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webrtc / src / refs/heads/main / . / modules / video_coding / codecs / vp8 / test / vp8_impl_unittest.cc
blob: 8c03148157756105b7242e56ac2057a54341d5b8 [file] [log] [blame]
/*
* 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 <stdio.h>
#include <algorithm>
#include <memory>
#include "absl/memory/memory.h"
#include "api/environment/environment_factory.h"
#include "api/test/create_frame_generator.h"
#include "api/test/frame_generator_interface.h"
#include "api/test/mock_video_decoder.h"
#include "api/test/mock_video_encoder.h"
#include "api/video_codecs/video_encoder.h"
#include "api/video_codecs/vp8_temporal_layers.h"
#include "common_video/libyuv/include/webrtc_libyuv.h"
#include "common_video/test/utilities.h"
#include "modules/video_coding/codecs/interface/mock_libvpx_interface.h"
#include "modules/video_coding/codecs/test/video_codec_unittest.h"
#include "modules/video_coding/codecs/vp8/include/vp8.h"
#include "modules/video_coding/codecs/vp8/libvpx_vp8_encoder.h"
#include "modules/video_coding/utility/vp8_header_parser.h"
#include "rtc_base/time_utils.h"
#include "test/field_trial.h"
#include "test/mappable_native_buffer.h"
#include "test/scoped_key_value_config.h"
#include "test/video_codec_settings.h"
namespace webrtc {
using ::testing::_;
using ::testing::AllOf;
using ::testing::ElementsAre;
using ::testing::ElementsAreArray;
using ::testing::Field;
using ::testing::Invoke;
using ::testing::NiceMock;
using ::testing::Return;
using EncoderInfo = webrtc::VideoEncoder::EncoderInfo;
using FramerateFractions =
absl::InlinedVector<uint8_t, webrtc::kMaxTemporalStreams>;
namespace {
constexpr uint32_t kLegacyScreenshareTl0BitrateKbps = 200;
constexpr uint32_t kLegacyScreenshareTl1BitrateKbps = 1000;
constexpr uint32_t kInitialTimestampRtp = 123;
constexpr int64_t kTestNtpTimeMs = 456;
constexpr int64_t kInitialTimestampMs = 789;
constexpr int kNumCores = 1;
constexpr size_t kMaxPayloadSize = 1440;
constexpr int kWidth = 172;
constexpr int kHeight = 144;
constexpr float kFramerateFps = 30;
const VideoEncoder::Capabilities kCapabilities(false);
const VideoEncoder::Settings kSettings(kCapabilities,
kNumCores,
kMaxPayloadSize);
} // namespace
class TestVp8Impl : public VideoCodecUnitTest {
protected:
std::unique_ptr<VideoEncoder> CreateEncoder() override {
return CreateVp8Encoder(env_);
}
std::unique_ptr<VideoDecoder> CreateDecoder() override {
return CreateVp8Decoder(env_);
}
void ModifyCodecSettings(VideoCodec* codec_settings) override {
webrtc::test::CodecSettings(kVideoCodecVP8, codec_settings);
codec_settings->width = kWidth;
codec_settings->height = kHeight;
codec_settings->SetVideoEncoderComplexity(
VideoCodecComplexity::kComplexityNormal);
}
void EncodeAndWaitForFrame(const VideoFrame& input_frame,
EncodedImage* encoded_frame,
CodecSpecificInfo* codec_specific_info,
bool keyframe = false) {
std::vector<VideoFrameType> frame_types;
if (keyframe) {
frame_types.emplace_back(VideoFrameType::kVideoFrameKey);
} else {
frame_types.emplace_back(VideoFrameType::kVideoFrameDelta);
}
EXPECT_EQ(WEBRTC_VIDEO_CODEC_OK,
encoder_->Encode(input_frame, &frame_types));
ASSERT_TRUE(WaitForEncodedFrame(encoded_frame, codec_specific_info));
VerifyQpParser(*encoded_frame);
EXPECT_EQ(kVideoCodecVP8, codec_specific_info->codecType);
EXPECT_EQ(0, encoded_frame->SimulcastIndex());
}
void EncodeAndExpectFrameWith(const VideoFrame& input_frame,
uint8_t temporal_idx,
bool keyframe = false) {
EncodedImage encoded_frame;
CodecSpecificInfo codec_specific_info;
EncodeAndWaitForFrame(input_frame, &encoded_frame, &codec_specific_info,
keyframe);
EXPECT_EQ(temporal_idx, codec_specific_info.codecSpecific.VP8.temporalIdx);
}
void VerifyQpParser(const EncodedImage& encoded_frame) const {
int qp;
EXPECT_GT(encoded_frame.size(), 0u);
ASSERT_TRUE(vp8::GetQp(encoded_frame.data(), encoded_frame.size(), &qp));
EXPECT_EQ(encoded_frame.qp_, qp) << "Encoder QP != parsed bitstream QP.";
}
};
TEST_F(TestVp8Impl, ErrorResilienceDisabledForNoTemporalLayers) {
codec_settings_.simulcastStream[0].numberOfTemporalLayers = 1;
auto* const vpx = new NiceMock<MockLibvpxInterface>();
LibvpxVp8Encoder encoder(CreateEnvironment(), {}, absl::WrapUnique(vpx));
EXPECT_CALL(*vpx,
codec_enc_init(
_, _, Field(&vpx_codec_enc_cfg_t::g_error_resilient, 0), _));
EXPECT_EQ(WEBRTC_VIDEO_CODEC_OK,
encoder.InitEncode(&codec_settings_, kSettings));
}
TEST_F(TestVp8Impl, DefaultErrorResilienceEnabledForTemporalLayers) {
codec_settings_.simulcastStream[0].numberOfTemporalLayers = 2;
codec_settings_.VP8()->numberOfTemporalLayers = 2;
auto* const vpx = new NiceMock<MockLibvpxInterface>();
LibvpxVp8Encoder encoder(CreateEnvironment(), {}, absl::WrapUnique(vpx));
EXPECT_CALL(*vpx,
codec_enc_init(_, _,
Field(&vpx_codec_enc_cfg_t::g_error_resilient,
VPX_ERROR_RESILIENT_DEFAULT),
_));
EXPECT_EQ(WEBRTC_VIDEO_CODEC_OK,
encoder.InitEncode(&codec_settings_, kSettings));
}
TEST_F(TestVp8Impl,
PartitionErrorResilienceEnabledForTemporalLayersWithFieldTrial) {
test::ScopedFieldTrials field_trials(
