modules/video_coding/rtp_frame_reference_finder.cc - src/webrtc - Git at Google

 /*
  *  Copyright (c) 2016 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 "webrtc/modules/video_coding/rtp_frame_reference_finder.h"

 #include <algorithm>
 #include <limits>

 #include "webrtc/modules/video_coding/frame_object.h"
 #include "webrtc/modules/video_coding/packet_buffer.h"
 #include "webrtc/rtc_base/checks.h"
 #include "webrtc/rtc_base/logging.h"

 namespace webrtc {
 namespace video_coding {

 RtpFrameReferenceFinder::RtpFrameReferenceFinder(
     OnCompleteFrameCallback* frame_callback)
     : last_picture_id_(-1),
       last_unwrap_(-1),
       current_ss_idx_(0),
       cleared_to_seq_num_(-1),
       frame_callback_(frame_callback) {}

 void RtpFrameReferenceFinder::ManageFrame(
     std::unique_ptr<RtpFrameObject> frame) {
   rtc::CritScope lock(&crit_);

   // If we have cleared past this frame, drop it.
   if (cleared_to_seq_num_ != -1 &&
       AheadOf<uint16_t>(cleared_to_seq_num_, frame->first_seq_num())) {
     return;
   }

   FrameDecision decision = ManageFrameInternal(frame.get());

   switch (decision) {
     case kStash:
       if (stashed_frames_.size() > kMaxStashedFrames)
         stashed_frames_.pop_back();
       stashed_frames_.push_front(std::move(frame));
       break;
     case kHandOff:
       frame_callback_->OnCompleteFrame(std::move(frame));
       RetryStashedFrames();
       break;
     case kDrop:
       break;
   }
 }

 void RtpFrameReferenceFinder::RetryStashedFrames() {
   bool complete_frame = false;
   do {
     complete_frame = false;
     for (auto frame_it = stashed_frames_.begin();
          frame_it != stashed_frames_.end();) {
       FrameDecision decision = ManageFrameInternal(frame_it->get());

       switch (decision) {
         case kStash:
           ++frame_it;
           break;
         case kHandOff:
           complete_frame = true;
           frame_callback_->OnCompleteFrame(std::move(*frame_it));
           FALLTHROUGH();
         case kDrop:
           frame_it = stashed_frames_.erase(frame_it);
       }
     }
   } while (complete_frame);
 }

 RtpFrameReferenceFinder::FrameDecision
 RtpFrameReferenceFinder::ManageFrameInternal(RtpFrameObject* frame) {
   switch (frame->codec_type()) {
     case kVideoCodecFlexfec:
     case kVideoCodecULPFEC:
     case kVideoCodecRED:
       RTC_NOTREACHED();
       break;
     case kVideoCodecVP8:
       return ManageFrameVp8(frame);
     case kVideoCodecVP9:
       return ManageFrameVp9(frame);
     // Since the EndToEndTests use kVicdeoCodecUnknow we treat it the same as
     // kVideoCodecGeneric.
     // TODO(philipel): Take a look at the EndToEndTests and see if maybe they
     //                 should be changed to use kVideoCodecGeneric instead.
     case kVideoCodecUnknown:
     case kVideoCodecH264:
     case kVideoCodecI420:
     case kVideoCodecGeneric:
       return ManageFrameGeneric(frame, kNoPictureId);
   }

   // If not all code paths return a value it makes the win compiler sad.
   RTC_NOTREACHED();
   return kDrop;
 }

 void RtpFrameReferenceFinder::PaddingReceived(uint16_t seq_num) {
   rtc::CritScope lock(&crit_);
   auto clean_padding_to =
       stashed_padding_.lower_bound(seq_num - kMaxPaddingAge);
   stashed_padding_.erase(stashed_padding_.begin(), clean_padding_to);
   stashed_padding_.insert(seq_num);
   UpdateLastPictureIdWithPadding(seq_num);
   RetryStashedFrames();
 }

 void RtpFrameReferenceFinder::ClearTo(uint16_t seq_num) {
   rtc::CritScope lock(&crit_);
   cleared_to_seq_num_ = seq_num;

   auto it = stashed_frames_.begin();
   while (it != stashed_frames_.end()) {
     if (AheadOf<uint16_t>(cleared_to_seq_num_, (*it)->first_seq_num())) {
       it = stashed_frames_.erase(it);
     } else {
       ++it;
     }
   }
 }

 void RtpFrameReferenceFinder::UpdateLastPictureIdWithPadding(uint16_t seq_num) {
   auto gop_seq_num_it = last_seq_num_gop_.upper_bound(seq_num);

   // If this padding packet "belongs" to a group of pictures that we don't track
   // anymore, do nothing.
   if (gop_seq_num_it == last_seq_num_gop_.begin())
     return;
   --gop_seq_num_it;

   // Calculate the next contiuous sequence number and search for it in
   // the padding packets we have stashed.
   uint16_t next_seq_num_with_padding = gop_seq_num_it->second.second + 1;
   auto padding_seq_num_it =
       stashed_padding_.lower_bound(next_seq_num_with_padding);

   // While there still are padding packets and those padding packets are
   // continuous, then advance the "last-picture-id-with-padding" and remove
   // the stashed padding packet.
   while (padding_seq_num_it != stashed_padding_.end() &&
          *padding_seq_num_it == next_seq_num_with_padding) {
     gop_seq_num_it->second.second = next_seq_num_with_padding;
     ++next_seq_num_with_padding;
     padding_seq_num_it = stashed_padding_.erase(padding_seq_num_it);
   }

   // In the case where the stream has been continuous without any new keyframes
   // for a while there is a risk that new frames will appear to be older than
   // the keyframe they belong to due to wrapping sequence number. In order
   // to prevent this we advance the picture id of the keyframe every so often.
   if (ForwardDiff(gop_seq_num_it->first, seq_num) > 10000) {
     RTC_DCHECK_EQ(1ul, last_seq_num_gop_.size());
     last_seq_num_gop_[seq_num] = gop_seq_num_it->second;
     last_seq_num_gop_.erase(gop_seq_num_it);
   }
 }

