src/optimizing-compiler-thread.cc - platform/external/chromium_org/v8 - Git at Google

 // Copyright 2012 the V8 project authors. All rights reserved.
 // Redistribution and use in source and binary forms, with or without
 // modification, are permitted provided that the following conditions are
 // met:
 //
 //     * Redistributions of source code must retain the above copyright
 //       notice, this list of conditions and the following disclaimer.
 //     * Redistributions in binary form must reproduce the above
 //       copyright notice, this list of conditions and the following
 //       disclaimer in the documentation and/or other materials provided
 //       with the distribution.
 //     * Neither the name of Google Inc. nor the names of its
 //       contributors may be used to endorse or promote products derived
 //       from this software without specific prior written permission.
 //
 // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
 // "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
 // LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
 // A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
 // OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
 // SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
 // LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
 // DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
 // THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
 // (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
 // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

 #include "optimizing-compiler-thread.h"

 #include "v8.h"

 #include "full-codegen.h"
 #include "hydrogen.h"
 #include "isolate.h"
 #include "v8threads.h"

 namespace v8 {
 namespace internal {

 OptimizingCompilerThread::~OptimizingCompilerThread() {
   ASSERT_EQ(0, input_queue_length_);
   DeleteArray(input_queue_);
   if (FLAG_concurrent_osr) {
 #ifdef DEBUG
     for (int i = 0; i < osr_buffer_capacity_; i++) {
       CHECK_EQ(NULL, osr_buffer_[i]);
     }
 #endif
     DeleteArray(osr_buffer_);
   }
 }


 void OptimizingCompilerThread::Run() {
 #ifdef DEBUG
   { LockGuard<Mutex> lock_guard(&thread_id_mutex_);
     thread_id_ = ThreadId::Current().ToInteger();
   }
 #endif
   Isolate::SetIsolateThreadLocals(isolate_, NULL);
   DisallowHeapAllocation no_allocation;
   DisallowHandleAllocation no_handles;
   DisallowHandleDereference no_deref;

   ElapsedTimer total_timer;
   if (FLAG_trace_concurrent_recompilation) total_timer.Start();

   while (true) {
     input_queue_semaphore_.Wait();
     Logger::TimerEventScope timer(
         isolate_, Logger::TimerEventScope::v8_recompile_concurrent);

     if (FLAG_concurrent_recompilation_delay != 0) {
       OS::Sleep(FLAG_concurrent_recompilation_delay);
     }

     switch (static_cast<StopFlag>(Acquire_Load(&stop_thread_))) {
       case CONTINUE:
         break;
       case STOP:
         if (FLAG_trace_concurrent_recompilation) {
           time_spent_total_ = total_timer.Elapsed();
         }
         stop_semaphore_.Signal();
         return;
       case FLUSH:
         // The main thread is blocked, waiting for the stop semaphore.
         { AllowHandleDereference allow_handle_dereference;
           FlushInputQueue(true);
         }
         Release_Store(&stop_thread_, static_cast<AtomicWord>(CONTINUE));
         stop_semaphore_.Signal();
         // Return to start of consumer loop.
         continue;
     }

     ElapsedTimer compiling_timer;
     if (FLAG_trace_concurrent_recompilation) compiling_timer.Start();

     CompileNext();

     if (FLAG_trace_concurrent_recompilation) {
       time_spent_compiling_ += compiling_timer.Elapsed();
     }
   }
 }


 RecompileJob* OptimizingCompilerThread::NextInput() {
   LockGuard<Mutex> access_input_queue_(&input_queue_mutex_);
   if (input_queue_length_ == 0) return NULL;
   RecompileJob* job = input_queue_[InputQueueIndex(0)];
   ASSERT_NE(NULL, job);
   input_queue_shift_ = InputQueueIndex(1);
   input_queue_length_--;
   return job;
 }


 void OptimizingCompilerThread::CompileNext() {
   RecompileJob* job = NextInput();
   ASSERT_NE(NULL, job);

   // The function may have already been optimized by OSR.  Simply continue.
   RecompileJob::Status status = job->OptimizeGraph();
   USE(status);   // Prevent an unused-variable error in release mode.
   ASSERT(status != RecompileJob::FAILED);