"WebRTC-VP8-ForcePartitionResilience/Enabled/");
codec_settings_.simulcastStream[0].numberOfTemporalLayers = 2;
codec_settings_.VP8()->numberOfTemporalLayers = 2;
auto* const vpx = new NiceMock<MockLibvpxInterface>();
LibvpxVp8Encoder encoder(CreateEnvironment(), {}, absl::WrapUnique(vpx));
EXPECT_CALL(*vpx,
codec_enc_init(_, _,
Field(&vpx_codec_enc_cfg_t::g_error_resilient,
VPX_ERROR_RESILIENT_PARTITIONS),
_));
EXPECT_EQ(WEBRTC_VIDEO_CODEC_OK,
encoder.InitEncode(&codec_settings_, kSettings));
}
TEST_F(TestVp8Impl, SetRates) {
codec_settings_.SetFrameDropEnabled(true);
auto* const vpx = new NiceMock<MockLibvpxInterface>();
LibvpxVp8Encoder encoder(CreateEnvironment(), {}, absl::WrapUnique(vpx));
EXPECT_EQ(WEBRTC_VIDEO_CODEC_OK,
encoder.InitEncode(&codec_settings_,
VideoEncoder::Settings(kCapabilities, 1, 1000)));
const uint32_t kBitrateBps = 300000;
VideoBitrateAllocation bitrate_allocation;
bitrate_allocation.SetBitrate(0, 0, kBitrateBps);
EXPECT_CALL(
*vpx,
codec_enc_config_set(
_, AllOf(Field(&vpx_codec_enc_cfg_t::rc_target_bitrate,
kBitrateBps / 1000),
Field(&vpx_codec_enc_cfg_t::rc_undershoot_pct, 100u),
Field(&vpx_codec_enc_cfg_t::rc_overshoot_pct, 15u),
Field(&vpx_codec_enc_cfg_t::rc_buf_sz, 1000u),
Field(&vpx_codec_enc_cfg_t::rc_buf_optimal_sz, 600u),
Field(&vpx_codec_enc_cfg_t::rc_dropframe_thresh, 30u))))
.WillOnce(Return(VPX_CODEC_OK));
encoder.SetRates(VideoEncoder::RateControlParameters(
bitrate_allocation, static_cast<double>(codec_settings_.maxFramerate)));
}
TEST_F(TestVp8Impl, EncodeFrameAndRelease) {
EXPECT_EQ(WEBRTC_VIDEO_CODEC_OK, encoder_->Release());
EXPECT_EQ(WEBRTC_VIDEO_CODEC_OK,
encoder_->InitEncode(&codec_settings_, kSettings));
EncodedImage encoded_frame;
CodecSpecificInfo codec_specific_info;
EncodeAndWaitForFrame(NextInputFrame(), &encoded_frame, &codec_specific_info);
EXPECT_EQ(WEBRTC_VIDEO_CODEC_OK, encoder_->Release());
EXPECT_EQ(WEBRTC_VIDEO_CODEC_UNINITIALIZED,
encoder_->Encode(NextInputFrame(), nullptr));
}
TEST_F(TestVp8Impl, EncodeNv12FrameSimulcast) {
EXPECT_EQ(WEBRTC_VIDEO_CODEC_OK, encoder_->Release());
EXPECT_EQ(WEBRTC_VIDEO_CODEC_OK,
encoder_->InitEncode(&codec_settings_, kSettings));
EncodedImage encoded_frame;
CodecSpecificInfo codec_specific_info;
input_frame_generator_ = test::CreateSquareFrameGenerator(
kWidth, kHeight, test::FrameGeneratorInterface::OutputType::kNV12,
absl::nullopt);
EncodeAndWaitForFrame(NextInputFrame(), &encoded_frame, &codec_specific_info);
EXPECT_EQ(WEBRTC_VIDEO_CODEC_OK, encoder_->Release());
EXPECT_EQ(WEBRTC_VIDEO_CODEC_UNINITIALIZED,
encoder_->Encode(NextInputFrame(), nullptr));
}
TEST_F(TestVp8Impl, EncodeI420FrameAfterNv12Frame) {
EXPECT_EQ(WEBRTC_VIDEO_CODEC_OK, encoder_->Release());
EXPECT_EQ(WEBRTC_VIDEO_CODEC_OK,
encoder_->InitEncode(&codec_settings_, kSettings));
EncodedImage encoded_frame;
CodecSpecificInfo codec_specific_info;
input_frame_generator_ = test::CreateSquareFrameGenerator(
kWidth, kHeight, test::FrameGeneratorInterface::OutputType::kNV12,
absl::nullopt);
EncodeAndWaitForFrame(NextInputFrame(), &encoded_frame, &codec_specific_info);
input_frame_generator_ = test::CreateSquareFrameGenerator(
kWidth, kHeight, test::FrameGeneratorInterface::OutputType::kI420,
absl::nullopt);
EncodeAndWaitForFrame(NextInputFrame(), &encoded_frame, &codec_specific_info);
EXPECT_EQ(WEBRTC_VIDEO_CODEC_OK, encoder_->Release());
EXPECT_EQ(WEBRTC_VIDEO_CODEC_UNINITIALIZED,
encoder_->Encode(NextInputFrame(), nullptr));
}
TEST_F(TestVp8Impl, Configure) {
EXPECT_EQ(WEBRTC_VIDEO_CODEC_OK, decoder_->Release());
EXPECT_TRUE(decoder_->Configure({}));
}
TEST_F(TestVp8Impl, OnEncodedImageReportsInfo) {
constexpr Timestamp kCaptureTimeIdentifier = Timestamp::Micros(1000);
VideoFrame input_frame = NextInputFrame();
input_frame.set_rtp_timestamp(kInitialTimestampRtp);
input_frame.set_timestamp_us(kInitialTimestampMs *
rtc::kNumMicrosecsPerMillisec);
input_frame.set_capture_time_identifier(kCaptureTimeIdentifier);
EncodedImage encoded_frame;
CodecSpecificInfo codec_specific_info;
EncodeAndWaitForFrame(input_frame, &encoded_frame, &codec_specific_info);
EXPECT_EQ(kInitialTimestampRtp, encoded_frame.RtpTimestamp());
EXPECT_EQ(kWidth, static_cast<int>(encoded_frame._encodedWidth));
EXPECT_EQ(kHeight, static_cast<int>(encoded_frame._encodedHeight));
ASSERT_TRUE(encoded_frame.CaptureTimeIdentifier().has_value());
EXPECT_EQ(kCaptureTimeIdentifier.us(),
encoded_frame.CaptureTimeIdentifier()->us());
}
TEST_F(TestVp8Impl,
EncoderFillsResolutionInCodecAgnosticSectionOfCodecSpecificInfo) {
EncodedImage encoded_frame;
CodecSpecificInfo codec_specific_info;
EncodeAndWaitForFrame(NextInputFrame(), &encoded_frame, &codec_specific_info);
ASSERT_TRUE(codec_specific_info.template_structure);
EXPECT_THAT(codec_specific_info.template_structure->resolutions,
ElementsAre(RenderResolution(kWidth, kHeight)));
}
TEST_F(TestVp8Impl, DecodedQpEqualsEncodedQp) {
VideoFrame input_frame = NextInputFrame();
EncodedImage encoded_frame;
CodecSpecificInfo codec_specific_info;
EncodeAndWaitForFrame(input_frame, &encoded_frame, &codec_specific_info);
// First frame should be a key frame.
