// Copyright 2018 Google LLC. All rights reserved. // // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file or at // https://developers.google.com/open-source/licenses/bsd #include #include #include #include #include namespace shaka { namespace media { namespace { // 3. Symbols and abbreviated terms. enum MotionType { IDENTITY = 0, TRANSLATION, ROTZOOM, AFFINE, }; const int kSelectScreenContentTools = 2; const int kSelectIntegerMv = 2; const int kPrimaryRefNone = 7; const int kNumRefFrames = 8; const int kAllFrames = (1 << kNumRefFrames) - 1; // 6.2.2. OBU header semantics. enum ObuType { OBU_SEQUENCE_HEADER = 1, OBU_TEMPORAL_DELIMITER, OBU_FRAME_HEADER, OBU_TILE_GROUP, OBU_METADATA, OBU_FRAME, OBU_REDUNDENT_FRAME_HEADER, OBU_TILE_LIST, // Reserved types between OBU_TILE_LIST and OBU_PADDING. OBU_PADDING = 15, }; // 6.4.2. Color config semantics. enum ColorPrimaries { CP_BT_709 = 1, CP_UNSPECIFIED = 2, // We are not interested in the others. }; enum TransferCharacteristics { TC_UNSPECIFIED = 2, TC_SRGB = 13, // We are not interested in the others. }; enum MatrixCoefficients { MC_IDENTITY = 0, MC_UNSPECIFIED = 2, // We are not interested in the others. }; enum ChromaSamplePosition { CSP_UNKNOWN = 0, CSP_VERTICAL, CSP_COLOCATED, CSP_RESERVED, }; // 6.8.2. Uncompressed header semantics. enum FrameType { KEY_FRAME = 0, INTER_FRAME, INTRA_ONLY_FRAME, SWITCH_FRAME, }; // 6.10.24. Ref frames semantics. enum RefFrameName { INTRA_FRAME = 0, LAST_FRAME, LAST2_FRAME, LAST3_FRAME, GOLDEN_FRAME, BWDREF_FRAME, ALTREF2_FRAME, ALTREF_FRAME, }; // 4.7. Mathematical functions. int Clip3(int min_value, int max_value, int value) { if (value < min_value) return min_value; if (value > max_value) return max_value; return value; } // 4.7. Mathematical functions. The FloorLog2(x) function is defined to be the // floor of the base 2 logarithm of the input x. int FloorLog2(int x) { int s = 0; while (x != 0) { x = x >> 1; s++; } return s - 1; } // 4.10.3. uvlc(). This is a modified form of Exponential-Golomb coding. bool ReadUvlc(BitReader* reader, uint32_t* val) { // Count the number of contiguous zero bits. int leading_zeros = 0; while (true) { bool done = false; RCHECK(reader->ReadBits(1, &done)); if (done) break; leading_zeros++; } if (leading_zeros >= 32) { *val = (1ull << 32) - 1; return true; } int value = 0; if (leading_zeros > 0) RCHECK(reader->ReadBits(leading_zeros, &value)); *val = value + (1 << leading_zeros) - 1; return true; } // 4.10.4. le(n). Unsigned little-endian n-byte number appearing directly in the // bitstream. bool ReadLe(int n, BitReader* reader, size_t* val) { size_t t = 0; for (int i = 0; i < n; i++) { size_t byte = 0; RCHECK(reader->ReadBits(8, &byte)); t += (byte << (i * 8)); } *val = t; return true; } // 4.10.5. leb128(). Unsigned integer represented by a variable number of // little-endian bytes. bool ReadLeb128(BitReader* reader, size_t* size) { size_t value = 0; for (int i = 0; i < 8; i++) { size_t leb128_byte = 0; RCHECK(reader->ReadBits(8, &leb128_byte)); value |= (leb128_byte & 0x7f) << (i * 7); if (!(leb128_byte & 0x80)) break; } // It is a requirement of bitstream conformance that the value returned from // the leb128 parsing process is less than or equal to (1<<32) - 1. RCHECK(value <= ((1ull << 32) - 1)); *size = value; return true; } // 4.10.6. su(n). Signed integer converted from an n bits unsigned integer in // the bitstream. bool ReadSu(int n, BitReader* reader, int* value) { RCHECK(reader->ReadBits(n, value)); int sign_mask = 1 << (n - 1); if (*value & sign_mask) *value = *value - 2 * sign_mask; return true; } // 4.10.7. ns(n). Unsigned encoded integer with maximum number of values in n // (i.e. output in range 0..n-1). bool ReadNs(int n, BitReader* reader, int* value) { const int w = FloorLog2(n) + 1; const int m = (1 << w) - n; RCHECK(reader->ReadBits(w - 1, value)); if (*value < m) return true; int extra_bit = 0; RCHECK(reader->ReadBits(1, &extra_bit)); *value = (*value << 1) - m + extra_bit; return true; } // 5.9.16. Tile size calculation function: returns the smallest value for k such // that blk_size << k is greater than or equal to target. int TileLog2(int blk_size, int target) { int k = 0; for (k = 0; (blk_size << k) < target; k++) continue; return k; } // See 7.8. Set frame refs process. int FindLatestBackward(int shifted_order_hints[], bool used_frame[], int cur_frame_hint) { int ref = -1; int latest_order_hint = 0; for (int i = 0; i < kNumRefFrames; i++) { const int hint = shifted_order_hints[i]; if (!used_frame[i] && hint >= cur_frame_hint && (ref < 0 || hint >= latest_order_hint)) { ref = i; latest_order_hint = hint; } } return ref; } // See 7.8. Set frame refs process. int FindEarliestBackward(int shifted_order_hints[], bool used_frame[], int cur_frame_hint) { int ref = -1; int earliest_order_hint = 0; for (int i = 0; i < kNumRefFrames; i++) { const int hint = shifted_order_hints[i]; if (!used_frame[i] && hint >= cur_frame_hint && (ref < 0 || hint < earliest_order_hint)) { ref = i; earliest_order_hint = hint; } } return ref; } // See 7.8. Set frame refs process. int FindLatestForward(int shifted_order_hints[], bool used_frame[], int cur_frame_hint) { int ref = -1; int latest_order_hint = 0; for (int i = 0; i < kNumRefFrames; i++) { const int hint = shifted_order_hints[i]; if (!used_frame[i] && hint < cur_frame_hint && (ref < 0 || hint >= latest_order_hint)) { ref = i; latest_order_hint = hint; } } return ref; } } // namespace AV1Parser::AV1Parser() = default; AV1Parser::~AV1Parser() = default; bool AV1Parser::Parse(const uint8_t* data, size_t data_size, std::vector* tiles) { tiles->clear(); BitReader reader(data, data_size); while (reader.bits_available() > 0) { if (!ParseOpenBitstreamUnit(&reader, tiles)) return false; } return true; } // 5.3.1. General OBU syntax. bool AV1Parser::ParseOpenBitstreamUnit(BitReader* reader, std::vector* tiles) { ObuHeader obu_header; RCHECK(ParseObuHeader(reader, &obu_header)); size_t obu_size = 0; if (obu_header.obu_has_size_field) RCHECK(ReadLeb128(reader, &obu_size)); else obu_size = reader->bits_available() / 8; VLOG(4) << "OBU " << obu_header.obu_type << " size " << obu_size; const size_t start_position = reader->bit_position(); switch (obu_header.obu_type) { case OBU_SEQUENCE_HEADER: RCHECK(ParseSequenceHeaderObu(reader)); break; case OBU_FRAME_HEADER: case OBU_REDUNDENT_FRAME_HEADER: RCHECK(ParseFrameHeaderObu(obu_header, reader)); break; case OBU_TILE_GROUP: RCHECK(ParseTileGroupObu(obu_size, reader, tiles)); break; case OBU_FRAME: RCHECK(ParseFrameObu(obu_header, obu_size, reader, tiles)); break; default: // Skip all OBUs we are not interested. RCHECK(reader->SkipBits(obu_size * 8)); break; } const size_t current_position = reader->bit_position(); const size_t payload_bits = current_position - start_position; if (obu_header.obu_type == OBU_TILE_GROUP || obu_header.obu_type == OBU_FRAME) { RCHECK(payload_bits == obu_size * 8); } else if (obu_size > 0) { RCHECK(payload_bits <= obu_size * 8); RCHECK(ParseTrailingBits(obu_size * 8 - payload_bits, reader)); } return true; } // 5.3.2. OBU header syntax. bool AV1Parser::ParseObuHeader(BitReader* reader, ObuHeader* obu_header) { int obu_forbidden_bit = 0; RCHECK(reader->ReadBits(1, &obu_forbidden_bit)); RCHECK(obu_forbidden_bit == 0); RCHECK(reader->ReadBits(4, &obu_header->obu_type)); bool obu_extension_flag = false; RCHECK(reader->ReadBits(1, &obu_extension_flag)); RCHECK(reader->ReadBits(1, &obu_header->obu_has_size_field)); RCHECK(reader->SkipBits(1)); // Skip obu_reserved_1bit. if (obu_extension_flag) RCHECK(ParseObuExtensionHeader(reader, &obu_header->extension_header)); return true; } // 5.3.3. OBU extension header syntax. bool AV1Parser::ParseObuExtensionHeader( BitReader* reader, ObuExtensionHeader* obu_extension_header) { RCHECK(reader->ReadBits(3, &obu_extension_header->temporal_id)); RCHECK(reader->ReadBits(2, &obu_extension_header->spatial_id)); RCHECK(reader->SkipBits(3)); // Skip extension_header_reserved_3bits. return true; } // 5.3.4. Trailing bits syntax. bool AV1Parser::ParseTrailingBits(size_t nb_bits, BitReader* reader) { int trailing_one_bit = 0; RCHECK(reader->ReadBits(1, &trailing_one_bit)); RCHECK(trailing_one_bit == 1); nb_bits--; while (nb_bits > 0) { int trailing_zero_bit = 0; RCHECK(reader->ReadBits(1, &trailing_zero_bit)); RCHECK(trailing_zero_bit == 0); nb_bits--; } return true; } bool AV1Parser::ByteAlignment(BitReader* reader) { while (reader->bit_position() & 7) { int zero_bit = 0; RCHECK(reader->ReadBits(1, &zero_bit)); RCHECK(zero_bit == 0); } return true; } // 5.5.1. General sequence header OBU syntax. bool AV1Parser::ParseSequenceHeaderObu(BitReader* reader) { RCHECK(reader->ReadBits(3, &sequence_header_.seq_profile)); // Skip still_picture. RCHECK(reader->SkipBits(1)); RCHECK(reader->ReadBits(1, &sequence_header_.reduced_still_picture_header)); if (sequence_header_.reduced_still_picture_header) { sequence_header_.decoder_model_info_present_flag = false; sequence_header_.operating_points_cnt_minus_1 = 0; sequence_header_.operating_point_idc[0] = 0; // Skip seq_level_idx[0]. RCHECK(reader->SkipBits(5)); sequence_header_.decoder_model_present_for_this_op[0] = false; } else { bool timing_info_present_flag = false; RCHECK(reader->ReadBits(1, &timing_info_present_flag)); bool decoder_model_info_present_flag = false; if (timing_info_present_flag) { RCHECK(ParseTimingInfo(reader)); RCHECK(reader->ReadBits(1, &decoder_model_info_present_flag)); if (decoder_model_info_present_flag) RCHECK(ParseDecoderModelInfo(reader)); } sequence_header_.decoder_model_info_present_flag = decoder_model_info_present_flag; bool initial_display_delay_present_flag = false; RCHECK(reader->ReadBits(1, &initial_display_delay_present_flag)); RCHECK(reader->ReadBits(5, &sequence_header_.operating_points_cnt_minus_1)); for (int i = 0; i <= sequence_header_.operating_points_cnt_minus_1; i++) { RCHECK(reader->ReadBits(12, &sequence_header_.operating_point_idc[i])); int seq_level_idx_i = 0; RCHECK(reader->ReadBits(5, &seq_level_idx_i)); if (seq_level_idx_i > 7) { // Skip seq_tier[i]. RCHECK(reader->SkipBits(1)); } if (sequence_header_.decoder_model_info_present_flag) { RCHECK(reader->ReadBits( 1, &sequence_header_.decoder_model_present_for_this_op[i])); if (sequence_header_.decoder_model_present_for_this_op[i]) { RCHECK(SkipOperatingParametersInfo(reader)); } } else { sequence_header_.decoder_model_present_for_this_op[i] = false; } if (initial_display_delay_present_flag) { // Skip initial_display_delay_present_for_this_op[i], // initial_display_delay_minus_1[i]. RCHECK(reader->SkipBitsConditional(true, 4)); } } } RCHECK(reader->ReadBits(4, &sequence_header_.frame_width_bits_minus_1)); RCHECK(reader->ReadBits(4, &sequence_header_.frame_height_bits_minus_1)); RCHECK(reader->ReadBits(sequence_header_.frame_width_bits_minus_1 + 1, &sequence_header_.max_frame_width_minus_1)); RCHECK(reader->ReadBits(sequence_header_.frame_height_bits_minus_1 + 1, &sequence_header_.max_frame_height_minus_1)); if (sequence_header_.reduced_still_picture_header) { sequence_header_.frame_id_numbers_present_flag = false; } else { RCHECK( reader->ReadBits(1, &sequence_header_.frame_id_numbers_present_flag)); } if (sequence_header_.frame_id_numbers_present_flag) { RCHECK( reader->ReadBits(4, &sequence_header_.delta_frame_id_length_minus_2)); RCHECK(reader->ReadBits( 3, &sequence_header_.additional_frame_id_length_minus_1)); } RCHECK(reader->ReadBits(1, &sequence_header_.use_128x128_superblock)); // Skip enable_filter_intra, enable_intra_edge_filter. RCHECK(reader->SkipBits(1 + 1)); if (sequence_header_.reduced_still_picture_header) { sequence_header_.enable_warped_motion = false; sequence_header_.enable_order_hint = false; sequence_header_.enable_ref_frame_mvs = false; sequence_header_.order_hint_bits = 0; sequence_header_.seq_force_screen_content_tools = kSelectScreenContentTools; sequence_header_.seq_force_integer_mv = kSelectIntegerMv; } else { // Skip enable_interintra_compound, enable_masked_compound, RCHECK(reader->SkipBits(1 + 1)); RCHECK(reader->ReadBits(1, &sequence_header_.enable_warped_motion)); RCHECK(reader->SkipBits(1)); // Skip enable_dual_filter. RCHECK(reader->ReadBits(1, &sequence_header_.enable_order_hint)); if (sequence_header_.enable_order_hint) { // Skip enable_jnt_comp. RCHECK(reader->SkipBits(1)); RCHECK(reader->ReadBits(1, &sequence_header_.enable_ref_frame_mvs)); } else { sequence_header_.enable_ref_frame_mvs = false; } bool seq_choose_screen_content_tools = false; RCHECK(reader->ReadBits(1, &seq_choose_screen_content_tools)); if (seq_choose_screen_content_tools) { sequence_header_.seq_force_screen_content_tools = kSelectScreenContentTools; } else { RCHECK(reader->ReadBits( 1, &sequence_header_.seq_force_screen_content_tools)); } if (sequence_header_.seq_force_screen_content_tools > 0) { bool seq_choose_integer_mv = false; RCHECK(reader->ReadBits(1, &seq_choose_integer_mv)); if (seq_choose_integer_mv) sequence_header_.seq_force_integer_mv = kSelectIntegerMv; else RCHECK(reader->ReadBits(1, &sequence_header_.seq_force_integer_mv)); } else { sequence_header_.seq_force_integer_mv = kSelectIntegerMv; } if (sequence_header_.enable_order_hint) { int order_hint_bits_minus_1 = 0; RCHECK(reader->ReadBits(3, &order_hint_bits_minus_1)); sequence_header_.order_hint_bits = order_hint_bits_minus_1 + 1; } else { sequence_header_.order_hint_bits = 0; } } RCHECK(reader->ReadBits(1, &sequence_header_.enable_superres)); RCHECK(reader->ReadBits(1, &sequence_header_.enable_cdef)); RCHECK(reader->ReadBits(1, &sequence_header_.enable_restoration)); RCHECK(ParseColorConfig(reader)); RCHECK(reader->ReadBits(1, &sequence_header_.film_grain_params_present)); return true; } // 5.5.2. Color config syntax. bool AV1Parser::ParseColorConfig(BitReader* reader) { ColorConfig& color_config = sequence_header_.color_config; bool high_bitdepth = false; RCHECK(reader->ReadBits(1, &high_bitdepth)); if (sequence_header_.seq_profile == 2 && high_bitdepth) { bool twelve_bit = false; RCHECK(reader->ReadBits(1, &twelve_bit)); color_config.bit_depth = twelve_bit ? 