modules/pacing/paced_sender.h - src/webrtc - Git at Google

 /*
  *  Copyright (c) 2012 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.
  */

 #ifndef WEBRTC_MODULES_PACING_PACED_SENDER_H_
 #define WEBRTC_MODULES_PACING_PACED_SENDER_H_

 #include <list>
 #include <memory>
 #include <set>

 #include "webrtc/api/optional.h"
 #include "webrtc/modules/pacing/pacer.h"
 #include "webrtc/rtc_base/criticalsection.h"
 #include "webrtc/rtc_base/thread_annotations.h"
 #include "webrtc/typedefs.h"

 namespace webrtc {
 class AlrDetector;
 class BitrateProber;
 class Clock;
 class ProbeClusterCreatedObserver;
 class RtcEventLog;
 class IntervalBudget;

 namespace paced_sender {
 class IntervalBudget;
 struct Packet;
 class PacketQueue;
 }  // namespace paced_sender

 class PacedSender : public Pacer {
  public:
   class PacketSender {
    public:
     // Note: packets sent as a result of a callback should not pass by this
     // module again.
     // Called when it's time to send a queued packet.
     // Returns false if packet cannot be sent.
     virtual bool TimeToSendPacket(uint32_t ssrc,
                                   uint16_t sequence_number,
                                   int64_t capture_time_ms,
                                   bool retransmission,
                                   const PacedPacketInfo& cluster_info) = 0;
     // Called when it's a good time to send a padding data.
     // Returns the number of bytes sent.
     virtual size_t TimeToSendPadding(size_t bytes,
                                      const PacedPacketInfo& cluster_info) = 0;

    protected:
     virtual ~PacketSender() {}
   };

   // Expected max pacer delay in ms. If ExpectedQueueTimeMs() is higher than
   // this value, the packet producers should wait (eg drop frames rather than
   // encoding them). Bitrate sent may temporarily exceed target set by
   // UpdateBitrate() so that this limit will be upheld.
   static const int64_t kMaxQueueLengthMs;
   // Pacing-rate relative to our target send rate.
   // Multiplicative factor that is applied to the target bitrate to calculate
   // the number of bytes that can be transmitted per interval.
   // Increasing this factor will result in lower delays in cases of bitrate
   // overshoots from the encoder.
   static const float kDefaultPaceMultiplier;

   PacedSender(const Clock* clock,
               PacketSender* packet_sender,
               RtcEventLog* event_log);

   ~PacedSender() override;

   virtual void CreateProbeCluster(int bitrate_bps);

   // Temporarily pause all sending.
   void Pause();

   // Resume sending packets.
   void Resume();

   // Enable bitrate probing. Enabled by default, mostly here to simplify
   // testing. Must be called before any packets are being sent to have an
   // effect.
   void SetProbingEnabled(bool enabled);

   // Sets the estimated capacity of the network. Must be called once before
   // packets can be sent.
   // |bitrate_bps| is our estimate of what we are allowed to send on average.
   // We will pace out bursts of packets at a bitrate of
   // |bitrate_bps| * kDefaultPaceMultiplier.
   void SetEstimatedBitrate(uint32_t bitrate_bps) override;

   // Sets the minimum send bitrate and maximum padding bitrate requested by send
   // streams.
   // |min_send_bitrate_bps| might be higher that the estimated available network
   // bitrate and if so, the pacer will send with |min_send_bitrate_bps|.
   // |max_padding_bitrate_bps| might be higher than the estimate available
   // network bitrate and if so, the pacer will send padding packets to reach
   // the min of the estimated available bitrate and |max_padding_bitrate_bps|.
   void SetSendBitrateLimits(int min_send_bitrate_bps,
                             int max_padding_bitrate_bps);

   // Returns true if we send the packet now, else it will add the packet
   // information to the queue and call TimeToSendPacket when it's time to send.
   void InsertPacket(RtpPacketSender::Priority priority,
                     uint32_t ssrc,
                     uint16_t sequence_number,
                     int64_t capture_time_ms,
                     size_t bytes,
                     bool retransmission) override;