encoded_frame._frameType = VideoFrameType::kVideoFrameKey;
EXPECT_EQ(WEBRTC_VIDEO_CODEC_OK, decoder_->Decode(encoded_frame, -1));
std::unique_ptr<VideoFrame> decoded_frame;
absl::optional<uint8_t> decoded_qp;
ASSERT_TRUE(WaitForDecodedFrame(&decoded_frame, &decoded_qp));
ASSERT_TRUE(decoded_frame);
ASSERT_TRUE(decoded_qp);
EXPECT_GT(I420PSNR(&input_frame, decoded_frame.get()), 36);
EXPECT_EQ(encoded_frame.qp_, *decoded_qp);
}
TEST_F(TestVp8Impl, ChecksSimulcastSettings) {
codec_settings_.numberOfSimulcastStreams = 2;
// Resolutions are not in ascending order, temporal layers do not match.
codec_settings_.simulcastStream[0] = {.width = kWidth,
.height = kHeight,
.maxFramerate = kFramerateFps,
.numberOfTemporalLayers = 2,
.maxBitrate = 4000,
.targetBitrate = 3000,
.minBitrate = 2000,
.qpMax = 80};
codec_settings_.simulcastStream[1] = {.width = kWidth / 2,
.height = kHeight / 2,
.maxFramerate = 30,
.numberOfTemporalLayers = 3,
.maxBitrate = 4000,
.targetBitrate = 3000,
.minBitrate = 2000,
.qpMax = 80};
EXPECT_EQ(WEBRTC_VIDEO_CODEC_ERR_SIMULCAST_PARAMETERS_NOT_SUPPORTED,
encoder_->InitEncode(&codec_settings_, kSettings));
codec_settings_.numberOfSimulcastStreams = 3;
// Resolutions are not in ascending order.
codec_settings_.simulcastStream[0] = {.width = kWidth / 2,
.height = kHeight / 2,
.maxFramerate = kFramerateFps,
.numberOfTemporalLayers = 1,
.maxBitrate = 4000,
.targetBitrate = 3000,
.minBitrate = 2000,
.qpMax = 80};
codec_settings_.simulcastStream[1] = {.width = kWidth / 2 - 1,
.height = kHeight / 2 - 1,
.maxFramerate = kFramerateFps,
.numberOfTemporalLayers = 1,
.maxBitrate = 4000,
.targetBitrate = 3000,
.minBitrate = 2000,
.qpMax = 80};
codec_settings_.simulcastStream[2] = {.width = kWidth,
.height = kHeight,
.maxFramerate = 30,
.numberOfTemporalLayers = 1,
.maxBitrate = 4000,
.targetBitrate = 3000,
.minBitrate = 2000,
.qpMax = 80};
EXPECT_EQ(WEBRTC_VIDEO_CODEC_ERR_SIMULCAST_PARAMETERS_NOT_SUPPORTED,
encoder_->InitEncode(&codec_settings_, kSettings));
// Resolutions are not in ascending order.
codec_settings_.simulcastStream[0] = {.width = kWidth,
.height = kHeight,
.maxFramerate = kFramerateFps,
.numberOfTemporalLayers = 1,
.maxBitrate = 4000,
.targetBitrate = 3000,
.minBitrate = 2000,
.qpMax = 80};
codec_settings_.simulcastStream[1] = {.width = kWidth,
.height = kHeight,
.maxFramerate = kFramerateFps,
.numberOfTemporalLayers = 1,
.maxBitrate = 4000,
.targetBitrate = 3000,
.minBitrate = 2000,
.qpMax = 80};
codec_settings_.simulcastStream[2] = {.width = kWidth - 1,
.height = kHeight - 1,
.maxFramerate = kFramerateFps,
.numberOfTemporalLayers = 1,
.maxBitrate = 4000,
.targetBitrate = 3000,
.minBitrate = 2000,
.qpMax = 80};
EXPECT_EQ(WEBRTC_VIDEO_CODEC_ERR_SIMULCAST_PARAMETERS_NOT_SUPPORTED,
encoder_->InitEncode(&codec_settings_, kSettings));
// Temporal layers do not match.
codec_settings_.simulcastStream[0] = {.width = kWidth / 4,
.height = kHeight / 4,
.maxFramerate = kFramerateFps,
.numberOfTemporalLayers = 1,
.maxBitrate = 4000,
.targetBitrate = 3000,
.minBitrate = 2000,
.qpMax = 80};
codec_settings_.simulcastStream[1] = {.width = kWidth / 2,
.height = kHeight / 2,
.maxFramerate = kFramerateFps,
.numberOfTemporalLayers = 2,
.maxBitrate = 4000,
.targetBitrate = 3000,
.minBitrate = 2000,
.qpMax = 80};
codec_settings_.simulcastStream[2] = {.width = kWidth,
.height = kHeight,
.maxFramerate = kFramerateFps,
.numberOfTemporalLayers = 3,
.maxBitrate = 4000,
.targetBitrate = 3000,
.minBitrate = 2000,
.qpMax = 80};
EXPECT_EQ(WEBRTC_VIDEO_CODEC_ERR_SIMULCAST_PARAMETERS_NOT_SUPPORTED,
encoder_->InitEncode(&codec_settings_, kSettings));
// Resolutions do not match codec config.
