blob: 2411c1622e775645a653e3b823b34405ca1ac2e3 [file] [log] [blame]
/*
* 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 "modules/video_coding/codecs/vp8/libvpx_vp8_encoder.h"
#include <assert.h>
#include <string.h>
#include <algorithm>
#include <cstdint>
#include <iterator>
#include <memory>
#include <string>
#include <utility>
#include <vector>
#include "absl/algorithm/container.h"
#include "api/scoped_refptr.h"
#include "api/video/video_content_type.h"
#include "api/video/video_frame_buffer.h"
#include "api/video/video_timing.h"
#include "api/video_codecs/vp8_temporal_layers.h"
#include "api/video_codecs/vp8_temporal_layers_factory.h"
#include "modules/video_coding/codecs/interface/common_constants.h"
#include "modules/video_coding/codecs/vp8/include/vp8.h"
#include "modules/video_coding/include/video_error_codes.h"
#include "modules/video_coding/utility/simulcast_rate_allocator.h"
#include "modules/video_coding/utility/simulcast_utility.h"
#include "rtc_base/checks.h"
#include "rtc_base/experiments/field_trial_parser.h"
#include "rtc_base/experiments/field_trial_units.h"
#include "rtc_base/logging.h"
#include "rtc_base/trace_event.h"
#include "system_wrappers/include/field_trial.h"
#include "third_party/libyuv/include/libyuv/scale.h"
#include "vpx/vp8cx.h"
namespace webrtc {
namespace {
#if defined(WEBRTC_IOS)
constexpr char kVP8IosMaxNumberOfThreadFieldTrial[] =
"WebRTC-VP8IosMaxNumberOfThread";
constexpr char kVP8IosMaxNumberOfThreadFieldTrialParameter[] = "max_thread";
#endif
constexpr char kVp8ForcePartitionResilience[] =
"WebRTC-VP8-ForcePartitionResilience";
// QP is obtained from VP8-bitstream for HW, so the QP corresponds to the
// bitstream range of [0, 127] and not the user-level range of [0,63].
constexpr int kLowVp8QpThreshold = 29;
constexpr int kHighVp8QpThreshold = 95;
constexpr int kTokenPartitions = VP8_ONE_TOKENPARTITION;
constexpr uint32_t kVp832ByteAlign = 32u;
constexpr int kRtpTicksPerSecond = 90000;
constexpr int kRtpTicksPerMs = kRtpTicksPerSecond / 1000;
// VP8 denoiser states.
enum denoiserState : uint32_t {
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;
}
static_assert(Vp8EncoderConfig::TemporalLayerConfig::kMaxPeriodicity ==
VPX_TS_MAX_PERIODICITY,
"Vp8EncoderConfig::kMaxPeriodicity must be kept in sync with the "
"constant in libvpx.");
static_assert(Vp8EncoderConfig::TemporalLayerConfig::kMaxLayers ==
VPX_TS_MAX_LAYERS,
"Vp8EncoderConfig::kMaxLayers must be kept in sync with the "
"constant in libvpx.");
// Allow a newer value to override a current value only if the new value
// is set.
template <typename T>
bool MaybeSetNewValue(const absl::optional<T>& new_value,
absl::optional<T>* base_value) {
if (new_value.has_value() && new_value != *base_value) {
*base_value = new_value;
return true;
} else {
return false;
}
}
// Adds configuration from |new_config| to |base_config|. Both configs consist
// of optionals, and only optionals which are set in |new_config| can have
// an effect. (That is, set values in |base_config| cannot be unset.)
// Returns |true| iff any changes were made to |base_config|.
bool MaybeExtendVp8EncoderConfig(const Vp8EncoderConfig& new_config,
Vp8EncoderConfig* base_config) {
bool changes_made = false;
changes_made |= MaybeSetNewValue(new_config.temporal_layer_config,
&base_config->temporal_layer_config);
changes_made |= MaybeSetNewValue(new_config.rc_target_bitrate,
&base_config->rc_target_bitrate);
changes_made |= MaybeSetNewValue(new_config.rc_max_quantizer,
&base_config->rc_max_quantizer);
changes_made |= MaybeSetNewValue(new_config.g_error_resilient,
&base_config->g_error_resilient);
return changes_made;
}
void ApplyVp8EncoderConfigToVpxConfig(const Vp8EncoderConfig& encoder_config,
vpx_codec_enc_cfg_t* vpx_config) {
if (encoder_config.temporal_layer_config.has_value()) {
const Vp8EncoderConfig::TemporalLayerConfig& ts_config =
encoder_config.temporal_layer_config.value();
vpx_config->ts_number_layers = ts_config.ts_number_layers;
std::copy(ts_config.ts_target_bitrate.begin(),
ts_config.ts_target_bitrate.end(),
std::begin(vpx_config->ts_target_bitrate));
std::copy(ts_config.ts_rate_decimator.begin(),
ts_config.ts_rate_decimator.end(),
std::begin(vpx_config->ts_rate_decimator));
vpx_config->ts_periodicity = ts_config.ts_periodicity;
std::copy(ts_config.ts_layer_id.begin(), ts_config.ts_layer_id.end(),
std::begin(vpx_config->ts_layer_id));
} else {
vpx_config->ts_number_layers = 1;
vpx_config->ts_rate_decimator[0] = 1;
vpx_config->ts_periodicity = 1;
vpx_config->ts_layer_id[0] = 0;
}
if (encoder_config.rc_target_bitrate.has_value()) {
vpx_config->rc_target_bitrate = encoder_config.rc_target_bitrate.value();
}
if (encoder_config.rc_max_quantizer.has_value()) {
vpx_config->rc_max_quantizer = encoder_config.rc_max_quantizer.value();
}
if (encoder_config.g_error_resilient.has_value()) {
vpx_config->g_error_resilient = encoder_config.g_error_resilient.value();
}
}
void SetRawImagePlanes(vpx_image_t* raw_image, VideoFrameBuffer* buffer) {
switch (buffer->type()) {
case VideoFrameBuffer::Type::kI420:
case VideoFrameBuffer::Type::kI420A: {
const I420BufferInterface* i420_buffer = buffer->GetI420();
