webrtc/call/bitrate_allocator.cc - src - Git at Google

 /*
  *  Copyright (c) 2015 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/call/bitrate_allocator.h"

 #include <algorithm>
 #include <utility>

 #include "webrtc/modules/bitrate_controller/include/bitrate_controller.h"

 namespace webrtc {

 // Allow packets to be transmitted in up to 2 times max video bitrate if the
 // bandwidth estimate allows it.
 const int kTransmissionMaxBitrateMultiplier = 2;
 const int kDefaultBitrateBps = 300000;

 BitrateAllocator::BitrateAllocator()
     : bitrate_observers_(),
       bitrate_observers_modified_(false),
       enforce_min_bitrate_(true),
       last_bitrate_bps_(kDefaultBitrateBps),
       last_fraction_loss_(0),
       last_rtt_(0) {}

 uint32_t BitrateAllocator::OnNetworkChanged(uint32_t bitrate,
                                             uint8_t fraction_loss,
                                             int64_t rtt) {
   rtc::CritScope lock(&crit_sect_);
   last_bitrate_bps_ = bitrate;
   last_fraction_loss_ = fraction_loss;
   last_rtt_ = rtt;
   uint32_t allocated_bitrate_bps = 0;
   ObserverBitrateMap allocation = AllocateBitrates();
   for (const auto& kv : allocation) {
     kv.first->OnBitrateUpdated(kv.second, last_fraction_loss_, last_rtt_);
     allocated_bitrate_bps += kv.second;
   }
   return allocated_bitrate_bps;
 }

 BitrateAllocator::ObserverBitrateMap BitrateAllocator::AllocateBitrates() {
   if (bitrate_observers_.empty())
     return ObserverBitrateMap();

   uint32_t sum_min_bitrates = 0;
   for (const auto& observer : bitrate_observers_)
     sum_min_bitrates += observer.second.min_bitrate;
   if (last_bitrate_bps_ <= sum_min_bitrates)
     return LowRateAllocation(last_bitrate_bps_);
   else
     return NormalRateAllocation(last_bitrate_bps_, sum_min_bitrates);
 }

 int BitrateAllocator::AddObserver(BitrateAllocatorObserver* observer,
                                   uint32_t min_bitrate_bps,
                                   uint32_t max_bitrate_bps) {
   rtc::CritScope lock(&crit_sect_);

   BitrateObserverConfList::iterator it =
       FindObserverConfigurationPair(observer);

   // Allow the max bitrate to be exceeded for FEC and retransmissions.
   // TODO(holmer): We have to get rid of this hack as it makes it difficult to
   // properly allocate bitrate. The allocator should instead distribute any
   // extra bitrate after all streams have maxed out.
   max_bitrate_bps *= kTransmissionMaxBitrateMultiplier;
   if (it != bitrate_observers_.end()) {
     // Update current configuration.
     it->second.min_bitrate = min_bitrate_bps;
     it->second.max_bitrate = max_bitrate_bps;
   } else {
     // Add new settings.
     bitrate_observers_.push_back(BitrateObserverConfiguration(
         observer, BitrateConfiguration(min_bitrate_bps, max_bitrate_bps)));
     bitrate_observers_modified_ = true;
   }

   ObserverBitrateMap allocation = AllocateBitrates();
   int new_observer_bitrate_bps = 0;
   for (auto& kv : allocation) {
     kv.first->OnBitrateUpdated(kv.second, last_fraction_loss_, last_rtt_);
     if (kv.first == observer)
       new_observer_bitrate_bps = kv.second;
   }
   return new_observer_bitrate_bps;
 }

 void BitrateAllocator::RemoveObserver(BitrateAllocatorObserver* observer) {
   rtc::CritScope lock(&crit_sect_);
   BitrateObserverConfList::iterator it =
       FindObserverConfigurationPair(observer);
   if (it != bitrate_observers_.end()) {
     bitrate_observers_.erase(it);
     bitrate_observers_modified_ = true;
   }
 }

 void BitrateAllocator::GetMinMaxBitrateSumBps(int* min_bitrate_sum_bps,
                                               int* max_bitrate_sum_bps) const {
   *min_bitrate_sum_bps = 0;
   *max_bitrate_sum_bps = 0;

   rtc::CritScope lock(&crit_sect_);
   for (const auto& observer : bitrate_observers_) {
     *min_bitrate_sum_bps += observer.second.min_bitrate;
     *max_bitrate_sum_bps += observer.second.max_bitrate;
   }
 }

 BitrateAllocator::BitrateObserverConfList::iterator
 BitrateAllocator::FindObserverConfigurationPair(
     const BitrateAllocatorObserver* observer) {
   for (auto it = bitrate_observers_.begin(); it != bitrate_observers_.end();
        ++it) {
     if (it->first == observer)
       return it;
   }
   return bitrate_observers_.end();
 }

 void BitrateAllocator::EnforceMinBitrate(bool enforce_min_bitrate) {
   rtc::CritScope lock(&crit_sect_);
   enforce_min_bitrate_ = enforce_min_bitrate;
 }

