Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
James Smart | 3564 | 100.00% | 3 | 100.00% |
Total | 3564 | 3 |
// SPDX-License-Identifier: GPL-2.0 /* * Copyright (C) 2021 Broadcom. All Rights Reserved. The term * “Broadcom” refers to Broadcom Inc. and/or its subsidiaries. */ #include "efct_driver.h" #include "efct_hw.h" #include "efct_unsol.h" int efct_hw_init_queues(struct efct_hw *hw) { struct hw_eq *eq = NULL; struct hw_cq *cq = NULL; struct hw_wq *wq = NULL; struct hw_mq *mq = NULL; struct hw_eq *eqs[EFCT_HW_MAX_NUM_EQ]; struct hw_cq *cqs[EFCT_HW_MAX_NUM_EQ]; struct hw_rq *rqs[EFCT_HW_MAX_NUM_EQ]; u32 i = 0, j; hw->eq_count = 0; hw->cq_count = 0; hw->mq_count = 0; hw->wq_count = 0; hw->rq_count = 0; hw->hw_rq_count = 0; INIT_LIST_HEAD(&hw->eq_list); for (i = 0; i < hw->config.n_eq; i++) { /* Create EQ */ eq = efct_hw_new_eq(hw, EFCT_HW_EQ_DEPTH); if (!eq) { efct_hw_queue_teardown(hw); return -ENOMEM; } eqs[i] = eq; /* Create one MQ */ if (!i) { cq = efct_hw_new_cq(eq, hw->num_qentries[SLI4_QTYPE_CQ]); if (!cq) { efct_hw_queue_teardown(hw); return -ENOMEM; } mq = efct_hw_new_mq(cq, EFCT_HW_MQ_DEPTH); if (!mq) { efct_hw_queue_teardown(hw); return -ENOMEM; } } /* Create WQ */ cq = efct_hw_new_cq(eq, hw->num_qentries[SLI4_QTYPE_CQ]); if (!cq) { efct_hw_queue_teardown(hw); return -ENOMEM; } wq = efct_hw_new_wq(cq, hw->num_qentries[SLI4_QTYPE_WQ]); if (!wq) { efct_hw_queue_teardown(hw); return -ENOMEM; } } /* Create CQ set */ if (efct_hw_new_cq_set(eqs, cqs, i, hw->num_qentries[SLI4_QTYPE_CQ])) { efct_hw_queue_teardown(hw); return -EIO; } /* Create RQ set */ if (efct_hw_new_rq_set(cqs, rqs, i, EFCT_HW_RQ_ENTRIES_DEF)) { efct_hw_queue_teardown(hw); return -EIO; } for (j = 0; j < i ; j++) { rqs[j]->filter_mask = 0; rqs[j]->is_mrq = true; rqs[j]->base_mrq_id = rqs[0]->hdr->id; } hw->hw_mrq_count = i; return 0; } int efct_hw_map_wq_cpu(struct efct_hw *hw) { struct efct *efct = hw->os; u32 cpu = 0, i; /* Init cpu_map array */ hw->wq_cpu_array = kcalloc(num_possible_cpus(), sizeof(void *), GFP_KERNEL); if (!hw->wq_cpu_array) return -ENOMEM; for (i = 0; i < hw->config.n_eq; i++) { const struct cpumask *maskp; /* Get a CPU mask for all CPUs affinitized to this vector */ maskp = pci_irq_get_affinity(efct->pci, i); if (!maskp) { efc_log_debug(efct, "maskp null for vector:%d\n", i); continue; } /* Loop through all CPUs associated with vector idx */ for_each_cpu_and(cpu, maskp, cpu_present_mask) { efc_log_debug(efct, "CPU:%d irq vector:%d\n", cpu, i); hw->wq_cpu_array[cpu] = hw->hw_wq[i]; } } return 0; } struct hw_eq * efct_hw_new_eq(struct efct_hw *hw, u32 entry_count) { struct hw_eq *eq = kzalloc(sizeof(*eq), GFP_KERNEL); if (!eq) return NULL; eq->type = SLI4_QTYPE_EQ; eq->hw = hw; eq->entry_count = entry_count; eq->instance = hw->eq_count++; eq->queue = &hw->eq[eq->instance]; INIT_LIST_HEAD(&eq->cq_list); if (sli_queue_alloc(&hw->sli, SLI4_QTYPE_EQ, eq->queue, entry_count, NULL)) { efc_log_err(hw->os, "EQ[%d] alloc