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webrtc / src / / c46385c346d5a98b83ecef16bd4b4aa219a61d71 / . / modules / video_coding / rtp_frame_reference_finder_unittest.cc
blob: e103023420bdcca194d1595d1b7f3a4d86d39456 [file] [log] [blame]
/*
* Copyright (c) 2016 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 <cstring>
#include <limits>
#include <map>
#include <set>
#include <utility>
#include <vector>
#include "modules/video_coding/frame_object.h"
#include "modules/video_coding/packet_buffer.h"
#include "modules/video_coding/rtp_frame_reference_finder.h"
#include "rtc_base/random.h"
#include "rtc_base/ref_count.h"
#include "system_wrappers/include/clock.h"
#include "test/gtest.h"
namespace webrtc {
namespace video_coding {
namespace {
std::unique_ptr<RtpFrameObject> CreateFrame(
uint16_t seq_num_start,
uint16_t seq_num_end,
bool keyframe,
VideoCodecType codec,
const RTPVideoTypeHeader& video_type_header,
const FrameMarking& frame_markings) {
RTPVideoHeader video_header;
video_header.frame_type = keyframe ? VideoFrameType::kVideoFrameKey
: VideoFrameType::kVideoFrameDelta;
video_header.video_type_header = video_type_header;
video_header.frame_marking = frame_markings;
// clang-format off
return std::make_unique<RtpFrameObject>(
seq_num_start,
seq_num_end,
/*markerBit=*/true,
/*times_nacked=*/0,
/*first_packet_received_time=*/0,
/*last_packet_received_time=*/0,
/*rtp_timestamp=*/0,
/*ntp_time_ms=*/0,
VideoSendTiming(),
/*payload_type=*/0,
codec,
kVideoRotation_0,
VideoContentType::UNSPECIFIED,
video_header,
/*color_space=*/absl::nullopt,
RtpPacketInfos(),
EncodedImageBuffer::Create(/*size=*/0));
// clang-format on
}
} // namespace
class TestRtpFrameReferenceFinder : public ::testing::Test,
public OnCompleteFrameCallback {
protected:
TestRtpFrameReferenceFinder()
: rand_(0x8739211),
reference_finder_(new RtpFrameReferenceFinder(this)),
frames_from_callback_(FrameComp()) {}
uint16_t Rand() { return rand_.Rand<uint16_t>(); }
void OnCompleteFrame(std::unique_ptr<EncodedFrame> frame) override {
int64_t pid = frame->id.picture_id;
uint16_t sidx = frame->id.spatial_layer;
auto frame_it = frames_from_callback_.find(std::make_pair(pid, sidx));
if (frame_it != frames_from_callback_.end()) {
ADD_FAILURE() << "Already received frame with (pid:sidx): (" << pid << ":"
<< sidx << ")";
return;
}
frames_from_callback_.insert(
std::make_pair(std::make_pair(pid, sidx), std::move(frame)));
}
void InsertGeneric(uint16_t seq_num_start,
uint16_t seq_num_end,
bool keyframe) {
std::unique_ptr<RtpFrameObject> frame =
CreateFrame(seq_num_start, seq_num_end, keyframe, kVideoCodecGeneric,
RTPVideoTypeHeader(), FrameMarking());
reference_finder_->ManageFrame(std::move(frame));
}
void InsertVp8(uint16_t seq_num_start,
uint16_t seq_num_end,
bool keyframe,
int32_t pid = kNoPictureId,
uint8_t tid = kNoTemporalIdx,
int32_t tl0 = kNoTl0PicIdx,
bool sync = false) {
RTPVideoHeaderVP8 vp8_header{};
vp8_header.pictureId = pid % (1 << 15);
vp8_header.temporalIdx = tid;
vp8_header.tl0PicIdx = tl0;
vp8_header.layerSync = sync;
std::unique_ptr<RtpFrameObject> frame =
CreateFrame(seq_num_start, seq_num_end, keyframe, kVideoCodecVP8,
vp8_header, FrameMarking());
reference_finder_->ManageFrame(std::move(frame));
}
void InsertVp9Gof(uint16_t seq_num_start,
uint16_t seq_num_end,
bool keyframe,
int32_t pid = kNoPictureId,
uint8_t sid = kNoSpatialIdx,
uint8_t tid = kNoTemporalIdx,
int32_t tl0 = kNoTl0PicIdx,
bool up_switch = false,
bool inter_pic_predicted = true,
GofInfoVP9* ss = nullptr) {
RTPVideoHeaderVP9 vp9_header{};
vp9_header.flexible_mode = false;
vp9_header.picture_id = pid % (1 << 15);
vp9_header.temporal_idx = tid;
vp9_header.spatial_idx = sid;
vp9_header.tl0_pic_idx = tl0;
vp9_header.temporal_up_switch = up_switch;
vp9_header.inter_pic_predicted = inter_pic_predicted && !keyframe;
if (ss != nullptr) {
vp9_header.ss_data_available = true;
vp9_header.gof = *ss;
}
std::unique_ptr<RtpFrameObject> frame =
CreateFrame(seq_num_start, seq_num_end, keyframe, kVideoCodecVP9,
vp9_header, FrameMarking());
reference_finder_->ManageFrame(std::move(frame));
}
void InsertVp9Flex(uint16_t seq_num_start,
uint16_t seq_num_end,
bool keyframe,
int32_t pid = kNoPictureId,
uint8_t sid = kNoSpatialIdx,
uint8_t tid = kNoTemporalIdx,
bool inter = false,
std::vector<uint8_t> refs = std::vector<uint8_t>()) {
RTPVideoHeaderVP9 vp9_header{};
vp9_header.inter_layer_predicted = inter;
vp9_header.flexible_mode = true;
vp9_header.picture_id = pid % (1 << 15);
vp9_header.temporal_idx = tid;
vp9_header.spatial_idx = sid;
vp9_header.tl0_pic_idx = kNoTl0PicIdx;
vp9_header.num_ref_pics = refs.size();
for (size_t i = 0; i < refs.size(); ++i)
vp9_header.pid_diff[i] = refs[i];
std::unique_ptr<RtpFrameObject> frame =
CreateFrame(seq_num_start, seq_num_end, keyframe, kVideoCodecVP9,
vp9_header, FrameMarking());
reference_finder_->ManageFrame(std::move(frame));
}
void InsertH264(uint16_t seq_num_start,
uint16_t seq_num_end,
bool keyframe,
uint8_t tid = kNoTemporalIdx,
int32_t tl0 = kNoTl0PicIdx,
bool sync = false) {
FrameMarking frame_marking{};
frame_marking.temporal_id = tid;
frame_marking.tl0_pic_idx = tl0;
frame_marking.base_layer_sync = sync;
std::unique_ptr<RtpFrameObject> frame =
CreateFrame(seq_num_start, seq_num_end, keyframe, kVideoCodecH264,
RTPVideoTypeHeader(), frame_marking);
reference_finder_->ManageFrame(std::move(frame));
}
// Check if a frame with picture id |pid| and spatial index |sidx| has been
// delivered from the packet buffer, and if so, if it has the references
// specified by |refs|.
template <typename... T>
void CheckReferences(int64_t picture_id_offset,
uint16_t sidx,
T... refs) const {
int64_t pid = picture_id_offset;
auto frame_it = frames_from_callback_.find(std::make_pair(pid, sidx));
if (frame_it == frames_from_callback_.end()) {
ADD_FAILURE() << "Could not find frame with (pid:sidx): (" << pid << ":"
<< sidx << ")";
return;
}
std::set<int64_t> actual_refs;
for (uint8_t r = 0; r < frame_it->second->num_references; ++r)
actual_refs.insert(frame_it->second->references[r]);
std::set<int64_t> expected_refs;
RefsToSet(&expected_refs, refs...);
ASSERT_EQ(expected_refs, actual_refs);
}
template <typename... T>
void CheckReferencesGeneric(int64_t pid, T... refs) const {
CheckReferences(pid, 0, refs...);
}
template <typename... T>
void CheckReferencesVp8(int64_t pid, T... refs) const {
CheckReferences(pid, 0, refs...);
}
template <typename... T>
void CheckReferencesVp9(int64_t pid, uint8_t sidx, T... refs) const {
CheckReferences(pid, sidx, refs...);
}
template <typename... T>
void CheckReferencesH264(int64_t pid, T... refs) const {
CheckReferences(pid, 0, refs...);
}
template <typename... T>
void RefsToSet(std::set<int64_t>* m, int64_t ref, T... refs) const {
m->insert(ref);
RefsToSet(m, refs...);
}
void RefsToSet(std::set<int64_t>* m) const {}
Random rand_;
std::unique_ptr<RtpFrameReferenceFinder> reference_finder_;
struct FrameComp {
bool operator()(const std::pair<int64_t, uint8_t> f1,
const std::pair<int64_t, uint8_t> f2) const {
if (f1.first == f2.first)
return f1.second < f2.second;
return f1.first < f2.first;
}
};
std::
map<std::pair<int64_t, uint8_t>, std::unique_ptr<EncodedFrame>, FrameComp>
frames_from_callback_;
};
TEST_F(TestRtpFrameReferenceFinder, PaddingPackets) {
uint16_t sn = Rand();
InsertGeneric(sn, sn, true);
InsertGeneric(sn + 2, sn + 2, false);
EXPECT_EQ(1UL, frames_from_callback_.size());
reference_finder_->PaddingReceived(sn + 1);
EXPECT_EQ(2UL, frames_from_callback_.size());
}
TEST_F(TestRtpFrameReferenceFinder, PaddingPacketsReordered) {
uint16_t sn = Rand();
InsertGeneric(sn, sn, true);
reference_finder_->PaddingReceived(sn + 1);
reference_finder_->PaddingReceived(sn + 4);
InsertGeneric(sn + 2, sn + 3, false);
EXPECT_EQ(2UL, frames_from_callback_.size());
CheckReferencesGeneric(sn);
CheckReferencesGeneric(sn + 3, sn + 0);
}
TEST_F(TestRtpFrameReferenceFinder, PaddingPacketsReorderedMultipleKeyframes) {
uint16_t sn = Rand();
InsertGeneric(sn, sn, true);
reference_finder_->PaddingReceived(sn + 1);
reference_finder_->PaddingReceived(sn + 4);
InsertGeneric(sn + 2, sn + 3, false);
InsertGeneric(sn + 5, sn + 5, true);
reference_finder_->PaddingReceived(sn + 6);
reference_finder_->PaddingReceived(sn + 9);
InsertGeneric(sn + 7, sn + 8, false);
EXPECT_EQ(4UL, frames_from_callback_.size());
}
TEST_F(TestRtpFrameReferenceFinder, AdvanceSavedKeyframe) {
uint16_t sn = Rand();
InsertGeneric(sn, sn, true);
InsertGeneric(sn + 1, sn + 1, true);
InsertGeneric(sn + 2, sn + 10000, false);
InsertGeneric(sn + 10001, sn + 20000, false);
InsertGeneric(sn + 20001, sn + 30000, false);
InsertGeneric(sn + 30001, sn + 40000, false);
EXPECT_EQ(6UL, frames_from_callback_.size());
}
TEST_F(TestRtpFrameReferenceFinder, ClearTo) {
uint16_t sn = Rand();
InsertGeneric(sn, sn + 1, true);
InsertGeneric(sn + 4, sn + 5, false); // stashed
EXPECT_EQ(1UL, frames_from_callback_.size());
InsertGeneric(sn + 6, sn + 7, true); // keyframe
EXPECT_EQ(2UL, frames_from_callback_.size());
reference_finder_->ClearTo(sn + 7);
InsertGeneric(sn + 8, sn + 9, false); // first frame after keyframe.
