ref: 02392eecccde436a76aca6c86a6fdf643e98eb38
dir: /test/simple_encode_test.cc/
/* * Copyright (c) 2019 The WebM 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 <math.h> #include <memory> #include <string> #include <vector> #include "third_party/googletest/src/include/gtest/gtest.h" #include "vp9/simple_encode.h" namespace vp9 { namespace { double GetBitrateInKbps(size_t bit_size, int num_frames, int frame_rate_num, int frame_rate_den) { return static_cast<double>(bit_size) / num_frames * frame_rate_num / frame_rate_den / 1000.0; } // Returns the number of unit in size of 4. // For example, if size is 7, return 2. int GetNumUnit4x4(int size) { return (size + 3) >> 2; } class SimpleEncodeTest : public ::testing::Test { protected: const int width_ = 352; const int height_ = 288; const int frame_rate_num_ = 30; const int frame_rate_den_ = 1; const int target_bitrate_ = 1000; const int num_frames_ = 17; const std::string in_file_path_str_ = "bus_352x288_420_f20_b8.yuv"; }; TEST_F(SimpleEncodeTest, ComputeFirstPassStats) { SimpleEncode simple_encode(width_, height_, frame_rate_num_, frame_rate_den_, target_bitrate_, num_frames_, in_file_path_str_.c_str()); simple_encode.ComputeFirstPassStats(); std::vector<std::vector<double>> frame_stats = simple_encode.ObserveFirstPassStats(); EXPECT_EQ(frame_stats.size(), static_cast<size_t>(num_frames_)); const size_t data_num = frame_stats[0].size(); // Read ObserveFirstPassStats before changing FIRSTPASS_STATS. EXPECT_EQ(data_num, static_cast<size_t>(25)); for (size_t i = 0; i < frame_stats.size(); ++i) { EXPECT_EQ(frame_stats[i].size(), data_num); // FIRSTPASS_STATS's first element is frame EXPECT_EQ(frame_stats[i][0], i); // FIRSTPASS_STATS's last element is count, and the count is 1 for single // frame stats EXPECT_EQ(frame_stats[i][data_num - 1], 1); } } TEST_F(SimpleEncodeTest, ObserveFirstPassMotionVectors) { SimpleEncode simple_encode(width_, height_, frame_rate_num_, frame_rate_den_, target_bitrate_, num_frames_, in_file_path_str_.c_str()); simple_encode.ComputeFirstPassStats(); std::vector<std::vector<MotionVectorInfo>> fps_motion_vectors = simple_encode.ObserveFirstPassMotionVectors(); EXPECT_EQ(fps_motion_vectors.size(), static_cast<size_t>(num_frames_)); const size_t num_blocks = ((width_ + 15) >> 4) * ((height_ + 15) >> 4); EXPECT_EQ(num_blocks, fps_motion_vectors[0].size()); for (size_t i = 0; i < fps_motion_vectors.size(); ++i) { EXPECT_EQ(num_blocks, fps_motion_vectors[i].size()); for (size_t j = 0; j < num_blocks; ++j) { const int mv_count = fps_motion_vectors[i][j].mv_count; const int ref_count = (fps_motion_vectors[i][j].ref_frame[0] != kRefFrameTypeNone) + (fps_motion_vectors[i][j].ref_frame[1] != kRefFrameTypeNone); EXPECT_EQ(mv_count, ref_count); } } } TEST_F(SimpleEncodeTest, GetCodingFrameNum) { SimpleEncode simple_encode(width_, height_, frame_rate_num_, frame_rate_den_, target_bitrate_, num_frames_, in_file_path_str_.c_str()); simple_encode.ComputeFirstPassStats(); const int num_coding_frames = simple_encode.GetCodingFrameNum(); EXPECT_EQ(num_coding_frames, 19); } TEST_F(SimpleEncodeTest, EncodeFrame) { SimpleEncode simple_encode(width_, height_, frame_rate_num_, frame_rate_den_, target_bitrate_, num_frames_, in_file_path_str_.c_str()); simple_encode.ComputeFirstPassStats(); int num_coding_frames = simple_encode.GetCodingFrameNum(); EXPECT_GE(num_coding_frames, num_frames_); simple_encode.StartEncode(); size_t total_data_bit_size = 0; int coded_show_frame_count = 0; int frame_coding_index = 0; while (coded_show_frame_count < num_frames_) { const GroupOfPicture group_of_picture = simple_encode.ObserveGroupOfPicture(); const