codec_settings_.simulcastStream[0] = {.width = kWidth / 4 + 1,
.height = kHeight / 4 + 1,
.maxFramerate = kFramerateFps,
.numberOfTemporalLayers = 1,
.maxBitrate = 4000,
.targetBitrate = 3000,
.minBitrate = 2000,
.qpMax = 80};
codec_settings_.simulcastStream[1] = {.width = kWidth / 2 + 2,
.height = kHeight / 2 + 2,
.maxFramerate = kFramerateFps,
.numberOfTemporalLayers = 1,
.maxBitrate = 4000,
.targetBitrate = 3000,
.minBitrate = 2000,
.qpMax = 80};
codec_settings_.simulcastStream[2] = {.width = kWidth + 4,
.height = kHeight + 4,
.maxFramerate = kFramerateFps,
.numberOfTemporalLayers = 1,
.maxBitrate = 4000,
.targetBitrate = 3000,
.minBitrate = 2000,
.qpMax = 80};
EXPECT_EQ(WEBRTC_VIDEO_CODEC_ERR_SIMULCAST_PARAMETERS_NOT_SUPPORTED,
encoder_->InitEncode(&codec_settings_, kSettings));
// Everything fine: scaling by 2, top resolution matches video, temporal
// settings are the same for all layers.
codec_settings_.simulcastStream[0] = {.width = kWidth / 4,
.height = kHeight / 4,
.maxFramerate = kFramerateFps,
.numberOfTemporalLayers = 1,
.maxBitrate = 4000,
.targetBitrate = 3000,
.minBitrate = 2000,
.qpMax = 80};
codec_settings_.simulcastStream[1] = {.width = kWidth / 2,
.height = kHeight / 2,
.maxFramerate = kFramerateFps,
.numberOfTemporalLayers = 1,
.maxBitrate = 4000,
.targetBitrate = 3000,
.minBitrate = 2000,
.qpMax = 80};
codec_settings_.simulcastStream[2] = {.width = kWidth,
.height = kHeight,
.maxFramerate = kFramerateFps,
.numberOfTemporalLayers = 1,
.maxBitrate = 4000,
.targetBitrate = 3000,
.minBitrate = 2000,
.qpMax = 80};
EXPECT_EQ(WEBRTC_VIDEO_CODEC_OK,
encoder_->InitEncode(&codec_settings_, kSettings));
// Everything fine: custom scaling, top resolution matches video, temporal
// settings are the same for all layers.
codec_settings_.simulcastStream[0] = {.width = kWidth / 4,
.height = kHeight / 4,
.maxFramerate = kFramerateFps,
.numberOfTemporalLayers = 1,
.maxBitrate = 4000,
.targetBitrate = 3000,
.minBitrate = 2000,
.qpMax = 80};
codec_settings_.simulcastStream[1] = {.width = kWidth,
.height = kHeight,
.maxFramerate = kFramerateFps,
.numberOfTemporalLayers = 1,
.maxBitrate = 4000,
.targetBitrate = 3000,
.minBitrate = 2000,
.qpMax = 80};
codec_settings_.simulcastStream[2] = {.width = kWidth,
.height = kHeight,
.maxFramerate = kFramerateFps,
.numberOfTemporalLayers = 1,
.maxBitrate = 4000,
.targetBitrate = 3000,
.minBitrate = 2000,
.qpMax = 80};
EXPECT_EQ(WEBRTC_VIDEO_CODEC_OK,
encoder_->InitEncode(&codec_settings_, kSettings));
}
#if defined(WEBRTC_ANDROID)
#define MAYBE_AlignedStrideEncodeDecode DISABLED_AlignedStrideEncodeDecode
#else
#define MAYBE_AlignedStrideEncodeDecode AlignedStrideEncodeDecode
#endif
TEST_F(TestVp8Impl, MAYBE_AlignedStrideEncodeDecode) {
VideoFrame input_frame = NextInputFrame();
input_frame.set_rtp_timestamp(kInitialTimestampRtp);
input_frame.set_timestamp_us(kInitialTimestampMs *
rtc::kNumMicrosecsPerMillisec);
EncodedImage encoded_frame;
CodecSpecificInfo codec_specific_info;
EncodeAndWaitForFrame(input_frame, &encoded_frame, &codec_specific_info);
// First frame should be a key frame.
encoded_frame._frameType = VideoFrameType::kVideoFrameKey;
encoded_frame.ntp_time_ms_ = kTestNtpTimeMs;
EXPECT_EQ(WEBRTC_VIDEO_CODEC_OK, decoder_->Decode(encoded_frame, -1));
std::unique_ptr<VideoFrame> decoded_frame;
absl::optional<uint8_t> decoded_qp;
ASSERT_TRUE(WaitForDecodedFrame(&decoded_frame, &decoded_qp));
ASSERT_TRUE(decoded_frame);
// Compute PSNR on all planes (faster than SSIM).
EXPECT_GT(I420PSNR(&input_frame, decoded_frame.get()), 36);
EXPECT_EQ(kInitialTimestampRtp, decoded_frame->rtp_timestamp());
}
TEST_F(TestVp8Impl, EncoderWith2TemporalLayers) {
codec_settings_.VP8()->numberOfTemporalLayers = 2;
EXPECT_EQ(WEBRTC_VIDEO_CODEC_OK,
encoder_->InitEncode(&codec_settings_, kSettings));
// Temporal layer 0.
EncodedImage encoded_frame;
CodecSpecificInfo codec_specific_info;
EncodeAndWaitForFrame(NextInputFrame(), &encoded_frame, &codec_specific_info);
EXPECT_EQ(0, codec_specific_info.codecSpecific.VP8.temporalIdx);
// Temporal layer 1.
EncodeAndExpectFrameWith(NextInputFrame(), 1);
// Temporal layer 0.
EncodeAndExpectFrameWith(NextInputFrame(), 0);
// Temporal layer 1.
