/* * Copyright (c) 2012 The WebRTC project authors. All Rights Reserved. * * Use of this source code is governed by a BSD-style license * that can be found in the LICENSE file in the root of the source * tree. An additional intellectual property rights grant can be found * in the file PATENTS. All contributing project authors may * be found in the AUTHORS file in the root of the source tree. */ #include "webrtc/tools/frame_analyzer/video_quality_analysis.h" #include #include #include #include #define STATS_LINE_LENGTH 32 #define Y4M_FILE_HEADER_MAX_SIZE 200 #define Y4M_FRAME_DELIMITER "FRAME" #define Y4M_FRAME_HEADER_SIZE 6 namespace webrtc { namespace test { using std::string; ResultsContainer::ResultsContainer() {} ResultsContainer::~ResultsContainer() {} int GetI420FrameSize(int width, int height) { int half_width = (width + 1) >> 1; int half_height = (height + 1) >> 1; int y_plane = width * height; // I420 Y plane. int u_plane = half_width * half_height; // I420 U plane. int v_plane = half_width * half_height; // I420 V plane. return y_plane + u_plane + v_plane; } int ExtractFrameSequenceNumber(std::string line) { size_t space_position = line.find(' '); if (space_position == string::npos) { return -1; } std::string frame = line.substr(0, space_position); size_t underscore_position = frame.find('_'); if (underscore_position == string::npos) { return -1; } std::string frame_number = frame.substr(underscore_position + 1); return strtol(frame_number.c_str(), NULL, 10); } int ExtractDecodedFrameNumber(std::string line) { size_t space_position = line.find(' '); if (space_position == string::npos) { return -1; } std::string decoded_number = line.substr(space_position + 1); return strtol(decoded_number.c_str(), NULL, 10); } bool IsThereBarcodeError(std::string line) { size_t barcode_error_position = line.find("Barcode error"); if (barcode_error_position != string::npos) { return true; } return false; } bool GetNextStatsLine(FILE* stats_file, char* line) { int chars = 0; char buf = 0; while (buf != '\n') { size_t chars_read = fread(&buf, 1, 1, stats_file); if (chars_read != 1 || feof(stats_file)) { return false; } line[chars] = buf; ++chars; } line[chars-1] = '\0'; // Strip the trailing \n and put end of string. return true; } bool ExtractFrameFromYuvFile(const char* i420_file_name, int width, int height, int frame_number, uint8_t* result_frame) { int frame_size = GetI420FrameSize(width, height); int offset = frame_number * frame_size; // Calculate offset for the frame. bool errors = false; FILE* input_file = fopen(i420_file_name, "rb"); if (input_file == NULL) { fprintf(stderr, "Couldn't open input file for reading: %s\n", i420_file_name); return false; } // Change stream pointer to new offset. fseek(input_file, offset, SEEK_SET); size_t bytes_read = fread(result_frame, 1, frame_size, input_file); if (bytes_read != static_cast(frame_size) && ferror(input_file)) { fprintf(stdout, "Error while reading frame no %d from file %s\n", frame_number, i420_file_name); errors = true; } fclose(input_file); return !errors; } bool ExtractFrameFromY4mFile(const char* y4m_file_name, int width, int height, int frame_number, uint8_t* result_frame) { int frame_size = GetI420FrameSize(width, height); int frame_offset = frame_number * frame_size; bool errors = false; FILE* input_file = fopen(y4m_file_name, "rb"); if (input_file == NULL) { fprintf(stderr, "Couldn't open input file for reading: %s\n", y4m_file_name); return false; } // YUV4MPEG2, a.k.a. Y4M File format has a file header and a frame header. The // file header has the aspect: "YUV4MPEG2 C420 W640 H360 Ip F30:1 A1:1". // Skip the header if this is the first frame of the file. if (frame_number == 0) { char frame_header[Y4M_FILE_HEADER_MAX_SIZE]; size_t bytes_read = fread(frame_header, 1, Y4M_FILE_HEADER_MAX_SIZE, input_file); if (bytes_read != static_cast(frame_size) && ferror(input_file)) { fprintf(stdout, "Error while reading first frame from file %s\n", y4m_file_name); fclose(input_file); return false; } std::string header_contents(frame_header); std::size_t found = header_contents.find(Y4M_FRAME_DELIMITER); if (found == std::string::npos) { fprintf(stdout, "Corrupted Y4M header, could not find \"FRAME\" in %s\n", header_contents.c_str()); fclose(input_file); return false; } frame_offset = static_cast(found); } // Change stream pointer to new offset, skipping the frame header as well. fseek(input_file, frame_offset + Y4M_FRAME_HEADER_SIZE, SEEK_SET); size_t bytes_read = fread(result_frame, 1, frame_size, input_file); if (bytes_read != static_cast(frame_size) && ferror(input_file)) { fprintf(stdout, "Error while reading frame no %d from file %s\n", frame_number, y4m_file_name); errors = true; } fclose(input_file); return !errors; } double CalculateMetrics(VideoAnalysisMetricsType video_metrics_type, const uint8_t* ref_frame, const uint8_t* test_frame, int width, int height) { if (!ref_frame || !test_frame) return -1; else if (height < 0 || width < 0) return -1; int half_width = (width + 1) >> 1; int half_height = (height + 1) >> 1; const uint8_t* src_y_a = ref_frame; const uint8_t* src_u_a = src_y_a + width * height; const uint8_t* src_v_a = src_u_a + half_width * half_height; const uint8_t* src_y_b = test_frame; const uint8_t* src_u_b = src_y_b + width * height; const uint8_t* src_v_b = src_u_b + half_width * half_height; int stride_y = width; int stride_uv = half_width; double result = 0.0; switch (video_metrics_type) { case kPSNR: // In the following: stride is determined by width. result = libyuv::I420Psnr(src_y_a, width, src_u_a, half_width, src_v_a, half_width, src_y_b, width, src_u_b, half_width, src_v_b, half_width, width, height); // LibYuv sets the max psnr value to 128, we restrict it to 48. // In case of 0 mse in one frame, 128 can skew the results significantly. result = (result > 48.0) ? 