Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
James Smart | 25883 | 99.95% | 5 | 55.56% |
Christoph Hellwig | 7 | 0.03% | 1 | 11.11% |
Christophe Jaillet | 4 | 0.02% | 1 | 11.11% |
Randy Dunlap | 1 | 0.00% | 1 | 11.11% |
Julia Lawall | 1 | 0.00% | 1 | 11.11% |
Total | 25896 | 9 |
// SPDX-License-Identifier: GPL-2.0 /* * Copyright (C) 2021 Broadcom. All Rights Reserved. The term * “Broadcom” refers to Broadcom Inc. and/or its subsidiaries. */ /* * All common (i.e. transport-independent) SLI-4 functions are implemented * in this file. */ #include "sli4.h" static struct sli4_asic_entry_t sli4_asic_table[] = { { SLI4_ASIC_REV_B0, SLI4_ASIC_GEN_5}, { SLI4_ASIC_REV_D0, SLI4_ASIC_GEN_5}, { SLI4_ASIC_REV_A3, SLI4_ASIC_GEN_6}, { SLI4_ASIC_REV_A0, SLI4_ASIC_GEN_6}, { SLI4_ASIC_REV_A1, SLI4_ASIC_GEN_6}, { SLI4_ASIC_REV_A3, SLI4_ASIC_GEN_6}, { SLI4_ASIC_REV_A1, SLI4_ASIC_GEN_7}, { SLI4_ASIC_REV_A0, SLI4_ASIC_GEN_7}, }; /* Convert queue type enum (SLI_QTYPE_*) into a string */ static char *SLI4_QNAME[] = { "Event Queue", "Completion Queue", "Mailbox Queue", "Work Queue", "Receive Queue", "Undefined" }; /** * sli_config_cmd_init() - Write a SLI_CONFIG command to the provided buffer. * * @sli4: SLI context pointer. * @buf: Destination buffer for the command. * @length: Length in bytes of attached command. * @dma: DMA buffer for non-embedded commands. * Return: Command payload buffer. */ static void * sli_config_cmd_init(struct sli4 *sli4, void *buf, u32 length, struct efc_dma *dma) { struct sli4_cmd_sli_config *config; u32 flags; if (length > sizeof(config->payload.embed) && !dma) { efc_log_err(sli4, "Too big for an embedded cmd with len(%d)\n", length); return NULL; } memset(buf, 0, SLI4_BMBX_SIZE); config = buf; config->hdr.command = SLI4_MBX_CMD_SLI_CONFIG; if (!dma) { flags = SLI4_SLICONF_EMB; config->dw1_flags = cpu_to_le32(flags); config->payload_len = cpu_to_le32(length); return config->payload.embed; } flags = SLI4_SLICONF_PMDCMD_VAL_1; flags &= ~SLI4_SLICONF_EMB; config->dw1_flags = cpu_to_le32(flags); config->payload.mem.addr.low = cpu_to_le32(lower_32_bits(dma->phys)); config->payload.mem.addr.high = cpu_to_le32(upper_32_bits(dma->phys)); config->payload.mem.length = cpu_to_le32(dma->size & SLI4_SLICONF_PMD_LEN); config->payload_len = cpu_to_le32(dma->size); /* save pointer to DMA for BMBX dumping purposes */ sli4->bmbx_non_emb_pmd = dma; return dma->virt; } /** * sli_cmd_common_create_cq() - Write a COMMON_CREATE_CQ V2 command. * * @sli4: SLI context pointer. * @buf: Destination buffer for the command. * @qmem: DMA memory for queue. * @eq_id: EQ id assosiated with this cq. * Return: status -EIO/0. */ static int sli_cmd_common_create_cq(struct sli4 *sli4, void *buf, struct efc_dma *qmem, u16 eq_id) { struct sli4_rqst_cmn_create_cq_v2 *cqv2 = NULL; u32 p; uintptr_t addr; u32 num_pages = 0; size_t cmd_size = 0; u32 page_size = 0; u32 n_cqe = 0; u32 dw5_flags = 0; u16 dw6w1_arm = 0; __le32 len; /* First calculate number of pages and the mailbox cmd length */ n_cqe = qmem->size / SLI4_CQE_BYTES; switch (n_cqe) { case 256: case 512: case 1024: case 2048: page_size = SZ_4K; break; case 4096: page_size = SZ_8K; break; default: return -EIO; } num_pages = sli_page_count(qmem->size, page_size); cmd_size = SLI4_RQST_CMDSZ(cmn_create_cq_v2) + SZ_DMAADDR * num_pages; cqv2 = sli_config_cmd_init(sli4, buf, cmd_size, NULL); if (!cqv2) return -EIO; len = SLI4_RQST_PYLD_LEN_VAR(cmn_create_cq_v2, SZ_DMAADDR * num_pages); sli_cmd_fill_hdr(&cqv2->hdr, SLI4_CMN_CREATE_CQ, SLI4_SUBSYSTEM_COMMON, CMD_V2, len); cqv2->page_size = page_size / SLI_PAGE_SIZE; /* valid values for number of pages: 1, 2, 4, 8 (sec 4.4.3) */ cqv2->num_pages = cpu_to_le16(num_pages); if (!num_pages || num_pages > SLI4_CREATE_CQV2_MAX_PAGES) return -EIO; switch (num_pages) { case 1: dw5_flags |= SLI4_CQ_CNT_VAL(256); break; case 2: dw5_flags |= SLI4_CQ_CNT_VAL(512); break; case 4: dw5_flags |= SLI4_CQ_CNT_VAL(1024); break; case 8: dw5_flags |= SLI4_CQ_CNT_VAL(LARGE); cqv2->cqe_count = cpu_to_le16(n_cqe); break; default: efc_log_err(sli4, "num_pages %d not valid\n", num_pages); return -EIO; } if (sli4->if_type == SLI4_INTF_IF_TYPE_6) dw5_flags |= SLI4_CREATE_CQV2_AUTOVALID; dw5_flags |= SLI4_CREATE_CQV2_EVT; dw5_flags |= SLI4_CREATE_CQV2_VALID; cqv2->dw5_flags = cpu_to_le32(dw5_flags); cqv2->dw6w1_arm = cpu_to_le16(dw6w1_arm); cqv2->eq_id = cpu_to_le16(eq_id); for (p = 0, addr = qmem->phys; p < num_pages; p++, addr += page_size) { cqv2->page_phys_addr[p].low = cpu_to_le32(lower_32_bits(addr)); cqv2->page_phys_addr[p].high = cpu_to_le32(upper_32_bits(addr)); } return 0; } static int sli_cmd_common_create_eq(struct sli4 *sli4, void *buf, struct efc_dma *qmem) { struct sli4_rqst_cmn_create_eq *eq; u32 p; uintptr_t addr; u16 num_pages; u32 dw5_flags = 0; u32 dw6_flags = 0, ver; eq = sli_config_cmd_init(sli4, buf, SLI4_CFG_PYLD_LENGTH(cmn_create_eq), NULL); if (!eq) return -EIO; if (sli4->if_type == SLI4_INTF_IF_TYPE_6) ver = CMD_V2; else ver = CMD_V0; sli_cmd_fill_hdr(&eq->hdr, SLI4_CMN_CREATE_EQ, SLI4_SUBSYSTEM_COMMON, ver, SLI4_RQST_PYLD_LEN(cmn_create_eq)); /* valid values for number of pages: 1, 2, 4 (sec 4.4.3) */ num_pages = qmem->size / SLI_PAGE_SIZE; eq->num_pages = cpu_to_le16(num_pages); switch (num_pages) { case 1: dw5_flags |= SLI4_EQE_SIZE_4; dw6_flags |= SLI4_EQ_CNT_VAL(1024); break; case 2: dw5_flags |= SLI4_EQE_SIZE_4; dw6_flags |= SLI4_EQ_CNT_VAL(2048); break; case 4: dw5_flags |= SLI4_EQE_SIZE_4; dw6_flags |= SLI4_EQ_CNT_VAL(4096); break; default: efc_log_err(sli4, "num_pages %d not valid\n", num_pages); return -EIO; } if (sli4->if_type == SLI4_INTF_IF_TYPE_6) dw5_flags |= SLI4_CREATE_EQ_AUTOVALID; dw5_flags |= SLI4_CREATE_EQ_VALID; dw6_flags &= (~SLI4_CREATE_EQ_ARM); eq->dw5_flags = cpu_to_le32(dw5_flags); eq->dw6_flags = cpu_to_le32(dw6_flags); eq->dw7_delaymulti = cpu_to_le32(SLI4_CREATE_EQ_DELAYMULTI); for (p = 0, addr = qmem->phys; p < num_pages; p++, addr += SLI_PAGE_SIZE) { eq->page_address[p].low = cpu_to_le32(lower_32_bits(addr)); eq->page_address[p].high = cpu_to_le32(upper_32_bits(addr)); } return 0; } static int sli_cmd_common_create_mq_ext(struct sli4 *sli4, void *buf, struct efc_dma *qmem, u16 cq_id) { struct sli4_rqst_cmn_create_mq_ext *mq; u32 p; uintptr_t addr; u32 num_pages; u16 dw6w1_flags = 0; mq = sli_config_cmd_init(sli4, buf, SLI4_CFG_PYLD_LENGTH(cmn_create_mq_ext), NULL); if (!mq) return -EIO; sli_cmd_fill_hdr(&mq->hdr, SLI4_CMN_CREATE_MQ_EXT, SLI4_SUBSYSTEM_COMMON, CMD_V0, SLI4_RQST_PYLD_LEN(cmn_create_mq_ext)); /* valid values for number of pages: 1, 2, 4, 8 (sec 4.4.12) */ num_pages = qmem->size / SLI_PAGE_SIZE; mq->num_pages = cpu_to_le16(num_pages); switch (num_pages) { case 1: dw6w1_flags |= SLI4_MQE_SIZE_16; break; case 2: dw6w1_flags |= SLI4_MQE_SIZE_32; break; case 4: dw6w1_flags |= SLI4_MQE_SIZE_64; break; case 8: dw6w1_flags |= SLI4_MQE_SIZE_128; break; default: efc_log_info(sli4, "num_pages %d not valid\n", num_pages); return -EIO; } mq->async_event_bitmap = cpu_to_le32(SLI4_ASYNC_EVT_FC_ALL); if (sli4->params.mq_create_version) { mq->cq_id_v1 = cpu_to_le16(cq_id); mq->hdr.dw3_version = cpu_to_le32(CMD_V1); } else { dw6w1_flags |= (cq_id << SLI4_CREATE_MQEXT_CQID_SHIFT); } mq->dw7_val = cpu_to_le32(SLI4_CREATE_MQEXT_VAL); mq->dw6w1_flags = cpu_to_le16(dw6w1_flags); for (p = 0, addr = qmem->phys; p < num_pages; p++, addr += SLI_PAGE_SIZE) { mq->page_phys_addr[p].low = cpu_to_le32(lower_32_bits(addr)); mq->page_phys_addr[p].high = cpu_to_le32(upper_32_bits(addr)); } return 0; } int sli_cmd_wq_create(struct sli4 *sli4, void *buf, struct efc_dma *qmem, u16 cq_id) { struct sli4_rqst_wq_create *wq; u32 p; uintptr_t addr; u32 page_size = 0; u32 n_wqe = 0; u16 num_pages; wq = sli_config_cmd_init(sli4, buf, SLI4_CFG_PYLD_LENGTH(wq_create), NULL); if (!wq) return -EIO; sli_cmd_fill_hdr(&wq->hdr, SLI4_OPC_WQ_CREATE, SLI4_SUBSYSTEM_FC, CMD_V1, SLI4_RQST_PYLD_LEN(wq_create)); n_wqe = qmem->size / sli4->wqe_size; switch (qmem->size) { case 4096: case 8192: case 16384: case 32768: page_size = SZ_4K; break; case 65536: page_size = SZ_8K; break; case 131072: page_size = SZ_16K; break; case 262144: page_size = SZ_32K; break; case 524288: page_size = SZ_64K; break; default: return -EIO; } /* valid values for number of pages(num_pages): 1-8 */ num_pages = sli_page_count(qmem->size, page_size); wq->num_pages = cpu_to_le16(num_pages); if (!num_pages || num_pages > SLI4_WQ_CREATE_MAX_PAGES) return -EIO; wq->cq_id = cpu_to_le16(cq_id); wq->page_size = page_size / SLI_PAGE_SIZE; if (sli4->wqe_size == SLI4_WQE_EXT_BYTES) wq->wqe_size_byte |= SLI4_WQE_EXT_SIZE; else wq->wqe_size_byte |= SLI4_WQE_SIZE; wq->wqe_count = cpu_to_le16(n_wqe); for (p = 0, addr = qmem->phys; p < num_pages; p++, addr += page_size) { wq->page_phys_addr[p].low = cpu_to_le32(lower_32_bits(addr)); wq->page_phys_addr[p].high = cpu_to_le32(upper_32_bits(addr)); } return 0; } static int sli_cmd_rq_create_v1(struct sli4 *sli4, void *buf, struct efc_dma *qmem, u16 cq_id, u16 buffer_size) { struct sli4_rqst_rq_create_v1 *rq; u32 p; uintptr_t addr; u32 num_pages; rq = sli_config_cmd_init(sli4, buf, SLI4_CFG_PYLD_LENGTH(rq_create_v1), NULL); if (!rq) return -EIO; sli_cmd_fill_hdr(&rq->hdr, SLI4_OPC_RQ_CREATE, SLI4_SUBSYSTEM_FC, CMD_V1, SLI4_RQST_PYLD_LEN(rq_create_v1)); /* Disable "no buffer warnings" to avoid Lancer bug */ rq->dim_dfd_dnb |= SLI4_RQ_CREATE_V1_DNB; /* valid values for number of pages: 1-8 (sec 4.5.6) */ num_pages = sli_page_count(qmem->size, SLI_PAGE_SIZE); rq->num_pages = cpu_to_le16(num_pages); if (!num_pages || num_pages > SLI4_RQ_CREATE_V1_MAX_PAGES) { efc_log_info(sli4, "num_pages %d not valid, max %d\n", num_pages, SLI4_RQ_CREATE_V1_MAX_PAGES); return -EIO; } /* * RQE count is the total number of entries (note not lg2(# entries)) */ rq->rqe_count = cpu_to_le16(qmem->size / SLI4_RQE_SIZE); rq->rqe_size_byte |= SLI4_RQE_SIZE_8; rq->page_size = SLI4_RQ_PAGE_SIZE_4096; if (buffer_size < sli4->rq_min_buf_size || buffer_size > sli4->rq_max_buf_size) { efc_log_err(sli4, "buffer_size %d out of range (%d-%d)\n", buffer_size, sli4->rq_min_buf_size, sli4->rq_max_buf_size); return -EIO; } rq->buffer_size = cpu_to_le32(buffer_size); rq->cq_id = cpu_to_le16(cq_id); for (p = 0, addr = qmem->phys; p < num_pages; p++, addr += SLI_PAGE_SIZE) { rq->page_phys_addr[p].low = cpu_to_le32(lower_32_bits(addr)); rq->page_phys_addr[p].high = cpu_to_le32(upper_32_bits(addr)); } return 0; } static int sli_cmd_rq_create_v2(struct sli4 *sli4, u32 num_rqs, struct sli4_queue *qs[], u32 base_cq_id, u32 header_buffer_size, u32 payload_buffer_size, struct efc_dma *dma) { struct sli4_rqst_rq_create_v2 *req = NULL; u32 i, p, offset = 0; u32 payload_size, page_count; uintptr_t addr; u32 num_pages; __le32 len; page_count = sli_page_count(qs[0]->dma.size, SLI_PAGE_SIZE) * num_rqs; /* Payload length must accommodate both request and response */ payload_size = max(SLI4_RQST_CMDSZ(rq_create_v2) + SZ_DMAADDR * page_count, sizeof(struct sli4_rsp_cmn_create_queue_set)); dma->size = payload_size; dma->virt = dma_alloc_coherent(&sli4->pci->dev, dma->size, &dma->phys, GFP_KERNEL); if (!dma->virt) return -EIO; memset(dma->virt, 0, payload_size); req = sli_config_cmd_init(sli4, sli4->bmbx.virt, payload_size, dma); if (!req) return -EIO; len = SLI4_RQST_PYLD_LEN_VAR(rq_create_v2, SZ_DMAADDR * page_count); sli_cmd_fill_hdr(&req->hdr, SLI4_OPC_RQ_CREATE, SLI4_SUBSYSTEM_FC, CMD_V2, len); /* Fill Payload fields */ req->dim_dfd_dnb |= SLI4_RQCREATEV2_DNB; num_pages = sli_page_count(qs[0]->dma.size, SLI_PAGE_SIZE); req->num_pages = cpu_to_le16(num_pages); req->rqe_count = cpu_to_le16(qs[0]->dma.size / SLI4_RQE_SIZE); req->rqe_size_byte |= SLI4_RQE_SIZE_8; req->page_size = SLI4_RQ_PAGE_SIZE_4096; req->rq_count = num_rqs; req->base_cq_id = cpu_to_le16(base_cq_id); req->hdr_buffer_size = cpu_to_le16(header_buffer_size); req->payload_buffer_size = cpu_to_le16(payload_buffer_size); for (i = 0; i < num_rqs; i++) { for (p = 0, addr = qs[i]->dma.phys; p < num_pages; p++, addr += SLI_PAGE_SIZE) { req->page_phys_addr[offset].low = cpu_to_le32(lower_32_bits(addr)); req->page_phys_addr[offset].high = cpu_to_le32(upper_32_bits(addr)); offset++; } } return 0; } static void __sli_queue_destroy(struct sli4 *sli4, struct sli4_queue *q) { if (!q->dma.size) return; dma_free_coherent(&sli4->pci->dev, q->dma.size, q->dma.virt, q->dma.phys); memset(&q->dma, 0, sizeof(struct efc_dma)); } int __sli_queue_init(struct sli4 *sli4, struct sli4_queue *q, u32 qtype, size_t size, u32 n_entries, u32 align) { if (q->dma.virt) { efc_log_err(sli4, "%s failed\n", __func__); return -EIO; } memset(q, 0, sizeof(struct sli4_queue)); q->dma.size = size * n_entries; q->dma.virt = dma_alloc_coherent(&sli4->pci->dev, q->dma.size, &q->dma.phys, GFP_KERNEL); if (!q->dma.virt) { memset(&q->dma, 0, sizeof(struct efc_dma)); efc_log_err(sli4, "%s allocation failed\n", SLI4_QNAME[qtype]); return -EIO; } memset(q->dma.virt, 0, size * n_entries); spin_lock_init(&q->lock); q->type = qtype; q->size = size; q->length = n_entries; if (q->type == SLI4_QTYPE_EQ || q->type == SLI4_QTYPE_CQ) { /* For prism, phase will be flipped after * a sweep through eq and cq */ q->phase = 1; } /* Limit to hwf the queue size per interrupt */ q->proc_limit = n_entries / 2; if (q->type == SLI4_QTYPE_EQ) q->posted_limit = q->length / 2; else q->posted_limit = 64; return 0; } int sli_fc_rq_alloc(struct sli4 *sli4, struct sli4_queue *q, u32 n_entries, u32 buffer_size, struct sli4_queue *cq, bool is_hdr) { if (__sli_queue_init(sli4, q, SLI4_QTYPE_RQ, SLI4_RQE_SIZE, n_entries, SLI_PAGE_SIZE)) return -EIO; if (sli_cmd_rq_create_v1(sli4, sli4->bmbx.virt, &q->dma, cq->id, buffer_size)) goto error; if (__sli_create_queue(sli4, q)) goto error; if (is_hdr && q->id & 1) { efc_log_info(sli4, "bad header RQ_ID %d\n", q->id); goto error; } else if (!is_hdr && (q->id & 1) == 0) { efc_log_info(sli4, "bad data RQ_ID %d\n", q->id); goto error; } if (is_hdr) q->u.flag |= SLI4_QUEUE_FLAG_HDR; else q->u.flag &= ~SLI4_QUEUE_FLAG_HDR; return 0; error: __sli_queue_destroy(sli4, q); return -EIO; } int sli_fc_rq_set_alloc(struct sli4 *sli4, u32 num_rq_pairs, struct sli4_queue *qs[], u32 base_cq_id, u32 n_entries, u32 header_buffer_size, u32 payload_buffer_size) { u32 i; struct efc_dma dma = {0}; struct sli4_rsp_cmn_create_queue_set *rsp = NULL; void __iomem *db_regaddr = NULL; u32 num_rqs = num_rq_pairs * 2; for (i = 0; i < num_rqs; i++) { if (__sli_queue_init(sli4, qs[i], SLI4_QTYPE_RQ, SLI4_RQE_SIZE, n_entries, SLI_PAGE_SIZE)) { goto error; } } if (sli_cmd_rq_create_v2(sli4, num_rqs, qs, base_cq_id, header_buffer_size, payload_buffer_size, &dma)) { goto error; } if (sli_bmbx_command(sli4)) { efc_log_err(sli4, "bootstrap mailbox write failed RQSet\n"); goto error; } if (sli4->if_type == SLI4_INTF_IF_TYPE_6) db_regaddr = sli4->reg[1] + SLI4_IF6_RQ_DB_REG; else db_regaddr = sli4->reg[0] + SLI4_RQ_DB_REG; rsp = dma.virt; if (rsp->hdr.status) { efc_log_err(sli4, "bad create RQSet status=%#x addl=%#x\n", rsp->hdr.status, rsp->hdr.additional_status); goto error; } for (i = 0; i < num_rqs; i++) { qs[i]->id = i + le16_to_cpu(rsp->q_id); if ((qs[i]->id & 1) == 0) qs[i]->u.flag |= SLI4_QUEUE_FLAG_HDR; else qs[i]->u.flag &= ~SLI4_QUEUE_FLAG_HDR; qs[i]->db_regaddr = db_regaddr; } dma_free_coherent(&sli4->pci->dev, dma.size, dma.virt, dma.phys); return 0; error: for (i = 0; i < num_rqs; i++) __sli_queue_destroy(sli4, qs[i]); if (dma.virt) dma_free_coherent(&sli4->pci->dev, dma.size, dma.virt, dma.phys); return -EIO; } static int sli_res_sli_config(struct sli4 *sli4, void *buf) { struct sli4_cmd_sli_config *sli_config = buf; /* sanity check */ if (!buf || sli_config->hdr.command != SLI4_MBX_CMD_SLI_CONFIG) { efc_log_err(sli4, "bad