#include #include #include #include #include #include #include "bits.h" #include "cta.h" #include "log.h" #include "edid.h" #include "displayid.h" /** * Number of bytes in the CTA header (tag + revision + DTD offset + flags). */ #define CTA_HEADER_SIZE 4 /** * Exclusive upper bound for the detailed timing definitions in the CTA block. */ #define CTA_DTD_END 127 /** * Number of bytes in a CTA short audio descriptor. */ #define CTA_SAD_SIZE 3 /** * Number of bytes in a HDMI 3D audio descriptor. */ #define CTA_HDMI_AUDIO_3D_DESCRIPTOR_SIZE 4 const struct di_cta_video_format * di_cta_video_format_from_vic(uint8_t vic) { if (vic > _di_cta_video_formats_len || _di_cta_video_formats[vic].vic == 0) return NULL; return &_di_cta_video_formats[vic]; } static void add_failure(struct di_edid_cta *cta, const char fmt[], ...) { va_list args; va_start(args, fmt); _di_logger_va_add_failure(cta->logger, fmt, args); va_end(args); } static void add_failure_until(struct di_edid_cta *cta, int revision, const char fmt[], ...) { va_list args; if (cta->revision > revision) { return; } va_start(args, fmt); _di_logger_va_add_failure(cta->logger, fmt, args); va_end(args); } static struct di_cta_svd * parse_svd(struct di_edid_cta *cta, uint8_t raw, const char *prefix) { struct di_cta_svd svd, *svd_ptr; if (raw == 0 || raw == 128 || raw >= 254) { /* Reserved */ add_failure_until(cta, 3, "%s: Unknown VIC %" PRIu8 ".", prefix, raw); return NULL; } else if (raw <= 127 || raw >= 193) { svd = (struct di_cta_svd) { .vic = raw, }; } else { svd = (struct di_cta_svd) { .vic = get_bit_range(raw, 6, 0), .native = true, }; } svd_ptr = calloc(1, sizeof(*svd_ptr)); if (!svd_ptr) return NULL; *svd_ptr = svd; return svd_ptr; } static bool parse_video_block(struct di_edid_cta *cta, struct di_cta_video_block_priv *video, const uint8_t *data, size_t size) { size_t i; struct di_cta_svd *svd; if (size == 0) add_failure(cta, "Video Data Block: Empty Data Block"); for (i = 0; i < size; i++) { svd = parse_svd(cta, data[i], "Video Data Block"); if (!svd) continue; assert(video->svds_len < EDID_CTA_MAX_VIDEO_BLOCK_ENTRIES); video->svds[video->svds_len++] = svd; } video->base.svds = (const struct di_cta_svd *const *)video->svds; return true; } static bool parse_ycbcr420_block(struct di_edid_cta *cta, struct di_cta_ycbcr420_video_block_priv *ycbcr420, const uint8_t *data, size_t size) { size_t i; struct di_cta_svd *svd; if (size == 0) add_failure(cta, "YCbCr 4:2:0 Video Data Block: Empty Data Block"); for (i = 0; i < size; i++) { svd = parse_svd(cta, data[i], "YCbCr 4:2:0 Video Data Block"); if (!svd) continue; assert(ycbcr420->svds_len < EDID_CTA_MAX_VIDEO_BLOCK_ENTRIES); ycbcr420->svds[ycbcr420->svds_len++] = svd; } ycbcr420->base.svds = (const struct di_cta_svd *const *)ycbcr420->svds; return true; } static bool parse_sad_format(struct di_edid_cta *cta, uint8_t code, uint8_t code_ext, enum di_cta_audio_format *format, const char *prefix) { switch (code) { case 0x0: add_failure_until(cta, 3, "%s: Audio Format Code 0x00 is reserved.", prefix); return false; case 0x1: *format = DI_CTA_AUDIO_FORMAT_LPCM; break; case 0x2: *format = DI_CTA_AUDIO_FORMAT_AC3; break; case 0x3: *format = DI_CTA_AUDIO_FORMAT_MPEG1; break; case 0x4: *format = DI_CTA_AUDIO_FORMAT_MP3; break; case 0x5: *format = DI_CTA_AUDIO_FORMAT_MPEG2; break; case 0x6: *format = DI_CTA_AUDIO_FORMAT_AAC_LC; break; case 0x7: *format = DI_CTA_AUDIO_FORMAT_DTS; break; case 0x8: *format = DI_CTA_AUDIO_FORMAT_ATRAC; break; case 0x9: *format = DI_CTA_AUDIO_FORMAT_ONE_BIT_AUDIO; break; case 0xA: *format = DI_CTA_AUDIO_FORMAT_ENHANCED_AC3; break; case 0xB: *format = DI_CTA_AUDIO_FORMAT_DTS_HD; break; case 0xC: *format = DI_CTA_AUDIO_FORMAT_MAT; break; case 0xD: *format = DI_CTA_AUDIO_FORMAT_DST; break; case 0xE: *format = DI_CTA_AUDIO_FORMAT_WMA_PRO; break; case 0xF: switch (code_ext) { case 0x04: *format = DI_CTA_AUDIO_FORMAT_MPEG4_HE_AAC; break; case 0x05: *format = DI_CTA_AUDIO_FORMAT_MPEG4_HE_AAC_V2; break; case 0x06: *format = DI_CTA_AUDIO_FORMAT_MPEG4_AAC_LC; break; case 0x07: *format = DI_CTA_AUDIO_FORMAT_DRA; break; case 0x08: *format = DI_CTA_AUDIO_FORMAT_MPEG4_HE_AAC_MPEG_SURROUND; break; case 0x0A: *format = DI_CTA_AUDIO_FORMAT_MPEG4_AAC_LC_MPEG_SURROUND; break; case 0x0B: *format = DI_CTA_AUDIO_FORMAT_MPEGH_3D; break; case 0x0C: *format = DI_CTA_AUDIO_FORMAT_AC4; break; case 0x0D: *format = DI_CTA_AUDIO_FORMAT_LPCM_3D; break; default: add_failure_until(cta, 3, "%s: Unknown Audio Ext Format 0x%02x.", prefix, code_ext); return false; } break; default: add_failure_until(cta, 3, "%s: Unknown Audio Format 0x%02x.", prefix, code); return false; } return true; } static bool parse_sad(struct di_edid_cta *cta, struct di_cta_audio_block_priv *audio, const uint8_t data[static CTA_SAD_SIZE]) { enum di_cta_audio_format format; struct di_cta_sad_priv *priv; struct di_cta_sad *sad; struct di_cta_sad_sample_rates *sample_rates; struct di_cta_sad_lpcm *lpcm; struct di_cta_sad_mpegh_3d *mpegh_3d; struct di_cta_sad_mpeg_aac *mpeg_aac; struct di_cta_sad_mpeg_surround *mpeg_surround; struct di_cta_sad_mpeg_aac_le *mpeg_aac_le; struct di_cta_sad_enhanced_ac3 *enhanced_ac3; struct di_cta_sad_mat *mat; struct di_cta_sad_wma_pro *wma_pro; uint8_t code, code_ext; code = get_bit_range(data[0], 6, 3); code_ext = get_bit_range(data[2], 7, 3); if (!parse_sad_format(cta, code, code_ext, &format, "Audio Data Block")) return true; priv = calloc(1, sizeof(*priv)); if (!priv) return false; sad = &priv->base; sample_rates = &priv->supported_sample_rates; lpcm = &priv->lpcm; mpegh_3d = &priv->mpegh_3d; mpeg_aac = &priv->mpeg_aac; mpeg_surround = &priv->mpeg_surround; mpeg_aac_le = &priv->mpeg_aac_le; enhanced_ac3 = &priv->enhanced_ac3; mat = &priv->mat; wma_pro = &priv->wma_pro; sad->format = format; /* TODO: Find DRA documentation */ switch (format) { case DI_CTA_AUDIO_FORMAT_LPCM: case DI_CTA_AUDIO_FORMAT_AC3: case DI_CTA_AUDIO_FORMAT_MPEG1: case DI_CTA_AUDIO_FORMAT_MP3: case DI_CTA_AUDIO_FORMAT_MPEG2: case DI_CTA_AUDIO_FORMAT_AAC_LC: case DI_CTA_AUDIO_FORMAT_DTS: case DI_CTA_AUDIO_FORMAT_ATRAC: case DI_CTA_AUDIO_FORMAT_ONE_BIT_AUDIO: case DI_CTA_AUDIO_FORMAT_ENHANCED_AC3: case DI_CTA_AUDIO_FORMAT_DTS_HD: case DI_CTA_AUDIO_FORMAT_MAT: case DI_CTA_AUDIO_FORMAT_DST: case DI_CTA_AUDIO_FORMAT_WMA_PRO: case DI_CTA_AUDIO_FORMAT_MPEG4_HE_AAC: case DI_CTA_AUDIO_FORMAT_MPEG4_HE_AAC_V2: case DI_CTA_AUDIO_FORMAT_MPEG4_AAC_LC: /* DRA is not documented but this is what edid-decode does */ case DI_CTA_AUDIO_FORMAT_DRA: case DI_CTA_AUDIO_FORMAT_MPEG4_HE_AAC_MPEG_SURROUND: case DI_CTA_AUDIO_FORMAT_MPEG4_AAC_LC_MPEG_SURROUND: sad->max_channels = get_bit_range(data[0], 2, 0) + 1; break; case DI_CTA_AUDIO_FORMAT_LPCM_3D: sad->max_channels = (get_bit_range(data[0], 2, 0) | (get_bit_range(data[0], 7, 7) << 3) | (get_bit_range(data[1], 7, 7) << 4)) + 1; break; case DI_CTA_AUDIO_FORMAT_MPEGH_3D: case DI_CTA_AUDIO_FORMAT_AC4: break; } switch (format) { case DI_CTA_AUDIO_FORMAT_LPCM: case DI_CTA_AUDIO_FORMAT_AC3: case DI_CTA_AUDIO_FORMAT_MPEG1: case DI_CTA_AUDIO_FORMAT_MP3: case DI_CTA_AUDIO_FORMAT_MPEG2: case DI_CTA_AUDIO_FORMAT_AAC_LC: case DI_CTA_AUDIO_FORMAT_DTS: case