src/net/base/network_throttle_manager_impl.h - cobalt - Git at Google

 // Copyright 2016 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #ifndef NET_BASE_NETWORK_THROTTLE_MANAGER_IMPL_H_
 #define NET_BASE_NETWORK_THROTTLE_MANAGER_IMPL_H_

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

 #include "base/memory/weak_ptr.h"
 #include "base/time/tick_clock.h"
 #include "base/time/time.h"
 #include "base/timer/timer.h"
 #include "net/base/network_throttle_manager.h"
 #include "net/base/percentile_estimator.h"

 namespace net {

 // The NetworkThrottleManagerImpl implements the following semantics:
 // * All throttles of priority above THROTTLED are created unblocked.
 // * Throttles of priority THROTTLED are created unblocked, unless
 //   there are |kActiveRequestThrottlingLimit| or more throttles active,
 //   in which case they are created blocked.
 //   When that condition is no longer true, throttles of priority
 //   THROTTLED are unblocked, in FIFO order.
 // * Throttles that have been alive for more than |kMedianLifetimeMultiple|
 //   times the current estimate of the throttle median lifetime do
 //   not count against the |kActiveRequestThrottlingLimit| limit.
 class NET_EXPORT NetworkThrottleManagerImpl : public NetworkThrottleManager {
  public:
   // Maximum number of active requests before new THROTTLED throttles
   // are created blocked.  Throttles are unblocked as the active requests
   // fall below this limit.
   static const size_t kActiveRequestThrottlingLimit;

   // Note that the following constants are implementation details exposed in the
   // header file only for testing, and should not be relied on by consumers.

   // Constants used for the running estimate of the median lifetime
   // for throttles created by this class.  That estimate is used to detect
   // throttles that are "unusually old" and hence may represent hanging GETs
   // or long-running streams.  Such throttles should not be considered
   // "active" for the purposes of determining whether THROTTLED throttles
   // should be created in a blocked state.
   // Note that the precise details of this algorithm aren't very important;
   // specifically, if it takes a while for the median estimate to reach the
   // "actual" median of a request stream, the consequence is either a bit more
   // of a delay in unblocking THROTTLED requests or more THROTTLED requests
   // being unblocked than would be ideal (i.e. performance tweaks at
   // the margins).

   // Multiple of the current median lifetime beyond which a throttle is
   // considered "unusually old" and not considered in counting active
   // requests. This is used instead of a percentile estimate because the goal
   // is eliminating requests that are qualitatively different
   // (e.g. hanging gets, streams), and the percentage of all requests
   // that are in that category can vary greatly.
   static const int kMedianLifetimeMultiple;

   // The median lifetime estimate starts at class creation at
   // |kInitialMedianInMs|.
   static const int kInitialMedianInMs;

   NetworkThrottleManagerImpl();
   ~NetworkThrottleManagerImpl() override;

   // NetworkThrottleManager:
   std::unique_ptr<Throttle> CreateThrottle(ThrottleDelegate* delegate,
                                            RequestPriority priority,
                                            bool ignore_limits) override;

   void SetTickClockForTesting(const base::TickClock* tick_clock);

   // If the |NowTicks()| value of |tick_clock_| is greater than the
   // time the outstanding_recomputation_timer_ has set to go off, Stop()
   // the timer and manually run the associated user task.  This is to allow
   // "fast-forwarding" of the clock for testing by working around
   // base::Timer's direct use of base::TimeTicks rather than a base::TickClock.
   //
   // Note specifically that base::Timer::Start takes a time delta into the
   // future and adds it to base::TimeTicks::Now() to get
   // base::Timer::desired_run_time(), which is what this method compares
   // |tick_clock_->NowTicks()| against.  So tests should be written so that
   // the timer Start() routine whose callback should be run is called
   // with |tick_clock_| in accord with wallclock time.  This routine can then
   // be called with |tick_clock_| set into the future.
   //
   // Returns true if there was a timer running and it was triggerred
   // (|tick_clock_->NowTicks() >
   //   outstanding_recomputation_timer_.desired_run_time()|).
   bool ConditionallyTriggerTimerForTesting();

  private:
   class ThrottleImpl;
   using ThrottleList = std::list<ThrottleImpl*>;

   void OnThrottlePriorityChanged(ThrottleImpl* throttle,
                                  RequestPriority old_priority,
                                  RequestPriority new_priority);
   void OnThrottleDestroyed(ThrottleImpl* throttle);