 RtpFrameReferenceFinder::FrameDecision
 RtpFrameReferenceFinder::ManageFrameGeneric(RtpFrameObject* frame,
                                             int picture_id) {
   // If |picture_id| is specified then we use that to set the frame references,
   // otherwise we use sequence number.
   if (picture_id != kNoPictureId) {
     if (last_unwrap_ == -1)
       last_unwrap_ = picture_id;

     frame->picture_id = unwrapper_.Unwrap(picture_id);
     frame->num_references = frame->frame_type() == kVideoFrameKey ? 0 : 1;
     frame->references[0] = frame->picture_id - 1;
     return kHandOff;
   }

   if (frame->frame_type() == kVideoFrameKey) {
     last_seq_num_gop_.insert(std::make_pair(
         frame->last_seq_num(),
         std::make_pair(frame->last_seq_num(), frame->last_seq_num())));
   }

   // We have received a frame but not yet a keyframe, stash this frame.
   if (last_seq_num_gop_.empty())
     return kStash;

   // Clean up info for old keyframes but make sure to keep info
   // for the last keyframe.
   auto clean_to = last_seq_num_gop_.lower_bound(frame->last_seq_num() - 100);
   for (auto it = last_seq_num_gop_.begin();
        it != clean_to && last_seq_num_gop_.size() > 1;) {
     it = last_seq_num_gop_.erase(it);
   }

   // Find the last sequence number of the last frame for the keyframe
   // that this frame indirectly references.
   auto seq_num_it = last_seq_num_gop_.upper_bound(frame->last_seq_num());
   if (seq_num_it == last_seq_num_gop_.begin()) {
     LOG(LS_WARNING) << "Generic frame with packet range ["
                     << frame->first_seq_num() << ", " << frame->last_seq_num()
                     << "] has no GoP, dropping frame.";
     return kDrop;
   }
   seq_num_it--;

   // Make sure the packet sequence numbers are continuous, otherwise stash
   // this frame.
   uint16_t last_picture_id_gop = seq_num_it->second.first;
   uint16_t last_picture_id_with_padding_gop = seq_num_it->second.second;
   if (frame->frame_type() == kVideoFrameDelta) {
     uint16_t prev_seq_num = frame->first_seq_num() - 1;

     if (prev_seq_num != last_picture_id_with_padding_gop)
       return kStash;
   }

   RTC_DCHECK(AheadOrAt(frame->last_seq_num(), seq_num_it->first));

   // Since keyframes can cause reordering we can't simply assign the
   // picture id according to some incrementing counter.
   frame->picture_id = frame->last_seq_num();
   frame->num_references = frame->frame_type() == kVideoFrameDelta;
   frame->references[0] = generic_unwrapper_.Unwrap(last_picture_id_gop);
   if (AheadOf<uint16_t>(frame->picture_id, last_picture_id_gop)) {
     seq_num_it->second.first = frame->picture_id;
     seq_num_it->second.second = frame->picture_id;
   }

   last_picture_id_ = frame->picture_id;
   UpdateLastPictureIdWithPadding(frame->picture_id);
   frame->picture_id = generic_unwrapper_.Unwrap(frame->picture_id);
   return kHandOff;
 }

 RtpFrameReferenceFinder::FrameDecision RtpFrameReferenceFinder::ManageFrameVp8(
     RtpFrameObject* frame) {
   rtc::Optional<RTPVideoTypeHeader> rtp_codec_header = frame->GetCodecHeader();
   if (!rtp_codec_header) {
     LOG(LS_WARNING) << "Failed to get codec header from frame, dropping frame.";
     return kDrop;
   }

   const RTPVideoHeaderVP8& codec_header = rtp_codec_header->VP8;

   if (codec_header.pictureId == kNoPictureId ||
       codec_header.temporalIdx == kNoTemporalIdx ||
       codec_header.tl0PicIdx == kNoTl0PicIdx) {
     return ManageFrameGeneric(std::move(frame), codec_header.pictureId);
   }

   frame->picture_id = codec_header.pictureId % kPicIdLength;

   if (last_unwrap_ == -1)
     last_unwrap_ = codec_header.pictureId;

   if (last_picture_id_ == -1)
     last_picture_id_ = frame->picture_id;

   // Find if there has been a gap in fully received frames and save the picture
   // id of those frames in |not_yet_received_frames_|.
   if (AheadOf<uint16_t, kPicIdLength>(frame->picture_id, last_picture_id_)) {
     do {
       last_picture_id_ = Add<kPicIdLength>(last_picture_id_, 1);
       not_yet_received_frames_.insert(last_picture_id_);
     } while (last_picture_id_ != frame->picture_id);
   }

   // Clean up info for base layers that are too old.
   uint8_t old_tl0_pic_idx = codec_header.tl0PicIdx - kMaxLayerInfo;
   auto clean_layer_info_to = layer_info_.lower_bound(old_tl0_pic_idx);
   layer_info_.erase(layer_info_.begin(), clean_layer_info_to);

   // Clean up info about not yet received frames that are too old.
   uint16_t old_picture_id =
       Subtract<kPicIdLength>(frame->picture_id, kMaxNotYetReceivedFrames);
   auto clean_frames_to = not_yet_received_frames_.lower_bound(old_picture_id);
   not_yet_received_frames_.erase(not_yet_received_frames_.begin(),
                                  clean_frames_to);

   if (frame->frame_type() == kVideoFrameKey) {
     frame->num_references = 0;
     layer_info_[codec_header.tl0PicIdx].fill(-1);
     UpdateLayerInfoVp8(frame);
     return kHandOff;
   }

   auto layer_info_it = layer_info_.find(codec_header.temporalIdx == 0
                                             ? codec_header.tl0PicIdx - 1
                                             : codec_header.tl0PicIdx);

   // If we don't have the base layer frame yet, stash this frame.
   if (layer_info_it == layer_info_.end())
     return kStash;

   // A non keyframe base layer frame has been received, copy the layer info
   // from the previous base layer frame and set a reference to the previous
   // base layer frame.
   if (codec_header.temporalIdx == 0) {
     layer_info_it =
         layer_info_
             .insert(make_pair(codec_header.tl0PicIdx, layer_info_it->second))
             .first;
     frame->num_references = 1;
     frame->references[0] = layer_info_it->second[0];
     UpdateLayerInfoVp8(frame);
     return kHandOff;
   }