failure\n", eq->instance); kfree(eq); return NULL; } sli_eq_modify_delay(&hw->sli, eq->queue, 1, 0, 8); hw->hw_eq[eq->instance] = eq; INIT_LIST_HEAD(&eq->list_entry); list_add_tail(&eq->list_entry, &hw->eq_list); efc_log_debug(hw->os, "create eq[%2d] id %3d len %4d\n", eq->instance, eq->queue->id, eq->entry_count); return eq; } struct hw_cq * efct_hw_new_cq(struct hw_eq *eq, u32 entry_count) { struct efct_hw *hw = eq->hw; struct hw_cq *cq = kzalloc(sizeof(*cq), GFP_KERNEL); if (!cq) return NULL; cq->eq = eq; cq->type = SLI4_QTYPE_CQ; cq->instance = eq->hw->cq_count++; cq->entry_count = entry_count; cq->queue = &hw->cq[cq->instance]; INIT_LIST_HEAD(&cq->q_list); if (sli_queue_alloc(&hw->sli, SLI4_QTYPE_CQ, cq->queue, cq->entry_count, eq->queue)) { efc_log_err(hw->os, "CQ[%d] allocation failure len=%d\n", eq->instance, eq->entry_count); kfree(cq); return NULL; } hw->hw_cq[cq->instance] = cq; INIT_LIST_HEAD(&cq->list_entry); list_add_tail(&cq->list_entry, &eq->cq_list); efc_log_debug(hw->os, "create cq[%2d] id %3d len %4d\n", cq->instance, cq->queue->id, cq->entry_count); return cq; } u32 efct_hw_new_cq_set(struct hw_eq *eqs[], struct hw_cq *cqs[], u32 num_cqs, u32 entry_count) { u32 i; struct efct_hw *hw = eqs[0]->hw; struct sli4 *sli4 = &hw->sli; struct hw_cq *cq = NULL; struct sli4_queue *qs[SLI4_MAX_CQ_SET_COUNT]; struct sli4_queue *assefct[SLI4_MAX_CQ_SET_COUNT]; /* Initialise CQS pointers to NULL */ for (i = 0; i < num_cqs; i++) cqs[i] = NULL; for (i = 0; i < num_cqs; i++) { cq = kzalloc(sizeof(*cq), GFP_KERNEL); if (!cq) goto error; cqs[i] = cq; cq->eq = eqs[i]; cq->type = SLI4_QTYPE_CQ; cq->instance = hw->cq_count++; cq->entry_count = entry_count; cq->queue = &hw->cq[cq->instance]; qs[i] = cq->queue; assefct[i] = eqs[i]->queue; INIT_LIST_HEAD(&cq->q_list); } if (sli_cq_alloc_set(sli4, qs, num_cqs, entry_count, assefct)) { efc_log_err(hw->os, "Failed to create CQ Set.\n"); goto error; } for (i = 0; i < num_cqs; i++) { hw->hw_cq[cqs[i]->instance] = cqs[i]; INIT_LIST_HEAD(&cqs[i]->list_entry); list_add_tail(&cqs[i]->list_entry, &cqs[i]->eq->cq_list); } return 0; error: for (i = 0; i < num_cqs; i++) { kfree(cqs[i]); cqs[i] = NULL; } return -EIO; } struct hw_mq * efct_hw_new_mq(struct hw_cq *cq, u32 entry_count) { struct efct_hw *hw = cq->eq->hw; struct hw_mq *mq = kzalloc(sizeof(*mq), GFP_KERNEL); if (!mq) return NULL; mq->cq = cq; mq->type = SLI4_QTYPE_MQ; mq->instance = cq->eq->hw->mq_count++; mq->entry_count = entry_count; mq->entry_size = EFCT_HW_MQ_DEPTH; mq->queue = &hw->mq[mq->instance]; if (sli_queue_alloc(&hw->sli, SLI4_QTYPE_MQ, mq->queue, mq->entry_size, cq->queue)) { efc_log_err(hw->os, "MQ allocation failure\n"); kfree(mq); return NULL; } hw->hw_mq[mq->instance] = mq; INIT_LIST_HEAD(&mq->list_entry); list_add_tail(&mq->list_entry, &cq->q_list); efc_log_debug(hw->os, "create mq[%2d] id %3d len %4d\n", mq->instance, mq->queue->id, mq->entry_count); return