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webrtc_m130/webrtc/modules/video_coding/codecs/vp8/vp8_impl.cc
sprang 8f46c679d2 Extract bitrate allocation of spatial/temporal layers out of codec impl. 
This CL makes a number of intervowen changes:

* Add BitrateAllocation struct, that contains a codec independent view
  of how the target bitrate is distributed over spatial and temporal
  layers.

* Adds the BitrateAllocator interface, which takes a bitrate and frame
  rate and produces a BitrateAllocation.

* A default (non layered) implementation is added, and
  SimulcastRateAllocator is extended to fully handle VP8 allocation.
  This includes capturing TemporalLayer instances created by the
  encoder.

* ViEEncoder now owns both the bitrate allocator and the temporal layer
  factories for VP8. This allows allocation to happen fully outside of
  the encoder implementation.

This refactoring will make it possible for ViEEncoder to signal the
full picture of target bitrates to the RTCP module.

BUG=webrtc:6301

Review-Url: https://codereview.webrtc.org/2434073003
Cr-Commit-Position: refs/heads/master@{#14998}
2016-11-09 13:09:12 +00:00

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/*
* Copyright (c) 2012 The WebRTC project authors. All Rights Reserved.
*
* Use of this source code is governed by a BSD-style license
* that can be found in the LICENSE file in the root of the source
* tree. An additional intellectual property rights grant can be found
* in the file PATENTS. All contributing project authors may
* be found in the AUTHORS file in the root of the source tree.
*/
#include "webrtc/modules/video_coding/codecs/vp8/vp8_impl.h"
#include <stdlib.h>
#include <string.h>
#include <time.h>
#include <algorithm>
// NOTE(ajm): Path provided by gyp.
#include "libyuv/scale.h" // NOLINT
#include "libyuv/convert.h" // NOLINT
#include "webrtc/base/checks.h"
#include "webrtc/base/timeutils.h"
#include "webrtc/base/trace_event.h"
#include "webrtc/common_types.h"
#include "webrtc/common_video/libyuv/include/webrtc_libyuv.h"
#include "webrtc/modules/include/module_common_types.h"
#include "webrtc/modules/video_coding/include/video_codec_interface.h"
#include "webrtc/modules/video_coding/codecs/vp8/include/vp8_common_types.h"
#include "webrtc/modules/video_coding/codecs/vp8/screenshare_layers.h"
#include "webrtc/modules/video_coding/codecs/vp8/temporal_layers.h"
#include "webrtc/modules/video_coding/utility/simulcast_rate_allocator.h"
#include "webrtc/system_wrappers/include/clock.h"
#include "webrtc/system_wrappers/include/metrics.h"
namespace webrtc {
namespace {
enum { kVp8ErrorPropagationTh = 30 };
enum { kVp832ByteAlign = 32 };
// VP8 denoiser states.
enum denoiserState {
kDenoiserOff,
kDenoiserOnYOnly,
kDenoiserOnYUV,
kDenoiserOnYUVAggressive,
// Adaptive mode defaults to kDenoiserOnYUV on key frame, but may switch
// to kDenoiserOnYUVAggressive based on a computed noise metric.
kDenoiserOnAdaptive
};
// Greatest common divisior
int GCD(int a, int b) {
int c = a % b;
while (c != 0) {
a = b;
b = c;
c = a % b;
}
return b;
}
uint32_t SumStreamMaxBitrate(int streams, const VideoCodec& codec) {
uint32_t bitrate_sum = 0;
for (int i = 0; i < streams; ++i) {
bitrate_sum += codec.simulcastStream[i].maxBitrate;
}
return bitrate_sum;
}
int NumberOfStreams(const VideoCodec& codec) {
int streams =
codec.numberOfSimulcastStreams < 1 ? 1 : codec.numberOfSimulcastStreams;
uint32_t simulcast_max_bitrate = SumStreamMaxBitrate(streams, codec);
if (simulcast_max_bitrate == 0) {
streams = 1;
}
return streams;
}
bool ValidSimulcastResolutions(const VideoCodec& codec, int num_streams) {
if (codec.width != codec.simulcastStream[num_streams - 1].width ||
codec.height != codec.simulcastStream[num_streams - 1].height) {
return false;
}
for (int i = 0; i < num_streams; ++i) {
if (codec.width * codec.simulcastStream[i].height !=
codec.height * codec.simulcastStream[i].width) {
return false;
}
}
return true;
}
int NumStreamsDisabled(const std::vector<bool>& streams) {
int num_disabled = 0;
for (bool stream : streams) {
if (!stream)
++num_disabled;
}
return num_disabled;
}
} // namespace
VP8Encoder* VP8Encoder::Create() {
return new VP8EncoderImpl();
}
VP8Decoder* VP8Decoder::Create() {
return new VP8DecoderImpl();
}
VP8EncoderImpl::VP8EncoderImpl()
: encoded_complete_callback_(nullptr),
inited_(false),
timestamp_(0),
feedback_mode_(false),
qp_max_(56), // Setting for max quantizer.
cpu_speed_default_(-6),
number_of_cores_(0),
rc_max_intra_target_(0),
token_partitions_(VP8_ONE_TOKENPARTITION),
down_scale_requested_(false),
down_scale_bitrate_(0),
key_frame_request_(kMaxSimulcastStreams, false),
quality_scaler_enabled_(false) {
uint32_t seed = rtc::Time32();
srand(seed);
picture_id_.reserve(kMaxSimulcastStreams);
last_key_frame_picture_id_.reserve(kMaxSimulcastStreams);
temporal_layers_.reserve(kMaxSimulcastStreams);
raw_images_.reserve(kMaxSimulcastStreams);
encoded_images_.reserve(kMaxSimulcastStreams);
send_stream_.reserve(kMaxSimulcastStreams);
cpu_speed_.assign(kMaxSimulcastStreams, -6); // Set default to -6.
encoders_.reserve(kMaxSimulcastStreams);
configurations_.reserve(kMaxSimulcastStreams);
downsampling_factors_.reserve(kMaxSimulcastStreams);
}
VP8EncoderImpl::~VP8EncoderImpl() {
Release();
}
int VP8EncoderImpl::Release() {
int ret_val = WEBRTC_VIDEO_CODEC_OK;
while (!encoded_images_.empty()) {
EncodedImage& image = encoded_images_.back();
delete[] image._buffer;
encoded_images_.pop_back();
}
while (!encoders_.empty()) {
vpx_codec_ctx_t& encoder = encoders_.back();
if (vpx_codec_destroy(&encoder)) {
ret_val = WEBRTC_VIDEO_CODEC_MEMORY;
}
encoders_.pop_back();
}
configurations_.clear();
send_stream_.clear();
cpu_speed_.clear();
while (!raw_images_.empty()) {
vpx_img_free(&raw_images_.back());
raw_images_.pop_back();
}
while (!temporal_layers_.empty()) {
delete temporal_layers_.back();
temporal_layers_.pop_back();
}
inited_ = false;
return ret_val;
}
int VP8EncoderImpl::SetRateAllocation(const BitrateAllocation& bitrate,
uint32_t new_framerate) {
if (!inited_)
return WEBRTC_VIDEO_CODEC_UNINITIALIZED;
if (encoders_[0].err)
return WEBRTC_VIDEO_CODEC_ERROR;
if (new_framerate < 1)
return WEBRTC_VIDEO_CODEC_ERR_PARAMETER;
if (bitrate.get_sum_bps() == 0) {
// Encoder paused, turn off all encoding.
