modules/video_coding/svc/scalability_structure_key_svc.cc - src - Git at Google

 /*
  *  Copyright (c) 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 "modules/video_coding/svc/scalability_structure_key_svc.h"

 #include <bitset>
 #include <utility>
 #include <vector>

 #include "absl/types/optional.h"
 #include "api/transport/rtp/dependency_descriptor.h"
 #include "api/video/video_bitrate_allocation.h"
 #include "common_video/generic_frame_descriptor/generic_frame_info.h"
 #include "modules/video_coding/svc/scalable_video_controller.h"
 #include "rtc_base/checks.h"
 #include "rtc_base/logging.h"

 namespace webrtc {

 constexpr int ScalabilityStructureKeySvc::kMaxNumSpatialLayers;
 constexpr int ScalabilityStructureKeySvc::kMaxNumTemporalLayers;

 ScalabilityStructureKeySvc::ScalabilityStructureKeySvc(int num_spatial_layers,
                                                        int num_temporal_layers)
     : num_spatial_layers_(num_spatial_layers),
       num_temporal_layers_(num_temporal_layers),
       active_decode_targets_(
           (uint32_t{1} << (num_spatial_layers * num_temporal_layers)) - 1) {
   // There is no point to use this structure without spatial scalability.
   RTC_DCHECK_GT(num_spatial_layers, 1);
   RTC_DCHECK_LE(num_spatial_layers, kMaxNumSpatialLayers);
   RTC_DCHECK_LE(num_temporal_layers, kMaxNumTemporalLayers);
 }

 ScalabilityStructureKeySvc::~ScalabilityStructureKeySvc() = default;

 ScalableVideoController::StreamLayersConfig
 ScalabilityStructureKeySvc::StreamConfig() const {
   StreamLayersConfig result;
   result.num_spatial_layers = num_spatial_layers_;
   result.num_temporal_layers = num_temporal_layers_;
   result.scaling_factor_num[num_spatial_layers_ - 1] = 1;
   result.scaling_factor_den[num_spatial_layers_ - 1] = 1;
   for (int sid = num_spatial_layers_ - 1; sid > 0; --sid) {
     result.scaling_factor_num[sid - 1] = 1;
     result.scaling_factor_den[sid - 1] = 2 * result.scaling_factor_den[sid];
   }
   result.uses_reference_scaling = true;
   return result;
 }

 bool ScalabilityStructureKeySvc::TemporalLayerIsActive(int tid) const {
   if (tid >= num_temporal_layers_) {
     return false;
   }
   for (int sid = 0; sid < num_spatial_layers_; ++sid) {
     if (DecodeTargetIsActive(sid, tid)) {
       return true;
     }
   }
   return false;
 }

 DecodeTargetIndication ScalabilityStructureKeySvc::Dti(
     int sid,
     int tid,
     const LayerFrameConfig& config) {
   if (config.IsKeyframe() || config.Id() == kKey) {
     RTC_DCHECK_EQ(config.TemporalId(), 0);
     return sid < config.SpatialId() ? DecodeTargetIndication::kNotPresent
                                     : DecodeTargetIndication::kSwitch;
   }

   if (sid != config.SpatialId() || tid < config.TemporalId()) {
     return DecodeTargetIndication::kNotPresent;
   }
   if (tid == config.TemporalId() && tid > 0) {
     return DecodeTargetIndication::kDiscardable;
   }
   return DecodeTargetIndication::kSwitch;
 }

 std::vector<ScalableVideoController::LayerFrameConfig>
 ScalabilityStructureKeySvc::KeyframeConfig() {
   std::vector<LayerFrameConfig> configs;
   configs.reserve(num_spatial_layers_);
   absl::optional<int> spatial_dependency_buffer_id;
   spatial_id_is_enabled_.reset();
   // Disallow temporal references cross T0 on higher temporal layers.
   can_reference_t1_frame_for_spatial_id_.reset();
   for (int sid = 0; sid < num_spatial_layers_; ++sid) {
     if (!DecodeTargetIsActive(sid, /*tid=*/0)) {
       continue;
     }
     configs.emplace_back();
     ScalableVideoController::LayerFrameConfig& config = configs.back();
     config.Id(kKey).S(sid).T(0);

     if (spatial_dependency_buffer_id) {
       config.Reference(*spatial_dependency_buffer_id);
     } else {
       config.Keyframe();
     }
     config.Update(BufferIndex(sid, /*tid=*/0));

