modules/video_coding/decoding_state.cc - src - Git at Google

 /*
  *  Copyright (c) 2011 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/decoding_state.h"

 #include "common_video/h264/h264_common.h"
 #include "modules/include/module_common_types_public.h"
 #include "modules/video_coding/frame_buffer.h"
 #include "modules/video_coding/jitter_buffer_common.h"
 #include "modules/video_coding/packet.h"
 #include "rtc_base/logging.h"

 namespace webrtc {

 VCMDecodingState::VCMDecodingState()
     : sequence_num_(0),
       time_stamp_(0),
       picture_id_(kNoPictureId),
       temporal_id_(kNoTemporalIdx),
       tl0_pic_id_(kNoTl0PicIdx),
       full_sync_(true),
       in_initial_state_(true) {
   memset(frame_decoded_, 0, sizeof(frame_decoded_));
 }

 VCMDecodingState::~VCMDecodingState() {}

 void VCMDecodingState::Reset() {
   // TODO(mikhal): Verify - not always would want to reset the sync
   sequence_num_ = 0;
   time_stamp_ = 0;
   picture_id_ = kNoPictureId;
   temporal_id_ = kNoTemporalIdx;
   tl0_pic_id_ = kNoTl0PicIdx;
   full_sync_ = true;
   in_initial_state_ = true;
   memset(frame_decoded_, 0, sizeof(frame_decoded_));
   received_sps_.clear();
   received_pps_.clear();
 }

 uint32_t VCMDecodingState::time_stamp() const {
   return time_stamp_;
 }

 uint16_t VCMDecodingState::sequence_num() const {
   return sequence_num_;
 }

 bool VCMDecodingState::IsOldFrame(const VCMFrameBuffer* frame) const {
   RTC_DCHECK(frame);
   if (in_initial_state_)
     return false;
   return !IsNewerTimestamp(frame->Timestamp(), time_stamp_);
 }

 bool VCMDecodingState::IsOldPacket(const VCMPacket* packet) const {
   RTC_DCHECK(packet);
   if (in_initial_state_)
     return false;
   return !IsNewerTimestamp(packet->timestamp, time_stamp_);
 }

 void VCMDecodingState::SetState(const VCMFrameBuffer* frame) {
   RTC_DCHECK(frame);
   RTC_CHECK_GE(frame->GetHighSeqNum(), 0);
   if (!UsingFlexibleMode(frame))
     UpdateSyncState(frame);
   sequence_num_ = static_cast<uint16_t>(frame->GetHighSeqNum());
   time_stamp_ = frame->Timestamp();
   picture_id_ = frame->PictureId();
   temporal_id_ = frame->TemporalId();
   tl0_pic_id_ = frame->Tl0PicId();

   for (const NaluInfo& nalu : frame->GetNaluInfos()) {
     if (nalu.type == H264::NaluType::kPps) {
       if (nalu.pps_id < 0) {
         RTC_LOG(LS_WARNING) << "Received pps without pps id.";
       } else if (nalu.sps_id < 0) {
         RTC_LOG(LS_WARNING) << "Received pps without sps id.";
       } else {
         received_pps_[nalu.pps_id] = nalu.sps_id;
       }
     } else if (nalu.type == H264::NaluType::kSps) {
       if (nalu.sps_id < 0) {
         RTC_LOG(LS_WARNING) << "Received sps without sps id.";
       } else {
         received_sps_.insert(nalu.sps_id);
       }
     }
   }

   if (UsingFlexibleMode(frame)) {
     uint16_t frame_index = picture_id_ % kFrameDecodedLength;
     if (in_initial_state_) {
       frame_decoded_cleared_to_ = frame_index;
     } else if (frame->FrameType() == VideoFrameType::kVideoFrameKey) {
       memset(frame_decoded_, 0, sizeof(frame_decoded_));
       frame_decoded_cleared_to_ = frame_index;
     } else {
       if (AheadOfFramesDecodedClearedTo(frame_index)) {
         while (frame_decoded_cleared_to_ != frame_index) {
           frame_decoded_cleared_to_ =
               (frame_decoded_cleared_to_ + 1) % kFrameDecodedLength;
           frame_decoded_[frame_decoded_cleared_to_] = false;
         }
       }
     }
     frame_decoded_[frame_index] = true;
   }

