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/*
* Copyright (c) 2018 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 "modules/video_coding/codecs/vp9/svc_config.h"
#include <cstddef>
#include <vector>
#include "modules/video_coding/codecs/vp9/include/vp9_globals.h"
#include "test/gmock.h"
#include "test/gtest.h"
using ::testing::ElementsAre;
using ::testing::Field;
namespace webrtc {
TEST(SvcConfig, NumSpatialLayers) {
const size_t max_num_spatial_layers = 6;
const size_t first_active_layer = 0;
const size_t num_spatial_layers = 2;
std::vector<SpatialLayer> spatial_layers = GetSvcConfig(
kMinVp9SpatialLayerLongSideLength << (num_spatial_layers - 1),
kMinVp9SpatialLayerShortSideLength << (num_spatial_layers - 1), 30,
first_active_layer, max_num_spatial_layers, 1, false);
EXPECT_EQ(spatial_layers.size(), num_spatial_layers);
}
TEST(SvcConfig, NumSpatialLayersPortrait) {
const size_t max_num_spatial_layers = 6;
const size_t first_active_layer = 0;
const size_t num_spatial_layers = 2;
std::vector<SpatialLayer> spatial_layers = GetSvcConfig(
kMinVp9SpatialLayerShortSideLength << (num_spatial_layers - 1),
kMinVp9SpatialLayerLongSideLength << (num_spatial_layers - 1), 30,
first_active_layer, max_num_spatial_layers, 1, false);
EXPECT_EQ(spatial_layers.size(), num_spatial_layers);
}
TEST(SvcConfig, NumSpatialLayersWithScalabilityMode) {
VideoCodec codec;
codec.codecType = kVideoCodecVP9;
codec.width = 960;
codec.height = 540;
codec.SetScalabilityMode(ScalabilityMode::kL3T3_KEY);
std::vector<SpatialLayer> spatial_layers = GetVp9SvcConfig(codec);
EXPECT_THAT(spatial_layers, ElementsAre(Field(&SpatialLayer::height, 135),
Field(&SpatialLayer::height, 270),
Field(&SpatialLayer::height, 540)));
EXPECT_THAT(spatial_layers,
ElementsAre(Field(&SpatialLayer::numberOfTemporalLayers, 3),
Field(&SpatialLayer::numberOfTemporalLayers, 3),
Field(&SpatialLayer::numberOfTemporalLayers, 3)));
EXPECT_EQ(codec.GetScalabilityMode(), ScalabilityMode::kL3T3_KEY);
}
TEST(SvcConfig, NumSpatialLayersLimitedWithScalabilityMode) {
VideoCodec codec;
codec.codecType = kVideoCodecVP9;
codec.width = 480;
codec.height = 270;
codec.SetScalabilityMode(ScalabilityMode::kL3T3_KEY);
// Scalability mode updated.
std::vector<SpatialLayer> spatial_layers = GetVp9SvcConfig(codec);
EXPECT_THAT(spatial_layers, ElementsAre(Field(&SpatialLayer::height, 135),
Field(&SpatialLayer::height, 270)));
EXPECT_THAT(spatial_layers,
ElementsAre(Field(&SpatialLayer::numberOfTemporalLayers, 3),
Field(&SpatialLayer::numberOfTemporalLayers, 3)));
EXPECT_EQ(codec.GetScalabilityMode(), ScalabilityMode::kL2T3_KEY);
}
TEST(SvcConfig, NumSpatialLayersLimitedWithScalabilityModePortrait) {
VideoCodec codec;
codec.codecType = kVideoCodecVP9;
codec.width = 270;
codec.height = 480;
codec.SetScalabilityMode(ScalabilityMode::kL3T1);
// Scalability mode updated.
