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// Copyright 2009-2021 Intel Corporation
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// SPDX-License-Identifier: Apache-2.0
# include "taskschedulerinternal.h"
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# include "../math/emath.h"
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# include "../sys/sysinfo.h"
# include <algorithm>
namespace embree
{
RTC_NAMESPACE_BEGIN
static MutexSys g_mutex ;
size_t TaskScheduler : : g_numThreads = 0 ;
__thread TaskScheduler * TaskScheduler : : g_instance = nullptr ;
std : : vector < Ref < TaskScheduler > > g_instance_vector ;
__thread TaskScheduler : : Thread * TaskScheduler : : thread_local_thread = nullptr ;
TaskScheduler : : ThreadPool * TaskScheduler : : threadPool = nullptr ;
template < typename Predicate , typename Body >
__forceinline void TaskScheduler : : steal_loop ( Thread & thread , const Predicate & pred , const Body & body )
{
while ( true )
{
/*! some rounds that yield */
for ( size_t i = 0 ; i < 32 ; i + + )
{
/*! some spinning rounds */
const size_t threadCount = thread . threadCount ( ) ;
for ( size_t j = 0 ; j < 1024 ; j + = threadCount )
{
if ( ! pred ( ) ) return ;
if ( thread . scheduler - > steal_from_other_threads ( thread ) ) {
i = j = 0 ;
body ( ) ;
}
}
yield ( ) ;
}
}
}
/*! run this task */
void TaskScheduler : : Task : : run_internal ( Thread & thread ) // FIXME: avoid as many dll_exports as possible
{
/* try to run if not already stolen */
if ( try_switch_state ( INITIALIZED , DONE ) )
{
Task * prevTask = thread . task ;
thread . task = this ;
// -- GODOT start --
// try {
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// if (context->cancellingException == nullptr)
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closure - > execute ( ) ;
// } catch (...) {
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// if (context->cancellingException == nullptr)
// context->cancellingException = std::current_exception();
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// }
// -- GODOT end --
thread . task = prevTask ;
add_dependencies ( - 1 ) ;
}
/* steal until all dependencies have completed */
steal_loop ( thread ,
[ & ] ( ) { return dependencies > 0 ; } ,
[ & ] ( ) { while ( thread . tasks . execute_local_internal ( thread , this ) ) ; } ) ;
/* now signal our parent task that we are finished */
if ( parent )
parent - > add_dependencies ( - 1 ) ;
}
/*! run this task */
dll_export void TaskScheduler : : Task : : run ( Thread & thread ) {
run_internal ( thread ) ;
}
bool TaskScheduler : : TaskQueue : : execute_local_internal ( Thread & thread , Task * parent )
{
/* stop if we run out of local tasks or reach the waiting task */
if ( right = = 0 | | & tasks [ right - 1 ] = = parent )
return false ;
/* execute task */
size_t oldRight = right ;
tasks [ right - 1 ] . run_internal ( thread ) ;
if ( right ! = oldRight ) {
THROW_RUNTIME_ERROR ( " you have to wait for spawned subtasks " ) ;
}
/* pop task and closure from stack */
right - - ;
if ( tasks [ right ] . stackPtr ! = size_t ( - 1 ) )
stackPtr = tasks [ right ] . stackPtr ;
/* also move left pointer */
if ( left > = right ) left . store ( right . load ( ) ) ;
return right ! = 0 ;
}
dll_export bool TaskScheduler : : TaskQueue : : execute_local ( Thread & thread , Task * parent ) {
return execute_local_internal ( thread , parent ) ;
}
bool TaskScheduler : : TaskQueue : : steal ( Thread & thread )
{
size_t l = left ;
size_t r = right ;
if ( l < r )
{
l = left + + ;
if ( l > = r )
return false ;
}
else
return false ;
if ( ! tasks [ l ] . try_steal ( thread . tasks . tasks [ thread . tasks . right ] ) )
return false ;
thread . tasks . right + + ;
return true ;
}