parameter buf=%p cmd=%#x\n", buf, buf ? sli_config->hdr.command : -1); return -EIO; } if (le16_to_cpu(sli_config->hdr.status)) return le16_to_cpu(sli_config->hdr.status); if (le32_to_cpu(sli_config->dw1_flags) & SLI4_SLICONF_EMB) return sli_config->payload.embed[4]; efc_log_info(sli4, "external buffers not supported\n"); return -EIO; } int __sli_create_queue(struct sli4 *sli4, struct sli4_queue *q) { struct sli4_rsp_cmn_create_queue *res_q = NULL; if (sli_bmbx_command(sli4)) { efc_log_crit(sli4, "bootstrap mailbox write fail %s\n", SLI4_QNAME[q->type]); return -EIO; } if (sli_res_sli_config(sli4, sli4->bmbx.virt)) { efc_log_err(sli4, "bad status create %s\n", SLI4_QNAME[q->type]); return -EIO; } res_q = (void *)((u8 *)sli4->bmbx.virt + offsetof(struct sli4_cmd_sli_config, payload)); if (res_q->hdr.status) { efc_log_err(sli4, "bad create %s status=%#x addl=%#x\n", SLI4_QNAME[q->type], res_q->hdr.status, res_q->hdr.additional_status); return -EIO; } q->id = le16_to_cpu(res_q->q_id); switch (q->type) { case SLI4_QTYPE_EQ: if (sli4->if_type == SLI4_INTF_IF_TYPE_6) q->db_regaddr = sli4->reg[1] + SLI4_IF6_EQ_DB_REG; else q->db_regaddr = sli4->reg[0] + SLI4_EQCQ_DB_REG; break; case SLI4_QTYPE_CQ: if (sli4->if_type == SLI4_INTF_IF_TYPE_6) q->db_regaddr = sli4->reg[1] + SLI4_IF6_CQ_DB_REG; else q->db_regaddr = sli4->reg[0] + SLI4_EQCQ_DB_REG; break; case SLI4_QTYPE_MQ: if (sli4->if_type == SLI4_INTF_IF_TYPE_6) q->db_regaddr = sli4->reg[1] + SLI4_IF6_MQ_DB_REG; else q->db_regaddr = sli4->reg[0] + SLI4_MQ_DB_REG; break; case SLI4_QTYPE_RQ: if (sli4->if_type == SLI4_INTF_IF_TYPE_6) q->db_regaddr = sli4->reg[1] + SLI4_IF6_RQ_DB_REG; else q->db_regaddr = sli4->reg[0] + SLI4_RQ_DB_REG; break; case SLI4_QTYPE_WQ: if (sli4->if_type == SLI4_INTF_IF_TYPE_6) q->db_regaddr = sli4->reg[1] + SLI4_IF6_WQ_DB_REG; else q->db_regaddr = sli4->reg[0] + SLI4_IO_WQ_DB_REG; break; default: break; } return 0; } int sli_get_queue_entry_size(struct sli4 *sli4, u32 qtype) { u32 size = 0; switch (qtype) { case SLI4_QTYPE_EQ: size = sizeof(u32); break; case SLI4_QTYPE_CQ: size = 16; break; case SLI4_QTYPE_MQ: size = 256; break; case SLI4_QTYPE_WQ: size = sli4->wqe_size; break; case SLI4_QTYPE_RQ: size = SLI4_RQE_SIZE; break; default: efc_log_info(sli4, "unknown queue type %d\n", qtype); return -1; } return size; } int sli_queue_alloc(struct sli4 *sli4, u32 qtype, struct sli4_queue *q, u32 n_entries, struct sli4_queue *assoc) { int size; u32 align = 0; /* get queue size */ size = sli_get_queue_entry_size(sli4, qtype); if (size < 0) return -EIO; align = SLI_PAGE_SIZE; if (__sli_queue_init(sli4, q, qtype, size, n_entries, align)) return -EIO; switch (qtype) { case SLI4_QTYPE_EQ: if (!sli_cmd_common_create_eq(sli4, sli4->bmbx.virt, &q->dma) && !__sli_create_queue(sli4, q)) return 0; break; case SLI4_QTYPE_CQ: if (!sli_cmd_common_create_cq(sli4, sli4->bmbx.virt, &q->dma, assoc ? assoc->id : 0) && !__sli_create_queue(sli4, q)) return 0; break; case SLI4_QTYPE_MQ: assoc->u.flag |= SLI4_QUEUE_FLAG_MQ; if (!sli_cmd_common_create_mq_ext(sli4, sli4->bmbx.virt, &q->dma, assoc->id) && !__sli_create_queue(sli4, q)) return 0; break; case SLI4_QTYPE_WQ: if (!sli_cmd_wq_create(sli4, sli4->bmbx.virt, &q->dma, assoc ? assoc->id : 0) && !__sli_create_queue(sli4, q)) return 0; break; default: efc_log_info(sli4, "unknown queue type %d\n", qtype); } __sli_queue_destroy(sli4, q); return -EIO; } static int sli_cmd_cq_set_create(struct sli4 *sli4, struct sli4_queue *qs[], u32 num_cqs, struct sli4_queue *eqs[], struct efc_dma *dma) { struct sli4_rqst_cmn_create_cq_set_v0 *req = NULL; uintptr_t addr; u32 i, offset = 0, page_bytes = 0, payload_size; u32 p = 0, page_size = 0, n_cqe = 0, num_pages_cq; u32 dw5_flags = 0; u16 dw6w1_flags = 0; __le32 req_len; n_cqe = qs[0]->dma.size / SLI4_CQE_BYTES; switch (n_cqe) { case 256: case 512: case 1024: case 2048: page_size = 1; break; case 4096: page_size = 2; break; default: return -EIO; } page_bytes = page_size * SLI_PAGE_SIZE; num_pages_cq = sli_page_count(qs[0]->dma.size, page_bytes); payload_size = max(SLI4_RQST_CMDSZ(cmn_create_cq_set_v0) + (SZ_DMAADDR * num_pages_cq * num_cqs), sizeof(struct sli4_rsp_cmn_create_queue_set)); dma->size = payload_size; dma->virt = dma_alloc_coherent(&sli4->pci->dev, dma->size, &dma->phys, GFP_KERNEL); if (!dma->virt) return -EIO; memset(dma->virt, 0, payload_size); req = sli_config_cmd_init(sli4, sli4->bmbx.virt, payload_size, dma); if (!req) return -EIO; req_len = SLI4_RQST_PYLD_LEN_VAR(cmn_create_cq_set_v0, SZ_DMAADDR * num_pages_cq * num_cqs); sli_cmd_fill_hdr(&req->hdr, SLI4_CMN_CREATE_CQ_SET, SLI4_SUBSYSTEM_FC, CMD_V0, req_len); req->page_size = page_size; req->num_pages = cpu_to_le16(num_pages_cq); switch (num_pages_cq) { case 1: dw5_flags |= SLI4_CQ_CNT_VAL(256); break; case 2: dw5_flags |= SLI4_CQ_CNT_VAL(512); break; case 4: dw5_flags |= SLI4_CQ_CNT_VAL(1024); break; case 8: dw5_flags |= SLI4_CQ_CNT_VAL(LARGE); dw6w1_flags |= (n_cqe & SLI4_CREATE_CQSETV0_CQE_COUNT); break; default: efc_log_info(sli4, "num_pages %d not valid\n", num_pages_cq); return -EIO; } dw5_flags |= SLI4_CREATE_CQSETV0_EVT; dw5_flags |= SLI4_CREATE_CQSETV0_VALID; if (sli4->if_type == SLI4_INTF_IF_TYPE_6) dw5_flags |= SLI4_CREATE_CQSETV0_AUTOVALID; dw6w1_flags &= ~SLI4_CREATE_CQSETV0_ARM; req->dw5_flags = cpu_to_le32(dw5_flags); req->dw6w1_flags = cpu_to_le16(dw6w1_flags); req->num_cq_req = cpu_to_le16(num_cqs); /* Fill page addresses of all the CQs. */ for (i = 0; i < num_cqs; i++) { req->eq_id[i] = cpu_to_le16(eqs[i]->id); for (p = 0, addr = qs[i]->dma.phys; p < num_pages_cq; p++, addr += page_bytes) { req->page_phys_addr[offset].low = cpu_to_le32(lower_32_bits(addr)); req->page_phys_addr[offset].high = cpu_to_le32(upper_32_bits(addr)); offset++; } } return 0; } int sli_cq_alloc_set(struct sli4 *sli4, struct sli4_queue *qs[], u32 num_cqs, u32 n_entries, struct sli4_queue *eqs[]) { u32 i; struct efc_dma dma = {0}; struct sli4_rsp_cmn_create_queue_set *res; void __iomem *db_regaddr; /* Align the queue DMA memory */ for (i = 0; i < num_cqs; i++) { if (__sli_queue_init(sli4, qs[i], SLI4_QTYPE_CQ, SLI4_CQE_BYTES, n_entries, SLI_PAGE_SIZE)) goto error; } if (sli_cmd_cq_set_create(sli4, qs, num_cqs, eqs, &dma)) goto error; if (sli_bmbx_command(sli4)) goto error; if (sli4->if_type == SLI4_INTF_IF_TYPE_6) db_regaddr = sli4->reg[1] + SLI4_IF6_CQ_DB_REG; else db_regaddr = sli4->reg[0] + SLI4_EQCQ_DB_REG; res = dma.virt; if (res->hdr.status) { efc_log_err(sli4, "bad create CQSet status=%#x addl=%#x\n", res->hdr.status, res->hdr.additional_status); goto error; } /* Check if we got all requested CQs. */ if (le16_to_cpu(res->num_q_allocated) != num_cqs) { efc_log_crit(sli4, "Requested count CQs doesn't match.\n"); goto error; } /* Fill the resp cq ids. */ for (i = 0; i < num_cqs; i++) { qs[i]->id = le16_to_cpu(res->q_id) + i; qs[i]->db_regaddr = db_regaddr; } dma_free_coherent(&sli4->pci->dev, dma.size, dma.virt, dma.phys); return 0; error: for (i = 0; i < num_cqs; i++) __sli_queue_destroy(sli4, qs[i]); if (dma.virt) dma_free_coherent(&sli4->pci->dev, dma.size, dma.virt, dma.phys); return -EIO; } static int sli_cmd_common_destroy_q(struct sli4 *sli4, u8 opc, u8 subsystem, u16 q_id) { struct sli4_rqst_cmn_destroy_q *req; /* Payload length must accommodate both request and response */ req = sli_config_cmd_init(sli4, sli4->bmbx.virt, SLI4_CFG_PYLD_LENGTH(cmn_destroy_q), NULL); if (!req) return -EIO; sli_cmd_fill_hdr(&req->hdr, opc, subsystem, CMD_V0, SLI4_RQST_PYLD_LEN(cmn_destroy_q)); req->q_id = cpu_to_le16(q_id); return 0; } int sli_queue_free(struct sli4 *sli4, struct sli4_queue *q, u32 destroy_queues, u32 free_memory) { int rc = 0; u8 opcode, subsystem; struct sli4_rsp_hdr *res; if (!q) { efc_log_err(sli4, "bad parameter sli4=%p q=%p\n", sli4, q); return -EIO; } if (!destroy_queues) goto free_mem; switch (q->type) { case SLI4_QTYPE_EQ: opcode = SLI4_CMN_DESTROY_EQ; subsystem = SLI4_SUBSYSTEM_COMMON; break; case SLI4_QTYPE_CQ: opcode = SLI4_CMN_DESTROY_CQ; subsystem = SLI4_SUBSYSTEM_COMMON; break; case SLI4_QTYPE_MQ: opcode = SLI4_CMN_DESTROY_MQ; subsystem = SLI4_SUBSYSTEM_COMMON; break; case SLI4_QTYPE_WQ: opcode = SLI4_OPC_WQ_DESTROY; subsystem = SLI4_SUBSYSTEM_FC; break; case SLI4_QTYPE_RQ: opcode = SLI4_OPC_RQ_DESTROY; subsystem = SLI4_SUBSYSTEM_FC; break; default: efc_log_info(sli4, "bad queue type %d\n", q->type); rc = -EIO; goto free_mem; } rc = sli_cmd_common_destroy_q(sli4, opcode, subsystem, q->id); if (rc) goto free_mem; rc = sli_bmbx_command(sli4); if (rc) goto free_mem; rc = sli_res_sli_config(sli4, sli4->bmbx.virt); if (rc) goto free_mem; res = (void *)((u8 *)sli4->bmbx.virt + offsetof(struct sli4_cmd_sli_config, payload)); if (res->status) { efc_log_err(sli4, "destroy %s st=%#x addl=%#x\n", SLI4_QNAME[q->type], res->status, res->additional_status); rc = -EIO; goto free_mem; } free_mem: if (free_memory) __sli_queue_destroy(sli4, q); return rc; } int sli_queue_eq_arm(struct sli4 *sli4, struct sli4_queue *q, bool arm) { u32 val; unsigned long flags = 0; u32 a = arm ? SLI4_EQCQ_ARM : SLI4_EQCQ_UNARM; spin_lock_irqsave(&q->lock, flags); if (sli4->if_type == SLI4_INTF_IF_TYPE_6) val = sli_format_if6_eq_db_data(q->n_posted, q->id, a); else val = sli_format_eq_db_data(q->n_posted, q->id, a); writel(val, q->db_regaddr); q->n_posted = 0; spin_unlock_irqrestore(&q->lock, flags); return 0; } int sli_queue_arm(struct sli4 *sli4, struct sli4_queue *q, bool arm) { u32 val = 0; unsigned long flags = 0; u32 a = arm ? SLI4_EQCQ_ARM : SLI4_EQCQ_UNARM; spin_lock_irqsave(&q->lock, flags); switch (q->type) { case SLI4_QTYPE_EQ: if (sli4->if_type == SLI4_INTF_IF_TYPE_6) val = sli_format_if6_eq_db_data(q->n_posted, q->id, a); else val = sli_format_eq_db_data(q->n_posted, q->id, a); writel(val, q->db_regaddr); q->n_posted = 0; break; case SLI4_QTYPE_CQ: if (sli4->if_type == SLI4_INTF_IF_TYPE_6) val = sli_format_if6_cq_db_data(q->n_posted, q->id, a); else val = sli_format_cq_db_data(q->n_posted, q->id, a); writel(val, q->db_regaddr); q->n_posted = 0; break; default: efc_log_info(sli4, "should only be used for EQ/CQ, not %s\n", SLI4_QNAME[q->type]); } spin_unlock_irqrestore(&q->lock, flags); return 0; } int sli_wq_write(struct sli4 *sli4, struct sli4_queue *q, u8 *entry) { u8 *qe = q->dma.virt; u32 qindex; u32 val = 0; qindex = q->index; qe += q->index * q->size; if (sli4->params.perf_wq_id_association) sli_set_wq_id_association(entry, q->id); memcpy(qe, entry, q->size); val = sli_format_wq_db_data(q->id); writel(val, q->db_regaddr); q->index = (q->index + 1) & (q->length - 1); return qindex; } int sli_mq_write(struct sli4 *sli4, struct sli4_queue *q, u8 *entry) { u8 *qe = q->dma.virt; u32 qindex; u32 val = 0; unsigned long flags; spin_lock_irqsave(&q->lock, flags); qindex = q->index; qe += q->index * q->size; memcpy(qe, entry, q->size); val = sli_format_mq_db_data(q->id); writel(val, q->db_regaddr); q->index = (q->index + 1) & (q->length - 1); spin_unlock_irqrestore(&q->lock, flags); return qindex; } int sli_rq_write(struct sli4 *sli4, struct sli4_queue *q, u8 *entry) { u8 *qe = q->dma.virt; u32 qindex; u32 val = 0; qindex = q->index; qe += q->index * q->size; memcpy(qe, entry, q->size); /* * In RQ-pair, an RQ either contains the FC header * (i.e. is_hdr == TRUE) or the payload. * * Don't ring doorbell for payload RQ */ if (!(q->u.flag & SLI4_QUEUE_FLAG_HDR)) goto skip; val = sli_format_rq_db_data(q->id); writel(val, q->db_regaddr); skip: q->index = (q->index + 1) & (q->length - 1); return qindex; } int sli_eq_read(struct sli4 *sli4, struct sli4_queue *q, u8 *entry) { u8 *qe = q->dma.virt; unsigned long flags = 0; u16 wflags = 0; spin_lock_irqsave(&q->lock, flags); qe += q->index * q->size; /* Check if eqe is valid */ wflags = le16_to_cpu(((struct sli4_eqe *)qe)->dw0w0_flags); if ((wflags & SLI4_EQE_VALID) != q->phase) { spin_unlock_irqrestore(&q->lock, flags); return -EIO; } if (sli4->if_type != SLI4_INTF_IF_TYPE_6) { wflags &= ~SLI4_EQE_VALID; ((struct sli4_eqe *)qe)->dw0w0_flags = cpu_to_le16(wflags); } memcpy(entry, qe, q->size); q->index = (q->index + 1) & (q->length - 1); q->n_posted++; /* * For prism, the phase value will be used * to check the validity of eq/cq entries. * The value toggles after a complete sweep * through the queue. */ if (sli4->if_type == SLI4_INTF_IF_TYPE_6 && q->index == 0) q->phase ^= (u16)0x1; spin_unlock_irqrestore(&q->lock, flags); return 0; } int sli_cq_read(struct sli4 *sli4, struct sli4_queue *q, u8 *entry) { u8 *qe = q->dma.virt; unsigned long flags = 0; u32 dwflags = 0; bool valid_bit_set; spin_lock_irqsave(&q->lock, flags); qe += q->index * q->size; /* Check if cqe is valid */ dwflags = le32_to_cpu(((struct sli4_mcqe *)qe)->dw3_flags); valid_bit_set = (dwflags & SLI4_MCQE_VALID) != 0; if (valid_bit_set != q->phase) { spin_unlock_irqrestore(&q->lock, flags); return -EIO; } if (sli4->if_type != SLI4_INTF_IF_TYPE_6) { dwflags &= ~SLI4_MCQE_VALID; ((struct sli4_mcqe *)qe)->dw3_flags = cpu_to_le32(dwflags); } memcpy(entry, qe, q->size); q->index = (q->index + 1) & (q->length - 1); q->n_posted++; /* * For prism, the phase value will be used * to check the validity of eq/cq entries. * The value toggles after a complete sweep * through the queue. */ if (sli4->if_type == SLI4_INTF_IF_TYPE_6 && q->index == 0) q->phase ^= (u16)0x1; spin_unlock_irqrestore(&q->lock, flags); return 0; } int sli_mq_read(struct sli4 *sli4, struct sli4_queue *q, u8 *entry) { u8 *qe = q->dma.virt; unsigned long flags = 0; spin_lock_irqsave(&q->lock, flags); qe += q->u.r_idx * q->size; /* Check if mqe is valid */ if (q->index == q->u.r_idx) { spin_unlock_irqrestore(&q->lock, flags); return -EIO; } memcpy(entry, qe, q->size); q->u.r_idx = (q->u.r_idx + 1) & (q->length - 1); spin_unlock_irqrestore(&q->lock, flags); return 0; } int sli_eq_parse(struct sli4 *sli4, u8 *buf, u16 *cq_id) { struct sli4_eqe *eqe = (void *)buf; int rc = 0; u16 flags = 0; u16 majorcode; u16 minorcode; if (!buf || !cq_id) { efc_log_err(sli4, "bad parameters sli4=%p buf=%p cq_id=%p\n", sli4, buf, cq_id); return -EIO; } flags = le16_to_cpu(eqe->dw0w0_flags); majorcode = (flags & SLI4_EQE_MJCODE) >> 1; minorcode = (flags & SLI4_EQE_MNCODE) >> 4; switch (majorcode) { case SLI4_MAJOR_CODE_STANDARD: *cq_id = le16_to_cpu(eqe->resource_id); break; case SLI4_MAJOR_CODE_SENTINEL: efc_log_info(sli4, "sentinel EQE\n"); rc = SLI4_EQE_STATUS_EQ_FULL; break; default: efc_log_info(sli4, "Unsupported EQE: major %x minor %x\n", majorcode, minorcode); rc = -EIO; } return rc; } int sli_cq_parse(struct sli4 *sli4, struct sli4_queue *cq, u8 *cqe, enum sli4_qentry *etype, u16 *q_id) { int rc = 0; if (!cq || !cqe || !etype) { efc_log_err(sli4, "bad params sli4=%p cq=%p cqe=%p etype=%p q_id=%p\n", sli4, cq, cqe, etype, q_id); return -EINVAL; } /* Parse a CQ entry to retrieve the event type and the queue id */ if (cq->u.flag & SLI4_QUEUE_FLAG_MQ) { struct sli4_mcqe *mcqe = (void *)cqe; if (le32_to_cpu(mcqe->dw3_flags) & SLI4_MCQE_AE) { *etype = SLI4_QENTRY_ASYNC; } else { *etype = SLI4_QENTRY_MQ; rc = sli_cqe_mq(sli4, mcqe); } *q_id = -1; } else { rc = sli_fc_cqe_parse(sli4, cq, cqe, etype, q_id); } return rc; } int sli_abort_wqe(struct sli4 *sli, void *buf, enum sli4_abort_type type, bool send_abts, u32 ids, u32 mask, u16 tag, u16 cq_id) { struct sli4_abort_wqe *abort = buf; memset(buf, 0, sli->wqe_size); switch (type) { case SLI4_ABORT_XRI: abort->criteria = SLI4_ABORT_CRITERIA_XRI_TAG; if (mask) { efc_log_warn(sli, "%#x aborting XRI %#x warning non-zero mask", mask, ids); mask = 0; } break; case SLI4_ABORT_ABORT_ID: abort->criteria = SLI4_ABORT_CRITERIA_ABORT_TAG; break; case SLI4_ABORT_REQUEST_ID: abort->criteria = SLI4_ABORT_CRITERIA_REQUEST_TAG; break; default: efc_log_info(sli, "unsupported type %#x\n", type); return -EIO; } abort->ia_ir_byte |= send_abts ? 