   // Layer sync frame, this frame only references its base layer frame.
   if (codec_header.layerSync) {
     frame->num_references = 1;
     frame->references[0] = layer_info_it->second[0];

     UpdateLayerInfoVp8(frame);
     return kHandOff;
   }

   // Find all references for this frame.
   frame->num_references = 0;
   for (uint8_t layer = 0; layer <= codec_header.temporalIdx; ++layer) {
     // If we have not yet received a previous frame on this temporal layer,
     // stash this frame.
     if (layer_info_it->second[layer] == -1)
       return kStash;

     // If the last frame on this layer is ahead of this frame it means that
     // a layer sync frame has been received after this frame for the same
     // base layer frame, drop this frame.
     if (AheadOf<uint16_t, kPicIdLength>(layer_info_it->second[layer],
                                         frame->picture_id)) {
       return kDrop;
     }

     // If we have not yet received a frame between this frame and the referenced
     // frame then we have to wait for that frame to be completed first.
     auto not_received_frame_it =
         not_yet_received_frames_.upper_bound(layer_info_it->second[layer]);
     if (not_received_frame_it != not_yet_received_frames_.end() &&
         AheadOf<uint16_t, kPicIdLength>(frame->picture_id,
                                         *not_received_frame_it)) {
       return kStash;
     }

     if (!(AheadOf<uint16_t, kPicIdLength>(frame->picture_id,
                                           layer_info_it->second[layer]))) {
       LOG(LS_WARNING) << "Frame with picture id " << frame->picture_id
                       << " and packet range [" << frame->first_seq_num() << ", "
                       << frame->last_seq_num() << "] already received, "
                       << " dropping frame.";
       return kDrop;
     }

     ++frame->num_references;
     frame->references[layer] = layer_info_it->second[layer];
   }

   UpdateLayerInfoVp8(frame);
   return kHandOff;
 }

 void RtpFrameReferenceFinder::UpdateLayerInfoVp8(RtpFrameObject* frame) {
   rtc::Optional<RTPVideoTypeHeader> rtp_codec_header = frame->GetCodecHeader();
   RTC_DCHECK(rtp_codec_header);
   const RTPVideoHeaderVP8& codec_header = rtp_codec_header->VP8;
   uint8_t tl0_pic_idx = codec_header.tl0PicIdx;
   uint8_t temporal_index = codec_header.temporalIdx;
   auto layer_info_it = layer_info_.find(tl0_pic_idx);

   // Update this layer info and newer.
   while (layer_info_it != layer_info_.end()) {
     if (layer_info_it->second[temporal_index] != -1 &&
         AheadOf<uint16_t, kPicIdLength>(layer_info_it->second[temporal_index],
                                         frame->picture_id)) {
       // The frame was not newer, then no subsequent layer info have to be
       // update.
       break;
     }

     layer_info_it->second[codec_header.temporalIdx] = frame->picture_id;
     ++tl0_pic_idx;
     layer_info_it = layer_info_.find(tl0_pic_idx);
   }
   not_yet_received_frames_.erase(frame->picture_id);

   UnwrapPictureIds(frame);
 }

 RtpFrameReferenceFinder::FrameDecision RtpFrameReferenceFinder::ManageFrameVp9(
     RtpFrameObject* frame) {
   rtc::Optional<RTPVideoTypeHeader> rtp_codec_header = frame->GetCodecHeader();
   if (!rtp_codec_header) {
     LOG(LS_WARNING) << "Failed to get codec header from frame, dropping frame.";
     return kDrop;
   }

   const RTPVideoHeaderVP9& codec_header = rtp_codec_header->VP9;

   if (codec_header.picture_id == kNoPictureId ||
       codec_header.temporal_idx == kNoTemporalIdx) {
     return ManageFrameGeneric(std::move(frame), codec_header.picture_id);
   }

   frame->spatial_layer = codec_header.spatial_idx;
   frame->inter_layer_predicted = codec_header.inter_layer_predicted;
   frame->picture_id = codec_header.picture_id % kPicIdLength;

   if (last_unwrap_ == -1)
     last_unwrap_ = codec_header.picture_id;

   if (last_picture_id_ == -1)
     last_picture_id_ = frame->picture_id;

   if (codec_header.flexible_mode) {
     frame->num_references = codec_header.num_ref_pics;
     for (size_t i = 0; i < frame->num_references; ++i) {
       frame->references[i] =
           Subtract<1 << 16>(frame->picture_id, codec_header.pid_diff[i]);
     }

     UnwrapPictureIds(frame);
     return kHandOff;
   }

   if (codec_header.ss_data_available) {
     // Scalability structures can only be sent with tl0 frames.
     if (codec_header.temporal_idx != 0) {
       LOG(LS_WARNING) << "Received scalability structure on a non base layer"
                          " frame. Scalability structure ignored.";
     } else {
       current_ss_idx_ = Add<kMaxGofSaved>(current_ss_idx_, 1);
       scalability_structures_[current_ss_idx_] = codec_header.gof;
       scalability_structures_[current_ss_idx_].pid_start = frame->picture_id;

       GofInfo info(&scalability_structures_[current_ss_idx_],
                    frame->picture_id);
       gof_info_.insert(std::make_pair(codec_header.tl0_pic_idx, info));
     }
   }

   // Clean up info for base layers that are too old.
   uint8_t old_tl0_pic_idx = codec_header.tl0_pic_idx - kMaxGofSaved;
   auto clean_gof_info_to = gof_info_.lower_bound(old_tl0_pic_idx);
   gof_info_.erase(gof_info_.begin(), clean_gof_info_to);

   if (frame->frame_type() == kVideoFrameKey) {
     // When using GOF all keyframes must include the scalability structure.
     if (!codec_header.ss_data_available)
       LOG(LS_WARNING) << "Received keyframe without scalability structure";

     frame->num_references = 0;
     GofInfo info = gof_info_.find(codec_header.tl0_pic_idx)->second;
     FrameReceivedVp9(frame->picture_id, &info);
     UnwrapPictureIds(frame);
     return kHandOff;
   }

   auto gof_info_it = gof_info_.find(
       (codec_header.temporal_idx == 0 && !codec_header.ss_data_available)
           ? codec_header.tl0_pic_idx - 1
           : codec_header.tl0_pic_idx);