EncodeAndExpectFrameWith(NextInputFrame(), 1);
}
TEST_F(TestVp8Impl, ScalingDisabledIfAutomaticResizeOff) {
codec_settings_.VP8()->automaticResizeOn = false;
EXPECT_EQ(WEBRTC_VIDEO_CODEC_OK,
encoder_->InitEncode(&codec_settings_, kSettings));
VideoEncoder::ScalingSettings settings =
encoder_->GetEncoderInfo().scaling_settings;
EXPECT_FALSE(settings.thresholds.has_value());
}
TEST_F(TestVp8Impl, ScalingEnabledIfAutomaticResizeOn) {
codec_settings_.SetFrameDropEnabled(true);
codec_settings_.VP8()->automaticResizeOn = true;
EXPECT_EQ(WEBRTC_VIDEO_CODEC_OK,
encoder_->InitEncode(&codec_settings_, kSettings));
VideoEncoder::ScalingSettings settings =
encoder_->GetEncoderInfo().scaling_settings;
EXPECT_TRUE(settings.thresholds.has_value());
EXPECT_EQ(kDefaultMinPixelsPerFrame, settings.min_pixels_per_frame);
}
TEST_F(TestVp8Impl, DontDropKeyframes) {
// Set very high resolution to trigger overuse more easily.
const int kScreenWidth = 1920;
const int kScreenHeight = 1080;
codec_settings_.width = kScreenWidth;
codec_settings_.height = kScreenHeight;
// Screensharing has the internal frame dropper off, and instead per frame
// asks ScreenshareLayers to decide if it should be dropped or not.
codec_settings_.SetFrameDropEnabled(false);
codec_settings_.mode = VideoCodecMode::kScreensharing;
// ScreenshareLayers triggers on 2 temporal layers and 1000kbps max bitrate.
codec_settings_.VP8()->numberOfTemporalLayers = 2;
codec_settings_.maxBitrate = 1000;
// Reset the frame generator with large number of squares, leading to lots of
// details and high probability of overshoot.
input_frame_generator_ = test::CreateSquareFrameGenerator(
codec_settings_.width, codec_settings_.height,
test::FrameGeneratorInterface::OutputType::kI420,
/* num_squares = */ absl::optional<int>(300));
EXPECT_EQ(WEBRTC_VIDEO_CODEC_OK,
encoder_->InitEncode(&codec_settings_, kSettings));
VideoBitrateAllocation bitrate_allocation;
// Bitrate only enough for TL0.
bitrate_allocation.SetBitrate(0, 0, 200000);
encoder_->SetRates(
VideoEncoder::RateControlParameters(bitrate_allocation, 5.0));
EncodedImage encoded_frame;
CodecSpecificInfo codec_specific_info;
EncodeAndWaitForFrame(NextInputFrame(), &encoded_frame, &codec_specific_info,
true);
EncodeAndExpectFrameWith(NextInputFrame(), 0, true);
EncodeAndExpectFrameWith(NextInputFrame(), 0, true);
EncodeAndExpectFrameWith(NextInputFrame(), 0, true);
}
TEST_F(TestVp8Impl, KeepsTimestampOnReencode) {
auto* const vpx = new NiceMock<MockLibvpxInterface>();
LibvpxVp8Encoder encoder(CreateEnvironment(), {}, absl::WrapUnique(vpx));
// Settings needed to trigger ScreenshareLayers usage, which is required for
// overshoot-drop-reencode logic.
codec_settings_.maxBitrate = 1000;
codec_settings_.mode = VideoCodecMode::kScreensharing;
codec_settings_.VP8()->numberOfTemporalLayers = 2;
codec_settings_.legacy_conference_mode = true;
EXPECT_CALL(*vpx, img_wrap(_, _, _, _, _, _))
.WillOnce(Invoke([](vpx_image_t* img, vpx_img_fmt_t fmt, unsigned int d_w,
unsigned int d_h, unsigned int stride_align,
unsigned char* img_data) {
img->fmt = fmt;
img->d_w = d_w;
img->d_h = d_h;
img->img_data = img_data;
return img;
}));
EXPECT_EQ(WEBRTC_VIDEO_CODEC_OK,
encoder.InitEncode(&codec_settings_,
VideoEncoder::Settings(kCapabilities, 1, 1000)));
MockEncodedImageCallback callback;
encoder.RegisterEncodeCompleteCallback(&callback);
// Simulate overshoot drop, re-encode: encode function will be called twice
// with the same parameters. codec_get_cx_data() will by default return no
// image data and be interpreted as drop.
EXPECT_CALL(*vpx, codec_encode(_, _, /* pts = */ 0, _, _, _))
.Times(2)
.WillRepeatedly(Return(vpx_codec_err_t::VPX_CODEC_OK));
auto delta_frame =
std::vector<VideoFrameType>{VideoFrameType::kVideoFrameDelta};
encoder.Encode(NextInputFrame(), &delta_frame);
}
TEST(LibvpxVp8EncoderTest, GetEncoderInfoReturnsStaticInformation) {
auto* const vpx = new NiceMock<MockLibvpxInterface>();
LibvpxVp8Encoder encoder(CreateEnvironment(), {}, absl::WrapUnique(vpx));
const auto info = encoder.GetEncoderInfo();
EXPECT_FALSE(info.supports_native_handle);
EXPECT_FALSE(info.is_hardware_accelerated);
EXPECT_TRUE(info.supports_simulcast);
EXPECT_EQ(info.implementation_name, "libvpx");
EXPECT_EQ(info.requested_resolution_alignment, 1u);
EXPECT_THAT(info.preferred_pixel_formats,
testing::UnorderedElementsAre(VideoFrameBuffer::Type::kNV12,
VideoFrameBuffer::Type::kI420));
}
TEST(LibvpxVp8EncoderTest, RequestedResolutionAlignmentFromFieldTrial) {
test::ScopedKeyValueConfig field_trials(
"WebRTC-VP8-GetEncoderInfoOverride/"
"requested_resolution_alignment:10/");
auto* const vpx = new NiceMock<MockLibvpxInterface>();
LibvpxVp8Encoder encoder(CreateEnvironment(&field_trials), {},
absl::WrapUnique(vpx));