 BitrateAllocator::ObserverBitrateMap BitrateAllocator::NormalRateAllocation(
     uint32_t bitrate,
     uint32_t sum_min_bitrates) {
   uint32_t number_of_observers =
       static_cast<uint32_t>(bitrate_observers_.size());
   uint32_t bitrate_per_observer =
       (bitrate - sum_min_bitrates) / number_of_observers;
   // Use map to sort list based on max bitrate.
   ObserverSortingMap list_max_bitrates;
   for (const auto& observer : bitrate_observers_) {
     list_max_bitrates.insert(std::pair<uint32_t, ObserverConfiguration>(
         observer.second.max_bitrate,
         ObserverConfiguration(observer.first, observer.second.min_bitrate)));
   }
   ObserverBitrateMap allocation;
   ObserverSortingMap::iterator max_it = list_max_bitrates.begin();
   while (max_it != list_max_bitrates.end()) {
     number_of_observers--;
     uint32_t observer_allowance =
         max_it->second.min_bitrate + bitrate_per_observer;
     if (max_it->first < observer_allowance) {
       // We have more than enough for this observer.
       // Carry the remainder forward.
       uint32_t remainder = observer_allowance - max_it->first;
       if (number_of_observers != 0) {
         bitrate_per_observer += remainder / number_of_observers;
       }
       allocation[max_it->second.observer] = max_it->first;
     } else {
       allocation[max_it->second.observer] = observer_allowance;
     }
     list_max_bitrates.erase(max_it);
     // Prepare next iteration.
     max_it = list_max_bitrates.begin();
   }
   return allocation;
 }

 BitrateAllocator::ObserverBitrateMap BitrateAllocator::LowRateAllocation(
     uint32_t bitrate) {
   ObserverBitrateMap allocation;
   if (enforce_min_bitrate_) {
     // Min bitrate to all observers.
     for (const auto& observer : bitrate_observers_)
       allocation[observer.first] = observer.second.min_bitrate;
   } else {
     // Allocate up to |min_bitrate| to one observer at a time, until
     // |bitrate| is depleted.
     uint32_t remainder = bitrate;
     for (const auto& observer : bitrate_observers_) {
       uint32_t allocated_bitrate =
           std::min(remainder, observer.second.min_bitrate);
       allocation[observer.first] = allocated_bitrate;
       remainder -= allocated_bitrate;
     }
   }
   return allocation;
 }
 }  // namespace webrtc
	/*
	* Copyright (c) 2015 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/call/bitrate_allocator.h"

	#include <algorithm>
	#include <utility>

	#include "webrtc/modules/bitrate_controller/include/bitrate_controller.h"

	namespace webrtc {

	// Allow packets to be transmitted in up to 2 times max video bitrate if the
	// bandwidth estimate allows it.
	const int kTransmissionMaxBitrateMultiplier = 2;
	const int kDefaultBitrateBps = 300000;

	BitrateAllocator::BitrateAllocator()
	: bitrate_observers_(),
	bitrate_observers_modified_(false),
	enforce_min_bitrate_(true),
	last_bitrate_bps_(kDefaultBitrateBps),
	last_fraction_loss_(0),
	last_rtt_(0) {}

	uint32_t BitrateAllocator::OnNetworkChanged(uint32_t bitrate,
	uint8_t fraction_loss,
	int64_t rtt) {
	rtc::CritScope lock(&crit_sect_);
	last_bitrate_bps_ = bitrate;
	last_fraction_loss_ = fraction_loss;
	last_rtt_ = rtt;
	uint32_t allocated_bitrate_bps = 0;
	ObserverBitrateMap allocation = AllocateBitrates();
	for (const auto& kv : allocation) {
	kv.first->OnBitrateUpdated(kv.second, last_fraction_loss_, last_rtt_);
	allocated_bitrate_bps += kv.second;
	}
	return allocated_bitrate_bps;
	}

	BitrateAllocator::ObserverBitrateMap BitrateAllocator::AllocateBitrates() {
	if (bitrate_observers_.empty())
	return ObserverBitrateMap();

	uint32_t sum_min_bitrates = 0;
	for (const auto& observer : bitrate_observers_)
	sum_min_bitrates += observer.second.min_bitrate;
	if (last_bitrate_bps_ <= sum_min_bitrates)
	return LowRateAllocation(last_bitrate_bps_);
	else
	return NormalRateAllocation(last_bitrate_bps_, sum_min_bitrates);
	}

	int BitrateAllocator::AddObserver(BitrateAllocatorObserver* observer,
	uint32_t min_bitrate_bps,
	uint32_t max_bitrate_bps) {
	rtc::CritScope lock(&crit_sect_);

	BitrateObserverConfList::iterator it =
	FindObserverConfigurationPair(observer);

