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webrtc_m130/webrtc/test/fake_encoder.cc
ilnik 04f4d126f8 Implement timing frames. 
Timing information is gathered in EncodedImage,
starting at encoders. Then it's sent using RTP header extension. In the
end, it's gathered at the GenericDecoder. Actual reporting and tests
will be in the next CLs.

BUG=webrtc:7594

Review-Url: https://codereview.webrtc.org/2911193002
Cr-Commit-Position: refs/heads/master@{#18659}
2017-06-19 14:18:55 +00:00

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/*
* Copyright (c) 2013 The WebRTC project authors. All Rights Reserved.
*
* Use of this source code is governed by a BSD-style license
* that can be found in the LICENSE file in the root of the source
* tree. An additional intellectual property rights grant can be found
* in the file PATENTS. All contributing project authors may
* be found in the AUTHORS file in the root of the source tree.
*/
#include "webrtc/test/fake_encoder.h"
#include <string.h>
#include <algorithm>
#include <memory>
#include "webrtc/base/checks.h"
#include "webrtc/common_types.h"
#include "webrtc/modules/video_coding/include/video_codec_interface.h"
#include "webrtc/system_wrappers/include/sleep.h"
#include "webrtc/test/gtest.h"
namespace webrtc {
namespace test {
FakeEncoder::FakeEncoder(Clock* clock)
: clock_(clock),
callback_(nullptr),
max_target_bitrate_kbps_(-1),
last_encode_time_ms_(0) {
// Generate some arbitrary not-all-zero data
for (size_t i = 0; i < sizeof(encoded_buffer_); ++i) {
encoded_buffer_[i] = static_cast<uint8_t>(i);
}
}
void FakeEncoder::SetMaxBitrate(int max_kbps) {
RTC_DCHECK_GE(max_kbps, -1); // max_kbps == -1 disables it.
rtc::CritScope cs(&crit_sect_);
max_target_bitrate_kbps_ = max_kbps;
}
int32_t FakeEncoder::InitEncode(const VideoCodec* config,
int32_t number_of_cores,
size_t max_payload_size) {
rtc::CritScope cs(&crit_sect_);
config_ = *config;
target_bitrate_.SetBitrate(0, 0, config_.startBitrate * 1000);
return 0;
}
int32_t FakeEncoder::Encode(const VideoFrame& input_image,
const CodecSpecificInfo* codec_specific_info,
const std::vector<FrameType>* frame_types) {
unsigned char max_framerate;
unsigned char num_simulcast_streams;
SimulcastStream simulcast_streams[kMaxSimulcastStreams];
EncodedImageCallback* callback;
uint32_t target_bitrate_sum_kbps;
int max_target_bitrate_kbps;
int64_t last_encode_time_ms;
size_t num_encoded_bytes;
VideoCodecMode mode;
{
rtc::CritScope cs(&crit_sect_);
max_framerate = config_.maxFramerate;
num_simulcast_streams = config_.numberOfSimulcastStreams;
for (int i = 0; i < num_simulcast_streams; ++i) {
simulcast_streams[i] = config_.simulcastStream[i];
}
callback = callback_;
target_bitrate_sum_kbps = target_bitrate_.get_sum_kbps();
max_target_bitrate_kbps = max_target_bitrate_kbps_;
last_encode_time_ms = last_encode_time_ms_;
num_encoded_bytes = sizeof(encoded_buffer_);
mode = config_.mode;
}
int64_t time_now_ms = clock_->TimeInMilliseconds();
const bool first_encode = (last_encode_time_ms == 0);
RTC_DCHECK_GT(max_framerate, 0);
int64_t time_since_last_encode_ms = 1000 / max_framerate;
if (!first_encode) {
// For all frames but the first we can estimate the display time by looking
// at the display time of the previous frame.
time_since_last_encode_ms = time_now_ms - last_encode_time_ms;
}
if (time_since_last_encode_ms > 3 * 1000 / max_framerate) {
// Rudimentary check to make sure we don't widely overshoot bitrate target
// when resuming encoding after a suspension.
time_since_last_encode_ms = 3 * 1000 / max_framerate;
}
size_t bits_available =
static_cast<size_t>(target_bitrate_sum_kbps * time_since_last_encode_ms);
size_t min_bits = static_cast<size_t>(simulcast_streams[0].minBitrate *
time_since_last_encode_ms);
if (bits_available < min_bits)
bits_available = min_bits;
size_t max_bits =
static_cast<size_t>(max_target_bitrate_kbps * time_since_last_encode_ms);
if (max_bits > 0 && max_bits < bits_available)
bits_available = max_bits;
{
rtc::CritScope cs(&crit_sect_);
last_encode_time_ms_ = time_now_ms;
}
RTC_DCHECK_GT(num_simulcast_streams, 0);
for (unsigned char i = 0; i < num_simulcast_streams; ++i) {
CodecSpecificInfo specifics;
memset(&specifics, 0, sizeof(specifics));
specifics.codecType = kVideoCodecGeneric;
specifics.codecSpecific.generic.simulcast_idx = i;
size_t min_stream_bits = static_cast<size_t>(
simulcast_streams[i].minBitrate * time_since_last_encode_ms);
size_t max_stream_bits = static_cast<size_t>(
simulcast_streams[i].maxBitrate * time_since_last_encode_ms);
size_t stream_bits = (bits_available > max_stream_bits) ? max_stream_bits :
bits_available;
size_t stream_bytes = (stream_bits + 7) / 8;
if (first_encode) {
// The first frame is a key frame and should be larger.
