blob: 9912778a8c8e10a856e6ffd759c5bb2f94bdd1f7 [file] [log] [blame]
// Copyright 2019 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 <algorithm>
#include <numeric>
#include <vector>
#include "base/command_line.h"
#include "base/files/file_util.h"
#include "base/json/json_writer.h"
#include "base/strings/stringprintf.h"
#include "media/base/test_data_util.h"
#include "media/gpu/test/video.h"
#include "media/gpu/test/video_player/frame_renderer_dummy.h"
#include "media/gpu/test/video_player/video_decoder_client.h"
#include "media/gpu/test/video_player/video_player.h"
#include "media/gpu/test/video_player/video_player_test_environment.h"
#include "testing/gtest/include/gtest/gtest.h"
namespace media {
namespace test {
namespace {
// Video decoder perf tests usage message. Make sure to also update the
// documentation under docs/media/gpu/video_decoder_perf_test_usage.md when
// making changes here.
constexpr const char* usage_msg =
"usage: video_decode_accelerator_perf_tests\n"
" [-v=<level>] [--vmodule=<config>] [--output_folder]\n"
" ([--use_vd]|[--use_vd_vda]) [--gtest_help] [--help]\n"
" [<video path>] [<video metadata path>]\n";
// Video decoder perf tests help message.
constexpr const char* help_msg =
"Run the video decode accelerator performance tests on the video\n"
"specified by <video path>. If no <video path> is given the default\n"
"\"test-25fps.h264\" video will be used.\n"
"\nThe <video metadata path> should specify the location of a json file\n"
"containing the video's metadata, such as frame checksums. By default\n"
"<video path>.json will be used.\n"
"\nThe following arguments are supported:\n"
" -v enable verbose mode, e.g. -v=2.\n"
" --vmodule enable verbose mode for the specified module,\n"
" e.g. --vmodule=*media/gpu*=2.\n"
" --output_folder overwrite the output folder used to store\n"
" performance metrics, if not specified results\n"
" will be stored in the current working directory.\n"
" --use_vd use the new VD-based video decoders, instead of\n"
" the default VDA-based video decoders.\n"
" --use_vd_vda use the new VD-based video decoders with a wrapper"
" that translates to the VDA interface, used to test"
" interaction with older components expecting the VDA"
" interface.\n"
" --gtest_help display the gtest help and exit.\n"
" --help display this help and exit.\n";
media::test::VideoPlayerTestEnvironment* g_env;
// Default output folder used to store performance metrics.
constexpr const base::FilePath::CharType* kDefaultOutputFolder =
FILE_PATH_LITERAL("perf_metrics");
// Struct storing various time-related statistics.
struct PerformanceTimeStats {
PerformanceTimeStats() {}
explicit PerformanceTimeStats(const std::vector<double>& times);
double avg_ms_ = 0.0;
double percentile_25_ms_ = 0.0;
double percentile_50_ms_ = 0.0;
double percentile_75_ms_ = 0.0;
};
PerformanceTimeStats::PerformanceTimeStats(const std::vector<double>& times) {
avg_ms_ = std::accumulate(times.begin(), times.end(), 0.0) / times.size();
std::vector<double> sorted_times = times;
std::sort(sorted_times.begin(), sorted_times.end());
percentile_25_ms_ = sorted_times[sorted_times.size() / 4];
percentile_50_ms_ = sorted_times[sorted_times.size() / 2];
percentile_75_ms_ = sorted_times[(sorted_times.size() * 3) / 4];
}
struct PerformanceMetrics {
// Total measurement duration.
base::TimeDelta total_duration_;
// The number of frames decoded.
size_t frames_decoded_ = 0;
// The overall number of frames decoded per second.
double frames_per_second_ = 0.0;
// The number of frames dropped because of the decoder running behind, only
// relevant for capped performance tests.
size_t frames_dropped_ = 0;
// The percentage of frames dropped because of the decoder running behind,
// only relevant for capped performance tests.
double dropped_frame_percentage_ = 0.0;
// Statistics about the time between subsequent frame deliveries.
PerformanceTimeStats delivery_time_stats_;
// Statistics about the time between decode start and frame deliveries.
PerformanceTimeStats decode_time_stats_;
};
// The performance evaluator can be plugged into the video player to collect
// various performance metrics.
