/* * Copyright (c) 2021, Hunter Salyer * * SPDX-License-Identifier: BSD-2-Clause */ #include "Parser.h" #include "Decoder.h" #include "Utilities.h" namespace Video::VP9 { #define RESERVED_ZERO \ if (m_bit_stream->read_bit() != 0) \ return false Parser::Parser(Decoder& decoder) : m_probability_tables(make()) , m_tree_parser(make(*this)) , m_decoder(decoder) { } Parser::~Parser() { cleanup_tile_allocations(); if (m_prev_segment_ids) free(m_prev_segment_ids); } void Parser::cleanup_tile_allocations() { if (m_skips) free(m_skips); if (m_tx_sizes) free(m_tx_sizes); if (m_mi_sizes) free(m_mi_sizes); if (m_y_modes) free(m_y_modes); if (m_segment_ids) free(m_segment_ids); if (m_ref_frames) free(m_ref_frames); if (m_interp_filters) free(m_interp_filters); if (m_mvs) free(m_mvs); if (m_sub_mvs) free(m_sub_mvs); if (m_sub_modes) free(m_sub_modes); } /* (6.1) */ bool Parser::parse_frame(ByteBuffer const& frame_data) { m_bit_stream = make(frame_data.data(), frame_data.size()); m_syntax_element_counter = make(); SAFE_CALL(uncompressed_header()); dbgln("Finished reading uncompressed header"); SAFE_CALL(trailing_bits()); if (m_header_size_in_bytes == 0) { dbgln("No header"); return true; } m_probability_tables->load_probs(m_frame_context_idx); m_probability_tables->load_probs2(m_frame_context_idx); m_syntax_element_counter->clear_counts(); SAFE_CALL(m_bit_stream->init_bool(m_header_size_in_bytes)); dbgln("Reading compressed header"); SAFE_CALL(compressed_header()); dbgln("Finished reading compressed header"); SAFE_CALL(m_bit_stream->exit_bool()); SAFE_CALL(decode_tiles()); SAFE_CALL(refresh_probs()); dbgln("Finished reading frame!"); return true; } bool Parser::trailing_bits() { while (m_bit_stream->get_position() & 7u) RESERVED_ZERO; return true; } bool Parser::refresh_probs() { if (!m_error_resilient_mode && !m_frame_parallel_decoding_mode) { m_probability_tables->load_probs(m_frame_context_idx); SAFE_CALL(m_decoder.adapt_coef_probs()); if (!m_frame_is_intra) { m_probability_tables->load_probs2(m_frame_context_idx); SAFE_CALL(m_decoder.adapt_non_coef_probs()); } } if (m_refresh_frame_context) m_probability_tables->save_probs(m_frame_context_idx); return true; } /* (6.2) */ bool Parser::uncompressed_header() { auto frame_marker = m_bit_stream->read_f(2); if (frame_marker != 2) return false; auto profile_low_bit = m_bit_stream->read_bit(); auto profile_high_bit = m_bit_stream->read_bit(); m_profile = (profile_high_bit << 1u) + profile_low_bit; if (m_profile == 3) RESERVED_ZERO; auto show_existing_frame = m_bit_stream->read_bit(); if (show_existing_frame) { m_frame_to_show_map_index = m_bit_stream->read_f(3); m_header_size_in_bytes = 0; m_refresh_frame_flags = 0; m_loop_filter_level = 0; return true; } m_last_frame_type = m_frame_type; m_frame_type = read_frame_type(); m_show_frame = m_bit_stream->read_bit(); m_error_resilient_mode = m_bit_stream->read_bit(); if (m_frame_type == KeyFrame) { SAFE_CALL(frame_sync_code()); SAFE_CALL(color_config()); SAFE_CALL(frame_size()); SAFE_CALL(render_size()); m_refresh_frame_flags = 0xFF; m_frame_is_intra = true; } else { m_frame_is_intra = !m_show_frame && m_bit_stream->read_bit(); if (!m_error_resilient_mode) { m_reset_frame_context = m_bit_stream->read_f(2); } else { m_reset_frame_context = 0; } if (m_frame_is_intra) { SAFE_CALL(frame_sync_code()); if (m_profile > 0) { SAFE_CALL(color_config()); } else { m_color_space = Bt601; m_subsampling_x = true; m_subsampling_y = true; m_bit_depth = 8; } m_refresh_frame_flags = m_bit_stream->read_f8(); SAFE_CALL(frame_size()); SAFE_CALL(render_size()); } else { m_refresh_frame_flags = m_bit_stream->read_f8(); for (auto i = 0; i < 3; i++) { m_ref_frame_idx[i] = m_bit_stream->read_f(3); m_ref_frame_sign_bias[LastFrame + i] = m_bit_stream->read_bit(); } SAFE_CALL(frame_size_with_refs()); m_allow_high_precision_mv = m_bit_stream->read_bit(); SAFE_CALL(read_interpolation_filter()); } } if (!m_error_resilient_mode) { m_refresh_frame_context = m_bit_stream->read_bit(); m_frame_parallel_decoding_mode = m_bit_stream->read_bit(); } else { m_refresh_frame_context = false; m_frame_parallel_decoding_mode = true; } m_frame_context_idx = m_bit_stream->read_f(2); if (m_frame_is_intra || m_error_resilient_mode) { SAFE_CALL(setup_past_independence()); if (m_frame_type == KeyFrame || m_error_resilient_mode || m_reset_frame_context == 3) { for (auto i = 0; i < 4; i++) { m_probability_tables->save_probs(i); } } else if (m_reset_frame_context == 2) { m_probability_tables->save_probs(m_frame_context_idx); } m_frame_context_idx = 0; } SAFE_CALL(loop_filter_params()); SAFE_CALL(quantization_params()); SAFE_CALL(segmentation_params()); SAFE_CALL(tile_info()); m_header_size_in_bytes = m_bit_stream->read_f16(); return true; } bool Parser::frame_sync_code() { if (m_bit_stream->read_byte() != 0x49) return false; if (m_bit_stream->read_byte() != 0x83) return false; return m_bit_stream->read_byte() == 0x42; } bool Parser::color_config() { if (m_profile >= 2) { m_bit_depth = m_bit_stream->read_bit() ? 