std::vector<SpatialLayer> spatial_layers = GetVp9SvcConfig(codec);
EXPECT_THAT(spatial_layers, ElementsAre(Field(&SpatialLayer::width, 135),
Field(&SpatialLayer::width, 270)));
EXPECT_THAT(spatial_layers,
ElementsAre(Field(&SpatialLayer::numberOfTemporalLayers, 1),
Field(&SpatialLayer::numberOfTemporalLayers, 1)));
EXPECT_EQ(codec.GetScalabilityMode(), ScalabilityMode::kL2T1);
}
TEST(SvcConfig, NumSpatialLayersWithScalabilityModeResolutionRatio1_5) {
VideoCodec codec;
codec.codecType = kVideoCodecVP9;
codec.width = 270;
codec.height = 480;
codec.SetScalabilityMode(ScalabilityMode::kL2T1h); // 1.5:1
std::vector<SpatialLayer> spatial_layers = GetVp9SvcConfig(codec);
EXPECT_THAT(spatial_layers, ElementsAre(Field(&SpatialLayer::width, 180),
Field(&SpatialLayer::width, 270)));
EXPECT_THAT(spatial_layers,
ElementsAre(Field(&SpatialLayer::numberOfTemporalLayers, 1),
Field(&SpatialLayer::numberOfTemporalLayers, 1)));
EXPECT_EQ(codec.GetScalabilityMode(), ScalabilityMode::kL2T1h);
}
TEST(SvcConfig, NumSpatialLayersLimitedWithScalabilityModeResolutionRatio1_5) {
VideoCodec codec;
codec.codecType = kVideoCodecVP9;
codec.width = 320;
codec.height = 180;
codec.SetScalabilityMode(ScalabilityMode::kL3T1h); // 1.5:1
// Scalability mode updated.
std::vector<SpatialLayer> spatial_layers = GetVp9SvcConfig(codec);
EXPECT_THAT(spatial_layers, ElementsAre(Field(&SpatialLayer::width, 320)));
EXPECT_THAT(spatial_layers,
ElementsAre(Field(&SpatialLayer::numberOfTemporalLayers, 1)));
EXPECT_EQ(codec.GetScalabilityMode(), ScalabilityMode::kL1T1);
}
TEST(SvcConfig, AlwaysSendsAtLeastOneLayer) {
const size_t max_num_spatial_layers = 6;
const size_t first_active_layer = 5;
std::vector<SpatialLayer> spatial_layers = GetSvcConfig(
kMinVp9SpatialLayerLongSideLength, kMinVp9SpatialLayerShortSideLength, 30,
first_active_layer, max_num_spatial_layers, 1, false);
EXPECT_EQ(spatial_layers.size(), 1u);
EXPECT_EQ(spatial_layers.back().width, kMinVp9SpatialLayerLongSideLength);
}
TEST(SvcConfig, AlwaysSendsAtLeastOneLayerPortrait) {
const size_t max_num_spatial_layers = 6;
const size_t first_active_layer = 5;
std::vector<SpatialLayer> spatial_layers = GetSvcConfig(
kMinVp9SpatialLayerShortSideLength, kMinVp9SpatialLayerLongSideLength, 30,
first_active_layer, max_num_spatial_layers, 1, false);
EXPECT_EQ(spatial_layers.size(), 1u);
EXPECT_EQ(spatial_layers.back().width, kMinVp9SpatialLayerShortSideLength);
}
TEST(SvcConfig, EnforcesMinimalRequiredParity) {
const size_t max_num_spatial_layers = 3;
const size_t kOddSize = 1023;
std::vector<SpatialLayer> spatial_layers =
GetSvcConfig(kOddSize, kOddSize, 30,
/*first_active_layer=*/1, max_num_spatial_layers, 1, false);
// Since there are 2 layers total (1, 2), divisiblity by 2 is required.
EXPECT_EQ(spatial_layers.back().width, kOddSize - 1);
EXPECT_EQ(spatial_layers.back().width, kOddSize - 1);
spatial_layers =
GetSvcConfig(kOddSize, kOddSize, 30,
/*first_active_layer=*/0, max_num_spatial_layers, 1, false);
// Since there are 3 layers total (0, 1, 2), divisiblity by 4 is required.
EXPECT_EQ(spatial_layers.back().width, kOddSize - 3);
EXPECT_EQ(spatial_layers.back().width, kOddSize - 3);
spatial_layers =
GetSvcConfig(kOddSize, kOddSize, 30,
/*first_active_layer=*/2, max_num_spatial_layers, 1, false);
// Since there is only 1 layer active (2), divisiblity by 1 is required.
EXPECT_EQ(spatial_layers.back().width, kOddSize);
EXPECT_EQ(spatial_layers.back().width, kOddSize);
}
TEST(SvcConfig, EnforcesMinimalRequiredParityWithScalabilityMode) {
VideoCodec codec;
codec.codecType = kVideoCodecVP9;
codec.width = 1023;
codec.height = 1023;
codec.SetScalabilityMode(ScalabilityMode::kL3T1);
std::vector<SpatialLayer> spatial_layers = GetVp9SvcConfig(codec);
EXPECT_THAT(spatial_layers, // Divisiblity by 4 required.