   in_initial_state_ = false;
 }

 void VCMDecodingState::CopyFrom(const VCMDecodingState& state) {
   sequence_num_ = state.sequence_num_;
   time_stamp_ = state.time_stamp_;
   picture_id_ = state.picture_id_;
   temporal_id_ = state.temporal_id_;
   tl0_pic_id_ = state.tl0_pic_id_;
   full_sync_ = state.full_sync_;
   in_initial_state_ = state.in_initial_state_;
   frame_decoded_cleared_to_ = state.frame_decoded_cleared_to_;
   memcpy(frame_decoded_, state.frame_decoded_, sizeof(frame_decoded_));
   received_sps_ = state.received_sps_;
   received_pps_ = state.received_pps_;
 }

 bool VCMDecodingState::UpdateEmptyFrame(const VCMFrameBuffer* frame) {
   bool empty_packet = frame->GetHighSeqNum() == frame->GetLowSeqNum();
   if (in_initial_state_ && empty_packet) {
     // Drop empty packets as long as we are in the initial state.
     return true;
   }
   if ((empty_packet && ContinuousSeqNum(frame->GetHighSeqNum())) ||
       ContinuousFrame(frame)) {
     // Continuous empty packets or continuous frames can be dropped if we
     // advance the sequence number.
     sequence_num_ = frame->GetHighSeqNum();
     time_stamp_ = frame->Timestamp();
     return true;
   }
   return false;
 }

 void VCMDecodingState::UpdateOldPacket(const VCMPacket* packet) {
   RTC_DCHECK(packet);
   if (packet->timestamp == time_stamp_) {
     // Late packet belonging to the last decoded frame - make sure we update the
     // last decoded sequence number.
     sequence_num_ = LatestSequenceNumber(packet->seqNum, sequence_num_);
   }
 }

 void VCMDecodingState::SetSeqNum(uint16_t new_seq_num) {
   sequence_num_ = new_seq_num;
 }

 bool VCMDecodingState::in_initial_state() const {
   return in_initial_state_;
 }

 bool VCMDecodingState::full_sync() const {
   return full_sync_;
 }

 void VCMDecodingState::UpdateSyncState(const VCMFrameBuffer* frame) {
   if (in_initial_state_)
     return;
   if (frame->TemporalId() == kNoTemporalIdx ||
       frame->Tl0PicId() == kNoTl0PicIdx) {
     full_sync_ = true;
   } else if (frame->FrameType() == VideoFrameType::kVideoFrameKey ||
              frame->LayerSync()) {
     full_sync_ = true;
   } else if (full_sync_) {
     // Verify that we are still in sync.
     // Sync will be broken if continuity is true for layers but not for the
     // other methods (PictureId and SeqNum).
     if (UsingPictureId(frame)) {
       // First check for a valid tl0PicId.
       if (frame->Tl0PicId() - tl0_pic_id_ > 1) {
         full_sync_ = false;
       } else {
         full_sync_ = ContinuousPictureId(frame->PictureId());
       }
     } else {
       full_sync_ =
           ContinuousSeqNum(static_cast<uint16_t>(frame->GetLowSeqNum()));
     }
   }
 }