12 : 10; } else { m_bit_depth = 8; } auto color_space = m_bit_stream->read_f(3); if (color_space > RGB) return false; m_color_space = static_cast(color_space); if (color_space != RGB) { m_color_range = read_color_range(); if (m_profile == 1 || m_profile == 3) { m_subsampling_x = m_bit_stream->read_bit(); m_subsampling_y = m_bit_stream->read_bit(); RESERVED_ZERO; } else { m_subsampling_x = true; m_subsampling_y = true; } } else { m_color_range = FullSwing; if (m_profile == 1 || m_profile == 3) { m_subsampling_x = false; m_subsampling_y = false; RESERVED_ZERO; } } return true; } bool Parser::frame_size() { m_frame_width = m_bit_stream->read_f16() + 1; m_frame_height = m_bit_stream->read_f16() + 1; SAFE_CALL(compute_image_size()); return true; } bool Parser::render_size() { if (m_bit_stream->read_bit()) { m_render_width = m_bit_stream->read_f16() + 1; m_render_height = m_bit_stream->read_f16() + 1; } else { m_render_width = m_frame_width; m_render_height = m_frame_height; } return true; } bool Parser::frame_size_with_refs() { bool found_ref; for (auto frame_index : m_ref_frame_idx) { found_ref = m_bit_stream->read_bit(); if (found_ref) { dbgln("Reading size from ref frame {}", frame_index); m_frame_width = m_ref_frame_width[frame_index]; m_frame_height = m_ref_frame_height[frame_index]; break; } } if (!found_ref) { SAFE_CALL(frame_size()); } else { SAFE_CALL(compute_image_size()); } SAFE_CALL(render_size()); return true; } bool Parser::compute_image_size() { m_mi_cols = (m_frame_width + 7u) >> 3u; m_mi_rows = (m_frame_height + 7u) >> 3u; m_sb64_cols = (m_mi_cols + 7u) >> 3u; m_sb64_rows = (m_mi_rows + 7u) >> 3u; return true; } bool Parser::read_interpolation_filter() { if (m_bit_stream->read_bit()) { m_interpolation_filter = Switchable; } else { m_interpolation_filter = literal_to_type[m_bit_stream->read_f(2)]; } return true; } bool Parser::loop_filter_params() { m_loop_filter_level = m_bit_stream->read_f(6); m_loop_filter_sharpness = m_bit_stream->read_f(3); m_loop_filter_delta_enabled = m_bit_stream->read_bit(); if (m_loop_filter_delta_enabled) { if (m_bit_stream->read_bit()) { for (auto& loop_filter_ref_delta : m_loop_filter_ref_deltas) { if (m_bit_stream->read_bit()) loop_filter_ref_delta = m_bit_stream->read_s(6); } for (auto& loop_filter_mode_delta : m_loop_filter_mode_deltas) { if (m_bit_stream->read_bit()) loop_filter_mode_delta = m_bit_stream->read_s(6); } } } return true; } bool Parser::quantization_params() { auto base_q_idx = m_bit_stream->read_byte(); auto delta_q_y_dc = read_delta_q(); auto delta_q_uv_dc = read_delta_q(); auto delta_q_uv_ac = read_delta_q(); m_lossless = base_q_idx == 0 && delta_q_y_dc == 0 && delta_q_uv_dc == 0 && delta_q_uv_ac == 0; return true; } i8 Parser::read_delta_q() { if (m_bit_stream->read_bit()) return m_bit_stream->read_s(4); return 0; } bool Parser::segmentation_params() { m_segmentation_enabled = m_bit_stream->read_bit(); if (!m_segmentation_enabled) return true; m_segmentation_update_map = m_bit_stream->read_bit(); if (m_segmentation_update_map) { for (auto& segmentation_tree_prob : m_segmentation_tree_probs) segmentation_tree_prob = read_prob(); m_segmentation_temporal_update = m_bit_stream->read_bit(); for (auto& segmentation_pred_prob : m_segmentation_pred_prob) segmentation_pred_prob = m_segmentation_temporal_update ? read_prob() : 255; } SAFE_CALL(m_bit_stream->read_bit()); m_segmentation_abs_or_delta_update = m_bit_stream->read_bit(); for (auto i = 0; i < MAX_SEGMENTS; i++) { for (auto j = 0; j < SEG_LVL_MAX; j++) { auto feature_value = 0; auto feature_enabled = m_bit_stream->read_bit(); m_feature_enabled[i][j] = feature_enabled; if (feature_enabled) { auto bits_to_read = segmentation_feature_bits[j]; feature_value = m_bit_stream->read_f(bits_to_read); if (segmentation_feature_signed[j]) { if (m_bit_stream->read_bit()) feature_value = -feature_value; } } m_feature_data[i][j] = feature_value; } } return true; } u8 Parser::read_prob() { if (m_bit_stream->read_bit()) return m_bit_stream->read_byte(); return 255; } bool Parser::tile_info() { auto min_log2_tile_cols = calc_min_log2_tile_cols(); auto max_log2_tile_cols = calc_max_log2_tile_cols(); m_tile_cols_log2 = min_log2_tile_cols; while (m_tile_cols_log2 < max_log2_tile_cols) { if (m_bit_stream->read_bit()) m_tile_cols_log2++; else break; } m_tile_rows_log2 = m_bit_stream->read_bit(); if (m_tile_rows_log2) { m_tile_rows_log2 += m_bit_stream->read_bit(); } return true; } u16 Parser::calc_min_log2_tile_cols() { auto min_log_2 = 0u; while ((u32)(MAX_TILE_WIDTH_B64 << min_log_2) < m_sb64_cols) min_log_2++; return min_log_2; } u16 Parser::calc_max_log2_tile_cols() { u16 max_log_2 = 1; while ((m_sb64_cols >> max_log_2) >= MIN_TILE_WIDTH_B64) max_log_2++; return