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/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
/* vim: set ts=8 sts=2 et sw=2 tw=80: */
/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at https://mozilla.org/MPL/2.0/. */
#include "VideoStreamFactory.h"
#include "common/browser_logging/CSFLog.h"
#include "VideoConduit.h"
#include <algorithm>
#include "api/video_codecs/video_codec.h"
#include <cmath>
#include <limits>
#include "mozilla/Assertions.h"
#include "mozilla/gfx/Point.h"
#include "mozilla/TemplateLib.h"
#include "rtc_base/time_utils.h"
#include <stdint.h>
#include <stdio.h>
#include <vector>
#include "video/config/video_encoder_config.h"
template <class t>
void ConstrainPreservingAspectRatio(uint16_t aMaxWidth, uint16_t aMaxHeight,
t* aWidth, t* aHeight) {
if (((*aWidth) <= aMaxWidth) && ((*aHeight) <= aMaxHeight)) {
return;
}
if ((*aWidth) * aMaxHeight > aMaxWidth * (*aHeight)) {
(*aHeight) = aMaxWidth * (*aHeight) / (*aWidth);
(*aWidth) = aMaxWidth;
} else {
(*aWidth) = aMaxHeight * (*aWidth) / (*aHeight);
(*aHeight) = aMaxHeight;
}
}
namespace mozilla {
#ifdef LOGTAG
# undef LOGTAG
#endif
#define LOGTAG "WebrtcVideoSessionConduit"
#define DEFAULT_VIDEO_MAX_FRAMERATE 30u
#define MB_OF(w, h) \
((unsigned int)((((w + 15) >> 4)) * ((unsigned int)((h + 15) >> 4))))
// For now, try to set the max rates well above the knee in the curve.
// Chosen somewhat arbitrarily; it's hard to find good data oriented for
// realtime interactive/talking-head recording. These rates assume
// 30fps.
// XXX Populate this based on a pref (which we should consider sorting because
// people won't assume they need to).
static VideoStreamFactory::ResolutionAndBitrateLimits
kResolutionAndBitrateLimits[] = {
// clang-format off
{MB_OF(1920, 1200), KBPS(1500), KBPS(2000), KBPS(10000)}, // >HD (3K, 4K, etc)
{MB_OF(1280, 720), KBPS(1200), KBPS(1500), KBPS(5000)}, // HD ~1080-1200
{MB_OF(800, 480), KBPS(200), KBPS(800), KBPS(2500)}, // HD ~720
{MB_OF(480, 270), KBPS(150), KBPS(500), KBPS(2000)}, // WVGA
{tl::Max<MB_OF(400, 240), MB_OF(352, 288)>::value, KBPS(125), KBPS(300), KBPS(1300)}, // VGA
{MB_OF(176, 144), KBPS(100), KBPS(150), KBPS(500)}, // WQVGA, CIF
{0 , KBPS(40), KBPS(80), KBPS(250)} // QCIF and below
// clang-format on
};
auto VideoStreamFactory::GetLimitsFor(unsigned int aWidth, unsigned int aHeight,
int aCapBps /* = 0 */)
-> ResolutionAndBitrateLimits {
// max bandwidth should be proportional (not linearly!) to resolution, and
// proportional (perhaps linearly, or close) to current frame rate.
int fs = MB_OF(aWidth, aHeight);
for (const auto& resAndLimits : kResolutionAndBitrateLimits) {
if (fs > resAndLimits.resolution_in_mb &&
// pick the highest range where at least start rate is within cap
// (or if we're at the end of the array).
