/* * Copyright (c) 2021, Hunter Salyer * Copyright (c) 2022-2023, Gregory Bertilson * * SPDX-License-Identifier: BSD-2-Clause */ #include #include #include #include #include #include #include "Reader.h" namespace Video::Matroska { #define TRY_READ(expression) DECODER_TRY(DecoderErrorCategory::Corrupted, expression) // RFC 8794 - Extensible Binary Meta Language // https://datatracker.ietf.org/doc/html/rfc8794 constexpr u32 EBML_MASTER_ELEMENT_ID = 0x1A45DFA3; constexpr u32 EBML_CRC32_ELEMENT_ID = 0xBF; constexpr u32 EBML_VOID_ELEMENT_ID = 0xEC; // Matroska elements' IDs and types are listed at this URL: // https://www.matroska.org/technical/elements.html constexpr u32 SEGMENT_ELEMENT_ID = 0x18538067; constexpr u32 DOCTYPE_ELEMENT_ID = 0x4282; constexpr u32 DOCTYPE_VERSION_ELEMENT_ID = 0x4287; constexpr u32 SEEK_HEAD_ELEMENT_ID = 0x114D9B74; constexpr u32 SEEK_ELEMENT_ID = 0x4DBB; constexpr u32 SEEK_ID_ELEMENT_ID = 0x53AB; constexpr u32 SEEK_POSITION_ELEMENT_ID = 0x53AC; constexpr u32 SEGMENT_INFORMATION_ELEMENT_ID = 0x1549A966; constexpr u32 TRACK_ELEMENT_ID = 0x1654AE6B; constexpr u32 CLUSTER_ELEMENT_ID = 0x1F43B675; constexpr u32 TIMESTAMP_SCALE_ID = 0x2AD7B1; constexpr u32 MUXING_APP_ID = 0x4D80; constexpr u32 WRITING_APP_ID = 0x5741; constexpr u32 DURATION_ID = 0x4489; // Tracks constexpr u32 TRACK_ENTRY_ID = 0xAE; constexpr u32 TRACK_NUMBER_ID = 0xD7; constexpr u32 TRACK_UID_ID = 0x73C5; constexpr u32 TRACK_TYPE_ID = 0x83; constexpr u32 TRACK_LANGUAGE_ID = 0x22B59C; constexpr u32 TRACK_CODEC_ID = 0x86; constexpr u32 TRACK_TIMESTAMP_SCALE_ID = 0x23314F; constexpr u32 TRACK_OFFSET_ID = 0x537F; constexpr u32 TRACK_VIDEO_ID = 0xE0; constexpr u32 TRACK_AUDIO_ID = 0xE1; // Video constexpr u32 PIXEL_WIDTH_ID = 0xB0; constexpr u32 PIXEL_HEIGHT_ID = 0xBA; constexpr u32 COLOR_ENTRY_ID = 0x55B0; constexpr u32 PRIMARIES_ID = 0x55BB; constexpr u32 TRANSFER_CHARACTERISTICS_ID = 0x55BA; constexpr u32 MATRIX_COEFFICIENTS_ID = 0x55B1; constexpr u32 BITS_PER_CHANNEL_ID = 0x55B2; // Audio constexpr u32 CHANNELS_ID = 0x9F; constexpr u32 BIT_DEPTH_ID = 0x6264; // Clusters constexpr u32 SIMPLE_BLOCK_ID = 0xA3; constexpr u32 TIMESTAMP_ID = 0xE7; // Cues constexpr u32 CUES_ID = 0x1C53BB6B; constexpr u32 CUE_POINT_ID = 0xBB; constexpr u32 CUE_TIME_ID = 0xB3; constexpr u32 CUE_TRACK_POSITIONS_ID = 0xB7; constexpr u32 CUE_TRACK_ID = 0xF7; constexpr u32 CUE_CLUSTER_POSITION_ID = 0xF1; constexpr u32 CUE_RELATIVE_POSITION_ID = 0xF0; constexpr u32 CUE_CODEC_STATE_ID = 0xEA; constexpr u32 CUE_REFERENCE_ID = 0xDB; DecoderErrorOr Reader::from_file(StringView path) { auto mapped_file = DECODER_TRY(DecoderErrorCategory::IO, Core::MappedFile::map(path)); return from_mapped_file(mapped_file); } DecoderErrorOr Reader::from_mapped_file(NonnullRefPtr mapped_file) { auto reader = TRY(from_data(mapped_file->bytes())); reader.m_mapped_file = move(mapped_file); return reader; } DecoderErrorOr Reader::from_data(ReadonlyBytes data) { Reader reader(data); TRY(reader.parse_initial_data()); return reader; } // Returns the position of the first element that is read from this master element. static DecoderErrorOr parse_master_element(Streamer& streamer, [[maybe_unused]] StringView element_name, Function(u64)> element_consumer) { auto element_data_size = TRY_READ(streamer.read_variable_size_integer()); dbgln_if(MATROSKA_DEBUG, "{} has {} octets of data.", element_name, element_data_size); bool first_element = true; auto first_element_position = streamer.position(); streamer.push_octets_read(); while (streamer.octets_read() < element_data_size) { dbgln_if(MATROSKA_TRACE_DEBUG, "====== Reading element ======"); auto element_id = TRY_READ(streamer.read_variable_size_integer(false)); dbgln_if(MATROSKA_TRACE_DEBUG, "{:s} element ID is {:#010x}", element_name, element_id); if (element_id == EBML_CRC32_ELEMENT_ID) { // The CRC-32 Element contains a 32-bit Cyclic Redundancy Check value of all the // Element Data of the Parent Element as stored except for the CRC-32 Element itself. // When the CRC-32 Element is present, the CRC-32 Element MUST be the first ordered // EBML Element within its Parent Element for easier reading. if (!first_element) return DecoderError::corrupted("CRC32 element must be the first child"sv); // All Top-Level Elements of an EBML Document that are Master Elements SHOULD include a // CRC-32 Element as a Child Element. The CRC in use is the IEEE-CRC-32 algorithm as used // in the [ISO3309] standard and in Section 8.1.1.6.2 of [ITU.V42], with initial value of // 0xFFFFFFFF. The CRC value MUST be computed on a little-endian bytestream and MUST use // little-endian storage. // FIXME: Currently we skip the CRC-32 Element instead of checking it. It may be worth // verifying the contents of the SeekHead, Segment Info, and Tracks Elements. // Note that Cluster Elements tend to be quite large, so verifying their integrity // will result in longer buffering times in streamed contexts, so it may not be // worth the effort checking