std::vector<EncodeFrameInfo> &encode_frame_list = group_of_picture.encode_frame_list; for (size_t group_index = 0; group_index < encode_frame_list.size(); ++group_index) { EncodeFrameResult encode_frame_result; simple_encode.EncodeFrame(&encode_frame_result); EXPECT_EQ(encode_frame_result.show_idx, encode_frame_list[group_index].show_idx); EXPECT_EQ(encode_frame_result.frame_type, encode_frame_list[group_index].frame_type); EXPECT_EQ(encode_frame_list[group_index].coding_index, frame_coding_index); EXPECT_GE(encode_frame_result.psnr, 34) << "The psnr is supposed to be greater than 34 given the " "target_bitrate 1000 kbps"; EXPECT_EQ(encode_frame_result.ref_frame_info, encode_frame_list[group_index].ref_frame_info); total_data_bit_size += encode_frame_result.coding_data_bit_size; ++frame_coding_index; } coded_show_frame_count += group_of_picture.show_frame_count; } const double bitrate = GetBitrateInKbps(total_data_bit_size, num_frames_, frame_rate_num_, frame_rate_den_); const double off_target_threshold = 150; EXPECT_LE(fabs(target_bitrate_ - bitrate), off_target_threshold); simple_encode.EndEncode(); } TEST_F(SimpleEncodeTest, ObserveKeyFrameMap) { SimpleEncode simple_encode(width_, height_, frame_rate_num_, frame_rate_den_, target_bitrate_, num_frames_, in_file_path_str_.c_str()); simple_encode.ComputeFirstPassStats(); std::vector<int> key_frame_map = simple_encode.ObserveKeyFrameMap(); EXPECT_EQ(key_frame_map.size(), static_cast<size_t>(num_frames_)); simple_encode.StartEncode(); int coded_show_frame_count = 0; while (coded_show_frame_count < num_frames_) { const GroupOfPicture group_of_picture = simple_encode.ObserveGroupOfPicture(); const std::vector<EncodeFrameInfo> &encode_frame_list = group_of_picture.encode_frame_list; for (size_t group_index = 0; group_index < encode_frame_list.size(); ++group_index) { EncodeFrameResult encode_frame_result; simple_encode.EncodeFrame(&encode_frame_result); if (encode_frame_result.frame_type == kFrameTypeKey) { EXPECT_EQ(key_frame_map[encode_frame_result.show_idx], 1); } else { EXPECT_EQ(key_frame_map[encode_frame_result.show_idx], 0); } } coded_show_frame_count += group_of_picture.show_frame_count; } simple_encode.EndEncode(); } TEST_F(SimpleEncodeTest, EncodeFrameWithTargetFrameBits) { SimpleEncode simple_encode(width_, height_, frame_rate_num_, frame_rate_den_, target_bitrate_, num_frames_, in_file_path_str_.c_str()); simple_encode.ComputeFirstPassStats(); const int num_coding_frames = simple_encode.GetCodingFrameNum(); simple_encode.StartEncode(); for (int i = 0; i < num_coding_frames; ++i) { EncodeFrameInfo encode_frame_info = simple_encode.GetNextEncodeFrameInfo(); int target_frame_bits; switch (encode_frame_info.frame_type) { case kFrameTypeInter: target_frame_bits = 20000; break; case kFrameTypeKey: case kFrameTypeAltRef: case kFrameTypeGolden: target_frame_bits = 100000; break; case kFrameTypeOverlay: target_frame_bits = 2000; break; default: target_frame_bits = 20000; } double percent_diff = 15; if (encode_frame_info.frame_type == kFrameTypeOverlay) { percent_diff = 100; } EncodeFrameResult encode_frame_result; simple_encode.EncodeFrameWithTargetFrameBits( &encode_frame_result, target_frame_bits, percent_diff); const int recode_count = encode_frame_result.recode_count; // TODO(angiebird): Replace 7 by RATE_CTRL_MAX_RECODE_NUM EXPECT_LE(recode_count, 7); EXPECT_GE(recode_count, 1); const double diff = fabs((double)encode_frame_result.coding_data_bit_size - target_frame_bits); EXPECT_LE(diff * 100 / target_frame_bits, percent_diff); } simple_encode.EndEncode(); } TEST_F(SimpleEncodeTest, EncodeFrameWithQuantizeIndex) { SimpleEncode