12 : 10; } else if (sequence_header_.seq_profile <= 2) { color_config.bit_depth = high_bitdepth ? 10 : 8; } if (sequence_header_.seq_profile == 1) color_config.mono_chrome = 0; else RCHECK(reader->ReadBits(1, &color_config.mono_chrome)); color_config.num_planes = color_config.mono_chrome ? 1 : 3; bool color_description_present_flag = false; RCHECK(reader->ReadBits(1, &color_description_present_flag)); if (color_description_present_flag) { RCHECK(reader->ReadBits(8, &color_config.color_primaries)); RCHECK(reader->ReadBits(8, &color_config.transfer_chracteristics)); RCHECK(reader->ReadBits(8, &color_config.matrix_coefficients)); } else { color_config.color_primaries = CP_UNSPECIFIED; color_config.transfer_chracteristics = TC_UNSPECIFIED; color_config.matrix_coefficients = MC_UNSPECIFIED; } if (color_config.mono_chrome) { RCHECK(reader->ReadBits(1, &color_config.color_range)); color_config.subsampling_x = true; color_config.subsampling_y = true; color_config.chroma_sampling_position = CSP_UNKNOWN; color_config.separate_uv_delta_q = false; return true; } else if (color_config.color_primaries == CP_BT_709 && color_config.transfer_chracteristics == TC_SRGB && color_config.matrix_coefficients == MC_IDENTITY) { color_config.color_range = true; color_config.subsampling_x = false; color_config.subsampling_y = false; } else { RCHECK(reader->ReadBits(1, &color_config.color_range)); if (sequence_header_.seq_profile == 0) { color_config.subsampling_x = true; color_config.subsampling_y = true; } else if (sequence_header_.seq_profile == 1) { color_config.subsampling_x = false; color_config.subsampling_y = false; } else { if (color_config.bit_depth == 12) { RCHECK(reader->ReadBits(1, &color_config.subsampling_x)); if (color_config.subsampling_x) RCHECK(reader->ReadBits(1, &color_config.subsampling_y)); else color_config.subsampling_y = false; } else { color_config.subsampling_x = true; color_config.subsampling_y = false; } } if (color_config.subsampling_x && color_config.subsampling_y) RCHECK(reader->ReadBits(2, &color_config.chroma_sampling_position)); } RCHECK(reader->ReadBits(1, &color_config.separate_uv_delta_q)); return true; } // 5.5.3.Timing info syntax. bool AV1Parser::ParseTimingInfo(BitReader* reader) { // Skip num_units_in_display_tick, time_scale. RCHECK(reader->SkipBits(32 + 32)); bool equal_picture_interval = false; RCHECK(reader->ReadBits(1, &equal_picture_interval)); sequence_header_.timing_info.equal_picture_interval = equal_picture_interval; if (equal_picture_interval) { uint32_t num_ticks_per_picture_minus_1 = 0; RCHECK(ReadUvlc(reader, &num_ticks_per_picture_minus_1)); } return true; } // 5.5.4. Decoder model info syntax. bool AV1Parser::ParseDecoderModelInfo(BitReader* reader) { DecoderModelInfo& decoder_model_info = sequence_header_.decoder_model_info; RCHECK(reader->ReadBits(5, &decoder_model_info.buffer_delay_length_minus_1)); // Skip num_units_in_decoding_tick. RCHECK(reader->SkipBits(32)); RCHECK(reader->ReadBits( 5, &decoder_model_info.buffer_removal_time_length_minus_1)); RCHECK(reader->ReadBits( 5, &decoder_model_info.frame_presentation_time_length_minus_1)); return true; } // 5.5.5. Operating parameters info syntax. bool AV1Parser::SkipOperatingParametersInfo(BitReader* reader) { const int n = sequence_header_.decoder_model_info.buffer_delay_length_minus_1 + 1; // Skip decoder_buffer_delay[op], encoder_buffer_delay[op], // low_delay_mode_flag[op]. RCHECK(reader->SkipBits(n + n + 1)); return true; } // 5.9.1. General frame header OBU syntax. bool AV1Parser::ParseFrameHeaderObu(const ObuHeader& obu_header, BitReader* reader) { if (frame_header_.seen_frame_header) return true; frame_header_.seen_frame_header = true; RCHECK(ParseUncompressedHeader(obu_header, reader)); if (frame_header_.show_existing_frame) { DecodeFrameWrapup(); frame_header_.seen_frame_header = false; } else { frame_header_.seen_frame_header = true; } return true; } // 5.9.2. Uncompressed header syntax. bool AV1Parser::ParseUncompressedHeader(const ObuHeader& obu_header, BitReader* reader) { int id_len = 0; if (sequence_header_.frame_id_numbers_present_flag) { id_len = sequence_header_.additional_frame_id_length_minus_1 + 1 + sequence_header_.delta_frame_id_length_minus_2 + 2; } bool frame_is_intra = false; bool show_frame = false; bool showable_frame = false; bool error_resilient_mode = false; if (sequence_header_.reduced_still_picture_header) { frame_header_.show_existing_frame = false; frame_header_.frame_type = KEY_FRAME; frame_is_intra = true; show_frame = true; showable_frame = false; } else { RCHECK(reader->ReadBits(1, &frame_header_.show_existing_frame)); if (frame_header_.show_existing_frame) { RCHECK(reader->ReadBits(3, &frame_header_.frame_to_show_map_idx)); if (sequence_header_.decoder_model_info_present_flag && !sequence_header_.timing_info.equal_picture_interval) { RCHECK(SkipTemporalPointInfo(reader)); } frame_header_.refresh_frame_flags = 0; if (sequence_header_.frame_id_numbers_present_flag) { // Skip display_frame_id. RCHECK(reader->SkipBits(id_len)); } frame_header_.frame_type = reference_frames_[frame_header_.frame_to_show_map_idx].frame_type; if (frame_header_.frame_type == KEY_FRAME) { frame_header_.refresh_frame_flags = kAllFrames; } return true; } RCHECK(reader->ReadBits(2, &frame_header_.frame_type)); frame_is_intra = frame_header_.frame_type == INTRA_ONLY_FRAME || frame_header_.frame_type == KEY_FRAME; RCHECK(reader->ReadBits(1, &show_frame)); if (show_frame && sequence_header_.decoder_model_info_present_flag && !sequence_header_.timing_info.equal_picture_interval) { RCHECK(SkipTemporalPointInfo(reader)); } if (show_frame) showable_frame = frame_header_.frame_type != KEY_FRAME; else RCHECK(reader->ReadBits(1, &showable_frame)); if (frame_header_.frame_type == SWITCH_FRAME || (frame_header_.frame_type == KEY_FRAME && show_frame)) { error_resilient_mode = true; } else { RCHECK(reader->ReadBits(1, &error_resilient_mode)); } } if (frame_header_.frame_type == KEY_FRAME && show_frame) { for (int i = 0; i < kNumRefFrames; i++) { reference_frames_[i].order_hint = 0; } } bool disable_cdf_update = false; RCHECK(reader->ReadBits(1, &disable_cdf_update)); bool allow_screen_content_tools = false; if (sequence_header_.seq_force_screen_content_tools == kSelectScreenContentTools) { RCHECK(reader->ReadBits(1, &allow_screen_content_tools)); } else { allow_screen_content_tools = sequence_header_.seq_force_screen_content_tools != 0; } int force_integer_mv = 0; if (allow_screen_content_tools) { if (sequence_header_.seq_force_integer_mv == kSelectIntegerMv) RCHECK(reader->ReadBits(1, &force_integer_mv)); else force_integer_mv = sequence_header_.seq_force_integer_mv; } if (frame_is_intra) force_integer_mv = 1; if (sequence_header_.frame_id_numbers_present_flag) { // Skip current_frame_id. RCHECK(reader->SkipBits(id_len)); } bool