RTC_DCHECK(i420_buffer);
raw_image->planes[VPX_PLANE_Y] =
const_cast<uint8_t*>(i420_buffer->DataY());
raw_image->planes[VPX_PLANE_U] =
const_cast<uint8_t*>(i420_buffer->DataU());
raw_image->planes[VPX_PLANE_V] =
const_cast<uint8_t*>(i420_buffer->DataV());
raw_image->stride[VPX_PLANE_Y] = i420_buffer->StrideY();
raw_image->stride[VPX_PLANE_U] = i420_buffer->StrideU();
raw_image->stride[VPX_PLANE_V] = i420_buffer->StrideV();
break;
}
case VideoFrameBuffer::Type::kNV12: {
const NV12BufferInterface* nv12_buffer = buffer->GetNV12();
RTC_DCHECK(nv12_buffer);
raw_image->planes[VPX_PLANE_Y] =
const_cast<uint8_t*>(nv12_buffer->DataY());
raw_image->planes[VPX_PLANE_U] =
const_cast<uint8_t*>(nv12_buffer->DataUV());
raw_image->planes[VPX_PLANE_V] = raw_image->planes[VPX_PLANE_U] + 1;
raw_image->stride[VPX_PLANE_Y] = nv12_buffer->StrideY();
raw_image->stride[VPX_PLANE_U] = nv12_buffer->StrideUV();
raw_image->stride[VPX_PLANE_V] = nv12_buffer->StrideUV();
break;
}
default:
RTC_NOTREACHED();
}
}
} // namespace
std::unique_ptr<VideoEncoder> VP8Encoder::Create() {
return std::make_unique<LibvpxVp8Encoder>(LibvpxInterface::Create(),
VP8Encoder::Settings());
}
std::unique_ptr<VideoEncoder> VP8Encoder::Create(
VP8Encoder::Settings settings) {
return std::make_unique<LibvpxVp8Encoder>(LibvpxInterface::Create(),
std::move(settings));
}
std::unique_ptr<VideoEncoder> VP8Encoder::Create(
std::unique_ptr<Vp8FrameBufferControllerFactory>
frame_buffer_controller_factory) {
VP8Encoder::Settings settings;
settings.frame_buffer_controller_factory =
std::move(frame_buffer_controller_factory);
return std::make_unique<LibvpxVp8Encoder>(LibvpxInterface::Create(),
std::move(settings));
}
vpx_enc_frame_flags_t LibvpxVp8Encoder::EncodeFlags(
const Vp8FrameConfig& references) {
RTC_DCHECK(!references.drop_frame);
vpx_enc_frame_flags_t flags = 0;
if ((references.last_buffer_flags &
Vp8FrameConfig::BufferFlags::kReference) == 0)
flags |= VP8_EFLAG_NO_REF_LAST;
if ((references.last_buffer_flags & Vp8FrameConfig::BufferFlags::kUpdate) ==
0)
flags |= VP8_EFLAG_NO_UPD_LAST;
if ((references.golden_buffer_flags &
Vp8FrameConfig::BufferFlags::kReference) == 0)
flags |= VP8_EFLAG_NO_REF_GF;
if ((references.golden_buffer_flags & Vp8FrameConfig::BufferFlags::kUpdate) ==
0)
flags |= VP8_EFLAG_NO_UPD_GF;
if ((references.arf_buffer_flags & Vp8FrameConfig::BufferFlags::kReference) ==
0)
flags |= VP8_EFLAG_NO_REF_ARF;
if ((references.arf_buffer_flags & Vp8FrameConfig::BufferFlags::kUpdate) == 0)
flags |= VP8_EFLAG_NO_UPD_ARF;
if (references.freeze_entropy)
flags |= VP8_EFLAG_NO_UPD_ENTROPY;
return flags;
}
LibvpxVp8Encoder::LibvpxVp8Encoder(std::unique_ptr<LibvpxInterface> interface,
VP8Encoder::Settings settings)
: libvpx_(std::move(interface)),
rate_control_settings_(RateControlSettings::ParseFromFieldTrials()),
frame_buffer_controller_factory_(
std::move(settings.frame_buffer_controller_factory)),
resolution_bitrate_limits_(std::move(settings.resolution_bitrate_limits)),
key_frame_request_(kMaxSimulcastStreams, false),
variable_framerate_experiment_(ParseVariableFramerateConfig(
"WebRTC-VP8VariableFramerateScreenshare")),
framerate_controller_(variable_framerate_experiment_.framerate_limit) {
// TODO(eladalon/ilnik): These reservations might be wasting memory.
// InitEncode() is resizing to the actual size, which might be smaller.
raw_images_.reserve(kMaxSimulcastStreams);
encoded_images_.reserve(kMaxSimulcastStreams);
send_stream_.reserve(kMaxSimulcastStreams);
cpu_speed_.assign(kMaxSimulcastStreams, cpu_speed_default_);
encoders_.reserve(kMaxSimulcastStreams);
vpx_configs_.reserve(kMaxSimulcastStreams);
config_overrides_.reserve(kMaxSimulcastStreams);
downsampling_factors_.reserve(kMaxSimulcastStreams);
}
LibvpxVp8Encoder::~LibvpxVp8Encoder() {
Release();
}
int LibvpxVp8Encoder::Release() {
int ret_val = WEBRTC_VIDEO_CODEC_OK;
encoded_images_.clear();
if (inited_) {
for (auto it = encoders_.rbegin(); it != encoders_.rend(); ++it) {
if (libvpx_->codec_destroy(&*it)) {
ret_val = WEBRTC_VIDEO_CODEC_MEMORY;
}
}
}
encoders_.clear();
vpx_configs_.clear();
config_overrides_.clear();
send_stream_.clear();
cpu_speed_.clear();
for (auto it = raw_images_.rbegin(); it != raw_images_.rend(); ++it) {
libvpx_->img_free(&*it);
}
raw_images_.clear();
frame_buffer_controller_.reset();
inited_ = false;
return ret_val;
}
void LibvpxVp8Encoder::SetRates(const RateControlParameters& parameters) {
if (!inited_) {
RTC_LOG(LS_WARNING) << "SetRates() while not initialize";
return;
}
if (encoders_[0].err) {
RTC_LOG(LS_WARNING) << "Encoder in error state.";
return;
}
if (parameters.framerate_fps < 1.0) {
RTC_LOG(LS_WARNING) << "Unsupported framerate (must be >= 1.0): "
<< parameters.framerate_fps;
return;
}
if (parameters.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;
}
codec_.maxFramerate = static_cast<uint32_t>(parameters.framerate_fps + 0.5);
if (encoders_.size() > 1) {
// 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 (rate_control_settings_.Vp8BoostBaseLayerQuality() &&
parameters.framerate_fps > 20.0) {
vpx_configs_[encoders_.size() - 1].rc_max_quantizer = 45;
} else {
// Go back to default value set in InitEncode.
