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/*
* ThreadHelper . actor . h
*
* This source file is part of the FoundationDB open source project
*
* Copyright 2013 - 2018 Apple Inc . and the FoundationDB project authors
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*
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* 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
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*
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* http : //www.apache.org/licenses/LICENSE-2.0
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*
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* 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 .
*/
# pragma once
// When actually compiled (NO_INTELLISENSE), include the generated
// version of this file. In intellisense use the source version.
# if defined(NO_INTELLISENSE) && !defined(FLOW_THREADHELPER_ACTOR_G_H)
# define FLOW_THREADHELPER_ACTOR_G_H
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# include "flow/ThreadHelper.actor.g.h"
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# elif !defined(FLOW_THREADHELPER_ACTOR_H)
# define FLOW_THREADHELPER_ACTOR_H
# include "flow/flow.h"
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# include "flow/actorcompiler.h" // This must be the last #include.
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// template <class F>
// void onMainThreadVoid( F f ) {
// Promise<Void> signal;
// doOnMainThreadVoid( signal.getFuture(), f );
// g_network->onMainThread( std::move(signal), TaskDefaultOnMainThread );
// }
template < class F >
void onMainThreadVoid ( F f , Error * err , int taskID = TaskDefaultOnMainThread ) {
Promise < Void > signal ;
doOnMainThreadVoid ( signal . getFuture ( ) , f , err ) ;
g_network - > onMainThread ( std : : move ( signal ) , taskID ) ;
}
struct ThreadCallback {
virtual bool canFire ( int notMadeActive ) = 0 ;
virtual void fire ( const Void & unused , int & userParam ) = 0 ;
virtual void error ( const Error & , int & userParam ) = 0 ;
virtual ThreadCallback * addCallback ( ThreadCallback * cb ) ;
virtual bool contains ( ThreadCallback * cb ) {
return false ;
}
virtual void clearCallback ( ThreadCallback * cb ) {
// If this is the only registered callback this will be called with (possibly) arbitrary pointers
}
virtual void destroy ( ) {
UNSTOPPABLE_ASSERT ( false ) ;
}
virtual bool isMultiCallback ( ) const {
return false ;
}
} ;
class ThreadMultiCallback : public ThreadCallback , public FastAllocated < ThreadMultiCallback > {
public :
ThreadMultiCallback ( ) { }
virtual ThreadCallback * addCallback ( ThreadCallback * callback ) {
UNSTOPPABLE_ASSERT ( callbackMap . count ( callback ) = = 0 ) ; //May be triggered by a waitForAll on a vector with the same future in it more than once
callbackMap [ callback ] = callbacks . size ( ) ;
callbacks . push_back ( callback ) ;
return ( ThreadCallback * ) this ;
}
virtual bool contains ( ThreadCallback * cb ) {
return callbackMap . count ( cb ) ! = 0 ;
}
virtual void clearCallback ( ThreadCallback * callback ) {
auto it = callbackMap . find ( callback ) ;
if ( it = = callbackMap . end ( ) )
return ;
UNSTOPPABLE_ASSERT ( it - > second < callbacks . size ( ) & & it - > second > = 0 ) ;
if ( it - > second ! = callbacks . size ( ) - 1 ) {
callbacks [ it - > second ] = callbacks . back ( ) ;
callbackMap [ callbacks [ it - > second ] ] = it - > second ;
}
callbacks . pop_back ( ) ;
callbackMap . erase ( it ) ;
}
virtual bool canFire ( int notMadeActive ) {
return true ;
}
virtual void fire ( const Void & value , int & loopDepth ) {
if ( callbacks . size ( ) > 10000 )
TraceEvent ( SevWarn , " LargeMultiCallback " ) . detail ( " CallbacksSize " , callbacks . size ( ) ) ;
UNSTOPPABLE_ASSERT ( loopDepth = = 0 ) ;
while ( callbacks . size ( ) ) {
auto cb = callbacks . back ( ) ;
callbacks . pop_back ( ) ;
callbackMap . erase ( cb ) ;
if ( cb - > canFire ( 0 ) ) {
int ld = 0 ;
cb - > fire ( value , ld ) ;
}
}
}
virtual void error ( const Error & err , int & loopDepth ) {
if ( callbacks . size ( ) > 10000 )
TraceEvent ( SevWarn , " LargeMultiCallback " ) . detail ( " CallbacksSize " , callbacks . size ( ) ) ;