 bool VCMDecodingState::ContinuousFrame(const VCMFrameBuffer* frame) const {
   // Check continuity based on the following hierarchy:
   // - Temporal layers (stop here if out of sync).
   // - Picture Id when available.
   // - Sequence numbers.
   // Return true when in initial state.
   // Note that when a method is not applicable it will return false.
   RTC_DCHECK(frame);
   // A key frame is always considered continuous as it doesn't refer to any
   // frames and therefore won't introduce any errors even if prior frames are
   // missing.
   if (frame->FrameType() == VideoFrameType::kVideoFrameKey &&
       HaveSpsAndPps(frame->GetNaluInfos())) {
     return true;
   }
   // When in the initial state we always require a key frame to start decoding.
   if (in_initial_state_)
     return false;
   if (ContinuousLayer(frame->TemporalId(), frame->Tl0PicId()))
     return true;
   // tl0picId is either not used, or should remain unchanged.
   if (frame->Tl0PicId() != tl0_pic_id_)
     return false;
   // Base layers are not continuous or temporal layers are inactive.
   // In the presence of temporal layers, check for Picture ID/sequence number
   // continuity if sync can be restored by this frame.
   if (!full_sync_ && !frame->LayerSync())
     return false;
   if (UsingPictureId(frame)) {
     if (UsingFlexibleMode(frame)) {
       return ContinuousFrameRefs(frame);
     } else {
       return ContinuousPictureId(frame->PictureId());
     }
   } else {
     return ContinuousSeqNum(static_cast<uint16_t>(frame->GetLowSeqNum())) &&
            HaveSpsAndPps(frame->GetNaluInfos());
   }
 }

 bool VCMDecodingState::ContinuousPictureId(int picture_id) const {
   int next_picture_id = picture_id_ + 1;
   if (picture_id < picture_id_) {
     // Wrap
     if (picture_id_ >= 0x80) {
       // 15 bits used for picture id
       return ((next_picture_id & 0x7FFF) == picture_id);
     } else {
       // 7 bits used for picture id
       return ((next_picture_id & 0x7F) == picture_id);
     }
   }
   // No wrap
   return (next_picture_id == picture_id);
 }

 bool VCMDecodingState::ContinuousSeqNum(uint16_t seq_num) const {
   return seq_num == static_cast<uint16_t>(sequence_num_ + 1);
 }

 bool VCMDecodingState::ContinuousLayer(int temporal_id, int tl0_pic_id) const {
   // First, check if applicable.
   if (temporal_id == kNoTemporalIdx || tl0_pic_id == kNoTl0PicIdx)
     return false;
   // If this is the first frame to use temporal layers, make sure we start
   // from base.
   else if (tl0_pic_id_ == kNoTl0PicIdx && temporal_id_ == kNoTemporalIdx &&
            temporal_id == 0)
     return true;

   // Current implementation: Look for base layer continuity.
   if (temporal_id != 0)
     return false;
   return (static_cast<uint8_t>(tl0_pic_id_ + 1) == tl0_pic_id);
 }

 bool VCMDecodingState::ContinuousFrameRefs(const VCMFrameBuffer* frame) const {
   uint8_t num_refs = frame->CodecSpecific()->codecSpecific.VP9.num_ref_pics;
   for (uint8_t r = 0; r < num_refs; ++r) {
     uint16_t frame_ref = frame->PictureId() -
                          frame->CodecSpecific()->codecSpecific.VP9.p_diff[r];
     uint16_t frame_index = frame_ref % kFrameDecodedLength;
     if (AheadOfFramesDecodedClearedTo(frame_index) ||
         !frame_decoded_[frame_index]) {
       return false;
     }
   }
   return true;
 }

 bool VCMDecodingState::UsingPictureId(const VCMFrameBuffer* frame) const {
   return (frame->PictureId() != kNoPictureId && picture_id_ != kNoPictureId);
 }

 bool VCMDecodingState::UsingFlexibleMode(const VCMFrameBuffer* frame) const {
   bool is_flexible_mode =
       frame->CodecSpecific()->codecType == kVideoCodecVP9 &&
       frame->CodecSpecific()->codecSpecific.VP9.flexible_mode;
   if (is_flexible_mode && frame->PictureId() == kNoPictureId) {
     RTC_LOG(LS_WARNING) << "Frame is marked as using flexible mode but no"
                            "picture id is set.";
     return false;
   }
   return is_flexible_mode;
 }