DI_CTA_AUDIO_FORMAT_ATRAC: case DI_CTA_AUDIO_FORMAT_ONE_BIT_AUDIO: case DI_CTA_AUDIO_FORMAT_ENHANCED_AC3: case DI_CTA_AUDIO_FORMAT_DTS_HD: case DI_CTA_AUDIO_FORMAT_MAT: case DI_CTA_AUDIO_FORMAT_DST: case DI_CTA_AUDIO_FORMAT_WMA_PRO: /* DRA is not documented but this is what edid-decode does */ case DI_CTA_AUDIO_FORMAT_DRA: case DI_CTA_AUDIO_FORMAT_MPEGH_3D: case DI_CTA_AUDIO_FORMAT_LPCM_3D: sample_rates->has_192_khz = has_bit(data[1], 6); sample_rates->has_176_4_khz = has_bit(data[1], 5); /* fallthrough */ case DI_CTA_AUDIO_FORMAT_MPEG4_HE_AAC: case DI_CTA_AUDIO_FORMAT_MPEG4_HE_AAC_V2: case DI_CTA_AUDIO_FORMAT_MPEG4_AAC_LC: case DI_CTA_AUDIO_FORMAT_MPEG4_HE_AAC_MPEG_SURROUND: case DI_CTA_AUDIO_FORMAT_MPEG4_AAC_LC_MPEG_SURROUND: sample_rates->has_96_khz = has_bit(data[1], 4); sample_rates->has_88_2_khz = has_bit(data[1], 3); sample_rates->has_48_khz = has_bit(data[1], 2); sample_rates->has_44_1_khz = has_bit(data[1], 1); sample_rates->has_32_khz = has_bit(data[1], 0); break; case DI_CTA_AUDIO_FORMAT_AC4: sample_rates->has_192_khz = has_bit(data[1], 6); sample_rates->has_96_khz = has_bit(data[1], 4); sample_rates->has_48_khz = has_bit(data[1], 2); sample_rates->has_44_1_khz = has_bit(data[1], 1); break; } sad->supported_sample_rates = sample_rates; switch (format) { case DI_CTA_AUDIO_FORMAT_AC3: case DI_CTA_AUDIO_FORMAT_MPEG1: case DI_CTA_AUDIO_FORMAT_MP3: case DI_CTA_AUDIO_FORMAT_MPEG2: case DI_CTA_AUDIO_FORMAT_AAC_LC: case DI_CTA_AUDIO_FORMAT_DTS: case DI_CTA_AUDIO_FORMAT_ATRAC: sad->max_bitrate_kbs = data[2] * 8; break; default: break; } switch (format) { case DI_CTA_AUDIO_FORMAT_LPCM: case DI_CTA_AUDIO_FORMAT_LPCM_3D: lpcm->has_sample_size_24_bits = has_bit(data[2], 2); lpcm->has_sample_size_20_bits = has_bit(data[2], 1); lpcm->has_sample_size_16_bits = has_bit(data[2], 0); sad->lpcm = lpcm; default: break; } switch (format) { case DI_CTA_AUDIO_FORMAT_MPEG4_HE_AAC: case DI_CTA_AUDIO_FORMAT_MPEG4_HE_AAC_V2: case DI_CTA_AUDIO_FORMAT_MPEG4_AAC_LC: case DI_CTA_AUDIO_FORMAT_MPEG4_HE_AAC_MPEG_SURROUND: case DI_CTA_AUDIO_FORMAT_MPEG4_AAC_LC_MPEG_SURROUND: mpeg_aac->has_frame_length_1024 = has_bit(data[2], 2); mpeg_aac->has_frame_length_960 = has_bit(data[2], 1); sad->mpeg_aac = mpeg_aac; break; default: break; } if (format == DI_CTA_AUDIO_FORMAT_MPEG4_AAC_LC) { mpeg_aac_le->supports_multichannel_sound = has_bit(data[2], 0); sad->mpeg_aac_le = mpeg_aac_le; } switch (format) { case DI_CTA_AUDIO_FORMAT_MPEG4_HE_AAC_MPEG_SURROUND: case DI_CTA_AUDIO_FORMAT_MPEG4_AAC_LC_MPEG_SURROUND: mpeg_surround->signaling = has_bit(data[2], 0); sad->mpeg_surround = mpeg_surround; break; default: break; } if (format == DI_CTA_AUDIO_FORMAT_MPEGH_3D) { mpegh_3d->low_complexity_profile = has_bit(data[2], 0); mpegh_3d->baseline_profile = has_bit(data[2], 1); mpegh_3d->level = get_bit_range(data[0], 2, 0); if (mpegh_3d->level > DI_CTA_SAD_MPEGH_3D_LEVEL_5) { add_failure_until(cta, 3, "Unknown MPEG-H 3D Audio Level 0x%02x.", mpegh_3d->level); mpegh_3d->level = DI_CTA_SAD_MPEGH_3D_LEVEL_UNSPECIFIED; } sad->mpegh_3d = mpegh_3d; } if (format == DI_CTA_AUDIO_FORMAT_ENHANCED_AC3) { enhanced_ac3->supports_joint_object_coding = has_bit(data[2], 0); enhanced_ac3->supports_joint_object_coding_ACMOD28 = has_bit(data[2], 1); sad->enhanced_ac3 = enhanced_ac3; } if (format == DI_CTA_AUDIO_FORMAT_MAT) { mat->supports_object_audio_and_channel_based = has_bit(data[2], 0); if (mat->supports_object_audio_and_channel_based) mat->requires_hash_calculation = !has_bit(data[2], 0); sad->mat = mat; } if (format == DI_CTA_AUDIO_FORMAT_WMA_PRO) { wma_pro->profile = get_bit_range(data[2], 2, 0); sad->wma_pro = wma_pro; } switch (format) { case DI_CTA_AUDIO_FORMAT_ONE_BIT_AUDIO: case DI_CTA_AUDIO_FORMAT_DTS_HD: case DI_CTA_AUDIO_FORMAT_DST: /* TODO data[2] 7:0 contains unknown Audio Format Code dependent value */ break; default: break; } if (format == DI_CTA_AUDIO_FORMAT_AC4) { /* TODO data[2] 2:0 contains unknown Audio Format Code dependent value */ } switch (format) { case DI_CTA_AUDIO_FORMAT_LPCM: case DI_CTA_AUDIO_FORMAT_WMA_PRO: if (has_bit(data[0], 7) || has_bit(data[1], 7) || get_bit_range(data[2], 7, 3) != 0) add_failure_until(cta, 3, "Bits F17, F27, F37:F33 must be 0."); break; case DI_CTA_AUDIO_FORMAT_AC3: case DI_CTA_AUDIO_FORMAT_MPEG1: case DI_CTA_AUDIO_FORMAT_MP3: case DI_CTA_AUDIO_FORMAT_MPEG2: case DI_CTA_AUDIO_FORMAT_AAC_LC: case DI_CTA_AUDIO_FORMAT_DTS: case DI_CTA_AUDIO_FORMAT_ATRAC: case DI_CTA_AUDIO_FORMAT_ONE_BIT_AUDIO: case DI_CTA_AUDIO_FORMAT_ENHANCED_AC3: case DI_CTA_AUDIO_FORMAT_DTS_HD: case DI_CTA_AUDIO_FORMAT_MAT: case DI_CTA_AUDIO_FORMAT_DST: if (has_bit(data[0], 7) || has_bit(data[1], 7)) add_failure_until(cta, 3, "Bits F17, F27 must be 0."); break; case DI_CTA_AUDIO_FORMAT_MPEG4_HE_AAC: case DI_CTA_AUDIO_FORMAT_MPEG4_HE_AAC_V2: case DI_CTA_AUDIO_FORMAT_MPEG4_AAC_LC: case DI_CTA_AUDIO_FORMAT_MPEG4_HE_AAC_MPEG_SURROUND: case DI_CTA_AUDIO_FORMAT_MPEG4_AAC_LC_MPEG_SURROUND: if (has_bit(data[0], 7) || get_bit_range(data[2], 7, 5) != 0) add_failure_until(cta, 3, "Bits F17, F27:F25 must be 0."); break; case DI_CTA_AUDIO_FORMAT_MPEGH_3D: if (has_bit(data[0], 7) || has_bit(data[1], 7) || has_bit(data[2], 2)) add_failure_until(cta, 3, "Bits F17, F27, F32 must be 0."); break; case DI_CTA_AUDIO_FORMAT_AC4: if ((data[0] & 0x87) != 0 || (data[1] & 0xA9) != 0) add_failure_until(cta, 3, "Bits F17, F12:F10, F27, F25, F23, " "F20 must be 0."); break; /* DRA documentation missing */ case DI_CTA_AUDIO_FORMAT_DRA: case DI_CTA_AUDIO_FORMAT_LPCM_3D: break; } assert(audio->sads_len < EDID_CTA_MAX_AUDIO_BLOCK_ENTRIES); audio->sads[audio->sads_len++] = priv; return true; } static bool parse_audio_block(struct di_edid_cta *cta, struct di_cta_audio_block_priv *audio, const uint8_t *data, size_t size) { size_t i; if (size % 3 != 0) add_failure(cta, "Broken CTA-861 audio block length %d.", size); for (i = 0; i + 3 <= size; i += 3) { if (!parse_sad(cta, audio, &data[i])) return false; } audio->audio.sads = (const struct di_cta_sad *const *) audio->sads; return true; } static bool parse_speaker_alloc(struct di_edid_cta *cta, struct di_cta_speaker_allocation *speaker_alloc, const uint8_t data[3], const char *prefix) { bool rlc_rrc; speaker_alloc->flw_frw = has_bit(data[0], 7); rlc_rrc = has_bit(data[0], 6); speaker_alloc->flc_frc = has_bit(data[0], 5); speaker_alloc->bc = has_bit(data[0], 4); speaker_alloc->bl_br = has_bit(data[0], 3); speaker_alloc->fc = has_bit(data[0], 2); speaker_alloc->lfe1 = has_bit(data[0], 1); speaker_alloc->fl_fr = has_bit(data[0], 0); if (rlc_rrc) { if (cta->revision >= 3) add_failure(cta, "%s: Deprecated bit F16 must be 0.", prefix); else speaker_alloc->bl_br = true; } speaker_alloc->tpsil_tpsir = has_bit(data[1], 7); speaker_alloc->sil_sir = has_bit(data[1], 6); speaker_alloc->tpbc = has_bit(data[1], 5); speaker_alloc->lfe2 = has_bit(data[1], 4); speaker_alloc->ls_rs = has_bit(data[1], 3); speaker_alloc->tpfc = has_bit(data[1], 2); speaker_alloc->tpc = has_bit(data[1], 1); speaker_alloc->tpfl_tpfr = has_bit(data[1], 0); if (get_bit_range(data[2], 7, 4) != 0) add_failure(cta, "%s: Bits F37, F36, F34 must be 0.", prefix); if (cta->revision >= 3 && has_bit(data[2], 