   // The function may have already been optimized by OSR.  Simply continue.
   // Use a mutex to make sure that functions marked for install
   // are always also queued.
   output_queue_.Enqueue(job);
   isolate_->stack_guard()->RequestInstallCode();
 }


 static void DisposeRecompileJob(RecompileJob* job,
                                 bool restore_function_code) {
   // The recompile job is allocated in the CompilationInfo's zone.
   CompilationInfo* info = job->info();
   if (restore_function_code) {
     if (info->is_osr()) {
       if (!job->IsWaitingForInstall()) BackEdgeTable::RemoveStackCheck(info);
     } else {
       Handle<JSFunction> function = info->closure();
       function->ReplaceCode(function->shared()->code());
     }
   }
   delete info;
 }


 void OptimizingCompilerThread::FlushInputQueue(bool restore_function_code) {
   RecompileJob* job;
   while ((job = NextInput())) {
     // This should not block, since we have one signal on the input queue
     // semaphore corresponding to each element in the input queue.
     input_queue_semaphore_.Wait();
     // OSR jobs are dealt with separately.
     if (!job->info()->is_osr()) {
       DisposeRecompileJob(job, restore_function_code);
     }
   }
 }


 void OptimizingCompilerThread::FlushOutputQueue(bool restore_function_code) {
   RecompileJob* job;
   while (output_queue_.Dequeue(&job)) {
     // OSR jobs are dealt with separately.
     if (!job->info()->is_osr()) {
       DisposeRecompileJob(job, restore_function_code);
     }
   }
 }


 void OptimizingCompilerThread::FlushOsrBuffer(bool restore_function_code) {
   for (int i = 0; i < osr_buffer_capacity_; i++) {
     if (osr_buffer_[i] != NULL) {
       DisposeRecompileJob(osr_buffer_[i], restore_function_code);
       osr_buffer_[i] = NULL;
     }
   }
 }


 void OptimizingCompilerThread::Flush() {
   ASSERT(!IsOptimizerThread());
   Release_Store(&stop_thread_, static_cast<AtomicWord>(FLUSH));
   if (FLAG_block_concurrent_recompilation) Unblock();
   input_queue_semaphore_.Signal();
   stop_semaphore_.Wait();
   FlushOutputQueue(true);
   if (FLAG_concurrent_osr) FlushOsrBuffer(true);
   if (FLAG_trace_concurrent_recompilation) {
     PrintF("  ** Flushed concurrent recompilation queues.\n");
   }
 }


 void OptimizingCompilerThread::Stop() {
   ASSERT(!IsOptimizerThread());
   Release_Store(&stop_thread_, static_cast<AtomicWord>(STOP));
   if (FLAG_block_concurrent_recompilation) Unblock();
   input_queue_semaphore_.Signal();
   stop_semaphore_.Wait();

   if (FLAG_concurrent_recompilation_delay != 0) {
     // At this point the optimizing compiler thread's event loop has stopped.
     // There is no need for a mutex when reading input_queue_length_.
     while (input_queue_length_ > 0) CompileNext();
     InstallOptimizedFunctions();
   } else {
     FlushInputQueue(false);
     FlushOutputQueue(false);
   }

   if (FLAG_concurrent_osr) FlushOsrBuffer(false);

   if (FLAG_trace_concurrent_recompilation) {
     double percentage = time_spent_compiling_.PercentOf(time_spent_total_);
     PrintF("  ** Compiler thread did %.2f%% useful work\n", percentage);
   }

   if ((FLAG_trace_osr || FLAG_trace_concurrent_recompilation) &&
       FLAG_concurrent_osr) {
     PrintF("[COSR hit rate %d / %d]\n", osr_hits_, osr_attempts_);
   }

   Join();
 }


 void OptimizingCompilerThread::InstallOptimizedFunctions() {
   ASSERT(!IsOptimizerThread());
   HandleScope handle_scope(isolate_);

   RecompileJob* job;
   while (output_queue_.Dequeue(&job)) {
     CompilationInfo* info = job->info();
     if (info->is_osr()) {
       if (FLAG_trace_osr) {
         PrintF("[COSR - ");
         info->closure()->PrintName();
         PrintF(" is ready for install and entry at AST id %d]\n",
                info->osr_ast_id().ToInt());
       }
       job->WaitForInstall();
       BackEdgeTable::RemoveStackCheck(info);
     } else {
       Compiler::InstallOptimizedCode(job);
     }
   }
 }