vpx_configs_[encoders_.size() - 1].rc_max_quantizer = qp_max_;
}
}
for (size_t i = 0; i < encoders_.size(); ++i) {
const size_t stream_idx = encoders_.size() - 1 - i;
unsigned int target_bitrate_kbps =
parameters.bitrate.GetSpatialLayerSum(stream_idx) / 1000;
bool send_stream = target_bitrate_kbps > 0;
if (send_stream || encoders_.size() > 1)
SetStreamState(send_stream, stream_idx);
vpx_configs_[i].rc_target_bitrate = target_bitrate_kbps;
if (send_stream) {
frame_buffer_controller_->OnRatesUpdated(
stream_idx, parameters.bitrate.GetTemporalLayerAllocation(stream_idx),
static_cast<int>(parameters.framerate_fps + 0.5));
}
UpdateVpxConfiguration(stream_idx);
vpx_codec_err_t err =
libvpx_->codec_enc_config_set(&encoders_[i], &vpx_configs_[i]);
if (err != VPX_CODEC_OK) {
RTC_LOG(LS_WARNING) << "Error configuring codec, error code: " << err
<< ", details: "
<< libvpx_->codec_error_detail(&encoders_[i]);
}
}
}
void LibvpxVp8Encoder::OnPacketLossRateUpdate(float packet_loss_rate) {
// TODO(bugs.webrtc.org/10431): Replace condition by DCHECK.
if (frame_buffer_controller_) {
frame_buffer_controller_->OnPacketLossRateUpdate(packet_loss_rate);
}
}
void LibvpxVp8Encoder::OnRttUpdate(int64_t rtt_ms) {
// TODO(bugs.webrtc.org/10431): Replace condition by DCHECK.
if (frame_buffer_controller_) {
frame_buffer_controller_->OnRttUpdate(rtt_ms);
}
}
void LibvpxVp8Encoder::OnLossNotification(
const LossNotification& loss_notification) {
if (frame_buffer_controller_) {
frame_buffer_controller_->OnLossNotification(loss_notification);
}
}
void LibvpxVp8Encoder::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 LibvpxVp8Encoder::SetFecControllerOverride(
FecControllerOverride* fec_controller_override) {
// TODO(bugs.webrtc.org/10769): Update downstream and remove ability to
// pass nullptr.
// RTC_DCHECK(fec_controller_override);
RTC_DCHECK(!fec_controller_override_);
fec_controller_override_ = fec_controller_override;
}
// TODO(eladalon): s/inst/codec_settings/g.
int LibvpxVp8Encoder::InitEncode(const VideoCodec* inst,
const VideoEncoder::Settings& settings) {
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 (settings.number_of_cores < 1) {
return WEBRTC_VIDEO_CODEC_ERR_PARAMETER;
}
num_active_streams_ = 0;
for (int i = 0; i < inst->numberOfSimulcastStreams; ++i) {
if (inst->simulcastStream[i].active) {
++num_active_streams_;
}
}
if (inst->numberOfSimulcastStreams == 0 && inst->active) {
num_active_streams_ = 1;
}
if (inst->VP8().automaticResizeOn && num_active_streams_ > 1) {
return WEBRTC_VIDEO_CODEC_ERR_PARAMETER;
}
// Use the previous pixel format to avoid extra image allocations.
vpx_img_fmt_t pixel_format =
raw_images_.empty() ? VPX_IMG_FMT_I420 : raw_images_[0].fmt;
int retVal = Release();
if (retVal < 0) {
return retVal;
}
int number_of_streams = SimulcastUtility::NumberOfSimulcastStreams(*inst);
if (number_of_streams > 1 &&
!SimulcastUtility::ValidSimulcastParameters(*inst, number_of_streams)) {
return WEBRTC_VIDEO_CODEC_ERR_SIMULCAST_PARAMETERS_NOT_SUPPORTED;
}
RTC_DCHECK(!frame_buffer_controller_);
if (frame_buffer_controller_factory_) {
frame_buffer_controller_ = frame_buffer_controller_factory_->Create(
*inst, settings, fec_controller_override_);
} else {
Vp8TemporalLayersFactory factory;
frame_buffer_controller_ =
factory.Create(*inst, settings, fec_controller_override_);
}
RTC_DCHECK(frame_buffer_controller_);
number_of_cores_ = settings.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;
}
encoded_images_.resize(number_of_streams);
encoders_.resize(number_of_streams);
vpx_configs_.resize(number_of_streams);
config_overrides_.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;
}
// populate encoder configuration with default values
if (libvpx_->codec_enc_config_default(vpx_codec_vp8_cx(), &vpx_configs_[0],
0)) {
return WEBRTC_VIDEO_CODEC_ERROR;
}
// setting the time base of the codec
vpx_configs_[0].g_timebase.num = 1;
vpx_configs_[0].g_timebase.den = kRtpTicksPerSecond;
vpx_configs_[0].g_lag_in_frames = 0; // 0- no frame lagging
// Set the error resilience mode for temporal layers (but not simulcast).
vpx_configs_[0].g_error_resilient =
(SimulcastUtility::NumberOfTemporalLayers(*inst, 0) > 1)
? VPX_ERROR_RESILIENT_DEFAULT
: 0;
// Override the error resilience mode if this is not simulcast, but we are
// using temporal layers.
if (field_trial::IsEnabled(kVp8ForcePartitionResilience) &&
(number_of_streams == 1) &&
(SimulcastUtility::NumberOfTemporalLayers(*inst, 0) > 1)) {
RTC_LOG(LS_INFO) << "Overriding g_error_resilient from "
<< vpx_configs_[0].g_error_resilient << " to "
<< VPX_ERROR_RESILIENT_PARTITIONS;
vpx_configs_[0].g_error_resilient = VPX_ERROR_RESILIENT_PARTITIONS;
}
// rate control settings
vpx_configs_[0].rc_dropframe_thresh = FrameDropThreshold(0);
vpx_configs_[0].rc_end_usage = VPX_CBR;
vpx_configs_[0].g_pass = VPX_RC_ONE_PASS;
// Handle resizing outside of libvpx.
vpx_configs_[0].rc_resize_allowed = 0;
vpx_configs_[0].rc_min_quantizer =
codec_.mode == VideoCodecMode::kScreensharing ? 12 : 2;
if (inst->qpMax >= vpx_configs_[0].rc_min_quantizer) {
qp_max_ = inst->qpMax;
}
if (rate_control_settings_.LibvpxVp8QpMax()) {
qp_max_ = std::max(rate_control_settings_.LibvpxVp8QpMax().value(),
static_cast<int>(vpx_configs_[0].rc_min_quantizer));
}
vpx_configs_[0].rc_max_quantizer = qp_max_;
vpx_configs_[0].rc_undershoot_pct = 100;
vpx_configs_[0].rc_overshoot_pct = 15;
vpx_configs_[0].rc_buf_initial_sz = 500;
vpx_configs_[0].rc_buf_optimal_sz = 600;
vpx_configs_[0].rc_buf_sz = 1000;
// Set the maximum target size of any key-frame.
