/* * The PCI Utilities -- List All PCI Devices * * Copyright (c) 1997--2020 Martin Mares * * Can be freely distributed and used under the terms of the GNU GPL. */ #include #include #include #include #include "lspci.h" /* Options */ int verbose; /* Show detailed information */ static int opt_hex; /* Show contents of config space as hexadecimal numbers */ struct pci_filter filter; /* Device filter */ static int opt_filter; /* Any filter was given */ static int opt_tree; /* Show bus tree */ static int opt_path; /* Show bridge path */ static int opt_machine; /* Generate machine-readable output */ static int opt_map_mode; /* Bus mapping mode enabled */ static int opt_domains; /* Show domain numbers (0=disabled, 1=auto-detected, 2=requested) */ static int opt_kernel; /* Show kernel drivers */ static int opt_query_dns; /* Query the DNS (0=disabled, 1=enabled, 2=refresh cache) */ static int opt_query_all; /* Query the DNS for all entries */ char *opt_pcimap; /* Override path to Linux modules.pcimap */ const char program_name[] = "lspci"; static char options[] = "nvbxs:d:tPi:mgp:qkMDQ" GENERIC_OPTIONS ; static char help_msg[] = "Usage: lspci []\n" "\n" "Basic display modes:\n" "-mm\t\tProduce machine-readable output (single -m for an obsolete format)\n" "-t\t\tShow bus tree\n" "\n" "Display options:\n" "-v\t\tBe verbose (-vv or -vvv for higher verbosity)\n" #ifdef PCI_OS_LINUX "-k\t\tShow kernel drivers handling each device\n" #endif "-x\t\tShow hex-dump of the standard part of the config space\n" "-xxx\t\tShow hex-dump of the whole config space (dangerous; root only)\n" "-xxxx\t\tShow hex-dump of the 4096-byte extended config space (root only)\n" "-b\t\tBus-centric view (addresses and IRQ's as seen by the bus)\n" "-D\t\tAlways show domain numbers\n" "-P\t\tDisplay bridge path in addition to bus and device number\n" "-PP\t\tDisplay bus path in addition to bus and device number\n" "\n" "Resolving of device ID's to names:\n" "-n\t\tShow numeric ID's\n" "-nn\t\tShow both textual and numeric ID's (names & numbers)\n" #ifdef PCI_USE_DNS "-q\t\tQuery the PCI ID database for unknown ID's via DNS\n" "-qq\t\tAs above, but re-query locally cached entries\n" "-Q\t\tQuery the PCI ID database for all ID's via DNS\n" #endif "\n" "Selection of devices:\n" "-s [[[[]:]]:][][.[]]\tShow only devices in selected slots\n" "-d []:[][:]\t\tShow only devices with specified ID's\n" "\n" "Other options:\n" "-i \tUse specified ID database instead of %s\n" #ifdef PCI_OS_LINUX "-p \tLook up kernel modules in a given file instead of default modules.pcimap\n" #endif "-M\t\tEnable `bus mapping' mode (dangerous; root only)\n" "\n" "PCI access options:\n" GENERIC_HELP ; /*** Our view of the PCI bus ***/ struct pci_access *pacc; struct device *first_dev; static int seen_errors; static int need_topology; int config_fetch(struct device *d, unsigned int pos, unsigned int len) { unsigned int end = pos+len; int result; while (pos < d->config_bufsize && len && d->present[pos]) pos++, len--; while (pos+len <= d->config_bufsize && len && d->present[pos+len-1]) len--; if (!len) return 1; if (end > d->config_bufsize) { int orig_size = d->config_bufsize; while (end > d->config_bufsize) d->config_bufsize *= 2; d->config = xrealloc(d->config, d->config_bufsize); d->present = xrealloc(d->present, d->config_bufsize); memset(d->present + orig_size, 0, d->config_bufsize - orig_size); } result = pci_read_block(d->dev, pos, d->config + pos, len); if (result) memset(d->present + pos, 1, len); return result; } struct device * scan_device(struct pci_dev *p) { struct device *d; if (p->domain && !opt_domains) opt_domains = 1; if (!pci_filter_match(&filter, p) && !need_topology) return NULL; d = xmalloc(sizeof(struct device)); memset(d, 