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a276e731683c673388cf3aeaa1888a5bcc3e1dc0
platform-external-webrtc/webrtc/modules/video_processing/test/video_processing_unittest.cc
Peter Boström e2976c87f7 Remove DISABLED_ON_ macros. 
Macro incorrectly displays DISABLED_ON_ANDROID in test names for
parameterized tests under --gtest_list_tests, causing tests to be
disabled on all platforms since they contain the DISABLED_ prefix rather
than their expanded variants.

This expands the macro variants to inline if they're disabled or not,
and removes building some tests under configurations where they should
fail, instead of building them but disabling them by default.

The change also removes gtest_disable.h as an unused include from many
other files.

BUG=webrtc:5387, webrtc:5400
R=kjellander@webrtc.org, phoglund@webrtc.org
TBR=henrik.lundin@webrtc.org

Review URL: https://codereview.webrtc.org/1547343002 .

Cr-Commit-Position: refs/heads/master@{#11150}
2016-01-04 21:44:16 +00:00

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/*
* 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/modules/video_processing/test/video_processing_unittest.h"
#include <gflags/gflags.h>
#include <string>
#include "webrtc/common_video/libyuv/include/webrtc_libyuv.h"
#include "webrtc/system_wrappers/include/tick_util.h"
#include "webrtc/test/testsupport/fileutils.h"
namespace webrtc {
namespace {
// Define command line flag 'gen_files' (default value: false).
DEFINE_bool(gen_files, false, "Output files for visual inspection.");
} // namespace
static void PreprocessFrameAndVerify(const VideoFrame& source,
int target_width,
int target_height,
VideoProcessing* vpm,
const VideoFrame* out_frame);
static void CropFrame(const uint8_t* source_data,
int source_width,
int source_height,
int offset_x,
int offset_y,
int cropped_width,
int cropped_height,
VideoFrame* cropped_frame);
// The |source_data| is cropped and scaled to |target_width| x |target_height|,
// and then scaled back to the expected cropped size. |expected_psnr| is used to
// verify basic quality, and is set to be ~0.1/0.05dB lower than actual PSNR
// verified under the same conditions.
static void TestSize(const VideoFrame& source_frame,
const VideoFrame& cropped_source_frame,
int target_width,
int target_height,
double expected_psnr,
VideoProcessing* vpm);
static bool CompareFrames(const webrtc::VideoFrame& frame1,
const webrtc::VideoFrame& frame2);
static void WriteProcessedFrameForVisualInspection(const VideoFrame& source,
const VideoFrame& processed);
VideoProcessingTest::VideoProcessingTest()
: vp_(NULL),
source_file_(NULL),
width_(352),
half_width_((width_ + 1) / 2),
height_(288),
size_y_(width_ * height_),
size_uv_(half_width_ * ((height_ + 1) / 2)),
frame_length_(CalcBufferSize(kI420, width_, height_)) {}
void VideoProcessingTest::SetUp() {
vp_ = VideoProcessing::Create();
ASSERT_TRUE(vp_ != NULL);
ASSERT_EQ(0, video_frame_.CreateEmptyFrame(width_, height_, width_,
half_width_, half_width_));
// Clear video frame so DrMemory/Valgrind will allow reads of the buffer.
memset(video_frame_.buffer(kYPlane), 0, video_frame_.allocated_size(kYPlane));
memset(video_frame_.buffer(kUPlane), 0, video_frame_.allocated_size(kUPlane));
memset(video_frame_.buffer(kVPlane), 0, video_frame_.allocated_size(kVPlane));
const std::string video_file =
webrtc::test::ResourcePath("foreman_cif", "yuv");
source_file_ = fopen(video_file.c_str(), "rb");
ASSERT_TRUE(source_file_ != NULL)
<< "Cannot read source file: " + video_file + "\n";
}
void VideoProcessingTest::TearDown() {
if (source_file_ != NULL) {
ASSERT_EQ(0, fclose(source_file_));
}
source_file_ = NULL;
delete vp_;
vp_ = NULL;
}
#if defined(WEBRTC_IOS)
TEST_F(VideoProcessingTest, DISABLED_HandleNullBuffer) {
#else
TEST_F(VideoProcessingTest, HandleNullBuffer) {
#endif
// TODO(mikhal/stefan): Do we need this one?
VideoProcessing::FrameStats stats;
// Video frame with unallocated buffer.