const int num_streams = static_cast<size_t>(encoders_.size());
for (int i = 0; i < num_streams; ++i)
SetStreamState(false, i);
return WEBRTC_VIDEO_CODEC_OK;
}
// At this point, bitrate allocation should already match codec settings.
if (codec_.maxBitrate > 0)
RTC_DCHECK_LE(bitrate.get_sum_kbps(), codec_.maxBitrate);
RTC_DCHECK_GE(bitrate.get_sum_kbps(), codec_.minBitrate);
if (codec_.numberOfSimulcastStreams > 0)
RTC_DCHECK_GE(bitrate.get_sum_kbps(), codec_.simulcastStream[0].minBitrate);
codec_.maxFramerate = new_framerate;
if (encoders_.size() == 1) {
// 1:1.
// Calculate a rough limit for when to trigger a potental down scale.
uint32_t k_pixels_per_frame = codec_.width * codec_.height / 1000;
// TODO(pwestin): we currently lack CAMA, this is a temporary fix to work
// around the current limitations.
// Only trigger keyframes if we are allowed to scale down.
if (configurations_[0].rc_resize_allowed) {
if (!down_scale_requested_) {
if (k_pixels_per_frame > bitrate.get_sum_kbps()) {
down_scale_requested_ = true;
down_scale_bitrate_ = bitrate.get_sum_kbps();
key_frame_request_[0] = true;
}
} else {
if (bitrate.get_sum_kbps() > (2 * down_scale_bitrate_) ||
bitrate.get_sum_kbps() < (down_scale_bitrate_ / 2)) {
down_scale_requested_ = false;
}
}
}
} else {
// If we have more than 1 stream, reduce the qp_max for the low resolution
// stream if frame rate is not too low. The trade-off with lower qp_max is
// possibly more dropped frames, so we only do this if the frame rate is
// above some threshold (base temporal layer is down to 1/4 for 3 layers).
// We may want to condition this on bitrate later.
if (new_framerate > 20) {
configurations_[encoders_.size() - 1].rc_max_quantizer = 45;
} else {
// Go back to default value set in InitEncode.
configurations_[encoders_.size() - 1].rc_max_quantizer = qp_max_;
}
}
size_t stream_idx = encoders_.size() - 1;
for (size_t i = 0; i < encoders_.size(); ++i, --stream_idx) {
unsigned int target_bitrate_kbps =
bitrate.GetSpatialLayerSum(stream_idx) / 1000;
bool send_stream = target_bitrate_kbps > 0;
if (send_stream || encoders_.size() > 1)
SetStreamState(send_stream, stream_idx);
configurations_[i].rc_target_bitrate = target_bitrate_kbps;
temporal_layers_[stream_idx]->UpdateConfiguration(&configurations_[i]);
if (vpx_codec_enc_config_set(&encoders_[i], &configurations_[i])) {
return WEBRTC_VIDEO_CODEC_ERROR;
}
}
quality_scaler_.ReportFramerate(new_framerate);
return WEBRTC_VIDEO_CODEC_OK;
}
void VP8EncoderImpl::OnDroppedFrame() {
if (quality_scaler_enabled_)
quality_scaler_.ReportDroppedFrame();
}
const char* VP8EncoderImpl::ImplementationName() const {
return "libvpx";
}
void VP8EncoderImpl::SetStreamState(bool send_stream,
int stream_idx) {
if (send_stream && !send_stream_[stream_idx]) {
// Need a key frame if we have not sent this stream before.
key_frame_request_[stream_idx] = true;
}
send_stream_[stream_idx] = send_stream;
}
void VP8EncoderImpl::SetupTemporalLayers(int num_streams,
int num_temporal_layers,
const VideoCodec& codec) {
RTC_DCHECK(codec.codecSpecific.VP8.tl_factory != nullptr);
const TemporalLayersFactory* tl_factory = codec.codecSpecific.VP8.tl_factory;
if (num_streams == 1) {
temporal_layers_.push_back(
tl_factory->Create(0, num_temporal_layers, rand()));
} else {
for (int i = 0; i < num_streams; ++i) {
RTC_CHECK_GT(num_temporal_layers, 0);
int layers = std::max(static_cast<uint8_t>(1),
codec.simulcastStream[i].numberOfTemporalLayers);
temporal_layers_.push_back(tl_factory->Create(i, layers, rand()));
}
}
}
int VP8EncoderImpl::InitEncode(const VideoCodec* inst,
int number_of_cores,
size_t /*maxPayloadSize */) {
if (inst == NULL) {
return WEBRTC_VIDEO_CODEC_ERR_PARAMETER;
}
if (inst->maxFramerate < 1) {
return WEBRTC_VIDEO_CODEC_ERR_PARAMETER;
}
// allow zero to represent an unspecified maxBitRate
if (inst->maxBitrate > 0 && inst->startBitrate > inst->maxBitrate) {
return WEBRTC_VIDEO_CODEC_ERR_PARAMETER;
}
if (inst->width <= 1 || inst->height <= 1) {
return WEBRTC_VIDEO_CODEC_ERR_PARAMETER;
}
if (number_of_cores < 1) {
return WEBRTC_VIDEO_CODEC_ERR_PARAMETER;
}
if (inst->VP8().feedbackModeOn && inst->numberOfSimulcastStreams > 1) {
return WEBRTC_VIDEO_CODEC_ERR_PARAMETER;
}
if (inst->VP8().automaticResizeOn && inst->numberOfSimulcastStreams > 1) {
return WEBRTC_VIDEO_CODEC_ERR_PARAMETER;
}
int retVal = Release();
if (retVal < 0) {
return retVal;
}
int number_of_streams = NumberOfStreams(*inst);
bool doing_simulcast = (number_of_streams > 1);
if (doing_simulcast && !ValidSimulcastResolutions(*inst, number_of_streams)) {
return WEBRTC_VIDEO_CODEC_ERR_PARAMETER;
}
int num_temporal_layers =
doing_simulcast ? inst->simulcastStream[0].numberOfTemporalLayers
: inst->VP8().numberOfTemporalLayers;
RTC_DCHECK_GT(num_temporal_layers, 0);
SetupTemporalLayers(number_of_streams, num_temporal_layers, *inst);
feedback_mode_ = inst->VP8().feedbackModeOn;
number_of_cores_ = number_of_cores;
timestamp_ = 0;
codec_ = *inst;
// Code expects simulcastStream resolutions to be correct, make sure they are
// filled even when there are no simulcast layers.
