/* SPDX-License-Identifier: GPL-2.0-only */ #include #include #include #include #include #include #include #include #include #include #include #include #include typedef uint8_t u8; typedef uint16_t u16; typedef uint32_t u32; #define DEF_ALLOC 1024 typedef struct { u16 signature; u8 size; u8 entrypoint[4]; u8 checksum; u8 reserved[16]; u16 pcir_offset; u16 vbt_offset; } __attribute__ ((packed)) optionrom_header_t; typedef struct { u32 signature; u16 vendor; u16 device; u16 reserved1; u16 length; u8 revision; u8 classcode[3]; u16 imagelength; u16 coderevision; u8 codetype; u8 indicator; u16 reserved2; } __attribute__((packed)) optionrom_pcir_t; struct vbt_header { u8 signature[20]; u16 version; u16 header_size; u16 vbt_size; u8 vbt_checksum; u8 reserved0; u32 bdb_offset; u32 aim_offset[4]; } __attribute__ ((packed)); struct bdb_header { u8 signature[16]; u16 version; u16 header_size; u16 bdb_size; }; struct vbios_data { u8 type; /* 0 == desktop, 1 == mobile */ u8 relstage; u8 chipset; u8 lvds_present:1; u8 tv_present:1; u8 rsvd2:6; /* finish byte */ u8 rsvd3[4]; u8 signon[155]; u8 copyright[61]; u16 code_segment; u8 dos_boot_mode; u8 bandwidth_percent; u8 rsvd4; /* popup memory size */ u8 resize_pci_bios; u8 rsvd5; /* is crt already on ddc2 */ } __attribute__ ((packed)); struct bdb_general_features { /* bits 1 */ u8 panel_fitting:2; u8 flexaim:1; u8 msg_enable:1; u8 clear_screen:3; u8 color_flip:1; /* bits 2 */ u8 download_ext_vbt:1; u8 enable_ssc:1; u8 ssc_freq:1; u8 enable_lfp_on_override:1; u8 disable_ssc_ddt:1; u8 rsvd7:1; u8 display_clock_mode:1; u8 rsvd8:1; /* finish byte */ /* bits 3 */ u8 disable_smooth_vision:1; u8 single_dvi:1; u8 rsvd9:1; u8 fdi_rx_polarity_inverted:1; u8 rsvd10:4; /* finish byte */ /* bits 4 */ u8 legacy_monitor_detect; /* bits 5 */ u8 int_crt_support:1; u8 int_tv_support:1; u8 int_efp_support:1; u8 dp_ssc_enb:1; /* PCH attached eDP supports SSC */ u8 dp_ssc_freq:1; /* SSC freq for PCH attached eDP */ u8 rsvd11:3; /* finish byte */ } __attribute__ ((packed)); struct common_child_dev_config { u16 handle; u16 device_type; u8 not_common1[12]; u8 dvo_port; u8 i2c_pin; u8 slave_addr; u8 ddc_pin; u16 edid_ptr; u8 not_common3[6]; u8 dvo_wiring; u8 not_common4[4]; } __attribute__ ((packed)); struct bdb_general_definitions { /* DDC GPIO */ u8 crt_ddc_gmbus_pin; /* DPMS bits */ u8 dpms_acpi:1; u8 skip_boot_crt_detect:1; u8 dpms_aim:1; u8 rsvd1:5; /* finish byte */ /* boot device bits */ u8 boot_display[2]; u8 child_dev_size; /* * Device info: * If TV is present, it'll be at devices[0]. * LVDS will be next, either devices[0] or [1], if present. * On some platforms the number of device is 6. But could be as few as * 4 if both TV and LVDS are missing. * And the device num is related with the size of general definition * block. It is obtained by using the following formula: * number = (block_size - sizeof(bdb_general_definitions))/ * sizeof(child_device_config); */ struct common_child_dev_config devices[]; } __attribute__ ((packed)); struct bdb_driver_features { u8 boot_dev_algorithm:1; u8 block_display_switch:1; u8 allow_display_switch:1; u8 hotplug_dvo:1; u8 dual_view_zoom:1; u8 int15h_hook:1; u8 sprite_in_clone:1; u8 primary_lfp_id:1; u16 boot_mode_x; u16 