modules/video_coding/frame_object.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/frame_object.h"
 #include "webrtc/common_video/h264/h264_common.h"
 #include "webrtc/modules/video_coding/packet_buffer.h"
 #include "webrtc/rtc_base/checks.h"

 namespace webrtc {
 namespace video_coding {

 FrameObject::FrameObject()
     : picture_id(0),
       spatial_layer(0),
       timestamp(0),
       num_references(0),
       inter_layer_predicted(false) {}

 RtpFrameObject::RtpFrameObject(PacketBuffer* packet_buffer,
                                uint16_t first_seq_num,
                                uint16_t last_seq_num,
                                size_t frame_size,
                                int times_nacked,
                                int64_t received_time)
     : packet_buffer_(packet_buffer),
       first_seq_num_(first_seq_num),
       last_seq_num_(last_seq_num),
       timestamp_(0),
       received_time_(received_time),
       times_nacked_(times_nacked) {
   VCMPacket* first_packet = packet_buffer_->GetPacket(first_seq_num);
   RTC_CHECK(first_packet);

   // RtpFrameObject members
   frame_type_ = first_packet->frameType;
   codec_type_ = first_packet->codec;

   // TODO(philipel): Remove when encoded image is replaced by FrameObject.
   // VCMEncodedFrame members
   CopyCodecSpecific(&first_packet->video_header);
   _completeFrame = true;
   _payloadType = first_packet->payloadType;
   _timeStamp = first_packet->timestamp;
   ntp_time_ms_ = first_packet->ntp_time_ms_;

   // Setting frame's playout delays to the same values
   // as of the first packet's.
   SetPlayoutDelay(first_packet->video_header.playout_delay);

   // Since FFmpeg use an optimized bitstream reader that reads in chunks of
   // 32/64 bits we have to add at least that much padding to the buffer
   // to make sure the decoder doesn't read out of bounds.
   // NOTE! EncodedImage::_size is the size of the buffer (think capacity of
   //       an std::vector) and EncodedImage::_length is the actual size of
   //       the bitstream (think size of an std::vector).
   if (codec_type_ == kVideoCodecH264)
     _size = frame_size + EncodedImage::kBufferPaddingBytesH264;
   else
     _size = frame_size;

   _buffer = new uint8_t[_size];
   _length = frame_size;

   // For H264 frames we can't determine the frame type by just looking at the
   // first packet. Instead we consider the frame to be a keyframe if it
   // contains an IDR NALU.
   if (codec_type_ == kVideoCodecH264) {
     _frameType = kVideoFrameDelta;
     frame_type_ = kVideoFrameDelta;
     for (uint16_t seq_num = first_seq_num;
          seq_num != static_cast<uint16_t>(last_seq_num + 1) &&
          _frameType == kVideoFrameDelta;
          ++seq_num) {
       VCMPacket* packet = packet_buffer_->GetPacket(seq_num);
       RTC_CHECK(packet);
       const RTPVideoHeaderH264& header = packet->video_header.codecHeader.H264;
       for (size_t i = 0; i < header.nalus_length; ++i) {
         if (header.nalus[i].type == H264::NaluType::kIdr) {
           _frameType = kVideoFrameKey;
           frame_type_ = kVideoFrameKey;
           break;
         }
       }
     }
   } else {
     _frameType = first_packet->frameType;
     frame_type_ = first_packet->frameType;
   }

   bool bitstream_copied = GetBitstream(_buffer);
   RTC_DCHECK(bitstream_copied);
   _encodedWidth = first_packet->width;
   _encodedHeight = first_packet->height;

   // FrameObject members
   timestamp = first_packet->timestamp;

   VCMPacket* last_packet = packet_buffer_->GetPacket(last_seq_num);
   RTC_CHECK(last_packet);
   RTC_CHECK(last_packet->markerBit);
   // http://www.etsi.org/deliver/etsi_ts/126100_126199/126114/12.07.00_60/
   // ts_126114v120700p.pdf Section 7.4.5.
   // The MTSI client shall add the payload bytes as defined in this clause
   // onto the last RTP packet in each group of packets which make up a key
   // frame (I-frame or IDR frame in H.264 (AVC), or an IRAP picture in H.265
   // (HEVC)).
   rotation_ = last_packet->video_header.rotation;
   _rotation_set = true;
   content_type_ = last_packet->video_header.content_type;
   if (last_packet->video_header.video_timing.flags !=
       TimingFrameFlags::kInvalid) {
     // ntp_time_ms_ may be -1 if not estimated yet. This is not a problem,
     // as this will be dealt with at the time of reporting.
     timing_.encode_start_ms =
         ntp_time_ms_ +
         last_packet->video_header.video_timing.encode_start_delta_ms;
     timing_.encode_finish_ms =
         ntp_time_ms_ +
         last_packet->video_header.video_timing.encode_finish_delta_ms;
     timing_.packetization_finish_ms =
         ntp_time_ms_ +
         last_packet->video_header.video_timing.packetization_finish_delta_ms;
     timing_.pacer_exit_ms =
         ntp_time_ms_ +
         last_packet->video_header.video_timing.pacer_exit_delta_ms;
     timing_.network_timestamp_ms =
         ntp_time_ms_ +
         last_packet->video_header.video_timing.network_timstamp_delta_ms;
     timing_.network2_timestamp_ms =
         ntp_time_ms_ +
         last_packet->video_header.video_timing.network2_timstamp_delta_ms;