if (codec_.numberOfSimulcastStreams == 0) {
codec_.simulcastStream[0].width = codec_.width;
codec_.simulcastStream[0].height = codec_.height;
}
picture_id_.resize(number_of_streams);
last_key_frame_picture_id_.resize(number_of_streams);
encoded_images_.resize(number_of_streams);
encoders_.resize(number_of_streams);
configurations_.resize(number_of_streams);
downsampling_factors_.resize(number_of_streams);
raw_images_.resize(number_of_streams);
send_stream_.resize(number_of_streams);
send_stream_[0] = true; // For non-simulcast case.
cpu_speed_.resize(number_of_streams);
std::fill(key_frame_request_.begin(), key_frame_request_.end(), false);
int idx = number_of_streams - 1;
for (int i = 0; i < (number_of_streams - 1); ++i, --idx) {
int gcd = GCD(inst->simulcastStream[idx].width,
inst->simulcastStream[idx - 1].width);
downsampling_factors_[i].num = inst->simulcastStream[idx].width / gcd;
downsampling_factors_[i].den = inst->simulcastStream[idx - 1].width / gcd;
send_stream_[i] = false;
}
if (number_of_streams > 1) {
send_stream_[number_of_streams - 1] = false;
downsampling_factors_[number_of_streams - 1].num = 1;
downsampling_factors_[number_of_streams - 1].den = 1;
}
for (int i = 0; i < number_of_streams; ++i) {
// Random start, 16 bits is enough.
picture_id_[i] = static_cast<uint16_t>(rand()) & 0x7FFF; // NOLINT
last_key_frame_picture_id_[i] = -1;
// allocate memory for encoded image
if (encoded_images_[i]._buffer != NULL) {
delete[] encoded_images_[i]._buffer;
}
encoded_images_[i]._size =
CalcBufferSize(kI420, codec_.width, codec_.height);
encoded_images_[i]._buffer = new uint8_t[encoded_images_[i]._size];
encoded_images_[i]._completeFrame = true;
}
// populate encoder configuration with default values
if (vpx_codec_enc_config_default(vpx_codec_vp8_cx(), &configurations_[0],
0)) {
return WEBRTC_VIDEO_CODEC_ERROR;
}
// setting the time base of the codec
configurations_[0].g_timebase.num = 1;
configurations_[0].g_timebase.den = 90000;
configurations_[0].g_lag_in_frames = 0; // 0- no frame lagging
// Set the error resilience mode according to user settings.
switch (inst->VP8().resilience) {
case kResilienceOff:
// TODO(marpan): We should set keep error resilience off for this mode,
// independent of temporal layer settings, and make sure we set
// |codecSpecific.VP8.resilience| = |kResilientStream| at higher level
// code if we want to get error resilience on.
configurations_[0].g_error_resilient = 1;
break;
case kResilientStream:
configurations_[0].g_error_resilient = 1; // TODO(holmer): Replace with
// VPX_ERROR_RESILIENT_DEFAULT when we
// drop support for libvpx 9.6.0.
break;
case kResilientFrames:
return WEBRTC_VIDEO_CODEC_ERR_PARAMETER; // Not supported
}
// rate control settings
configurations_[0].rc_dropframe_thresh = inst->VP8().frameDroppingOn ? 30 : 0;
configurations_[0].rc_end_usage = VPX_CBR;
configurations_[0].g_pass = VPX_RC_ONE_PASS;
// TODO(hellner): investigate why the following two lines produce
// automaticResizeOn value of 3 when running
// WebRtcVideoMediaChannelTest.GetStatsMultipleSendStreams inside the talk
// framework.
// configurations_[0].rc_resize_allowed =
// inst->codecSpecific.VP8.automaticResizeOn ? 1 : 0;
configurations_[0].rc_resize_allowed = 0;
// Handle resizing outside of libvpx when doing single-stream.
if (inst->VP8().automaticResizeOn && number_of_streams > 1) {
configurations_[0].rc_resize_allowed = 1;
}
configurations_[0].rc_min_quantizer = 2;
if (inst->qpMax >= configurations_[0].rc_min_quantizer) {
qp_max_ = inst->qpMax;
}
configurations_[0].rc_max_quantizer = qp_max_;
configurations_[0].rc_undershoot_pct = 100;
configurations_[0].rc_overshoot_pct = 15;
configurations_[0].rc_buf_initial_sz = 500;
configurations_[0].rc_buf_optimal_sz = 600;
configurations_[0].rc_buf_sz = 1000;
// Set the maximum target size of any key-frame.
rc_max_intra_target_ = MaxIntraTarget(configurations_[0].rc_buf_optimal_sz);
if (feedback_mode_) {
// Disable periodic key frames if we get feedback from the decoder
// through SLI and RPSI.
configurations_[0].kf_mode = VPX_KF_DISABLED;
} else if (inst->VP8().keyFrameInterval > 0) {
configurations_[0].kf_mode = VPX_KF_AUTO;
configurations_[0].kf_max_dist = inst->VP8().keyFrameInterval;
} else {
configurations_[0].kf_mode = VPX_KF_DISABLED;
}
// Allow the user to set the complexity for the base stream.
switch (inst->VP8().complexity) {
case kComplexityHigh:
cpu_speed_[0] = -5;
break;
case kComplexityHigher:
cpu_speed_[0] = -4;
break;
case kComplexityMax:
cpu_speed_[0] = -3;
break;
default:
cpu_speed_[0] = -6;
break;
}
cpu_speed_default_ = cpu_speed_[0];
// Set encoding complexity (cpu_speed) based on resolution and/or platform.
cpu_speed_[0] = SetCpuSpeed(inst->width, inst->height);
for (int i = 1; i < number_of_streams; ++i) {
cpu_speed_[i] =
SetCpuSpeed(inst->simulcastStream[number_of_streams - 1 - i].width,
inst->simulcastStream[number_of_streams - 1 - i].height);
}
configurations_[0].g_w = inst->width;
configurations_[0].g_h = inst->height;
// Determine number of threads based on the image size and #cores.
// TODO(fbarchard): Consider number of Simulcast layers.
configurations_[0].g_threads = NumberOfThreads(
configurations_[0].g_w, configurations_[0].g_h, number_of_cores);
// Creating a wrapper to the image - setting image data to NULL.
