This patch continues the efct driver population. This patch adds driver definitions for: Routines for SCSI transport IO alloc, build and send IO. Signed-off-by: Ram Vegesna <ram.vegesna@xxxxxxxxxxxx> Signed-off-by: James Smart <jsmart2021@xxxxxxxxx> Reviewed-by: Hannes Reinecke <hare@xxxxxxx> --- v3: Removed DIF related code which is not used. Removed SCSI get property. --- drivers/scsi/elx/efct/efct_scsi.c | 1192 +++++++++++++++++++++++++++++++++++++ drivers/scsi/elx/efct/efct_scsi.h | 235 ++++++++ 2 files changed, 1427 insertions(+) create mode 100644 drivers/scsi/elx/efct/efct_scsi.c create mode 100644 drivers/scsi/elx/efct/efct_scsi.h diff --git a/drivers/scsi/elx/efct/efct_scsi.c b/drivers/scsi/elx/efct/efct_scsi.c new file mode 100644 index 000000000000..c299eadbc492 --- /dev/null +++ b/drivers/scsi/elx/efct/efct_scsi.c @@ -0,0 +1,1192 @@ +// SPDX-License-Identifier: GPL-2.0 +/* + * Copyright (C) 2019 Broadcom. All Rights Reserved. The term + * “Broadcom” refers to Broadcom Inc. and/or its subsidiaries. + */ + +#include "efct_driver.h" +#include "efct_els.h" +#include "efct_hw.h" + +#define enable_tsend_auto_resp(efct) 1 +#define enable_treceive_auto_resp(efct) 0 + +#define SCSI_IOFMT "[%04x][i:%04x t:%04x h:%04x]" + +#define scsi_io_printf(io, fmt, ...) \ + efc_log_debug(io->efct, "[%s]" SCSI_IOFMT fmt, \ + io->node->display_name, io->instance_index,\ + io->init_task_tag, io->tgt_task_tag, io->hw_tag, ##__VA_ARGS__) + +#define EFCT_LOG_ENABLE_SCSI_TRACE(efct) \ + (((efct) != NULL) ? (((efct)->logmask & (1U << 2)) != 0) : 0) + +#define scsi_io_trace(io, fmt, ...) \ + do { \ + if (EFCT_LOG_ENABLE_SCSI_TRACE(io->efct)) \ + scsi_io_printf(io, fmt, ##__VA_ARGS__); \ + } while (0) + +/* Enable the SCSI and Transport IO allocations */ +void +efct_scsi_io_alloc_enable(struct efc *efc, struct efc_node *node) +{ + unsigned long flags = 0; + + spin_lock_irqsave(&node->active_ios_lock, flags); + node->io_alloc_enabled = true; + spin_unlock_irqrestore(&node->active_ios_lock, flags); +} + +/* Disable the SCSI and Transport IO allocations */ +void +efct_scsi_io_alloc_disable(struct efc *efc, struct efc_node *node) +{ + unsigned long flags = 0; + + spin_lock_irqsave(&node->active_ios_lock, flags); + node->io_alloc_enabled = false; + spin_unlock_irqrestore(&node->active_ios_lock, flags); +} + +struct efct_io * +efct_scsi_io_alloc(struct efc_node *node, enum efct_scsi_io_role role) +{ + struct efct *efct; + struct efc *efcp; + struct efct_xport *xport; + struct efct_io *io; + unsigned long flags = 0; + + efcp = node->efc; + efct = efcp->base; + + xport = efct->xport; + + spin_lock_irqsave(&node->active_ios_lock, flags); + + if (!node->io_alloc_enabled) { + spin_unlock_irqrestore(&node->active_ios_lock, flags); + return NULL; + } + + io = efct_io_pool_io_alloc(efct->xport->io_pool); + if (!io) { + atomic_add_return(1, &xport->io_alloc_failed_count); + spin_unlock_irqrestore(&node->active_ios_lock, flags); + return NULL; + } + + /* initialize refcount */ + kref_init(&io->ref); + io->release = _efct_scsi_io_free; + + if (io->hio) { + efc_log_err(efct, + "assertion failed: io->hio is not NULL\n"); + spin_unlock_irqrestore(&node->active_ios_lock, flags); + return NULL; + } + + /* set generic fields */ + io->efct = efct; + io->node = node; + + /* set type and name */ + io->io_type = EFCT_IO_TYPE_IO; + io->display_name = "scsi_io"; + + switch (role) { + case EFCT_SCSI_IO_ROLE_ORIGINATOR: + io->cmd_ini = true; + io->cmd_tgt = false; + break; + case EFCT_SCSI_IO_ROLE_RESPONDER: + io->cmd_ini = false; + io->cmd_tgt = true; + break; + } + + /* Add to node's active_ios list */ + INIT_LIST_HEAD(&io->list_entry); + list_add_tail(&io->list_entry, &node->active_ios); + + spin_unlock_irqrestore(&node->active_ios_lock, flags); + + return io; +} + +void +_efct_scsi_io_free(struct kref *arg) +{ + struct efct_io *io = container_of(arg, struct efct_io, ref); + struct efct *efct = io->efct; + struct efc_node *node = io->node; + int send_empty_event; + unsigned long flags = 0; + + scsi_io_trace(io, "freeing io 0x%p %s\n", io, io->display_name); + + if (io->io_free) { + efc_log_err(efct, "IO already freed.\n"); + return; + } + + spin_lock_irqsave(&node->active_ios_lock, flags); + list_del(&io->list_entry); + send_empty_event = (!node->io_alloc_enabled) && + list_empty(&node->active_ios); + spin_unlock_irqrestore(&node->active_ios_lock, flags); + + if (send_empty_event) + efc_scsi_io_list_empty(node->efc, node); + + io->node = NULL; + efct_io_pool_io_free(efct->xport->io_pool, io); +} + +void +efct_scsi_io_free(struct efct_io *io) +{ + scsi_io_trace(io, "freeing io 0x%p %s\n", io, io->display_name); + WARN_ON(refcount_read(&io->ref.refcount) != 0); + kref_put(&io->ref, io->release); +} + +static void +efct_target_io_cb(struct efct_hw_io *hio, struct efc_remote_node *rnode, + u32 length, int status, u32 ext_status, void *app) +{ + struct efct_io *io = app; + struct