     spatial_id_is_enabled_.set(sid);
     spatial_dependency_buffer_id = BufferIndex(sid, /*tid=*/0);
   }
   return configs;
 }

 std::vector<ScalableVideoController::LayerFrameConfig>
 ScalabilityStructureKeySvc::T0Config() {
   std::vector<LayerFrameConfig> configs;
   configs.reserve(num_spatial_layers_);
   // Disallow temporal references cross T0 on higher temporal layers.
   can_reference_t1_frame_for_spatial_id_.reset();
   for (int sid = 0; sid < num_spatial_layers_; ++sid) {
     if (!DecodeTargetIsActive(sid, /*tid=*/0)) {
       spatial_id_is_enabled_.reset(sid);
       continue;
     }
     configs.emplace_back();
     configs.back().Id(kDeltaT0).S(sid).T(0).ReferenceAndUpdate(
         BufferIndex(sid, /*tid=*/0));
   }
   return configs;
 }

 std::vector<ScalableVideoController::LayerFrameConfig>
 ScalabilityStructureKeySvc::T1Config() {
   std::vector<LayerFrameConfig> configs;
   configs.reserve(num_spatial_layers_);
   for (int sid = 0; sid < num_spatial_layers_; ++sid) {
     if (!DecodeTargetIsActive(sid, /*tid=*/1)) {
       continue;
     }
     configs.emplace_back();
     ScalableVideoController::LayerFrameConfig& config = configs.back();
     config.Id(kDeltaT1).S(sid).T(1).Reference(BufferIndex(sid, /*tid=*/0));
     if (num_temporal_layers_ > 2) {
       config.Update(BufferIndex(sid, /*tid=*/1));
     }
   }
   return configs;
 }

 std::vector<ScalableVideoController::LayerFrameConfig>
 ScalabilityStructureKeySvc::T2Config(FramePattern pattern) {
   std::vector<LayerFrameConfig> configs;
   configs.reserve(num_spatial_layers_);
   for (int sid = 0; sid < num_spatial_layers_; ++sid) {
     if (!DecodeTargetIsActive(sid, /*tid=*/2)) {
       continue;
     }
     configs.emplace_back();
     ScalableVideoController::LayerFrameConfig& config = configs.back();
     config.Id(pattern).S(sid).T(2);
     if (can_reference_t1_frame_for_spatial_id_[sid]) {
       config.Reference(BufferIndex(sid, /*tid=*/1));
     } else {
       config.Reference(BufferIndex(sid, /*tid=*/0));
     }
   }
   return configs;
 }

 ScalabilityStructureKeySvc::FramePattern
 ScalabilityStructureKeySvc::NextPattern(FramePattern last_pattern) const {
   switch (last_pattern) {
     case kNone:
       return kKey;
     case kDeltaT2B:
       return kDeltaT0;
     case kDeltaT2A:
       if (TemporalLayerIsActive(1)) {
         return kDeltaT1;
       }
       return kDeltaT0;
     case kDeltaT1:
       if (TemporalLayerIsActive(2)) {
         return kDeltaT2B;
       }
       return kDeltaT0;
     case kDeltaT0:
     case kKey:
       if (TemporalLayerIsActive(2)) {
         return kDeltaT2A;
       }
       if (TemporalLayerIsActive(1)) {
         return kDeltaT1;
       }
       return kDeltaT0;
   }
   RTC_NOTREACHED();
   return kNone;
 }

 std::vector<ScalableVideoController::LayerFrameConfig>
 ScalabilityStructureKeySvc::NextFrameConfig(bool restart) {
   if (active_decode_targets_.none()) {
     last_pattern_ = kNone;
     return {};
   }

   if (restart) {
     last_pattern_ = kNone;
   }

   FramePattern current_pattern = NextPattern(last_pattern_);
   switch (current_pattern) {
     case kKey:
       return KeyframeConfig();
     case kDeltaT0:
       return T0Config();
     case kDeltaT1:
       return T1Config();
     case kDeltaT2A:
     case kDeltaT2B:
       return T2Config(current_pattern);
     case kNone:
       break;
   }
   RTC_NOTREACHED();
   return {};
 }