// Actual pointer will be set in encode. Setting align to 1, as it
// is meaningless (no memory allocation is done here).
vpx_img_wrap(&raw_images_[0], VPX_IMG_FMT_I420, inst->width, inst->height, 1,
NULL);
// Note the order we use is different from webm, we have lowest resolution
// at position 0 and they have highest resolution at position 0.
int stream_idx = encoders_.size() - 1;
SimulcastRateAllocator init_allocator(codec_, nullptr);
BitrateAllocation allocation = init_allocator.GetAllocation(
inst->startBitrate * 1000, inst->maxFramerate);
std::vector<uint32_t> stream_bitrates;
for (int i = 0; i == 0 || i < inst->numberOfSimulcastStreams; ++i) {
uint32_t bitrate = allocation.GetSpatialLayerSum(i) / 1000;
stream_bitrates.push_back(bitrate);
}
configurations_[0].rc_target_bitrate = stream_bitrates[stream_idx];
temporal_layers_[stream_idx]->OnRatesUpdated(
stream_bitrates[stream_idx], inst->maxBitrate, inst->maxFramerate);
temporal_layers_[stream_idx]->UpdateConfiguration(&configurations_[0]);
--stream_idx;
for (size_t i = 1; i < encoders_.size(); ++i, --stream_idx) {
memcpy(&configurations_[i], &configurations_[0],
sizeof(configurations_[0]));
configurations_[i].g_w = inst->simulcastStream[stream_idx].width;
configurations_[i].g_h = inst->simulcastStream[stream_idx].height;
// Use 1 thread for lower resolutions.
configurations_[i].g_threads = 1;
// Setting alignment to 32 - as that ensures at least 16 for all
// planes (32 for Y, 16 for U,V). Libvpx sets the requested stride for
// the y plane, but only half of it to the u and v planes.
vpx_img_alloc(&raw_images_[i], VPX_IMG_FMT_I420,
inst->simulcastStream[stream_idx].width,
inst->simulcastStream[stream_idx].height, kVp832ByteAlign);
SetStreamState(stream_bitrates[stream_idx] > 0, stream_idx);
configurations_[i].rc_target_bitrate = stream_bitrates[stream_idx];
temporal_layers_[stream_idx]->OnRatesUpdated(
stream_bitrates[stream_idx], inst->maxBitrate, inst->maxFramerate);
temporal_layers_[stream_idx]->UpdateConfiguration(&configurations_[i]);
}
rps_.Init();
quality_scaler_.Init(codec_.codecType, codec_.startBitrate, codec_.width,
codec_.height, codec_.maxFramerate);
// Only apply scaling to improve for single-layer streams. The scaling metrics
// use frame drops as a signal and is only applicable when we drop frames.
quality_scaler_enabled_ = encoders_.size() == 1 &&
configurations_[0].rc_dropframe_thresh > 0 &&
codec_.VP8()->automaticResizeOn;
return InitAndSetControlSettings();
}
int VP8EncoderImpl::SetCpuSpeed(int width, int height) {
#if defined(WEBRTC_ARCH_ARM) || defined(WEBRTC_ARCH_ARM64) || defined(ANDROID)
// On mobile platform, use a lower speed setting for lower resolutions for
// CPUs with 4 or more cores.
RTC_DCHECK_GT(number_of_cores_, 0);
if (number_of_cores_ <= 3)
return -12;
if (width * height <= 352 * 288)
return -8;
else if (width * height <= 640 * 480)
return -10;
else
return -12;
#else
// For non-ARM, increase encoding complexity (i.e., use lower speed setting)
// if resolution is below CIF. Otherwise, keep the default/user setting
// (|cpu_speed_default_|) set on InitEncode via VP8().complexity.
if (width * height < 352 * 288)
return (cpu_speed_default_ < -4) ? -4 : cpu_speed_default_;
else
return cpu_speed_default_;
#endif
}
int VP8EncoderImpl::NumberOfThreads(int width, int height, int cpus) {
#if defined(ANDROID)
if (width * height >= 320 * 180) {
if (cpus >= 4) {
// 3 threads for CPUs with 4 and more cores since most of times only 4
// cores will be active.
return 3;
} else if (cpus == 3 || cpus == 2) {
return 2;
} else {
return 1;
}
}
return 1;
#else
if (width * height >= 1920 * 1080 && cpus > 8) {
return 8; // 8 threads for 1080p on high perf machines.
} else if (width * height > 1280 * 960 && cpus >= 6) {
// 3 threads for 1080p.
return 3;
} else if (width * height > 640 * 480 && cpus >= 3) {
// 2 threads for qHD/HD.
return 2;
} else {
// 1 thread for VGA or less.
return 1;
}
#endif
}
int VP8EncoderImpl::InitAndSetControlSettings() {
vpx_codec_flags_t flags = 0;
flags |= VPX_CODEC_USE_OUTPUT_PARTITION;
if (encoders_.size() > 1) {
int error = vpx_codec_enc_init_multi(&encoders_[0], vpx_codec_vp8_cx(),
&configurations_[0], encoders_.size(),
flags, &downsampling_factors_[0]);
if (error) {
return WEBRTC_VIDEO_CODEC_UNINITIALIZED;
}
} else {
if (vpx_codec_enc_init(&encoders_[0], vpx_codec_vp8_cx(),
&configurations_[0], flags)) {
return WEBRTC_VIDEO_CODEC_UNINITIALIZED;
}
}
// Enable denoising for the highest resolution stream, and for
// the second highest resolution if we are doing more than 2
// spatial layers/streams.
// TODO(holmer): Investigate possibility of adding a libvpx API
// for getting the denoised frame from the encoder and using that
// when encoding lower resolution streams. Would it work with the
// multi-res encoding feature?
denoiserState denoiser_state = kDenoiserOnYOnly;
#if defined(WEBRTC_ARCH_ARM) || defined(WEBRTC_ARCH_ARM64) || defined(ANDROID)
denoiser_state = kDenoiserOnYOnly;
#else
denoiser_state = kDenoiserOnAdaptive;
#endif
vpx_codec_control(&encoders_[0], VP8E_SET_NOISE_SENSITIVITY,
codec_.VP8()->denoisingOn ? denoiser_state : kDenoiserOff);
if (encoders_.size() > 2) {
vpx_codec_control(
&encoders_[1], VP8E_SET_NOISE_SENSITIVITY,
codec_.VP8()->denoisingOn ? denoiser_state : kDenoiserOff);
}
for (size_t i = 0; i < encoders_.size(); ++i) {
// Allow more screen content to be detected as static.
vpx_codec_control(&(encoders_[i]), VP8E_SET_STATIC_THRESHOLD,
codec_.mode == kScreensharing ? 300 : 1);
vpx_codec_control(&(encoders_[i]), VP8E_SET_CPUUSED, cpu_speed_[i]);
vpx_codec_control(&(encoders_[i]), VP8E_SET_TOKEN_PARTITIONS,
static_cast<vp8e_token_partitions>(token_partitions_));
vpx_codec_control(&(encoders_[i]), VP8E_SET_MAX_INTRA_BITRATE_PCT,
rc_max_intra_target_);
// VP8E_SET_SCREEN_CONTENT_MODE 2 = screen content with more aggressive
// rate control (drop frames on large target bitrate overshoot)
vpx_codec_control(&(encoders_[i]), VP8E_SET_SCREEN_CONTENT_MODE,
codec_.mode == kScreensharing ? 2 : 0);
}
inited_ = true;
return WEBRTC_VIDEO_CODEC_OK;
}
uint32_t VP8EncoderImpl::MaxIntraTarget(uint32_t optimalBuffersize) {
// Set max to the optimal buffer level (normalized by target BR),
// and scaled by a scalePar.
// Max target size = scalePar * optimalBufferSize * targetBR[Kbps].
// This values is presented in percentage of perFrameBw:
// perFrameBw = targetBR[Kbps] * 1000 / frameRate.
