, size_t size) { static bool rss_key_generated = false; static uint8_t rss_key[MANA_HASH_KEY_SIZE]; KASSERT(size <= MANA_HASH_KEY_SIZE, ("Request more buytes than MANA RSS key can hold")); if (!rss_key_generated) { arc4random_buf(rss_key, MANA_HASH_KEY_SIZE); rss_key_generated = true; } memcpy(k, rss_key, size); } static int -mana_ifmedia_change(struct ifnet *ifp __unused) +mana_ifmedia_change(if_t ifp __unused) { return EOPNOTSUPP; } static void -mana_ifmedia_status(struct ifnet *ifp, struct ifmediareq *ifmr) +mana_ifmedia_status(if_t ifp, struct ifmediareq *ifmr) { struct mana_port_context *apc = if_getsoftc(ifp); if (!apc) { if_printf(ifp, "Port not available\n"); return; } MANA_APC_LOCK_LOCK(apc); ifmr->ifm_status = IFM_AVALID; ifmr->ifm_active = IFM_ETHER; if (!apc->port_is_up) { MANA_APC_LOCK_UNLOCK(apc); mana_dbg(NULL, "Port %u link is down\n", apc->port_idx); return; } ifmr->ifm_status |= IFM_ACTIVE; ifmr->ifm_active |= IFM_100G_DR | IFM_FDX; MANA_APC_LOCK_UNLOCK(apc); } static uint64_t -mana_get_counter(struct ifnet *ifp, ift_counter cnt) +mana_get_counter(if_t ifp, ift_counter cnt) { struct mana_port_context *apc = if_getsoftc(ifp); struct mana_port_stats *stats = &apc->port_stats; switch (cnt) { case IFCOUNTER_IPACKETS: return (counter_u64_fetch(stats->rx_packets)); case IFCOUNTER_OPACKETS: return (counter_u64_fetch(stats->tx_packets)); case IFCOUNTER_IBYTES: return (counter_u64_fetch(stats->rx_bytes)); case IFCOUNTER_OBYTES: return (counter_u64_fetch(stats->tx_bytes)); case IFCOUNTER_IQDROPS: return (counter_u64_fetch(stats->rx_drops)); case IFCOUNTER_OQDROPS: return (counter_u64_fetch(stats->tx_drops)); default: return (if_get_counter_default(ifp, cnt)); } } static void -mana_qflush(struct ifnet *ifp) +mana_qflush(if_t ifp) { if_qflush(ifp); } int mana_restart(struct mana_port_context *apc) { int rc = 0; MANA_APC_LOCK_LOCK(apc); if (apc->port_is_up) mana_down(apc); rc = mana_up(apc); MANA_APC_LOCK_UNLOCK(apc); return (rc); } static int -mana_ioctl(struct ifnet *ifp, u_long command, caddr_t data) +mana_ioctl(if_t ifp, u_long command, caddr_t data) { struct mana_port_context *apc = if_getsoftc(ifp); struct ifrsskey *ifrk; struct ifrsshash *ifrh; struct ifreq *ifr; uint16_t new_mtu; int rc = 0; switch (command) { case SIOCSIFMTU: ifr = (struct ifreq *)data; new_mtu = ifr->ifr_mtu; - if (ifp->if_mtu == new_mtu) + if (if_getmtu(ifp) == new_mtu) break; if ((new_mtu + 18 > MAX_FRAME_SIZE) || (new_mtu + 18 < MIN_FRAME_SIZE)) { if_printf(ifp, "Invalid MTU. new_mtu: %d, " "max allowed: %d, min allowed: %d\n", new_mtu, MAX_FRAME_SIZE - 18, MIN_FRAME_SIZE - 18); return EINVAL; } MANA_APC_LOCK_LOCK(apc); if (apc->port_is_up) mana_down(apc); apc->frame_size = new_mtu + 18; if_setmtu(ifp, new_mtu); mana_dbg(NULL, "Set MTU to %d\n", new_mtu); rc = mana_up(apc); MANA_APC_LOCK_UNLOCK(apc); break; case SIOCSIFFLAGS: - if (ifp->if_flags & IFF_UP) { - if ((ifp->if_drv_flags & IFF_DRV_RUNNING) == 0) { + if (if_getflags(ifp) & IFF_UP) { + if ((if_getdrvflags(ifp) & IFF_DRV_RUNNING) == 0) { MANA_APC_LOCK_LOCK(apc); if (!apc->port_is_up) rc = mana_up(apc); MANA_APC_LOCK_UNLOCK(apc); } } else { - if (ifp->if_drv_flags & IFF_DRV_RUNNING) { + if (if_getdrvflags(ifp) & IFF_DRV_RUNNING) { MANA_APC_LOCK_LOCK(apc); if (apc->port_is_up) mana_down(apc); MANA_APC_LOCK_UNLOCK(apc); } } break; case SIOCSIFMEDIA: case SIOCGIFMEDIA: case SIOCGIFXMEDIA: ifr = (struct ifreq *)data; rc = ifmedia_ioctl(ifp, ifr, &apc->media, command); break; case SIOCGIFRSSKEY: ifrk = (struct ifrsskey *)data; ifrk->ifrk_func = RSS_FUNC_TOEPLITZ; ifrk->ifrk_keylen = MANA_HASH_KEY_SIZE; memcpy(ifrk->ifrk_key, apc->hashkey, MANA_HASH_KEY_SIZE); break; case SIOCGIFRSSHASH: ifrh = (struct ifrsshash *)data; ifrh->ifrh_func = RSS_FUNC_TOEPLITZ; ifrh->ifrh_types = RSS_TYPE_TCP_IPV4 | RSS_TYPE_UDP_IPV4 | RSS_TYPE_TCP_IPV6 | RSS_TYPE_UDP_IPV6; break; default: rc = ether_ioctl(ifp, command, data); break; } return (rc); } static inline void mana_alloc_counters(counter_u64_t *begin, int size) { counter_u64_t *end = (counter_u64_t *)((char *)begin + size); for (; begin < end; ++begin) *begin = counter_u64_alloc(M_WAITOK); } static inline void mana_free_counters(counter_u64_t *begin, int size) { counter_u64_t *end = (counter_u64_t *)((char *)begin + size); for (; begin < end; ++begin) counter_u64_free(*begin); } static bool mana_can_tx(struct gdma_queue *wq) { return mana_gd_wq_avail_space(wq) >= MAX_TX_WQE_SIZE; } static inline int mana_tx_map_mbuf(struct mana_port_context *apc, struct mana_send_buf_info *tx_info, struct mbuf **m_head, struct mana_tx_package *tp, struct mana_stats *tx_stats) { struct gdma_dev *gd = apc->ac->gdma_dev; bus_dma_segment_t segs[MAX_MBUF_FRAGS]; struct mbuf *m = *m_head; int err, nsegs, i; err = bus_dmamap_load_mbuf_sg(apc->tx_buf_tag, tx_info->dma_map, m, segs, &nsegs, BUS_DMA_NOWAIT); if (err == EFBIG) { struct mbuf *m_new; counter_u64_add(tx_stats->collapse, 1); m_new = m_collapse(m, M_NOWAIT, MAX_MBUF_FRAGS); if (unlikely(m_new == NULL)) { counter_u64_add(tx_stats->collapse_err, 1); return ENOBUFS; } else { *m_head = m = m_new; } mana_warn(NULL, "Too many segs in orig mbuf, m_collapse called\n"); err = bus_dmamap_load_mbuf_sg(apc->tx_buf_tag, tx_info->dma_map, m, segs, &nsegs, BUS_DMA_NOWAIT); } if (!err) { for (i = 0; i < nsegs; i++) { tp->wqe_req.sgl[i].address = segs[i].ds_addr; tp->wqe_req.sgl[i].mem_key = gd->gpa_mkey; tp->wqe_req.sgl[i].size = segs[i].ds_len; } tp->wqe_req.num_sge = nsegs; tx_info->mbuf = *m_head; bus_dmamap_sync(apc->tx_buf_tag, tx_info->dma_map, BUS_DMASYNC_PREWRITE); } return err; } static inline void mana_tx_unmap_mbuf(struct mana_port_context *apc, struct mana_send_buf_info *tx_info) { bus_dmamap_sync(apc->tx_buf_tag, tx_info->dma_map, BUS_DMASYNC_POSTWRITE); bus_dmamap_unload(apc->tx_buf_tag, tx_info->dma_map); if (tx_info->mbuf) { m_freem(tx_info->mbuf); tx_info->mbuf = NULL; } } static inline int mana_load_rx_mbuf(struct mana_port_context *apc, struct mana_rxq *rxq, struct mana_recv_buf_oob *rx_oob, bool alloc_mbuf) { bus_dma_segment_t segs[1]; struct mbuf *mbuf; int nsegs, err; uint32_t mlen; if (alloc_mbuf) { mbuf = m_getjcl(M_NOWAIT, MT_DATA, M_PKTHDR, rxq->datasize); if (unlikely(mbuf == NULL)) { mbuf = m_getcl(M_NOWAIT, MT_DATA, M_PKTHDR); if (unlikely(mbuf == NULL)) { return ENOMEM; } mlen = MCLBYTES; } else { mlen = rxq->datasize; } mbuf->m_pkthdr.len = mbuf->m_len = mlen; } else { if (rx_oob->mbuf) { mbuf = rx_oob->mbuf; mlen = rx_oob->mbuf->m_pkthdr.len; } else { return ENOMEM; } } err = bus_dmamap_load_mbuf_sg(apc->rx_buf_tag, rx_oob->dma_map, mbuf, segs, &nsegs, BUS_DMA_NOWAIT); if (unlikely((err != 0) || (nsegs != 1))) { mana_warn(NULL, "Failed to map mbuf, error: %d, " "nsegs: %d\n", err, nsegs); counter_u64_add(rxq->stats.dma_mapping_err, 1); goto error; } bus_dmamap_sync(apc->rx_buf_tag, rx_oob->dma_map, BUS_DMASYNC_PREREAD); rx_oob->mbuf = mbuf; rx_oob->num_sge = 1; rx_oob->sgl[0].address = segs[0].ds_addr; rx_oob->sgl[0].size = mlen; rx_oob->sgl[0].mem_key = apc->ac->gdma_dev->gpa_mkey; return 0; error: m_freem(mbuf); return EFAULT; } static inline void mana_unload_rx_mbuf(struct mana_port_context *apc, struct mana_rxq *rxq, struct mana_recv_buf_oob *rx_oob, bool free_mbuf) { bus_dmamap_sync(apc->rx_buf_tag, rx_oob->dma_map, BUS_DMASYNC_POSTREAD); bus_dmamap_unload(apc->rx_buf_tag, rx_oob->dma_map); if (free_mbuf && rx_oob->mbuf) { m_freem(rx_oob->mbuf); rx_oob->mbuf = NULL; } } /* Use couple mbuf PH_loc spaces for l3 and l4 protocal type */ #define MANA_L3_PROTO(_mbuf) ((_mbuf)->m_pkthdr.PH_loc.sixteen[0]) #define MANA_L4_PROTO(_mbuf) ((_mbuf)->m_pkthdr.PH_loc.sixteen[1]) #define MANA_TXQ_FULL (IFF_DRV_RUNNING | IFF_DRV_OACTIVE) static void mana_xmit(struct mana_txq *txq) { enum mana_tx_pkt_format pkt_fmt = MANA_SHORT_PKT_FMT; struct mana_send_buf_info *tx_info; - struct ifnet *ndev = txq->ndev; + if_t ndev = txq->ndev; struct mbuf *mbuf; struct mana_port_context *apc = if_getsoftc(ndev); struct mana_port_stats *port_stats = &apc->port_stats; struct gdma_dev *gd = apc->ac->gdma_dev; uint64_t