Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Bradley Grove | 3474 | 100.00% | 2 | 100.00% |
Total | 3474 | 2 |
/* * linux/drivers/scsi/esas2r/esas2r_io.c * For use with ATTO ExpressSAS R6xx SAS/SATA RAID controllers * * Copyright (c) 2001-2013 ATTO Technology, Inc. * (mailto:linuxdrivers@attotech.com)mpt3sas/mpt3sas_trigger_diag. * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * as published by the Free Software Foundation; either version 2 * of the License, or (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * NO WARRANTY * THE PROGRAM IS PROVIDED ON AN "AS IS" BASIS, WITHOUT WARRANTIES OR * CONDITIONS OF ANY KIND, EITHER EXPRESS OR IMPLIED INCLUDING, WITHOUT * LIMITATION, ANY WARRANTIES OR CONDITIONS OF TITLE, NON-INFRINGEMENT, * MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. Each Recipient is * solely responsible for determining the appropriateness of using and * distributing the Program and assumes all risks associated with its * exercise of rights under this Agreement, including but not limited to * the risks and costs of program errors, damage to or loss of data, * programs or equipment, and unavailability or interruption of operations. * * DISCLAIMER OF LIABILITY * NEITHER RECIPIENT NOR ANY CONTRIBUTORS SHALL HAVE ANY LIABILITY FOR ANY * DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING WITHOUT LIMITATION LOST PROFITS), 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 OR DISTRIBUTION OF THE PROGRAM OR THE EXERCISE OF ANY RIGHTS GRANTED * HEREUNDER, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGES * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, * USA. */ #include "esas2r.h" void esas2r_start_request(struct esas2r_adapter *a, struct esas2r_request *rq) { struct esas2r_target *t = NULL; struct esas2r_request *startrq = rq; unsigned long flags; if (unlikely(test_bit(AF_DEGRADED_MODE, &a->flags) || test_bit(AF_POWER_DOWN, &a->flags))) { if (rq->vrq->scsi.function == VDA_FUNC_SCSI) rq->req_stat = RS_SEL2; else rq->req_stat = RS_DEGRADED; } else if (likely(rq->vrq->scsi.function == VDA_FUNC_SCSI)) { t = a->targetdb + rq->target_id; if (unlikely(t >= a->targetdb_end || !(t->flags & TF_USED))) { rq->req_stat = RS_SEL; } else { /* copy in the target ID. */ rq->vrq->scsi.target_id = cpu_to_le16(t->virt_targ_id); /* * Test if we want to report RS_SEL for missing target. * Note that if AF_DISC_PENDING is set than this will * go on the defer queue. */ if (unlikely(t->target_state != TS_PRESENT && !test_bit(AF_DISC_PENDING, &a->flags))) rq->req_stat = RS_SEL; } } if (unlikely(rq->req_stat != RS_PENDING)) { esas2r_complete_request(a, rq); return; } esas2r_trace("rq=%p", rq); esas2r_trace("rq->vrq->scsi.handle=%x", rq->vrq->scsi.handle); if (rq->vrq->scsi.function == VDA_FUNC_SCSI) { esas2r_trace("rq->target_id=%d", rq->target_id); esas2r_trace("rq->vrq->scsi.flags=%x", rq->vrq->scsi.flags); } spin_lock_irqsave(&a->queue_lock, flags); if (likely(list_empty(&a->defer_list) && !test_bit(AF_CHPRST_PENDING, &a->flags) && !test_bit(AF_FLASHING, &a->flags) && !test_bit(AF_DISC_PENDING, &a->flags))) esas2r_local_start_request(a, startrq); else list_add_tail(&startrq->req_list, &a->defer_list); spin_unlock_irqrestore(&a->queue_lock, flags); } /* * Starts the specified request. all requests have RS_PENDING set when this * routine is called. The caller is usually esas2r_start_request, but * esas2r_do_deferred_processes will start request that are deferred. * * The caller must ensure that requests can be