frame_size_override_flag = false; if (frame_header_.frame_type == SWITCH_FRAME) frame_size_override_flag = true; else if (sequence_header_.reduced_still_picture_header) frame_size_override_flag = false; else RCHECK(reader->ReadBits(1, &frame_size_override_flag)); RCHECK(reader->ReadBits(sequence_header_.order_hint_bits, &frame_header_.order_hint)); int primary_ref_frame = 0; if (frame_is_intra || error_resilient_mode) { primary_ref_frame = kPrimaryRefNone; } else { RCHECK(reader->ReadBits(3, &primary_ref_frame)); } if (sequence_header_.decoder_model_info_present_flag) { bool buffer_removal_time_present_flag = false; RCHECK(reader->ReadBits(1, &buffer_removal_time_present_flag)); if (buffer_removal_time_present_flag) { for (int op_num = 0; op_num <= sequence_header_.operating_points_cnt_minus_1; op_num++) { if (sequence_header_.decoder_model_present_for_this_op[op_num]) { const int op_pt_idc = sequence_header_.operating_point_idc[op_num]; const int in_temporal_layer = (op_pt_idc >> obu_header.extension_header.temporal_id) & 1; const int in_spatial_layer = (op_pt_idc >> (obu_header.extension_header.spatial_id + 8)) & 1; if (op_pt_idc == 0 || (in_temporal_layer && in_spatial_layer)) { // Skip buffer_removal_time[ opNum ]. RCHECK(reader->SkipBits(sequence_header_.decoder_model_info .buffer_removal_time_length_minus_1 + 1)); } } } } } bool allow_high_precision_mv = false; bool allow_intrabc = false; if (frame_header_.frame_type == SWITCH_FRAME || (frame_header_.frame_type == KEY_FRAME && show_frame)) { frame_header_.refresh_frame_flags = kAllFrames; } else { RCHECK(reader->ReadBits(8, &frame_header_.refresh_frame_flags)); } if (!frame_is_intra || frame_header_.refresh_frame_flags != kAllFrames) { if (error_resilient_mode && sequence_header_.enable_order_hint) { for (int i = 0; i < kNumRefFrames; i++) { // Skip ref_order_hint[ i ]. RCHECK(reader->SkipBits(sequence_header_.order_hint_bits)); } } } if (frame_is_intra) { RCHECK(ParseFrameSize(frame_size_override_flag, reader)); RCHECK(ParseRenderSize(reader)); if (allow_screen_content_tools && frame_header_.upscaled_width == frame_header_.frame_width) RCHECK(reader->ReadBits(1, &allow_intrabc)); } else { bool frame_refs_short_signaling = false; if (sequence_header_.enable_order_hint) { RCHECK(reader->ReadBits(1, &frame_refs_short_signaling)); if (frame_refs_short_signaling) { int last_frame_idx = 0; RCHECK(reader->ReadBits(3, &last_frame_idx)); int gold_frame_idx = 0; RCHECK(reader->ReadBits(3, &gold_frame_idx)); RCHECK(SetFrameRefs(last_frame_idx, gold_frame_idx)); } } for (int i = 0; i < kRefsPerFrame; i++) { if (!frame_refs_short_signaling) RCHECK(reader->ReadBits(3, &frame_header_.ref_frame_idx[i])); if (sequence_header_.frame_id_numbers_present_flag) { // Skip delta_frame_id_minus_1. RCHECK(reader->SkipBits(sequence_header_.delta_frame_id_length_minus_2 + 2)); } } if (frame_size_override_flag && !error_resilient_mode) { RCHECK(ParseFrameSizeWithRefs(frame_size_override_flag, reader)); } else { RCHECK(ParseFrameSize(frame_size_override_flag, reader)); RCHECK(ParseRenderSize(reader)); } if (force_integer_mv) allow_high_precision_mv = false; else RCHECK(reader->ReadBits(1, &allow_high_precision_mv)); RCHECK(SkipInterpolationFilter(reader)); // Skip is_motion_mode_switchable. RCHECK(reader->SkipBits(1)); if (!error_resilient_mode && sequence_header_.enable_ref_frame_mvs) { // Skip use_ref_frame_mvs. RCHECK(reader->SkipBits(1)); } } if (!sequence_header_.reduced_still_picture_header && !disable_cdf_update) { // Skip disable_frame_end_update_cdf. RCHECK(reader->SkipBits(1)); } RCHECK(ParseTileInfo(reader)); RCHECK(ParseQuantizationParams(reader)); RCHECK(ParseSegmentationParams(primary_ref_frame, reader)); bool delta_q_present = false; RCHECK(SkipDeltaQParams(reader, &delta_q_present)); RCHECK(SkipDeltaLfParams(delta_q_present, allow_intrabc, reader)); const auto& quantization_params = frame_header_.quantization_params; bool coded_lossless = true; for (int segment_id = 0; segment_id < kMaxSegments; segment_id++) { const int qindex = GetQIndex(true, segment_id); const bool lossless = qindex == 0 && quantization_params.delta_qydc == 0 && quantization_params.delta_quac == 0 && quantization_params.delta_qudc == 0 && quantization_params.delta_qvac == 0 && quantization_params.delta_qvdc == 0; if (!lossless) coded_lossless = false; } const bool all_lossless = coded_lossless && (frame_header_.frame_width == frame_header_.upscaled_width); RCHECK(ParseLoopFilterParams(coded_lossless, allow_intrabc, reader)); RCHECK(ParseCdefParams(coded_lossless, allow_intrabc, reader)); RCHECK(ParseLrParams(all_lossless, allow_intrabc, reader)); RCHECK(SkipTxMode(coded_lossless, reader)); bool reference_select = false; RCHECK(ParseFrameReferenceMode(frame_is_intra, reader, &reference_select)); RCHECK(SkipSkipModeParams(frame_is_intra, reference_select, reader)); bool allow_warped_motion = false; if (frame_is_intra || error_resilient_mode || !sequence_header_.enable_warped_motion) { allow_warped_motion = false; } else { RCHECK(reader->ReadBits(1, &allow_warped_motion)); } // Skip reduced_tx_set. RCHECK(reader->SkipBits(1)); RCHECK( SkipGlobalMotionParams(frame_is_intra, allow_high_precision_mv, reader)); RCHECK(SkipFilmGrainParams(show_frame, showable_frame, reader)); return true; } // 5.9.3. Get relative distance function. int AV1Parser::GetRelativeDist(int a, int b) { if (!sequence_header_.enable_order_hint) return 0; int diff = a - b; const int m = 1 << (sequence_header_.order_hint_bits - 1); diff = (diff & (m - 1)) - (diff & m); return diff; } // 5.9.5. Frame size syntax. bool AV1Parser::ParseFrameSize(bool frame_size_override_flag, BitReader* reader) { if (frame_size_override_flag) { int frame_width_minus_1 = 0; RCHECK(reader->ReadBits(sequence_header_.frame_width_bits_minus_1 + 1, &frame_width_minus_1)); int frame_height_minus_1 = 0; RCHECK(reader->ReadBits(sequence_header_.frame_height_bits_minus_1 + 1, &frame_height_minus_1)); frame_header_.frame_width = frame_width_minus_1 + 1; frame_header_.frame_height = frame_height_minus_1 + 1; } else { frame_header_.frame_width = sequence_header_.max_frame_width_minus_1 + 1; frame_header_.frame_height = sequence_header_.max_frame_height_minus_1 + 1; } RCHECK(ParseSuperresParams(reader)); ComputeImageSize(); return true; } // 5.9.6. Render size syntax. bool AV1Parser::ParseRenderSize(BitReader* reader) { bool render_and_frame_size_different = false; RCHECK(reader->ReadBits(1, &render_and_frame_size_different)); if (render_and_frame_size_different) { int render_width_minus_1 = 0; RCHECK(reader->ReadBits(16, &render_width_minus_1)); int render_height_minus_1 = 0; RCHECK(reader->ReadBits(16, &render_height_minus_1)); frame_header_.render_width = render_width_minus_1 + 1; frame_header_.render_height = render_height_minus_1 + 1; } else { frame_header_.render_width = frame_header_.upscaled_width; frame_header_.render_height = frame_header_.frame_height; } return true; } // 5.9.7. Frame size