mq; } struct hw_wq * efct_hw_new_wq(struct hw_cq *cq, u32 entry_count) { struct efct_hw *hw = cq->eq->hw; struct hw_wq *wq = kzalloc(sizeof(*wq), GFP_KERNEL); if (!wq) return NULL; wq->hw = cq->eq->hw; wq->cq = cq; wq->type = SLI4_QTYPE_WQ; wq->instance = cq->eq->hw->wq_count++; wq->entry_count = entry_count; wq->queue = &hw->wq[wq->instance]; wq->wqec_set_count = EFCT_HW_WQEC_SET_COUNT; wq->wqec_count = wq->wqec_set_count; wq->free_count = wq->entry_count - 1; INIT_LIST_HEAD(&wq->pending_list); if (sli_queue_alloc(&hw->sli, SLI4_QTYPE_WQ, wq->queue, wq->entry_count, cq->queue)) { efc_log_err(hw->os, "WQ allocation failure\n"); kfree(wq); return NULL; } hw->hw_wq[wq->instance] = wq; INIT_LIST_HEAD(&wq->list_entry); list_add_tail(&wq->list_entry, &cq->q_list); efc_log_debug(hw->os, "create wq[%2d] id %3d len %4d cls %d\n", wq->instance, wq->queue->id, wq->entry_count, wq->class); return wq; } u32 efct_hw_new_rq_set(struct hw_cq *cqs[], struct hw_rq *rqs[], u32 num_rq_pairs, u32 entry_count) { struct efct_hw *hw = cqs[0]->eq->hw; struct hw_rq *rq = NULL; struct sli4_queue *qs[SLI4_MAX_RQ_SET_COUNT * 2] = { NULL }; u32 i, q_count, size; /* Initialise RQS pointers */ for (i = 0; i < num_rq_pairs; i++) rqs[i] = NULL; /* * Allocate an RQ object SET, where each element in set * encapsulates 2 SLI queues (for rq pair) */ for (i = 0, q_count = 0; i < num_rq_pairs; i++, q_count += 2) { rq = kzalloc(sizeof(*rq), GFP_KERNEL); if (!rq) goto error; rqs[i] = rq; rq->instance = hw->hw_rq_count++; rq->cq = cqs[i]; rq->type = SLI4_QTYPE_RQ; rq->entry_count = entry_count; /* Header RQ */ rq->hdr = &hw->rq[hw->rq_count]; rq->hdr_entry_size = EFCT_HW_RQ_HEADER_SIZE; hw->hw_rq_lookup[hw->rq_count] = rq->instance; hw->rq_count++; qs[q_count] = rq->hdr; /* Data RQ */ rq->data = &hw->rq[hw->rq_count]; rq->data_entry_size = hw->config.rq_default_buffer_size; hw->hw_rq_lookup[hw->rq_count] = rq->instance; hw->rq_count++; qs[q_count + 1] = rq->data; rq->rq_tracker = NULL; } if (sli_fc_rq_set_alloc(&hw->sli, num_rq_pairs, qs, cqs[0]->queue->id, rqs[0]->entry_count, rqs[0]->hdr_entry_size, rqs[0]->data_entry_size)) { efc_log_err(hw->os, "RQ Set alloc failure for base CQ=%d\n", cqs[0]->queue->id); goto error; } for (i = 0; i < num_rq_pairs; i++) { hw->hw_rq[rqs[i]->instance] = rqs[i]; INIT_LIST_HEAD(&rqs[i]->list_entry); list_add_tail(&rqs[i]->list_entry, &cqs[i]->q_list); size = sizeof(struct efc_hw_sequence *) * rqs[i]->entry_count; rqs[i]->rq_tracker = kzalloc(size, GFP_KERNEL); if (!rqs[i]->rq_tracker) goto error; } return 0; error: for (i = 0; i < num_rq_pairs; i++) { if (rqs[i]) { kfree(rqs[i]->rq_tracker); kfree(rqs[i]); } } return -EIO; } void efct_hw_del_eq(struct hw_eq *eq) { struct hw_cq *cq; struct hw_cq *cq_next; if (!eq) return; list_for_each_entry_safe(cq, cq_next, &eq->cq_list, list_entry) efct_hw_del_cq(cq); list_del(&eq->list_entry); eq->hw->hw_eq[eq->instance] = NULL; kfree(eq); } void