started. * * esas2r_start_request will defer a request if there are already requests * waiting or there is a chip reset pending. once the reset condition clears, * esas2r_do_deferred_processes will call this function to start the request. * * When a request is started, it is placed on the active list and queued to * the controller. */ void esas2r_local_start_request(struct esas2r_adapter *a, struct esas2r_request *rq) { esas2r_trace_enter(); esas2r_trace("rq=%p", rq); esas2r_trace("rq->vrq:%p", rq->vrq); esas2r_trace("rq->vrq_md->phys_addr:%x", rq->vrq_md->phys_addr); if (unlikely(rq->vrq->scsi.function == VDA_FUNC_FLASH && rq->vrq->flash.sub_func == VDA_FLASH_COMMIT)) set_bit(AF_FLASHING, &a->flags); list_add_tail(&rq->req_list, &a->active_list); esas2r_start_vda_request(a, rq); esas2r_trace_exit(); return; } void esas2r_start_vda_request(struct esas2r_adapter *a, struct esas2r_request *rq) { struct esas2r_inbound_list_source_entry *element; u32 dw; rq->req_stat = RS_STARTED; /* * Calculate the inbound list entry location and the current state of * toggle bit. */ a->last_write++; if (a->last_write >= a->list_size) { a->last_write = 0; /* update the toggle bit */ if (test_bit(AF_COMM_LIST_TOGGLE, &a->flags)) clear_bit(AF_COMM_LIST_TOGGLE, &a->flags); else set_bit(AF_COMM_LIST_TOGGLE, &a->flags); } element = (struct esas2r_inbound_list_source_entry *)a->inbound_list_md. virt_addr + a->last_write; /* Set the VDA request size if it was never modified */ if (rq->vda_req_sz == RQ_SIZE_DEFAULT) rq->vda_req_sz = (u16)(a->max_vdareq_size / sizeof(u32)); element->address = cpu_to_le64(rq->vrq_md->phys_addr); element->length = cpu_to_le32(rq->vda_req_sz); /* Update the write pointer */ dw = a->last_write; if (test_bit(AF_COMM_LIST_TOGGLE, &a->flags)) dw |= MU_ILW_TOGGLE; esas2r_trace("rq->vrq->scsi.handle:%x", rq->vrq->scsi.handle); esas2r_trace("dw:%x", dw); esas2r_trace("rq->vda_req_sz:%x", rq->vda_req_sz); esas2r_write_register_dword(a, MU_IN_LIST_WRITE, dw); } /* * Build the scatter/gather list for an I/O request according to the * specifications placed in the s/g context. The caller must initialize * context prior to the initial call by calling esas2r_sgc_init(). */ bool esas2r_build_sg_list_sge(struct esas2r_adapter *a, struct esas2r_sg_context *sgc) { struct esas2r_request *rq = sgc->first_req; union atto_vda_req *vrq = rq->vrq; while (sgc->length) { u32 rem = 0; u64 addr; u32 len; len = (*sgc->get_phys_addr)(sgc, &addr); if (unlikely(len == 0)) return false; /* if current length is more than what's left, stop there */ if (unlikely(len > sgc->length)) len = sgc->length; another_entry: /* limit to a round number less than the maximum length */ if (len > SGE_LEN_MAX) { /* * Save the remainder of the split. Whenever we limit * an entry we come back around to build entries out * of the leftover. We do this to prevent multiple * calls to the get_phys_addr() function for an SGE * that is too large. */ rem = len - SGE_LEN_MAX; len = SGE_LEN_MAX; } /* See if we need to allocate a new SGL */ if (unlikely(sgc->sge.a64.curr > sgc->sge.a64.limit)) { u8 sgelen; struct esas2r_mem_desc *sgl; /* * If no SGls are available, return failure. The * caller can call us later with the current context * to pick up here. */ sgl = esas2r_alloc_sgl(a); if (unlikely(sgl == NULL)) return false; /* Calculate the length of the last SGE filled in */ sgelen = (u8)((u8 *)sgc->sge.a64.curr - (u8 *)sgc->sge.a64.last); /* * Copy the last SGE filled in to the first entry of * the new SGL to make room for the