3)) add_failure(cta, "%s: Deprecated bit F33 must be 0.", prefix); speaker_alloc->btfl_btfr = has_bit(data[2], 2); speaker_alloc->btfc = has_bit(data[2], 1); speaker_alloc->tpbl_tpbr = has_bit(data[2], 0); return true; } static bool parse_speaker_alloc_block(struct di_edid_cta *cta, struct di_cta_speaker_alloc_block *speaker_alloc, const uint8_t *data, size_t size) { if (size < 3) { add_failure(cta, "Speaker Allocation Data Block: Empty Data Block with length %zu.", size); return false; } parse_speaker_alloc(cta, &speaker_alloc->speakers, data, "Speaker Allocation Data Block"); return true; } static bool parse_video_cap_block(struct di_edid_cta *cta, struct di_cta_video_cap_block *video_cap, const uint8_t *data, size_t size) { if (size < 1) { add_failure(cta, "Video Capability Data Block: Empty Data Block with length %u.", size); return false; } video_cap->selectable_ycc_quantization_range = has_bit(data[0], 7); video_cap->selectable_rgb_quantization_range = has_bit(data[0], 6); video_cap->pt_over_underscan = get_bit_range(data[0], 5, 4); video_cap->it_over_underscan = get_bit_range(data[0], 3, 2); video_cap->ce_over_underscan = get_bit_range(data[0], 1, 0); if (!video_cap->selectable_rgb_quantization_range && cta->revision >= 3) add_failure(cta, "Video Capability Data Block: Set Selectable RGB Quantization to avoid interop issues."); /* TODO: add failure if selectable_ycc_quantization_range is unset, * the sink supports YCbCr formats and the revision is 3+ */ switch (video_cap->it_over_underscan) { case DI_CTA_VIDEO_CAP_ALWAYS_OVERSCAN: if (cta->flags.it_underscan) add_failure(cta, "Video Capability Data Block: IT video formats are always overscanned, but bit 7 of Byte 3 of the CTA-861 Extension header is set to underscanned."); break; case DI_CTA_VIDEO_CAP_ALWAYS_UNDERSCAN: if (!cta->flags.it_underscan) add_failure(cta, "Video Capability Data Block: IT video formats are always underscanned, but bit 7 of Byte 3 of the CTA-861 Extension header is set to overscanned."); default: break; } return true; } static bool check_vesa_display_device_num_channels(enum di_cta_vesa_display_device_interface_type interface, uint8_t num_channels) { switch (interface) { case DI_CTA_VESA_DISPLAY_DEVICE_INTERFACE_VGA: case DI_CTA_VESA_DISPLAY_DEVICE_INTERFACE_NAVI_V: case DI_CTA_VESA_DISPLAY_DEVICE_INTERFACE_NAVI_D: return num_channels == 0; case DI_CTA_VESA_DISPLAY_DEVICE_INTERFACE_LVDS: case DI_CTA_VESA_DISPLAY_DEVICE_INTERFACE_RSDS: return true; case DI_CTA_VESA_DISPLAY_DEVICE_INTERFACE_DVI_D: return num_channels == 1 || num_channels == 2; case DI_CTA_VESA_DISPLAY_DEVICE_INTERFACE_DVI_I_ANALOG: return num_channels == 0; case DI_CTA_VESA_DISPLAY_DEVICE_INTERFACE_DVI_I_DIGITAL: return num_channels == 1 || num_channels == 2; case DI_CTA_VESA_DISPLAY_DEVICE_INTERFACE_HDMI_A: return num_channels == 1; case DI_CTA_VESA_DISPLAY_DEVICE_INTERFACE_HDMI_B: return num_channels == 2; case DI_CTA_VESA_DISPLAY_DEVICE_INTERFACE_MDDI: return num_channels == 1 || num_channels == 2; case DI_CTA_VESA_DISPLAY_DEVICE_INTERFACE_DISPLAYPORT: return num_channels == 1 || num_channels == 2 || num_channels == 4; case DI_CTA_VESA_DISPLAY_DEVICE_INTERFACE_IEEE_1394: case DI_CTA_VESA_DISPLAY_DEVICE_INTERFACE_M1_ANALOG: return num_channels == 0; case DI_CTA_VESA_DISPLAY_DEVICE_INTERFACE_M1_DIGITAL: return num_channels == 1 || num_channels == 2; } abort(); /* unreachable */ } static void parse_vesa_display_device_additional_primary_chromaticity(struct di_cta_vesa_display_device_additional_primary_chromaticity *coords, uint8_t low, const uint8_t high[static 2]) { uint16_t raw_x, raw_y; /* only 10 bits are used */ raw_x = (uint16_t) ((high[0] << 2) | get_bit_range(low, 3, 2)); raw_y = (uint16_t) ((high[1] << 2) | get_bit_range(low, 1, 0)); *coords = (struct di_cta_vesa_display_device_additional_primary_chromaticity) { .x = (float) raw_x / 1024, .y = (float) raw_y / 1024, }; } static bool parse_vesa_display_device(struct di_edid_cta *cta, struct di_cta_vesa_display_device_block *dddb, const uint8_t *data, size_t size) { const size_t offset = 2; /* CTA block header */ uint8_t interface_type, num_channels, content_protection, scan_direction, subpixel_layout; if (size + offset != 32) { add_failure(cta, "VESA Video Display Device Data Block: Invalid length %u.", size); return false; } interface_type = get_bit_range(data[0x02 - offset], 7, 4); num_channels = get_bit_range(data[0x02 - offset], 3, 0); switch (interface_type) { case 0x0: /* Analog */ /* Special case: num_channels contains the detailed interface * type. */ switch (num_channels) { case 0x0: dddb->interface_type = DI_CTA_VESA_DISPLAY_DEVICE_INTERFACE_VGA; break; case 0x1: dddb->interface_type = DI_CTA_VESA_DISPLAY_DEVICE_INTERFACE_NAVI_V; break; case 0x2: dddb->interface_type = DI_CTA_VESA_DISPLAY_DEVICE_INTERFACE_NAVI_D; break; default: add_failure(cta, "VESA Video Display Device Data Block: Unknown analog interface type 0x%x.", num_channels); return false; } num_channels = 0; break; case 0x1: dddb->interface_type = DI_CTA_VESA_DISPLAY_DEVICE_INTERFACE_LVDS; break; case 0x2: dddb->interface_type = DI_CTA_VESA_DISPLAY_DEVICE_INTERFACE_RSDS; break; case 0x3: dddb->interface_type = DI_CTA_VESA_DISPLAY_DEVICE_INTERFACE_DVI_D; break; case 0x4: dddb->interface_type = DI_CTA_VESA_DISPLAY_DEVICE_INTERFACE_DVI_I_ANALOG; break; case 0x5: dddb->interface_type = DI_CTA_VESA_DISPLAY_DEVICE_INTERFACE_DVI_I_DIGITAL; break; case 0x6: dddb->interface_type = DI_CTA_VESA_DISPLAY_DEVICE_INTERFACE_HDMI_A; break; case 0x7: dddb->interface_type = DI_CTA_VESA_DISPLAY_DEVICE_INTERFACE_HDMI_B; break; case 0x8: dddb->interface_type = DI_CTA_VESA_DISPLAY_DEVICE_INTERFACE_MDDI; break; case 0x9: dddb->interface_type = DI_CTA_VESA_DISPLAY_DEVICE_INTERFACE_DISPLAYPORT; break; case 0xA: dddb->interface_type = DI_CTA_VESA_DISPLAY_DEVICE_INTERFACE_IEEE_1394; break; case 0xB: dddb->interface_type = DI_CTA_VESA_DISPLAY_DEVICE_INTERFACE_M1_ANALOG; break; case 0xC: dddb->interface_type = DI_CTA_VESA_DISPLAY_DEVICE_INTERFACE_M1_DIGITAL; break; default: add_failure(cta, "VESA Video Display Device Data Block: Unknown interface type 0x%x.", interface_type); return false; } if (check_vesa_display_device_num_channels(dddb->interface_type, num_channels)) dddb->num_channels = num_channels; else add_failure(cta, "VESA Video Display Device Data Block: Invalid number of lanes/channels %u.", num_channels); dddb->interface_version = get_bit_range(data[0x03 - offset], 7, 4); dddb->interface_release = get_bit_range(data[0x03 - offset], 3, 0); content_protection = data[0x04 - offset]; switch (content_protection) { case DI_CTA_VESA_DISPLAY_DEVICE_CONTENT_PROTECTION_NONE: case DI_CTA_VESA_DISPLAY_DEVICE_CONTENT_PROTECTION_HDCP: case DI_CTA_VESA_DISPLAY_DEVICE_CONTENT_PROTECTION_DTCP: case DI_CTA_VESA_DISPLAY_DEVICE_CONTENT_PROTECTION_DPCP: dddb->content_protection = content_protection; break; default: add_failure(cta, "VESA Video Display Device Data Block: Invalid content protection 0x%x.", content_protection); } dddb->min_clock_freq_mhz = get_bit_range(data[0x05 - offset], 7, 2); dddb->max_clock_freq_mhz = (get_bit_range(data[0x05 - offset], 1, 0) << 8) | data[0x06 - offset]; if (dddb->min_clock_freq_mhz > dddb->max_clock_freq_mhz) { add_failure(cta, "VESA Video Display Device Data Block: Minimum clock frequency (%d MHz) greater than maximum (%d MHz).", dddb->min_clock_freq_mhz, dddb->max_clock_freq_mhz); dddb->min_clock_freq_mhz = dddb->max_clock_freq_mhz = 0; } dddb->native_horiz_pixels = data[0x07 - offset] | (data[0x08 - offset] << 8); dddb->native_vert_pixels = data[0x09 - offset] | (data[0x0A - offset] << 8); dddb->aspect_ratio = (float)data[0x0B - offset] / 100 + 1; dddb->default_orientation = get_bit_range(data[0x0C - offset], 7, 6); dddb->rotation_cap = get_bit_range(data[0x0C - offset], 5, 4); dddb->zero_pixel_location = get_bit_range(data[0x0C - offset], 3, 2); scan_direction = get_bit_range(data[0x0C - offset], 1, 0); if (scan_direction != 3) dddb->scan_direction = scan_direction; else add_failure(cta, "VESA Video Display Device Data Block: Invalid scan direction 0x%x.", scan_direction); subpixel_layout = data[0x0D - offset]; switch (subpixel_layout) { case DI_CTA_VESA_DISPLAY_DEVICE_SUBPIXEL_UNDEFINED: case DI_CTA_VESA_DISPLAY_DEVICE_SUBPIXEL_RGB_VERT: case DI_CTA_VESA_DISPLAY_DEVICE_SUBPIXEL_RGB_HORIZ: case DI_CTA_VESA_DISPLAY_DEVICE_SUBPIXEL_EDID_CHROM_VERT: case DI_CTA_VESA_DISPLAY_DEVICE_SUBPIXEL_EDID_CHROM_HORIZ: case DI_CTA_VESA_DISPLAY_DEVICE_SUBPIXEL_QUAD_RGGB: case DI_CTA_VESA_DISPLAY_DEVICE_SUBPIXEL_QUAD_GBRG: case DI_CTA_VESA_DISPLAY_DEVICE_SUBPIXEL_DELTA_RGB: case DI_CTA_VESA_DISPLAY_DEVICE_SUBPIXEL_MOSAIC: case DI_CTA_VESA_DISPLAY_DEVICE_SUBPIXEL_QUAD_ANY: case DI_CTA_VESA_DISPLAY_DEVICE_SUBPIXEL_FIVE: case DI_CTA_VESA_DISPLAY_DEVICE_SUBPIXEL_SIX: case DI_CTA_VESA_DISPLAY_DEVICE_SUBPIXEL_CLAIRVOYANTE_PENTILE: dddb->subpixel_layout = subpixel_layout; break; default: add_failure(cta, "VESA Video Display Device Data Block: Invalid subpixel layout 0x%x.", subpixel_layout); } dddb->horiz_pitch_mm = (float)data[0x0E - offset] * 0.01f; dddb->vert_pitch_mm = (float)data[0x0F - offset] * 0.01f; dddb->dithering_type = get_bit_range(data[0x10 - offset], 7, 6); dddb->direct_drive = has_bit(data[0x10 - offset], 5); dddb->overdrive_not_recommended = has_bit(data[0x10 - offset], 4); dddb->deinterlacing = has_bit(data[0x10 - offset], 3); if (get_bit_range(data[0x10 - offset], 2, 0) != 0) add_failure(cta, "VESA Video Display Device Data Block: Reserved miscellaneous display capabilities bits 2-0 must be 0."); dddb->audio_support = has_bit(data[0x11 - offset], 7); dddb->separate_audio_inputs = has_bit(data[0x11 - offset], 6); dddb->audio_input_override = has_bit(data[0x11 - offset], 5); if (get_bit_range(data[0x11 - offset], 4, 0) != 0) add_failure(cta, "VESA Video Display Device Data Block: Reserved audio bits 4-0 must be 0."); dddb->audio_delay_provided = data[0x12 - offset] != 0; dddb->audio_delay_ms = 2 * get_bit_range(data[0x12 - offset], 6, 0); if (!has_bit(data[0x12 - offset], 7)) dddb->audio_delay_ms = -dddb->audio_delay_ms; dddb->frame_rate_conversion = get_bit_range(data[0x13 - offset], 7, 6); dddb->frame_rate_range_hz = get_bit_range(data[0x13 - offset], 5, 0); dddb->frame_rate_native_hz = data[0x14 - offset]; dddb->bit_depth_interface = get_bit_range(data[0x15 - offset], 7, 4) + 1; dddb->bit_depth_display = get_bit_range(data[0x15 - offset], 3, 0) + 1; dddb->additional_primary_chromaticities_len = get_bit_range(data[0x17 - offset], 1, 0); parse_vesa_display_device_additional_primary_chromaticity(&dddb->additional_primary_chromaticities[0], get_bit_range(data[0x16 - offset], 7, 4), &data[0x18 - offset]); parse_vesa_display_device_additional_primary_chromaticity(&dddb->additional_primary_chromaticities[1], get_bit_range(data[0x16 - offset], 3, 0), &data[0x1A - offset]); parse_vesa_display_device_additional_primary_chromaticity(&dddb->additional_primary_chromaticities[2], get_bit_range(data[0x17 - offset], 7, 4), &data[0x1C - offset]); if (get_bit_range(data[0x17 - offset], 3, 2) != 0) add_failure(cta, "VESA Video Display Device Data Block: Reserved additional primary chromaticities bits 3-2 of byte 0x17 must be 0."); dddb->resp_time_transition = has_bit(data[0x1E - offset], 7); dddb->resp_time_ms = get_bit_range(data[0x1E - offset], 6, 0); dddb->overscan_horiz_pct = get_bit_range(data[0x1F - offset], 7, 4); dddb->overscan_vert_pct = get_bit_range(data[0x1F - offset], 3, 0); return true; } static bool parse_colorimetry_block(struct di_edid_cta *cta, struct di_cta_colorimetry_block *colorimetry, const uint8_t *data, size_t size) { if (size < 2) { add_failure(cta, "Colorimetry Data Block: Empty Data Block with length %u.", size); return false; } colorimetry->bt2020_rgb = has_bit(data[0], 7); colorimetry->bt2020_ycc = has_bit(data[0], 6); colorimetry->bt2020_cycc = has_bit(data[0], 5); colorimetry->oprgb = has_bit(data[0], 4); colorimetry->opycc_601 = has_bit(data[0], 3); colorimetry->sycc_601 = has_bit(data[0], 2); colorimetry->xvycc_709 = has_bit(data[0], 1); colorimetry->xvycc_601 = has_bit(data[0], 0); colorimetry->st2113_rgb = has_bit(data[1], 7); colorimetry->ictcp = has_bit(data[1], 6); if (get_bit_range(data[1], 5, 0) != 0) add_failure_until(cta, 3, "Colorimetry Data Block: Reserved bits MD0-MD3 must be 0."); return true; } static float parse_max_luminance(uint8_t raw) { if (raw == 0) return 0; return 50 * powf(2, (float) raw / 32); } static float parse_min_luminance(uint8_t raw, float max) { if (raw == 0) return 0; return max * powf((float) raw / 255, 2) / 100; } static bool parse_hdr_static_metadata_block(struct di_edid_cta *cta, struct di_cta_hdr_static_metadata_block_priv *metadata, const uint8_t *data, size_t size) { uint8_t eotfs, descriptors; if (size < 2) { add_failure(cta, "HDR Static Metadata Data Block: Empty Data Block with length %u.", size); return false; } metadata->base.eotfs = &metadata->eotfs; metadata->base.descriptors = &metadata->descriptors; eotfs = data[0]; metadata->eotfs.traditional_sdr = has_bit(eotfs, 0); metadata->eotfs.traditional_hdr = has_bit(eotfs, 1); metadata->eotfs.pq = has_bit(eotfs, 2); metadata->eotfs.hlg = has_bit(eotfs, 3); if (get_bit_range(eotfs, 7, 4)) add_failure_until(cta, 3, "HDR Static Metadata Data Block: Unknown EOTF."); descriptors = data[1]; metadata->descriptors.type1 = has_bit(descriptors, 0); if (get_bit_range(descriptors, 7, 1)) add_failure_until(cta, 3, "HDR Static Metadata Data Block: Unknown descriptor type."); if (size > 2) metadata->base.desired_content_max_luminance = parse_max_luminance(data[2]); if (size > 3) metadata->base.desired_content_max_frame_avg_luminance = parse_max_luminance(data[3]); if (size > 4) { if (metadata->base.desired_content_max_luminance == 0) add_failure(cta, "HDR Static Metadata Data Block: Desired content min luminance is set, but max luminance is unset."); else metadata->base.desired_content_min_luminance = parse_min_luminance(data[4], metadata->base.desired_content_max_luminance); } return true; } static bool parse_hdr_dynamic_metadata_block(struct di_edid_cta *cta, struct di_cta_hdr_dynamic_metadata_block_priv *priv, const uint8_t *data, size_t size) { struct di_cta_hdr_dynamic_metadata_block *base; struct di_cta_hdr_dynamic_metadata_type1 *type1; struct di_cta_hdr_dynamic_metadata_type2 *type2; struct