     timing_.receive_start_ms = first_packet->receive_time_ms;
     timing_.receive_finish_ms = last_packet->receive_time_ms;
   }
   timing_.flags = last_packet->video_header.video_timing.flags;
 }

 RtpFrameObject::~RtpFrameObject() {
   packet_buffer_->ReturnFrame(this);
 }

 uint16_t RtpFrameObject::first_seq_num() const {
   return first_seq_num_;
 }

 uint16_t RtpFrameObject::last_seq_num() const {
   return last_seq_num_;
 }

 int RtpFrameObject::times_nacked() const {
   return times_nacked_;
 }

 FrameType RtpFrameObject::frame_type() const {
   return frame_type_;
 }

 VideoCodecType RtpFrameObject::codec_type() const {
   return codec_type_;
 }

 bool RtpFrameObject::GetBitstream(uint8_t* destination) const {
   return packet_buffer_->GetBitstream(*this, destination);
 }

 uint32_t RtpFrameObject::Timestamp() const {
   return timestamp_;
 }

 int64_t RtpFrameObject::ReceivedTime() const {
   return received_time_;
 }

 int64_t RtpFrameObject::RenderTime() const {
   return _renderTimeMs;
 }

 bool RtpFrameObject::delayed_by_retransmission() const {
   return times_nacked() > 0;
 }

 rtc::Optional<RTPVideoTypeHeader> RtpFrameObject::GetCodecHeader() const {
   rtc::CritScope lock(&packet_buffer_->crit_);
   VCMPacket* packet = packet_buffer_->GetPacket(first_seq_num_);
   if (!packet)
     return rtc::Optional<RTPVideoTypeHeader>();
   return rtc::Optional<RTPVideoTypeHeader>(packet->video_header.codecHeader);
 }

 }  // 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/frame_object.h"
	#include "webrtc/common_video/h264/h264_common.h"
	#include "webrtc/modules/video_coding/packet_buffer.h"
	#include "webrtc/rtc_base/checks.h"

	namespace webrtc {
	namespace video_coding {

	FrameObject::FrameObject()
	: picture_id(0),
	spatial_layer(0),
	timestamp(0),
	num_references(0),
	inter_layer_predicted(false) {}

	RtpFrameObject::RtpFrameObject(PacketBuffer* packet_buffer,
	uint16_t first_seq_num,
	uint16_t last_seq_num,
	size_t frame_size,
	int times_nacked,
	int64_t received_time)
	: packet_buffer_(packet_buffer),
	first_seq_num_(first_seq_num),
	last_seq_num_(last_seq_num),
	timestamp_(0),
	received_time_(received_time),
	times_nacked_(times_nacked) {
	VCMPacket* first_packet = packet_buffer_->GetPacket(first_seq_num);
	RTC_CHECK(first_packet);

	// RtpFrameObject members
	frame_type_ = first_packet->frameType;
	codec_type_ = first_packet->codec;

	// TODO(philipel): Remove when encoded image is replaced by FrameObject.
	// VCMEncodedFrame members
	CopyCodecSpecific(&first_packet->video_header);
	_completeFrame = true;
	_payloadType = first_packet->payloadType;
	_timeStamp = first_packet->timestamp;
	ntp_time_ms_ = first_packet->ntp_time_ms_;

	// Setting frame's playout delays to the same values
	// as of the first packet's.
	SetPlayoutDelay(first_packet->video_header.playout_delay);

	// Since FFmpeg use an optimized bitstream reader that reads in chunks of
	// 32/64 bits we have to add at least that much padding to the buffer
	// to make sure the decoder doesn't read out of bounds.
	// NOTE! EncodedImage::_size is the size of the buffer (think capacity of
	// an std::vector) and EncodedImage::_length is the actual size of
	// the bitstream (think size of an std::vector).
	if (codec_type_ == kVideoCodecH264)
	_size = frame_size + EncodedImage::kBufferPaddingBytesH264;
	else
	_size = frame_size;

	_buffer = new uint8_t[_size];
	_length = frame_size;