   // Recompute how many requests count as outstanding (i.e.
   // are not older than kMedianLifetimeMultiple * MedianThrottleLifetime()).
   // If outstanding_recomputation_timer_ is not set, it will be set
   // to the earliest a throttle might "age out" of the outstanding list.
   void RecomputeOutstanding();

   // Unblock the specified throttle.  May result in re-entrant calls
   // into NetworkThrottleManagerImpl.
   void UnblockThrottle(ThrottleImpl* throttle);

   // Recomputes how many requests count as outstanding, checks to see
   // if any currently blocked throttles should be unblocked,
   // and unblock them if so.  Note that unblocking may result in
   // re-entrant calls to this class, so no assumptions about state persistence
   // should be made across this call.
   void MaybeUnblockThrottles();

   PercentileEstimator lifetime_median_estimate_;

   // base::Timer controlling outstanding request recomputation.
   //
   // This is started whenever it is not running and a new throttle is
   // added to |outstanding_throttles_|, and is never cleared except by
   // execution, which re-starts it if there are any
   // outstanding_throttles_.  So it should always be running if any
   // throttles are outstanding.  This guarantees that the class will
   // eventually detect aging out of outstanding throttles and unblock
   // throttles blocked on those outstanding throttles.
   std::unique_ptr<base::OneShotTimer> outstanding_recomputation_timer_;

   // FIFO of OUTSTANDING throttles (ordered by time of entry into the
   // OUTSTANDING state).
   ThrottleList outstanding_throttles_;

   // FIFO list of BLOCKED throttles.  This is a list so that the
   // throttles can store iterators to themselves.
   ThrottleList blocked_throttles_;

   // For testing.
   const base::TickClock* tick_clock_;

   base::WeakPtrFactory<NetworkThrottleManagerImpl> weak_ptr_factory_;

   DISALLOW_COPY_AND_ASSIGN(NetworkThrottleManagerImpl);
 };

 }  // namespace net

 #endif  // NET_BASE_NETWORK_THROTTLE_MANAGER_IMPL_H_
	// Copyright 2016 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#ifndef NET_BASE_NETWORK_THROTTLE_MANAGER_IMPL_H_
	#define NET_BASE_NETWORK_THROTTLE_MANAGER_IMPL_H_

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

	#include "base/memory/weak_ptr.h"
	#include "base/time/tick_clock.h"
	#include "base/time/time.h"
	#include "base/timer/timer.h"
	#include "net/base/network_throttle_manager.h"
	#include "net/base/percentile_estimator.h"

	namespace net {

	// The NetworkThrottleManagerImpl implements the following semantics:
	// * All throttles of priority above THROTTLED are created unblocked.
	// * Throttles of priority THROTTLED are created unblocked, unless
	// there are \|kActiveRequestThrottlingLimit\| or more throttles active,
	// in which case they are created blocked.
	// When that condition is no longer true, throttles of priority
	// THROTTLED are unblocked, in FIFO order.
	// * Throttles that have been alive for more than \|kMedianLifetimeMultiple\|
	// times the current estimate of the throttle median lifetime do
	// not count against the \|kActiveRequestThrottlingLimit\| limit.
	class NET_EXPORT NetworkThrottleManagerImpl : public NetworkThrottleManager {
	public:
	// Maximum number of active requests before new THROTTLED throttles
	// are created blocked. Throttles are unblocked as the active requests
	// fall below this limit.
	static const size_t kActiveRequestThrottlingLimit;

	// Note that the following constants are implementation details exposed in the
	// header file only for testing, and should not be relied on by consumers.

	// Constants used for the running estimate of the median lifetime
	// for throttles created by this class. That estimate is used to detect
	// throttles that are "unusually old" and hence may represent hanging GETs
	// or long-running streams. Such throttles should not be considered
	// "active" for the purposes of determining whether THROTTLED throttles
	// should be created in a blocked state.
	// Note that the precise details of this algorithm aren't very important;
	// specifically, if it takes a while for the median estimate to reach the
	// "actual" median of a request stream, the consequence is either a bit more
	// of a delay in unblocking THROTTLED requests or more THROTTLED requests
	// being unblocked than would be ideal (i.e. performance tweaks at
	// the margins).