 GenericFrameInfo ScalabilityStructureKeySvc::OnEncodeDone(
     const LayerFrameConfig& config) {
   // When encoder drops all frames for a temporal unit, it is better to reuse
   // old temporal pattern rather than switch to next one, thus switch to next
   // pattern defered here from the `NextFrameConfig`.
   // In particular creating VP9 references rely on this behavior.
   last_pattern_ = static_cast<FramePattern>(config.Id());
   if (config.TemporalId() == 1) {
     can_reference_t1_frame_for_spatial_id_.set(config.SpatialId());
   }

   GenericFrameInfo frame_info;
   frame_info.spatial_id = config.SpatialId();
   frame_info.temporal_id = config.TemporalId();
   frame_info.encoder_buffers = config.Buffers();
   frame_info.decode_target_indications.reserve(num_spatial_layers_ *
                                                num_temporal_layers_);
   for (int sid = 0; sid < num_spatial_layers_; ++sid) {
     for (int tid = 0; tid < num_temporal_layers_; ++tid) {
       frame_info.decode_target_indications.push_back(Dti(sid, tid, config));
     }
   }
   frame_info.part_of_chain.assign(num_spatial_layers_, false);
   if (config.IsKeyframe() || config.Id() == kKey) {
     RTC_DCHECK_EQ(config.TemporalId(), 0);
     for (int sid = config.SpatialId(); sid < num_spatial_layers_; ++sid) {
       frame_info.part_of_chain[sid] = true;
     }
   } else if (config.TemporalId() == 0) {
     frame_info.part_of_chain[config.SpatialId()] = true;
   }
   frame_info.active_decode_targets = active_decode_targets_;
   return frame_info;
 }

 void ScalabilityStructureKeySvc::OnRatesUpdated(
     const VideoBitrateAllocation& bitrates) {
   for (int sid = 0; sid < num_spatial_layers_; ++sid) {
     // Enable/disable spatial layers independetely.
     bool active = bitrates.GetBitrate(sid, /*tid=*/0) > 0;
     SetDecodeTargetIsActive(sid, /*tid=*/0, active);
     if (!spatial_id_is_enabled_[sid] && active) {
       // Key frame is required to reenable any spatial layer.
       last_pattern_ = kNone;
     }

     for (int tid = 1; tid < num_temporal_layers_; ++tid) {
       // To enable temporal layer, require bitrates for lower temporal layers.
       active = active && bitrates.GetBitrate(sid, tid) > 0;
       SetDecodeTargetIsActive(sid, tid, active);
     }
   }
 }

 ScalabilityStructureL2T1Key::~ScalabilityStructureL2T1Key() = default;

 FrameDependencyStructure ScalabilityStructureL2T1Key::DependencyStructure()
     const {
   FrameDependencyStructure structure;
   structure.num_decode_targets = 2;
   structure.num_chains = 2;
   structure.decode_target_protected_by_chain = {0, 1};
   structure.templates.resize(4);
   structure.templates[0].S(0).Dtis("S-").ChainDiffs({2, 1}).FrameDiffs({2});
   structure.templates[1].S(0).Dtis("SS").ChainDiffs({0, 0});
   structure.templates[2].S(1).Dtis("-S").ChainDiffs({1, 2}).FrameDiffs({2});
   structure.templates[3].S(1).Dtis("-S").ChainDiffs({1, 1}).FrameDiffs({1});
   return structure;
 }

 ScalabilityStructureL2T2Key::~ScalabilityStructureL2T2Key() = default;

 FrameDependencyStructure ScalabilityStructureL2T2Key::DependencyStructure()
     const {
   FrameDependencyStructure structure;
   structure.num_decode_targets = 4;
   structure.num_chains = 2;
   structure.decode_target_protected_by_chain = {0, 0, 1, 1};
   structure.templates.resize(6);
   auto& templates = structure.templates;
   templates[0].S(0).T(0).Dtis("SSSS").ChainDiffs({0, 0});
   templates[1].S(0).T(0).Dtis("SS--").ChainDiffs({4, 3}).FrameDiffs({4});
   templates[2].S(0).T(1).Dtis("-D--").ChainDiffs({2, 1}).FrameDiffs({2});
   templates[3].S(1).T(0).Dtis("--SS").ChainDiffs({1, 1}).FrameDiffs({1});
   templates[4].S(1).T(0).Dtis("--SS").ChainDiffs({1, 4}).FrameDiffs({4});
   templates[5].S(1).T(1).Dtis("---D").ChainDiffs({3, 2}).FrameDiffs({2});
   return structure;
 }