those. It would also prevent error correction in // video codecs from taking effect. TRY_READ(streamer.read_unknown_element()); continue; } if (element_id == EBML_VOID_ELEMENT_ID) { // Used to void data or to avoid unexpected behaviors when using damaged data. // The content is discarded. Also used to reserve space in a subelement for later use. TRY_READ(streamer.read_unknown_element()); continue; } auto result = element_consumer(element_id); if (result.is_error()) return DecoderError::format(result.error().category(), "{} -> {}", element_name, result.error().description()); if (result.release_value() == IterationDecision::Break) break; dbgln_if(MATROSKA_TRACE_DEBUG, "Read {} octets of the {} so far.", streamer.octets_read(), element_name); first_element = false; } streamer.pop_octets_read(); return first_element_position; } static DecoderErrorOr parse_ebml_header(Streamer& streamer) { EBMLHeader header; TRY(parse_master_element(streamer, "Header"sv, [&](u64 element_id) -> DecoderErrorOr { switch (element_id) { case DOCTYPE_ELEMENT_ID: header.doc_type = TRY_READ(streamer.read_string()); dbgln_if(MATROSKA_DEBUG, "Read DocType attribute: {}", header.doc_type); break; case DOCTYPE_VERSION_ELEMENT_ID: header.doc_type_version = TRY_READ(streamer.read_u64()); dbgln_if(MATROSKA_DEBUG, "Read DocTypeVersion attribute: {}", header.doc_type_version); break; default: TRY_READ(streamer.read_unknown_element()); } return IterationDecision::Continue; })); return header; } DecoderErrorOr Reader::parse_initial_data() { Streamer streamer { m_data }; auto first_element_id = TRY_READ(streamer.read_variable_size_integer(false)); dbgln_if(MATROSKA_TRACE_DEBUG, "First element ID is {:#010x}\n", first_element_id); if (first_element_id != EBML_MASTER_ELEMENT_ID) return DecoderError::corrupted("First element was not an EBML header"sv); m_header = TRY(parse_ebml_header(streamer)); dbgln_if(MATROSKA_DEBUG, "Parsed EBML header"); auto root_element_id = TRY_READ(streamer.read_variable_size_integer(false)); if (root_element_id != SEGMENT_ELEMENT_ID) return DecoderError::corrupted("Second element was not a segment element"sv); m_segment_contents_size = TRY_READ(streamer.read_variable_size_integer()); m_segment_contents_position = streamer.position(); dbgln_if(true, "Segment is at {} with size {}, available size is {}", m_segment_contents_position, m_segment_contents_size, m_data.size() - m_segment_contents_position); m_segment_contents_size = min(m_segment_contents_size, m_data.size() - m_segment_contents_position); return {}; } static DecoderErrorOr parse_seek_head(Streamer& streamer, size_t base_position, HashMap& table) { TRY(parse_master_element(streamer, "SeekHead"sv, [&](u64 seek_head_child_id) -> DecoderErrorOr { if (seek_head_child_id == SEEK_ELEMENT_ID) { Optional seek_id; Optional seek_position; TRY(parse_master_element(streamer, "Seek"sv, [&](u64 seek_entry_child_id) -> DecoderErrorOr { switch (seek_entry_child_id) { case SEEK_ID_ELEMENT_ID: seek_id = TRY_READ(streamer.read_u64()); dbgln_if(MATROSKA_TRACE_DEBUG, "Read Seek Element ID value {:#010x}", seek_id.value()); break; case SEEK_POSITION_ELEMENT_ID: seek_position = TRY_READ(streamer.read_u64()); dbgln_if(MATROSKA_TRACE_DEBUG, "Read Seek Position value {}", seek_position.value()); break; default: TRY_READ(streamer.read_unknown_element()); } return IterationDecision::Continue; })); if (!seek_id.has_value()) return DecoderError::corrupted("Seek entry is missing the element ID"sv); if (!seek_position.has_value()) return DecoderError::corrupted("Seek entry is missing the seeking position"sv); if (seek_id.value() > NumericLimits::max()) return DecoderError::corrupted("Seek entry's element ID is too large"sv); dbgln_if(MATROSKA_TRACE_DEBUG, "Seek entry found with ID {:#010x} and position {} offset from SeekHead at {}", seek_id.value(), seek_position.value(), base_position); // FIXME: SeekHead can reference another SeekHead, we should recursively parse all SeekHeads. if (table.contains(seek_id.value())) { dbgln_if(MATROSKA_DEBUG, "Warning: Duplicate seek entry with ID {:#010x} at position {}", seek_id.value(), seek_position.value()); return IterationDecision::Continue; } DECODER_TRY_ALLOC(table.try_set(seek_id.release_value(), base_position + seek_position.release_value())); } else { dbgln_if(MATROSKA_TRACE_DEBUG, "Unknown SeekHead child element ID {:#010x}", seek_head_child_id); } return IterationDecision::Continue; })); return {}; } DecoderErrorOr> Reader::find_first_top_level_element_with_id([[maybe_unused]] StringView element_name, u32 element_id) { dbgln_if(MATROSKA_DEBUG, "====== Finding element {} with ID {:#010x} ======", element_name, element_id); if (m_seek_entries.contains(element_id)) { dbgln_if(MATROSKA_TRACE_DEBUG, "Cache hit!"); return m_seek_entries.get(element_id).release_value(); } Streamer streamer { m_data }; if (m_last_top_level_element_position != 0) TRY_READ(streamer.seek_to_position(m_last_top_level_element_position)); else