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/*
* Copyright (c) 2015 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 <limits>
#include "testing/gtest/include/gtest/gtest.h"
#include "vpx/vp8cx.h"
#include "webrtc/base/logging.h"
#include "webrtc/modules/video_coding/codecs/vp9/screenshare_layers.h"
#include "webrtc/modules/video_coding/codecs/vp9/vp9_impl.h"
#include "webrtc/system_wrappers/include/clock.h"
namespace webrtc {
typedef VP9EncoderImpl::SuperFrameRefSettings Settings;
const uint32_t kTickFrequency = 90000;
class ScreenshareLayerTestVP9 : public ::testing::Test {
protected:
ScreenshareLayerTestVP9() : clock_(0) {}
virtual ~ScreenshareLayerTestVP9() {}
void InitScreenshareLayers(int layers) {
layers_.reset(new ScreenshareLayersVP9(layers));
}
void ConfigureBitrateForLayer(int kbps, uint8_t layer_id) {
layers_->ConfigureBitrate(kbps, layer_id);
}
void AdvanceTime(int64_t milliseconds) {
clock_.AdvanceTimeMilliseconds(milliseconds);
}
void AddKilobitsToLayer(int kilobits, uint8_t layer_id) {
layers_->LayerFrameEncoded(kilobits * 1000 / 8, layer_id);
}
void EqualRefsForLayer(const Settings& actual, uint8_t layer_id) {
EXPECT_EQ(expected_.layer[layer_id].upd_buf,
actual.layer[layer_id].upd_buf);
EXPECT_EQ(expected_.layer[layer_id].ref_buf1,
actual.layer[layer_id].ref_buf1);
EXPECT_EQ(expected_.layer[layer_id].ref_buf2,
actual.layer[layer_id].ref_buf2);
EXPECT_EQ(expected_.layer[layer_id].ref_buf3,
actual.layer[layer_id].ref_buf3);
}
void EqualRefs(const Settings& actual) {
for (unsigned int layer_id = 0; layer_id < kMaxVp9NumberOfSpatialLayers;
++layer_id) {
EqualRefsForLayer(actual, layer_id);
}
}
void EqualStartStopKeyframe(const Settings& actual) {
EXPECT_EQ(expected_.start_layer, actual.start_layer);
EXPECT_EQ(expected_.stop_layer, actual.stop_layer);
EXPECT_EQ(expected_.is_keyframe, actual.is_keyframe);
}
// Check that the settings returned by GetSuperFrameSettings() is
// equal to the expected_ settings.
void EqualToExpected() {
uint32_t frame_timestamp_ =
clock_.TimeInMilliseconds() * (kTickFrequency / 1000);
Settings actual =
layers_->GetSuperFrameSettings(frame_timestamp_, expected_.is_keyframe);
EqualRefs(actual);
EqualStartStopKeyframe(actual);
}
Settings expected_;
SimulatedClock clock_;
rtc::scoped_ptr<ScreenshareLayersVP9> layers_;
};
TEST_F(ScreenshareLayerTestVP9, NoRefsOnKeyFrame) {
const int kNumLayers = kMaxVp9NumberOfSpatialLayers;
InitScreenshareLayers(kNumLayers);
expected_.start_layer = 0;
expected_.stop_layer = kNumLayers - 1;
for (int l = 0; l < kNumLayers; ++l) {
expected_.layer[l].upd_buf = l;
}
expected_.is_keyframe = true;
EqualToExpected();
for (int l = 0; l < kNumLayers; ++l) {
expected_.layer[l].ref_buf1 = l;
}
expected_.is_keyframe = false;
EqualToExpected();
}
// Test if it is possible to send at a high bitrate (over the threshold)
// after a longer period of low bitrate. This should not be possible.
TEST_F(ScreenshareLayerTestVP9, DontAccumelateAvailableBitsOverTime) {
InitScreenshareLayers(2);
ConfigureBitrateForLayer(100, 0);
expected_.layer[0].upd_buf = 0;
expected_.layer[0].ref_buf1 = 0;
expected_.layer[1].upd_buf = 1;
expected_.layer[1].ref_buf1 = 1;
expected_.start_layer = 0;
expected_.stop_layer = 1;
// Send 10 frames at a low bitrate (50 kbps)
for (int i = 0; i < 10; ++i) {
AdvanceTime(200);
EqualToExpected();
AddKilobitsToLayer(10, 0);
}
AdvanceTime(200);
EqualToExpected();
AddKilobitsToLayer(301, 0);
// Send 10 frames at a high bitrate (200 kbps)
expected_.start_layer = 1;
for (int i = 0; i < 10; ++i) {
AdvanceTime(200);
EqualToExpected();
AddKilobitsToLayer(40, 1);
}
}
// Test if used bits are accumelated over layers, as they should;
TEST_F(ScreenshareLayerTestVP9, AccumelateUsedBitsOverLayers) {
const int kNumLayers = kMaxVp9NumberOfSpatialLayers;
InitScreenshareLayers(kNumLayers);
for (int l = 0; l < kNumLayers - 1; ++l)
ConfigureBitrateForLayer(100, l);
for (int l = 0; l < kNumLayers; ++l) {
expected_.layer[l].upd_buf = l;
expected_.layer[l].ref_buf1 = l;
}
expected_.start_layer = 0;
expected_.stop_layer = kNumLayers - 1;
EqualToExpected();
for (int layer = 0; layer < kNumLayers - 1; ++layer) {
expected_.start_layer = layer;
EqualToExpected();
AddKilobitsToLayer(101, layer);
}
}
// General testing of the bitrate controller.
