Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
James Smart | 3466 | 98.97% | 1 | 33.33% |
Dmitry Bogdanov | 34 | 0.97% | 1 | 33.33% |
Christoph Hellwig | 2 | 0.06% | 1 | 33.33% |
Total | 3502 | 3 |
// SPDX-License-Identifier: GPL-2.0 /* * Copyright (C) 2021 Broadcom. All Rights Reserved. The term * “Broadcom” refers to Broadcom Inc. and/or its subsidiaries. */ #include "efclib.h" #include "../libefc_sli/sli4.h" #include "efc_cmds.h" #include "efc_sm.h" static void efc_nport_free_resources(struct efc_nport *nport, int evt, void *data) { struct efc *efc = nport->efc; /* Clear the nport attached flag */ nport->attached = false; /* Free the service parameters buffer */ if (nport->dma.virt) { dma_free_coherent(&efc->pci->dev, nport->dma.size, nport->dma.virt, nport->dma.phys); memset(&nport->dma, 0, sizeof(struct efc_dma)); } /* Free the SLI resources */ sli_resource_free(efc->sli, SLI4_RSRC_VPI, nport->indicator); efc_nport_cb(efc, evt, nport); } static int efc_nport_get_mbox_status(struct efc_nport *nport, u8 *mqe, int status) { struct efc *efc = nport->efc; struct sli4_mbox_command_header *hdr = (struct sli4_mbox_command_header *)mqe; if (status || le16_to_cpu(hdr->status)) { efc_log_debug(efc, "bad status vpi=%#x st=%x hdr=%x\n", nport->indicator, status, le16_to_cpu(hdr->status)); return -EIO; } return 0; } static int efc_nport_free_unreg_vpi_cb(struct efc *efc, int status, u8 *mqe, void *arg) { struct efc_nport *nport = arg; int evt = EFC_EVT_NPORT_FREE_OK; int rc; rc = efc_nport_get_mbox_status(nport, mqe, status); if (rc) evt = EFC_EVT_NPORT_FREE_FAIL; efc_nport_free_resources(nport, evt, mqe); return rc; } static void efc_nport_free_unreg_vpi(struct efc_nport *nport) { struct efc *efc = nport->efc; int rc; u8 data[SLI4_BMBX_SIZE]; rc = sli_cmd_unreg_vpi(efc->sli, data, nport->indicator, SLI4_UNREG_TYPE_PORT); if (rc) { efc_log_err(efc, "UNREG_VPI format failure\n"); efc_nport_free_resources(nport, EFC_EVT_NPORT_FREE_FAIL, data); return; } rc = efc->tt.issue_mbox_rqst(efc->base, data, efc_nport_free_unreg_vpi_cb, nport); if (rc) { efc_log_err(efc, "UNREG_VPI command failure\n"); efc_nport_free_resources(nport, EFC_EVT_NPORT_FREE_FAIL, data); } } static void efc_nport_send_evt(struct efc_nport *nport, int evt, void *data) { struct efc *efc = nport->efc; /* Now inform the registered callbacks */ efc_nport_cb(efc, evt, nport); /* Set the nport attached flag */ if (evt == EFC_EVT_NPORT_ATTACH_OK) nport->attached = true; /* If there is a pending free request, then handle it now */ if (nport->free_req_pending) efc_nport_free_unreg_vpi(nport); } static int efc_nport_alloc_init_vpi_cb(struct efc *efc, int status, u8 *mqe, void *arg) { struct efc_nport *nport = arg; if (efc_nport_get_mbox_status(nport, mqe, status)) { efc_nport_free_resources(nport, EFC_EVT_NPORT_ALLOC_FAIL, mqe); return -EIO; } efc_nport_send_evt(nport, EFC_EVT_NPORT_ALLOC_OK, mqe); return 0; } static void efc_nport_alloc_init_vpi(struct efc_nport *nport) { struct efc *efc = nport->efc; u8 data[SLI4_BMBX_SIZE]; int rc; /* If there is a pending free request, then handle it now */ if (nport->free_req_pending) { efc_nport_free_resources(nport, EFC_EVT_NPORT_FREE_OK, data); return; } rc = sli_cmd_init_vpi(efc->sli, data, nport->indicator, nport->domain->indicator); if (rc) { efc_log_err(efc, "INIT_VPI format failure\n"); efc_nport_free_resources(nport, EFC_EVT_NPORT_ALLOC_FAIL, data); return; } rc = efc->tt.issue_mbox_rqst(efc->base, data, efc_nport_alloc_init_vpi_cb, nport); if (rc) { efc_log_err(efc, "INIT_VPI command failure\n"); efc_nport_free_resources(nport, EFC_EVT_NPORT_ALLOC_FAIL, data); } } static int efc_nport_alloc_read_sparm64_cb(struct efc *efc, int status, u8 *mqe, void *arg) { struct efc_nport *nport = arg; u8 *payload = NULL; if (efc_nport_get_mbox_status(nport, mqe, status)) { efc_nport_free_resources(nport, EFC_EVT_NPORT_ALLOC_FAIL, mqe); return -EIO; } payload = nport->dma.virt; memcpy(&nport->sli_wwpn, payload + SLI4_READ_SPARM64_WWPN_OFFSET, sizeof(nport->sli_wwpn)); memcpy(&nport->sli_wwnn, payload + SLI4_READ_SPARM64_WWNN_OFFSET, sizeof(nport->sli_wwnn)); dma_free_coherent(&efc->pci->dev, nport->dma.size, nport->dma.virt, nport->dma.phys); memset(&nport->dma, 0, sizeof(struct efc_dma)); efc_nport_alloc_init_vpi(nport); return 0; } static void efc_nport_alloc_read_sparm64(struct efc *efc, struct efc_nport *nport) { u8 data[SLI4_BMBX_SIZE]; int rc; /* Allocate memory for the service parameters */ nport->dma.size = EFC_SPARAM_DMA_SZ; nport->dma.virt = dma_alloc_coherent(&efc->pci->dev, nport->dma.size, &nport->dma.phys, GFP_KERNEL); if (!nport->dma.virt) { efc_log_err(efc, "Failed to allocate DMA memory\n"); efc_nport_free_resources(nport, EFC_EVT_NPORT_ALLOC_FAIL, data); return; } rc = sli_cmd_read_sparm64(efc->sli, data, &nport->dma, nport->indicator); if (rc) { efc_log_err(efc, "READ_SPARM64 format failure\n"); efc_nport_free_resources(nport, EFC_EVT_NPORT_ALLOC_FAIL, data); return; } rc = efc->tt.issue_mbox_rqst(efc->base, data, efc_nport_alloc_read_sparm64_cb, nport); if (rc) { efc_log_err(efc, "READ_SPARM64 command failure\n"); efc_nport_free_resources(nport, EFC_EVT_NPORT_ALLOC_FAIL, data); } } int efc_cmd_nport_alloc(struct efc *efc, struct efc_nport *nport, struct efc_domain *domain, u8 *wwpn) { u32 index; nport->indicator = U32_MAX; nport->free_req_pending = false; if (wwpn) memcpy(&nport->sli_wwpn, wwpn, sizeof(nport->sli_wwpn)); /* * allocate a VPI object for the port and stores it in the * indicator field of the port object. */ if (sli_resource_alloc(efc->sli, SLI4_RSRC_VPI, &nport->indicator, &index)) { efc_log_err(efc, "VPI allocation failure\n"); return -EIO; } if (domain) { /* * If the WWPN is NULL, fetch the default * WWPN and WWNN before initializing the VPI */ if (!wwpn) efc_nport_alloc_read_sparm64(efc, nport); else efc_nport_alloc_init_vpi(nport); } else if (!wwpn) { /* domain NULL and wwpn non-NULL */ efc_log_err(efc, "need WWN for physical port\n"); sli_resource_free(efc->sli, SLI4_RSRC_VPI, nport->indicator); return -EIO; } return 0; } static int efc_nport_attach_reg_vpi_cb(struct efc *efc, int status, u8 *mqe, void *arg) { struct efc_nport *nport = arg; nport->attaching = false; if (efc_nport_get_mbox_status(nport, mqe, status)) { efc_nport_free_resources(nport, EFC_EVT_NPORT_ATTACH_FAIL, mqe); return -EIO; } efc_nport_send_evt(nport, EFC_EVT_NPORT_ATTACH_OK, mqe); return 0; } int efc_cmd_nport_attach(struct efc *efc, struct efc_nport *nport, u32 fc_id) { u8 buf[SLI4_BMBX_SIZE]; int rc = 0; if (!nport) { efc_log_err(efc, "bad param(s) nport=%p\n", nport); return -EIO; } nport->fc_id = fc_id; /* register previously-allocated VPI with the device */ rc = sli_cmd_reg_vpi(efc->sli, buf, nport->fc_id, nport->sli_wwpn, nport->indicator, nport->domain->indicator, false); if (rc) { efc_log_err(efc, "REG_VPI format failure\n"); efc_nport_free_resources(nport, EFC_EVT_NPORT_ATTACH_FAIL, buf); return rc; } rc = efc->tt.issue_mbox_rqst(efc->base, buf, efc_nport_attach_reg_vpi_cb, nport); if (rc) { efc_log_err(efc, "REG_VPI command failure\n"); efc_nport_free_resources(nport, EFC_EVT_NPORT_ATTACH_FAIL, buf); } else { nport->attaching = true; } return rc; } int efc_cmd_nport_free(struct efc *efc, struct efc_nport *nport) { if (!nport) { efc_log_err(efc, "bad parameter(s) nport=%p\n", nport); return -EIO; } /* Issue the UNREG_VPI command to free the assigned VPI context */ if (nport->attached) efc_nport_free_unreg_vpi(nport); else if (nport->attaching) nport->free_req_pending = true; else efc_sm_post_event(&nport->sm, EFC_EVT_NPORT_FREE_OK, NULL); return 0; } static int efc_domain_get_mbox_status(struct efc_domain *domain, u8 *mqe, int status) { struct efc *efc = domain->efc; struct sli4_mbox_command_header *hdr = (struct sli4_mbox_command_header *)mqe; if (status || le16_to_cpu(hdr->status)) { efc_log_debug(efc, "bad status vfi=%#x st=%x hdr=%x\n", domain->indicator, status, le16_to_cpu(hdr->status)); return -EIO; } return 0; } static void efc_domain_free_resources(struct efc_domain *domain, int evt, void *data) { struct efc *efc = domain->efc; /* Free the service parameters buffer */ if (domain->dma.virt) { dma_free_coherent(&efc->pci->dev, domain->dma.size, domain->dma.virt, domain->dma.phys); memset(&domain->dma, 0, sizeof(struct efc_dma)); } /* Free the SLI resources */ sli_resource_free(efc->sli, SLI4_RSRC_VFI, domain->indicator); efc_domain_cb(efc, evt, domain); } static void efc_domain_send_nport_evt(struct efc_domain *domain, int port_evt, int domain_evt, void *data) { struct efc *efc = domain->efc; /* Send alloc/attach ok to the physical nport */ efc_nport_send_evt(domain->nport, port_evt, NULL); /* Now inform the registered callbacks */ efc_domain_cb(efc, domain_evt, domain); } static int efc_domain_alloc_read_sparm64_cb(struct efc *efc, int status, u8 *mqe, void *arg) { struct efc_domain *domain = arg; if (efc_domain_get_mbox_status(domain, mqe, status)) { efc_domain_free_resources(domain, EFC_HW_DOMAIN_ALLOC_FAIL, mqe); return -EIO; } efc_domain_send_nport_evt(domain, EFC_EVT_NPORT_ALLOC_OK, EFC_HW_DOMAIN_ALLOC_OK, mqe); return 0; } static void efc_domain_alloc_read_sparm64(struct efc_domain *domain) { struct efc *efc = domain->efc; u8 data[SLI4_BMBX_SIZE]; int rc; rc = sli_cmd_read_sparm64(efc->sli, data, &domain->dma, 0); if (rc) { efc_log_err(efc, "READ_SPARM64 format failure\n"); efc_domain_free_resources(domain, EFC_HW_DOMAIN_ALLOC_FAIL, data); return; } rc = efc->tt.issue_mbox_rqst(efc->base, data, efc_domain_alloc_read_sparm64_cb, domain); if (rc) { efc_log_err(efc, "READ_SPARM64 command failure\n"); efc_domain_free_resources(domain, EFC_HW_DOMAIN_ALLOC_FAIL, data); } } static int efc_domain_alloc_init_vfi_cb(struct efc *efc, int status, u8 *mqe, void *arg) { struct efc_domain *domain = arg; if (efc_domain_get_mbox_status(domain, mqe, status)) { efc_domain_free_resources(domain, EFC_HW_DOMAIN_ALLOC_FAIL, mqe); return -EIO; } efc_domain_alloc_read_sparm64(domain); return 0; } static void efc_domain_alloc_init_vfi(struct efc_domain *domain) { struct efc *efc = domain->efc; struct efc_nport *nport = domain->nport; u8 data[SLI4_BMBX_SIZE]; int rc; /* * For FC, the HW alread registered an FCFI. * Copy FCF information into the domain and jump to INIT_VFI. */ domain->fcf_indicator = efc->fcfi; rc = sli_cmd_init_vfi(efc->sli, data, domain->indicator, domain->fcf_indicator, nport->indicator); if (rc) { efc_log_err(efc, "INIT_VFI format failure\n"); efc_domain_free_resources(domain, EFC_HW_DOMAIN_ALLOC_FAIL, data); return; } efc_log_err(efc, "%s