// The target in % is as follows:
float scalePar = 0.5;
uint32_t targetPct = optimalBuffersize * scalePar * codec_.maxFramerate / 10;
// Don't go below 3 times the per frame bandwidth.
const uint32_t minIntraTh = 300;
return (targetPct < minIntraTh) ? minIntraTh : targetPct;
}
int VP8EncoderImpl::Encode(const VideoFrame& frame,
const CodecSpecificInfo* codec_specific_info,
const std::vector<FrameType>* frame_types) {
if (!inited_)
return WEBRTC_VIDEO_CODEC_UNINITIALIZED;
if (frame.IsZeroSize())
return WEBRTC_VIDEO_CODEC_ERR_PARAMETER;
if (encoded_complete_callback_ == NULL)
return WEBRTC_VIDEO_CODEC_UNINITIALIZED;
rtc::scoped_refptr<VideoFrameBuffer> input_image = frame.video_frame_buffer();
if (quality_scaler_enabled_) {
quality_scaler_.OnEncodeFrame(frame.width(), frame.height());
input_image = quality_scaler_.GetScaledBuffer(input_image);
if (input_image->width() != codec_.width ||
input_image->height() != codec_.height) {
int ret =
UpdateCodecFrameSize(input_image->width(), input_image->height());
if (ret < 0)
return ret;
}
}
// Since we are extracting raw pointers from |input_image| to
// |raw_images_[0]|, the resolution of these frames must match. Note that
// |input_image| might be scaled from |frame|. In that case, the resolution of
// |raw_images_[0]| should have been updated in UpdateCodecFrameSize.
RTC_DCHECK_EQ(input_image->width(), static_cast<int>(raw_images_[0].d_w));
RTC_DCHECK_EQ(input_image->height(), static_cast<int>(raw_images_[0].d_h));
// Image in vpx_image_t format.
// Input image is const. VP8's raw image is not defined as const.
raw_images_[0].planes[VPX_PLANE_Y] =
const_cast<uint8_t*>(input_image->DataY());
raw_images_[0].planes[VPX_PLANE_U] =
const_cast<uint8_t*>(input_image->DataU());
raw_images_[0].planes[VPX_PLANE_V] =
const_cast<uint8_t*>(input_image->DataV());
raw_images_[0].stride[VPX_PLANE_Y] = input_image->StrideY();
raw_images_[0].stride[VPX_PLANE_U] = input_image->StrideU();
raw_images_[0].stride[VPX_PLANE_V] = input_image->StrideV();
for (size_t i = 1; i < encoders_.size(); ++i) {
// Scale the image down a number of times by downsampling factor
libyuv::I420Scale(
raw_images_[i - 1].planes[VPX_PLANE_Y],
raw_images_[i - 1].stride[VPX_PLANE_Y],
raw_images_[i - 1].planes[VPX_PLANE_U],
raw_images_[i - 1].stride[VPX_PLANE_U],
raw_images_[i - 1].planes[VPX_PLANE_V],
raw_images_[i - 1].stride[VPX_PLANE_V], raw_images_[i - 1].d_w,
raw_images_[i - 1].d_h, raw_images_[i].planes[VPX_PLANE_Y],
raw_images_[i].stride[VPX_PLANE_Y], raw_images_[i].planes[VPX_PLANE_U],
raw_images_[i].stride[VPX_PLANE_U], raw_images_[i].planes[VPX_PLANE_V],
raw_images_[i].stride[VPX_PLANE_V], raw_images_[i].d_w,
raw_images_[i].d_h, libyuv::kFilterBilinear);
}
vpx_enc_frame_flags_t flags[kMaxSimulcastStreams];
for (size_t i = 0; i < encoders_.size(); ++i) {
int ret = temporal_layers_[i]->EncodeFlags(frame.timestamp());
if (ret < 0) {
// Drop this frame.
return WEBRTC_VIDEO_CODEC_OK;
}
flags[i] = ret;
}
bool send_key_frame = false;
for (size_t i = 0; i < key_frame_request_.size() && i < send_stream_.size();
++i) {
if (key_frame_request_[i] && send_stream_[i]) {
send_key_frame = true;
break;
}
}
if (!send_key_frame && frame_types) {
for (size_t i = 0; i < frame_types->size() && i < send_stream_.size();
++i) {
if ((*frame_types)[i] == kVideoFrameKey && send_stream_[i]) {
send_key_frame = true;
break;
}
}
}
// The flag modification below (due to forced key frame, RPS, etc.,) for now
// will be the same for all encoders/spatial layers.
// TODO(marpan/holmer): Allow for key frame request to be set per encoder.
bool only_predict_from_key_frame = false;
if (send_key_frame) {
// Adapt the size of the key frame when in screenshare with 1 temporal
// layer.
if (encoders_.size() == 1 && codec_.mode == kScreensharing &&
codec_.VP8()->numberOfTemporalLayers <= 1) {
const uint32_t forceKeyFrameIntraTh = 100;
vpx_codec_control(&(encoders_[0]), VP8E_SET_MAX_INTRA_BITRATE_PCT,
forceKeyFrameIntraTh);
}
// Key frame request from caller.
// Will update both golden and alt-ref.
for (size_t i = 0; i < encoders_.size(); ++i) {
flags[i] = VPX_EFLAG_FORCE_KF;
}
std::fill(key_frame_request_.begin(), key_frame_request_.end(), false);
} else if (codec_specific_info &&
codec_specific_info->codecType == kVideoCodecVP8) {
if (feedback_mode_) {
// Handle RPSI and SLI messages and set up the appropriate encode flags.
bool sendRefresh = false;
if (codec_specific_info->codecSpecific.VP8.hasReceivedRPSI) {
rps_.ReceivedRPSI(codec_specific_info->codecSpecific.VP8.pictureIdRPSI);
}
if (codec_specific_info->codecSpecific.VP8.hasReceivedSLI) {
sendRefresh = rps_.ReceivedSLI(frame.timestamp());
}
for (size_t i = 0; i < encoders_.size(); ++i) {
flags[i] = rps_.EncodeFlags(picture_id_[i], sendRefresh,
frame.timestamp());
}
} else {
if (codec_specific_info->codecSpecific.VP8.hasReceivedRPSI) {
// Is this our last key frame? If not ignore.
// |picture_id_| is defined per spatial stream/layer, so check that
// |RPSI| matches the last key frame from any of the spatial streams.
// If so, then all spatial streams for this encoding will predict from
// its long-term reference (last key frame).
int RPSI = codec_specific_info->codecSpecific.VP8.pictureIdRPSI;
for (size_t i = 0; i < encoders_.size(); ++i) {
if (last_key_frame_picture_id_[i] == RPSI) {
// Request for a long term reference frame.
// Note 1: overwrites any temporal settings.
// Note 2: VP8_EFLAG_NO_UPD_ENTROPY is not needed as that flag is
// set by error_resilient mode.
for (size_t j = 0; j < encoders_.size(); ++j) {
flags[j] = VP8_EFLAG_NO_UPD_ARF;
flags[j] |= VP8_EFLAG_NO_REF_GF;
flags[j] |= VP8_EFLAG_NO_REF_LAST;
}
only_predict_from_key_frame = true;
break;
}
}
}
}
}
// Set the encoder frame flags and temporal layer_id for each spatial stream.
