webrtc/config.h - src - Git at Google

 /*
  *  Copyright (c) 2013 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.
  */

 // TODO(pbos): Move Config from common.h to here.

 #ifndef WEBRTC_CONFIG_H_
 #define WEBRTC_CONFIG_H_

 #include <string>
 #include <vector>

 #include "webrtc/common_types.h"
 #include "webrtc/typedefs.h"

 namespace webrtc {

 // Settings for NACK, see RFC 4585 for details.
 struct NackConfig {
   NackConfig() : rtp_history_ms(0) {}
   // Send side: the time RTP packets are stored for retransmissions.
   // Receive side: the time the receiver is prepared to wait for
   // retransmissions.
   // Set to '0' to disable.
   int rtp_history_ms;
 };

 // Settings for forward error correction, see RFC 5109 for details. Set the
 // payload types to '-1' to disable.
 struct FecConfig {
   FecConfig()
       : ulpfec_payload_type(-1),
         red_payload_type(-1),
         red_rtx_payload_type(-1) {}
   std::string ToString() const;
   // Payload type used for ULPFEC packets.
   int ulpfec_payload_type;

   // Payload type used for RED packets.
   int red_payload_type;

   // RTX payload type for RED payload.
   int red_rtx_payload_type;
 };

 // RTP header extension to use for the video stream, see RFC 5285.
 struct RtpExtension {
   RtpExtension(const std::string& name, int id) : name(name), id(id) {}
   std::string ToString() const;
   static bool IsSupportedForAudio(const std::string& name);
   static bool IsSupportedForVideo(const std::string& name);

   static const char* kTOffset;
   static const char* kAbsSendTime;
   static const char* kVideoRotation;
   static const char* kAudioLevel;
   static const char* kTransportSequenceNumber;
   std::string name;
   int id;
 };

 struct VideoStream {
   VideoStream();
   ~VideoStream();
   std::string ToString() const;

   size_t width;
   size_t height;
   int max_framerate;

   int min_bitrate_bps;
   int target_bitrate_bps;
   int max_bitrate_bps;

   int max_qp;

   // Bitrate thresholds for enabling additional temporal layers. Since these are
   // thresholds in between layers, we have one additional layer. One threshold
   // gives two temporal layers, one below the threshold and one above, two give
   // three, and so on.
   // The VideoEncoder may redistribute bitrates over the temporal layers so a
   // bitrate threshold of 100k and an estimate of 105k does not imply that we
   // get 100k in one temporal layer and 5k in the other, just that the bitrate
   // in the first temporal layer should not exceed 100k.
   // TODO(pbos): Apart from a special case for two-layer screencast these
   // thresholds are not propagated to the VideoEncoder. To be implemented.
   std::vector<int> temporal_layer_thresholds_bps;
 };

 struct VideoEncoderConfig {
   enum class ContentType {
     kRealtimeVideo,
     kScreen,
   };

   VideoEncoderConfig();
   ~VideoEncoderConfig();
   std::string ToString() const;

   std::vector<VideoStream> streams;
   ContentType content_type;
   void* encoder_specific_settings;

   // Padding will be used up to this bitrate regardless of the bitrate produced
   // by the encoder. Padding above what's actually produced by the encoder helps
   // maintaining a higher bitrate estimate. Padding will however not be sent
   // unless the estimated bandwidth indicates that the link can handle it.
   int min_transmit_bitrate_bps;
 };

 // Controls the capacity of the packet buffer in NetEq. The capacity is the
 // maximum number of packets that the buffer can contain. If the limit is
 // exceeded, the buffer will be flushed. The capacity does not affect the actual
 // audio delay in the general case, since this is governed by the target buffer
 // level (calculated from the jitter profile). It is only in the rare case of
 // severe network freezes that a higher capacity will lead to a (transient)
 // increase in audio delay.
 struct NetEqCapacityConfig {
   NetEqCapacityConfig() : enabled(false), capacity(0) {}
   explicit NetEqCapacityConfig(int value) : enabled(true), capacity(value) {}
   bool enabled;
   int capacity;
 };

 struct NetEqFastAccelerate {
   NetEqFastAccelerate() : enabled(false) {}
   explicit NetEqFastAccelerate(bool value) : enabled(value) {}
   bool enabled;
 };

 }  // namespace webrtc

 #endif  // WEBRTC_CONFIG_H_
	/*
	* Copyright (c) 2013 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.
	*/

	// TODO(pbos): Move Config from common.h to here.

