third_party/llvm-16.0/llvm/include/llvm/Support/ThreadPool.h - SwiftShader - Git at Google

 //===-- llvm/Support/ThreadPool.h - A ThreadPool implementation -*- C++ -*-===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//
 //
 // This file defines a crude C++11 based thread pool.
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_SUPPORT_THREADPOOL_H
 #define LLVM_SUPPORT_THREADPOOL_H

 #include "llvm/ADT/DenseMap.h"
 #include "llvm/Config/llvm-config.h"
 #include "llvm/Support/RWMutex.h"
 #include "llvm/Support/Threading.h"
 #include "llvm/Support/thread.h"

 #include <future>

 #include <condition_variable>
 #include <deque>
 #include <functional>
 #include <memory>
 #include <mutex>
 #include <utility>

 namespace llvm {

 class ThreadPoolTaskGroup;

 /// A ThreadPool for asynchronous parallel execution on a defined number of
 /// threads.
 ///
 /// The pool keeps a vector of threads alive, waiting on a condition variable
 /// for some work to become available.
 ///
 /// It is possible to reuse one thread pool for different groups of tasks
 /// by grouping tasks using ThreadPoolTaskGroup. All tasks are processed using
 /// the same queue, but it is possible to wait only for a specific group of
 /// tasks to finish.
 ///
 /// It is also possible for worker threads to submit new tasks and wait for
 /// them. Note that this may result in a deadlock in cases such as when a task
 /// (directly or indirectly) tries to wait for its own completion, or when all
 /// available threads are used up by tasks waiting for a task that has no thread
 /// left to run on (this includes waiting on the returned future). It should be
 /// generally safe to wait() for a group as long as groups do not form a cycle.
 class ThreadPool {
 public:
   /// Construct a pool using the hardware strategy \p S for mapping hardware
   /// execution resources (threads, cores, CPUs)
   /// Defaults to using the maximum execution resources in the system, but
   /// accounting for the affinity mask.
   ThreadPool(ThreadPoolStrategy S = hardware_concurrency());

   /// Blocking destructor: the pool will wait for all the threads to complete.
   ~ThreadPool();

   /// Asynchronous submission of a task to the pool. The returned future can be
   /// used to wait for the task to finish and is *non-blocking* on destruction.
   template <typename Function, typename... Args>
   auto async(Function &&F, Args &&...ArgList) {
     auto Task =
         std::bind(std::forward<Function>(F), std::forward<Args>(ArgList)...);
     return async(std::move(Task));
   }

   /// Overload, task will be in the given task group.
   template <typename Function, typename... Args>
   auto async(ThreadPoolTaskGroup &Group, Function &&F, Args &&...ArgList) {
     auto Task =
         std::bind(std::forward<Function>(F), std::forward<Args>(ArgList)...);
     return async(Group, std::move(Task));
   }

   /// Asynchronous submission of a task to the pool. The returned future can be
   /// used to wait for the task to finish and is *non-blocking* on destruction.
   template <typename Func>
   auto async(Func &&F) -> std::shared_future<decltype(F())> {
     return asyncImpl(std::function<decltype(F())()>(std::forward<Func>(F)),
                      nullptr);
   }

   template <typename Func>
   auto async(ThreadPoolTaskGroup &Group, Func &&F)
       -> std::shared_future<decltype(F())> {
     return asyncImpl(std::function<decltype(F())()>(std::forward<Func>(F)),
                      &Group);
   }

   /// Blocking wait for all the threads to complete and the queue to be empty.
   /// It is an error to try to add new tasks while blocking on this call.
   /// Calling wait() from a task would deadlock waiting for itself.
   void wait();

   /// Blocking wait for only all the threads in the given group to complete.
   /// It is possible to wait even inside a task, but waiting (directly or
   /// indirectly) on itself will deadlock. If called from a task running on a
   /// worker thread, the call may process pending tasks while waiting in order
   /// not to waste the thread.
   void wait(ThreadPoolTaskGroup &Group);

   // TODO: misleading legacy name warning!
   // Returns the maximum number of worker threads in the pool, not the current
   // number of threads!
   unsigned getThreadCount() const { return MaxThreadCount; }