TRY_READ(streamer.seek_to_position(m_segment_contents_position)); Optional position; while (streamer.position() < m_segment_contents_position + m_segment_contents_size) { auto found_element_id = TRY_READ(streamer.read_variable_size_integer(false)); auto found_element_position = streamer.position(); dbgln_if(MATROSKA_TRACE_DEBUG, "Found element ID {:#010x} with position {}.", found_element_id, found_element_position); if (found_element_id == SEEK_HEAD_ELEMENT_ID) { dbgln_if(MATROSKA_TRACE_DEBUG, "Found SeekHead, parsing it into the lookup table."); m_seek_entries.clear(); TRY(parse_seek_head(streamer, found_element_position, m_seek_entries)); m_last_top_level_element_position = 0; if (m_seek_entries.contains(element_id)) { dbgln_if(MATROSKA_TRACE_DEBUG, "SeekHead hit!"); position = m_seek_entries.get(element_id).release_value(); break; } continue; } auto result = streamer.read_unknown_element(); if (result.is_error()) return DecoderError::format(DecoderErrorCategory::Corrupted, "While seeking to {}: {}", element_name, result.release_error().string_literal()); m_last_top_level_element_position = streamer.position(); DECODER_TRY_ALLOC(m_seek_entries.try_set(found_element_id, found_element_position)); if (found_element_id == element_id) { position = found_element_position; break; } dbgln_if(MATROSKA_TRACE_DEBUG, "Skipped to position {}.", m_last_top_level_element_position); } return position; } static DecoderErrorOr parse_information(Streamer& streamer) { SegmentInformation segment_information; TRY(parse_master_element(streamer, "Segment Information"sv, [&](u64 element_id) -> DecoderErrorOr { switch (element_id) { case TIMESTAMP_SCALE_ID: segment_information.set_timestamp_scale(TRY_READ(streamer.read_u64())); dbgln_if(MATROSKA_DEBUG, "Read TimestampScale attribute: {}", segment_information.timestamp_scale()); break; case MUXING_APP_ID: segment_information.set_muxing_app(TRY_READ(streamer.read_string())); dbgln_if(MATROSKA_DEBUG, "Read MuxingApp attribute: {}", segment_information.muxing_app().as_string()); break; case WRITING_APP_ID: segment_information.set_writing_app(TRY_READ(streamer.read_string())); dbgln_if(MATROSKA_DEBUG, "Read WritingApp attribute: {}", segment_information.writing_app().as_string()); break; case DURATION_ID: segment_information.set_duration_unscaled(TRY_READ(streamer.read_float())); dbgln_if(MATROSKA_DEBUG, "Read Duration attribute: {}", segment_information.duration_unscaled().value()); break; default: TRY_READ(streamer.read_unknown_element()); } return IterationDecision::Continue; })); return segment_information; } DecoderErrorOr Reader::segment_information() { if (m_segment_information.has_value()) return m_segment_information.value(); auto position = TRY(find_first_top_level_element_with_id("Segment Information"sv, SEGMENT_INFORMATION_ELEMENT_ID)); if (!position.has_value()) return DecoderError::corrupted("No Segment Information element found"sv); Streamer streamer { m_data }; TRY_READ(streamer.seek_to_position(position.release_value())); m_segment_information = TRY(parse_information(streamer)); return m_segment_information.value(); } DecoderErrorOr Reader::ensure_tracks_are_parsed() { if (!m_tracks.is_empty()) return {}; auto position = TRY(find_first_top_level_element_with_id("Tracks"sv, TRACK_ELEMENT_ID)); if (!position.has_value()) return DecoderError::corrupted("No Tracks element found"sv); Streamer streamer { m_data }; TRY_READ(streamer.seek_to_position(position.release_value())); TRY(parse_tracks(streamer)); return {}; } static DecoderErrorOr parse_video_color_information(Streamer& streamer) { TrackEntry::ColorFormat color_format {}; TRY(parse_master_element(streamer, "Colour"sv, [&](u64 element_id) -> DecoderErrorOr { switch (element_id) { case PRIMARIES_ID: color_format.color_primaries = static_cast(TRY_READ(streamer.read_u64())); dbgln_if(MATROSKA_TRACE_DEBUG, "Read Colour's Primaries attribute: {}", color_primaries_to_string(color_format.color_primaries)); break; case TRANSFER_CHARACTERISTICS_ID: color_format.transfer_characteristics = static_cast(TRY_READ(streamer.read_u64())); dbgln_if(MATROSKA_TRACE_DEBUG, "Read Colour's TransferCharacteristics attribute: {}", transfer_characteristics_to_string(color_format.transfer_characteristics)); break; case MATRIX_COEFFICIENTS_ID: color_format.matrix_coefficients = static_cast(TRY_READ(streamer.read_u64())); dbgln_if(MATROSKA_TRACE_DEBUG, "Read Colour's MatrixCoefficients attribute: {}", matrix_coefficients_to_string(color_format.matrix_coefficients)); break; case BITS_PER_CHANNEL_ID: color_format.bits_per_channel = TRY_READ(streamer.read_u64()); dbgln_if(MATROSKA_TRACE_DEBUG, "Read Colour's BitsPerChannel attribute: {}", color_format.bits_per_channel); break; default: TRY_READ(streamer.read_unknown_element()); } return IterationDecision::Continue; })); return color_format; } static DecoderErrorOr parse_video_track_information(Streamer& streamer) { TrackEntry::VideoTrack video_track {}; TRY(parse_master_element(streamer, "VideoTrack"sv, [&](u64 