simple_encode(width_, height_, frame_rate_num_, frame_rate_den_, target_bitrate_, num_frames_, in_file_path_str_.c_str()); simple_encode.ComputeFirstPassStats(); const int num_coding_frames = simple_encode.GetCodingFrameNum(); simple_encode.StartEncode(); for (int i = 0; i < num_coding_frames; ++i) { const int assigned_quantize_index = 100 + i; EncodeFrameResult encode_frame_result; simple_encode.EncodeFrameWithQuantizeIndex(&encode_frame_result, assigned_quantize_index); EXPECT_EQ(encode_frame_result.quantize_index, assigned_quantize_index); } simple_encode.EndEncode(); } // This test encodes the video using EncodeFrame(), where quantize indexes // are selected by vp9 rate control. // Encode stats and the quantize_indexes are collected. // Then the test encodes the video again using EncodeFrameWithQuantizeIndex() // using the quantize indexes collected from the first run. // Then test whether the encode stats of the two encoding runs match. TEST_F(SimpleEncodeTest, EncodeConsistencyTest) { std::vector<int> quantize_index_list; std::vector<uint64_t> ref_sse_list; std::vector<double> ref_psnr_list; std::vector<size_t> ref_bit_size_list; std::vector<FrameType> ref_frame_type_list; std::vector<int> ref_show_idx_list; { // The first encode. SimpleEncode simple_encode(width_, height_, frame_rate_num_, frame_rate_den_, target_bitrate_, num_frames_, in_file_path_str_.c_str()); simple_encode.ComputeFirstPassStats(); const int num_coding_frames = simple_encode.GetCodingFrameNum(); simple_encode.StartEncode(); for (int i = 0; i < num_coding_frames; ++i) { EncodeFrameResult encode_frame_result; simple_encode.EncodeFrame(&encode_frame_result); quantize_index_list.push_back(encode_frame_result.quantize_index); ref_sse_list.push_back(encode_frame_result.sse); ref_psnr_list.push_back(encode_frame_result.psnr); ref_bit_size_list.push_back(encode_frame_result.coding_data_bit_size); ref_frame_type_list.push_back(encode_frame_result.frame_type); ref_show_idx_list.push_back(encode_frame_result.show_idx); } simple_encode.EndEncode(); } { // The second encode with quantize index got from the first encode. SimpleEncode simple_encode(width_, height_, frame_rate_num_, frame_rate_den_, target_bitrate_, num_frames_, in_file_path_str_.c_str()); simple_encode.ComputeFirstPassStats(); const int num_coding_frames = simple_encode.GetCodingFrameNum(); EXPECT_EQ(static_cast<size_t>(num_coding_frames), quantize_index_list.size()); simple_encode.StartEncode(); for (int i = 0; i < num_coding_frames; ++i) { EncodeFrameResult encode_frame_result; simple_encode.EncodeFrameWithQuantizeIndex(&encode_frame_result, quantize_index_list[i]); EXPECT_EQ(encode_frame_result.quantize_index, quantize_index_list[i]); EXPECT_EQ(encode_frame_result.sse, ref_sse_list[i]); EXPECT_DOUBLE_EQ(encode_frame_result.psnr, ref_psnr_list[i]); EXPECT_EQ(encode_frame_result.coding_data_bit_size, ref_bit_size_list[i]); EXPECT_EQ(encode_frame_result.frame_type, ref_frame_type_list[i]); EXPECT_EQ(encode_frame_result.show_idx, ref_show_idx_list[i]); } simple_encode.EndEncode(); } } // Test the information (partition info and motion vector info) stored in // encoder is the same between two encode runs. TEST_F(SimpleEncodeTest, EncodeConsistencyTest2) { const int num_rows_4x4 = GetNumUnit4x4(width_); const int num_cols_4x4 = GetNumUnit4x4(height_); const int num_units_4x4 = num_rows_4x4 * num_cols_4x4; // The first encode. SimpleEncode simple_encode(width_, height_, frame_rate_num_, frame_rate_den_, target_bitrate_, num_frames_, in_file_path_str_.c_str()); simple_encode.ComputeFirstPassStats(); const int num_coding_frames = simple_encode.GetCodingFrameNum(); std::vector<PartitionInfo> partition_info_list(num_units_4x4 * num_coding_frames); std::vector<MotionVectorInfo> motion_vector_info_list(num_units_4x4 * num_coding_frames); simple_encode.StartEncode(); for (int i = 0; i < num_coding_frames; ++i) { EncodeFrameResult encode_frame_result; simple_encode.EncodeFrame(&encode_frame_result); for (int j = 0; j < num_rows_4x4 * num_cols_4x4; ++j) { partition_info_list[i * num_units_4x4 + j] = encode_frame_result.partition_info[j]; motion_vector_info_list[i * num_units_4x4 + j] = encode_frame_result.motion_vector_info[j]; } } simple_encode.EndEncode(); // The second encode. SimpleEncode simple_encode_2(width_, height_, frame_rate_num_, frame_rate_den_, target_bitrate_, num_frames_, in_file_path_str_.c_str()); simple_encode_2.ComputeFirstPassStats(); const int num_coding_frames_2 = simple_encode_2.GetCodingFrameNum(); simple_encode_2.StartEncode(); for (int i = 0; i < num_coding_frames_2; ++i) { EncodeFrameResult encode_frame_result; simple_encode_2.EncodeFrame(&encode_frame_result); for (int j = 0; j < num_rows_4x4 * num_cols_4x4; ++j) { EXPECT_EQ(encode_frame_result.partition_info[j].row, partition_info_list[i * num_units_4x4 + j].row); EXPECT_EQ(encode_frame_result.partition_info[j].column, partition_info_list[i * num_units_4x4 + j].column); EXPECT_EQ(encode_frame_result.partition_info[j].row_start, partition_info_list[i * num_units_4x4 + j].row_start); EXPECT_EQ(encode_frame_result.partition_info[j].column_start, partition_info_list[i * num_units_4x4 + j].column_start); EXPECT_EQ(encode_frame_result.partition_info[j].width, partition_info_list[i * num_units_4x4 + j].width); EXPECT_EQ(encode_frame_result.partition_info[j].height, partition_info_list[i * num_units_4x4 + j].height); EXPECT_EQ(encode_frame_result.motion_vector_info[j].mv_count, motion_vector_info_list[i * num_units_4x4 + j].mv_count); EXPECT_EQ(encode_frame_result.motion_vector_info[j].ref_frame[0], motion_vector_info_list[i * num_units_4x4 + j].ref_frame[0]); EXPECT_EQ(encode_frame_result.motion_vector_info[j].ref_frame[1], motion_vector_info_list[i * num_units_4x4 + j].ref_frame[1]); EXPECT_EQ(encode_frame_result.motion_vector_info[j].mv_row[0], motion_vector_info_list[i * num_units_4x4 + j].mv_row[0]); EXPECT_EQ(encode_frame_result.motion_vector_info[j].mv_column[0], motion_vector_info_list[i * num_units_4x4 + j].mv_column[0]); EXPECT_EQ(encode_frame_result.motion_vector_info[j].mv_row[1], motion_vector_info_list[i * num_units_4x4 + j].mv_row[1]); EXPECT_EQ(encode_frame_result.motion_vector_info[j].mv_column[1], motion_vector_info_list[i * num_units_4x4 + j].mv_column[1]); } } simple_encode_2.EndEncode(); } // Test the information stored in encoder is the same between two encode runs. TEST_F(SimpleEncodeTest, EncodeConsistencyTest3) { std::vector<int> quantize_index_list; const int num_rows_4x4 = GetNumUnit4x4(width_); const int num_cols_4x4 = GetNumUnit4x4(height_); const int num_units_4x4 = num_rows_4x4 * num_cols_4x4; // The first encode. SimpleEncode simple_encode(width_, height_, frame_rate_num_, frame_rate_den_, target_bitrate_, num_frames_, in_file_path_str_.c_str()); simple_encode.ComputeFirstPassStats(); const int num_coding_frames = simple_encode.GetCodingFrameNum(); std::vector<PartitionInfo> partition_info_list(num_units_4x4 * num_coding_frames); simple_encode.StartEncode(); for (int i = 0; i < num_coding_frames; ++i) { EncodeFrameResult encode_frame_result; simple_encode.EncodeFrame(&encode_frame_result); quantize_index_list.push_back(encode_frame_result.quantize_index); for (int j = 0; j < num_rows_4x4 * num_cols_4x4; ++j) { partition_info_list[i * num_units_4x4 + j] = encode_frame_result.partition_info[j]; } } simple_encode.EndEncode(); // The second encode. SimpleEncode