0 : 1; /* Suppress ABTS retries */ abort->ia_ir_byte |= SLI4_ABRT_WQE_IR; abort->t_mask = cpu_to_le32(mask); abort->t_tag = cpu_to_le32(ids); abort->command = SLI4_WQE_ABORT; abort->request_tag = cpu_to_le16(tag); abort->dw10w0_flags = cpu_to_le16(SLI4_ABRT_WQE_QOSD); abort->cq_id = cpu_to_le16(cq_id); abort->cmdtype_wqec_byte |= SLI4_CMD_ABORT_WQE; return 0; } int sli_els_request64_wqe(struct sli4 *sli, void *buf, struct efc_dma *sgl, struct sli_els_params *params) { struct sli4_els_request64_wqe *els = buf; struct sli4_sge *sge = sgl->virt; bool is_fabric = false; struct sli4_bde *bptr; memset(buf, 0, sli->wqe_size); bptr = &els->els_request_payload; if (sli->params.sgl_pre_registered) { els->qosd_xbl_hlm_iod_dbde_wqes &= ~SLI4_REQ_WQE_XBL; els->qosd_xbl_hlm_iod_dbde_wqes |= SLI4_REQ_WQE_DBDE; bptr->bde_type_buflen = cpu_to_le32((SLI4_BDE_TYPE_VAL(64)) | (params->xmit_len & SLI4_BDE_LEN_MASK)); bptr->u.data.low = sge[0].buffer_address_low; bptr->u.data.high = sge[0].buffer_address_high; } else { els->qosd_xbl_hlm_iod_dbde_wqes |= SLI4_REQ_WQE_XBL; bptr->bde_type_buflen = cpu_to_le32((SLI4_BDE_TYPE_VAL(BLP)) | ((2 * sizeof(struct sli4_sge)) & SLI4_BDE_LEN_MASK)); bptr->u.blp.low = cpu_to_le32(lower_32_bits(sgl->phys)); bptr->u.blp.high = cpu_to_le32(upper_32_bits(sgl->phys)); } els->els_request_payload_length = cpu_to_le32(params->xmit_len); els->max_response_payload_length = cpu_to_le32(params->rsp_len); els->xri_tag = cpu_to_le16(params->xri); els->timer = params->timeout; els->class_byte |= SLI4_GENERIC_CLASS_CLASS_3; els->command = SLI4_WQE_ELS_REQUEST64; els->request_tag = cpu_to_le16(params->tag); els->qosd_xbl_hlm_iod_dbde_wqes |= SLI4_REQ_WQE_IOD; els->qosd_xbl_hlm_iod_dbde_wqes |= SLI4_REQ_WQE_QOSD; /* figure out the ELS_ID value from the request buffer */ switch (params->cmd) { case ELS_LOGO: els->cmdtype_elsid_byte |= SLI4_ELS_REQUEST64_LOGO << SLI4_REQ_WQE_ELSID_SHFT; if (params->rpi_registered) { els->ct_byte |= SLI4_GENERIC_CONTEXT_RPI << SLI4_REQ_WQE_CT_SHFT; els->context_tag = cpu_to_le16(params->rpi); } else { els->ct_byte |= SLI4_GENERIC_CONTEXT_VPI << SLI4_REQ_WQE_CT_SHFT; els->context_tag = cpu_to_le16(params->vpi); } if (params->d_id == FC_FID_FLOGI) is_fabric = true; break; case ELS_FDISC: if (params->d_id == FC_FID_FLOGI) is_fabric = true; if (params->s_id == 0) { els->cmdtype_elsid_byte |= SLI4_ELS_REQUEST64_FDISC << SLI4_REQ_WQE_ELSID_SHFT; is_fabric = true; } else { els->cmdtype_elsid_byte |= SLI4_ELS_REQUEST64_OTHER << SLI4_REQ_WQE_ELSID_SHFT; } els->ct_byte |= SLI4_GENERIC_CONTEXT_VPI << SLI4_REQ_WQE_CT_SHFT; els->context_tag = cpu_to_le16(params->vpi); els->sid_sp_dword |= cpu_to_le32(1 << SLI4_REQ_WQE_SP_SHFT); break; case ELS_FLOGI: els->ct_byte |= SLI4_GENERIC_CONTEXT_VPI << SLI4_REQ_WQE_CT_SHFT; els->context_tag = cpu_to_le16(params->vpi); /* * Set SP here ... we haven't done a REG_VPI yet * need to maybe not set this when we have * completed VFI/VPI registrations ... * * Use the FC_ID of the SPORT if it has been allocated, * otherwise use an S_ID of zero. */ els->sid_sp_dword |= cpu_to_le32(1 << SLI4_REQ_WQE_SP_SHFT); if (params->s_id != U32_MAX) els->sid_sp_dword |= cpu_to_le32(params->s_id); break; case ELS_PLOGI: els->cmdtype_elsid_byte |= SLI4_ELS_REQUEST64_PLOGI << SLI4_REQ_WQE_ELSID_SHFT; els->ct_byte |= SLI4_GENERIC_CONTEXT_VPI << SLI4_REQ_WQE_CT_SHFT; els->context_tag = cpu_to_le16(params->vpi); break; case ELS_SCR: els->cmdtype_elsid_byte |= SLI4_ELS_REQUEST64_OTHER << SLI4_REQ_WQE_ELSID_SHFT; els->ct_byte |= SLI4_GENERIC_CONTEXT_VPI << SLI4_REQ_WQE_CT_SHFT; els->context_tag = cpu_to_le16(params->vpi); break; default: els->cmdtype_elsid_byte |= SLI4_ELS_REQUEST64_OTHER << SLI4_REQ_WQE_ELSID_SHFT; if (params->rpi_registered) { els->ct_byte |= (SLI4_GENERIC_CONTEXT_RPI << SLI4_REQ_WQE_CT_SHFT); els->context_tag = cpu_to_le16(params->vpi); } else { els->ct_byte |= SLI4_GENERIC_CONTEXT_VPI << SLI4_REQ_WQE_CT_SHFT; els->context_tag = cpu_to_le16(params->vpi); } break; } if (is_fabric) els->cmdtype_elsid_byte |= SLI4_ELS_REQUEST64_CMD_FABRIC; else els->cmdtype_elsid_byte |= SLI4_ELS_REQUEST64_CMD_NON_FABRIC; els->cq_id = cpu_to_le16(SLI4_CQ_DEFAULT); if (((els->ct_byte & SLI4_REQ_WQE_CT) >> SLI4_REQ_WQE_CT_SHFT) != SLI4_GENERIC_CONTEXT_RPI) els->remote_id_dword = cpu_to_le32(params->d_id); if (((els->ct_byte & SLI4_REQ_WQE_CT) >> SLI4_REQ_WQE_CT_SHFT) == SLI4_GENERIC_CONTEXT_VPI) els->temporary_rpi = cpu_to_le16(params->rpi); return 0; } int sli_fcp_icmnd64_wqe(struct sli4 *sli, void *buf, struct efc_dma *sgl, u16 xri, u16 tag, u16 cq_id, u32 rpi, u32 rnode_fcid, u8 timeout) { struct sli4_fcp_icmnd64_wqe *icmnd = buf; struct sli4_sge *sge = NULL; struct sli4_bde *bptr; u32 len; memset(buf, 0, sli->wqe_size); if (!sgl || !sgl->virt) { efc_log_err(sli, "bad parameter sgl=%p virt=%p\n", sgl, sgl ? sgl->virt : NULL); return -EIO; } sge = sgl->virt; bptr = &icmnd->bde; if (sli->params.sgl_pre_registered) { icmnd->qosd_xbl_hlm_iod_dbde_wqes &= ~SLI4_ICMD_WQE_XBL; icmnd->qosd_xbl_hlm_iod_dbde_wqes |= SLI4_ICMD_WQE_DBDE; bptr->bde_type_buflen = cpu_to_le32((SLI4_BDE_TYPE_VAL(64)) | (le32_to_cpu(sge[0].buffer_length) & SLI4_BDE_LEN_MASK)); bptr->u.data.low = sge[0].buffer_address_low; bptr->u.data.high = sge[0].buffer_address_high; } else { icmnd->qosd_xbl_hlm_iod_dbde_wqes |= SLI4_ICMD_WQE_XBL; bptr->bde_type_buflen = cpu_to_le32((SLI4_BDE_TYPE_VAL(BLP)) | (sgl->size & SLI4_BDE_LEN_MASK)); bptr->u.blp.low = cpu_to_le32(lower_32_bits(sgl->phys)); bptr->u.blp.high = cpu_to_le32(upper_32_bits(sgl->phys)); } len = le32_to_cpu(sge[0].buffer_length) + le32_to_cpu(sge[1].buffer_length); icmnd->payload_offset_length = cpu_to_le16(len); icmnd->xri_tag = cpu_to_le16(xri); icmnd->context_tag = cpu_to_le16(rpi); icmnd->timer = timeout; /* WQE word 4 contains read transfer length */ icmnd->class_pu_byte |= 2 << SLI4_ICMD_WQE_PU_SHFT; icmnd->class_pu_byte |= SLI4_GENERIC_CLASS_CLASS_3; icmnd->command = SLI4_WQE_FCP_ICMND64; icmnd->dif_ct_bs_byte |= SLI4_GENERIC_CONTEXT_RPI << SLI4_ICMD_WQE_CT_SHFT; icmnd->abort_tag = cpu_to_le32(xri); icmnd->request_tag = cpu_to_le16(tag); icmnd->len_loc1_byte |= SLI4_ICMD_WQE_LEN_LOC_BIT1; icmnd->qosd_xbl_hlm_iod_dbde_wqes |= SLI4_ICMD_WQE_LEN_LOC_BIT2; icmnd->cmd_type_byte |= SLI4_CMD_FCP_ICMND64_WQE; icmnd->cq_id = cpu_to_le16(cq_id); return 0; } int sli_fcp_iread64_wqe(struct sli4 *sli, void *buf, struct efc_dma *sgl, u32 first_data_sge, u32 xfer_len, u16 xri, u16 tag, u16 cq_id, u32 rpi, u32 rnode_fcid, u8 dif, u8 bs, u8 timeout) { struct sli4_fcp_iread64_wqe *iread = buf; struct sli4_sge *sge = NULL; struct sli4_bde *bptr; u32 sge_flags, len; memset(buf, 0, sli->wqe_size); if (!sgl || !sgl->virt) { efc_log_err(sli, "bad parameter sgl=%p virt=%p\n", sgl, sgl ? sgl->virt : NULL); return -EIO; } sge = sgl->virt; bptr = &iread->bde; if (sli->params.sgl_pre_registered) { iread->qosd_xbl_hlm_iod_dbde_wqes &= ~SLI4_IR_WQE_XBL; iread->qosd_xbl_hlm_iod_dbde_wqes |= SLI4_IR_WQE_DBDE; bptr->bde_type_buflen = cpu_to_le32((SLI4_BDE_TYPE_VAL(64)) | (le32_to_cpu(sge[0].buffer_length) & SLI4_BDE_LEN_MASK)); bptr->u.blp.low = sge[0].buffer_address_low; bptr->u.blp.high = sge[0].buffer_address_high; } else { iread->qosd_xbl_hlm_iod_dbde_wqes |= SLI4_IR_WQE_XBL; bptr->bde_type_buflen = cpu_to_le32((SLI4_BDE_TYPE_VAL(BLP)) | (sgl->size & SLI4_BDE_LEN_MASK)); bptr->u.blp.low = cpu_to_le32(lower_32_bits(sgl->phys)); bptr->u.blp.high = cpu_to_le32(upper_32_bits(sgl->phys)); /* * fill out fcp_cmnd buffer len and change resp buffer to be of * type "skip" (note: response will still be written to sge[1] * if necessary) */ len = le32_to_cpu(sge[0].buffer_length); iread->fcp_cmd_buffer_length = cpu_to_le16(len); sge_flags = le32_to_cpu(sge[1].dw2_flags); sge_flags &= (~SLI4_SGE_TYPE_MASK); sge_flags |= (SLI4_SGE_TYPE_SKIP << SLI4_SGE_TYPE_SHIFT); sge[1].dw2_flags = cpu_to_le32(sge_flags); } len = le32_to_cpu(sge[0].buffer_length) + le32_to_cpu(sge[1].buffer_length); iread->payload_offset_length = cpu_to_le16(len); iread->total_transfer_length = cpu_to_le32(xfer_len); iread->xri_tag = cpu_to_le16(xri); iread->context_tag = cpu_to_le16(rpi); iread->timer = timeout; /* WQE word 4 contains read transfer length */ iread->class_pu_byte |= 2 << SLI4_IR_WQE_PU_SHFT; iread->class_pu_byte |= SLI4_GENERIC_CLASS_CLASS_3; iread->command = SLI4_WQE_FCP_IREAD64; iread->dif_ct_bs_byte |= SLI4_GENERIC_CONTEXT_RPI << SLI4_IR_WQE_CT_SHFT; iread->dif_ct_bs_byte |= dif; iread->dif_ct_bs_byte |= bs << SLI4_IR_WQE_BS_SHFT; iread->abort_tag = cpu_to_le32(xri); iread->request_tag = cpu_to_le16(tag); iread->len_loc1_byte |= SLI4_IR_WQE_LEN_LOC_BIT1; iread->qosd_xbl_hlm_iod_dbde_wqes |= SLI4_IR_WQE_LEN_LOC_BIT2; iread->qosd_xbl_hlm_iod_dbde_wqes |= SLI4_IR_WQE_IOD; iread->cmd_type_byte |= SLI4_CMD_FCP_IREAD64_WQE; iread->cq_id = cpu_to_le16(cq_id); if (sli->params.perf_hint) { bptr = &iread->first_data_bde; bptr->bde_type_buflen = cpu_to_le32((SLI4_BDE_TYPE_VAL(64)) | (le32_to_cpu(sge[first_data_sge].buffer_length) & SLI4_BDE_LEN_MASK)); bptr->u.data.low = sge[first_data_sge].buffer_address_low; bptr->u.data.high = sge[first_data_sge].buffer_address_high; } return 0; } int sli_fcp_iwrite64_wqe(struct sli4 *sli, void *buf, struct efc_dma *sgl, u32 first_data_sge, u32 xfer_len, u32 first_burst, u16 xri, u16 tag, u16 cq_id, u32 rpi, u32 rnode_fcid, u8 dif, u8 bs, u8 timeout) { struct sli4_fcp_iwrite64_wqe *iwrite = buf; struct sli4_sge *sge = NULL; struct sli4_bde *bptr; u32 sge_flags, min, len; memset(buf, 0, sli->wqe_size); if (!sgl || !sgl->virt) { efc_log_err(sli, "bad parameter sgl=%p virt=%p\n", sgl, sgl ? sgl->virt : NULL); return -EIO; } sge = sgl->virt; bptr = &iwrite->bde; if (sli->params.sgl_pre_registered) { iwrite->qosd_xbl_hlm_iod_dbde_wqes &= ~SLI4_IWR_WQE_XBL; iwrite->qosd_xbl_hlm_iod_dbde_wqes |= SLI4_IWR_WQE_DBDE; bptr->bde_type_buflen = cpu_to_le32((SLI4_BDE_TYPE_VAL(64)) | (le32_to_cpu(sge[0].buffer_length) & SLI4_BDE_LEN_MASK)); bptr->u.data.low = sge[0].buffer_address_low; bptr->u.data.high = sge[0].buffer_address_high; } else { iwrite->qosd_xbl_hlm_iod_dbde_wqes |= SLI4_IWR_WQE_XBL; bptr->bde_type_buflen = cpu_to_le32((SLI4_BDE_TYPE_VAL(64)) | (sgl->size & SLI4_BDE_LEN_MASK)); bptr->u.blp.low = cpu_to_le32(lower_32_bits(sgl->phys)); bptr->u.blp.high = cpu_to_le32(upper_32_bits(sgl->phys)); /* * fill out fcp_cmnd buffer len and change resp buffer to be of * type "skip" (note: response will still be written to sge[1] * if necessary) */ len = le32_to_cpu(sge[0].buffer_length); iwrite->fcp_cmd_buffer_length = cpu_to_le16(len); sge_flags = le32_to_cpu(sge[1].dw2_flags); sge_flags &= ~SLI4_SGE_TYPE_MASK; sge_flags |= (SLI4_SGE_TYPE_SKIP << SLI4_SGE_TYPE_SHIFT); sge[1].dw2_flags = cpu_to_le32(sge_flags); } len = le32_to_cpu(sge[0].buffer_length) + le32_to_cpu(sge[1].buffer_length); iwrite->payload_offset_length = cpu_to_le16(len); iwrite->total_transfer_length = cpu_to_le16(xfer_len); min = (xfer_len < first_burst) ? xfer_len : first_burst; iwrite->initial_transfer_length = cpu_to_le16(min); iwrite->xri_tag = cpu_to_le16(xri); iwrite->context_tag = cpu_to_le16(rpi); iwrite->timer = timeout; /* WQE word 4 contains read transfer length */ iwrite->class_pu_byte |= 2 << SLI4_IWR_WQE_PU_SHFT; iwrite->class_pu_byte |= SLI4_GENERIC_CLASS_CLASS_3; iwrite->command = SLI4_WQE_FCP_IWRITE64; iwrite->dif_ct_bs_byte |= SLI4_GENERIC_CONTEXT_RPI << SLI4_IWR_WQE_CT_SHFT; iwrite->dif_ct_bs_byte |= dif; iwrite->dif_ct_bs_byte |= bs << SLI4_IWR_WQE_BS_SHFT; iwrite->abort_tag = cpu_to_le32(xri); iwrite->request_tag = cpu_to_le16(tag); iwrite->len_loc1_byte |= SLI4_IWR_WQE_LEN_LOC_BIT1; iwrite->qosd_xbl_hlm_iod_dbde_wqes |= SLI4_IWR_WQE_LEN_LOC_BIT2; iwrite->cmd_type_byte |= SLI4_CMD_FCP_IWRITE64_WQE; iwrite->cq_id = cpu_to_le16(cq_id); if (sli->params.perf_hint) { bptr = &iwrite->first_data_bde; bptr->bde_type_buflen = cpu_to_le32((SLI4_BDE_TYPE_VAL(64)) | (le32_to_cpu(sge[first_data_sge].buffer_length) & SLI4_BDE_LEN_MASK)); bptr->u.data.low = sge[first_data_sge].buffer_address_low; bptr->u.data.high = sge[first_data_sge].buffer_address_high; } return 0; } int sli_fcp_treceive64_wqe(struct sli4 *sli, void *buf, struct efc_dma *sgl, u32 first_data_sge, u16 cq_id, u8 dif, u8 bs, struct sli_fcp_tgt_params *params) { struct sli4_fcp_treceive64_wqe *trecv = buf; struct sli4_fcp_128byte_wqe *trecv_128 = buf; struct sli4_sge *sge = NULL; struct sli4_bde *bptr; memset(buf, 0, sli->wqe_size); if (!sgl || !sgl->virt) { efc_log_err(sli, "bad parameter sgl=%p virt=%p\n", sgl, sgl ? sgl->virt : NULL); return -EIO; } sge = sgl->virt; bptr = &trecv->bde; if (sli->params.sgl_pre_registered) { trecv->qosd_xbl_hlm_iod_dbde_wqes &= ~SLI4_TRCV_WQE_XBL; trecv->qosd_xbl_hlm_iod_dbde_wqes |= SLI4_TRCV_WQE_DBDE; bptr->bde_type_buflen = cpu_to_le32((SLI4_BDE_TYPE_VAL(64)) | (le32_to_cpu(sge[0].buffer_length) & SLI4_BDE_LEN_MASK)); bptr->u.data.low = sge[0].buffer_address_low; bptr->u.data.high = sge[0].buffer_address_high; trecv->payload_offset_length = sge[0].buffer_length; } else { trecv->qosd_xbl_hlm_iod_dbde_wqes |= SLI4_TRCV_WQE_XBL; /* if data is a single physical address, use a BDE */ if (!dif && params->xmit_len <= le32_to_cpu(sge[2].buffer_length)) { trecv->qosd_xbl_hlm_iod_dbde_wqes |= SLI4_TRCV_WQE_DBDE; bptr->bde_type_buflen = cpu_to_le32((SLI4_BDE_TYPE_VAL(64)) | (le32_to_cpu(sge[2].buffer_length) & SLI4_BDE_LEN_MASK)); bptr->u.data.low = sge[2].buffer_address_low; bptr->u.data.high = sge[2].buffer_address_high; } else { bptr->bde_type_buflen = cpu_to_le32((SLI4_BDE_TYPE_VAL(BLP)) | (sgl->size & SLI4_BDE_LEN_MASK)); bptr->u.blp.low = cpu_to_le32(lower_32_bits(sgl->phys)); bptr->u.blp.high = cpu_to_le32(upper_32_bits(sgl->phys)); } } trecv->relative_offset = cpu_to_le32(params->offset); if (params->flags & SLI4_IO_CONTINUATION) trecv->eat_xc_ccpe |= SLI4_TRCV_WQE_XC; trecv->xri_tag = cpu_to_le16(params->xri); trecv->context_tag = cpu_to_le16(params->rpi); /* WQE uses relative offset */ trecv->class_ar_pu_byte |= 1 << SLI4_TRCV_WQE_PU_SHFT; if (params->flags & SLI4_IO_AUTO_GOOD_RESPONSE) trecv->class_ar_pu_byte |= SLI4_TRCV_WQE_AR; trecv->command = SLI4_WQE_FCP_TRECEIVE64; trecv->class_ar_pu_byte |= SLI4_GENERIC_CLASS_CLASS_3; trecv->dif_ct_bs_byte |= SLI4_GENERIC_CONTEXT_RPI << SLI4_TRCV_WQE_CT_SHFT; trecv->dif_ct_bs_byte |= bs << SLI4_TRCV_WQE_BS_SHFT; trecv->remote_xid = cpu_to_le16(params->ox_id); trecv->request_tag = cpu_to_le16(params->tag); trecv->qosd_xbl_hlm_iod_dbde_wqes |= SLI4_TRCV_WQE_IOD; trecv->qosd_xbl_hlm_iod_dbde_wqes |= SLI4_TRCV_WQE_LEN_LOC_BIT2; trecv->cmd_type_byte |= SLI4_CMD_FCP_TRECEIVE64_WQE; trecv->cq_id = cpu_to_le16(cq_id); trecv->fcp_data_receive_length = cpu_to_le32(params->xmit_len); if (sli->params.perf_hint) { bptr = &trecv->first_data_bde; bptr->bde_type_buflen = cpu_to_le32((SLI4_BDE_TYPE_VAL(64)) | (le32_to_cpu(sge[first_data_sge].buffer_length) & SLI4_BDE_LEN_MASK)); bptr->u.data.low = sge[first_data_sge].buffer_address_low; bptr->u.data.high = sge[first_data_sge].buffer_address_high; } /* The upper 7 bits of csctl is the priority */ if (params->cs_ctl & SLI4_MASK_CCP) { trecv->eat_xc_ccpe |= SLI4_TRCV_WQE_CCPE; trecv->ccp = (params->cs_ctl & SLI4_MASK_CCP); } if (params->app_id && sli->wqe_size == SLI4_WQE_EXT_BYTES && !