   // Returns the time since the oldest queued packet was enqueued.
   virtual int64_t QueueInMs() const;

   virtual size_t QueueSizePackets() const;

   // Returns the time when the first packet was sent, or -1 if no packet is
   // sent.
   virtual int64_t FirstSentPacketTimeMs() const;

   // Returns the number of milliseconds it will take to send the current
   // packets in the queue, given the current size and bitrate, ignoring prio.
   virtual int64_t ExpectedQueueTimeMs() const;

   // Returns time in milliseconds when the current application-limited region
   // started or empty result if the sender is currently not application-limited.
   //
   // Application Limited Region (ALR) refers to operating in a state where the
   // traffic on network is limited due to application not having enough
   // traffic to meet the current channel capacity.
   virtual rtc::Optional<int64_t> GetApplicationLimitedRegionStartTime() const;

   // Returns the average time since being enqueued, in milliseconds, for all
   // packets currently in the pacer queue, excluding any time the pacer has been
   // paused. Returns 0 if queue is empty.
   virtual int64_t AverageQueueTimeMs();

   // Returns the number of milliseconds until the module want a worker thread
   // to call Process.
   int64_t TimeUntilNextProcess() override;

   // Process any pending packets in the queue(s).
   void Process() override;

   // Called when the prober is associated with a process thread.
   void ProcessThreadAttached(ProcessThread* process_thread) override;
   void SetPacingFactor(float pacing_factor);
   void SetQueueTimeLimit(int limit_ms);

  private:
   // Updates the number of bytes that can be sent for the next time interval.
   void UpdateBudgetWithElapsedTime(int64_t delta_time_in_ms)
       EXCLUSIVE_LOCKS_REQUIRED(critsect_);
   void UpdateBudgetWithBytesSent(size_t bytes)
       EXCLUSIVE_LOCKS_REQUIRED(critsect_);

   bool SendPacket(const paced_sender::Packet& packet,
                   const PacedPacketInfo& cluster_info)
       EXCLUSIVE_LOCKS_REQUIRED(critsect_);
   size_t SendPadding(size_t padding_needed, const PacedPacketInfo& cluster_info)
       EXCLUSIVE_LOCKS_REQUIRED(critsect_);

   const Clock* const clock_;
   PacketSender* const packet_sender_;
   std::unique_ptr<AlrDetector> alr_detector_ GUARDED_BY(critsect_);

   rtc::CriticalSection critsect_;
   bool paused_ GUARDED_BY(critsect_);
   // This is the media budget, keeping track of how many bits of media
   // we can pace out during the current interval.
   std::unique_ptr<IntervalBudget> media_budget_ GUARDED_BY(critsect_);
   // This is the padding budget, keeping track of how many bits of padding we're
   // allowed to send out during the current interval. This budget will be
   // utilized when there's no media to send.
   std::unique_ptr<IntervalBudget> padding_budget_ GUARDED_BY(critsect_);

   std::unique_ptr<BitrateProber> prober_ GUARDED_BY(critsect_);
   bool probing_send_failure_;
   // Actual configured bitrates (media_budget_ may temporarily be higher in
   // order to meet pace time constraint).
   uint32_t estimated_bitrate_bps_ GUARDED_BY(critsect_);
   uint32_t min_send_bitrate_kbps_ GUARDED_BY(critsect_);
   uint32_t max_padding_bitrate_kbps_ GUARDED_BY(critsect_);
   uint32_t pacing_bitrate_kbps_ GUARDED_BY(critsect_);

   int64_t time_last_update_us_ GUARDED_BY(critsect_);
   int64_t first_sent_packet_ms_ GUARDED_BY(critsect_);

   std::unique_ptr<paced_sender::PacketQueue> packets_ GUARDED_BY(critsect_);
   uint64_t packet_counter_;
   ProcessThread* process_thread_ = nullptr;

   float pacing_factor_ GUARDED_BY(critsect_);
   int64_t queue_time_limit GUARDED_BY(critsect_);
 };
 }  // namespace webrtc
 #endif  // WEBRTC_MODULES_PACING_PACED_SENDER_H_
	/*
	* Copyright (c) 2012 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.
	*/