rc_max_intra_target_ = MaxIntraTarget(vpx_configs_[0].rc_buf_optimal_sz);
if (inst->VP8().keyFrameInterval > 0) {
vpx_configs_[0].kf_mode = VPX_KF_AUTO;
vpx_configs_[0].kf_max_dist = inst->VP8().keyFrameInterval;
} else {
vpx_configs_[0].kf_mode = VPX_KF_DISABLED;
}
// Allow the user to set the complexity for the base stream.
switch (inst->VP8().complexity) {
case VideoCodecComplexity::kComplexityHigh:
cpu_speed_[0] = -5;
break;
case VideoCodecComplexity::kComplexityHigher:
cpu_speed_[0] = -4;
break;
case VideoCodecComplexity::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] = GetCpuSpeed(inst->width, inst->height);
for (int i = 1; i < number_of_streams; ++i) {
cpu_speed_[i] =
GetCpuSpeed(inst->simulcastStream[number_of_streams - 1 - i].width,
inst->simulcastStream[number_of_streams - 1 - i].height);
}
vpx_configs_[0].g_w = inst->width;
vpx_configs_[0].g_h = inst->height;
// Determine number of threads based on the image size and #cores.
// TODO(fbarchard): Consider number of Simulcast layers.
vpx_configs_[0].g_threads = NumberOfThreads(
vpx_configs_[0].g_w, vpx_configs_[0].g_h, settings.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).
libvpx_->img_wrap(&raw_images_[0], pixel_format, 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.
const size_t stream_idx_cfg_0 = encoders_.size() - 1;
SimulcastRateAllocator init_allocator(codec_);
VideoBitrateAllocation allocation =
init_allocator.Allocate(VideoBitrateAllocationParameters(
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);
}
vpx_configs_[0].rc_target_bitrate = stream_bitrates[stream_idx_cfg_0];
if (stream_bitrates[stream_idx_cfg_0] > 0) {
uint32_t maxFramerate =
inst->simulcastStream[stream_idx_cfg_0].maxFramerate;
if (!maxFramerate) {
maxFramerate = inst->maxFramerate;
}
frame_buffer_controller_->OnRatesUpdated(
stream_idx_cfg_0,
allocation.GetTemporalLayerAllocation(stream_idx_cfg_0), maxFramerate);
}
frame_buffer_controller_->SetQpLimits(stream_idx_cfg_0,
vpx_configs_[0].rc_min_quantizer,
vpx_configs_[0].rc_max_quantizer);
UpdateVpxConfiguration(stream_idx_cfg_0);
vpx_configs_[0].rc_dropframe_thresh = FrameDropThreshold(stream_idx_cfg_0);
for (size_t i = 1; i < encoders_.size(); ++i) {
const size_t stream_idx = encoders_.size() - 1 - i;
memcpy(&vpx_configs_[i], &vpx_configs_[0], sizeof(vpx_configs_[0]));
vpx_configs_[i].g_w = inst->simulcastStream[stream_idx].width;
vpx_configs_[i].g_h = inst->simulcastStream[stream_idx].height;
// Use 1 thread for lower resolutions.
vpx_configs_[i].g_threads = 1;
vpx_configs_[i].rc_dropframe_thresh = FrameDropThreshold(stream_idx);
// 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.
libvpx_->img_alloc(
&raw_images_[i], pixel_format, inst->simulcastStream[stream_idx].width,
inst->simulcastStream[stream_idx].height, kVp832ByteAlign);
SetStreamState(stream_bitrates[stream_idx] > 0, stream_idx);
vpx_configs_[i].rc_target_bitrate = stream_bitrates[stream_idx];
if (stream_bitrates[stream_idx] > 0) {
uint32_t maxFramerate = inst->simulcastStream[stream_idx].maxFramerate;
if (!maxFramerate) {
maxFramerate = inst->maxFramerate;
}
frame_buffer_controller_->OnRatesUpdated(
stream_idx, allocation.GetTemporalLayerAllocation(stream_idx),
maxFramerate);
}
frame_buffer_controller_->SetQpLimits(stream_idx,
vpx_configs_[i].rc_min_quantizer,
vpx_configs_[i].rc_max_quantizer);
UpdateVpxConfiguration(stream_idx);
}
return InitAndSetControlSettings();
}
int LibvpxVp8Encoder::GetCpuSpeed(int width, int height) {
#if defined(WEBRTC_ARCH_ARM) || defined(WEBRTC_ARCH_ARM64) || \
defined(WEBRTC_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 (experimental_cpu_speed_config_arm_
.GetValue(width * height, number_of_cores_)
.has_value()) {
return experimental_cpu_speed_config_arm_
.GetValue(width * height, number_of_cores_)
.value();
}
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 LibvpxVp8Encoder::NumberOfThreads(int width, int height, int cpus) {
#if defined(WEBRTC_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 defined(WEBRTC_IOS)
std::string trial_string =
field_trial::FindFullName(kVP8IosMaxNumberOfThreadFieldTrial);
FieldTrialParameter<int> max_thread_number(
kVP8IosMaxNumberOfThreadFieldTrialParameter, 0);
ParseFieldTrial({&max_thread_number}, trial_string);
if (max_thread_number.Get() > 0) {
if (width * height < 320 * 180) {
return 1; // Use single thread for small screens
}
// thread number must be less than or equal to the number of CPUs.
return std::min(cpus, max_thread_number.Get());
}
#endif // defined(WEBRTC_IOS)
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) {
// Default 2 threads for qHD/HD, but allow 3 if core count is high enough,
// as this will allow more margin for high-core/low clock machines or if
// not built with highest optimization.
if (cpus >= 6) {
return 3;
}
return 2;
} else {
// 1 thread for VGA or less.
