/* * Copyright 2020 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 "call/adaptation/video_stream_adapter.h" #include #include #include #include "absl/types/optional.h" #include "absl/types/variant.h" #include "api/video/video_adaptation_counters.h" #include "api/video/video_adaptation_reason.h" #include "api/video_codecs/video_encoder.h" #include "call/adaptation/video_source_restrictions.h" #include "call/adaptation/video_stream_input_state.h" #include "rtc_base/checks.h" #include "rtc_base/constructor_magic.h" #include "rtc_base/logging.h" #include "rtc_base/numerics/safe_conversions.h" #include "rtc_base/synchronization/sequence_checker.h" namespace webrtc { const int kMinFrameRateFps = 2; namespace { // For frame rate, the steps we take are 2/3 (down) and 3/2 (up). int GetLowerFrameRateThan(int fps) { RTC_DCHECK(fps != std::numeric_limits::max()); return (fps * 2) / 3; } // TODO(hbos): Use absl::optional<> instead? int GetHigherFrameRateThan(int fps) { return fps != std::numeric_limits::max() ? (fps * 3) / 2 : std::numeric_limits::max(); } // For resolution, the steps we take are 3/5 (down) and 5/3 (up). // Notice the asymmetry of which restriction property is set depending on if // we are adapting up or down: // - VideoSourceRestrictor::DecreaseResolution() sets the max_pixels_per_frame() // to the desired target and target_pixels_per_frame() to null. // - VideoSourceRestrictor::IncreaseResolutionTo() sets the // target_pixels_per_frame() to the desired target, and max_pixels_per_frame() // is set according to VideoSourceRestrictor::GetIncreasedMaxPixelsWanted(). int GetLowerResolutionThan(int pixel_count) { RTC_DCHECK(pixel_count != std::numeric_limits::max()); return (pixel_count * 3) / 5; } int GetIncreasedMaxPixelsWanted(int target_pixels) { if (target_pixels == std::numeric_limits::max()) return std::numeric_limits::max(); // When we decrease resolution, we go down to at most 3/5 of current pixels. // Thus to increase resolution, we need 3/5 to get back to where we started. // When going up, the desired max_pixels_per_frame() has to be significantly // higher than the target because the source's native resolutions might not // match the target. We pick 12/5 of the target. // // (This value was historically 4 times the old target, which is (3/5)*4 of // the new target - or 12/5 - assuming the target is adjusted according to // the above steps.) RTC_DCHECK(target_pixels != std::numeric_limits::max()); return (target_pixels * 12) / 5; } bool CanDecreaseResolutionTo(int target_pixels, const VideoStreamInputState& input_state, const VideoSourceRestrictions& restrictions) { int max_pixels_per_frame = rtc::dchecked_cast(restrictions.max_pixels_per_frame().value_or( std::numeric_limits::max())); return target_pixels < max_pixels_per_frame && target_pixels >= input_state.min_pixels_per_frame(); } bool CanIncreaseResolutionTo(int target_pixels, const VideoSourceRestrictions& restrictions) { int max_pixels_wanted = GetIncreasedMaxPixelsWanted(target_pixels); int max_pixels_per_frame = rtc::dchecked_cast(restrictions.max_pixels_per_frame().value_or( std::numeric_limits::max())); return max_pixels_wanted > max_pixels_per_frame; } bool CanDecreaseFrameRateTo(int max_frame_rate, const VideoSourceRestrictions& restrictions) { const int fps_wanted = std::max(kMinFrameRateFps, max_frame_rate); return fps_wanted < rtc::dchecked_cast(restrictions.max_frame_rate().value_or( std::numeric_limits::max())); } bool CanIncreaseFrameRateTo(int max_frame_rate, const VideoSourceRestrictions& restrictions) { return max_frame_rate > rtc::dchecked_cast(restrictions.max_frame_rate().value_or( std::numeric_limits::max())); } } // namespace VideoSourceRestrictionsListener::~VideoSourceRestrictionsListener() = default; VideoSourceRestrictions FilterRestrictionsByDegradationPreference( VideoSourceRestrictions source_restrictions, DegradationPreference degradation_preference) { switch (degradation_preference) { case DegradationPreference::BALANCED: break; case DegradationPreference::MAINTAIN_FRAMERATE: source_restrictions.set_max_frame_rate(absl::nullopt); break; case DegradationPreference::MAINTAIN_RESOLUTION: source_restrictions.set_max_pixels_per_frame(absl::nullopt); source_restrictions.set_target_pixels_per_frame(absl::nullopt); break; case DegradationPreference::DISABLED: source_restrictions.set_max_pixels_per_frame(absl::nullopt); source_restrictions.set_target_pixels_per_frame(absl::nullopt); source_restrictions.set_max_frame_rate(absl::nullopt); } return source_restrictions; } // TODO(hbos): Use absl::optional<> instead? int GetHigherResolutionThan(int pixel_count) { return pixel_count != std::numeric_limits::max() ? (pixel_count * 5) / 3 : std::numeric_limits::max(); } // static const char* Adaptation::StatusToString(Adaptation::Status status) { switch (status) { case Adaptation::Status::kValid: return "kValid"; case Adaptation::Status::kLimitReached: return "kLimitReached"; case Adaptation::Status::kAwaitingPreviousAdaptation: return "kAwaitingPreviousAdaptation"; case Status::kInsufficientInput: return "kInsufficientInput"; case Status::kAdaptationDisabled: return "kAdaptationDisabled"; case Status::kRejectedByConstraint: return "kRejectedByConstraint"; } } Adaptation::Adaptation(int validation_id, VideoSourceRestrictions restrictions, VideoAdaptationCounters counters, VideoStreamInputState input_state, bool min_pixel_limit_reached) : validation_id_(validation_id), status_(Status::kValid), min_pixel_limit_reached_(min_pixel_limit_reached), input_state_(std::move(input_state)), restrictions_(std::move(restrictions)), counters_(std::move(counters)) {} Adaptation::Adaptation(int validation_id, Status invalid_status, VideoStreamInputState input_state, bool min_pixel_limit_reached) : validation_id_(validation_id), status_(invalid_status), min_pixel_limit_reached_(min_pixel_limit_reached), input_state_(std::move(input_state)) { RTC_DCHECK_NE(status_, Status::kValid); } Adaptation::Status Adaptation::status() const { return status_; } bool Adaptation::min_pixel_limit_reached() const { return min_pixel_limit_reached_; } const VideoStreamInputState& Adaptation::input_state() const { return input_state_; } const VideoSourceRestrictions& Adaptation::restrictions() const { return restrictions_; } const VideoAdaptationCounters& Adaptation::counters() const { return counters_; } VideoStreamAdapter::VideoStreamAdapter( VideoStreamInputStateProvider* input_state_provider) : input_state_provider_(input_state_provider), balanced_settings_(), adaptation_validation_id_(0), degradation_preference_(DegradationPreference::DISABLED), awaiting_frame_size_change_(absl::nullopt), last_video_source_restrictions_() { sequence_checker_.Detach(); } VideoStreamAdapter::~VideoStreamAdapter() { RTC_DCHECK(adaptation_listeners_.empty()) << "There are listener(s) attached to a VideoStreamAdapter being " "destroyed."; RTC_DCHECK(adaptation_constraints_.empty()) << "There are constaint(s) attached to a VideoStreamAdapter being " "destroyed."; } VideoSourceRestrictions VideoStreamAdapter::source_restrictions() const { RTC_DCHECK_RUN_ON(&sequence_checker_); return