(trecv->eat_xc_ccpe & SLI4_TRSP_WQE_EAT)) { trecv->lloc1_appid |= SLI4_TRCV_WQE_APPID; trecv->qosd_xbl_hlm_iod_dbde_wqes |= SLI4_TRCV_WQE_WQES; trecv_128->dw[31] = params->app_id; } return 0; } int sli_fcp_cont_treceive64_wqe(struct sli4 *sli, void *buf, struct efc_dma *sgl, u32 first_data_sge, u16 sec_xri, u16 cq_id, u8 dif, u8 bs, struct sli_fcp_tgt_params *params) { int rc; rc = sli_fcp_treceive64_wqe(sli, buf, sgl, first_data_sge, cq_id, dif, bs, params); if (!rc) { struct sli4_fcp_treceive64_wqe *trecv = buf; trecv->command = SLI4_WQE_FCP_CONT_TRECEIVE64; trecv->dword5.sec_xri_tag = cpu_to_le16(sec_xri); } return rc; } int sli_fcp_trsp64_wqe(struct sli4 *sli4, void *buf, struct efc_dma *sgl, u16 cq_id, u8 port_owned, struct sli_fcp_tgt_params *params) { struct sli4_fcp_trsp64_wqe *trsp = buf; struct sli4_fcp_128byte_wqe *trsp_128 = buf; memset(buf, 0, sli4->wqe_size); if (params->flags & SLI4_IO_AUTO_GOOD_RESPONSE) { trsp->class_ag_byte |= SLI4_TRSP_WQE_AG; } else { struct sli4_sge *sge = sgl->virt; struct sli4_bde *bptr; if (sli4->params.sgl_pre_registered || port_owned) trsp->qosd_xbl_hlm_dbde_wqes |= SLI4_TRSP_WQE_DBDE; else trsp->qosd_xbl_hlm_dbde_wqes |= SLI4_TRSP_WQE_XBL; bptr = &trsp->bde; bptr->bde_type_buflen = cpu_to_le32((SLI4_BDE_TYPE_VAL(64)) | (le32_to_cpu(sge[0].buffer_length) & SLI4_BDE_LEN_MASK)); bptr->u.data.low = sge[0].buffer_address_low; bptr->u.data.high = sge[0].buffer_address_high; trsp->fcp_response_length = cpu_to_le32(params->xmit_len); } if (params->flags & SLI4_IO_CONTINUATION) trsp->eat_xc_ccpe |= SLI4_TRSP_WQE_XC; trsp->xri_tag = cpu_to_le16(params->xri); trsp->rpi = cpu_to_le16(params->rpi); trsp->command = SLI4_WQE_FCP_TRSP64; trsp->class_ag_byte |= SLI4_GENERIC_CLASS_CLASS_3; trsp->remote_xid = cpu_to_le16(params->ox_id); trsp->request_tag = cpu_to_le16(params->tag); if (params->flags & SLI4_IO_DNRX) trsp->ct_dnrx_byte |= SLI4_TRSP_WQE_DNRX; else trsp->ct_dnrx_byte &= ~SLI4_TRSP_WQE_DNRX; trsp->lloc1_appid |= 0x1; trsp->cq_id = cpu_to_le16(cq_id); trsp->cmd_type_byte = SLI4_CMD_FCP_TRSP64_WQE; /* The upper 7 bits of csctl is the priority */ if (params->cs_ctl & SLI4_MASK_CCP) { trsp->eat_xc_ccpe |= SLI4_TRSP_WQE_CCPE; trsp->ccp = (params->cs_ctl & SLI4_MASK_CCP); } if (params->app_id && sli4->wqe_size == SLI4_WQE_EXT_BYTES && !(trsp->eat_xc_ccpe & SLI4_TRSP_WQE_EAT)) { trsp->lloc1_appid |= SLI4_TRSP_WQE_APPID; trsp->qosd_xbl_hlm_dbde_wqes |= SLI4_TRSP_WQE_WQES; trsp_128->dw[31] = params->app_id; } return 0; } int sli_fcp_tsend64_wqe(struct sli4 *sli4, void *buf, struct efc_dma *sgl, u32 first_data_sge, u16 cq_id, u8 dif, u8 bs, struct sli_fcp_tgt_params *params) { struct sli4_fcp_tsend64_wqe *tsend = buf; struct sli4_fcp_128byte_wqe *tsend_128 = buf; struct sli4_sge *sge = NULL; struct sli4_bde *bptr; memset(buf, 0, sli4->wqe_size); if (!sgl || !sgl->virt) { efc_log_err(sli4, "bad parameter sgl=%p virt=%p\n", sgl, sgl ? sgl->virt : NULL); return -EIO; } sge = sgl->virt; bptr = &tsend->bde; if (sli4->params.sgl_pre_registered) { tsend->ll_qd_xbl_hlm_iod_dbde &= ~SLI4_TSEND_WQE_XBL; tsend->ll_qd_xbl_hlm_iod_dbde |= SLI4_TSEND_WQE_DBDE; bptr->bde_type_buflen = cpu_to_le32((SLI4_BDE_TYPE_VAL(64)) | (le32_to_cpu(sge[2].buffer_length) & SLI4_BDE_LEN_MASK)); /* TSEND64_WQE specifies first two SGE are skipped (3rd is * valid) */ bptr->u.data.low = sge[2].buffer_address_low; bptr->u.data.high = sge[2].buffer_address_high; } else { tsend->ll_qd_xbl_hlm_iod_dbde |= SLI4_TSEND_WQE_XBL; /* if data is a single physical address, use a BDE */ if (!dif && params->xmit_len <= le32_to_cpu(sge[2].buffer_length)) { tsend->ll_qd_xbl_hlm_iod_dbde |= SLI4_TSEND_WQE_DBDE; bptr->bde_type_buflen = cpu_to_le32((SLI4_BDE_TYPE_VAL(64)) | (le32_to_cpu(sge[2].buffer_length) & SLI4_BDE_LEN_MASK)); /* * TSEND64_WQE specifies first two SGE are skipped * (i.e. 3rd is valid) */ bptr->u.data.low = sge[2].buffer_address_low; bptr->u.data.high = sge[2].buffer_address_high; } else { bptr->bde_type_buflen = cpu_to_le32((SLI4_BDE_TYPE_VAL(BLP)) | (sgl->size & SLI4_BDE_LEN_MASK)); bptr->u.blp.low = cpu_to_le32(lower_32_bits(sgl->phys)); bptr->u.blp.high = cpu_to_le32(upper_32_bits(sgl->phys)); } } tsend->relative_offset = cpu_to_le32(params->offset); if (params->flags & SLI4_IO_CONTINUATION) tsend->dw10byte2 |= SLI4_TSEND_XC; tsend->xri_tag = cpu_to_le16(params->xri); tsend->rpi = cpu_to_le16(params->rpi); /* WQE uses relative offset */ tsend->class_pu_ar_byte |= 1 << SLI4_TSEND_WQE_PU_SHFT; if (params->flags & SLI4_IO_AUTO_GOOD_RESPONSE) tsend->class_pu_ar_byte |= SLI4_TSEND_WQE_AR; tsend->command = SLI4_WQE_FCP_TSEND64; tsend->class_pu_ar_byte |= SLI4_GENERIC_CLASS_CLASS_3; tsend->ct_byte |= SLI4_GENERIC_CONTEXT_RPI << SLI4_TSEND_CT_SHFT; tsend->ct_byte |= dif; tsend->ct_byte |= bs << SLI4_TSEND_BS_SHFT; tsend->remote_xid = cpu_to_le16(params->ox_id); tsend->request_tag = cpu_to_le16(params->tag); tsend->ll_qd_xbl_hlm_iod_dbde |= SLI4_TSEND_LEN_LOC_BIT2; tsend->cq_id = cpu_to_le16(cq_id); tsend->cmd_type_byte |= SLI4_CMD_FCP_TSEND64_WQE; tsend->fcp_data_transmit_length = cpu_to_le32(params->xmit_len); if (sli4->params.perf_hint) { bptr = &tsend->first_data_bde; bptr->bde_type_buflen = cpu_to_le32((SLI4_BDE_TYPE_VAL(64)) | (le32_to_cpu(sge[first_data_sge].buffer_length) & SLI4_BDE_LEN_MASK)); bptr->u.data.low = sge[first_data_sge].buffer_address_low; bptr->u.data.high = sge[first_data_sge].buffer_address_high; } /* The upper 7 bits of csctl is the priority */ if (params->cs_ctl & SLI4_MASK_CCP) { tsend->dw10byte2 |= SLI4_TSEND_CCPE; tsend->ccp = (params->cs_ctl & SLI4_MASK_CCP); } if (params->app_id && sli4->wqe_size == SLI4_WQE_EXT_BYTES && !(tsend->dw10byte2 & SLI4_TSEND_EAT)) { tsend->dw10byte0 |= SLI4_TSEND_APPID_VALID; tsend->ll_qd_xbl_hlm_iod_dbde |= SLI4_TSEND_WQES; tsend_128->dw[31] = params->app_id; } return 0; } int sli_gen_request64_wqe(struct sli4 *sli4, void *buf, struct efc_dma *sgl, struct sli_ct_params *params) { struct sli4_gen_request64_wqe *gen = buf; struct sli4_sge *sge = NULL; struct sli4_bde *bptr; memset(buf, 0, sli4->wqe_size); if (!sgl || !sgl->virt) { efc_log_err(sli4, "bad parameter sgl=%p virt=%p\n", sgl, sgl ? sgl->virt : NULL); return -EIO; } sge = sgl->virt; bptr = &gen->bde; if (sli4->params.sgl_pre_registered) { gen->dw10flags1 &= ~SLI4_GEN_REQ64_WQE_XBL; gen->dw10flags1 |= SLI4_GEN_REQ64_WQE_DBDE; bptr->bde_type_buflen = cpu_to_le32((SLI4_BDE_TYPE_VAL(64)) | (params->xmit_len & SLI4_BDE_LEN_MASK)); bptr->u.data.low = sge[0].buffer_address_low; bptr->u.data.high = sge[0].buffer_address_high; } else { gen->dw10flags1 |= SLI4_GEN_REQ64_WQE_XBL; bptr->bde_type_buflen = cpu_to_le32((SLI4_BDE_TYPE_VAL(BLP)) | ((2 * sizeof(struct sli4_sge)) & SLI4_BDE_LEN_MASK)); bptr->u.blp.low = cpu_to_le32(lower_32_bits(sgl->phys)); bptr->u.blp.high = cpu_to_le32(upper_32_bits(sgl->phys)); } gen->request_payload_length = cpu_to_le32(params->xmit_len); gen->max_response_payload_length = cpu_to_le32(params->rsp_len); gen->df_ctl = params->df_ctl; gen->type = params->type; gen->r_ctl = params->r_ctl; gen->xri_tag = cpu_to_le16(params->xri); gen->ct_byte = SLI4_GENERIC_CONTEXT_RPI << SLI4_GEN_REQ64_CT_SHFT; gen->context_tag = cpu_to_le16(params->rpi); gen->class_byte = SLI4_GENERIC_CLASS_CLASS_3; gen->command = SLI4_WQE_GEN_REQUEST64; gen->timer = params->timeout; gen->request_tag = cpu_to_le16(params->tag); gen->dw10flags1 |= SLI4_GEN_REQ64_WQE_IOD; gen->dw10flags0 |= SLI4_GEN_REQ64_WQE_QOSD; gen->cmd_type_byte = SLI4_CMD_GEN_REQUEST64_WQE; gen->cq_id = cpu_to_le16(SLI4_CQ_DEFAULT); return 0; } int sli_send_frame_wqe(struct sli4 *sli, void *buf, u8 sof, u8 eof, u32 *hdr, struct efc_dma *payload, u32 req_len, u8 timeout, u16 xri, u16 req_tag) { struct sli4_send_frame_wqe *sf = buf; memset(buf, 0, sli->wqe_size); sf->dw10flags1 |= SLI4_SF_WQE_DBDE; sf->bde.bde_type_buflen = cpu_to_le32(req_len & SLI4_BDE_LEN_MASK); sf->bde.u.data.low = cpu_to_le32(lower_32_bits(payload->phys)); sf->bde.u.data.high = cpu_to_le32(upper_32_bits(payload->phys)); /* Copy FC header */ sf->fc_header_0_1[0] = cpu_to_le32(hdr[0]); sf->fc_header_0_1[1] = cpu_to_le32(hdr[1]); sf->fc_header_2_5[0] = cpu_to_le32(hdr[2]); sf->fc_header_2_5[1] = cpu_to_le32(hdr[3]); sf->fc_header_2_5[2] = cpu_to_le32(hdr[4]); sf->fc_header_2_5[3] = cpu_to_le32(hdr[5]); sf->frame_length = cpu_to_le32(req_len); sf->xri_tag = cpu_to_le16(xri); sf->dw7flags0 &= ~SLI4_SF_PU; sf->context_tag = 0; sf->ct_byte &= ~SLI4_SF_CT; sf->command = SLI4_WQE_SEND_FRAME; sf->dw7flags0 |= SLI4_GENERIC_CLASS_CLASS_3; sf->timer = timeout; sf->request_tag = cpu_to_le16(req_tag); sf->eof = eof; sf->sof = sof; sf->dw10flags1 &= ~SLI4_SF_QOSD; sf->dw10flags0 |= SLI4_SF_LEN_LOC_BIT1; sf->dw10flags2 &= ~SLI4_SF_XC; sf->dw10flags1 |= SLI4_SF_XBL; sf->cmd_type_byte |= SLI4_CMD_SEND_FRAME_WQE; sf->cq_id = cpu_to_le16(0xffff); return 0; } int sli_xmit_bls_rsp64_wqe(struct sli4 *sli, void *buf, struct sli_bls_payload *payload, struct sli_bls_params *params) { struct sli4_xmit_bls_rsp_wqe *bls = buf; u32 dw_ridflags = 0; /* * Callers can either specify RPI or S_ID, but not both */ if (params->rpi_registered && params->s_id != U32_MAX) { efc_log_info(sli, "S_ID specified for attached remote node %d\n", params->rpi); return -EIO; } memset(buf, 0, sli->wqe_size); if (payload->type == SLI4_SLI_BLS_ACC) { bls->payload_word0 = cpu_to_le32((payload->u.acc.seq_id_last << 16) | (payload->u.acc.seq_id_validity << 24)); bls->high_seq_cnt = payload->u.acc.high_seq_cnt; bls->low_seq_cnt = payload->u.acc.low_seq_cnt; } else if (payload->type == SLI4_SLI_BLS_RJT) { bls->payload_word0 = cpu_to_le32(*((u32 *)&payload->u.rjt)); dw_ridflags |= SLI4_BLS_RSP_WQE_AR; } else { efc_log_info(sli, "bad BLS type %#x\n", payload->type); return -EIO; } bls->ox_id = payload->ox_id; bls->rx_id = payload->rx_id; if (params->rpi_registered) { bls->dw8flags0 |= SLI4_GENERIC_CONTEXT_RPI << SLI4_BLS_RSP_WQE_CT_SHFT; bls->context_tag = cpu_to_le16(params->rpi); } else { bls->dw8flags0 |= SLI4_GENERIC_CONTEXT_VPI << SLI4_BLS_RSP_WQE_CT_SHFT; bls->context_tag = cpu_to_le16(params->vpi); if (params->s_id != U32_MAX) bls->local_n_port_id_dword |= cpu_to_le32(params->s_id & 0x00ffffff); else bls->local_n_port_id_dword |= cpu_to_le32(params->s_id & 0x00ffffff); dw_ridflags = (dw_ridflags & ~SLI4_BLS_RSP_RID) | (params->d_id & SLI4_BLS_RSP_RID); bls->temporary_rpi = cpu_to_le16(params->rpi); } bls->xri_tag = cpu_to_le16(params->xri); bls->dw8flags1 |= SLI4_GENERIC_CLASS_CLASS_3; bls->command = SLI4_WQE_XMIT_BLS_RSP; bls->request_tag = cpu_to_le16(params->tag); bls->dw11flags1 |= SLI4_BLS_RSP_WQE_QOSD; bls->remote_id_dword = cpu_to_le32(dw_ridflags); bls->cq_id = cpu_to_le16(SLI4_CQ_DEFAULT); bls->dw12flags0 |= SLI4_CMD_XMIT_BLS_RSP64_WQE; return 0; } int sli_xmit_els_rsp64_wqe(struct sli4 *sli, void *buf, struct efc_dma *rsp, struct sli_els_params *params) { struct sli4_xmit_els_rsp64_wqe *els = buf; memset(buf, 0, sli->wqe_size); if (sli->params.sgl_pre_registered) els->flags2 |= SLI4_ELS_DBDE; else els->flags2 |= SLI4_ELS_XBL; els->els_response_payload.bde_type_buflen = cpu_to_le32((SLI4_BDE_TYPE_VAL(64)) | (params->rsp_len & SLI4_BDE_LEN_MASK)); els->els_response_payload.u.data.low = cpu_to_le32(lower_32_bits(rsp->phys)); els->els_response_payload.u.data.high = cpu_to_le32(upper_32_bits(rsp->phys)); els->els_response_payload_length = cpu_to_le32(params->rsp_len); els->xri_tag = cpu_to_le16(params->xri); els->class_byte |= SLI4_GENERIC_CLASS_CLASS_3; els->command = SLI4_WQE_ELS_RSP64; els->request_tag = cpu_to_le16(params->tag); els->ox_id = cpu_to_le16(params->ox_id); els->flags2 |= SLI4_ELS_QOSD; els->cmd_type_wqec = SLI4_ELS_REQUEST64_CMD_GEN; els->cq_id = cpu_to_le16(SLI4_CQ_DEFAULT); if (params->rpi_registered) { els->ct_byte |= SLI4_GENERIC_CONTEXT_RPI << SLI4_ELS_CT_OFFSET; els->context_tag = cpu_to_le16(params->rpi); return 0; } els->ct_byte |= SLI4_GENERIC_CONTEXT_VPI << SLI4_ELS_CT_OFFSET; els->context_tag = cpu_to_le16(params->vpi); els->rid_dw = cpu_to_le32(params->d_id & SLI4_ELS_RID); els->temporary_rpi = cpu_to_le16(params->rpi); if (params->s_id != U32_MAX) { els->sid_dw |= cpu_to_le32(SLI4_ELS_SP | (params->s_id & SLI4_ELS_SID)); } return 0; } int sli_xmit_sequence64_wqe(struct sli4 *sli4, void *buf, struct efc_dma *payload, struct sli_ct_params *params) { struct sli4_xmit_sequence64_wqe *xmit = buf; memset(buf, 0, sli4->wqe_size); if (!payload || !payload->virt) { efc_log_err(sli4, "bad parameter sgl=%p virt=%p\n", payload, payload ? payload->virt : NULL); return -EIO; } if (sli4->params.sgl_pre_registered) xmit->dw10w0 |= cpu_to_le16(SLI4_SEQ_WQE_DBDE); else xmit->dw10w0 |= cpu_to_le16(SLI4_SEQ_WQE_XBL); xmit->bde.bde_type_buflen = cpu_to_le32((SLI4_BDE_TYPE_VAL(64)) | (params->rsp_len & SLI4_BDE_LEN_MASK)); xmit->bde.u.data.low = cpu_to_le32(lower_32_bits(payload->phys)); xmit->bde.u.data.high = cpu_to_le32(upper_32_bits(payload->phys)); xmit->sequence_payload_len = cpu_to_le32(params->rsp_len); xmit->remote_n_port_id_dword |= cpu_to_le32(params->d_id & 0x00ffffff); xmit->relative_offset = 0; /* sequence initiative - this matches what is seen from * FC switches in response to FCGS commands */ xmit->dw5flags0 &= (~SLI4_SEQ_WQE_SI); xmit->dw5flags0 &= (~SLI4_SEQ_WQE_FT);/* force transmit */ xmit->dw5flags0 &= (~SLI4_SEQ_WQE_XO);/* exchange responder */ xmit->dw5flags0 |= SLI4_SEQ_WQE_LS;/* last in seqence */ xmit->df_ctl = params->df_ctl; xmit->type = params->type; xmit->r_ctl = params->r_ctl; xmit->xri_tag = cpu_to_le16(params->xri); xmit->context_tag = cpu_to_le16(params->rpi); xmit->dw7flags0 &= ~SLI4_SEQ_WQE_DIF; xmit->dw7flags0 |= SLI4_GENERIC_CONTEXT_RPI << SLI4_SEQ_WQE_CT_SHIFT; xmit->dw7flags0 &= ~SLI4_SEQ_WQE_BS; xmit->command = SLI4_WQE_XMIT_SEQUENCE64; xmit->dw7flags1 |= SLI4_GENERIC_CLASS_CLASS_3; xmit->dw7flags1 &= ~SLI4_SEQ_WQE_PU; xmit->timer = params->timeout; xmit->abort_tag = 0; xmit->request_tag = cpu_to_le16(params->tag); xmit->remote_xid = cpu_to_le16(params->ox_id); xmit->dw10w0 |= cpu_to_le16(SLI4_ELS_REQUEST64_DIR_READ << SLI4_SEQ_WQE_IOD_SHIFT); xmit->cmd_type_wqec_byte |= SLI4_CMD_XMIT_SEQUENCE64_WQE; xmit->dw10w0 |= cpu_to_le16(2 << SLI4_SEQ_WQE_LEN_LOC_SHIFT); xmit->cq_id = cpu_to_le16(0xFFFF); return 0; } int sli_requeue_xri_wqe(struct sli4 *sli4, void *buf, u16 xri, u16 tag, u16 cq_id) { struct sli4_requeue_xri_wqe *requeue = buf; memset(buf, 0, sli4->wqe_size); requeue->command = SLI4_WQE_REQUEUE_XRI; requeue->xri_tag = cpu_to_le16(xri); requeue->request_tag = cpu_to_le16(tag); requeue->flags2 |= cpu_to_le16(SLI4_REQU_XRI_WQE_XC); requeue->flags1 |= cpu_to_le16(SLI4_REQU_XRI_WQE_QOSD); requeue->cq_id = cpu_to_le16(cq_id); requeue->cmd_type_wqec_byte = SLI4_CMD_REQUEUE_XRI_WQE; return 0; } int sli_fc_process_link_attention(struct sli4 *sli4, void *acqe) { struct sli4_link_attention *link_attn = acqe; struct sli4_link_event event = { 0 }; efc_log_info(sli4, "link=%d attn_type=%#x top=%#x speed=%#x pfault=%#x\n", link_attn->link_number, link_attn->attn_type, link_attn->topology, link_attn->port_speed, link_attn->port_fault); efc_log_info(sli4, "shared_lnk_status=%#x logl_lnk_speed=%#x evttag=%#x\n", link_attn->shared_link_status, le16_to_cpu(link_attn->logical_link_speed), le32_to_cpu(link_attn->event_tag)); if (!sli4->link) return -EIO; event.medium = SLI4_LINK_MEDIUM_FC; switch (link_attn->attn_type) { case SLI4_LNK_ATTN_TYPE_LINK_UP: event.status = SLI4_LINK_STATUS_UP; break; case SLI4_LNK_ATTN_TYPE_LINK_DOWN: event.status = SLI4_LINK_STATUS_DOWN; break; case SLI4_LNK_ATTN_TYPE_NO_HARD_ALPA: efc_log_info(sli4, "attn_type: no hard alpa\n"); event.status = SLI4_LINK_STATUS_NO_ALPA; break; default: efc_log_info(sli4, "attn_type: unknown\n"); break; } switch (link_attn->event_type) { case SLI4_EVENT_LINK_ATTENTION: break; case SLI4_EVENT_SHARED_LINK_ATTENTION: efc_log_info(sli4, "event_type: FC shared link event\n"); break; default: efc_log_info(sli4, "event_type: unknown\n"); break; } switch (link_attn->topology) { case SLI4_LNK_ATTN_P2P: event.topology = SLI4_LINK_TOPO_NON_FC_AL; break; case SLI4_LNK_ATTN_FC_AL: event.topology = SLI4_LINK_TOPO_FC_AL; break; case SLI4_LNK_ATTN_INTERNAL_LOOPBACK: efc_log_info(sli4, "topology Internal loopback\n"); event.topology = SLI4_LINK_TOPO_LOOPBACK_INTERNAL; break; case SLI4_LNK_ATTN_SERDES_LOOPBACK: efc_log_info(sli4, "topology serdes loopback\n"); event.topology = SLI4_LINK_TOPO_LOOPBACK_EXTERNAL; break; default: efc_log_info(sli4, "topology: unknown\n"); break; } event.speed = link_attn->port_speed * 1000; sli4->link(sli4->link_arg, (void *)&event); return 0; } int sli_fc_cqe_parse(struct sli4 *sli4, struct sli4_queue *cq, u8 *cqe, enum sli4_qentry *etype, u16 *r_id) { u8 code = cqe[SLI4_CQE_CODE_OFFSET]; int rc; switch (code) { case SLI4_CQE_CODE_WORK_REQUEST_COMPLETION: { struct sli4_fc_wcqe *wcqe = (void *)cqe; *etype = SLI4_QENTRY_WQ; *r_id = le16_to_cpu(wcqe->request_tag); rc = wcqe->status; /* Flag errors except for FCP_RSP_FAILURE */ if (rc && rc != SLI4_FC_WCQE_STATUS_FCP_RSP_FAILURE) { efc_log_info(sli4, "WCQE: status=%#x hw_status=%#x tag=%#x\n", wcqe->status, wcqe->hw_status, le16_to_cpu(wcqe->request_tag)); efc_log_info(sli4, "w1=%#x w2=%#x xb=%d\n", le32_to_cpu(wcqe->wqe_specific_1), le32_to_cpu(wcqe->wqe_specific_2), (wcqe->flags & SLI4_WCQE_XB)); efc_log_info(sli4, " %08X %08X %08X %08X\n", ((u32 *)cqe)[0], ((u32 *)cqe)[1], ((u32 *)cqe)[2], ((u32 *)cqe)[3]); } break; } case SLI4_CQE_CODE_RQ_ASYNC: { struct sli4_fc_async_rcqe *rcqe = (void *)cqe; *etype = SLI4_QENTRY_RQ; *r_id = le16_to_cpu(rcqe->fcfi_rq_id_word) & SLI4_RACQE_RQ_ID; rc = rcqe->status; break; } case SLI4_CQE_CODE_RQ_ASYNC_V1: { struct sli4_fc_async_rcqe_v1 *rcqe = (void *)cqe; *etype = SLI4_QENTRY_RQ; *r_id = le16_to_cpu(rcqe->rq_id); rc = rcqe->status; break; } case SLI4_CQE_CODE_OPTIMIZED_WRITE_CMD: { struct sli4_fc_optimized_write_cmd_cqe *optcqe = (void *)cqe; *etype = SLI4_QENTRY_OPT_WRITE_CMD; *r_id = le16_to_cpu(optcqe->rq_id); rc = optcqe->status; break; } case SLI4_CQE_CODE_OPTIMIZED_WRITE_DATA: { struct sli4_fc_optimized_write_data_cqe *dcqe = (void *)cqe; *etype = SLI4_QENTRY_OPT_WRITE_DATA; *r_id = le16_to_cpu(dcqe->xri); rc = dcqe->status; /* Flag errors */ if (rc != SLI4_FC_WCQE_STATUS_SUCCESS) { efc_log_info(sli4, "Optimized DATA CQE: status=%#x\n", dcqe->status); efc_log_info(sli4, "hstat=%#x xri=%#x dpl=%#x w3=%#x xb=%d\n", dcqe->hw_status, le16_to_cpu(dcqe->xri), le32_to_cpu(dcqe->total_data_placed), ((u32 *)cqe)[3], (dcqe->flags & SLI4_OCQE_XB)); } break; } case SLI4_CQE_CODE_RQ_COALESCING: { struct sli4_fc_coalescing_rcqe *rcqe = (void *)cqe; *etype = SLI4_QENTRY_RQ; *r_id = le16_to_cpu(rcqe->rq_id); rc = rcqe->status; break; } case SLI4_CQE_CODE_XRI_ABORTED: { struct sli4_fc_xri_aborted_cqe *xa = (void *)cqe; *etype = SLI4_QENTRY_XABT; *r_id = le16_to_cpu(xa->xri); rc = 0; break; } case SLI4_CQE_CODE_RELEASE_WQE: { struct sli4_fc_wqec *wqec = (void *)cqe; *etype = SLI4_QENTRY_WQ_RELEASE; *r_id = le16_to_cpu(wqec->wq_id); rc = 0; break; } default: efc_log_info(sli4, "CQE completion code %d not handled\n", code); *etype = SLI4_QENTRY_MAX; *r_id = U16_MAX; rc = -EINVAL; } return rc; } u32 sli_fc_response_length(struct sli4 *sli4, u8 *cqe) { struct sli4_fc_wcqe *wcqe = (void *)cqe; return le32_to_cpu(wcqe->wqe_specific_1); } u32 sli_fc_io_length(struct sli4 *sli4, u8 *cqe) { struct sli4_fc_wcqe *wcqe = (void *)cqe; return le32_to_cpu(wcqe->wqe_specific_1); } int sli_fc_els_did(struct sli4 *sli4, u8 *cqe, u32 *d_id) { struct sli4_fc_wcqe *wcqe = (void *)cqe; *d_id = 0; if (wcqe->status) return -EIO; *d_id = le32_to_cpu(wcqe->wqe_specific_2) & 0x00ffffff; return 0; } u32 sli_fc_ext_status(struct sli4 *sli4, u8 *cqe) { struct sli4_fc_wcqe *wcqe = (void *)cqe; u32 mask; switch (wcqe->status) { case SLI4_FC_WCQE_STATUS_FCP_RSP_FAILURE: mask = U32_MAX; break; case SLI4_FC_WCQE_STATUS_LOCAL_REJECT: case SLI4_FC_WCQE_STATUS_CMD_REJECT: mask = 0xff; break; case SLI4_FC_WCQE_STATUS_NPORT_RJT: case SLI4_FC_WCQE_STATUS_FABRIC_RJT: case SLI4_FC_WCQE_STATUS_NPORT_BSY: case SLI4_FC_WCQE_STATUS_FABRIC_BSY: case SLI4_FC_WCQE_STATUS_LS_RJT: mask = U32_MAX; break; case SLI4_FC_WCQE_STATUS_DI_ERROR: mask = U32_MAX; break; default: mask = 0; } return le32_to_cpu(wcqe->wqe_specific_2) & mask; } int sli_fc_rqe_rqid_and_index(struct sli4 *sli4, u8 *cqe, u16 *rq_id, u32 *index) { int rc = -EIO; u8 code = 0; u16 rq_element_index; *rq_id = 0; *index = U32_MAX; code = cqe[SLI4_CQE_CODE_OFFSET]; /* Retrieve the RQ index from the completion */ if (code == SLI4_CQE_CODE_RQ_ASYNC) { struct sli4_fc_async_rcqe *rcqe = (void *)cqe; *rq_id = le16_to_cpu(rcqe->fcfi_rq_id_word) & SLI4_RACQE_RQ_ID; rq_element_index = le16_to_cpu(rcqe->rq_elmt_indx_word) & SLI4_RACQE_RQ_EL_INDX; *index = rq_element_index; if (rcqe->status == SLI4_FC_ASYNC_RQ_SUCCESS) { rc = 0; } else { rc = rcqe->status; efc_log_info(sli4, "status=%02x (%s) rq_id=%d\n", rcqe->status, sli_fc_get_status_string(rcqe->status), le16_to_cpu(rcqe->fcfi_rq_id_word) & SLI4_RACQE_RQ_ID); efc_log_info(sli4, "pdpl=%x sof=%02x eof=%02x hdpl=%x\n", le16_to_cpu(rcqe->data_placement_length), rcqe->sof_byte, rcqe->eof_byte, rcqe->hdpl_byte & SLI4_RACQE_HDPL); } } else if (code == SLI4_CQE_CODE_RQ_ASYNC_V1) { struct sli4_fc_async_rcqe_v1 *rcqe_v1 = (void *)cqe; *rq_id = le16_to_cpu(rcqe_v1->rq_id); rq_element_index = (le16_to_cpu(rcqe_v1->rq_elmt_indx_word) & SLI4_RACQE_RQ_EL_INDX); *index = rq_element_index; if (rcqe_v1->status == SLI4_FC_ASYNC_RQ_SUCCESS) { rc = 0; } else { rc = rcqe_v1->status; efc_log_info(sli4, "status=%02x (%s) rq_id=%d, index=%x\n", rcqe_v1->status, sli_fc_get_status_string(rcqe_v1->status), le16_to_cpu(rcqe_v1->rq_id), rq_element_index); efc_log_info(sli4, "pdpl=%x sof=%02x eof=%02x hdpl=%x\n", le16_to_cpu(rcqe_v1->data_placement_length), rcqe_v1->sof_byte, rcqe_v1->eof_byte, rcqe_v1->hdpl_byte & SLI4_RACQE_HDPL); } } else if (code == SLI4_CQE_CODE_OPTIMIZED_WRITE_CMD) { struct sli4_fc_optimized_write_cmd_cqe *optcqe = (void *)cqe; *rq_id = le16_to_cpu(optcqe->rq_id); *index = le16_to_cpu(optcqe->w1) & SLI4_OCQE_RQ_EL_INDX; if (optcqe->status == SLI4_FC_ASYNC_RQ_SUCCESS) { rc = 0; } else { rc = optcqe->status; efc_log_info(sli4, "stat=%02x (%s) rqid=%d, idx=%x pdpl=%x\n", optcqe->status, sli_fc_get_status_string(optcqe->status), le16_to_cpu(optcqe->rq_id), *index, le16_to_cpu(optcqe->data_placement_length)); efc_log_info(sli4, "hdpl=%x oox=%d agxr=%d xri=0x%x rpi=%x\n", (optcqe->hdpl_vld & SLI4_OCQE_HDPL), (optcqe->flags1 & SLI4_OCQE_OOX), (optcqe->flags1 & SLI4_OCQE_AGXR), optcqe->xri, le16_to_cpu(optcqe->rpi)); } } else if (code == SLI4_CQE_CODE_RQ_COALESCING) { struct sli4_fc_coalescing_rcqe *rcqe = (void *)cqe; rq_element_index = (le16_to_cpu(rcqe->rq_elmt_indx_word) & SLI4_RCQE_RQ_EL_INDX); *rq_id = le16_to_cpu(rcqe->rq_id); if (rcqe->status == SLI4_FC_COALESCE_RQ_SUCCESS) { *index = rq_element_index; rc = 0; } else { *index = U32_MAX; rc = rcqe->status; efc_log_info(sli4, "stat=%02x (%s) rq_id=%d, idx=%x\n", rcqe->status, sli_fc_get_status_string(rcqe->status), le16_to_cpu(rcqe->rq_id), rq_element_index); efc_log_info(sli4, "rq_id=%#x sdpl=%x\n", le16_to_cpu(rcqe->rq_id), le16_to_cpu(rcqe->seq_placement_length)); } } else { struct sli4_fc_async_rcqe *rcqe = (void *)cqe; *index = U32_MAX; rc = rcqe->status; efc_log_info(sli4, "status=%02x rq_id=%d, index=%x pdpl=%x\n", rcqe->status, le16_to_cpu(rcqe->fcfi_rq_id_word) & SLI4_RACQE_RQ_ID, (le16_to_cpu(rcqe->rq_elmt_indx_word) & SLI4_RACQE_RQ_EL_INDX), le16_to_cpu(rcqe->data_placement_length)); efc_log_info(sli4, "sof=%02x eof=%02x hdpl=%x\n", rcqe->sof_byte, rcqe->eof_byte, rcqe->hdpl_byte & SLI4_RACQE_HDPL); } return rc; } static int sli_bmbx_wait(struct sli4 *sli4, u32 msec) { u32 val; unsigned long end; /* Wait for the bootstrap mailbox to report "ready" */ end = jiffies + msecs_to_jiffies(msec); do { val = readl(sli4->reg[0] + SLI4_BMBX_REG); if (val & SLI4_BMBX_RDY) return 0; usleep_range(1000, 2000); } while (time_before(jiffies, end)); return -EIO; } static int sli_bmbx_write(struct sli4 *sli4) { u32 val; /* write buffer location to bootstrap mailbox register */ val = sli_bmbx_write_hi(sli4->bmbx.phys); writel(val, (sli4->reg[0] + SLI4_BMBX_REG)); if (sli_bmbx_wait(sli4, SLI4_BMBX_DELAY_US)) { efc_log_crit(sli4, "BMBX WRITE_HI failed\n"); return -EIO; } val = sli_bmbx_write_lo(sli4->bmbx.phys); writel(val, (sli4->reg[0] + SLI4_BMBX_REG)); /* wait for SLI Port to set ready bit */ return sli_bmbx_wait(sli4, SLI4_BMBX_TIMEOUT_MSEC); } int sli_bmbx_command(struct sli4 *sli4) { void *cqe = (u8 *)sli4->bmbx.virt + SLI4_BMBX_SIZE; if (sli_fw_error_status(sli4) > 0) { efc_log_crit(sli4, "Chip is in an error state -Mailbox command rejected"); efc_log_crit(sli4, " status=%#x error1=%#x error2=%#x\n", sli_reg_read_status(sli4), sli_reg_read_err1(sli4), sli_reg_read_err2(sli4)); return -EIO; } /* Submit a command to the bootstrap mailbox and check the status */ if (sli_bmbx_write(sli4)) { efc_log_crit(sli4, "bmbx write fail phys=%pad reg=%#x\n", &sli4->bmbx.phys, readl(sli4->reg[0] + SLI4_BMBX_REG)); return -EIO; } /* check completion queue entry status */ if (le32_to_cpu(((struct sli4_mcqe *)cqe)->dw3_flags) & SLI4_MCQE_VALID) { return sli_cqe_mq(sli4, cqe); } efc_log_crit(sli4, "invalid or wrong type\n"); return -EIO; } int sli_cmd_config_link(struct sli4 *sli4, void *buf) { struct sli4_cmd_config_link *config_link = buf; memset(buf, 0, SLI4_BMBX_SIZE); config_link->hdr.command = SLI4_MBX_CMD_CONFIG_LINK; /* Port interprets zero in a field as "use default value" */ return 0; } int sli_cmd_down_link(struct sli4 *sli4, void *buf) { struct sli4_mbox_command_header *hdr = buf; memset(buf, 0, SLI4_BMBX_SIZE); hdr->command = SLI4_MBX_CMD_DOWN_LINK; /* Port interprets zero in a field as "use default value" */ return 0; } int sli_cmd_dump_type4(struct sli4 *sli4, void *buf, u16 wki) { struct sli4_cmd_dump4 *cmd = buf; memset(buf, 0, SLI4_BMBX_SIZE); cmd->hdr.command = SLI4_MBX_CMD_DUMP; cmd->type_dword = cpu_to_le32(0x4); cmd->wki_selection = cpu_to_le16(wki); return 0; } int sli_cmd_common_read_transceiver_data(struct sli4 *sli4, void *buf, u32 page_num, struct efc_dma *dma) { struct sli4_rqst_cmn_read_transceiver_data *req = NULL; u32 psize; if (!dma) psize = SLI4_CFG_PYLD_LENGTH(cmn_read_transceiver_data); else psize = dma->size; req = sli_config_cmd_init(sli4, buf, psize, dma); if (!req) return -EIO; sli_cmd_fill_hdr(&req->hdr, SLI4_CMN_READ_TRANS_DATA, SLI4_SUBSYSTEM_COMMON, CMD_V0, SLI4_RQST_PYLD_LEN(cmn_read_transceiver_data)); req->page_number = cpu_to_le32(page_num); req->port = cpu_to_le32(sli4->port_number); return 0; } int sli_cmd_read_link_stats(struct sli4 *sli4, void *buf, u8 req_ext_counters, u8 clear_overflow_flags, u8 clear_all_counters) { struct sli4_cmd_read_link_stats *cmd = buf; u32 flags; memset(buf, 0, SLI4_BMBX_SIZE); cmd->hdr.command = SLI4_MBX_CMD_READ_LNK_STAT; flags = 0; if (req_ext_counters) flags |= SLI4_READ_LNKSTAT_REC; if (clear_all_counters) flags |= SLI4_READ_LNKSTAT_CLRC; if (clear_overflow_flags) flags |= SLI4_READ_LNKSTAT_CLOF; cmd->dw1_flags = cpu_to_le32(flags); return 0; } int sli_cmd_read_status(struct sli4 *sli4, void *buf, u8 clear_counters) { struct sli4_cmd_read_status *cmd = buf; u32 flags = 0; memset(buf, 0, SLI4_BMBX_SIZE); cmd->hdr.command = SLI4_MBX_CMD_READ_STATUS; if (clear_counters) flags |= SLI4_READSTATUS_CLEAR_COUNTERS; else flags &= ~SLI4_READSTATUS_CLEAR_COUNTERS; cmd->dw1_flags = cpu_to_le32(flags); return 0; } int sli_cmd_init_link(struct sli4 *sli4, void *buf, u32 speed, u8 reset_alpa) { struct sli4_cmd_init_link *init_link = buf; u32 flags = 0; memset(buf, 0, SLI4_BMBX_SIZE); init_link->hdr.command = SLI4_MBX_CMD_INIT_LINK; init_link->sel_reset_al_pa_dword = cpu_to_le32(reset_alpa); flags &= ~SLI4_INIT_LINK_F_LOOPBACK; init_link->link_speed_sel_code = cpu_to_le32(speed); switch (speed) { case SLI4_LINK_SPEED_1G: case SLI4_LINK_SPEED_2G: case SLI4_LINK_SPEED_4G: case SLI4_LINK_SPEED_8G: case SLI4_LINK_SPEED_16G: case SLI4_LINK_SPEED_32G: case SLI4_LINK_SPEED_64G: flags |= SLI4_INIT_LINK_F_FIXED_SPEED; break; case SLI4_LINK_SPEED_10G: efc_log_info(sli4, "unsupported FC speed %d\n", speed); init_link->flags0 = cpu_to_le32(flags); return -EIO; } switch (sli4->topology) { case SLI4_READ_CFG_TOPO_FC: /* Attempt P2P but failover to FC-AL */ flags |= SLI4_INIT_LINK_F_FAIL_OVER; flags |= SLI4_INIT_LINK_F_P2P_FAIL_OVER; break; case SLI4_READ_CFG_TOPO_FC_AL: flags |= SLI4_INIT_LINK_F_FCAL_ONLY; if (speed == SLI4_LINK_SPEED_16G || speed == SLI4_LINK_SPEED_32G) { efc_log_info(sli4, "unsupported FC-AL speed %d\n", speed); init_link->flags0 = cpu_to_le32(flags); return -EIO; } break; case SLI4_READ_CFG_TOPO_NON_FC_AL: flags |= SLI4_INIT_LINK_F_P2P_ONLY; break; default: efc_log_info(sli4, "unsupported topology %#x\n", sli4->topology); init_link->flags0 = cpu_to_le32(flags); return -EIO; } flags &= ~SLI4_INIT_LINK_F_UNFAIR; flags &= ~SLI4_INIT_LINK_F_NO_LIRP; flags &= ~SLI4_INIT_LINK_F_LOOP_VALID_CHK; flags &= ~SLI4_INIT_LINK_F_NO_LISA; flags &= ~SLI4_INIT_LINK_F_PICK_HI_ALPA; init_link->flags0 = cpu_to_le32(flags); return 0; } int sli_cmd_init_vfi(struct sli4 *sli4, void *buf, u16 vfi, u16 fcfi, u16 vpi) { struct sli4_cmd_init_vfi *init_vfi = buf; u16 flags = 0; memset(buf, 0, SLI4_BMBX_SIZE); init_vfi->hdr.command = SLI4_MBX_CMD_INIT_VFI; init_vfi->vfi = cpu_to_le16(vfi); init_vfi->fcfi = cpu_to_le16(fcfi); /* * If the VPI is valid, initialize it at the same time as * the VFI */ if (vpi != U16_MAX) { flags |= SLI4_INIT_VFI_FLAG_VP; init_vfi->flags0_word = cpu_to_le16(flags); init_vfi->vpi = cpu_to_le16(vpi); } return 0; } int sli_cmd_init_vpi(struct sli4 *sli4, void *buf, u16 vpi, u16 vfi) { struct sli4_cmd_init_vpi *init_vpi = buf; memset(buf, 0, SLI4_BMBX_SIZE); init_vpi->hdr.command = SLI4_MBX_CMD_INIT_VPI; init_vpi->vpi = cpu_to_le16(vpi); init_vpi->vfi = cpu_to_le16(vfi); return 0; } int sli_cmd_post_xri(struct sli4 *sli4, void *buf, u16 xri_base, u16 xri_count) { struct sli4_cmd_post_xri *post_xri = buf; u16 xri_count_flags = 0; memset(buf, 0, SLI4_BMBX_SIZE); post_xri->hdr.command = SLI4_MBX_CMD_POST_XRI; post_xri->xri_base = cpu_to_le16(xri_base); xri_count_flags = xri_count & SLI4_POST_XRI_COUNT; xri_count_flags |= SLI4_POST_XRI_FLAG_ENX; xri_count_flags |= SLI4_POST_XRI_FLAG_VAL; post_xri->xri_count_flags = cpu_to_le16(xri_count_flags); return 0; } int sli_cmd_release_xri(struct sli4 *sli4, void *buf, u8 num_xri) { struct sli4_cmd_release_xri *release_xri = buf; memset(buf, 0, SLI4_BMBX_SIZE); release_xri->hdr.command = SLI4_MBX_CMD_RELEASE_XRI; release_xri->xri_count_word = cpu_to_le16(num_xri & SLI4_RELEASE_XRI_COUNT); return 0; } static int sli_cmd_read_config(struct sli4 *sli4, void *buf) { struct sli4_cmd_read_config *read_config = buf; memset(buf, 0, SLI4_BMBX_SIZE); read_config->hdr.command = SLI4_MBX_CMD_READ_CONFIG; return 0; } int sli_cmd_read_nvparms(struct sli4 *sli4, void *buf) { struct sli4_cmd_read_nvparms *read_nvparms = buf; memset(buf, 0, SLI4_BMBX_SIZE); read_nvparms->hdr.command = SLI4_MBX_CMD_READ_NVPARMS; return 0; } int sli_cmd_write_nvparms(struct sli4 *sli4, void *buf, u8 *wwpn, u8 *wwnn, u8 hard_alpa, u32 preferred_d_id) { struct sli4_cmd_write_nvparms *write_nvparms = buf; memset(buf, 0, SLI4_BMBX_SIZE); write_nvparms->hdr.command = SLI4_MBX_CMD_WRITE_NVPARMS; memcpy(write_nvparms->wwpn, wwpn, 8); memcpy(write_nvparms->wwnn, wwnn, 8); write_nvparms->hard_alpa_d_id = cpu_to_le32((preferred_d_id << 8) | hard_alpa); return 0; } static int sli_cmd_read_rev(struct sli4 *sli4, void *buf, struct efc_dma *vpd) { struct sli4_cmd_read_rev *read_rev = buf; memset(buf, 0, SLI4_BMBX_SIZE); read_rev->hdr.command = SLI4_MBX_CMD_READ_REV; if (vpd && vpd->size) { read_rev->flags0_word |= cpu_to_le16(SLI4_READ_REV_FLAG_VPD); read_rev->available_length_dword = cpu_to_le32(vpd->size & SLI4_READ_REV_AVAILABLE_LENGTH); read_rev->hostbuf.low = cpu_to_le32(lower_32_bits(vpd->phys)); read_rev->hostbuf.high = cpu_to_le32(upper_32_bits(vpd->phys)); } return 0; } int sli_cmd_read_sparm64(struct sli4 *sli4, void *buf, struct efc_dma *dma, u16 vpi) { struct sli4_cmd_read_sparm64 *read_sparm64 = buf; if (vpi == U16_MAX) { efc_log_err(sli4, "special VPI not supported!!!