	#ifndef WEBRTC_MODULES_PACING_PACED_SENDER_H_
	#define WEBRTC_MODULES_PACING_PACED_SENDER_H_

	#include <list>
	#include <memory>
	#include <set>

	#include "webrtc/api/optional.h"
	#include "webrtc/modules/pacing/pacer.h"
	#include "webrtc/rtc_base/criticalsection.h"
	#include "webrtc/rtc_base/thread_annotations.h"
	#include "webrtc/typedefs.h"

	namespace webrtc {
	class AlrDetector;
	class BitrateProber;
	class Clock;
	class ProbeClusterCreatedObserver;
	class RtcEventLog;
	class IntervalBudget;

	namespace paced_sender {
	class IntervalBudget;
	struct Packet;
	class PacketQueue;
	} // namespace paced_sender

	class PacedSender : public Pacer {
	public:
	class PacketSender {
	public:
	// Note: packets sent as a result of a callback should not pass by this
	// module again.
	// Called when it's time to send a queued packet.
	// Returns false if packet cannot be sent.
	virtual bool TimeToSendPacket(uint32_t ssrc,
	uint16_t sequence_number,
	int64_t capture_time_ms,
	bool retransmission,
	const PacedPacketInfo& cluster_info) = 0;
	// Called when it's a good time to send a padding data.
	// Returns the number of bytes sent.
	virtual size_t TimeToSendPadding(size_t bytes,
	const PacedPacketInfo& cluster_info) = 0;

	protected:
	virtual ~PacketSender() {}
	};

	// Expected max pacer delay in ms. If ExpectedQueueTimeMs() is higher than
	// this value, the packet producers should wait (eg drop frames rather than
	// encoding them). Bitrate sent may temporarily exceed target set by
	// UpdateBitrate() so that this limit will be upheld.
	static const int64_t kMaxQueueLengthMs;
	// Pacing-rate relative to our target send rate.
	// Multiplicative factor that is applied to the target bitrate to calculate
	// the number of bytes that can be transmitted per interval.
	// Increasing this factor will result in lower delays in cases of bitrate
	// overshoots from the encoder.
	static const float kDefaultPaceMultiplier;

	PacedSender(const Clock* clock,
	PacketSender* packet_sender,
	RtcEventLog* event_log);

	~PacedSender() override;

	virtual void CreateProbeCluster(int bitrate_bps);

	// Temporarily pause all sending.
	void Pause();

	// Resume sending packets.
	void Resume();

	// Enable bitrate probing. Enabled by default, mostly here to simplify
	// testing. Must be called before any packets are being sent to have an
	// effect.
	void SetProbingEnabled(bool enabled);

	// Sets the estimated capacity of the network. Must be called once before
	// packets can be sent.
	// \|bitrate_bps\| is our estimate of what we are allowed to send on average.
	// We will pace out bursts of packets at a bitrate of
	// \|bitrate_bps\| * kDefaultPaceMultiplier.
	void SetEstimatedBitrate(uint32_t bitrate_bps) override;

	// Sets the minimum send bitrate and maximum padding bitrate requested by send
	// streams.
	// \|min_send_bitrate_bps\| might be higher that the estimated available network
	// bitrate and if so, the pacer will send with \|min_send_bitrate_bps\|.
	// \|max_padding_bitrate_bps\| might be higher than the estimate available
	// network bitrate and if so, the pacer will send padding packets to reach
	// the min of the estimated available bitrate and \|max_padding_bitrate_bps\|.
	void SetSendBitrateLimits(int min_send_bitrate_bps,
	int max_padding_bitrate_bps);

	// Returns true if we send the packet now, else it will add the packet
	// information to the queue and call TimeToSendPacket when it's time to send.
	void InsertPacket(RtpPacketSender::Priority priority,
	uint32_t ssrc,
	uint16_t sequence_number,
	int64_t capture_time_ms,
	size_t bytes,
	bool retransmission) override;