	// Multiple of the current median lifetime beyond which a throttle is
	// considered "unusually old" and not considered in counting active
	// requests. This is used instead of a percentile estimate because the goal
	// is eliminating requests that are qualitatively different
	// (e.g. hanging gets, streams), and the percentage of all requests
	// that are in that category can vary greatly.
	static const int kMedianLifetimeMultiple;

	// The median lifetime estimate starts at class creation at
	// \|kInitialMedianInMs\|.
	static const int kInitialMedianInMs;

	NetworkThrottleManagerImpl();
	~NetworkThrottleManagerImpl() override;

	// NetworkThrottleManager:
	std::unique_ptr<Throttle> CreateThrottle(ThrottleDelegate* delegate,
	RequestPriority priority,
	bool ignore_limits) override;

	void SetTickClockForTesting(const base::TickClock* tick_clock);

	// If the \|NowTicks()\| value of \|tick_clock_\| is greater than the
	// time the outstanding_recomputation_timer_ has set to go off, Stop()
	// the timer and manually run the associated user task. This is to allow
	// "fast-forwarding" of the clock for testing by working around
	// base::Timer's direct use of base::TimeTicks rather than a base::TickClock.
	//
	// Note specifically that base::Timer::Start takes a time delta into the
	// future and adds it to base::TimeTicks::Now() to get
	// base::Timer::desired_run_time(), which is what this method compares
	// \|tick_clock_->NowTicks()\| against. So tests should be written so that
	// the timer Start() routine whose callback should be run is called
	// with \|tick_clock_\| in accord with wallclock time. This routine can then
	// be called with \|tick_clock_\| set into the future.
	//
	// Returns true if there was a timer running and it was triggerred
	// (\|tick_clock_->NowTicks() >
	// outstanding_recomputation_timer_.desired_run_time()\|).
	bool ConditionallyTriggerTimerForTesting();

	private:
	class ThrottleImpl;
	using ThrottleList = std::list<ThrottleImpl*>;

	void OnThrottlePriorityChanged(ThrottleImpl* throttle,
	RequestPriority old_priority,
	RequestPriority new_priority);
	void OnThrottleDestroyed(ThrottleImpl* throttle);

	// Recompute how many requests count as outstanding (i.e.
	// are not older than kMedianLifetimeMultiple * MedianThrottleLifetime()).
	// If outstanding_recomputation_timer_ is not set, it will be set
	// to the earliest a throttle might "age out" of the outstanding list.
	void RecomputeOutstanding();

	// Unblock the specified throttle. May result in re-entrant calls
	// into NetworkThrottleManagerImpl.
	void UnblockThrottle(ThrottleImpl* throttle);

	// Recomputes how many requests count as outstanding, checks to see
	// if any currently blocked throttles should be unblocked,
	// and unblock them if so. Note that unblocking may result in
	// re-entrant calls to this class, so no assumptions about state persistence
	// should be made across this call.
	void MaybeUnblockThrottles();

	PercentileEstimator lifetime_median_estimate_;

	// base::Timer controlling outstanding request recomputation.
	//
	// This is started whenever it is not running and a new throttle is
	// added to \|outstanding_throttles_\|, and is never cleared except by
	// execution, which re-starts it if there are any
	// outstanding_throttles_. So it should always be running if any
	// throttles are outstanding. This guarantees that the class will
	// eventually detect aging out of outstanding throttles and unblock
	// throttles blocked on those outstanding throttles.
	std::unique_ptr<base::OneShotTimer> outstanding_recomputation_timer_;

	// FIFO of OUTSTANDING throttles (ordered by time of entry into the
	// OUTSTANDING state).
	ThrottleList outstanding_throttles_;

	// FIFO list of BLOCKED throttles. This is a list so that the
	// throttles can store iterators to themselves.
	ThrottleList blocked_throttles_;

	// For testing.
	const base::TickClock* tick_clock_;

	base::WeakPtrFactory<NetworkThrottleManagerImpl> weak_ptr_factory_;

	DISALLOW_COPY_AND_ASSIGN(NetworkThrottleManagerImpl);
	};

	} // namespace net

	#endif // NET_BASE_NETWORK_THROTTLE_MANAGER_IMPL_H_