/* we steal from the left */
size_t TaskScheduler : : TaskQueue : : getTaskSizeAtLeft ( )
{
if ( left > = right ) return 0 ;
return tasks [ left ] . N ;
}
void threadPoolFunction ( std : : pair < TaskScheduler : : ThreadPool * , size_t > * pair )
{
TaskScheduler : : ThreadPool * pool = pair - > first ;
size_t threadIndex = pair - > second ;
delete pair ;
pool - > thread_loop ( threadIndex ) ;
}
TaskScheduler : : ThreadPool : : ThreadPool ( bool set_affinity )
: numThreads ( 0 ) , numThreadsRunning ( 0 ) , set_affinity ( set_affinity ) , running ( false ) { }
dll_export void TaskScheduler : : ThreadPool : : startThreads ( )
{
if ( running ) return ;
setNumThreads ( numThreads , true ) ;
}
void TaskScheduler : : ThreadPool : : setNumThreads ( size_t newNumThreads , bool startThreads )
{
Lock < MutexSys > lock ( g_mutex ) ;
assert ( newNumThreads ) ;
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if ( newNumThreads = = std : : numeric_limits < size_t > : : max ( ) )
newNumThreads = ( size_t ) getNumberOfLogicalThreads ( ) ;
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numThreads = newNumThreads ;
if ( ! startThreads & & ! running ) return ;
running = true ;
size_t numThreadsActive = numThreadsRunning ;
mutex . lock ( ) ;
numThreadsRunning = newNumThreads ;
mutex . unlock ( ) ;
condition . notify_all ( ) ;
/* start new threads */
for ( size_t t = numThreadsActive ; t < numThreads ; t + + )
{
if ( t = = 0 ) continue ;
auto pair = new std : : pair < TaskScheduler : : ThreadPool * , size_t > ( this , t ) ;
threads . push_back ( createThread ( ( thread_func ) threadPoolFunction , pair , 4 * 1024 * 1024 , set_affinity ? t : - 1 ) ) ;
}
/* stop some threads if we reduce the number of threads */
for ( ssize_t t = numThreadsActive - 1 ; t > = ssize_t ( numThreadsRunning ) ; t - - ) {
if ( t = = 0 ) continue ;
embree : : join ( threads . back ( ) ) ;
threads . pop_back ( ) ;
}
}
TaskScheduler : : ThreadPool : : ~ ThreadPool ( )
{
/* leave all taskschedulers */
mutex . lock ( ) ;
numThreadsRunning = 0 ;
mutex . unlock ( ) ;
condition . notify_all ( ) ;
/* wait for threads to terminate */
for ( size_t i = 0 ; i < threads . size ( ) ; i + + )
embree : : join ( threads [ i ] ) ;
}
dll_export void TaskScheduler : : ThreadPool : : add ( const Ref < TaskScheduler > & scheduler )
{
mutex . lock ( ) ;
schedulers . push_back ( scheduler ) ;
mutex . unlock ( ) ;
condition . notify_all ( ) ;
}
dll_export void TaskScheduler : : ThreadPool : : remove ( const Ref < TaskScheduler > & scheduler )
{
Lock < MutexSys > lock ( mutex ) ;
for ( std : : list < Ref < TaskScheduler > > : : iterator it = schedulers . begin ( ) ; it ! = schedulers . end ( ) ; it + + ) {
if ( scheduler = = * it ) {
schedulers . erase ( it ) ;
return ;
}
}
}
void TaskScheduler : : ThreadPool : : thread_loop ( size_t globalThreadIndex )
{
while ( globalThreadIndex < numThreadsRunning )
{
Ref < TaskScheduler > scheduler = NULL ;
ssize_t threadIndex = - 1 ;
{
Lock < MutexSys > lock ( mutex ) ;
condition . wait ( mutex , [ & ] ( ) { return globalThreadIndex > = numThreadsRunning | | ! schedulers . empty ( ) ; } ) ;
if ( globalThreadIndex > = numThreadsRunning ) break ;
scheduler = schedulers . front ( ) ;
threadIndex = scheduler - > allocThreadIndex ( ) ;
}
scheduler - > thread_loop ( threadIndex ) ;
}
}
TaskScheduler : : TaskScheduler ( )
: threadCounter ( 0 ) , anyTasksRunning ( 0 ) , hasRootTask ( false )
{
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assert ( threadPool ) ;
threadLocal . resize ( 2 * TaskScheduler : : threadCount ( ) ) ; // FIXME: this has to be 2x as in the compatibility join mode with rtcCommitScene the worker threads also join. When disallowing rtcCommitScene to join a build we can remove the 2x.