(aCapBps == 0 || resAndLimits.start_bitrate_bps <= aCapBps ||
resAndLimits.resolution_in_mb == 0)) {
return resAndLimits;
}
}
MOZ_CRASH("Loop should have handled fallback");
}
/**
* Function to set the encoding bitrate limits based on incoming frame size and
* rate
* @param width, height: dimensions of the frame
* @param min: minimum bitrate in bps
* @param start: bitrate in bps that the encoder should start with
* @param cap: user-enforced max bitrate, or 0
* @param pref_cap: cap enforced by prefs
* @param negotiated_cap: cap negotiated through SDP
* @param aVideoStream stream to apply bitrates to
*/
static void SelectBitrates(unsigned short width, unsigned short height, int min,
int start, int cap, int pref_cap, int negotiated_cap,
webrtc::VideoStream& aVideoStream) {
int& out_min = aVideoStream.min_bitrate_bps;
int& out_start = aVideoStream.target_bitrate_bps;
int& out_max = aVideoStream.max_bitrate_bps;
VideoStreamFactory::ResolutionAndBitrateLimits resAndLimits =
VideoStreamFactory::GetLimitsFor(width, height);
out_min = MinIgnoreZero(resAndLimits.min_bitrate_bps, cap);
out_start = MinIgnoreZero(resAndLimits.start_bitrate_bps, cap);
out_max = MinIgnoreZero(resAndLimits.max_bitrate_bps, cap);
// Note: negotiated_cap is the max transport bitrate - it applies to
// a single codec encoding, but should also apply to the sum of all
// simulcast layers in this encoding! So sum(layers.maxBitrate) <=
// negotiated_cap
// Note that out_max already has had pref_cap applied to it
out_max = MinIgnoreZero(negotiated_cap, out_max);
out_min = std::min(out_min, out_max);
out_start = std::min(out_start, out_max);
if (min && min > out_min) {
out_min = min;
}
// If we try to set a minimum bitrate that is too low, ViE will reject it.
out_min = std::max(kViEMinCodecBitrate_bps, out_min);
out_max = std::max(kViEMinCodecBitrate_bps, out_max);
if (start && start > out_start) {
out_start = start;
}
// Ensure that min <= start <= max
if (out_min > out_max) {
out_min = out_max;
}
out_start = std::clamp(out_start, out_min, out_max);
MOZ_ASSERT(pref_cap == 0 || out_max <= pref_cap);
}
void VideoStreamFactory::SelectMaxFramerate(
int aWidth, int aHeight, const VideoCodecConfig::Encoding& aEncoding,
webrtc::VideoStream& aVideoStream) {
MOZ_ASSERT(aEncoding.constraints.scaleDownBy >= 1.0);
gfx::IntSize newSize(0, 0);
if (aWidth && aHeight) {
auto maxPixelCount = mLockScaling ? 0U : mWants.max_pixel_count;
newSize = CalculateScaledResolution(
aWidth, aHeight, aEncoding.constraints.scaleDownBy, maxPixelCount);
}
if (newSize.width == 0 || newSize.height == 0) {
return;
}
uint16_t max_width = mCodecConfig.mEncodingConstraints.maxWidth;
uint16_t max_height = mCodecConfig.mEncodingConstraints.maxHeight;
if (max_width || max_height) {
max_width = max_width ? max_width : UINT16_MAX;
max_height = max_height ? max_height : UINT16_MAX;
ConstrainPreservingAspectRatio(max_width, max_height, &newSize.width,
&newSize.height);
}
MOZ_ASSERT(newSize.width > 0);
MOZ_ASSERT(newSize.height > 0);
aVideoStream.width = newSize.width;
aVideoStream.height = newSize.height;
SelectMaxFramerateForAllStreams(newSize.width, newSize.height);
CSFLogInfo(LOGTAG, "%s Input frame %ux%u, RID %s scaling to %zux%zu",
__FUNCTION__, aWidth, aHeight, aEncoding.rid.c_str(),
aVideoStream.width, aVideoStream.height);
// mMaxFramerateForAllStreams is based on codec-wide stuff like fmtp, and
// hard-coded limits based on the source resolution.