return 1;
}
#endif
}
int LibvpxVp8Encoder::InitAndSetControlSettings() {
vpx_codec_flags_t flags = 0;
flags |= VPX_CODEC_USE_OUTPUT_PARTITION;
if (encoders_.size() > 1) {
int error = libvpx_->codec_enc_init_multi(
&encoders_[0], vpx_codec_vp8_cx(), &vpx_configs_[0], encoders_.size(),
flags, &downsampling_factors_[0]);
if (error) {
return WEBRTC_VIDEO_CODEC_UNINITIALIZED;
}
} else {
if (libvpx_->codec_enc_init(&encoders_[0], vpx_codec_vp8_cx(),
&vpx_configs_[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(WEBRTC_ANDROID)
denoiser_state = kDenoiserOnYOnly;
#else
denoiser_state = kDenoiserOnAdaptive;
#endif
libvpx_->codec_control(
&encoders_[0], VP8E_SET_NOISE_SENSITIVITY,
codec_.VP8()->denoisingOn ? denoiser_state : kDenoiserOff);
if (encoders_.size() > 2) {
libvpx_->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.
libvpx_->codec_control(
&(encoders_[i]), VP8E_SET_STATIC_THRESHOLD,
codec_.mode == VideoCodecMode::kScreensharing ? 100u : 1u);
libvpx_->codec_control(&(encoders_[i]), VP8E_SET_CPUUSED, cpu_speed_[i]);
libvpx_->codec_control(
&(encoders_[i]), VP8E_SET_TOKEN_PARTITIONS,
static_cast<vp8e_token_partitions>(kTokenPartitions));
libvpx_->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)
libvpx_->codec_control(
&(encoders_[i]), VP8E_SET_SCREEN_CONTENT_MODE,
codec_.mode == VideoCodecMode::kScreensharing ? 2u : 0u);
}
inited_ = true;
return WEBRTC_VIDEO_CODEC_OK;
}
uint32_t LibvpxVp8Encoder::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;
}
uint32_t LibvpxVp8Encoder::FrameDropThreshold(size_t spatial_idx) const {
bool enable_frame_dropping = codec_.VP8().frameDroppingOn;
// If temporal layers are used, they get to override the frame dropping
// setting, as eg. ScreenshareLayers does not work as intended with frame
// dropping on and DefaultTemporalLayers will have performance issues with
// frame dropping off.
RTC_DCHECK(frame_buffer_controller_);
RTC_DCHECK_LT(spatial_idx, frame_buffer_controller_->StreamCount());
enable_frame_dropping =
frame_buffer_controller_->SupportsEncoderFrameDropping(spatial_idx);
return enable_frame_dropping ? 30 : 0;
}
size_t LibvpxVp8Encoder::SteadyStateSize(int sid, int tid) {
const int encoder_id = encoders_.size() - 1 - sid;
size_t bitrate_bps;
float fps;
if ((SimulcastUtility::IsConferenceModeScreenshare(codec_) && sid == 0) ||
vpx_configs_[encoder_id].ts_number_layers <= 1) {
// In conference screenshare there's no defined per temporal layer bitrate
// and framerate.
bitrate_bps = vpx_configs_[encoder_id].rc_target_bitrate * 1000;
fps = codec_.maxFramerate;
} else {
bitrate_bps = vpx_configs_[encoder_id].ts_target_bitrate[tid] * 1000;
fps = codec_.maxFramerate /
fmax(vpx_configs_[encoder_id].ts_rate_decimator[tid], 1.0);
if (tid > 0) {
// Layer bitrate and fps are counted as a partial sums.
bitrate_bps -= vpx_configs_[encoder_id].ts_target_bitrate[tid - 1] * 1000;
fps = codec_.maxFramerate /
fmax(vpx_configs_[encoder_id].ts_rate_decimator[tid - 1], 1.0);
}
}
if (fps < 1e-9)
return 0;
return static_cast<size_t>(
bitrate_bps / (8 * fps) *
(100 -
variable_framerate_experiment_.steady_state_undershoot_percentage) /
100 +
0.5);
}
bool LibvpxVp8Encoder::UpdateVpxConfiguration(size_t stream_index) {
RTC_DCHECK(frame_buffer_controller_);
const size_t config_index = vpx_configs_.size() - 1 - stream_index;
RTC_DCHECK_LT(config_index, config_overrides_.size());
Vp8EncoderConfig* config = &config_overrides_[config_index];
const Vp8EncoderConfig new_config =
frame_buffer_controller_->UpdateConfiguration(stream_index);
if (new_config.reset_previous_configuration_overrides) {
*config = new_config;
return true;
}
const bool changes_made = MaybeExtendVp8EncoderConfig(new_config, config);
// Note that overrides must be applied even if they haven't changed.
RTC_DCHECK_LT(config_index, vpx_configs_.size());
vpx_codec_enc_cfg_t* vpx_config = &vpx_configs_[config_index];
ApplyVp8EncoderConfigToVpxConfig(*config, vpx_config);
return changes_made;
}
int LibvpxVp8Encoder::Encode(const VideoFrame& frame,
const std::vector<VideoFrameType>* frame_types) {
RTC_DCHECK_EQ(frame.width(), codec_.width);
RTC_DCHECK_EQ(frame.height(), codec_.height);
if (!inited_)
return WEBRTC_VIDEO_CODEC_UNINITIALIZED;
if (encoded_complete_callback_ == NULL)
return WEBRTC_VIDEO_CODEC_UNINITIALIZED;
bool key_frame_requested = false;
for (size_t i = 0; i < key_frame_request_.size() && i < send_stream_.size();
++i) {
if (key_frame_request_[i] && send_stream_[i]) {
key_frame_requested = true;
break;
}
}
if (!key_frame_requested && frame_types) {
for (size_t i = 0; i < frame_types->size() && i < send_stream_.size();
++i) {
if ((*frame_types)[i] == VideoFrameType::kVideoFrameKey &&
send_stream_[i]) {
key_frame_requested = true;
break;
}
}
}
if (frame.update_rect().IsEmpty() && num_steady_state_frames_ >= 3 &&
!key_frame_requested) {
if (variable_framerate_experiment_.enabled &&
framerate_controller_.DropFrame(frame.timestamp() / kRtpTicksPerMs)) {
return WEBRTC_VIDEO_CODEC_OK;
}
framerate_controller_.AddFrame(frame.timestamp() / kRtpTicksPerMs);
}
bool send_key_frame = key_frame_requested;
bool drop_frame = false;
bool retransmission_allowed = true;
Vp8FrameConfig tl_configs[kMaxSimulcastStreams];
for (size_t i = 0; i < encoders_.size(); ++i) {
tl_configs[i] =
frame_buffer_controller_->NextFrameConfig(i, frame.timestamp());
send_key_frame |= tl_configs[i].IntraFrame();
drop_frame |= tl_configs[i].drop_frame;
RTC_DCHECK(i == 0 ||
retransmission_allowed == tl_configs[i].retransmission_allowed);
retransmission_allowed = tl_configs[i].retransmission_allowed;
}
if (drop_frame && !send_key_frame) {
return WEBRTC_VIDEO_CODEC_OK;
}
vpx_enc_frame_flags_t flags[kMaxSimulcastStreams];
for (size_t i = 0; i < encoders_.size(); ++i) {
flags[i] = send_key_frame ? VPX_EFLAG_FORCE_KF : EncodeFlags(tl_configs[i]);
}
// Scale and map buffers and set |raw_images_| to hold pointers to the result.