with refs syntax. bool AV1Parser::ParseFrameSizeWithRefs(bool frame_size_override_flag, BitReader* reader) { bool found_ref = false; for (int i = 0; i < kRefsPerFrame; i++) { RCHECK(reader->ReadBits(1, &found_ref)); if (found_ref) { const ReferenceFrame& reference_frame = reference_frames_[frame_header_.ref_frame_idx[i]]; frame_header_.upscaled_width = reference_frame.upscaled_width; frame_header_.frame_width = frame_header_.upscaled_width; frame_header_.frame_height = reference_frame.frame_height; frame_header_.render_width = reference_frame.render_width; frame_header_.render_height = reference_frame.render_height; break; } } if (!found_ref) { RCHECK(ParseFrameSize(frame_size_override_flag, reader)); RCHECK(ParseRenderSize(reader)); } else { RCHECK(ParseSuperresParams(reader)); ComputeImageSize(); } return true; } // 5.9.8. Superres params syntax. bool AV1Parser::ParseSuperresParams(BitReader* reader) { const int kSuperresNum = 8; const int kSuperresDenomMin = 9; const int kSuperresDenomBits = 3; bool use_superres = false; if (sequence_header_.enable_superres) RCHECK(reader->ReadBits(1, &use_superres)); int superres_denom = 0; if (use_superres) { int coded_denom = 0; RCHECK(reader->ReadBits(kSuperresDenomBits, &coded_denom)); superres_denom = coded_denom + kSuperresDenomMin; } else { superres_denom = kSuperresNum; } const int upscaled_width = frame_header_.frame_width; frame_header_.upscaled_width = (upscaled_width * kSuperresNum + superres_denom / 2) / superres_denom; return true; } // 5.9.9. Compute image size function. void AV1Parser::ComputeImageSize() { frame_header_.mi_cols = 2 * ((frame_header_.frame_width + 7) >> 3); frame_header_.mi_rows = 2 * ((frame_header_.frame_height + 7) >> 3); } // 5.9.10. Interpolation filter syntax. bool AV1Parser::SkipInterpolationFilter(BitReader* reader) { // SKip is_filter_switchable, interpolation_filter. RCHECK(reader->SkipBitsConditional(false, 2)); return true; } // 5.9.11. Loop filter parms syntax. bool AV1Parser::ParseLoopFilterParams(bool coded_lossless, bool allow_intrabc, BitReader* reader) { if (coded_lossless || allow_intrabc) return true; int loop_filter_level[] = {0, 0}; RCHECK(reader->ReadBits(6, &loop_filter_level[0])); RCHECK(reader->ReadBits(6, &loop_filter_level[1])); if (sequence_header_.color_config.num_planes > 1) { if (loop_filter_level[0] || loop_filter_level[1]) { // Skip loop_filter_level[2], loop_filter_level[3]. RCHECK(reader->SkipBits(6 + 6)); } } // Skip loop_filter_sharpness. RCHECK(reader->SkipBits(3)); bool loop_filter_delta_enabled = false; RCHECK(reader->ReadBits(1, &loop_filter_delta_enabled)); if (loop_filter_delta_enabled) { bool loop_filter_delta_update = false; RCHECK(reader->ReadBits(1, &loop_filter_delta_update)); if (loop_filter_delta_update) { const int kTotalRefsPerFrame = 8; for (int i = 0; i < kTotalRefsPerFrame; i++) { // Skip update_ref_delta, loop_filter_ref_delta[ i ]. RCHECK(reader->SkipBitsConditional(true, 1 + 6)); } for (int i = 0; i < 2; i++) { // Skip update_mode_delta, loop_filter_mode_delta[ i ]. RCHECK(reader->SkipBitsConditional(true, 1 + 6)); } } } return true; } // 5.9.12. Quantization params syntax. bool AV1Parser::ParseQuantizationParams(BitReader* reader) { QuantizationParams& quantization_params = frame_header_.quantization_params; RCHECK(reader->ReadBits(8, &quantization_params.base_q_idx)); RCHECK(ReadDeltaQ(reader, &quantization_params.delta_qydc)); const ColorConfig& color_config = sequence_header_.color_config; if (color_config.num_planes > 1) { bool diff_uv_delta = false; if (color_config.separate_uv_delta_q) RCHECK(reader->ReadBits(1, &diff_uv_delta)); RCHECK(ReadDeltaQ(reader, &quantization_params.delta_qudc)); RCHECK(ReadDeltaQ(reader, &quantization_params.delta_quac)); if (diff_uv_delta) { RCHECK(ReadDeltaQ(reader, &quantization_params.delta_qvdc)); RCHECK(ReadDeltaQ(reader, &quantization_params.delta_qvac)); } else { quantization_params.delta_qvdc = quantization_params.delta_qudc; quantization_params.delta_qvac = quantization_params.delta_quac; } } else { quantization_params.delta_qudc = 0; quantization_params.delta_quac = 0; quantization_params.delta_qvdc = 0; quantization_params.delta_qvac = 0; } bool using_qmatrix = false; RCHECK(reader->ReadBits(1, &using_qmatrix)); if (using_qmatrix) { // Skip qm_y, qm_u. RCHECK(reader->SkipBits(4 + 4)); if (color_config.separate_uv_delta_q) { // Skip qm_v. RCHECK(reader->SkipBits(4)); } } return true; } // 5.9.13. Delta quantizer syntax. bool AV1Parser::ReadDeltaQ(BitReader* reader, int* delta_q) { bool delta_coded = false; RCHECK(reader->ReadBits(1, &delta_coded)); if (delta_coded) RCHECK(ReadSu(1 + 6, reader, delta_q)); else *delta_q = 0; return true; } // 5.9.14. Segmentation params syntax. bool AV1Parser::ParseSegmentationParams(int primary_ref_frame, BitReader* reader) { SegmentationParams& segmentation_params = frame_header_.segmentation_params; RCHECK(reader->ReadBits(1, &segmentation_params.segmentation_enabled)); if (segmentation_params.segmentation_enabled) { bool segmentation_update_data = false; if (primary_ref_frame == kPrimaryRefNone) { segmentation_update_data = true; } else { // Skip segmentation_update_map, segmentation_temporal_update. RCHECK(reader->SkipBitsConditional(true, 1)); RCHECK(reader->ReadBits(1, &segmentation_update_data)); } if (segmentation_update_data) { static const int kSegmentationFeatureBits[kSegLvlMax] = {8, 6, 6, 6, 6, 3, 0, 0}; static const int kSegmentationFeatureSigned[kSegLvlMax] = {1, 1, 1, 1, 1, 0, 0, 0}; const int kMaxLoopFilter = 63; static const int kSegmentationFeatureMax[kSegLvlMax] = {255, kMaxLoopFilter, kMaxLoopFilter, kMaxLoopFilter, kMaxLoopFilter, 7, 0, 0}; for (int i = 0; i < kMaxSegments; i++) { for (int j = 0; j < kSegLvlMax; j++) { bool feature_enabled = false; RCHECK(reader->ReadBits(1, &feature_enabled)); segmentation_params.feature_enabled[i][j] = feature_enabled; int clipped_value = 0; if (feature_enabled) { const int bits_to_read = kSegmentationFeatureBits[j]; const int limit = kSegmentationFeatureMax[j]; if (kSegmentationFeatureSigned[j]) { int feature_value = 0; RCHECK(ReadSu(1 + bits_to_read, reader, &feature_value)); clipped_value = Clip3(-limit, limit, feature_value); } else { int feature_value = 0; RCHECK(reader->ReadBits(bits_to_read, &feature_value)); clipped_value = Clip3(0, limit, feature_value); } } segmentation_params.feature_data[i][j] = clipped_value; } } } } else { for (int i = 0; i < kMaxSegments; i++) { for (int j = 0; j < kSegLvlMax; j++) { segmentation_params.feature_enabled[i][j] = false; segmentation_params.feature_data[i][j] = 0; } } } return true; } // 5.9.15. Tile info syntax. bool AV1Parser::ParseTileInfo(BitReader* reader) { const int kMaxTileWidth = 4096; const int kMaxTileArea = 4096 * 2304; const int kMaxTileRows = 64; const int kMaxTileCols = 64; TileInfo& tile_info = frame_header_.tile_info; const int sb_cols = sequence_header_.use_128x128_superblock ? ((frame_header_.mi_cols + 31) >> 5) : ((frame_header_.mi_cols + 15) >> 4); const int sb_rows = sequence_header_.use_128x128_superblock ? ((frame_header_.mi_rows + 31) >> 5) : ((frame_header_.mi_rows + 15) >> 4); const int sb_shift = sequence_header_.use_128x128_superblock ? 