// TODO(dstaessens@) Check and post warning when CPU frequency scaling is
// enabled as this affects test results.
class PerformanceEvaluator : public VideoFrameProcessor {
public:
// Create a new performance evaluator. The caller should makes sure
// |frame_renderer| outlives the performance evaluator.
explicit PerformanceEvaluator(const FrameRendererDummy* const frame_renderer)
: frame_renderer_(frame_renderer) {}
// Interface VideoFrameProcessor
void ProcessVideoFrame(scoped_refptr<const VideoFrame> video_frame,
size_t frame_index) override;
bool WaitUntilDone() override { return true; }
// Start/Stop collecting performance metrics.
void StartMeasuring();
void StopMeasuring();
// Write the collected performance metrics to file.
void WriteMetricsToFile() const;
private:
// Start/end time of the measurement period.
base::TimeTicks start_time_;
base::TimeTicks end_time_;
// Time at which the previous frame was delivered.
base::TimeTicks prev_frame_delivery_time_;
// List of times between subsequent frame deliveries.
std::vector<double> frame_delivery_times_;
// List of times between decode start and frame delivery.
std::vector<double> frame_decode_times_;
// Collection of various performance metrics.
PerformanceMetrics perf_metrics_;
// Frame renderer used to get the dropped frame rate, owned by the creator of
// the performance evaluator.
const FrameRendererDummy* const frame_renderer_;
};
void PerformanceEvaluator::ProcessVideoFrame(
scoped_refptr<const VideoFrame> video_frame,
size_t frame_index) {
base::TimeTicks now = base::TimeTicks::Now();
base::TimeDelta delivery_time = (now - prev_frame_delivery_time_);
frame_delivery_times_.push_back(delivery_time.InMillisecondsF());
prev_frame_delivery_time_ = now;
base::TimeDelta decode_time = now.since_origin() - video_frame->timestamp();
frame_decode_times_.push_back(decode_time.InMillisecondsF());
perf_metrics_.frames_decoded_++;
}
void PerformanceEvaluator::StartMeasuring() {
start_time_ = base::TimeTicks::Now();
prev_frame_delivery_time_ = start_time_;
}
void PerformanceEvaluator::StopMeasuring() {
end_time_ = base::TimeTicks::Now();
perf_metrics_.total_duration_ = end_time_ - start_time_;
perf_metrics_.frames_per_second_ = perf_metrics_.frames_decoded_ /
perf_metrics_.total_duration_.InSecondsF();
perf_metrics_.frames_dropped_ = frame_renderer_->FramesDropped();
// Calculate the dropped frame percentage.
perf_metrics_.dropped_frame_percentage_ =
static_cast<double>(perf_metrics_.frames_dropped_) /
static_cast<double>(
std::max<size_t>(perf_metrics_.frames_decoded_, 1ul)) *
100.0;
// Calculate delivery and decode time metrics.
perf_metrics_.delivery_time_stats_ =
PerformanceTimeStats(frame_delivery_times_);
perf_metrics_.decode_time_stats_ = PerformanceTimeStats(frame_decode_times_);
std::cout << "Frames decoded: " << perf_metrics_.frames_decoded_
<< std::endl;
std::cout << "Total duration: "
<< perf_metrics_.total_duration_.InMillisecondsF() << "ms"
<< std::endl;
std::cout << "FPS: " << perf_metrics_.frames_per_second_
<< std::endl;
std::cout << "Frames Dropped: " << perf_metrics_.frames_dropped_
<< std::endl;
std::cout << "Dropped frame percentage: "
<< perf_metrics_.dropped_frame_percentage_ << "%" << std::endl;
std::cout << "Frame delivery time - average: "
<< perf_metrics_.delivery_time_stats_.avg_ms_ << "ms" << std::endl;
std::cout << "Frame delivery time - percentile 25: "
<< perf_metrics_.delivery_time_stats_.percentile_25_ms_ << "ms"
<< std::endl;
std::cout << "Frame delivery time - percentile 50: "
<< perf_metrics_.delivery_time_stats_.percentile_50_ms_ << "ms"
<< std::endl;
std::cout << "Frame delivery time - percentile 75: "
<< perf_metrics_.delivery_time_stats_.percentile_75_ms_ << "ms"
<< std::endl;
std::cout << "Frame decode time - average: "
<< perf_metrics_.decode_time_stats_.avg_ms_ << "ms" << std::endl;
std::cout << "Frame decode time - percentile 25: "
<< perf_metrics_.decode_time_stats_.percentile_25_ms_ << "ms"
<< std::endl;
std::cout << "Frame decode time - percentile 50: "
<< perf_metrics_.decode_time_stats_.percentile_50_ms_ << "ms"
<< std::endl;
std::cout << "Frame decode time - percentile 75: "
<< perf_metrics_.decode_time_stats_.percentile_75_ms_ << "ms"
<< std::endl;
}
void PerformanceEvaluator::WriteMetricsToFile() const {
base::FilePath output_folder_path = base::FilePath(g_env->OutputFolder());
if (!DirectoryExists(output_folder_path))
base::CreateDirectory(output_folder_path);
output_folder_path = base::MakeAbsoluteFilePath(output_folder_path);
// Write performance metrics to json.