   /// Returns true if the current thread is a worker thread of this thread pool.
   bool isWorkerThread() const;

 private:
   /// Helpers to create a promise and a callable wrapper of \p Task that sets
   /// the result of the promise. Returns the callable and a future to access the
   /// result.
   template <typename ResTy>
   static std::pair<std::function<void()>, std::future<ResTy>>
   createTaskAndFuture(std::function<ResTy()> Task) {
     std::shared_ptr<std::promise<ResTy>> Promise =
         std::make_shared<std::promise<ResTy>>();
     auto F = Promise->get_future();
     return {
         [Promise = std::move(Promise), Task]() { Promise->set_value(Task()); },
         std::move(F)};
   }
   static std::pair<std::function<void()>, std::future<void>>
   createTaskAndFuture(std::function<void()> Task) {
     std::shared_ptr<std::promise<void>> Promise =
         std::make_shared<std::promise<void>>();
     auto F = Promise->get_future();
     return {[Promise = std::move(Promise), Task]() {
               Task();
               Promise->set_value();
             },
             std::move(F)};
   }

   /// Returns true if all tasks in the given group have finished (nullptr means
   /// all tasks regardless of their group). QueueLock must be locked.
   bool workCompletedUnlocked(ThreadPoolTaskGroup *Group) const;

   /// Asynchronous submission of a task to the pool. The returned future can be
   /// used to wait for the task to finish and is *non-blocking* on destruction.
   template <typename ResTy>
   std::shared_future<ResTy> asyncImpl(std::function<ResTy()> Task,
                                       ThreadPoolTaskGroup *Group) {

 #if LLVM_ENABLE_THREADS
     /// Wrap the Task in a std::function<void()> that sets the result of the
     /// corresponding future.
     auto R = createTaskAndFuture(Task);

     int requestedThreads;
     {
       // Lock the queue and push the new task
       std::unique_lock<std::mutex> LockGuard(QueueLock);

       // Don't allow enqueueing after disabling the pool
       assert(EnableFlag && "Queuing a thread during ThreadPool destruction");
       Tasks.emplace_back(std::make_pair(std::move(R.first), Group));
       requestedThreads = ActiveThreads + Tasks.size();
     }
     QueueCondition.notify_one();
     grow(requestedThreads);
     return R.second.share();

 #else // LLVM_ENABLE_THREADS Disabled

     // Get a Future with launch::deferred execution using std::async
     auto Future = std::async(std::launch::deferred, std::move(Task)).share();
     // Wrap the future so that both ThreadPool::wait() can operate and the
     // returned future can be sync'ed on.
     Tasks.emplace_back(std::make_pair([Future]() { Future.get(); }, Group));
     return Future;
 #endif
   }

 #if LLVM_ENABLE_THREADS
   // Grow to ensure that we have at least `requested` Threads, but do not go
   // over MaxThreadCount.
   void grow(int requested);

   void processTasks(ThreadPoolTaskGroup *WaitingForGroup);
 #endif

   /// Threads in flight
   std::vector<llvm::thread> Threads;
   /// Lock protecting access to the Threads vector.
   mutable llvm::sys::RWMutex ThreadsLock;

   /// Tasks waiting for execution in the pool.
   std::deque<std::pair<std::function<void()>, ThreadPoolTaskGroup *>> Tasks;

   /// Locking and signaling for accessing the Tasks queue.
   std::mutex QueueLock;
   std::condition_variable QueueCondition;

   /// Signaling for job completion (all tasks or all tasks in a group).
   std::condition_variable CompletionCondition;

   /// Keep track of the number of thread actually busy
   unsigned ActiveThreads = 0;
   /// Number of threads active for tasks in the given group (only non-zero).
   DenseMap<ThreadPoolTaskGroup *, unsigned> ActiveGroups;

 #if LLVM_ENABLE_THREADS // avoids warning for unused variable
   /// Signal for the destruction of the pool, asking thread to exit.
   bool EnableFlag = true;
 #endif

   const ThreadPoolStrategy Strategy;

   /// Maximum number of threads to potentially grow this pool to.
   const unsigned MaxThreadCount;
 };

 /// A group of tasks to be run on a thread pool. Thread pool tasks in different
 /// groups can run on the same threadpool but can be waited for separately.
 /// It is even possible for tasks of one group to submit and wait for tasks
 /// of another group, as long as this does not form a loop.
 class ThreadPoolTaskGroup {
 public:
   /// The ThreadPool argument is the thread pool to forward calls to.
   ThreadPoolTaskGroup(ThreadPool &Pool) : Pool(Pool) {}