 // TODO(philipel): change how check work, this check practially
 // limits the max p_diff to 64.
 bool VCMDecodingState::AheadOfFramesDecodedClearedTo(uint16_t index) const {
   // No way of knowing for sure if we are actually ahead of
   // frame_decoded_cleared_to_. We just make the assumption
   // that we are not trying to reference back to a very old
   // index, but instead are referencing a newer index.
   uint16_t diff =
       index > frame_decoded_cleared_to_
           ? kFrameDecodedLength - (index - frame_decoded_cleared_to_)
           : frame_decoded_cleared_to_ - index;
   return diff > kFrameDecodedLength / 2;
 }

 bool VCMDecodingState::HaveSpsAndPps(const std::vector<NaluInfo>& nalus) const {
   std::set<int> new_sps;
   std::map<int, int> new_pps;
   for (const NaluInfo& nalu : nalus) {
     // Check if this nalu actually contains sps/pps information or dependencies.
     if (nalu.sps_id == -1 && nalu.pps_id == -1)
       continue;
     switch (nalu.type) {
       case H264::NaluType::kPps:
         if (nalu.pps_id < 0) {
           RTC_LOG(LS_WARNING) << "Received pps without pps id.";
         } else if (nalu.sps_id < 0) {
           RTC_LOG(LS_WARNING) << "Received pps without sps id.";
         } else {
           new_pps[nalu.pps_id] = nalu.sps_id;
         }
         break;
       case H264::NaluType::kSps:
         if (nalu.sps_id < 0) {
           RTC_LOG(LS_WARNING) << "Received sps without sps id.";
         } else {
           new_sps.insert(nalu.sps_id);
         }
         break;
       default: {
         int needed_sps = -1;
         auto pps_it = new_pps.find(nalu.pps_id);
         if (pps_it != new_pps.end()) {
           needed_sps = pps_it->second;
         } else {
           auto pps_it2 = received_pps_.find(nalu.pps_id);
           if (pps_it2 == received_pps_.end()) {
             return false;
           }
           needed_sps = pps_it2->second;
         }
         if (new_sps.find(needed_sps) == new_sps.end() &&
             received_sps_.find(needed_sps) == received_sps_.end()) {
           return false;
         }
         break;
       }
     }
   }
   return true;
 }

 }  // namespace webrtc
	/*
	* Copyright (c) 2011 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/decoding_state.h"

	#include "common_video/h264/h264_common.h"
	#include "modules/include/module_common_types_public.h"
	#include "modules/video_coding/frame_buffer.h"
	#include "modules/video_coding/jitter_buffer_common.h"
	#include "modules/video_coding/packet.h"
	#include "rtc_base/logging.h"

	namespace webrtc {

	VCMDecodingState::VCMDecodingState()
	: sequence_num_(0),
	time_stamp_(0),
	picture_id_(kNoPictureId),
	temporal_id_(kNoTemporalIdx),
	tl0_pic_id_(kNoTl0PicIdx),
	full_sync_(true),
	in_initial_state_(true) {
	memset(frame_decoded_, 0, sizeof(frame_decoded_));
	}

	VCMDecodingState::~VCMDecodingState() {}

	void VCMDecodingState::Reset() {
	// TODO(mikhal): Verify - not always would want to reset the sync
	sequence_num_ = 0;
	time_stamp_ = 0;
	picture_id_ = kNoPictureId;
	temporal_id_ = kNoTemporalIdx;
	tl0_pic_id_ = kNoTl0PicIdx;
	full_sync_ = true;
	in_initial_state_ = true;
	memset(frame_decoded_, 0, sizeof(frame_decoded_));
	received_sps_.clear();
	received_pps_.clear();
	}

	uint32_t VCMDecodingState::time_stamp() const {
	return time_stamp_;
	}

	uint16_t VCMDecodingState::sequence_num() const {
	return sequence_num_;
	}

	bool VCMDecodingState::IsOldFrame(const VCMFrameBuffer* frame) const {
	RTC_DCHECK(frame);
	if (in_initial_state_)
	return false;
	return !IsNewerTimestamp(frame->Timestamp(), time_stamp_);
	}

	bool VCMDecodingState::IsOldPacket(const VCMPacket* packet) const {
	RTC_DCHECK(packet);
	if (in_initial_state_)
	return false;
	return !IsNewerTimestamp(packet->timestamp, time_stamp_);
	}