   // Gof info for this frame is not available yet, stash this frame.
   if (gof_info_it == gof_info_.end())
     return kStash;

   GofInfo* info = &gof_info_it->second;
   FrameReceivedVp9(frame->picture_id, info);

   // Make sure we don't miss any frame that could potentially have the
   // up switch flag set.
   if (MissingRequiredFrameVp9(frame->picture_id, *info))
     return kStash;

   if (codec_header.temporal_up_switch) {
     auto pid_tidx =
         std::make_pair(frame->picture_id, codec_header.temporal_idx);
     up_switch_.insert(pid_tidx);
   }

   // If this is a base layer frame that contains a scalability structure
   // then gof info has already been inserted earlier, so we only want to
   // insert if we haven't done so already.
   if (codec_header.temporal_idx == 0 && !codec_header.ss_data_available) {
     GofInfo new_info(info->gof, frame->picture_id);
     gof_info_.insert(std::make_pair(codec_header.tl0_pic_idx, new_info));
   }

   // Clean out old info about up switch frames.
   uint16_t old_picture_id = Subtract<kPicIdLength>(frame->picture_id, 50);
   auto up_switch_erase_to = up_switch_.lower_bound(old_picture_id);
   up_switch_.erase(up_switch_.begin(), up_switch_erase_to);

   size_t diff = ForwardDiff<uint16_t, kPicIdLength>(info->gof->pid_start,
                                                     frame->picture_id);
   size_t gof_idx = diff % info->gof->num_frames_in_gof;

   // Populate references according to the scalability structure.
   frame->num_references = info->gof->num_ref_pics[gof_idx];
   for (size_t i = 0; i < frame->num_references; ++i) {
     frame->references[i] = Subtract<kPicIdLength>(
         frame->picture_id, info->gof->pid_diff[gof_idx][i]);

     // If this is a reference to a frame earlier than the last up switch point,
     // then ignore this reference.
     if (UpSwitchInIntervalVp9(frame->picture_id, codec_header.temporal_idx,
                               frame->references[i])) {
       --frame->num_references;
     }
   }

   UnwrapPictureIds(frame);
   return kHandOff;
 }

 bool RtpFrameReferenceFinder::MissingRequiredFrameVp9(uint16_t picture_id,
                                                       const GofInfo& info) {
   size_t diff =
       ForwardDiff<uint16_t, kPicIdLength>(info.gof->pid_start, picture_id);
   size_t gof_idx = diff % info.gof->num_frames_in_gof;
   size_t temporal_idx = info.gof->temporal_idx[gof_idx];

   // For every reference this frame has, check if there is a frame missing in
   // the interval (|ref_pid|, |picture_id|) in any of the lower temporal
   // layers. If so, we are missing a required frame.
   uint8_t num_references = info.gof->num_ref_pics[gof_idx];
   for (size_t i = 0; i < num_references; ++i) {
     uint16_t ref_pid =
         Subtract<kPicIdLength>(picture_id, info.gof->pid_diff[gof_idx][i]);
     for (size_t l = 0; l < temporal_idx; ++l) {
       auto missing_frame_it = missing_frames_for_layer_[l].lower_bound(ref_pid);
       if (missing_frame_it != missing_frames_for_layer_[l].end() &&
           AheadOf<uint16_t, kPicIdLength>(picture_id, *missing_frame_it)) {
         return true;
       }
     }
   }
   return false;
 }

 void RtpFrameReferenceFinder::FrameReceivedVp9(uint16_t picture_id,
                                                GofInfo* info) {
   int last_picture_id = info->last_picture_id;

   // If there is a gap, find which temporal layer the missing frames
   // belong to and add the frame as missing for that temporal layer.
   // Otherwise, remove this frame from the set of missing frames.
   if (AheadOf<uint16_t, kPicIdLength>(picture_id, last_picture_id)) {
     size_t diff = ForwardDiff<uint16_t, kPicIdLength>(info->gof->pid_start,
                                                       last_picture_id);
     size_t gof_idx = diff % info->gof->num_frames_in_gof;

     last_picture_id = Add<kPicIdLength>(last_picture_id, 1);
     while (last_picture_id != picture_id) {
       ++gof_idx;
       RTC_DCHECK_NE(0ul, gof_idx % info->gof->num_frames_in_gof);
       size_t temporal_idx = info->gof->temporal_idx[gof_idx];
       missing_frames_for_layer_[temporal_idx].insert(last_picture_id);
       last_picture_id = Add<kPicIdLength>(last_picture_id, 1);
     }
     info->last_picture_id = last_picture_id;
   } else {
     size_t diff =
         ForwardDiff<uint16_t, kPicIdLength>(info->gof->pid_start, picture_id);
     size_t gof_idx = diff % info->gof->num_frames_in_gof;
     size_t temporal_idx = info->gof->temporal_idx[gof_idx];
     missing_frames_for_layer_[temporal_idx].erase(picture_id);
   }
 }

 bool RtpFrameReferenceFinder::UpSwitchInIntervalVp9(uint16_t picture_id,
                                                     uint8_t temporal_idx,
                                                     uint16_t pid_ref) {
   for (auto up_switch_it = up_switch_.upper_bound(pid_ref);
        up_switch_it != up_switch_.end() &&
        AheadOf<uint16_t, kPicIdLength>(picture_id, up_switch_it->first);
        ++up_switch_it) {
     if (up_switch_it->second < temporal_idx)
       return true;
   }

   return false;
 }

 void RtpFrameReferenceFinder::UnwrapPictureIds(RtpFrameObject* frame) {
   for (size_t i = 0; i < frame->num_references; ++i)
     frame->references[i] = unwrapper_.Unwrap(frame->references[i]);
   frame->picture_id = unwrapper_.Unwrap(frame->picture_id);
 }