0, sizeof(*d)); d->dev = p; d->no_config_access = p->no_config_access; d->config_cached = d->config_bufsize = 64; d->config = xmalloc(64); d->present = xmalloc(64); memset(d->present, 1, 64); if (!d->no_config_access && !pci_read_block(p, 0, d->config, 64)) { d->no_config_access = 1; d->config_cached = d->config_bufsize = 0; memset(d->present, 0, 64); } if (!d->no_config_access && (d->config[PCI_HEADER_TYPE] & 0x7f) == PCI_HEADER_TYPE_CARDBUS) { /* For cardbus bridges, we need to fetch 64 bytes more to get the * full standard header... */ if (config_fetch(d, 64, 64)) d->config_cached += 64; } pci_setup_cache(p, d->config, d->config_cached); pci_fill_info(p, PCI_FILL_IDENT | PCI_FILL_CLASS | PCI_FILL_CLASS_EXT | PCI_FILL_SUBSYS | (need_topology ? PCI_FILL_PARENT : 0)); return d; } static void scan_devices(void) { struct device *d; struct pci_dev *p; pci_scan_bus(pacc); for (p=pacc->devices; p; p=p->next) if (d = scan_device(p)) { d->next = first_dev; first_dev = d; } } /*** Config space accesses ***/ static void check_conf_range(struct device *d, unsigned int pos, unsigned int len) { while (len) if (!d->present[pos]) die("Internal bug: Accessing non-read configuration byte at position %x", pos); else pos++, len--; } byte get_conf_byte(struct device *d, unsigned int pos) { check_conf_range(d, pos, 1); return d->config[pos]; } word get_conf_word(struct device *d, unsigned int pos) { check_conf_range(d, pos, 2); return d->config[pos] | (d->config[pos+1] << 8); } u32 get_conf_long(struct device *d, unsigned int pos) { check_conf_range(d, pos, 4); return d->config[pos] | (d->config[pos+1] << 8) | (d->config[pos+2] << 16) | (d->config[pos+3] << 24); } /*** Sorting ***/ static int compare_them(const void *A, const void *B) { const struct pci_dev *a = (*(const struct device **)A)->dev; const struct pci_dev *b = (*(const struct device **)B)->dev; if (a->domain < b->domain) return -1; if (a->domain > b->domain) return 1; if (a->bus < b->bus) return -1; if (a->bus > b->bus) return 1; if (a->dev < b->dev) return -1; if (a->dev > b->dev) return 1; if (a->func < b->func) return -1; if (a->func > b->func) return 1; return 0; } static void sort_them(void) { struct device **index, **h, **last_dev; int cnt; struct device *d; cnt = 0; for (d=first_dev; d; d=d->next) cnt++; h = index = alloca(sizeof(struct device *) * cnt); for (d=first_dev; d; d=d->next) *h++ = d; qsort(index, cnt, sizeof(struct device *), compare_them); last_dev = &first_dev; h = index; while (cnt--) { *last_dev = *h; last_dev = &(*h)->next; h++; } *last_dev = NULL; } /*** Normal output ***/ static void show_slot_path(struct device *d) { struct pci_dev *p = d->dev; if (opt_path) { struct bus *bus = d->parent_bus; struct bridge *br = bus->parent_bridge; if (br && br->br_dev) { show_slot_path(br->br_dev); if (opt_path > 1) printf("/%02x:%02x.%d", p->bus, p->dev, p->func); else printf("/%02x.%d", p->dev, p->func); return; } } printf("%02x:%02x.%d", p->bus, p->dev, p->func); } static void show_slot_name(struct device *d) { struct pci_dev *p = d->dev; if (!opt_machine ? opt_domains : (p->domain || opt_domains >= 2)) printf("%04x:", p->domain); show_slot_path(d); } static void show_terse(struct device *d) { int c; struct pci_dev *p = d->dev; char classbuf[256], devbuf[256]; show_slot_name(d); printf(" %s: %s", pci_lookup_name(pacc, classbuf, sizeof(classbuf), PCI_LOOKUP_CLASS, p->device_class), pci_lookup_name(pacc, devbuf, sizeof(devbuf), PCI_LOOKUP_VENDOR | PCI_LOOKUP_DEVICE, p->vendor_id, p->device_id)); if ((p->known_fields & PCI_FILL_CLASS_EXT) && p->rev_id) printf(" (rev %02x)", p->rev_id); if (verbose) { char *x; c = (p->known_fields & PCI_FILL_CLASS_EXT) ? p->prog_if : 0; x = pci_lookup_name(pacc, devbuf, sizeof(devbuf), PCI_LOOKUP_PROGIF | PCI_LOOKUP_NO_NUMBERS, p->device_class, c); if (c || x) { printf(" (prog-if %02x", c); if (x) printf(" [%s]", x); putchar(')'); } } putchar('\n'); if (verbose || opt_kernel) { char ssnamebuf[256]; pci_fill_info(p, PCI_FILL_LABEL); if (p->label) printf("\tDeviceName: %s", p->label); if ((p->known_fields & PCI_FILL_SUBSYS) && p->subsys_vendor_id && p->subsys_vendor_id != 0xffff) printf("\tSubsystem: %s\n", pci_lookup_name(pacc, ssnamebuf, sizeof(ssnamebuf), PCI_LOOKUP_SUBSYSTEM | PCI_LOOKUP_VENDOR | PCI_LOOKUP_DEVICE, p->vendor_id, p->device_id, p->subsys_vendor_id, p->subsys_id)); } } /*** Verbose output ***/ static void show_size(u64 x) { static const char suffix[][2] = { "", "K", "M", "G", "T" }; unsigned i; if (!x) return; for (i = 0; i < (sizeof(suffix) / sizeof(*suffix) - 1); i++) { if (x % 1024) break; x /= 1024; } printf(" [size=%u%s]", (unsigned)x, suffix[i]); } static void show_range(const char *prefix, u64 base, u64 limit, int bits, int disabled) { printf("%s:", prefix); if (base <= limit || verbose > 2) printf(" %0*" PCI_U64_FMT_X "-%0*" PCI_U64_FMT_X, (bits+3)/4, base, (bits+3)/4, limit); if (!disabled && base <= limit) show_size(limit - base + 1); else printf(" [disabled]"); if (bits) printf(" [%d-bit]", bits); putchar('\n'); } static u32 ioflg_to_pciflg(pciaddr_t ioflg) { u32 flg; if (ioflg & PCI_IORESOURCE_IO) flg = PCI_BASE_ADDRESS_SPACE_IO; else if (!(ioflg & PCI_IORESOURCE_MEM)) flg = 0; else { flg = PCI_BASE_ADDRESS_SPACE_MEMORY; if (ioflg & PCI_IORESOURCE_MEM_64) flg |= PCI_BASE_ADDRESS_MEM_TYPE_64; else flg |= PCI_BASE_ADDRESS_MEM_TYPE_32; if (ioflg & PCI_IORESOURCE_PREFETCH) flg |= PCI_BASE_ADDRESS_MEM_PREFETCH; } return flg; } static void show_bases(struct device *d, int cnt, int without_config_data) { struct pci_dev *p = d->dev; word cmd = without_config_data ? (PCI_COMMAND_IO | PCI_COMMAND_MEMORY) : get_conf_word(d, PCI_COMMAND); int i; for (i=0; ibase_addr[i]; pciaddr_t len = (p->known_fields & PCI_FILL_SIZES) ? p->size[i] : 0; pciaddr_t ioflg = (p->known_fields & PCI_FILL_IO_FLAGS) ? p->flags[i] : 0; u32 flg = (p->known_fields & PCI_FILL_IO_FLAGS) ? ioflg_to_pciflg(ioflg) : without_config_data ? 0 : get_conf_long(d, PCI_BASE_ADDRESS_0 + 4*i); u32 hw_lower = 0; u32 hw_upper = 0; int broken = 0; int virtual = 0; if (flg == 0xffffffff) flg = 0; if (!pos && !flg && !len) continue; if (verbose > 1) printf("\tRegion %d: ", i); else putchar('\t'); /* Detect virtual regions, which are reported by the OS, but unassigned in the device */ if ((p->known_fields & PCI_FILL_IO_FLAGS) && !without_config_data) { /* Read address as seen by the hardware */ hw_lower = get_conf_long(d, PCI_BASE_ADDRESS_0 + 4*i); if ((hw_lower & PCI_BASE_ADDRESS_SPACE) == (ioflg_to_pciflg(ioflg) & PCI_BASE_ADDRESS_SPACE)) { if ((ioflg & PCI_IORESOURCE_TYPE_BITS) == PCI_IORESOURCE_MEM && (hw_lower & PCI_BASE_ADDRESS_MEM_TYPE_MASK) == PCI_BASE_ADDRESS_MEM_TYPE_64) { if (i >= cnt - 1) broken = 1; else hw_upper = get_conf_long(d, PCI_BASE_ADDRESS_0 + 4*i + 1); } if (pos && !hw_lower && !hw_upper && !(ioflg & PCI_IORESOURCE_PCI_EA_BEI)) virtual = 1; } } /* Print base address */ if (flg & PCI_BASE_ADDRESS_SPACE_IO) { pciaddr_t a = pos & PCI_BASE_ADDRESS_IO_MASK; printf("I/O ports at "); if (a || (cmd & PCI_COMMAND_IO)) printf(PCIADDR_PORT_FMT, a); else if (hw_lower) printf(""); else printf(""); if (virtual) printf(" [virtual]"); else if (!(cmd & PCI_COMMAND_IO)) printf(" [disabled]"); } else { int t = flg & PCI_BASE_ADDRESS_MEM_TYPE_MASK; pciaddr_t a = pos & PCI_ADDR_MEM_MASK; printf("Memory at "); if (broken) printf(""); else if (a) printf(PCIADDR_T_FMT, a); else if (hw_lower || hw_upper) printf(""); else printf(""); printf(" (%s, %sprefetchable)", (t == PCI_BASE_ADDRESS_MEM_TYPE_32) ? "32-bit" : (t == PCI_BASE_ADDRESS_MEM_TYPE_64) ? "64-bit" : (t == PCI_BASE_ADDRESS_MEM_TYPE_1M) ? "low-1M" : "type 3", (flg & PCI_BASE_ADDRESS_MEM_PREFETCH) ? "" : "non-"); if (virtual) printf(" [virtual]"); else if (!