/* * BSD LICENSE * * Copyright(c) 2017 Cavium, Inc.. All rights reserved. * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * * Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * 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. * * Neither the name of Cavium, Inc. nor the names of its * contributors may be used to endorse or promote products derived * from this software without specific prior written permission. * * 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(S) 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 "lio_bsd.h" #include "lio_common.h" #include "lio_droq.h" #include "lio_iq.h" #include "lio_response_manager.h" #include "lio_device.h" #include "lio_main.h" #include "lio_network.h" #include "cn23xx_pf_device.h" #include "lio_rxtx.h" struct lio_iq_post_status { int status; int index; }; static void lio_check_db_timeout(void *arg, int pending); static void __lio_check_db_timeout(struct octeon_device *oct, uint64_t iq_no); /* Return 0 on success, 1 on failure */ int lio_init_instr_queue(struct octeon_device *oct, union octeon_txpciq txpciq, uint32_t num_descs) { struct lio_instr_queue *iq; struct lio_iq_config *conf = NULL; struct lio_tq *db_tq; struct lio_request_list *request_buf; bus_size_t max_size; uint32_t iq_no = (uint32_t)txpciq.s.q_no; uint32_t q_size; int error, i; if (LIO_CN23XX_PF(oct)) conf = &(LIO_GET_IQ_CFG(LIO_CHIP_CONF(oct, cn23xx_pf))); if (conf == NULL) { lio_dev_err(oct, "Unsupported Chip %x\n", oct->chip_id); return (1); } q_size = (uint32_t)conf->instr_type * num_descs; iq = oct->instr_queue[iq_no]; iq->oct_dev = oct; max_size = LIO_CN23XX_PKI_MAX_FRAME_SIZE * num_descs; error = bus_dma_tag_create(bus_get_dma_tag(oct->device), /* parent */ 1, 0, /* alignment, bounds */ BUS_SPACE_MAXADDR, /* lowaddr */ BUS_SPACE_MAXADDR, /* highaddr */ NULL, NULL, /* filter, filterarg */ max_size, /* maxsize */ LIO_MAX_SG, /* nsegments */ PAGE_SIZE, /* maxsegsize */ 0, /* flags */ NULL, /* lockfunc */ NULL, /* lockfuncarg */ &iq->txtag); if (error) { lio_dev_err(oct, "Cannot allocate memory for instr queue %d\n", iq_no); return (1); } iq->base_addr = lio_dma_alloc(q_size, (vm_paddr_t *)&iq->base_addr_dma); if (!iq->base_addr) { lio_dev_err(oct, "Cannot allocate memory for instr queue %d\n", iq_no); return (1); } iq->max_count = num_descs; /* * Initialize a list to holds requests that have been posted to * Octeon but has yet to be fetched by octeon */ iq->request_list = malloc(sizeof(*iq->request_list) * num_descs, M_DEVBUF, M_NOWAIT | M_ZERO); if (iq->request_list == NULL) { lio_dev_err(oct, "Alloc failed for IQ[%d] nr free list\n", iq_no); return (1); } lio_dev_dbg(oct, "IQ[%d]: base: %p basedma: %llx count: %d\n", iq_no, iq->base_addr, LIO_CAST64(iq->base_addr_dma), iq->max_count); /* Create the descriptor buffer dma maps */ request_buf = iq->request_list; for (i = 0; i < num_descs; i++, request_buf++) { error = bus_dmamap_create(iq->txtag, 0, &request_buf->map); if (error) { lio_dev_err(oct, "Unable to create TX DMA map\n"); return (1); } } iq->txpciq.txpciq64 = txpciq.txpciq64; iq->fill_cnt = 0; iq->host_write_index = 0; iq->octeon_read_index = 0; iq->flush_index = 0; iq->last_db_time = 0; iq->db_timeout = (uint32_t)conf->db_timeout; atomic_store_rel_int(&iq->instr_pending, 