 void OptimizingCompilerThread::QueueForOptimization(RecompileJob* job) {
   ASSERT(IsQueueAvailable());
   ASSERT(!IsOptimizerThread());
   CompilationInfo* info = job->info();
   if (info->is_osr()) {
     if (FLAG_trace_concurrent_recompilation) {
       PrintF("  ** Queueing ");
       info->closure()->PrintName();
       PrintF(" for concurrent on-stack replacement.\n");
     }
     osr_attempts_++;
     BackEdgeTable::AddStackCheck(info);
     AddToOsrBuffer(job);
     // Add job to the front of the input queue.
     LockGuard<Mutex> access_input_queue(&input_queue_mutex_);
     ASSERT_LT(input_queue_length_, input_queue_capacity_);
     // Move shift_ back by one.
     input_queue_shift_ = InputQueueIndex(input_queue_capacity_ - 1);
     input_queue_[InputQueueIndex(0)] = job;
     input_queue_length_++;
   } else {
     info->closure()->MarkInRecompileQueue();
     // Add job to the back of the input queue.
     LockGuard<Mutex> access_input_queue(&input_queue_mutex_);
     ASSERT_LT(input_queue_length_, input_queue_capacity_);
     input_queue_[InputQueueIndex(input_queue_length_)] = job;
     input_queue_length_++;
   }
   if (FLAG_block_concurrent_recompilation) {
     blocked_jobs_++;
   } else {
     input_queue_semaphore_.Signal();
   }
 }


 void OptimizingCompilerThread::Unblock() {
   ASSERT(!IsOptimizerThread());
   while (blocked_jobs_ > 0) {
     input_queue_semaphore_.Signal();
     blocked_jobs_--;
   }
 }


 RecompileJob* OptimizingCompilerThread::FindReadyOSRCandidate(
     Handle<JSFunction> function, uint32_t osr_pc_offset) {
   ASSERT(!IsOptimizerThread());
   for (int i = 0; i < osr_buffer_capacity_; i++) {
     RecompileJob* current = osr_buffer_[i];
     if (current != NULL &&
         current->IsWaitingForInstall() &&
         current->info()->HasSameOsrEntry(function, osr_pc_offset)) {
       osr_hits_++;
       osr_buffer_[i] = NULL;
       return current;
     }
   }
   return NULL;
 }


 bool OptimizingCompilerThread::IsQueuedForOSR(Handle<JSFunction> function,
                                               uint32_t osr_pc_offset) {
   ASSERT(!IsOptimizerThread());
   for (int i = 0; i < osr_buffer_capacity_; i++) {
     RecompileJob* current = osr_buffer_[i];
     if (current != NULL &&
         current->info()->HasSameOsrEntry(function, osr_pc_offset)) {
       return !current->IsWaitingForInstall();
     }
   }
   return false;
 }


 bool OptimizingCompilerThread::IsQueuedForOSR(JSFunction* function) {
   ASSERT(!IsOptimizerThread());
   for (int i = 0; i < osr_buffer_capacity_; i++) {
     RecompileJob* current = osr_buffer_[i];
     if (current != NULL && *current->info()->closure() == function) {
       return !current->IsWaitingForInstall();
     }
   }
   return false;
 }


 void OptimizingCompilerThread::AddToOsrBuffer(RecompileJob* job) {
   ASSERT(!IsOptimizerThread());
   // Find the next slot that is empty or has a stale job.
   RecompileJob* stale = NULL;
   while (true) {
     stale = osr_buffer_[osr_buffer_cursor_];
     if (stale == NULL || stale->IsWaitingForInstall()) break;
     osr_buffer_cursor_ = (osr_buffer_cursor_ + 1) % osr_buffer_capacity_;
   }

   // Add to found slot and dispose the evicted job.
   if (stale != NULL) {
     ASSERT(stale->IsWaitingForInstall());
     CompilationInfo* info = stale->info();
     if (FLAG_trace_osr) {
       PrintF("[COSR - Discarded ");
       info->closure()->PrintName();
       PrintF(", AST id %d]\n", info->osr_ast_id().ToInt());
     }
     DisposeRecompileJob(stale, false);
   }
   osr_buffer_[osr_buffer_cursor_] = job;
   osr_buffer_cursor_ = (osr_buffer_cursor_ + 1) % osr_buffer_capacity_;
 }


 #ifdef DEBUG
 bool OptimizingCompilerThread::IsOptimizerThread(Isolate* isolate) {
   return isolate->concurrent_recompilation_enabled() &&
          isolate->optimizing_compiler_thread()->IsOptimizerThread();
 }


 bool OptimizingCompilerThread::IsOptimizerThread() {
   LockGuard<Mutex> lock_guard(&thread_id_mutex_);
   return ThreadId::Current().ToInteger() == thread_id_;
 }
 #endif