// TODO(holmer): The FakeEncoder should store the bits_available between
// encodes so that it can compensate for oversized frames.
stream_bytes *= 10;
}
if (stream_bytes > num_encoded_bytes)
stream_bytes = num_encoded_bytes;
// Always encode something on the first frame.
if (min_stream_bits > bits_available && i > 0)
continue;
std::unique_ptr<uint8_t[]> encoded_buffer(new uint8_t[num_encoded_bytes]);
memcpy(encoded_buffer.get(), encoded_buffer_, num_encoded_bytes);
EncodedImage encoded(encoded_buffer.get(), stream_bytes, num_encoded_bytes);
encoded._timeStamp = input_image.timestamp();
encoded.capture_time_ms_ = input_image.render_time_ms();
encoded._frameType = (*frame_types)[i];
encoded._encodedWidth = simulcast_streams[i].width;
encoded._encodedHeight = simulcast_streams[i].height;
encoded.rotation_ = input_image.rotation();
encoded.content_type_ = (mode == kScreensharing)
? VideoContentType::SCREENSHARE
: VideoContentType::UNSPECIFIED;
specifics.codec_name = ImplementationName();
specifics.codecSpecific.generic.simulcast_idx = i;
RTC_DCHECK(callback);
if (callback->OnEncodedImage(encoded, &specifics, nullptr).error !=
EncodedImageCallback::Result::OK) {
return -1;
}
bits_available -= std::min(encoded._length * 8, bits_available);
}
return 0;
}
int32_t FakeEncoder::RegisterEncodeCompleteCallback(
EncodedImageCallback* callback) {
rtc::CritScope cs(&crit_sect_);
callback_ = callback;
return 0;
}
int32_t FakeEncoder::Release() { return 0; }
int32_t FakeEncoder::SetChannelParameters(uint32_t packet_loss, int64_t rtt) {
return 0;
}
int32_t FakeEncoder::SetRateAllocation(const BitrateAllocation& rate_allocation,
uint32_t framerate) {
rtc::CritScope cs(&crit_sect_);
target_bitrate_ = rate_allocation;
return 0;
}
const char* FakeEncoder::kImplementationName = "fake_encoder";
const char* FakeEncoder::ImplementationName() const {
return kImplementationName;
}
FakeH264Encoder::FakeH264Encoder(Clock* clock)
: FakeEncoder(clock), callback_(nullptr), idr_counter_(0) {
FakeEncoder::RegisterEncodeCompleteCallback(this);
}
int32_t FakeH264Encoder::RegisterEncodeCompleteCallback(
EncodedImageCallback* callback) {
rtc::CritScope cs(&local_crit_sect_);
callback_ = callback;
return 0;
}
EncodedImageCallback::Result FakeH264Encoder::OnEncodedImage(
const EncodedImage& encoded_image,
const CodecSpecificInfo* codec_specific_info,
const RTPFragmentationHeader* fragments) {
const size_t kSpsSize = 8;
const size_t kPpsSize = 11;
const int kIdrFrequency = 10;
EncodedImageCallback* callback;
int current_idr_counter;
{
rtc::CritScope cs(&local_crit_sect_);
callback = callback_;
current_idr_counter = idr_counter_;
++idr_counter_;
}
RTPFragmentationHeader fragmentation;
if (current_idr_counter % kIdrFrequency == 0 &&
encoded_image._length > kSpsSize + kPpsSize + 1) {
const size_t kNumSlices = 3;
fragmentation.VerifyAndAllocateFragmentationHeader(kNumSlices);
fragmentation.fragmentationOffset[0] = 0;
fragmentation.fragmentationLength[0] = kSpsSize;
fragmentation.fragmentationOffset[1] = kSpsSize;
fragmentation.fragmentationLength[1] = kPpsSize;
fragmentation.fragmentationOffset[2] = kSpsSize + kPpsSize;
fragmentation.fragmentationLength[2] =
encoded_image._length - (kSpsSize + kPpsSize);
const size_t kSpsNalHeader = 0x67;
const size_t kPpsNalHeader = 0x68;
const size_t kIdrNalHeader = 0x65;
encoded_image._buffer[fragmentation.fragmentationOffset[0]] = kSpsNalHeader;
encoded_image._buffer[fragmentation.fragmentationOffset[1]] = kPpsNalHeader;
encoded_image._buffer[fragmentation.fragmentationOffset[2]] = kIdrNalHeader;
} else {
const size_t kNumSlices = 1;
fragmentation.VerifyAndAllocateFragmentationHeader(kNumSlices);
fragmentation.fragmentationOffset[0] = 0;
fragmentation.fragmentationLength[0] = encoded_image._length;
const size_t kNalHeader = 0x41;
encoded_image._buffer[fragmentation.fragmentationOffset[0]] = kNalHeader;
}
uint8_t value = 0;
int fragment_counter = 0;
for (size_t i = 0; i < encoded_image._length; ++i) {
if (fragment_counter == fragmentation.fragmentationVectorSize ||
i != fragmentation.fragmentationOffset[fragment_counter]) {
encoded_image._buffer[i] = value++;
} else {
++fragment_counter;
}
}
CodecSpecificInfo specifics;
memset(&specifics, 0, sizeof(specifics));
specifics.codecType = kVideoCodecH264;
specifics.codecSpecific.H264.packetization_mode =
H264PacketizationMode::NonInterleaved;
RTC_DCHECK(callback);
return callback->OnEncodedImage(encoded_image, &specifics, &fragmentation);
}
DelayedEncoder::DelayedEncoder(Clock* clock, int delay_ms)
: test::FakeEncoder(clock), delay_ms_(delay_ms) {
// The encoder could be created on a different thread than
// it is being used on.