EXPECT_EQ(encoder.GetEncoderInfo().requested_resolution_alignment, 10u);
EXPECT_FALSE(
encoder.GetEncoderInfo().apply_alignment_to_all_simulcast_layers);
EXPECT_TRUE(encoder.GetEncoderInfo().resolution_bitrate_limits.empty());
}
TEST(LibvpxVp8EncoderTest, ResolutionBitrateLimitsFromFieldTrial) {
test::ScopedKeyValueConfig field_trials(
"WebRTC-VP8-GetEncoderInfoOverride/"
"frame_size_pixels:123|456|789,"
"min_start_bitrate_bps:11000|22000|33000,"
"min_bitrate_bps:44000|55000|66000,"
"max_bitrate_bps:77000|88000|99000/");
auto* const vpx = new NiceMock<MockLibvpxInterface>();
LibvpxVp8Encoder encoder(CreateEnvironment(&field_trials), {},
absl::WrapUnique(vpx));
EXPECT_THAT(
encoder.GetEncoderInfo().resolution_bitrate_limits,
::testing::ElementsAre(
VideoEncoder::ResolutionBitrateLimits{123, 11000, 44000, 77000},
VideoEncoder::ResolutionBitrateLimits{456, 22000, 55000, 88000},
VideoEncoder::ResolutionBitrateLimits{789, 33000, 66000, 99000}));
}
TEST(LibvpxVp8EncoderTest,
GetEncoderInfoReturnsEmptyResolutionBitrateLimitsByDefault) {
auto* const vpx = new NiceMock<MockLibvpxInterface>();
LibvpxVp8Encoder encoder(CreateEnvironment(), {}, absl::WrapUnique(vpx));
const auto info = encoder.GetEncoderInfo();
EXPECT_TRUE(info.resolution_bitrate_limits.empty());
}
TEST(LibvpxVp8EncoderTest,
GetEncoderInfoReturnsResolutionBitrateLimitsAsConfigured) {
std::vector<VideoEncoder::ResolutionBitrateLimits> resolution_bitrate_limits =
{VideoEncoder::ResolutionBitrateLimits(/*frame_size_pixels=*/640 * 360,
/*min_start_bitrate_bps=*/300,
/*min_bitrate_bps=*/100,
/*max_bitrate_bps=*/1000),
VideoEncoder::ResolutionBitrateLimits(320 * 180, 100, 30, 500)};
Vp8EncoderSettings settings;
settings.resolution_bitrate_limits = resolution_bitrate_limits;
auto* const vpx = new NiceMock<MockLibvpxInterface>();
LibvpxVp8Encoder encoder(CreateEnvironment(), std::move(settings),
absl::WrapUnique(vpx));
const auto info = encoder.GetEncoderInfo();
EXPECT_EQ(info.resolution_bitrate_limits, resolution_bitrate_limits);
}
TEST_F(TestVp8Impl, GetEncoderInfoFpsAllocationNoLayers) {
FramerateFractions expected_fps_allocation[kMaxSpatialLayers] = {
FramerateFractions(1, EncoderInfo::kMaxFramerateFraction)};
EXPECT_THAT(encoder_->GetEncoderInfo().fps_allocation,
::testing::ElementsAreArray(expected_fps_allocation));
}
TEST_F(TestVp8Impl, GetEncoderInfoFpsAllocationTwoTemporalLayers) {
EXPECT_EQ(WEBRTC_VIDEO_CODEC_OK, encoder_->Release());
codec_settings_.numberOfSimulcastStreams = 1;
codec_settings_.simulcastStream[0].active = true;
codec_settings_.simulcastStream[0].targetBitrate = 100;
codec_settings_.simulcastStream[0].maxBitrate = 100;
codec_settings_.simulcastStream[0].numberOfTemporalLayers = 2;
EXPECT_EQ(WEBRTC_VIDEO_CODEC_OK,
encoder_->InitEncode(&codec_settings_, kSettings));
FramerateFractions expected_fps_allocation[kMaxSpatialLayers];
expected_fps_allocation[0].push_back(EncoderInfo::kMaxFramerateFraction / 2);
expected_fps_allocation[0].push_back(EncoderInfo::kMaxFramerateFraction);
EXPECT_THAT(encoder_->GetEncoderInfo().fps_allocation,
::testing::ElementsAreArray(expected_fps_allocation));
}
TEST_F(TestVp8Impl, GetEncoderInfoFpsAllocationThreeTemporalLayers) {
EXPECT_EQ(WEBRTC_VIDEO_CODEC_OK, encoder_->Release());
codec_settings_.numberOfSimulcastStreams = 1;
codec_settings_.simulcastStream[0].active = true;
codec_settings_.simulcastStream[0].targetBitrate = 100;
codec_settings_.simulcastStream[0].maxBitrate = 100;
codec_settings_.simulcastStream[0].numberOfTemporalLayers = 3;
EXPECT_EQ(WEBRTC_VIDEO_CODEC_OK,
encoder_->InitEncode(&codec_settings_, kSettings));
FramerateFractions expected_fps_allocation[kMaxSpatialLayers];
expected_fps_allocation[0].push_back(EncoderInfo::kMaxFramerateFraction / 4);
expected_fps_allocation[0].push_back(EncoderInfo::kMaxFramerateFraction / 2);
expected_fps_allocation[0].push_back(EncoderInfo::kMaxFramerateFraction);
EXPECT_THAT(encoder_->GetEncoderInfo().fps_allocation,
::testing::ElementsAreArray(expected_fps_allocation));
}
TEST_F(TestVp8Impl, GetEncoderInfoFpsAllocationScreenshareLayers) {
EXPECT_EQ(WEBRTC_VIDEO_CODEC_OK, encoder_->Release());
codec_settings_.numberOfSimulcastStreams = 1;
codec_settings_.mode = VideoCodecMode::kScreensharing;
codec_settings_.simulcastStream[0].active = true;
codec_settings_.simulcastStream[0].minBitrate = 30;
codec_settings_.simulcastStream[0].targetBitrate =
kLegacyScreenshareTl0BitrateKbps;
codec_settings_.simulcastStream[0].maxBitrate =
kLegacyScreenshareTl1BitrateKbps;
codec_settings_.simulcastStream[0].numberOfTemporalLayers = 2;
codec_settings_.legacy_conference_mode = true;
EXPECT_EQ(WEBRTC_VIDEO_CODEC_OK,
encoder_->InitEncode(&codec_settings_, kSettings));
// Expect empty vector, since this mode doesn't have a fixed framerate.
