// Copyright 2020 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 { RgbaColor ConvertYuv(uint8_t Y, uint8_t Cr, uint8_t Cb, uint8_t T) { // Converts based on ITU-R BT.601. // See https://en.wikipedia.org/wiki/YCbCr // // Note that the T value should be interpolated based on a full transparency // being 256. This means that T=255 should not be fully transparent. Y=0 is // used to signal full transparency. // Values for Y<16 (except Y=0) are invalid, so clamp to 16. RgbaColor color; const double y_transform = 255.0 / 219 * (std::max(Y, 16) - 16); const double cb_transform = 255.0 / 244 * 1.772 * (Cb - 128); const double cr_transform = 255.0 / 244 * 1.402 * (Cr - 128); const double f1 = 0.114 / 0.587; const double f2 = 0.299 / 0.587; color.r = static_cast(y_transform + cr_transform); color.g = static_cast(y_transform - cb_transform * f1 - cr_transform * f2); color.b = static_cast(y_transform + cb_transform); color.a = Y == 0 ? 0 : (T == 0 ? 255 : 256 - T); return color; } } // namespace DvbSubParser::DvbSubParser() : last_pts_(0), timeout_(0) {} DvbSubParser::~DvbSubParser() {} bool DvbSubParser::Parse(DvbSubSegmentType segment_type, int64_t pts, const uint8_t* payload, size_t size, std::vector>* samples) { switch (segment_type) { case DvbSubSegmentType::kPageComposition: return ParsePageComposition(pts, payload, size, samples); case DvbSubSegmentType::kRegionComposition: return ParseRegionComposition(payload, size); case DvbSubSegmentType::kClutDefinition: return ParseClutDefinition(payload, size); case DvbSubSegmentType::kObjectData: return ParseObjectData(pts, payload, size); case DvbSubSegmentType::kDisplayDefinition: return ParseDisplayDefinition(payload, size); case DvbSubSegmentType::kEndOfDisplay: // This signals all the current objects are available. But we need to // know the end time, so we do nothing for now. return true; default: LOG(WARNING) << "Unknown DVB-sub segment_type=0x" << std::hex << static_cast(segment_type); return true; } } bool DvbSubParser::Flush(std::vector>* samples) { RCHECK(composer_.GetSamples(last_pts_, last_pts_ + timeout_ * kMpeg2Timescale, samples)); composer_.ClearObjects(); return true; } const DvbImageColorSpace* DvbSubParser::GetColorSpace(uint8_t clut_id) { return composer_.GetColorSpace(clut_id); } const DvbImageBuilder* DvbSubParser::GetImageForObject(uint16_t object_id) { return composer_.GetObjectImage(object_id); } bool DvbSubParser::ParsePageComposition( int64_t pts, const uint8_t* data, size_t size, std::vector>* samples) { // See ETSI EN 300 743 Section 7.2.2. BitReader reader(data, size); uint8_t page_state; RCHECK(reader.ReadBits(8, &timeout_)); RCHECK(reader.SkipBits(4)); // page_version_number RCHECK(reader.ReadBits(2, &page_state)); RCHECK(reader.SkipBits(2)); // reserved if (page_state == 0x1 || page_state == 0x2) { // If this is a "acquisition point" or a "mode change", then this is a new // page and we should clear the old data. RCHECK(composer_.GetSamples(last_pts_, pts, samples)); composer_.ClearObjects(); last_pts_ = pts; } while (reader.bits_available() > 0u) { uint8_t region_id; uint16_t x, y; RCHECK(reader.ReadBits(8, ®ion_id)); RCHECK(reader.SkipBits(8)); // reserved RCHECK(reader.ReadBits(16, &x)); RCHECK(reader.ReadBits(16, &y)); RCHECK(composer_.SetRegionPosition(region_id, x, y)); } return true; } bool DvbSubParser::ParseRegionComposition(const