	void VCMDecodingState::SetState(const VCMFrameBuffer* frame) {
	RTC_DCHECK(frame);
	RTC_CHECK_GE(frame->GetHighSeqNum(), 0);
	if (!UsingFlexibleMode(frame))
	UpdateSyncState(frame);
	sequence_num_ = static_cast<uint16_t>(frame->GetHighSeqNum());
	time_stamp_ = frame->Timestamp();
	picture_id_ = frame->PictureId();
	temporal_id_ = frame->TemporalId();
	tl0_pic_id_ = frame->Tl0PicId();

	for (const NaluInfo& nalu : frame->GetNaluInfos()) {
	if (nalu.type == H264::NaluType::kPps) {
	if (nalu.pps_id < 0) {
	RTC_LOG(LS_WARNING) << "Received pps without pps id.";
	} else if (nalu.sps_id < 0) {
	RTC_LOG(LS_WARNING) << "Received pps without sps id.";
	} else {
	received_pps_[nalu.pps_id] = nalu.sps_id;
	}
	} else if (nalu.type == H264::NaluType::kSps) {
	if (nalu.sps_id < 0) {
	RTC_LOG(LS_WARNING) << "Received sps without sps id.";
	} else {
	received_sps_.insert(nalu.sps_id);
	}
	}
	}

	if (UsingFlexibleMode(frame)) {
	uint16_t frame_index = picture_id_ % kFrameDecodedLength;
	if (in_initial_state_) {
	frame_decoded_cleared_to_ = frame_index;
	} else if (frame->FrameType() == VideoFrameType::kVideoFrameKey) {
	memset(frame_decoded_, 0, sizeof(frame_decoded_));
	frame_decoded_cleared_to_ = frame_index;
	} else {
	if (AheadOfFramesDecodedClearedTo(frame_index)) {
	while (frame_decoded_cleared_to_ != frame_index) {
	frame_decoded_cleared_to_ =
	(frame_decoded_cleared_to_ + 1) % kFrameDecodedLength;
	frame_decoded_[frame_decoded_cleared_to_] = false;
	}
	}
	}
	frame_decoded_[frame_index] = true;
	}

	in_initial_state_ = false;
	}

	void VCMDecodingState::CopyFrom(const VCMDecodingState& state) {
	sequence_num_ = state.sequence_num_;
	time_stamp_ = state.time_stamp_;
	picture_id_ = state.picture_id_;
	temporal_id_ = state.temporal_id_;
	tl0_pic_id_ = state.tl0_pic_id_;
	full_sync_ = state.full_sync_;
	in_initial_state_ = state.in_initial_state_;
	frame_decoded_cleared_to_ = state.frame_decoded_cleared_to_;
	memcpy(frame_decoded_, state.frame_decoded_, sizeof(frame_decoded_));
	received_sps_ = state.received_sps_;
	received_pps_ = state.received_pps_;
	}

	bool VCMDecodingState::UpdateEmptyFrame(const VCMFrameBuffer* frame) {
	bool empty_packet = frame->GetHighSeqNum() == frame->GetLowSeqNum();
	if (in_initial_state_ && empty_packet) {
	// Drop empty packets as long as we are in the initial state.
	return true;
	}
	if ((empty_packet && ContinuousSeqNum(frame->GetHighSeqNum())) \|\|
	ContinuousFrame(frame)) {
	// Continuous empty packets or continuous frames can be dropped if we
	// advance the sequence number.
	sequence_num_ = frame->GetHighSeqNum();
	time_stamp_ = frame->Timestamp();
	return true;
	}
	return false;
	}

	void VCMDecodingState::UpdateOldPacket(const VCMPacket* packet) {
	RTC_DCHECK(packet);
	if (packet->timestamp == time_stamp_) {
	// Late packet belonging to the last decoded frame - make sure we update the
	// last decoded sequence number.
	sequence_num_ = LatestSequenceNumber(packet->seqNum, sequence_num_);
	}
	}