// mCodecConfig.mEncodingConstraints.maxFps does not take the hard-coded
// limits into account, so we have mMaxFramerateForAllStreams which
// incorporates those. Per-encoding max framerate is based on parameters
// from JS, and maybe rid
unsigned int max_framerate = SelectFrameRate(
mMaxFramerateForAllStreams, aVideoStream.width, aVideoStream.height);
max_framerate = std::min(
WebrtcVideoConduit::ToLibwebrtcMaxFramerate(aEncoding.constraints.maxFps),
max_framerate);
if (max_framerate >= std::numeric_limits<int>::max()) {
// If nothing has specified any kind of limit (uncommon), pick something
// reasonable.
max_framerate = DEFAULT_VIDEO_MAX_FRAMERATE;
}
aVideoStream.max_framerate = static_cast<int>(max_framerate);
}
std::vector<webrtc::VideoStream> VideoStreamFactory::CreateEncoderStreams(
const webrtc::FieldTrialsView& field_trials, int aWidth, int aHeight,
const webrtc::VideoEncoderConfig& aConfig) {
const size_t streamCount = aConfig.number_of_streams;
MOZ_RELEASE_ASSERT(streamCount >= 1, "Should request at least one stream");
MOZ_RELEASE_ASSERT(streamCount <= aConfig.simulcast_layers.size());
std::vector<webrtc::VideoStream> streams;
streams.reserve(streamCount);
{
auto frameRateController = mFramerateController.Lock();
frameRateController->Reset();
}
for (size_t idx = 0; idx < streamCount; ++idx) {
webrtc::VideoStream video_stream = aConfig.simulcast_layers[idx];
auto& encoding = mCodecConfig.mEncodings[idx];
MOZ_ASSERT(video_stream.active == encoding.active);
SelectMaxFramerate(aWidth, aHeight, encoding, video_stream);
if (video_stream.width == 0 || video_stream.height == 0) {
CSFLogInfo(LOGTAG,
"%s Stream with RID %s ignored because of no resolution.",
__FUNCTION__, encoding.rid.c_str());
continue;
}
CSFLogInfo(LOGTAG, "%s Stream with RID %s maxFps=%d (global max fps = %u)",
__FUNCTION__, encoding.rid.c_str(), video_stream.max_framerate,
(unsigned)mMaxFramerateForAllStreams);
SelectBitrates(video_stream.width, video_stream.height, mMinBitrate,
mStartBitrate, encoding.constraints.maxBr, mPrefMaxBitrate,
mNegotiatedMaxBitrate, video_stream);
video_stream.bitrate_priority = aConfig.bitrate_priority;
video_stream.max_qp = kQpMax;
if (streamCount > 1) {
video_stream.num_temporal_layers = 2;
// XXX Bug 1390215 investigate using more of
// simulcast.cc:GetSimulcastConfig() or our own algorithm to replace it
}
if (mCodecConfig.mName == "H264") {
if (mCodecConfig.mEncodingConstraints.maxMbps > 0) {
// Not supported yet!
CSFLogError(LOGTAG, "%s H.264 max_mbps not supported yet",
__FUNCTION__);
}
}
streams.push_back(video_stream);
}
MOZ_RELEASE_ASSERT(streams.size(), "Should configure at least one stream");
return streams;
}
gfx::IntSize VideoStreamFactory::CalculateScaledResolution(
int aWidth, int aHeight, double aScaleDownByResolution,
unsigned int aMaxPixelCount) {
// If any adjustments like scaleResolutionDownBy or maxFS are being given
// we want to choose a height and width here to provide for more variety
// in possible resolutions.
int width = aWidth;
int height = aHeight;
if (aScaleDownByResolution > 1) {
width = static_cast<int>(aWidth / aScaleDownByResolution);
height = static_cast<int>(aHeight / aScaleDownByResolution);
}
// Check if we still need to adjust resolution down more due to other
// constraints.
if (mCodecConfig.mEncodingConstraints.maxFs > 0 || aMaxPixelCount > 0) {
auto currentFs = static_cast<unsigned int>(width * height);
auto maxFs =
(mCodecConfig.mEncodingConstraints.maxFs > 0 && aMaxPixelCount > 0)
? std::min((mCodecConfig.mEncodingConstraints.maxFs * 16 * 16),
aMaxPixelCount)
: std::max((mCodecConfig.mEncodingConstraints.maxFs * 16 * 16),
aMaxPixelCount);
// If our currentFs is greater than maxFs we calculate a width and height
// that will get as close as possible to maxFs and try to maintain aspect
// ratio.