// Because |raw_images_| are set to hold pointers to the prepared buffers, we
// need to keep these buffers alive through reference counting until after
// encoding is complete.
std::vector<rtc::scoped_refptr<VideoFrameBuffer>> prepared_buffers =
PrepareBuffers(frame.video_frame_buffer());
if (prepared_buffers.empty()) {
return WEBRTC_VIDEO_CODEC_ERROR;
}
struct CleanUpOnExit {
explicit CleanUpOnExit(
vpx_image_t* raw_image,
std::vector<rtc::scoped_refptr<VideoFrameBuffer>> prepared_buffers)
: raw_image_(raw_image),
prepared_buffers_(std::move(prepared_buffers)) {}
~CleanUpOnExit() {
raw_image_->planes[VPX_PLANE_Y] = nullptr;
raw_image_->planes[VPX_PLANE_U] = nullptr;
raw_image_->planes[VPX_PLANE_V] = nullptr;
}
vpx_image_t* raw_image_;
std::vector<rtc::scoped_refptr<VideoFrameBuffer>> prepared_buffers_;
} clean_up_on_exit(&raw_images_[0], std::move(prepared_buffers));
if (send_key_frame) {
// Adapt the size of the key frame when in screenshare with 1 temporal
// layer.
if (encoders_.size() == 1 &&
codec_.mode == VideoCodecMode::kScreensharing &&
codec_.VP8()->numberOfTemporalLayers <= 1) {
const uint32_t forceKeyFrameIntraTh = 100;
libvpx_->codec_control(&(encoders_[0]), VP8E_SET_MAX_INTRA_BITRATE_PCT,
forceKeyFrameIntraTh);
}
std::fill(key_frame_request_.begin(), key_frame_request_.end(), false);
}
// Set the encoder frame flags and temporal layer_id for each spatial stream.
// Note that streams 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.
for (size_t i = 0; i < encoders_.size(); ++i) {
const size_t stream_idx = encoders_.size() - 1 - i;
if (UpdateVpxConfiguration(stream_idx)) {
if (libvpx_->codec_enc_config_set(&encoders_[i], &vpx_configs_[i]))
return WEBRTC_VIDEO_CODEC_ERROR;
}
libvpx_->codec_control(&encoders_[i], VP8E_SET_FRAME_FLAGS,
static_cast<int>(flags[stream_idx]));
libvpx_->codec_control(&encoders_[i], VP8E_SET_TEMPORAL_LAYER_ID,
tl_configs[i].encoder_layer_id);
}
// 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 = kRtpTicksPerSecond / codec_.maxFramerate;
int error = WEBRTC_VIDEO_CODEC_OK;
int num_tries = 0;
// If the first try returns WEBRTC_VIDEO_CODEC_TARGET_BITRATE_OVERSHOOT
// the frame must be reencoded with the same parameters again because
// target bitrate is exceeded and encoder state has been reset.
while (num_tries == 0 ||
(num_tries == 1 &&
error == WEBRTC_VIDEO_CODEC_TARGET_BITRATE_OVERSHOOT)) {
++num_tries;
// Note we must pass 0 for |flags| field in encode call below since they are
// set above in |libvpx_interface_->vpx_codec_control_| function for each
// encoder/spatial layer.
error = libvpx_->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) {
libvpx_->codec_control(&(encoders_[0]), VP8E_SET_MAX_INTRA_BITRATE_PCT,
rc_max_intra_target_);
}
if (error)
return WEBRTC_VIDEO_CODEC_ERROR;
// Examines frame timestamps only.
error = GetEncodedPartitions(frame, retransmission_allowed);
}
// TODO(sprang): Shouldn't we use the frame timestamp instead?
timestamp_ += duration;
return error;
}
void LibvpxVp8Encoder::PopulateCodecSpecific(CodecSpecificInfo* codec_specific,
const vpx_codec_cx_pkt_t& pkt,
int stream_idx,
int encoder_idx,
uint32_t timestamp) {
assert(codec_specific != NULL);
codec_specific->codecType = kVideoCodecVP8;
codec_specific->codecSpecific.VP8.keyIdx =
kNoKeyIdx; // TODO(hlundin) populate this
codec_specific->codecSpecific.VP8.nonReference =
(pkt.data.frame.flags & VPX_FRAME_IS_DROPPABLE) != 0;
int qp = 0;
vpx_codec_control(&encoders_[encoder_idx], VP8E_GET_LAST_QUANTIZER_64, &qp);
bool is_keyframe = (pkt.data.frame.flags & VPX_FRAME_IS_KEY) != 0;
frame_buffer_controller_->OnEncodeDone(stream_idx, timestamp,
encoded_images_[encoder_idx].size(),
is_keyframe, qp, codec_specific);
if (is_keyframe && codec_specific->template_structure != absl::nullopt) {
// Number of resolutions must match number of spatial layers, VP8 structures
// expected to use single spatial layer. Templates must be ordered by
// spatial_id, so assumption there is exactly one spatial layer is same as
// assumption last template uses spatial_id = 0.
// This check catches potential scenario where template_structure is shared
// across multiple vp8 streams and they are distinguished using spatial_id.
// Assigning single resolution doesn't support such scenario, i.e. assumes
// vp8 simulcast is sent using multiple ssrcs.