boot_mode_y; u8 boot_mode_bpp; u8 boot_mode_refresh; u16 enable_lfp_primary:1; u16 selective_mode_pruning:1; u16 dual_frequency:1; u16 render_clock_freq:1; /* 0: high freq; 1: low freq */ u16 nt_clone_support:1; u16 power_scheme_ui:1; /* 0: CUI; 1: 3rd party */ u16 sprite_display_assign:1; /* 0: secondary; 1: primary */ u16 cui_aspect_scaling:1; u16 preserve_aspect_ratio:1; u16 sdvo_device_power_down:1; u16 crt_hotplug:1; u16 lvds_config:2; u16 tv_hotplug:1; u16 hdmi_config:2; u8 static_display:1; u8 reserved2:7; u16 legacy_crt_max_x; u16 legacy_crt_max_y; u8 legacy_crt_max_refresh; u8 hdmi_termination; u8 custom_vbt_version; } __attribute__ ((packed)); struct bdb_lvds_options { u8 panel_type; u8 rsvd1; /* LVDS capabilities, stored in a dword */ u8 pfit_mode:2; u8 pfit_text_mode_enhanced:1; u8 pfit_gfx_mode_enhanced:1; u8 pfit_ratio_auto:1; u8 pixel_dither:1; u8 lvds_edid:1; u8 rsvd2:1; u8 rsvd4; } __attribute__ ((packed)); struct bdb_sdvo_lvds_options { u8 panel_backlight; u8 h40_set_panel_type; u8 panel_type; u8 ssc_clk_freq; u16 als_low_trip; u16 als_high_trip; u8 sclalarcoeff_tab_row_num; u8 sclalarcoeff_tab_row_size; u8 coefficient[8]; u8 panel_misc_bits_1; u8 panel_misc_bits_2; u8 panel_misc_bits_3; u8 panel_misc_bits_4; } __attribute__ ((packed)); static const size_t ignore_checksum = 1; #define BDB_GENERAL_FEATURES 1 #define BDB_GENERAL_DEFINITIONS 2 #define BDB_DRIVER_FEATURES 12 #define BDB_SDVO_LVDS_OPTIONS 22 #define BDB_SDVO_PANEL_DTDS 23 #define BDB_LVDS_OPTIONS 40 #define BDB_LVDS_LFP_DATA_PTRS 41 #define BDB_LVDS_LFP_DATA 42 #define BDB_SKIP 254 /* print helpers */ static void print(const char *format, ...) { va_list args; fprintf(stdout, "VBTTOOL: "); va_start(args, format); vfprintf(stdout, format, args); va_end(args); } static void printt(const char *format, ...) { va_list args; fprintf(stdout, "\t"); va_start(args, format); vfprintf(stdout, format, args); va_end(args); } static void printwarn(const char *format, ...) { va_list args; fprintf(stderr, "VBTTOOL: WARN: "); va_start(args, format); vfprintf(stderr, format, args); va_end(args); } static void printerr(const char *format, ...) { va_list args; fprintf(stderr, "VBTTOOL: ERR: "); va_start(args, format); vfprintf(stderr, format, args); va_end(args); } struct fileobject { unsigned char *data; size_t size; }; /* file object helpers */ /* * Alloc a file object of given size. * Returns NULL on error. */ static struct fileobject *malloc_fo(const size_t size) { struct fileobject *fo; if (!size) return NULL; fo = malloc(sizeof(*fo)); if (!fo) return NULL; fo->data = malloc(size); if (!fo->data) { free(fo); return NULL; } fo->size = size; return fo; } /* Free a fileobject structure */ static void free_fo(struct fileobject *fo) { if (fo) { free(fo->data); free(fo); } } /* Resize file object and keep memory content */ static struct fileobject *remalloc_fo(struct fileobject *old, const size_t size) { struct fileobject *fo = old; if (!old || !size) return NULL; fo->data = realloc(fo->data, size); if (!fo->data) return NULL; if (fo->size < size) memset(&fo->data[fo->size], 0, size - fo->size); fo->size = size; return fo; } /* * Creates a new subregion copy of fileobject. * Returns NULL if offset is greater than