	// For H264 frames we can't determine the frame type by just looking at the
	// first packet. Instead we consider the frame to be a keyframe if it
	// contains an IDR NALU.
	if (codec_type_ == kVideoCodecH264) {
	_frameType = kVideoFrameDelta;
	frame_type_ = kVideoFrameDelta;
	for (uint16_t seq_num = first_seq_num;
	seq_num != static_cast<uint16_t>(last_seq_num + 1) &&
	_frameType == kVideoFrameDelta;
	++seq_num) {
	VCMPacket* packet = packet_buffer_->GetPacket(seq_num);
	RTC_CHECK(packet);
	const RTPVideoHeaderH264& header = packet->video_header.codecHeader.H264;
	for (size_t i = 0; i < header.nalus_length; ++i) {
	if (header.nalus[i].type == H264::NaluType::kIdr) {
	_frameType = kVideoFrameKey;
	frame_type_ = kVideoFrameKey;
	break;
	}
	}
	}
	} else {
	_frameType = first_packet->frameType;
	frame_type_ = first_packet->frameType;
	}

	bool bitstream_copied = GetBitstream(_buffer);
	RTC_DCHECK(bitstream_copied);
	_encodedWidth = first_packet->width;
	_encodedHeight = first_packet->height;

	// FrameObject members
	timestamp = first_packet->timestamp;

	VCMPacket* last_packet = packet_buffer_->GetPacket(last_seq_num);
	RTC_CHECK(last_packet);
	RTC_CHECK(last_packet->markerBit);
	// http://www.etsi.org/deliver/etsi_ts/126100_126199/126114/12.07.00_60/
	// ts_126114v120700p.pdf Section 7.4.5.
	// The MTSI client shall add the payload bytes as defined in this clause
	// onto the last RTP packet in each group of packets which make up a key
	// frame (I-frame or IDR frame in H.264 (AVC), or an IRAP picture in H.265
	// (HEVC)).
	rotation_ = last_packet->video_header.rotation;
	_rotation_set = true;
	content_type_ = last_packet->video_header.content_type;
	if (last_packet->video_header.video_timing.flags !=
	TimingFrameFlags::kInvalid) {
	// ntp_time_ms_ may be -1 if not estimated yet. This is not a problem,
	// as this will be dealt with at the time of reporting.
	timing_.encode_start_ms =
	ntp_time_ms_ +
	last_packet->video_header.video_timing.encode_start_delta_ms;
	timing_.encode_finish_ms =
	ntp_time_ms_ +
	last_packet->video_header.video_timing.encode_finish_delta_ms;
	timing_.packetization_finish_ms =
	ntp_time_ms_ +
	last_packet->video_header.video_timing.packetization_finish_delta_ms;
	timing_.pacer_exit_ms =
	ntp_time_ms_ +
	last_packet->video_header.video_timing.pacer_exit_delta_ms;
	timing_.network_timestamp_ms =
	ntp_time_ms_ +
	last_packet->video_header.video_timing.network_timstamp_delta_ms;
	timing_.network2_timestamp_ms =
	ntp_time_ms_ +
	last_packet->video_header.video_timing.network2_timstamp_delta_ms;

	timing_.receive_start_ms = first_packet->receive_time_ms;
	timing_.receive_finish_ms = last_packet->receive_time_ms;
	}
	timing_.flags = last_packet->video_header.video_timing.flags;
	}

	RtpFrameObject::~RtpFrameObject() {
	packet_buffer_->ReturnFrame(this);
	}

	uint16_t RtpFrameObject::first_seq_num() const {
	return first_seq_num_;
	}

	uint16_t RtpFrameObject::last_seq_num() const {
	return last_seq_num_;
	}

	int RtpFrameObject::times_nacked() const {
	return times_nacked_;
	}

	FrameType RtpFrameObject::frame_type() const {
	return frame_type_;
	}

	VideoCodecType RtpFrameObject::codec_type() const {
	return codec_type_;
	}

	bool RtpFrameObject::GetBitstream(uint8_t* destination) const {
	return packet_buffer_->GetBitstream(*this, destination);
	}

	uint32_t RtpFrameObject::Timestamp() const {
	return timestamp_;
	}

	int64_t RtpFrameObject::ReceivedTime() const {
	return received_time_;
	}

	int64_t RtpFrameObject::RenderTime() const {
	return _renderTimeMs;
	}

	bool RtpFrameObject::delayed_by_retransmission() const {
	return times_nacked() > 0;
	}

	rtc::Optional<RTPVideoTypeHeader> RtpFrameObject::GetCodecHeader() const {
	rtc::CritScope lock(&packet_buffer_->crit_);
	VCMPacket* packet = packet_buffer_->GetPacket(first_seq_num_);
	if (!packet)
	return rtc::Optional<RTPVideoTypeHeader>();
	return rtc::Optional<RTPVideoTypeHeader>(packet->video_header.codecHeader);
	}

	} // namespace video_coding
	} // namespace webrtc