EXPECT_EQ(3UL, frames_from_callback_.size());
InsertGeneric(sn + 2, sn + 3, false); // late, cleared past this frame.
EXPECT_EQ(3UL, frames_from_callback_.size());
}
TEST_F(TestRtpFrameReferenceFinder, Vp8NoPictureId) {
uint16_t sn = Rand();
InsertVp8(sn, sn + 2, true);
ASSERT_EQ(1UL, frames_from_callback_.size());
InsertVp8(sn + 3, sn + 4, false);
ASSERT_EQ(2UL, frames_from_callback_.size());
InsertVp8(sn + 5, sn + 8, false);
ASSERT_EQ(3UL, frames_from_callback_.size());
InsertVp8(sn + 9, sn + 9, false);
ASSERT_EQ(4UL, frames_from_callback_.size());
InsertVp8(sn + 10, sn + 11, false);
ASSERT_EQ(5UL, frames_from_callback_.size());
InsertVp8(sn + 12, sn + 12, true);
ASSERT_EQ(6UL, frames_from_callback_.size());
InsertVp8(sn + 13, sn + 17, false);
ASSERT_EQ(7UL, frames_from_callback_.size());
InsertVp8(sn + 18, sn + 18, false);
ASSERT_EQ(8UL, frames_from_callback_.size());
InsertVp8(sn + 19, sn + 20, false);
ASSERT_EQ(9UL, frames_from_callback_.size());
InsertVp8(sn + 21, sn + 21, false);
ASSERT_EQ(10UL, frames_from_callback_.size());
CheckReferencesVp8(sn + 2);
CheckReferencesVp8(sn + 4, sn + 2);
CheckReferencesVp8(sn + 8, sn + 4);
CheckReferencesVp8(sn + 9, sn + 8);
CheckReferencesVp8(sn + 11, sn + 9);
CheckReferencesVp8(sn + 12);
CheckReferencesVp8(sn + 17, sn + 12);
CheckReferencesVp8(sn + 18, sn + 17);
CheckReferencesVp8(sn + 20, sn + 18);
CheckReferencesVp8(sn + 21, sn + 20);
}
TEST_F(TestRtpFrameReferenceFinder, Vp8NoPictureIdReordered) {
uint16_t sn = 0xfffa;
InsertVp8(sn, sn + 2, true);
InsertVp8(sn + 3, sn + 4, false);
InsertVp8(sn + 5, sn + 8, false);
InsertVp8(sn + 9, sn + 9, false);
InsertVp8(sn + 10, sn + 11, false);
InsertVp8(sn + 12, sn + 12, true);
InsertVp8(sn + 13, sn + 17, false);
InsertVp8(sn + 18, sn + 18, false);
InsertVp8(sn + 19, sn + 20, false);
InsertVp8(sn + 21, sn + 21, false);
ASSERT_EQ(10UL, frames_from_callback_.size());
CheckReferencesVp8(sn + 2);
CheckReferencesVp8(sn + 4, sn + 2);
CheckReferencesVp8(sn + 8, sn + 4);
CheckReferencesVp8(sn + 9, sn + 8);
CheckReferencesVp8(sn + 11, sn + 9);
CheckReferencesVp8(sn + 12);
CheckReferencesVp8(sn + 17, sn + 12);
CheckReferencesVp8(sn + 18, sn + 17);
CheckReferencesVp8(sn + 20, sn + 18);
CheckReferencesVp8(sn + 21, sn + 20);
}
TEST_F(TestRtpFrameReferenceFinder, Vp8KeyFrameReferences) {
uint16_t sn = Rand();
InsertVp8(sn, sn, true);
ASSERT_EQ(1UL, frames_from_callback_.size());
CheckReferencesVp8(sn);
}
// Test with 1 temporal layer.
TEST_F(TestRtpFrameReferenceFinder, Vp8TemporalLayers_0) {
uint16_t pid = Rand();
uint16_t sn = Rand();
InsertVp8(sn, sn, true, pid, 0, 1);
InsertVp8(sn + 1, sn + 1, false, pid + 1, 0, 2);
InsertVp8(sn + 2, sn + 2, false, pid + 2, 0, 3);
InsertVp8(sn + 3, sn + 3, false, pid + 3, 0, 4);
ASSERT_EQ(4UL, frames_from_callback_.size());
CheckReferencesVp8(pid);
CheckReferencesVp8(pid + 1, pid);
CheckReferencesVp8(pid + 2, pid + 1);
CheckReferencesVp8(pid + 3, pid + 2);
}
TEST_F(TestRtpFrameReferenceFinder, Vp8DuplicateTl1Frames) {
uint16_t pid = Rand();
uint16_t sn = Rand();
InsertVp8(sn, sn, true, pid, 0, 0);
InsertVp8(sn + 1, sn + 1, false, pid + 1, 1, 0, true);
InsertVp8(sn + 2, sn + 2, false, pid + 2, 0, 1);
InsertVp8(sn + 3, sn + 3, false, pid + 3, 1, 1);
InsertVp8(sn + 3, sn + 3, false, pid + 3, 1, 1);
InsertVp8(sn + 4, sn + 4, false, pid + 4, 0, 2);
InsertVp8(sn + 5, sn + 5, false, pid + 5, 1, 2);
ASSERT_EQ(6UL, frames_from_callback_.size());
CheckReferencesVp8(pid);
CheckReferencesVp8(pid + 1, pid);
CheckReferencesVp8(pid + 2, pid);
CheckReferencesVp8(pid + 3, pid + 1, pid + 2);
CheckReferencesVp8(pid + 4, pid + 2);
CheckReferencesVp8(pid + 5, pid + 3, pid + 4);
}
// Test with 1 temporal layer.
TEST_F(TestRtpFrameReferenceFinder, Vp8TemporalLayersReordering_0) {
uint16_t pid = Rand();
uint16_t sn = Rand();
InsertVp8(sn, sn, true, pid, 0, 1);
InsertVp8(sn + 1, sn + 1, false, pid + 1, 0, 2);
InsertVp8(sn + 3, sn + 3, false, pid + 3, 0, 4);
InsertVp8(sn + 2, sn + 2, false, pid + 2, 0, 3);
InsertVp8(sn + 5, sn + 5, false, pid + 5, 0, 6);
InsertVp8(sn + 6, sn + 6, false, pid + 6, 0, 7);
InsertVp8(sn + 4, sn + 4, false, pid + 4, 0, 5);
ASSERT_EQ(7UL, frames_from_callback_.size());
CheckReferencesVp8(pid);
CheckReferencesVp8(pid + 1, pid);
CheckReferencesVp8(pid + 2, pid + 1);
CheckReferencesVp8(pid + 3, pid + 2);
CheckReferencesVp8(pid + 4, pid + 3);
CheckReferencesVp8(pid + 5, pid + 4);
CheckReferencesVp8(pid + 6, pid + 5);
}
// Test with 2 temporal layers in a 01 pattern.
TEST_F(TestRtpFrameReferenceFinder, Vp8TemporalLayers_01) {
uint16_t pid = Rand();
uint16_t sn = Rand();
InsertVp8(sn, sn, true, pid, 0, 255);
InsertVp8(sn + 1, sn + 1, false, pid + 1, 1, 255, true);
InsertVp8(sn + 2, sn + 2, false, pid + 2, 0, 0);
InsertVp8(sn + 3, sn + 3, false, pid + 3, 1, 0);
ASSERT_EQ(4UL, frames_from_callback_.size());
CheckReferencesVp8(pid);
CheckReferencesVp8(pid + 1, pid);
CheckReferencesVp8(pid + 2, pid);
CheckReferencesVp8(pid + 3, pid + 1, pid + 2);
}
// Test with 2 temporal layers in a 01 pattern.
TEST_F(TestRtpFrameReferenceFinder, Vp8TemporalLayersReordering_01) {
uint16_t pid = Rand();
uint16_t sn = Rand();
InsertVp8(sn + 1, sn + 1, false, pid + 1, 1, 255, true);
InsertVp8(sn, sn, true, pid, 0, 255);
InsertVp8(sn + 3, sn + 3, false, pid + 3, 1, 0);
InsertVp8(sn + 5, sn + 5, false, pid + 5, 1, 1);
InsertVp8(sn + 2, sn + 2, false, pid + 2, 0, 0);
InsertVp8(sn + 4, sn + 4, false, pid + 4, 0, 1);
InsertVp8(sn + 6, sn + 6, false, pid + 6, 0, 2);
InsertVp8(sn + 7, sn + 7, false, pid + 7, 1, 2);
ASSERT_EQ(8UL, frames_from_callback_.size());
CheckReferencesVp8(pid);
CheckReferencesVp8(pid + 1, pid);
CheckReferencesVp8(pid + 2, pid);
CheckReferencesVp8(pid + 3, pid + 1, pid + 2);
CheckReferencesVp8(pid + 4, pid + 2);
CheckReferencesVp8(pid + 5, pid + 3, pid + 4);
CheckReferencesVp8(pid + 6, pid + 4);
CheckReferencesVp8(pid + 7, pid + 5, pid + 6);
}
// Test with 3 temporal layers in a 0212 pattern.
TEST_F(TestRtpFrameReferenceFinder, Vp8TemporalLayers_0212) {
uint16_t pid = Rand();
uint16_t sn = Rand();
InsertVp8(sn, sn, true, pid, 0, 55);
InsertVp8(sn + 1, sn + 1, false, pid + 1, 2, 55, true);
InsertVp8(sn + 2, sn + 2, false, pid + 2, 1, 55, true);
InsertVp8(sn + 3, sn + 3, false, pid + 3, 2, 55);
InsertVp8(sn + 4, sn + 4, false, pid + 4, 0, 56);
InsertVp8(sn + 5, sn + 5, false, pid + 5, 2, 56);
InsertVp8(sn + 6, sn + 6, false, pid + 6, 1, 56);
InsertVp8(sn + 7, sn + 7, false, pid + 7, 2, 56);
InsertVp8(sn + 8, sn + 8, false, pid + 8, 0, 57);
InsertVp8(sn + 9, sn + 9, false, pid + 9, 2, 57, true);
InsertVp8(sn + 10, sn + 10, false, pid + 10, 1, 57, true);
InsertVp8(sn + 11, sn + 11, false, pid + 11, 2, 57);
ASSERT_EQ(12UL, frames_from_callback_.size());
CheckReferencesVp8(pid);
CheckReferencesVp8(pid + 1, pid);
CheckReferencesVp8(pid + 2, pid);
CheckReferencesVp8(pid + 3, pid, pid + 1, pid + 2);
CheckReferencesVp8(pid + 4, pid);
CheckReferencesVp8(pid + 5, pid + 2, pid + 3, pid + 4);
CheckReferencesVp8(pid + 6, pid + 2, pid + 4);
CheckReferencesVp8(pid + 7, pid + 4, pid + 5, pid + 6);
CheckReferencesVp8(pid + 8, pid + 4);
CheckReferencesVp8(pid + 9, pid + 8);
CheckReferencesVp8(pid + 10, pid + 8);
CheckReferencesVp8(pid + 11, pid + 8, pid + 9, pid + 10);
}
// Test with 3 temporal layers in a 0212 pattern.
TEST_F(TestRtpFrameReferenceFinder, Vp8TemporalLayersMissingFrame_0212) {
uint16_t pid = Rand();
uint16_t sn = Rand();
InsertVp8(sn, sn, true, pid, 0, 55, false);
InsertVp8(sn + 2, sn + 2, false, pid + 2, 1, 55, true);
InsertVp8(sn + 3, sn + 3, false, pid + 3, 2, 55, false);
ASSERT_EQ(2UL, frames_from_callback_.size());
CheckReferencesVp8(pid);
CheckReferencesVp8(pid + 2, pid);
}
// Test with 3 temporal layers in a 0212 pattern.