current_restrictions_.restrictions; } const VideoAdaptationCounters& VideoStreamAdapter::adaptation_counters() const { RTC_DCHECK_RUN_ON(&sequence_checker_); return current_restrictions_.counters; } void VideoStreamAdapter::ClearRestrictions() { RTC_DCHECK_RUN_ON(&sequence_checker_); // Invalidate any previously returned Adaptation. RTC_LOG(INFO) << "Resetting restrictions"; ++adaptation_validation_id_; current_restrictions_ = {VideoSourceRestrictions(), VideoAdaptationCounters()}; awaiting_frame_size_change_ = absl::nullopt; BroadcastVideoRestrictionsUpdate(input_state_provider_->InputState(), nullptr); } void VideoStreamAdapter::AddRestrictionsListener( VideoSourceRestrictionsListener* restrictions_listener) { RTC_DCHECK_RUN_ON(&sequence_checker_); RTC_DCHECK(std::find(restrictions_listeners_.begin(), restrictions_listeners_.end(), restrictions_listener) == restrictions_listeners_.end()); restrictions_listeners_.push_back(restrictions_listener); } void VideoStreamAdapter::RemoveRestrictionsListener( VideoSourceRestrictionsListener* restrictions_listener) { RTC_DCHECK_RUN_ON(&sequence_checker_); auto it = std::find(restrictions_listeners_.begin(), restrictions_listeners_.end(), restrictions_listener); RTC_DCHECK(it != restrictions_listeners_.end()); restrictions_listeners_.erase(it); } void VideoStreamAdapter::AddAdaptationListener( AdaptationListener* adaptation_listener) { RTC_DCHECK_RUN_ON(&sequence_checker_); RTC_DCHECK(std::find(adaptation_listeners_.begin(), adaptation_listeners_.end(), adaptation_listener) == adaptation_listeners_.end()); adaptation_listeners_.push_back(adaptation_listener); } void VideoStreamAdapter::RemoveAdaptationListener( AdaptationListener* adaptation_listener) { RTC_DCHECK_RUN_ON(&sequence_checker_); auto it = std::find(adaptation_listeners_.begin(), adaptation_listeners_.end(), adaptation_listener); RTC_DCHECK(it != adaptation_listeners_.end()); adaptation_listeners_.erase(it); } void VideoStreamAdapter::AddAdaptationConstraint( AdaptationConstraint* adaptation_constraint) { RTC_DCHECK_RUN_ON(&sequence_checker_); RTC_DCHECK(std::find(adaptation_constraints_.begin(), adaptation_constraints_.end(), adaptation_constraint) == adaptation_constraints_.end()); adaptation_constraints_.push_back(adaptation_constraint); } void VideoStreamAdapter::RemoveAdaptationConstraint( AdaptationConstraint* adaptation_constraint) { RTC_DCHECK_RUN_ON(&sequence_checker_); auto it = std::find(adaptation_constraints_.begin(), adaptation_constraints_.end(), adaptation_constraint); RTC_DCHECK(it != adaptation_constraints_.end()); adaptation_constraints_.erase(it); } void VideoStreamAdapter::SetDegradationPreference( DegradationPreference degradation_preference) { RTC_DCHECK_RUN_ON(&sequence_checker_); if (degradation_preference_ == degradation_preference) return; // Invalidate any previously returned Adaptation. ++adaptation_validation_id_; bool balanced_switch = degradation_preference == DegradationPreference::BALANCED || degradation_preference_ == DegradationPreference::BALANCED; degradation_preference_ = degradation_preference; if (balanced_switch) { // ClearRestrictions() calls BroadcastVideoRestrictionsUpdate(nullptr). ClearRestrictions(); } else { BroadcastVideoRestrictionsUpdate(input_state_provider_->InputState(), nullptr); } } struct VideoStreamAdapter::RestrictionsOrStateVisitor { Adaptation operator()(const RestrictionsWithCounters& r) const { return Adaptation(adaptation_validation_id, r.restrictions, r.counters, input_state, min_pixel_limit_reached()); } Adaptation operator()(const Adaptation::Status& status) const { RTC_DCHECK_NE(status, Adaptation::Status::kValid); return Adaptation(adaptation_validation_id, status, input_state, min_pixel_limit_reached()); } bool min_pixel_limit_reached() const { return input_state.frame_size_pixels().has_value() && GetLowerResolutionThan(input_state.frame_size_pixels().value()) < input_state.min_pixels_per_frame(); } const int adaptation_validation_id; const VideoStreamInputState& input_state; }; Adaptation VideoStreamAdapter::RestrictionsOrStateToAdaptation( VideoStreamAdapter::RestrictionsOrState step_or_state, const VideoStreamInputState& input_state) const { RTC_DCHECK(!step_or_state.valueless_by_exception()); return absl::visit( RestrictionsOrStateVisitor{adaptation_validation_id_, input_state}, step_or_state); } Adaptation VideoStreamAdapter::GetAdaptationUp( const VideoStreamInputState& input_state, rtc::scoped_refptr resource) const { RestrictionsOrState step = GetAdaptationUpStep(input_state); // If an adaptation proposed, check with the constraints that it is ok. if (absl::holds_alternative(step)) { RestrictionsWithCounters restrictions = absl::get(step); for (const auto* constraint : adaptation_constraints_) { if (!constraint->IsAdaptationUpAllowed( input_state, current_restrictions_.restrictions, restrictions.restrictions, resource)) { RTC_LOG(INFO) << "Not adapting up because constraint \"" << constraint->Name() << "\" disallowed it"; step = Adaptation::Status::kRejectedByConstraint; } } } return RestrictionsOrStateToAdaptation(step, input_state); } Adaptation VideoStreamAdapter::GetAdaptationUp( rtc::scoped_refptr resource) { RTC_DCHECK_RUN_ON(&sequence_checker_); RTC_DCHECK(resource); VideoStreamInputState input_state = input_state_provider_->InputState(); ++adaptation_validation_id_; Adaptation adaptation = GetAdaptationUp(input_state, resource); return adaptation; } VideoStreamAdapter::RestrictionsOrState VideoStreamAdapter::GetAdaptationUpStep( const VideoStreamInputState& input_state) const { if (!HasSufficientInputForAdaptation(input_state)) { return Adaptation::Status::kInsufficientInput; } // Don't adapt if we're awaiting a previous adaptation to have an effect. if (awaiting_frame_size_change_ && awaiting_frame_size_change_->pixels_increased && degradation_preference_ == DegradationPreference::MAINTAIN_FRAMERATE && input_state.frame_size_pixels().value() <= awaiting_frame_size_change_->frame_size_pixels) { return Adaptation::Status::kAwaitingPreviousAdaptation; } // Maybe propose targets based on degradation preference. switch (degradation_preference_) { case DegradationPreference::BALANCED: { // Attempt to increase target frame rate. RestrictionsOrState increase_frame_rate = IncreaseFramerate(input_state, current_restrictions_); if (absl::holds_alternative( increase_frame_rate)) { return increase_frame_rate; } // else, increase resolution. ABSL_FALLTHROUGH_INTENDED; } case DegradationPreference::MAINTAIN_FRAMERATE: { // Attempt to increase pixel count. return IncreaseResolution(input_state, current_restrictions_); } case DegradationPreference::MAINTAIN_RESOLUTION: { // Scale up framerate. return IncreaseFramerate(input_state, current_restrictions_); } case DegradationPreference::DISABLED: return Adaptation::Status::kAdaptationDisabled; } } Adaptation VideoStreamAdapter::GetAdaptationDown() { RTC_DCHECK_RUN_ON(&sequence_checker_); VideoStreamInputState input_state = input_state_provider_->InputState(); ++adaptation_validation_id_; return RestrictionsOrStateToAdaptation(GetAdaptationDownStep(input_state), input_state); } VideoStreamAdapter::RestrictionsOrState