chain entry. */ memcpy(sgl->virt_addr, sgc->sge.a64.last, sgelen); /* Figure out the new curr pointer in the new segment */ sgc->sge.a64.curr = (struct atto_vda_sge *)((u8 *)sgl->virt_addr + sgelen); /* Set the limit pointer and build the chain entry */ sgc->sge.a64.limit = (struct atto_vda_sge *)((u8 *)sgl->virt_addr + sgl_page_size - sizeof(struct atto_vda_sge)); sgc->sge.a64.last->length = cpu_to_le32( SGE_CHAIN | SGE_ADDR_64); sgc->sge.a64.last->address = cpu_to_le64(sgl->phys_addr); /* * Now, if there was a previous chain entry, then * update it to contain the length of this segment * and size of this chain. otherwise this is the * first SGL, so set the chain_offset in the request. */ if (sgc->sge.a64.chain) { sgc->sge.a64.chain->length |= cpu_to_le32( ((u8 *)(sgc->sge.a64. last + 1) - (u8 *)rq->sg_table-> virt_addr) + sizeof(struct atto_vda_sge) * LOBIT(SGE_CHAIN_SZ)); } else { vrq->scsi.chain_offset = (u8) ((u8 *)sgc-> sge.a64.last - (u8 *)vrq); /* * This is the first SGL, so set the * chain_offset and the VDA request size in * the request. */ rq->vda_req_sz = (vrq->scsi.chain_offset + sizeof(struct atto_vda_sge) + 3) / sizeof(u32); } /* * Remember this so when we get a new SGL filled in we * can update the length of this chain entry. */ sgc->sge.a64.chain = sgc->sge.a64.last; /* Now link the new SGL onto the primary request. */ list_add(&sgl->next_desc, &rq->sg_table_head); } /* Update last one filled in */ sgc->sge.a64.last = sgc->sge.a64.curr; /* Build the new SGE and update the S/G context */ sgc->sge.a64.curr->length = cpu_to_le32(SGE_ADDR_64 | len); sgc->sge.a64.curr->address = cpu_to_le32(addr); sgc->sge.a64.curr++; sgc->cur_offset += len; sgc->length -= len; /* * Check if we previously split an entry. If so we have to * pick up where we left off. */ if (rem) { addr += len; len = rem; rem = 0; goto another_entry; } } /* Mark the end of the SGL */ sgc->sge.a64.last->length |= cpu_to_le32(SGE_LAST); /* * If there was a previous chain entry, update the length to indicate * the length of this last segment. */ if (sgc->sge.a64.chain) { sgc->sge.a64.chain->length |= cpu_to_le32( ((u8 *)(sgc->sge.a64.curr) - (u8 *)rq->sg_table->virt_addr)); } else { u16 reqsize; /* * The entire VDA request was not used so lets * set the size of the VDA request to be DMA'd */ reqsize = ((u16)((u8 *)sgc->sge.a64.last - (u8 *)vrq) + sizeof(struct atto_vda_sge) + 3) / sizeof(u32); /* * Only update the request size if it is bigger than what is * already there. We can come in here twice for some management * commands. */ if (reqsize > rq->vda_req_sz) rq->vda_req_sz = reqsize; } return true; } /* * Create PRD list for each I-block consumed by the command. This routine * determines how much data is required from each I-block being consumed * by the command. The first and last I-blocks can be partials and all of * the I-blocks in between are for a full I-block of data. * * The interleave size is used to determine the number of bytes in the 1st * I-block and the remaining I-blocks are what remeains. */ static bool esas2r_build_prd_iblk(struct esas2r_adapter *a, struct esas2r_sg_context *sgc) { struct esas2r_request *rq = sgc->first_req; u64 addr; u32 len; struct esas2r_mem_desc *sgl; u32 numchain = 1; u32 rem = 0; while (sgc->length) { /* Get the next address/length pair */ len = (*sgc->get_phys_addr)(sgc, &addr); if (unlikely(len == 0)) return false; /* If current length is more than what's left, stop there */ if (unlikely(len > sgc->length)) len = sgc->length; another_entry: /* Limit to a round number less than the maximum length */ if (len > PRD_LEN_MAX) { /* * Save the remainder of the split. whenever we limit * an entry we come back around to build entries out * of the leftover. We do this to prevent multiple * calls to the get_phys_addr() function for an SGE * that is too large. */ rem = len - PRD_LEN_MAX; len = PRD_LEN_MAX; } /* See if we need to allocate a new SGL */ if (sgc->sge.prd.sge_cnt == 0) { if (len == sgc->length) { /* * We only have 1 PRD entry left. * It can be placed where the chain * entry would have gone */ /* Build the simple SGE */ sgc->sge.prd.curr->ctl_len = cpu_to_le32( PRD_DATA | len); sgc->sge.prd.curr->address = cpu_to_le64(addr); /* Adjust length related fields */ sgc->cur_offset += len; sgc->length -= len; /* We use the reserved chain entry for data */ numchain = 0; break; } if (sgc->sge.prd.chain) { /* * Fill # of entries of current SGL in previous * chain the length of this current SGL may not * full. */ sgc->sge.prd.chain->ctl_len |= cpu_to_le32( sgc->sge.prd.sgl_max_cnt); } /* * If no SGls are available, return failure. The * caller can call us later with the current context * to pick up here. */ sgl = esas2r_alloc_sgl(a); if (unlikely(sgl == NULL)) return false; /* * Link the new SGL onto the chain * They are in reverse order */ list_add(&sgl->next_desc, &rq->sg_table_head); /* * An SGL was just filled in and we are starting * a new SGL. Prime the chain of the ending SGL with * info that points to the new SGL. The length gets * filled in when the new SGL is filled or ended */ sgc->sge.prd.chain = sgc->sge.prd.curr; sgc->sge.prd.chain->ctl_len = cpu_to_le32(PRD_CHAIN); sgc->sge.prd.chain->address = cpu_to_le64(sgl->phys_addr); /* * Start a new segment. * Take one away and save for chain SGE */ sgc->sge.prd.curr = (struct atto_physical_region_description *)sgl -> virt_addr; sgc->sge.prd.sge_cnt = sgc->sge.prd.sgl_max_cnt - 1; } sgc->sge.prd.sge_cnt--; /* Build the simple SGE */ sgc->sge.prd.curr->ctl_len = cpu_to_le32(PRD_DATA | len); sgc->sge.prd.curr->address = cpu_to_le64(addr); /* Used another element. Point to the next one */ sgc->sge.prd.curr++; /* Adjust length related fields */ sgc->cur_offset += len; sgc->length -= len; /* * Check if we previously split an entry. If so we have to * pick up where we left off. */ if (rem) { addr += len; len = rem; rem = 0; goto another_entry; } } if (!list_empty(&rq->sg_table_head)) { if (sgc->sge.prd.chain) { sgc->sge.prd.chain->ctl_len |= cpu_to_le32(sgc->sge.prd.sgl_max_cnt - sgc->sge.prd.sge_cnt - numchain); } } return true; } bool esas2r_build_sg_list_prd(struct esas2r_adapter *a, struct esas2r_sg_context *sgc) { struct esas2r_request *rq = sgc->first_req; u32 len = sgc->length; struct esas2r_target *t = a->targetdb + rq->target_id; u8 is_i_o = 0; u16 reqsize; struct atto_physical_region_description *curr_iblk_chn; u8 *cdb = (u8 *)&rq->vrq->scsi.cdb[0]; /* * extract LBA from command so we can determine * the I-Block boundary */ if (rq->vrq->scsi.function == VDA_FUNC_SCSI && t->target_state == TS_PRESENT && !