48.0 : result; break; case kSSIM: result = libyuv::I420Ssim(src_y_a, stride_y, src_u_a, stride_uv, src_v_a, stride_uv, src_y_b, stride_y, src_u_b, stride_uv, src_v_b, stride_uv, width, height); break; default: assert(false); } return result; } void RunAnalysis(const char* reference_file_name, const char* test_file_name, const char* stats_file_name, int width, int height, ResultsContainer* results) { // Check if the reference_file_name ends with "y4m". bool y4m_mode = false; if (std::string(reference_file_name).find("y4m") != std::string::npos) { y4m_mode = true; } int size = GetI420FrameSize(width, height); FILE* stats_file = fopen(stats_file_name, "r"); // String buffer for the lines in the stats file. char line[STATS_LINE_LENGTH]; // Allocate buffers for test and reference frames. uint8_t* test_frame = new uint8_t[size]; uint8_t* reference_frame = new uint8_t[size]; int previous_frame_number = -1; // While there are entries in the stats file. while (GetNextStatsLine(stats_file, line)) { int extracted_test_frame = ExtractFrameSequenceNumber(line); int decoded_frame_number = ExtractDecodedFrameNumber(line); // If there was problem decoding the barcode in this frame or the frame has // been duplicated, continue. if (IsThereBarcodeError(line) || decoded_frame_number == previous_frame_number) { continue; } assert(extracted_test_frame != -1); assert(decoded_frame_number != -1); ExtractFrameFromYuvFile(test_file_name, width, height, extracted_test_frame, test_frame); if (y4m_mode) { ExtractFrameFromY4mFile(reference_file_name, width, height, decoded_frame_number, reference_frame); } else { ExtractFrameFromYuvFile(reference_file_name, width, height, decoded_frame_number, reference_frame); } // Calculate the PSNR and SSIM. double result_psnr = CalculateMetrics(kPSNR, reference_frame, test_frame, width, height); double result_ssim = CalculateMetrics(kSSIM, reference_frame, test_frame, width, height); previous_frame_number = decoded_frame_number; // Fill in the result struct. AnalysisResult result; result.frame_number = decoded_frame_number; result.psnr_value = result_psnr; result.ssim_value = result_ssim; results->frames.push_back(result); } // Cleanup. fclose(stats_file); delete[] test_frame; delete[] reference_frame; } void PrintMaxRepeatedAndSkippedFrames(const std::string& label, const std::string& stats_file_name) { PrintMaxRepeatedAndSkippedFrames(stdout, label, stats_file_name); } void PrintMaxRepeatedAndSkippedFrames(FILE* output, const std::string& label, const std::string& stats_file_name) { FILE* stats_file = fopen(stats_file_name.c_str(), "r"); if (stats_file == NULL) { fprintf(stderr, "Couldn't open stats file for reading: %s\n", stats_file_name.c_str()); return; } char line[STATS_LINE_LENGTH]; int repeated_frames = 1; int max_repeated_frames = 1; int max_skipped_frames = 1; int previous_frame_number = -1; while (GetNextStatsLine(stats_file, line)) { int decoded_frame_number = ExtractDecodedFrameNumber(line); if (decoded_frame_number == -1) { continue; } // Calculate how many frames a cluster of repeated frames contains. if (decoded_frame_number == previous_frame_number) { ++repeated_frames; if (repeated_frames > max_repeated_frames) { max_repeated_frames = repeated_frames; } } else { repeated_frames = 1; } // Calculate how much frames have been skipped. if (decoded_frame_number != 0 && previous_frame_number != -1) { int skipped_frames = decoded_frame_number - previous_frame_number - 1; if (skipped_frames > max_skipped_frames) { max_skipped_frames = skipped_frames; } } previous_frame_number = decoded_frame_number; } fprintf(output, "RESULT Max_repeated: %s= %d\n", label.c_str(), max_repeated_frames); fprintf(output, "RESULT Max_skipped: %s= %d\n", label.c_str(), max_skipped_frames); fclose(stats_file); } void PrintAnalysisResults(const std::string& label, ResultsContainer* results) { PrintAnalysisResults(stdout, label, results); } void PrintAnalysisResults(FILE* output, const std::string& label, ResultsContainer* results) { std::vector::iterator iter; fprintf(output, "RESULT Unique_frames_count: %s= %u\n", label.c_str(), static_cast(results->frames.size())); if (results->frames.size() > 0u) { fprintf(output, "RESULT PSNR: %s= [", label.c_str()); for (iter = results->frames.begin(); iter != results->frames.end() - 1; ++iter) { fprintf(output, "%f,", iter->psnr_value); } fprintf(output, "%f] dB\n", iter->psnr_value); fprintf(output, "RESULT SSIM: %s= [", label.c_str()); for (iter = results->frames.begin(); iter != results->frames.end() - 1; ++iter) { fprintf(output, "%f,", iter->ssim_value); } fprintf(output, "%f] score\n", iter->ssim_value); } } } // namespace test } // namespace webrtc