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for ( size_t i = 0 ; i < threadLocal . size ( ) ; i + + )
threadLocal [ i ] . store ( nullptr ) ;
}
TaskScheduler : : ~ TaskScheduler ( )
{
assert ( threadCounter = = 0 ) ;
}
dll_export size_t TaskScheduler : : threadID ( )
{
Thread * thread = TaskScheduler : : thread ( ) ;
if ( thread ) return thread - > threadIndex ;
else return 0 ;
}
dll_export size_t TaskScheduler : : threadIndex ( )
{
Thread * thread = TaskScheduler : : thread ( ) ;
if ( thread ) return thread - > threadIndex ;
else return 0 ;
}
dll_export size_t TaskScheduler : : threadCount ( ) {
return threadPool - > size ( ) ;
}
dll_export TaskScheduler * TaskScheduler : : instance ( )
{
if ( g_instance = = NULL ) {
Lock < MutexSys > lock ( g_mutex ) ;
g_instance = new TaskScheduler ;
g_instance_vector . push_back ( g_instance ) ;
}
return g_instance ;
}
void TaskScheduler : : create ( size_t numThreads , bool set_affinity , bool start_threads )
{
if ( ! threadPool ) threadPool = new TaskScheduler : : ThreadPool ( set_affinity ) ;
threadPool - > setNumThreads ( numThreads , start_threads ) ;
}
void TaskScheduler : : destroy ( ) {
delete threadPool ; threadPool = nullptr ;
}
dll_export ssize_t TaskScheduler : : allocThreadIndex ( )
{
size_t threadIndex = threadCounter + + ;
assert ( threadIndex < threadLocal . size ( ) ) ;
return threadIndex ;
}
void TaskScheduler : : join ( )
{
mutex . lock ( ) ;
size_t threadIndex = allocThreadIndex ( ) ;
condition . wait ( mutex , [ & ] ( ) { return hasRootTask . load ( ) ; } ) ;
mutex . unlock ( ) ;
thread_loop ( threadIndex ) ;
}
void TaskScheduler : : reset ( ) {
hasRootTask = false ;
}
void TaskScheduler : : wait_for_threads ( size_t threadCount )
{
while ( threadCounter < threadCount - 1 )
pause_cpu ( ) ;
}
dll_export TaskScheduler : : Thread * TaskScheduler : : thread ( ) {
return thread_local_thread ;
}
dll_export TaskScheduler : : Thread * TaskScheduler : : swapThread ( Thread * thread )
{
Thread * old = thread_local_thread ;
thread_local_thread = thread ;
return old ;
}
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dll_export void TaskScheduler : : wait ( )
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{
Thread * thread = TaskScheduler : : thread ( ) ;
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if ( thread = = nullptr )
return ;
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while ( thread - > tasks . execute_local_internal ( * thread , thread - > task ) ) { } ;
}
void TaskScheduler : : thread_loop ( size_t threadIndex )
{
/* allocate thread structure */
std : : unique_ptr < Thread > mthread ( new Thread ( threadIndex , this ) ) ; // too large for stack allocation
Thread & thread = * mthread ;
threadLocal [ threadIndex ] . store ( & thread ) ;
Thread * oldThread = swapThread ( & thread ) ;
/* main thread loop */
while ( anyTasksRunning )
{
steal_loop ( thread ,
[ & ] ( ) { return anyTasksRunning > 0 ; } ,
[ & ] ( ) {
anyTasksRunning + + ;
while ( thread . tasks . execute_local_internal ( thread , nullptr ) ) ;
anyTasksRunning - - ;
} ) ;
}
threadLocal [ threadIndex ] . store ( nullptr ) ;
swapThread ( oldThread ) ;
/* wait for all threads to terminate */
threadCounter - - ;
# if defined(__WIN32__)
size_t loopIndex = 1 ;
# endif
# define LOOP_YIELD_THRESHOLD (4096)
while ( threadCounter > 0 ) {
# if defined(__WIN32__)
if ( ( loopIndex % LOOP_YIELD_THRESHOLD ) = = 0 )
yield ( ) ;
else
_mm_pause ( ) ;
loopIndex + + ;
# else
yield ( ) ;
# endif
}
}
bool TaskScheduler : : steal_from_other_threads ( Thread & thread )
{
const size_t threadIndex = thread . threadIndex ;
const size_t threadCount = this - > threadCounter ;
for ( size_t i = 1 ; i < threadCount ; i + + )
{
pause_cpu ( 32 ) ;
size_t otherThreadIndex = threadIndex + i ;
if ( otherThreadIndex > = threadCount ) otherThreadIndex - = threadCount ;
Thread * othread = threadLocal [ otherThreadIndex ] . load ( ) ;
if ( ! othread )
continue ;
if ( othread - > tasks . steal ( thread ) )
return true ;
}
return false ;
}
dll_export void TaskScheduler : : startThreads ( ) {
threadPool - > startThreads ( ) ;
}
dll_export void TaskScheduler : : addScheduler ( const Ref < TaskScheduler > & scheduler ) {
threadPool - > add ( scheduler ) ;
}
dll_export void TaskScheduler : : removeScheduler ( const Ref < TaskScheduler > & scheduler ) {
threadPool - > remove ( scheduler ) ;
}
RTC_NAMESPACE_END
}