 } }  // namespace v8::internal
	// Copyright 2012 the V8 project authors. All rights reserved.
	// Redistribution and use in source and binary forms, with or without
	// modification, are permitted provided that the following conditions are
	// met:
	//
	// * Redistributions of source code must retain the above copyright
	// notice, this list of conditions and the following disclaimer.
	// * Redistributions in binary form must reproduce the above
	// copyright notice, this list of conditions and the following
	// disclaimer in the documentation and/or other materials provided
	// with the distribution.
	// * Neither the name of Google Inc. nor the names of its
	// contributors may be used to endorse or promote products derived
	// from this software without specific prior written permission.
	//
	// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
	// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
	// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
	// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
	// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
	// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
	// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
	// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
	// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
	// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
	// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

	#include "optimizing-compiler-thread.h"

	#include "v8.h"

	#include "full-codegen.h"
	#include "hydrogen.h"
	#include "isolate.h"
	#include "v8threads.h"

	namespace v8 {
	namespace internal {

	OptimizingCompilerThread::~OptimizingCompilerThread() {
	ASSERT_EQ(0, input_queue_length_);
	DeleteArray(input_queue_);
	if (FLAG_concurrent_osr) {
	#ifdef DEBUG
	for (int i = 0; i < osr_buffer_capacity_; i++) {
	CHECK_EQ(NULL, osr_buffer_[i]);
	}
	#endif
	DeleteArray(osr_buffer_);
	}
	}


	void OptimizingCompilerThread::Run() {
	#ifdef DEBUG
	{ LockGuard<Mutex> lock_guard(&thread_id_mutex_);
	thread_id_ = ThreadId::Current().ToInteger();
	}
	#endif
	Isolate::SetIsolateThreadLocals(isolate_, NULL);
	DisallowHeapAllocation no_allocation;
	DisallowHandleAllocation no_handles;
	DisallowHandleDereference no_deref;

	ElapsedTimer total_timer;
	if (FLAG_trace_concurrent_recompilation) total_timer.Start();

	while (true) {
	input_queue_semaphore_.Wait();
	Logger::TimerEventScope timer(
	isolate_, Logger::TimerEventScope::v8_recompile_concurrent);

	if (FLAG_concurrent_recompilation_delay != 0) {
	OS::Sleep(FLAG_concurrent_recompilation_delay);
	}

	switch (static_cast<StopFlag>(Acquire_Load(&stop_thread_))) {
	case CONTINUE:
	break;
	case STOP:
	if (FLAG_trace_concurrent_recompilation) {
	time_spent_total_ = total_timer.Elapsed();
	}
	stop_semaphore_.Signal();
	return;
	case FLUSH:
	// The main thread is blocked, waiting for the stop semaphore.
	{ AllowHandleDereference allow_handle_dereference;
	FlushInputQueue(true);
	}
	Release_Store(&stop_thread_, static_cast<AtomicWord>(CONTINUE));
	stop_semaphore_.Signal();
	// Return to start of consumer loop.
	continue;
	}

	ElapsedTimer compiling_timer;
	if (FLAG_trace_concurrent_recompilation) compiling_timer.Start();

	CompileNext();

	if (FLAG_trace_concurrent_recompilation) {
	time_spent_compiling_ += compiling_timer.Elapsed();
	}
	}
	}


	RecompileJob* OptimizingCompilerThread::NextInput() {
	LockGuard<Mutex> access_input_queue_(&input_queue_mutex_);
	if (input_queue_length_ == 0) return NULL;
	RecompileJob* job = input_queue_[InputQueueIndex(0)];
	ASSERT_NE(NULL, job);
	input_queue_shift_ = InputQueueIndex(1);
	input_queue_length_--;
	return job;
	}


	void OptimizingCompilerThread::CompileNext() {
	RecompileJob* job = NextInput();
	ASSERT_NE(NULL, job);

	// The function may have already been optimized by OSR. Simply continue.
	RecompileJob::Status status = job->OptimizeGraph();
	USE(status); // Prevent an unused-variable error in release mode.
	ASSERT(status != RecompileJob::FAILED);