 ScalabilityStructureL2T3Key::~ScalabilityStructureL2T3Key() = default;

 FrameDependencyStructure ScalabilityStructureL2T3Key::DependencyStructure()
     const {
   FrameDependencyStructure structure;
   structure.num_decode_targets = 6;
   structure.num_chains = 2;
   structure.decode_target_protected_by_chain = {0, 0, 0, 1, 1, 1};
   auto& templates = structure.templates;
   templates.resize(10);
   templates[0].S(0).T(0).Dtis("SSSSSS").ChainDiffs({0, 0});
   templates[1].S(0).T(0).Dtis("SSS---").ChainDiffs({8, 7}).FrameDiffs({8});
   templates[2].S(0).T(1).Dtis("-DS---").ChainDiffs({4, 3}).FrameDiffs({4});
   templates[3].S(0).T(2).Dtis("--D---").ChainDiffs({2, 1}).FrameDiffs({2});
   templates[4].S(0).T(2).Dtis("--D---").ChainDiffs({6, 5}).FrameDiffs({2});
   templates[5].S(1).T(0).Dtis("---SSS").ChainDiffs({1, 1}).FrameDiffs({1});
   templates[6].S(1).T(0).Dtis("---SSS").ChainDiffs({1, 8}).FrameDiffs({8});
   templates[7].S(1).T(1).Dtis("----DS").ChainDiffs({5, 4}).FrameDiffs({4});
   templates[8].S(1).T(2).Dtis("-----D").ChainDiffs({3, 2}).FrameDiffs({2});
   templates[9].S(1).T(2).Dtis("-----D").ChainDiffs({7, 6}).FrameDiffs({2});
   return structure;
 }

 ScalabilityStructureL3T3Key::~ScalabilityStructureL3T3Key() = default;

 FrameDependencyStructure ScalabilityStructureL3T3Key::DependencyStructure()
     const {
   FrameDependencyStructure structure;
   structure.num_decode_targets = 9;
   structure.num_chains = 3;
   structure.decode_target_protected_by_chain = {0, 0, 0, 1, 1, 1, 2, 2, 2};
   auto& t = structure.templates;
   t.resize(15);
   // Templates are shown in the order frames following them appear in the
   // stream, but in `structure.templates` array templates are sorted by
   // (`spatial_id`, `temporal_id`) since that is a dependency descriptor
   // requirement. Indexes are written in hex for nicer alignment.
   t[0x0].S(0).T(0).Dtis("SSSSSSSSS").ChainDiffs({0, 0, 0});
   t[0x5].S(1).T(0).Dtis("---SSSSSS").ChainDiffs({1, 1, 1}).FrameDiffs({1});
   t[0xA].S(2).T(0).Dtis("------SSS").ChainDiffs({2, 1, 1}).FrameDiffs({1});
   t[0x3].S(0).T(2).Dtis("--D------").ChainDiffs({3, 2, 1}).FrameDiffs({3});
   t[0x8].S(1).T(2).Dtis("-----D---").ChainDiffs({4, 3, 2}).FrameDiffs({3});
   t[0xD].S(2).T(2).Dtis("--------D").ChainDiffs({5, 4, 3}).FrameDiffs({3});
   t[0x2].S(0).T(1).Dtis("-DS------").ChainDiffs({6, 5, 4}).FrameDiffs({6});
   t[0x7].S(1).T(1).Dtis("----DS---").ChainDiffs({7, 6, 5}).FrameDiffs({6});
   t[0xC].S(2).T(1).Dtis("-------DS").ChainDiffs({8, 7, 6}).FrameDiffs({6});
   t[0x4].S(0).T(2).Dtis("--D------").ChainDiffs({9, 8, 7}).FrameDiffs({3});
   t[0x9].S(1).T(2).Dtis("-----D---").ChainDiffs({10, 9, 8}).FrameDiffs({3});
   t[0xE].S(2).T(2).Dtis("--------D").ChainDiffs({11, 10, 9}).FrameDiffs({3});
   t[0x1].S(0).T(0).Dtis("SSS------").ChainDiffs({12, 11, 10}).FrameDiffs({12});
   t[0x6].S(1).T(0).Dtis("---SSS---").ChainDiffs({1, 12, 11}).FrameDiffs({12});
   t[0xB].S(2).T(0).Dtis("------SSS").ChainDiffs({2, 1, 12}).FrameDiffs({12});
   return structure;
 }