efct_hw_del_cq(struct hw_cq *cq) { struct hw_q *q; struct hw_q *q_next; if (!cq) return; list_for_each_entry_safe(q, q_next, &cq->q_list, list_entry) { switch (q->type) { case SLI4_QTYPE_MQ: efct_hw_del_mq((struct hw_mq *)q); break; case SLI4_QTYPE_WQ: efct_hw_del_wq((struct hw_wq *)q); break; case SLI4_QTYPE_RQ: efct_hw_del_rq((struct hw_rq *)q); break; default: break; } } list_del(&cq->list_entry); cq->eq->hw->hw_cq[cq->instance] = NULL; kfree(cq); } void efct_hw_del_mq(struct hw_mq *mq) { if (!mq) return; list_del(&mq->list_entry); mq->cq->eq->hw->hw_mq[mq->instance] = NULL; kfree(mq); } void efct_hw_del_wq(struct hw_wq *wq) { if (!wq) return; list_del(&wq->list_entry); wq->cq->eq->hw->hw_wq[wq->instance] = NULL; kfree(wq); } void efct_hw_del_rq(struct hw_rq *rq) { struct efct_hw *hw = NULL; if (!rq) return; /* Free RQ tracker */ kfree(rq->rq_tracker); rq->rq_tracker = NULL; list_del(&rq->list_entry); hw = rq->cq->eq->hw; hw->hw_rq[rq->instance] = NULL; kfree(rq); } void efct_hw_queue_teardown(struct efct_hw *hw) { struct hw_eq *eq; struct hw_eq *eq_next; if (!hw->eq_list.next) return; list_for_each_entry_safe(eq, eq_next, &hw->eq_list, list_entry) efct_hw_del_eq(eq); } static inline int efct_hw_rqpair_find(struct efct_hw *hw, u16 rq_id) { return efct_hw_queue_hash_find(hw->rq_hash, rq_id); } static struct efc_hw_sequence * efct_hw_rqpair_get(struct efct_hw *hw, u16 rqindex, u16 bufindex) { struct sli4_queue *rq_hdr = &hw->rq[rqindex]; struct efc_hw_sequence *seq = NULL; struct hw_rq *rq = hw->hw_rq[hw->hw_rq_lookup[rqindex]]; unsigned long flags = 0; if (bufindex >= rq_hdr->length) { efc_log_err(hw->os, "RQidx %d bufidx %d exceed ring len %d for id %d\n", rqindex, bufindex, rq_hdr->length, rq_hdr->id); return NULL; } /* rq_hdr lock also covers rqindex+1 queue */ spin_lock_irqsave(&rq_hdr->lock, flags); seq = rq->rq_tracker[bufindex]; rq->rq_tracker[bufindex] = NULL; if (!seq) { efc_log_err(hw->os, "RQbuf NULL, rqidx %d, bufidx %d, cur q idx = %d\n", rqindex, bufindex, rq_hdr->index); } spin_unlock_irqrestore(&rq_hdr->lock, flags); return seq; } int efct_hw_rqpair_process_rq(struct efct_hw *hw, struct hw_cq *cq, u8 *cqe) { u16 rq_id; u32 index; int rqindex; int rq_status; u32 h_len; u32 p_len; struct efc_hw_sequence *seq; struct hw_rq *rq; rq_status = sli_fc_rqe_rqid_and_index(&hw->sli, cqe, &rq_id, &index); if (rq_status != 0) { switch (rq_status) { case SLI4_FC_ASYNC_RQ_BUF_LEN_EXCEEDED: case SLI4_FC_ASYNC_RQ_DMA_FAILURE: /* just get RQ buffer then return to chip */ rqindex = efct_hw_rqpair_find(hw, rq_id); if (rqindex < 0) { efc_log_debug(hw->os, "status=%#x: lookup fail id=%#x\n", rq_status, rq_id); break; } /* get RQ buffer */ seq = efct_hw_rqpair_get(hw, rqindex, index); /* return to chip */ if (efct_hw_rqpair_sequence_free(hw, seq)) { efc_log_debug(hw->os, "status=%#x,fail rtrn buf to RQ\n", rq_status); break; } break; case SLI4_FC_ASYNC_RQ_INSUFF_BUF_NEEDED: case