(cmd & PCI_COMMAND_MEMORY)) printf(" [disabled]"); } if (ioflg & PCI_IORESOURCE_PCI_EA_BEI) printf(" [enhanced]"); show_size(len); putchar('\n'); } } static void show_rom(struct device *d, int reg) { struct pci_dev *p = d->dev; pciaddr_t rom = p->rom_base_addr; pciaddr_t len = (p->known_fields & PCI_FILL_SIZES) ? p->rom_size : 0; pciaddr_t ioflg = (p->known_fields & PCI_FILL_IO_FLAGS) ? p->rom_flags : 0; u32 flg = reg >= 0 ? get_conf_long(d, reg) : ioflg_to_pciflg(ioflg); word cmd = reg >= 0 ? get_conf_word(d, PCI_COMMAND) : PCI_COMMAND_MEMORY; int virtual = 0; if (!rom && !flg && !len) return; if (reg >= 0 && (rom & PCI_ROM_ADDRESS_MASK) && !(flg & PCI_ROM_ADDRESS_MASK) && !(ioflg & PCI_IORESOURCE_PCI_EA_BEI)) { flg = rom; virtual = 1; } printf("\tExpansion ROM at "); if (rom & PCI_ROM_ADDRESS_MASK) printf(PCIADDR_T_FMT, rom & PCI_ROM_ADDRESS_MASK); else if (flg & PCI_ROM_ADDRESS_MASK) printf(""); else printf(""); if (virtual) printf(" [virtual]"); if (!(flg & PCI_ROM_ADDRESS_ENABLE)) printf(" [disabled]"); else if (!virtual && !(cmd & PCI_COMMAND_MEMORY)) printf(" [disabled by cmd]"); if (ioflg & PCI_IORESOURCE_PCI_EA_BEI) printf(" [enhanced]"); show_size(len); putchar('\n'); } static void show_htype0(struct device *d) { show_bases(d, 6, 0); show_rom(d, PCI_ROM_ADDRESS); show_caps(d, PCI_CAPABILITY_LIST); } static void show_htype1(struct device *d) { struct pci_dev *p = d->dev; u32 io_base = get_conf_byte(d, PCI_IO_BASE); u32 io_limit = get_conf_byte(d, PCI_IO_LIMIT); u32 io_type = io_base & PCI_IO_RANGE_TYPE_MASK; u32 mem_base = get_conf_word(d, PCI_MEMORY_BASE); u32 mem_limit = get_conf_word(d, PCI_MEMORY_LIMIT); u32 mem_type = mem_base & PCI_MEMORY_RANGE_TYPE_MASK; u32 pref_base = get_conf_word(d, PCI_PREF_MEMORY_BASE); u32 pref_limit = get_conf_word(d, PCI_PREF_MEMORY_LIMIT); u32 pref_type = pref_base & PCI_PREF_RANGE_TYPE_MASK; word sec_stat = get_conf_word(d, PCI_SEC_STATUS); word brc = get_conf_word(d, PCI_BRIDGE_CONTROL); int io_disabled = (p->known_fields & PCI_FILL_BRIDGE_BASES) && !p->bridge_size[0]; int mem_disabled = (p->known_fields & PCI_FILL_BRIDGE_BASES) && !p->bridge_size[1]; int pref_disabled = (p->known_fields & PCI_FILL_BRIDGE_BASES) && !p->bridge_size[2]; int io_bits, pref_bits; show_bases(d, 2, 0); printf("\tBus: primary=%02x, secondary=%02x, subordinate=%02x, sec-latency=%d\n", get_conf_byte(d, PCI_PRIMARY_BUS), get_conf_byte(d, PCI_SECONDARY_BUS), get_conf_byte(d, PCI_SUBORDINATE_BUS), get_conf_byte(d, PCI_SEC_LATENCY_TIMER)); if ((p->known_fields & PCI_FILL_BRIDGE_BASES) && !io_disabled) { io_base = p->bridge_base_addr[0] & PCI_IO_RANGE_MASK; io_limit = io_base + p->bridge_size[0] - 1; io_type = p->bridge_base_addr[0] & PCI_IO_RANGE_TYPE_MASK; io_bits = (io_type == PCI_IO_RANGE_TYPE_32) ? 32 : 16; show_range("\tI/O behind bridge", io_base, io_limit, io_bits, io_disabled); } else if (io_type != (io_limit & PCI_IO_RANGE_TYPE_MASK) || (io_type != PCI_IO_RANGE_TYPE_16 && io_type != PCI_IO_RANGE_TYPE_32)) printf("\t!!! Unknown I/O range types %x/%x\n", io_base, io_limit); else { io_base = (io_base & PCI_IO_RANGE_MASK) << 8; io_limit = (io_limit & PCI_IO_RANGE_MASK) << 8; if (io_type == PCI_IO_RANGE_TYPE_32) { io_base |= (get_conf_word(d, PCI_IO_BASE_UPPER16) << 16); io_limit |= (get_conf_word(d, PCI_IO_LIMIT_UPPER16) << 16); } /* I/O is unsupported if both base and limit are zeros and resource is disabled */ if (!(io_base == 0x0 && io_limit == 0x0 && io_disabled)) { io_limit += 0xfff; io_bits = (io_type == PCI_IO_RANGE_TYPE_32) ? 