	// Allow the max bitrate to be exceeded for FEC and retransmissions.
	// TODO(holmer): We have to get rid of this hack as it makes it difficult to
	// properly allocate bitrate. The allocator should instead distribute any
	// extra bitrate after all streams have maxed out.
	max_bitrate_bps *= kTransmissionMaxBitrateMultiplier;
	if (it != bitrate_observers_.end()) {
	// Update current configuration.
	it->second.min_bitrate = min_bitrate_bps;
	it->second.max_bitrate = max_bitrate_bps;
	} else {
	// Add new settings.
	bitrate_observers_.push_back(BitrateObserverConfiguration(
	observer, BitrateConfiguration(min_bitrate_bps, max_bitrate_bps)));
	bitrate_observers_modified_ = true;
	}

	ObserverBitrateMap allocation = AllocateBitrates();
	int new_observer_bitrate_bps = 0;
	for (auto& kv : allocation) {
	kv.first->OnBitrateUpdated(kv.second, last_fraction_loss_, last_rtt_);
	if (kv.first == observer)
	new_observer_bitrate_bps = kv.second;
	}
	return new_observer_bitrate_bps;
	}

	void BitrateAllocator::RemoveObserver(BitrateAllocatorObserver* observer) {
	rtc::CritScope lock(&crit_sect_);
	BitrateObserverConfList::iterator it =
	FindObserverConfigurationPair(observer);
	if (it != bitrate_observers_.end()) {
	bitrate_observers_.erase(it);
	bitrate_observers_modified_ = true;
	}
	}

	void BitrateAllocator::GetMinMaxBitrateSumBps(int* min_bitrate_sum_bps,
	int* max_bitrate_sum_bps) const {
	*min_bitrate_sum_bps = 0;
	*max_bitrate_sum_bps = 0;

	rtc::CritScope lock(&crit_sect_);
	for (const auto& observer : bitrate_observers_) {
	*min_bitrate_sum_bps += observer.second.min_bitrate;
	*max_bitrate_sum_bps += observer.second.max_bitrate;
	}
	}

	BitrateAllocator::BitrateObserverConfList::iterator
	BitrateAllocator::FindObserverConfigurationPair(
	const BitrateAllocatorObserver* observer) {
	for (auto it = bitrate_observers_.begin(); it != bitrate_observers_.end();
	++it) {
	if (it->first == observer)
	return it;
	}
	return bitrate_observers_.end();
	}

	void BitrateAllocator::EnforceMinBitrate(bool enforce_min_bitrate) {
	rtc::CritScope lock(&crit_sect_);
	enforce_min_bitrate_ = enforce_min_bitrate;
	}

	BitrateAllocator::ObserverBitrateMap BitrateAllocator::NormalRateAllocation(
	uint32_t bitrate,
	uint32_t sum_min_bitrates) {
	uint32_t number_of_observers =
	static_cast<uint32_t>(bitrate_observers_.size());
	uint32_t bitrate_per_observer =
	(bitrate - sum_min_bitrates) / number_of_observers;
	// Use map to sort list based on max bitrate.
	ObserverSortingMap list_max_bitrates;
	for (const auto& observer : bitrate_observers_) {
	list_max_bitrates.insert(std::pair<uint32_t, ObserverConfiguration>(
	observer.second.max_bitrate,
	ObserverConfiguration(observer.first, observer.second.min_bitrate)));
	}
	ObserverBitrateMap allocation;
	ObserverSortingMap::iterator max_it = list_max_bitrates.begin();
	while (max_it != list_max_bitrates.end()) {
	number_of_observers--;
	uint32_t observer_allowance =
	max_it->second.min_bitrate + bitrate_per_observer;
	if (max_it->first < observer_allowance) {
	// We have more than enough for this observer.
	// Carry the remainder forward.
	uint32_t remainder = observer_allowance - max_it->first;
	if (number_of_observers != 0) {
	bitrate_per_observer += remainder / number_of_observers;
	}
	allocation[max_it->second.observer] = max_it->first;
	} else {
	allocation[max_it->second.observer] = observer_allowance;
	}
	list_max_bitrates.erase(max_it);
	// Prepare next iteration.
	max_it = list_max_bitrates.begin();
	}
	return allocation;
	}

	BitrateAllocator::ObserverBitrateMap BitrateAllocator::LowRateAllocation(
	uint32_t bitrate) {
	ObserverBitrateMap allocation;
	if (enforce_min_bitrate_) {
	// Min bitrate to all observers.
	for (const auto& observer : bitrate_observers_)
	allocation[observer.first] = observer.second.min_bitrate;
	} else {
	// Allocate up to \|min_bitrate\| to one observer at a time, until
	// \|bitrate\| is depleted.
	uint32_t remainder = bitrate;
	for (const auto& observer : bitrate_observers_) {
	uint32_t allocated_bitrate =
	std::min(remainder, observer.second.min_bitrate);
	allocation[observer.first] = allocated_bitrate;
	remainder -= allocated_bitrate;
	}
	}
	return allocation;
	}
	} // namespace webrtc