 }  // namespace video_coding
 }  // namespace webrtc
	/*
	* Copyright (c) 2016 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 "webrtc/modules/video_coding/rtp_frame_reference_finder.h"

	#include <algorithm>
	#include <limits>

	#include "webrtc/modules/video_coding/frame_object.h"
	#include "webrtc/modules/video_coding/packet_buffer.h"
	#include "webrtc/rtc_base/checks.h"
	#include "webrtc/rtc_base/logging.h"

	namespace webrtc {
	namespace video_coding {

	RtpFrameReferenceFinder::RtpFrameReferenceFinder(
	OnCompleteFrameCallback* frame_callback)
	: last_picture_id_(-1),
	last_unwrap_(-1),
	current_ss_idx_(0),
	cleared_to_seq_num_(-1),
	frame_callback_(frame_callback) {}

	void RtpFrameReferenceFinder::ManageFrame(
	std::unique_ptr<RtpFrameObject> frame) {
	rtc::CritScope lock(&crit_);

	// If we have cleared past this frame, drop it.
	if (cleared_to_seq_num_ != -1 &&
	AheadOf<uint16_t>(cleared_to_seq_num_, frame->first_seq_num())) {
	return;
	}

	FrameDecision decision = ManageFrameInternal(frame.get());

	switch (decision) {
	case kStash:
	if (stashed_frames_.size() > kMaxStashedFrames)
	stashed_frames_.pop_back();
	stashed_frames_.push_front(std::move(frame));
	break;
	case kHandOff:
	frame_callback_->OnCompleteFrame(std::move(frame));
	RetryStashedFrames();
	break;
	case kDrop:
	break;
	}
	}

	void RtpFrameReferenceFinder::RetryStashedFrames() {
	bool complete_frame = false;
	do {
	complete_frame = false;
	for (auto frame_it = stashed_frames_.begin();
	frame_it != stashed_frames_.end();) {
	FrameDecision decision = ManageFrameInternal(frame_it->get());

	switch (decision) {
	case kStash:
	++frame_it;
	break;
	case kHandOff:
	complete_frame = true;
	frame_callback_->OnCompleteFrame(std::move(*frame_it));
	FALLTHROUGH();
	case kDrop:
	frame_it = stashed_frames_.erase(frame_it);
	}
	}
	} while (complete_frame);
	}

	RtpFrameReferenceFinder::FrameDecision
	RtpFrameReferenceFinder::ManageFrameInternal(RtpFrameObject* frame) {
	switch (frame->codec_type()) {
	case kVideoCodecFlexfec:
	case kVideoCodecULPFEC:
	case kVideoCodecRED:
	RTC_NOTREACHED();
	break;
	case kVideoCodecVP8:
	return ManageFrameVp8(frame);
	case kVideoCodecVP9:
	return ManageFrameVp9(frame);
	// Since the EndToEndTests use kVicdeoCodecUnknow we treat it the same as
	// kVideoCodecGeneric.
	// TODO(philipel): Take a look at the EndToEndTests and see if maybe they
	// should be changed to use kVideoCodecGeneric instead.
	case kVideoCodecUnknown:
	case kVideoCodecH264:
	case kVideoCodecI420:
	case kVideoCodecGeneric:
	return ManageFrameGeneric(frame, kNoPictureId);
	}

	// If not all code paths return a value it makes the win compiler sad.
	RTC_NOTREACHED();
	return kDrop;
	}

	void RtpFrameReferenceFinder::PaddingReceived(uint16_t seq_num) {
	rtc::CritScope lock(&crit_);
	auto clean_padding_to =
	stashed_padding_.lower_bound(seq_num - kMaxPaddingAge);
	stashed_padding_.erase(stashed_padding_.begin(), clean_padding_to);
	stashed_padding_.insert(seq_num);
	UpdateLastPictureIdWithPadding(seq_num);
	RetryStashedFrames();
	}

	void RtpFrameReferenceFinder::ClearTo(uint16_t seq_num) {
	rtc::CritScope lock(&crit_);
	cleared_to_seq_num_ = seq_num;

	auto it = stashed_frames_.begin();
	while (it != stashed_frames_.end()) {
	if (AheadOf<uint16_t>(cleared_to_seq_num_, (*it)->first_seq_num())) {
	it = stashed_frames_.erase(it);
	} else {
	++it;
	}
	}
	}

	void RtpFrameReferenceFinder::UpdateLastPictureIdWithPadding(uint16_t seq_num) {
	auto gop_seq_num_it = last_seq_num_gop_.upper_bound(seq_num);

	// If this padding packet "belongs" to a group of pictures that we don't track
	// anymore, do nothing.
	if (gop_seq_num_it == last_seq_num_gop_.begin())
	return;
	--gop_seq_num_it;

	// Calculate the next contiuous sequence number and search for it in
	// the padding packets we have stashed.
	uint16_t next_seq_num_with_padding = gop_seq_num_it->second.second + 1;
	auto padding_seq_num_it =
	stashed_padding_.lower_bound(next_seq_num_with_padding);

	// While there still are padding packets and those padding packets are
	// continuous, then advance the "last-picture-id-with-padding" and remove
	// the stashed padding packet.
	while (padding_seq_num_it != stashed_padding_.end() &&
	*padding_seq_num_it == next_seq_num_with_padding) {
	gop_seq_num_it->second.second = next_seq_num_with_padding;
	++next_seq_num_with_padding;
	padding_seq_num_it = stashed_padding_.erase(padding_seq_num_it);
	}

	// In the case where the stream has been continuous without any new keyframes
	// for a while there is a risk that new frames will appear to be older than
	// the keyframe they belong to due to wrapping sequence number. In order
	// to prevent this we advance the picture id of the keyframe every so often.
	if (ForwardDiff(gop_seq_num_it->first, seq_num) > 10000) {
	RTC_DCHECK_EQ(1ul, last_seq_num_gop_.size());
	last_seq_num_gop_[seq_num] = gop_seq_num_it->second;
	last_seq_num_gop_.erase(gop_seq_num_it);
	}
	}