efct *efct; + enum efct_scsi_io_status scsi_stat = EFCT_SCSI_STATUS_GOOD; + + if (!io || !io->efct) { + pr_err("%s: IO can not be NULL\n", __func__); + return; + } + + scsi_io_trace(io, "status x%x ext_status x%x\n", status, ext_status); + + efct = io->efct; + + io->transferred += length; + + /* Call target server completion */ + if (io->scsi_tgt_cb) { + efct_scsi_io_cb_t cb = io->scsi_tgt_cb; + u32 flags = 0; + + /* Clear the callback before invoking the callback */ + io->scsi_tgt_cb = NULL; + + /* if status was good, and auto-good-response was set, + * then callback target-server with IO_CMPL_RSP_SENT, + * otherwise send IO_CMPL + */ + if (status == 0 && io->auto_resp) + flags |= EFCT_SCSI_IO_CMPL_RSP_SENT; + else + flags |= EFCT_SCSI_IO_CMPL; + + switch (status) { + case SLI4_FC_WCQE_STATUS_SUCCESS: + scsi_stat = EFCT_SCSI_STATUS_GOOD; + break; + case SLI4_FC_WCQE_STATUS_DI_ERROR: + if (ext_status & SLI4_FC_DI_ERROR_GE) + scsi_stat = EFCT_SCSI_STATUS_DIF_GUARD_ERR; + else if (ext_status & SLI4_FC_DI_ERROR_AE) + scsi_stat = EFCT_SCSI_STATUS_DIF_APP_TAG_ERROR; + else if (ext_status & SLI4_FC_DI_ERROR_RE) + scsi_stat = EFCT_SCSI_STATUS_DIF_REF_TAG_ERROR; + else + scsi_stat = EFCT_SCSI_STATUS_DIF_UNKNOWN_ERROR; + break; + case SLI4_FC_WCQE_STATUS_LOCAL_REJECT: + switch (ext_status) { + case SLI4_FC_LOCAL_REJECT_INVALID_RELOFFSET: + case SLI4_FC_LOCAL_REJECT_ABORT_REQUESTED: + scsi_stat = EFCT_SCSI_STATUS_ABORTED; + break; + case SLI4_FC_LOCAL_REJECT_INVALID_RPI: + scsi_stat = EFCT_SCSI_STATUS_NEXUS_LOST; + break; + case SLI4_FC_LOCAL_REJECT_NO_XRI: + scsi_stat = EFCT_SCSI_STATUS_NO_IO; + break; + default: + /*we have seen 0x0d(TX_DMA_FAILED err)*/ + scsi_stat = EFCT_SCSI_STATUS_ERROR; + break; + } + break; + + case SLI4_FC_WCQE_STATUS_TARGET_WQE_TIMEOUT: + /* target IO timed out */ + scsi_stat = EFCT_SCSI_STATUS_TIMEDOUT_AND_ABORTED; + break; + + case SLI4_FC_WCQE_STATUS_SHUTDOWN: + /* Target IO cancelled by HW */ + scsi_stat = EFCT_SCSI_STATUS_SHUTDOWN; + break; + + default: + scsi_stat = EFCT_SCSI_STATUS_ERROR; + break; + } + + cb(io, scsi_stat, flags, io->scsi_tgt_cb_arg); + } + efct_scsi_check_pending(efct); +} + +static int +efct_scsi_build_sgls(struct efct_hw *hw, struct efct_hw_io *hio, + struct efct_scsi_sgl *sgl, u32 sgl_count, + enum efct_hw_io_type type) +{ + int rc; + u32 i; + struct efct *efct = hw->os; + + /* Initialize HW SGL */ + rc = efct_hw_io_init_sges(hw, hio, type); + if (rc) { + efc_log_err(efct, "efct_hw_io_init_sges failed: %d\n", rc); + return EFC_FAIL; + } + + for (i = 0; i < sgl_count; i++) { + + /* Add data SGE */ + rc = efct_hw_io_add_sge(hw, hio, + sgl[i].addr, sgl[i].len); + if (rc) { + efc_log_err(efct, + "add sge failed cnt=%d rc=%d\n", + sgl_count, rc); + return rc; + } + } + + return EFC_SUCCESS; +} + +static void efc_log_sgl(struct efct_io *io) +{ + struct efct_hw_io *hio = io->hio; + struct sli4_sge *data = NULL; + u32 *dword = NULL; + u32 i; + u32 n_sge; + + scsi_io_trace(io, "def_sgl at 0x%x 0x%08x\n", + upper_32_bits(hio->def_sgl.phys), + lower_32_bits(hio->def_sgl.phys)); + n_sge = (hio->sgl == &hio->def_sgl ? + hio->n_sge : hio->def_sgl_count); + for (i = 0, data = hio->def_sgl.virt; i < n_sge; i++, data++) { + dword = (u32 *)data; + + scsi_io_trace(io, "SGL %2d 0x%08x 0x%08x 0x%08x 0x%08x\n", + i, dword[0], dword[1], dword[2], dword[3]); + + if (dword[2] & (1U << 31)) + break; + } + +} + +static int +efct_scsi_check_pending_async_cb(struct efct_hw *hw, int status, + u8 *mqe, void *arg) +{ + struct efct_io *io = arg; + + if (io) { + if (io->hw_cb) { + efct_hw_done_t cb = io->hw_cb; + + io->hw_cb = NULL; + (cb)(io->hio, NULL, 0, + SLI4_FC_WCQE_STATUS_DISPATCH_ERROR, 0, io); + } + } + return EFC_SUCCESS; +} + +static int +efct_scsi_io_dispatch_hw_io(struct efct_io *io, struct efct_hw_io *hio) +{ + int rc = 0; + struct efct *efct = io->efct; + + /* Got a HW IO; + * update ini/tgt_task_tag with HW IO info and dispatch + */ + io->hio = hio; + if (io->cmd_tgt) + io->tgt_task_tag = hio->indicator; + else if (io->cmd_ini) + io->init_task_tag = hio->indicator; + io->hw_tag = hio->reqtag; + + hio->eq = io->hw_priv; + + /* Copy WQ steering */ + switch (io->wq_steering) { + case EFCT_SCSI_WQ_STEERING_CLASS >> EFCT_SCSI_WQ_STEERING_SHIFT: + hio->wq_steering = EFCT_HW_WQ_STEERING_CLASS; + break; + case EFCT_SCSI_WQ_STEERING_REQUEST >> EFCT_SCSI_WQ_STEERING_SHIFT: + hio->wq_steering = EFCT_HW_WQ_STEERING_REQUEST; + break; + case EFCT_SCSI_WQ_STEERING_CPU >> EFCT_SCSI_WQ_STEERING_SHIFT: + hio->wq_steering = EFCT_HW_WQ_STEERING_CPU; + break; + } + + switch (io->io_type) { + case EFCT_IO_TYPE_IO: + rc = efct_scsi_build_sgls(&efct->hw, io->hio, + io->sgl, io->sgl_count, io->hio_type); + if (rc) + break; + + if (EFCT_LOG_ENABLE_SCSI_TRACE(efct)) + efc_log_sgl(io); + + if (io->app_id) + io->iparam.fcp_tgt.app_id = io->app_id; + + rc = efct_hw_io_send(&io->efct->hw, io->hio_type, io->hio, + io->wire_len, &io->iparam, + &io->node->rnode, io->hw_cb, io); + break; + case