ElementsAre(Field(&SpatialLayer::width, 255),
Field(&SpatialLayer::width, 510),
Field(&SpatialLayer::width, 1020)));
codec.SetScalabilityMode(ScalabilityMode::kL2T1);
spatial_layers = GetVp9SvcConfig(codec);
EXPECT_THAT(spatial_layers, // Divisiblity by 2 required.
ElementsAre(Field(&SpatialLayer::width, 511),
Field(&SpatialLayer::width, 1022)));
codec.SetScalabilityMode(ScalabilityMode::kL1T1);
spatial_layers = GetVp9SvcConfig(codec);
EXPECT_THAT(spatial_layers, // Divisiblity by 1 required.
ElementsAre(Field(&SpatialLayer::width, 1023)));
}
TEST(SvcConfig, EnforcesMinimalRequiredParityWithScalabilityModeResRatio1_5) {
VideoCodec codec;
codec.codecType = kVideoCodecVP9;
codec.width = 1280;
codec.height = 1280;
codec.SetScalabilityMode(ScalabilityMode::kL2T1h); // 1.5:1
std::vector<SpatialLayer> spatial_layers = GetVp9SvcConfig(codec);
EXPECT_THAT(spatial_layers, // Divisiblity by 3 required.
ElementsAre(Field(&SpatialLayer::width, 852),
Field(&SpatialLayer::width, 1278)));
}
TEST(SvcConfig, SkipsInactiveLayers) {
const size_t num_spatial_layers = 4;
const size_t first_active_layer = 2;
std::vector<SpatialLayer> spatial_layers = GetSvcConfig(
kMinVp9SpatialLayerLongSideLength << (num_spatial_layers - 1),
kMinVp9SpatialLayerShortSideLength << (num_spatial_layers - 1), 30,
first_active_layer, num_spatial_layers, 1, false);
EXPECT_EQ(spatial_layers.size(), 2u);
EXPECT_EQ(spatial_layers.back().width,
kMinVp9SpatialLayerLongSideLength << (num_spatial_layers - 1));
}
TEST(SvcConfig, BitrateThresholds) {
const size_t first_active_layer = 0;
const size_t num_spatial_layers = 3;
std::vector<SpatialLayer> spatial_layers = GetSvcConfig(
kMinVp9SpatialLayerLongSideLength << (num_spatial_layers - 1),
kMinVp9SpatialLayerShortSideLength << (num_spatial_layers - 1), 30,
first_active_layer, num_spatial_layers, 1, false);
EXPECT_EQ(spatial_layers.size(), num_spatial_layers);
for (const SpatialLayer& layer : spatial_layers) {
EXPECT_LE(layer.minBitrate, layer.maxBitrate);
EXPECT_LE(layer.minBitrate, layer.targetBitrate);
EXPECT_LE(layer.targetBitrate, layer.maxBitrate);
}
}
TEST(SvcConfig, BitrateThresholdsWithScalabilityMode) {
VideoCodec codec;
codec.codecType = kVideoCodecVP9;
codec.width = 960;
codec.height = 540;
codec.SetScalabilityMode(ScalabilityMode::kS3T3);
std::vector<SpatialLayer> spatial_layers = GetVp9SvcConfig(codec);
EXPECT_THAT(spatial_layers, ElementsAre(Field(&SpatialLayer::height, 135),
Field(&SpatialLayer::height, 270),
Field(&SpatialLayer::height, 540)));
for (const SpatialLayer& layer : spatial_layers) {
EXPECT_LE(layer.minBitrate, layer.maxBitrate);
EXPECT_LE(layer.minBitrate, layer.targetBitrate);
EXPECT_LE(layer.targetBitrate, layer.maxBitrate);
}
}
TEST(SvcConfig, ScreenSharing) {
std::vector<SpatialLayer> spatial_layers =
GetSvcConfig(1920, 1080, 30, 1, 3, 3, true);
EXPECT_EQ(spatial_layers.size(), 3UL);
for (size_t i = 0; i < 3; ++i) {
const SpatialLayer& layer = spatial_layers[i];
EXPECT_EQ(layer.width, 1920);
EXPECT_EQ(layer.height, 1080);
EXPECT_EQ(layer.maxFramerate, (i < 1) ? 5 : (i < 2 ? 10 : 30));
EXPECT_EQ(layer.numberOfTemporalLayers, 1);
EXPECT_LE(layer.minBitrate, layer.maxBitrate);
EXPECT_LE(layer.minBitrate, layer.targetBitrate);
EXPECT_LE(layer.targetBitrate, layer.maxBitrate);
}
}
} // namespace webrtc