max_log_2 - 1; } bool Parser::setup_past_independence() { for (auto i = 0; i < 8; i++) { for (auto j = 0; j < 4; j++) { m_feature_data[i][j] = 0; m_feature_enabled[i][j] = false; } } m_segmentation_abs_or_delta_update = false; if (m_prev_segment_ids) free(m_prev_segment_ids); m_prev_segment_ids = static_cast(malloc(m_mi_rows * m_mi_cols)); m_loop_filter_delta_enabled = true; m_loop_filter_ref_deltas[IntraFrame] = 1; m_loop_filter_ref_deltas[LastFrame] = 0; m_loop_filter_ref_deltas[GoldenFrame] = -1; m_loop_filter_ref_deltas[AltRefFrame] = -1; for (auto& loop_filter_mode_delta : m_loop_filter_mode_deltas) loop_filter_mode_delta = 0; m_probability_tables->reset_probs(); return true; } bool Parser::compressed_header() { SAFE_CALL(read_tx_mode()); if (m_tx_mode == TXModeSelect) SAFE_CALL(tx_mode_probs()); SAFE_CALL(read_coef_probs()); SAFE_CALL(read_skip_prob()); if (!m_frame_is_intra) { SAFE_CALL(read_inter_mode_probs()); if (m_interpolation_filter == Switchable) SAFE_CALL(read_interp_filter_probs()); SAFE_CALL(read_is_inter_probs()); SAFE_CALL(frame_reference_mode()); SAFE_CALL(frame_reference_mode_probs()); SAFE_CALL(read_y_mode_probs()); SAFE_CALL(read_partition_probs()); SAFE_CALL(mv_probs()); } return true; } bool Parser::read_tx_mode() { if (m_lossless) { m_tx_mode = Only_4x4; } else { auto tx_mode = m_bit_stream->read_literal(2); if (tx_mode == Allow_32x32) tx_mode += m_bit_stream->read_literal(1); m_tx_mode = static_cast(tx_mode); } return true; } bool Parser::tx_mode_probs() { auto& tx_probs = m_probability_tables->tx_probs(); for (auto i = 0; i < TX_SIZE_CONTEXTS; i++) { for (auto j = 0; j < TX_SIZES - 3; j++) tx_probs[TX_8x8][i][j] = diff_update_prob(tx_probs[TX_8x8][i][j]); } for (auto i = 0; i < TX_SIZE_CONTEXTS; i++) { for (auto j = 0; j < TX_SIZES - 2; j++) tx_probs[TX_16x16][i][j] = diff_update_prob(tx_probs[TX_16x16][i][j]); } for (auto i = 0; i < TX_SIZE_CONTEXTS; i++) { for (auto j = 0; j < TX_SIZES - 1; j++) tx_probs[TX_32x32][i][j] = diff_update_prob(tx_probs[TX_32x32][i][j]); } return true; } u8 Parser::diff_update_prob(u8 prob) { if (m_bit_stream->read_bool(252)) { auto delta_prob = decode_term_subexp(); prob = inv_remap_prob(delta_prob, prob); } return prob; } u8 Parser::decode_term_subexp() { if (m_bit_stream->read_literal(1) == 0) return m_bit_stream->read_literal(4); if (m_bit_stream->read_literal(1) == 0) return m_bit_stream->read_literal(4) + 16; if (m_bit_stream->read_literal(1) == 0) return m_bit_stream->read_literal(4) + 32; auto v = m_bit_stream->read_literal(7); if (v < 65) return v + 64; return (v << 1u) - 1 + m_bit_stream->read_literal(1); } u8 Parser::inv_remap_prob(u8 delta_prob, u8 prob) { u8 m = prob - 1; auto v = inv_map_table[delta_prob]; if ((m << 1u) <= 255) return 1 + inv_recenter_nonneg(v, m); return 255 - inv_recenter_nonneg(v, 254 - m); } u8 Parser::inv_recenter_nonneg(u8 v, u8 m) { if (v > 2 * m) return v; if (v & 1u) return m - ((v + 1u) >> 1u); return m + (v >> 1u); } bool Parser::read_coef_probs() { m_max_tx_size = tx_mode_to_biggest_tx_size[m_tx_mode]; for (auto tx_size = TX_4x4; tx_size <= m_max_tx_size; tx_size = static_cast(static_cast(tx_size) + 1)) { auto update_probs = m_bit_stream->read_literal(1); if (update_probs == 1) { for (auto i = 0; i < 2; i++) { for (auto j = 0; j < 2; j++) { for (auto k = 0; k < 6; k++) { auto max_l = (k == 0) ? 3 : 6; for (auto l = 0; l < max_l; l++) { for (auto m = 0; m < 3; m++) { auto& coef_probs = m_probability_tables->coef_probs()[tx_size]; coef_probs[i][j][k][l][m] = diff_update_prob(coef_probs[i][j][k][l][m]); } } } } } } } return true; } bool Parser::read_skip_prob() { for (auto i = 0; i < SKIP_CONTEXTS; i++) m_probability_tables->skip_prob()[i] = diff_update_prob(m_probability_tables->skip_prob()[i]); return true; } bool Parser::read_inter_mode_probs() { for (auto i = 0; i < INTER_MODE_CONTEXTS; i++) { for (auto j = 0; j < INTER_MODES - 1; j++) m_probability_tables->inter_mode_probs()[i][j] = diff_update_prob(m_probability_tables->inter_mode_probs()[i][j]); } return true; } bool Parser::read_interp_filter_probs() { for (auto i = 0; i < INTERP_FILTER_CONTEXTS; i++) { for (auto j = 0; j < SWITCHABLE_FILTERS - 1; j++) m_probability_tables->interp_filter_probs()[i][j] = diff_update_prob(m_probability_tables->interp_filter_probs()[i][j]); } return true; } bool Parser::read_is_inter_probs() { for (auto i = 0; i < IS_INTER_CONTEXTS; i++) m_probability_tables->is_inter_prob()[i] = diff_update_prob(m_probability_tables->is_inter_prob()[i]); return true; } bool Parser::frame_reference_mode() { auto compound_reference_allowed = false; for (size_t i = 2; i <= REFS_PER_FRAME; i++) { if (m_ref_frame_sign_bias[i] != m_ref_frame_sign_bias[1]) compound_reference_allowed = true; } if (compound_reference_allowed) { auto non_single_reference = m_bit_stream->read_literal(1); if (non_single_reference == 