fileobject size. * Returns NULL on error. */ static struct fileobject *malloc_fo_sub(const struct fileobject *old, const size_t off) { struct fileobject *fo; if (!old || off > old->size) return NULL; fo = malloc_fo(old->size - off); if (!fo) return NULL; memcpy(fo->data, old->data + off, fo->size); return fo; } /* file helpers */ /* Create fileobject from file */ static struct fileobject *read_file(const char *filename) { FILE *fd = fopen(filename, "rb"); off_t read_size = DEF_ALLOC; if (!fd) { printerr("%s open failed: %s\n", filename, strerror(errno)); return NULL; } struct fileobject *fo = malloc_fo(read_size); if (!fo) { printerr("malloc failed\n"); fclose(fd); return NULL; } off_t total_bytes_read = 0, bytes_read; while ((bytes_read = fread(fo->data + total_bytes_read, 1, read_size, fd)) > 0) { total_bytes_read += bytes_read; struct fileobject *newfo = remalloc_fo(fo, fo->size + read_size); if (!newfo) { fclose(fd); free_fo(fo); return NULL; } fo = newfo; } if (!total_bytes_read) { fclose(fd); free_fo(fo); return NULL; } if (fclose(fd)) { printerr("%s close failed: %s\n", filename, strerror(errno)); free_fo(fo); return NULL; } fo->size = total_bytes_read; return fo; } /* Create fileobject from physical memory at given address of size 64 KiB */ static struct fileobject *read_physmem(size_t addr) { const int fd = open("/dev/mem", O_RDONLY); const size_t size = 64 * 2 * KiB; if (fd < 0) { printerr("/dev/mem open failed: %s\n", strerror(errno)); return NULL; } const void *data = mmap(0, size, PROT_READ, MAP_SHARED, fd, addr); if (data == MAP_FAILED) { close(fd); printerr("mmap failed: %s\n", strerror(errno)); return NULL; } struct fileobject *fo = malloc_fo(size); if (!fo) { printerr("malloc failed\n"); munmap((void *)data, size); close(fd); return NULL; } memcpy(fo->data, data, size); munmap((void *)data, size); if (close(fd)) { printerr("/dev/mem close failed: %s\n", strerror(errno)); free_fo(fo); return NULL; } return fo; } /* Write fileobject contents to file */ static int write_file(const char *filename, const struct fileobject *fo) { FILE *fd_out = fopen(filename, "wb"); if (!fd_out) { printerr("%s open failed: %s\n", filename, strerror(errno)); return 1; } if (fwrite(fo->data, 1, fo->size, fd_out) != fo->size) { fclose(fd_out); return 1; } return fclose(fd_out); } /* dump VBT contents in human readable form */ static void dump_vbt(const struct fileobject *fo) { if (fo->size < sizeof(struct vbt_header)) return; const struct vbt_header *head = (const struct vbt_header *)fo->data; const struct bdb_header *bdb; const u8 *ptr; int i; int is_first_skip = 1; printt("signature: <%20.20s>\n", head->signature); printt("version: %d.%02d\n", head->version / 100, head->version % 100); if (head->header_size != sizeof(struct vbt_header)) printt("header size: 0x%x\n", head->header_size); printt("VBT size: 0x%x\n", head->vbt_size); printt("VBT checksum: 0x%x\n", head->vbt_checksum); if (head->reserved0) printt("header reserved0: 0x%x\n", head->reserved0); if (head->bdb_offset != sizeof(struct vbt_header)) printt("BDB offset: 0x%x\n", head->bdb_offset); for (i = 0; i < 4; i++) if (head->aim_offset[i]) printt("AIM[%d] offset: 0x%x\n", i, head->aim_offset[i]); if (head->bdb_offset + sizeof(*bdb) > fo->size) return; bdb = (const void *) (fo->data + head->bdb_offset); if (memcmp("BIOS_DATA_BLOCK ", bdb->signature, 16) != 0) { printerr("invalid BDB signature:%s\n", bdb->signature); exit(1); } printt("BDB version: %d.