VideoStreamAdapter::GetAdaptationDownStep( const VideoStreamInputState& input_state) const { if (!HasSufficientInputForAdaptation(input_state)) { return Adaptation::Status::kInsufficientInput; } // Don't adapt if we're awaiting a previous adaptation to have an effect or // if we switched degradation preference. if (awaiting_frame_size_change_ && !awaiting_frame_size_change_->pixels_increased && degradation_preference_ == DegradationPreference::MAINTAIN_FRAMERATE && input_state.frame_size_pixels().value() >= awaiting_frame_size_change_->frame_size_pixels) { return Adaptation::Status::kAwaitingPreviousAdaptation; } // Maybe propose targets based on degradation preference. switch (degradation_preference_) { case DegradationPreference::BALANCED: { // Try scale down framerate, if lower. RestrictionsOrState decrease_frame_rate = DecreaseFramerate(input_state, current_restrictions_); if (absl::holds_alternative( decrease_frame_rate)) { return decrease_frame_rate; } // else, decrease resolution. ABSL_FALLTHROUGH_INTENDED; } case DegradationPreference::MAINTAIN_FRAMERATE: { return DecreaseResolution(input_state, current_restrictions_); } case DegradationPreference::MAINTAIN_RESOLUTION: { return DecreaseFramerate(input_state, current_restrictions_); } case DegradationPreference::DISABLED: return Adaptation::Status::kAdaptationDisabled; } } VideoStreamAdapter::RestrictionsOrState VideoStreamAdapter::DecreaseResolution( const VideoStreamInputState& input_state, const RestrictionsWithCounters& current_restrictions) { int target_pixels = GetLowerResolutionThan(input_state.frame_size_pixels().value()); if (!CanDecreaseResolutionTo(target_pixels, input_state, current_restrictions.restrictions)) { return Adaptation::Status::kLimitReached; } RestrictionsWithCounters new_restrictions = current_restrictions; RTC_LOG(LS_INFO) << "Scaling down resolution, max pixels: " << target_pixels; new_restrictions.restrictions.set_max_pixels_per_frame( target_pixels != std::numeric_limits::max() ? absl::optional(target_pixels) : absl::nullopt); new_restrictions.restrictions.set_target_pixels_per_frame(absl::nullopt); ++new_restrictions.counters.resolution_adaptations; return new_restrictions; } VideoStreamAdapter::RestrictionsOrState VideoStreamAdapter::DecreaseFramerate( const VideoStreamInputState& input_state, const RestrictionsWithCounters& current_restrictions) const { int max_frame_rate; if (degradation_preference_ == DegradationPreference::MAINTAIN_RESOLUTION) { max_frame_rate = GetLowerFrameRateThan(input_state.frames_per_second()); } else if (degradation_preference_ == DegradationPreference::BALANCED) { max_frame_rate = balanced_settings_.MinFps(input_state.video_codec_type(), input_state.frame_size_pixels().value()); } else { RTC_NOTREACHED(); max_frame_rate = GetLowerFrameRateThan(input_state.frames_per_second()); } if (!CanDecreaseFrameRateTo(max_frame_rate, current_restrictions.restrictions)) { return Adaptation::Status::kLimitReached; } RestrictionsWithCounters new_restrictions = current_restrictions; max_frame_rate = std::max(kMinFrameRateFps, max_frame_rate); RTC_LOG(LS_INFO) << "Scaling down framerate: " << max_frame_rate; new_restrictions.restrictions.set_max_frame_rate( max_frame_rate != std::numeric_limits::max() ? absl::optional(max_frame_rate) : absl::nullopt); ++new_restrictions.counters.fps_adaptations; return new_restrictions; } VideoStreamAdapter::RestrictionsOrState VideoStreamAdapter::IncreaseResolution( const VideoStreamInputState& input_state, const RestrictionsWithCounters& current_restrictions) { int