TEST_F(TestRtpFrameReferenceFinder, Vp8TemporalLayersReordering_0212) {
uint16_t pid = 126;
uint16_t sn = Rand();
InsertVp8(sn + 1, sn + 1, false, pid + 1, 2, 55, true);
InsertVp8(sn, sn, true, pid, 0, 55, false);
InsertVp8(sn + 2, sn + 2, false, pid + 2, 1, 55, true);
InsertVp8(sn + 4, sn + 4, false, pid + 4, 0, 56, false);
InsertVp8(sn + 5, sn + 5, false, pid + 5, 2, 56, false);
InsertVp8(sn + 3, sn + 3, false, pid + 3, 2, 55, false);
InsertVp8(sn + 7, sn + 7, false, pid + 7, 2, 56, false);
InsertVp8(sn + 9, sn + 9, false, pid + 9, 2, 57, true);
InsertVp8(sn + 6, sn + 6, false, pid + 6, 1, 56, false);
InsertVp8(sn + 8, sn + 8, false, pid + 8, 0, 57, false);
InsertVp8(sn + 11, sn + 11, false, pid + 11, 2, 57, false);
InsertVp8(sn + 10, sn + 10, false, pid + 10, 1, 57, true);
ASSERT_EQ(12UL, frames_from_callback_.size());
CheckReferencesVp8(pid);
CheckReferencesVp8(pid + 1, pid);
CheckReferencesVp8(pid + 2, pid);
CheckReferencesVp8(pid + 3, pid, pid + 1, pid + 2);
CheckReferencesVp8(pid + 4, pid);
CheckReferencesVp8(pid + 5, pid + 2, pid + 3, pid + 4);
CheckReferencesVp8(pid + 6, pid + 2, pid + 4);
CheckReferencesVp8(pid + 7, pid + 4, pid + 5, pid + 6);
CheckReferencesVp8(pid + 8, pid + 4);
CheckReferencesVp8(pid + 9, pid + 8);
CheckReferencesVp8(pid + 10, pid + 8);
CheckReferencesVp8(pid + 11, pid + 8, pid + 9, pid + 10);
}
TEST_F(TestRtpFrameReferenceFinder, Vp8InsertManyFrames_0212) {
uint16_t pid = Rand();
uint16_t sn = Rand();
const int keyframes_to_insert = 50;
const int frames_per_keyframe = 120; // Should be a multiple of 4.
uint8_t tl0 = 128;
for (int k = 0; k < keyframes_to_insert; ++k) {
InsertVp8(sn, sn, true, pid, 0, tl0, false);
InsertVp8(sn + 1, sn + 1, false, pid + 1, 2, tl0, true);
InsertVp8(sn + 2, sn + 2, false, pid + 2, 1, tl0, true);
InsertVp8(sn + 3, sn + 3, false, pid + 3, 2, tl0, false);
CheckReferencesVp8(pid);
CheckReferencesVp8(pid + 1, pid);
CheckReferencesVp8(pid + 2, pid);
CheckReferencesVp8(pid + 3, pid, pid + 1, pid + 2);
frames_from_callback_.clear();
++tl0;
for (int f = 4; f < frames_per_keyframe; f += 4) {
uint16_t sf = sn + f;
int64_t pidf = pid + f;
InsertVp8(sf, sf, false, pidf, 0, tl0, false);
InsertVp8(sf + 1, sf + 1, false, pidf + 1, 2, tl0, false);
InsertVp8(sf + 2, sf + 2, false, pidf + 2, 1, tl0, false);
InsertVp8(sf + 3, sf + 3, false, pidf + 3, 2, tl0, false);
CheckReferencesVp8(pidf, pidf - 4);
CheckReferencesVp8(pidf + 1, pidf, pidf - 1, pidf - 2);
CheckReferencesVp8(pidf + 2, pidf, pidf - 2);
CheckReferencesVp8(pidf + 3, pidf, pidf + 1, pidf + 2);
frames_from_callback_.clear();
++tl0;
}
pid += frames_per_keyframe;
sn += frames_per_keyframe;
}
}
TEST_F(TestRtpFrameReferenceFinder, Vp8LayerSync) {
uint16_t pid = Rand();
uint16_t sn = Rand();
InsertVp8(sn, sn, true, pid, 0, 0, false);
InsertVp8(sn + 1, sn + 1, false, pid + 1, 1, 0, true);
InsertVp8(sn + 2, sn + 2, false, pid + 2, 0, 1, false);
ASSERT_EQ(3UL, frames_from_callback_.size());
InsertVp8(sn + 4, sn + 4, false, pid + 4, 0, 2, false);
InsertVp8(sn + 5, sn + 5, false, pid + 5, 1, 2, true);
InsertVp8(sn + 6, sn + 6, false, pid + 6, 0, 3, false);
InsertVp8(sn + 7, sn + 7, false, pid + 7, 1, 3, false);
ASSERT_EQ(7UL, frames_from_callback_.size());
CheckReferencesVp8(pid);
CheckReferencesVp8(pid + 1, pid);
CheckReferencesVp8(pid + 2, pid);
CheckReferencesVp8(pid + 4, pid + 2);
CheckReferencesVp8(pid + 5, pid + 4);
CheckReferencesVp8(pid + 6, pid + 4);
CheckReferencesVp8(pid + 7, pid + 6, pid + 5);
}
TEST_F(TestRtpFrameReferenceFinder, Vp8Tl1SyncFrameAfterTl1Frame) {
InsertVp8(1000, 1000, true, 1, 0, 247, true);
InsertVp8(1001, 1001, false, 3, 0, 248, false);
InsertVp8(1002, 1002, false, 4, 1, 248, false); // Will be dropped
InsertVp8(1003, 1003, false, 5, 1, 248, true); // due to this frame.
ASSERT_EQ(3UL, frames_from_callback_.size());
CheckReferencesVp8(1);
CheckReferencesVp8(3, 1);
CheckReferencesVp8(5, 3);
}
TEST_F(TestRtpFrameReferenceFinder, Vp8DetectMissingFrame_0212) {
InsertVp8(1, 1, true, 1, 0, 1, false);
InsertVp8(2, 2, false, 2, 2, 1, true);
InsertVp8(3, 3, false, 3, 1, 1, true);
InsertVp8(4, 4, false, 4, 2, 1, false);
InsertVp8(6, 6, false, 6, 2, 2, false);
InsertVp8(7, 7, false, 7, 1, 2, false);
InsertVp8(8, 8, false, 8, 2, 2, false);
ASSERT_EQ(4UL, frames_from_callback_.size());
InsertVp8(5, 5, false, 5, 0, 2, false);
ASSERT_EQ(8UL, frames_from_callback_.size());
CheckReferencesVp8(1);
CheckReferencesVp8(2, 1);
CheckReferencesVp8(3, 1);
CheckReferencesVp8(4, 3, 2, 1);
CheckReferencesVp8(5, 1);
CheckReferencesVp8(6, 5, 4, 3);
CheckReferencesVp8(7, 5, 3);
CheckReferencesVp8(8, 7, 6, 5);
}
TEST_F(TestRtpFrameReferenceFinder, Vp9GofInsertOneFrame) {
uint16_t pid = Rand();
uint16_t sn = Rand();
GofInfoVP9 ss;
ss.SetGofInfoVP9(kTemporalStructureMode1);
InsertVp9Gof(sn, sn, true, pid, 0, 0, 0, false, false, &ss);
CheckReferencesVp9(pid, 0);
}
TEST_F(TestRtpFrameReferenceFinder, Vp9NoPictureIdReordered) {
uint16_t sn = 0xfffa;
InsertVp9Gof(sn, sn + 2, true);
InsertVp9Gof(sn + 3, sn + 4, false);
InsertVp9Gof(sn + 9, sn + 9, false);
InsertVp9Gof(sn + 5, sn + 8, false);
InsertVp9Gof(sn + 12, sn + 12, true);
InsertVp9Gof(sn + 10, sn + 11, false);
InsertVp9Gof(sn + 13, sn + 17, false);
InsertVp9Gof(sn + 19, sn + 20, false);
InsertVp9Gof(sn + 21, sn + 21, false);
InsertVp9Gof(sn + 18, sn + 18, false);
ASSERT_EQ(10UL, frames_from_callback_.size());
CheckReferencesVp9(sn + 2, 0);
CheckReferencesVp9(sn + 4, 0, sn + 2);
CheckReferencesVp9(sn + 8, 0, sn + 4);
CheckReferencesVp9(sn + 9, 0, sn + 8);
CheckReferencesVp9(sn + 11, 0, sn + 9);
CheckReferencesVp9(sn + 12, 0);
CheckReferencesVp9(sn + 17, 0, sn + 12);
CheckReferencesVp9(sn + 18, 0, sn + 17);
CheckReferencesVp9(sn + 20, 0, sn + 18);
CheckReferencesVp9(sn + 21, 0, sn + 20);
}
TEST_F(TestRtpFrameReferenceFinder, Vp9GofTemporalLayers_0) {
uint16_t pid = Rand();
uint16_t sn = Rand();
GofInfoVP9 ss;
ss.SetGofInfoVP9(kTemporalStructureMode1); // Only 1 spatial layer.
InsertVp9Gof(sn, sn, true, pid, 0, 0, 0, false, false, &ss);
InsertVp9Gof(sn + 1, sn + 1, false, pid + 1, 0, 0, 1, false);
InsertVp9Gof(sn + 2, sn + 2, false, pid + 2, 0, 0, 2, false);
InsertVp9Gof(sn + 3, sn + 3, false, pid + 3, 0, 0, 3, false);
InsertVp9Gof(sn + 4, sn + 4, false, pid + 4, 0, 0, 4, false);
InsertVp9Gof(sn + 5, sn + 5, false, pid + 5, 0, 0, 5, false);
InsertVp9Gof(sn + 6, sn + 6, false, pid + 6, 0, 0, 6, false);
InsertVp9Gof(sn + 7, sn + 7, false, pid + 7, 0, 0, 7, false);
InsertVp9Gof(sn + 8, sn + 8, false, pid + 8, 0, 0, 8, false);
InsertVp9Gof(sn + 9, sn + 9, false, pid + 9, 0, 0, 9, false);
InsertVp9Gof(sn + 10, sn + 10, false, pid + 10, 0, 0, 10, false);
InsertVp9Gof(sn + 11, sn + 11, false, pid + 11, 0, 0, 11, false);
InsertVp9Gof(sn + 12, sn + 12, false, pid + 12, 0, 0, 12, false);
InsertVp9Gof(sn + 13, sn + 13, false, pid + 13, 0, 0, 13, false);
InsertVp9Gof(sn + 14, sn + 14, false, pid + 14, 0, 0, 14, false);
InsertVp9Gof(sn + 15, sn + 15, false, pid + 15, 0, 0, 15, false);
InsertVp9Gof(sn + 16, sn + 16, false, pid + 16, 0, 0, 16, false);
InsertVp9Gof(sn + 17, sn + 17, false, pid + 17, 0, 0, 17, false);
InsertVp9Gof(sn + 18, sn + 18, false, pid + 18, 0, 0, 18, false);
InsertVp9Gof(sn + 19, sn + 19, false, pid + 19, 0, 0, 19, false);
ASSERT_EQ(20UL, frames_from_callback_.size());
CheckReferencesVp9(pid, 0);
CheckReferencesVp9(pid + 1, 0, pid);
CheckReferencesVp9(pid + 2, 0, pid + 1);
CheckReferencesVp9(pid + 3, 0, pid + 2);
CheckReferencesVp9(pid + 4, 0, pid + 3);
CheckReferencesVp9(pid + 5, 0, pid + 4);
CheckReferencesVp9(pid + 6, 0, pid + 5);
CheckReferencesVp9(pid + 7, 0, pid + 6);
CheckReferencesVp9(pid + 8, 0, pid + 7);
CheckReferencesVp9(pid + 9, 0, pid + 8);
CheckReferencesVp9(pid + 10, 0, pid + 9);
CheckReferencesVp9(pid + 11, 0, pid + 10);
CheckReferencesVp9(pid + 12, 0, pid + 11);
CheckReferencesVp9(pid + 13, 0, pid + 12);
CheckReferencesVp9(pid + 14, 0, pid + 13);
CheckReferencesVp9(pid + 15, 0, pid + 14);
CheckReferencesVp9(pid + 16, 0, pid + 15);
CheckReferencesVp9(pid + 17, 0, pid + 16);
CheckReferencesVp9(pid + 18, 0, pid + 17);
CheckReferencesVp9(pid + 19, 0, pid + 18);
}
TEST_F(TestRtpFrameReferenceFinder, Vp9GofSpatialLayers_2) {
uint16_t pid = Rand();
uint16_t sn = Rand();
GofInfoVP9 ss;
ss.SetGofInfoVP9(kTemporalStructureMode1); // Only 1 spatial layer.