	RtpFrameReferenceFinder::FrameDecision
	RtpFrameReferenceFinder::ManageFrameGeneric(RtpFrameObject* frame,
	int picture_id) {
	// If \|picture_id\| is specified then we use that to set the frame references,
	// otherwise we use sequence number.
	if (picture_id != kNoPictureId) {
	if (last_unwrap_ == -1)
	last_unwrap_ = picture_id;

	frame->picture_id = unwrapper_.Unwrap(picture_id);
	frame->num_references = frame->frame_type() == kVideoFrameKey ? 0 : 1;
	frame->references[0] = frame->picture_id - 1;
	return kHandOff;
	}

	if (frame->frame_type() == kVideoFrameKey) {
	last_seq_num_gop_.insert(std::make_pair(
	frame->last_seq_num(),
	std::make_pair(frame->last_seq_num(), frame->last_seq_num())));
	}

	// We have received a frame but not yet a keyframe, stash this frame.
	if (last_seq_num_gop_.empty())
	return kStash;

	// Clean up info for old keyframes but make sure to keep info
	// for the last keyframe.
	auto clean_to = last_seq_num_gop_.lower_bound(frame->last_seq_num() - 100);
	for (auto it = last_seq_num_gop_.begin();
	it != clean_to && last_seq_num_gop_.size() > 1;) {
	it = last_seq_num_gop_.erase(it);
	}

	// Find the last sequence number of the last frame for the keyframe
	// that this frame indirectly references.
	auto seq_num_it = last_seq_num_gop_.upper_bound(frame->last_seq_num());
	if (seq_num_it == last_seq_num_gop_.begin()) {
	LOG(LS_WARNING) << "Generic frame with packet range ["
	<< frame->first_seq_num() << ", " << frame->last_seq_num()
	<< "] has no GoP, dropping frame.";
	return kDrop;
	}
	seq_num_it--;

	// Make sure the packet sequence numbers are continuous, otherwise stash
	// this frame.
	uint16_t last_picture_id_gop = seq_num_it->second.first;
	uint16_t last_picture_id_with_padding_gop = seq_num_it->second.second;
	if (frame->frame_type() == kVideoFrameDelta) {
	uint16_t prev_seq_num = frame->first_seq_num() - 1;

	if (prev_seq_num != last_picture_id_with_padding_gop)
	return kStash;
	}

	RTC_DCHECK(AheadOrAt(frame->last_seq_num(), seq_num_it->first));

	// Since keyframes can cause reordering we can't simply assign the
	// picture id according to some incrementing counter.
	frame->picture_id = frame->last_seq_num();
	frame->num_references = frame->frame_type() == kVideoFrameDelta;
	frame->references[0] = generic_unwrapper_.Unwrap(last_picture_id_gop);
	if (AheadOf<uint16_t>(frame->picture_id, last_picture_id_gop)) {
	seq_num_it->second.first = frame->picture_id;
	seq_num_it->second.second = frame->picture_id;
	}

	last_picture_id_ = frame->picture_id;
	UpdateLastPictureIdWithPadding(frame->picture_id);
	frame->picture_id = generic_unwrapper_.Unwrap(frame->picture_id);
	return kHandOff;
	}

	RtpFrameReferenceFinder::FrameDecision RtpFrameReferenceFinder::ManageFrameVp8(
	RtpFrameObject* frame) {
	rtc::Optional<RTPVideoTypeHeader> rtp_codec_header = frame->GetCodecHeader();
	if (!rtp_codec_header) {
	LOG(LS_WARNING) << "Failed to get codec header from frame, dropping frame.";
	return kDrop;
	}

	const RTPVideoHeaderVP8& codec_header = rtp_codec_header->VP8;

	if (codec_header.pictureId == kNoPictureId \|\|
	codec_header.temporalIdx == kNoTemporalIdx \|\|
	codec_header.tl0PicIdx == kNoTl0PicIdx) {
	return ManageFrameGeneric(std::move(frame), codec_header.pictureId);
	}

	frame->picture_id = codec_header.pictureId % kPicIdLength;

	if (last_unwrap_ == -1)
	last_unwrap_ = codec_header.pictureId;

	if (last_picture_id_ == -1)
	last_picture_id_ = frame->picture_id;

	// Find if there has been a gap in fully received frames and save the picture
	// id of those frames in \|not_yet_received_frames_\|.
	if (AheadOf<uint16_t, kPicIdLength>(frame->picture_id, last_picture_id_)) {
	do {
	last_picture_id_ = Add<kPicIdLength>(last_picture_id_, 1);
	not_yet_received_frames_.insert(last_picture_id_);
	} while (last_picture_id_ != frame->picture_id);
	}

	// Clean up info for base layers that are too old.
	uint8_t old_tl0_pic_idx = codec_header.tl0PicIdx - kMaxLayerInfo;
	auto clean_layer_info_to = layer_info_.lower_bound(old_tl0_pic_idx);
	layer_info_.erase(layer_info_.begin(), clean_layer_info_to);

	// Clean up info about not yet received frames that are too old.
	uint16_t old_picture_id =
	Subtract<kPicIdLength>(frame->picture_id, kMaxNotYetReceivedFrames);
	auto clean_frames_to = not_yet_received_frames_.lower_bound(old_picture_id);
	not_yet_received_frames_.erase(not_yet_received_frames_.begin(),
	clean_frames_to);

	if (frame->frame_type() == kVideoFrameKey) {
	frame->num_references = 0;
	layer_info_[codec_header.tl0PicIdx].fill(-1);
	UpdateLayerInfoVp8(frame);
	return kHandOff;
	}

	auto layer_info_it = layer_info_.find(codec_header.temporalIdx == 0
	? codec_header.tl0PicIdx - 1
	: codec_header.tl0PicIdx);

	// If we don't have the base layer frame yet, stash this frame.
	if (layer_info_it == layer_info_.end())
	return kStash;

	// A non keyframe base layer frame has been received, copy the layer info
	// from the previous base layer frame and set a reference to the previous
	// base layer frame.
	if (codec_header.temporalIdx == 0) {
	layer_info_it =
	layer_info_
	.insert(make_pair(codec_header.tl0PicIdx, layer_info_it->second))
	.first;
	frame->num_references = 1;
	frame->references[0] = layer_info_it->second[0];
	UpdateLayerInfoVp8(frame);
	return kHandOff;
	}