element_id) -> DecoderErrorOr { switch (element_id) { case PIXEL_WIDTH_ID: video_track.pixel_width = TRY_READ(streamer.read_u64()); dbgln_if(MATROSKA_TRACE_DEBUG, "Read VideoTrack's PixelWidth attribute: {}", video_track.pixel_width); break; case PIXEL_HEIGHT_ID: video_track.pixel_height = TRY_READ(streamer.read_u64()); dbgln_if(MATROSKA_TRACE_DEBUG, "Read VideoTrack's PixelHeight attribute: {}", video_track.pixel_height); break; case COLOR_ENTRY_ID: video_track.color_format = TRY(parse_video_color_information(streamer)); break; default: TRY_READ(streamer.read_unknown_element()); } return IterationDecision::Continue; })); return video_track; } static DecoderErrorOr parse_audio_track_information(Streamer& streamer) { TrackEntry::AudioTrack audio_track {}; TRY(parse_master_element(streamer, "AudioTrack"sv, [&](u64 element_id) -> DecoderErrorOr { switch (element_id) { case CHANNELS_ID: audio_track.channels = TRY_READ(streamer.read_u64()); dbgln_if(MATROSKA_TRACE_DEBUG, "Read AudioTrack's Channels attribute: {}", audio_track.channels); break; case BIT_DEPTH_ID: audio_track.bit_depth = TRY_READ(streamer.read_u64()); dbgln_if(MATROSKA_TRACE_DEBUG, "Read AudioTrack's BitDepth attribute: {}", audio_track.bit_depth); break; default: TRY_READ(streamer.read_unknown_element()); } return IterationDecision::Continue; })); return audio_track; } static DecoderErrorOr parse_track_entry(Streamer& streamer) { TrackEntry track_entry; TRY(parse_master_element(streamer, "Track"sv, [&](u64 element_id) -> DecoderErrorOr { switch (element_id) { case TRACK_NUMBER_ID: track_entry.set_track_number(TRY_READ(streamer.read_u64())); dbgln_if(MATROSKA_TRACE_DEBUG, "Read TrackNumber attribute: {}", track_entry.track_number()); break; case TRACK_UID_ID: track_entry.set_track_uid(TRY_READ(streamer.read_u64())); dbgln_if(MATROSKA_TRACE_DEBUG, "Read TrackUID attribute: {}", track_entry.track_uid()); break; case TRACK_TYPE_ID: track_entry.set_track_type(static_cast(TRY_READ(streamer.read_u64()))); dbgln_if(MATROSKA_TRACE_DEBUG, "Read TrackType attribute: {}", to_underlying(track_entry.track_type())); break; case TRACK_LANGUAGE_ID: track_entry.set_language(TRY_READ(streamer.read_string())); dbgln_if(MATROSKA_TRACE_DEBUG, "Read Track's Language attribute: {}", track_entry.language()); break; case TRACK_CODEC_ID: track_entry.set_codec_id(TRY_READ(streamer.read_string())); dbgln_if(MATROSKA_TRACE_DEBUG, "Read Track's CodecID attribute: {}", track_entry.codec_id()); break; case TRACK_TIMESTAMP_SCALE_ID: track_entry.set_timestamp_scale(TRY_READ(streamer.read_float())); dbgln_if(MATROSKA_TRACE_DEBUG, "Read Track's TrackTimestampScale attribute: {}", track_entry.timestamp_scale()); break; case TRACK_OFFSET_ID: track_entry.set_timestamp_offset(TRY_READ(streamer.read_variable_size_signed_integer())); dbgln_if(MATROSKA_TRACE_DEBUG, "Read Track's TrackOffset attribute: {}", track_entry.timestamp_offset()); break; case TRACK_VIDEO_ID: track_entry.set_video_track(TRY(parse_video_track_information(streamer))); break; case TRACK_AUDIO_ID: track_entry.set_audio_track(TRY(parse_audio_track_information(streamer))); break; default: TRY_READ(streamer.read_unknown_element()); } return IterationDecision::Continue; })); return track_entry; } DecoderErrorOr Reader::parse_tracks(Streamer& streamer) { TRY(parse_master_element(streamer, "Tracks"sv, [&](u64 element_id) -> DecoderErrorOr { if (element_id == TRACK_ENTRY_ID) { auto track_entry = TRY(parse_track_entry(streamer)); dbgln_if(MATROSKA_DEBUG, "Parsed track {}", track_entry.track_number()); DECODER_TRY_ALLOC(m_tracks.try_set(track_entry.track_number(), track_entry)); } else { TRY_READ(streamer.read_unknown_element()); } return IterationDecision::Continue; })); return {}; } DecoderErrorOr Reader::for_each_track(TrackEntryCallback callback) { TRY(ensure_tracks_are_parsed()); for (auto const& track_entry : m_tracks) { auto decision = TRY(callback(track_entry.value)); if (decision == IterationDecision::Break) break; } return {}; } DecoderErrorOr Reader::for_each_track_of_type(TrackEntry::TrackType type, TrackEntryCallback callback) { return for_each_track([&](TrackEntry const& track_entry) -> DecoderErrorOr { if (track_entry.track_type() != type) return IterationDecision::Continue; return callback(track_entry); }); } DecoderErrorOr Reader::track_for_track_number(u64 track_number) { TRY(ensure_tracks_are_parsed()); auto optional_track_entry = m_tracks.get(track_number); if (!optional_track_entry.has_value()) return DecoderError::format(DecoderErrorCategory::Invalid, "No track found with number {}", track_number); return optional_track_entry.release_value(); } DecoderErrorOr Reader::track_count() { TRY(ensure_tracks_are_parsed()); return m_tracks.size(); } constexpr size_t get_element_id_size(u32 element_id) { return sizeof(element_id) - (count_leading_zeroes(element_id) / 8); } static DecoderErrorOr parse_cluster(Streamer& streamer, u64 timestamp_scale) { Optional timestamp; auto