\n"); return -EIO; } if (!dma || !dma->phys) { efc_log_err(sli4, "bad DMA buffer\n"); return -EIO; } memset(buf, 0, SLI4_BMBX_SIZE); read_sparm64->hdr.command = SLI4_MBX_CMD_READ_SPARM64; read_sparm64->bde_64.bde_type_buflen = cpu_to_le32((SLI4_BDE_TYPE_VAL(64)) | (dma->size & SLI4_BDE_LEN_MASK)); read_sparm64->bde_64.u.data.low = cpu_to_le32(lower_32_bits(dma->phys)); read_sparm64->bde_64.u.data.high = cpu_to_le32(upper_32_bits(dma->phys)); read_sparm64->vpi = cpu_to_le16(vpi); return 0; } int sli_cmd_read_topology(struct sli4 *sli4, void *buf, struct efc_dma *dma) { struct sli4_cmd_read_topology *read_topo = buf; if (!dma || !dma->size) return -EIO; if (dma->size < SLI4_MIN_LOOP_MAP_BYTES) { efc_log_err(sli4, "loop map buffer too small %zx\n", dma->size); return -EIO; } memset(buf, 0, SLI4_BMBX_SIZE); read_topo->hdr.command = SLI4_MBX_CMD_READ_TOPOLOGY; memset(dma->virt, 0, dma->size); read_topo->bde_loop_map.bde_type_buflen = cpu_to_le32((SLI4_BDE_TYPE_VAL(64)) | (dma->size & SLI4_BDE_LEN_MASK)); read_topo->bde_loop_map.u.data.low = cpu_to_le32(lower_32_bits(dma->phys)); read_topo->bde_loop_map.u.data.high = cpu_to_le32(upper_32_bits(dma->phys)); return 0; } int sli_cmd_reg_fcfi(struct sli4 *sli4, void *buf, u16 index, struct sli4_cmd_rq_cfg *rq_cfg) { struct sli4_cmd_reg_fcfi *reg_fcfi = buf; u32 i; memset(buf, 0, SLI4_BMBX_SIZE); reg_fcfi->hdr.command = SLI4_MBX_CMD_REG_FCFI; reg_fcfi->fcf_index = cpu_to_le16(index); for (i = 0; i < SLI4_CMD_REG_FCFI_NUM_RQ_CFG; i++) { switch (i) { case 0: reg_fcfi->rqid0 = rq_cfg[0].rq_id; break; case 1: reg_fcfi->rqid1 = rq_cfg[1].rq_id; break; case 2: reg_fcfi->rqid2 = rq_cfg[2].rq_id; break; case 3: reg_fcfi->rqid3 = rq_cfg[3].rq_id; break; } reg_fcfi->rq_cfg[i].r_ctl_mask = rq_cfg[i].r_ctl_mask; reg_fcfi->rq_cfg[i].r_ctl_match = rq_cfg[i].r_ctl_match; reg_fcfi->rq_cfg[i].type_mask = rq_cfg[i].type_mask; reg_fcfi->rq_cfg[i].type_match = rq_cfg[i].type_match; } return 0; } int sli_cmd_reg_fcfi_mrq(struct sli4 *sli4, void *buf, u8 mode, u16 fcf_index, u8 rq_selection_policy, u8 mrq_bit_mask, u16 num_mrqs, struct sli4_cmd_rq_cfg *rq_cfg) { struct sli4_cmd_reg_fcfi_mrq *reg_fcfi_mrq = buf; u32 i; u32 mrq_flags = 0; memset(buf, 0, SLI4_BMBX_SIZE); reg_fcfi_mrq->hdr.command = SLI4_MBX_CMD_REG_FCFI_MRQ; if (mode == SLI4_CMD_REG_FCFI_SET_FCFI_MODE) { reg_fcfi_mrq->fcf_index = cpu_to_le16(fcf_index); goto done; } reg_fcfi_mrq->dw8_vlan = cpu_to_le32(SLI4_REGFCFI_MRQ_MODE); for (i = 0; i < SLI4_CMD_REG_FCFI_NUM_RQ_CFG; i++) { reg_fcfi_mrq->rq_cfg[i].r_ctl_mask = rq_cfg[i].r_ctl_mask; reg_fcfi_mrq->rq_cfg[i].r_ctl_match = rq_cfg[i].r_ctl_match; reg_fcfi_mrq->rq_cfg[i].type_mask = rq_cfg[i].type_mask; reg_fcfi_mrq->rq_cfg[i].type_match = rq_cfg[i].type_match; switch (i) { case 3: reg_fcfi_mrq->rqid3 = rq_cfg[i].rq_id; break; case 2: reg_fcfi_mrq->rqid2 = rq_cfg[i].rq_id; break; case 1: reg_fcfi_mrq->rqid1 = rq_cfg[i].rq_id; break; case 0: reg_fcfi_mrq->rqid0 = rq_cfg[i].rq_id; break; } } mrq_flags = num_mrqs & SLI4_REGFCFI_MRQ_MASK_NUM_PAIRS; mrq_flags |= (mrq_bit_mask << 8); mrq_flags |= (rq_selection_policy << 12); reg_fcfi_mrq->dw9_mrqflags = cpu_to_le32(mrq_flags); done: return 0; } int sli_cmd_reg_rpi(struct sli4 *sli4, void *buf, u32 rpi, u32 vpi, u32 fc_id, struct efc_dma *dma, u8 update, u8 enable_t10_pi) { struct sli4_cmd_reg_rpi *reg_rpi = buf; u32 rportid_flags = 0; memset(buf, 0, SLI4_BMBX_SIZE); reg_rpi->hdr.command = SLI4_MBX_CMD_REG_RPI; reg_rpi->rpi = cpu_to_le16(rpi); rportid_flags = fc_id & SLI4_REGRPI_REMOTE_N_PORTID; if (update) rportid_flags |= SLI4_REGRPI_UPD; else rportid_flags &= ~SLI4_REGRPI_UPD; if (enable_t10_pi) rportid_flags |= SLI4_REGRPI_ETOW; else rportid_flags &= ~SLI4_REGRPI_ETOW; reg_rpi->dw2_rportid_flags = cpu_to_le32(rportid_flags); reg_rpi->bde_64.bde_type_buflen = cpu_to_le32((SLI4_BDE_TYPE_VAL(64)) | (SLI4_REG_RPI_BUF_LEN & SLI4_BDE_LEN_MASK)); reg_rpi->bde_64.u.data.low = cpu_to_le32(lower_32_bits(dma->phys)); reg_rpi->bde_64.u.data.high = cpu_to_le32(upper_32_bits(dma->phys)); reg_rpi->vpi = cpu_to_le16(vpi); return 0; } int sli_cmd_reg_vfi(struct sli4 *sli4, void *buf, size_t size, u16 vfi, u16 fcfi, struct efc_dma dma, u16 vpi, __be64 sli_wwpn, u32 fc_id) { struct sli4_cmd_reg_vfi *reg_vfi = buf; memset(buf, 0, SLI4_BMBX_SIZE); reg_vfi->hdr.command = SLI4_MBX_CMD_REG_VFI; reg_vfi->vfi = cpu_to_le16(vfi); reg_vfi->fcfi = cpu_to_le16(fcfi); reg_vfi->sparm.bde_type_buflen = cpu_to_le32((SLI4_BDE_TYPE_VAL(64)) | (SLI4_REG_RPI_BUF_LEN & SLI4_BDE_LEN_MASK)); reg_vfi->sparm.u.data.low = cpu_to_le32(lower_32_bits(dma.phys)); reg_vfi->sparm.u.data.high = cpu_to_le32(upper_32_bits(dma.phys)); reg_vfi->e_d_tov = cpu_to_le32(sli4->e_d_tov); reg_vfi->r_a_tov = cpu_to_le32(sli4->r_a_tov); reg_vfi->dw0w1_flags |= cpu_to_le16(SLI4_REGVFI_VP); reg_vfi->vpi = cpu_to_le16(vpi); memcpy(reg_vfi->wwpn, &sli_wwpn, sizeof(reg_vfi->wwpn)); reg_vfi->dw10_lportid_flags = cpu_to_le32(fc_id); return 0; } int sli_cmd_reg_vpi(struct sli4 *sli4, void *buf, u32 fc_id, __be64 sli_wwpn, u16 vpi, u16 vfi, bool update) { struct sli4_cmd_reg_vpi *reg_vpi = buf; u32 flags = 0; memset(buf, 0, SLI4_BMBX_SIZE); reg_vpi->hdr.command = SLI4_MBX_CMD_REG_VPI; flags = (fc_id & SLI4_REGVPI_LOCAL_N_PORTID); if (update) flags |= SLI4_REGVPI_UPD; else flags &= ~SLI4_REGVPI_UPD; reg_vpi->dw2_lportid_flags = cpu_to_le32(flags); memcpy(reg_vpi->wwpn, &sli_wwpn, sizeof(reg_vpi->wwpn)); reg_vpi->vpi = cpu_to_le16(vpi); reg_vpi->vfi = cpu_to_le16(vfi); return 0; } static int sli_cmd_request_features(struct sli4 *sli4, void *buf, u32 features_mask, bool query) { struct sli4_cmd_request_features *req_features = buf; memset(buf, 0, SLI4_BMBX_SIZE); req_features->hdr.command = SLI4_MBX_CMD_RQST_FEATURES; if (query) req_features->dw1_qry = cpu_to_le32(SLI4_REQFEAT_QRY); req_features->cmd = cpu_to_le32(features_mask); return 0; } int sli_cmd_unreg_fcfi(struct sli4 *sli4, void *buf, u16 indicator) { struct sli4_cmd_unreg_fcfi *unreg_fcfi = buf; memset(buf, 0, SLI4_BMBX_SIZE); unreg_fcfi->hdr.command = SLI4_MBX_CMD_UNREG_FCFI; unreg_fcfi->fcfi = cpu_to_le16(indicator); return 0; } int sli_cmd_unreg_rpi(struct sli4 *sli4, void *buf, u16 indicator, enum sli4_resource which, u32 fc_id) { struct sli4_cmd_unreg_rpi *unreg_rpi = buf; u32 flags = 0; memset(buf, 0, SLI4_BMBX_SIZE); unreg_rpi->hdr.command = SLI4_MBX_CMD_UNREG_RPI; switch (which) { case SLI4_RSRC_RPI: flags |= SLI4_UNREG_RPI_II_RPI; if (fc_id == U32_MAX) break; flags |= SLI4_UNREG_RPI_DP; unreg_rpi->dw2_dest_n_portid = cpu_to_le32(fc_id & SLI4_UNREG_RPI_DEST_N_PORTID_MASK); break; case SLI4_RSRC_VPI: flags |= SLI4_UNREG_RPI_II_VPI; break; case SLI4_RSRC_VFI: flags |= SLI4_UNREG_RPI_II_VFI; break; case SLI4_RSRC_FCFI: flags |= SLI4_UNREG_RPI_II_FCFI; break; default: efc_log_info(sli4, "unknown type %#x\n", which); return -EIO; } unreg_rpi->dw1w1_flags = cpu_to_le16(flags); unreg_rpi->index = cpu_to_le16(indicator); return 0; } int sli_cmd_unreg_vfi(struct sli4 *sli4, void *buf, u16 index, u32 which) { struct sli4_cmd_unreg_vfi *unreg_vfi = buf; memset(buf, 0, SLI4_BMBX_SIZE); unreg_vfi->hdr.command = SLI4_MBX_CMD_UNREG_VFI; switch (which) { case SLI4_UNREG_TYPE_DOMAIN: unreg_vfi->index = cpu_to_le16(index); break; case SLI4_UNREG_TYPE_FCF: unreg_vfi->index = cpu_to_le16(index); break; case SLI4_UNREG_TYPE_ALL: unreg_vfi->index = cpu_to_le16(U32_MAX); break; default: return -EIO; } if (which != SLI4_UNREG_TYPE_DOMAIN) unreg_vfi->dw2_flags = cpu_to_le16(SLI4_UNREG_VFI_II_FCFI); return 0; } int sli_cmd_unreg_vpi(struct sli4 *sli4, void *buf, u16 indicator, u32 which) { struct sli4_cmd_unreg_vpi *unreg_vpi = buf; u32 flags = 0; memset(buf, 0, SLI4_BMBX_SIZE); unreg_vpi->hdr.command = SLI4_MBX_CMD_UNREG_VPI; unreg_vpi->index = cpu_to_le16(indicator); switch (which) { case SLI4_UNREG_TYPE_PORT: flags |= SLI4_UNREG_VPI_II_VPI; break; case SLI4_UNREG_TYPE_DOMAIN: flags |= SLI4_UNREG_VPI_II_VFI; break; case SLI4_UNREG_TYPE_FCF: flags |= SLI4_UNREG_VPI_II_FCFI; break; case SLI4_UNREG_TYPE_ALL: /* override indicator */ unreg_vpi->index = cpu_to_le16(U32_MAX); flags |= SLI4_UNREG_VPI_II_FCFI; break; default: return -EIO; } unreg_vpi->dw2w0_flags = cpu_to_le16(flags); return 0; } static int sli_cmd_common_modify_eq_delay(struct sli4 *sli4, void *buf, struct sli4_queue *q, int num_q, u32 shift, u32 delay_mult) { struct sli4_rqst_cmn_modify_eq_delay *req = NULL; int i; req = sli_config_cmd_init(sli4, buf, SLI4_CFG_PYLD_LENGTH(cmn_modify_eq_delay), NULL); if (!req) return -EIO; sli_cmd_fill_hdr(&req->hdr, SLI4_CMN_MODIFY_EQ_DELAY, SLI4_SUBSYSTEM_COMMON, CMD_V0, SLI4_RQST_PYLD_LEN(cmn_modify_eq_delay)); req->num_eq = cpu_to_le32(num_q); for (i = 0; i < num_q; i++) { req->eq_delay_record[i].eq_id = cpu_to_le32(q[i].id); req->eq_delay_record[i].phase = cpu_to_le32(shift); req->eq_delay_record[i].delay_multiplier = cpu_to_le32(delay_mult); } return 0; } void sli4_cmd_lowlevel_set_watchdog(struct sli4 *sli4, void *buf, size_t size, u16 timeout) { struct sli4_rqst_lowlevel_set_watchdog *req = NULL; req = sli_config_cmd_init(sli4, buf, SLI4_CFG_PYLD_LENGTH(lowlevel_set_watchdog), NULL); if (!req) return; sli_cmd_fill_hdr(&req->hdr, SLI4_OPC_LOWLEVEL_SET_WATCHDOG, SLI4_SUBSYSTEM_LOWLEVEL, CMD_V0, SLI4_RQST_PYLD_LEN(lowlevel_set_watchdog)); req->watchdog_timeout = cpu_to_le16(timeout); } static int sli_cmd_common_get_cntl_attributes(struct sli4 *sli4, void *buf, struct efc_dma *dma) { struct sli4_rqst_hdr *hdr = NULL; hdr = sli_config_cmd_init(sli4, buf, SLI4_RQST_CMDSZ(hdr), dma); if (!hdr) return -EIO; hdr->opcode = SLI4_CMN_GET_CNTL_ATTRIBUTES; hdr->subsystem = SLI4_SUBSYSTEM_COMMON; hdr->request_length = cpu_to_le32(dma->size); return 0; } static int sli_cmd_common_get_cntl_addl_attributes(struct sli4 *sli4, void *buf, struct efc_dma *dma) { struct sli4_rqst_hdr *hdr = NULL; hdr = sli_config_cmd_init(sli4, buf, SLI4_RQST_CMDSZ(hdr), dma); if (!hdr) return -EIO; hdr->opcode = SLI4_CMN_GET_CNTL_ADDL_ATTRS; hdr->subsystem = SLI4_SUBSYSTEM_COMMON; hdr->request_length = cpu_to_le32(dma->size); return 0; } int sli_cmd_common_nop(struct sli4 *sli4, void *buf, uint64_t context) { struct sli4_rqst_cmn_nop *nop = NULL; nop = sli_config_cmd_init(sli4, buf, SLI4_CFG_PYLD_LENGTH(cmn_nop), NULL); if (!nop) return -EIO; sli_cmd_fill_hdr(&nop->hdr, SLI4_CMN_NOP, SLI4_SUBSYSTEM_COMMON, CMD_V0, SLI4_RQST_PYLD_LEN(cmn_nop)); memcpy(&nop->context, &context, sizeof(context)); return 0; } int sli_cmd_common_get_resource_extent_info(struct sli4 *sli4, void *buf, u16 rtype) { struct sli4_rqst_cmn_get_resource_extent_info *ext = NULL; ext = sli_config_cmd_init(sli4, buf, SLI4_RQST_CMDSZ(cmn_get_resource_extent_info), NULL); if (!ext) return -EIO; sli_cmd_fill_hdr(&ext->hdr, SLI4_CMN_GET_RSC_EXTENT_INFO, SLI4_SUBSYSTEM_COMMON, CMD_V0, SLI4_RQST_PYLD_LEN(cmn_get_resource_extent_info)); ext->resource_type = cpu_to_le16(rtype); return 0; } int sli_cmd_common_get_sli4_parameters(struct sli4 *sli4, void *buf) { struct sli4_rqst_hdr *hdr = NULL; hdr = sli_config_cmd_init(sli4, buf, SLI4_CFG_PYLD_LENGTH(cmn_get_sli4_params), NULL); if (!hdr) return -EIO; hdr->opcode = SLI4_CMN_GET_SLI4_PARAMS; hdr->subsystem = SLI4_SUBSYSTEM_COMMON; hdr->request_length = SLI4_RQST_PYLD_LEN(cmn_get_sli4_params); return 0; } static int sli_cmd_common_get_port_name(struct sli4 *sli4, void *buf) { struct sli4_rqst_cmn_get_port_name *pname; pname = sli_config_cmd_init(sli4, buf, SLI4_CFG_PYLD_LENGTH(cmn_get_port_name), NULL); if (!pname) return -EIO; sli_cmd_fill_hdr(&pname->hdr, SLI4_CMN_GET_PORT_NAME, SLI4_SUBSYSTEM_COMMON, CMD_V1, SLI4_RQST_PYLD_LEN(cmn_get_port_name)); /* Set the port type value (ethernet=0, FC=1) for V1 commands */ pname->port_type = SLI4_PORT_TYPE_FC; return 0; } int sli_cmd_common_write_object(struct sli4 *sli4, void *buf, u16 noc, u16 eof, u32 desired_write_length, u32 offset, char *obj_name, struct efc_dma *dma) { struct sli4_rqst_cmn_write_object *wr_obj = NULL; struct sli4_bde *bde; u32 dwflags = 0; wr_obj = sli_config_cmd_init(sli4, buf, SLI4_RQST_CMDSZ(cmn_write_object) + sizeof(*bde), NULL); if (!wr_obj) return -EIO; sli_cmd_fill_hdr(&wr_obj->hdr, SLI4_CMN_WRITE_OBJECT, SLI4_SUBSYSTEM_COMMON, CMD_V0, SLI4_RQST_PYLD_LEN_VAR(cmn_write_object, sizeof(*bde))); if (noc) dwflags |= SLI4_RQ_DES_WRITE_LEN_NOC; if (eof) dwflags |= SLI4_RQ_DES_WRITE_LEN_EOF; dwflags |= (desired_write_length & SLI4_RQ_DES_WRITE_LEN); wr_obj->desired_write_len_dword = cpu_to_le32(dwflags); wr_obj->write_offset = cpu_to_le32(offset); strncpy(wr_obj->object_name, obj_name, sizeof(wr_obj->object_name) - 1); wr_obj->host_buffer_descriptor_count = cpu_to_le32(1); bde = (struct sli4_bde *)wr_obj->host_buffer_descriptor; /* Setup to transfer xfer_size bytes to device */ bde->bde_type_buflen = cpu_to_le32((SLI4_BDE_TYPE_VAL(64)) | (desired_write_length & SLI4_BDE_LEN_MASK)); bde->u.data.low = cpu_to_le32(lower_32_bits(dma->phys)); bde->u.data.high = cpu_to_le32(upper_32_bits(dma->phys)); return 0; } int sli_cmd_common_delete_object(struct sli4 *sli4, void *buf, char *obj_name) { struct sli4_rqst_cmn_delete_object *req = NULL; req = sli_config_cmd_init(sli4, buf, SLI4_RQST_CMDSZ(cmn_delete_object), NULL); if (!req) return -EIO; sli_cmd_fill_hdr(&req->hdr, SLI4_CMN_DELETE_OBJECT, SLI4_SUBSYSTEM_COMMON, CMD_V0, SLI4_RQST_PYLD_LEN(cmn_delete_object)); strncpy(req->object_name, obj_name, sizeof(req->object_name) - 1); return 0; } int sli_cmd_common_read_object(struct sli4 *sli4, void *buf, u32 desired_read_len, u32 offset, char *obj_name, struct efc_dma *dma) { struct sli4_rqst_cmn_read_object *rd_obj = NULL; struct sli4_bde *bde; rd_obj = sli_config_cmd_init(sli4, buf, SLI4_RQST_CMDSZ(cmn_read_object) + sizeof(*bde), NULL); if (!rd_obj) return -EIO; sli_cmd_fill_hdr(&rd_obj->hdr, SLI4_CMN_READ_OBJECT, SLI4_SUBSYSTEM_COMMON, CMD_V0, SLI4_RQST_PYLD_LEN_VAR(cmn_read_object, sizeof(*bde))); rd_obj->desired_read_length_dword = cpu_to_le32(desired_read_len & SLI4_REQ_DESIRE_READLEN); rd_obj->read_offset = cpu_to_le32(offset); strncpy(rd_obj->object_name, obj_name, sizeof(rd_obj->object_name) - 1); rd_obj->host_buffer_descriptor_count = cpu_to_le32(1); bde = (struct sli4_bde *)rd_obj->host_buffer_descriptor; /* Setup to transfer xfer_size bytes to device */ bde->bde_type_buflen = cpu_to_le32((SLI4_BDE_TYPE_VAL(64)) | (desired_read_len & SLI4_BDE_LEN_MASK)); if (dma) { bde->u.data.low = cpu_to_le32(lower_32_bits(dma->phys)); bde->u.data.high = cpu_to_le32(upper_32_bits(dma->phys)); } else { bde->u.data.low = 0; bde->u.data.high = 0; } return 0; } int sli_cmd_dmtf_exec_clp_cmd(struct sli4 *sli4, void *buf, struct efc_dma *cmd, struct efc_dma *resp) { struct sli4_rqst_dmtf_exec_clp_cmd *clp_cmd = NULL; clp_cmd = sli_config_cmd_init(sli4, buf, SLI4_RQST_CMDSZ(dmtf_exec_clp_cmd), NULL); if (!clp_cmd) return -EIO; sli_cmd_fill_hdr(&clp_cmd->hdr, DMTF_EXEC_CLP_CMD, SLI4_SUBSYSTEM_DMTF, CMD_V0, SLI4_RQST_PYLD_LEN(dmtf_exec_clp_cmd)); clp_cmd->cmd_buf_length = cpu_to_le32(cmd->size); clp_cmd->cmd_buf_addr_low = cpu_to_le32(lower_32_bits(cmd->phys)); clp_cmd->cmd_buf_addr_high = cpu_to_le32(upper_32_bits(cmd->phys)); clp_cmd->resp_buf_length = cpu_to_le32(resp->size); clp_cmd->resp_buf_addr_low = cpu_to_le32(lower_32_bits(resp->phys)); clp_cmd->resp_buf_addr_high = cpu_to_le32(upper_32_bits(resp->phys)); return 0; } int sli_cmd_common_set_dump_location(struct sli4 *sli4, void *buf, bool query, bool is_buffer_list, struct efc_dma *buffer, u8 fdb) { struct sli4_rqst_cmn_set_dump_location *set_dump_loc = NULL; u32 buffer_length_flag = 0; set_dump_loc = sli_config_cmd_init(sli4, buf, SLI4_RQST_CMDSZ(cmn_set_dump_location), NULL); if (!set_dump_loc) return -EIO; sli_cmd_fill_hdr(&set_dump_loc->hdr, SLI4_CMN_SET_DUMP_LOCATION, SLI4_SUBSYSTEM_COMMON, CMD_V0, SLI4_RQST_PYLD_LEN(cmn_set_dump_location)); if (is_buffer_list) buffer_length_flag |= SLI4_CMN_SET_DUMP_BLP; if (query) buffer_length_flag |= SLI4_CMN_SET_DUMP_QRY; if (fdb) buffer_length_flag |= SLI4_CMN_SET_DUMP_FDB; if (buffer) { set_dump_loc->buf_addr_low = cpu_to_le32(lower_32_bits(buffer->phys)); set_dump_loc->buf_addr_high = cpu_to_le32(upper_32_bits(buffer->phys)); buffer_length_flag |= buffer->len & SLI4_CMN_SET_DUMP_BUFFER_LEN; } else { set_dump_loc->buf_addr_low = 0; set_dump_loc->buf_addr_high = 0; set_dump_loc->buffer_length_dword = 0; } set_dump_loc->buffer_length_dword = cpu_to_le32(buffer_length_flag); return 0; } int sli_cmd_common_set_features(struct sli4 *sli4, void *buf, u32 feature, u32 param_len, void *parameter) { struct sli4_rqst_cmn_set_features *cmd = NULL; cmd = sli_config_cmd_init(sli4, buf, SLI4_RQST_CMDSZ(cmn_set_features), NULL); if (!cmd) return -EIO; sli_cmd_fill_hdr(&cmd->hdr, SLI4_CMN_SET_FEATURES, SLI4_SUBSYSTEM_COMMON, CMD_V0, SLI4_RQST_PYLD_LEN(cmn_set_features)); cmd->feature = cpu_to_le32(feature); cmd->param_len = cpu_to_le32(param_len); memcpy(cmd->params, parameter, param_len); return 0; } int sli_cqe_mq(struct sli4 *sli4, void *buf) { struct sli4_mcqe *mcqe = buf; u32 dwflags = le32_to_cpu(mcqe->dw3_flags); /* * Firmware can split mbx completions into two MCQEs: first with only * the "consumed" bit set and a second with the "complete" bit set. * Thus, ignore MCQE unless "complete" is set. */ if (!