// Note that |temporal_layers_| are defined starting from lowest resolution at
// position 0 to highest resolution at position |encoders_.size() - 1|,
// whereas |encoder_| is from highest to lowest resolution.
size_t stream_idx = encoders_.size() - 1;
for (size_t i = 0; i < encoders_.size(); ++i, --stream_idx) {
// Allow the layers adapter to temporarily modify the configuration. This
// change isn't stored in configurations_ so change will be discarded at
// the next update.
vpx_codec_enc_cfg_t temp_config;
memcpy(&temp_config, &configurations_[i], sizeof(vpx_codec_enc_cfg_t));
if (temporal_layers_[stream_idx]->UpdateConfiguration(&temp_config)) {
if (vpx_codec_enc_config_set(&encoders_[i], &temp_config))
return WEBRTC_VIDEO_CODEC_ERROR;
}
vpx_codec_control(&encoders_[i], VP8E_SET_FRAME_FLAGS, flags[stream_idx]);
vpx_codec_control(&encoders_[i], VP8E_SET_TEMPORAL_LAYER_ID,
temporal_layers_[stream_idx]->CurrentLayerId());
}
// TODO(holmer): Ideally the duration should be the timestamp diff of this
// frame and the next frame to be encoded, which we don't have. Instead we
// would like to use the duration of the previous frame. Unfortunately the
// rate control seems to be off with that setup. Using the average input
// frame rate to calculate an average duration for now.
assert(codec_.maxFramerate > 0);
uint32_t duration = 90000 / codec_.maxFramerate;
// Note we must pass 0 for |flags| field in encode call below since they are
// set above in |vpx_codec_control| function for each encoder/spatial layer.
int error = vpx_codec_encode(&encoders_[0], &raw_images_[0], timestamp_,
duration, 0, VPX_DL_REALTIME);
// Reset specific intra frame thresholds, following the key frame.
if (send_key_frame) {
vpx_codec_control(&(encoders_[0]), VP8E_SET_MAX_INTRA_BITRATE_PCT,
rc_max_intra_target_);
}
if (error)
return WEBRTC_VIDEO_CODEC_ERROR;
timestamp_ += duration;
// Examines frame timestamps only.
return GetEncodedPartitions(frame, only_predict_from_key_frame);
}
// TODO(pbos): Make sure this works for properly for >1 encoders.
int VP8EncoderImpl::UpdateCodecFrameSize(int width, int height) {
codec_.width = width;
codec_.height = height;
if (codec_.numberOfSimulcastStreams <= 1) {
// For now scaling is only used for single-layer streams.
codec_.simulcastStream[0].width = width;
codec_.simulcastStream[0].height = height;
}
// Update the cpu_speed setting for resolution change.
vpx_codec_control(&(encoders_[0]), VP8E_SET_CPUUSED,
SetCpuSpeed(codec_.width, codec_.height));
raw_images_[0].w = codec_.width;
raw_images_[0].h = codec_.height;
raw_images_[0].d_w = codec_.width;
raw_images_[0].d_h = codec_.height;
vpx_img_set_rect(&raw_images_[0], 0, 0, codec_.width, codec_.height);
// Update encoder context for new frame size.
// Change of frame size will automatically trigger a key frame.
configurations_[0].g_w = codec_.width;
configurations_[0].g_h = codec_.height;
if (vpx_codec_enc_config_set(&encoders_[0], &configurations_[0])) {
return WEBRTC_VIDEO_CODEC_ERROR;
}
return WEBRTC_VIDEO_CODEC_OK;
}
void VP8EncoderImpl::PopulateCodecSpecific(
CodecSpecificInfo* codec_specific,
const vpx_codec_cx_pkt_t& pkt,
int stream_idx,
uint32_t timestamp,
bool only_predicting_from_key_frame) {
assert(codec_specific != NULL);
codec_specific->codecType = kVideoCodecVP8;
codec_specific->codec_name = ImplementationName();
CodecSpecificInfoVP8* vp8Info = &(codec_specific->codecSpecific.VP8);
vp8Info->pictureId = picture_id_[stream_idx];
if (pkt.data.frame.flags & VPX_FRAME_IS_KEY) {
last_key_frame_picture_id_[stream_idx] = picture_id_[stream_idx];
}
vp8Info->simulcastIdx = stream_idx;
vp8Info->keyIdx = kNoKeyIdx; // TODO(hlundin) populate this
vp8Info->nonReference =
(pkt.data.frame.flags & VPX_FRAME_IS_DROPPABLE) ? true : false;
bool base_layer_sync_point = (pkt.data.frame.flags & VPX_FRAME_IS_KEY) ||
only_predicting_from_key_frame;
temporal_layers_[stream_idx]->PopulateCodecSpecific(base_layer_sync_point,
vp8Info, timestamp);
// Prepare next.
picture_id_[stream_idx] = (picture_id_[stream_idx] + 1) & 0x7FFF;
}
int VP8EncoderImpl::GetEncodedPartitions(const VideoFrame& input_image,
bool only_predicting_from_key_frame) {
int bw_resolutions_disabled =
(encoders_.size() > 1) ? NumStreamsDisabled(send_stream_) : -1;
int stream_idx = static_cast<int>(encoders_.size()) - 1;
int result = WEBRTC_VIDEO_CODEC_OK;
for (size_t encoder_idx = 0; encoder_idx < encoders_.size();
++encoder_idx, --stream_idx) {
vpx_codec_iter_t iter = NULL;
int part_idx = 0;
encoded_images_[encoder_idx]._length = 0;
encoded_images_[encoder_idx]._frameType = kVideoFrameDelta;
RTPFragmentationHeader frag_info;
// token_partitions_ is number of bits used.
