services/audioflinger/StateQueue.h - third_party/android/platform/frameworks/av - Git at Google

 /*
  * Copyright (C) 2012 The Android Open Source Project
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 #ifndef ANDROID_AUDIO_STATE_QUEUE_H
 #define ANDROID_AUDIO_STATE_QUEUE_H

 #include <stdatomic.h>

 // The state queue template class was originally driven by this use case / requirements:
 //  There are two threads: a fast mixer, and a normal mixer, and they share state.
 //  The interesting part of the shared state is a set of active fast tracks,
 //  and the output HAL configuration (buffer size in frames, sample rate, etc.).
 //  Fast mixer thread:
 //      periodic with typical period < 10 ms
 //      FIFO/RR scheduling policy and a low fixed priority
 //      ok to block for bounded time using nanosleep() to achieve desired period
 //      must not block on condition wait, mutex lock, atomic operation spin, I/O, etc.
 //        under typical operations of mixing, writing, or adding/removing tracks
 //      ok to block for unbounded time when the output HAL configuration changes,
 //        and this may result in an audible artifact
 //      needs read-only access to a recent stable state,
 //        but not necessarily the most current one
 //      only allocate and free memory when configuration changes
 //      avoid conventional logging, as this is a form of I/O and could block
 //      defer computation to other threads when feasible; for example
 //        cycle times are collected by fast mixer thread but the floating-point
 //        statistical calculations on these cycle times are computed by normal mixer
 //      these requirements also apply to callouts such as AudioBufferProvider and VolumeProvider
 //  Normal mixer thread:
 //      periodic with typical period ~20 ms
 //      SCHED_OTHER scheduling policy and nice priority == urgent audio
 //      ok to block, but prefer to avoid as much as possible
 //      needs read/write access to state
 //  The normal mixer may need to temporarily suspend the fast mixer thread during mode changes.
 //  It will do this using the state -- one of the fields tells the fast mixer to idle.

 // Additional requirements:
 //  - observer must always be able to poll for and view the latest pushed state; it must never be
 //    blocked from seeing that state
 //  - observer does not need to see every state in sequence; it is OK for it to skip states
 //    [see below for more on this]
 //  - mutator must always be able to read/modify a state, it must never be blocked from reading or
 //    modifying state
 //  - reduce memcpy where possible
 //  - work well if the observer runs more frequently than the mutator,
 //    as is the case with fast mixer/normal mixer.
 // It is not a requirement to work well if the roles were reversed,
 // and the mutator were to run more frequently than the observer.
 // In this case, the mutator could get blocked waiting for a slot to fill up for
 // it to work with. This could be solved somewhat by increasing the depth of the queue, but it would
 // still limit the mutator to a finite number of changes before it would block.  A future
 // possibility, not implemented here, would be to allow the mutator to safely overwrite an already
 // pushed state. This could be done by the mutator overwriting mNext, but then being prepared to
 // read an mAck which is actually for the earlier mNext (since there is a race).

 // Solution:
 //  Let's call the fast mixer thread the "observer" and normal mixer thread the "mutator".
 //  We assume there is only a single observer and a single mutator; this is critical.
 //  Each state is of type <T>, and should contain only POD (Plain Old Data) and raw pointers, as
 //  memcpy() may be used to copy state, and the destructors are run in unpredictable order.
 //  The states in chronological order are: previous, current, next, and mutating:
 //      previous    read-only, observer can compare vs. current to see the subset that changed
 //      current     read-only, this is the primary state for observer
 //      next        read-only, when observer is ready to accept a new state it will shift it in:
 //                      previous = current
 //                      current = next
 //                  and the slot formerly used by previous is now available to the mutator.
 //      mutating    invisible to observer, read/write to mutator
 //  Initialization is tricky, especially for the observer.  If the observer starts execution
 //  before the mutator, there are no previous, current, or next states.  And even if the observer
 //  starts execution after the mutator, there is a next state but no previous or current states.
 //  To solve this, we'll have the observer idle until there is a next state,
 //  and it will have to deal with the case where there is no previous state.
 //  The states are stored in a shared FIFO queue represented using a circular array.
 //  The observer polls for mutations, and receives a new state pointer after a
 //  a mutation is pushed onto the queue.  To the observer, the state pointers are
 //  effectively in random order, that is the observer should not do address
 //  arithmetic on the state pointers.  However to the mutator, the state pointers
 //  are in a definite circular order.