(dwflags & SLI4_MCQE_COMPLETED)) return SLI4_MCQE_STATUS_NOT_COMPLETED; if (le16_to_cpu(mcqe->completion_status)) { efc_log_info(sli4, "status(st=%#x ext=%#x con=%d cmp=%d ae=%d val=%d)\n", le16_to_cpu(mcqe->completion_status), le16_to_cpu(mcqe->extended_status), (dwflags & SLI4_MCQE_CONSUMED), (dwflags & SLI4_MCQE_COMPLETED), (dwflags & SLI4_MCQE_AE), (dwflags & SLI4_MCQE_VALID)); } return le16_to_cpu(mcqe->completion_status); } int sli_cqe_async(struct sli4 *sli4, void *buf) { struct sli4_acqe *acqe = buf; int rc = -EIO; if (!buf) { efc_log_err(sli4, "bad parameter sli4=%p buf=%p\n", sli4, buf); return -EIO; } switch (acqe->event_code) { case SLI4_ACQE_EVENT_CODE_LINK_STATE: efc_log_info(sli4, "Unsupported by FC link, evt code:%#x\n", acqe->event_code); break; case SLI4_ACQE_EVENT_CODE_GRP_5: efc_log_info(sli4, "ACQE GRP5\n"); break; case SLI4_ACQE_EVENT_CODE_SLI_PORT_EVENT: efc_log_info(sli4, "ACQE SLI Port, type=0x%x, data1,2=0x%08x,0x%08x\n", acqe->event_type, le32_to_cpu(acqe->event_data[0]), le32_to_cpu(acqe->event_data[1])); break; case SLI4_ACQE_EVENT_CODE_FC_LINK_EVENT: rc = sli_fc_process_link_attention(sli4, buf); break; default: efc_log_info(sli4, "ACQE unknown=%#x\n", acqe->event_code); } return rc; } bool sli_fw_ready(struct sli4 *sli4) { u32 val; /* Determine if the chip FW is in a ready state */ val = sli_reg_read_status(sli4); return (val & SLI4_PORT_STATUS_RDY) ? 1 : 0; } static bool sli_wait_for_fw_ready(struct sli4 *sli4, u32 timeout_ms) { unsigned long end; end = jiffies + msecs_to_jiffies(timeout_ms); do { if (sli_fw_ready(sli4)) return true; usleep_range(1000, 2000); } while (time_before(jiffies, end)); return false; } static bool sli_sliport_reset(struct sli4 *sli4) { bool rc; u32 val; val = SLI4_PORT_CTRL_IP; /* Initialize port, endian */ writel(val, (sli4->reg[0] + SLI4_PORT_CTRL_REG)); rc = sli_wait_for_fw_ready(sli4, SLI4_FW_READY_TIMEOUT_MSEC); if (!rc) efc_log_crit(sli4, "port failed to become ready after initialization\n"); return rc; } static bool sli_fw_init(struct sli4 *sli4) { /* * Is firmware ready for operation? */ if (!sli_wait_for_fw_ready(sli4, SLI4_FW_READY_TIMEOUT_MSEC)) { efc_log_crit(sli4, "FW status is NOT ready\n"); return false; } /* * Reset port to a known state */ return sli_sliport_reset(sli4); } static int sli_request_features(struct sli4 *sli4, u32 *features, bool query) { struct sli4_cmd_request_features *req_features = sli4->bmbx.virt; if (sli_cmd_request_features(sli4, sli4->bmbx.virt, *features, query)) { efc_log_err(sli4, "bad REQUEST_FEATURES write\n"); return -EIO; } if (sli_bmbx_command(sli4)) { efc_log_crit(sli4, "bootstrap mailbox write fail\n"); return -EIO; } if (le16_to_cpu(req_features->hdr.status)) { efc_log_err(sli4, "REQUEST_FEATURES bad status %#x\n", le16_to_cpu(req_features->hdr.status)); return -EIO; } *features = le32_to_cpu(req_features->resp); return 0; } void sli_calc_max_qentries(struct sli4 *sli4) { enum sli4_qtype q; u32 qentries; for (q = SLI4_QTYPE_EQ; q < SLI4_QTYPE_MAX; q++) { sli4->qinfo.max_qentries[q] = sli_convert_mask_to_count(sli4->qinfo.count_method[q], sli4->qinfo.count_mask[q]); } /* single, contiguous DMA allocations will be called for each queue * of size (max_qentries * queue entry size); since these can be large, * check against the OS max DMA allocation size */ for (q = SLI4_QTYPE_EQ; q < SLI4_QTYPE_MAX; q++) { qentries = sli4->qinfo.max_qentries[q]; efc_log_info(sli4, "[%s]: max_qentries from %d to %d\n", SLI4_QNAME[q], sli4->qinfo.max_qentries[q], qentries); sli4->qinfo.max_qentries[q] = qentries; } } static int sli_get_read_config(struct sli4 *sli4) { struct sli4_rsp_read_config *conf = sli4->bmbx.virt; u32 i, total; u32 *base; if (sli_cmd_read_config(sli4, sli4->bmbx.virt)) { efc_log_err(sli4, "bad READ_CONFIG write\n"); return -EIO; } if (sli_bmbx_command(sli4)) { efc_log_crit(sli4, "bootstrap mailbox fail (READ_CONFIG)\n"); return -EIO; } if (le16_to_cpu(conf->hdr.status)) { efc_log_err(sli4, "READ_CONFIG bad status %#x\n", le16_to_cpu(conf->hdr.status)); return -EIO; } sli4->params.has_extents = le32_to_cpu(conf->ext_dword) & SLI4_READ_CFG_RESP_RESOURCE_EXT; if (sli4->params.has_extents) { efc_log_err(sli4, "extents not supported\n"); return -EIO; } base = sli4->ext[0].base; if (!base) { int size = SLI4_RSRC_MAX * sizeof(u32); base = kzalloc(size, GFP_KERNEL); if (!base) return -EIO; } for (i = 0; i < SLI4_RSRC_MAX; i++) { sli4->ext[i].number = 1; sli4->ext[i].n_alloc = 0; sli4->ext[i].base = &base[i]; } sli4->ext[SLI4_RSRC_VFI].base[0] = le16_to_cpu(conf->vfi_base); sli4->ext[SLI4_RSRC_VFI].size = le16_to_cpu(conf->vfi_count); sli4->ext[SLI4_RSRC_VPI].base[0] = le16_to_cpu(conf->vpi_base); sli4->ext[SLI4_RSRC_VPI].size = le16_to_cpu(conf->vpi_count); sli4->ext[SLI4_RSRC_RPI].base[0] = le16_to_cpu(conf->rpi_base); sli4->ext[SLI4_RSRC_RPI].size = le16_to_cpu(conf->rpi_count); sli4->ext[SLI4_RSRC_XRI].base[0] = le16_to_cpu(conf->xri_base); sli4->ext[SLI4_RSRC_XRI].size = le16_to_cpu(conf->xri_count); sli4->ext[SLI4_RSRC_FCFI].base[0] = 0; sli4->ext[SLI4_RSRC_FCFI].size = le16_to_cpu(conf->fcfi_count); for (i = 0; i < SLI4_RSRC_MAX; i++) { total = sli4->ext[i].number * sli4->ext[i].size; sli4->ext[i].use_map = bitmap_zalloc(total, GFP_KERNEL); if (!sli4->ext[i].use_map) { efc_log_err(sli4, "bitmap memory allocation failed %d\n", i); return -EIO; } sli4->ext[i].map_size = total; } sli4->topology = (le32_to_cpu(conf->topology_dword) & SLI4_READ_CFG_RESP_TOPOLOGY) >> 24; switch (sli4->topology) { case SLI4_READ_CFG_TOPO_FC: efc_log_info(sli4, "FC (unknown)\n"); break; case SLI4_READ_CFG_TOPO_NON_FC_AL: efc_log_info(sli4, "FC (direct attach)\n"); break; case SLI4_READ_CFG_TOPO_FC_AL: efc_log_info(sli4, "FC (arbitrated loop)\n"); break; default: efc_log_info(sli4, "bad topology %#x\n", sli4->topology); } sli4->e_d_tov = le16_to_cpu(conf->e_d_tov); sli4->r_a_tov = le16_to_cpu(conf->r_a_tov); sli4->link_module_type = le16_to_cpu(conf->lmt); sli4->qinfo.max_qcount[SLI4_QTYPE_EQ] = le16_to_cpu(conf->eq_count); sli4->qinfo.max_qcount[SLI4_QTYPE_CQ] = le16_to_cpu(conf->cq_count); sli4->qinfo.max_qcount[SLI4_QTYPE_WQ] = le16_to_cpu(conf->wq_count); sli4->qinfo.max_qcount[SLI4_QTYPE_RQ] = le16_to_cpu(conf->rq_count); /* * READ_CONFIG doesn't give the max number of MQ. Applications * will typically want 1, but we may need another at some future * date. Dummy up a "max" MQ count here. */ sli4->qinfo.max_qcount[SLI4_QTYPE_MQ] = SLI4_USER_MQ_COUNT; return 0; } static int sli_get_sli4_parameters(struct sli4 *sli4) { struct sli4_rsp_cmn_get_sli4_params *parms; u32 dw_loopback; u32 dw_eq_pg_cnt; u32 dw_cq_pg_cnt; u32 dw_mq_pg_cnt; u32 dw_wq_pg_cnt; u32 dw_rq_pg_cnt; u32 dw_sgl_pg_cnt; if (sli_cmd_common_get_sli4_parameters(sli4, sli4->bmbx.virt)) return -EIO; parms = (struct sli4_rsp_cmn_get_sli4_params *) (((u8 *)sli4->bmbx.virt) + offsetof(struct sli4_cmd_sli_config, payload.embed)); if (sli_bmbx_command(sli4)) { efc_log_crit(sli4, "bootstrap mailbox write fail\n"); return -EIO; } if (parms->hdr.status) { efc_log_err(sli4, "COMMON_GET_SLI4_PARAMETERS bad status %#x", parms->hdr.status); efc_log_err(sli4, "additional status %#x\n", parms->hdr.additional_status); return -EIO; } dw_loopback = le32_to_cpu(parms->dw16_loopback_scope); dw_eq_pg_cnt = le32_to_cpu(parms->dw6_eq_page_cnt); dw_cq_pg_cnt = le32_to_cpu(parms->dw8_cq_page_cnt); dw_mq_pg_cnt = le32_to_cpu(parms->dw10_mq_page_cnt); dw_wq_pg_cnt = le32_to_cpu(parms->dw12_wq_page_cnt); dw_rq_pg_cnt = le32_to_cpu(parms->dw14_rq_page_cnt); sli4->params.auto_reg = (dw_loopback & SLI4_PARAM_AREG); sli4->params.auto_xfer_rdy = (dw_loopback & SLI4_PARAM_AGXF); sli4->params.hdr_template_req = (dw_loopback & SLI4_PARAM_HDRR); sli4->params.t10_dif_inline_capable = (dw_loopback & SLI4_PARAM_TIMM); sli4->params.t10_dif_separate_capable = (dw_loopback & SLI4_PARAM_TSMM); sli4->params.mq_create_version = GET_Q_CREATE_VERSION(dw_mq_pg_cnt); sli4->params.cq_create_version = GET_Q_CREATE_VERSION(dw_cq_pg_cnt); sli4->rq_min_buf_size = le16_to_cpu(parms->min_rq_buffer_size); sli4->rq_max_buf_size = le32_to_cpu(parms->max_rq_buffer_size); sli4->qinfo.qpage_count[SLI4_QTYPE_EQ] = (dw_eq_pg_cnt & SLI4_PARAM_EQ_PAGE_CNT_MASK); sli4->qinfo.qpage_count[SLI4_QTYPE_CQ] = (dw_cq_pg_cnt & SLI4_PARAM_CQ_PAGE_CNT_MASK); sli4->qinfo.qpage_count[SLI4_QTYPE_MQ] = (dw_mq_pg_cnt & SLI4_PARAM_MQ_PAGE_CNT_MASK); sli4->qinfo.qpage_count[SLI4_QTYPE_WQ] = (dw_wq_pg_cnt & SLI4_PARAM_WQ_PAGE_CNT_MASK); sli4->qinfo.qpage_count[SLI4_QTYPE_RQ] = (dw_rq_pg_cnt & SLI4_PARAM_RQ_PAGE_CNT_MASK); /* save count methods and masks for each queue type */ sli4->qinfo.count_mask[SLI4_QTYPE_EQ] = le16_to_cpu(parms->eqe_count_mask); sli4->qinfo.count_method[SLI4_QTYPE_EQ] = GET_Q_CNT_METHOD(dw_eq_pg_cnt); sli4->qinfo.count_mask[SLI4_QTYPE_CQ] = le16_to_cpu(parms->cqe_count_mask); sli4->qinfo.count_method[SLI4_QTYPE_CQ] = GET_Q_CNT_METHOD(dw_cq_pg_cnt); sli4->qinfo.count_mask[SLI4_QTYPE_MQ] = le16_to_cpu(parms->mqe_count_mask); sli4->qinfo.count_method[SLI4_QTYPE_MQ] = GET_Q_CNT_METHOD(dw_mq_pg_cnt); sli4->qinfo.count_mask[SLI4_QTYPE_WQ] = le16_to_cpu(parms->wqe_count_mask); sli4->qinfo.count_method[SLI4_QTYPE_WQ] = GET_Q_CNT_METHOD(dw_wq_pg_cnt); sli4->qinfo.count_mask[SLI4_QTYPE_RQ] = le16_to_cpu(parms->rqe_count_mask); sli4->qinfo.count_method[SLI4_QTYPE_RQ] = GET_Q_CNT_METHOD(dw_rq_pg_cnt); /* now calculate max queue entries */ sli_calc_max_qentries(sli4); dw_sgl_pg_cnt = le32_to_cpu(parms->dw18_sgl_page_cnt); /* max # of pages */ sli4->max_sgl_pages = (dw_sgl_pg_cnt & SLI4_PARAM_SGL_PAGE_CNT_MASK); /* bit map of available sizes */ sli4->sgl_page_sizes = (dw_sgl_pg_cnt & SLI4_PARAM_SGL_PAGE_SZS_MASK) >> 8; /* ignore HLM here. Use value from REQUEST_FEATURES */ sli4->sge_supported_length = le32_to_cpu(parms->sge_supported_length); sli4->params.sgl_pre_reg_required = (dw_loopback & SLI4_PARAM_SGLR); /* default to using pre-registered SGL's */ sli4->params.sgl_pre_registered = true; sli4->params.perf_hint = dw_loopback & SLI4_PARAM_PHON; sli4->params.perf_wq_id_association = (dw_loopback & SLI4_PARAM_PHWQ); sli4->rq_batch = (le16_to_cpu(parms->dw15w1_rq_db_window) & SLI4_PARAM_RQ_DB_WINDOW_MASK) >> 12; /* Use the highest available WQE size. */ if (((dw_wq_pg_cnt & SLI4_PARAM_WQE_SZS_MASK) >> 8) & SLI4_128BYTE_WQE_SUPPORT) sli4->wqe_size = SLI4_WQE_EXT_BYTES; else sli4->wqe_size = SLI4_WQE_BYTES; return 0; } static int sli_get_ctrl_attributes(struct sli4 *sli4) { struct sli4_rsp_cmn_get_cntl_attributes *attr; struct sli4_rsp_cmn_get_cntl_addl_attributes *add_attr; struct efc_dma data; u32 psize; /* * Issue COMMON_GET_CNTL_ATTRIBUTES to get port_number. Temporarily * uses VPD DMA buffer as the response won't fit in the embedded * buffer. */ memset(sli4->vpd_data.virt, 0, sli4->vpd_data.size); if (sli_cmd_common_get_cntl_attributes(sli4, sli4->bmbx.virt, &sli4->vpd_data)) { efc_log_err(sli4, "bad COMMON_GET_CNTL_ATTRIBUTES write\n"); return -EIO; } attr = sli4->vpd_data.virt; if (sli_bmbx_command(sli4)) { efc_log_crit(sli4, "bootstrap mailbox write fail\n"); return -EIO; } if (attr->hdr.status) { efc_log_err(sli4, "COMMON_GET_CNTL_ATTRIBUTES bad status %#x", attr->hdr.status); efc_log_err(sli4, "additional status %#x\n", attr->hdr.additional_status); return -EIO; } sli4->port_number = attr->port_num_type_flags & SLI4_CNTL_ATTR_PORTNUM; memcpy(sli4->bios_version_string, attr->bios_version_str, sizeof(sli4->bios_version_string)); /* get additional attributes */ psize = sizeof(struct sli4_rsp_cmn_get_cntl_addl_attributes); data.size = psize; data.virt = dma_alloc_coherent(&sli4->pci->dev, data.size, &data.phys, GFP_KERNEL); if (!data.virt) { memset(&data, 0, sizeof(struct efc_dma)); efc_log_err(sli4, "Failed to allocate memory for GET_CNTL_ADDL_ATTR\n"); return -EIO; } if (sli_cmd_common_get_cntl_addl_attributes(sli4, sli4->bmbx.virt, &data)) { efc_log_err(sli4, "bad GET_CNTL_ADDL_ATTR write\n"); dma_free_coherent(&sli4->pci->dev, data.size, data.virt, data.phys); return -EIO; } if (sli_bmbx_command(sli4)) { efc_log_crit(sli4, "mailbox fail (GET_CNTL_ADDL_ATTR)\n"); dma_free_coherent(&sli4->pci->dev, data.size, data.virt, data.phys); return -EIO; } add_attr = data.virt; if (add_attr->hdr.status) { efc_log_err(sli4, "GET_CNTL_ADDL_ATTR bad status %#x\n", add_attr->hdr.status); dma_free_coherent(&sli4->pci->dev, data.size, data.virt, data.phys); return -EIO; } memcpy(sli4->ipl_name, add_attr->ipl_file_name, sizeof(sli4->ipl_name)); efc_log_info(sli4, "IPL:%s\n", (char *)sli4->ipl_name); dma_free_coherent(&sli4->pci->dev, data.size, data.virt, data.phys); memset(&data, 0, sizeof(struct efc_dma)); return 0; } static int sli_get_fw_rev(struct sli4 *sli4) { struct sli4_cmd_read_rev *read_rev = sli4->bmbx.virt; if (sli_cmd_read_rev(sli4, sli4->bmbx.virt, &sli4->vpd_data)) return -EIO; if (sli_bmbx_command(sli4)) { efc_log_crit(sli4, "bootstrap mailbox write fail (READ_REV)\n"); return -EIO; } if (le16_to_cpu(read_rev->hdr.status)) { efc_log_err(sli4, "READ_REV bad status %#x\n", le16_to_cpu(read_rev->hdr.status)); return -EIO; } sli4->fw_rev[0] = le32_to_cpu(read_rev->first_fw_id); memcpy(sli4->fw_name[0], read_rev->first_fw_name, sizeof(sli4->fw_name[0])); sli4->fw_rev[1] = le32_to_cpu(read_rev->second_fw_id); memcpy(sli4->fw_name[1], read_rev->second_fw_name, sizeof(sli4->fw_name[1])); sli4->hw_rev[0] = le32_to_cpu(read_rev->first_hw_rev); sli4->hw_rev[1] = le32_to_cpu(read_rev->second_hw_rev); sli4->hw_rev[2] = le32_to_cpu(read_rev->third_hw_rev); efc_log_info(sli4, "FW1:%s (%08x) / FW2:%s (%08x)\n", read_rev->first_fw_name, le32_to_cpu(read_rev->first_fw_id), read_rev->second_fw_name, le32_to_cpu(read_rev->second_fw_id)); efc_log_info(sli4, "HW1: %08x / HW2: %08x\n", le32_to_cpu(read_rev->first_hw_rev), le32_to_cpu(read_rev->second_hw_rev)); /* Check