packets, bytes; uint16_t next_to_use; struct mana_tx_package pkg = {}; struct mana_stats *tx_stats; struct gdma_queue *gdma_sq; struct mana_cq *cq; int err, len; gdma_sq = txq->gdma_sq; cq = &apc->tx_qp[txq->idx].tx_cq; tx_stats = &txq->stats; packets = 0; bytes = 0; next_to_use = txq->next_to_use; while ((mbuf = drbr_peek(ndev, txq->txq_br)) != NULL) { if (!apc->port_is_up || (if_getdrvflags(ndev) & MANA_TXQ_FULL) != IFF_DRV_RUNNING) { drbr_putback(ndev, txq->txq_br, mbuf); break; } if (!mana_can_tx(gdma_sq)) { /* SQ is full. Set the IFF_DRV_OACTIVE flag */ if_setdrvflagbits(apc->ndev, IFF_DRV_OACTIVE, 0); counter_u64_add(tx_stats->stop, 1); uint64_t stops = counter_u64_fetch(tx_stats->stop); uint64_t wakeups = counter_u64_fetch(tx_stats->wakeup); #define MANA_TXQ_STOP_THRESHOLD 50 if (stops > MANA_TXQ_STOP_THRESHOLD && wakeups > 0 && stops > wakeups && txq->alt_txq_idx == txq->idx) { txq->alt_txq_idx = (txq->idx + (stops / wakeups)) % apc->num_queues; counter_u64_add(tx_stats->alt_chg, 1); } drbr_putback(ndev, txq->txq_br, mbuf); taskqueue_enqueue(cq->cleanup_tq, &cq->cleanup_task); break; } tx_info = &txq->tx_buf_info[next_to_use]; memset(&pkg, 0, sizeof(struct mana_tx_package)); pkg.wqe_req.sgl = pkg.sgl_array; err = mana_tx_map_mbuf(apc, tx_info, &mbuf, &pkg, tx_stats); if (unlikely(err)) { mana_dbg(NULL, "Failed to map tx mbuf, err %d\n", err); counter_u64_add(tx_stats->dma_mapping_err, 1); /* The mbuf is still there. Free it */ m_freem(mbuf); /* Advance the drbr queue */ drbr_advance(ndev, txq->txq_br); continue; } pkg.tx_oob.s_oob.vcq_num = cq->gdma_id; pkg.tx_oob.s_oob.vsq_frame = txq->vsq_frame; if (txq->vp_offset > MANA_SHORT_VPORT_OFFSET_MAX) { pkg.tx_oob.l_oob.long_vp_offset = txq->vp_offset; pkt_fmt = MANA_LONG_PKT_FMT; } else { pkg.tx_oob.s_oob.short_vp_offset = txq->vp_offset; } pkg.tx_oob.s_oob.pkt_fmt = pkt_fmt; if (pkt_fmt == MANA_SHORT_PKT_FMT) pkg.wqe_req.inline_oob_size = sizeof(struct mana_tx_short_oob); else pkg.wqe_req.inline_oob_size = sizeof(struct mana_tx_oob); pkg.wqe_req.inline_oob_data = &pkg.tx_oob; pkg.wqe_req.flags = 0; pkg.wqe_req.client_data_unit = 0; if (mbuf->m_pkthdr.csum_flags & CSUM_TSO) { if (MANA_L3_PROTO(mbuf) == ETHERTYPE_IP) pkg.tx_oob.s_oob.is_outer_ipv4 = 1; else pkg.tx_oob.s_oob.is_outer_ipv6 = 1; pkg.tx_oob.s_oob.comp_iphdr_csum = 1; pkg.tx_oob.s_oob.comp_tcp_csum = 1; pkg.tx_oob.s_oob.trans_off = mbuf->m_pkthdr.l3hlen; pkg.wqe_req.client_data_unit = mbuf->m_pkthdr.tso_segsz; pkg.wqe_req.flags = GDMA_WR_OOB_IN_SGL | GDMA_WR_PAD_BY_SGE0; } else if (mbuf->m_pkthdr.csum_flags & (CSUM_IP_UDP | CSUM_IP_TCP | CSUM_IP6_UDP | CSUM_IP6_TCP)) { if (MANA_L3_PROTO(mbuf) == ETHERTYPE_IP) { pkg.tx_oob.s_oob.is_outer_ipv4 = 1; pkg.tx_oob.s_oob.comp_iphdr_csum = 1; } else { pkg.tx_oob.s_oob.is_outer_ipv6 = 1; } if (MANA_L4_PROTO(mbuf) == IPPROTO_TCP) { pkg.tx_oob.s_oob.comp_tcp_csum = 1; pkg.tx_oob.s_oob.trans_off = mbuf->m_pkthdr.l3hlen; } else { pkg.tx_oob.s_oob.comp_udp_csum = 1; } } else if (mbuf->m_pkthdr.csum_flags & CSUM_IP) { pkg.tx_oob.s_oob.is_outer_ipv4 = 1; pkg.tx_oob.s_oob.comp_iphdr_csum = 1; } else { if (MANA_L3_PROTO(mbuf) == ETHERTYPE_IP) pkg.tx_oob.s_oob.is_outer_ipv4 = 1; else if (MANA_L3_PROTO(mbuf) == ETHERTYPE_IPV6) pkg.tx_oob.s_oob.is_outer_ipv6 = 1; } len = mbuf->m_pkthdr.len; err = mana_gd_post_work_request(gdma_sq, &pkg.wqe_req, (struct gdma_posted_wqe_info *)&tx_info->wqe_inf); if (unlikely(err)) { /* Should not happen */ if_printf(ndev, "Failed to post TX OOB: %d\n", err); mana_tx_unmap_mbuf(apc, tx_info); drbr_advance(ndev, txq->txq_br); continue; } next_to_use = (next_to_use + 1) % MAX_SEND_BUFFERS_PER_QUEUE; (void)atomic_inc_return(&txq->pending_sends); drbr_advance(ndev, txq->txq_br); mana_gd_wq_ring_doorbell(gd->gdma_context, gdma_sq); packets++; bytes += len; } counter_enter(); counter_u64_add_protected(tx_stats->packets, packets); counter_u64_add_protected(port_stats->tx_packets, packets); counter_u64_add_protected(tx_stats->bytes, bytes); counter_u64_add_protected(port_stats->tx_bytes, bytes); counter_exit(); txq->next_to_use = next_to_use; } static void mana_xmit_taskfunc(void *arg, int pending) { struct mana_txq *txq = (struct mana_txq *)arg; - struct ifnet *ndev = txq->ndev; + if_t ndev = txq->ndev; struct mana_port_context *apc = if_getsoftc(ndev); while (!drbr_empty(ndev, txq->txq_br) && apc->port_is_up && (if_getdrvflags(ndev) & MANA_TXQ_FULL) == IFF_DRV_RUNNING) { mtx_lock(&txq->txq_mtx); mana_xmit(txq); mtx_unlock(&txq->txq_mtx); } } #define PULLUP_HDR(m, len) \ do { \ if (unlikely((m)->m_len < (len))) { \ (m) = m_pullup((m), (len)); \ if ((m) == NULL) \ return (NULL); \ } \ } while (0) /* * If this function failed, the mbuf would be freed. */ static inline struct mbuf * mana_tso_fixup(struct mbuf *mbuf) { struct ether_vlan_header *eh = mtod(mbuf, struct ether_vlan_header *); struct tcphdr *th; uint16_t etype; int ehlen; if (eh->evl_encap_proto == ntohs(ETHERTYPE_VLAN)) { etype = ntohs(eh->evl_proto); ehlen = ETHER_HDR_LEN + ETHER_VLAN_ENCAP_LEN; } else { etype = ntohs(eh->evl_encap_proto); ehlen = ETHER_HDR_LEN; } if (etype == ETHERTYPE_IP) { struct ip *ip; int iphlen; PULLUP_HDR(mbuf, ehlen + sizeof(*ip)); ip = mtodo(mbuf, ehlen); iphlen = ip->ip_hl << 2; mbuf->m_pkthdr.l3hlen = ehlen + iphlen; PULLUP_HDR(mbuf, ehlen + iphlen + sizeof(*th)); th = mtodo(mbuf, ehlen + iphlen); ip->ip_len = 0; ip->ip_sum = 0; th->th_sum = in_pseudo(ip->ip_src.s_addr, ip->ip_dst.s_addr, htons(IPPROTO_TCP)); } else if (etype == ETHERTYPE_IPV6) { struct ip6_hdr *ip6; PULLUP_HDR(mbuf, ehlen + sizeof(*ip6) + sizeof(*th)); ip6 = mtodo(mbuf, ehlen); if (ip6->ip6_nxt != IPPROTO_TCP) { /* Realy something wrong, just return */ mana_dbg(NULL, "TSO mbuf not TCP, freed.\n"); m_freem(mbuf); return NULL; } mbuf->m_pkthdr.l3hlen = ehlen + sizeof(*ip6); th = mtodo(mbuf, ehlen + sizeof(*ip6)); ip6->ip6_plen = 0; th->th_sum = in6_cksum_pseudo(ip6, 0, IPPROTO_TCP, 0); } else { /* CSUM_TSO is set but not IP protocol. */ mana_warn(NULL, "TSO mbuf not right, freed.\n"); m_freem(mbuf); return NULL; } MANA_L3_PROTO(mbuf) = etype; return (mbuf); } /* * If this function failed, the mbuf would be freed. */ static inline struct mbuf * mana_mbuf_csum_check(struct mbuf *mbuf) { struct ether_vlan_header *eh = mtod(mbuf, struct ether_vlan_header *); struct mbuf *mbuf_next; uint16_t etype; int offset; int ehlen; if (eh->evl_encap_proto == ntohs(ETHERTYPE_VLAN)) { etype = ntohs(eh->evl_proto); ehlen = ETHER_HDR_LEN + ETHER_VLAN_ENCAP_LEN; } else { etype = ntohs(eh->evl_encap_proto); ehlen = ETHER_HDR_LEN; } mbuf_next = m_getptr(mbuf, ehlen, &offset); MANA_L4_PROTO(mbuf) = 0; if (etype == ETHERTYPE_IP) { const struct ip *ip; int iphlen; ip = (struct ip *)(mtodo(mbuf_next, offset)); iphlen = ip->ip_hl << 2; mbuf->m_pkthdr.l3hlen = ehlen + iphlen; MANA_L4_PROTO(mbuf) = ip->ip_p; } else if (etype == ETHERTYPE_IPV6) { const struct ip6_hdr *ip6; ip6 = (struct ip6_hdr *)(mtodo(mbuf_next, offset)); mbuf->m_pkthdr.l3hlen = ehlen + sizeof(*ip6); MANA_L4_PROTO(mbuf) = ip6->ip6_nxt; } else { MANA_L4_PROTO(mbuf) = 0; } MANA_L3_PROTO(mbuf) = etype; return (mbuf); } static int -mana_start_xmit(struct ifnet *ifp, struct mbuf *m) +mana_start_xmit(if_t ifp, struct mbuf *m) { struct mana_port_context *apc = if_getsoftc(ifp); struct mana_txq *txq; int is_drbr_empty; uint16_t txq_id; int err; if (unlikely((!apc->port_is_up) || (if_getdrvflags(ifp) & IFF_DRV_RUNNING) == 0)) return ENODEV; if (m->m_pkthdr.csum_flags & CSUM_TSO) { m = mana_tso_fixup(m); if (unlikely(m == NULL)) { counter_enter(); counter_u64_add_protected(apc->port_stats.tx_drops, 1); counter_exit(); return EIO; } } else { m = mana_mbuf_csum_check(m); if (unlikely(m == NULL)) { counter_enter(); counter_u64_add_protected(apc->port_stats.tx_drops, 1); counter_exit(); return EIO; } } if (M_HASHTYPE_GET(m) != M_HASHTYPE_NONE) { uint32_t hash = m->m_pkthdr.flowid; txq_id = apc->indir_table[(hash) & MANA_INDIRECT_TABLE_MASK] % apc->num_queues; } else { txq_id = m->m_pkthdr.flowid % apc->num_queues; } if (apc->enable_tx_altq) txq_id = apc->tx_qp[txq_id].txq.alt_txq_idx; txq = &apc->tx_qp[txq_id].txq; is_drbr_empty = drbr_empty(ifp, txq->txq_br); err = drbr_enqueue(ifp, txq->txq_br, m); if (unlikely(err)) { mana_warn(NULL, "txq %u failed to enqueue: %d\n", txq_id, err); taskqueue_enqueue(txq->enqueue_tq, &txq->enqueue_task); return err; } if (is_drbr_empty && mtx_trylock(&txq->txq_mtx)) { mana_xmit(txq); mtx_unlock(&txq->txq_mtx); } else { taskqueue_enqueue(txq->enqueue_tq, &txq->enqueue_task); } return 0; } static void mana_cleanup_port_context(struct mana_port_context *apc) { bus_dma_tag_destroy(apc->tx_buf_tag); bus_dma_tag_destroy(apc->rx_buf_tag); apc->rx_buf_tag = NULL; free(apc->rxqs, M_DEVBUF); apc->rxqs = NULL; mana_free_counters((counter_u64_t *)&apc->port_stats, sizeof(struct mana_port_stats)); } static int mana_init_port_context(struct mana_port_context *apc) { device_t dev = apc->ac->gdma_dev->gdma_context->dev; uint32_t tso_maxsize; int err; tso_maxsize = MAX_MBUF_FRAGS * MANA_TSO_MAXSEG_SZ - (ETHER_HDR_LEN + ETHER_VLAN_ENCAP_LEN); /* Create DMA tag for tx bufs */ err = bus_dma_tag_create(bus_get_dma_tag(dev), /* parent */ 1, 0, /* alignment, boundary */ BUS_SPACE_MAXADDR, /* lowaddr */ BUS_SPACE_MAXADDR, /* highaddr */ NULL, NULL, /* filter, filterarg */ tso_maxsize, /* maxsize */ MAX_MBUF_FRAGS, /* nsegments */ tso_maxsize, /* maxsegsize */ 0, /* flags */ NULL, NULL, /* lockfunc, lockfuncarg*/ &apc->tx_buf_tag); if (unlikely(err)) { device_printf(dev, "Feiled to create TX DMA tag\n"); return err; } /* Create DMA tag for rx bufs */ err = bus_dma_tag_create(bus_get_dma_tag(dev), /* parent */ 64, 0, /* alignment, boundary */ BUS_SPACE_MAXADDR, /* lowaddr */ BUS_SPACE_MAXADDR, /* highaddr */ NULL, NULL, /* filter, filterarg */ MJUMPAGESIZE, /* maxsize */ 1, /* nsegments */ MJUMPAGESIZE, /* maxsegsize */ 0, /* flags */ NULL, NULL, /* lockfunc, lockfuncarg*/ &apc->rx_buf_tag); if (unlikely(err)) { device_printf(dev, "Feiled to create RX DMA tag\n"); return err; } apc->rxqs = mallocarray(apc->num_queues, sizeof(struct mana_rxq *), M_DEVBUF, M_WAITOK | M_ZERO); if (!apc->rxqs) { bus_dma_tag_destroy(apc->tx_buf_tag); bus_dma_tag_destroy(apc->rx_buf_tag); apc->rx_buf_tag = NULL; return ENOMEM; } return 0; } static int mana_send_request(struct mana_context *ac, void *in_buf, uint32_t in_len, void *out_buf, uint32_t out_len) { struct gdma_context *gc = ac->gdma_dev->gdma_context; struct gdma_resp_hdr *resp = out_buf; struct gdma_req_hdr *req = in_buf; device_t dev = gc->dev; static atomic_t activity_id; int err; req->dev_id = gc->mana.dev_id; req->activity_id = atomic_inc_return(&activity_id); mana_dbg(NULL, "activity_id = %u\n", activity_id); err = mana_gd_send_request(gc, in_len, in_buf, out_len, out_buf); if (err || resp->status) { device_printf(dev, "Failed to send mana message: %d, 0x%x\n", err, resp->status); return err ? err : EPROTO; } if (req->dev_id.as_uint32 != resp->dev_id.as_uint32 || req->activity_id != resp->activity_id) { device_printf(dev, "Unexpected mana message response: %x,%x,%x,%x\n", req->dev_id.as_uint32, resp->dev_id.as_uint32, req->activity_id, resp->activity_id); return EPROTO; } return 0; } static int mana_verify_resp_hdr(const struct gdma_resp_hdr *resp_hdr, const enum mana_command_code expected_code, const uint32_t min_size) { if (resp_hdr->response.msg_type != expected_code) return EPROTO; if (resp_hdr->response.msg_version < GDMA_MESSAGE_V1) return EPROTO; if (resp_hdr->response.msg_size < min_size) return EPROTO; return 0; } static int mana_query_device_cfg(struct mana_context *ac, uint32_t proto_major_ver, uint32_t proto_minor_ver, uint32_t proto_micro_ver, uint16_t *max_num_vports) { struct gdma_context *gc = ac->gdma_dev->gdma_context; struct mana_query_device_cfg_resp resp = {}; struct mana_query_device_cfg_req req = {}; device_t dev = gc->dev; int err = 0; mana_gd_init_req_hdr(&req.hdr, MANA_QUERY_DEV_CONFIG, sizeof(req), sizeof(resp)); req.proto_major_ver = proto_major_ver; req.proto_minor_ver = proto_minor_ver; req.proto_micro_ver = proto_micro_ver; err = mana_send_request(ac, &req, sizeof(req), &resp, sizeof(resp)); if (err) { device_printf(dev, "Failed to query config: %d", err); return err; } err = mana_verify_resp_hdr(&resp.hdr, MANA_QUERY_DEV_CONFIG, sizeof(resp)); if (err || resp.hdr.status) { device_printf(dev, "Invalid query result: %d, 0x%x\n", err, resp.hdr.status); if (!err) err = EPROTO; return err; } *max_num_vports = resp.max_num_vports; mana_dbg(NULL, "mana max_num_vports from device = %d\n", *max_num_vports); return 0; } static int mana_query_vport_cfg(struct mana_port_context *apc, uint32_t vport_index, uint32_t *max_sq, uint32_t *max_rq, uint32_t *num_indir_entry) { struct mana_query_vport_cfg_resp resp = {}; struct mana_query_vport_cfg_req req = {}; int err; mana_gd_init_req_hdr(&req.hdr, MANA_QUERY_VPORT_CONFIG, sizeof(req), sizeof(resp)); req.vport_index = vport_index; err = mana_send_request(apc->ac, &req, sizeof(req), &resp, sizeof(resp)); if (err) return err; err = mana_verify_resp_hdr(&resp.hdr, MANA_QUERY_VPORT_CONFIG, sizeof(resp)); if (err) return err; if (resp.hdr.status) return EPROTO; *max_sq = resp.max_num_sq; *max_rq = resp.max_num_rq; *num_indir_entry = resp.num_indirection_ent; apc->port_handle = resp.vport; memcpy(apc->mac_addr, resp.mac_addr, ETHER_ADDR_LEN); return 0; } void mana_uncfg_vport(struct mana_port_context *apc) { MANA_APC_LOCK_LOCK(apc); apc->vport_use_count--; if (apc->vport_use_count < 0) { mana_err(NULL, "WARNING: vport_use_count less than 0: %u\n", apc->vport_use_count); } MANA_APC_LOCK_UNLOCK(apc); } int mana_cfg_vport(struct mana_port_context *apc, uint32_t protection_dom_id, uint32_t doorbell_pg_id) { struct mana_config_vport_resp resp = {}; struct mana_config_vport_req req = {}; int err; /* This function is used to program the Ethernet port in the hardware * table. It can be called from the Ethernet driver or the RDMA driver. * * For Ethernet usage, the hardware supports only one active user on a * physical port. The driver checks on the port usage before programming * the hardware when creating the RAW QP (RDMA driver) or exposing the * device to kernel NET layer (Ethernet driver). * * Because the RDMA driver doesn't know in advance which QP type the * user will create, it exposes the device with all its ports. The user * may not be able to create RAW QP on a port if this port is already * in used by the Ethernet driver from the kernel. * * This physical port limitation only applies to the RAW QP. For RC QP, * the hardware doesn't have this limitation. The user can create RC * QPs on a physical port up to the hardware limits independent of the * Ethernet usage on the same port. */ MANA_APC_LOCK_LOCK(apc); if (apc->vport_use_count > 0) { MANA_APC_LOCK_UNLOCK(apc); return EBUSY; } apc->vport_use_count++; MANA_APC_LOCK_UNLOCK(apc); mana_gd_init_req_hdr(&req.hdr, MANA_CONFIG_VPORT_TX, sizeof(req), sizeof(resp)); req.vport = apc->port_handle; req.pdid = protection_dom_id; req.doorbell_pageid = doorbell_pg_id; err = mana_send_request(apc->ac, &req, sizeof(req), &resp, sizeof(resp)); if (err) { if_printf(apc->ndev, "Failed to configure vPort: %d\n", err); goto out; } err = mana_verify_resp_hdr(&resp.hdr, MANA_CONFIG_VPORT_TX, sizeof(resp)); if (err || resp.hdr.status) { if_printf(apc->ndev, "Failed to configure vPort: %d, 0x%x\n", err, resp.hdr.status); if (!err) err = EPROTO; goto out; } apc->tx_shortform_allowed = resp.short_form_allowed; apc->tx_vp_offset = resp.tx_vport_offset; if_printf(apc->ndev, "Configured vPort %ju PD %u DB %u\n", apc->port_handle, protection_dom_id, doorbell_pg_id); out: if (err) mana_uncfg_vport(apc); return err; } static int mana_cfg_vport_steering(struct mana_port_context *apc, enum TRI_STATE rx, bool update_default_rxobj, bool update_key, bool update_tab) { uint16_t num_entries = MANA_INDIRECT_TABLE_SIZE; struct mana_cfg_rx_steer_req *req = NULL; struct mana_cfg_rx_steer_resp resp = {}; - struct ifnet *ndev = apc->ndev; + if_t ndev = apc->ndev; mana_handle_t *req_indir_tab; uint32_t req_buf_size; int err; req_buf_size = sizeof(*req) + sizeof(mana_handle_t) * num_entries; req = malloc(req_buf_size, M_DEVBUF, M_WAITOK | M_ZERO); if (!req) return ENOMEM; mana_gd_init_req_hdr(&req->hdr, MANA_CONFIG_VPORT_RX, req_buf_size, sizeof(resp)); req->vport = apc->port_handle; req->num_indir_entries = num_entries; req->indir_tab_offset = sizeof(*req); req->rx_enable = rx; req->rss_enable = apc->rss_state; req->update_default_rxobj = update_default_rxobj; req->update_hashkey = update_key; req->update_indir_tab = update_tab; req->default_rxobj = apc->default_rxobj; if (update_key) memcpy(&req->hashkey, apc->hashkey, MANA_HASH_KEY_SIZE); if (update_tab) { req_indir_tab = (mana_handle_t *)(req + 1); memcpy(req_indir_tab, apc->rxobj_table, req->num_indir_entries * sizeof(mana_handle_t)); } err = mana_send_request(apc->ac, req, req_buf_size, &resp, sizeof(resp)); if (err) { if_printf(ndev, "Failed to configure vPort RX: %d\n", err); goto out; } err = mana_verify_resp_hdr(&resp.hdr, MANA_CONFIG_VPORT_RX, sizeof(resp)); if (err) { if_printf(ndev, "vPort RX configuration failed: %d\n", err); goto out; } if (resp.hdr.status) { if_printf(ndev, "vPort RX configuration failed: 0x%x\n", resp.hdr.status); err = EPROTO; } if_printf(ndev, "Configured steering vPort %ju entries %u\n", apc->port_handle, num_entries); out: free(req, M_DEVBUF); return err; } int mana_create_wq_obj(struct mana_port_context *apc, mana_handle_t vport, uint32_t wq_type, struct mana_obj_spec *wq_spec, struct mana_obj_spec *cq_spec, mana_handle_t *wq_obj) { struct mana_create_wqobj_resp resp = {}; struct mana_create_wqobj_req req = {}; - struct ifnet *ndev = apc->ndev; + if_t ndev = apc->ndev; int err; mana_gd_init_req_hdr(&req.hdr, MANA_CREATE_WQ_OBJ, sizeof(req), sizeof(resp)); req.vport = vport; req.wq_type = wq_type; req.wq_gdma_region = wq_spec->gdma_region; req.cq_gdma_region = cq_spec->gdma_region; req.wq_size = wq_spec->queue_size; req.cq_size = cq_spec->queue_size; req.cq_moderation_ctx_id = cq_spec->modr_ctx_id; req.cq_parent_qid = cq_spec->attached_eq; err = mana_send_request(apc->ac, &req, sizeof(req), &resp, sizeof(resp)); if (err) { if_printf(ndev, "Failed to create WQ object: %d\n", err); goto out; } err = mana_verify_resp_hdr(&resp.hdr, MANA_CREATE_WQ_OBJ, sizeof(resp)); if (err || resp.hdr.status) { if_printf(ndev, "Failed to create WQ object: %d, 0x%x\n", err, resp.hdr.status); if (!err) err = EPROTO; goto out; } if (resp.wq_obj == INVALID_MANA_HANDLE) { if_printf(ndev, "Got an invalid WQ object handle\n"); err = EPROTO; goto out; } *wq_obj = resp.wq_obj; wq_spec->queue_index = resp.wq_id; cq_spec->queue_index = resp.cq_id; return 0; out: return err; } void mana_destroy_wq_obj(struct mana_port_context *apc, uint32_t wq_type, mana_handle_t wq_obj) { struct mana_destroy_wqobj_resp resp = {}; struct mana_destroy_wqobj_req req = {}; - struct ifnet *ndev = apc->ndev; + if_t ndev = apc->ndev; int err; mana_gd_init_req_hdr(&req.hdr, MANA_DESTROY_WQ_OBJ, sizeof(req), sizeof(resp)); req.wq_type = wq_type; req.wq_obj_handle = wq_obj; err = mana_send_request(apc->ac, &req, sizeof(req), &resp, sizeof(resp)); if (err) { if_printf(ndev, "Failed to destroy WQ object: %d\n", err); return; } err = mana_verify_resp_hdr(&resp.hdr, MANA_DESTROY_WQ_OBJ, sizeof(resp)); if (err || resp.hdr.status) if_printf(ndev, "Failed to destroy WQ object: %d, 0x%x\n", err, resp.hdr.status); } static void mana_destroy_eq(struct mana_context *ac) { struct gdma_context *gc = ac->gdma_dev->gdma_context; struct gdma_queue *eq; int i; if (!ac->eqs) return; for (i = 0; i < gc->max_num_queues; i++) { eq = ac->eqs[i].eq; if (!eq) continue; mana_gd_destroy_queue(gc, eq); } free(ac->eqs, M_DEVBUF); ac->eqs = NULL; } static int mana_create_eq(struct mana_context *ac) { struct gdma_dev *gd = ac->gdma_dev; struct gdma_context *gc = gd->gdma_context; struct gdma_queue_spec spec = {}; int err; int i; ac->eqs = mallocarray(gc->max_num_queues, sizeof(struct mana_eq), M_DEVBUF, M_WAITOK | M_ZERO); if (!ac->eqs) return ENOMEM; spec.type = GDMA_EQ; spec.monitor_avl_buf = false; spec.queue_size = EQ_SIZE; spec.eq.callback = NULL; spec.eq.context = ac->eqs; spec.eq.log2_throttle_limit = LOG2_EQ_THROTTLE; for (i = 0; i < gc->max_num_queues; i++) { err = mana_gd_create_mana_eq(gd, &spec, &ac->eqs[i].eq); if (err) goto out; } return 0; out: mana_destroy_eq(ac); return err; } static int mana_fence_rq(struct mana_port_context *apc, struct mana_rxq *rxq) { struct mana_fence_rq_resp resp = {}; struct mana_fence_rq_req req = {}; int err; init_completion(&rxq->fence_event); mana_gd_init_req_hdr(&req.hdr, MANA_FENCE_RQ, sizeof(req), sizeof(resp)); req.wq_obj_handle = rxq->rxobj; err = mana_send_request(apc->ac, &req, sizeof(req), &resp, sizeof(resp)); if (err) { if_printf(apc->ndev, "Failed to fence RQ %u: %d\n", rxq->rxq_idx, err); return err; } err = mana_verify_resp_hdr(&resp.hdr, MANA_FENCE_RQ, sizeof(resp)); if (err || resp.hdr.status) { if_printf(apc->ndev, "Failed to fence RQ %u: %d, 0x%x\n", rxq->rxq_idx, err, resp.hdr.status); if (!err) err = EPROTO; return err; } if (wait_for_completion_timeout(&rxq->fence_event, 10 * hz)) { if_printf(apc->ndev, "Failed to fence RQ %u: timed out\n", rxq->rxq_idx); return ETIMEDOUT; } return 0; } static void mana_fence_rqs(struct mana_port_context *apc) { unsigned int rxq_idx; struct mana_rxq *rxq; int err; for (rxq_idx = 0; rxq_idx < apc->num_queues; rxq_idx++) { rxq = apc->rxqs[rxq_idx]; err = mana_fence_rq(apc, rxq); /* In case of any error, use sleep instead. */ if (err) gdma_msleep(100); } } static int mana_move_wq_tail(struct gdma_queue *wq, uint32_t num_units) { uint32_t used_space_old; uint32_t used_space_new; used_space_old = wq->head - wq->tail; used_space_new = wq->head - (wq->tail + num_units); if (used_space_new > used_space_old) { mana_err(NULL, "WARNING: new used space %u greater than old one %u\n", used_space_new, used_space_old); return ERANGE; } wq->tail += num_units; return 0; } static void mana_poll_tx_cq(struct mana_cq *cq) { struct gdma_comp *completions = cq->gdma_comp_buf; struct gdma_posted_wqe_info *wqe_info; struct mana_send_buf_info *tx_info; unsigned int pkt_transmitted = 0; unsigned int wqe_unit_cnt = 0; struct mana_txq *txq = cq->txq; struct mana_port_context *apc; uint16_t next_to_complete; - struct ifnet *ndev; + if_t ndev; int comp_read; int txq_idx = txq->idx;; int i; int sa_drop = 0; struct gdma_queue *gdma_wq; unsigned int avail_space; bool txq_full = false; ndev = txq->ndev; apc = if_getsoftc(ndev); comp_read = mana_gd_poll_cq(cq->gdma_cq, completions, CQE_POLLING_BUFFER); if (comp_read < 1) return; next_to_complete = txq->next_to_complete; for (i = 0; i < comp_read; i++) { struct mana_tx_comp_oob *cqe_oob; if (!completions[i].is_sq) { mana_err(NULL, "WARNING: Not for SQ\n"); return; } cqe_oob = (struct mana_tx_comp_oob *)completions[i].cqe_data; if (cqe_oob->cqe_hdr.client_type != MANA_CQE_COMPLETION) { mana_err(NULL, "WARNING: Invalid CQE client type %u\n", cqe_oob->cqe_hdr.client_type); return; } switch (cqe_oob->cqe_hdr.cqe_type) { case CQE_TX_OKAY: break; case CQE_TX_SA_DROP: case CQE_TX_MTU_DROP: case CQE_TX_INVALID_OOB: case CQE_TX_INVALID_ETH_TYPE: case CQE_TX_HDR_PROCESSING_ERROR: case CQE_TX_VF_DISABLED: case CQE_TX_VPORT_IDX_OUT_OF_RANGE: case CQE_TX_VPORT_DISABLED: case CQE_TX_VLAN_TAGGING_VIOLATION: sa_drop ++; mana_err(NULL, "TX: txq %d CQE error %d, ntc = %d, " "pending sends = %d: err ignored.\n", txq_idx, cqe_oob->cqe_hdr.cqe_type, next_to_complete, txq->pending_sends); break; default: /* If the CQE type is unexpected, log an error, * and go through the error path. */ mana_err(NULL, "ERROR: TX: Unexpected CQE type %d: HW BUG?\n", cqe_oob->cqe_hdr.cqe_type); return; } if (txq->gdma_txq_id != completions[i].wq_num) { mana_dbg(NULL, "txq gdma id not match completion wq num: " "%d != %d\n", txq->gdma_txq_id, completions[i].wq_num); break; } tx_info = &txq->tx_buf_info[next_to_complete]; if (!tx_info->mbuf) { mana_err(NULL, "WARNING: txq %d Empty mbuf on tx_info: %u, " "ntu = %u, pending_sends = %d, " "transmitted = %d, sa_drop = %d, i = %d, comp_read = %d\n", txq_idx, next_to_complete, txq->next_to_use, txq->pending_sends, pkt_transmitted, sa_drop, i, comp_read); break; } wqe_info = &tx_info->wqe_inf; wqe_unit_cnt += wqe_info->wqe_size_in_bu; mana_tx_unmap_mbuf(apc, tx_info); mb(); next_to_complete = (next_to_complete + 1) % MAX_SEND_BUFFERS_PER_QUEUE; pkt_transmitted++; } txq->next_to_complete = next_to_complete; if (wqe_unit_cnt == 0) { mana_err(NULL, "WARNING: TX ring not proceeding!