issue mbox\n", __func__); rc = efc->tt.issue_mbox_rqst(efc->base, data, efc_domain_alloc_init_vfi_cb, domain); if (rc) { efc_log_err(efc, "INIT_VFI command failure\n"); efc_domain_free_resources(domain, EFC_HW_DOMAIN_ALLOC_FAIL, data); } } int efc_cmd_domain_alloc(struct efc *efc, struct efc_domain *domain, u32 fcf) { u32 index; if (!domain || !domain->nport) { efc_log_err(efc, "bad parameter(s) domain=%p nport=%p\n", domain, domain ? domain->nport : NULL); return -EIO; } /* allocate memory for the service parameters */ domain->dma.size = EFC_SPARAM_DMA_SZ; domain->dma.virt = dma_alloc_coherent(&efc->pci->dev, domain->dma.size, &domain->dma.phys, GFP_KERNEL); if (!domain->dma.virt) { efc_log_err(efc, "Failed to allocate DMA memory\n"); return -EIO; } domain->fcf = fcf; domain->fcf_indicator = U32_MAX; domain->indicator = U32_MAX; if (sli_resource_alloc(efc->sli, SLI4_RSRC_VFI, &domain->indicator, &index)) { efc_log_err(efc, "VFI allocation failure\n"); dma_free_coherent(&efc->pci->dev, domain->dma.size, domain->dma.virt, domain->dma.phys); memset(&domain->dma, 0, sizeof(struct efc_dma)); return -EIO; } efc_domain_alloc_init_vfi(domain); return 0; } static int efc_domain_attach_reg_vfi_cb(struct efc *efc, int status, u8 *mqe, void *arg) { struct efc_domain *domain = arg; if (efc_domain_get_mbox_status(domain, mqe, status)) { efc_domain_free_resources(domain, EFC_HW_DOMAIN_ATTACH_FAIL, mqe); return -EIO; } efc_domain_send_nport_evt(domain, EFC_EVT_NPORT_ATTACH_OK, EFC_HW_DOMAIN_ATTACH_OK, mqe); return 0; } int efc_cmd_domain_attach(struct efc *efc, struct efc_domain *domain, u32 fc_id) { u8 buf[SLI4_BMBX_SIZE]; int rc = 0; if (!domain) { efc_log_err(efc, "bad param(s) domain=%p\n", domain); return -EIO; } domain->nport->fc_id = fc_id; rc = sli_cmd_reg_vfi(efc->sli, buf, SLI4_BMBX_SIZE, domain->indicator, domain->fcf_indicator, domain->dma, domain->nport->indicator, domain->nport->sli_wwpn, domain->nport->fc_id); if (rc) { efc_log_err(efc, "REG_VFI format failure\n"); goto cleanup; } rc = efc->tt.issue_mbox_rqst(efc->base, buf, efc_domain_attach_reg_vfi_cb, domain); if (rc) { efc_log_err(efc, "REG_VFI command failure\n"); goto cleanup; } return rc; cleanup: efc_domain_free_resources(domain, EFC_HW_DOMAIN_ATTACH_FAIL, buf); return rc; } static int efc_domain_free_unreg_vfi_cb(struct efc *efc, int status, u8 *mqe, void *arg) { struct efc_domain *domain = arg; int evt = EFC_HW_DOMAIN_FREE_OK; int rc; rc = efc_domain_get_mbox_status(domain, mqe, status); if (rc) { evt = EFC_HW_DOMAIN_FREE_FAIL; rc = -EIO; } efc_domain_free_resources(domain, evt, mqe); return rc; } static void efc_domain_free_unreg_vfi(struct efc_domain *domain) { struct efc *efc = domain->efc; int rc; u8 data[SLI4_BMBX_SIZE]; rc = sli_cmd_unreg_vfi(efc->sli, data, domain->indicator, SLI4_UNREG_TYPE_DOMAIN); if (rc) { efc_log_err(efc, "UNREG_VFI format failure\n"); goto cleanup; } rc = efc->tt.issue_mbox_rqst(efc->base, data, efc_domain_free_unreg_vfi_cb, domain); if (rc) { efc_log_err(efc, "UNREG_VFI command failure\n"); goto cleanup; } return; cleanup: efc_domain_free_resources(domain, EFC_HW_DOMAIN_FREE_FAIL, data); } int efc_cmd_domain_free(struct efc *efc, struct efc_domain *domain) { if (!domain) { efc_log_err(efc, "bad parameter(s) domain=%p\n", domain); return -EIO; } efc_domain_free_unreg_vfi(domain); return 0; } int efc_cmd_node_alloc(struct efc *efc, struct efc_remote_node *rnode, u32 fc_addr, struct efc_nport *nport) { /* Check for invalid