(t->flags & TF_PASS_THRU)) { u32 lbalo = 0; switch (rq->vrq->scsi.cdb[0]) { case READ_16: case WRITE_16: { lbalo = MAKEDWORD(MAKEWORD(cdb[9], cdb[8]), MAKEWORD(cdb[7], cdb[6])); is_i_o = 1; break; } case READ_12: case WRITE_12: case READ_10: case WRITE_10: { lbalo = MAKEDWORD(MAKEWORD(cdb[5], cdb[4]), MAKEWORD(cdb[3], cdb[2])); is_i_o = 1; break; } case READ_6: case WRITE_6: { lbalo = MAKEDWORD(MAKEWORD(cdb[3], cdb[2]), MAKEWORD(cdb[1] & 0x1F, 0)); is_i_o = 1; break; } default: break; } if (is_i_o) { u32 startlba; rq->vrq->scsi.iblk_cnt_prd = 0; /* Determine size of 1st I-block PRD list */ startlba = t->inter_block - (lbalo & (t->inter_block - 1)); sgc->length = startlba * t->block_size; /* Chk if the 1st iblk chain starts at base of Iblock */ if ((lbalo & (t->inter_block - 1)) == 0) rq->flags |= RF_1ST_IBLK_BASE; if (sgc->length > len) sgc->length = len; } else { sgc->length = len; } } else { sgc->length = len; } /* get our starting chain address */ curr_iblk_chn = (struct atto_physical_region_description *)sgc->sge.a64.curr; sgc->sge.prd.sgl_max_cnt = sgl_page_size / sizeof(struct atto_physical_region_description); /* create all of the I-block PRD lists */ while (len) { sgc->sge.prd.sge_cnt = 0; sgc->sge.prd.chain = NULL; sgc->sge.prd.curr = curr_iblk_chn; /* increment to next I-Block */ len -= sgc->length; /* go build the next I-Block PRD list */ if (unlikely(!esas2r_build_prd_iblk(a, sgc))) return false; curr_iblk_chn++; if (is_i_o) { rq->vrq->scsi.iblk_cnt_prd++; if (len > t->inter_byte) sgc->length = t->inter_byte; else sgc->length = len; } } /* figure out the size used of the VDA request */ reqsize = ((u16)((u8 *)curr_iblk_chn - (u8 *)rq->vrq)) / sizeof(u32); /* * only update the request size if it is bigger than what is * already there. we can come in here twice for some management * commands. */ if (reqsize > rq->vda_req_sz) rq->vda_req_sz = reqsize; return true; } static void esas2r_handle_pending_reset(struct esas2r_adapter *a, u32 currtime) { u32 delta = currtime - a->chip_init_time; if (delta <= ESAS2R_CHPRST_WAIT_TIME) { /* Wait before accessing registers */ } else if (delta >= ESAS2R_CHPRST_TIME) { /* * The last reset failed so try again. Reset * processing will give up after three tries. */ esas2r_local_reset_adapter(a); } else { /* We can now see if the firmware is ready */ u32 doorbell; doorbell = esas2r_read_register_dword(a, MU_DOORBELL_OUT); if (doorbell == 0xFFFFFFFF || !(doorbell & DRBL_FORCE_INT)) { esas2r_force_interrupt(a); } else { u32 ver = (doorbell & DRBL_FW_VER_MSK); /* Driver supports API version 0 and 1 */ esas2r_write_register_dword(a, MU_DOORBELL_OUT, doorbell); if (ver == DRBL_FW_VER_0) { set_bit(AF_CHPRST_DETECTED, &a->flags); set_bit(AF_LEGACY_SGE_MODE, &a->flags); a->max_vdareq_size = 128; a->build_sgl = esas2r_build_sg_list_sge; } else if (ver == DRBL_FW_VER_1) { set_bit(AF_CHPRST_DETECTED, &a->flags); clear_bit(AF_LEGACY_SGE_MODE, &a->flags); a->max_vdareq_size = 1024; a->build_sgl = esas2r_build_sg_list_prd; } else { esas2r_local_reset_adapter(a); } } } } /* This function must be called once per timer tick */ void esas2r_timer_tick(struct esas2r_adapter *a) { u32 currtime = jiffies_to_msecs(jiffies); u32 deltatime = currtime - a->last_tick_time; a->last_tick_time = currtime; /* count down the uptime */ if (a->chip_uptime && !test_bit(AF_CHPRST_PENDING, &a->flags) && !test_bit(AF_DISC_PENDING, &a->flags)) { if (deltatime >= a->chip_uptime) a->chip_uptime = 0; else a->chip_uptime -= deltatime; } if (test_bit(AF_CHPRST_PENDING, &a->flags)) { if (!test_bit(AF_CHPRST_NEEDED, &a->flags) && !test_bit(AF_CHPRST_DETECTED, &a->flags)) esas2r_handle_pending_reset(a, currtime); } else { if (test_bit(AF_DISC_PENDING, &a->flags)) esas2r_disc_check_complete(a); if (test_bit(AF_HEARTBEAT_ENB, &a->flags)) { if (test_bit(AF_HEARTBEAT, &a->flags)) { if ((currtime - a->heartbeat_time) >= ESAS2R_HEARTBEAT_TIME) { clear_bit(AF_HEARTBEAT, &a->flags); esas2r_hdebug("heartbeat