VideoFrame videoFrame;
vp_->GetFrameStats(videoFrame, &stats);
EXPECT_EQ(stats.num_pixels, 0u);
EXPECT_EQ(-1, vp_->Deflickering(&videoFrame, &stats));
EXPECT_EQ(-3, vp_->BrightnessDetection(videoFrame, stats));
}
#if defined(WEBRTC_IOS)
TEST_F(VideoProcessingTest, DISABLED_HandleBadStats) {
#else
TEST_F(VideoProcessingTest, HandleBadStats) {
#endif
VideoProcessing::FrameStats stats;
vp_->ClearFrameStats(&stats);
rtc::scoped_ptr<uint8_t[]> video_buffer(new uint8_t[frame_length_]);
ASSERT_EQ(frame_length_,
fread(video_buffer.get(), 1, frame_length_, source_file_));
EXPECT_EQ(0, ConvertToI420(kI420, video_buffer.get(), 0, 0, width_, height_,
0, kVideoRotation_0, &video_frame_));
EXPECT_EQ(-1, vp_->Deflickering(&video_frame_, &stats));
EXPECT_EQ(-3, vp_->BrightnessDetection(video_frame_, stats));
}
#if defined(WEBRTC_IOS)
TEST_F(VideoProcessingTest, DISABLED_IdenticalResultsAfterReset) {
#else
TEST_F(VideoProcessingTest, IdenticalResultsAfterReset) {
#endif
VideoFrame video_frame2;
VideoProcessing::FrameStats stats;
// Only testing non-static functions here.
rtc::scoped_ptr<uint8_t[]> video_buffer(new uint8_t[frame_length_]);
ASSERT_EQ(frame_length_,
fread(video_buffer.get(), 1, frame_length_, source_file_));
EXPECT_EQ(0, ConvertToI420(kI420, video_buffer.get(), 0, 0, width_, height_,
0, kVideoRotation_0, &video_frame_));
vp_->GetFrameStats(video_frame_, &stats);
EXPECT_GT(stats.num_pixels, 0u);
ASSERT_EQ(0, video_frame2.CopyFrame(video_frame_));
ASSERT_EQ(0, vp_->Deflickering(&video_frame_, &stats));
// Retrieve frame stats again in case Deflickering() has zeroed them.
vp_->GetFrameStats(video_frame2, &stats);
EXPECT_GT(stats.num_pixels, 0u);
ASSERT_EQ(0, vp_->Deflickering(&video_frame2, &stats));
EXPECT_TRUE(CompareFrames(video_frame_, video_frame2));
ASSERT_EQ(frame_length_,
fread(video_buffer.get(), 1, frame_length_, source_file_));
EXPECT_EQ(0, ConvertToI420(kI420, video_buffer.get(), 0, 0, width_, height_,
0, kVideoRotation_0, &video_frame_));
vp_->GetFrameStats(video_frame_, &stats);
EXPECT_GT(stats.num_pixels, 0u);
video_frame2.CopyFrame(video_frame_);
ASSERT_EQ(0, vp_->BrightnessDetection(video_frame_, stats));
ASSERT_EQ(0, vp_->BrightnessDetection(video_frame2, stats));
EXPECT_TRUE(CompareFrames(video_frame_, video_frame2));
}
#if defined(WEBRTC_IOS)
TEST_F(VideoProcessingTest, DISABLED_FrameStats) {
#else
TEST_F(VideoProcessingTest, FrameStats) {
#endif
VideoProcessing::FrameStats stats;
vp_->ClearFrameStats(&stats);
rtc::scoped_ptr<uint8_t[]> video_buffer(new uint8_t[frame_length_]);
ASSERT_EQ(frame_length_,
fread(video_buffer.get(), 1, frame_length_, source_file_));
EXPECT_EQ(0, ConvertToI420(kI420, video_buffer.get(), 0, 0, width_, height_,
0, kVideoRotation_0, &video_frame_));
EXPECT_FALSE(vp_->ValidFrameStats(stats));
vp_->GetFrameStats(video_frame_, &stats);
EXPECT_GT(stats.num_pixels, 0u);
EXPECT_TRUE(vp_->ValidFrameStats(stats));
printf("\nFrameStats\n");
printf("mean: %u\nnum_pixels: %u\nsubSamplFactor: %u\nsum: %u\n\n",
static_cast<unsigned int>(stats.mean),
static_cast<unsigned int>(stats.num_pixels),
static_cast<unsigned int>(stats.sub_sampling_factor),
static_cast<unsigned int>(stats.sum));
vp_->ClearFrameStats(&stats);
EXPECT_FALSE(vp_->ValidFrameStats(stats));
}
#if defined(WEBRTC_IOS)
TEST_F(VideoProcessingTest, DISABLED_PreprocessorLogic) {
#else
TEST_F(VideoProcessingTest, PreprocessorLogic) {
#endif
// Disable temporal sampling (frame dropping).