uint8_t* data, size_t size) { // See ETSI EN 300 743 Section 7.2.3. BitReader reader(data, size); uint8_t region_id, clut_id; uint16_t region_width, region_height; bool region_fill_flag; int background_pixel_code; RCHECK(reader.ReadBits(8, ®ion_id)); RCHECK(reader.SkipBits(4)); // region_version_number RCHECK(reader.ReadBits(1, ®ion_fill_flag)); RCHECK(reader.SkipBits(3)); // reserved RCHECK(reader.ReadBits(16, ®ion_width)); RCHECK(reader.ReadBits(16, ®ion_height)); RCHECK(reader.SkipBits(3)); // region_level_of_compatibility RCHECK(reader.SkipBits(3)); // region_depth RCHECK(reader.SkipBits(2)); // reserved RCHECK(reader.ReadBits(8, &clut_id)); RCHECK(reader.ReadBits(8, &background_pixel_code)); RCHECK(reader.SkipBits(4)); // region_4-bit_pixel_code RCHECK(reader.SkipBits(2)); // region_2-bit_pixel_code RCHECK(reader.SkipBits(2)); // reserved RCHECK( composer_.SetRegionInfo(region_id, clut_id, region_width, region_height)); if (!region_fill_flag) background_pixel_code = -1; while (reader.bits_available() > 0) { uint16_t object_id, x, y; uint8_t object_type; RCHECK(reader.ReadBits(16, &object_id)); RCHECK(reader.ReadBits(2, &object_type)); RCHECK(reader.SkipBits(2)); // object_provider_flag RCHECK(reader.ReadBits(12, &x)); RCHECK(reader.SkipBits(4)); // reserved RCHECK(reader.ReadBits(12, &y)); if (object_type == 0x01 || object_type == 0x02) { RCHECK(reader.SkipBits(8)); // foreground_pixel_code RCHECK(reader.SkipBits(8)); // background_pixel_code } RCHECK(composer_.SetObjectInfo(object_id, region_id, x, y, background_pixel_code)); } return true; } bool DvbSubParser::ParseClutDefinition(const uint8_t* data, size_t size) { // See ETSI EN 300 743 Section 7.2.4. BitReader reader(data, size); uint8_t clut_id; RCHECK(reader.ReadBits(8, &clut_id)); auto* color_space = composer_.GetColorSpace(clut_id); RCHECK(reader.SkipBits(4)); // CLUT_version_number RCHECK(reader.SkipBits(4)); // reserved while (reader.bits_available() > 0) { uint8_t clut_entry_id; uint8_t has_2_bit; uint8_t has_4_bit; uint8_t has_8_bit; uint8_t full_range_flag; RCHECK(reader.ReadBits(8, &clut_entry_id)); RCHECK(reader.ReadBits(1, &has_2_bit)); RCHECK(reader.ReadBits(1, &has_4_bit)); RCHECK(reader.ReadBits(1, &has_8_bit)); RCHECK(reader.SkipBits(4)); // reserved RCHECK(reader.ReadBits(1, &full_range_flag)); if (has_2_bit + has_4_bit + has_8_bit != 1) { LOG(ERROR) << "Must specify exactly one bit depth in CLUT definition"; return false; } const BitDepth bit_depth = has_2_bit ? BitDepth::k2Bit : (has_4_bit ? BitDepth::k4Bit : BitDepth::k8Bit); uint8_t Y, Cr, Cb, T; if (full_range_flag) { RCHECK(reader.ReadBits(8, &Y)); RCHECK(reader.ReadBits(8, &Cr)); RCHECK(reader.ReadBits(8, &Cb)); RCHECK(reader.ReadBits(8, &T)); } else { // These store the most-significant bits, so shift them up. RCHECK(reader.ReadBits(6, &Y)); Y <<= 2; RCHECK(reader.ReadBits(4, &Cr)); Cr <<= 4; RCHECK(reader.ReadBits(4, &Cb)); Cb <<= 4; RCHECK(reader.ReadBits(2, &T)); T <<= 6; } color_space->SetColor(bit_depth, clut_entry_id, ConvertYuv(Y, Cr, Cb, T)); } return true; } bool DvbSubParser::ParseObjectData(int64_t pts, const uint8_t* data, size_t size) { // See ETSI EN 300 743 Section 7.2.5 Table 17. BitReader reader(data, size); uint16_t object_id; uint8_t object_coding_method; RCHECK(reader.ReadBits(16, &object_id)); RCHECK(reader.SkipBits(4)); // object_version_number