 #include "Configuration.h"

 namespace android {

 #ifdef STATE_QUEUE_DUMP
 // The StateQueueObserverDump and StateQueueMutatorDump keep
 // a cache of StateQueue statistics that can be logged by dumpsys.
 // Each individual native word-sized field is accessed atomically.  But the
 // overall structure is non-atomic, that is there may be an inconsistency between fields.
 // No barriers or locks are used for either writing or reading.
 // Only POD types are permitted, and the contents shouldn't be trusted (i.e. do range checks).
 // It has a different lifetime than the StateQueue, and so it can't be a member of StateQueue.

 struct StateQueueObserverDump {
     StateQueueObserverDump() : mStateChanges(0) { }
     /*virtual*/ ~StateQueueObserverDump() { }
     unsigned    mStateChanges;    // incremented each time poll() detects a state change
     void        dump(int fd);
 };

 struct StateQueueMutatorDump {
     StateQueueMutatorDump() : mPushDirty(0), mPushAck(0), mBlockedSequence(0) { }
     /*virtual*/ ~StateQueueMutatorDump() { }
     unsigned    mPushDirty;       // incremented each time push() is called with a dirty state
     unsigned    mPushAck;         // incremented each time push(BLOCK_UNTIL_ACKED) is called
     unsigned    mBlockedSequence; // incremented before and after each time that push()
                                   // blocks for more than one PUSH_BLOCK_ACK_NS;
                                   // if odd, then mutator is currently blocked inside push()
     void        dump(int fd);
 };
 #endif

 // manages a FIFO queue of states
 template<typename T> class StateQueue {

 public:
             StateQueue();
     virtual ~StateQueue();

     // Observer APIs

     // Poll for a state change.  Returns a pointer to a read-only state,
     // or NULL if the state has not been initialized yet.
     // If a new state has not pushed by mutator since the previous poll,
     // then the returned pointer will be unchanged.
     // The previous state pointer is guaranteed to still be valid;
     // this allows the observer to diff the previous and new states.
     const T* poll();

     // Mutator APIs

     // Begin a mutation.  Returns a pointer to a read/write state, except the
     // first time it is called the state is write-only and _must_ be initialized.
     // Mutations cannot be nested.
     // If the state is dirty and has not been pushed onto the state queue yet, then
     // this new mutation will be squashed together with the previous one.
     T*      begin();

     // End the current mutation and indicate whether caller modified the state.
     // If didModify is true, then the state is marked dirty (in need of pushing).
     // There is no rollback option because modifications are done in place.
     // Does not automatically push the new state onto the state queue.
     void    end(bool didModify = true);

     // Push a new state, if any, out to the observer via the state queue.
     // For BLOCK_NEVER, returns:
     //      true if not dirty, or dirty and pushed successfully
     //      false if dirty and not pushed because that would block; remains dirty
     // For BLOCK_UNTIL_PUSHED and BLOCK_UNTIL_ACKED, always returns true.
     // No-op if there are no pending modifications (not dirty), except
     //      for BLOCK_UNTIL_ACKED it will wait until a prior push has been acknowledged.
     // Must not be called in the middle of a mutation.
     enum block_t {
         BLOCK_NEVER,        // do not block
         BLOCK_UNTIL_PUSHED, // block until there's a slot available for the push
         BLOCK_UNTIL_ACKED,  // also block until the push is acknowledged by the observer
     };
     bool    push(block_t block = BLOCK_NEVER);

     // Return whether the current state is dirty (modified and not pushed).
     bool    isDirty() const { return mIsDirty; }

 #ifdef STATE_QUEUE_DUMP
     // Register location of observer dump area
     void    setObserverDump(StateQueueObserverDump *dump)
             { mObserverDump = dump != NULL ? dump : &mObserverDummyDump; }

     // Register location of mutator dump area
     void    setMutatorDump(StateQueueMutatorDump *dump)
             { mMutatorDump = dump != NULL ? dump : &mMutatorDummyDump; }
 #endif

 private:
     static const unsigned kN = 4;       // values < 4 are not supported by this code
     T                 mStates[kN];      // written by mutator, read by observer

     // "volatile" is meaningless with SMP, but here it indicates that we're using atomic ops
     atomic_uintptr_t  mNext; // written by mutator to advance next, read by observer
     volatile const T* mAck;  // written by observer to acknowledge advance of next, read by mutator

     // only used by observer
     const T*          mCurrent;         // most recent value returned by poll()

     // only used by mutator
     T*                mMutating;        // where updates by mutator are done in place
     const T*          mExpecting;       // what the mutator expects mAck to be set to
     bool              mInMutation;      // whether we're currently in the middle of a mutation
     bool              mIsDirty;         // whether mutating state has been modified since last push
     bool              mIsInitialized;   // whether mutating state has been initialized yet

 #ifdef STATE_QUEUE_DUMP
     StateQueueObserverDump  mObserverDummyDump; // default area for observer dump if not set
     StateQueueObserverDump* mObserverDump;      // pointer to active observer dump, always non-NULL
     StateQueueMutatorDump   mMutatorDummyDump;  // default area for mutator dump if not set
     StateQueueMutatorDump*  mMutatorDump;       // pointer to active mutator dump, always non-NULL
 #endif