   /// Blocking destructor: will wait for all the tasks in the group to complete
   /// by calling ThreadPool::wait().
   ~ThreadPoolTaskGroup() { wait(); }

   /// Calls ThreadPool::async() for this group.
   template <typename Function, typename... Args>
   inline auto async(Function &&F, Args &&...ArgList) {
     return Pool.async(*this, std::forward<Function>(F),
                       std::forward<Args>(ArgList)...);
   }

   /// Calls ThreadPool::wait() for this group.
   void wait() { Pool.wait(*this); }

 private:
   ThreadPool &Pool;
 };

 } // namespace llvm

 #endif // LLVM_SUPPORT_THREADPOOL_H
	//===-- llvm/Support/ThreadPool.h - A ThreadPool implementation -- C++ --===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//
	//
	// This file defines a crude C++11 based thread pool.
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_SUPPORT_THREADPOOL_H
	#define LLVM_SUPPORT_THREADPOOL_H

	#include "llvm/ADT/DenseMap.h"
	#include "llvm/Config/llvm-config.h"
	#include "llvm/Support/RWMutex.h"
	#include "llvm/Support/Threading.h"
	#include "llvm/Support/thread.h"

	#include <future>

	#include <condition_variable>
	#include <deque>
	#include <functional>
	#include <memory>
	#include <mutex>
	#include <utility>

	namespace llvm {

	class ThreadPoolTaskGroup;

	/// A ThreadPool for asynchronous parallel execution on a defined number of
	/// threads.
	///
	/// The pool keeps a vector of threads alive, waiting on a condition variable
	/// for some work to become available.
	///
	/// It is possible to reuse one thread pool for different groups of tasks
	/// by grouping tasks using ThreadPoolTaskGroup. All tasks are processed using
	/// the same queue, but it is possible to wait only for a specific group of
	/// tasks to finish.
	///
	/// It is also possible for worker threads to submit new tasks and wait for
	/// them. Note that this may result in a deadlock in cases such as when a task
	/// (directly or indirectly) tries to wait for its own completion, or when all
	/// available threads are used up by tasks waiting for a task that has no thread
	/// left to run on (this includes waiting on the returned future). It should be
	/// generally safe to wait() for a group as long as groups do not form a cycle.
	class ThreadPool {
	public:
	/// Construct a pool using the hardware strategy \p S for mapping hardware
	/// execution resources (threads, cores, CPUs)
	/// Defaults to using the maximum execution resources in the system, but
	/// accounting for the affinity mask.
	ThreadPool(ThreadPoolStrategy S = hardware_concurrency());

	/// Blocking destructor: the pool will wait for all the threads to complete.
	~ThreadPool();

	/// Asynchronous submission of a task to the pool. The returned future can be
	/// used to wait for the task to finish and is non-blocking on destruction.
	template <typename Function, typename... Args>
	auto async(Function &&F, Args &&...ArgList) {
	auto Task =
	std::bind(std::forward<Function>(F), std::forward<Args>(ArgList)...);
	return async(std::move(Task));
	}

	/// Overload, task will be in the given task group.
	template <typename Function, typename... Args>
	auto async(ThreadPoolTaskGroup &Group, Function &&F, Args &&...ArgList) {
	auto Task =
	std::bind(std::forward<Function>(F), std::forward<Args>(ArgList)...);
	return async(Group, std::move(Task));
	}

	/// Asynchronous submission of a task to the pool. The returned future can be
	/// used to wait for the task to finish and is non-blocking on destruction.
	template <typename Func>
	auto async(Func &&F) -> std::shared_future<decltype(F())> {
	return asyncImpl(std::function<decltype(F())()>(std::forward<Func>(F)),
	nullptr);
	}

	template <typename Func>
	auto async(ThreadPoolTaskGroup &Group, Func &&F)
	-> std::shared_future<decltype(F())> {
	return asyncImpl(std::function<decltype(F())()>(std::forward<Func>(F)),
	&Group);
	}

	/// Blocking wait for all the threads to complete and the queue to be empty.
	/// It is an error to try to add new tasks while blocking on this call.
	/// Calling wait() from a task would deadlock waiting for itself.
	void wait();