	#ifndef WEBRTC_CONFIG_H_
	#define WEBRTC_CONFIG_H_

	#include <string>
	#include <vector>

	#include "webrtc/common_types.h"
	#include "webrtc/typedefs.h"

	namespace webrtc {

	// Settings for NACK, see RFC 4585 for details.
	struct NackConfig {
	NackConfig() : rtp_history_ms(0) {}
	// Send side: the time RTP packets are stored for retransmissions.
	// Receive side: the time the receiver is prepared to wait for
	// retransmissions.
	// Set to '0' to disable.
	int rtp_history_ms;
	};

	// Settings for forward error correction, see RFC 5109 for details. Set the
	// payload types to '-1' to disable.
	struct FecConfig {
	FecConfig()
	: ulpfec_payload_type(-1),
	red_payload_type(-1),
	red_rtx_payload_type(-1) {}
	std::string ToString() const;
	// Payload type used for ULPFEC packets.
	int ulpfec_payload_type;

	// Payload type used for RED packets.
	int red_payload_type;

	// RTX payload type for RED payload.
	int red_rtx_payload_type;
	};

	// RTP header extension to use for the video stream, see RFC 5285.
	struct RtpExtension {
	RtpExtension(const std::string& name, int id) : name(name), id(id) {}
	std::string ToString() const;
	static bool IsSupportedForAudio(const std::string& name);
	static bool IsSupportedForVideo(const std::string& name);

	static const char* kTOffset;
	static const char* kAbsSendTime;
	static const char* kVideoRotation;
	static const char* kAudioLevel;
	static const char* kTransportSequenceNumber;
	std::string name;
	int id;
	};

	struct VideoStream {
	VideoStream();
	~VideoStream();
	std::string ToString() const;

	size_t width;
	size_t height;
	int max_framerate;

	int min_bitrate_bps;
	int target_bitrate_bps;
	int max_bitrate_bps;

	int max_qp;

	// Bitrate thresholds for enabling additional temporal layers. Since these are
	// thresholds in between layers, we have one additional layer. One threshold
	// gives two temporal layers, one below the threshold and one above, two give
	// three, and so on.
	// The VideoEncoder may redistribute bitrates over the temporal layers so a
	// bitrate threshold of 100k and an estimate of 105k does not imply that we
	// get 100k in one temporal layer and 5k in the other, just that the bitrate
	// in the first temporal layer should not exceed 100k.
	// TODO(pbos): Apart from a special case for two-layer screencast these
	// thresholds are not propagated to the VideoEncoder. To be implemented.
	std::vector<int> temporal_layer_thresholds_bps;
	};

	struct VideoEncoderConfig {
	enum class ContentType {
	kRealtimeVideo,
	kScreen,
	};

	VideoEncoderConfig();
	~VideoEncoderConfig();
	std::string ToString() const;

	std::vector<VideoStream> streams;
	ContentType content_type;
	void* encoder_specific_settings;

	// Padding will be used up to this bitrate regardless of the bitrate produced
	// by the encoder. Padding above what's actually produced by the encoder helps
	// maintaining a higher bitrate estimate. Padding will however not be sent
	// unless the estimated bandwidth indicates that the link can handle it.
	int min_transmit_bitrate_bps;
	};

	// Controls the capacity of the packet buffer in NetEq. The capacity is the
	// maximum number of packets that the buffer can contain. If the limit is
	// exceeded, the buffer will be flushed. The capacity does not affect the actual
	// audio delay in the general case, since this is governed by the target buffer
	// level (calculated from the jitter profile). It is only in the rare case of
	// severe network freezes that a higher capacity will lead to a (transient)
	// increase in audio delay.
	struct NetEqCapacityConfig {
	NetEqCapacityConfig() : enabled(false), capacity(0) {}
	explicit NetEqCapacityConfig(int value) : enabled(true), capacity(value) {}
	bool enabled;
	int capacity;
	};

	struct NetEqFastAccelerate {
	NetEqFastAccelerate() : enabled(false) {}
	explicit NetEqFastAccelerate(bool value) : enabled(value) {}
	bool enabled;
	};

	} // namespace webrtc

	#endif // WEBRTC_CONFIG_H_