 }  // namespace webrtc
	/*
	* Copyright (c) 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 "modules/video_coding/svc/scalability_structure_key_svc.h"

	#include <bitset>
	#include <utility>
	#include <vector>

	#include "absl/types/optional.h"
	#include "api/transport/rtp/dependency_descriptor.h"
	#include "api/video/video_bitrate_allocation.h"
	#include "common_video/generic_frame_descriptor/generic_frame_info.h"
	#include "modules/video_coding/svc/scalable_video_controller.h"
	#include "rtc_base/checks.h"
	#include "rtc_base/logging.h"

	namespace webrtc {

	constexpr int ScalabilityStructureKeySvc::kMaxNumSpatialLayers;
	constexpr int ScalabilityStructureKeySvc::kMaxNumTemporalLayers;

	ScalabilityStructureKeySvc::ScalabilityStructureKeySvc(int num_spatial_layers,
	int num_temporal_layers)
	: num_spatial_layers_(num_spatial_layers),
	num_temporal_layers_(num_temporal_layers),
	active_decode_targets_(
	(uint32_t{1} << (num_spatial_layers * num_temporal_layers)) - 1) {
	// There is no point to use this structure without spatial scalability.
	RTC_DCHECK_GT(num_spatial_layers, 1);
	RTC_DCHECK_LE(num_spatial_layers, kMaxNumSpatialLayers);
	RTC_DCHECK_LE(num_temporal_layers, kMaxNumTemporalLayers);
	}

	ScalabilityStructureKeySvc::~ScalabilityStructureKeySvc() = default;

	ScalableVideoController::StreamLayersConfig
	ScalabilityStructureKeySvc::StreamConfig() const {
	StreamLayersConfig result;
	result.num_spatial_layers = num_spatial_layers_;
	result.num_temporal_layers = num_temporal_layers_;
	result.scaling_factor_num[num_spatial_layers_ - 1] = 1;
	result.scaling_factor_den[num_spatial_layers_ - 1] = 1;
	for (int sid = num_spatial_layers_ - 1; sid > 0; --sid) {
	result.scaling_factor_num[sid - 1] = 1;
	result.scaling_factor_den[sid - 1] = 2 * result.scaling_factor_den[sid];
	}
	result.uses_reference_scaling = true;
	return result;
	}

	bool ScalabilityStructureKeySvc::TemporalLayerIsActive(int tid) const {
	if (tid >= num_temporal_layers_) {
	return false;
	}
	for (int sid = 0; sid < num_spatial_layers_; ++sid) {
	if (DecodeTargetIsActive(sid, tid)) {
	return true;
	}
	}
	return false;
	}

	DecodeTargetIndication ScalabilityStructureKeySvc::Dti(
	int sid,
	int tid,
	const LayerFrameConfig& config) {
	if (config.IsKeyframe() \|\| config.Id() == kKey) {
	RTC_DCHECK_EQ(config.TemporalId(), 0);
	return sid < config.SpatialId() ? DecodeTargetIndication::kNotPresent
	: DecodeTargetIndication::kSwitch;
	}

	if (sid != config.SpatialId() \|\| tid < config.TemporalId()) {
	return DecodeTargetIndication::kNotPresent;
	}
	if (tid == config.TemporalId() && tid > 0) {
	return DecodeTargetIndication::kDiscardable;
	}
	return DecodeTargetIndication::kSwitch;
	}

	std::vector<ScalableVideoController::LayerFrameConfig>
	ScalabilityStructureKeySvc::KeyframeConfig() {
	std::vector<LayerFrameConfig> configs;
	configs.reserve(num_spatial_layers_);
	absl::optional<int> spatial_dependency_buffer_id;
	spatial_id_is_enabled_.reset();
	// Disallow temporal references cross T0 on higher temporal layers.
	can_reference_t1_frame_for_spatial_id_.reset();
	for (int sid = 0; sid < num_spatial_layers_; ++sid) {
	if (!DecodeTargetIsActive(sid, /tid=/0)) {
	continue;
	}
	configs.emplace_back();
	ScalableVideoController::LayerFrameConfig& config = configs.back();
	config.Id(kKey).S(sid).T(0);

	if (spatial_dependency_buffer_id) {
	config.Reference(*spatial_dependency_buffer_id);
	} else {
	config.Keyframe();
	}
	config.Update(BufferIndex(sid, /tid=/0));