	// Returns the time since the oldest queued packet was enqueued.
	virtual int64_t QueueInMs() const;

	virtual size_t QueueSizePackets() const;

	// Returns the time when the first packet was sent, or -1 if no packet is
	// sent.
	virtual int64_t FirstSentPacketTimeMs() const;

	// Returns the number of milliseconds it will take to send the current
	// packets in the queue, given the current size and bitrate, ignoring prio.
	virtual int64_t ExpectedQueueTimeMs() const;

	// Returns time in milliseconds when the current application-limited region
	// started or empty result if the sender is currently not application-limited.
	//
	// Application Limited Region (ALR) refers to operating in a state where the
	// traffic on network is limited due to application not having enough
	// traffic to meet the current channel capacity.
	virtual rtc::Optional<int64_t> GetApplicationLimitedRegionStartTime() const;

	// Returns the average time since being enqueued, in milliseconds, for all
	// packets currently in the pacer queue, excluding any time the pacer has been
	// paused. Returns 0 if queue is empty.
	virtual int64_t AverageQueueTimeMs();

	// Returns the number of milliseconds until the module want a worker thread
	// to call Process.
	int64_t TimeUntilNextProcess() override;

	// Process any pending packets in the queue(s).
	void Process() override;

	// Called when the prober is associated with a process thread.
	void ProcessThreadAttached(ProcessThread* process_thread) override;
	void SetPacingFactor(float pacing_factor);
	void SetQueueTimeLimit(int limit_ms);

	private:
	// Updates the number of bytes that can be sent for the next time interval.
	void UpdateBudgetWithElapsedTime(int64_t delta_time_in_ms)
	EXCLUSIVE_LOCKS_REQUIRED(critsect_);
	void UpdateBudgetWithBytesSent(size_t bytes)
	EXCLUSIVE_LOCKS_REQUIRED(critsect_);

	bool SendPacket(const paced_sender::Packet& packet,
	const PacedPacketInfo& cluster_info)
	EXCLUSIVE_LOCKS_REQUIRED(critsect_);
	size_t SendPadding(size_t padding_needed, const PacedPacketInfo& cluster_info)
	EXCLUSIVE_LOCKS_REQUIRED(critsect_);

	const Clock* const clock_;
	PacketSender* const packet_sender_;
	std::unique_ptr<AlrDetector> alr_detector_ GUARDED_BY(critsect_);

	rtc::CriticalSection critsect_;
	bool paused_ GUARDED_BY(critsect_);
	// This is the media budget, keeping track of how many bits of media
	// we can pace out during the current interval.
	std::unique_ptr<IntervalBudget> media_budget_ GUARDED_BY(critsect_);
	// This is the padding budget, keeping track of how many bits of padding we're
	// allowed to send out during the current interval. This budget will be
	// utilized when there's no media to send.
	std::unique_ptr<IntervalBudget> padding_budget_ GUARDED_BY(critsect_);

	std::unique_ptr<BitrateProber> prober_ GUARDED_BY(critsect_);
	bool probing_send_failure_;
	// Actual configured bitrates (media_budget_ may temporarily be higher in
	// order to meet pace time constraint).
	uint32_t estimated_bitrate_bps_ GUARDED_BY(critsect_);
	uint32_t min_send_bitrate_kbps_ GUARDED_BY(critsect_);
	uint32_t max_padding_bitrate_kbps_ GUARDED_BY(critsect_);
	uint32_t pacing_bitrate_kbps_ GUARDED_BY(critsect_);

	int64_t time_last_update_us_ GUARDED_BY(critsect_);
	int64_t first_sent_packet_ms_ GUARDED_BY(critsect_);

	std::unique_ptr<paced_sender::PacketQueue> packets_ GUARDED_BY(critsect_);
	uint64_t packet_counter_;
	ProcessThread* process_thread_ = nullptr;

	float pacing_factor_ GUARDED_BY(critsect_);
	int64_t queue_time_limit GUARDED_BY(critsect_);
	};
	} // namespace webrtc
	#endif // WEBRTC_MODULES_PACING_PACED_SENDER_H_