	// The function may have already been optimized by OSR. Simply continue.
	// Use a mutex to make sure that functions marked for install
	// are always also queued.
	output_queue_.Enqueue(job);
	isolate_->stack_guard()->RequestInstallCode();
	}


	static void DisposeRecompileJob(RecompileJob* job,
	bool restore_function_code) {
	// The recompile job is allocated in the CompilationInfo's zone.
	CompilationInfo* info = job->info();
	if (restore_function_code) {
	if (info->is_osr()) {
	if (!job->IsWaitingForInstall()) BackEdgeTable::RemoveStackCheck(info);
	} else {
	Handle<JSFunction> function = info->closure();
	function->ReplaceCode(function->shared()->code());
	}
	}
	delete info;
	}


	void OptimizingCompilerThread::FlushInputQueue(bool restore_function_code) {
	RecompileJob* job;
	while ((job = NextInput())) {
	// This should not block, since we have one signal on the input queue
	// semaphore corresponding to each element in the input queue.
	input_queue_semaphore_.Wait();
	// OSR jobs are dealt with separately.
	if (!job->info()->is_osr()) {
	DisposeRecompileJob(job, restore_function_code);
	}
	}
	}


	void OptimizingCompilerThread::FlushOutputQueue(bool restore_function_code) {
	RecompileJob* job;
	while (output_queue_.Dequeue(&job)) {
	// OSR jobs are dealt with separately.
	if (!job->info()->is_osr()) {
	DisposeRecompileJob(job, restore_function_code);
	}
	}
	}


	void OptimizingCompilerThread::FlushOsrBuffer(bool restore_function_code) {
	for (int i = 0; i < osr_buffer_capacity_; i++) {
	if (osr_buffer_[i] != NULL) {
	DisposeRecompileJob(osr_buffer_[i], restore_function_code);
	osr_buffer_[i] = NULL;
	}
	}
	}


	void OptimizingCompilerThread::Flush() {
	ASSERT(!IsOptimizerThread());
	Release_Store(&stop_thread_, static_cast<AtomicWord>(FLUSH));
	if (FLAG_block_concurrent_recompilation) Unblock();
	input_queue_semaphore_.Signal();
	stop_semaphore_.Wait();
	FlushOutputQueue(true);
	if (FLAG_concurrent_osr) FlushOsrBuffer(true);
	if (FLAG_trace_concurrent_recompilation) {
	PrintF(" ** Flushed concurrent recompilation queues.\n");
	}
	}


	void OptimizingCompilerThread::Stop() {
	ASSERT(!IsOptimizerThread());
	Release_Store(&stop_thread_, static_cast<AtomicWord>(STOP));
	if (FLAG_block_concurrent_recompilation) Unblock();
	input_queue_semaphore_.Signal();
	stop_semaphore_.Wait();

	if (FLAG_concurrent_recompilation_delay != 0) {
	// At this point the optimizing compiler thread's event loop has stopped.
	// There is no need for a mutex when reading input_queue_length_.
	while (input_queue_length_ > 0) CompileNext();
	InstallOptimizedFunctions();
	} else {
	FlushInputQueue(false);
	FlushOutputQueue(false);
	}

	if (FLAG_concurrent_osr) FlushOsrBuffer(false);

	if (FLAG_trace_concurrent_recompilation) {
	double percentage = time_spent_compiling_.PercentOf(time_spent_total_);
	PrintF(" ** Compiler thread did %.2f%% useful work\n", percentage);
	}

	if ((FLAG_trace_osr \|\| FLAG_trace_concurrent_recompilation) &&
	FLAG_concurrent_osr) {
	PrintF("[COSR hit rate %d / %d]\n", osr_hits_, osr_attempts_);
	}

	Join();
	}


	void OptimizingCompilerThread::InstallOptimizedFunctions() {
	ASSERT(!IsOptimizerThread());
	HandleScope handle_scope(isolate_);

	RecompileJob* job;
	while (output_queue_.Dequeue(&job)) {
	CompilationInfo* info = job->info();
	if (info->is_osr()) {
	if (FLAG_trace_osr) {
	PrintF("[COSR - ");
	info->closure()->PrintName();
	PrintF(" is ready for install and entry at AST id %d]\n",
	info->osr_ast_id().ToInt());
	}
	job->WaitForInstall();
	BackEdgeTable::RemoveStackCheck(info);
	} else {
	Compiler::InstallOptimizedCode(job);
	}
	}
	}