indicator */ if (rnode->indicator != U32_MAX) { efc_log_err(efc, "RPI allocation failure addr=%#x rpi=%#x\n", fc_addr, rnode->indicator); return -EIO; } /* NULL SLI port indicates an unallocated remote node */ rnode->nport = NULL; if (sli_resource_alloc(efc->sli, SLI4_RSRC_RPI, &rnode->indicator, &rnode->index)) { efc_log_err(efc, "RPI allocation failure addr=%#x\n", fc_addr); return -EIO; } rnode->fc_id = fc_addr; rnode->nport = nport; return 0; } static int efc_cmd_node_attach_cb(struct efc *efc, int status, u8 *mqe, void *arg) { struct efc_remote_node *rnode = arg; struct sli4_mbox_command_header *hdr = (struct sli4_mbox_command_header *)mqe; int evt = 0; if (status || le16_to_cpu(hdr->status)) { efc_log_debug(efc, "bad status cqe=%#x mqe=%#x\n", status, le16_to_cpu(hdr->status)); rnode->attached = false; evt = EFC_EVT_NODE_ATTACH_FAIL; } else { rnode->attached = true; evt = EFC_EVT_NODE_ATTACH_OK; } efc_remote_node_cb(efc, evt, rnode); return 0; } int efc_cmd_node_attach(struct efc *efc, struct efc_remote_node *rnode, struct efc_dma *sparms) { int rc = -EIO; u8 buf[SLI4_BMBX_SIZE]; if (!rnode || !sparms) { efc_log_err(efc, "bad parameter(s) rnode=%p sparms=%p\n", rnode, sparms); return -EIO; } /* * If the attach count is non-zero, this RPI has already been reg'd. * Otherwise, register the RPI */ if (rnode->index == U32_MAX) { efc_log_err(efc, "bad parameter rnode->index invalid\n"); return -EIO; } /* Update a remote node object with the remote port's service params */ if (!sli_cmd_reg_rpi(efc->sli, buf, rnode->indicator, rnode->nport->indicator, rnode->fc_id, sparms, 0, 0)) rc = efc->tt.issue_mbox_rqst(efc->base, buf, efc_cmd_node_attach_cb, rnode); return rc; } int efc_node_free_resources(struct efc *efc, struct efc_remote_node *rnode) { int rc = 0; if (!rnode) { efc_log_err(efc, "bad parameter rnode=%p\n", rnode); return -EIO; } if (rnode->nport) { if (rnode->attached) { efc_log_err(efc, "rnode is still attached\n"); return -EIO; } if (rnode->indicator != U32_MAX) { if (sli_resource_free(efc->sli, SLI4_RSRC_RPI, rnode->indicator)) { efc_log_err(efc, "RPI free fail RPI %d addr=%#x\n", rnode->indicator, rnode->fc_id); rc = -EIO; } else { rnode->indicator = U32_MAX; rnode->index = U32_MAX; } } } return rc; } static int efc_cmd_node_free_cb(struct efc *efc, int status, u8 *mqe, void *arg) { struct efc_remote_node *rnode = arg; struct sli4_mbox_command_header *hdr = (struct sli4_mbox_command_header *)mqe; int evt = EFC_EVT_NODE_FREE_FAIL; int rc = 0; if (status || le16_to_cpu(hdr->status)) { efc_log_debug(efc, "bad status cqe=%#x mqe=%#x\n", status, le16_to_cpu(hdr->status)); /* * In certain cases, a non-zero MQE status is OK (all must be * true): * - node is attached * - status is 0x1400 */ if (!rnode->attached || (le16_to_cpu(hdr->status) != SLI4_MBX_STATUS_RPI_NOT_REG)) rc = -EIO; } if (!rc) { rnode->attached = false; evt = EFC_EVT_NODE_FREE_OK; } efc_remote_node_cb(efc, evt, rnode); return rc; } int efc_cmd_node_detach(struct efc *efc, struct efc_remote_node *rnode) { u8 buf[SLI4_BMBX_SIZE]; int rc = -EIO; if (!rnode) { efc_log_err(efc, "bad parameter rnode=%p\n", rnode); return -EIO; } if (rnode->nport) { if (!rnode->attached) return -EIO; rc = -EIO; if (!sli_cmd_unreg_rpi(efc->sli, buf, rnode->indicator, SLI4_RSRC_RPI, U32_MAX)) rc = efc->tt.issue_mbox_rqst(efc->base, buf, efc_cmd_node_free_cb, rnode); if (rc != 0) { efc_log_err(efc, "UNREG_RPI failed\n"); rc = -EIO; } } return rc; }
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