base::Value metrics(base::Value::Type::DICTIONARY);
metrics.SetKey(
"FramesDecoded",
base::Value(base::checked_cast<int>(perf_metrics_.frames_decoded_)));
metrics.SetKey("TotalDurationMs",
base::Value(perf_metrics_.total_duration_.InMillisecondsF()));
metrics.SetKey("FPS", base::Value(perf_metrics_.frames_per_second_));
metrics.SetKey(
"FramesDropped",
base::Value(base::checked_cast<int>(perf_metrics_.frames_dropped_)));
metrics.SetKey("DroppedFramePercentage",
base::Value(perf_metrics_.dropped_frame_percentage_));
metrics.SetKey("FrameDeliveryTimeAverage",
base::Value(perf_metrics_.delivery_time_stats_.avg_ms_));
metrics.SetKey(
"FrameDeliveryTimePercentile25",
base::Value(perf_metrics_.delivery_time_stats_.percentile_25_ms_));
metrics.SetKey(
"FrameDeliveryTimePercentile50",
base::Value(perf_metrics_.delivery_time_stats_.percentile_50_ms_));
metrics.SetKey(
"FrameDeliveryTimePercentile75",
base::Value(perf_metrics_.delivery_time_stats_.percentile_75_ms_));
metrics.SetKey("FrameDecodeTimeAverage",
base::Value(perf_metrics_.decode_time_stats_.avg_ms_));
metrics.SetKey(
"FrameDecodeTimePercentile25",
base::Value(perf_metrics_.decode_time_stats_.percentile_25_ms_));
metrics.SetKey(
"FrameDecodeTimePercentile50",
base::Value(perf_metrics_.decode_time_stats_.percentile_50_ms_));
metrics.SetKey(
"FrameDecodeTimePercentile75",
base::Value(perf_metrics_.decode_time_stats_.percentile_75_ms_));
// Write frame delivery times to json.
base::Value delivery_times(base::Value::Type::LIST);
for (double frame_delivery_time : frame_delivery_times_) {
delivery_times.Append(frame_delivery_time);
}
metrics.SetKey("FrameDeliveryTimes", std::move(delivery_times));
// Write frame decodes times to json.
base::Value decode_times(base::Value::Type::LIST);
for (double frame_decode_time : frame_decode_times_) {
decode_times.Append(frame_decode_time);
}
metrics.SetKey("FrameDecodeTimes", std::move(decode_times));
// Write json to file.
std::string metrics_str;
ASSERT_TRUE(base::JSONWriter::WriteWithOptions(
metrics, base::JSONWriter::OPTIONS_PRETTY_PRINT, &metrics_str));
base::FilePath metrics_file_path = output_folder_path.Append(
g_env->GetTestOutputFilePath().AddExtension(FILE_PATH_LITERAL(".json")));
// Make sure that the directory into which json is saved is created.
LOG_ASSERT(base::CreateDirectory(metrics_file_path.DirName()));
base::File metrics_output_file(
base::FilePath(metrics_file_path),
base::File::FLAG_CREATE_ALWAYS | base::File::FLAG_WRITE);
int bytes_written = metrics_output_file.WriteAtCurrentPos(
metrics_str.data(), metrics_str.length());
ASSERT_EQ(bytes_written, static_cast<int>(metrics_str.length()));
VLOG(0) << "Wrote performance metrics to: " << metrics_file_path;
}
// Video decode test class. Performs setup and teardown for each single test.
class VideoDecoderTest : public ::testing::Test {
public:
// Create a new video player instance. |render_frame_rate| is the rate at
// which the video player will simulate rendering frames, if 0 no rendering is
// simulated. The |vsync_rate| is used during simulated rendering, if 0 Vsync
// is disabled.
std::unique_ptr<VideoPlayer> CreateVideoPlayer(const Video* video,
uint32_t render_frame_rate = 0,
uint32_t vsync_rate = 0) {
LOG_ASSERT(video);
// Create dummy frame renderer, simulates rendering at specified frame rate.
base::TimeDelta frame_duration;
base::TimeDelta vsync_interval_duration;
if (render_frame_rate > 0) {
frame_duration = base::TimeDelta::FromSeconds(1) / render_frame_rate;
vsync_interval_duration = base::TimeDelta::FromSeconds(1) / vsync_rate;
}
auto frame_renderer =
FrameRendererDummy::Create(frame_duration, vsync_interval_duration);
std::vector<std::unique_ptr<VideoFrameProcessor>> frame_processors;
auto performance_evaluator =
std::make_unique<PerformanceEvaluator>(frame_renderer.get());
performance_evaluator_ = performance_evaluator.get();
frame_processors.push_back(std::move(performance_evaluator));
// Use the new VD-based video decoders if requested.