SLI4_FC_ASYNC_RQ_INSUFF_BUF_FRM_DISC: /* * since RQ buffers were not consumed, cannot return * them to chip */ efc_log_debug(hw->os, "Warning: RCQE status=%#x,\n", rq_status); fallthrough; default: break; } return -EIO; } rqindex = efct_hw_rqpair_find(hw, rq_id); if (rqindex < 0) { efc_log_debug(hw->os, "Error: rq_id lookup failed for id=%#x\n", rq_id); return -EIO; } rq = hw->hw_rq[hw->hw_rq_lookup[rqindex]]; rq->use_count++; seq = efct_hw_rqpair_get(hw, rqindex, index); if (WARN_ON(!seq)) return -EIO; seq->hw = hw; sli_fc_rqe_length(&hw->sli, cqe, &h_len, &p_len); seq->header->dma.len = h_len; seq->payload->dma.len = p_len; seq->fcfi = sli_fc_rqe_fcfi(&hw->sli, cqe); seq->hw_priv = cq->eq; efct_unsolicited_cb(hw->os, seq); return 0; } static int efct_hw_rqpair_put(struct efct_hw *hw, struct efc_hw_sequence *seq) { struct sli4_queue *rq_hdr = &hw->rq[seq->header->rqindex]; struct sli4_queue *rq_payload = &hw->rq[seq->payload->rqindex]; u32 hw_rq_index = hw->hw_rq_lookup[seq->header->rqindex]; struct hw_rq *rq = hw->hw_rq[hw_rq_index]; u32 phys_hdr[2]; u32 phys_payload[2]; int qindex_hdr; int qindex_payload; unsigned long flags = 0; /* Update the RQ verification lookup tables */ phys_hdr[0] = upper_32_bits(seq->header->dma.phys); phys_hdr[1] = lower_32_bits(seq->header->dma.phys); phys_payload[0] = upper_32_bits(seq->payload->dma.phys); phys_payload[1] = lower_32_bits(seq->payload->dma.phys); /* rq_hdr lock also covers payload / header->rqindex+1 queue */ spin_lock_irqsave(&rq_hdr->lock, flags); /* * Note: The header must be posted last for buffer pair mode because * posting on the header queue posts the payload queue as well. * We do not ring the payload queue independently in RQ pair mode. */ qindex_payload = sli_rq_write(&hw->sli, rq_payload, (void *)phys_payload); qindex_hdr = sli_rq_write(&hw->sli, rq_hdr, (void *)phys_hdr); if (qindex_hdr < 0 || qindex_payload < 0) { efc_log_err(hw->os, "RQ_ID=%#x write failed\n", rq_hdr->id); spin_unlock_irqrestore(&rq_hdr->lock, flags); return -EIO; } /* ensure the indexes are the same */ WARN_ON(qindex_hdr != qindex_payload); /* Update the lookup table */ if (!rq->rq_tracker[qindex_hdr]) { rq->rq_tracker[qindex_hdr] = seq; } else { efc_log_debug(hw->os, "expected rq_tracker[%d][%d] buffer to be NULL\n", hw_rq_index, qindex_hdr); } spin_unlock_irqrestore(&rq_hdr->lock, flags); return 0; } int efct_hw_rqpair_sequence_free(struct efct_hw *hw, struct efc_hw_sequence *seq) { int rc = 0; /* * Post the data buffer first. Because in RQ pair mode, ringing the * doorbell of the header ring will post the data buffer as well. */ if (efct_hw_rqpair_put(hw, seq)) { efc_log_err(hw->os, "error writing buffers\n"); return -EIO; } return rc; } int efct_efc_hw_sequence_free(struct efc *efc, struct efc_hw_sequence *seq) { struct efct *efct = efc->base; return efct_hw_rqpair_sequence_free(&efct->hw, seq); }
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