\n"); return; } mana_move_wq_tail(txq->gdma_sq, wqe_unit_cnt); /* Ensure tail updated before checking q stop */ wmb(); gdma_wq = txq->gdma_sq; avail_space = mana_gd_wq_avail_space(gdma_wq); if ((if_getdrvflags(ndev) & MANA_TXQ_FULL) == MANA_TXQ_FULL) { txq_full = true; } /* Ensure checking txq_full before apc->port_is_up. */ rmb(); if (txq_full && apc->port_is_up && avail_space >= MAX_TX_WQE_SIZE) { /* Grab the txq lock and re-test */ mtx_lock(&txq->txq_mtx); avail_space = mana_gd_wq_avail_space(gdma_wq); if ((if_getdrvflags(ndev) & MANA_TXQ_FULL) == MANA_TXQ_FULL && apc->port_is_up && avail_space >= MAX_TX_WQE_SIZE) { /* Clear the Q full flag */ if_setdrvflagbits(apc->ndev, IFF_DRV_RUNNING, IFF_DRV_OACTIVE); counter_u64_add(txq->stats.wakeup, 1); if (txq->alt_txq_idx != txq->idx) { uint64_t stops = counter_u64_fetch(txq->stats.stop); uint64_t wakeups = counter_u64_fetch(txq->stats.wakeup); /* Reset alt_txq_idx back if it is not overloaded */ if (stops < wakeups) { txq->alt_txq_idx = txq->idx; counter_u64_add(txq->stats.alt_reset, 1); } } rmb(); /* Schedule a tx enqueue task */ taskqueue_enqueue(txq->enqueue_tq, &txq->enqueue_task); } mtx_unlock(&txq->txq_mtx); } if (atomic_sub_return(pkt_transmitted, &txq->pending_sends) < 0) mana_err(NULL, "WARNING: TX %d pending_sends error: %d\n", txq->idx, txq->pending_sends); cq->work_done = pkt_transmitted; } static void mana_post_pkt_rxq(struct mana_rxq *rxq) { struct mana_recv_buf_oob *recv_buf_oob; uint32_t curr_index; int err; curr_index = rxq->buf_index++; if (rxq->buf_index == rxq->num_rx_buf) rxq->buf_index = 0; recv_buf_oob = &rxq->rx_oobs[curr_index]; err = mana_gd_post_and_ring(rxq->gdma_rq, &recv_buf_oob->wqe_req, &recv_buf_oob->wqe_inf); if (err) { mana_err(NULL, "WARNING: rxq %u post pkt err %d\n", rxq->rxq_idx, err); return; } if (recv_buf_oob->wqe_inf.wqe_size_in_bu != 1) { mana_err(NULL, "WARNING: rxq %u wqe_size_in_bu %u\n", rxq->rxq_idx, recv_buf_oob->wqe_inf.wqe_size_in_bu); } } static void mana_rx_mbuf(struct mbuf *mbuf, struct mana_rxcomp_oob *cqe, struct mana_rxq *rxq) { struct mana_stats *rx_stats = &rxq->stats; - struct ifnet *ndev = rxq->ndev; + if_t ndev = rxq->ndev; uint32_t pkt_len = cqe->ppi[0].pkt_len; uint16_t rxq_idx = rxq->rxq_idx; struct mana_port_context *apc; bool do_lro = false; bool do_if_input; apc = if_getsoftc(ndev); rxq->rx_cq.work_done++; if (!mbuf) { return; } mbuf->m_flags |= M_PKTHDR; mbuf->m_pkthdr.len = pkt_len; mbuf->m_len = pkt_len; mbuf->m_pkthdr.rcvif = ndev; - if ((ndev->if_capenable & IFCAP_RXCSUM || - ndev->if_capenable & IFCAP_RXCSUM_IPV6) && + if ((if_getcapenable(ndev) & IFCAP_RXCSUM || + if_getcapenable(ndev) & IFCAP_RXCSUM_IPV6) && (cqe->rx_iphdr_csum_succeed)) { mbuf->m_pkthdr.csum_flags = CSUM_IP_CHECKED; mbuf->m_pkthdr.csum_flags |= CSUM_IP_VALID; if (cqe->rx_tcp_csum_succeed || cqe->rx_udp_csum_succeed) { mbuf->m_pkthdr.csum_flags |= (CSUM_DATA_VALID | CSUM_PSEUDO_HDR); mbuf->m_pkthdr.csum_data = 0xffff; if (cqe->rx_tcp_csum_succeed) do_lro = true; } } if (cqe->rx_hashtype != 0) { mbuf->m_pkthdr.flowid = cqe->ppi[0].pkt_hash; uint16_t hashtype = cqe->rx_hashtype; if (hashtype & NDIS_HASH_IPV4_MASK) { hashtype &= NDIS_HASH_IPV4_MASK; switch (hashtype) { case NDIS_HASH_TCP_IPV4: M_HASHTYPE_SET(mbuf, M_HASHTYPE_RSS_TCP_IPV4); break; case NDIS_HASH_UDP_IPV4: M_HASHTYPE_SET(mbuf, M_HASHTYPE_RSS_UDP_IPV4); break; default: M_HASHTYPE_SET(mbuf, M_HASHTYPE_RSS_IPV4); } } else if (hashtype & NDIS_HASH_IPV6_MASK) { hashtype &= NDIS_HASH_IPV6_MASK; switch (hashtype) { case NDIS_HASH_TCP_IPV6: M_HASHTYPE_SET(mbuf, M_HASHTYPE_RSS_TCP_IPV6); break; case NDIS_HASH_TCP_IPV6_EX: M_HASHTYPE_SET(mbuf, M_HASHTYPE_RSS_TCP_IPV6_EX); break; case NDIS_HASH_UDP_IPV6: M_HASHTYPE_SET(mbuf, M_HASHTYPE_RSS_UDP_IPV6); break; case NDIS_HASH_UDP_IPV6_EX: M_HASHTYPE_SET(mbuf, M_HASHTYPE_RSS_UDP_IPV6_EX); break; default: M_HASHTYPE_SET(mbuf, M_HASHTYPE_RSS_IPV6); } } else { M_HASHTYPE_SET(mbuf, M_HASHTYPE_OPAQUE_HASH); } } else { mbuf->m_pkthdr.flowid = rxq_idx; M_HASHTYPE_SET(mbuf, M_HASHTYPE_NONE); } do_if_input = true; - if ((ndev->if_capenable & IFCAP_LRO) && do_lro) { + if ((if_getcapenable(ndev) & IFCAP_LRO) && do_lro) { if (rxq->lro.lro_cnt != 0 && tcp_lro_rx(&rxq->lro, mbuf, 0) == 0) do_if_input = false; } if (do_if_input) { - ndev->if_input(ndev, mbuf); + if_input(ndev, mbuf); } counter_enter(); counter_u64_add_protected(rx_stats->packets, 1); counter_u64_add_protected(apc->port_stats.rx_packets, 1); counter_u64_add_protected(rx_stats->bytes, pkt_len); counter_u64_add_protected(apc->port_stats.rx_bytes, pkt_len); counter_exit(); } static void mana_process_rx_cqe(struct mana_rxq *rxq, struct mana_cq *cq, struct gdma_comp *cqe) { struct mana_rxcomp_oob *oob = (struct mana_rxcomp_oob *)cqe->cqe_data; struct mana_recv_buf_oob *rxbuf_oob; - struct ifnet *ndev = rxq->ndev; + if_t ndev = rxq->ndev; struct mana_port_context *apc; struct mbuf *old_mbuf; uint32_t curr, pktlen; int err; switch (oob->cqe_hdr.cqe_type) { case CQE_RX_OKAY: break; case CQE_RX_TRUNCATED: apc = if_getsoftc(ndev); counter_u64_add(apc->port_stats.rx_drops, 1); rxbuf_oob = &rxq->rx_oobs[rxq->buf_index]; if_printf(ndev, "Dropped a truncated packet\n"); goto drop; case CQE_RX_COALESCED_4: if_printf(ndev, "RX coalescing is unsupported\n"); return; case CQE_RX_OBJECT_FENCE: complete(&rxq->fence_event); return; default: if_printf(ndev, "Unknown RX CQE type = %d\n", oob->cqe_hdr.cqe_type); return; } if (oob->cqe_hdr.cqe_type != CQE_RX_OKAY) return; pktlen = oob->ppi[0].pkt_len; if (pktlen == 0) { /* data packets should never have packetlength of zero */ if_printf(ndev, "RX pkt len=0, rq=%u, cq=%u, rxobj=0x%jx\n", rxq->gdma_id, cq->gdma_id, rxq->rxobj); return; } curr = rxq->buf_index; rxbuf_oob = &rxq->rx_oobs[curr]; if (rxbuf_oob->wqe_inf.wqe_size_in_bu != 1) { mana_err(NULL, "WARNING: Rx Incorrect complete " "WQE size %u\n", rxbuf_oob->wqe_inf.wqe_size_in_bu); } apc = if_getsoftc(ndev); old_mbuf = rxbuf_oob->mbuf; /* Unload DMA map for the old mbuf */ mana_unload_rx_mbuf(apc, rxq, rxbuf_oob, false); /* Load a new mbuf to replace the old one */ err = mana_load_rx_mbuf(apc, rxq, rxbuf_oob, true); if (err) { mana_dbg(NULL, "failed to load rx mbuf, err = %d, packet dropped.\n", err); counter_u64_add(rxq->stats.mbuf_alloc_fail, 1); /* * Failed to load new mbuf, rxbuf_oob->mbuf is still * pointing to the old one. Drop the packet. */ old_mbuf = NULL; /* Reload the existing mbuf */ mana_load_rx_mbuf(apc, rxq, rxbuf_oob, false); } mana_rx_mbuf(old_mbuf, oob, rxq); drop: mana_move_wq_tail(rxq->gdma_rq, rxbuf_oob->wqe_inf.wqe_size_in_bu); mana_post_pkt_rxq(rxq); } static void mana_poll_rx_cq(struct mana_cq *cq) { struct gdma_comp *comp = cq->gdma_comp_buf; int comp_read, i; comp_read = mana_gd_poll_cq(cq->gdma_cq, comp, CQE_POLLING_BUFFER); KASSERT(comp_read <= CQE_POLLING_BUFFER, ("comp_read %d great than buf size %d", comp_read, CQE_POLLING_BUFFER)); for (i = 0; i < comp_read; i++) { if (comp[i].is_sq == true) { mana_err(NULL, "WARNING: CQE not for receive queue\n"); return; } /* verify recv cqe references the right rxq */ if (comp[i].wq_num != cq->rxq->gdma_id) { mana_err(NULL, "WARNING: Received CQE %d not for " "this receive queue %d\n", comp[i].wq_num, cq->rxq->gdma_id); return; } mana_process_rx_cqe(cq->rxq, cq, &comp[i]); } tcp_lro_flush_all(&cq->rxq->lro); } static void mana_cq_handler(void *context, struct gdma_queue *gdma_queue) { struct mana_cq *cq = context; uint8_t arm_bit; KASSERT(cq->gdma_cq == gdma_queue, ("cq do not match %p, %p", cq->gdma_cq, gdma_queue)); if (cq->type == MANA_CQ_TYPE_RX) { mana_poll_rx_cq(cq); } else { mana_poll_tx_cq(cq); } if (cq->work_done < cq->budget && cq->do_not_ring_db == false) arm_bit = SET_ARM_BIT; else arm_bit = 0; mana_gd_ring_cq(gdma_queue, arm_bit); } #define MANA_POLL_BUDGET 8 #define MANA_RX_BUDGET 256 #define MANA_TX_BUDGET MAX_SEND_BUFFERS_PER_QUEUE static void mana_poll(void *arg, int pending) { struct mana_cq *cq = arg; int i; cq->work_done = 0; if (cq->type == MANA_CQ_TYPE_RX) { cq->budget = MANA_RX_BUDGET; } else { cq->budget = MANA_TX_BUDGET; } for (i = 0; i < MANA_POLL_BUDGET; i++) { /* * If this is the last loop, set the budget big enough * so it will arm the CQ any way. */ if (i == (MANA_POLL_BUDGET - 1)) cq->budget = CQE_POLLING_BUFFER + 1; mana_cq_handler(cq, cq->gdma_cq); if (cq->work_done < cq->budget) break; cq->work_done = 0; } } static void mana_schedule_task(void *arg, struct gdma_queue *gdma_queue) { struct mana_cq *cq = arg; taskqueue_enqueue(cq->cleanup_tq, &cq->cleanup_task); } static void mana_deinit_cq(struct mana_port_context *apc, struct mana_cq *cq) { struct gdma_dev *gd = apc->ac->gdma_dev; if (!cq->gdma_cq) return; /* Drain cleanup taskqueue */ if (cq->cleanup_tq) { while (taskqueue_cancel(cq->cleanup_tq, &cq->cleanup_task, NULL)) { taskqueue_drain(cq->cleanup_tq, &cq->cleanup_task); } taskqueue_free(cq->cleanup_tq); } mana_gd_destroy_queue(gd->gdma_context, cq->gdma_cq); } static void mana_deinit_txq(struct mana_port_context *apc, struct mana_txq *txq) { struct gdma_dev *gd = apc->ac->gdma_dev; struct mana_send_buf_info *txbuf_info; uint32_t pending_sends; int i; if (!txq->gdma_sq) return; if ((pending_sends = atomic_read(&txq->pending_sends)) > 0) { mana_err(NULL, "WARNING: txq pending sends not zero: %u\n", pending_sends); } if (txq->next_to_use != txq->next_to_complete) { mana_err(NULL, "WARNING: txq buf not completed, " "next use %u, next complete %u\n", txq->next_to_use, txq->next_to_complete); } /* Flush buf ring. Grab txq mtx lock */ if (txq->txq_br) { mtx_lock(&txq->txq_mtx); drbr_flush(apc->ndev, txq->txq_br); mtx_unlock(&txq->txq_mtx); buf_ring_free(txq->txq_br, M_DEVBUF); } /* Drain taskqueue */ if (txq->enqueue_tq) { while (taskqueue_cancel(txq->enqueue_tq, &txq->enqueue_task, NULL)) { taskqueue_drain(txq->enqueue_tq, &txq->enqueue_task); } taskqueue_free(txq->enqueue_tq); } if (txq->tx_buf_info) { /* Free all mbufs which are still in-flight */ for (i = 0; i < MAX_SEND_BUFFERS_PER_QUEUE; i++) { txbuf_info = &txq->tx_buf_info[i]; if (txbuf_info->mbuf) { mana_tx_unmap_mbuf(apc, txbuf_info); } } free(txq->tx_buf_info, M_DEVBUF); } mana_free_counters((counter_u64_t *)&txq->stats, sizeof(txq->stats)); mana_gd_destroy_queue(gd->gdma_context, txq->gdma_sq); mtx_destroy(&txq->txq_mtx); } static void mana_destroy_txq(struct mana_port_context *apc) { int i; if (!apc->tx_qp) return; for (i = 0; i < apc->num_queues; i++) { mana_destroy_wq_obj(apc, GDMA_SQ, apc->tx_qp[i].tx_object); mana_deinit_cq(apc, &apc->tx_qp[i].tx_cq); mana_deinit_txq(apc, &apc->tx_qp[i].txq); } free(apc->tx_qp, M_DEVBUF); apc->tx_qp = NULL; } static int -mana_create_txq(struct mana_port_context *apc, struct ifnet *net) +mana_create_txq(struct mana_port_context *apc, if_t net) { struct mana_context *ac = apc->ac; struct gdma_dev *gd = ac->gdma_dev; struct mana_obj_spec wq_spec; struct mana_obj_spec cq_spec; struct gdma_queue_spec spec; struct gdma_context *gc; struct mana_txq *txq; struct mana_cq *cq; uint32_t txq_size; uint32_t cq_size; int err; int i; apc->tx_qp = mallocarray(apc->num_queues, sizeof(struct mana_tx_qp), M_DEVBUF, M_WAITOK | M_ZERO); if (!apc->tx_qp) return ENOMEM; /* The minimum size of the WQE is 32 bytes, hence * MAX_SEND_BUFFERS_PER_QUEUE represents the maximum number of WQEs * the SQ can store. This value is then used to size other queues * to prevent overflow. */ txq_size = MAX_SEND_BUFFERS_PER_QUEUE * 32; KASSERT(IS_ALIGNED(txq_size, PAGE_SIZE), ("txq size not page aligned")); cq_size = MAX_SEND_BUFFERS_PER_QUEUE * COMP_ENTRY_SIZE; cq_size = ALIGN(cq_size, PAGE_SIZE); gc = gd->gdma_context; for (i = 0; i < apc->num_queues; i++) { apc->tx_qp[i].tx_object = INVALID_MANA_HANDLE; /* Create SQ */ txq = &apc->tx_qp[i].txq; txq->ndev = net; txq->vp_offset = apc->tx_vp_offset; txq->idx = i; txq->alt_txq_idx = i; memset(&spec, 0, sizeof(spec)); spec.type = GDMA_SQ; spec.monitor_avl_buf = true; spec.queue_size = txq_size; err = mana_gd_create_mana_wq_cq(gd, &spec, &txq->gdma_sq); if (err) goto out; /* Create SQ's CQ */ cq = &apc->tx_qp[i].tx_cq; cq->type = MANA_CQ_TYPE_TX; cq->txq = txq; memset(&spec, 0, sizeof(spec)); spec.type = GDMA_CQ; spec.monitor_avl_buf = false; spec.queue_size = cq_size; spec.cq.callback = mana_schedule_task; spec.cq.parent_eq = ac->eqs[i].eq; spec.cq.context = cq; err = mana_gd_create_mana_wq_cq(gd, &spec, &cq->gdma_cq); if (err) goto out; memset(&wq_spec, 0, sizeof(wq_spec)); memset(&cq_spec, 0, sizeof(cq_spec)); wq_spec.gdma_region = txq->gdma_sq->mem_info.dma_region_handle; wq_spec.queue_size = txq->gdma_sq->queue_size; cq_spec.gdma_region = cq->gdma_cq->mem_info.dma_region_handle; cq_spec.queue_size = cq->gdma_cq->queue_size; cq_spec.modr_ctx_id = 0; cq_spec.attached_eq = cq->gdma_cq->cq.parent->id; err = mana_create_wq_obj(apc, apc->port_handle, GDMA_SQ, &wq_spec, &cq_spec, &apc->tx_qp[i].tx_object); if (err) goto out; txq->gdma_sq->id = wq_spec.queue_index; cq->gdma_cq->id = cq_spec.queue_index; txq->gdma_sq->mem_info.dma_region_handle = GDMA_INVALID_DMA_REGION; cq->gdma_cq->mem_info.dma_region_handle = GDMA_INVALID_DMA_REGION; txq->gdma_txq_id = txq->gdma_sq->id; cq->gdma_id = cq->gdma_cq->id; mana_dbg(NULL, "txq %d, txq gdma id %d, txq cq gdma id %d\n", i, txq->gdma_txq_id, cq->gdma_id);; if (cq->gdma_id >= gc->max_num_cqs) { if_printf(net, "CQ id %u too large.\n", cq->gdma_id); err = EINVAL; goto out; } gc->cq_table[cq->gdma_id] = cq->gdma_cq; /* Initialize tx specific data */ txq->tx_buf_info = malloc(MAX_SEND_BUFFERS_PER_QUEUE * sizeof(struct mana_send_buf_info), M_DEVBUF, M_WAITOK | M_ZERO); if (unlikely(txq->tx_buf_info == NULL)) { if_printf(net, "Failed to allocate tx buf info for SQ %u\n", txq->gdma_sq->id); err = ENOMEM; goto out; } snprintf(txq->txq_mtx_name, nitems(txq->txq_mtx_name), "mana:tx(%d)", i); mtx_init(&txq->txq_mtx, txq->txq_mtx_name, NULL, MTX_DEF); txq->txq_br = buf_ring_alloc(4 * MAX_SEND_BUFFERS_PER_QUEUE, M_DEVBUF, M_WAITOK, &txq->txq_mtx); if (unlikely(txq->txq_br == NULL)) { if_printf(net, "Failed to allocate buf ring for SQ %u\n", txq->gdma_sq->id); err = ENOMEM; goto out; } /* Allocate taskqueue for deferred send */ TASK_INIT(&txq->enqueue_task, 0, mana_xmit_taskfunc, txq); txq->enqueue_tq = taskqueue_create_fast("mana_tx_enque", M_NOWAIT, taskqueue_thread_enqueue, &txq->enqueue_tq); if (unlikely(txq->enqueue_tq == NULL)) { if_printf(net, "Unable to create tx %d enqueue task queue\n", i); err = ENOMEM; goto out; } taskqueue_start_threads(&txq->enqueue_tq, 1, PI_NET, "mana txq p%u-tx%d", apc->port_idx, i); mana_alloc_counters((counter_u64_t *)&txq->stats, sizeof(txq->stats)); /* Allocate and start the cleanup task on CQ */ cq->do_not_ring_db = false; NET_TASK_INIT(&cq->cleanup_task, 0, mana_poll, cq); cq->cleanup_tq = taskqueue_create_fast("mana tx cq cleanup", M_WAITOK, taskqueue_thread_enqueue, &cq->cleanup_tq); if (apc->last_tx_cq_bind_cpu < 0) apc->last_tx_cq_bind_cpu = CPU_FIRST(); cq->cpu = apc->last_tx_cq_bind_cpu; apc->last_tx_cq_bind_cpu = CPU_NEXT(apc->last_tx_cq_bind_cpu); if (apc->bind_cleanup_thread_cpu) { cpuset_t cpu_mask; CPU_SETOF(cq->cpu, &cpu_mask); taskqueue_start_threads_cpuset(&cq->cleanup_tq, 1, PI_NET, &cpu_mask, "mana cq p%u-tx%u-cpu%d", apc->port_idx, txq->idx, cq->cpu); } else { taskqueue_start_threads(&cq->cleanup_tq, 1, PI_NET, "mana cq p%u-tx%u", apc->port_idx, txq->idx); } mana_gd_ring_cq(cq->gdma_cq, SET_ARM_BIT); } return 0; out: mana_destroy_txq(apc); return err; } static void mana_destroy_rxq(struct mana_port_context *apc, struct mana_rxq *rxq, bool validate_state) { struct gdma_context *gc = apc->ac->gdma_dev->gdma_context; struct mana_recv_buf_oob *rx_oob; int i; if (!rxq) return; if (validate_state) { /* * XXX Cancel and drain cleanup task queue