	spatial_id_is_enabled_.set(sid);
	spatial_dependency_buffer_id = BufferIndex(sid, /tid=/0);
	}
	return configs;
	}

	std::vector<ScalableVideoController::LayerFrameConfig>
	ScalabilityStructureKeySvc::T0Config() {
	std::vector<LayerFrameConfig> configs;
	configs.reserve(num_spatial_layers_);
	// Disallow temporal references cross T0 on higher temporal layers.
	can_reference_t1_frame_for_spatial_id_.reset();
	for (int sid = 0; sid < num_spatial_layers_; ++sid) {
	if (!DecodeTargetIsActive(sid, /tid=/0)) {
	spatial_id_is_enabled_.reset(sid);
	continue;
	}
	configs.emplace_back();
	configs.back().Id(kDeltaT0).S(sid).T(0).ReferenceAndUpdate(
	BufferIndex(sid, /tid=/0));
	}
	return configs;
	}

	std::vector<ScalableVideoController::LayerFrameConfig>
	ScalabilityStructureKeySvc::T1Config() {
	std::vector<LayerFrameConfig> configs;
	configs.reserve(num_spatial_layers_);
	for (int sid = 0; sid < num_spatial_layers_; ++sid) {
	if (!DecodeTargetIsActive(sid, /tid=/1)) {
	continue;
	}
	configs.emplace_back();
	ScalableVideoController::LayerFrameConfig& config = configs.back();
	config.Id(kDeltaT1).S(sid).T(1).Reference(BufferIndex(sid, /tid=/0));
	if (num_temporal_layers_ > 2) {
	config.Update(BufferIndex(sid, /tid=/1));
	}
	}
	return configs;
	}

	std::vector<ScalableVideoController::LayerFrameConfig>
	ScalabilityStructureKeySvc::T2Config(FramePattern pattern) {
	std::vector<LayerFrameConfig> configs;
	configs.reserve(num_spatial_layers_);
	for (int sid = 0; sid < num_spatial_layers_; ++sid) {
	if (!DecodeTargetIsActive(sid, /tid=/2)) {
	continue;
	}
	configs.emplace_back();
	ScalableVideoController::LayerFrameConfig& config = configs.back();
	config.Id(pattern).S(sid).T(2);
	if (can_reference_t1_frame_for_spatial_id_[sid]) {
	config.Reference(BufferIndex(sid, /tid=/1));
	} else {
	config.Reference(BufferIndex(sid, /tid=/0));
	}
	}
	return configs;
	}

	ScalabilityStructureKeySvc::FramePattern
	ScalabilityStructureKeySvc::NextPattern(FramePattern last_pattern) const {
	switch (last_pattern) {
	case kNone:
	return kKey;
	case kDeltaT2B:
	return kDeltaT0;
	case kDeltaT2A:
	if (TemporalLayerIsActive(1)) {
	return kDeltaT1;
	}
	return kDeltaT0;
	case kDeltaT1:
	if (TemporalLayerIsActive(2)) {
	return kDeltaT2B;
	}
	return kDeltaT0;
	case kDeltaT0:
	case kKey:
	if (TemporalLayerIsActive(2)) {
	return kDeltaT2A;
	}
	if (TemporalLayerIsActive(1)) {
	return kDeltaT1;
	}
	return kDeltaT0;
	}
	RTC_NOTREACHED();
	return kNone;
	}

	std::vector<ScalableVideoController::LayerFrameConfig>
	ScalabilityStructureKeySvc::NextFrameConfig(bool restart) {
	if (active_decode_targets_.none()) {
	last_pattern_ = kNone;
	return {};
	}

	if (restart) {
	last_pattern_ = kNone;
	}

	FramePattern current_pattern = NextPattern(last_pattern_);
	switch (current_pattern) {
	case kKey:
	return KeyframeConfig();
	case kDeltaT0:
	return T0Config();
	case kDeltaT1:
	return T1Config();
	case kDeltaT2A:
	case kDeltaT2B:
	return T2Config(current_pattern);
	case kNone:
	break;
	}
	RTC_NOTREACHED();
	return {};
	}