RTC_DCHECK(!codec_specific->template_structure->templates.empty());
RTC_DCHECK_EQ(
codec_specific->template_structure->templates.back().spatial_id, 0);
codec_specific->template_structure->resolutions = {
RenderResolution(pkt.data.frame.width[0], pkt.data.frame.height[0])};
}
}
int LibvpxVp8Encoder::GetEncodedPartitions(const VideoFrame& input_image,
bool retransmission_allowed) {
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;
encoded_images_[encoder_idx].set_size(0);
encoded_images_[encoder_idx]._frameType = VideoFrameType::kVideoFrameDelta;
CodecSpecificInfo codec_specific;
const vpx_codec_cx_pkt_t* pkt = NULL;
size_t encoded_size = 0;
while ((pkt = libvpx_->codec_get_cx_data(&encoders_[encoder_idx], &iter)) !=
NULL) {
if (pkt->kind == VPX_CODEC_CX_FRAME_PKT) {
encoded_size += pkt->data.frame.sz;
}
}
// TODO(nisse): Introduce some buffer cache or buffer pool, to reduce
// allocations and/or copy operations.
auto buffer = EncodedImageBuffer::Create(encoded_size);
iter = NULL;
size_t encoded_pos = 0;
while ((pkt = libvpx_->codec_get_cx_data(&encoders_[encoder_idx], &iter)) !=
NULL) {
switch (pkt->kind) {
case VPX_CODEC_CX_FRAME_PKT: {
RTC_CHECK_LE(encoded_pos + pkt->data.frame.sz, buffer->size());
memcpy(&buffer->data()[encoded_pos], pkt->data.frame.buf,
pkt->data.frame.sz);
encoded_pos += pkt->data.frame.sz;
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 =
VideoFrameType::kVideoFrameKey;
}
encoded_images_[encoder_idx].SetEncodedData(buffer);
encoded_images_[encoder_idx].set_size(encoded_pos);
encoded_images_[encoder_idx].SetSpatialIndex(stream_idx);
PopulateCodecSpecific(&codec_specific, *pkt, stream_idx, encoder_idx,
input_image.timestamp());
break;
}
}
encoded_images_[encoder_idx].SetTimestamp(input_image.timestamp());
encoded_images_[encoder_idx].SetRetransmissionAllowed(
retransmission_allowed);
if (send_stream_[stream_idx]) {
if (encoded_images_[encoder_idx].size() > 0) {
TRACE_COUNTER_ID1("webrtc", "EncodedFrameSize", encoder_idx,
encoded_images_[encoder_idx].size());
encoded_images_[encoder_idx]._encodedHeight =
codec_.simulcastStream[stream_idx].height;
encoded_images_[encoder_idx]._encodedWidth =
codec_.simulcastStream[stream_idx].width;
int qp_128 = -1;
libvpx_->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);
const size_t steady_state_size = SteadyStateSize(
stream_idx, codec_specific.codecSpecific.VP8.temporalIdx);
if (qp_128 > variable_framerate_experiment_.steady_state_qp ||
encoded_images_[encoder_idx].size() > steady_state_size) {
num_steady_state_frames_ = 0;
} else {
++num_steady_state_frames_;
}
} else if (!frame_buffer_controller_->SupportsEncoderFrameDropping(
stream_idx)) {
result = WEBRTC_VIDEO_CODEC_TARGET_BITRATE_OVERSHOOT;
if (encoded_images_[encoder_idx].size() == 0) {
// Dropped frame that will be re-encoded.
frame_buffer_controller_->OnFrameDropped(stream_idx,
input_image.timestamp());
}
}
}
}
return result;
}
VideoEncoder::EncoderInfo LibvpxVp8Encoder::GetEncoderInfo() const {
EncoderInfo info;
info.supports_native_handle = false;
info.implementation_name = "libvpx";
info.has_trusted_rate_controller =
rate_control_settings_.LibvpxVp8TrustedRateController();
info.is_hardware_accelerated = false;
info.has_internal_source = false;
info.supports_simulcast = true;
if (!resolution_bitrate_limits_.empty()) {
info.resolution_bitrate_limits = resolution_bitrate_limits_;
}
if (encoder_info_override_.requested_resolution_alignment()) {
info.requested_resolution_alignment =
*encoder_info_override_.requested_resolution_alignment();
info.apply_alignment_to_all_simulcast_layers =
encoder_info_override_.apply_alignment_to_all_simulcast_layers();
}
if (!encoder_info_override_.resolution_bitrate_limits().empty()) {
info.resolution_bitrate_limits =
encoder_info_override_.resolution_bitrate_limits();
}
const bool enable_scaling =
num_active_streams_ == 1 &&
(vpx_configs_.empty() || vpx_configs_[0].rc_dropframe_thresh > 0) &&
codec_.VP8().automaticResizeOn;
info.scaling_settings = enable_scaling
? VideoEncoder::ScalingSettings(
kLowVp8QpThreshold, kHighVp8QpThreshold)
: VideoEncoder::ScalingSettings::kOff;
if (rate_control_settings_.LibvpxVp8MinPixels()) {
info.scaling_settings.min_pixels_per_frame =
rate_control_settings_.LibvpxVp8MinPixels().value();
}
info.preferred_pixel_formats = {VideoFrameBuffer::Type::kI420,
VideoFrameBuffer::Type::kNV12};
if (inited_) {
// |encoder_idx| is libvpx index where 0 is highest resolution.
// |si| is simulcast index, where 0 is lowest resolution.
for (size_t si = 0, encoder_idx = encoders_.size() - 1;
si < encoders_.size(); ++si, --encoder_idx) {
info.fps_allocation[si].clear();
if ((codec_.numberOfSimulcastStreams > si &&
!codec_.simulcastStream[si].active) ||
(si == 0 && SimulcastUtility::IsConferenceModeScreenshare(codec_))) {
// No defined frame rate fractions if not active or if using
// ScreenshareLayers, leave vector empty and continue;
continue;
}
if (vpx_configs_[encoder_idx].ts_number_layers <= 1) {
info.fps_allocation[si].push_back(EncoderInfo::kMaxFramerateFraction);
} else {
for (size_t ti = 0; ti < vpx_configs_[encoder_idx].ts_number_layers;
++ti) {
RTC_DCHECK_GT(vpx_configs_[encoder_idx].ts_rate_decimator[ti], 0);
info.fps_allocation[si].push_back(rtc::saturated_cast<uint8_t>(
EncoderInfo::kMaxFramerateFraction /
vpx_configs_[encoder_idx].ts_rate_decimator[ti] +
0.5));
}
}
}
}
return info;
}
int LibvpxVp8Encoder::RegisterEncodeCompleteCallback(
EncodedImageCallback* callback) {
encoded_complete_callback_ = callback;
return WEBRTC_VIDEO_CODEC_OK;
}
void LibvpxVp8Encoder::MaybeUpdatePixelFormat(vpx_img_fmt fmt) {
RTC_DCHECK(!raw_images_.empty());
if (raw_images_[0].fmt == fmt) {
RTC_DCHECK(std::all_of(
std::next(raw_images_.begin()), raw_images_.end(),
[fmt](const vpx_image_t& raw_img) { return raw_img.fmt == fmt; }))
<< "Not all raw images had the right format!";
return;
}
RTC_LOG(INFO) << "Updating vp8 encoder pixel format to "
<< (fmt == VPX_IMG_FMT_NV12 ? "NV12" : "I420");
for (size_t i = 0; i < raw_images_.size(); ++i) {
vpx_image_t& img = raw_images_[i];
auto d_w = img.d_w;
auto d_h = img.d_h;
libvpx_->img_free(&img);
// First image is wrapping the input frame, the rest are allocated.