UNSTOPPABLE_ASSERT ( loopDepth = = 0 ) ;
while ( callbacks . size ( ) ) {
auto cb = callbacks . back ( ) ;
callbacks . pop_back ( ) ;
callbackMap . erase ( cb ) ;
if ( cb - > canFire ( 0 ) ) {
int ld = 0 ;
cb - > error ( err , ld ) ;
}
}
}
virtual void destroy ( ) {
UNSTOPPABLE_ASSERT ( callbacks . empty ( ) ) ;
delete this ;
}
virtual bool isMultiCallback ( ) const {
return true ;
}
private :
std : : vector < ThreadCallback * > callbacks ;
std : : unordered_map < ThreadCallback * , int > callbackMap ;
} ;
struct SetCallbackResult {
enum Result { FIRED , CANNOT_FIRE , CALLBACK_SET } ;
} ;
class ThreadSingleAssignmentVarBase {
public :
enum Status { Unset , NeverSet , Set , ErrorSet } ; // order is important
// volatile long referenceCount;
ThreadSpinLock mutex ;
Status status ;
Error error ;
ThreadCallback * callback ;
bool isReady ( ) {
ThreadSpinLockHolder holder ( mutex ) ;
return isReadyUnsafe ( ) ;
}
bool isError ( ) {
ThreadSpinLockHolder holder ( mutex ) ;
return isErrorUnsafe ( ) ;
}
int getErrorCode ( ) {
ThreadSpinLockHolder holder ( mutex ) ;
if ( ! isReadyUnsafe ( ) ) return error_code_future_not_set ;
if ( ! isErrorUnsafe ( ) ) return error_code_success ;
return error . code ( ) ;
}
bool canBeSet ( ) {
ThreadSpinLockHolder holder ( mutex ) ;
return canBeSetUnsafe ( ) ;
}
class BlockCallback : public ThreadCallback {
public :
Event ev ;
BlockCallback ( ThreadSingleAssignmentVarBase & sav ) { int ignore = 0 ; sav . callOrSetAsCallback ( this , ignore , 0 ) ; ev . block ( ) ; }
virtual bool canFire ( int notMadeActive ) { return true ; }
virtual void fire ( const Void & unused , int & userParam ) { ev . set ( ) ; }
virtual void error ( const Error & , int & userParam ) { ev . set ( ) ; }
} ;
void blockUntilReady ( ) {
if ( isReadyUnsafe ( ) ) {
ThreadSpinLockHolder holder ( mutex ) ;
ASSERT ( isReadyUnsafe ( ) ) ;
}
else {
BlockCallback cb ( * this ) ;
}
}
ThreadSingleAssignmentVarBase ( ) : status ( Unset ) , callback ( NULL ) , valueReferenceCount ( 0 ) { } //, referenceCount(1) {}
~ ThreadSingleAssignmentVarBase ( ) {
this - > mutex . assertNotEntered ( ) ;
if ( callback )
callback - > destroy ( ) ;
}
virtual void addref ( ) = 0 ;
virtual void delref ( ) = 0 ;
void send ( Never ) {
if ( TRACE_SAMPLE ( ) ) TraceEvent ( SevSample , " Promise_sendNever " ) ;
ThreadSpinLockHolder holder ( mutex ) ;
if ( ! canBeSetUnsafe ( ) )
ASSERT ( false ) ; // Promise fulfilled twice
this - > status = NeverSet ;
}
void sendError ( const Error & err ) {
if ( TRACE_SAMPLE ( ) ) TraceEvent ( SevSample , " Promise_sendError " ) . detail ( " ErrorCode " , err . code ( ) ) ;
this - > mutex . enter ( ) ;
if ( ! canBeSetUnsafe ( ) ) {
this - > mutex . leave ( ) ;
ASSERT ( false ) ; // Promise fulfilled twice
}
error = err ;
status = ErrorSet ;
if ( ! callback ) {
this - > mutex . leave ( ) ;
return ;
}
auto func = callback ;
if ( ! callback - > isMultiCallback ( ) )
callback = NULL ;
if ( ! func - > canFire ( 0 ) ) {
this - > mutex . leave ( ) ;
} else {
this - > mutex . leave ( ) ;
//Thread safe because status is now ErrorSet and callback is NULL, meaning than callback cannot change
int userParam = 0 ;
func - > error ( err , userParam ) ;
}
}
SetCallbackResult : : Result callOrSetAsCallback ( ThreadCallback * callback , int & userParam1 , int notMadeActive ) {
this - > mutex . enter ( ) ;
if ( isReadyUnsafe ( ) ) {
if ( callback - > canFire ( notMadeActive ) ) {
this - > mutex . leave ( ) ;
//Thread safe because the Future is ready, meaning that status and this->error will not change
if ( status = = ErrorSet ) {
auto error = this - > error ; // Since callback might free this
callback - > error ( error , userParam1 ) ;
} else {
callback - > fire ( Void ( ) , userParam1 ) ;
}
return SetCallbackResult : : FIRED ;
} else {
this - > mutex . leave ( ) ;
return SetCallbackResult : : CANNOT_FIRE ;
}
} else {
if ( this - > callback )
this - > callback = this - > callback - > addCallback ( callback ) ;
else
this - > callback = callback ;
this - > mutex . leave ( ) ;
return SetCallbackResult : : CALLBACK_SET ;
}
}
// If this function returns false, then this SAV has already been set and the callback has been or will be called.