target_pixels = input_state.frame_size_pixels().value(); if (current_restrictions.counters.resolution_adaptations == 1) { RTC_LOG(LS_INFO) << "Removing resolution down-scaling setting."; target_pixels = std::numeric_limits::max(); } target_pixels = GetHigherResolutionThan(target_pixels); if (!CanIncreaseResolutionTo(target_pixels, current_restrictions.restrictions)) { return Adaptation::Status::kLimitReached; } int max_pixels_wanted = GetIncreasedMaxPixelsWanted(target_pixels); RestrictionsWithCounters new_restrictions = current_restrictions; RTC_LOG(LS_INFO) << "Scaling up resolution, max pixels: " << max_pixels_wanted; new_restrictions.restrictions.set_max_pixels_per_frame( max_pixels_wanted != std::numeric_limits::max() ? absl::optional(max_pixels_wanted) : absl::nullopt); new_restrictions.restrictions.set_target_pixels_per_frame( max_pixels_wanted != std::numeric_limits::max() ? absl::optional(target_pixels) : absl::nullopt); --new_restrictions.counters.resolution_adaptations; RTC_DCHECK_GE(new_restrictions.counters.resolution_adaptations, 0); return new_restrictions; } VideoStreamAdapter::RestrictionsOrState VideoStreamAdapter::IncreaseFramerate( const VideoStreamInputState& input_state, const RestrictionsWithCounters& current_restrictions) const { int max_frame_rate; if (degradation_preference_ == DegradationPreference::MAINTAIN_RESOLUTION) { max_frame_rate = GetHigherFrameRateThan(input_state.frames_per_second()); } else if (degradation_preference_ == DegradationPreference::BALANCED) { max_frame_rate = balanced_settings_.MaxFps(input_state.video_codec_type(), input_state.frame_size_pixels().value()); // In BALANCED, the max_frame_rate must be checked before proceeding. This // is because the MaxFps might be the current Fps and so the balanced // settings may want to scale up the resolution.= if (!CanIncreaseFrameRateTo(max_frame_rate, current_restrictions.restrictions)) { return Adaptation::Status::kLimitReached; } } else { RTC_NOTREACHED(); max_frame_rate = GetHigherFrameRateThan(input_state.frames_per_second()); } if (current_restrictions.counters.fps_adaptations == 1) { RTC_LOG(LS_INFO) << "Removing framerate down-scaling setting."; max_frame_rate = std::numeric_limits::max(); } if (!CanIncreaseFrameRateTo(max_frame_rate, current_restrictions.restrictions)) { return Adaptation::Status::kLimitReached; } RTC_LOG(LS_INFO) << "Scaling up framerate: " << max_frame_rate; RestrictionsWithCounters new_restrictions = current_restrictions; new_restrictions.restrictions.set_max_frame_rate( max_frame_rate != std::numeric_limits::max() ? absl::optional(max_frame_rate) : absl::nullopt); --new_restrictions.counters.fps_adaptations; RTC_DCHECK_GE(new_restrictions.counters.fps_adaptations, 0); return new_restrictions; } Adaptation VideoStreamAdapter::GetAdaptDownResolution() { RTC_DCHECK_RUN_ON(&sequence_checker_); VideoStreamInputState input_state = input_state_provider_->InputState(); switch (degradation_preference_) { case DegradationPreference::DISABLED: return RestrictionsOrStateToAdaptation( Adaptation::Status::kAdaptationDisabled, input_state); case DegradationPreference::MAINTAIN_RESOLUTION: return RestrictionsOrStateToAdaptation(Adaptation::Status::kLimitReached, input_state); case DegradationPreference::MAINTAIN_FRAMERATE: return GetAdaptationDown(); case DegradationPreference::BALANCED: { return RestrictionsOrStateToAdaptation( GetAdaptDownResolutionStepForBalanced(input_state), input_state); } default: RTC_NOTREACHED(); } } VideoStreamAdapter::RestrictionsOrState VideoStreamAdapter::GetAdaptDownResolutionStepForBalanced( const