failed"); esas2r_log(ESAS2R_LOG_CRIT, "heartbeat failed"); esas2r_bugon(); esas2r_local_reset_adapter(a); } } else { set_bit(AF_HEARTBEAT, &a->flags); a->heartbeat_time = currtime; esas2r_force_interrupt(a); } } } if (atomic_read(&a->disable_cnt) == 0) esas2r_do_deferred_processes(a); } /* * Send the specified task management function to the target and LUN * specified in rqaux. in addition, immediately abort any commands that * are queued but not sent to the device according to the rules specified * by the task management function. */ bool esas2r_send_task_mgmt(struct esas2r_adapter *a, struct esas2r_request *rqaux, u8 task_mgt_func) { u16 targetid = rqaux->target_id; u8 lun = (u8)le32_to_cpu(rqaux->vrq->scsi.flags); bool ret = false; struct esas2r_request *rq; struct list_head *next, *element; unsigned long flags; LIST_HEAD(comp_list); esas2r_trace_enter(); esas2r_trace("rqaux:%p", rqaux); esas2r_trace("task_mgt_func:%x", task_mgt_func); spin_lock_irqsave(&a->queue_lock, flags); /* search the defer queue looking for requests for the device */ list_for_each_safe(element, next, &a->defer_list) { rq = list_entry(element, struct esas2r_request, req_list); if (rq->vrq->scsi.function == VDA_FUNC_SCSI && rq->target_id == targetid && (((u8)le32_to_cpu(rq->vrq->scsi.flags)) == lun || task_mgt_func == 0x20)) { /* target reset */ /* Found a request affected by the task management */ if (rq->req_stat == RS_PENDING) { /* * The request is pending or waiting. We can * safelycomplete the request now. */ if (esas2r_ioreq_aborted(a, rq, RS_ABORTED)) list_add_tail(&rq->comp_list, &comp_list); } } } /* Send the task management request to the firmware */ rqaux->sense_len = 0; rqaux->vrq->scsi.length = 0; rqaux->target_id = targetid; rqaux->vrq->scsi.flags |= cpu_to_le32(lun); memset(rqaux->vrq->scsi.cdb, 0, sizeof(rqaux->vrq->scsi.cdb)); rqaux->vrq->scsi.flags |= cpu_to_le16(task_mgt_func * LOBIT(FCP_CMND_TM_MASK)); if (test_bit(AF_FLASHING, &a->flags)) { /* Assume success. if there are active requests, return busy */ rqaux->req_stat = RS_SUCCESS; list_for_each_safe(element, next, &a->active_list) { rq = list_entry(element, struct esas2r_request, req_list); if (rq->vrq->scsi.function == VDA_FUNC_SCSI && rq->target_id == targetid && (((u8)le32_to_cpu(rq->vrq->scsi.flags)) == lun || task_mgt_func == 0x20)) /* target reset */ rqaux->req_stat = RS_BUSY; } ret = true; } spin_unlock_irqrestore(&a->queue_lock, flags); if (!test_bit(AF_FLASHING, &a->flags)) esas2r_start_request(a, rqaux); esas2r_comp_list_drain(a, &comp_list); if (atomic_read(&a->disable_cnt) == 0) esas2r_do_deferred_processes(a); esas2r_trace_exit(); return ret; } void esas2r_reset_bus(struct esas2r_adapter *a) { esas2r_log(ESAS2R_LOG_INFO, "performing a bus reset"); if (!test_bit(AF_DEGRADED_MODE, &a->flags) && !test_bit(AF_CHPRST_PENDING, &a->flags) && !test_bit(AF_DISC_PENDING, &a->flags)) { set_bit(AF_BUSRST_NEEDED, &a->flags); set_bit(AF_BUSRST_PENDING, &a->flags); set_bit(AF_OS_RESET, &a->flags); esas2r_schedule_tasklet(a); } } bool esas2r_ioreq_aborted(struct esas2r_adapter *a, struct esas2r_request *rq, u8 status) { esas2r_trace_enter(); esas2r_trace("rq:%p", rq); list_del_init(&rq->req_list); if (rq->timeout > RQ_MAX_TIMEOUT) { /* * The request timed out, but we could not abort it because a * chip reset occurred. Return busy status. */ rq->req_stat = RS_BUSY; esas2r_trace_exit(); return true; } rq->req_stat = status; esas2r_trace_exit(); return true; }
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