// If this function returns true, then the callback has not and will not be called by this SAV (unless it is set later).
// This doesn't clear callbacks that are nested multiple levels inside of multi-callbacks
bool clearCallback ( ThreadCallback * cb ) {
this - > mutex . enter ( ) ;
//If another thread is calling fire in send/sendError, it would be unsafe to clear the callback
if ( isReadyUnsafe ( ) ) {
this - > mutex . leave ( ) ;
return false ;
}
// Only clear the callback if it belongs to the caller, because
// another actor could be waiting on it now!
if ( callback = = cb )
callback = NULL ;
else if ( callback ! = NULL )
callback - > clearCallback ( cb ) ;
this - > mutex . leave ( ) ;
return true ;
}
void setCancel ( Future < Void > & & cf ) {
cancelFuture = std : : move ( cf ) ;
}
virtual void cancel ( ) {
// Cancels the action and decrements the reference count by 1
// The if statement is just an optimization. It's ok if we take the wrong path due to a race
if ( isReadyUnsafe ( ) )
delref ( ) ;
else
onMainThreadVoid ( [ this ] ( ) { this - > cancelFuture . cancel ( ) ; this - > delref ( ) ; } , NULL ) ;
}
void releaseMemory ( ) {
ThreadSpinLockHolder holder ( mutex ) ;
if ( - - valueReferenceCount = = 0 )
cleanupUnsafe ( ) ;
}
private :
Future < Void > cancelFuture ;
int32_t valueReferenceCount ;
protected :
bool isReadyUnsafe ( ) const { return status > = Set ; }
bool isErrorUnsafe ( ) const { return status = = ErrorSet ; }
bool canBeSetUnsafe ( ) const { return status = = Unset ; }
void addValueReferenceUnsafe ( ) {
+ + valueReferenceCount ;
}
virtual void cleanupUnsafe ( ) {
if ( status ! = ErrorSet ) {
error = future_released ( ) ;
status = ErrorSet ;
}
valueReferenceCount = 0 ;
this - > addref ( ) ;
cancel ( ) ;
}
} ;
template < class T >
class ThreadSingleAssignmentVar : public ThreadSingleAssignmentVarBase , /* public FastAllocated<ThreadSingleAssignmentVar<T>>,*/ public ThreadSafeReferenceCounted < ThreadSingleAssignmentVar < T > >
{
public :
virtual ~ ThreadSingleAssignmentVar ( ) { }
T value ;
T get ( ) {
ThreadSpinLockHolder holder ( mutex ) ;
if ( ! isReadyUnsafe ( ) )
throw future_not_set ( ) ;
if ( isErrorUnsafe ( ) )
throw error ;
addValueReferenceUnsafe ( ) ;
return value ;
}
virtual void addref ( ) {
ThreadSafeReferenceCounted < ThreadSingleAssignmentVar < T > > : : addref ( ) ;
}
virtual void delref ( ) {
ThreadSafeReferenceCounted < ThreadSingleAssignmentVar < T > > : : delref ( ) ;
}
void send ( const T & value ) {
if ( TRACE_SAMPLE ( ) ) TraceEvent ( SevSample , " Promise_send " ) ;
this - > mutex . enter ( ) ;
if ( ! canBeSetUnsafe ( ) ) {
this - > mutex . leave ( ) ;
ASSERT ( false ) ; // Promise fulfilled twice
}
this - > value = value ; //< Danger: polymorphic operation inside lock
this - > status = Set ;
if ( ! callback ) {
this - > mutex . leave ( ) ;
return ;
}
auto func = callback ;
if ( ! callback - > isMultiCallback ( ) )
callback = NULL ;
if ( ! func - > canFire ( 0 ) ) {
this - > mutex . leave ( ) ;
} else {
this - > mutex . leave ( ) ;
//Thread safe because status is now Set and callback is NULL, meaning than callback cannot change
int userParam = 0 ;
func - > fire ( Void ( ) , userParam ) ;
}
}
virtual void cleanupUnsafe ( ) {
value = T ( ) ;
ThreadSingleAssignmentVarBase : : cleanupUnsafe ( ) ;
}
} ;
template < class T >
class ThreadFuture
{
public :
T get ( ) { return sav - > get ( ) ; }
T getBlocking ( ) {
sav - > blockUntilReady ( ) ;
return sav - > get ( ) ;
}