5 : 4; const int sb_size = sb_shift + 2; const int max_tile_width_sb = kMaxTileWidth >> sb_size; int max_tile_area_sb = kMaxTileArea >> (2 * sb_size); const int min_log2_tile_cols = TileLog2(max_tile_width_sb, sb_cols); const int max_log2_tile_cols = TileLog2(1, std::min(sb_cols, kMaxTileCols)); const int max_log2_tile_rows = TileLog2(1, std::min(sb_rows, kMaxTileRows)); const int min_log2_tiles = std::max( min_log2_tile_cols, TileLog2(max_tile_area_sb, sb_rows * sb_cols)); bool uniform_tile_spacing_flag = false; RCHECK(reader->ReadBits(1, &uniform_tile_spacing_flag)); if (uniform_tile_spacing_flag) { tile_info.tile_cols_log2 = min_log2_tile_cols; while (tile_info.tile_cols_log2 < max_log2_tile_cols) { bool increment_tile_cols_log2 = false; RCHECK(reader->ReadBits(1, &increment_tile_cols_log2)); if (increment_tile_cols_log2) tile_info.tile_cols_log2++; else break; } const int tile_width_sb = (sb_cols + (1 << tile_info.tile_cols_log2) - 1) >> tile_info.tile_cols_log2; int i = 0; for (int start_sb = 0; start_sb < sb_cols; start_sb += tile_width_sb) { i += 1; } tile_info.tile_cols = i; const int min_log2_tile_rows = std::max(min_log2_tiles - tile_info.tile_cols_log2, 0); tile_info.tile_rows_log2 = min_log2_tile_rows; while (tile_info.tile_rows_log2 < max_log2_tile_rows) { bool increment_tile_rows_log2 = false; RCHECK(reader->ReadBits(1, &increment_tile_rows_log2)); if (increment_tile_rows_log2) tile_info.tile_rows_log2++; else break; } const int tile_height_sb = (sb_rows + (1 << tile_info.tile_rows_log2) - 1) >> tile_info.tile_rows_log2; i = 0; for (int start_sb = 0; start_sb < sb_rows; start_sb += tile_height_sb) { i += 1; } tile_info.tile_rows = i; } else { int widest_tile_sb = 0; int start_sb = 0; int i = 0; for (; start_sb < sb_cols; i++) { const int max_width = std::min(sb_cols - start_sb, max_tile_width_sb); int width_in_sbs_minus_1 = 0; RCHECK(ReadNs(max_width, reader, &width_in_sbs_minus_1)); const int size_sb = width_in_sbs_minus_1 + 1; widest_tile_sb = std::max(size_sb, widest_tile_sb); start_sb += size_sb; } tile_info.tile_cols = i; tile_info.tile_cols_log2 = TileLog2(1, tile_info.tile_cols); if (min_log2_tiles > 0) max_tile_area_sb = (sb_rows * sb_cols) >> (min_log2_tiles + 1); else max_tile_area_sb = sb_rows * sb_cols; const int max_tile_height_sb = std::max(max_tile_area_sb / widest_tile_sb, 1); start_sb = 0; i = 0; for (; start_sb < sb_rows; i++) { const int max_height = std::min(sb_rows - start_sb, max_tile_height_sb); int height_in_sbs_minus_1 = 0; RCHECK(ReadNs(max_height, reader, &height_in_sbs_minus_1)); const int size_sb = height_in_sbs_minus_1 + 1; start_sb += size_sb; } tile_info.tile_rows = i; tile_info.tile_rows_log2 = TileLog2(1, tile_info.tile_rows); } if (tile_info.tile_cols_log2 > 0 || tile_info.tile_rows_log2 > 0) { // Skip context_update_tile_id. RCHECK( reader->SkipBits(tile_info.tile_rows_log2 + tile_info.tile_cols_log2)); int tile_size_bytes_minus_1 = 0; RCHECK(reader->ReadBits(2, &tile_size_bytes_minus_1)); tile_info.tile_size_bytes = tile_size_bytes_minus_1 + 1; } return true; } // 5.9.17. Quantizer index delta parameters syntax. bool AV1Parser::SkipDeltaQParams(BitReader* reader, bool* delta_q_present) { *delta_q_present = false; if (frame_header_.quantization_params.base_q_idx > 0) RCHECK(reader->ReadBits(1, delta_q_present)); if (*delta_q_present) { // Skip delta_q_res. RCHECK(reader->SkipBits(2)); } return true; } // 5.9.18. Loop filter delta parameters syntax. bool AV1Parser::SkipDeltaLfParams(bool delta_q_present, bool allow_intrabc, BitReader* reader) { bool delta_lf_present = false; if (delta_q_present) { if (!allow_intrabc) RCHECK(reader->ReadBits(1, &delta_lf_present)); if (delta_lf_present) { // Skip delta_lf_res, delta_lf_multi. RCHECK(reader->SkipBits(2 + 1)); } } return true; } // 5.9.19. CDEF params syntax. bool AV1Parser::ParseCdefParams(bool coded_lossless, bool allow_intrabc, BitReader* reader) { if (coded_lossless || allow_intrabc || !sequence_header_.enable_cdef) return true; // Skip cdef_damping_minus_3. RCHECK(reader->SkipBits(2)); int cdef_bits = 0; RCHECK(reader->ReadBits(2, &cdef_bits)); for (int i = 0; i < (1 << cdef_bits); i++) { // Skip cdef_y_pri_strength[i], Skip cdef_y_sec_strength[i]. RCHECK(reader->SkipBits(4 + 2)); if (sequence_header_.color_config.num_planes > 1) { // Skip cdef_uv_pri_strength[i], Skip cdef_uv_sec_strength[i]. RCHECK(reader->SkipBits(4 + 2)); } } return true; } // 5.9.20. Loop restoration params syntax. bool AV1Parser::ParseLrParams(bool all_lossless, bool allow_intrabc, BitReader* reader) { if (all_lossless || allow_intrabc || !sequence_header_.enable_restoration) return true; enum FrameRestorationType { RESTORE_NONE = 0, RESTORE_SWITCHABLE = 3, RESTORE_WIENER = 1, RESTORE_SGRPROJ = 2, }; static const int kRemapLrType[4] = {RESTORE_NONE, RESTORE_SWITCHABLE, RESTORE_WIENER, RESTORE_SGRPROJ}; bool uses_lr = false; bool uses_chroma_lr = false; for (int i = 0; i < sequence_header_.color_config.num_planes; i++) { int lr_type = 0; RCHECK(reader->ReadBits(2, &lr_type)); const int frame_restoration_type = kRemapLrType[lr_type]; if (frame_restoration_type != RESTORE_NONE) { uses_lr = true; if (i > 0) uses_chroma_lr = true; } } if (uses_lr) { if (sequence_header_.use_128x128_superblock) { // Skip lr_unit_shift. RCHECK(reader->SkipBits(1)); } else { // Skip lr_unit_shift, lr_unit_extra_shift. RCHECK(reader->SkipBitsConditional(true, 1)); } if (sequence_header_.color_config.subsampling_x && sequence_header_.color_config.subsampling_y && uses_chroma_lr) { // Skip lr_uv_shift. RCHECK(reader->SkipBits(1)); } } return true; } // 5.9.21. TX mode syntax. bool AV1Parser::SkipTxMode(bool coded_lossless, BitReader* reader) { if (!coded_lossless) { // Skip tx_mode_select. RCHECK(reader->SkipBits(1)); } return true; } // 5.9.22. Skip mode params syntax. bool AV1Parser::SkipSkipModeParams(bool frame_is_intra, bool reference_select, BitReader* reader) { bool skip_mode_allowed = false; if (frame_is_intra || !reference_select || !sequence_header_.enable_order_hint) { skip_mode_allowed = false; } else { int forward_idx = -1; int forward_hint = 0; int backward_idx = -1; int backward_hint = 0; for (int i = 0; i < kRefsPerFrame; i++) { const int ref_hint = reference_frames_[frame_header_.ref_frame_idx[i]].order_hint; if (GetRelativeDist(ref_hint, frame_header_.order_hint) < 0) { if (forward_idx < 0 || GetRelativeDist(ref_hint, forward_hint) > 0) { forward_idx = i; forward_hint = ref_hint; } } else if (GetRelativeDist(ref_hint, frame_header_.order_hint) > 0) { if (backward_idx < 0 || GetRelativeDist(ref_hint, backward_hint) < 0) { backward_idx = i; backward_hint = ref_hint; } } } if (forward_idx < 0) { skip_mode_allowed = false; } else if (backward_idx >= 0) { skip_mode_allowed = true; } else { int second_forward_idx = -1; int second_forward_hint = 0; for (int i = 0; i < kRefsPerFrame; i++) { const int ref_hint = reference_frames_[frame_header_.ref_frame_idx[i]].order_hint; if (GetRelativeDist(ref_hint, forward_hint) < 0) { if (second_forward_idx < 0 || GetRelativeDist(ref_hint, second_forward_hint) > 0) { second_forward_idx = i; second_forward_hint = ref_hint; } } } skip_mode_allowed = second_forward_idx >= 0; } } if (skip_mode_allowed) { // Skip skip_mode_present. RCHECK(reader->SkipBits(1)); } return true; } // 5.9.23. Frame reference mode syntax. bool AV1Parser::ParseFrameReferenceMode(bool frame_is_intra, BitReader* reader, bool* reference_select) { if (frame_is_intra) *reference_select = false; else RCHECK(reader->ReadBits(1, reference_select)); return true; } // 5.9.24. Global motion params syntax. bool AV1Parser::SkipGlobalMotionParams(bool frame_is_intra, bool allow_high_precision_mv, BitReader* reader) { if (frame_is_intra) return true; for (int ref = LAST_FRAME; ref <= ALTREF_FRAME; ref++) { int type = 0; bool is_global = false; RCHECK(reader->ReadBits(1, &is_global)); if (is_global) { bool is_rot_zoom = false; RCHECK(reader->ReadBits(1, &is_rot_zoom)); if (is_rot_zoom) { type = ROTZOOM; } else { bool is_translation = false; RCHECK(reader->ReadBits(1, &is_translation)); type = is_translation ? TRANSLATION : AFFINE; } } else { type = IDENTITY; } if (type >= ROTZOOM) { RCHECK(SkipGlobalParam(type, ref, 2, allow_high_precision_mv, reader)); RCHECK(SkipGlobalParam(type, ref, 3, allow_high_precision_mv, reader)); if (type == AFFINE) { RCHECK(SkipGlobalParam(type, ref, 4, allow_high_precision_mv, reader)); RCHECK(SkipGlobalParam(type, ref, 5, allow_high_precision_mv, reader)); } } if (type >= TRANSLATION) { RCHECK(SkipGlobalParam(type, ref, 0, allow_high_precision_mv, reader)); RCHECK(SkipGlobalParam(type, ref, 1, allow_high_precision_mv, reader)); } } return true; } // 5.9.25. Global param syntax. bool AV1Parser::SkipGlobalParam(int type, int /*ref*/, int idx, bool allow_high_precision_mv, BitReader* reader) { const int kGmAbsTransBits = 12; const int kGmAbsTransOnlyBits = 9; const int kGmAbsAlphaBits = 12; int abs_bits = kGmAbsAlphaBits; if (idx < 2) { if (type == TRANSLATION) { abs_bits = kGmAbsTransOnlyBits - (allow_high_precision_mv ? 0 : 1); } else { abs_bits = kGmAbsTransBits; } } const int mx = 1 << abs_bits; RCHECK(SkipDecodeSignedSubexpWithRef(-mx, mx + 1, reader)); return true; } // 5.9.26. Decode signed subexp with ref syntax. bool AV1Parser::SkipDecodeSignedSubexpWithRef(int low, int high, BitReader* reader) { RCHECK(SkipDecodeUnsignedSubexpWithRef(high - low, reader)); return true; } // 5.9.27. Decode unsigned subbexp with ref syntax. bool AV1Parser::SkipDecodeUnsignedSubexpWithRef(int mx, BitReader* reader) { RCHECK(SkipDecodeSubexp(mx, reader)); return true; } // 5.9.28. Decode subexp syntax. bool AV1Parser::SkipDecodeSubexp(int num_syms, BitReader* reader) { int i = 0; int mk = 0; int k = 3; while (true) { const int b2 = i ? (k + i - 1) : k; const int a = 1 << b2; if (num_syms <= mk + 3 * a) { int subexp_final_bits = 0; RCHECK(ReadNs(num_syms - mk, reader, &subexp_final_bits)); return true; } else { bool subexp_more_bits = false; RCHECK(reader->ReadBits(1, &subexp_more_bits)); if (subexp_more_bits) { i++; mk += a; } else { // Skip subexp_bits. RCHECK(reader->SkipBits(b2)); return true; } } } return true; } // 5.9.30. Film grain params syntax. bool AV1Parser::SkipFilmGrainParams(bool show_frame, bool showable_frame, BitReader* reader) { if (!sequence_header_.film_grain_params_present || (!show_frame && !showable_frame)) { return true; } bool apply_grain = false; RCHECK(reader->ReadBits(1, &apply_grain)); if (!apply_grain) return true; // Skip grain_seed. RCHECK(reader->SkipBits(16)); bool update_grain = true; if (frame_header_.frame_type == INTER_FRAME) RCHECK(reader->ReadBits(1, &update_grain)); if (!update_grain) { // Skip film_grain_params_ref_idx. RCHECK(reader->SkipBits(3)); return true; } int num_y_points = 0; RCHECK(reader->ReadBits(4, &num_y_points)); // Skip point_y_value, point_y_scaling. RCHECK(reader->SkipBits((8 + 8) * num_y_points)); const ColorConfig& color_config = sequence_header_.color_config; bool chroma_scaling_from_luma = false; if (!color_config.mono_chrome) RCHECK(reader->ReadBits(1, &chroma_scaling_from_luma)); int num_cb_points = 0; int num_cr_points = 0; if (color_config.mono_chrome || chroma_scaling_from_luma || (color_config.subsampling_x && color_config.subsampling_y && num_y_points == 0)) { num_cb_points = 0; num_cr_points = 0; } else { RCHECK(reader->ReadBits(4, &num_cb_points)); // Skip point_cb_value, point_cb_scaling. RCHECK(reader->SkipBits((8 + 8) * num_cb_points)); RCHECK(reader->ReadBits(4, &num_cr_points)); // Skip point_cr_value, point_cr_scaling. RCHECK(reader->SkipBits((8 + 8) * num_cr_points)); } // Skip grain_scaling_minus_8. RCHECK(reader->SkipBits(2)); int ar_coeff_lag = 0; RCHECK(reader->ReadBits(2, &ar_coeff_lag)); const int num_pos_luma = 2 * ar_coeff_lag * (ar_coeff_lag + 1); int num_pos_chroma = num_pos_luma; if (num_y_points) { num_pos_chroma = num_pos_luma + 1; // Skip ar_coeffs_y_plus_128. RCHECK(reader->SkipBits(8 * num_pos_luma)); } if (chroma_scaling_from_luma || num_cb_points) { // Skip ar_coeffs_cb_plus_128. RCHECK(reader->SkipBits(8 * num_pos_chroma)); } if (chroma_scaling_from_luma || num_cr_points) { // Skip ar_coeffs_cb_plus_128. RCHECK(reader->SkipBits(8 * num_pos_chroma)); } // Skip ar_coeff_shift_minus_6, grain_scale_shift. RCHECK(reader->SkipBits(2 + 2)); if (num_cb_points) { // Skip cb_mult, cb_luma_mult, cb_offset. RCHECK(reader->SkipBits(8 + 8 + 9)); } if (num_cr_points) { // Skip cr_mult, cr_luma_mult, cr_offset. RCHECK(reader->SkipBits(8 + 8 + 9)); } // Skip overlap_flag, clip_restricted_range. RCHECK(reader->SkipBits(1 + 1)); return true; } // 5.9.31. Temporal point info syntax. bool AV1Parser::SkipTemporalPointInfo(BitReader* reader) { const int frame_presentation_time_length = sequence_header_.decoder_model_info .frame_presentation_time_length_minus_1 + 1; // Skip frame_presentation_time. RCHECK(reader->SkipBits(frame_presentation_time_length)); return true; } // 5.10. Frame OBU syntax. bool AV1Parser::ParseFrameObu(const ObuHeader& obu_header, size_t size, BitReader* reader, std::vector* tiles) { const size_t start_bit_pos = reader->bit_position(); RCHECK(ParseFrameHeaderObu(obu_header, reader)); RCHECK(ByteAlignment(reader)); const size_t end_bit_pos = reader->bit_position(); const size_t header_bytes = (end_bit_pos - start_bit_pos) / 8; RCHECK(ParseTileGroupObu(size - header_bytes, reader, tiles)); return true; } // 5.11.1. General tile group OBU syntax. bool AV1Parser::ParseTileGroupObu(size_t size, BitReader* reader, std::vector* tiles) { const TileInfo& tile_info = frame_header_.tile_info; const size_t start_bit_pos = reader->bit_position(); const int num_tiles = tile_info.tile_cols * tile_info.tile_rows; bool