that all VPD data was returned */ if (le32_to_cpu(read_rev->returned_vpd_length) != le32_to_cpu(read_rev->actual_vpd_length)) { efc_log_info(sli4, "VPD length: avail=%d return=%d actual=%d\n", le32_to_cpu(read_rev->available_length_dword) & SLI4_READ_REV_AVAILABLE_LENGTH, le32_to_cpu(read_rev->returned_vpd_length), le32_to_cpu(read_rev->actual_vpd_length)); } sli4->vpd_length = le32_to_cpu(read_rev->returned_vpd_length); return 0; } static int sli_get_config(struct sli4 *sli4) { struct sli4_rsp_cmn_get_port_name *port_name; struct sli4_cmd_read_nvparms *read_nvparms; /* * Read the device configuration */ if (sli_get_read_config(sli4)) return -EIO; if (sli_get_sli4_parameters(sli4)) return -EIO; if (sli_get_ctrl_attributes(sli4)) return -EIO; if (sli_cmd_common_get_port_name(sli4, sli4->bmbx.virt)) return -EIO; port_name = (struct sli4_rsp_cmn_get_port_name *) (((u8 *)sli4->bmbx.virt) + offsetof(struct sli4_cmd_sli_config, payload.embed)); if (sli_bmbx_command(sli4)) { efc_log_crit(sli4, "bootstrap mailbox fail (GET_PORT_NAME)\n"); return -EIO; } sli4->port_name[0] = port_name->port_name[sli4->port_number]; sli4->port_name[1] = '\0'; if (sli_get_fw_rev(sli4)) return -EIO; if (sli_cmd_read_nvparms(sli4, sli4->bmbx.virt)) { efc_log_err(sli4, "bad READ_NVPARMS write\n"); return -EIO; } if (sli_bmbx_command(sli4)) { efc_log_crit(sli4, "bootstrap mailbox fail (READ_NVPARMS)\n"); return -EIO; } read_nvparms = sli4->bmbx.virt; if (le16_to_cpu(read_nvparms->hdr.status)) { efc_log_err(sli4, "READ_NVPARMS bad status %#x\n", le16_to_cpu(read_nvparms->hdr.status)); return -EIO; } memcpy(sli4->wwpn, read_nvparms->wwpn, sizeof(sli4->wwpn)); memcpy(sli4->wwnn, read_nvparms->wwnn, sizeof(sli4->wwnn)); efc_log_info(sli4, "WWPN %02x:%02x:%02x:%02x:%02x:%02x:%02x:%02x\n", sli4->wwpn[0], sli4->wwpn[1], sli4->wwpn[2], sli4->wwpn[3], sli4->wwpn[4], sli4->wwpn[5], sli4->wwpn[6], sli4->wwpn[7]); efc_log_info(sli4, "WWNN %02x:%02x:%02x:%02x:%02x:%02x:%02x:%02x\n", sli4->wwnn[0], sli4->wwnn[1], sli4->wwnn[2], sli4->wwnn[3], sli4->wwnn[4], sli4->wwnn[5], sli4->wwnn[6], sli4->wwnn[7]); return 0; } int sli_setup(struct sli4 *sli4, void *os, struct pci_dev *pdev, void __iomem *reg[]) { u32 intf = U32_MAX; u32 pci_class_rev = 0; u32 rev_id = 0; u32 family = 0; u32 asic_id = 0; u32 i; struct sli4_asic_entry_t *asic; memset(sli4, 0, sizeof(struct sli4)); sli4->os = os; sli4->pci = pdev; for (i = 0; i < 6; i++) sli4->reg[i] = reg[i]; /* * Read the SLI_INTF register to discover the register layout * and other capability information */ if (pci_read_config_dword(pdev, SLI4_INTF_REG, &intf)) return -EIO; if ((intf & SLI4_INTF_VALID_MASK) != (u32)SLI4_INTF_VALID_VALUE) { efc_log_err(sli4, "SLI_INTF is not valid\n"); return -EIO; } /* driver only support SLI-4 */ if ((intf & SLI4_INTF_REV_MASK) != SLI4_INTF_REV_S4) { efc_log_err(sli4, "Unsupported SLI revision (intf=%#x)\n", intf); return -EIO; } sli4->sli_family = intf & SLI4_INTF_FAMILY_MASK; sli4->if_type = intf & SLI4_INTF_IF_TYPE_MASK; efc_log_info(sli4, "status=%#x error1=%#x error2=%#x\n", sli_reg_read_status(sli4), sli_reg_read_err1(sli4), sli_reg_read_err2(sli4)); /* * set the ASIC type and revision */ if (pci_read_config_dword(pdev, PCI_CLASS_REVISION, &pci_class_rev)) return -EIO; rev_id = pci_class_rev & 0xff; family = sli4->sli_family; if (family == SLI4_FAMILY_CHECK_ASIC_TYPE) { if (!pci_read_config_dword(pdev, SLI4_ASIC_ID_REG, &asic_id)) family = asic_id & SLI4_ASIC_GEN_MASK; } for (i = 0, asic = sli4_asic_table; i < ARRAY_SIZE(sli4_asic_table); i++, asic++) { if (rev_id == asic->rev_id && family == asic->family) { sli4->asic_type = family; sli4->asic_rev = rev_id; break; } } /* Fail if no matching asic type/rev was found */ if (!sli4->asic_type) { efc_log_err(sli4, "no matching asic family/rev found: %02x/%02x\n", family, rev_id); return -EIO; } /* * The bootstrap mailbox is equivalent to a MQ with a single 256 byte * entry, a CQ with a single 16 byte entry, and no event queue. * Alignment must be 16 bytes as the low order address bits in the * address register are also control / status. */ sli4->bmbx.size = SLI4_BMBX_SIZE + sizeof(struct sli4_mcqe); sli4->bmbx.virt = dma_alloc_coherent(&pdev->dev, sli4->bmbx.size, &sli4->bmbx.phys, GFP_KERNEL); if (!sli4->bmbx.virt) { memset(&sli4->bmbx, 0, sizeof(struct efc_dma)); efc_log_err(sli4, "bootstrap mailbox allocation failed\n"); return -EIO; } if (sli4->bmbx.phys & SLI4_BMBX_MASK_LO) { efc_log_err(sli4, "bad alignment for bootstrap mailbox\n"); return -EIO; } efc_log_info(sli4, "bmbx v=%p p=0x%x %08x s=%zd\n", sli4->bmbx.virt, upper_32_bits(sli4->bmbx.phys), lower_32_bits(sli4->bmbx.phys), sli4->bmbx.size); /* 4096 is arbitrary. What should this value actually be? */ sli4->vpd_data.size = 4096; sli4->vpd_data.virt = dma_alloc_coherent(&pdev->dev, sli4->vpd_data.size, &sli4->vpd_data.phys, GFP_KERNEL); if (!sli4->vpd_data.virt) { memset(&sli4->vpd_data, 0, sizeof(struct efc_dma)); /* Note that failure isn't fatal in this specific case */ efc_log_info(sli4, "VPD buffer allocation failed\n"); } if (!sli_fw_init(sli4)) { efc_log_err(sli4, "FW initialization failed\n"); return -EIO; } /* * Set one of fcpi(initiator), fcpt(target), fcpc(combined) to true * in addition to any other desired features */ sli4->features = (SLI4_REQFEAT_IAAB | SLI4_REQFEAT_NPIV | SLI4_REQFEAT_DIF | SLI4_REQFEAT_VF | SLI4_REQFEAT_FCPC | SLI4_REQFEAT_IAAR | SLI4_REQFEAT_HLM | SLI4_REQFEAT_PERFH | SLI4_REQFEAT_RXSEQ | SLI4_REQFEAT_RXRI | SLI4_REQFEAT_MRQP); /* use performance hints if available */ if (sli4->params.perf_hint) sli4->features |= SLI4_REQFEAT_PERFH; if (sli_request_features(sli4, &sli4->features, true)) return -EIO; if (sli_get_config(sli4)) return -EIO; return 0; } int sli_init(struct sli4 *sli4) { if (sli4->params.has_extents) { efc_log_info(sli4, "extend allocation not supported\n"); return -EIO; } sli4->features &= (~SLI4_REQFEAT_HLM); sli4->features &= (~SLI4_REQFEAT_RXSEQ); sli4->features &= (~SLI4_REQFEAT_RXRI); if (sli_request_features(sli4, &sli4->features, false)) return -EIO; return 0; } int sli_reset(struct sli4 *sli4) { u32 i; if (!sli_fw_init(sli4)) { efc_log_crit(sli4, "FW initialization failed\n"); return -EIO; } kfree(sli4->ext[0].base); sli4->ext[0].base = NULL; for (i = 0; i < SLI4_RSRC_MAX; i++) { bitmap_free(sli4->ext[i].use_map); sli4->ext[i].use_map = NULL; sli4->ext[i].base = NULL; } return sli_get_config(sli4); } int sli_fw_reset(struct sli4 *sli4) { /* * Firmware must be ready before issuing the reset. */ if (!sli_wait_for_fw_ready(sli4, SLI4_FW_READY_TIMEOUT_MSEC)) { efc_log_crit(sli4, "FW status is NOT ready\n"); return -EIO; } /* Lancer uses PHYDEV_CONTROL */ writel(SLI4_PHYDEV_CTRL_FRST, (sli4->reg[0] + SLI4_PHYDEV_CTRL_REG)); /* wait for the FW to become ready after the reset */ if (!sli_wait_for_fw_ready(sli4, SLI4_FW_READY_TIMEOUT_MSEC)) { efc_log_crit(sli4, "Failed to be ready after firmware reset\n"); return -EIO; } return 0; } void sli_teardown(struct sli4 *sli4) { u32 i; kfree(sli4->ext[0].base); sli4->ext[0].base = NULL; for (i = 0; i < SLI4_RSRC_MAX; i++) { sli4->ext[i].base = NULL; bitmap_free(sli4->ext[i].use_map); sli4->ext[i].use_map = NULL; } if (!sli_sliport_reset(sli4)) efc_log_err(sli4, "FW deinitialization failed\n"); dma_free_coherent(&sli4->pci->dev, sli4->vpd_data.size, sli4->vpd_data.virt, sli4->vpd_data.phys); memset(&sli4->vpd_data, 0, sizeof(struct efc_dma)); dma_free_coherent(&sli4->pci->dev, sli4->bmbx.size, sli4->bmbx.virt, sli4->bmbx.phys); memset(&sli4->bmbx, 0, sizeof(struct efc_dma)); } int sli_callback(struct sli4 *sli4, enum sli4_callback which, void *func, void *arg) { if (!func) { efc_log_err(sli4, "bad parameter sli4=%p which=%#x func=%p\n", sli4, which, func); return -EIO; } switch (which) { case SLI4_CB_LINK: sli4->link = func; sli4->link_arg = arg; break; default: efc_log_info(sli4, "unknown callback %#x\n", which); return -EIO; } return 0; } int sli_eq_modify_delay(struct sli4 *sli4, struct sli4_queue *eq, u32 num_eq, u32 shift, u32 delay_mult) { sli_cmd_common_modify_eq_delay(sli4, sli4->bmbx.virt, eq, num_eq, shift, delay_mult); if (sli_bmbx_command(sli4)) { efc_log_crit(sli4, "bootstrap mailbox write fail (MODIFY EQ DELAY)\n"); return -EIO; } if (sli_res_sli_config(sli4, sli4->bmbx.virt)) { efc_log_err(sli4, "bad status MODIFY EQ DELAY\n"); return -EIO; } return 0; } int sli_resource_alloc(struct sli4 *sli4, enum sli4_resource rtype, u32 *rid, u32 *index) { int rc = 0; u32 size; u32 ext_idx; u32 item_idx; u32 position; *rid = U32_MAX; *index = U32_MAX; switch (rtype) { case SLI4_RSRC_VFI: case SLI4_RSRC_VPI: case SLI4_RSRC_RPI: case SLI4_RSRC_XRI: position = find_first_zero_bit(sli4->ext[rtype].use_map, sli4->ext[rtype].map_size); if (position >= sli4->ext[rtype].map_size) { efc_log_err(sli4, "out of resource %d (alloc=%d)\n", rtype, sli4->ext[rtype].n_alloc); rc = -EIO; break; } set_bit(position, sli4->ext[rtype].use_map); *index = position; size = sli4->ext[rtype].size; ext_idx = *index / size; item_idx = *index % size; *rid = sli4->ext[rtype].base[ext_idx] + item_idx; sli4->ext[rtype].n_alloc++; break; default: rc = -EIO; } return rc; } int sli_resource_free(struct sli4 *sli4, enum sli4_resource rtype, u32 rid) { int rc = -EIO; u32 x; u32 size, *base; switch (rtype) { case SLI4_RSRC_VFI: case SLI4_RSRC_VPI: case SLI4_RSRC_RPI: case SLI4_RSRC_XRI: /* * Figure out which extent contains the resource ID. I.e. find * the extent such that * extent->base <= resource ID < extent->base + extent->size */ base = sli4->ext[rtype].base; size = sli4->ext[rtype].size; /* * In the case of FW reset, this may be cleared * but the force_free path will still attempt to * free the resource. Prevent a NULL pointer access. */ if (!base) break; for (x = 0; x < sli4->ext[rtype].number; x++) { if ((rid < base[x] || (rid >= (base[x] + size)))) continue; rid -= base[x]; clear_bit((x * size) + rid, sli4->ext[rtype].use_map); rc = 0; break; } break; default: break; } return rc; } int sli_resource_reset(struct sli4 *sli4, enum sli4_resource rtype) { int rc = -EIO; u32 i; switch (rtype) { case SLI4_RSRC_VFI: case SLI4_RSRC_VPI: case SLI4_RSRC_RPI: case SLI4_RSRC_XRI: for (i = 0; i < sli4->ext[rtype].map_size; i++) clear_bit(i, sli4->ext[rtype].use_map); rc = 0; break; default: break; } return rc; } int sli_raise_ue(struct sli4 *sli4, u8 dump) { u32 val = 0; if (dump == SLI4_FUNC_DESC_DUMP) { val = SLI4_PORT_CTRL_FDD | SLI4_PORT_CTRL_IP; writel(val, (sli4->reg[0] + SLI4_PORT_CTRL_REG)); } else { val = SLI4_PHYDEV_CTRL_FRST; if (dump == SLI4_CHIP_LEVEL_DUMP) val |= SLI4_PHYDEV_CTRL_DD; writel(val, (sli4->reg[0] + SLI4_PHYDEV_CTRL_REG)); } return 0; } int sli_dump_is_ready(struct sli4 *sli4) { int rc = SLI4_DUMP_READY_STATUS_NOT_READY; u32 port_val; u32 bmbx_val; /* * Ensure that the port is ready AND the mailbox is * ready before signaling that the dump is ready to go. */ port_val = sli_reg_read_status(sli4); bmbx_val = readl(sli4->reg[0] + SLI4_BMBX_REG); if ((bmbx_val & SLI4_BMBX_RDY) && (port_val & SLI4_PORT_STATUS_RDY)) { if (port_val & SLI4_PORT_STATUS_DIP) rc = SLI4_DUMP_READY_STATUS_DD_PRESENT; else if (port_val & SLI4_PORT_STATUS_FDP) rc = SLI4_DUMP_READY_STATUS_FDB_PRESENT; } return rc; } bool sli_reset_required(struct sli4 *sli4) { u32 val; val = sli_reg_read_status(sli4); return (val & SLI4_PORT_STATUS_RN); } int sli_cmd_post_sgl_pages(struct sli4 *sli4, void *buf, u16 xri, u32 xri_count, struct efc_dma *page0[], struct efc_dma *page1[], struct efc_dma *dma) { struct sli4_rqst_post_sgl_pages *post = NULL; u32 i; __le32 req_len; post = sli_config_cmd_init(sli4, buf, SLI4_CFG_PYLD_LENGTH(post_sgl_pages), dma); if (!post) return -EIO; /* payload size calculation */ /* 4 = xri_start + xri_count */ /* xri_count = # of XRI's registered */ /* sizeof(uint64_t) = physical address size */ /* 2 = # of physical addresses per page set */ req_len = cpu_to_le32(4 + (xri_count * (sizeof(uint64_t) * 2))); sli_cmd_fill_hdr(&post->hdr, SLI4_OPC_POST_SGL_PAGES, SLI4_SUBSYSTEM_FC, CMD_V0, req_len); post->xri_start = cpu_to_le16(xri); post->xri_count = cpu_to_le16(xri_count); for (i = 0; i < xri_count; i++) { post->page_set[i].page0_low = cpu_to_le32(lower_32_bits(page0[i]->phys)); post->page_set[i].page0_high = cpu_to_le32(upper_32_bits(page0[i]->phys)); } if (page1) { for (i = 0; i < xri_count; i++) { post->page_set[i].page1_low = cpu_to_le32(lower_32_bits(page1[i]->phys)); post->page_set[i].page1_high = cpu_to_le32(upper_32_bits(page1[i]->phys)); } } return 0; } int sli_cmd_post_hdr_templates(struct sli4 *sli4, void *buf, struct efc_dma *dma, u16 rpi, struct efc_dma *payload_dma) { struct sli4_rqst_post_hdr_templates *req = NULL; uintptr_t phys = 0; u32 i = 0; u32 page_count, payload_size; page_count = sli_page_count(dma->size, SLI_PAGE_SIZE); payload_size = ((sizeof(struct sli4_rqst_post_hdr_templates) + (page_count * SZ_DMAADDR)) - sizeof(struct sli4_rqst_hdr)); if (page_count > 16) { /* * We can't fit more than 16 descriptors into an embedded mbox * command, it has to be non-embedded */ payload_dma->size = payload_size; payload_dma->virt = dma_alloc_coherent(&sli4->pci->dev, payload_dma->size, &payload_dma->phys, GFP_KERNEL); if (!payload_dma->virt) { memset(payload_dma, 0, sizeof(struct efc_dma)); efc_log_err(sli4, "mbox payload memory allocation fail\n"); return -EIO; } req = sli_config_cmd_init(sli4, buf, payload_size, payload_dma); } else { req = sli_config_cmd_init(sli4, buf, payload_size, NULL); } if (!req) return -EIO; if (rpi == U16_MAX) rpi = sli4->ext[SLI4_RSRC_RPI].base[0]; sli_cmd_fill_hdr(&req->hdr, SLI4_OPC_POST_HDR_TEMPLATES, SLI4_SUBSYSTEM_FC, CMD_V0, SLI4_RQST_PYLD_LEN(post_hdr_templates)); req->rpi_offset = cpu_to_le16(rpi); req->page_count = cpu_to_le16(page_count); phys = dma->phys; for (i = 0; i < page_count; i++) { req->page_descriptor[i].low = cpu_to_le32(lower_32_bits(phys)); req->page_descriptor[i].high = cpu_to_le32(upper_32_bits(phys)); phys += SLI_PAGE_SIZE; } return 0; } u32 sli_fc_get_rpi_requirements(struct sli4 *sli4, u32 n_rpi) { u32 bytes = 0; /* Check if header templates needed */ if (sli4->params.hdr_template_req) /* round up to a page */ bytes = round_up(n_rpi * SLI4_HDR_TEMPLATE_SIZE, SLI_PAGE_SIZE); return bytes; } const char * sli_fc_get_status_string(u32 status) { static struct { u32 code; const char *label; } lookup[] = { {SLI4_FC_WCQE_STATUS_SUCCESS, "SUCCESS"}, {SLI4_FC_WCQE_STATUS_FCP_RSP_FAILURE, "FCP_RSP_FAILURE"}, {SLI4_FC_WCQE_STATUS_REMOTE_STOP, "REMOTE_STOP"}, {SLI4_FC_WCQE_STATUS_LOCAL_REJECT, "LOCAL_REJECT"}, {SLI4_FC_WCQE_STATUS_NPORT_RJT, "NPORT_RJT"}, {SLI4_FC_WCQE_STATUS_FABRIC_RJT, "FABRIC_RJT"}, {SLI4_FC_WCQE_STATUS_NPORT_BSY, "NPORT_BSY"}, {SLI4_FC_WCQE_STATUS_FABRIC_BSY, "FABRIC_BSY"}, {SLI4_FC_WCQE_STATUS_LS_RJT, "LS_RJT"}, {SLI4_FC_WCQE_STATUS_CMD_REJECT, "CMD_REJECT"}, {SLI4_FC_WCQE_STATUS_FCP_TGT_LENCHECK, "FCP_TGT_LENCHECK"}, {SLI4_FC_WCQE_STATUS_RQ_BUF_LEN_EXCEEDED, "BUF_LEN_EXCEEDED"}, {SLI4_FC_WCQE_STATUS_RQ_INSUFF_BUF_NEEDED, "RQ_INSUFF_BUF_NEEDED"}, {SLI4_FC_WCQE_STATUS_RQ_INSUFF_FRM_DISC, "RQ_INSUFF_FRM_DESC"}, {SLI4_FC_WCQE_STATUS_RQ_DMA_FAILURE, "RQ_DMA_FAILURE"}, {SLI4_FC_WCQE_STATUS_FCP_RSP_TRUNCATE, "FCP_RSP_TRUNCATE"}, {SLI4_FC_WCQE_STATUS_DI_ERROR, "DI_ERROR"}, {SLI4_FC_WCQE_STATUS_BA_RJT, "BA_RJT"}, {SLI4_FC_WCQE_STATUS_RQ_INSUFF_XRI_NEEDED, "RQ_INSUFF_XRI_NEEDED"}, {SLI4_FC_WCQE_STATUS_RQ_INSUFF_XRI_DISC, "INSUFF_XRI_DISC"}, {SLI4_FC_WCQE_STATUS_RX_ERROR_DETECT, "RX_ERROR_DETECT"}, {SLI4_FC_WCQE_STATUS_RX_ABORT_REQUEST, "RX_ABORT_REQUEST"}, }; u32 i; for (i = 0; i < ARRAY_SIZE(lookup); i++) { if (status == lookup[i].code) return lookup[i].label; } return "unknown"; }
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