	void VCMDecodingState::SetSeqNum(uint16_t new_seq_num) {
	sequence_num_ = new_seq_num;
	}

	bool VCMDecodingState::in_initial_state() const {
	return in_initial_state_;
	}

	bool VCMDecodingState::full_sync() const {
	return full_sync_;
	}

	void VCMDecodingState::UpdateSyncState(const VCMFrameBuffer* frame) {
	if (in_initial_state_)
	return;
	if (frame->TemporalId() == kNoTemporalIdx \|\|
	frame->Tl0PicId() == kNoTl0PicIdx) {
	full_sync_ = true;
	} else if (frame->FrameType() == VideoFrameType::kVideoFrameKey \|\|
	frame->LayerSync()) {
	full_sync_ = true;
	} else if (full_sync_) {
	// Verify that we are still in sync.
	// Sync will be broken if continuity is true for layers but not for the
	// other methods (PictureId and SeqNum).
	if (UsingPictureId(frame)) {
	// First check for a valid tl0PicId.
	if (frame->Tl0PicId() - tl0_pic_id_ > 1) {
	full_sync_ = false;
	} else {
	full_sync_ = ContinuousPictureId(frame->PictureId());
	}
	} else {
	full_sync_ =
	ContinuousSeqNum(static_cast<uint16_t>(frame->GetLowSeqNum()));
	}
	}
	}

	bool VCMDecodingState::ContinuousFrame(const VCMFrameBuffer* frame) const {
	// Check continuity based on the following hierarchy:
	// - Temporal layers (stop here if out of sync).
	// - Picture Id when available.
	// - Sequence numbers.
	// Return true when in initial state.
	// Note that when a method is not applicable it will return false.
	RTC_DCHECK(frame);
	// A key frame is always considered continuous as it doesn't refer to any
	// frames and therefore won't introduce any errors even if prior frames are
	// missing.
	if (frame->FrameType() == VideoFrameType::kVideoFrameKey &&
	HaveSpsAndPps(frame->GetNaluInfos())) {
	return true;
	}
	// When in the initial state we always require a key frame to start decoding.
	if (in_initial_state_)
	return false;
	if (ContinuousLayer(frame->TemporalId(), frame->Tl0PicId()))
	return true;
	// tl0picId is either not used, or should remain unchanged.
	if (frame->Tl0PicId() != tl0_pic_id_)
	return false;
	// Base layers are not continuous or temporal layers are inactive.
	// In the presence of temporal layers, check for Picture ID/sequence number
	// continuity if sync can be restored by this frame.
	if (!full_sync_ && !frame->LayerSync())
	return false;
	if (UsingPictureId(frame)) {
	if (UsingFlexibleMode(frame)) {
	return ContinuousFrameRefs(frame);
	} else {
	return ContinuousPictureId(frame->PictureId());
	}
	} else {
	return ContinuousSeqNum(static_cast<uint16_t>(frame->GetLowSeqNum())) &&
	HaveSpsAndPps(frame->GetNaluInfos());
	}
	}

	bool VCMDecodingState::ContinuousPictureId(int picture_id) const {
	int next_picture_id = picture_id_ + 1;
	if (picture_id < picture_id_) {
	// Wrap
	if (picture_id_ >= 0x80) {
	// 15 bits used for picture id
	return ((next_picture_id & 0x7FFF) == picture_id);
	} else {
	// 7 bits used for picture id
	return ((next_picture_id & 0x7F) == picture_id);
	}
	}
	// No wrap
	return (next_picture_id == picture_id);
	}

	bool VCMDecodingState::ContinuousSeqNum(uint16_t seq_num) const {
	return seq_num == static_cast<uint16_t>(sequence_num_ + 1);
	}

	bool VCMDecodingState::ContinuousLayer(int temporal_id, int tl0_pic_id) const {
	// First, check if applicable.
	if (temporal_id == kNoTemporalIdx \|\| tl0_pic_id == kNoTl0PicIdx)
	return false;
	// If this is the first frame to use temporal layers, make sure we start
	// from base.
	else if (tl0_pic_id_ == kNoTl0PicIdx && temporal_id_ == kNoTemporalIdx &&
	temporal_id == 0)
	return true;