void blockUntilReady ( ) {
sav - > blockUntilReady ( ) ;
}
bool isValid ( ) const {
return sav ! = 0 ;
}
bool isReady ( ) {
return sav - > isReady ( ) ;
}
bool isError ( ) {
return sav - > isError ( ) ;
}
Error & getError ( ) {
if ( ! isError ( ) )
throw future_not_error ( ) ;
return sav - > error ;
}
SetCallbackResult : : Result callOrSetAsCallback ( ThreadCallback * callback , int & userParam1 , int notMadeActive ) {
return sav - > callOrSetAsCallback ( callback , userParam1 , notMadeActive ) ;
}
bool clearCallback ( ThreadCallback * cb ) {
return sav - > clearCallback ( cb ) ;
}
void cancel ( ) {
extractPtr ( ) - > cancel ( ) ;
}
ThreadFuture ( ) : sav ( 0 ) { }
explicit ThreadFuture ( ThreadSingleAssignmentVar < T > * sav ) : sav ( sav ) {
// sav->addref();
}
ThreadFuture ( const ThreadFuture < T > & rhs ) : sav ( rhs . sav ) {
if ( sav ) sav - > addref ( ) ;
}
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ThreadFuture ( ThreadFuture < T > & & rhs ) BOOST_NOEXCEPT : sav ( rhs . sav ) {
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rhs . sav = 0 ;
}
ThreadFuture ( const T & presentValue )
: sav ( new ThreadSingleAssignmentVar < T > ( ) )
{
sav - > send ( presentValue ) ;
}
ThreadFuture ( Never )
: sav ( new ThreadSingleAssignmentVar < T > ( ) )
{
}
ThreadFuture ( const Error & error )
: sav ( new ThreadSingleAssignmentVar < T > ( ) )
{
sav - > sendError ( error ) ;
}
~ ThreadFuture ( ) {
if ( sav ) sav - > delref ( ) ;
}
void operator = ( const ThreadFuture < T > & rhs ) {
if ( rhs . sav ) rhs . sav - > addref ( ) ;
if ( sav ) sav - > delref ( ) ;
sav = rhs . sav ;
}
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void operator = ( ThreadFuture < T > & & rhs ) BOOST_NOEXCEPT {
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if ( sav ! = rhs . sav ) {
if ( sav ) sav - > delref ( ) ;
sav = rhs . sav ;
rhs . sav = 0 ;
}
}
bool operator = = ( const ThreadFuture & rhs ) { return rhs . sav = = sav ; }
bool operator ! = ( const ThreadFuture & rhs ) { return rhs . sav ! = sav ; }
ThreadSingleAssignmentVarBase * getPtr ( ) const { return sav ; }
ThreadSingleAssignmentVarBase * extractPtr ( ) { auto * p = sav ; sav = NULL ; return p ; }
private :
ThreadSingleAssignmentVar < T > * sav ;
} ;
//A callback class used to convert a ThreadFuture into a Future
template < class T >
struct CompletionCallback : public ThreadCallback , ReferenceCounted < CompletionCallback < T > > {
//The thread future being waited on
ThreadFuture < T > threadFuture ;
//The promise whose future we are triggering when this callback gets called
Promise < T > promise ;
//Unused
int userParam ;
//Holds own reference to prevent deletion until callback is fired
Reference < CompletionCallback < T > > self ;
CompletionCallback ( ThreadFuture < T > threadFuture ) {
this - > threadFuture = threadFuture ;
}
bool canFire ( int notMadeActive ) {
return true ;
}
//Trigger the promise
void fire ( const Void & unused , int & userParam ) {
promise . send ( threadFuture . get ( ) ) ;
self . clear ( ) ;
}
//Send the error through the promise
void error ( const Error & e , int & userParam ) {
promise . sendError ( e ) ;
self . clear ( ) ;
}
} ;
//Converts a ThreadFuture into a Future
//WARNING: This is not actually thread safe! It can only be safely used from the main thread, on futures which are being set on the main thread
//FIXME: does not support cancellation
template < class T >
Future < T > unsafeThreadFutureToFuture ( ThreadFuture < T > threadFuture ) {