32 : 16; show_range("\tI/O behind bridge", io_base, io_limit, io_bits, io_disabled); } } if ((p->known_fields & PCI_FILL_BRIDGE_BASES) && !mem_disabled) { mem_base = p->bridge_base_addr[1] & PCI_MEMORY_RANGE_MASK; mem_limit = mem_base + p->bridge_size[1] - 1; show_range("\tMemory behind bridge", mem_base, mem_limit, 32, mem_disabled); } else if (mem_type != (mem_limit & PCI_MEMORY_RANGE_TYPE_MASK) || mem_type) printf("\t!!! Unknown memory range types %x/%x\n", mem_base, mem_limit); else { mem_base = (mem_base & PCI_MEMORY_RANGE_MASK) << 16; mem_limit = (mem_limit & PCI_MEMORY_RANGE_MASK) << 16; show_range("\tMemory behind bridge", mem_base, mem_limit + 0xfffff, 32, mem_disabled); } if ((p->known_fields & PCI_FILL_BRIDGE_BASES) && !pref_disabled) { u64 pref_base_64 = p->bridge_base_addr[2] & PCI_MEMORY_RANGE_MASK; u64 pref_limit_64 = pref_base_64 + p->bridge_size[2] - 1; pref_type = p->bridge_base_addr[2] & PCI_MEMORY_RANGE_TYPE_MASK; pref_bits = (pref_type == PCI_PREF_RANGE_TYPE_64) ? 64 : 32; show_range("\tPrefetchable memory behind bridge", pref_base_64, pref_limit_64, pref_bits, pref_disabled); } else if (pref_type != (pref_limit & PCI_PREF_RANGE_TYPE_MASK) || (pref_type != PCI_PREF_RANGE_TYPE_32 && pref_type != PCI_PREF_RANGE_TYPE_64)) printf("\t!!! Unknown prefetchable memory range types %x/%x\n", pref_base, pref_limit); else { u64 pref_base_64 = (pref_base & PCI_PREF_RANGE_MASK) << 16; u64 pref_limit_64 = (pref_limit & PCI_PREF_RANGE_MASK) << 16; if (pref_type == PCI_PREF_RANGE_TYPE_64) { pref_base_64 |= (u64) get_conf_long(d, PCI_PREF_BASE_UPPER32) << 32; pref_limit_64 |= (u64) get_conf_long(d, PCI_PREF_LIMIT_UPPER32) << 32; } /* Prefetchable memory is unsupported if both base and limit are zeros and resource is disabled */ if (!(pref_base_64 == 0x0 && pref_limit_64 == 0x0 && pref_disabled)) { pref_limit_64 += 0xfffff; pref_bits = (pref_type == PCI_PREF_RANGE_TYPE_64) ? 64 : 32; show_range("\tPrefetchable memory behind bridge", pref_base_64, pref_limit_64, pref_bits, pref_disabled); } } if (verbose > 1) printf("\tSecondary status: 66MHz%c FastB2B%c ParErr%c DEVSEL=%s >TAbort%c 1) { printf("\tBridgeCtl: Parity%c SERR%c NoISA%c VGA%c VGA16%c MAbort%c >Reset%c FastB2B%c\n", FLAG(brc, PCI_BRIDGE_CTL_PARITY), FLAG(brc, PCI_BRIDGE_CTL_SERR), FLAG(brc, PCI_BRIDGE_CTL_NO_ISA), FLAG(brc, PCI_BRIDGE_CTL_VGA), FLAG(brc, PCI_BRIDGE_CTL_VGA_16BIT), FLAG(brc, PCI_BRIDGE_CTL_MASTER_ABORT), FLAG(brc, PCI_BRIDGE_CTL_BUS_RESET), FLAG(brc, PCI_BRIDGE_CTL_FAST_BACK)); printf("\t\tPriDiscTmr%c SecDiscTmr%c DiscTmrStat%c DiscTmrSERREn%c\n", FLAG(brc, PCI_BRIDGE_CTL_PRI_DISCARD_TIMER), FLAG(brc, PCI_BRIDGE_CTL_SEC_DISCARD_TIMER), FLAG(brc, PCI_BRIDGE_CTL_DISCARD_TIMER_STATUS), FLAG(brc, PCI_BRIDGE_CTL_DISCARD_TIMER_SERR_EN)); } show_caps(d, PCI_CAPABILITY_LIST); } static void show_htype2(struct device *d) { int i; word cmd = get_conf_word(d, PCI_COMMAND); word brc = get_conf_word(d, PCI_CB_BRIDGE_CONTROL); word exca; int verb = verbose > 2; show_bases(d, 1, 0); printf("\tBus: primary=%02x, secondary=%02x, subordinate=%02x, sec-latency=%d\n", get_conf_byte(d, PCI_CB_PRIMARY_BUS), get_conf_byte(d, PCI_CB_CARD_BUS), get_conf_byte(d, PCI_CB_SUBORDINATE_BUS), get_conf_byte(d, PCI_CB_LATENCY_TIMER)); for (i=0; i<2; i++) { int p = 8*i; u32 base = get_conf_long(d, PCI_CB_MEMORY_BASE_0 + p); u32 limit = get_conf_long(d, PCI_CB_MEMORY_LIMIT_0 + p); limit = limit + 0xfff; if (base <= limit || verb) printf("\tMemory window %d: %08x-%08x%s%s\n", i, base, limit, (cmd & PCI_COMMAND_MEMORY) ? "" : " [disabled]", (brc & (PCI_CB_BRIDGE_CTL_PREFETCH_MEM0 << i)) ? " (prefetchable)" : ""); } for (i=0; i<2; i++) { int p = 8*i; u32 base = get_conf_long(d, PCI_CB_IO_BASE_0 + p); u32 limit = get_conf_long(d, PCI_CB_IO_LIMIT_0 + p); if (!