InsertVp9Gof(sn, sn, true, pid, 0, 0, 0, false, false, &ss);
InsertVp9Gof(sn + 1, sn + 1, false, pid + 1, 0, 0, 1, false, true);
// Not inter_pic_predicted because it's the first frame with this layer.
InsertVp9Gof(sn + 2, sn + 2, false, pid + 1, 1, 0, 1, false, false);
InsertVp9Gof(sn + 3, sn + 3, false, pid + 2, 0, 0, 1, false, true);
InsertVp9Gof(sn + 4, sn + 4, false, pid + 2, 1, 0, 1, false, true);
ASSERT_EQ(5UL, frames_from_callback_.size());
CheckReferencesVp9(pid, 0);
CheckReferencesVp9(pid + 1, 0, pid);
CheckReferencesVp9(pid + 1, 1);
CheckReferencesVp9(pid + 2, 0, pid + 1);
CheckReferencesVp9(pid + 2, 1, pid + 1);
}
TEST_F(TestRtpFrameReferenceFinder, Vp9GofTemporalLayersReordered_0) {
uint16_t pid = Rand();
uint16_t sn = Rand();
GofInfoVP9 ss;
ss.SetGofInfoVP9(kTemporalStructureMode1); // Only 1 spatial layer.
InsertVp9Gof(sn + 2, sn + 2, false, pid + 2, 0, 0, 2, false);
InsertVp9Gof(sn + 1, sn + 1, false, pid + 1, 0, 0, 1, false);
InsertVp9Gof(sn, sn, true, pid, 0, 0, 0, false, false, &ss);
InsertVp9Gof(sn + 4, sn + 4, false, pid + 4, 0, 0, 4, false);
InsertVp9Gof(sn + 3, sn + 3, false, pid + 3, 0, 0, 3, false);
InsertVp9Gof(sn + 5, sn + 5, false, pid + 5, 0, 0, 5, false);
InsertVp9Gof(sn + 7, sn + 7, false, pid + 7, 0, 0, 7, false);
InsertVp9Gof(sn + 6, sn + 6, false, pid + 6, 0, 0, 6, false);
InsertVp9Gof(sn + 8, sn + 8, false, pid + 8, 0, 0, 8, false);
InsertVp9Gof(sn + 10, sn + 10, false, pid + 10, 0, 0, 10, false);
InsertVp9Gof(sn + 13, sn + 13, false, pid + 13, 0, 0, 13, false);
InsertVp9Gof(sn + 11, sn + 11, false, pid + 11, 0, 0, 11, false);
InsertVp9Gof(sn + 9, sn + 9, false, pid + 9, 0, 0, 9, false);
InsertVp9Gof(sn + 16, sn + 16, false, pid + 16, 0, 0, 16, false);
InsertVp9Gof(sn + 14, sn + 14, false, pid + 14, 0, 0, 14, false);
InsertVp9Gof(sn + 15, sn + 15, false, pid + 15, 0, 0, 15, false);
InsertVp9Gof(sn + 12, sn + 12, false, pid + 12, 0, 0, 12, false);
InsertVp9Gof(sn + 17, sn + 17, false, pid + 17, 0, 0, 17, false);
InsertVp9Gof(sn + 19, sn + 19, false, pid + 19, 0, 0, 19, false);
InsertVp9Gof(sn + 18, sn + 18, false, pid + 18, 0, 0, 18, false);
ASSERT_EQ(20UL, frames_from_callback_.size());
CheckReferencesVp9(pid, 0);
CheckReferencesVp9(pid + 1, 0, pid);
CheckReferencesVp9(pid + 2, 0, pid + 1);
CheckReferencesVp9(pid + 3, 0, pid + 2);
CheckReferencesVp9(pid + 4, 0, pid + 3);
CheckReferencesVp9(pid + 5, 0, pid + 4);
CheckReferencesVp9(pid + 6, 0, pid + 5);
CheckReferencesVp9(pid + 7, 0, pid + 6);
CheckReferencesVp9(pid + 8, 0, pid + 7);
CheckReferencesVp9(pid + 9, 0, pid + 8);
CheckReferencesVp9(pid + 10, 0, pid + 9);
CheckReferencesVp9(pid + 11, 0, pid + 10);
CheckReferencesVp9(pid + 12, 0, pid + 11);
CheckReferencesVp9(pid + 13, 0, pid + 12);
CheckReferencesVp9(pid + 14, 0, pid + 13);
CheckReferencesVp9(pid + 15, 0, pid + 14);
CheckReferencesVp9(pid + 16, 0, pid + 15);
CheckReferencesVp9(pid + 17, 0, pid + 16);
CheckReferencesVp9(pid + 18, 0, pid + 17);
CheckReferencesVp9(pid + 19, 0, pid + 18);
}
TEST_F(TestRtpFrameReferenceFinder, Vp9GofSkipFramesTemporalLayers_01) {
uint16_t pid = Rand();
uint16_t sn = Rand();
GofInfoVP9 ss;
ss.SetGofInfoVP9(kTemporalStructureMode2); // 0101 pattern
InsertVp9Gof(sn, sn, true, pid, 0, 0, 0, false, false, &ss);
InsertVp9Gof(sn + 1, sn + 1, false, pid + 1, 0, 1, 0, false);
// Skip GOF with tl0 1
InsertVp9Gof(sn + 4, sn + 4, true, pid + 4, 0, 0, 2, false, true, &ss);
InsertVp9Gof(sn + 5, sn + 5, false, pid + 5, 0, 1, 2, false);
// Skip GOF with tl0 3
// Skip GOF with tl0 4
InsertVp9Gof(sn + 10, sn + 10, false, pid + 10, 0, 0, 5, false, true, &ss);
InsertVp9Gof(sn + 11, sn + 11, false, pid + 11, 0, 1, 5, false);
ASSERT_EQ(6UL, frames_from_callback_.size());
CheckReferencesVp9(pid, 0);
CheckReferencesVp9(pid + 1, 0, pid);
CheckReferencesVp9(pid + 4, 0);
CheckReferencesVp9(pid + 5, 0, pid + 4);
CheckReferencesVp9(pid + 10, 0, pid + 8);
CheckReferencesVp9(pid + 11, 0, pid + 10);
}
TEST_F(TestRtpFrameReferenceFinder, Vp9GofSkipFramesTemporalLayers_0212) {
uint16_t pid = Rand();
uint16_t sn = Rand();
GofInfoVP9 ss;
ss.SetGofInfoVP9(kTemporalStructureMode3); // 02120212 pattern
InsertVp9Gof(sn, sn, true, pid, 0, 0, 0, false, false, &ss);
InsertVp9Gof(sn + 1, sn + 1, false, pid + 1, 0, 2, 0, false);
InsertVp9Gof(sn + 2, sn + 2, false, pid + 2, 0, 1, 0, false);
InsertVp9Gof(sn + 3, sn + 3, false, pid + 3, 0, 2, 0, false);
ASSERT_EQ(4UL, frames_from_callback_.size());
CheckReferencesVp9(pid, 0);
CheckReferencesVp9(pid + 1, 0, pid);
CheckReferencesVp9(pid + 2, 0, pid);
CheckReferencesVp9(pid + 3, 0, pid + 2);
// Skip frames with tl0 = 1
InsertVp9Gof(sn + 8, sn + 8, true, pid + 8, 0, 0, 2, false, false, &ss);
InsertVp9Gof(sn + 9, sn + 9, false, pid + 9, 0, 2, 2, false);
InsertVp9Gof(sn + 10, sn + 10, false, pid + 10, 0, 1, 2, false);
InsertVp9Gof(sn + 11, sn + 11, false, pid + 11, 0, 2, 2, false);
ASSERT_EQ(8UL, frames_from_callback_.size());
CheckReferencesVp9(pid + 8, 0);
CheckReferencesVp9(pid + 9, 0, pid + 8);
CheckReferencesVp9(pid + 10, 0, pid + 8);
CheckReferencesVp9(pid + 11, 0, pid + 10);
// Now insert frames with tl0 = 1
InsertVp9Gof(sn + 4, sn + 4, true, pid + 4, 0, 0, 1, false, true, &ss);
InsertVp9Gof(sn + 7, sn + 7, false, pid + 7, 0, 2, 1, false);
ASSERT_EQ(9UL, frames_from_callback_.size());
CheckReferencesVp9(pid + 4, 0);
// Rest of frames belonging to tl0 = 1
InsertVp9Gof(sn + 5, sn + 5, false, pid + 5, 0, 2, 1, false);
InsertVp9Gof(sn + 6, sn + 6, false, pid + 6, 0, 1, 1, true); // up-switch
ASSERT_EQ(12UL, frames_from_callback_.size());
CheckReferencesVp9(pid + 5, 0, pid + 4);
CheckReferencesVp9(pid + 6, 0, pid + 4);
CheckReferencesVp9(pid + 7, 0, pid + 6);
}
TEST_F(TestRtpFrameReferenceFinder, Vp9GofTemporalLayers_01) {
uint16_t pid = Rand();
uint16_t sn = Rand();
GofInfoVP9 ss;
ss.SetGofInfoVP9(kTemporalStructureMode2); // 0101 pattern
InsertVp9Gof(sn, sn, true, pid, 0, 0, 0, false, false, &ss);
InsertVp9Gof(sn + 1, sn + 1, false, pid + 1, 0, 1, 0, false);
InsertVp9Gof(sn + 2, sn + 2, false, pid + 2, 0, 0, 1, false);
InsertVp9Gof(sn + 3, sn + 3, false, pid + 3, 0, 1, 1, false);
InsertVp9Gof(sn + 4, sn + 4, false, pid + 4, 0, 0, 2, false);
InsertVp9Gof(sn + 5, sn + 5, false, pid + 5, 0, 1, 2, false);
InsertVp9Gof(sn + 6, sn + 6, false, pid + 6, 0, 0, 3, false);
InsertVp9Gof(sn + 7, sn + 7, false, pid + 7, 0, 1, 3, false);
InsertVp9Gof(sn + 8, sn + 8, false, pid + 8, 0, 0, 4, false);
InsertVp9Gof(sn + 9, sn + 9, false, pid + 9, 0, 1, 4, false);
InsertVp9Gof(sn + 10, sn + 10, false, pid + 10, 0, 0, 5, false);
InsertVp9Gof(sn + 11, sn + 11, false, pid + 11, 0, 1, 5, false);
InsertVp9Gof(sn + 12, sn + 12, false, pid + 12, 0, 0, 6, false);
InsertVp9Gof(sn + 13, sn + 13, false, pid + 13, 0, 1, 6, false);
InsertVp9Gof(sn + 14, sn + 14, false, pid + 14, 0, 0, 7, false);
InsertVp9Gof(sn + 15, sn + 15, false, pid + 15, 0, 1, 7, false);
InsertVp9Gof(sn + 16, sn + 16, false, pid + 16, 0, 0, 8, false);
InsertVp9Gof(sn + 17, sn + 17, false, pid + 17, 0, 1, 8, false);
InsertVp9Gof(sn + 18, sn + 18, false, pid + 18, 0, 0, 9, false);
InsertVp9Gof(sn + 19, sn + 19, false, pid + 19, 0, 1, 9, false);
ASSERT_EQ(20UL, frames_from_callback_.size());