frag_info.VerifyAndAllocateFragmentationHeader((1 << token_partitions_) +
1);
CodecSpecificInfo codec_specific;
const vpx_codec_cx_pkt_t* pkt = NULL;
while ((pkt = vpx_codec_get_cx_data(&encoders_[encoder_idx], &iter)) !=
NULL) {
switch (pkt->kind) {
case VPX_CODEC_CX_FRAME_PKT: {
size_t length = encoded_images_[encoder_idx]._length;
if (pkt->data.frame.sz + length >
encoded_images_[encoder_idx]._size) {
uint8_t* buffer = new uint8_t[pkt->data.frame.sz + length];
memcpy(buffer, encoded_images_[encoder_idx]._buffer, length);
delete[] encoded_images_[encoder_idx]._buffer;
encoded_images_[encoder_idx]._buffer = buffer;
encoded_images_[encoder_idx]._size = pkt->data.frame.sz + length;
}
memcpy(&encoded_images_[encoder_idx]._buffer[length],
pkt->data.frame.buf, pkt->data.frame.sz);
frag_info.fragmentationOffset[part_idx] = length;
frag_info.fragmentationLength[part_idx] = pkt->data.frame.sz;
frag_info.fragmentationPlType[part_idx] = 0; // not known here
frag_info.fragmentationTimeDiff[part_idx] = 0;
encoded_images_[encoder_idx]._length += pkt->data.frame.sz;
assert(length <= encoded_images_[encoder_idx]._size);
++part_idx;
break;
}
default:
break;
}
// End of frame
if ((pkt->data.frame.flags & VPX_FRAME_IS_FRAGMENT) == 0) {
// check if encoded frame is a key frame
if (pkt->data.frame.flags & VPX_FRAME_IS_KEY) {
encoded_images_[encoder_idx]._frameType = kVideoFrameKey;
rps_.EncodedKeyFrame(picture_id_[stream_idx]);
}
PopulateCodecSpecific(&codec_specific, *pkt, stream_idx,
input_image.timestamp(),
only_predicting_from_key_frame);
break;
}
}
encoded_images_[encoder_idx]._timeStamp = input_image.timestamp();
encoded_images_[encoder_idx].capture_time_ms_ =
input_image.render_time_ms();
encoded_images_[encoder_idx].rotation_ = input_image.rotation();
int qp = -1;
vpx_codec_control(&encoders_[encoder_idx], VP8E_GET_LAST_QUANTIZER_64, &qp);
temporal_layers_[stream_idx]->FrameEncoded(
encoded_images_[encoder_idx]._length,
encoded_images_[encoder_idx]._timeStamp, qp);
if (send_stream_[stream_idx]) {
if (encoded_images_[encoder_idx]._length > 0) {
TRACE_COUNTER_ID1("webrtc", "EncodedFrameSize", encoder_idx,
encoded_images_[encoder_idx]._length);
encoded_images_[encoder_idx]._encodedHeight =
codec_.simulcastStream[stream_idx].height;
encoded_images_[encoder_idx]._encodedWidth =
codec_.simulcastStream[stream_idx].width;
encoded_images_[encoder_idx]
.adapt_reason_.quality_resolution_downscales =
quality_scaler_enabled_ ? quality_scaler_.downscale_shift() : -1;
// Report once per frame (lowest stream always sent).
encoded_images_[encoder_idx].adapt_reason_.bw_resolutions_disabled =
(stream_idx == 0) ? bw_resolutions_disabled : -1;
int qp_128 = -1;
vpx_codec_control(&encoders_[encoder_idx], VP8E_GET_LAST_QUANTIZER,
&qp_128);
encoded_images_[encoder_idx].qp_ = qp_128;
encoded_complete_callback_->OnEncodedImage(encoded_images_[encoder_idx],
&codec_specific, &frag_info);
} else if (codec_.mode == kScreensharing) {
result = WEBRTC_VIDEO_CODEC_TARGET_BITRATE_OVERSHOOT;
}
}
}
if (encoders_.size() == 1 && send_stream_[0]) {
if (encoded_images_[0]._length > 0) {
int qp_128;
vpx_codec_control(&encoders_[0], VP8E_GET_LAST_QUANTIZER, &qp_128);
quality_scaler_.ReportQP(qp_128);
} else {
quality_scaler_.ReportDroppedFrame();
}
}
return result;
}
int VP8EncoderImpl::SetChannelParameters(uint32_t packetLoss, int64_t rtt) {
rps_.SetRtt(rtt);
return WEBRTC_VIDEO_CODEC_OK;
}
int VP8EncoderImpl::RegisterEncodeCompleteCallback(
EncodedImageCallback* callback) {
encoded_complete_callback_ = callback;
return WEBRTC_VIDEO_CODEC_OK;
}
VP8DecoderImpl::VP8DecoderImpl()
: buffer_pool_(false, 300 /* max_number_of_buffers*/),
decode_complete_callback_(NULL),
inited_(false),
feedback_mode_(false),
decoder_(NULL),
image_format_(VPX_IMG_FMT_NONE),
ref_frame_(NULL),
propagation_cnt_(-1),
last_frame_width_(0),
last_frame_height_(0),
key_frame_required_(true) {}
VP8DecoderImpl::~VP8DecoderImpl() {
inited_ = true; // in order to do the actual release
Release();
}
int VP8DecoderImpl::InitDecode(const VideoCodec* inst, int number_of_cores) {
int ret_val = Release();
if (ret_val < 0) {
return ret_val;
}
if (decoder_ == NULL) {
decoder_ = new vpx_codec_ctx_t;
}
if (inst && inst->codecType == kVideoCodecVP8) {
feedback_mode_ = inst->VP8().feedbackModeOn;
}
vpx_codec_dec_cfg_t cfg;
// Setting number of threads to a constant value (1)
cfg.threads = 1;
cfg.h = cfg.w = 0; // set after decode
vpx_codec_flags_t flags = 0;
#if !defined(WEBRTC_ARCH_ARM) && !defined(WEBRTC_ARCH_ARM64) && \
!defined(ANDROID)
flags = VPX_CODEC_USE_POSTPROC;
#endif
if (vpx_codec_dec_init(decoder_, vpx_codec_vp8_dx(), &cfg, flags)) {
return WEBRTC_VIDEO_CODEC_MEMORY;
}
// Save VideoCodec instance for later; mainly for duplicating the decoder.
if (&codec_ != inst)
codec_ = *inst;
propagation_cnt_ = -1;
inited_ = true;
// Always start with a complete key frame.
key_frame_required_ = true;
return WEBRTC_VIDEO_CODEC_OK;
}
int VP8DecoderImpl::Decode(const EncodedImage& input_image,
bool missing_frames,
const RTPFragmentationHeader* fragmentation,
const CodecSpecificInfo* codec_specific_info,
int64_t /*render_time_ms*/) {
if (!inited_) {
return WEBRTC_VIDEO_CODEC_UNINITIALIZED;
}
if (decode_complete_callback_ == NULL) {
return WEBRTC_VIDEO_CODEC_UNINITIALIZED;
}
if (input_image._buffer == NULL && input_image._length > 0) {
// Reset to avoid requesting key frames too often.
if (propagation_cnt_ > 0)
propagation_cnt_ = 0;
return WEBRTC_VIDEO_CODEC_ERR_PARAMETER;
}
#if !defined(WEBRTC_ARCH_ARM) && !defined(WEBRTC_ARCH_ARM64) && \
!defined(ANDROID)
vp8_postproc_cfg_t ppcfg;
// MFQE enabled to reduce key frame popping.
ppcfg.post_proc_flag = VP8_MFQE | VP8_DEBLOCK;
// For VGA resolutions and lower, enable the demacroblocker postproc.
if (last_frame_width_ * last_frame_height_ <= 640 * 360) {
ppcfg.post_proc_flag |= VP8_DEMACROBLOCK;
}
// Strength of deblocking filter. Valid range:[0,16]
ppcfg.deblocking_level = 3;
vpx_codec_control(decoder_, VP8_SET_POSTPROC, &ppcfg);
#endif
// Always start with a complete key frame.
if (key_frame_required_) {
if (input_image._frameType != kVideoFrameKey)
return WEBRTC_VIDEO_CODEC_ERROR;
// We have a key frame - is it complete?
if (input_image._completeFrame) {
key_frame_required_ = false;
} else {
return WEBRTC_VIDEO_CODEC_ERROR;
}
}
// Restrict error propagation using key frame requests. Disabled when
// the feedback mode is enabled (RPS).