first_element_position = TRY(parse_master_element(streamer, "Cluster"sv, [&](u64 element_id) -> DecoderErrorOr { switch (element_id) { case TIMESTAMP_ID: timestamp = TRY_READ(streamer.read_u64()); return IterationDecision::Break; default: TRY_READ(streamer.read_unknown_element()); } return IterationDecision::Continue; })); if (!timestamp.has_value()) return DecoderError::corrupted("Cluster was missing a timestamp"sv); if (first_element_position == 0) return DecoderError::corrupted("Cluster had no children"sv); dbgln_if(MATROSKA_TRACE_DEBUG, "Seeking back to position {}", first_element_position); TRY_READ(streamer.seek_to_position(first_element_position)); Cluster cluster; cluster.set_timestamp(Duration::from_nanoseconds(timestamp.release_value() * timestamp_scale)); return cluster; } static DecoderErrorOr parse_simple_block(Streamer& streamer, Duration cluster_timestamp, u64 segment_timestamp_scale, TrackEntry track) { Block block; auto content_size = TRY_READ(streamer.read_variable_size_integer()); auto position_before_track_number = streamer.position(); block.set_track_number(TRY_READ(streamer.read_variable_size_integer())); // https://www.matroska.org/technical/notes.html // Block Timestamps: // The Block Element and SimpleBlock Element store their timestamps as signed integers, // relative to the Cluster\Timestamp value of the Cluster they are stored in. To get the // timestamp of a Block or SimpleBlock in nanoseconds you have to use the following formula: // `( Cluster\Timestamp + ( block timestamp * TrackTimestampScale ) ) * TimestampScale` // // When a CodecDelay Element is set, its value MUST be subtracted from each Block timestamp // of that track. To get the timestamp in nanoseconds of the first frame in a Block or // SimpleBlock, the formula becomes: // `( ( Cluster\Timestamp + ( block timestamp * TrackTimestampScale ) ) * TimestampScale ) - CodecDelay` Duration timestamp_offset = Duration::from_nanoseconds(static_cast(static_cast(TRY_READ(streamer.read_i16()) * segment_timestamp_scale) * track.timestamp_scale())); timestamp_offset -= Duration::from_nanoseconds(static_cast(track.codec_delay())); // This is only mentioned in the elements specification under TrackOffset. // https://www.matroska.org/technical/elements.html timestamp_offset += Duration::from_nanoseconds(static_cast(track.timestamp_offset())); block.set_timestamp(cluster_timestamp + timestamp_offset); auto flags = TRY_READ(streamer.read_octet()); block.set_only_keyframes((flags & (1u << 7u)) != 0); block.set_invisible((flags & (1u << 3u)) != 0); block.set_lacing(static_cast((flags & 0b110u) >> 1u)); block.set_discardable((flags & 1u) != 0); auto total_frame_content_size = content_size - (streamer.position() - position_before_track_number); Vector frames; if (block.lacing() == Block::Lacing::EBML) { auto octets_read_before_frame_sizes = streamer.octets_read(); auto frame_count = TRY_READ(streamer.read_octet()) + 1; Vector frame_sizes; frame_sizes.ensure_capacity(frame_count); u64 frame_size_sum = 0; u64 previous_frame_size; auto first_frame_size = TRY_READ(streamer.read_variable_size_integer()); frame_sizes.append(first_frame_size); frame_size_sum += first_frame_size; previous_frame_size = first_frame_size; for (int i = 0; i < frame_count - 2; i++) { auto frame_size_difference = TRY_READ(streamer.read_variable_size_signed_integer()); u64 frame_size; // FIXME: x - (-y) == x + y? if (frame_size_difference < 0) frame_size = previous_frame_size - (-frame_size_difference); else frame_size = previous_frame_size + frame_size_difference; frame_sizes.append(frame_size); frame_size_sum += frame_size; previous_frame_size = frame_size; } frame_sizes.append(total_frame_content_size - frame_size_sum - (streamer.octets_read() - octets_read_before_frame_sizes)); for (int i = 0; i < frame_count; i++) { // FIXME: ReadonlyBytes instead of copying the frame data? auto current_frame_size = frame_sizes.at(i); frames.append(TRY_READ(streamer.read_raw_octets(current_frame_size))); } } else if (block.lacing() == Block::Lacing::FixedSize) { auto frame_count = TRY_READ(streamer.read_octet()) + 1; auto individual_frame_size = total_frame_content_size / frame_count; for (int i = 0; i < frame_count; i++) frames.append(TRY_READ(streamer.read_raw_octets(individual_frame_size))); } else { frames.append(TRY_READ(streamer.read_raw_octets(total_frame_content_size))); } block.set_frames(move(frames)); return block; } DecoderErrorOr Reader::create_sample_iterator(u64 track_number) { auto optional_position = TRY(find_first_top_level_element_with_id("Cluster"sv, CLUSTER_ELEMENT_ID)); if (!optional_position.has_value()) return DecoderError::corrupted("No clusters are present in the segment"sv); ReadonlyBytes segment_view = m_data.slice(m_segment_contents_position, m_segment_contents_size); // We need to have the element ID included so that the iterator knows where it is. auto position = optional_position.value() - get_element_id_size(CLUSTER_ELEMENT_ID) - m_segment_contents_position; dbgln_if(MATROSKA_DEBUG, "Creating