	void OptimizingCompilerThread::QueueForOptimization(RecompileJob* job) {
	ASSERT(IsQueueAvailable());
	ASSERT(!IsOptimizerThread());
	CompilationInfo* info = job->info();
	if (info->is_osr()) {
	if (FLAG_trace_concurrent_recompilation) {
	PrintF(" ** Queueing ");
	info->closure()->PrintName();
	PrintF(" for concurrent on-stack replacement.\n");
	}
	osr_attempts_++;
	BackEdgeTable::AddStackCheck(info);
	AddToOsrBuffer(job);
	// Add job to the front of the input queue.
	LockGuard<Mutex> access_input_queue(&input_queue_mutex_);
	ASSERT_LT(input_queue_length_, input_queue_capacity_);
	// Move shift_ back by one.
	input_queue_shift_ = InputQueueIndex(input_queue_capacity_ - 1);
	input_queue_[InputQueueIndex(0)] = job;
	input_queue_length_++;
	} else {
	info->closure()->MarkInRecompileQueue();
	// Add job to the back of the input queue.
	LockGuard<Mutex> access_input_queue(&input_queue_mutex_);
	ASSERT_LT(input_queue_length_, input_queue_capacity_);
	input_queue_[InputQueueIndex(input_queue_length_)] = job;
	input_queue_length_++;
	}
	if (FLAG_block_concurrent_recompilation) {
	blocked_jobs_++;
	} else {
	input_queue_semaphore_.Signal();
	}
	}


	void OptimizingCompilerThread::Unblock() {
	ASSERT(!IsOptimizerThread());
	while (blocked_jobs_ > 0) {
	input_queue_semaphore_.Signal();
	blocked_jobs_--;
	}
	}


	RecompileJob* OptimizingCompilerThread::FindReadyOSRCandidate(
	Handle<JSFunction> function, uint32_t osr_pc_offset) {
	ASSERT(!IsOptimizerThread());
	for (int i = 0; i < osr_buffer_capacity_; i++) {
	RecompileJob* current = osr_buffer_[i];
	if (current != NULL &&
	current->IsWaitingForInstall() &&
	current->info()->HasSameOsrEntry(function, osr_pc_offset)) {
	osr_hits_++;
	osr_buffer_[i] = NULL;
	return current;
	}
	}
	return NULL;
	}


	bool OptimizingCompilerThread::IsQueuedForOSR(Handle<JSFunction> function,
	uint32_t osr_pc_offset) {
	ASSERT(!IsOptimizerThread());
	for (int i = 0; i < osr_buffer_capacity_; i++) {
	RecompileJob* current = osr_buffer_[i];
	if (current != NULL &&
	current->info()->HasSameOsrEntry(function, osr_pc_offset)) {
	return !current->IsWaitingForInstall();
	}
	}
	return false;
	}


	bool OptimizingCompilerThread::IsQueuedForOSR(JSFunction* function) {
	ASSERT(!IsOptimizerThread());
	for (int i = 0; i < osr_buffer_capacity_; i++) {
	RecompileJob* current = osr_buffer_[i];
	if (current != NULL && *current->info()->closure() == function) {
	return !current->IsWaitingForInstall();
	}
	}
	return false;
	}


	void OptimizingCompilerThread::AddToOsrBuffer(RecompileJob* job) {
	ASSERT(!IsOptimizerThread());
	// Find the next slot that is empty or has a stale job.
	RecompileJob* stale = NULL;
	while (true) {
	stale = osr_buffer_[osr_buffer_cursor_];
	if (stale == NULL \|\| stale->IsWaitingForInstall()) break;
	osr_buffer_cursor_ = (osr_buffer_cursor_ + 1) % osr_buffer_capacity_;
	}

	// Add to found slot and dispose the evicted job.
	if (stale != NULL) {
	ASSERT(stale->IsWaitingForInstall());
	CompilationInfo* info = stale->info();
	if (FLAG_trace_osr) {
	PrintF("[COSR - Discarded ");
	info->closure()->PrintName();
	PrintF(", AST id %d]\n", info->osr_ast_id().ToInt());
	}
	DisposeRecompileJob(stale, false);
	}
	osr_buffer_[osr_buffer_cursor_] = job;
	osr_buffer_cursor_ = (osr_buffer_cursor_ + 1) % osr_buffer_capacity_;
	}


	#ifdef DEBUG
	bool OptimizingCompilerThread::IsOptimizerThread(Isolate* isolate) {
	return isolate->concurrent_recompilation_enabled() &&
	isolate->optimizing_compiler_thread()->IsOptimizerThread();
	}


	bool OptimizingCompilerThread::IsOptimizerThread() {
	LockGuard<Mutex> lock_guard(&thread_id_mutex_);
	return ThreadId::Current().ToInteger() == thread_id_;
	}
	#endif


	} } // namespace v8::internal