	GenericFrameInfo ScalabilityStructureKeySvc::OnEncodeDone(
	const LayerFrameConfig& config) {
	// When encoder drops all frames for a temporal unit, it is better to reuse
	// old temporal pattern rather than switch to next one, thus switch to next
	// pattern defered here from the `NextFrameConfig`.
	// In particular creating VP9 references rely on this behavior.
	last_pattern_ = static_cast<FramePattern>(config.Id());
	if (config.TemporalId() == 1) {
	can_reference_t1_frame_for_spatial_id_.set(config.SpatialId());
	}

	GenericFrameInfo frame_info;
	frame_info.spatial_id = config.SpatialId();
	frame_info.temporal_id = config.TemporalId();
	frame_info.encoder_buffers = config.Buffers();
	frame_info.decode_target_indications.reserve(num_spatial_layers_ *
	num_temporal_layers_);
	for (int sid = 0; sid < num_spatial_layers_; ++sid) {
	for (int tid = 0; tid < num_temporal_layers_; ++tid) {
	frame_info.decode_target_indications.push_back(Dti(sid, tid, config));
	}
	}
	frame_info.part_of_chain.assign(num_spatial_layers_, false);
	if (config.IsKeyframe() \|\| config.Id() == kKey) {
	RTC_DCHECK_EQ(config.TemporalId(), 0);
	for (int sid = config.SpatialId(); sid < num_spatial_layers_; ++sid) {
	frame_info.part_of_chain[sid] = true;
	}
	} else if (config.TemporalId() == 0) {
	frame_info.part_of_chain[config.SpatialId()] = true;
	}
	frame_info.active_decode_targets = active_decode_targets_;
	return frame_info;
	}

	void ScalabilityStructureKeySvc::OnRatesUpdated(
	const VideoBitrateAllocation& bitrates) {
	for (int sid = 0; sid < num_spatial_layers_; ++sid) {
	// Enable/disable spatial layers independetely.
	bool active = bitrates.GetBitrate(sid, /tid=/0) > 0;
	SetDecodeTargetIsActive(sid, /tid=/0, active);
	if (!spatial_id_is_enabled_[sid] && active) {
	// Key frame is required to reenable any spatial layer.
	last_pattern_ = kNone;
	}

	for (int tid = 1; tid < num_temporal_layers_; ++tid) {
	// To enable temporal layer, require bitrates for lower temporal layers.
	active = active && bitrates.GetBitrate(sid, tid) > 0;
	SetDecodeTargetIsActive(sid, tid, active);
	}
	}
	}

	ScalabilityStructureL2T1Key::~ScalabilityStructureL2T1Key() = default;

	FrameDependencyStructure ScalabilityStructureL2T1Key::DependencyStructure()
	const {
	FrameDependencyStructure structure;
	structure.num_decode_targets = 2;
	structure.num_chains = 2;
	structure.decode_target_protected_by_chain = {0, 1};
	structure.templates.resize(4);
	structure.templates[0].S(0).Dtis("S-").ChainDiffs({2, 1}).FrameDiffs({2});
	structure.templates[1].S(0).Dtis("SS").ChainDiffs({0, 0});
	structure.templates[2].S(1).Dtis("-S").ChainDiffs({1, 2}).FrameDiffs({2});
	structure.templates[3].S(1).Dtis("-S").ChainDiffs({1, 1}).FrameDiffs({1});
	return structure;
	}

	ScalabilityStructureL2T2Key::~ScalabilityStructureL2T2Key() = default;

	FrameDependencyStructure ScalabilityStructureL2T2Key::DependencyStructure()
	const {
	FrameDependencyStructure structure;
	structure.num_decode_targets = 4;
	structure.num_chains = 2;
	structure.decode_target_protected_by_chain = {0, 0, 1, 1};
	structure.templates.resize(6);
	auto& templates = structure.templates;
	templates[0].S(0).T(0).Dtis("SSSS").ChainDiffs({0, 0});
	templates[1].S(0).T(0).Dtis("SS--").ChainDiffs({4, 3}).FrameDiffs({4});
	templates[2].S(0).T(1).Dtis("-D--").ChainDiffs({2, 1}).FrameDiffs({2});
	templates[3].S(1).T(0).Dtis("--SS").ChainDiffs({1, 1}).FrameDiffs({1});
	templates[4].S(1).T(0).Dtis("--SS").ChainDiffs({1, 4}).FrameDiffs({4});
	templates[5].S(1).T(1).Dtis("---D").ChainDiffs({3, 2}).FrameDiffs({2});
	return structure;
	}

	ScalabilityStructureL2T3Key::~ScalabilityStructureL2T3Key() = default;