0); /* Initialize the lock for this instruction queue */ mtx_init(&iq->lock, "Tx_lock", NULL, MTX_DEF); mtx_init(&iq->post_lock, "iq_post_lock", NULL, MTX_DEF); mtx_init(&iq->enq_lock, "enq_lock", NULL, MTX_DEF); mtx_init(&iq->iq_flush_running_lock, "iq_flush_running_lock", NULL, MTX_DEF); oct->io_qmask.iq |= BIT_ULL(iq_no); /* Set the 32B/64B mode for each input queue */ oct->io_qmask.iq64B |= ((conf->instr_type == 64) << iq_no); iq->iqcmd_64B = (conf->instr_type == 64); oct->fn_list.setup_iq_regs(oct, iq_no); db_tq = &oct->check_db_tq[iq_no]; db_tq->tq = taskqueue_create("lio_check_db_timeout", M_WAITOK, taskqueue_thread_enqueue, &db_tq->tq); TIMEOUT_TASK_INIT(db_tq->tq, &db_tq->work, 0, lio_check_db_timeout, (void *)db_tq); db_tq->ctxul = iq_no; db_tq->ctxptr = oct; taskqueue_start_threads(&db_tq->tq, 1, PI_NET, "lio%d_check_db_timeout:%d", oct->octeon_id, iq_no); taskqueue_enqueue_timeout(db_tq->tq, &db_tq->work, 1); /* Allocate a buf ring */ oct->instr_queue[iq_no]->br = buf_ring_alloc(LIO_BR_SIZE, M_DEVBUF, M_WAITOK, &oct->instr_queue[iq_no]->enq_lock); return (0); } int lio_delete_instr_queue(struct octeon_device *oct, uint32_t iq_no) { struct lio_instr_queue *iq = oct->instr_queue[iq_no]; struct lio_request_list *request_buf; struct lio_mbuf_free_info *finfo; uint64_t desc_size = 0, q_size; int i; lio_dev_dbg(oct, "%s[%d]\n", __func__, iq_no); if (oct->check_db_tq[iq_no].tq != NULL) { while (taskqueue_cancel_timeout(oct->check_db_tq[iq_no].tq, &oct->check_db_tq[iq_no].work, NULL)) taskqueue_drain_timeout(oct->check_db_tq[iq_no].tq, &oct->check_db_tq[iq_no].work); taskqueue_free(oct->check_db_tq[iq_no].tq); oct->check_db_tq[iq_no].tq = NULL; } if (LIO_CN23XX_PF(oct)) desc_size = LIO_GET_IQ_INSTR_TYPE_CFG(LIO_CHIP_CONF(oct, cn23xx_pf)); request_buf = iq->request_list; for (i = 0; i < iq->max_count; i++, request_buf++) { if ((request_buf->reqtype == LIO_REQTYPE_NORESP_NET) || (request_buf->reqtype == LIO_REQTYPE_NORESP_NET_SG)) { if (request_buf->buf != NULL) { finfo = request_buf->buf; bus_dmamap_sync(iq->txtag, request_buf->map, BUS_DMASYNC_POSTWRITE); bus_dmamap_unload(iq->txtag, request_buf->map); m_freem(finfo->mb); request_buf->buf = NULL; if (request_buf->map != NULL) { bus_dmamap_destroy(iq->txtag, request_buf->map); request_buf->map = NULL; } } else if (request_buf->map != NULL) { bus_dmamap_unload(iq->txtag, request_buf->map); bus_dmamap_destroy(iq->txtag, request_buf->map); request_buf->map = NULL; } } } if (iq->br != NULL) { buf_ring_free(iq->br, M_DEVBUF); iq->br = NULL; } if (iq->request_list != NULL) { free(iq->request_list, M_DEVBUF); iq->request_list = NULL; } if (iq->txtag != NULL) { bus_dma_tag_destroy(iq->txtag); iq->txtag = NULL; } if (iq->base_addr) { q_size = iq->max_count * desc_size; lio_dma_free((uint32_t)q_size, iq->base_addr); oct->io_qmask.iq &= ~(1ULL << iq_no); bzero(oct->instr_queue[iq_no], sizeof(struct lio_instr_queue)); oct->num_iqs--; return (0); } return (1); } /* Return 0 on success, 1 on failure */ int lio_setup_iq(struct octeon_device *oct, int ifidx, int q_index, union octeon_txpciq txpciq, uint32_t num_descs) { uint32_t iq_no = (uint32_t)txpciq.s.q_no; if (oct->instr_queue[iq_no]->oct_dev != NULL) { lio_dev_dbg(oct, "IQ is in