simple_encode_2(width_, height_, frame_rate_num_, frame_rate_den_, target_bitrate_, num_frames_, in_file_path_str_.c_str()); simple_encode_2.ComputeFirstPassStats(); const int num_coding_frames_2 = simple_encode_2.GetCodingFrameNum(); simple_encode_2.StartEncode(); for (int i = 0; i < num_coding_frames_2; ++i) { EncodeFrameResult encode_frame_result; simple_encode_2.EncodeFrameWithQuantizeIndex(&encode_frame_result, quantize_index_list[i]); for (int j = 0; j < num_rows_4x4 * num_cols_4x4; ++j) { EXPECT_EQ(encode_frame_result.partition_info[j].row, partition_info_list[i * num_units_4x4 + j].row); EXPECT_EQ(encode_frame_result.partition_info[j].column, partition_info_list[i * num_units_4x4 + j].column); EXPECT_EQ(encode_frame_result.partition_info[j].row_start, partition_info_list[i * num_units_4x4 + j].row_start); EXPECT_EQ(encode_frame_result.partition_info[j].column_start, partition_info_list[i * num_units_4x4 + j].column_start); EXPECT_EQ(encode_frame_result.partition_info[j].width, partition_info_list[i * num_units_4x4 + j].width); EXPECT_EQ(encode_frame_result.partition_info[j].height, partition_info_list[i * num_units_4x4 + j].height); } } simple_encode_2.EndEncode(); } // Encode with default VP9 decision first. // Get QPs and arf locations from the first encode. // Set external arfs and QPs for the second encode. // Expect to get matched results. TEST_F(SimpleEncodeTest, EncodeConsistencySetExternalGroupOfPicturesMap) { std::vector<int> quantize_index_list; std::vector<uint64_t> ref_sse_list; std::vector<double> ref_psnr_list; std::vector<size_t> ref_bit_size_list; std::vector<int> gop_map(num_frames_, 0); { // The first encode. SimpleEncode simple_encode(width_, height_, frame_rate_num_, frame_rate_den_, target_bitrate_, num_frames_, in_file_path_str_.c_str()); simple_encode.ComputeFirstPassStats(); simple_encode.StartEncode(); int coded_show_frame_count = 0; while (coded_show_frame_count < num_frames_) { const GroupOfPicture group_of_picture = simple_encode.ObserveGroupOfPicture(); gop_map[coded_show_frame_count] |= kGopMapFlagStart; if (group_of_picture.use_alt_ref) { gop_map[coded_show_frame_count] |= kGopMapFlagUseAltRef; } const std::vector<EncodeFrameInfo> &encode_frame_list = group_of_picture.encode_frame_list; for (size_t group_index = 0; group_index < encode_frame_list.size(); ++group_index) { EncodeFrameResult encode_frame_result; simple_encode.EncodeFrame(&encode_frame_result); quantize_index_list.push_back(encode_frame_result.quantize_index); ref_sse_list.push_back(encode_frame_result.sse); ref_psnr_list.push_back(encode_frame_result.psnr); ref_bit_size_list.push_back(encode_frame_result.coding_data_bit_size); } coded_show_frame_count += group_of_picture.show_frame_count; } simple_encode.EndEncode(); } { // The second encode with quantize index got from the first encode. // The external arfs are the same as the first encode. SimpleEncode simple_encode(width_, height_, frame_rate_num_, frame_rate_den_, target_bitrate_, num_frames_, in_file_path_str_.c_str()); simple_encode.ComputeFirstPassStats(); simple_encode.SetExternalGroupOfPicturesMap(gop_map.data(), gop_map.size()); const int num_coding_frames = simple_encode.GetCodingFrameNum(); EXPECT_EQ(static_cast<size_t>(num_coding_frames), quantize_index_list.size()); simple_encode.StartEncode(); for (int i = 0; i < num_coding_frames; ++i) { EncodeFrameResult encode_frame_result; simple_encode.EncodeFrameWithQuantizeIndex(&encode_frame_result, quantize_index_list[i]); EXPECT_EQ(encode_frame_result.quantize_index, quantize_index_list[i]); EXPECT_EQ(encode_frame_result.sse, ref_sse_list[i]); EXPECT_DOUBLE_EQ(encode_frame_result.psnr, ref_psnr_list[i]); EXPECT_EQ(encode_frame_result.coding_data_bit_size, ref_bit_size_list[i]); } simple_encode.EndEncode(); } } TEST_F(SimpleEncodeTest, SetExternalGroupOfPicturesMap) { SimpleEncode