%02d\n", bdb->version / 100, bdb->version % 100); if (bdb->header_size != sizeof(struct bdb_header)) printt("BDB header size: 0x%x\n", bdb->header_size); if (bdb->bdb_size != head->vbt_size - head->bdb_offset) printt("BDB size: 0x%x\n", bdb->bdb_size); for (ptr = (const u8 *) bdb + bdb->header_size; ptr < (const u8 *) bdb + bdb->bdb_size;) { u16 secsz = (ptr[1] | (ptr[2] << 8)); u8 sectype = ptr[0]; const u8 *section = ptr + 3; printt("section type %d, size 0x%x\n", sectype, secsz); ptr += secsz + 3; switch (sectype) { case BDB_GENERAL_FEATURES:{ const struct bdb_general_features *sec = (const void *) section; printt("General features:\n"); if (sec->panel_fitting) printt("\tpanel_fitting = 0x%x\n", sec->panel_fitting); if (sec->flexaim) printt("\tflexaim = 0x%x\n", sec->flexaim); if (sec->msg_enable) printt("\tmsg_enable = 0x%x\n", sec->msg_enable); if (sec->clear_screen) printt("\tclear_screen = 0x%x\n", sec->clear_screen); if (sec->color_flip) printt("\tcolor_flip = 0x%x\n", sec->color_flip); if (sec->download_ext_vbt) printt ("\tdownload_ext_vbt = 0x%x\n", sec->download_ext_vbt); printt("\t*enable_ssc = 0x%x\n", sec->enable_ssc); printt("\t*ssc_freq = 0x%x\n", sec->ssc_freq); if (sec->enable_lfp_on_override) printt ("\tenable_lfp_on_override = 0x%x\n", sec->enable_lfp_on_override); if (sec->disable_ssc_ddt) printt ("\tdisable_ssc_ddt = 0x%x\n", sec->disable_ssc_ddt); if (sec->rsvd7) printt("\trsvd7 = 0x%x\n", sec->rsvd7); printt("\t*display_clock_mode = 0x%x\n", sec->display_clock_mode); if (sec->rsvd8) printt("\trsvd8 = 0x%x\n", sec->rsvd8); printt("\tdisable_smooth_vision = 0x%x\n", sec->disable_smooth_vision); if (sec->single_dvi) printt("\tsingle_dvi = 0x%x\n", sec->single_dvi); if (sec->rsvd9) printt("\trsvd9 = 0x%x\n", sec->rsvd9); printt ("\t*fdi_rx_polarity_inverted = 0x%x\n", sec->fdi_rx_polarity_inverted); if (sec->rsvd10) printt("\trsvd10 = 0x%x\n", sec->rsvd10); if (sec->legacy_monitor_detect) printt ("\tlegacy_monitor_detect = 0x%x\n", sec->legacy_monitor_detect); printt("\t*int_crt_support = 0x%x\n", sec->int_crt_support); printt("\t*int_tv_support = 0x%x\n", sec->int_tv_support); if (sec->int_efp_support) printt ("\tint_efp_support = 0x%x\n", sec->int_efp_support); if (sec->dp_ssc_enb) printt("\tdp_ssc_enb = 0x%x\n", sec->dp_ssc_enb); if (sec->dp_ssc_freq) printt("\tdp_ssc_freq = 0x%x\n", sec->dp_ssc_freq); if (sec->rsvd11) printt("\trsvd11 = 0x%x\n", sec->rsvd11); break; } case BDB_DRIVER_FEATURES:{ const struct bdb_driver_features *sec = (const void *) section; printt("\t*LVDS config: %d\n", sec->lvds_config); printt("\t*Dual frequency: %d\n", sec->dual_frequency); break; } case BDB_SDVO_LVDS_OPTIONS:{ const struct bdb_sdvo_lvds_options *sec = (const void *) section; printt("\t*Panel type: %d\n", sec->panel_type); break; } case BDB_GENERAL_DEFINITIONS:{ const struct bdb_general_definitions *sec = (const void *) section; int ndev; printt("\t*CRT DDC GMBUS pin: %d\n", sec->crt_ddc_gmbus_pin); printt("\tDPMS ACPI: %d\n", sec->dpms_acpi); printt("\tSkip boot CRT detect: %d\n", sec->skip_boot_crt_detect); printt("\tDPMS aim: %d\n", sec->dpms_aim); if (sec->rsvd1) printt("\trsvd1: 0x%x\n", sec->rsvd1); printt("\tboot_display: { %x, %x }\n", sec->boot_display[0], sec->boot_display[1]); if (sec->child_dev_size != sizeof(struct common_child_dev_config)) printt("\tchild_dev_size: %d\n", sec->child_dev_size); ndev = (secsz - sizeof(*sec)) / sizeof(struct common_child_dev_config); printt("\t%d devices\n", ndev); for (i = 0; i < ndev; i++) { printt("\t*device type: %x ", sec->devices[i]. device_type); #define DEVICE_TYPE_INT_LFP 0x1022 #define DEVICE_TYPE_INT_TV 0x1009 #define DEVICE_TYPE_EFP_DVI_HOTPLUG_PWR 0x6052 switch (sec->devices[i].device_type) { case DEVICE_TYPE_INT_LFP: printt("(flat panel)\n"); break; case DEVICE_TYPE_INT_TV: printt("(TV)\n"); break; case DEVICE_TYPE_EFP_DVI_HOTPLUG_PWR: printt ("(DVI)\n"); break; case 0: printt("(Empty)\n"); break; default: printt("(Unknown)\n"); break; } if (!sec->devices[i].device_type) continue; printt("\t *dvo_port: %x\n", sec->devices[i].dvo_port); printt("\t *i2c_pin: %x\n", sec->devices[i].i2c_pin); printt("\t *slave_addr: %x\n", sec->devices[i].slave_addr); printt("\t *ddc_pin: %x\n", sec->devices[i].ddc_pin); printt("\t *dvo_wiring: %x\n", sec->devices[i].dvo_wiring); printt("\t edid_ptr: %x\n", sec->devices[i].edid_ptr); } break; } case BDB_SKIP:{ const struct vbios_data *sec = (const void *) section; if (!is_first_skip) break; is_first_skip = 0; printt("\ttype: %x\n", sec->type); printt("\trelstage: %x\n", sec->relstage); printt("\tchipset: %x\n", sec->chipset); printt(sec->lvds_present ? "\tLVDS\n" : "\tNo LVDS\n"); printt(sec->tv_present ? "\tTV\n" : "\tNo TV\n"); if (sec->rsvd2) printt("\trsvd2: 0x%x\n", sec->rsvd2); for (i = 0; i < 4; i++) if (sec->rsvd3[i]) printt ("\trsvd3[%d]: 0x%x\n", i, sec->rsvd3[i]); printt("\tSignon: %.155s\n", sec->signon); printt("\tCopyright: %.155s\n", sec->copyright); printt("\tCode segment: %x\n", sec->code_segment); printt("\tDOS Boot mode: %x\n", sec->dos_boot_mode); printt("\tBandwidth percent: %x\n", sec->bandwidth_percent); if (sec->rsvd4) printt("\trsvd4: 0x%x\n", sec->rsvd4); printt("\tBandwidth percent: %x\n", sec->resize_pci_bios); if (sec->rsvd5) printt("\trsvd5: 0x%x\n", sec->rsvd5); break; } } } } /* Returns a new fileobject containing a valid VBT */ static void parse_vbt(const struct fileobject *fo, struct fileobject **vbt) { *vbt = NULL; if (fo->size < sizeof(struct vbt_header)) { printerr("image is too small\n"); return; } const struct vbt_header *head = (const struct vbt_header *)fo->data; if (memcmp(head->signature, "$VBT", 4) != 0) { printerr("invalid VBT signature\n"); return; } if (!head->vbt_size || head->vbt_size > fo->size) { printerr("invalid VBT size\n"); return; } if (!head->bdb_offset || head->bdb_offset > fo->size - sizeof(struct bdb_header)) { printerr("invalid BDB offset\n"); return; } if (!head->header_size || head->header_size > fo->size) { printerr("invalid header size\n"); return; } const struct bdb_header *const bdb_head = (const struct bdb_header *)((const u8 *)head + head->bdb_offset); if (memcmp(bdb_head->signature, "BIOS_DATA_BLOCK ", 16) != 0) { printerr("invalid BDB