EFCT_IO_TYPE_ELS: + case EFCT_IO_TYPE_CT: + rc = efct_hw_srrs_send(&efct->hw, io->hio_type, io->hio, + &io->els_req, io->wire_len, + &io->els_rsp, &io->node->rnode, &io->iparam, + io->hw_cb, io); + break; + case EFCT_IO_TYPE_CT_RESP: + rc = efct_hw_srrs_send(&efct->hw, io->hio_type, io->hio, + &io->els_rsp, io->wire_len, + NULL, &io->node->rnode, &io->iparam, + io->hw_cb, io); + break; + case EFCT_IO_TYPE_BLS_RESP: + /* no need to update tgt_task_tag for BLS response since + * the RX_ID will be specified by the payload, not the XRI + */ + rc = efct_hw_srrs_send(&efct->hw, io->hio_type, io->hio, + NULL, 0, NULL, &io->node->rnode, + &io->iparam, io->hw_cb, io); + break; + default: + scsi_io_printf(io, "Unknown IO type=%d\n", io->io_type); + rc = -1; + break; + } + return rc; +} + +static int +efct_scsi_io_dispatch_no_hw_io(struct efct_io *io) +{ + int rc; + + switch (io->io_type) { + case EFCT_IO_TYPE_ABORT: { + struct efct_hw_io *hio_to_abort = NULL; + + hio_to_abort = io->io_to_abort->hio; + + if (!hio_to_abort) { + /* + * If "IO to abort" does not have an + * associated HW IO, immediately make callback with + * success. The command must have been sent to + * the backend, but the data phase has not yet + * started, so we don't have a HW IO. + * + * Note: since the backend shims should be + * taking a reference on io_to_abort, it should not + * be possible to have been completed and freed by + * the backend before the abort got here. + */ + scsi_io_printf(io, "IO: not active\n"); + ((efct_hw_done_t)io->hw_cb)(io->hio, NULL, 0, + SLI4_FC_WCQE_STATUS_SUCCESS, 0, io); + rc = 0; + } else { + /* HW IO is valid, abort it */ + scsi_io_printf(io, "aborting\n"); + rc = efct_hw_io_abort(&io->efct->hw, hio_to_abort, + io->send_abts, io->hw_cb, io); + if (rc) { + int status = SLI4_FC_WCQE_STATUS_SUCCESS; + + if (rc != EFCT_HW_RTN_IO_NOT_ACTIVE && + rc != EFCT_HW_RTN_IO_ABORT_IN_PROGRESS) { + status = -1; + scsi_io_printf(io, + "Failed to abort IO: status=%d\n", + rc); + } + ((efct_hw_done_t)io->hw_cb)(io->hio, + NULL, 0, status, 0, io); + rc = 0; + } + } + + break; + } + default: + scsi_io_printf(io, "Unknown IO type=%d\n", io->io_type); + rc = -1; + break; + } + return rc; +} + +/** + * Check for pending IOs to dispatch. + * + * If there are IOs on the pending list, and a HW IO is available, then + * dispatch the IOs. + */ +void +efct_scsi_check_pending(struct efct *efct) +{ + struct efct_xport *xport = efct->xport; + struct efct_io *io = NULL; + struct efct_hw_io *hio; + int status; + int count = 0; + int dispatch; + unsigned long flags = 0; + + /* Guard against recursion */ + if (atomic_add_return(1, &xport->io_pending_recursing)) { + /* This function is already running. Decrement and return. */ + atomic_sub_return(1, &xport->io_pending_recursing); + return; + } + + do { + spin_lock_irqsave(&xport->io_pending_lock, flags); + status = 0; + hio = NULL; + if (!list_empty(&xport->io_pending_list)) { + io = list_first_entry(&xport->io_pending_list, + struct efct_io, + io_pending_link); + } + if (io) { + list_del(&io->io_pending_link); + if (io->io_type == EFCT_IO_TYPE_ABORT) { + hio = NULL; + } else { + hio = efct_hw_io_alloc(&efct->hw); + if (!hio) { + /* + * No HW IO available.Put IO back on + * the front of pending list + */ + list_add(&xport->io_pending_list, + &io->io_pending_link); + io = NULL; + } else { + hio->eq = io->hw_priv; + } + } + } + /* Must drop the lock before dispatching the IO */ + spin_unlock_irqrestore(&xport->io_pending_lock, flags); + + if (io) { + count++; + + /* + * We pulled an IO off the pending list, + * and either got an HW IO or don't need one + */ + atomic_sub_return(1, &xport->io_pending_count); + if (!hio) + status = efct_scsi_io_dispatch_no_hw_io(io); + else + status = efct_scsi_io_dispatch_hw_io(io, hio); + if (status) { + /* + * Invoke the HW callback, but do so in the + * separate execution context,provided by the + * NOP mailbox completion processing context + * by using efct_hw_async_call() + */ + if (efct_hw_async_call(&efct->hw, + efct_scsi_check_pending_async_cb, + io)) { + efc_log_test(efct, + "call hw async failed\n"); + } + } + } + } while (io); + + /* + * If nothing was removed from the list, + * we might be in a case where we need to abort an + * active IO and the abort is on the pending list. + * Look for an abort we can dispatch. + */ + if (count == 0) { + dispatch = 0; + + spin_lock_irqsave(&xport->io_pending_lock, flags); + list_for_each_entry(io, &xport->io_pending_list, + io_pending_link) { + if (io->io_type == EFCT_IO_TYPE_ABORT) { + if (io->io_to_abort->hio) { + /* This IO has a HW IO, so it is + * active. Dispatch the abort. + */ + dispatch = 1; + } else { + /* Leave this abort on the pending + * list and keep looking + */ + dispatch = 0; + } + } + if (dispatch) { + list_del(&io->io_pending_link); + atomic_sub_return(1, &xport->io_pending_count); + break; + } + } + spin_unlock_irqrestore(&xport->io_pending_lock, flags); + + if (dispatch) { + status = efct_scsi_io_dispatch_no_hw_io(io); + if (status) { + if (efct_hw_async_call(&efct->hw, + efct_scsi_check_pending_async_cb, + io)) { + efc_log_test(efct, + "call to hw async failed\n"); + } + } + } + } + + atomic_sub_return(1, &xport->io_pending_recursing); +} + +/** + * An IO is dispatched: + * - if the pending list is not empty, add IO to pending list + * and call a function to process the pending list. + * - if pending list is empty, try to allocate a HW IO. If none + * is available, place this IO at the tail of the pending IO + * list. + * - if HW IO is available, attach this IO to the HW IO and + * submit it. + */ +int +efct_scsi_io_dispatch(struct efct_io *io, void *cb) +{ + struct efct_hw_io *hio; + struct efct *efct = io->efct; + struct efct_xport *xport = efct->xport; + unsigned long flags = 0; + + io->hw_cb = cb; + + /* + * if this IO already has a HW IO, then this is either + * not the first phase of the IO. Send it to the HW. + */ + if (io->hio) + return efct_scsi_io_dispatch_hw_io(io, io->hio); + + /* + * We don't already have a HW IO associated with the IO. First check + * the pending list. If not empty, add IO to the tail and process the + * pending list. + */ + spin_lock_irqsave(&xport->io_pending_lock, flags); + if (!list_empty(&xport->io_pending_list)) { + /* + * If this is a low latency request, + * the put at the front of the IO pending + * queue, otherwise put it at the end of the queue. + */ + if (io->low_latency) { + INIT_LIST_HEAD(&io->io_pending_link); + list_add(&xport->io_pending_list, + &io->io_pending_link); + } else { + INIT_LIST_HEAD(&io->io_pending_link); + list_add_tail(&io->io_pending_link, + &xport->io_pending_list); + } + spin_unlock_irqrestore(&xport->io_pending_lock, flags); + atomic_add_return(1, &xport->io_pending_count); + atomic_add_return(1, &xport->io_total_pending); + + /* process pending list */ + efct_scsi_check_pending(efct); + return EFC_SUCCESS; + } + spin_unlock_irqrestore(&xport->io_pending_lock, flags); + + /* + * We don't have a HW IO associated with the IO and there's nothing + * on the pending list. Attempt to allocate a HW IO and dispatch it. + */ + hio = efct_hw_io_alloc(&io->efct->hw); + if (!hio) { + /* Couldn't get a HW IO. Save this IO on the pending list */ + spin_lock_irqsave(&xport->io_pending_lock, flags); + INIT_LIST_HEAD(&io->io_pending_link); + list_add_tail(&io->io_pending_link, &xport->io_pending_list); + spin_unlock_irqrestore(&xport->io_pending_lock, flags); + + atomic_add_return(1, &xport->io_total_pending); + atomic_add_return(1, &xport->io_pending_count); + return EFC_SUCCESS; + } + + /* We successfully allocated a HW IO; dispatch to HW */ + return efct_scsi_io_dispatch_hw_io(io, hio); +} + +/** + * An Abort IO is dispatched: + * - if the pending list is not empty, add IO to pending list + * and call a function to process the pending list. + * - if pending list is empty, send abort to the HW. + */ + +int +efct_scsi_io_dispatch_abort(struct efct_io *io, void *cb) +{ + struct efct *efct = io->efct; + struct efct_xport *xport = efct->xport; + unsigned long flags = 0; + + io->hw_cb = cb; + + /* + * For aborts, we don't need a HW IO, but we still want + * to pass through the pending list to preserve ordering. + * Thus, if the pending list is not empty, add this abort + * to the pending list and process the pending list. + */ + spin_lock_irqsave(&xport->io_pending_lock, flags); + if (!list_empty(&xport->io_pending_list)) { + INIT_LIST_HEAD(&io->io_pending_link); + list_add_tail(&io->io_pending_link, + &xport->io_pending_list); + spin_unlock_irqrestore(&xport->io_pending_lock, flags); + atomic_add_return(1, &xport->io_pending_count); + atomic_add_return(1, &xport->io_total_pending); + + /* process pending list */ + efct_scsi_check_pending(efct); + return EFC_SUCCESS; + } + spin_unlock_irqrestore(&xport->io_pending_lock, flags); + + /* nothing on pending list, dispatch abort */ + return efct_scsi_io_dispatch_no_hw_io(io); +} + +static inline int +efct_scsi_xfer_data(struct efct_io *io, u32 flags, + struct efct_scsi_sgl *sgl, u32 sgl_count, u64 xwire_len, + enum efct_hw_io_type type, int enable_ar, + efct_scsi_io_cb_t cb, void *arg) +{ + struct efct *efct; + size_t residual = 0; + + io->sgl_count = sgl_count; + + efct = io->efct; + + scsi_io_trace(io, "%s wire_len %llu\n", + (type == EFCT_HW_IO_TARGET_READ) ? "send" : "recv", + xwire_len); + + io->hio_type = type; + + io->scsi_tgt_cb = cb; + io->scsi_tgt_cb_arg = arg; + + residual = io->exp_xfer_len - io->transferred; + io->wire_len = (xwire_len < residual) ? xwire_len : residual; + residual = (xwire_len - io->wire_len); + + memset(&io->iparam, 0, sizeof(io->iparam)); + io->iparam.fcp_tgt.ox_id = io->init_task_tag; + io->iparam.fcp_tgt.offset = io->transferred; + io->iparam.fcp_tgt.cs_ctl = io->cs_ctl; + io->iparam.fcp_tgt.timeout = io->timeout; + + /* if this is the last data phase and there is no residual, enable + * auto-good-response + */ + if (enable_ar && (flags & EFCT_SCSI_LAST_DATAPHASE) && + residual == 0 && + ((io->transferred + io->wire_len) == io->exp_xfer_len) && + (!