TEST_F(ScreenshareLayerTestVP9, 2LayerBitrate) {
InitScreenshareLayers(2);
ConfigureBitrateForLayer(100, 0);
expected_.layer[0].upd_buf = 0;
expected_.layer[1].upd_buf = 1;
expected_.layer[0].ref_buf1 = -1;
expected_.layer[1].ref_buf1 = -1;
expected_.start_layer = 0;
expected_.stop_layer = 1;
expected_.is_keyframe = true;
EqualToExpected();
AddKilobitsToLayer(100, 0);
expected_.layer[0].ref_buf1 = 0;
expected_.layer[1].ref_buf1 = 1;
expected_.is_keyframe = false;
AdvanceTime(199);
EqualToExpected();
AddKilobitsToLayer(100, 0);
expected_.start_layer = 1;
for (int frame = 0; frame < 3; ++frame) {
AdvanceTime(200);
EqualToExpected();
AddKilobitsToLayer(100, 1);
}
// Just before enough bits become available for L0 @0.999 seconds.
AdvanceTime(199);
EqualToExpected();
AddKilobitsToLayer(100, 1);
// Just after enough bits become available for L0 @1.0001 seconds.
expected_.start_layer = 0;
AdvanceTime(2);
EqualToExpected();
AddKilobitsToLayer(100, 0);
// Keyframes always encode all layers, even if it is over budget.
expected_.layer[0].ref_buf1 = -1;
expected_.layer[1].ref_buf1 = -1;
expected_.is_keyframe = true;
AdvanceTime(499);
EqualToExpected();
expected_.layer[0].ref_buf1 = 0;
expected_.layer[1].ref_buf1 = 1;
expected_.start_layer = 1;
expected_.is_keyframe = false;
EqualToExpected();
AddKilobitsToLayer(100, 0);
// 400 kb in L0 --> @3 second mark to fall below the threshold..
// just before @2.999 seconds.
expected_.is_keyframe = false;
AdvanceTime(1499);
EqualToExpected();
AddKilobitsToLayer(100, 1);
// just after @3.001 seconds.
expected_.start_layer = 0;
AdvanceTime(2);
EqualToExpected();
AddKilobitsToLayer(100, 0);
}
// General testing of the bitrate controller.
TEST_F(ScreenshareLayerTestVP9, 3LayerBitrate) {
InitScreenshareLayers(3);
ConfigureBitrateForLayer(100, 0);
ConfigureBitrateForLayer(100, 1);
for (int l = 0; l < 3; ++l) {
expected_.layer[l].upd_buf = l;
expected_.layer[l].ref_buf1 = l;
}
expected_.start_layer = 0;
expected_.stop_layer = 2;
EqualToExpected();
AddKilobitsToLayer(105, 0);
AddKilobitsToLayer(30, 1);
AdvanceTime(199);
EqualToExpected();
AddKilobitsToLayer(105, 0);
AddKilobitsToLayer(30, 1);
expected_.start_layer = 1;
AdvanceTime(200);
EqualToExpected();
AddKilobitsToLayer(130, 1);
expected_.start_layer = 2;
AdvanceTime(200);
EqualToExpected();
// 400 kb in L1 --> @1.0 second mark to fall below threshold.
// 210 kb in L0 --> @1.1 second mark to fall below threshold.
// Just before L1 @0.999 seconds.
AdvanceTime(399);
EqualToExpected();
// Just after L1 @1.001 seconds.
expected_.start_layer = 1;
AdvanceTime(2);
EqualToExpected();
// Just before L0 @1.099 seconds.
AdvanceTime(99);
EqualToExpected();
// Just after L0 @1.101 seconds.
expected_.start_layer = 0;
AdvanceTime(2);
EqualToExpected();
// @1.1 seconds
AdvanceTime(99);
EqualToExpected();
AddKilobitsToLayer(200, 1);
expected_.is_keyframe = true;
for (int l = 0; l < 3; ++l)
expected_.layer[l].ref_buf1 = -1;
AdvanceTime(200);
EqualToExpected();
expected_.is_keyframe = false;
expected_.start_layer = 2;
for (int l = 0; l < 3; ++l)
expected_.layer[l].ref_buf1 = l;
AdvanceTime(200);
EqualToExpected();
}
// Test that the bitrate calculations are
// correct when the timestamp wrap.
TEST_F(ScreenshareLayerTestVP9, TimestampWrap) {
InitScreenshareLayers(2);
ConfigureBitrateForLayer(100, 0);
expected_.layer[0].upd_buf = 0;
expected_.layer[0].ref_buf1 = 0;
expected_.layer[1].upd_buf = 1;
expected_.layer[1].ref_buf1 = 1;
expected_.start_layer = 0;
expected_.stop_layer = 1;
// Advance time to just before the timestamp wraps.
AdvanceTime(std::numeric_limits<uint32_t>::max() / (kTickFrequency / 1000));
EqualToExpected();
AddKilobitsToLayer(200, 0);
// Wrap
expected_.start_layer = 1;
AdvanceTime(1);
EqualToExpected();
}
} // namespace webrtc
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