simple_encode(width_, height_, frame_rate_num_, frame_rate_den_, target_bitrate_, num_frames_, in_file_path_str_.c_str()); simple_encode.ComputeFirstPassStats(); std::vector<int> gop_map(num_frames_, 0); // Should be the first gop group. gop_map[0] = 0; // Second gop group with an alt ref. gop_map[5] |= kGopMapFlagStart | kGopMapFlagUseAltRef; // Third gop group without an alt ref. gop_map[10] |= kGopMapFlagStart; // Last gop group. gop_map[14] |= kGopMapFlagStart | kGopMapFlagUseAltRef; simple_encode.SetExternalGroupOfPicturesMap(gop_map.data(), gop_map.size()); std::vector<int> observed_gop_map = simple_encode.ObserveExternalGroupOfPicturesMap(); // First gop group. // There is always a key frame at show_idx 0 and key frame should always be // the start of a gop. We expect ObserveExternalGroupOfPicturesMap() will // insert an extra gop start here. EXPECT_EQ(observed_gop_map[0], kGopMapFlagStart | kGopMapFlagUseAltRef); // Second gop group with an alt ref. EXPECT_EQ(observed_gop_map[5], kGopMapFlagStart | kGopMapFlagUseAltRef); // Third gop group without an alt ref. EXPECT_EQ(observed_gop_map[10], kGopMapFlagStart); // Last gop group. The last gop is not supposed to use an alt ref. We expect // ObserveExternalGroupOfPicturesMap() will remove the alt ref flag here. EXPECT_EQ(observed_gop_map[14], kGopMapFlagStart); int ref_gop_show_frame_count_list[4] = { 5, 5, 4, 3 }; size_t ref_gop_coded_frame_count_list[4] = { 6, 6, 4, 3 }; int gop_count = 0; simple_encode.StartEncode(); int coded_show_frame_count = 0; while (coded_show_frame_count < num_frames_) { const GroupOfPicture group_of_picture = simple_encode.ObserveGroupOfPicture(); const std::vector<EncodeFrameInfo> &encode_frame_list = group_of_picture.encode_frame_list; EXPECT_EQ(encode_frame_list.size(), ref_gop_coded_frame_count_list[gop_count]); EXPECT_EQ(group_of_picture.show_frame_count, ref_gop_show_frame_count_list[gop_count]); for (size_t group_index = 0; group_index < encode_frame_list.size(); ++group_index) { EncodeFrameResult encode_frame_result; simple_encode.EncodeFrame(&encode_frame_result); } coded_show_frame_count += group_of_picture.show_frame_count; ++gop_count; } EXPECT_EQ(gop_count, 4); simple_encode.EndEncode(); } TEST_F(SimpleEncodeTest, GetEncodeFrameInfo) { // Makes sure that the encode_frame_info obtained from GetEncodeFrameInfo() // matches the counterpart in encode_frame_result obtained from EncodeFrame() SimpleEncode simple_encode(width_, height_, frame_rate_num_, frame_rate_den_, target_bitrate_, num_frames_, in_file_path_str_.c_str()); simple_encode.ComputeFirstPassStats(); const int num_coding_frames = simple_encode.GetCodingFrameNum(); simple_encode.StartEncode(); for (int i = 0; i < num_coding_frames; ++i) { EncodeFrameInfo encode_frame_info = simple_encode.GetNextEncodeFrameInfo(); EncodeFrameResult encode_frame_result; simple_encode.EncodeFrame(&encode_frame_result); EXPECT_EQ(encode_frame_info.show_idx, encode_frame_result.show_idx); EXPECT_EQ(encode_frame_info.frame_type, encode_frame_result.frame_type); } simple_encode.EndEncode(); } TEST_F(SimpleEncodeTest, GetFramePixelCount) { SimpleEncode simple_encode(width_, height_, frame_rate_num_, frame_rate_den_, target_bitrate_, num_frames_, in_file_path_str_.c_str()); EXPECT_EQ(simple_encode.GetFramePixelCount(), static_cast<uint64_t>(width_ * height_ * 3 / 2)); } } // namespace } // namespace vp9 int main(int argc, char **argv) { ::testing::InitGoogleTest(&argc, argv); return RUN_ALL_TESTS(); }