use. Cannot create the IQ: %d again\n", iq_no); oct->instr_queue[iq_no]->txpciq.txpciq64 = txpciq.txpciq64; return (0); } oct->instr_queue[iq_no]->q_index = q_index; oct->instr_queue[iq_no]->ifidx = ifidx; if (lio_init_instr_queue(oct, txpciq, num_descs)) { lio_delete_instr_queue(oct, iq_no); return (1); } oct->num_iqs++; if (oct->fn_list.enable_io_queues(oct)) return (1); return (0); } int lio_wait_for_instr_fetch(struct octeon_device *oct) { int i, retry = 1000, pending, instr_cnt = 0; do { instr_cnt = 0; for (i = 0; i < LIO_MAX_INSTR_QUEUES(oct); i++) { if (!(oct->io_qmask.iq & BIT_ULL(i))) continue; pending = atomic_load_acq_int( &oct->instr_queue[i]->instr_pending); if (pending) __lio_check_db_timeout(oct, i); instr_cnt += pending; } if (instr_cnt == 0) break; lio_sleep_timeout(1); } while (retry-- && instr_cnt); return (instr_cnt); } static inline void lio_ring_doorbell(struct octeon_device *oct, struct lio_instr_queue *iq) { if (atomic_load_acq_int(&oct->status) == LIO_DEV_RUNNING) { lio_write_csr32(oct, iq->doorbell_reg, iq->fill_cnt); /* make sure doorbell write goes through */ __compiler_membar(); iq->fill_cnt = 0; iq->last_db_time = ticks; return; } } static inline void __lio_copy_cmd_into_iq(struct lio_instr_queue *iq, uint8_t *cmd) { uint8_t *iqptr, cmdsize; cmdsize = ((iq->iqcmd_64B) ? 64 : 32); iqptr = iq->base_addr + (cmdsize * iq->host_write_index); memcpy(iqptr, cmd, cmdsize); } static inline struct lio_iq_post_status __lio_post_command2(struct lio_instr_queue *iq, uint8_t *cmd) { struct lio_iq_post_status st; st.status = LIO_IQ_SEND_OK; /* * This ensures that the read index does not wrap around to the same * position if queue gets full before Octeon could fetch any instr. */ if (atomic_load_acq_int(&iq->instr_pending) >= (int32_t)(iq->max_count - 1)) { st.status = LIO_IQ_SEND_FAILED; st.index = -1; return (st); } if (atomic_load_acq_int(&iq->instr_pending) >= (int32_t)(iq->max_count - 2)) st.status = LIO_IQ_SEND_STOP; __lio_copy_cmd_into_iq(iq, cmd); /* "index" is returned, host_write_index is modified. */ st.index = iq->host_write_index; iq->host_write_index = lio_incr_index(iq->host_write_index, 1, iq->max_count); iq->fill_cnt++; /* * Flush the command into memory. We need to be sure the data is in * memory before indicating that the instruction is pending. */ wmb(); atomic_add_int(&iq->instr_pending, 1); return (st); } static inline void __lio_add_to_request_list(struct lio_instr_queue *iq, int idx, void *buf, int reqtype) { iq->request_list[idx].buf = buf; iq->request_list[idx].reqtype = reqtype; } /* Can only run in process context */ int lio_process_iq_request_list(struct octeon_device *oct, struct lio_instr_queue *iq, uint32_t budget) { struct lio_soft_command *sc; struct octeon_instr_irh *irh = NULL; void *buf; uint32_t inst_count = 0; uint32_t old = iq->flush_index; int reqtype; while (old != iq->octeon_read_index) { reqtype = iq->request_list[old].reqtype; buf = iq->request_list[old].buf; if (reqtype == LIO_REQTYPE_NONE) goto skip_this; switch (reqtype) { case LIO_REQTYPE_NORESP_NET: lio_free_mbuf(iq, buf); break; case LIO_REQTYPE_NORESP_NET_SG: lio_free_sgmbuf(iq, buf); break; case LIO_REQTYPE_RESP_NET: case LIO_REQTYPE_SOFT_COMMAND: sc = buf; if (LIO_CN23XX_PF(oct)) irh = (struct octeon_instr_irh *) &sc->cmd.cmd3.irh; if (irh->rflag) { /* * We're expecting a response from Octeon. * It's up to lio_process_ordered_list() to * process sc. Add sc to the ordered soft * command response list because we expect * a response from Octeon. */ mtx_lock(&oct->response_list [LIO_ORDERED_SC_LIST].lock); atomic_add_int(&oct->response_list [LIO_ORDERED_SC_LIST]. pending_req_count, 1); STAILQ_INSERT_TAIL(&oct->response_list [LIO_ORDERED_SC_LIST]. head, &sc->node, entries); mtx_unlock(&oct->response_list [LIO_ORDERED_SC_LIST].lock); } else { if (sc->callback != NULL) { /* This callback must not sleep */ sc->callback(oct, LIO_REQUEST_DONE, sc->callback_arg); } } break; default: lio_dev_err(oct, "%s Unknown reqtype: %d buf: %p at idx %d\n", __func__, reqtype, buf, old); } iq->request_list[old].buf = NULL; iq->request_list[old].reqtype = 0; skip_this: inst_count++; old = lio_incr_index(old, 1, iq->max_count); if ((budget) && (inst_count >= budget)) break; } iq->flush_index = old; return (inst_count); } /* Can only be called from process context */ int lio_flush_iq(struct octeon_device *oct, struct lio_instr_queue *iq, uint32_t budget) { uint32_t inst_processed = 0; uint32_t tot_inst_processed = 0; int tx_done = 1; if (!mtx_trylock(&iq->iq_flush_running_lock)) return (tx_done); mtx_lock(&iq->lock); iq->octeon_read_index = oct->fn_list.update_iq_read_idx(iq); do { /* Process any outstanding IQ packets. */ if (iq->flush_index == iq->octeon_read_index) break; if (budget) inst_processed = lio_process_iq_request_list(oct, iq, budget - tot_inst_processed); else inst_processed = lio_process_iq_request_list(oct, iq, 0); if (inst_processed) { atomic_subtract_int(&iq->instr_pending, inst_processed); iq->stats.instr_processed += inst_processed; } tot_inst_processed += inst_processed; inst_processed = 0; } while (tot_inst_processed < budget); if (budget && (tot_inst_processed >= budget)) tx_done = 0; iq->last_db_time = ticks; mtx_unlock(&iq->lock); mtx_unlock(&iq->iq_flush_running_lock); return (tx_done); } /* * Process instruction queue after timeout. * This routine gets called from a taskqueue or when removing the module. */ static void __lio_check_db_timeout(struct octeon_device *oct, uint64_t iq_no) { struct lio_instr_queue *iq; uint64_t next_time; if (oct == NULL) return; iq = oct->instr_queue[iq_no]; if (iq == NULL) return; if (atomic_load_acq_int(&iq->instr_pending)) { /* If ticks - last_db_time < db_timeout do nothing */ next_time = iq->last_db_time + lio_ms_to_ticks(iq->db_timeout); if (!lio_check_timeout(ticks, next_time)) return; iq->last_db_time = ticks; /* Flush the instruction queue */ lio_flush_iq(oct, iq, 0); lio_enable_irq(NULL, iq); } if (oct->props.ifp != NULL && iq->br != NULL) { if (mtx_trylock(&iq->enq_lock)) { if (!drbr_empty(oct->props.ifp, iq->br)) lio_mq_start_locked(oct->props.ifp, iq); mtx_unlock(&iq->enq_lock); } } } /* * Called by the Poll thread at regular intervals to check the instruction * queue for commands to be posted and for commands that were fetched by Octeon. */ static void lio_check_db_timeout(void *arg, int pending) { struct lio_tq *db_tq = (struct lio_tq *)arg; struct octeon_device *oct = db_tq->ctxptr; uint64_t iq_no = db_tq->ctxul; uint32_t