sequence_checker_.Detach();
}
void DelayedEncoder::SetDelay(int delay_ms) {
RTC_DCHECK_CALLED_SEQUENTIALLY(&sequence_checker_);
delay_ms_ = delay_ms;
}
int32_t DelayedEncoder::Encode(const VideoFrame& input_image,
const CodecSpecificInfo* codec_specific_info,
const std::vector<FrameType>* frame_types) {
RTC_DCHECK_CALLED_SEQUENTIALLY(&sequence_checker_);
SleepMs(delay_ms_);
return FakeEncoder::Encode(input_image, codec_specific_info, frame_types);
}
MultithreadedFakeH264Encoder::MultithreadedFakeH264Encoder(Clock* clock)
: test::FakeH264Encoder(clock),
current_queue_(0),
queue1_(nullptr),
queue2_(nullptr) {
// The encoder could be created on a different thread than
// it is being used on.
sequence_checker_.Detach();
}
int32_t MultithreadedFakeH264Encoder::InitEncode(const VideoCodec* config,
int32_t number_of_cores,
size_t max_payload_size) {
RTC_DCHECK_CALLED_SEQUENTIALLY(&sequence_checker_);
queue1_.reset(new rtc::TaskQueue("Queue 1"));
queue2_.reset(new rtc::TaskQueue("Queue 2"));
return FakeH264Encoder::InitEncode(config, number_of_cores, max_payload_size);
}
class MultithreadedFakeH264Encoder::EncodeTask : public rtc::QueuedTask {
public:
EncodeTask(MultithreadedFakeH264Encoder* encoder,
const VideoFrame& input_image,
const CodecSpecificInfo* codec_specific_info,
const std::vector<FrameType>* frame_types)
: encoder_(encoder),
input_image_(input_image),
codec_specific_info_(),
frame_types_(*frame_types) {
if (codec_specific_info)
codec_specific_info_ = *codec_specific_info;
}
private:
bool Run() override {
encoder_->EncodeCallback(input_image_, &codec_specific_info_,
&frame_types_);
return true;
}
MultithreadedFakeH264Encoder* const encoder_;
VideoFrame input_image_;
CodecSpecificInfo codec_specific_info_;
std::vector<FrameType> frame_types_;
};
int32_t MultithreadedFakeH264Encoder::Encode(
const VideoFrame& input_image,
const CodecSpecificInfo* codec_specific_info,
const std::vector<FrameType>* frame_types) {
RTC_DCHECK_CALLED_SEQUENTIALLY(&sequence_checker_);
std::unique_ptr<rtc::TaskQueue>& queue =
(current_queue_++ % 2 == 0) ? queue1_ : queue2_;
if (!queue) {
return WEBRTC_VIDEO_CODEC_UNINITIALIZED;
}
queue->PostTask(std::unique_ptr<rtc::QueuedTask>(
new EncodeTask(this, input_image, codec_specific_info, frame_types)));
return WEBRTC_VIDEO_CODEC_OK;
}
int32_t MultithreadedFakeH264Encoder::EncodeCallback(
const VideoFrame& input_image,
const CodecSpecificInfo* codec_specific_info,
const std::vector<FrameType>* frame_types) {
return FakeH264Encoder::Encode(input_image, codec_specific_info, frame_types);
}
int32_t MultithreadedFakeH264Encoder::Release() {
RTC_DCHECK_CALLED_SEQUENTIALLY(&sequence_checker_);
queue1_.reset();
queue2_.reset();
return FakeH264Encoder::Release();
}
} // namespace test
} // namespace webrtc
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