sample iterator starting at {} relative to segment at {}", position, m_segment_contents_position); return SampleIterator(this->m_mapped_file, segment_view, TRY(track_for_track_number(track_number)), TRY(segment_information()).timestamp_scale(), position); } static DecoderErrorOr parse_cue_track_position(Streamer& streamer) { CueTrackPosition track_position; bool had_cluster_position = false; TRY_READ(parse_master_element(streamer, "CueTrackPositions"sv, [&](u64 element_id) -> DecoderErrorOr { switch (element_id) { case CUE_TRACK_ID: track_position.set_track_number(TRY_READ(streamer.read_u64())); dbgln_if(MATROSKA_TRACE_DEBUG, "Read CueTrackPositions track number {}", track_position.track_number()); break; case CUE_CLUSTER_POSITION_ID: track_position.set_cluster_position(TRY_READ(streamer.read_u64())); dbgln_if(MATROSKA_TRACE_DEBUG, "Read CueTrackPositions cluster position {}", track_position.cluster_position()); had_cluster_position = true; break; case CUE_RELATIVE_POSITION_ID: track_position.set_block_offset(TRY_READ(streamer.read_u64())); dbgln_if(MATROSKA_TRACE_DEBUG, "Read CueTrackPositions relative position {}", track_position.block_offset()); break; case CUE_CODEC_STATE_ID: // Mandatory in spec, but not present in files? 0 means use TrackEntry's codec state. // FIXME: Do something with this value. dbgln_if(MATROSKA_DEBUG, "Found CodecState, skipping"); TRY_READ(streamer.read_unknown_element()); break; case CUE_REFERENCE_ID: return DecoderError::not_implemented(); default: TRY_READ(streamer.read_unknown_element()); break; } return IterationDecision::Continue; })); if (track_position.track_number() == 0) return DecoderError::corrupted("Track number was not present or 0"sv); if (!had_cluster_position) return DecoderError::corrupted("Cluster was missing the cluster position"sv); return track_position; } static DecoderErrorOr parse_cue_point(Streamer& streamer, u64 timestamp_scale) { CuePoint cue_point; TRY(parse_master_element(streamer, "CuePoint"sv, [&](u64 element_id) -> DecoderErrorOr { switch (element_id) { case CUE_TIME_ID: { // On https://www.matroska.org/technical/elements.html, spec says of the CueTime element: // > Absolute timestamp of the seek point, expressed in Matroska Ticks -- ie in nanoseconds; see timestamp-ticks. // Matroska Ticks are specified in https://www.matroska.org/technical/notes.html: // > For such elements, the timestamp value is stored directly in nanoseconds. // However, my test files appear to use Segment Ticks, which uses the segment's timestamp scale, and Mozilla's nestegg parser agrees: // https://github.com/mozilla/nestegg/tree/ec6adfbbf979678e3058cc4695257366f39e290b/src/nestegg.c#L1941 // https://github.com/mozilla/nestegg/tree/ec6adfbbf979678e3058cc4695257366f39e290b/src/nestegg.c#L2411-L2416 // https://github.com/mozilla/nestegg/tree/ec6adfbbf979678e3058cc4695257366f39e290b/src/nestegg.c#L1383-L1392 // Other fields that specify Matroska Ticks may also use Segment Ticks instead, who knows :^( auto timestamp = Duration::from_nanoseconds(static_cast(TRY_READ(streamer.read_u64()) * timestamp_scale)); cue_point.set_timestamp(timestamp); dbgln_if(MATROSKA_DEBUG, "Read CuePoint timestamp {}ms", cue_point.timestamp().to_milliseconds()); break; } case CUE_TRACK_POSITIONS_ID: { auto track_position = TRY_READ(parse_cue_track_position(streamer)); DECODER_TRY_ALLOC(cue_point.track_positions().try_set(track_position.track_number(), track_position)); break; } default: TRY_READ(streamer.read_unknown_element()); break; } return IterationDecision::Continue; })); if (cue_point.timestamp().is_negative()) return DecoderError::corrupted("CuePoint was missing a timestamp"sv); if (cue_point.track_positions().is_empty()) return DecoderError::corrupted("CuePoint was missing track positions"sv); return cue_point; } DecoderErrorOr Reader::parse_cues(Streamer& streamer) { m_cues.clear(); TRY(parse_master_element(streamer, "Cues"sv, [&](u64 element_id) -> DecoderErrorOr { switch (element_id) { case CUE_POINT_ID: { auto cue_point = TRY(parse_cue_point(streamer, TRY(segment_information()).timestamp_scale())); // FIXME: Verify that these are already in order of timestamp. If they are not, return a corrupted error for now, // but if it turns out that Matroska files with out-of-order cue points are valid, sort them instead. for (auto track_position_entry : cue_point.track_positions()) { if (!m_cues.contains(track_position_entry.key)) DECODER_TRY_ALLOC(m_cues.try_set(track_position_entry.key, Vector())); Vector& cue_points_for_track = m_cues.get(track_position_entry.key).release_value(); cue_points_for_track.append(cue_point); } break; } default: return DecoderError::format(DecoderErrorCategory::Corrupted, "Unknown Cues child ID {:#010x}", element_id); } return IterationDecision::Continue; })); return {}; } DecoderErrorOr Reader::ensure_cues_are_parsed() { if (m_cues_have_been_parsed) return {}; auto position = TRY(find_first_top_level_element_with_id("Cues"sv, CUES_ID)); if (!position.has_value()) return DecoderError::corrupted("No Tracks element found"sv); Streamer streamer { m_data }; TRY_READ(streamer.seek_to_position(position.release_value())); TRY(parse_cues(streamer)); m_cues_have_been_parsed = true; return {}; } DecoderErrorOr Reader::seek_to_cue_for_timestamp(SampleIterator& iterator, Duration const& timestamp) { auto const& cue_points = MUST(cue_points_for_track(iterator.m_track.track_number())).release_value(); // Take a guess at where in the cues the timestamp will be and correct from there. auto duration = TRY(segment_information()).duration(); size_t index = 0; if (duration.has_value()) index = clamp(((timestamp.to_nanoseconds() * cue_points.size()) / TRY(segment_information()).duration()->to_nanoseconds()), 0, cue_points.size() - 1); CuePoint const* prev_cue_point = &cue_points[index]; dbgln_if(MATROSKA_DEBUG, "Finding Matroska cue points for timestamp {}ms starting from cue at {}ms", timestamp.to_milliseconds(), prev_cue_point->timestamp().to_milliseconds()); if (prev_cue_point->timestamp() == timestamp) { TRY(iterator.seek_to_cue_point(*prev_cue_point)); return {}; } if (prev_cue_point->timestamp() > timestamp) { while (index > 0 && prev_cue_point->timestamp() > timestamp) { prev_cue_point = &cue_points[--index]; dbgln_if(MATROSKA_DEBUG, "Checking previous cue point {}ms", prev_cue_point->timestamp().to_milliseconds()); } TRY(iterator.seek_to_cue_point(*prev_cue_point)); return {}; } while (++index < cue_points.size()) { auto const& cue_point = cue_points[index]; dbgln_if(MATROSKA_DEBUG, "Checking future cue point {}ms", cue_point.timestamp().to_milliseconds()); if (cue_point.timestamp() > timestamp) break; prev_cue_point = &cue_point; } TRY(iterator.seek_to_cue_point(*prev_cue_point)); return {}; } static DecoderErrorOr search_clusters_for_keyframe_before_timestamp(SampleIterator& iterator, Duration const& timestamp) { #if MATROSKA_DEBUG size_t inter_frames_count; #endif Optional last_keyframe; while (true) { SampleIterator rewind_iterator = iterator; auto block = TRY(iterator.next_block()); if (block.only_keyframes()) { last_keyframe.emplace(rewind_iterator); #if MATROSKA_DEBUG inter_frames_count = 0; #endif } if (block.timestamp() > timestamp) break; #if MATROSKA_DEBUG inter_frames_count++; #endif } if (last_keyframe.has_value()) { #if MATROSKA_DEBUG dbgln("Seeked to a keyframe with {} inter frames to skip", inter_frames_count); #endif iterator = last_keyframe.release_value(); } return {}; } DecoderErrorOr Reader::has_cues_for_track(u64 track_number) { TRY(ensure_cues_are_parsed()); return m_cues.contains(track_number); } DecoderErrorOr Reader::seek_to_random_access_point(SampleIterator iterator, Duration timestamp) { if (TRY(has_cues_for_track(iterator.m_track.track_number()))) { TRY(seek_to_cue_for_timestamp(iterator, timestamp)); VERIFY(iterator.last_timestamp().has_value()); return iterator; } if (!iterator.last_timestamp().has_value() || timestamp < iterator.last_timestamp().value()) { // If the timestamp is before the iterator's current position, then we need to start from the beginning of the Segment. iterator = TRY(create_sample_iterator(iterator.m_track.track_number())); TRY(search_clusters_for_keyframe_before_timestamp(iterator, timestamp)); return iterator; } TRY(search_clusters_for_keyframe_before_timestamp(iterator, timestamp)); return iterator; } DecoderErrorOr const&>> Reader::cue_points_for_track(u64 track_number) { TRY(ensure_cues_are_parsed()); return m_cues.get(track_number); } DecoderErrorOr SampleIterator::next_block() { if (m_position >= m_data.size()) return DecoderError::with_description(DecoderErrorCategory::EndOfStream, "Still at end of stream :^)"sv); Streamer streamer { m_data }; TRY_READ(streamer.seek_to_position(m_position)); Optional block; while (streamer.has_octet()) { #if MATROSKA_TRACE_DEBUG auto element_position = streamer.position(); #endif auto element_id = TRY_READ(streamer.read_variable_size_integer(false)); #if MATROSKA_TRACE_DEBUG dbgln("Iterator found element with ID {:#010x} at offset {} within the segment.", element_id, element_position); #endif if (element_id == CLUSTER_ELEMENT_ID) { dbgln_if(MATROSKA_DEBUG, " Iterator is parsing new cluster."); m_current_cluster = TRY(parse_cluster(streamer, m_segment_timestamp_scale)); } else if (element_id == SIMPLE_BLOCK_ID) { dbgln_if(MATROSKA_TRACE_DEBUG, " Iterator is parsing new block."); auto candidate_block = TRY(parse_simple_block(streamer, m_current_cluster->timestamp(), m_segment_timestamp_scale, m_track)); if (candidate_block.track_number() == m_track.track_number()) block = move(candidate_block); } else { dbgln_if(MATROSKA_TRACE_DEBUG, " Iterator is skipping unknown element with ID {:#010x}.", element_id); TRY_READ(streamer.read_unknown_element()); } m_position = streamer.position(); if (block.has_value()) { m_last_timestamp = block->timestamp(); return block.release_value(); } } m_current_cluster.clear(); return