// Reset on a key frame refresh.
if (!feedback_mode_) {
if (input_image._frameType == kVideoFrameKey &&
input_image._completeFrame) {
propagation_cnt_ = -1;
// Start count on first loss.
} else if ((!input_image._completeFrame || missing_frames) &&
propagation_cnt_ == -1) {
propagation_cnt_ = 0;
}
if (propagation_cnt_ >= 0) {
propagation_cnt_++;
}
}
vpx_codec_iter_t iter = NULL;
vpx_image_t* img;
int ret;
// Check for missing frames.
if (missing_frames) {
// Call decoder with zero data length to signal missing frames.
if (vpx_codec_decode(decoder_, NULL, 0, 0, VPX_DL_REALTIME)) {
// Reset to avoid requesting key frames too often.
if (propagation_cnt_ > 0)
propagation_cnt_ = 0;
return WEBRTC_VIDEO_CODEC_ERROR;
}
img = vpx_codec_get_frame(decoder_, &iter);
iter = NULL;
}
uint8_t* buffer = input_image._buffer;
if (input_image._length == 0) {
buffer = NULL; // Triggers full frame concealment.
}
if (vpx_codec_decode(decoder_, buffer, input_image._length, 0,
VPX_DL_REALTIME)) {
// Reset to avoid requesting key frames too often.
if (propagation_cnt_ > 0) {
propagation_cnt_ = 0;
}
return WEBRTC_VIDEO_CODEC_ERROR;
}
img = vpx_codec_get_frame(decoder_, &iter);
ret = ReturnFrame(img, input_image._timeStamp, input_image.ntp_time_ms_);
if (ret != 0) {
// Reset to avoid requesting key frames too often.
if (ret < 0 && propagation_cnt_ > 0)
propagation_cnt_ = 0;
return ret;
}
if (feedback_mode_) {
// Whenever we receive an incomplete key frame all reference buffers will
// be corrupt. If that happens we must request new key frames until we
// decode a complete key frame.
if (input_image._frameType == kVideoFrameKey && !input_image._completeFrame)
return WEBRTC_VIDEO_CODEC_ERROR;
// Check for reference updates and last reference buffer corruption and
// signal successful reference propagation or frame corruption to the
// encoder.
int reference_updates = 0;
if (vpx_codec_control(decoder_, VP8D_GET_LAST_REF_UPDATES,
&reference_updates)) {
// Reset to avoid requesting key frames too often.
if (propagation_cnt_ > 0) {
propagation_cnt_ = 0;
}
return WEBRTC_VIDEO_CODEC_ERROR;
}
int corrupted = 0;
if (vpx_codec_control(decoder_, VP8D_GET_FRAME_CORRUPTED, &corrupted)) {
// Reset to avoid requesting key frames too often.
if (propagation_cnt_ > 0)
propagation_cnt_ = 0;
return WEBRTC_VIDEO_CODEC_ERROR;
}
int16_t picture_id = -1;
if (codec_specific_info) {
picture_id = codec_specific_info->codecSpecific.VP8.pictureId;
}
if (picture_id > -1) {
if (((reference_updates & VP8_GOLD_FRAME) ||
(reference_updates & VP8_ALTR_FRAME)) &&
!corrupted) {
decode_complete_callback_->ReceivedDecodedReferenceFrame(picture_id);
}
decode_complete_callback_->ReceivedDecodedFrame(picture_id);
}
if (corrupted) {
// we can decode but with artifacts
return WEBRTC_VIDEO_CODEC_REQUEST_SLI;
}
}
// Check Vs. threshold
if (propagation_cnt_ > kVp8ErrorPropagationTh) {
// Reset to avoid requesting key frames too often.
propagation_cnt_ = 0;
return WEBRTC_VIDEO_CODEC_ERROR;
}
return WEBRTC_VIDEO_CODEC_OK;
}
int VP8DecoderImpl::ReturnFrame(const vpx_image_t* img,
uint32_t timestamp,
int64_t ntp_time_ms) {
if (img == NULL) {
// Decoder OK and NULL image => No show frame
return WEBRTC_VIDEO_CODEC_NO_OUTPUT;
}
last_frame_width_ = img->d_w;
last_frame_height_ = img->d_h;
// Allocate memory for decoded image.
rtc::scoped_refptr<I420Buffer> buffer =
buffer_pool_.CreateBuffer(img->d_w, img->d_h);
if (!buffer.get()) {
// Pool has too many pending frames.
RTC_HISTOGRAM_BOOLEAN("WebRTC.Video.VP8DecoderImpl.TooManyPendingFrames",
1);
return WEBRTC_VIDEO_CODEC_NO_OUTPUT;
}
libyuv::I420Copy(img->planes[VPX_PLANE_Y], img->stride[VPX_PLANE_Y],
img->planes[VPX_PLANE_U], img->stride[VPX_PLANE_U],
img->planes[VPX_PLANE_V], img->stride[VPX_PLANE_V],
buffer->MutableDataY(), buffer->StrideY(),
buffer->MutableDataU(), buffer->StrideU(),
buffer->MutableDataV(), buffer->StrideV(),
img->d_w, img->d_h);
VideoFrame decoded_image(buffer, timestamp, 0, kVideoRotation_0);
decoded_image.set_ntp_time_ms(ntp_time_ms);
int ret = decode_complete_callback_->Decoded(decoded_image);
if (ret != 0)
return ret;
// Remember image format for later
image_format_ = img->fmt;
return WEBRTC_VIDEO_CODEC_OK;
}
int VP8DecoderImpl::RegisterDecodeCompleteCallback(
DecodedImageCallback* callback) {
decode_complete_callback_ = callback;
return WEBRTC_VIDEO_CODEC_OK;
}
int VP8DecoderImpl::Release() {
if (decoder_ != NULL) {
if (vpx_codec_destroy(decoder_)) {
return WEBRTC_VIDEO_CODEC_MEMORY;
}
delete decoder_;
decoder_ = NULL;
}
if (ref_frame_ != NULL) {
vpx_img_free(&ref_frame_->img);
delete ref_frame_;
ref_frame_ = NULL;
}
buffer_pool_.Release();
inited_ = false;
return WEBRTC_VIDEO_CODEC_OK;
}
const char* VP8DecoderImpl::ImplementationName() const {
return "libvpx";
}
int VP8DecoderImpl::CopyReference(VP8DecoderImpl* copy) {
// The type of frame to copy should be set in ref_frame_->frame_type
// before the call to this function.
if (vpx_codec_control(decoder_, VP8_COPY_REFERENCE, ref_frame_) !=
VPX_CODEC_OK) {
return -1;
}
if (vpx_codec_control(copy->decoder_, VP8_SET_REFERENCE, ref_frame_) !=
VPX_CODEC_OK) {
return -1;
}
return 0;
}
} // namespace webrtc
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