(base & PCI_IO_RANGE_TYPE_32)) { base &= 0xffff; limit &= 0xffff; } base &= PCI_CB_IO_RANGE_MASK; limit = (limit & PCI_CB_IO_RANGE_MASK) + 3; if (base <= limit || verb) printf("\tI/O window %d: %08x-%08x%s\n", i, base, limit, (cmd & PCI_COMMAND_IO) ? "" : " [disabled]"); } if (get_conf_word(d, PCI_CB_SEC_STATUS) & PCI_STATUS_SIG_SYSTEM_ERROR) printf("\tSecondary status: SERR\n"); if (verbose > 1) printf("\tBridgeCtl: Parity%c SERR%c ISA%c VGA%c MAbort%c >Reset%c 16bInt%c PostWrite%c\n", FLAG(brc, PCI_CB_BRIDGE_CTL_PARITY), FLAG(brc, PCI_CB_BRIDGE_CTL_SERR), FLAG(brc, PCI_CB_BRIDGE_CTL_ISA), FLAG(brc, PCI_CB_BRIDGE_CTL_VGA), FLAG(brc, PCI_CB_BRIDGE_CTL_MASTER_ABORT), FLAG(brc, PCI_CB_BRIDGE_CTL_CB_RESET), FLAG(brc, PCI_CB_BRIDGE_CTL_16BIT_INT), FLAG(brc, PCI_CB_BRIDGE_CTL_POST_WRITES)); if (d->config_cached < 128) { printf("\t\n"); return; } exca = get_conf_word(d, PCI_CB_LEGACY_MODE_BASE); if (exca) printf("\t16-bit legacy interface ports at %04x\n", exca); show_caps(d, PCI_CB_CAPABILITY_LIST); } static void show_htype_unknown(struct device *d) { struct pci_dev *p = d->dev; u64 base, limit, flags; const char *str; int i, bits; if (pacc->buscentric) return; show_bases(d, 6, 1); for (i = 0; i < 4; i++) { if (!p->bridge_base_addr[i]) continue; base = p->bridge_base_addr[i]; limit = base + p->bridge_size[i] - 1; flags = p->bridge_flags[i]; if (flags & PCI_IORESOURCE_IO) { bits = (flags & PCI_IORESOURCE_IO_16BIT_ADDR) ? 16 : 32; str = "\tI/O behind bridge"; } else if (flags & PCI_IORESOURCE_MEM) { bits = (flags & PCI_IORESOURCE_MEM_64) ? 64 : 32; if (flags & PCI_IORESOURCE_PREFETCH) str = "\tPrefetchable memory behind bridge"; else str = "\tMemory behind bridge"; } else { bits = 0; str = "\tUnknown resource behind bridge"; } show_range(str, base, limit, bits, 0); } show_rom(d, -1); } static void show_verbose(struct device *d) { struct pci_dev *p = d->dev; int unknown_config_data = 0; word class = p->device_class; byte htype = d->no_config_access ? -1 : (get_conf_byte(d, PCI_HEADER_TYPE) & 0x7f); byte bist; byte max_lat, min_gnt; char *dt_node, *iommu_group; show_terse(d); pci_fill_info(p, PCI_FILL_IRQ | PCI_FILL_BASES | PCI_FILL_ROM_BASE | PCI_FILL_SIZES | PCI_FILL_PHYS_SLOT | PCI_FILL_NUMA_NODE | PCI_FILL_DT_NODE | PCI_FILL_IOMMU_GROUP | PCI_FILL_BRIDGE_BASES | PCI_FILL_CLASS_EXT | PCI_FILL_SUBSYS); switch (htype) { case PCI_HEADER_TYPE_NORMAL: if (class == PCI_CLASS_BRIDGE_PCI) printf("\t!!! Invalid class %04x for header type %02x\n", class, htype); bist = get_conf_byte(d, PCI_BIST); max_lat = get_conf_byte(d, PCI_MAX_LAT); min_gnt = get_conf_byte(d, PCI_MIN_GNT); break; case PCI_HEADER_TYPE_BRIDGE: if ((class >> 8) != PCI_BASE_CLASS_BRIDGE) printf("\t!!! Invalid class %04x for header type %02x\n", class, htype); bist = get_conf_byte(d, PCI_BIST); min_gnt = max_lat = 0; break; case PCI_HEADER_TYPE_CARDBUS: if ((class >> 8) != PCI_BASE_CLASS_BRIDGE) printf("\t!!! Invalid class %04x for header type %02x\n", class, htype); bist = get_conf_byte(d, PCI_BIST); min_gnt = max_lat = 0; break; default: if (!d->no_config_access) printf("\t!!! Unknown header type %02x\n", htype); bist = 0; min_gnt = max_lat = 0; unknown_config_data = 1; } if (p->phy_slot) printf("\tPhysical Slot: %s\n", p->phy_slot); if (dt_node = pci_get_string_property(p, PCI_FILL_DT_NODE)) printf("\tDevice tree node: %s\n", dt_node); if (!unknown_config_data && verbose > 1) { word cmd = get_conf_word(d, PCI_COMMAND); word status = get_conf_word(d, PCI_STATUS); printf("\tControl: I/O%c Mem%c BusMaster%c SpecCycle%c MemWINV%c VGASnoop%c ParErr%c Stepping%c SERR%c FastB2B%c DisINTx%c\n", FLAG(cmd, PCI_COMMAND_IO), FLAG(cmd, PCI_COMMAND_MEMORY), FLAG(cmd, PCI_COMMAND_MASTER), FLAG(cmd, PCI_COMMAND_SPECIAL), FLAG(cmd, PCI_COMMAND_INVALIDATE), FLAG(cmd, PCI_COMMAND_VGA_PALETTE), FLAG(cmd, PCI_COMMAND_PARITY), FLAG(cmd, PCI_COMMAND_WAIT), FLAG(cmd, PCI_COMMAND_SERR), FLAG(cmd, PCI_COMMAND_FAST_BACK), FLAG(cmd, PCI_COMMAND_DISABLE_INTx)); printf("\tStatus: Cap%c 66MHz%c UDF%c FastB2B%c ParErr%c DEVSEL=%s >TAbort%c SERR%c 1) { byte int_pin = unknown_config_data ? 