DecoderError::with_description(DecoderErrorCategory::EndOfStream, "End of stream"sv); } DecoderErrorOr SampleIterator::seek_to_cue_point(CuePoint const& cue_point) { // This is a private function. The position getter can return optional, but the caller should already know that this track has a position. auto const& cue_position = cue_point.position_for_track(m_track.track_number()).release_value(); Streamer streamer { m_data }; TRY_READ(streamer.seek_to_position(cue_position.cluster_position())); auto element_id = TRY_READ(streamer.read_variable_size_integer(false)); if (element_id != CLUSTER_ELEMENT_ID) return DecoderError::corrupted("Cue point's cluster position didn't point to a cluster"sv); m_current_cluster = TRY(parse_cluster(streamer, m_segment_timestamp_scale)); dbgln_if(MATROSKA_DEBUG, "SampleIterator set to cue point at timestamp {}ms", m_current_cluster->timestamp().to_milliseconds()); m_position = streamer.position() + cue_position.block_offset(); m_last_timestamp = cue_point.timestamp(); return {}; } ErrorOr Streamer::read_string() { auto string_length = TRY(read_variable_size_integer()); if (remaining() < string_length) return Error::from_string_literal("String length extends past the end of the stream"); auto string_value = DeprecatedString(data_as_chars(), string_length); TRY(read_raw_octets(string_length)); return string_value; } ErrorOr Streamer::read_octet() { if (!has_octet()) { dbgln_if(MATROSKA_TRACE_DEBUG, "Ran out of stream data"); return Error::from_string_literal("Stream is out of data"); } u8 byte = *data(); m_octets_read.last()++; m_position++; return byte; } ErrorOr Streamer::read_i16() { return (TRY(read_octet()) << 8) | TRY(read_octet()); } ErrorOr Streamer::read_variable_size_integer(bool mask_length) { dbgln_if(MATROSKA_TRACE_DEBUG, "Reading VINT from offset {:p}", position()); auto length_descriptor = TRY(read_octet()); dbgln_if(MATROSKA_TRACE_DEBUG, "Reading VINT, first byte is {:#02x}", length_descriptor); if (length_descriptor == 0) return Error::from_string_literal("read_variable_size_integer: Length descriptor has no terminating set bit"); size_t length = 0; while (length < 8) { if (((length_descriptor >> (8 - length)) & 1) == 1) break; length++; } dbgln_if(MATROSKA_TRACE_DEBUG, "Reading VINT of total length {}", length); if (length > 8) return Error::from_string_literal("read_variable_size_integer: Length is too large"); u64 result; if (mask_length) result = length_descriptor & ~(1u << (8 - length)); else result = length_descriptor; dbgln_if(MATROSKA_TRACE_DEBUG, "Beginning of VINT is {:#02x}", result); for (size_t i = 1; i < length; i++) { u8 next_octet = TRY(read_octet()); dbgln_if(MATROSKA_TRACE_DEBUG, "Read octet of {:#02x}", next_octet); result = (result << 8u) | next_octet; dbgln_if(MATROSKA_TRACE_DEBUG, "New result is {:#010x}", result); } return result; } ErrorOr Streamer::read_variable_size_signed_integer() { auto length_descriptor = TRY(read_octet()); if (length_descriptor == 0) return Error::from_string_literal("read_variable_sized_signed_integer: Length descriptor has no terminating set bit"); i64 length = 0; while (length < 8) { if (((length_descriptor >> (8 - length)) & 1) == 1) break; length++; } if (length > 8) return Error::from_string_literal("read_variable_size_integer: Length is too large"); i64 result = length_descriptor & ~(1u << (8 - length)); for (i64 i = 1; i < length; i++) { u8 next_octet = TRY(read_octet()); result = (result << 8u) | next_octet; } result -= AK::exp2(length * 7 - 1) - 1; return result; } ErrorOr Streamer::read_raw_octets(size_t num_octets) { if (remaining() < num_octets) return Error::from_string_literal("Tried to drop octets past the end of the stream"); ReadonlyBytes result = { data(), num_octets }; m_position += num_octets; m_octets_read.last() += num_octets; return result; } ErrorOr Streamer::read_u64() { auto integer_length = TRY(read_variable_size_integer()); u64 result = 0; for (size_t i = 0; i < integer_length; i++) { result = (result << 8u) + TRY(read_octet()); } return result; } ErrorOr Streamer::read_float() { auto length = TRY(read_variable_size_integer()); if (length != 4u && length != 8u) return Error::from_string_literal("Float size must be 4 or 8 bytes"); union { u64 value; float float_value; double double_value; } read_data; read_data.value = 0; for (size_t i = 0; i < length; i++) { read_data.value = (read_data.value << 8u) + TRY(read_octet()); } if (length == 4u) return read_data.float_value; return read_data.double_value; } ErrorOr Streamer::read_unknown_element() { auto element_length = TRY(read_variable_size_integer()); dbgln_if(MATROSKA_TRACE_DEBUG, "Skipping unknown element of size {}.", element_length); TRY(read_raw_octets(element_length)); return {}; } ErrorOr Streamer::seek_to_position(size_t position) { if (position >= m_data.size()) return Error::from_string_literal("Attempted to seek past the end of the stream"); m_position = position; return {}; } }