(flags & EFCT_SCSI_NO_AUTO_RESPONSE))) { + io->iparam.fcp_tgt.flags |= SLI4_IO_AUTO_GOOD_RESPONSE; + io->auto_resp = true; + } else { + io->auto_resp = false; + } + + /* save this transfer length */ + io->xfer_req = io->wire_len; + + /* Adjust the transferred count to account for overrun + * when the residual is calculated in efct_scsi_send_resp + */ + io->transferred += residual; + + /* Adjust the SGL size if there is overrun */ + + if (residual) { + struct efct_scsi_sgl *sgl_ptr = &io->sgl[sgl_count - 1]; + + while (residual) { + size_t len = sgl_ptr->len; + + if (len > residual) { + sgl_ptr->len = len - residual; + residual = 0; + } else { + sgl_ptr->len = 0; + residual -= len; + io->sgl_count--; + } + sgl_ptr--; + } + } + + /* Set latency and WQ steering */ + io->low_latency = (flags & EFCT_SCSI_LOW_LATENCY) != 0; + io->wq_steering = (flags & EFCT_SCSI_WQ_STEERING_MASK) >> + EFCT_SCSI_WQ_STEERING_SHIFT; + io->wq_class = (flags & EFCT_SCSI_WQ_CLASS_MASK) >> + EFCT_SCSI_WQ_CLASS_SHIFT; + + if (efct->xport) { + struct efct_xport *xport = efct->xport; + + if (type == EFCT_HW_IO_TARGET_READ) { + xport->fcp_stats.input_requests++; + xport->fcp_stats.input_bytes += xwire_len; + } else if (type == EFCT_HW_IO_TARGET_WRITE) { + xport->fcp_stats.output_requests++; + xport->fcp_stats.output_bytes += xwire_len; + } + } + return efct_scsi_io_dispatch(io, efct_target_io_cb); +} + +int +efct_scsi_send_rd_data(struct efct_io *io, u32 flags, + struct efct_scsi_sgl *sgl, u32 sgl_count, u64 len, + efct_scsi_io_cb_t cb, void *arg) +{ + return efct_scsi_xfer_data(io, flags, sgl, sgl_count, + len, EFCT_HW_IO_TARGET_READ, + enable_tsend_auto_resp(io->efct), cb, arg); +} + +int +efct_scsi_recv_wr_data(struct efct_io *io, u32 flags, + struct efct_scsi_sgl *sgl, u32 sgl_count, u64 len, + efct_scsi_io_cb_t cb, void *arg) +{ + return efct_scsi_xfer_data(io, flags, sgl, sgl_count, len, + EFCT_HW_IO_TARGET_WRITE, + enable_treceive_auto_resp(io->efct), cb, arg); +} + +int +efct_scsi_send_resp(struct efct_io *io, u32 flags, + struct efct_scsi_cmd_resp *rsp, + efct_scsi_io_cb_t cb, void *arg) +{ + struct efct *efct; + int residual; + bool auto_resp = true; /* Always try auto resp */ + u8 scsi_status = 0; + u16 scsi_status_qualifier = 0; + u8 *sense_data = NULL; + u32 sense_data_length = 0; + + efct = io->efct; + + if (rsp) { + scsi_status = rsp->scsi_status; + scsi_status_qualifier = rsp->scsi_status_qualifier; + sense_data = rsp->sense_data; + sense_data_length = rsp->sense_data_length; + residual = rsp->residual; + } else { + residual = io->exp_xfer_len - io->transferred; + } + + io->wire_len = 0; + io->hio_type = EFCT_HW_IO_TARGET_RSP; + + io->scsi_tgt_cb = cb; + io->scsi_tgt_cb_arg = arg; + + memset(&io->iparam, 0, sizeof(io->iparam)); + io->iparam.fcp_tgt.ox_id = io->init_task_tag; + io->iparam.fcp_tgt.offset = 0; + io->iparam.fcp_tgt.cs_ctl = io->cs_ctl; + io->iparam.fcp_tgt.timeout = io->timeout; + + /* Set low latency queueing request */ + io->low_latency = (flags & EFCT_SCSI_LOW_LATENCY) != 0; + io->wq_steering = (flags & EFCT_SCSI_WQ_STEERING_MASK) >> + EFCT_SCSI_WQ_STEERING_SHIFT; + io->wq_class = (flags & EFCT_SCSI_WQ_CLASS_MASK) >> + EFCT_SCSI_WQ_CLASS_SHIFT; + + if (scsi_status != 0 || residual || sense_data_length) { + struct fcp_resp_with_ext *fcprsp = io->rspbuf.virt; + u8 *sns_data = io->rspbuf.virt + sizeof(*fcprsp); + + if (!fcprsp) { + efc_log_err(efct, "NULL response buffer\n"); + return EFC_FAIL; + } + + auto_resp = false; + + memset(fcprsp, 0, sizeof(*fcprsp)); + + io->wire_len += sizeof(*fcprsp); + + fcprsp->resp.fr_status = scsi_status; + fcprsp->resp.fr_retry_delay = + cpu_to_be16(scsi_status_qualifier); + + /* set residual status if necessary */ + if (residual != 0) { + /* FCP: if data transferred is less than the + * amount expected, then this is an underflow. + * If data transferred would have been greater + * than the amount expected this is an overflow + */ + if (residual > 0) { + fcprsp->resp.fr_flags |= FCP_RESID_UNDER; + fcprsp->ext.fr_resid = cpu_to_be32(residual); + } else { + fcprsp->resp.fr_flags |= FCP_RESID_OVER; + fcprsp->ext.fr_resid = cpu_to_be32(-residual); + } + } + + if (EFCT_SCSI_SNS_BUF_VALID(sense_data) && sense_data_length) { + if (sense_data_length > SCSI_SENSE_BUFFERSIZE) { + efc_log_err(efct, "Sense exceeds max size.