//#define PCILIB_FILE_IO #define _XOPEN_SOURCE 700 #define _BSD_SOURCE #define _DEFAULT_SOURCE #define _POSIX_C_SOURCE 200809L #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "pcilib.h" #include "pci.h" #include "tools.h" #include "error.h" #include "model.h" #include "plugin.h" #include "bar.h" #include "xml.h" #include "locking.h" static int pcilib_detect_model(pcilib_t *ctx, const char *model) { int i, j; const pcilib_model_description_t *model_info = NULL; const pcilib_board_info_t *board_info = pcilib_get_board_info(ctx); model_info = pcilib_find_plugin_model(ctx, board_info->vendor_id, board_info->device_id, model); if (model_info) { memcpy(&ctx->model_info, model_info, sizeof(pcilib_model_description_t)); memcpy(&ctx->dma, model_info->dma, sizeof(pcilib_dma_description_t)); ctx->model = strdup(model_info->name); } else if (model) { // If not found, check for DMA models for (i = 0; pcilib_dma[i].name; i++) { if (!strcasecmp(model, pcilib_dma[i].name)) break; } if (pcilib_dma[i].api) { model_info = &ctx->model_info; memcpy(&ctx->dma, &pcilib_dma[i], sizeof(pcilib_dma_description_t)); ctx->model_info.dma = &ctx->dma; } } // Precedens of register configuration: DMA/Event Initialization (top), XML, Event Description, DMA Description (least) if (model_info) { const pcilib_dma_description_t *dma = model_info->dma; if (dma) { if (dma->banks) pcilib_add_register_banks(ctx, 0, dma->banks); if (dma->registers) pcilib_add_registers(ctx, 0, dma->registers); if (dma->engines) { for (j = 0; dma->engines[j].addr_bits; j++); memcpy(ctx->engines, dma->engines, j * sizeof(pcilib_dma_engine_description_t)); ctx->num_engines = j; } else ctx->dma.engines = ctx->engines; } if (model_info->protocols) pcilib_add_register_protocols(ctx, 0, model_info->protocols); if (model_info->banks) pcilib_add_register_banks(ctx, 0, model_info->banks); if (model_info->registers) pcilib_add_registers(ctx, 0, model_info->registers); if (model_info->ranges) pcilib_add_register_ranges(ctx, 0, model_info->ranges); } // Load XML registers // Check for all installed models // memcpy(&ctx->model_info, model, sizeof(pcilib_model_description_t)); // how we reconcile the banks from event model and dma description? The banks specified in the DMA description should override corresponding banks of events... if (!model_info) { if ((model)&&(strcasecmp(model, "pci"))/*&&(no xml)*/) return PCILIB_ERROR_NOTFOUND; ctx->model = strdup("pci"); } return 0; } pcilib_t *pcilib_open(const char *device, const char *model) { int err; size_t i; pcilib_t *ctx = malloc(sizeof(pcilib_t)); if (!model) model = getenv("PCILIB_MODEL"); if (ctx) { memset(ctx, 0, sizeof(pcilib_t)); ctx->pci_cfg_space_fd = -1; ctx->handle = open(device, O_RDWR); if (ctx->handle < 0) { pcilib_error("Error opening device (%s)", device); free(ctx); return NULL; } ctx->page_mask = (uintptr_t)-1; if ((model)&&(!strcasecmp(model, "maintenance"))) { ctx->model = strdup("maintenance"); return ctx; } err = pcilib_init_locking(ctx); if (err) { pcilib_error("Error (%i) initializing locking subsystem", err); pcilib_close(ctx); return NULL; } ctx->alloc_reg = PCILIB_DEFAULT_REGISTER_SPACE; ctx->registers = (pcilib_register_description_t *)malloc(PCILIB_DEFAULT_REGISTER_SPACE * sizeof(pcilib_register_description_t)); ctx->register_ctx = (pcilib_register_context_t *)malloc(PCILIB_DEFAULT_REGISTER_SPACE * sizeof(pcilib_register_context_t)); if ((!ctx->registers)||(!ctx->register_ctx)) { pcilib_error("Error allocating memory for register model"); pcilib_close(ctx); return NULL; } memset(ctx->registers, 0, sizeof(pcilib_register_description_t)); memset(ctx->banks, 0, sizeof(pcilib_register_bank_description_t)); memset(ctx->ranges, 0, sizeof(pcilib_register_range_t)); memset(ctx->register_ctx, 0, PCILIB_DEFAULT_REGISTER_SPACE * sizeof(pcilib_register_context_t)); for (i = 0; pcilib_protocols[i].api; i++); memcpy(ctx->protocols, pcilib_protocols, i * sizeof(pcilib_register_protocol_description_t)); ctx->num_protocols = i; err = pcilib_detect_model(ctx, model); if (err) { const pcilib_board_info_t *board_info = pcilib_get_board_info(ctx); if (board_info) pcilib_error("Error (%i) configuring model %s (%x:%x)", err, (model?model:""), board_info->vendor_id, board_info->device_id); else pcilib_error("Error (%i) configuring model %s", err, (model?model:"")); pcilib_close(ctx); return NULL; } if (!ctx->model) ctx->model = strdup(model?model:"pci"); pcilib_init_xml(ctx); ctx->model_info.registers = ctx->registers; ctx->model_info.banks = ctx->banks; ctx->model_info.protocols = ctx->protocols; ctx->model_info.ranges = ctx->ranges; err = pcilib_init_register_banks(ctx); if (err) { pcilib_error("Error (%i) initializing regiser banks\n", err); pcilib_close(ctx); return NULL; } err = pcilib_init_event_engine(ctx); if (err) { pcilib_error("Error (%i) initializing event engine\n", err); pcilib_close(ctx); return NULL; } } return ctx; } const pcilib_board_info_t *pcilib_get_board_info(pcilib_t *ctx) { int ret; if (ctx->page_mask == (uintptr_t)-1) { ret = ioctl( ctx->handle, PCIDRIVER_IOC_PCI_INFO, &ctx->board_info ); if (ret) { pcilib_error("PCIDRIVER_IOC_PCI_INFO ioctl have failed"); return NULL; } ctx->page_mask = pcilib_get_page_mask(); } return &ctx->board_info; } pcilib_context_t *pcilib_get_implementation_context(pcilib_t *ctx) { return ctx->event_ctx; } int pcilib_map_data_space(pcilib_t *ctx, uintptr_t addr) { int err; pcilib_bar_t i; if (!ctx->data_bar_mapped) { const pcilib_board_info_t *board_info = pcilib_get_board_info(ctx); if (!board_info) return PCILIB_ERROR_FAILED; err = pcilib_map_register_space(ctx); if (err) { pcilib_error("Error mapping register space"); return err; } int data_bar = -1; for (i = 0; i < PCILIB_MAX_BARS; i++) { if ((ctx->bar_space[i])||(!board_info->bar_length[i])) continue; if (addr) { if (board_info->bar_start[i] == addr) { data_bar = i; break; } } else { if (data_bar >= 0) { data_bar = -1; break; } data_bar = i; } } if (data_bar < 0) { if (addr) pcilib_error("Unable to find the specified data space (%lx)", addr); else pcilib_error("Unable to find the data space"); return PCILIB_ERROR_NOTFOUND; } ctx->data_bar = data_bar; if (!ctx->bar_space[data_bar]) { char *data_space = pcilib_map_bar(ctx, data_bar); if (data_space) ctx->bar_space[data_bar] = data_space; else { pcilib_error("Unable