vp_->EnableTemporalDecimation(false);
int resolution = 100;
EXPECT_EQ(VPM_OK, vp_->SetTargetResolution(resolution, resolution, 15));
EXPECT_EQ(VPM_OK, vp_->SetTargetResolution(resolution, resolution, 30));
// Disable spatial sampling.
vp_->SetInputFrameResampleMode(kNoRescaling);
EXPECT_EQ(VPM_OK, vp_->SetTargetResolution(resolution, resolution, 30));
VideoFrame* out_frame = NULL;
// Set rescaling => output frame != NULL.
vp_->SetInputFrameResampleMode(kFastRescaling);
PreprocessFrameAndVerify(video_frame_, resolution, resolution, vp_,
out_frame);
// No rescaling=> output frame = NULL.
vp_->SetInputFrameResampleMode(kNoRescaling);
EXPECT_TRUE(vp_->PreprocessFrame(video_frame_) != nullptr);
}
#if defined(WEBRTC_IOS)
TEST_F(VideoProcessingTest, DISABLED_Resampler) {
#else
TEST_F(VideoProcessingTest, Resampler) {
#endif
enum { NumRuns = 1 };
int64_t min_runtime = 0;
int64_t total_runtime = 0;
rewind(source_file_);
ASSERT_TRUE(source_file_ != NULL) << "Cannot read input file \n";
// CA not needed here
vp_->EnableContentAnalysis(false);
// no temporal decimation
vp_->EnableTemporalDecimation(false);
// Reading test frame
rtc::scoped_ptr<uint8_t[]> video_buffer(new uint8_t[frame_length_]);
ASSERT_EQ(frame_length_,
fread(video_buffer.get(), 1, frame_length_, source_file_));
// Using ConvertToI420 to add stride to the image.
EXPECT_EQ(0, ConvertToI420(kI420, video_buffer.get(), 0, 0, width_, height_,
0, kVideoRotation_0, &video_frame_));
// Cropped source frame that will contain the expected visible region.
VideoFrame cropped_source_frame;
cropped_source_frame.CopyFrame(video_frame_);
for (uint32_t run_idx = 0; run_idx < NumRuns; run_idx++) {
// Initiate test timer.
const TickTime time_start = TickTime::Now();
// Init the sourceFrame with a timestamp.
video_frame_.set_render_time_ms(time_start.MillisecondTimestamp());
video_frame_.set_timestamp(time_start.MillisecondTimestamp() * 90);
// Test scaling to different sizes: source is of |width|/|height| = 352/288.
// Pure scaling:
TestSize(video_frame_, video_frame_, width_ / 4, height_ / 4, 25.2, vp_);
TestSize(video_frame_, video_frame_, width_ / 2, height_ / 2, 28.1, vp_);
// No resampling:
TestSize(video_frame_, video_frame_, width_, height_, -1, vp_);
TestSize(video_frame_, video_frame_, 2 * width_, 2 * height_, 32.2, vp_);
// Scaling and cropping. The cropped source frame is the largest center
// aligned region that can be used from the source while preserving aspect
// ratio.
CropFrame(video_buffer.get(), width_, height_, 0, 56, 352, 176,
&cropped_source_frame);
TestSize(video_frame_, cropped_source_frame, 100, 50, 24.0, vp_);
CropFrame(video_buffer.get(), width_, height_, 0, 30, 352, 225,
&cropped_source_frame);
TestSize(video_frame_, cropped_source_frame, 400, 256, 31.3, vp_);
CropFrame(video_buffer.get(), width_, height_, 68, 0, 216, 288,
&cropped_source_frame);
TestSize(video_frame_, cropped_source_frame, 480, 640, 32.15, vp_);
CropFrame(video_buffer.get(), width_, height_, 0, 12, 352, 264,
&cropped_source_frame);
TestSize(video_frame_, cropped_source_frame, 960, 720, 32.2, vp_);
CropFrame(video_buffer.get(), width_, height_, 0, 44, 352, 198,
&cropped_source_frame);
TestSize(video_frame_, cropped_source_frame, 1280, 720, 32.15, vp_);
// Upsampling to odd size.
CropFrame(video_buffer.get(), width_, height_, 0, 26, 352, 233,
&cropped_source_frame);
TestSize(video_frame_, cropped_source_frame, 501, 333, 32.05, vp_);
// Downsample to odd size.