	// Layer sync frame, this frame only references its base layer frame.
	if (codec_header.layerSync) {
	frame->num_references = 1;
	frame->references[0] = layer_info_it->second[0];

	UpdateLayerInfoVp8(frame);
	return kHandOff;
	}

	// Find all references for this frame.
	frame->num_references = 0;
	for (uint8_t layer = 0; layer <= codec_header.temporalIdx; ++layer) {
	// If we have not yet received a previous frame on this temporal layer,
	// stash this frame.
	if (layer_info_it->second[layer] == -1)
	return kStash;

	// If the last frame on this layer is ahead of this frame it means that
	// a layer sync frame has been received after this frame for the same
	// base layer frame, drop this frame.
	if (AheadOf<uint16_t, kPicIdLength>(layer_info_it->second[layer],
	frame->picture_id)) {
	return kDrop;
	}

	// If we have not yet received a frame between this frame and the referenced
	// frame then we have to wait for that frame to be completed first.
	auto not_received_frame_it =
	not_yet_received_frames_.upper_bound(layer_info_it->second[layer]);
	if (not_received_frame_it != not_yet_received_frames_.end() &&
	AheadOf<uint16_t, kPicIdLength>(frame->picture_id,
	*not_received_frame_it)) {
	return kStash;
	}

	if (!(AheadOf<uint16_t, kPicIdLength>(frame->picture_id,
	layer_info_it->second[layer]))) {
	LOG(LS_WARNING) << "Frame with picture id " << frame->picture_id
	<< " and packet range [" << frame->first_seq_num() << ", "
	<< frame->last_seq_num() << "] already received, "
	<< " dropping frame.";
	return kDrop;
	}

	++frame->num_references;
	frame->references[layer] = layer_info_it->second[layer];
	}

	UpdateLayerInfoVp8(frame);
	return kHandOff;
	}

	void RtpFrameReferenceFinder::UpdateLayerInfoVp8(RtpFrameObject* frame) {
	rtc::Optional<RTPVideoTypeHeader> rtp_codec_header = frame->GetCodecHeader();
	RTC_DCHECK(rtp_codec_header);
	const RTPVideoHeaderVP8& codec_header = rtp_codec_header->VP8;
	uint8_t tl0_pic_idx = codec_header.tl0PicIdx;
	uint8_t temporal_index = codec_header.temporalIdx;
	auto layer_info_it = layer_info_.find(tl0_pic_idx);

	// Update this layer info and newer.
	while (layer_info_it != layer_info_.end()) {
	if (layer_info_it->second[temporal_index] != -1 &&
	AheadOf<uint16_t, kPicIdLength>(layer_info_it->second[temporal_index],
	frame->picture_id)) {
	// The frame was not newer, then no subsequent layer info have to be
	// update.
	break;
	}

	layer_info_it->second[codec_header.temporalIdx] = frame->picture_id;
	++tl0_pic_idx;
	layer_info_it = layer_info_.find(tl0_pic_idx);
	}
	not_yet_received_frames_.erase(frame->picture_id);

	UnwrapPictureIds(frame);
	}

	RtpFrameReferenceFinder::FrameDecision RtpFrameReferenceFinder::ManageFrameVp9(
	RtpFrameObject* frame) {
	rtc::Optional<RTPVideoTypeHeader> rtp_codec_header = frame->GetCodecHeader();
	if (!rtp_codec_header) {
	LOG(LS_WARNING) << "Failed to get codec header from frame, dropping frame.";
	return kDrop;
	}

	const RTPVideoHeaderVP9& codec_header = rtp_codec_header->VP9;

	if (codec_header.picture_id == kNoPictureId \|\|
	codec_header.temporal_idx == kNoTemporalIdx) {
	return ManageFrameGeneric(std::move(frame), codec_header.picture_id);
	}

	frame->spatial_layer = codec_header.spatial_idx;
	frame->inter_layer_predicted = codec_header.inter_layer_predicted;
	frame->picture_id = codec_header.picture_id % kPicIdLength;

	if (last_unwrap_ == -1)
	last_unwrap_ = codec_header.picture_id;

	if (last_picture_id_ == -1)
	last_picture_id_ = frame->picture_id;

	if (codec_header.flexible_mode) {
	frame->num_references = codec_header.num_ref_pics;
	for (size_t i = 0; i < frame->num_references; ++i) {
	frame->references[i] =
	Subtract<1 << 16>(frame->picture_id, codec_header.pid_diff[i]);
	}

	UnwrapPictureIds(frame);
	return kHandOff;
	}

	if (codec_header.ss_data_available) {
	// Scalability structures can only be sent with tl0 frames.
	if (codec_header.temporal_idx != 0) {
	LOG(LS_WARNING) << "Received scalability structure on a non base layer"
	" frame. Scalability structure ignored.";
	} else {
	current_ss_idx_ = Add<kMaxGofSaved>(current_ss_idx_, 1);
	scalability_structures_[current_ss_idx_] = codec_header.gof;
	scalability_structures_[current_ss_idx_].pid_start = frame->picture_id;

	GofInfo info(&scalability_structures_[current_ss_idx_],
	frame->picture_id);
	gof_info_.insert(std::make_pair(codec_header.tl0_pic_idx, info));
	}
	}

	// Clean up info for base layers that are too old.
	uint8_t old_tl0_pic_idx = codec_header.tl0_pic_idx - kMaxGofSaved;
	auto clean_gof_info_to = gof_info_.lower_bound(old_tl0_pic_idx);
	gof_info_.erase(gof_info_.begin(), clean_gof_info_to);

	if (frame->frame_type() == kVideoFrameKey) {
	// When using GOF all keyframes must include the scalability structure.
	if (!codec_header.ss_data_available)
	LOG(LS_WARNING) << "Received keyframe without scalability structure";

	frame->num_references = 0;
	GofInfo info = gof_info_.find(codec_header.tl0_pic_idx)->second;
	FrameReceivedVp9(frame->picture_id, &info);
	UnwrapPictureIds(frame);
	return kHandOff;
	}

	auto gof_info_it = gof_info_.find(
	(codec_header.temporal_idx == 0 && !codec_header.ss_data_available)
	? codec_header.tl0_pic_idx - 1
	: codec_header.tl0_pic_idx);