to map the data space"); return PCILIB_ERROR_FAILED; } } ctx->data_bar_mapped = 0; } return 0; } char *pcilib_resolve_register_address(pcilib_t *ctx, pcilib_bar_t bar, uintptr_t addr) { if (bar == PCILIB_BAR_DETECT) { printf("bar = PCILIB_BAR_DETECT\n"); // First checking the default register bar size_t offset = addr - ctx->board_info.bar_start[ctx->reg_bar]; if ((addr > ctx->board_info.bar_start[ctx->reg_bar])&&(offset < ctx->board_info.bar_length[ctx->reg_bar])) { if (!ctx->bar_space[ctx->reg_bar]) { pcilib_error("The register bar is not mapped"); return NULL; } return ctx->bar_space[ctx->reg_bar] + offset + (ctx->board_info.bar_start[ctx->reg_bar] & ctx->page_mask); } // Otherwise trying to detect bar = pcilib_detect_bar(ctx, addr, 1); if (bar != PCILIB_BAR_INVALID) { printf("bar pas ainvalid\n"); size_t offset = addr - ctx->board_info.bar_start[bar]; if ((offset < ctx->board_info.bar_length[bar])&&(ctx->bar_space[bar])) { if (!ctx->bar_space[bar]) { pcilib_error("The requested bar (%i) is not mapped", bar); return NULL; } return ctx->bar_space[bar] + offset + (ctx->board_info.bar_start[bar] & ctx->page_mask); } } } else { printf("bar internal :%i\n",bar); // printf("bar invalid\n"); if (!ctx->bar_space[bar]) { pcilib_error("The requested bar (%i) is not mapped", bar); return NULL; } if (addr < ctx->board_info.bar_length[bar]) { printf("path1\n"); // printf("apres: %s\n",ctx->bar_space[bar] + addr); return ctx->bar_space[bar] + addr + (ctx->board_info.bar_start[bar] & ctx->page_mask); } if ((addr >= ctx->board_info.bar_start[bar])&&(addr < (ctx->board_info.bar_start[bar] + ctx->board_info.bar_length[ctx->reg_bar]))) { printf("path2\n"); return ctx->bar_space[bar] + (addr - ctx->board_info.bar_start[bar]) + (ctx->board_info.bar_start[bar] & ctx->page_mask); } } return NULL; } char *pcilib_resolve_data_space(pcilib_t *ctx, uintptr_t addr, size_t *size) { int err; err = pcilib_map_data_space(ctx, addr); if (err) { pcilib_error("Failed to map the specified address space (%lx)", addr); return NULL; } if (size) *size = ctx->board_info.bar_length[ctx->data_bar]; return ctx->bar_space[ctx->data_bar] + (ctx->board_info.bar_start[ctx->data_bar] & ctx->page_mask); } void pcilib_close(pcilib_t *ctx) { pcilib_bar_t i; if (ctx) { pcilib_dma_engine_t dma; const pcilib_model_description_t *model_info = pcilib_get_model_description(ctx); const pcilib_event_api_description_t *eapi = model_info->api; const pcilib_dma_api_description_t *dapi = ctx->dma.api; if ((eapi)&&(eapi->free)) eapi->free(ctx->event_ctx); if ((dapi)&&(dapi->free)) dapi->free(ctx->dma_ctx); for (dma = 0; dma < PCILIB_MAX_DMA_ENGINES; dma++) { if (ctx->dma_rlock[dma]) pcilib_return_lock(ctx, PCILIB_LOCK_FLAGS_DEFAULT, ctx->dma_rlock[dma]); if (ctx->dma_wlock[dma]) pcilib_return_lock(ctx, PCILIB_LOCK_FLAGS_DEFAULT, ctx->dma_wlock[dma]); } pcilib_free_register_banks(ctx); if (ctx->register_ctx) free(ctx->register_ctx); if (ctx->event_plugin) pcilib_plugin_close(ctx->event_plugin); if (ctx->locks.kmem) pcilib_free_locking(ctx); if (ctx->kmem_list) { pcilib_warning("Not all kernel buffers are properly cleaned"); while (ctx->kmem_list) { pcilib_free_kernel_memory(ctx, ctx->kmem_list, 