0 : get_conf_byte(d, PCI_INTERRUPT_PIN); if (int_pin || p->irq) printf("\tInterrupt: pin %c routed to IRQ " PCIIRQ_FMT "\n", (int_pin ? 'A' + int_pin - 1 : '?'), p->irq); if (p->numa_node != -1) printf("\tNUMA node: %d\n", p->numa_node); if (iommu_group = pci_get_string_property(p, PCI_FILL_IOMMU_GROUP)) printf("\tIOMMU group: %s\n", iommu_group); } if (!unknown_config_data && verbose <= 1) { word cmd = get_conf_word(d, PCI_COMMAND); word status = get_conf_word(d, PCI_STATUS); byte latency = get_conf_byte(d, PCI_LATENCY_TIMER); printf("\tFlags: "); if (cmd & PCI_COMMAND_MASTER) printf("bus master, "); if (cmd & PCI_COMMAND_VGA_PALETTE) printf("VGA palette snoop, "); if (cmd & PCI_COMMAND_WAIT) printf("stepping, "); if (cmd & PCI_COMMAND_FAST_BACK) printf("fast Back2Back, "); if (status & PCI_STATUS_66MHZ) printf("66MHz, "); if (status & PCI_STATUS_UDF) printf("user-definable features, "); printf("%s devsel", ((status & PCI_STATUS_DEVSEL_MASK) == PCI_STATUS_DEVSEL_SLOW) ? "slow" : ((status & PCI_STATUS_DEVSEL_MASK) == PCI_STATUS_DEVSEL_MEDIUM) ? "medium" : ((status & PCI_STATUS_DEVSEL_MASK) == PCI_STATUS_DEVSEL_FAST) ? "fast" : "??"); if (cmd & PCI_COMMAND_MASTER) printf(", latency %d", latency); if (p->irq) printf(", IRQ " PCIIRQ_FMT, p->irq); if (p->numa_node != -1) printf(", NUMA node %d", p->numa_node); if (iommu_group = pci_get_string_property(p, PCI_FILL_IOMMU_GROUP)) printf(", IOMMU group %s", iommu_group); putchar('\n'); } if (bist & PCI_BIST_CAPABLE) { if (bist & PCI_BIST_START) printf("\tBIST is running\n"); else printf("\tBIST result: %02x\n", bist & PCI_BIST_CODE_MASK); } switch (htype) { case PCI_HEADER_TYPE_NORMAL: show_htype0(d); break; case PCI_HEADER_TYPE_BRIDGE: show_htype1(d); break; case PCI_HEADER_TYPE_CARDBUS: show_htype2(d); break; default: show_htype_unknown(d); } } /*** Machine-readable dumps ***/ static void show_hex_dump(struct device *d) { unsigned int i, cnt; if (d->no_config_access) { printf("WARNING: Cannot show hex-dump of the config space\n"); return; } cnt = d->config_cached; if (opt_hex >= 3 && config_fetch(d, cnt, 256-cnt)) { cnt = 256; if (opt_hex >= 4 && config_fetch(d, 256, 4096-256)) cnt = 4096; } for (i=0; idev; char classbuf[256], vendbuf[256], devbuf[256], svbuf[256], sdbuf[256]; char *dt_node, *iommu_group; if (verbose) { pci_fill_info(p, PCI_FILL_PHYS_SLOT | PCI_FILL_NUMA_NODE | PCI_FILL_DT_NODE | PCI_FILL_IOMMU_GROUP); printf((opt_machine >= 2) ? "Slot:\t" : "Device:\t"); show_slot_name(d); putchar('\n'); printf("Class:\t%s\n", pci_lookup_name(pacc, classbuf, sizeof(classbuf), PCI_LOOKUP_CLASS, p->device_class)); printf("Vendor:\t%s\n", pci_lookup_name(pacc, vendbuf, sizeof(vendbuf), PCI_LOOKUP_VENDOR, p->vendor_id, p->device_id)); printf("Device:\t%s\n", pci_lookup_name(pacc, devbuf, sizeof(devbuf), PCI_LOOKUP_DEVICE, p->vendor_id, p->device_id)); if ((p->known_fields & PCI_FILL_SUBSYS) && p->subsys_vendor_id && p->subsys_vendor_id != 0xffff) { printf("SVendor:\t%s\n", pci_lookup_name(pacc, svbuf, sizeof(svbuf), PCI_LOOKUP_SUBSYSTEM | PCI_LOOKUP_VENDOR, p->subsys_vendor_id)); printf("SDevice:\t%s\n", pci_lookup_name(pacc, sdbuf, sizeof(sdbuf), PCI_LOOKUP_SUBSYSTEM | PCI_LOOKUP_DEVICE, p->vendor_id, p->device_id, p->subsys_vendor_id, p->subsys_id)); } if (p->phy_slot) printf("PhySlot:\t%s\n", p->phy_slot); if ((p->known_fields & PCI_FILL_CLASS_EXT) && p->rev_id) printf("Rev:\t%02x\n", p->rev_id); if (p->known_fields & PCI_FILL_CLASS_EXT) printf("ProgIf:\t%02x\n", p->prog_if); if (opt_kernel) show_kernel_machine(d); if (p->numa_node != -1) printf("NUMANode:\t%d\n", p->numa_node); if (dt_node = pci_get_string_property(p, PCI_FILL_DT_NODE)) printf("DTNode:\t%s\n", dt_node); if (iommu_group = pci_get_string_property(p, PCI_FILL_IOMMU_GROUP)) printf("IOMMUGroup:\t%s\n", iommu_group); } else { show_slot_name(d); print_shell_escaped(pci_lookup_name(pacc, classbuf, sizeof(classbuf), PCI_LOOKUP_CLASS, p->device_class)); print_shell_escaped(pci_lookup_name(pacc, vendbuf, sizeof(vendbuf), PCI_LOOKUP_VENDOR, p->vendor_id, p->device_id)); print_shell_escaped(pci_lookup_name(pacc, devbuf, sizeof(devbuf), PCI_LOOKUP_DEVICE, p->vendor_id, p->device_id)); if ((p->known_fields & PCI_FILL_CLASS_EXT) && p->rev_id) printf(" -r%02x", p->rev_id); if (p->known_fields & PCI_FILL_CLASS_EXT) printf(" -p%02x", p->prog_if); if ((p->known_fields & PCI_FILL_SUBSYS) && p->subsys_vendor_id && p->subsys_vendor_id != 0xffff) { print_shell_escaped(pci_lookup_name(pacc, svbuf, sizeof(svbuf), PCI_LOOKUP_SUBSYSTEM | PCI_LOOKUP_VENDOR, p->subsys_vendor_id)); print_shell_escaped(pci_lookup_name(pacc, sdbuf, sizeof(sdbuf), PCI_LOOKUP_SUBSYSTEM | PCI_LOOKUP_DEVICE, p->vendor_id, p->device_id, p->subsys_vendor_id, p->subsys_id)); } else printf(" \"\" \"\""); putchar('\n'); } } /*** Main show function ***/ void show_device(struct device *d) { if (opt_machine) show_machine(d); else { if (verbose) show_verbose(d); else show_terse(d); if (opt_kernel || verbose) show_kernel(d); } if (opt_hex) show_hex_dump(d); if (verbose || opt_hex) putchar('\n'); } static void show(void) { struct device *d; for (d=first_dev; d; d=d->next) if (pci_filter_match(&filter, d->dev)) show_device(d); } /* Main */ int main(int argc, char **argv) { int i; char *msg; if (argc == 2 && !strcmp(argv[1], "--version")) { puts("lspci version " PCIUTILS_VERSION); return 0; } pacc = pci_alloc(); pacc->error = die; pci_filter_init(pacc, &filter); while ((i = getopt(argc, argv, options)) != -1) switch (i) { case 'n': pacc->numeric_ids++; break; case 'v': verbose++; break; case 'b': pacc->buscentric = 1; break; case 's': if (msg = pci_filter_parse_slot(&filter, optarg)) die("-s: %s", msg); opt_filter = 1; break; case 'd': if (msg = pci_filter_parse_id(&filter, optarg)) die("-d: %s", msg); opt_filter = 1; break; case 'x': opt_hex++; break; case 'P': opt_path++; need_topology = 1; break; case 't': opt_tree++; need_topology = 1; break; case 'i': pci_set_name_list_path(pacc, optarg, 0); break; case 'm': opt_machine++; break; case 'p': opt_pcimap = optarg; break; #ifdef PCI_OS_LINUX case 'k': opt_kernel++; break; #endif case 'M': opt_map_mode++; break; case 'D': opt_domains = 2; break; #ifdef PCI_USE_DNS case 'q': opt_query_dns++; break; case 'Q': opt_query_all = 1; break; #else case 'q': case 'Q': die("DNS queries are not available in this version"); #endif default: if (parse_generic_option(i, pacc, optarg)) break; bad: fprintf(stderr, help_msg, pacc->id_file_name); return 1; } if (optind < argc) goto bad; if (opt_query_dns) { pacc->id_lookup_mode |= PCI_LOOKUP_NETWORK; if (opt_query_dns > 1) pacc->id_lookup_mode |= PCI_LOOKUP_REFRESH_CACHE; } if (opt_query_all) pacc->id_lookup_mode |= PCI_LOOKUP_NETWORK | PCI_LOOKUP_SKIP_LOCAL; pci_init(pacc); if (opt_map_mode) { if (need_topology) die("Bus mapping mode does not recognize bus topology"); map_the_bus(); } else { scan_devices(); sort_them(); if (need_topology) grow_tree(); if (opt_tree) show_forest(opt_filter ? &filter : NULL); else show(); } show_kernel_cleanup(); pci_cleanup(pacc); return (seen_errors ? 2 : 0); }