if (i == 0) {
libvpx_->img_wrap(&img, fmt, d_w, d_h, 1, NULL);
} else {
libvpx_->img_alloc(&img, fmt, d_w, d_h, kVp832ByteAlign);
}
}
}
std::vector<rtc::scoped_refptr<VideoFrameBuffer>>
LibvpxVp8Encoder::PrepareBuffers(rtc::scoped_refptr<VideoFrameBuffer> buffer) {
RTC_DCHECK_EQ(buffer->width(), raw_images_[0].d_w);
RTC_DCHECK_EQ(buffer->height(), raw_images_[0].d_h);
absl::InlinedVector<VideoFrameBuffer::Type, kMaxPreferredPixelFormats>
supported_formats = {VideoFrameBuffer::Type::kI420,
VideoFrameBuffer::Type::kNV12};
rtc::scoped_refptr<VideoFrameBuffer> mapped_buffer;
if (buffer->type() != VideoFrameBuffer::Type::kNative) {
// |buffer| is already mapped.
mapped_buffer = buffer;
} else {
// Attempt to map to one of the supported formats.
mapped_buffer = buffer->GetMappedFrameBuffer(supported_formats);
}
if (!mapped_buffer ||
(absl::c_find(supported_formats, mapped_buffer->type()) ==
supported_formats.end() &&
mapped_buffer->type() != VideoFrameBuffer::Type::kI420A)) {
// Unknown pixel format or unable to map, convert to I420 and prepare that
// buffer instead to ensure Scale() is safe to use.
auto converted_buffer = buffer->ToI420();
if (!converted_buffer) {
RTC_LOG(LS_ERROR) << "Failed to convert "
<< VideoFrameBufferTypeToString(buffer->type())
<< " image to I420. Can't encode frame.";
return {};
}
// The buffer should now be a mapped I420 or I420A format, but some buffer
// implementations incorrectly return the wrong buffer format, such as
// kNative. As a workaround to this, we perform ToI420() a second time.
// TODO(https://crbug.com/webrtc/12602): When Android buffers have a correct
// ToI420() implementaion, remove his workaround.
if (converted_buffer->type() != VideoFrameBuffer::Type::kI420 &&
converted_buffer->type() != VideoFrameBuffer::Type::kI420A) {
converted_buffer = converted_buffer->ToI420();
RTC_CHECK(converted_buffer->type() == VideoFrameBuffer::Type::kI420 ||
converted_buffer->type() == VideoFrameBuffer::Type::kI420A);
}
// Because |buffer| had to be converted, use |converted_buffer| instead...
buffer = mapped_buffer = converted_buffer;
}
// Maybe update pixel format.
absl::InlinedVector<VideoFrameBuffer::Type, kMaxPreferredPixelFormats>
mapped_type = {mapped_buffer->type()};
switch (mapped_buffer->type()) {
case VideoFrameBuffer::Type::kI420:
case VideoFrameBuffer::Type::kI420A:
MaybeUpdatePixelFormat(VPX_IMG_FMT_I420);
break;
case VideoFrameBuffer::Type::kNV12:
MaybeUpdatePixelFormat(VPX_IMG_FMT_NV12);
break;
default:
RTC_NOTREACHED();
}
// Prepare |raw_images_| from |mapped_buffer| and, if simulcast, scaled
// versions of |buffer|.
std::vector<rtc::scoped_refptr<VideoFrameBuffer>> prepared_buffers;
SetRawImagePlanes(&raw_images_[0], mapped_buffer);
prepared_buffers.push_back(mapped_buffer);
for (size_t i = 1; i < encoders_.size(); ++i) {
// Native buffers should implement optimized scaling and is the preferred
// buffer to scale. But if the buffer isn't native, it should be cheaper to
// scale from the previously prepared buffer which is smaller than |buffer|.
VideoFrameBuffer* buffer_to_scale =
buffer->type() == VideoFrameBuffer::Type::kNative
? buffer.get()
: prepared_buffers.back().get();
auto scaled_buffer =
buffer_to_scale->Scale(raw_images_[i].d_w, raw_images_[i].d_h);
if (scaled_buffer->type() == VideoFrameBuffer::Type::kNative) {
auto mapped_scaled_buffer =
scaled_buffer->GetMappedFrameBuffer(mapped_type);
RTC_DCHECK(mapped_scaled_buffer) << "Unable to map the scaled buffer.";
if (!mapped_scaled_buffer) {
RTC_LOG(LS_ERROR) << "Failed to map scaled "
<< VideoFrameBufferTypeToString(scaled_buffer->type())
<< " image to "
<< VideoFrameBufferTypeToString(mapped_buffer->type())
<< ". Can't encode frame.";
return {};
}
scaled_buffer = mapped_scaled_buffer;
}
RTC_DCHECK_EQ(scaled_buffer->type(), mapped_buffer->type())
<< "Scaled frames must have the same type as the mapped frame.";
if (scaled_buffer->type() != mapped_buffer->type()) {
RTC_LOG(LS_ERROR) << "When scaling "
<< VideoFrameBufferTypeToString(buffer_to_scale->type())
<< ", the image was unexpectedly converted to "
<< VideoFrameBufferTypeToString(scaled_buffer->type())
<< " instead of "
<< VideoFrameBufferTypeToString(mapped_buffer->type())
<< ". Can't encode frame.";
return {};
}
SetRawImagePlanes(&raw_images_[i], scaled_buffer);
prepared_buffers.push_back(scaled_buffer);
}
return prepared_buffers;
}
// static
LibvpxVp8Encoder::VariableFramerateExperiment
LibvpxVp8Encoder::ParseVariableFramerateConfig(std::string group_name) {
FieldTrialFlag disabled = FieldTrialFlag("Disabled");
FieldTrialParameter<double> framerate_limit("min_fps", 5.0);
FieldTrialParameter<int> qp("min_qp", 15);
FieldTrialParameter<int> undershoot_percentage("undershoot", 30);
ParseFieldTrial({&disabled, &framerate_limit, &qp, &undershoot_percentage},
field_trial::FindFullName(group_name));
VariableFramerateExperiment config;
config.enabled = !disabled.Get();
config.framerate_limit = framerate_limit.Get();
config.steady_state_qp = qp.Get();
config.steady_state_undershoot_percentage = undershoot_percentage.Get();
return config;
}
} // namespace webrtc