CheckReferencesVp9(pid, 0);
CheckReferencesVp9(pid + 1, 0, pid);
CheckReferencesVp9(pid + 2, 0, pid);
CheckReferencesVp9(pid + 3, 0, pid + 2);
CheckReferencesVp9(pid + 4, 0, pid + 2);
CheckReferencesVp9(pid + 5, 0, pid + 4);
CheckReferencesVp9(pid + 6, 0, pid + 4);
CheckReferencesVp9(pid + 7, 0, pid + 6);
CheckReferencesVp9(pid + 8, 0, pid + 6);
CheckReferencesVp9(pid + 9, 0, pid + 8);
CheckReferencesVp9(pid + 10, 0, pid + 8);
CheckReferencesVp9(pid + 11, 0, pid + 10);
CheckReferencesVp9(pid + 12, 0, pid + 10);
CheckReferencesVp9(pid + 13, 0, pid + 12);
CheckReferencesVp9(pid + 14, 0, pid + 12);
CheckReferencesVp9(pid + 15, 0, pid + 14);
CheckReferencesVp9(pid + 16, 0, pid + 14);
CheckReferencesVp9(pid + 17, 0, pid + 16);
CheckReferencesVp9(pid + 18, 0, pid + 16);
CheckReferencesVp9(pid + 19, 0, pid + 18);
}
TEST_F(TestRtpFrameReferenceFinder, Vp9GofTemporalLayersReordered_01) {
uint16_t pid = Rand();
uint16_t sn = Rand();
GofInfoVP9 ss;
ss.SetGofInfoVP9(kTemporalStructureMode2); // 01 pattern
InsertVp9Gof(sn + 1, sn + 1, false, pid + 1, 0, 1, 0, false);
InsertVp9Gof(sn, sn, true, pid, 0, 0, 0, false, false, &ss);
InsertVp9Gof(sn + 2, sn + 2, false, pid + 2, 0, 0, 1, false);
InsertVp9Gof(sn + 4, sn + 4, false, pid + 4, 0, 0, 2, false);
InsertVp9Gof(sn + 3, sn + 3, false, pid + 3, 0, 1, 1, false);
InsertVp9Gof(sn + 5, sn + 5, false, pid + 5, 0, 1, 2, false);
InsertVp9Gof(sn + 7, sn + 7, false, pid + 7, 0, 1, 3, false);
InsertVp9Gof(sn + 6, sn + 6, false, pid + 6, 0, 0, 3, false);
InsertVp9Gof(sn + 10, sn + 10, false, pid + 10, 0, 0, 5, false);
InsertVp9Gof(sn + 8, sn + 8, false, pid + 8, 0, 0, 4, false);
InsertVp9Gof(sn + 9, sn + 9, false, pid + 9, 0, 1, 4, false);
InsertVp9Gof(sn + 11, sn + 11, false, pid + 11, 0, 1, 5, false);
InsertVp9Gof(sn + 13, sn + 13, false, pid + 13, 0, 1, 6, false);
InsertVp9Gof(sn + 16, sn + 16, false, pid + 16, 0, 0, 8, false);
InsertVp9Gof(sn + 12, sn + 12, false, pid + 12, 0, 0, 6, false);
InsertVp9Gof(sn + 14, sn + 14, false, pid + 14, 0, 0, 7, false);
InsertVp9Gof(sn + 17, sn + 17, false, pid + 17, 0, 1, 8, false);
InsertVp9Gof(sn + 19, sn + 19, false, pid + 19, 0, 1, 9, false);
InsertVp9Gof(sn + 15, sn + 15, false, pid + 15, 0, 1, 7, false);
InsertVp9Gof(sn + 18, sn + 18, false, pid + 18, 0, 0, 9, false);
ASSERT_EQ(20UL, frames_from_callback_.size());
CheckReferencesVp9(pid, 0);
CheckReferencesVp9(pid + 1, 0, pid);
CheckReferencesVp9(pid + 2, 0, pid);
CheckReferencesVp9(pid + 3, 0, pid + 2);
CheckReferencesVp9(pid + 4, 0, pid + 2);
CheckReferencesVp9(pid + 5, 0, pid + 4);
CheckReferencesVp9(pid + 6, 0, pid + 4);
CheckReferencesVp9(pid + 7, 0, pid + 6);
CheckReferencesVp9(pid + 8, 0, pid + 6);
CheckReferencesVp9(pid + 9, 0, pid + 8);
CheckReferencesVp9(pid + 10, 0, pid + 8);
CheckReferencesVp9(pid + 11, 0, pid + 10);
CheckReferencesVp9(pid + 12, 0, pid + 10);
CheckReferencesVp9(pid + 13, 0, pid + 12);
CheckReferencesVp9(pid + 14, 0, pid + 12);
CheckReferencesVp9(pid + 15, 0, pid + 14);
CheckReferencesVp9(pid + 16, 0, pid + 14);
CheckReferencesVp9(pid + 17, 0, pid + 16);
CheckReferencesVp9(pid + 18, 0, pid + 16);
CheckReferencesVp9(pid + 19, 0, pid + 18);
}
TEST_F(TestRtpFrameReferenceFinder, Vp9GofTemporalLayers_0212) {
uint16_t pid = Rand();
uint16_t sn = Rand();
GofInfoVP9 ss;
ss.SetGofInfoVP9(kTemporalStructureMode3); // 0212 pattern
InsertVp9Gof(sn, sn, true, pid, 0, 0, 0, false, false, &ss);
InsertVp9Gof(sn + 1, sn + 1, false, pid + 1, 0, 2, 0, false);
InsertVp9Gof(sn + 2, sn + 2, false, pid + 2, 0, 1, 0, false);
InsertVp9Gof(sn + 3, sn + 3, false, pid + 3, 0, 2, 0, false);
InsertVp9Gof(sn + 4, sn + 4, false, pid + 4, 0, 0, 1, false);
InsertVp9Gof(sn + 5, sn + 5, false, pid + 5, 0, 2, 1, false);
InsertVp9Gof(sn + 6, sn + 6, false, pid + 6, 0, 1, 1, false);
InsertVp9Gof(sn + 7, sn + 7, false, pid + 7, 0, 2, 1, false);
InsertVp9Gof(sn + 8, sn + 8, false, pid + 8, 0, 0, 2, false);
InsertVp9Gof(sn + 9, sn + 9, false, pid + 9, 0, 2, 2, false);
InsertVp9Gof(sn + 10, sn + 10, false, pid + 10, 0, 1, 2, false);
InsertVp9Gof(sn + 11, sn + 11, false, pid + 11, 0, 2, 2, false);
InsertVp9Gof(sn + 12, sn + 12, false, pid + 12, 0, 0, 3, false);
InsertVp9Gof(sn + 13, sn + 13, false, pid + 13, 0, 2, 3, false);
InsertVp9Gof(sn + 14, sn + 14, false, pid + 14, 0, 1, 3, false);
InsertVp9Gof(sn + 15, sn + 15, false, pid + 15, 0, 2, 3, false);
InsertVp9Gof(sn + 16, sn + 16, false, pid + 16, 0, 0, 4, false);
InsertVp9Gof(sn + 17, sn + 17, false, pid + 17, 0, 2, 4, false);
InsertVp9Gof(sn + 18, sn + 18, false, pid + 18, 0, 1, 4, false);
InsertVp9Gof(sn + 19, sn + 19, false, pid + 19, 0, 2, 4, false);
ASSERT_EQ(20UL, frames_from_callback_.size());
CheckReferencesVp9(pid, 0);
CheckReferencesVp9(pid + 1, 0, pid);
CheckReferencesVp9(pid + 2, 0, pid);
CheckReferencesVp9(pid + 3, 0, pid + 2);
CheckReferencesVp9(pid + 4, 0, pid);
CheckReferencesVp9(pid + 5, 0, pid + 4);
CheckReferencesVp9(pid + 6, 0, pid + 4);
CheckReferencesVp9(pid + 7, 0, pid + 6);
CheckReferencesVp9(pid + 8, 0, pid + 4);
CheckReferencesVp9(pid + 9, 0, pid + 8);
CheckReferencesVp9(pid + 10, 0, pid + 8);
CheckReferencesVp9(pid + 11, 0, pid + 10);
CheckReferencesVp9(pid + 12, 0, pid + 8);
CheckReferencesVp9(pid + 13, 0, pid + 12);
CheckReferencesVp9(pid + 14, 0, pid + 12);
CheckReferencesVp9(pid + 15, 0, pid + 14);
CheckReferencesVp9(pid + 16, 0, pid + 12);
CheckReferencesVp9(pid + 17, 0, pid + 16);
CheckReferencesVp9(pid + 18, 0, pid + 16);
CheckReferencesVp9(pid + 19, 0, pid + 18);
}
TEST_F(TestRtpFrameReferenceFinder, Vp9GofTemporalLayersReordered_0212) {
uint16_t pid = Rand();
uint16_t sn = Rand();
GofInfoVP9 ss;
ss.SetGofInfoVP9(kTemporalStructureMode3); // 0212 pattern
InsertVp9Gof(sn + 2, sn + 2, false, pid + 2, 0, 1, 0, false);
InsertVp9Gof(sn + 1, sn + 1, false, pid + 1, 0, 2, 0, false);
InsertVp9Gof(sn, sn, true, pid, 0, 0, 0, false, false, &ss);
InsertVp9Gof(sn + 3, sn + 3, false, pid + 3, 0, 2, 0, false);
InsertVp9Gof(sn + 6, sn + 6, false, pid + 6, 0, 1, 1, false);
InsertVp9Gof(sn + 5, sn + 5, false, pid + 5, 0, 2, 1, false);
InsertVp9Gof(sn + 4, sn + 4, false, pid + 4, 0, 0, 1, false);
InsertVp9Gof(sn + 9, sn + 9, false, pid + 9, 0, 2, 2, false);
InsertVp9Gof(sn + 7, sn + 7, false, pid + 7, 0, 2, 1, false);
InsertVp9Gof(sn + 8, sn + 8, false, pid + 8, 0, 0, 2, false);
InsertVp9Gof(sn + 11, sn + 11, false, pid + 11, 0, 2, 2, false);
InsertVp9Gof(sn + 10, sn + 10, false, pid + 10, 0, 1, 2, false);
InsertVp9Gof(sn + 13, sn + 13, false, pid + 13, 0, 2, 3, false);
InsertVp9Gof(sn + 12, sn + 12, false, pid + 12, 0, 0, 3, false);
InsertVp9Gof(sn + 14, sn + 14, false, pid + 14, 0, 1, 3, false);
InsertVp9Gof(sn + 16, sn + 16, false, pid + 16, 0, 0, 4, false);
InsertVp9Gof(sn + 15, sn + 15, false, pid + 15, 0, 2, 3, false);
InsertVp9Gof(sn + 17, sn + 17, false, pid + 17, 0, 2, 4, false);
InsertVp9Gof(sn + 19, sn + 19, false, pid + 19, 0, 2, 4, false);
InsertVp9Gof(sn + 18, sn + 18, false, pid + 18, 0, 1, 4, false);
ASSERT_EQ(20UL, frames_from_callback_.size());
CheckReferencesVp9(pid, 0);
CheckReferencesVp9(pid + 1, 0, pid);
CheckReferencesVp9(pid + 2, 0, pid);
CheckReferencesVp9(pid + 3, 0, pid + 2);