RCHECK(reader.ReadBits(2, &object_coding_method)); RCHECK(reader.SkipBits(1)); // non_modifying_colour_flag RCHECK(reader.SkipBits(1)); // reserved auto* image = composer_.GetObjectImage(object_id); auto* color_space = composer_.GetColorSpaceForObject(object_id); if (!image || !color_space) return false; if (object_coding_method == 0) { uint16_t top_field_length; uint16_t bottom_field_length; RCHECK(reader.ReadBits(16, &top_field_length)); RCHECK(reader.ReadBits(16, &bottom_field_length)); RCHECK(ParsePixelDataSubObject(top_field_length, true, &reader, color_space, image)); RCHECK(ParsePixelDataSubObject(bottom_field_length, false, &reader, color_space, image)); // Ignore 8_stuff_bits since we don't need to read to the end. if (bottom_field_length == 0) { // If there are no bottom rows, then the top rows are used instead. See // beginning of section 7.2.5.1. image->MirrorToBottomRows(); } } else { LOG(ERROR) << "Unsupported DVB-sub object coding method: " << static_cast(object_coding_method); return false; } return true; } bool DvbSubParser::ParseDisplayDefinition(const uint8_t* data, size_t size) { // See ETSI EN 300 743 Section 7.2.1. BitReader reader(data, size); uint16_t width, height; RCHECK(reader.SkipBits(4)); // dds_version_number RCHECK(reader.SkipBits(1)); // display_window_flag RCHECK(reader.SkipBits(3)); // reserved RCHECK(reader.ReadBits(16, &width)); RCHECK(reader.ReadBits(16, &height)); // Size is stored as -1. composer_.SetDisplaySize(width + 1, height + 1); return true; } bool DvbSubParser::ParsePixelDataSubObject(size_t sub_object_length, bool is_top_fields, BitReader* reader, DvbImageColorSpace* color_space, DvbImageBuilder* image) { const size_t start = reader->bit_position() / 8; while (reader->bit_position() / 8 < start + sub_object_length) { // See ETSI EN 300 743 Section 7.2.5.1 Table 20 uint8_t data_type; RCHECK(reader->ReadBits(8, &data_type)); uint8_t temp[16]; switch (data_type) { case 0x10: RCHECK(Parse2BitPixelData(is_top_fields, reader, image)); reader->SkipToNextByte(); break; case 0x11: RCHECK(Parse4BitPixelData(is_top_fields, reader, image)); reader->SkipToNextByte(); break; case 0x12: RCHECK(Parse8BitPixelData(is_top_fields, reader, image)); break; case 0x20: for (int i = 0; i < 4; i++) { RCHECK(reader->ReadBits(4, &temp[i])); } color_space->Set2To4BitDepthMap(temp); break; case 0x21: for (int i = 0; i < 4; i++) { RCHECK(reader->ReadBits(8, &temp[i])); } color_space->Set2To8BitDepthMap(temp); break; case 0x22: for (int i = 0; i < 16; i++) { RCHECK(reader->ReadBits(8, &temp[i])); } color_space->Set4To8BitDepthMap(temp); break; case 0xf0: image->NewRow(is_top_fields); break; default: LOG(ERROR) << "Unsupported DVB-sub pixel data format: 0x" << std::hex << static_cast(data_type); return false; } } return true; } bool DvbSubParser::Parse2BitPixelData(bool is_top_fields, BitReader* reader, DvbImageBuilder* image) { // 2-bit/pixel code string, Section 7.2.5.2.1, Table 22. while (true) { uint8_t peek; RCHECK(reader->ReadBits(2, &peek)); if (peek != 0) { RCHECK(image->AddPixel(BitDepth::k2Bit, peek, is_top_fields)); } else { uint8_t switch_1; RCHECK(reader->ReadBits(1, &switch_1)); if (switch_1 == 1) { uint8_t count_minus_3; RCHECK(reader->ReadBits(3, &count_minus_3)); RCHECK(reader->ReadBits(2, &peek)); for (uint8_t i = 0; i < count_minus_3 + 3; i++) RCHECK(image->AddPixel(BitDepth::k2Bit, peek, is_top_fields)); } else { uint8_t