// Copyright 2015 The Chromium Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #include "media/gpu/vaapi/vaapi_jpeg_decoder.h" #include #include #include "base/logging.h" #include "base/macros.h" #include "media/filters/jpeg_parser.h" namespace media { // VAAPI only support subset of JPEG profiles. This function determines a given // parsed JPEG result is supported or not. static bool IsVaapiSupportedJpeg(const JpegParseResult& jpeg) { if (jpeg.frame_header.visible_width < 1 || jpeg.frame_header.visible_height < 1) { DLOG(ERROR) << "width(" << jpeg.frame_header.visible_width << ") and height(" << jpeg.frame_header.visible_height << ") should be at least 1"; return false; } // Size 64k*64k is the maximum in the JPEG standard. VAAPI doesn't support // resolutions larger than 16k*16k. const int kMaxDimension = 16384; if (jpeg.frame_header.coded_width > kMaxDimension || jpeg.frame_header.coded_height > kMaxDimension) { DLOG(ERROR) << "VAAPI doesn't support size(" << jpeg.frame_header.coded_width << "*" << jpeg.frame_header.coded_height << ") larger than " << kMaxDimension << "*" << kMaxDimension; return false; } if (jpeg.frame_header.num_components != 3) { DLOG(ERROR) << "VAAPI doesn't support num_components(" << static_cast(jpeg.frame_header.num_components) << ") != 3"; return false; } if (jpeg.frame_header.components[0].horizontal_sampling_factor < jpeg.frame_header.components[1].horizontal_sampling_factor || jpeg.frame_header.components[0].horizontal_sampling_factor < jpeg.frame_header.components[2].horizontal_sampling_factor) { DLOG(ERROR) << "VAAPI doesn't supports horizontal sampling factor of Y" << " smaller than Cb and Cr"; return false; } if (jpeg.frame_header.components[0].vertical_sampling_factor < jpeg.frame_header.components[1].vertical_sampling_factor || jpeg.frame_header.components[0].vertical_sampling_factor < jpeg.frame_header.components[2].vertical_sampling_factor) { DLOG(ERROR) << "VAAPI doesn't supports vertical sampling factor of Y" << " smaller than Cb and Cr"; return false; } return true; } static void FillPictureParameters( const JpegFrameHeader& frame_header, VAPictureParameterBufferJPEGBaseline* pic_param) { memset(pic_param, 0, sizeof(*pic_param)); pic_param->picture_width = frame_header.coded_width; pic_param->picture_height = frame_header.coded_height; pic_param->num_components = frame_header.num_components; for (int i = 0; i < pic_param->num_components; i++) { pic_param->components[i].component_id = frame_header.components[i].id; pic_param->components[i].h_sampling_factor = frame_header.components[i].horizontal_sampling_factor; pic_param->components[i].v_sampling_factor = frame_header.components[i].vertical_sampling_factor; pic_param->components[i].quantiser_table_selector = frame_header.components[i].quantization_table_selector; } } static void FillIQMatrix(const JpegQuantizationTable* q_table, VAIQMatrixBufferJPEGBaseline* iq_matrix) { memset(iq_matrix, 0, sizeof(*iq_matrix)); static_assert(kJpegMaxQuantizationTableNum == arraysize(iq_matrix->load_quantiser_table), "max number of quantization table mismatched"); for (size_t i = 0; i < kJpegMaxQuantizationTableNum; i++) { if (!q_table[i].valid) continue; iq_matrix->load_quantiser_table[i] = 1; static_assert( arraysize(iq_matrix->quantiser_table[i]) == arraysize(q_table[i].value), "number of quantization entries mismatched"); for (size_t j = 0; j < arraysize(q_table[i].value); j++) iq_matrix->quantiser_table[i][j] = q_table[i].value[j]; } } static void FillHuffmanTable(const JpegHuffmanTable* dc_table, const JpegHuffmanTable* ac_table, VAHuffmanTableBufferJPEGBaseline* huffman_table) { memset(huffman_table, 0, sizeof(*huffman_table)); // Use default huffman tables if not specified in header. bool has_huffman_table = false; for (size_t i = 0; i < kJpegMaxHuffmanTableNumBaseline; i++) { if (dc_table[i].valid || ac_table[i].valid) { has_huffman_table = true; break; } } if (!has_huffman_table) { dc_table = kDefaultDcTable; ac_table = kDefaultAcTable; } static_assert(kJpegMaxHuffmanTableNumBaseline == arraysize(huffman_table->load_huffman_table), "max number of huffman table mismatched"); static_assert(sizeof(huffman_table->huffman_table[0].num_dc_codes) == sizeof(dc_table[0].code_length), "size of huffman table code length mismatch"); static_assert(sizeof(huffman_table->huffman_table[0].dc_values[0]) == sizeof(dc_table[0].code_value[0]), "size of huffman table code value mismatch"); for (size_t i = 0; i < kJpegMaxHuffmanTableNumBaseline; i++) { if (!dc_table[i].valid || !ac_table[i].valid) continue; huffman_table->load_huffman_table[i] = 1; memcpy(huffman_table->huffman_table[i].num_dc_codes, dc_table[i].code_length, sizeof(huffman_table->huffman_table[i].num_dc_codes)); memcpy(huffman_table->huffman_table[i].dc_values, dc_table[i].code_value, sizeof(huffman_table->huffman_table[i].dc_values)); memcpy(huffman_table->huffman_table[i].num_ac_codes, ac_table[i].code_length, sizeof(huffman_table->huffman_table[i].num_ac_codes)); memcpy(huffman_table->huffman_table[i].ac_values, ac_table[i].code_value, sizeof(huffman_table->huffman_table[i].ac_values)); } } static void FillSliceParameters( const JpegParseResult& parse_result, VASliceParameterBufferJPEGBaseline* slice_param) { memset(slice_param, 0, sizeof(*slice_param)); slice_param->slice_data_size = parse_result.data_size; slice_param->slice_data_offset = 0; slice_param->slice_data_flag = VA_SLICE_DATA_FLAG_ALL; slice_param->slice_horizontal_position = 0; slice_param->slice_vertical_position = 0; slice_param->num_components = parse_result.scan.num_components; for (int i = 0; i < slice_param->num_components; i++) { slice_param->components[i].component_selector = parse_result.scan.components[i].component_selector; slice_param->components[i].dc_table_selector = parse_result.scan.components[i].dc_selector; slice_param->components[i].ac_table_selector = parse_result.scan.components[i].ac_selector; } slice_param->restart_interval = parse_result.restart_interval; // Cast to int to prevent overflow. int max_h_factor = parse_result.frame_header.components[0].horizontal_sampling_factor; int max_v_factor = parse_result.frame_header.components[0].vertical_sampling_factor; int mcu_cols = parse_result.frame_header.coded_width / (max_h_factor * 8); DCHECK_GT(mcu_cols, 0); int mcu_rows = parse_result.frame_header.coded_height / (max_v_factor * 8); DCHECK_GT(mcu_rows, 0); slice_param->num_mcus = mcu_rows * mcu_cols; } // static bool VaapiJpegDecoder::Decode(VaapiWrapper* vaapi_wrapper, const JpegParseResult& parse_result, VASurfaceID va_surface) { DCHECK_NE(va_surface, VA_INVALID_SURFACE); if (!IsVaapiSupportedJpeg(parse_result)) return false; // Set picture parameters. VAPictureParameterBufferJPEGBaseline pic_param; FillPictureParameters(parse_result.frame_header, &pic_param); if (!vaapi_wrapper->SubmitBuffer(VAPictureParameterBufferType, sizeof(pic_param), &pic_param)) { return false; } // Set quantization table. VAIQMatrixBufferJPEGBaseline iq_matrix; FillIQMatrix(parse_result.q_table, &iq_matrix); if (!vaapi_wrapper->SubmitBuffer(VAIQMatrixBufferType, sizeof(iq_matrix), &iq_matrix)) { return false; } // Set huffman table. VAHuffmanTableBufferJPEGBaseline huffman_table; FillHuffmanTable(parse_result.dc_table, parse_result.ac_table, &huffman_table); if (!vaapi_wrapper->SubmitBuffer(VAHuffmanTableBufferType, sizeof(huffman_table), &huffman_table)) { return false; } // Set slice parameters. VASliceParameterBufferJPEGBaseline slice_param; FillSliceParameters(parse_result, &slice_param); if (!vaapi_wrapper->SubmitBuffer(VASliceParameterBufferType, sizeof(slice_param), &slice_param)) { return false; } // Set scan data. if (!vaapi_wrapper->SubmitBuffer(VASliceDataBufferType, parse_result.data_size, const_cast(parse_result.data))) { return false; } return vaapi_wrapper->ExecuteAndDestroyPendingBuffers(va_surface); } } // namespace media