0) { m_reference_mode = SingleReference; } else { auto reference_select = m_bit_stream->read_literal(1); if (reference_select == 0) m_reference_mode = CompoundReference; else m_reference_mode = ReferenceModeSelect; SAFE_CALL(setup_compound_reference_mode()); } } else { m_reference_mode = SingleReference; } return true; } bool Parser::frame_reference_mode_probs() { if (m_reference_mode == ReferenceModeSelect) { for (auto i = 0; i < COMP_MODE_CONTEXTS; i++) { auto& comp_mode_prob = m_probability_tables->comp_mode_prob(); comp_mode_prob[i] = diff_update_prob(comp_mode_prob[i]); } } if (m_reference_mode != CompoundReference) { for (auto i = 0; i < REF_CONTEXTS; i++) { auto& single_ref_prob = m_probability_tables->single_ref_prob(); single_ref_prob[i][0] = diff_update_prob(single_ref_prob[i][0]); single_ref_prob[i][1] = diff_update_prob(single_ref_prob[i][1]); } } if (m_reference_mode != SingleReference) { for (auto i = 0; i < REF_CONTEXTS; i++) { auto& comp_ref_prob = m_probability_tables->comp_ref_prob(); comp_ref_prob[i] = diff_update_prob(comp_ref_prob[i]); } } return true; } bool Parser::read_y_mode_probs() { for (auto i = 0; i < BLOCK_SIZE_GROUPS; i++) { for (auto j = 0; j < INTRA_MODES - 1; j++) { auto& y_mode_probs = m_probability_tables->y_mode_probs(); y_mode_probs[i][j] = diff_update_prob(y_mode_probs[i][j]); } } return true; } bool Parser::read_partition_probs() { for (auto i = 0; i < PARTITION_CONTEXTS; i++) { for (auto j = 0; j < PARTITION_TYPES - 1; j++) { auto& partition_probs = m_probability_tables->partition_probs(); partition_probs[i][j] = diff_update_prob(partition_probs[i][j]); } } return true; } bool Parser::mv_probs() { for (auto j = 0; j < MV_JOINTS - 1; j++) { auto& mv_joint_probs = m_probability_tables->mv_joint_probs(); mv_joint_probs[j] = update_mv_prob(mv_joint_probs[j]); } for (auto i = 0; i < 2; i++) { auto& mv_sign_prob = m_probability_tables->mv_sign_prob(); mv_sign_prob[i] = update_mv_prob(mv_sign_prob[i]); for (auto j = 0; j < MV_CLASSES - 1; j++) { auto& mv_class_probs = m_probability_tables->mv_class_probs(); mv_class_probs[i][j] = update_mv_prob(mv_class_probs[i][j]); } auto& mv_class0_bit_prob = m_probability_tables->mv_class0_bit_prob(); mv_class0_bit_prob[i] = update_mv_prob(mv_class0_bit_prob[i]); for (auto j = 0; j < MV_OFFSET_BITS; j++) { auto& mv_bits_prob = m_probability_tables->mv_bits_prob(); mv_bits_prob[i][j] = update_mv_prob(mv_bits_prob[i][j]); } } for (auto i = 0; i < 2; i++) { for (auto j = 0; j < CLASS0_SIZE; j++) { for (auto k = 0; k < MV_FR_SIZE - 1; k++) { auto& mv_class0_fr_probs = m_probability_tables->mv_class0_fr_probs(); mv_class0_fr_probs[i][j][k] = update_mv_prob(mv_class0_fr_probs[i][j][k]); } } for (auto k = 0; k < MV_FR_SIZE - 1; k++) { auto& mv_fr_probs = m_probability_tables->mv_fr_probs(); mv_fr_probs[i][k] = update_mv_prob(mv_fr_probs[i][k]); } } if (m_allow_high_precision_mv) { for (auto i = 0; i < 2; i++) { auto& mv_class0_hp_prob = m_probability_tables->mv_class0_hp_prob(); auto& mv_hp_prob = m_probability_tables->mv_hp_prob(); mv_class0_hp_prob[i] = update_mv_prob(mv_class0_hp_prob[i]); mv_hp_prob[i] = update_mv_prob(mv_hp_prob[i]); } } return true; } u8 Parser::update_mv_prob(u8 prob) { if (m_bit_stream->read_bool(252)) { return (m_bit_stream->read_literal(7) << 1u) | 1u; } return prob; } bool Parser::setup_compound_reference_mode() { if (m_ref_frame_sign_bias[LastFrame] == m_ref_frame_sign_bias[GoldenFrame]) { m_comp_fixed_ref = AltRefFrame; m_comp_var_ref[0] = LastFrame; m_comp_var_ref[1] = GoldenFrame; } else if (m_ref_frame_sign_bias[LastFrame] == m_ref_frame_sign_bias[AltRefFrame]) { m_comp_fixed_ref = GoldenFrame; m_comp_var_ref[0] = LastFrame; m_comp_var_ref[1] = AltRefFrame; } else { m_comp_fixed_ref = LastFrame; m_comp_var_ref[0] = GoldenFrame; m_comp_var_ref[1] = AltRefFrame; } return true; } void Parser::allocate_tile_data() { auto dimensions = m_mi_rows * m_mi_cols; if (dimensions == m_allocated_dimensions) return; cleanup_tile_allocations(); m_skips = static_cast(malloc(sizeof(bool) * dimensions)); m_tx_sizes = static_cast(malloc(sizeof(TXSize) * dimensions)); m_mi_sizes = static_cast(malloc(sizeof(u32) * dimensions)); m_y_modes = static_cast(malloc(sizeof(u8) * dimensions)); m_segment_ids = static_cast(malloc(sizeof(u8) * dimensions)); m_ref_frames = static_cast(malloc(sizeof(ReferenceFrame) * dimensions * 2)); m_interp_filters = static_cast(malloc(sizeof(InterpolationFilter) * dimensions)); m_mvs = static_cast(malloc(sizeof(MV) * dimensions * 2)); m_sub_mvs = static_cast(malloc(sizeof(MV) * dimensions * 2 * 4)); m_sub_modes = static_cast(malloc(sizeof(IntraMode) * dimensions * 4)); m_allocated_dimensions = dimensions; } bool Parser::decode_tiles() { auto tile_cols = 1 << m_tile_cols_log2; auto tile_rows = 1 << m_tile_rows_log2; allocate_tile_data(); SAFE_CALL(clear_above_context()); for (auto tile_row = 0; tile_row < tile_rows; tile_row++) { for (auto tile_col = 0; tile_col < tile_cols; tile_col++) { auto last_tile = (tile_row == tile_rows - 1) && (tile_col == tile_cols - 1); auto tile_size = last_tile ? m_bit_stream->bytes_remaining() : m_bit_stream->read_f(32); m_mi_row_start = get_tile_offset(tile_row, m_mi_rows, m_tile_rows_log2); m_mi_row_end = get_tile_offset(tile_row + 1, m_mi_rows, m_tile_rows_log2); m_mi_col_start = get_tile_offset(tile_col, m_mi_cols, m_tile_cols_log2); m_mi_col_end = get_tile_offset(tile_col + 1, m_mi_cols, m_tile_cols_log2); SAFE_CALL(m_bit_stream->init_bool(tile_size)); SAFE_CALL(decode_tile()); SAFE_CALL(m_bit_stream->exit_bool()); } } return true; } void Parser::clear_context(Vector& context, size_t size) { context.resize_and_keep_capacity(size); __builtin_memset(context.data(), 0, sizeof(u8) * size); } void Parser::clear_context(Vector>& context, size_t outer_size, size_t inner_size) { if (context.size() < outer_size) context.resize(outer_size); for (auto& sub_vector : context) clear_context(sub_vector, inner_size); } bool Parser::clear_above_context() { clear_context(m_above_nonzero_context, 3, 2 * m_mi_cols); clear_context(m_above_seg_pred_context, m_mi_cols); clear_context(m_above_partition_context, m_sb64_cols * 8); return true; } u32 Parser::get_tile_offset(u32 tile_num, u32 mis, u32 tile_size_log2) { u32 super_blocks = (mis + 7) >> 3u; u32 offset = ((tile_num * super_blocks) >> tile_size_log2) << 3u; return min(offset, mis); } bool Parser::decode_tile() { for (auto row = m_mi_row_start; row < m_mi_row_end; row += 8) { SAFE_CALL(clear_left_context()); m_row = row; for (auto col = m_mi_col_start; col < m_mi_col_end; col += 8) { m_col = col; SAFE_CALL(decode_partition(row, col, Block_64x64)); } } return true; } bool Parser::clear_left_context() { clear_context(m_left_nonzero_context, 3, 2 * m_mi_rows); clear_context(m_left_seg_pred_context, m_mi_rows); clear_context(m_left_partition_context, m_sb64_rows * 8); return true; } bool Parser::decode_partition(u32 row, u32 col, u8 block_subsize) { if (row >= m_mi_rows || col >= m_mi_cols) return false; m_block_subsize = block_subsize; m_num_8x8 = num_8x8_blocks_wide_lookup[block_subsize]; auto half_block_8x8 = m_num_8x8 >> 1; m_has_rows = (row + half_block_8x8) < m_mi_rows; m_has_cols = (col + half_block_8x8) < m_mi_cols; auto partition = m_tree_parser->parse_tree(SyntaxElementType::Partition); auto subsize = subsize_lookup[partition][block_subsize]; if (subsize < Block_8x8 || partition == PartitionNone) { SAFE_CALL(decode_block(row, col, subsize)); } else if (partition == PartitionHorizontal) { SAFE_CALL(decode_block(row, col, subsize)); if (m_has_rows) SAFE_CALL(decode_block(row + half_block_8x8, col, subsize)); } else if (partition == PartitionVertical) { SAFE_CALL(decode_block(row, col, subsize)); if (m_has_cols) SAFE_CALL(decode_block(row, col + half_block_8x8, subsize)); } else { SAFE_CALL(decode_partition(row, col, subsize)); SAFE_CALL(decode_partition(row, col + half_block_8x8, subsize)); SAFE_CALL(decode_partition(row + half_block_8x8, col, subsize)); SAFE_CALL(decode_partition(row + half_block_8x8, col + half_block_8x8, subsize)); } if (block_subsize == Block_8x8 || partition != PartitionSplit) { for (size_t i = 0; i < m_num_8x8; i++) { m_above_partition_context[col + i] = 15 >> b_width_log2_lookup[subsize]; m_left_partition_context[row + i] = 15 >> b_width_log2_lookup[subsize]; } } return true; } bool Parser::decode_block(u32 row, u32 col, u8 subsize) { m_mi_row = row; m_mi_col = col; m_mi_size = subsize; m_available_u = row > 0; m_available_l = col > m_mi_col_start; SAFE_CALL(mode_info()); m_eob_total = 0; SAFE_CALL(residual()); if (m_is_inter && subsize >= Block_8x8 && m_eob_total == 0) m_skip = true; for (size_t y = 0; y < num_8x8_blocks_high_lookup[subsize]; y++) { for (size_t x = 0; x < num_8x8_blocks_wide_lookup[subsize]; x++) { auto pos = (row + y) * m_mi_cols + (col + x); m_skips[pos] = m_skip; m_tx_sizes[pos] = m_tx_size; m_mi_sizes[pos] = m_mi_size; m_y_modes[pos] = m_y_mode; m_segment_ids[pos] = m_segment_id; for (size_t ref_list = 0; ref_list < 2; ref_list++) m_ref_frames[(pos * 2) + ref_list] = m_ref_frame[ref_list]; if (m_is_inter) { m_interp_filters[pos] = m_interp_filter; for (size_t ref_list = 0; ref_list < 2; ref_list++) { auto pos_with_ref_list = (pos * 2 + ref_list) * sizeof(MV); m_mvs[pos_with_ref_list] = m_block_mvs[ref_list][3]; for (size_t b = 0; b < 4; b++) m_sub_mvs[pos_with_ref_list * 4 + b * sizeof(MV)] = m_block_mvs[ref_list][b]; } } else { for (size_t b = 0; b < 4; b++) m_sub_modes[pos * 4 + b] = static_cast(m_block_sub_modes[b]); } } } return true; } bool Parser::mode_info() { if (m_frame_is_intra) return intra_frame_mode_info(); return inter_frame_mode_info(); } bool Parser::intra_frame_mode_info() { SAFE_CALL(intra_segment_id()); SAFE_CALL(read_skip()); SAFE_CALL(read_tx_size(true)); m_ref_frame[0] = IntraFrame; m_ref_frame[1] = None; m_is_inter = false; if (m_mi_size >= Block_8x8) { m_default_intra_mode = m_tree_parser->parse_tree(SyntaxElementType::DefaultIntraMode); m_y_mode = m_default_intra_mode; for (auto& block_sub_mode : m_block_sub_modes) block_sub_mode = m_y_mode; } else { m_num_4x4_w = num_4x4_blocks_wide_lookup[m_mi_size]; m_num_4x4_h = num_4x4_blocks_high_lookup[m_mi_size]; for (auto idy = 0; idy < 2; idy += m_num_4x4_h) { for (auto idx = 0; idx < 2; idx += m_num_4x4_w) { m_tree_parser->set_default_intra_mode_variables(idx, idy); m_default_intra_mode = m_tree_parser->parse_tree(SyntaxElementType::DefaultIntraMode); for (auto y = 0; y < m_num_4x4_h; y++) { for (auto x = 0; x < m_num_4x4_w; x++) { auto index = (idy + y) * 2 + idx + x; if (index > 3) dbgln("Trying to access index {} on m_sub_modes", index); m_block_sub_modes[index] = m_default_intra_mode; } } } } m_y_mode = m_default_intra_mode; } m_uv_mode = m_tree_parser->parse_tree(SyntaxElementType::DefaultUVMode); return true; } bool Parser::intra_segment_id() { if (m_segmentation_enabled && m_segmentation_update_map) m_segment_id = m_tree_parser->parse_tree(SyntaxElementType::SegmentID); else m_segment_id = 0; return true; } bool Parser::read_skip() { if (seg_feature_active(SEG_LVL_SKIP)) m_skip = true; else m_skip = m_tree_parser->parse_tree(SyntaxElementType::Skip); return true; } bool Parser::seg_feature_active(u8 feature) { return m_segmentation_enabled && m_feature_enabled[m_segment_id][feature]; } bool Parser::read_tx_size(bool allow_select) { m_max_tx_size = max_txsize_lookup[m_mi_size]; if (allow_select && m_tx_mode == TXModeSelect && m_mi_size >= Block_8x8) m_tx_size = m_tree_parser->parse_tree(SyntaxElementType::TXSize); else m_tx_size = min(m_max_tx_size, tx_mode_to_biggest_tx_size[m_tx_mode]); return true; } bool Parser::inter_frame_mode_info() { m_left_ref_frame[0] = m_available_l ? m_ref_frames[m_mi_row * m_mi_cols + (m_mi_col - 1)] : IntraFrame; m_above_ref_frame[0] = m_available_u ? m_ref_frames[(m_mi_row - 1) * m_mi_cols + m_mi_col] : IntraFrame; m_left_ref_frame[1] = m_available_l ? m_ref_frames[m_mi_row * m_mi_cols + (m_mi_col - 1) + 1] : None; m_above_ref_frame[1] = m_available_u ? m_ref_frames[(m_mi_row - 1) * m_mi_cols + m_mi_col + 1] : None; m_left_intra = m_left_ref_frame[0] <= IntraFrame; m_above_intra = m_above_ref_frame[0] <= IntraFrame; m_left_single = m_left_ref_frame[1] <= None; m_above_single = m_above_ref_frame[1] <= None; SAFE_CALL(inter_segment_id()); SAFE_CALL(read_skip()); SAFE_CALL(read_is_inter()); SAFE_CALL(read_tx_size(!m_skip || !m_is_inter)); if (m_is_inter) { SAFE_CALL(inter_block_mode_info()); } else { SAFE_CALL(intra_block_mode_info()); } return true; } bool Parser::inter_segment_id() { if (!m_segmentation_enabled) { m_segment_id = 0; return true; } auto predicted_segment_id = get_segment_id(); if (!m_segmentation_update_map) { m_segment_id = predicted_segment_id; return true; } if (!m_segmentation_temporal_update) { m_segment_id = m_tree_parser->parse_tree(SyntaxElementType::SegmentID); return true; } auto seg_id_predicted = m_tree_parser->parse_tree(SyntaxElementType::SegIDPredicted); if (seg_id_predicted) m_segment_id = predicted_segment_id; else m_segment_id = m_tree_parser->parse_tree(SyntaxElementType::SegmentID); for (size_t i = 0; i < num_8x8_blocks_wide_lookup[m_mi_size]; i++) m_above_seg_pred_context[m_mi_col + i] = seg_id_predicted; for (size_t i = 0; i < num_8x8_blocks_high_lookup[m_mi_size]; i++) m_left_seg_pred_context[m_mi_row + i] = seg_id_predicted; return true; } u8 Parser::get_segment_id() { auto bw = num_8x8_blocks_wide_lookup[m_mi_size]; auto bh = num_8x8_blocks_high_lookup[m_mi_size]; auto xmis = min(m_mi_cols - m_mi_col, (u32)bw); auto ymis = min(m_mi_rows - m_mi_row, (u32)bh); u8 segment = 7; for (size_t y = 0; y < ymis; y++) { for (size_t x = 0; x < xmis; x++) { segment = min(segment, m_prev_segment_ids[(m_mi_row + y) + (m_mi_col + x)]); } } return segment; } bool Parser::read_is_inter() { if (seg_feature_active(SEG_LVL_REF_FRAME)) m_is_inter = m_feature_data[m_segment_id][SEG_LVL_REF_FRAME] != IntraFrame; else m_is_inter = m_tree_parser->parse_tree(SyntaxElementType::IsInter); return true; } bool Parser::intra_block_mode_info() { m_ref_frame[0] = IntraFrame; m_ref_frame[1] = None; if (m_mi_size >= Block_8x8) { m_y_mode = m_tree_parser->parse_tree(SyntaxElementType::IntraMode); for (auto& block_sub_mode : m_block_sub_modes) block_sub_mode = m_y_mode; } else { m_num_4x4_w = num_4x4_blocks_wide_lookup[m_mi_size]; m_num_4x4_h = num_4x4_blocks_high_lookup[m_mi_size]; u8 sub_intra_mode; for (auto idy = 0; idy < 2; idy += m_num_4x4_h) { for (auto idx = 0; idx < 2; idx += m_num_4x4_w) { sub_intra_mode = m_tree_parser->parse_tree(SyntaxElementType::SubIntraMode); for (auto y = 0; y < m_num_4x4_h; y++) { for (auto x = 0; x < m_num_4x4_w; x++) m_block_sub_modes[(idy + y) * 2 + idx + x] = sub_intra_mode; } } } m_y_mode = sub_intra_mode; } m_uv_mode = m_tree_parser->parse_tree(SyntaxElementType::UVMode); return true; } bool Parser::inter_block_mode_info() { SAFE_CALL(read_ref_frames()); for (auto j = 0; j < 2; j++) { if (m_ref_frame[j] > IntraFrame) { SAFE_CALL(find_mv_refs(m_ref_frame[j], -1)); SAFE_CALL(find_best_ref_mvs(j)); } } auto is_compound = m_ref_frame[1] > IntraFrame; if (seg_feature_active(SEG_LVL_SKIP)) { m_y_mode = ZeroMv; } else if (m_mi_size >= Block_8x8) { auto inter_mode = m_tree_parser->parse_tree(SyntaxElementType::InterMode); m_y_mode = NearestMv + inter_mode; } if (m_interpolation_filter == Switchable) m_interp_filter = m_tree_parser->parse_tree(SyntaxElementType::InterpFilter); else m_interp_filter = m_interpolation_filter; if (m_mi_size < Block_8x8) { m_num_4x4_w = num_4x4_blocks_wide_lookup[m_mi_size]; m_num_4x4_h = num_4x4_blocks_high_lookup[m_mi_size]; for (auto idy = 0; idy < 2; idy += m_num_4x4_h) { for (auto idx = 0; idx < 2; idx += m_num_4x4_w) { auto inter_mode = m_tree_parser->parse_tree(SyntaxElementType::InterMode); m_y_mode = NearestMv + inter_mode; if (m_y_mode == NearestMv || m_y_mode == NearMv) { for (auto j = 0; j < 1 + is_compound; j++) SAFE_CALL(append_sub8x8_mvs(idy * 2 + idx, j)); } SAFE_CALL(assign_mv(is_compound)); for (auto y = 0; y < m_num_4x4_h; y++) { for (auto x = 0; x < m_num_4x4_w; x++) { auto block = (idy + y) * 2 + idx + x; for (auto ref_list = 0; ref_list < 1 + is_compound; ref_list++) { m_block_mvs[ref_list][block] = m_mv[ref_list]; } } } } } return true; } SAFE_CALL(assign_mv(is_compound)); for (auto ref_list = 0; ref_list < 1 + is_compound; ref_list++) { for (auto block = 0; block < 4; block++) { m_block_mvs[ref_list][block] = m_mv[ref_list]; } } return true; } bool Parser::read_ref_frames() { if (seg_feature_active(SEG_LVL_REF_FRAME)) { m_ref_frame[0] = static_cast(m_feature_data[m_segment_id][SEG_LVL_REF_FRAME]); m_ref_frame[1] = None; return true; } ReferenceMode comp_mode; if (m_reference_mode == ReferenceModeSelect) comp_mode = m_tree_parser->parse_tree(SyntaxElementType::CompMode); else comp_mode = m_reference_mode; if (comp_mode == CompoundReference) { auto idx = m_ref_frame_sign_bias[m_comp_fixed_ref]; auto comp_ref = m_tree_parser->parse_tree(SyntaxElementType::CompRef); m_ref_frame[idx] = m_comp_fixed_ref; m_ref_frame[!idx] = m_comp_var_ref[comp_ref]; return true; } auto single_ref_p1 = m_tree_parser->parse_tree(SyntaxElementType::SingleRefP1); if (single_ref_p1) { auto single_ref_p2 = m_tree_parser->parse_tree(SyntaxElementType::SingleRefP2); m_ref_frame[0] = single_ref_p2 ? AltRefFrame : GoldenFrame; } else { m_ref_frame[0] = LastFrame; } m_ref_frame[1] = None; return true; } bool Parser::assign_mv(bool is_compound) { m_mv[1] = 0; for (auto i = 0; i < 1 + is_compound; i++) { if (m_y_mode == NewMv) { SAFE_CALL(read_mv(i)); } else if (m_y_mode == NearestMv) { m_mv[i] = m_nearest_mv[i]; } else if (m_y_mode == NearMv) { m_mv[i] = m_near_mv[i]; } else { m_mv[i] = 0; } } return true; } bool Parser::read_mv(u8 ref) { m_use_hp = m_allow_high_precision_mv && use_mv_hp(m_best_mv[ref]); MV diff_mv; auto mv_joint = m_tree_parser->parse_tree(SyntaxElementType::MVJoint); if (mv_joint == MvJointHzvnz || mv_joint == MvJointHnzvnz) diff_mv.set_row(read_mv_component(0)); if (mv_joint == MvJointHnzvz || mv_joint == MvJointHnzvnz) diff_mv.set_col(read_mv_component(1)); m_mv[ref] = m_best_mv[ref] + diff_mv; return true; } i32 Parser::read_mv_component(u8) { auto mv_sign = m_tree_parser->parse_tree(SyntaxElementType::MVSign); auto mv_class = m_tree_parser->parse_tree(SyntaxElementType::MVClass); u32 mag; if (mv_class == MvClass0) { auto mv_class0_bit = m_tree_parser->parse_tree(SyntaxElementType::MVClass0Bit); auto mv_class0_fr = m_tree_parser->parse_tree(SyntaxElementType::MVClass0FR); auto mv_class0_hp = m_tree_parser->parse_tree(SyntaxElementType::MVClass0HP); mag = ((mv_class0_bit << 3) | (mv_class0_fr << 1) | mv_class0_hp) + 1; } else { auto d = 0; for (size_t i = 0; i < mv_class; i++) { auto mv_bit = m_tree_parser->parse_tree(SyntaxElementType::MVBit); d |= mv_bit << i; } mag = CLASS0_SIZE << (mv_class + 2); auto mv_fr = m_tree_parser->parse_tree(SyntaxElementType::MVFR); auto mv_hp = m_tree_parser->parse_tree(SyntaxElementType::MVHP); mag += ((d << 3) | (mv_fr << 1) | mv_hp) + 1; } return mv_sign ? -static_cast(mag) : static_cast(mag); } bool Parser::residual() { auto block_size = m_mi_size < Block_8x8 ? Block_8x8 : static_cast(m_mi_size); for (size_t plane = 0; plane < 3; plane++) { auto tx_size = (plane > 0) ? get_uv_tx_size() : m_tx_size; auto step = 1 << tx_size; auto plane_size = get_plane_block_size(block_size, plane); auto num_4x4_w = num_4x4_blocks_wide_lookup[plane_size]; auto num_4x4_h = num_4x4_blocks_high_lookup[plane_size]; auto sub_x = (plane > 0) ? m_subsampling_x : 0; auto sub_y = (plane > 0) ? m_subsampling_y : 0; auto base_x = (m_mi_col * 8) >> sub_x; auto base_y = (m_mi_row * 8) >> sub_y; if (m_is_inter) { if (m_mi_size < Block_8x8) { for (auto y = 0; y < num_4x4_h; y++) { for (auto x = 0; x < num_4x4_w; x++) { SAFE_CALL(m_decoder.predict_inter(plane, base_x + (4 * x), base_y + (4 * y), 4, 4, (y * num_4x4_w) + x)); } } } else { SAFE_CALL(m_decoder.predict_inter(plane, base_x, base_y, num_4x4_w * 4, num_4x4_h * 4, 0)); } } auto max_x = (m_mi_cols * 8) >> sub_x; auto max_y = (m_mi_rows * 8) >> sub_y; auto block_index = 0; for (auto y = 0; y < num_4x4_h; y += step) { for (auto x = 0; x < num_4x4_w; x += step) { auto start_x = base_x + (4 * x); auto start_y = base_y + (4 * y); auto non_zero = false; if (start_x < max_x && start_y < max_y) { if (!m_is_inter) SAFE_CALL(m_decoder.predict_intra(plane, start_x, start_y, m_available_l || x > 0, m_available_u || y > 0, (x + step) < num_4x4_w, tx_size, block_index)); if (!m_skip) { non_zero = tokens(plane, start_x, start_y, tx_size, block_index); SAFE_CALL(m_decoder.reconstruct(plane, start_x, start_y, tx_size)); } } auto above_sub_context = m_above_nonzero_context[plane]; auto left_sub_context = m_left_nonzero_context[plane]; above_sub_context.resize_and_keep_capacity((start_x >> 2) + step); left_sub_context.resize_and_keep_capacity((start_y >> 2) + step); for (auto i = 0; i < step; i++) { above_sub_context[(start_x >> 2) + i] = non_zero; left_sub_context[(start_y >> 2) + i] = non_zero; } block_index++; } } } return true; } TXSize Parser::get_uv_tx_size() { if (m_mi_size < Block_8x8) return TX_4x4; return min(m_tx_size, max_txsize_lookup[get_plane_block_size(m_mi_size, 1)]); } BlockSubsize Parser::get_plane_block_size(u32 subsize, u8 plane) { auto sub_x = (plane > 0) ? m_subsampling_x : 0; auto sub_y = (plane > 0) ? m_subsampling_y : 0; return ss_size_lookup[subsize][sub_x][sub_y]; } bool Parser::tokens(size_t plane, u32 start_x, u32 start_y, TXSize tx_size, u32 block_index) { m_tree_parser->set_start_x_and_y(start_x, start_y); size_t segment_eob = 16 << (tx_size << 1); auto scan = get_scan(plane, tx_size, block_index); auto check_eob = true; size_t c = 0; for (; c < segment_eob; c++) { auto pos = scan[c]; auto band = (tx_size == TX_4x4) ? coefband_4x4[c] : coefband_8x8plus[c]; m_tree_parser->set_tokens_variables(band, c, plane, tx_size, pos); if (check_eob) { auto more_coefs = m_tree_parser->parse_tree(SyntaxElementType::MoreCoefs); if (!more_coefs) break; } auto token = m_tree_parser->parse_tree(SyntaxElementType::Token); m_token_cache[pos] = energy_class[token]; if (token == ZeroToken) { m_tokens[pos] = 0; check_eob = false; } else { i32 coef = static_cast(read_coef(token)); auto sign_bit = m_bit_stream->read_literal(1); m_tokens[pos] = sign_bit ? -coef : coef; check_eob = true; } } auto non_zero = c > 0; m_eob_total += non_zero; for (size_t i = c; i < segment_eob; i++) m_tokens[scan[i]] = 0; return non_zero; } u32 const* Parser::get_scan(size_t plane, TXSize tx_size, u32 block_index) { if (plane > 0 || tx_size == TX_32x32) { m_tx_type = DCT_DCT; } else if (tx_size == TX_4x4) { if (m_lossless || m_is_inter) m_tx_type = DCT_DCT; else m_tx_type = mode_to_txfm_map[m_mi_size < Block_8x8 ? m_block_sub_modes[block_index] : m_y_mode]; } else { m_tx_type = mode_to_txfm_map[m_y_mode]; } if (tx_size == TX_4x4) { if (m_tx_type == ADST_DCT) return row_scan_4x4; if (m_tx_type == DCT_ADST) return col_scan_4x4; return default_scan_4x4; } if (tx_size == TX_8x8) { if (m_tx_type == ADST_DCT) return row_scan_8x8; if (m_tx_type == DCT_ADST) return col_scan_8x8; return default_scan_8x8; } if (tx_size == TX_16x16) { if (m_tx_type == ADST_DCT) return row_scan_16x16; if (m_tx_type == DCT_ADST) return col_scan_16x16; return default_scan_16x16; } return default_scan_32x32; } u32 Parser::read_coef(Token token) { auto cat = extra_bits[token][0]; auto num_extra = extra_bits[token][1]; auto coef = extra_bits[token][2]; if (token == DctValCat6) { for (size_t e = 0; e < (u8)(m_bit_depth - 8); e++) { auto high_bit = m_bit_stream->read_bool(255); coef += high_bit << (5 + m_bit_depth - e); } } for (size_t e = 0; e < num_extra; e++) { auto coef_bit = m_bit_stream->read_bool(cat_probs[cat][e]); coef += coef_bit << (num_extra - 1 - e); } return coef; } bool Parser::find_mv_refs(ReferenceFrame, int) { // TODO: Implement return true; } bool Parser::find_best_ref_mvs(int) { // TODO: Implement return true; } bool Parser::append_sub8x8_mvs(u8, u8) { // TODO: Implement return true; } bool Parser::use_mv_hp(const MV&) { // TODO: Implement return true; } void Parser::dump_info() { outln("Frame dimensions: {}x{}", m_frame_width, m_frame_height); outln("Render dimensions: {}x{}", m_render_width, m_render_height); outln("Bit depth: {}", m_bit_depth); outln("Interpolation filter: {}", (u8)m_interpolation_filter); } }