 };  // class StateQueue

 }   // namespace android

 #endif  // ANDROID_AUDIO_STATE_QUEUE_H
	/*
	* Copyright (C) 2012 The Android Open Source Project
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	#ifndef ANDROID_AUDIO_STATE_QUEUE_H
	#define ANDROID_AUDIO_STATE_QUEUE_H

	#include <stdatomic.h>

	// The state queue template class was originally driven by this use case / requirements:
	// There are two threads: a fast mixer, and a normal mixer, and they share state.
	// The interesting part of the shared state is a set of active fast tracks,
	// and the output HAL configuration (buffer size in frames, sample rate, etc.).
	// Fast mixer thread:
	// periodic with typical period < 10 ms
	// FIFO/RR scheduling policy and a low fixed priority
	// ok to block for bounded time using nanosleep() to achieve desired period
	// must not block on condition wait, mutex lock, atomic operation spin, I/O, etc.
	// under typical operations of mixing, writing, or adding/removing tracks
	// ok to block for unbounded time when the output HAL configuration changes,
	// and this may result in an audible artifact
	// needs read-only access to a recent stable state,
	// but not necessarily the most current one
	// only allocate and free memory when configuration changes
	// avoid conventional logging, as this is a form of I/O and could block
	// defer computation to other threads when feasible; for example
	// cycle times are collected by fast mixer thread but the floating-point
	// statistical calculations on these cycle times are computed by normal mixer
	// these requirements also apply to callouts such as AudioBufferProvider and VolumeProvider
	// Normal mixer thread:
	// periodic with typical period ~20 ms
	// SCHED_OTHER scheduling policy and nice priority == urgent audio
	// ok to block, but prefer to avoid as much as possible
	// needs read/write access to state
	// The normal mixer may need to temporarily suspend the fast mixer thread during mode changes.
	// It will do this using the state -- one of the fields tells the fast mixer to idle.

	// Additional requirements:
	// - observer must always be able to poll for and view the latest pushed state; it must never be
	// blocked from seeing that state
	// - observer does not need to see every state in sequence; it is OK for it to skip states
	// [see below for more on this]
	// - mutator must always be able to read/modify a state, it must never be blocked from reading or
	// modifying state
	// - reduce memcpy where possible
	// - work well if the observer runs more frequently than the mutator,
	// as is the case with fast mixer/normal mixer.
	// It is not a requirement to work well if the roles were reversed,
	// and the mutator were to run more frequently than the observer.
	// In this case, the mutator could get blocked waiting for a slot to fill up for
	// it to work with. This could be solved somewhat by increasing the depth of the queue, but it would
	// still limit the mutator to a finite number of changes before it would block. A future
	// possibility, not implemented here, would be to allow the mutator to safely overwrite an already
	// pushed state. This could be done by the mutator overwriting mNext, but then being prepared to
	// read an mAck which is actually for the earlier mNext (since there is a race).

	// Solution:
	// Let's call the fast mixer thread the "observer" and normal mixer thread the "mutator".
	// We assume there is only a single observer and a single mutator; this is critical.
	// Each state is of type <T>, and should contain only POD (Plain Old Data) and raw pointers, as
	// memcpy() may be used to copy state, and the destructors are run in unpredictable order.
	// The states in chronological order are: previous, current, next, and mutating:
	// previous read-only, observer can compare vs. current to see the subset that changed
	// current read-only, this is the primary state for observer
	// next read-only, when observer is ready to accept a new state it will shift it in:
	// previous = current
	// current = next
	// and the slot formerly used by previous is now available to the mutator.
	// mutating invisible to observer, read/write to mutator
	// Initialization is tricky, especially for the observer. If the observer starts execution
	// before the mutator, there are no previous, current, or next states. And even if the observer
	// starts execution after the mutator, there is a next state but no previous or current states.
	// To solve this, we'll have the observer idle until there is a next state,
	// and it will have to deal with the case where there is no previous state.
	// The states are stored in a shared FIFO queue represented using a circular array.
	// The observer polls for mutations, and receives a new state pointer after a
	// a mutation is pushed onto the queue. To the observer, the state pointers are
	// effectively in random order, that is the observer should not do address
	// arithmetic on the state pointers. However to the mutator, the state pointers
	// are in a definite circular order.