di_cta_hdr_dynamic_metadata_type3 *type3; struct di_cta_hdr_dynamic_metadata_type4 *type4; struct di_cta_hdr_dynamic_metadata_type256 *type256; size_t length; int type; base = &priv->base; type1 = &priv->type1; type2 = &priv->type2; type3 = &priv->type3; type4 = &priv->type4; type256 = &priv->type256; if (size < 3) { add_failure(cta, "HDR Dynamic Metadata Data Block: Empty Data Block with length %u.", size); return false; } while (size >= 3) { length = data[0]; if (size < length + 1) { add_failure(cta, "HDR Dynamic Metadata Data Block: Length of type bigger than block size."); return false; } if (length < 2) { add_failure(cta, "HDR Dynamic Metadata Data Block: Type has wrong length."); return false; } type = (data[2] << 8) | data[1]; switch (type) { case 0x0001: if (length < 3) { add_failure(cta, "HDR Dynamic Metadata Data Block: Type 1 missing Support Flags."); break; } if (length != 3) add_failure(cta, "HDR Dynamic Metadata Data Block: Type 1 length must be 3."); type1->type_1_hdr_metadata_version = get_bit_range(data[3], 3, 0); base->type1 = type1; if (get_bit_range(data[3], 7, 4) != 0) add_failure(cta, "HDR Dynamic Metadata Data Block: Type 1 support flags bits 7-4 must be 0."); break; case 0x0002: if (length < 3) { add_failure(cta, "HDR Dynamic Metadata Data Block: Type 2 missing Support Flags."); break; } if (length != 3) add_failure(cta, "HDR Dynamic Metadata Data Block: Type 2 length must be 3."); type2->ts_103_433_spec_version = get_bit_range(data[3], 3, 0); if (type2->ts_103_433_spec_version == 0) { add_failure(cta, "HDR Dynamic Metadata Data Block: Type 2 spec version of 0 is not allowed."); break; } type2->ts_103_433_1_capable = has_bit(data[3], 4); type2->ts_103_433_2_capable = has_bit(data[3], 5); type2->ts_103_433_3_capable = has_bit(data[3], 6); base->type2 = type2; if (has_bit(data[3], 7) != 0) add_failure(cta, "HDR Dynamic Metadata Data Block: Type 1 support flags bit 7 must be 0."); break; case 0x0003: if (length != 2) add_failure(cta, "HDR Dynamic Metadata Data Block: Type 3 length must be 2."); base->type3 = type3; break; case 0x0004: if (length < 3) { add_failure(cta, "HDR Dynamic Metadata Data Block: Type 4 missing Support Flags."); break; } if (length != 3) add_failure(cta, "HDR Dynamic Metadata Data Block: Type 4 length must be 3."); type4->type_4_hdr_metadata_version = get_bit_range(data[3], 3, 0); base->type4 = type4; if (get_bit_range(data[3], 7, 4) != 0) add_failure(cta, "HDR Dynamic Metadata Data Block: Type 4 support flags bits 7-4 must be 0."); break; case 0x0100: if (length < 3) { add_failure(cta, "HDR Dynamic Metadata Data Block: Type 256 missing Support Flags."); break; } if (length != 3) add_failure(cta, "HDR Dynamic Metadata Data Block: Type 256 length must be 3."); type256->graphics_overlay_flag_version = get_bit_range(data[3], 3, 0); base->type256 = type256; if (get_bit_range(data[3], 7, 4) != 0) add_failure(cta, "HDR Dynamic Metadata Data Block: Type 256 support flags bits 7-4 must be 0."); break; default: add_failure(cta, "HDR Dynamic Metadata Data Block: Unknown Type 0x%04x.", type); break; } size -= length + 1; data += length + 1; } return true; } static bool parse_vesa_transfer_characteristics_block(struct di_edid_cta *cta, struct di_cta_vesa_transfer_characteristics_block *tf, const uint8_t *data, size_t size) { size_t i; if (size != 7 && size != 15 && size != 31) { add_failure(cta, "Invalid length %u.", size); return false; } tf->points_len = (uint8_t) size + 1; tf->usage = get_bit_range(data[0], 7, 6); tf->points[0] = get_bit_range(data[0], 5, 0) / 1023.0f; for (i = 1; i < size; i++) tf->points[i] = tf->points[i - 1] + data[i] / 1023.0f; tf->points[i] = 1.0f; return true; } static bool parse_video_format_pref_block(struct di_edid_cta *cta, struct di_cta_video_format_pref_priv *vfpdb, const uint8_t *data, size_t size) { struct di_cta_svr *svr; size_t i; uint8_t code; for (i = 0; i < size; i++) { code = data[i]; if (code == 0 || code == 128 || (code >= 161 && code <= 192) || code == 255) { add_failure(cta, "Video Format Preference Data Block: " "using reserved Short Video Reference value %u.", code); continue; } svr = calloc(1, sizeof(*svr)); if (!svr) return false; if ((code >= 1 && code <= 127) || (code >= 193 && code <= 253)) { svr->type = DI_CTA_SVR_TYPE_VIC; svr->vic = code; } else if (code >= 129 && code <= 144) { svr->type = DI_CTA_SVR_TYPE_DTD_INDEX; svr->dtd_index = code - 129; } else if (code >= 145 && code <= 160) { svr->type = DI_CTA_SVR_TYPE_T7T10VTDB; svr->dtd_index = code - 145; } else if (code == 254) { svr->type = DI_CTA_SVR_TYPE_FIRST_T8VTDB; } else { abort(); /* unreachable */ } assert(vfpdb->svrs_len < EDID_CTA_MAX_VIDEO_FORMAT_PREF_BLOCK_ENTRIES); vfpdb->svrs[vfpdb->svrs_len++] = svr; } vfpdb->base.svrs = (const struct di_cta_svr *const *)vfpdb->svrs; return true; } static void parse_ycbcr420_cap_map(struct di_edid_cta *cta, struct di_cta_ycbcr420_cap_map_block *ycbcr420_cap_map, const uint8_t *data, size_t size) { if (size == 0) { ycbcr420_cap_map->all = true; return; } assert(size <= sizeof(ycbcr420_cap_map->svd_bitmap)); memcpy(ycbcr420_cap_map->svd_bitmap, data, size); } static bool parse_hdmi_audio_3d_descriptor(struct di_edid_cta *cta, struct di_cta_sad_priv *sad, const uint8_t *data, size_t size) { /* Contains the same data as the Short Audio Descriptor, packed differently */ struct di_cta_sad *base = &sad->base; struct di_cta_sad_sample_rates *sample_rate = &sad->supported_sample_rates; struct di_cta_sad_lpcm *lpcm = &sad->lpcm; uint8_t code; assert(size >= CTA_HDMI_AUDIO_3D_DESCRIPTOR_SIZE); code = get_bit_range(data[0], 3, 0); if (!parse_sad_format(cta, code, 0, &base->format, "HDMI Audio Data Block")) return false; if (base->format != DI_CTA_AUDIO_FORMAT_LPCM && base->format != DI_CTA_AUDIO_FORMAT_ONE_BIT_AUDIO) { add_failure(cta, "HDMI Audio Data Block: Unsupported 3D Audio Format 0x%04x.", code); return false; } base->max_channels = get_bit_range(data[1], 4, 0) + 1; sample_rate->has_192_khz = has_bit(data[2], 6); sample_rate->has_176_4_khz = has_bit(data[2], 5); sample_rate->has_96_khz = has_bit(data[2], 4); sample_rate->has_88_2_khz = has_bit(data[2], 3); sample_rate->has_48_khz = has_bit(data[2], 2); sample_rate->has_44_1_khz = has_bit(data[2], 1); sample_rate->has_32_khz = has_bit(data[2], 0); base->supported_sample_rates = sample_rate; if (base->format == DI_CTA_AUDIO_FORMAT_LPCM) { lpcm->has_sample_size_24_bits = has_bit(data[3], 2); lpcm->has_sample_size_20_bits = has_bit(data[3], 1); lpcm->has_sample_size_16_bits = has_bit(data[3], 0); base->lpcm = lpcm; } if (base->format == DI_CTA_AUDIO_FORMAT_ONE_BIT_AUDIO) { /* TODO data[3] 7:0 contains unknown Audio Format Code dependent value */ } return true; } static bool parse_hdmi_audio_block(struct di_edid_cta *cta, struct di_cta_hdmi_audio_block_priv *priv, const uint8_t *data, size_t size) { struct di_cta_hdmi_audio_block *hdmi_audio = &priv->base; struct di_cta_hdmi_audio_multi_stream *ms = &priv->ms; struct di_cta_hdmi_audio_3d *a3d = &priv->a3d; uint8_t multi_stream; bool ms_non_mixed; size_t num_3d_audio_descs; size_t num_descs; struct di_cta_sad_priv *sad_priv; uint8_t channels; if (size < 