VideoDecoderClientConfig config;
config.implementation = g_env->GetDecoderImplementation();
// Force allocate mode if import mode is not supported.
if (!g_env->ImportSupported())
config.allocation_mode = AllocationMode::kAllocate;
auto video_player = VideoPlayer::Create(
config, g_env->GetGpuMemoryBufferFactory(), std::move(frame_renderer),
std::move(frame_processors));
LOG_ASSERT(video_player);
LOG_ASSERT(video_player->Initialize(video));
// Make sure the event timeout is at least as long as the video's duration.
video_player->SetEventWaitTimeout(
std::max(kDefaultEventWaitTimeout, g_env->Video()->GetDuration()));
return video_player;
}
PerformanceEvaluator* performance_evaluator_;
};
} // namespace
// Play video from start to end while measuring uncapped performance. This test
// will decode a video as fast as possible, and gives an idea about the maximum
// output of the decoder.
TEST_F(VideoDecoderTest, MeasureUncappedPerformance) {
auto tvp = CreateVideoPlayer(g_env->Video());
performance_evaluator_->StartMeasuring();
tvp->Play();
EXPECT_TRUE(tvp->WaitForFlushDone());
performance_evaluator_->StopMeasuring();
performance_evaluator_->WriteMetricsToFile();
EXPECT_EQ(tvp->GetFlushDoneCount(), 1u);
EXPECT_EQ(tvp->GetFrameDecodedCount(), g_env->Video()->NumFrames());
}
// Play video from start to end while measuring capped performance. This test
// will simulate rendering the video at its actual frame rate, and will
// calculate the number of frames that were dropped. Vsync is enabled at 60 FPS.
TEST_F(VideoDecoderTest, MeasureCappedPerformance) {
auto tvp = CreateVideoPlayer(g_env->Video(), g_env->Video()->FrameRate(), 60);
performance_evaluator_->StartMeasuring();
tvp->Play();
EXPECT_TRUE(tvp->WaitForFlushDone());
tvp->WaitForRenderer();
performance_evaluator_->StopMeasuring();
performance_evaluator_->WriteMetricsToFile();
EXPECT_EQ(tvp->GetFlushDoneCount(), 1u);
EXPECT_EQ(tvp->GetFrameDecodedCount(), g_env->Video()->NumFrames());
}
} // namespace test
} // namespace media
int main(int argc, char** argv) {
// Set the default test data path.
media::test::Video::SetTestDataPath(media::GetTestDataPath());
// Print the help message if requested. This needs to be done before
// initializing gtest, to overwrite the default gtest help message.
base::CommandLine::Init(argc, argv);
const base::CommandLine* cmd_line = base::CommandLine::ForCurrentProcess();
LOG_ASSERT(cmd_line);
if (cmd_line->HasSwitch("help")) {
std::cout << media::test::usage_msg << "\n" << media::test::help_msg;
return 0;
}
// Check if a video was specified on the command line.
base::CommandLine::StringVector args = cmd_line->GetArgs();
base::FilePath video_path =
(args.size() >= 1) ? base::FilePath(args[0]) : base::FilePath();
base::FilePath video_metadata_path =
(args.size() >= 2) ? base::FilePath(args[1]) : base::FilePath();
// Parse command line arguments.
base::FilePath::StringType output_folder = media::test::kDefaultOutputFolder;
bool use_vd = false;
bool use_vd_vda = false;
media::test::DecoderImplementation implementation =
media::test::DecoderImplementation::kVDA;
base::CommandLine::SwitchMap switches = cmd_line->GetSwitches();
for (base::CommandLine::SwitchMap::const_iterator it = switches.begin();
it != switches.end(); ++it) {
if (it->first.find("gtest_") == 0 || // Handled by GoogleTest
it->first == "v" || it->first == "vmodule") { // Handled by Chrome
continue;
}
if (it->first == "output_folder") {
output_folder = it->second;
} else if (it->first == "use_vd") {
use_vd = true;
implementation = media::test::DecoderImplementation::kVD;
} else if (it->first == "use_vd_vda") {
use_vd_vda = true;
implementation = media::test::DecoderImplementation::kVDVDA;
} else {
std::cout << "unknown option: --" << it->first << "\n"
<< media::test::usage_msg;
return EXIT_FAILURE;
}
}
if (use_vd && use_vd_vda) {
std::cout << "--use_vd and --use_vd_vda cannot be enabled together.\n"
<< media::test::usage_msg;
return EXIT_FAILURE;
}
testing::InitGoogleTest(&argc, argv);
// Set up our test environment.
media::test::VideoPlayerTestEnvironment* test_environment =
media::test::VideoPlayerTestEnvironment::Create(
video_path, video_metadata_path, false, implementation,
base::FilePath(output_folder));
if (!test_environment)
return EXIT_FAILURE;
media::test::g_env = static_cast<media::test::VideoPlayerTestEnvironment*>(
testing::AddGlobalTestEnvironment(test_environment));
return RUN_ALL_TESTS();
}