	// Current implementation: Look for base layer continuity.
	if (temporal_id != 0)
	return false;
	return (static_cast<uint8_t>(tl0_pic_id_ + 1) == tl0_pic_id);
	}

	bool VCMDecodingState::ContinuousFrameRefs(const VCMFrameBuffer* frame) const {
	uint8_t num_refs = frame->CodecSpecific()->codecSpecific.VP9.num_ref_pics;
	for (uint8_t r = 0; r < num_refs; ++r) {
	uint16_t frame_ref = frame->PictureId() -
	frame->CodecSpecific()->codecSpecific.VP9.p_diff[r];
	uint16_t frame_index = frame_ref % kFrameDecodedLength;
	if (AheadOfFramesDecodedClearedTo(frame_index) \|\|
	!frame_decoded_[frame_index]) {
	return false;
	}
	}
	return true;
	}

	bool VCMDecodingState::UsingPictureId(const VCMFrameBuffer* frame) const {
	return (frame->PictureId() != kNoPictureId && picture_id_ != kNoPictureId);
	}

	bool VCMDecodingState::UsingFlexibleMode(const VCMFrameBuffer* frame) const {
	bool is_flexible_mode =
	frame->CodecSpecific()->codecType == kVideoCodecVP9 &&
	frame->CodecSpecific()->codecSpecific.VP9.flexible_mode;
	if (is_flexible_mode && frame->PictureId() == kNoPictureId) {
	RTC_LOG(LS_WARNING) << "Frame is marked as using flexible mode but no"
	"picture id is set.";
	return false;
	}
	return is_flexible_mode;
	}

	// TODO(philipel): change how check work, this check practially
	// limits the max p_diff to 64.
	bool VCMDecodingState::AheadOfFramesDecodedClearedTo(uint16_t index) const {
	// No way of knowing for sure if we are actually ahead of
	// frame_decoded_cleared_to_. We just make the assumption
	// that we are not trying to reference back to a very old
	// index, but instead are referencing a newer index.
	uint16_t diff =
	index > frame_decoded_cleared_to_
	? kFrameDecodedLength - (index - frame_decoded_cleared_to_)
	: frame_decoded_cleared_to_ - index;
	return diff > kFrameDecodedLength / 2;
	}

	bool VCMDecodingState::HaveSpsAndPps(const std::vector<NaluInfo>& nalus) const {
	std::set<int> new_sps;
	std::map<int, int> new_pps;
	for (const NaluInfo& nalu : nalus) {
	// Check if this nalu actually contains sps/pps information or dependencies.
	if (nalu.sps_id == -1 && nalu.pps_id == -1)
	continue;
	switch (nalu.type) {
	case H264::NaluType::kPps:
	if (nalu.pps_id < 0) {
	RTC_LOG(LS_WARNING) << "Received pps without pps id.";
	} else if (nalu.sps_id < 0) {
	RTC_LOG(LS_WARNING) << "Received pps without sps id.";
	} else {
	new_pps[nalu.pps_id] = nalu.sps_id;
	}
	break;
	case H264::NaluType::kSps:
	if (nalu.sps_id < 0) {
	RTC_LOG(LS_WARNING) << "Received sps without sps id.";
	} else {
	new_sps.insert(nalu.sps_id);
	}
	break;
	default: {
	int needed_sps = -1;
	auto pps_it = new_pps.find(nalu.pps_id);
	if (pps_it != new_pps.end()) {
	needed_sps = pps_it->second;
	} else {
	auto pps_it2 = received_pps_.find(nalu.pps_id);
	if (pps_it2 == received_pps_.end()) {
	return false;
	}
	needed_sps = pps_it2->second;
	}
	if (new_sps.find(needed_sps) == new_sps.end() &&
	received_sps_.find(needed_sps) == received_sps_.end()) {
	return false;
	}
	break;
	}
	}
	}
	return true;
	}

	} // namespace webrtc