Reference < CompletionCallback < T > > callback = Reference < CompletionCallback < T > > ( new CompletionCallback < T > ( threadFuture ) ) ;
callback - > self = callback ;
threadFuture . callOrSetAsCallback ( callback . getPtr ( ) , callback - > userParam , 0 ) ;
return callback - > promise . getFuture ( ) ;
}
ACTOR template < class R , class F > Future < Void > doOnMainThread ( Future < Void > signal , F f , ThreadSingleAssignmentVar < R > * result ) {
try {
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wait ( signal ) ;
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R r = wait ( f ( ) ) ;
result - > send ( r ) ;
} catch ( Error & e ) {
if ( ! result - > canBeSet ( ) ) {
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TraceEvent ( SevError , " OnMainThreadSetTwice " ) . error ( e , true ) ;
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}
result - > sendError ( e ) ;
}
ThreadFuture < R > destroyResultAfterReturning ( result ) ; // Call result->delref(), but only after our return promise is no longer referenced on this thread
return Void ( ) ;
}
ACTOR template < class F > void doOnMainThreadVoid ( Future < Void > signal , F f , Error * err ) {
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wait ( signal ) ;
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if ( err & & err - > code ( ) ! = invalid_error_code )
return ;
try {
f ( ) ;
} catch ( Error & e ) {
if ( err )
* err = e ;
}
}
template < class F > ThreadFuture < decltype ( fake < F > ( ) ( ) . getValue ( ) ) > onMainThread ( F f ) {
Promise < Void > signal ;
auto returnValue = new ThreadSingleAssignmentVar < decltype ( fake < F > ( ) ( ) . getValue ( ) ) > ( ) ;
returnValue - > addref ( ) ; // For the ThreadFuture we return
Future < Void > cancelFuture = doOnMainThread < decltype ( fake < F > ( ) ( ) . getValue ( ) ) , F > ( signal . getFuture ( ) , f , returnValue ) ;
returnValue - > setCancel ( std : : move ( cancelFuture ) ) ;
g_network - > onMainThread ( std : : move ( signal ) , TaskDefaultOnMainThread ) ;
return ThreadFuture < decltype ( fake < F > ( ) ( ) . getValue ( ) ) > ( returnValue ) ;
}
template < class V >
class ThreadSafeAsyncVar : NonCopyable , public ThreadSafeReferenceCounted < ThreadSafeAsyncVar < V > > {
public :
struct State {
State ( V value , ThreadFuture < Void > onChange ) : value ( value ) , onChange ( onChange ) { }
V value ;
ThreadFuture < Void > onChange ;
} ;
ThreadSafeAsyncVar ( ) : value ( ) , nextChange ( new ThreadSingleAssignmentVar < Void > ( ) ) { }
ThreadSafeAsyncVar ( V const & v ) : value ( v ) , nextChange ( new ThreadSingleAssignmentVar < Void > ( ) ) { }
State get ( ) {
ThreadSpinLockHolder holder ( lock ) ;
nextChange - > addref ( ) ;
return State ( value , ThreadFuture < Void > ( nextChange . getPtr ( ) ) ) ;
}
void set ( V const & v , bool triggerIfSame = false ) {
Reference < ThreadSingleAssignmentVar < Void > > trigger ( new ThreadSingleAssignmentVar < Void > ( ) ) ;
lock . enter ( ) ;
bool changed = this - > value ! = v ;
if ( changed | | triggerIfSame ) {
std : : swap ( this - > nextChange , trigger ) ;
this - > value = v ;
}
lock . leave ( ) ;
if ( changed | | triggerIfSame ) {
trigger - > send ( Void ( ) ) ;
}
}
private :
V value ;
Reference < ThreadSingleAssignmentVar < Void > > nextChange ;
ThreadSpinLock lock ;
} ;
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# include "flow/unactorcompiler.h"
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# endif