signature\n"); return; } if (!bdb_head->header_size || bdb_head->header_size > fo->size) { printerr("invalid BDB header size\n"); return; } /* Duplicate fo as caller is owner and remalloc frees the object */ struct fileobject *dupfo = malloc_fo_sub(fo, 0); if (!dupfo) { printerr("malloc failed\n"); return; } struct fileobject *newfo = remalloc_fo(dupfo, head->vbt_size); if (!newfo) { printerr("remalloc failed\n"); free_fo(dupfo); return; } *vbt = newfo; } /* Option ROM checksum */ static u8 checksum_vbios(const optionrom_header_t *oh) { const u8 *ptr = (const u8 *)oh; size_t i; u8 cksum = 0; for (i = 0; i < ((MIN(oh->size, 128)) * 512); i++) cksum += ptr[i]; return cksum; } /* Verify Option ROM contents */ static int is_valid_vbios(const struct fileobject *fo) { if (fo->size > 64 * 2 * KiB) { printerr("VBIOS is too big\n"); return 0; } if (fo->size < sizeof(optionrom_header_t)) { printerr("VBIOS is too small\n"); return 0; } const optionrom_header_t *oh = (const optionrom_header_t *)fo->data; if (oh->signature != 0xaa55) { printerr("bad oprom signature: 0x%x\n", oh->signature); return 0; } if (oh->size == 0 || oh->size > 0x80 || oh->size * 512 > fo->size) { printerr("bad oprom size: 0x%x\n", oh->size); return 0; } const u8 cksum = checksum_vbios(oh); if (cksum) { if (!ignore_checksum) { printerr("bad oprom checksum: 0x%x\n", cksum); return 0; } printwarn("bad oprom checksum: 0x%x\n", cksum); } if (oh->pcir_offset + sizeof(optionrom_pcir_t) > fo->size) { printerr("bad pcir offset: 0x%x\n", oh->pcir_offset); return 0; } if (oh->pcir_offset) { const optionrom_pcir_t *pcir; pcir = (const optionrom_pcir_t *) ((const u8 *)oh + oh->pcir_offset); if (pcir->signature != 0x52494350) { printerr("Invalid PCIR signature\n"); return 0; } if (pcir->vendor != 0x8086) { printerr("Not an Intel VBIOS\n"); return 0; } if (pcir->classcode[0] != 0 || pcir->classcode[1] != 0 || pcir->classcode[2] != 3) { printerr("Not a VGA Option Rom\n"); return 0; } } else { printwarn("no PCIR header found\n"); } return 1; } /* * Parse Option ROM and return a valid VBT fileobject. * Caller has to make sure that it is a valid VBIOS. * Return a NULL fileobject on error. */ static void parse_vbios(const struct fileobject *fo, struct fileobject **vbt) { const optionrom_header_t *oh = (const optionrom_header_t *)fo->data; size_t i; *vbt = NULL; if (!oh->vbt_offset) { printerr("no VBT found\n"); return; } if (oh->vbt_offset > (fo->size - sizeof(struct vbt_header))) { printerr("invalid VBT offset\n"); return; } struct fileobject *fo_vbt = malloc_fo_sub(fo, oh->vbt_offset); if (fo_vbt) { parse_vbt(fo_vbt, vbt); free_fo(fo_vbt); if (*vbt) return; } printwarn("VBT wasn't found at specified offset of %04x\n", oh->vbt_offset); for (i = sizeof(optionrom_header_t); i <= fo->size - sizeof(struct vbt_header); i++) { struct fileobject *fo_vbt = malloc_fo_sub(fo, i); if (!fo_vbt) break; parse_vbt(fo_vbt, vbt); free_fo(fo_vbt); if (*vbt) return; } } /* Short VBT summary in human readable form */ static void print_vbt(const struct fileobject *fo) { const struct bdb_header *bdb; if (fo->size < sizeof(struct vbt_header)) return; const struct vbt_header *head = (const struct vbt_header *)fo->data; print("Found VBT:\n"); printt("signature: <%20.20s>\n", head->signature); printt("version: %d.