VideoStreamInputState& input_state) const { // Adapt twice if the first adaptation did not decrease resolution. auto first_step = GetAdaptationDownStep(input_state); if (!absl::holds_alternative(first_step)) { return first_step; } auto first_restrictions = absl::get(first_step); if (first_restrictions.counters.resolution_adaptations > current_restrictions_.counters.resolution_adaptations) { return first_step; } // We didn't decrease resolution so force it; amend a resolution resuction // to the existing framerate reduction in |first_restrictions|. auto second_step = DecreaseResolution(input_state, first_restrictions); if (absl::holds_alternative(second_step)) { return second_step; } // If the second step was not successful then settle for the first one. return first_step; } void VideoStreamAdapter::ApplyAdaptation( const Adaptation& adaptation, rtc::scoped_refptr resource) { RTC_DCHECK_RUN_ON(&sequence_checker_); RTC_DCHECK_EQ(adaptation.validation_id_, adaptation_validation_id_); if (adaptation.status() != Adaptation::Status::kValid) return; // Remember the input pixels and fps of this adaptation. Used to avoid // adapting again before this adaptation has had an effect. if (DidIncreaseResolution(current_restrictions_.restrictions, adaptation.restrictions())) { awaiting_frame_size_change_.emplace( true, adaptation.input_state().frame_size_pixels().value()); } else if (DidDecreaseResolution(current_restrictions_.restrictions, adaptation.restrictions())) { awaiting_frame_size_change_.emplace( false, adaptation.input_state().frame_size_pixels().value()); } else { awaiting_frame_size_change_ = absl::nullopt; } current_restrictions_ = {adaptation.restrictions(), adaptation.counters()}; BroadcastVideoRestrictionsUpdate(adaptation.input_state(), resource); } Adaptation VideoStreamAdapter::GetAdaptationTo( const VideoAdaptationCounters& counters, const VideoSourceRestrictions& restrictions) { // Adapts up/down from the current levels so counters are equal. RTC_DCHECK_RUN_ON(&sequence_checker_); VideoStreamInputState input_state = input_state_provider_->InputState(); return Adaptation(adaptation_validation_id_, restrictions, counters, input_state, false); } void VideoStreamAdapter::BroadcastVideoRestrictionsUpdate( const VideoStreamInputState& input_state, const rtc::scoped_refptr& resource) { RTC_DCHECK_RUN_ON(&sequence_checker_); VideoSourceRestrictions filtered = FilterRestrictionsByDegradationPreference( source_restrictions(), degradation_preference_); if (last_filtered_restrictions_ == filtered) { return; } for (auto* restrictions_listener : restrictions_listeners_) { restrictions_listener->OnVideoSourceRestrictionsUpdated( filtered, current_restrictions_.counters, resource, source_restrictions()); } for (auto* adaptation_listener : adaptation_listeners_) { adaptation_listener->OnAdaptationApplied( input_state, last_video_source_restrictions_, current_restrictions_.restrictions, resource); } last_video_source_restrictions_ = current_restrictions_.restrictions; last_filtered_restrictions_ = filtered; } bool VideoStreamAdapter::HasSufficientInputForAdaptation( const VideoStreamInputState& input_state) const { return input_state.HasInputFrameSizeAndFramesPerSecond() && (degradation_preference_ != DegradationPreference::MAINTAIN_RESOLUTION || input_state.frames_per_second() >= kMinFrameRateFps); } VideoStreamAdapter::AwaitingFrameSizeChange::AwaitingFrameSizeChange( bool pixels_increased, int frame_size_pixels) : pixels_increased(pixels_increased), frame_size_pixels(frame_size_pixels) {} } // namespace webrtc