1) { add_failure(cta, "HDMI Audio Data Block: Empty Data Block with length 0."); return false; } multi_stream = get_bit_range(data[0], 1, 0); ms_non_mixed = has_bit(data[0], 2); if (multi_stream > 0) { hdmi_audio->multi_stream = ms; ms->max_streams = multi_stream + 1; ms->supports_non_mixed = ms_non_mixed; } else if (ms_non_mixed) { add_failure(cta, "HDMI Audio Data Block: MS NonMixed support indicated but " "Max Stream Count == 0."); } if (size < 2) return true; num_3d_audio_descs = get_bit_range(data[1], 2, 0); if (num_3d_audio_descs == 0) return true; /* If there are 3d Audio Descriptors, there is one last Speaker Allocation Descriptor */ num_descs = num_3d_audio_descs + 1; /* Skip to the first descriptor */ size -= 2; data += 2; /* Make sure there is enough space for the descriptors */ if (num_descs > size / CTA_HDMI_AUDIO_3D_DESCRIPTOR_SIZE) { add_failure(cta, "HDMI Audio Data Block: More descriptors indicated than block size allows."); return true; } hdmi_audio->audio_3d = a3d; a3d->sads = (const struct di_cta_sad * const*)priv->sads; /* First the 3D Audio Descriptors, the last one is the 3D Speaker Allocation Descriptor */ while (num_descs > 1) { sad_priv = calloc(1, sizeof(*sad_priv)); if (!sad_priv) return false; if (!parse_hdmi_audio_3d_descriptor(cta, sad_priv, data, size)) { free(sad_priv); goto skip; } assert(priv->sads_len < EDID_CTA_MAX_HDMI_AUDIO_BLOCK_ENTRIES); priv->sads[priv->sads_len++] = sad_priv; skip: num_descs--; size -= CTA_HDMI_AUDIO_3D_DESCRIPTOR_SIZE; data += CTA_HDMI_AUDIO_3D_DESCRIPTOR_SIZE; } channels = get_bit_range(data[3], 7, 4); switch (channels) { case DI_CTA_HDMI_AUDIO_3D_CHANNELS_UNKNOWN: case DI_CTA_HDMI_AUDIO_3D_CHANNELS_10_2: case DI_CTA_HDMI_AUDIO_3D_CHANNELS_22_2: case DI_CTA_HDMI_AUDIO_3D_CHANNELS_30_2: a3d->channels = channels; break; default: a3d->channels = DI_CTA_HDMI_AUDIO_3D_CHANNELS_UNKNOWN; break; } parse_speaker_alloc(cta, &a3d->speakers, data, "Room Configuration Data Block"); return true; } static struct di_cta_infoframe_descriptor * parse_infoframe(struct di_edid_cta *cta, uint8_t type, const uint8_t *data, size_t size) { struct di_cta_infoframe_descriptor infoframe = {0}; struct di_cta_infoframe_descriptor *ifp; if (type >= 8 && type <= 0x1f) { add_failure(cta, "InfoFrame Data Block: Type code %u is reserved.", type); return NULL; } if (type >= 0x20) { add_failure(cta, "InfoFrame Data Block: Type code %u is forbidden.", type); return NULL; } if (type == 1) { /* No known vendor specific InfoFrames, yet */ return NULL; } else { switch (type) { case 0x02: infoframe.type = DI_CTA_INFOFRAME_TYPE_AUXILIARY_VIDEO_INFORMATION; break; case 0x03: infoframe.type = DI_CTA_INFOFRAME_TYPE_SOURCE_PRODUCT_DESCRIPTION; break; case 0x04: infoframe.type = DI_CTA_INFOFRAME_TYPE_AUDIO; break; case 0x05: infoframe.type = DI_CTA_INFOFRAME_TYPE_MPEG_SOURCE; break; case 0x06: infoframe.type = DI_CTA_INFOFRAME_TYPE_NTSC_VBI; break; case 0x07: infoframe.type = DI_CTA_INFOFRAME_TYPE_DYNAMIC_RANGE_AND_MASTERING; break; default: abort(); /* unreachable */ } } ifp = calloc(1, sizeof(*ifp)); if (!ifp) return NULL; *ifp = infoframe; return ifp; } static bool parse_infoframe_block(struct di_edid_cta *cta, struct di_cta_infoframe_block_priv *ifb, const uint8_t *data, size_t size) { size_t index = 0, length; uint8_t type; struct di_cta_infoframe_descriptor *infoframe; if (size < 2) { add_failure(cta, "InfoFrame Data Block: Empty Data Block with length %u.", size); return false; } ifb->base.num_simultaneous_vsifs = data[1] + 1; ifb->base.infoframes = (const struct di_cta_infoframe_descriptor *const *)ifb->infoframes; index = get_bit_range(data[0], 7, 5) + 2; if (get_bit_range(data[0], 4, 0) != 0) add_failure(cta, "InfoFrame Data Block: InfoFrame Processing " "Descriptor Header bits F14-F10 shall be 0."); while (true) { if (index == size) break; if (index > size) { add_failure(cta, "InfoFrame Data Block: Payload length exceeds block size."); return false; } length = get_bit_range(data[index], 7, 5); type = get_bit_range(data[index], 4, 0); if (type == 0) { add_failure(cta, "InfoFrame Data Block: Short InfoFrame Descriptor with type 0 is forbidden."); return false; } else if (type == 1) { length += 4; } else { length += 1; } if (index + length > size) { add_failure(cta, "InfoFrame Data Block: Payload length exceeds block size."); return false; } infoframe = parse_infoframe(cta, type, &data[index], length); if (infoframe) { assert(ifb->infoframes_len < EDID_CTA_INFOFRAME_BLOCK_ENTRIES); ifb->infoframes[ifb->infoframes_len++] = infoframe; } index += length; } return true; } static double decode_coord(unsigned char x) { signed char s = (signed char)x; return s / 64.0; } static bool parse_room_config_block(struct di_edid_cta *cta, struct di_cta_room_configuration_block *rc, const uint8_t *data, size_t size) { bool has_display_coords; bool has_speaker_count; if (size < 4) { add_failure(cta, "Room Configuration Data Block: Empty Data Block with length %u.", size); return false; } has_display_coords = has_bit(data[0], 7); has_speaker_count = has_bit(data[0], 6); rc->has_speaker_location_descriptors = has_bit(data[0], 5); if (has_speaker_count) { rc->speaker_count = get_bit_range(data[0], 4, 0) + 1; } else { if (get_bit_range(data[0], 4, 0) != 0) { add_failure(cta, "Room Configuration Data Block: " "'Speaker' flag is 0, but the Speaker Count is not 0."); } if (rc->has_speaker_location_descriptors) { add_failure(cta, "Room Configuration Data Block: " "'Speaker' flag is 0, but there are " "Speaker Location Descriptors."); } } parse_speaker_alloc(cta, &rc->speakers, &data[1], "Room Configuration Data Block"); rc->max_x = 16; rc->max_y = 16; rc->max_z = 8; rc->display_x = 0.0; rc->display_y = 1.0; rc->display_z = 0.0; if (size < 7) { if (has_display_coords) add_failure(cta, "Room Configuration Data Block: " "'Display' flag is 1, but the Display and Maximum coordinates are not present."); return true; } rc->max_x = data[4]; rc->max_y = data[5]; rc->max_z = data[6]; if (size < 10) { if (has_display_coords) add_failure(cta, "Room Configuration Data Block: " "'Display' flag is 1, but the Display coordinates are not present."); return true; } rc->display_x = decode_coord(data[7]); rc->display_y = decode_coord(data[8]); rc->display_z = decode_coord(data[9]); return true; } static bool parse_speaker_location_block(struct di_edid_cta *cta, struct di_cta_speaker_location_priv *sldb, const uint8_t *data, size_t size) { struct di_cta_speaker_location_descriptor speaker_loc, *slp; if (size < 2) { add_failure(cta, "Speaker Location Data Block: Empty Data Block with length %u.", size); return false; } while (size >= 2) { speaker_loc.has_coords = has_bit(data[0], 6); speaker_loc.is_active = has_bit(data[0], 5); speaker_loc.channel_index = get_bit_range(data[0], 4, 0); speaker_loc.speaker_id = get_bit_range(data[1], 4, 0); if (has_bit(data[0], 7) || get_bit_range(data[1], 7, 5) != 0) { add_failure(cta, "Speaker Location Data Block: Bits F27-F25, F17 must be 0."); } if (speaker_loc.has_coords && size >= 5) { speaker_loc.x = decode_coord(data[2]); speaker_loc.y = decode_coord(data[3]); speaker_loc.z = decode_coord(data[4]); size -= 5; data += 