CropFrame(video_buffer.get(), width_, height_, 0, 34, 352, 219,
&cropped_source_frame);
TestSize(video_frame_, cropped_source_frame, 281, 175, 29.3, vp_);
// Stop timer.
const int64_t runtime = (TickTime::Now() - time_start).Microseconds();
if (runtime < min_runtime || run_idx == 0) {
min_runtime = runtime;
}
total_runtime += runtime;
}
printf("\nAverage run time = %d us / frame\n",
static_cast<int>(total_runtime));
printf("Min run time = %d us / frame\n\n", static_cast<int>(min_runtime));
}
void PreprocessFrameAndVerify(const VideoFrame& source,
int target_width,
int target_height,
VideoProcessing* vpm,
const VideoFrame* out_frame) {
ASSERT_EQ(VPM_OK, vpm->SetTargetResolution(target_width, target_height, 30));
out_frame = vpm->PreprocessFrame(source);
EXPECT_TRUE(out_frame != nullptr);
// If no resizing is needed, expect the original frame.
if (target_width == source.width() && target_height == source.height()) {
EXPECT_EQ(&source, out_frame);
return;
}
// Verify the resampled frame.
EXPECT_TRUE(out_frame != NULL);
EXPECT_EQ(source.render_time_ms(), (out_frame)->render_time_ms());
EXPECT_EQ(source.timestamp(), (out_frame)->timestamp());
EXPECT_EQ(target_width, (out_frame)->width());
EXPECT_EQ(target_height, (out_frame)->height());
}
void CropFrame(const uint8_t* source_data,
int source_width,
int source_height,
int offset_x,
int offset_y,
int cropped_width,
int cropped_height,
VideoFrame* cropped_frame) {
cropped_frame->CreateEmptyFrame(cropped_width, cropped_height, cropped_width,
(cropped_width + 1) / 2,
(cropped_width + 1) / 2);
EXPECT_EQ(0,
ConvertToI420(kI420, source_data, offset_x, offset_y, source_width,
source_height, 0, kVideoRotation_0, cropped_frame));
}
void TestSize(const VideoFrame& source_frame,
const VideoFrame& cropped_source_frame,
int target_width,
int target_height,
double expected_psnr,
VideoProcessing* vpm) {
// Resample source_frame to out_frame.
VideoFrame* out_frame = NULL;
vpm->SetInputFrameResampleMode(kBox);
PreprocessFrameAndVerify(source_frame, target_width, target_height, vpm,
out_frame);
if (out_frame == NULL)
return;
WriteProcessedFrameForVisualInspection(source_frame, *out_frame);
// Scale |resampled_source_frame| back to the source scale.
VideoFrame resampled_source_frame;
resampled_source_frame.CopyFrame(*out_frame);
PreprocessFrameAndVerify(resampled_source_frame, cropped_source_frame.width(),
cropped_source_frame.height(), vpm, out_frame);
WriteProcessedFrameForVisualInspection(resampled_source_frame, *out_frame);
// Compute PSNR against the cropped source frame and check expectation.
double psnr = I420PSNR(&cropped_source_frame, out_frame);
EXPECT_GT(psnr, expected_psnr);
printf(
"PSNR: %f. PSNR is between source of size %d %d, and a modified "
"source which is scaled down/up to: %d %d, and back to source size \n",
psnr, source_frame.width(), source_frame.height(), target_width,
target_height);
}
bool CompareFrames(const webrtc::VideoFrame& frame1,
const webrtc::VideoFrame& frame2) {
for (int plane = 0; plane < webrtc::kNumOfPlanes; plane++) {
webrtc::PlaneType plane_type = static_cast<webrtc::PlaneType>(plane);
int allocated_size1 = frame1.allocated_size(plane_type);
int allocated_size2 = frame2.allocated_size(plane_type);
if (allocated_size1 != allocated_size2)
return false;
const uint8_t* plane_buffer1 = frame1.buffer(plane_type);
const uint8_t* plane_buffer2 = frame2.buffer(plane_type);
if (memcmp(plane_buffer1, plane_buffer2, allocated_size1))
return false;
}
return true;
}
void WriteProcessedFrameForVisualInspection(const VideoFrame& source,
const VideoFrame& processed) {
// Skip if writing to files is not enabled.
if (!FLAGS_gen_files)
return;
// Write the processed frame to file for visual inspection.
std::ostringstream filename;
filename << webrtc::test::OutputPath() << "Resampler_from_" << source.width()
<< "x" << source.height() << "_to_" << processed.width() << "x"
<< processed.height() << "_30Hz_P420.yuv";
std::cout << "Watch " << filename.str() << " and verify that it is okay."
<< std::endl;
FILE* stand_alone_file = fopen(filename.str().c_str(), "wb");
if (PrintVideoFrame(processed, stand_alone_file) < 0)
std::cerr << "Failed to write: " << filename.str() << std::endl;
if (stand_alone_file)
fclose(stand_alone_file);
}
} // namespace webrtc
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