if (currentFs > maxFs) {
if (aWidth > aHeight) { // Landscape
auto aspectRatio = static_cast<double>(aWidth) / aHeight;
height = static_cast<int>(std::sqrt(maxFs / aspectRatio));
width = static_cast<int>(height * aspectRatio);
} else { // Portrait
auto aspectRatio = static_cast<double>(aHeight) / aWidth;
width = static_cast<int>(std::sqrt(maxFs / aspectRatio));
height = static_cast<int>(width * aspectRatio);
}
}
}
// Simplest possible adaptation to resolution alignment.
width -= width % mWants.resolution_alignment;
height -= height % mWants.resolution_alignment;
// Dont scale below our minimum value to prevent problems.
const int minSize = 1;
if (width < minSize || height < minSize) {
width = minSize;
height = minSize;
}
return gfx::IntSize(width, height);
}
void VideoStreamFactory::SelectMaxFramerateForAllStreams(
unsigned short aWidth, unsigned short aHeight) {
int max_fs = std::numeric_limits<int>::max();
if (!mLockScaling) {
max_fs = mWants.max_pixel_count;
}
// Limit resolution to max-fs
if (mCodecConfig.mEncodingConstraints.maxFs) {
// max-fs is in macroblocks, convert to pixels
max_fs = std::min(
max_fs,
static_cast<int>(mCodecConfig.mEncodingConstraints.maxFs * (16 * 16)));
}
unsigned int framerate_all_streams =
SelectFrameRate(mMaxFramerateForAllStreams, aWidth, aHeight);
unsigned int maxFrameRate = mMaxFramerateForAllStreams;
if (mMaxFramerateForAllStreams != framerate_all_streams) {
CSFLogDebug(LOGTAG, "%s: framerate changing to %u (from %u)", __FUNCTION__,
framerate_all_streams, maxFrameRate);
mMaxFramerateForAllStreams = framerate_all_streams;
}
int framerate_with_wants;
if (framerate_all_streams > std::numeric_limits<int>::max()) {
framerate_with_wants = std::numeric_limits<int>::max();
} else {
framerate_with_wants = static_cast<int>(framerate_all_streams);
}
framerate_with_wants =
std::min(framerate_with_wants, mWants.max_framerate_fps);
CSFLogDebug(LOGTAG,
"%s: Calling OnOutputFormatRequest, max_fs=%d, max_fps=%d",
__FUNCTION__, max_fs, framerate_with_wants);
auto frameRateController = mFramerateController.Lock();
frameRateController->SetMaxFramerate(framerate_with_wants);
}
unsigned int VideoStreamFactory::SelectFrameRate(
unsigned int aOldFramerate, unsigned short aSendingWidth,
unsigned short aSendingHeight) {
unsigned int new_framerate = aOldFramerate;
// Limit frame rate based on max-mbps
if (mCodecConfig.mEncodingConstraints.maxMbps) {
unsigned int cur_fs, mb_width, mb_height;
mb_width = (aSendingWidth + 15) >> 4;
mb_height = (aSendingHeight + 15) >> 4;
cur_fs = mb_width * mb_height;
if (cur_fs > 0) { // in case no frames have been sent
new_framerate = mCodecConfig.mEncodingConstraints.maxMbps / cur_fs;
}
}
new_framerate =
std::min(new_framerate, WebrtcVideoConduit::ToLibwebrtcMaxFramerate(
mCodecConfig.mEncodingConstraints.maxFps));
return new_framerate;
}
bool VideoStreamFactory::ShouldDropFrame(const webrtc::VideoFrame& aFrame) {
bool hasNonZeroLayer = false;
{
const size_t streamCount = mCodecConfig.mEncodings.size();
for (int idx = streamCount - 1; idx >= 0; --idx) {
const auto& encoding = mCodecConfig.mEncodings[idx];
if (aFrame.width() / encoding.constraints.scaleDownBy >= 1.0 &&
aFrame.height() / encoding.constraints.scaleDownBy >= 1.0) {
hasNonZeroLayer = true;
break;
}
}
}
if (!hasNonZeroLayer) {
return true;
}
auto frameRateController = mFramerateController.Lock();
return frameRateController->ShouldDropFrame(aFrame.timestamp_us() *
rtc::kNumNanosecsPerMicrosec);
}
} // namespace mozilla