5; } else if (speaker_loc.has_coords) { add_failure(cta, "Speaker Location Data Block: COORD bit " "set but contains no Coordinates."); return false; } else { size -= 2; data += 2; } slp = calloc(1, sizeof(*slp)); if (!slp) return false; *slp = speaker_loc; assert(sldb->locations_len < EDID_CTA_MAX_SPEAKER_LOCATION_BLOCK_ENTRIES); sldb->locations[sldb->locations_len++] = slp; } sldb->base.locations = (const struct di_cta_speaker_location_descriptor *const *)sldb->locations; return true; } static bool parse_did_type_vii_timing(struct di_edid_cta *cta, struct di_cta_type_vii_timing_priv *t, const uint8_t *data, size_t size) { uint8_t revision; if (size != 21) { add_failure(cta, "DisplayID Type VII Video Timing Data Block: " "Empty Data Block with length %u.", size); return false; } if (get_bit_range(data[0], 6, 4) != 0) { add_failure(cta, "DisplayID Type VII Video Timing Data Block: " "T7_M shall be 000b."); return false; } revision = get_bit_range(data[0], 2, 0); if (revision != 2) { add_failure(cta, "DisplayID Type VII Video Timing Data Block: " "Unexpected revision (%u != %u).", revision, 2); return false; } if (has_bit(data[0], 3)) { add_failure(cta, "DisplayID Type VII Video Timing Data Block: " "DSC_PT shall be 0."); } if (has_bit(data[0], 7)) { add_failure(cta, "DisplayID Type VII Video Timing Data Block: " "Block Revision and Other Data Bit 7 must be 0."); } data += 1; size -= 1; if (!_di_displayid_parse_type_1_7_timing(&t->timing, cta->logger, "DisplayID Type VII Video Timing Data Block", data, true)) return false; t->base.timing = &t->timing; return true; } static void destroy_data_block(struct di_cta_data_block *data_block) { size_t i; struct di_cta_video_block_priv *video; struct di_cta_audio_block_priv *audio; struct di_cta_infoframe_block_priv *infoframe; struct di_cta_speaker_location_priv *speaker_location; struct di_cta_video_format_pref_priv *vfpdb; struct di_cta_hdmi_audio_block_priv *hdmi_audio; struct di_cta_ycbcr420_video_block_priv *ycbcr420; switch (data_block->tag) { case DI_CTA_DATA_BLOCK_VIDEO: video = &data_block->video; for (i = 0; i < video->svds_len; i++) free(video->svds[i]); break; case DI_CTA_DATA_BLOCK_YCBCR420: ycbcr420 = &data_block->ycbcr420; for (i = 0; i < ycbcr420->svds_len; i++) free(ycbcr420->svds[i]); break; case DI_CTA_DATA_BLOCK_AUDIO: audio = &data_block->audio; for (i = 0; i < audio->sads_len; i++) free(audio->sads[i]); break; case DI_CTA_DATA_BLOCK_INFOFRAME: infoframe = &data_block->infoframe; for (i = 0; i < infoframe->infoframes_len; i++) free(infoframe->infoframes[i]); break; case DI_CTA_DATA_BLOCK_SPEAKER_LOCATION: speaker_location = &data_block->speaker_location; for (i = 0; i < speaker_location->locations_len; i++) free(speaker_location->locations[i]); break; case DI_CTA_DATA_BLOCK_VIDEO_FORMAT_PREF: vfpdb = &data_block->video_format_pref; for (i = 0; i < vfpdb->svrs_len; i++) free(vfpdb->svrs[i]); break; case DI_CTA_DATA_BLOCK_HDMI_AUDIO: hdmi_audio = &data_block->hdmi_audio; for (i = 0; i < hdmi_audio->sads_len; i++) free(hdmi_audio->sads[i]); break; default: break; /* Nothing to do */ } free(data_block); } static bool parse_data_block(struct di_edid_cta *cta, uint8_t raw_tag, const uint8_t *data, size_t size) { enum di_cta_data_block_tag tag; uint8_t extended_tag; struct di_cta_data_block *data_block; data_block = calloc(1, sizeof(*data_block)); if (!data_block) { return false; } switch (raw_tag) { case 1: tag = DI_CTA_DATA_BLOCK_AUDIO; if (!parse_audio_block(cta, &data_block->audio, data, size)) goto error; break; case 2: tag = DI_CTA_DATA_BLOCK_VIDEO; if (!parse_video_block(cta, &data_block->video, data, size)) goto error; break; case 3: /* Vendor-Specific Data Block */ goto skip; case 4: tag = DI_CTA_DATA_BLOCK_SPEAKER_ALLOC; if (!parse_speaker_alloc_block(cta, &data_block->speaker_alloc, data, size)) goto error; break; case 5: tag = DI_CTA_DATA_BLOCK_VESA_DISPLAY_TRANSFER_CHARACTERISTIC; if (!parse_vesa_transfer_characteristics_block(cta, &data_block->vesa_transfer_characteristics, data, size)) goto error; break; case 6: tag = DI_CTA_DATA_BLOCK_VIDEO_FORMAT; break; case 7: /* Use Extended Tag */ if (size < 1) { add_failure(cta, "Empty block with extended tag."); goto skip; } extended_tag = data[0]; data = &data[1]; size--; switch (extended_tag) { case 0: tag = DI_CTA_DATA_BLOCK_VIDEO_CAP; if (!parse_video_cap_block(cta, &data_block->video_cap, data, size)) goto skip; break; case 2: tag = DI_CTA_DATA_BLOCK_VESA_DISPLAY_DEVICE; if (!parse_vesa_display_device(cta, &data_block->vesa_display_device, data, size)) goto skip; break; case 5: tag = DI_CTA_DATA_BLOCK_COLORIMETRY; if (!parse_colorimetry_block(cta, &data_block->colorimetry, data, size)) goto skip; break; case 6: tag = DI_CTA_DATA_BLOCK_HDR_STATIC_METADATA; if (!parse_hdr_static_metadata_block(cta, &data_block->hdr_static_metadata, data, size)) goto skip; break; case 7: tag = DI_CTA_DATA_BLOCK_HDR_DYNAMIC_METADATA; if (!parse_hdr_dynamic_metadata_block(cta, &data_block->hdr_dynamic_metadata, data, size)) goto skip; break; case 8: tag = DI_CTA_DATA_BLOCK_NATIVE_VIDEO_RESOLUTION; break; case 13: tag = DI_CTA_DATA_BLOCK_VIDEO_FORMAT_PREF; if (!parse_video_format_pref_block(cta, &data_block->video_format_pref, data, size)) goto skip; break; case 14: tag = DI_CTA_DATA_BLOCK_YCBCR420; if (!parse_ycbcr420_block(cta, &data_block->ycbcr420, data, size)) goto skip; break; case 15: tag = DI_CTA_DATA_BLOCK_YCBCR420_CAP_MAP; parse_ycbcr420_cap_map(cta, &data_block->ycbcr420_cap_map, data, size); break; case 18: tag = DI_CTA_DATA_BLOCK_HDMI_AUDIO; if (!parse_hdmi_audio_block(cta, &data_block->hdmi_audio, data, size)) goto skip; break; case 19: tag = DI_CTA_DATA_BLOCK_ROOM_CONFIG; if (!parse_room_config_block(cta, &data_block->room_config, data, size)) goto skip; break; case 20: tag = DI_CTA_DATA_BLOCK_SPEAKER_LOCATION; if (!parse_speaker_location_block(cta, &data_block->speaker_location, data, size)) goto skip; break; case 32: tag = DI_CTA_DATA_BLOCK_INFOFRAME; if (!parse_infoframe_block(cta, &data_block->infoframe, data, size)) goto skip; break; case 34: tag = DI_CTA_DATA_BLOCK_DISPLAYID_VIDEO_TIMING_VII; if (!parse_did_type_vii_timing(cta, &data_block->did_vii_timing, data, size)) goto skip; break; case 35: tag = DI_CTA_DATA_BLOCK_DISPLAYID_VIDEO_TIMING_VIII; break; case 42: tag = DI_CTA_DATA_BLOCK_DISPLAYID_VIDEO_TIMING_X; break; case 120: tag = DI_CTA_DATA_BLOCK_HDMI_EDID_EXT_OVERRIDE; break; case 121: tag = DI_CTA_DATA_BLOCK_HDMI_SINK_CAP; break; case 1: /* Vendor-Specific Video Data Block */ case 17: /* Vendor-Specific Audio Data Block */ goto skip; default: /* Reserved */ add_failure_until(cta, 3, "Unknown CTA-861 Data Block (extended tag 0x"PRIx8", length %zu).", extended_tag, size); goto skip; } break; default: /* Reserved */ add_failure_until(cta, 3, "Unknown CTA-861 Data Block (tag 0x"PRIx8", length %zu).", raw_tag, size); goto skip; } data_block->tag = tag; assert(cta->data_blocks_len < EDID_CTA_MAX_DATA_BLOCKS); cta->data_blocks[cta->data_blocks_len++] = data_block; return true; skip: free(data_block); return true; error: destroy_data_block(data_block); return false; } bool _di_edid_cta_parse(struct di_edid_cta *cta, const