CheckReferencesVp9(pid + 4, 0, pid);
CheckReferencesVp9(pid + 5, 0, pid + 4);
CheckReferencesVp9(pid + 6, 0, pid + 4);
CheckReferencesVp9(pid + 7, 0, pid + 6);
CheckReferencesVp9(pid + 8, 0, pid + 4);
CheckReferencesVp9(pid + 9, 0, pid + 8);
CheckReferencesVp9(pid + 10, 0, pid + 8);
CheckReferencesVp9(pid + 11, 0, pid + 10);
CheckReferencesVp9(pid + 12, 0, pid + 8);
CheckReferencesVp9(pid + 13, 0, pid + 12);
CheckReferencesVp9(pid + 14, 0, pid + 12);
CheckReferencesVp9(pid + 15, 0, pid + 14);
CheckReferencesVp9(pid + 16, 0, pid + 12);
CheckReferencesVp9(pid + 17, 0, pid + 16);
CheckReferencesVp9(pid + 18, 0, pid + 16);
CheckReferencesVp9(pid + 19, 0, pid + 18);
}
TEST_F(TestRtpFrameReferenceFinder, Vp9GofTemporalLayersUpSwitch_02120212) {
uint16_t pid = Rand();
uint16_t sn = Rand();
GofInfoVP9 ss;
ss.SetGofInfoVP9(kTemporalStructureMode4); // 02120212 pattern
InsertVp9Gof(sn, sn, true, pid, 0, 0, 0, false, false, &ss);
InsertVp9Gof(sn + 1, sn + 1, false, pid + 1, 0, 2, 0, false);
InsertVp9Gof(sn + 2, sn + 2, false, pid + 2, 0, 1, 0, false);
InsertVp9Gof(sn + 3, sn + 3, false, pid + 3, 0, 2, 0, false);
InsertVp9Gof(sn + 4, sn + 4, false, pid + 4, 0, 0, 1, false);
InsertVp9Gof(sn + 5, sn + 5, false, pid + 5, 0, 2, 1, false);
InsertVp9Gof(sn + 6, sn + 6, false, pid + 6, 0, 1, 1, true);
InsertVp9Gof(sn + 7, sn + 7, false, pid + 7, 0, 2, 1, false);
InsertVp9Gof(sn + 8, sn + 8, false, pid + 8, 0, 0, 2, true);
InsertVp9Gof(sn + 9, sn + 9, false, pid + 9, 0, 2, 2, false);
InsertVp9Gof(sn + 10, sn + 10, false, pid + 10, 0, 1, 2, false);
InsertVp9Gof(sn + 11, sn + 11, false, pid + 11, 0, 2, 2, true);
InsertVp9Gof(sn + 12, sn + 12, false, pid + 12, 0, 0, 3, false);
InsertVp9Gof(sn + 13, sn + 13, false, pid + 13, 0, 2, 3, false);
InsertVp9Gof(sn + 14, sn + 14, false, pid + 14, 0, 1, 3, false);
InsertVp9Gof(sn + 15, sn + 15, false, pid + 15, 0, 2, 3, false);
ASSERT_EQ(16UL, frames_from_callback_.size());
CheckReferencesVp9(pid, 0);
CheckReferencesVp9(pid + 1, 0, pid);
CheckReferencesVp9(pid + 2, 0, pid);
CheckReferencesVp9(pid + 3, 0, pid + 1, pid + 2);
CheckReferencesVp9(pid + 4, 0, pid);
CheckReferencesVp9(pid + 5, 0, pid + 3, pid + 4);
CheckReferencesVp9(pid + 6, 0, pid + 2, pid + 4);
CheckReferencesVp9(pid + 7, 0, pid + 6);
CheckReferencesVp9(pid + 8, 0, pid + 4);
CheckReferencesVp9(pid + 9, 0, pid + 8);
CheckReferencesVp9(pid + 10, 0, pid + 8);
CheckReferencesVp9(pid + 11, 0, pid + 9, pid + 10);
CheckReferencesVp9(pid + 12, 0, pid + 8);
CheckReferencesVp9(pid + 13, 0, pid + 11, pid + 12);
CheckReferencesVp9(pid + 14, 0, pid + 10, pid + 12);
CheckReferencesVp9(pid + 15, 0, pid + 13, pid + 14);
}
TEST_F(TestRtpFrameReferenceFinder,
Vp9GofTemporalLayersUpSwitchReordered_02120212) {
uint16_t pid = Rand();
uint16_t sn = Rand();
GofInfoVP9 ss;
ss.SetGofInfoVP9(kTemporalStructureMode4); // 02120212 pattern
InsertVp9Gof(sn + 1, sn + 1, false, pid + 1, 0, 2, 0, false);
InsertVp9Gof(sn, sn, true, pid, 0, 0, 0, false, false, &ss);
InsertVp9Gof(sn + 4, sn + 4, false, pid + 4, 0, 0, 1, false);
InsertVp9Gof(sn + 2, sn + 2, false, pid + 2, 0, 1, 0, false);
InsertVp9Gof(sn + 5, sn + 5, false, pid + 5, 0, 2, 1, false);
InsertVp9Gof(sn + 3, sn + 3, false, pid + 3, 0, 2, 0, false);
InsertVp9Gof(sn + 7, sn + 7, false, pid + 7, 0, 2, 1, false);
InsertVp9Gof(sn + 9, sn + 9, false, pid + 9, 0, 2, 2, false);
InsertVp9Gof(sn + 6, sn + 6, false, pid + 6, 0, 1, 1, true);
InsertVp9Gof(sn + 12, sn + 12, false, pid + 12, 0, 0, 3, false);
InsertVp9Gof(sn + 10, sn + 10, false, pid + 10, 0, 1, 2, false);
InsertVp9Gof(sn + 8, sn + 8, false, pid + 8, 0, 0, 2, true);
InsertVp9Gof(sn + 11, sn + 11, false, pid + 11, 0, 2, 2, true);
InsertVp9Gof(sn + 13, sn + 13, false, pid + 13, 0, 2, 3, false);
InsertVp9Gof(sn + 15, sn + 15, false, pid + 15, 0, 2, 3, false);
InsertVp9Gof(sn + 14, sn + 14, false, pid + 14, 0, 1, 3, false);
ASSERT_EQ(16UL, frames_from_callback_.size());
CheckReferencesVp9(pid, 0);
CheckReferencesVp9(pid + 1, 0, pid);
CheckReferencesVp9(pid + 2, 0, pid);
CheckReferencesVp9(pid + 3, 0, pid + 1, pid + 2);
CheckReferencesVp9(pid + 4, 0, pid);
CheckReferencesVp9(pid + 5, 0, pid + 3, pid + 4);
CheckReferencesVp9(pid + 6, 0, pid + 2, pid + 4);
CheckReferencesVp9(pid + 7, 0, pid + 6);
CheckReferencesVp9(pid + 8, 0, pid + 4);
CheckReferencesVp9(pid + 9, 0, pid + 8);
CheckReferencesVp9(pid + 10, 0, pid + 8);
CheckReferencesVp9(pid + 11, 0, pid + 9, pid + 10);
CheckReferencesVp9(pid + 12, 0, pid + 8);
CheckReferencesVp9(pid + 13, 0, pid + 11, pid + 12);
CheckReferencesVp9(pid + 14, 0, pid + 10, pid + 12);
CheckReferencesVp9(pid + 15, 0, pid + 13, pid + 14);
}
TEST_F(TestRtpFrameReferenceFinder, Vp9GofTemporalLayersReordered_01_0212) {
uint16_t pid = Rand();
uint16_t sn = Rand();
GofInfoVP9 ss;
ss.SetGofInfoVP9(kTemporalStructureMode2); // 01 pattern
InsertVp9Gof(sn + 1, sn + 1, false, pid + 1, 0, 1, 0, false);
InsertVp9Gof(sn, sn, true, pid, 0, 0, 0, false, false, &ss);
InsertVp9Gof(sn + 3, sn + 3, false, pid + 3, 0, 1, 1, false);
InsertVp9Gof(sn + 6, sn + 6, false, pid + 6, 0, 1, 2, false);
ss.SetGofInfoVP9(kTemporalStructureMode3); // 0212 pattern
InsertVp9Gof(sn + 4, sn + 4, false, pid + 4, 0, 0, 2, false, true, &ss);
InsertVp9Gof(sn + 2, sn + 2, false, pid + 2, 0, 0, 1, false);
InsertVp9Gof(sn + 5, sn + 5, false, pid + 5, 0, 2, 2, false);
InsertVp9Gof(sn + 8, sn + 8, false, pid + 8, 0, 0, 3, false);
InsertVp9Gof(sn + 10, sn + 10, false, pid + 10, 0, 1, 3, false);
InsertVp9Gof(sn + 7, sn + 7, false, pid + 7, 0, 2, 2, false);
InsertVp9Gof(sn + 11, sn + 11, false, pid + 11, 0, 2, 3, false);
InsertVp9Gof(sn + 9, sn + 9, false, pid + 9, 0, 2, 3, false);
ASSERT_EQ(12UL, frames_from_callback_.size());
CheckReferencesVp9(pid, 0);
CheckReferencesVp9(pid + 1, 0, pid);
CheckReferencesVp9(pid + 2, 0, pid);
CheckReferencesVp9(pid + 3, 0, pid + 2);
CheckReferencesVp9(pid + 4, 0, pid);
CheckReferencesVp9(pid + 5, 0, pid + 4);
CheckReferencesVp9(pid + 6, 0, pid + 4);
CheckReferencesVp9(pid + 7, 0, pid + 6);
CheckReferencesVp9(pid + 8, 0, pid + 4);
CheckReferencesVp9(pid + 9, 0, pid + 8);
CheckReferencesVp9(pid + 10, 0, pid + 8);
CheckReferencesVp9(pid + 11, 0, pid + 10);
}
TEST_F(TestRtpFrameReferenceFinder, Vp9FlexibleModeOneFrame) {
uint16_t pid = Rand();
uint16_t sn = Rand();
InsertVp9Flex(sn, sn, true, pid, 0, 0, false);
ASSERT_EQ(1UL, frames_from_callback_.size());
CheckReferencesVp9(pid, 0);
}
TEST_F(TestRtpFrameReferenceFinder, Vp9FlexibleModeTwoSpatialLayers) {
uint16_t pid = Rand();
uint16_t sn = Rand();
InsertVp9Flex(sn, sn, true, pid, 0, 0, false);
InsertVp9Flex(sn + 1, sn + 1, true, pid, 1, 0, true);
InsertVp9Flex(sn + 2, sn + 2, false, pid + 1, 1, 0, false, {1});
InsertVp9Flex(sn + 3, sn + 3, false, pid + 2, 0, 0, false, {2});
InsertVp9Flex(sn + 4, sn + 4, false, pid + 2, 1, 0, false, {1});
InsertVp9Flex(sn + 5, sn + 5, false, pid + 3, 1, 0, false, {1});
InsertVp9Flex(sn + 6, sn + 6, false, pid + 4, 0, 0, false, {2});
InsertVp9Flex(sn + 7, sn + 7, false, pid + 4, 1, 0, false, {1});
InsertVp9Flex(sn + 8, sn + 8, false, pid + 5, 1, 0, false, {1});
InsertVp9Flex(sn + 9, sn + 9, false, pid + 6, 0, 0, false, {2});