0); } } for (i = 0; i < PCILIB_MAX_BARS; i++) { if (ctx->bar_space[i]) { char *ptr = ctx->bar_space[i]; ctx->bar_space[i] = NULL; pcilib_unmap_bar(ctx, i, ptr); } } if (ctx->pci_cfg_space_fd >= 0) close(ctx->pci_cfg_space_fd); if (ctx->registers) free(ctx->registers); if (ctx->model) free(ctx->model); if (ctx->handle >= 0) close(ctx->handle); free(ctx); } } static int pcilib_update_pci_configuration_space(pcilib_t *ctx) { int err; int size; if (ctx->pci_cfg_space_fd < 0) { char fname[128]; const pcilib_board_info_t *board_info = pcilib_get_board_info(ctx); if (!board_info) { pcilib_error("Failed to acquire board info"); return PCILIB_ERROR_FAILED; } sprintf(fname, "/sys/bus/pci/devices/0000:%02x:%02x.%1x/config", board_info->bus, board_info->slot, board_info->func); ctx->pci_cfg_space_fd = open(fname, O_RDONLY); if (ctx->pci_cfg_space_fd < 0) { pcilib_error("Failed to open configuration space in %s", fname); return PCILIB_ERROR_FAILED; } } else { err = lseek(ctx->pci_cfg_space_fd, SEEK_SET, 0); if (err) { close(ctx->pci_cfg_space_fd); ctx->pci_cfg_space_fd = -1; return pcilib_update_pci_configuration_space(ctx); } } size = read(ctx->pci_cfg_space_fd, ctx->pci_cfg_space_cache, 256); if (size < 64) { if (size <= 0) pcilib_error("Failed to read PCI configuration from sysfs, errno: %i", errno); else pcilib_error("Failed to read PCI configuration from sysfs, only %zu bytes read (expected at least 64)", size); return PCILIB_ERROR_FAILED; } ctx->pci_cfg_space_size = size; return 0; } static uint32_t *pcilib_get_pci_capabilities(pcilib_t *ctx, int cap_id) { int err; uint32_t cap; uint8_t cap_offset; /**< Offset of capability in the configuration space */ if (!ctx->pci_cfg_space_fd) { err = pcilib_update_pci_configuration_space(ctx); if (err) { pcilib_error("Error (%i) reading PCI configuration space", err); return NULL; } } // This is just a pointer to the first cap cap = ctx->pci_cfg_space_cache[(0x34>>2)]; cap_offset = cap&0xFC; while ((cap_offset)&&(cap_offset < ctx->pci_cfg_space_size)) { cap = ctx->pci_cfg_space_cache[cap_offset>>2]; if ((cap&0xFF) == cap_id) return &ctx->pci_cfg_space_cache[cap_offset>>2]; cap_offset = (cap>>8)&0xFC; } return NULL; }; static const uint32_t *pcilib_get_pcie_capabilities(pcilib_t *ctx) { if (ctx->pcie_capabilities) return ctx->pcie_capabilities; ctx->pcie_capabilities = pcilib_get_pci_capabilities(ctx, 0x10); return ctx->pcie_capabilities; } const pcilib_pcie_link_info_t *pcilib_get_pcie_link_info(pcilib_t *ctx) { int err; const uint32_t *cap; err = pcilib_update_pci_configuration_space(ctx); if (err) { pcilib_error("Error (%i) updating PCI configuration space", err); return NULL; } cap = pcilib_get_pcie_capabilities(ctx); if (!cap) return NULL; // Generally speaking this can be updated during the application life time ctx->link_info.max_payload = (cap[1] & 0x07) + 7; ctx->link_info.payload = ((cap[2] >> 5) & 0x07) + 7; ctx->link_info.link_speed = (cap[3]&0xF); ctx->link_info.link_width = (cap[3]&0x3F0) >> 4; ctx->link_info.max_link_speed = (cap[4]&0xF0000) >> 16; ctx->link_info.max_link_width = (cap[4]&0x3F00000) >> 20; return &ctx->link_info; }