uint8_t *data, size_t size, struct di_logger *logger) { uint8_t flags, dtd_start; uint8_t data_block_header, data_block_tag, data_block_size; size_t i; struct di_edid_detailed_timing_def_priv *detailed_timing_def; assert(size == 128); assert(data[0] == 0x02); cta->logger = logger; cta->revision = data[1]; dtd_start = data[2]; flags = data[3]; if (cta->revision >= 2) { cta->flags.it_underscan = has_bit(flags, 7); cta->flags.basic_audio = has_bit(flags, 6); cta->flags.ycc444 = has_bit(flags, 5); cta->flags.ycc422 = has_bit(flags, 4); cta->flags.native_dtds = get_bit_range(flags, 3, 0); } else if (flags != 0) { /* Reserved */ add_failure(cta, "Non-zero byte 3."); } if (dtd_start == 0) { return true; } else if (dtd_start < CTA_HEADER_SIZE || dtd_start >= size) { errno = EINVAL; return false; } i = CTA_HEADER_SIZE; while (i < dtd_start) { data_block_header = data[i]; data_block_tag = get_bit_range(data_block_header, 7, 5); data_block_size = get_bit_range(data_block_header, 4, 0); if (i + 1 + data_block_size > dtd_start) { add_failure(cta, "Data Block at offset %zu overlaps Detailed Timing " "Definitions. Skipping all further Data Blocks.", i); break; } if (!parse_data_block(cta, data_block_tag, &data[i + 1], data_block_size)) { _di_edid_cta_finish(cta); return false; } i += 1 + data_block_size; } if (i != dtd_start) add_failure(cta, "Offset is %"PRIu8", but should be %zu.", dtd_start, i); for (i = dtd_start; i + EDID_BYTE_DESCRIPTOR_SIZE <= CTA_DTD_END; i += EDID_BYTE_DESCRIPTOR_SIZE) { if (data[i] == 0) break; detailed_timing_def = _di_edid_parse_detailed_timing_def(&data[i]); if (!detailed_timing_def) { _di_edid_cta_finish(cta); return false; } assert(cta->detailed_timing_defs_len < EDID_CTA_MAX_DETAILED_TIMING_DEFS); cta->detailed_timing_defs[cta->detailed_timing_defs_len++] = detailed_timing_def; } /* All padding bytes after the last DTD must be zero */ while (i < CTA_DTD_END) { if (data[i] != 0) { add_failure(cta, "Padding: Contains non-zero bytes."); break; } i++; } cta->logger = NULL; return true; } void _di_edid_cta_finish(struct di_edid_cta *cta) { size_t i; for (i = 0; i < cta->data_blocks_len; i++) { destroy_data_block(cta->data_blocks[i]); } for (i = 0; i < cta->detailed_timing_defs_len; i++) { free(cta->detailed_timing_defs[i]); } } int di_edid_cta_get_revision(const struct di_edid_cta *cta) { return cta->revision; } const struct di_edid_cta_flags * di_edid_cta_get_flags(const struct di_edid_cta *cta) { return &cta->flags; } const struct di_cta_data_block *const * di_edid_cta_get_data_blocks(const struct di_edid_cta *cta) { return (const struct di_cta_data_block *const *) cta->data_blocks; } enum di_cta_data_block_tag di_cta_data_block_get_tag(const struct di_cta_data_block *block) { return block->tag; } const struct di_cta_video_block * di_cta_data_block_get_video(const struct di_cta_data_block *block) { if (block->tag != DI_CTA_DATA_BLOCK_VIDEO) { return NULL; } return &block->video.base; } const struct di_cta_ycbcr420_video_block * di_cta_data_block_get_ycbcr420_video(const struct di_cta_data_block *block) { if (block->tag != DI_CTA_DATA_BLOCK_YCBCR420) { return NULL; } return &block->ycbcr420.base; } const struct di_cta_video_format_pref_block * di_cta_data_block_get_video_format_pref(const struct di_cta_data_block *block) { if (block->tag != DI_CTA_DATA_BLOCK_VIDEO_FORMAT_PREF) { return NULL; } return &block->video_format_pref.base; } const struct di_cta_audio_block * di_cta_data_block_get_audio(const struct di_cta_data_block *block) { if (block->tag != DI_CTA_DATA_BLOCK_AUDIO) { return NULL; } return &block->audio.audio; } const struct di_cta_speaker_alloc_block * di_cta_data_block_get_speaker_alloc(const struct di_cta_data_block *block) { if (block->tag != DI_CTA_DATA_BLOCK_SPEAKER_ALLOC) { return NULL; } return &block->speaker_alloc; } const struct di_cta_colorimetry_block * di_cta_data_block_get_colorimetry(const struct di_cta_data_block *block) { if (block->tag != DI_CTA_DATA_BLOCK_COLORIMETRY) { return NULL; } return &block->colorimetry; } const struct di_cta_hdr_static_metadata_block * di_cta_data_block_get_hdr_static_metadata(const struct di_cta_data_block *block) { if (block->tag != DI_CTA_DATA_BLOCK_HDR_STATIC_METADATA) { return NULL; } return &block->hdr_static_metadata.base; } const struct di_cta_hdr_dynamic_metadata_block * di_cta_data_block_get_hdr_dynamic_metadata(const struct di_cta_data_block *block) { if (block->tag != DI_CTA_DATA_BLOCK_HDR_DYNAMIC_METADATA) { return NULL; } return &block->hdr_dynamic_metadata.base; } const struct di_cta_video_cap_block * di_cta_data_block_get_video_cap(const struct di_cta_data_block *block) { if (block->tag != DI_CTA_DATA_BLOCK_VIDEO_CAP) { return NULL; } return &block->video_cap; } const struct di_cta_vesa_display_device_block * di_cta_data_block_get_vesa_display_device(const struct di_cta_data_block *block) { if (block->tag != DI_CTA_DATA_BLOCK_VESA_DISPLAY_DEVICE) { return NULL; } return &block->vesa_display_device; } bool di_cta_ycbcr420_cap_map_supported(const struct di_cta_ycbcr420_cap_map_block *cap_map, size_t svd_index) { size_t byte, bit; if (cap_map->all) return true; byte = svd_index / 8; bit = svd_index % 8; if (byte >= EDID_CTA_MAX_YCBCR420_CAP_MAP_BLOCK_ENTRIES) return false; return cap_map->svd_bitmap[byte] & (1 << bit); } const struct di_cta_ycbcr420_cap_map_block * di_cta_data_block_get_ycbcr420_cap_map(const struct di_cta_data_block *block) { if (block->tag != DI_CTA_DATA_BLOCK_YCBCR420_CAP_MAP) { return NULL; } return &block->ycbcr420_cap_map; } const struct di_cta_hdmi_audio_block * di_cta_data_block_get_hdmi_audio(const struct di_cta_data_block *block) { if (block->tag != DI_CTA_DATA_BLOCK_HDMI_AUDIO) { return NULL; } return &block->hdmi_audio.base; } const struct di_cta_infoframe_block * di_cta_data_block_get_infoframe(const struct di_cta_data_block *block) { if (block->tag != DI_CTA_DATA_BLOCK_INFOFRAME) { return NULL; } return &block->infoframe.base; } const struct di_cta_speaker_location_block * di_cta_data_block_get_speaker_locations(const struct di_cta_data_block *block) { if (block->tag != DI_CTA_DATA_BLOCK_SPEAKER_LOCATION) { return NULL; } return &block->speaker_location.base; } const struct di_cta_type_vii_timing_block * di_cta_data_block_get_did_type_vii_timing(const struct di_cta_data_block *block) { if (block->tag != DI_CTA_DATA_BLOCK_DISPLAYID_VIDEO_TIMING_VII) { return NULL; } return &block->did_vii_timing.base; } const struct di_edid_detailed_timing_def *const * di_edid_cta_get_detailed_timing_defs(const struct di_edid_cta *cta) { return (const struct di_edid_detailed_timing_def *const *) cta->detailed_timing_defs; } const struct di_cta_vesa_transfer_characteristics_block * di_cta_data_block_get_vesa_transfer_characteristics(const struct di_cta_data_block *block) { if (block->tag != DI_CTA_DATA_BLOCK_VESA_DISPLAY_TRANSFER_CHARACTERISTIC) { return NULL; } return &block->vesa_transfer_characteristics; } const struct di_cta_room_configuration_block * di_cta_data_block_get_room_configuration(const struct di_cta_data_block *block) { if (block->tag != DI_CTA_DATA_BLOCK_ROOM_CONFIG) { return NULL; } return &block->room_config; }