\n"); + return EFC_FAIL; + } + + fcprsp->resp.fr_flags |= FCP_SNS_LEN_VAL; + memcpy(sns_data, sense_data, sense_data_length); + fcprsp->ext.fr_sns_len = cpu_to_be32(sense_data_length); + io->wire_len += sense_data_length; + } + + io->sgl[0].addr = io->rspbuf.phys; + //io->sgl[0].dif_addr = 0; + io->sgl[0].len = io->wire_len; + io->sgl_count = 1; + } + + if (auto_resp) + io->iparam.fcp_tgt.flags |= SLI4_IO_AUTO_GOOD_RESPONSE; + + return efct_scsi_io_dispatch(io, efct_target_io_cb); +} + +static int +efct_target_bls_resp_cb(struct efct_hw_io *hio, + struct efc_remote_node *rnode, + u32 length, int status, u32 ext_status, void *app) +{ + struct efct_io *io = app; + struct efct *efct; + enum efct_scsi_io_status bls_status; + + efct = io->efct; + + /* BLS isn't really a "SCSI" concept, but use SCSI status */ + if (status) { + io_error_log(io, "s=%#x x=%#x\n", status, ext_status); + bls_status = EFCT_SCSI_STATUS_ERROR; + } else { + bls_status = EFCT_SCSI_STATUS_GOOD; + } + + if (io->bls_cb) { + efct_scsi_io_cb_t bls_cb = io->bls_cb; + void *bls_cb_arg = io->bls_cb_arg; + + io->bls_cb = NULL; + io->bls_cb_arg = NULL; + + /* invoke callback */ + bls_cb(io, bls_status, 0, bls_cb_arg); + } + + efct_scsi_check_pending(efct); + return EFC_SUCCESS; +} + +static int +efct_target_send_bls_resp(struct efct_io *io, + efct_scsi_io_cb_t cb, void *arg) +{ + int rc; + struct fc_ba_acc *acc; + + /* fill out IO structure with everything needed to send BA_ACC */ + memset(&io->iparam, 0, sizeof(io->iparam)); + io->iparam.bls.ox_id = io->init_task_tag; + io->iparam.bls.rx_id = io->abort_rx_id; + + acc = (void *)io->iparam.bls.payload; + + memset(io->iparam.bls.payload, 0, + sizeof(io->iparam.bls.payload)); + acc->ba_ox_id = cpu_to_be16(io->iparam.bls.ox_id); + acc->ba_rx_id = cpu_to_be16(io->iparam.bls.rx_id); + acc->ba_high_seq_cnt = cpu_to_be16(U16_MAX); + + /* generic io fields have already been populated */ + + /* set type and BLS-specific fields */ + io->io_type = EFCT_IO_TYPE_BLS_RESP; + io->display_name = "bls_rsp"; + io->hio_type = EFCT_HW_BLS_ACC; + io->bls_cb = cb; + io->bls_cb_arg = arg; + + /* dispatch IO */ + rc = efct_scsi_io_dispatch(io, efct_target_bls_resp_cb); + return rc; +} + +int +efct_scsi_send_tmf_resp(struct efct_io *io, + enum efct_scsi_tmf_resp rspcode, + u8 addl_rsp_info[3], + efct_scsi_io_cb_t cb, void *arg) +{ + int rc = -1; + struct fcp_resp_with_ext *fcprsp = NULL; + struct fcp_resp_rsp_info *rspinfo = NULL; + u8 fcp_rspcode; + + io->wire_len = 0; + + switch (rspcode) { + case EFCT_SCSI_TMF_FUNCTION_COMPLETE: + fcp_rspcode = FCP_TMF_CMPL; + break; + case EFCT_SCSI_TMF_FUNCTION_SUCCEEDED: + case EFCT_SCSI_TMF_FUNCTION_IO_NOT_FOUND: + fcp_rspcode = FCP_TMF_CMPL; + break; + case EFCT_SCSI_TMF_FUNCTION_REJECTED: + fcp_rspcode = FCP_TMF_REJECTED; + break; + case EFCT_SCSI_TMF_INCORRECT_LOGICAL_UNIT_NUMBER: + fcp_rspcode = FCP_TMF_INVALID_LUN; + break; + case EFCT_SCSI_TMF_SERVICE_DELIVERY: + fcp_rspcode = FCP_TMF_FAILED; + break; + default: + fcp_rspcode = FCP_TMF_REJECTED; + break; + } + + io->hio_type = EFCT_HW_IO_TARGET_RSP; + + io->scsi_tgt_cb = cb; + io->scsi_tgt_cb_arg = arg; + + if (io->tmf_cmd == EFCT_SCSI_TMF_ABORT_TASK) { + rc = efct_target_send_bls_resp(io, cb, arg); + return rc; + } + + /* populate the FCP TMF response */ + fcprsp = io->rspbuf.virt; + memset(fcprsp, 0, sizeof(*fcprsp)); + + fcprsp->resp.fr_flags |= FCP_SNS_LEN_VAL; + + rspinfo = io->rspbuf.virt + sizeof(*fcprsp); + if (addl_rsp_info) { + memcpy(rspinfo->_fr_resvd, addl_rsp_info, + sizeof(rspinfo->_fr_resvd)); + } + rspinfo->rsp_code = fcp_rspcode; + + io->wire_len = sizeof(*fcprsp) + sizeof(*rspinfo); + + fcprsp->ext.fr_rsp_len = cpu_to_be32(sizeof(*rspinfo)); + + io->sgl[0].addr = io->rspbuf.phys; + io->sgl[0].dif_addr = 0; + io->sgl[0].len = io->wire_len; + io->sgl_count = 1; + + memset(&io->iparam, 0, sizeof(io->iparam)); + io->iparam.fcp_tgt.ox_id = io->init_task_tag; + io->iparam.fcp_tgt.offset = 0; + io->iparam.fcp_tgt.cs_ctl = io->cs_ctl; + io->iparam.fcp_tgt.timeout = io->timeout; + + rc = efct_scsi_io_dispatch(io, efct_target_io_cb); + + return rc; +} + +static int +efct_target_abort_cb(struct efct_hw_io *hio, + struct efc_remote_node *rnode, + u32 length, int status, + u32 ext_status, void *app) +{ + struct efct_io *io = app; + struct efct *efct; + enum efct_scsi_io_status scsi_status; + + efct = io->efct; + + if (io->abort_cb) { + efct_scsi_io_cb_t abort_cb = io->abort_cb; + void *abort_cb_arg = io->abort_cb_arg; + + io->abort_cb = NULL; + io->abort_cb_arg = NULL; + + switch (status) { + case SLI4_FC_WCQE_STATUS_SUCCESS: + scsi_status = EFCT_SCSI_STATUS_GOOD; + break; + case SLI4_FC_WCQE_STATUS_LOCAL_REJECT: + switch (ext_status) { + case SLI4_FC_LOCAL_REJECT_NO_XRI: + scsi_status = EFCT_SCSI_STATUS_NO_IO; + break; + case SLI4_FC_LOCAL_REJECT_ABORT_IN_PROGRESS: + scsi_status = + EFCT_SCSI_STATUS_ABORT_IN_PROGRESS; + break; + default: + /*we have seen 0x15 (abort in progress)*/ + scsi_status = EFCT_SCSI_STATUS_ERROR; + break; + } + break; + case SLI4_FC_WCQE_STATUS_FCP_RSP_FAILURE: + scsi_status = EFCT_SCSI_STATUS_CHECK_RESPONSE; + break; + default: + scsi_status = EFCT_SCSI_STATUS_ERROR; + break; + } + /* invoke callback */ + abort_cb(io->io_to_abort, scsi_status, 0, abort_cb_arg); + } + + /* done with IO to abort,efct_ref_get(): efct_scsi_tgt_abort_io() */ + kref_put(&io->io_to_abort->ref, io->io_to_abort->release); + + efct_io_pool_io_free(efct->xport->io_pool, io); + + efct_scsi_check_pending(efct); + return EFC_SUCCESS; +} + +int +efct_scsi_tgt_abort_io(struct efct_io *io, efct_scsi_io_cb_t cb, void *arg) +{ + struct efct *efct; + struct efct_xport *xport; + int rc; + struct efct_io *abort_io = NULL; + + efct = io->efct; + xport = efct->xport; + + /* take a reference on IO being aborted */ + if ((kref_get_unless_zero(&io->ref) == 0)) { + /* command no longer active */ + scsi_io_printf(io, "command no longer active\n"); + return EFC_FAIL; + } + + /* + * allocate a new IO to send the abort request. Use efct_io_alloc() + * directly, as we need an IO object that will not fail allocation + * due to allocations being disabled (in efct_scsi_io_alloc()) + */ + abort_io = efct_io_pool_io_alloc(efct->xport->io_pool); + if (!abort_io) { + atomic_add_return(1, &xport->io_alloc_failed_count); + kref_put(&io->ref, io->release); + return EFC_FAIL; + } + + /* Save the target server callback and argument */ + /* set generic fields */ + abort_io->cmd_tgt = true; + abort_io->node = io->node; + + /* set type and abort-specific fields */ + abort_io->io_type = EFCT_IO_TYPE_ABORT; + abort_io->display_name = "tgt_abort"; + abort_io->io_to_abort = io; + abort_io->send_abts = false; + abort_io->abort_cb = cb; + abort_io->abort_cb_arg = arg; + + /* now dispatch IO */ + rc = efct_scsi_io_dispatch_abort(abort_io, efct_target_abort_cb); + if (rc) + kref_put(&io->ref, io->release); + return rc; +} + +void +efct_scsi_io_complete(struct efct_io *io) +{ + if (io->io_free) { + efc_log_test(io->efct, + "Got completion for non-busy io with tag 0x%x\n", + io->tag); + return; + } + + scsi_io_trace(io, "freeing io 0x%p %s\n", io, io->display_name); + kref_put(&io->ref, io->release); +} diff --git a/drivers/scsi/elx/efct/efct_scsi.h b/drivers/scsi/elx/efct/efct_scsi.h new file mode 100644 index 000000000000..28204c5fde69 --- /dev/null +++ b/drivers/scsi/elx/efct/efct_scsi.h @@ -0,0 +1,235 @@ +/* SPDX-License-Identifier: GPL-2.0 */ +/* + * Copyright (C) 2019 Broadcom. All Rights Reserved. The term + * “Broadcom” refers to Broadcom Inc. and/or its subsidiaries. + */ + +#if !defined(__EFCT_SCSI_H__) +#define __EFCT_SCSI_H__ +#include <scsi/scsi_host.h> +#include <scsi/scsi_transport_fc.h> + +/* efct_scsi_rcv_cmd() efct_scsi_rcv_tmf() flags */ +#define EFCT_SCSI_CMD_DIR_IN (1 << 0) +#define EFCT_SCSI_CMD_DIR_OUT (1 << 1) +#define EFCT_SCSI_CMD_SIMPLE (1 << 2) +#define EFCT_SCSI_CMD_HEAD_OF_QUEUE (1 << 3) +#define EFCT_SCSI_CMD_ORDERED (1 << 4) +#define EFCT_SCSI_CMD_UNTAGGED (1 << 5) +#define EFCT_SCSI_CMD_ACA (1 << 6) +#define EFCT_SCSI_FIRST_BURST_ERR (1 << 7) +#define EFCT_SCSI_FIRST_BURST_ABORTED (1 << 8) + +/* efct_scsi_send_rd_data/recv_wr_data/send_resp flags */ +#define EFCT_SCSI_LAST_DATAPHASE (1 << 0) +#define EFCT_SCSI_NO_AUTO_RESPONSE (1 << 1) +#define EFCT_SCSI_LOW_LATENCY (1 << 2) + +#define EFCT_SCSI_SNS_BUF_VALID(sense) ((sense) && \ + (0x70 == (((const u8 *)(sense))[0] & 0x70))) + +#define EFCT_SCSI_WQ_STEERING_SHIFT 16 +#define EFCT_SCSI_WQ_STEERING_MASK (0xf << EFCT_SCSI_WQ_STEERING_SHIFT) +#define EFCT_SCSI_WQ_STEERING_CLASS (0 << EFCT_SCSI_WQ_STEERING_SHIFT) +#define EFCT_SCSI_WQ_STEERING_REQUEST (1 << EFCT_SCSI_WQ_STEERING_SHIFT) +#define EFCT_SCSI_WQ_STEERING_CPU (2 << EFCT_SCSI_WQ_STEERING_SHIFT) + +#define EFCT_SCSI_WQ_CLASS_SHIFT (20) +#define EFCT_SCSI_WQ_CLASS_MASK (0xf << EFCT_SCSI_WQ_CLASS_SHIFT) +#define EFCT_SCSI_WQ_CLASS(x) ((x & EFCT_SCSI_WQ_CLASS_MASK) << \ + EFCT_SCSI_WQ_CLASS_SHIFT) + +#define EFCT_SCSI_WQ_CLASS_LOW_LATENCY 1 + +struct efct_scsi_cmd_resp { + u8 scsi_status; /* SCSI status */ + u16 scsi_status_qualifier; /* SCSI status qualifier */ + /* pointer to response data buffer */ + u8 *response_data; + /* length of response data buffer (bytes) */ + u32 response_data_length; + u8 *sense_data; /* pointer to sense data buffer */ + /* length of sense data buffer (bytes) */ + u32 sense_data_length; + /* command residual (not used for target), positive value + * indicates an underflow, negative value indicates overflow + */ + int residual; + /* Command response length received in wcqe */ + u32 response_wire_length; +}; + +struct efct_vport { + struct efct *efct; + bool is_vport; + struct fc_host_statistics fc_host_stats; + struct Scsi_Host *shost; + struct fc_vport *fc_vport; + u64 npiv_wwpn; + u64 npiv_wwnn; +}; + +/* Status values returned by IO callbacks */ +enum efct_scsi_io_status { + EFCT_SCSI_STATUS_GOOD = 0, + EFCT_SCSI_STATUS_ABORTED, + EFCT_SCSI_STATUS_ERROR, + EFCT_SCSI_STATUS_DIF_GUARD_ERR, + EFCT_SCSI_STATUS_DIF_REF_TAG_ERROR, + EFCT_SCSI_STATUS_DIF_APP_TAG_ERROR, + EFCT_SCSI_STATUS_DIF_UNKNOWN_ERROR, + EFCT_SCSI_STATUS_PROTOCOL_CRC_ERROR, + EFCT_SCSI_STATUS_NO_IO, + EFCT_SCSI_STATUS_ABORT_IN_PROGRESS, + EFCT_SCSI_STATUS_CHECK_RESPONSE, + EFCT_SCSI_STATUS_COMMAND_TIMEOUT, + EFCT_SCSI_STATUS_TIMEDOUT_AND_ABORTED, + EFCT_SCSI_STATUS_SHUTDOWN, + EFCT_SCSI_STATUS_NEXUS_LOST, +}; + +struct