delay = 10; __lio_check_db_timeout(oct, iq_no); taskqueue_enqueue_timeout(db_tq->tq, &db_tq->work, lio_ms_to_ticks(delay)); } int lio_send_command(struct octeon_device *oct, uint32_t iq_no, uint32_t force_db, void *cmd, void *buf, uint32_t datasize, uint32_t reqtype) { struct lio_iq_post_status st; struct lio_instr_queue *iq = oct->instr_queue[iq_no]; /* * Get the lock and prevent other tasks and tx interrupt handler * from running. */ mtx_lock(&iq->post_lock); st = __lio_post_command2(iq, cmd); if (st.status != LIO_IQ_SEND_FAILED) { __lio_add_to_request_list(iq, st.index, buf, reqtype); LIO_INCR_INSTRQUEUE_PKT_COUNT(oct, iq_no, bytes_sent, datasize); LIO_INCR_INSTRQUEUE_PKT_COUNT(oct, iq_no, instr_posted, 1); if (force_db || (st.status == LIO_IQ_SEND_STOP)) lio_ring_doorbell(oct, iq); } else { LIO_INCR_INSTRQUEUE_PKT_COUNT(oct, iq_no, instr_dropped, 1); } mtx_unlock(&iq->post_lock); /* * This is only done here to expedite packets being flushed for * cases where there are no IQ completion interrupts. */ return (st.status); } void lio_prepare_soft_command(struct octeon_device *oct, struct lio_soft_command *sc, uint8_t opcode, uint8_t subcode, uint32_t irh_ossp, uint64_t ossp0, uint64_t ossp1) { struct octeon_instr_ih3 *ih3; struct octeon_instr_pki_ih3 *pki_ih3; struct octeon_instr_irh *irh; struct octeon_instr_rdp *rdp; KASSERT(opcode <= 15, ("%s, %d, opcode > 15", __func__, __LINE__)); KASSERT(subcode <= 127, ("%s, %d, opcode > 127", __func__, __LINE__)); if (LIO_CN23XX_PF(oct)) { ih3 = (struct octeon_instr_ih3 *)&sc->cmd.cmd3.ih3; ih3->pkind = oct->instr_queue[sc->iq_no]->txpciq.s.pkind; pki_ih3 = (struct octeon_instr_pki_ih3 *)&sc->cmd.cmd3.pki_ih3; pki_ih3->w = 1; pki_ih3->raw = 1; pki_ih3->utag = 1; pki_ih3->uqpg = oct->instr_queue[sc->iq_no]->txpciq.s.use_qpg; pki_ih3->utt = 1; pki_ih3->tag = LIO_CONTROL; pki_ih3->tagtype = LIO_ATOMIC_TAG; pki_ih3->qpg = oct->instr_queue[sc->iq_no]->txpciq.s.qpg; pki_ih3->pm = 0x7; pki_ih3->sl = 8; if (sc->datasize) ih3->dlengsz = sc->datasize; irh = (struct octeon_instr_irh *)&sc->cmd.cmd3.irh; irh->opcode = opcode; irh->subcode = subcode; /* opcode/subcode specific parameters (ossp) */ irh->ossp = irh_ossp; sc->cmd.cmd3.ossp[0] = ossp0; sc->cmd.cmd3.ossp[1] = ossp1; if (sc->rdatasize) { rdp = (struct octeon_instr_rdp *)&sc->cmd.cmd3.rdp; rdp->pcie_port = oct->pcie_port; rdp->rlen = sc->rdatasize; irh->rflag = 1; /* PKI IH3 */ /* pki_ih3 irh+ossp[0]+ossp[1]+rdp+rptr = 48 bytes */ ih3->fsz = LIO_SOFTCMDRESP_IH3; } else { irh->rflag = 0; /* PKI IH3 */ /* pki_h3 + irh + ossp[0] + ossp[1] = 32 bytes */ ih3->fsz = LIO_PCICMD_O3; } } } int lio_send_soft_command(struct octeon_device *oct, struct lio_soft_command *sc) { struct octeon_instr_ih3 *ih3; struct octeon_instr_irh *irh; uint32_t len = 0; if (LIO_CN23XX_PF(oct)) { ih3 = (struct octeon_instr_ih3 *)&sc->cmd.cmd3.ih3; if (ih3->dlengsz) { KASSERT(sc->dmadptr, ("%s, %d, sc->dmadptr is NULL", __func__, __LINE__)); sc->cmd.cmd3.dptr = sc->dmadptr; } irh = (struct octeon_instr_irh *)&sc->cmd.cmd3.irh; if (irh->rflag) { KASSERT(sc->dmarptr, ("%s, %d, sc->dmarptr is NULL", __func__, __LINE__)); KASSERT(sc->status_word, ("%s, %d, sc->status_word is NULL", __func__, __LINE__)); *sc->status_word = COMPLETION_WORD_INIT; sc->cmd.cmd3.rptr = sc->dmarptr; } len = (uint32_t)ih3->dlengsz; } if (sc->wait_time) sc->timeout = ticks + lio_ms_to_ticks(sc->wait_time); return (lio_send_command(oct, sc->iq_no, 1, &sc->cmd, sc, len, LIO_REQTYPE_SOFT_COMMAND)); } int lio_setup_sc_buffer_pool(struct octeon_device *oct) { struct lio_soft_command *sc; uint64_t dma_addr; int i; STAILQ_INIT(&oct->sc_buf_pool.head); mtx_init(&oct->sc_buf_pool.lock, "sc_pool_lock", NULL, MTX_DEF); atomic_store_rel_int(&oct->sc_buf_pool.alloc_buf_count, 0); for (i = 0; i < LIO_MAX_SOFT_COMMAND_BUFFERS; i++) { sc = (struct lio_soft_command *) lio_dma_alloc(LIO_SOFT_COMMAND_BUFFER_SIZE, (vm_paddr_t *)&dma_addr); if (sc == NULL) { lio_free_sc_buffer_pool(oct); return (1); } sc->dma_addr = dma_addr; sc->size = LIO_SOFT_COMMAND_BUFFER_SIZE; STAILQ_INSERT_TAIL(&oct->sc_buf_pool.head, &sc->node, entries); } return (0); } int lio_free_sc_buffer_pool(struct octeon_device *oct) { struct lio_stailq_node *tmp, *tmp2; struct lio_soft_command *sc; mtx_lock(&oct->sc_buf_pool.lock); STAILQ_FOREACH_SAFE(tmp, &oct->sc_buf_pool.head, entries, tmp2) { sc = LIO_STAILQ_FIRST_ENTRY(&oct->sc_buf_pool.head, struct lio_soft_command, node); STAILQ_REMOVE_HEAD(&oct->sc_buf_pool.head, entries); lio_dma_free(sc->size, sc); } STAILQ_INIT(&oct->sc_buf_pool.head); mtx_unlock(&oct->sc_buf_pool.lock); return (0); } struct lio_soft_command * lio_alloc_soft_command(struct octeon_device *oct, uint32_t datasize, uint32_t rdatasize, uint32_t ctxsize) { struct lio_soft_command *sc = NULL; struct lio_stailq_node *tmp; uint64_t dma_addr; uint32_t size; uint32_t offset = sizeof(struct lio_soft_command); KASSERT((offset + datasize + rdatasize + ctxsize) <= LIO_SOFT_COMMAND_BUFFER_SIZE, ("%s, %d, offset + datasize + rdatasize + ctxsize > LIO_SOFT_COMMAND_BUFFER_SIZE", __func__, __LINE__)); mtx_lock(&oct->sc_buf_pool.lock); if (STAILQ_EMPTY(&oct->sc_buf_pool.head)) { mtx_unlock(&oct->sc_buf_pool.lock); return (NULL); } tmp = STAILQ_LAST(&oct->sc_buf_pool.head, lio_stailq_node, entries); STAILQ_REMOVE(&oct->sc_buf_pool.head, tmp, lio_stailq_node, entries); atomic_add_int(&oct->sc_buf_pool.alloc_buf_count, 1); mtx_unlock(&oct->sc_buf_pool.lock); sc = (struct lio_soft_command *)tmp; dma_addr = sc->dma_addr; size = sc->size; bzero(sc, sc->size); sc->dma_addr = dma_addr; sc->size = size; if (ctxsize) { sc->ctxptr = (uint8_t *)sc + offset; sc->ctxsize = ctxsize; } /* Start data at 128 byte boundary */ offset = (offset + ctxsize + 127) & 0xffffff80; if (datasize) { sc->virtdptr = (uint8_t *)sc + offset; sc->dmadptr = dma_addr + offset; sc->datasize = datasize; } /* Start rdata at 128 byte boundary */ offset = (offset + datasize + 127) & 0xffffff80; if (rdatasize) { KASSERT(rdatasize >= 16, ("%s, %d, rdatasize < 16", __func__, __LINE__)); sc->virtrptr = (uint8_t *)sc + offset; sc->dmarptr = dma_addr + offset; sc->rdatasize = rdatasize; sc->status_word = (uint64_t *)((uint8_t *)(sc->virtrptr) + rdatasize - 8); } return (sc); } void lio_free_soft_command(struct octeon_device *oct, struct lio_soft_command *sc) { mtx_lock(&oct->sc_buf_pool.lock); STAILQ_INSERT_TAIL(&oct->sc_buf_pool.head, &sc->node, entries); atomic_subtract_int(&oct->sc_buf_pool.alloc_buf_count, 1); mtx_unlock(&oct->sc_buf_pool.lock); }