here. */ ; } mana_destroy_wq_obj(apc, GDMA_RQ, rxq->rxobj); mana_deinit_cq(apc, &rxq->rx_cq); mana_free_counters((counter_u64_t *)&rxq->stats, sizeof(rxq->stats)); /* Free LRO resources */ tcp_lro_free(&rxq->lro); for (i = 0; i < rxq->num_rx_buf; i++) { rx_oob = &rxq->rx_oobs[i]; if (rx_oob->mbuf) mana_unload_rx_mbuf(apc, rxq, rx_oob, true); bus_dmamap_destroy(apc->rx_buf_tag, rx_oob->dma_map); } if (rxq->gdma_rq) mana_gd_destroy_queue(gc, rxq->gdma_rq); free(rxq, M_DEVBUF); } #define MANA_WQE_HEADER_SIZE 16 #define MANA_WQE_SGE_SIZE 16 static int mana_alloc_rx_wqe(struct mana_port_context *apc, struct mana_rxq *rxq, uint32_t *rxq_size, uint32_t *cq_size) { struct mana_recv_buf_oob *rx_oob; uint32_t buf_idx; int err; if (rxq->datasize == 0 || rxq->datasize > PAGE_SIZE) { mana_err(NULL, "WARNING: Invalid rxq datasize %u\n", rxq->datasize); } *rxq_size = 0; *cq_size = 0; for (buf_idx = 0; buf_idx < rxq->num_rx_buf; buf_idx++) { rx_oob = &rxq->rx_oobs[buf_idx]; memset(rx_oob, 0, sizeof(*rx_oob)); err = bus_dmamap_create(apc->rx_buf_tag, 0, &rx_oob->dma_map); if (err) { mana_err(NULL, "Failed to create rx DMA map for buf %d\n", buf_idx); return err; } err = mana_load_rx_mbuf(apc, rxq, rx_oob, true); if (err) { mana_err(NULL, "Failed to create rx DMA map for buf %d\n", buf_idx); bus_dmamap_destroy(apc->rx_buf_tag, rx_oob->dma_map); return err; } rx_oob->wqe_req.sgl = rx_oob->sgl; rx_oob->wqe_req.num_sge = rx_oob->num_sge; rx_oob->wqe_req.inline_oob_size = 0; rx_oob->wqe_req.inline_oob_data = NULL; rx_oob->wqe_req.flags = 0; rx_oob->wqe_req.client_data_unit = 0; *rxq_size += ALIGN(MANA_WQE_HEADER_SIZE + MANA_WQE_SGE_SIZE * rx_oob->num_sge, 32); *cq_size += COMP_ENTRY_SIZE; } return 0; } static int mana_push_wqe(struct mana_rxq *rxq) { struct mana_recv_buf_oob *rx_oob; uint32_t buf_idx; int err; for (buf_idx = 0; buf_idx < rxq->num_rx_buf; buf_idx++) { rx_oob = &rxq->rx_oobs[buf_idx]; err = mana_gd_post_and_ring(rxq->gdma_rq, &rx_oob->wqe_req, &rx_oob->wqe_inf); if (err) return ENOSPC; } return 0; } static struct mana_rxq * mana_create_rxq(struct mana_port_context *apc, uint32_t rxq_idx, - struct mana_eq *eq, struct ifnet *ndev) + struct mana_eq *eq, if_t ndev) { struct gdma_dev *gd = apc->ac->gdma_dev; struct mana_obj_spec wq_spec; struct mana_obj_spec cq_spec; struct gdma_queue_spec spec; struct mana_cq *cq = NULL; uint32_t cq_size, rq_size; struct gdma_context *gc; struct mana_rxq *rxq; int err; gc = gd->gdma_context; rxq = malloc(sizeof(*rxq) + RX_BUFFERS_PER_QUEUE * sizeof(struct mana_recv_buf_oob), M_DEVBUF, M_WAITOK | M_ZERO); if (!rxq) return NULL; rxq->ndev = ndev; rxq->num_rx_buf = RX_BUFFERS_PER_QUEUE; rxq->rxq_idx = rxq_idx; /* * Minimum size is MCLBYTES(2048) bytes for a mbuf cluster. * Now we just allow maximum size of 4096. */ rxq->datasize = ALIGN(apc->frame_size, MCLBYTES); if (rxq->datasize > MAX_FRAME_SIZE) rxq->datasize = MAX_FRAME_SIZE; mana_dbg(NULL, "Setting rxq %d datasize %d\n", rxq_idx, rxq->datasize); rxq->rxobj = INVALID_MANA_HANDLE; err = mana_alloc_rx_wqe(apc, rxq, &rq_size, &cq_size); if (err) goto out; /* Create LRO for the RQ */ - if (ndev->if_capenable & IFCAP_LRO) { + if (if_getcapenable(ndev) & IFCAP_LRO) { err = tcp_lro_init(&rxq->lro); if (err) { if_printf(ndev, "Failed to create LRO for rxq %d\n", rxq_idx); } else { rxq->lro.ifp = ndev; } } mana_alloc_counters((counter_u64_t *)&rxq->stats, sizeof(rxq->stats)); rq_size = ALIGN(rq_size, PAGE_SIZE); cq_size = ALIGN(cq_size, PAGE_SIZE); /* Create RQ */ memset(&spec, 0, sizeof(spec)); spec.type = GDMA_RQ; spec.monitor_avl_buf = true; spec.queue_size = rq_size; err = mana_gd_create_mana_wq_cq(gd, &spec, &rxq->gdma_rq); if (err) goto out; /* Create RQ's CQ */ cq = &rxq->rx_cq; cq->type = MANA_CQ_TYPE_RX; cq->rxq = rxq; memset(&spec, 0, sizeof(spec)); spec.type = GDMA_CQ; spec.monitor_avl_buf = false; spec.queue_size = cq_size; spec.cq.callback = mana_schedule_task; spec.cq.parent_eq = eq->eq; spec.cq.context = cq; err = mana_gd_create_mana_wq_cq(gd, &spec, &cq->gdma_cq); if (err) goto out; memset(&wq_spec, 0, sizeof(wq_spec)); memset(&cq_spec, 0, sizeof(cq_spec)); wq_spec.gdma_region = rxq->gdma_rq->mem_info.dma_region_handle; wq_spec.queue_size = rxq->gdma_rq->queue_size; cq_spec.gdma_region = cq->gdma_cq->mem_info.dma_region_handle; cq_spec.queue_size = cq->gdma_cq->queue_size; cq_spec.modr_ctx_id = 0; cq_spec.attached_eq = cq->gdma_cq->cq.parent->id; err = mana_create_wq_obj(apc, apc->port_handle, GDMA_RQ, &wq_spec, &cq_spec, &rxq->rxobj); if (err) goto out; rxq->gdma_rq->id = wq_spec.queue_index; cq->gdma_cq->id = cq_spec.queue_index; rxq->gdma_rq->mem_info.dma_region_handle = GDMA_INVALID_DMA_REGION; cq->gdma_cq->mem_info.dma_region_handle = GDMA_INVALID_DMA_REGION; rxq->gdma_id = rxq->gdma_rq->id; cq->gdma_id = cq->gdma_cq->id; err = mana_push_wqe(rxq); if (err) goto out; if (cq->gdma_id >= gc->max_num_cqs) { err = EINVAL; goto out; } gc->cq_table[cq->gdma_id] = cq->gdma_cq; /* Allocate and start the cleanup task on CQ */ cq->do_not_ring_db = false; NET_TASK_INIT(&cq->cleanup_task, 0, mana_poll, cq); cq->cleanup_tq = taskqueue_create_fast("mana rx cq cleanup", M_WAITOK, taskqueue_thread_enqueue, &cq->cleanup_tq); if (apc->last_rx_cq_bind_cpu < 0) apc->last_rx_cq_bind_cpu = CPU_FIRST(); cq->cpu = apc->last_rx_cq_bind_cpu; apc->last_rx_cq_bind_cpu = CPU_NEXT(apc->last_rx_cq_bind_cpu); if (apc->bind_cleanup_thread_cpu) { cpuset_t cpu_mask; CPU_SETOF(cq->cpu, &cpu_mask); taskqueue_start_threads_cpuset(&cq->cleanup_tq, 1, PI_NET, &cpu_mask, "mana cq p%u-rx%u-cpu%d", apc->port_idx, rxq->rxq_idx, cq->cpu); } else { taskqueue_start_threads(&cq->cleanup_tq, 1, PI_NET, "mana cq p%u-rx%u", apc->port_idx, rxq->rxq_idx); } mana_gd_ring_cq(cq->gdma_cq, SET_ARM_BIT); out: if (!err) return rxq; if_printf(ndev, "Failed to create RXQ: err = %d\n", err); mana_destroy_rxq(apc, rxq, false); if (cq) mana_deinit_cq(apc, cq); return NULL; } static int -mana_add_rx_queues(struct mana_port_context *apc, struct ifnet *ndev) +mana_add_rx_queues(struct mana_port_context *apc, if_t ndev) { struct mana_context *ac = apc->ac; struct mana_rxq *rxq; int err = 0; int i; for (i = 0; i < apc->num_queues; i++) { rxq = mana_create_rxq(apc, i, &ac->eqs[i], ndev); if (!rxq) { err = ENOMEM; goto out; } apc->rxqs[i] = rxq; } apc->default_rxobj = apc->rxqs[0]->rxobj; out: return err; } static void mana_destroy_vport(struct mana_port_context *apc) { struct mana_rxq *rxq; uint32_t rxq_idx; for (rxq_idx = 0; rxq_idx < apc->num_queues; rxq_idx++) { rxq = apc->rxqs[rxq_idx]; if (!rxq) continue; mana_destroy_rxq(apc, rxq, true); apc->rxqs[rxq_idx] = NULL; } mana_destroy_txq(apc); mana_uncfg_vport(apc); } static int -mana_create_vport(struct mana_port_context *apc, struct ifnet *net) +mana_create_vport(struct mana_port_context *apc, if_t net) { struct gdma_dev *gd = apc->ac->gdma_dev; int err; apc->default_rxobj = INVALID_MANA_HANDLE; err = mana_cfg_vport(apc, gd->pdid, gd->doorbell); if (err) return err; return mana_create_txq(apc, net); } static void mana_rss_table_init(struct mana_port_context *apc) { int i; for (i = 0; i < MANA_INDIRECT_TABLE_SIZE; i++) apc->indir_table[i] = i % apc->num_queues; } int mana_config_rss(struct mana_port_context *apc, enum TRI_STATE rx, bool update_hash, bool update_tab) { uint32_t queue_idx; int err; int i; if (update_tab) { for (i = 0; i < MANA_INDIRECT_TABLE_SIZE; i++) { queue_idx = apc->indir_table[i]; apc->rxobj_table[i] = apc->rxqs[queue_idx]->rxobj; } } err = mana_cfg_vport_steering(apc, rx, true, update_hash, update_tab); if (err) return err; mana_fence_rqs(apc); return 0; } static int -mana_init_port(struct ifnet *ndev) +mana_init_port(if_t ndev) { struct mana_port_context *apc = if_getsoftc(ndev); uint32_t max_txq, max_rxq, max_queues; int port_idx = apc->port_idx; uint32_t num_indirect_entries; int err; err = mana_init_port_context(apc); if (err) return err; err = mana_query_vport_cfg(apc, port_idx, &max_txq, &max_rxq, &num_indirect_entries); if (err) { if_printf(ndev, "Failed to query info for vPort %d\n", port_idx); goto reset_apc; } max_queues = min_t(uint32_t, max_txq, max_rxq); if (apc->max_queues > max_queues) apc->max_queues = max_queues; if (apc->num_queues > apc->max_queues) apc->num_queues = apc->max_queues; return 0; reset_apc: bus_dma_tag_destroy(apc->rx_buf_tag); apc->rx_buf_tag = NULL; free(apc->rxqs, M_DEVBUF); apc->rxqs = NULL; return err; } int -mana_alloc_queues(struct ifnet *ndev) +mana_alloc_queues(if_t ndev) { struct mana_port_context *apc = if_getsoftc(ndev); int err; err = mana_create_vport(apc, ndev); if (err) return err; err = mana_add_rx_queues(apc, ndev); if (err) goto destroy_vport; apc->rss_state = apc->num_queues > 1 ? TRI_STATE_TRUE : TRI_STATE_FALSE; mana_rss_table_init(apc); err = mana_config_rss(apc, TRI_STATE_TRUE, true, true); if (err) goto destroy_vport; return 0; destroy_vport: mana_destroy_vport(apc); return err; } static int mana_up(struct mana_port_context *apc) { int err; mana_dbg(NULL, "mana_up called\n"); err = mana_alloc_queues(apc->ndev); if (err) { mana_err(NULL, "Faile alloc mana queues: %d\n", err); return err; } /* Add queue specific sysctl */ mana_sysctl_add_queues(apc); apc->port_is_up = true; /* Ensure port state updated before txq state */ wmb(); if_link_state_change(apc->ndev, LINK_STATE_UP); if_setdrvflagbits(apc->ndev, IFF_DRV_RUNNING, IFF_DRV_OACTIVE); return 0; } static void mana_init(void *arg) { struct mana_port_context *apc = (struct mana_port_context *)arg; MANA_APC_LOCK_LOCK(apc); if (!apc->port_is_up) { mana_up(apc); } MANA_APC_LOCK_UNLOCK(apc); } static int -mana_dealloc_queues(struct ifnet *ndev) +mana_dealloc_queues(if_t ndev) { struct mana_port_context *apc = if_getsoftc(ndev); struct mana_txq *txq; int i, err; if (apc->port_is_up) return EINVAL; /* No packet can be transmitted now since apc->port_is_up is false. * There is still a tiny chance that mana_poll_tx_cq() can re-enable * a txq because it may not timely see apc->port_is_up being cleared * to false, but it doesn't matter since mana_start_xmit() drops any * new packets due to apc->port_is_up being false. * * Drain all the in-flight TX packets */ for (i = 0; i < apc->num_queues; i++) { txq = &apc->tx_qp[i].txq; struct mana_cq *tx_cq = &apc->tx_qp[i].tx_cq; struct mana_cq *rx_cq = &(apc->rxqs[i]->rx_cq); tx_cq->do_not_ring_db = true; rx_cq->do_not_ring_db = true; /* Schedule a cleanup task */ taskqueue_enqueue(tx_cq->cleanup_tq, &tx_cq->cleanup_task); while (atomic_read(&txq->pending_sends) > 0) usleep_range(1000, 2000); } /* We're 100% sure the queues can no longer be woken up, because * we're sure now mana_poll_tx_cq() can't be running. */ apc->rss_state = TRI_STATE_FALSE; err = mana_config_rss(apc, TRI_STATE_FALSE, false, false); if (err) { if_printf(ndev, "Failed to disable vPort: %d\n", err); return err; } mana_destroy_vport(apc); return 0; } static int mana_down(struct mana_port_context *apc) { int err = 0; apc->port_st_save = apc->port_is_up; apc->port_is_up = false; /* Ensure port state updated before txq state */ wmb(); if (apc->port_st_save) { if_setdrvflagbits(apc->ndev, IFF_DRV_OACTIVE, IFF_DRV_RUNNING); if_link_state_change(apc->ndev, LINK_STATE_DOWN); mana_sysctl_free_queues(apc); err = mana_dealloc_queues(apc->ndev); if (err) { if_printf(apc->ndev, "Failed to bring down mana interface: %d\n", err); } } return err; } int -mana_detach(struct ifnet *ndev) +mana_detach(if_t ndev) { struct mana_port_context *apc = if_getsoftc(ndev); int err; ether_ifdetach(ndev); if (!apc) return 0; MANA_APC_LOCK_LOCK(apc); err = mana_down(apc); MANA_APC_LOCK_UNLOCK(apc); mana_cleanup_port_context(apc); MANA_APC_LOCK_DESTROY(apc); free(apc, M_DEVBUF); return err; } static int mana_probe_port(struct mana_context *ac, int port_idx, - struct ifnet **ndev_storage) + if_t *ndev_storage) { struct gdma_context *gc = ac->gdma_dev->gdma_context; struct mana_port_context *apc; - struct ifnet *ndev; + if_t ndev; int err; ndev = if_alloc_dev(IFT_ETHER, gc->dev); if (!ndev) { mana_err(NULL, "Failed to allocate ifnet struct\n"); return ENOMEM; } *ndev_storage = ndev; apc = malloc(sizeof(*apc), M_DEVBUF, M_WAITOK | M_ZERO); if (!apc) { mana_err(NULL, "Failed to allocate port context\n"); err = ENOMEM; goto free_net; } apc->ac = ac; apc->ndev = ndev; apc->max_queues = gc->max_num_queues; apc->num_queues = min_t(unsigned int, gc->max_num_queues, MANA_MAX_NUM_QUEUES); apc->port_handle = INVALID_MANA_HANDLE; apc->port_idx = port_idx; apc->frame_size = DEFAULT_FRAME_SIZE; apc->last_tx_cq_bind_cpu = -1; apc->last_rx_cq_bind_cpu = -1; apc->vport_use_count = 0; MANA_APC_LOCK_INIT(apc); if_initname(ndev, device_get_name(gc->dev), port_idx); if_setdev(ndev,gc->dev); if_setsoftc(ndev, apc); if_setflags(ndev, IFF_BROADCAST | IFF_SIMPLEX | IFF_MULTICAST); if_setinitfn(ndev, mana_init); if_settransmitfn(ndev, mana_start_xmit); if_setqflushfn(ndev, mana_qflush); if_setioctlfn(ndev, mana_ioctl); if_setgetcounterfn(ndev, mana_get_counter); if_setmtu(ndev, ETHERMTU); if_setbaudrate(ndev, IF_Gbps(100)); mana_rss_key_fill(apc->hashkey, MANA_HASH_KEY_SIZE); err = mana_init_port(ndev); if (err) goto reset_apc; - ndev->if_capabilities |= IFCAP_TXCSUM | IFCAP_TXCSUM_IPV6; - ndev->if_capabilities |= IFCAP_RXCSUM | IFCAP_RXCSUM_IPV6; - ndev->if_capabilities |= IFCAP_TSO4 | IFCAP_TSO6; - - ndev->if_capabilities |= IFCAP_LRO | IFCAP_LINKSTATE; + if_setcapabilitiesbit(ndev, + IFCAP_TXCSUM | IFCAP_TXCSUM_IPV6 | + IFCAP_RXCSUM | IFCAP_RXCSUM_IPV6 | + IFCAP_TSO4 | IFCAP_TSO6 | + IFCAP_LRO | IFCAP_LINKSTATE, 0); /* Enable all available capabilities by default. */ - ndev->if_capenable = ndev->if_capabilities; + if_setcapenable(ndev, if_getcapabilities(ndev)); /* TSO parameters */ - ndev->if_hw_tsomax = MAX_MBUF_FRAGS * MANA_TSO_MAXSEG_SZ - - (ETHER_HDR_LEN + ETHER_VLAN_ENCAP_LEN); - ndev->if_hw_tsomaxsegcount = MAX_MBUF_FRAGS; - ndev->if_hw_tsomaxsegsize = PAGE_SIZE; + if_sethwtsomax(ndev, MAX_MBUF_FRAGS * MANA_TSO_MAXSEG_SZ - + (ETHER_HDR_LEN + ETHER_VLAN_ENCAP_LEN)); + if_sethwtsomaxsegcount(ndev, MAX_MBUF_FRAGS); + if_sethwtsomaxsegsize(ndev, PAGE_SIZE); ifmedia_init(&apc->media, IFM_IMASK, mana_ifmedia_change, mana_ifmedia_status); ifmedia_add(&apc->media, IFM_ETHER | IFM_AUTO, 0, NULL); ifmedia_set(&apc->media, IFM_ETHER | IFM_AUTO); ether_ifattach(ndev, apc->mac_addr); /* Initialize statistics */ mana_alloc_counters((counter_u64_t *)&apc->port_stats, sizeof(struct mana_port_stats)); mana_sysctl_add_port(apc); /* Tell the stack that the interface is not active */ if_setdrvflagbits(ndev, IFF_DRV_OACTIVE, IFF_DRV_RUNNING); return 0; reset_apc: free(apc, M_DEVBUF); free_net: *ndev_storage = NULL; if_printf(ndev, "Failed to probe vPort %d: %d\n", port_idx, err); if_free(ndev); return err; } int mana_probe(struct gdma_dev *gd) { struct gdma_context *gc = gd->gdma_context; device_t dev = gc->dev; struct mana_context *ac; int err; int i; device_printf(dev, "%s protocol version: %d.%d.%d\n", DEVICE_NAME, MANA_MAJOR_VERSION, MANA_MINOR_VERSION, MANA_MICRO_VERSION); err = mana_gd_register_device(gd); if (err) return err; ac = malloc(sizeof(*ac), M_DEVBUF, M_WAITOK | M_ZERO); if (!ac) return ENOMEM; ac->gdma_dev = gd; ac->num_ports = 1; gd->driver_data = ac; err = mana_create_eq(ac); if (err) goto out; err = mana_query_device_cfg(ac, MANA_MAJOR_VERSION, MANA_MINOR_VERSION, MANA_MICRO_VERSION, &ac->num_ports); if (err) goto out; if (ac->num_ports > MAX_PORTS_IN_MANA_DEV) ac->num_ports = MAX_PORTS_IN_MANA_DEV; for (i = 0; i < ac->num_ports; i++) { err = mana_probe_port(ac, i, &ac->ports[i]); if (err) { device_printf(dev, "Failed to probe mana port %d\n", i); break; } } out: if (err) mana_remove(gd); return err; } void mana_remove(struct gdma_dev *gd) { struct gdma_context *gc = gd->gdma_context; struct mana_context *ac = gd->driver_data; device_t dev = gc->dev; - struct ifnet *ndev; + if_t ndev; int i; for (i = 0; i < ac->num_ports; i++) { ndev = ac->ports[i]; if (!ndev) { if (i == 0) device_printf(dev, "No net device to remove\n"); goto out; } mana_detach(ndev); if_free(ndev); } mana_destroy_eq(ac); out: mana_gd_deregister_device(gd); gd->driver_data = NULL; gd->gdma_context = NULL; free(ac, M_DEVBUF); }