	#include "Configuration.h"

	namespace android {

	#ifdef STATE_QUEUE_DUMP
	// The StateQueueObserverDump and StateQueueMutatorDump keep
	// a cache of StateQueue statistics that can be logged by dumpsys.
	// Each individual native word-sized field is accessed atomically. But the
	// overall structure is non-atomic, that is there may be an inconsistency between fields.
	// No barriers or locks are used for either writing or reading.
	// Only POD types are permitted, and the contents shouldn't be trusted (i.e. do range checks).
	// It has a different lifetime than the StateQueue, and so it can't be a member of StateQueue.

	struct StateQueueObserverDump {
	StateQueueObserverDump() : mStateChanges(0) { }
	/virtual/ ~StateQueueObserverDump() { }
	unsigned mStateChanges; // incremented each time poll() detects a state change
	void dump(int fd);
	};

	struct StateQueueMutatorDump {
	StateQueueMutatorDump() : mPushDirty(0), mPushAck(0), mBlockedSequence(0) { }
	/virtual/ ~StateQueueMutatorDump() { }
	unsigned mPushDirty; // incremented each time push() is called with a dirty state
	unsigned mPushAck; // incremented each time push(BLOCK_UNTIL_ACKED) is called
	unsigned mBlockedSequence; // incremented before and after each time that push()
	// blocks for more than one PUSH_BLOCK_ACK_NS;
	// if odd, then mutator is currently blocked inside push()
	void dump(int fd);
	};
	#endif

	// manages a FIFO queue of states
	template<typename T> class StateQueue {

	public:
	StateQueue();
	virtual ~StateQueue();

	// Observer APIs

	// Poll for a state change. Returns a pointer to a read-only state,
	// or NULL if the state has not been initialized yet.
	// If a new state has not pushed by mutator since the previous poll,
	// then the returned pointer will be unchanged.
	// The previous state pointer is guaranteed to still be valid;
	// this allows the observer to diff the previous and new states.
	const T* poll();

	// Mutator APIs

	// Begin a mutation. Returns a pointer to a read/write state, except the
	// first time it is called the state is write-only and _must_ be initialized.
	// Mutations cannot be nested.
	// If the state is dirty and has not been pushed onto the state queue yet, then
	// this new mutation will be squashed together with the previous one.
	T* begin();

	// End the current mutation and indicate whether caller modified the state.
	// If didModify is true, then the state is marked dirty (in need of pushing).
	// There is no rollback option because modifications are done in place.
	// Does not automatically push the new state onto the state queue.
	void end(bool didModify = true);

	// Push a new state, if any, out to the observer via the state queue.
	// For BLOCK_NEVER, returns:
	// true if not dirty, or dirty and pushed successfully
	// false if dirty and not pushed because that would block; remains dirty
	// For BLOCK_UNTIL_PUSHED and BLOCK_UNTIL_ACKED, always returns true.
	// No-op if there are no pending modifications (not dirty), except
	// for BLOCK_UNTIL_ACKED it will wait until a prior push has been acknowledged.
	// Must not be called in the middle of a mutation.
	enum block_t {
	BLOCK_NEVER, // do not block
	BLOCK_UNTIL_PUSHED, // block until there's a slot available for the push
	BLOCK_UNTIL_ACKED, // also block until the push is acknowledged by the observer
	};
	bool push(block_t block = BLOCK_NEVER);

	// Return whether the current state is dirty (modified and not pushed).
	bool isDirty() const { return mIsDirty; }

	#ifdef STATE_QUEUE_DUMP
	// Register location of observer dump area
	void setObserverDump(StateQueueObserverDump *dump)
	{ mObserverDump = dump != NULL ? dump : &mObserverDummyDump; }

	// Register location of mutator dump area
	void setMutatorDump(StateQueueMutatorDump *dump)
	{ mMutatorDump = dump != NULL ? dump : &mMutatorDummyDump; }
	#endif

	private:
	static const unsigned kN = 4; // values < 4 are not supported by this code
	T mStates[kN]; // written by mutator, read by observer

	// "volatile" is meaningless with SMP, but here it indicates that we're using atomic ops
	atomic_uintptr_t mNext; // written by mutator to advance next, read by observer
	volatile const T* mAck; // written by observer to acknowledge advance of next, read by mutator

	// only used by observer
	const T* mCurrent; // most recent value returned by poll()

	// only used by mutator
	T* mMutating; // where updates by mutator are done in place
	const T* mExpecting; // what the mutator expects mAck to be set to
	bool mInMutation; // whether we're currently in the middle of a mutation
	bool mIsDirty; // whether mutating state has been modified since last push
	bool mIsInitialized; // whether mutating state has been initialized yet

	#ifdef STATE_QUEUE_DUMP
	StateQueueObserverDump mObserverDummyDump; // default area for observer dump if not set
	StateQueueObserverDump* mObserverDump; // pointer to active observer dump, always non-NULL
	StateQueueMutatorDump mMutatorDummyDump; // default area for mutator dump if not set
	StateQueueMutatorDump* mMutatorDump; // pointer to active mutator dump, always non-NULL
	#endif

	}; // class StateQueue

	} // namespace android

	#endif // ANDROID_AUDIO_STATE_QUEUE_H