InsertVp9Flex(sn + 10, sn + 10, false, pid + 6, 1, 0, false, {1});
InsertVp9Flex(sn + 11, sn + 11, false, pid + 7, 1, 0, false, {1});
InsertVp9Flex(sn + 12, sn + 12, false, pid + 8, 0, 0, false, {2});
InsertVp9Flex(sn + 13, sn + 13, false, pid + 8, 1, 0, false, {1});
ASSERT_EQ(14UL, frames_from_callback_.size());
CheckReferencesVp9(pid, 0);
CheckReferencesVp9(pid, 1);
CheckReferencesVp9(pid + 1, 1, pid);
CheckReferencesVp9(pid + 2, 0, pid);
CheckReferencesVp9(pid + 2, 1, pid + 1);
CheckReferencesVp9(pid + 3, 1, pid + 2);
CheckReferencesVp9(pid + 4, 0, pid + 2);
CheckReferencesVp9(pid + 4, 1, pid + 3);
CheckReferencesVp9(pid + 5, 1, pid + 4);
CheckReferencesVp9(pid + 6, 0, pid + 4);
CheckReferencesVp9(pid + 6, 1, pid + 5);
CheckReferencesVp9(pid + 7, 1, pid + 6);
CheckReferencesVp9(pid + 8, 0, pid + 6);
CheckReferencesVp9(pid + 8, 1, pid + 7);
}
TEST_F(TestRtpFrameReferenceFinder, Vp9FlexibleModeTwoSpatialLayersReordered) {
uint16_t pid = Rand();
uint16_t sn = Rand();
InsertVp9Flex(sn + 1, sn + 1, true, pid, 1, 0, true);
InsertVp9Flex(sn + 2, sn + 2, false, pid + 1, 1, 0, false, {1});
InsertVp9Flex(sn, sn, true, pid, 0, 0, false);
InsertVp9Flex(sn + 4, sn + 4, false, pid + 2, 1, 0, false, {1});
InsertVp9Flex(sn + 5, sn + 5, false, pid + 3, 1, 0, false, {1});
InsertVp9Flex(sn + 3, sn + 3, false, pid + 2, 0, 0, false, {2});
InsertVp9Flex(sn + 7, sn + 7, false, pid + 4, 1, 0, false, {1});
InsertVp9Flex(sn + 6, sn + 6, false, pid + 4, 0, 0, false, {2});
InsertVp9Flex(sn + 8, sn + 8, false, pid + 5, 1, 0, false, {1});
InsertVp9Flex(sn + 9, sn + 9, false, pid + 6, 0, 0, false, {2});
InsertVp9Flex(sn + 11, sn + 11, false, pid + 7, 1, 0, false, {1});
InsertVp9Flex(sn + 10, sn + 10, false, pid + 6, 1, 0, false, {1});
InsertVp9Flex(sn + 13, sn + 13, false, pid + 8, 1, 0, false, {1});
InsertVp9Flex(sn + 12, sn + 12, false, pid + 8, 0, 0, false, {2});
ASSERT_EQ(14UL, frames_from_callback_.size());
CheckReferencesVp9(pid, 0);
CheckReferencesVp9(pid, 1);
CheckReferencesVp9(pid + 1, 1, pid);
CheckReferencesVp9(pid + 2, 0, pid);
CheckReferencesVp9(pid + 2, 1, pid + 1);
CheckReferencesVp9(pid + 3, 1, pid + 2);
CheckReferencesVp9(pid + 4, 0, pid + 2);
CheckReferencesVp9(pid + 4, 1, pid + 3);
CheckReferencesVp9(pid + 5, 1, pid + 4);
CheckReferencesVp9(pid + 6, 0, pid + 4);
CheckReferencesVp9(pid + 6, 1, pid + 5);
CheckReferencesVp9(pid + 7, 1, pid + 6);
CheckReferencesVp9(pid + 8, 0, pid + 6);
CheckReferencesVp9(pid + 8, 1, pid + 7);
}
TEST_F(TestRtpFrameReferenceFinder, WrappingFlexReference) {
InsertVp9Flex(0, 0, false, 0, 0, 0, false, {1});
ASSERT_EQ(1UL, frames_from_callback_.size());
const EncodedFrame& frame = *frames_from_callback_.begin()->second;
ASSERT_EQ(frame.id.picture_id - frame.references[0], 1);
}
TEST_F(TestRtpFrameReferenceFinder, Vp9GofPidJump) {
uint16_t pid = Rand();
uint16_t sn = Rand();
GofInfoVP9 ss;
ss.SetGofInfoVP9(kTemporalStructureMode3);
InsertVp9Gof(sn, sn, true, pid, 0, 0, 0, false, false, &ss);
InsertVp9Gof(sn + 1, sn + 1, false, pid + 1000, 0, 0, 1);
}
TEST_F(TestRtpFrameReferenceFinder, Vp9GofTl0Jump) {
uint16_t pid = Rand();
uint16_t sn = Rand();
GofInfoVP9 ss;
ss.SetGofInfoVP9(kTemporalStructureMode3);
InsertVp9Gof(sn, sn, true, pid, 0, 0, 125, true, false, &ss);
InsertVp9Gof(sn + 1, sn + 1, false, pid + 1, 0, 0, 0, false, true, &ss);
}
TEST_F(TestRtpFrameReferenceFinder, Vp9GofTidTooHigh) {
// Same as RtpFrameReferenceFinder::kMaxTemporalLayers.
const int kMaxTemporalLayers = 5;
uint16_t pid = Rand();
uint16_t sn = Rand();
GofInfoVP9 ss;
ss.SetGofInfoVP9(kTemporalStructureMode2);
ss.temporal_idx[1] = kMaxTemporalLayers;
InsertVp9Gof(sn, sn, true, pid, 0, 0, 0, false, false, &ss);
InsertVp9Gof(sn + 1, sn + 1, false, pid + 1, 0, 0, 1);
ASSERT_EQ(1UL, frames_from_callback_.size());
CheckReferencesVp9(pid, 0);
}
TEST_F(TestRtpFrameReferenceFinder, Vp9GofZeroFrames) {
uint16_t pid = Rand();
uint16_t sn = Rand();
GofInfoVP9 ss;
ss.num_frames_in_gof = 0;
InsertVp9Gof(sn, sn, true, pid, 0, 0, 0, false, false, &ss);
InsertVp9Gof(sn + 1, sn + 1, false, pid + 1, 0, 0, 1);
ASSERT_EQ(2UL, frames_from_callback_.size());
CheckReferencesVp9(pid, 0);
CheckReferencesVp9(pid + 1, 0, pid);
}
TEST_F(TestRtpFrameReferenceFinder, H264KeyFrameReferences) {
uint16_t sn = Rand();
InsertH264(sn, sn, true);
ASSERT_EQ(1UL, frames_from_callback_.size());
CheckReferencesH264(sn);
}
// Test with 1 temporal layer.
TEST_F(TestRtpFrameReferenceFinder, H264TemporalLayers_0) {
uint16_t sn = Rand();
InsertH264(sn, sn, true, 0, 1);
InsertH264(sn + 1, sn + 1, false, 0, 2);
InsertH264(sn + 2, sn + 2, false, 0, 3);
InsertH264(sn + 3, sn + 3, false, 0, 4);
ASSERT_EQ(4UL, frames_from_callback_.size());
CheckReferencesH264(sn);
CheckReferencesH264(sn + 1, sn);
CheckReferencesH264(sn + 2, sn + 1);
CheckReferencesH264(sn + 3, sn + 2);
}
TEST_F(TestRtpFrameReferenceFinder, H264DuplicateTl1Frames) {
uint16_t sn = Rand();
InsertH264(sn, sn, true, 0, 0);
InsertH264(sn + 1, sn + 1, false, 1, 0, true);
InsertH264(sn + 2, sn + 2, false, 0, 1);
InsertH264(sn + 3, sn + 3, false, 1, 1);
InsertH264(sn + 3, sn + 3, false, 1, 1);
InsertH264(sn + 4, sn + 4, false, 0, 2);
InsertH264(sn + 5, sn + 5, false, 1, 2);
ASSERT_EQ(6UL, frames_from_callback_.size());
CheckReferencesH264(sn);
CheckReferencesH264(sn + 1, sn);
CheckReferencesH264(sn + 2, sn);
CheckReferencesH264(sn + 3, sn + 1, sn + 2);
CheckReferencesH264(sn + 4, sn + 2);
CheckReferencesH264(sn + 5, sn + 3, sn + 4);
}
// Test with 1 temporal layer.
TEST_F(TestRtpFrameReferenceFinder, H264TemporalLayersReordering_0) {
uint16_t sn = Rand();
InsertH264(sn, sn, true, 0, 1);
InsertH264(sn + 1, sn + 1, false, 0, 2);
InsertH264(sn + 3, sn + 3, false, 0, 4);
InsertH264(sn + 2, sn + 2, false, 0, 3);
InsertH264(sn + 5, sn + 5, false, 0, 6);
InsertH264(sn + 6, sn + 6, false, 0, 7);
InsertH264(sn + 4, sn + 4, false, 0, 5);
ASSERT_EQ(7UL, frames_from_callback_.size());
CheckReferencesH264(sn);
CheckReferencesH264(sn + 1, sn);
CheckReferencesH264(sn + 2, sn + 1);
CheckReferencesH264(sn + 3, sn + 2);
CheckReferencesH264(sn + 4, sn + 3);
CheckReferencesH264(sn + 5, sn + 4);
CheckReferencesH264(sn + 6, sn + 5);
}
// Test with 2 temporal layers in a 01 pattern.
TEST_F(TestRtpFrameReferenceFinder, H264TemporalLayers_01) {
uint16_t sn = Rand();
InsertH264(sn, sn, true, 0, 255);
InsertH264(sn + 1, sn + 1, false, 1, 255, true);
InsertH264(sn + 2, sn + 2, false, 0, 0);
InsertH264(sn + 3, sn + 3, false, 1, 0);
ASSERT_EQ(4UL, frames_from_callback_.size());
CheckReferencesH264(sn);
CheckReferencesH264(sn + 1, sn);
CheckReferencesH264(sn + 2, sn);
CheckReferencesH264(sn + 3, sn + 1, sn + 2);
}
TEST_F(TestRtpFrameReferenceFinder, H264TemporalLayersMultiSn_01) {
uint16_t sn = Rand();
InsertH264(sn, sn + 3, true, 0, 255);
InsertH264(sn + 4, sn + 5, false, 1, 255, true);
InsertH264(sn + 6, sn + 8, false, 0, 0);
InsertH264(sn + 9, sn + 9, false, 1, 0);
ASSERT_EQ(4UL, frames_from_callback_.size());
CheckReferencesH264(sn + 3);
CheckReferencesH264(sn + 5, sn + 3);
CheckReferencesH264(sn + 8, sn + 3);
CheckReferencesH264(sn + 9, sn + 5, sn + 8);
}
// Test with 2 temporal layers in a 01 pattern.