switch_2; RCHECK(reader->ReadBits(1, &switch_2)); if (switch_2 == 1) { RCHECK(image->AddPixel(BitDepth::k2Bit, 0, is_top_fields)); } else { uint8_t switch_3; RCHECK(reader->ReadBits(2, &switch_3)); if (switch_3 == 0) { break; } else if (switch_3 == 1) { RCHECK(image->AddPixel(BitDepth::k2Bit, 0, is_top_fields)); RCHECK(image->AddPixel(BitDepth::k2Bit, 0, is_top_fields)); } else if (switch_3 == 2) { uint8_t count_minus_12; RCHECK(reader->ReadBits(4, &count_minus_12)); RCHECK(reader->ReadBits(2, &peek)); for (uint8_t i = 0; i < count_minus_12 + 12; i++) RCHECK(image->AddPixel(BitDepth::k2Bit, peek, is_top_fields)); } else if (switch_3 == 3) { uint8_t count_minus_29; RCHECK(reader->ReadBits(8, &count_minus_29)); RCHECK(reader->ReadBits(2, &peek)); for (uint8_t i = 0; i < count_minus_29 + 29; i++) RCHECK(image->AddPixel(BitDepth::k2Bit, peek, is_top_fields)); } } } } } return true; } bool DvbSubParser::Parse4BitPixelData(bool is_top_fields, BitReader* reader, DvbImageBuilder* image) { // 4-bit/pixel code string, Section 7.2.5.2.2, Table 24. DCHECK(reader->bits_available() % 8 == 0); while (true) { uint8_t peek; RCHECK(reader->ReadBits(4, &peek)); if (peek != 0) { RCHECK(image->AddPixel(BitDepth::k4Bit, peek, is_top_fields)); } else { uint8_t switch_1; RCHECK(reader->ReadBits(1, &switch_1)); if (switch_1 == 0) { RCHECK(reader->ReadBits(3, &peek)); if (peek != 0) { for (int i = 0; i < peek + 2; i++) RCHECK(image->AddPixel(BitDepth::k4Bit, 0, is_top_fields)); } else { break; } } else { uint8_t switch_2; RCHECK(reader->ReadBits(1, &switch_2)); if (switch_2 == 0) { RCHECK(reader->ReadBits(2, &peek)); // run_length_4-7 uint8_t code; RCHECK(reader->ReadBits(4, &code)); for (int i = 0; i < peek + 4; i++) RCHECK(image->AddPixel(BitDepth::k4Bit, code, is_top_fields)); } else { uint8_t switch_3; RCHECK(reader->ReadBits(2, &switch_3)); if (switch_3 == 0) { RCHECK(image->AddPixel(BitDepth::k4Bit, 0, is_top_fields)); } else if (switch_3 == 1) { RCHECK(image->AddPixel(BitDepth::k4Bit, 0, is_top_fields)); RCHECK(image->AddPixel(BitDepth::k4Bit, 0, is_top_fields)); } else if (switch_3 == 2) { RCHECK(reader->ReadBits(4, &peek)); // run_length_9-24 uint8_t code; RCHECK(reader->ReadBits(4, &code)); for (int i = 0; i < peek + 9; i++) RCHECK(image->AddPixel(BitDepth::k4Bit, code, is_top_fields)); } else { // switch_3 == 3 RCHECK(reader->ReadBits(8, &peek)); // run_length_25-280 uint8_t code; RCHECK(reader->ReadBits(4, &code)); for (int i = 0; i < peek + 25; i++) RCHECK(image->AddPixel(BitDepth::k4Bit, code, is_top_fields)); } } } } } return true; } bool DvbSubParser::Parse8BitPixelData(bool is_top_fields, BitReader* reader, DvbImageBuilder* image) { // 8-bit/pixel code string, Section 7.2.5.2.3, Table 26. while (true) { uint8_t peek; RCHECK(reader->ReadBits(8, &peek)); if (peek != 0) { RCHECK(image->AddPixel(BitDepth::k8Bit, peek, is_top_fields)); } else { uint8_t switch_1; RCHECK(reader->ReadBits(1, &switch_1)); if (switch_1 == 0) { RCHECK(reader->ReadBits(7, &peek)); if (peek != 0) { for (uint8_t i = 0; i < peek; i++) RCHECK(image->AddPixel(BitDepth::k8Bit, 0, is_top_fields)); } else { break; } } else { uint8_t count; RCHECK(reader->ReadBits(7, &count)); RCHECK(reader->ReadBits(8, &peek)); for (uint8_t i = 0; i < count; i++) RCHECK(image->AddPixel(BitDepth::k8Bit, peek, is_top_fields)); } } } return true; } } // namespace media } // namespace shaka