tile_start_and_end_present_flag = false; if (num_tiles > 1) RCHECK(reader->ReadBits(1, &tile_start_and_end_present_flag)); int tg_start = 0; int tg_end = num_tiles - 1; if (num_tiles > 1 && tile_start_and_end_present_flag) { const int tile_bits = tile_info.tile_cols_log2 + tile_info.tile_rows_log2; RCHECK(reader->ReadBits(tile_bits, &tg_start)); RCHECK(reader->ReadBits(tile_bits, &tg_end)); } RCHECK(ByteAlignment(reader)); const size_t end_bit_pos = reader->bit_position(); const size_t header_bytes = (end_bit_pos - start_bit_pos) / 8; size -= header_bytes; for (int tile_num = tg_start; tile_num <= tg_end; tile_num++) { const bool last_tile = tile_num == tg_end; size_t tile_size = size; if (!last_tile) { size_t tile_size_minus_1 = 0; RCHECK(ReadLe(tile_info.tile_size_bytes, reader, &tile_size_minus_1)); tile_size = tile_size_minus_1 + 1; size -= tile_size + tile_info.tile_size_bytes; } tiles->push_back({reader->bit_position() / 8, tile_size}); RCHECK(reader->SkipBits(tile_size * 8)); // Skip the tile. } if (tg_end == num_tiles - 1) { DecodeFrameWrapup(); frame_header_.seen_frame_header = false; } return true; } // 5.11.14. Segmentation feature active function. bool AV1Parser::SegFeatureActiveIdx(int idx, int feature) { const SegmentationParams& segmentation_params = frame_header_.segmentation_params; return segmentation_params.segmentation_enabled && segmentation_params.feature_enabled[idx][feature]; } // 7.4. Decode frame wrapup process. void AV1Parser::DecodeFrameWrapup() { const int refresh_frame_flags = frame_header_.refresh_frame_flags; if (frame_header_.show_existing_frame && frame_header_.frame_type == KEY_FRAME) { // 7.21. Reference frame loading process. const ReferenceFrame& reference_frame = reference_frames_[frame_header_.frame_to_show_map_idx]; frame_header_.upscaled_width = reference_frame.upscaled_width; frame_header_.frame_width = reference_frame.frame_width; frame_header_.frame_height = reference_frame.frame_height; frame_header_.render_width = reference_frame.render_width; frame_header_.render_height = reference_frame.render_height; frame_header_.mi_cols = reference_frame.mi_cols; frame_header_.mi_rows = reference_frame.mi_rows; ColorConfig& color_config = sequence_header_.color_config; color_config.subsampling_x = reference_frame.subsampling_x; color_config.subsampling_y = reference_frame.subsampling_y; color_config.bit_depth = reference_frame.bit_depth; frame_header_.order_hint = reference_frame.order_hint; } // 7.20. Reference frame update process. for (int i = 0; i <= kNumRefFrames - 1; i++) { if ((refresh_frame_flags >> i) & 1) { ReferenceFrame& reference_frame = reference_frames_[i]; reference_frame.upscaled_width = frame_header_.upscaled_width; reference_frame.frame_width = frame_header_.frame_width; reference_frame.frame_height = frame_header_.frame_height; reference_frame.render_width = frame_header_.render_width; reference_frame.render_height = frame_header_.render_height; reference_frame.mi_cols = frame_header_.mi_cols; reference_frame.mi_rows = frame_header_.mi_rows; reference_frame.frame_type = frame_header_.frame_type; const ColorConfig& color_config = sequence_header_.color_config; reference_frame.subsampling_x = color_config.subsampling_x; reference_frame.subsampling_y = color_config.subsampling_y; reference_frame.bit_depth = color_config.bit_depth; reference_frame.order_hint = frame_header_.order_hint; } } } // 7.8. Set frame refs process. bool AV1Parser::SetFrameRefs(int last_frame_idx, int gold_frame_idx) { for (int i = 0; i < kRefsPerFrame; i++) frame_header_.ref_frame_idx[i] = -1; frame_header_.ref_frame_idx[LAST_FRAME - LAST_FRAME] = last_frame_idx; frame_header_.ref_frame_idx[GOLDEN_FRAME - LAST_FRAME] = gold_frame_idx; bool used_frame[kNumRefFrames] = {}; used_frame[last_frame_idx] = true; used_frame[gold_frame_idx] = true; const int cur_frame_hint = 1 << (sequence_header_.order_hint_bits - 1); // An array containing the expected output order shifted such that the // current frame has hint equal to |cur_frame_hint| is prepared. int shifted_order_hints[kNumRefFrames]; for (int i = 0; i < kNumRefFrames; i++) { shifted_order_hints[i] = cur_frame_hint + GetRelativeDist(reference_frames_[i].order_hint, frame_header_.order_hint); } const int last_order_hint = shifted_order_hints[last_frame_idx]; RCHECK(last_order_hint < cur_frame_hint); const int gold_order_hint = shifted_order_hints[gold_frame_idx]; RCHECK(gold_order_hint < cur_frame_hint); // The ALTREF_FRAME reference is set to be a backward reference to the frame // with highest output order. int ref = FindLatestBackward(shifted_order_hints, used_frame, cur_frame_hint); if (ref >= 0) { frame_header_.ref_frame_idx[ALTREF_FRAME - LAST_FRAME] = ref; used_frame[ref] = true; } // The BWDREF_FRAME reference is set to be a backward reference to the cloest // frame. ref = FindEarliestBackward(shifted_order_hints, used_frame, cur_frame_hint); if (ref >= 0) { frame_header_.ref_frame_idx[BWDREF_FRAME - LAST_FRAME] = ref; used_frame[ref] = true; } // The ALTREF2_FRAME reference is set to the next closest backward reference. ref = FindEarliestBackward(shifted_order_hints, used_frame, cur_frame_hint); if (ref >= 0) { frame_header_.ref_frame_idx[ALTREF2_FRAME - LAST_FRAME] = ref; used_frame[ref] = true; } // The remaining references are set to be forward references in // anti-chronological order. static const int kRefFrameList[] = { LAST2_FRAME, LAST3_FRAME, BWDREF_FRAME, ALTREF2_FRAME, ALTREF_FRAME, }; static_assert(std::size(kRefFrameList) == kRefsPerFrame - 2, "Unexpected kRefFrameList size."); for (const int ref_frame : kRefFrameList) { if (frame_header_.ref_frame_idx[ref_frame - LAST_FRAME] < 0) { ref = FindLatestForward(shifted_order_hints, used_frame, cur_frame_hint); if (ref >= 0) { frame_header_.ref_frame_idx[ref_frame - LAST_FRAME] = ref; used_frame[ref] = true; } } } // Finally, any remaining references are set to the reference frame with // smallest output order. ref = -1; int earliest_order_hint = 0; for (int i = 0; i < kNumRefFrames; i++) { const int hint = shifted_order_hints[i]; if (ref < 0 || hint < earliest_order_hint) { ref = i; earliest_order_hint = hint; } } for (int i = 0; i < kRefsPerFrame; i++) { if (frame_header_.ref_frame_idx[i] < 0) { frame_header_.ref_frame_idx[i] = ref; } } return true; } // 7.12.2. Dequantization functions. The function returns the quantizer index // for the current block. int AV1Parser::GetQIndex(bool ignore_delta_q, int segment_id) { // We do not have use case for ignore_delta_q false case. CHECK(ignore_delta_q) << "ignoreDeltaQ equal to 0 is not supported."; const int base_q_idx = frame_header_.quantization_params.base_q_idx; const int kSegLvlAltQ = 0; if (SegFeatureActiveIdx(segment_id, kSegLvlAltQ)) { const int data = frame_header_.segmentation_params.feature_data[segment_id][kSegLvlAltQ]; const int qindex = base_q_idx + data; return Clip3(0, 255, qindex); } else { return base_q_idx; } } } // namespace media } // namespace shaka