TEST_F(TestRtpFrameReferenceFinder, H264TemporalLayersReordering_01) {
uint16_t sn = Rand();
InsertH264(sn + 1, sn + 1, false, 1, 255, true);
InsertH264(sn, sn, true, 0, 255);
InsertH264(sn + 3, sn + 3, false, 1, 0);
InsertH264(sn + 5, sn + 5, false, 1, 1);
InsertH264(sn + 2, sn + 2, false, 0, 0);
InsertH264(sn + 4, sn + 4, false, 0, 1);
InsertH264(sn + 6, sn + 6, false, 0, 2);
InsertH264(sn + 7, sn + 7, false, 1, 2);
ASSERT_EQ(8UL, frames_from_callback_.size());
CheckReferencesH264(sn);
CheckReferencesH264(sn + 1, sn);
CheckReferencesH264(sn + 2, sn);
CheckReferencesH264(sn + 3, sn + 1, sn + 2);
CheckReferencesH264(sn + 4, sn + 2);
CheckReferencesH264(sn + 5, sn + 3, sn + 4);
CheckReferencesH264(sn + 6, sn + 4);
CheckReferencesH264(sn + 7, sn + 5, sn + 6);
}
// Test with 3 temporal layers in a 0212 pattern.
TEST_F(TestRtpFrameReferenceFinder, H264TemporalLayers_0212) {
uint16_t sn = Rand();
InsertH264(sn, sn, true, 0, 55);
InsertH264(sn + 1, sn + 1, false, 2, 55, true);
InsertH264(sn + 2, sn + 2, false, 1, 55, true);
InsertH264(sn + 3, sn + 3, false, 2, 55);
InsertH264(sn + 4, sn + 4, false, 0, 56);
InsertH264(sn + 5, sn + 5, false, 2, 56, true);
InsertH264(sn + 6, sn + 6, false, 1, 56, true);
InsertH264(sn + 7, sn + 7, false, 2, 56);
InsertH264(sn + 8, sn + 8, false, 0, 57);
InsertH264(sn + 9, sn + 9, false, 2, 57, true);
InsertH264(sn + 10, sn + 10, false, 1, 57, true);
InsertH264(sn + 11, sn + 11, false, 2, 57);
ASSERT_EQ(12UL, frames_from_callback_.size());
CheckReferencesH264(sn);
CheckReferencesH264(sn + 1, sn);
CheckReferencesH264(sn + 2, sn);
CheckReferencesH264(sn + 3, sn, sn + 1, sn + 2);
CheckReferencesH264(sn + 4, sn);
CheckReferencesH264(sn + 5, sn + 4);
CheckReferencesH264(sn + 6, sn + 4);
CheckReferencesH264(sn + 7, sn + 4, sn + 5, sn + 6);
CheckReferencesH264(sn + 8, sn + 4);
CheckReferencesH264(sn + 9, sn + 8);
CheckReferencesH264(sn + 10, sn + 8);
CheckReferencesH264(sn + 11, sn + 8, sn + 9, sn + 10);
}
// Test with 3 temporal layers in a 0212 pattern.
TEST_F(TestRtpFrameReferenceFinder, H264TemporalLayersMissingFrame_0212) {
uint16_t sn = Rand();
InsertH264(sn, sn, true, 0, 55, false);
InsertH264(sn + 2, sn + 2, false, 1, 55, true);
InsertH264(sn + 3, sn + 3, false, 2, 55, false);
ASSERT_EQ(2UL, frames_from_callback_.size());
CheckReferencesH264(sn);
CheckReferencesH264(sn + 2, sn);
}
// Test with 3 temporal layers in a 0212 pattern.
TEST_F(TestRtpFrameReferenceFinder, H264TemporalLayersReordering_0212) {
uint16_t sn = Rand();
InsertH264(sn + 1, sn + 1, false, 2, 55, true);
InsertH264(sn, sn, true, 0, 55, false);
InsertH264(sn + 2, sn + 2, false, 1, 55, true);
InsertH264(sn + 4, sn + 4, false, 0, 56, false);
InsertH264(sn + 5, sn + 5, false, 2, 56, false);
InsertH264(sn + 3, sn + 3, false, 2, 55, false);
InsertH264(sn + 7, sn + 7, false, 2, 56, false);
InsertH264(sn + 9, sn + 9, false, 2, 57, true);
InsertH264(sn + 6, sn + 6, false, 1, 56, false);
InsertH264(sn + 8, sn + 8, false, 0, 57, false);
InsertH264(sn + 11, sn + 11, false, 2, 57, false);
InsertH264(sn + 10, sn + 10, false, 1, 57, true);
ASSERT_EQ(12UL, frames_from_callback_.size());
CheckReferencesH264(sn);
CheckReferencesH264(sn + 1, sn);
CheckReferencesH264(sn + 2, sn);
CheckReferencesH264(sn + 3, sn, sn + 1, sn + 2);
CheckReferencesH264(sn + 4, sn);
CheckReferencesH264(sn + 5, sn + 2, sn + 3, sn + 4);
CheckReferencesH264(sn + 6, sn + 2, sn + 4);
CheckReferencesH264(sn + 7, sn + 4, sn + 5, sn + 6);
CheckReferencesH264(sn + 8, sn + 4);
CheckReferencesH264(sn + 9, sn + 8);
CheckReferencesH264(sn + 10, sn + 8);
CheckReferencesH264(sn + 11, sn + 8, sn + 9, sn + 10);
}
TEST_F(TestRtpFrameReferenceFinder, H264InsertManyFrames_0212) {
uint16_t sn = Rand();
const int keyframes_to_insert = 50;
const int frames_per_keyframe = 120; // Should be a multiple of 4.
uint8_t tl0 = 128;
for (int k = 0; k < keyframes_to_insert; ++k) {
InsertH264(sn, sn, true, 0, tl0, false);
InsertH264(sn + 1, sn + 1, false, 2, tl0, true);
InsertH264(sn + 2, sn + 2, false, 1, tl0, true);
InsertH264(sn + 3, sn + 3, false, 2, tl0, false);
CheckReferencesH264(sn);
CheckReferencesH264(sn + 1, sn);
CheckReferencesH264(sn + 2, sn);
CheckReferencesH264(sn + 3, sn, sn + 1, sn + 2);
frames_from_callback_.clear();
++tl0;
for (int f = 4; f < frames_per_keyframe; f += 4) {
uint16_t sf = sn + f;
InsertH264(sf, sf, false, 0, tl0, false);
InsertH264(sf + 1, sf + 1, false, 2, tl0, false);
InsertH264(sf + 2, sf + 2, false, 1, tl0, false);
InsertH264(sf + 3, sf + 3, false, 2, tl0, false);
CheckReferencesH264(sf, sf - 4);
CheckReferencesH264(sf + 1, sf, sf - 1, sf - 2);
CheckReferencesH264(sf + 2, sf, sf - 2);
CheckReferencesH264(sf + 3, sf, sf + 1, sf + 2);
frames_from_callback_.clear();
++tl0;
}
sn += frames_per_keyframe;
}
}
TEST_F(TestRtpFrameReferenceFinder, H264LayerSync) {
uint16_t sn = Rand();
InsertH264(sn, sn, true, 0, 0, false);
InsertH264(sn + 1, sn + 1, false, 1, 0, true);
InsertH264(sn + 2, sn + 2, false, 0, 1, false);
ASSERT_EQ(3UL, frames_from_callback_.size());
InsertH264(sn + 4, sn + 4, false, 0, 2, false);
InsertH264(sn + 5, sn + 5, false, 1, 2, true);
InsertH264(sn + 6, sn + 6, false, 0, 3, false);
InsertH264(sn + 7, sn + 7, false, 1, 3, false);
ASSERT_EQ(7UL, frames_from_callback_.size());
CheckReferencesH264(sn);
CheckReferencesH264(sn + 1, sn);
CheckReferencesH264(sn + 2, sn);
CheckReferencesH264(sn + 4, sn + 2);
CheckReferencesH264(sn + 5, sn + 4);
CheckReferencesH264(sn + 6, sn + 4);
CheckReferencesH264(sn + 7, sn + 6, sn + 5);
}
TEST_F(TestRtpFrameReferenceFinder, H264Tl1SyncFrameAfterTl1Frame) {
InsertH264(1000, 1000, true, 0, 247, true);
InsertH264(1001, 1001, false, 0, 248, false);
InsertH264(1002, 1002, false, 1, 248, false); // Will be dropped
InsertH264(1003, 1003, false, 1, 248, true); // due to this frame.
ASSERT_EQ(3UL, frames_from_callback_.size());
CheckReferencesH264(1000);
CheckReferencesH264(1001, 1000);
CheckReferencesH264(1003, 1001);
}
TEST_F(TestRtpFrameReferenceFinder, H264DetectMissingFrame_0212) {
InsertH264(1, 1, true, 0, 1, false);
InsertH264(2, 2, false, 2, 1, true);
InsertH264(3, 3, false, 1, 1, true);
InsertH264(4, 4, false, 2, 1, false);
InsertH264(6, 6, false, 2, 2, false);
InsertH264(7, 7, false, 1, 2, false);
InsertH264(8, 8, false, 2, 2, false);
ASSERT_EQ(4UL, frames_from_callback_.size());
InsertH264(5, 5, false, 0, 2, false);
ASSERT_EQ(8UL, frames_from_callback_.size());
CheckReferencesH264(1);
CheckReferencesH264(2, 1);
CheckReferencesH264(3, 1);
CheckReferencesH264(4, 3, 2, 1);
CheckReferencesH264(5, 1);
CheckReferencesH264(6, 5, 4, 3);
CheckReferencesH264(7, 5, 3);
CheckReferencesH264(8, 7, 6, 5);
}
TEST_F(TestRtpFrameReferenceFinder, H264SequenceNumberWrap) {
uint16_t sn = 0xFFFF;
InsertH264(sn - 1, sn - 1, true, 0, 1);
InsertH264(sn, sn, false, 0, 2);
InsertH264(sn + 1, sn + 1, false, 0, 3);
InsertH264(sn + 2, sn + 2, false, 0, 4);
ASSERT_EQ(4UL, frames_from_callback_.size());
CheckReferencesH264(sn - 1);
CheckReferencesH264(sn, sn - 1);
CheckReferencesH264(sn + 1, sn);
CheckReferencesH264(sn + 2, sn + 1);
}
TEST_F(TestRtpFrameReferenceFinder, H264SequenceNumberWrapMulti) {
uint16_t sn = 0xFFFF;
InsertH264(sn - 3, sn - 2, true, 0, 1);
InsertH264(sn - 1, sn + 1, false, 0, 2);
InsertH264(sn + 2, sn + 3, false, 0, 3);
InsertH264(sn + 4, sn + 7, false, 0, 4);
ASSERT_EQ(4UL, frames_from_callback_.size());
CheckReferencesH264(sn - 2);
CheckReferencesH264(sn + 1, sn - 2);
CheckReferencesH264(sn + 3, sn + 1);
CheckReferencesH264(sn + 7, sn + 3);
}
TEST_F(TestRtpFrameReferenceFinder, H264Tl0PicIdxWrap) {
int numTl0Wraps = 1000;
int64_t sn = Rand();
for (int i = 0; i < numTl0Wraps; i++) {
for (int tl0 = 0; tl0 < 256; tl0 += 16, sn += 16) {
InsertH264(sn, sn, true, 0, tl0);
reference_finder_->ClearTo(sn); // Too many stashed frames cause errors.
for (int k = 1; k < 8; k++) {
InsertH264(sn + k, sn + k, false, 0, tl0 + k);
}
// Skip a TL0 index.
for (int k = 9; k < 16; k++) {
InsertH264(sn + k, sn + k, false, 0, tl0 + k);
}
ASSERT_EQ(8UL, frames_from_callback_.size());
CheckReferencesH264(sn);
for (int k = 1; k < 8; k++) {
CheckReferencesH264(sn + k, sn + k - 1);
}
frames_from_callback_.clear();
}
}
}
} // namespace video_coding
} // namespace webrtc