	// Gof info for this frame is not available yet, stash this frame.
	if (gof_info_it == gof_info_.end())
	return kStash;

	GofInfo* info = &gof_info_it->second;
	FrameReceivedVp9(frame->picture_id, info);

	// Make sure we don't miss any frame that could potentially have the
	// up switch flag set.
	if (MissingRequiredFrameVp9(frame->picture_id, *info))
	return kStash;

	if (codec_header.temporal_up_switch) {
	auto pid_tidx =
	std::make_pair(frame->picture_id, codec_header.temporal_idx);
	up_switch_.insert(pid_tidx);
	}

	// If this is a base layer frame that contains a scalability structure
	// then gof info has already been inserted earlier, so we only want to
	// insert if we haven't done so already.
	if (codec_header.temporal_idx == 0 && !codec_header.ss_data_available) {
	GofInfo new_info(info->gof, frame->picture_id);
	gof_info_.insert(std::make_pair(codec_header.tl0_pic_idx, new_info));
	}

	// Clean out old info about up switch frames.
	uint16_t old_picture_id = Subtract<kPicIdLength>(frame->picture_id, 50);
	auto up_switch_erase_to = up_switch_.lower_bound(old_picture_id);
	up_switch_.erase(up_switch_.begin(), up_switch_erase_to);

	size_t diff = ForwardDiff<uint16_t, kPicIdLength>(info->gof->pid_start,
	frame->picture_id);
	size_t gof_idx = diff % info->gof->num_frames_in_gof;

	// Populate references according to the scalability structure.
	frame->num_references = info->gof->num_ref_pics[gof_idx];
	for (size_t i = 0; i < frame->num_references; ++i) {
	frame->references[i] = Subtract<kPicIdLength>(
	frame->picture_id, info->gof->pid_diff[gof_idx][i]);

	// If this is a reference to a frame earlier than the last up switch point,
	// then ignore this reference.
	if (UpSwitchInIntervalVp9(frame->picture_id, codec_header.temporal_idx,
	frame->references[i])) {
	--frame->num_references;
	}
	}

	UnwrapPictureIds(frame);
	return kHandOff;
	}

	bool RtpFrameReferenceFinder::MissingRequiredFrameVp9(uint16_t picture_id,
	const GofInfo& info) {
	size_t diff =
	ForwardDiff<uint16_t, kPicIdLength>(info.gof->pid_start, picture_id);
	size_t gof_idx = diff % info.gof->num_frames_in_gof;
	size_t temporal_idx = info.gof->temporal_idx[gof_idx];

	// For every reference this frame has, check if there is a frame missing in
	// the interval (\|ref_pid\|, \|picture_id\|) in any of the lower temporal
	// layers. If so, we are missing a required frame.
	uint8_t num_references = info.gof->num_ref_pics[gof_idx];
	for (size_t i = 0; i < num_references; ++i) {
	uint16_t ref_pid =
	Subtract<kPicIdLength>(picture_id, info.gof->pid_diff[gof_idx][i]);
	for (size_t l = 0; l < temporal_idx; ++l) {
	auto missing_frame_it = missing_frames_for_layer_[l].lower_bound(ref_pid);
	if (missing_frame_it != missing_frames_for_layer_[l].end() &&
	AheadOf<uint16_t, kPicIdLength>(picture_id, *missing_frame_it)) {
	return true;
	}
	}
	}
	return false;
	}

	void RtpFrameReferenceFinder::FrameReceivedVp9(uint16_t picture_id,
	GofInfo* info) {
	int last_picture_id = info->last_picture_id;

	// If there is a gap, find which temporal layer the missing frames
	// belong to and add the frame as missing for that temporal layer.
	// Otherwise, remove this frame from the set of missing frames.
	if (AheadOf<uint16_t, kPicIdLength>(picture_id, last_picture_id)) {
	size_t diff = ForwardDiff<uint16_t, kPicIdLength>(info->gof->pid_start,
	last_picture_id);
	size_t gof_idx = diff % info->gof->num_frames_in_gof;

	last_picture_id = Add<kPicIdLength>(last_picture_id, 1);
	while (last_picture_id != picture_id) {
	++gof_idx;
	RTC_DCHECK_NE(0ul, gof_idx % info->gof->num_frames_in_gof);
	size_t temporal_idx = info->gof->temporal_idx[gof_idx];
	missing_frames_for_layer_[temporal_idx].insert(last_picture_id);
	last_picture_id = Add<kPicIdLength>(last_picture_id, 1);
	}
	info->last_picture_id = last_picture_id;
	} else {
	size_t diff =
	ForwardDiff<uint16_t, kPicIdLength>(info->gof->pid_start, picture_id);
	size_t gof_idx = diff % info->gof->num_frames_in_gof;
	size_t temporal_idx = info->gof->temporal_idx[gof_idx];
	missing_frames_for_layer_[temporal_idx].erase(picture_id);
	}
	}

	bool RtpFrameReferenceFinder::UpSwitchInIntervalVp9(uint16_t picture_id,
	uint8_t temporal_idx,
	uint16_t pid_ref) {
	for (auto up_switch_it = up_switch_.upper_bound(pid_ref);
	up_switch_it != up_switch_.end() &&
	AheadOf<uint16_t, kPicIdLength>(picture_id, up_switch_it->first);
	++up_switch_it) {
	if (up_switch_it->second < temporal_idx)
	return true;
	}

	return false;
	}

	void RtpFrameReferenceFinder::UnwrapPictureIds(RtpFrameObject* frame) {
	for (size_t i = 0; i < frame->num_references; ++i)
	frame->references[i] = unwrapper_.Unwrap(frame->references[i]);
	frame->picture_id = unwrapper_.Unwrap(frame->picture_id);
	}

	} // namespace video_coding
	} // namespace webrtc