%02d\n", head->version / 100, head->version % 100); if (head->header_size != sizeof(struct vbt_header)) printt("header size: 0x%x\n", head->header_size); printt("VBT size: 0x%x\n", head->vbt_size); printt("VBT checksum: 0x%x\n", head->vbt_checksum); if (head->bdb_offset > (fo->size - sizeof(struct bdb_header))) { printerr("invalid BDB offset\n"); return; } bdb = (const struct bdb_header *) ((const char *)head + head->bdb_offset); if (memcmp("BIOS_DATA_BLOCK ", bdb->signature, 16) != 0) { printerr("invalid BDB signature:%s\n", bdb->signature); return; } printt("BDB version: %u.%02u\n", bdb->version / 100, bdb->version % 100); } static void print_usage(const char *argv0, struct option *long_options) { size_t i = 0; printf("\nUsage:\n"); printf("%s -- [filename] -- [filename]\n\n", argv0); printf("SOURCECMD set the VBT source. Supported:\n"); printf(" %-10s: Legacy BIOS area at phys. memory 0xc0000\n", "inlegacy"); printf(" %-10s: Read raw Intel VBT file\n", "invbt"); printf(" %-10s: Read VBT from Intel Option ROM file\n\n", "inoprom"); printf("DESTCMD set the VBT destination. Supported:\n"); printf(" %-10s: Print VBT in human readable form\n", "outdump"); printf(" %-10s: Write raw Intel VBT file\n", "outvbt"); printf(" %-10s: Patch existing Intel Option ROM\n\n", "patchoprom"); printf("Supported arguments:\n"); while (long_options[i].name) { printf("\t-%c --%s %s\n", long_options[i].val, long_options[i].name, long_options[i].has_arg ? "" : ""); i++; }; } /* Fix VBIOS header and PCIR */ static int fix_vbios_header(struct fileobject *fo) { if (!fo || fo->size < sizeof(optionrom_header_t)) return 1; optionrom_header_t *oh = (optionrom_header_t *)fo->data; /* Fix size alignment */ if (fo->size % 512) { print("Aligning size to 512\n"); fo = remalloc_fo(fo, (fo->size + 511) / 512 * 512); if (!fo) return 1; oh = (optionrom_header_t *)fo->data; } /* Fix size field */ oh->size = fo->size / 512; /* Fix checksum field */ oh->checksum = -(checksum_vbios(oh) - oh->checksum); return 0; } /* Return the VBT structure size in bytes */ static size_t vbt_size(const struct fileobject *fo) { if (!fo || fo->size < sizeof(struct vbt_header)) return 0; const struct vbt_header *head = (const struct vbt_header *)fo->data; return head->vbt_size; } /* * Patch an Intel Option ROM with new VBT. * Caller has to make sure that VBIOS and VBT are valid. * Return 1 on error. */ static int patch_vbios(struct fileobject *fo, const struct fileobject *fo_vbt) { optionrom_header_t *oh = (optionrom_header_t *)fo->data; struct vbt_header *head; struct fileobject *old_vbt = NULL; parse_vbios(fo, &old_vbt); if (old_vbt) { if (oh->vbt_offset + vbt_size(old_vbt) == fo->size) { /* Located at the end of file - reduce file size */ if (fo->size < vbt_size(old_vbt)) { free_fo(old_vbt); return 1; } fo = remalloc_fo(fo, fo->size - vbt_size(old_vbt)); if (!fo) { printerr("Failed to allocate memory\n"); free_fo(old_vbt); return 1; } oh = (optionrom_header_t *)fo->data; oh->vbt_offset = 0; } else if (vbt_size(old_vbt) < vbt_size(fo_vbt)) { /* In the middle of the file - Remove old VBT */ memset(fo->data + oh->vbt_offset, 0xff, vbt_size(old_vbt)); oh->vbt_offset = 0; } else { /* New VBT overwrites existing one - Clear memory */ memset(fo->data + oh->vbt_offset, 0xff, vbt_size(old_vbt)); } free_fo(old_vbt); } if (!oh->vbt_offset) { print("increasing VBIOS to append VBT\n"); if ((fo->size + vbt_size(fo_vbt)) >= 2 * 64 * KiB) { printerr("VBT won't fit\n"); return 1; } oh->vbt_offset = fo->size; fo = remalloc_fo(fo, fo->size + vbt_size(fo_vbt)); if (!fo) { printerr("Failed to allocate memory\n"); return 1; } oh = (optionrom_header_t *)fo->data; } head = (struct vbt_header *)((u8 *)oh + oh->vbt_offset); memcpy(head, fo_vbt->data, vbt_size(fo_vbt)); return 0; } int main(int argc, char **argv) { int opt, ret, option_index = 0; size_t has_input = 0, has_output = 0; size_t dump = 0, in_legacy = 0; char *in_vbt = NULL, *in_oprom = NULL; char *out_vbt = NULL, *patch_oprom = NULL; static struct option long_options[] = { {"help", 0, 0, 'h'}, {"outdump", 0, 0, 'd'}, {"inlegacy", 0, 0, 'l'}, {"invbt", required_argument, 0, 'f'}, {"inoprom", required_argument, 0, 'o'}, {"outvbt", required_argument, 0, 'v'}, {"patchoprom", required_argument, 0, 'p'}, {0, 0, 0, 0} }; while ((opt = getopt_long(argc, argv, "hdlf:o:v:p:i", long_options, &option_index)) != EOF) { switch (opt) { case 'd': dump = 1; has_output = 1; break; case 'l': in_legacy = 1; has_input = 1; break; case 'f': in_vbt = strdup(optarg); has_input = 1; break; case 'o': in_oprom = strdup(optarg); has_input = 1; break; case 'v': out_vbt = strdup(optarg); has_output = 1; break; case 'p': patch_oprom = strdup(optarg); has_output = 1; break; case '?': case 'h': print_usage(argv[0], long_options); exit(0); break; } } if (!has_input) printerr("No input specified !\n"); if (!has_output) printerr("No output specified !\n"); if (argc < 2 || argc > 6 || !has_input || !has_output) { print_usage(argv[0], long_options); return 1; } struct fileobject *fo; if (in_legacy) fo = read_physmem(0xc0000); else if (in_vbt) fo = read_file(in_vbt); else fo = read_file(in_oprom); if (!fo) { printerr("Failed to read input file\n"); return 1; } struct fileobject *vbt = NULL; if (in_legacy || in_oprom) { if (!is_valid_vbios(fo)) { printerr("Invalid input file\n"); free_fo(fo); return 1; } parse_vbios(fo, &vbt); } else parse_vbt(fo, &vbt); free_fo(fo); if (!vbt) { printerr("Failed to find VBT.\n"); return 1; } if (!dump) print_vbt(vbt); ret = 0; if (dump) { dump_vbt(vbt); } else if (out_vbt) { if (write_file(out_vbt, vbt)) { printerr("Failed to write VBT\n"); ret = 1; } else { print("VBT written to %s\n", out_vbt); } } else if (patch_oprom) { fo = read_file(patch_oprom); if (!fo) { printerr("Failed to read input file\n"); ret = 1; } if (ret != 1 && !is_valid_vbios(fo)) { printerr("Invalid input file\n"); ret = 1; } if (ret != 1 && patch_vbios(fo, vbt)) { printerr("Failed to patch VBIOS\n"); ret = 1; } if (ret != 1 && fix_vbios_header(fo)) { printerr("Failed to fix VBIOS header\n"); ret = 1; } if (ret != 1 && write_file(patch_oprom, fo)) { printerr("Failed to write VBIOS\n"); ret = 1; } free_fo(fo); if (ret != 1) print("VBIOS %s successfully patched\n", patch_oprom); } /* cleanup */ if (patch_oprom) free(patch_oprom); if (out_vbt) free(out_vbt); if (in_vbt) free(in_vbt); if (in_oprom) free(in_oprom); free_fo(vbt); return ret; }