FramerateFractions expected_fps_allocation[kMaxSpatialLayers];
EXPECT_THAT(encoder_->GetEncoderInfo().fps_allocation,
::testing::ElementsAreArray(expected_fps_allocation));
}
TEST_F(TestVp8Impl, GetEncoderInfoFpsAllocationSimulcastVideo) {
EXPECT_EQ(WEBRTC_VIDEO_CODEC_OK, encoder_->Release());
// Set up three simulcast streams with three temporal layers each.
codec_settings_.numberOfSimulcastStreams = 3;
for (int i = 0; i < codec_settings_.numberOfSimulcastStreams; ++i) {
codec_settings_.simulcastStream[i].active = true;
codec_settings_.simulcastStream[i].minBitrate = 30;
codec_settings_.simulcastStream[i].targetBitrate = 30;
codec_settings_.simulcastStream[i].maxBitrate = 30;
codec_settings_.simulcastStream[i].numberOfTemporalLayers = 3;
codec_settings_.simulcastStream[i].width =
codec_settings_.width >>
(codec_settings_.numberOfSimulcastStreams - i - 1);
codec_settings_.simulcastStream[i].height =
codec_settings_.height >>
(codec_settings_.numberOfSimulcastStreams - i - 1);
}
EXPECT_EQ(WEBRTC_VIDEO_CODEC_OK,
encoder_->InitEncode(&codec_settings_, kSettings));
FramerateFractions expected_fps_allocation[kMaxSpatialLayers];
expected_fps_allocation[0].push_back(EncoderInfo::kMaxFramerateFraction / 4);
expected_fps_allocation[0].push_back(EncoderInfo::kMaxFramerateFraction / 2);
expected_fps_allocation[0].push_back(EncoderInfo::kMaxFramerateFraction);
expected_fps_allocation[1] = expected_fps_allocation[0];
expected_fps_allocation[2] = expected_fps_allocation[0];
EXPECT_THAT(encoder_->GetEncoderInfo().fps_allocation,
::testing::ElementsAreArray(expected_fps_allocation));
// Release encoder and re-init without temporal layers.
EXPECT_EQ(WEBRTC_VIDEO_CODEC_OK, encoder_->Release());
// Sanity check fps allocation when not inited.
FramerateFractions default_fps_fraction[kMaxSpatialLayers];
default_fps_fraction[0].push_back(EncoderInfo::kMaxFramerateFraction);
EXPECT_THAT(encoder_->GetEncoderInfo().fps_allocation,
::testing::ElementsAreArray(default_fps_fraction));
for (int i = 0; i < codec_settings_.numberOfSimulcastStreams; ++i) {
codec_settings_.simulcastStream[i].numberOfTemporalLayers = 1;
}
EXPECT_EQ(WEBRTC_VIDEO_CODEC_OK,
encoder_->InitEncode(&codec_settings_, kSettings));
for (size_t i = 0; i < 3; ++i) {
expected_fps_allocation[i].clear();
expected_fps_allocation[i].push_back(EncoderInfo::kMaxFramerateFraction);
}
EXPECT_THAT(encoder_->GetEncoderInfo().fps_allocation,
::testing::ElementsAreArray(expected_fps_allocation));
}
class TestVp8ImplWithMaxFrameDropTrial
: public TestVp8Impl,
public ::testing::WithParamInterface<
std::tuple<std::string, TimeDelta, TimeDelta>> {
public:
TestVp8ImplWithMaxFrameDropTrial()
: TestVp8Impl(), trials_(std::get<0>(GetParam())) {}
protected:
test::ScopedFieldTrials trials_;
};
TEST_P(TestVp8ImplWithMaxFrameDropTrial, EnforcesMaxFrameDropInterval) {
static constexpr int kFps = 5;
auto [trial_string, max_interval_config, min_expected_interval] = GetParam();
// Allow one frame interval over the configured max frame drop interval.
TimeDelta max_frame_delta =
max_interval_config + (TimeDelta::Seconds(1) / kFps);
EXPECT_EQ(WEBRTC_VIDEO_CODEC_OK, encoder_->Release());
// Set up low-bitrate screenshare stream.
codec_settings_.numberOfSimulcastStreams = 1;
codec_settings_.legacy_conference_mode = false;
codec_settings_.mode = VideoCodecMode::kScreensharing;
codec_settings_.maxFramerate = kFps;
codec_settings_.width = 2880;
codec_settings_.height = 1800;
codec_settings_.minBitrate = 30;
codec_settings_.maxBitrate = 420;
codec_settings_.SetFrameDropEnabled(true);
codec_settings_.simulcastStream[0].active = true;
codec_settings_.simulcastStream[0].minBitrate = codec_settings_.minBitrate;
codec_settings_.simulcastStream[0].targetBitrate = codec_settings_.maxBitrate;
codec_settings_.simulcastStream[0].maxBitrate = codec_settings_.maxBitrate;
codec_settings_.simulcastStream[0].numberOfTemporalLayers = 2;
codec_settings_.simulcastStream[0].width = codec_settings_.width;
codec_settings_.simulcastStream[0].height = codec_settings_.height;
codec_settings_.simulcastStream[0].maxFramerate =
codec_settings_.maxFramerate;
EXPECT_EQ(WEBRTC_VIDEO_CODEC_OK,
encoder_->InitEncode(&codec_settings_, kSettings));
// Allocate a very constained amount of bitrate to increase risk of frame
// drops.
VideoBitrateAllocation bitrate_allocation;
bitrate_allocation.SetBitrate(0, 0, 50'000);
bitrate_allocation.SetBitrate(0, 1, 50'000);
encoder_->SetRates(
VideoEncoder::RateControlParameters(bitrate_allocation, 5.0));
EncodedImage encoded_frame;
CodecSpecificInfo codec_specific_info;
// Create a low-complexity 1 square test sequence.
input_frame_generator_ = test::CreateSquareFrameGenerator(
codec_settings_.width, codec_settings_.height,
test::FrameGeneratorInterface::OutputType::kI420,
/*num_squares=*/1);
class Callback : public EncodedImageCallback {
public:
Callback() : last_callback_(Timestamp::MinusInfinity()) {}
const std::vector<TimeDelta>& GetCallbackDeltas() const {
return callback_deltas_;
}
void ClearCallbackDeltas() { callback_deltas_.clear(); }
protected:
Result OnEncodedImage(const EncodedImage& encoded_image,
const CodecSpecificInfo* codec_specific_info) {
Timestamp timestamp =
Timestamp::Millis(encoded_image.RtpTimestamp() / 90);
if (last_callback_.IsFinite()) {
callback_deltas_.push_back(timestamp - last_callback_);
}
last_callback_ = timestamp;
return Result(Result::Error::OK);
}
private:
std::vector<TimeDelta> callback_deltas_;
Timestamp last_callback_;
} callback;
encoder_->RegisterEncodeCompleteCallback(&callback);
std::vector<VideoFrameType> frame_types = {VideoFrameType::kVideoFrameKey};
EXPECT_EQ(encoder_->Encode(NextInputFrame(), &frame_types),
WEBRTC_VIDEO_CODEC_OK);
frame_types[0] = VideoFrameType::kVideoFrameDelta;
// Encode a couple of frames and verify reasonable frame spacing.