efct_io; +struct efc_node; +struct efc_domain; +struct efc_sli_port; + +/* Callback used by send_rd_data(), recv_wr_data(), send_resp() */ +typedef int (*efct_scsi_io_cb_t)(struct efct_io *io, + enum efct_scsi_io_status status, + u32 flags, void *arg); + +/* Callback used by send_rd_io(), send_wr_io() */ +typedef int (*efct_scsi_rsp_io_cb_t)(struct efct_io *io, + enum efct_scsi_io_status status, + struct efct_scsi_cmd_resp *rsp, + u32 flags, void *arg); + +/* efct_scsi_cb_t flags */ +#define EFCT_SCSI_IO_CMPL (1 << 0) +/* IO completed, response sent */ +#define EFCT_SCSI_IO_CMPL_RSP_SENT (1 << 1) +#define EFCT_SCSI_IO_ABORTED (1 << 2) + +/* efct_scsi_recv_tmf() request values */ +enum efct_scsi_tmf_cmd { + EFCT_SCSI_TMF_ABORT_TASK = 1, + EFCT_SCSI_TMF_QUERY_TASK_SET, + EFCT_SCSI_TMF_ABORT_TASK_SET, + EFCT_SCSI_TMF_CLEAR_TASK_SET, + EFCT_SCSI_TMF_QUERY_ASYNCHRONOUS_EVENT, + EFCT_SCSI_TMF_LOGICAL_UNIT_RESET, + EFCT_SCSI_TMF_CLEAR_ACA, + EFCT_SCSI_TMF_TARGET_RESET, +}; + +/* efct_scsi_send_tmf_resp() response values */ +enum efct_scsi_tmf_resp { + EFCT_SCSI_TMF_FUNCTION_COMPLETE = 1, + EFCT_SCSI_TMF_FUNCTION_SUCCEEDED, + EFCT_SCSI_TMF_FUNCTION_IO_NOT_FOUND, + EFCT_SCSI_TMF_FUNCTION_REJECTED, + EFCT_SCSI_TMF_INCORRECT_LOGICAL_UNIT_NUMBER, + EFCT_SCSI_TMF_SERVICE_DELIVERY, +}; + +struct efct_scsi_sgl { + uintptr_t addr; + uintptr_t dif_addr; + size_t len; +}; + +/* Return values for calls from base driver to libefc */ +#define EFCT_SCSI_CALL_COMPLETE 0 /* All work is done */ +#define EFCT_SCSI_CALL_ASYNC 1 /* Work will be completed asynchronously */ + +enum efct_scsi_io_role { + EFCT_SCSI_IO_ROLE_ORIGINATOR, + EFCT_SCSI_IO_ROLE_RESPONDER, +}; + +void efct_scsi_io_alloc_enable(struct efc *efc, struct efc_node *node); +void efct_scsi_io_alloc_disable(struct efc *efc, struct efc_node *node); +extern struct efct_io * +efct_scsi_io_alloc(struct efc_node *node, enum efct_scsi_io_role); +void efct_scsi_io_free(struct efct_io *io); +struct efct_io *efct_io_get_instance(struct efct *efct, u32 index); + +int efct_scsi_tgt_driver_init(void); +int efct_scsi_tgt_driver_exit(void); +int efct_scsi_tgt_new_device(struct efct *efct); +int efct_scsi_tgt_del_device(struct efct *efct); +int +efct_scsi_tgt_new_domain(struct efc *efc, struct efc_domain *domain); +void +efct_scsi_tgt_del_domain(struct efc *efc, struct efc_domain *domain); +int +efct_scsi_tgt_new_sport(struct efc *efc, struct efc_sli_port *sport); +void +efct_scsi_tgt_del_sport(struct efc *efc, struct efc_sli_port *sport); +int +efct_scsi_validate_initiator(struct efc *efc, struct efc_node *node); +int +efct_scsi_new_initiator(struct efc *efc, struct efc_node *node); + +enum efct_scsi_del_initiator_reason { + EFCT_SCSI_INITIATOR_DELETED, + EFCT_SCSI_INITIATOR_MISSING, +}; + +extern int +efct_scsi_del_initiator(struct efc *efc, struct efc_node *node, + int reason); +extern int +efct_scsi_recv_cmd(struct efct_io *io, uint64_t lun, u8 *cdb, + u32 cdb_len, u32 flags); +extern int +efct_scsi_recv_tmf(struct efct_io *tmfio, u32 lun, + enum efct_scsi_tmf_cmd cmd, struct efct_io *abortio, + u32 flags); + +extern int +efct_scsi_send_rd_data(struct efct_io *io, u32 flags, + struct efct_scsi_sgl *sgl, u32 sgl_count, + u64 wire_len, efct_scsi_io_cb_t cb, void *arg); +extern int +efct_scsi_recv_wr_data(struct efct_io *io, u32 flags, + struct efct_scsi_sgl *sgl, u32 sgl_count, + u64 wire_len, efct_scsi_io_cb_t cb, void *arg); +extern int +efct_scsi_send_resp(struct efct_io *io, u32 flags, + struct efct_scsi_cmd_resp *rsp, efct_scsi_io_cb_t cb, + void *arg); +extern int +efct_scsi_send_tmf_resp(struct efct_io *io, + enum efct_scsi_tmf_resp rspcode, + u8 addl_rsp_info[3], + efct_scsi_io_cb_t cb, void *arg); +extern int +efct_scsi_tgt_abort_io(struct efct_io *io, efct_scsi_io_cb_t cb, void *arg); + +void efct_scsi_io_complete(struct efct_io *io); + +int efct_scsi_reg_fc_transport(void); +int efct_scsi_release_fc_transport(void); +int efct_scsi_new_device(struct efct *efct); +int efct_scsi_del_device(struct efct *efct); +void _efct_scsi_io_free(struct kref *arg); + +int efct_scsi_send_tmf(struct efc_node *node, + struct efct_io *io, + struct efct_io *io_to_abort, u32 lun, + enum efct_scsi_tmf_cmd tmf, + struct efct_scsi_sgl *sgl, + u32 sgl_count, u32 len, + efct_scsi_rsp_io_cb_t cb, void *arg); + +extern int +efct_scsi_del_vport(struct efct *efct, struct Scsi_Host *shost); +extern struct efct_vport * +efct_scsi_new_vport(struct efct *efct, struct device *dev); + +int efct_scsi_io_dispatch(struct efct_io *io, void *cb); +int efct_scsi_io_dispatch_abort(struct efct_io *io, void *cb); +void efct_scsi_check_pending(struct efct *efct); + +#endif /* __EFCT_SCSI_H__ */ -- 2.16.4