	FrameDependencyStructure ScalabilityStructureL2T3Key::DependencyStructure()
	const {
	FrameDependencyStructure structure;
	structure.num_decode_targets = 6;
	structure.num_chains = 2;
	structure.decode_target_protected_by_chain = {0, 0, 0, 1, 1, 1};
	auto& templates = structure.templates;
	templates.resize(10);
	templates[0].S(0).T(0).Dtis("SSSSSS").ChainDiffs({0, 0});
	templates[1].S(0).T(0).Dtis("SSS---").ChainDiffs({8, 7}).FrameDiffs({8});
	templates[2].S(0).T(1).Dtis("-DS---").ChainDiffs({4, 3}).FrameDiffs({4});
	templates[3].S(0).T(2).Dtis("--D---").ChainDiffs({2, 1}).FrameDiffs({2});
	templates[4].S(0).T(2).Dtis("--D---").ChainDiffs({6, 5}).FrameDiffs({2});
	templates[5].S(1).T(0).Dtis("---SSS").ChainDiffs({1, 1}).FrameDiffs({1});
	templates[6].S(1).T(0).Dtis("---SSS").ChainDiffs({1, 8}).FrameDiffs({8});
	templates[7].S(1).T(1).Dtis("----DS").ChainDiffs({5, 4}).FrameDiffs({4});
	templates[8].S(1).T(2).Dtis("-----D").ChainDiffs({3, 2}).FrameDiffs({2});
	templates[9].S(1).T(2).Dtis("-----D").ChainDiffs({7, 6}).FrameDiffs({2});
	return structure;
	}

	ScalabilityStructureL3T3Key::~ScalabilityStructureL3T3Key() = default;

	FrameDependencyStructure ScalabilityStructureL3T3Key::DependencyStructure()
	const {
	FrameDependencyStructure structure;
	structure.num_decode_targets = 9;
	structure.num_chains = 3;
	structure.decode_target_protected_by_chain = {0, 0, 0, 1, 1, 1, 2, 2, 2};
	auto& t = structure.templates;
	t.resize(15);
	// Templates are shown in the order frames following them appear in the
	// stream, but in `structure.templates` array templates are sorted by
	// (`spatial_id`, `temporal_id`) since that is a dependency descriptor
	// requirement. Indexes are written in hex for nicer alignment.
	t[0x0].S(0).T(0).Dtis("SSSSSSSSS").ChainDiffs({0, 0, 0});
	t[0x5].S(1).T(0).Dtis("---SSSSSS").ChainDiffs({1, 1, 1}).FrameDiffs({1});
	t[0xA].S(2).T(0).Dtis("------SSS").ChainDiffs({2, 1, 1}).FrameDiffs({1});
	t[0x3].S(0).T(2).Dtis("--D------").ChainDiffs({3, 2, 1}).FrameDiffs({3});
	t[0x8].S(1).T(2).Dtis("-----D---").ChainDiffs({4, 3, 2}).FrameDiffs({3});
	t[0xD].S(2).T(2).Dtis("--------D").ChainDiffs({5, 4, 3}).FrameDiffs({3});
	t[0x2].S(0).T(1).Dtis("-DS------").ChainDiffs({6, 5, 4}).FrameDiffs({6});
	t[0x7].S(1).T(1).Dtis("----DS---").ChainDiffs({7, 6, 5}).FrameDiffs({6});
	t[0xC].S(2).T(1).Dtis("-------DS").ChainDiffs({8, 7, 6}).FrameDiffs({6});
	t[0x4].S(0).T(2).Dtis("--D------").ChainDiffs({9, 8, 7}).FrameDiffs({3});
	t[0x9].S(1).T(2).Dtis("-----D---").ChainDiffs({10, 9, 8}).FrameDiffs({3});
	t[0xE].S(2).T(2).Dtis("--------D").ChainDiffs({11, 10, 9}).FrameDiffs({3});
	t[0x1].S(0).T(0).Dtis("SSS------").ChainDiffs({12, 11, 10}).FrameDiffs({12});
	t[0x6].S(1).T(0).Dtis("---SSS---").ChainDiffs({1, 12, 11}).FrameDiffs({12});
	t[0xB].S(2).T(0).Dtis("------SSS").ChainDiffs({2, 1, 12}).FrameDiffs({12});
	return structure;
	}

	} // namespace webrtc