for (uint32_t i = 0; i < codec_settings_.maxFramerate * 10; ++i) {
EXPECT_EQ(encoder_->Encode(NextInputFrame(), &frame_types),
WEBRTC_VIDEO_CODEC_OK);
}
auto deltas = callback.GetCallbackDeltas();
ASSERT_FALSE(deltas.empty());
EXPECT_LE(*std::max_element(deltas.begin(), deltas.end()), max_frame_delta);
// Switch to a much more complex input. Verify time deltas are still OK.
input_frame_generator_ = test::CreateSquareFrameGenerator(
codec_settings_.width, codec_settings_.height,
test::FrameGeneratorInterface::OutputType::kI420,
/*num_squares=*/5000);
callback.ClearCallbackDeltas();
for (uint32_t i = 0; i < codec_settings_.maxFramerate * 10; ++i) {
EXPECT_EQ(encoder_->Encode(NextInputFrame(), &frame_types),
WEBRTC_VIDEO_CODEC_OK);
}
deltas = callback.GetCallbackDeltas();
ASSERT_FALSE(deltas.empty());
EXPECT_LE(*std::max_element(deltas.begin(), deltas.end()), max_frame_delta);
// Check that encoder is causing the expected long frame drop intervals.
EXPECT_GT(*std::max_element(deltas.begin(), deltas.end()),
min_expected_interval);
EXPECT_EQ(WEBRTC_VIDEO_CODEC_OK, encoder_->Release());
}
INSTANTIATE_TEST_SUITE_P(
All,
TestVp8ImplWithMaxFrameDropTrial,
::testing::Values(
// Tuple of {
// trial string,
// configured max frame interval,
// lower bound on expected frame drop intervals
// }
std::make_tuple("WebRTC-VP8-MaxFrameInterval/Disabled/",
TimeDelta::PlusInfinity(),
TimeDelta::Seconds(2)),
std::make_tuple("WebRTC-VP8-MaxFrameInterval/interval:1s/",
TimeDelta::Seconds(1),
TimeDelta::Seconds(0)),
std::make_tuple("", TimeDelta::Seconds(2), TimeDelta::Seconds(1))));
class TestVp8ImplForPixelFormat
: public TestVp8Impl,
public ::testing::WithParamInterface<VideoFrameBuffer::Type> {
public:
TestVp8ImplForPixelFormat() : TestVp8Impl(), mappable_type_(GetParam()) {}
protected:
VideoFrameBuffer::Type mappable_type_;
};
TEST_P(TestVp8ImplForPixelFormat, EncodeNativeFrameSimulcast) {
EXPECT_EQ(WEBRTC_VIDEO_CODEC_OK, encoder_->Release());
// Configure simulcast.
codec_settings_.numberOfSimulcastStreams = 3;
codec_settings_.simulcastStream[0] = {.width = kWidth / 4,
.height = kHeight / 4,
.maxFramerate = kFramerateFps,
.numberOfTemporalLayers = 1,
.maxBitrate = 4000,
.targetBitrate = 3000,
.minBitrate = 2000,
.qpMax = 80,
.active = true};
codec_settings_.simulcastStream[1] = {.width = kWidth / 2,
.height = kHeight / 2,
.maxFramerate = kFramerateFps,
.numberOfTemporalLayers = 1,
.maxBitrate = 4000,
.targetBitrate = 3000,
.minBitrate = 2000,
.qpMax = 80,
.active = true};
codec_settings_.simulcastStream[2] = {.width = kWidth,
.height = kHeight,
.maxFramerate = kFramerateFps,
.numberOfTemporalLayers = 1,
.maxBitrate = 4000,
.targetBitrate = 3000,
.minBitrate = 2000,
.qpMax = 80,
.active = true};
EXPECT_EQ(WEBRTC_VIDEO_CODEC_OK,
encoder_->InitEncode(&codec_settings_, kSettings));
// Create a zero-conversion NV12 frame (calling ToI420 on it crashes).
VideoFrame input_frame =
test::CreateMappableNativeFrame(1, mappable_type_, kWidth, kHeight);
EncodedImage encoded_frame;
CodecSpecificInfo codec_specific_info;
EncodeAndWaitForFrame(input_frame, &encoded_frame, &codec_specific_info);
// After encoding, we expect one mapping per simulcast layer.
rtc::scoped_refptr<test::MappableNativeBuffer> mappable_buffer =
test::GetMappableNativeBufferFromVideoFrame(input_frame);
std::vector<rtc::scoped_refptr<VideoFrameBuffer>> mapped_buffers =
mappable_buffer->GetMappedFramedBuffers();
ASSERT_EQ(mapped_buffers.size(), 3u);
EXPECT_EQ(mapped_buffers[0]->type(), mappable_type_);
EXPECT_EQ(mapped_buffers[0]->width(), kWidth);
EXPECT_EQ(mapped_buffers[0]->height(), kHeight);
EXPECT_EQ(mapped_buffers[1]->type(), mappable_type_);
EXPECT_EQ(mapped_buffers[1]->width(), kWidth / 2);
EXPECT_EQ(mapped_buffers[1]->height(), kHeight / 2);
EXPECT_EQ(mapped_buffers[2]->type(), mappable_type_);
EXPECT_EQ(mapped_buffers[2]->width(), kWidth / 4);
EXPECT_EQ(mapped_buffers[2]->height(), kHeight / 4);
EXPECT_FALSE(mappable_buffer->DidConvertToI420());
EXPECT_EQ(WEBRTC_VIDEO_CODEC_OK, encoder_->Release());
}
INSTANTIATE_TEST_SUITE_P(All,
TestVp8ImplForPixelFormat,
::testing::Values(VideoFrameBuffer::Type::kI420,
VideoFrameBuffer::Type::kNV12));
} // namespace webrtc