	/// Blocking wait for only all the threads in the given group to complete.
	/// It is possible to wait even inside a task, but waiting (directly or
	/// indirectly) on itself will deadlock. If called from a task running on a
	/// worker thread, the call may process pending tasks while waiting in order
	/// not to waste the thread.
	void wait(ThreadPoolTaskGroup &Group);

	// TODO: misleading legacy name warning!
	// Returns the maximum number of worker threads in the pool, not the current
	// number of threads!
	unsigned getThreadCount() const { return MaxThreadCount; }

	/// Returns true if the current thread is a worker thread of this thread pool.
	bool isWorkerThread() const;

	private:
	/// Helpers to create a promise and a callable wrapper of \p Task that sets
	/// the result of the promise. Returns the callable and a future to access the
	/// result.
	template <typename ResTy>
	static std::pair<std::function<void()>, std::future<ResTy>>
	createTaskAndFuture(std::function<ResTy()> Task) {
	std::shared_ptr<std::promise<ResTy>> Promise =
	std::make_shared<std::promise<ResTy>>();
	auto F = Promise->get_future();
	return {
	[Promise = std::move(Promise), Task]() { Promise->set_value(Task()); },
	std::move(F)};
	}
	static std::pair<std::function<void()>, std::future<void>>
	createTaskAndFuture(std::function<void()> Task) {
	std::shared_ptr<std::promise<void>> Promise =
	std::make_shared<std::promise<void>>();
	auto F = Promise->get_future();
	return {[Promise = std::move(Promise), Task]() {
	Task();
	Promise->set_value();
	},
	std::move(F)};
	}

	/// Returns true if all tasks in the given group have finished (nullptr means
	/// all tasks regardless of their group). QueueLock must be locked.
	bool workCompletedUnlocked(ThreadPoolTaskGroup *Group) const;

	/// Asynchronous submission of a task to the pool. The returned future can be
	/// used to wait for the task to finish and is non-blocking on destruction.
	template <typename ResTy>
	std::shared_future<ResTy> asyncImpl(std::function<ResTy()> Task,
	ThreadPoolTaskGroup *Group) {

	#if LLVM_ENABLE_THREADS
	/// Wrap the Task in a std::function<void()> that sets the result of the
	/// corresponding future.
	auto R = createTaskAndFuture(Task);

	int requestedThreads;
	{
	// Lock the queue and push the new task
	std::unique_lock<std::mutex> LockGuard(QueueLock);

	// Don't allow enqueueing after disabling the pool
	assert(EnableFlag && "Queuing a thread during ThreadPool destruction");
	Tasks.emplace_back(std::make_pair(std::move(R.first), Group));
	requestedThreads = ActiveThreads + Tasks.size();
	}
	QueueCondition.notify_one();
	grow(requestedThreads);
	return R.second.share();

	#else // LLVM_ENABLE_THREADS Disabled

	// Get a Future with launch::deferred execution using std::async
	auto Future = std::async(std::launch::deferred, std::move(Task)).share();
	// Wrap the future so that both ThreadPool::wait() can operate and the
	// returned future can be sync'ed on.
	Tasks.emplace_back(std::make_pair([Future]() { Future.get(); }, Group));
	return Future;
	#endif
	}

	#if LLVM_ENABLE_THREADS
	// Grow to ensure that we have at least `requested` Threads, but do not go
	// over MaxThreadCount.
	void grow(int requested);

	void processTasks(ThreadPoolTaskGroup *WaitingForGroup);
	#endif

	/// Threads in flight
	std::vector<llvm::thread> Threads;
	/// Lock protecting access to the Threads vector.
	mutable llvm::sys::RWMutex ThreadsLock;

	/// Tasks waiting for execution in the pool.
	std::deque<std::pair<std::function<void()>, ThreadPoolTaskGroup *>> Tasks;

	/// Locking and signaling for accessing the Tasks queue.
	std::mutex QueueLock;
	std::condition_variable QueueCondition;

	/// Signaling for job completion (all tasks or all tasks in a group).
	std::condition_variable CompletionCondition;

	/// Keep track of the number of thread actually busy
	unsigned ActiveThreads = 0;
	/// Number of threads active for tasks in the given group (only non-zero).
	DenseMap<ThreadPoolTaskGroup *, unsigned> ActiveGroups;

	#if LLVM_ENABLE_THREADS // avoids warning for unused variable
	/// Signal for the destruction of the pool, asking thread to exit.
	bool EnableFlag = true;
	#endif

	const ThreadPoolStrategy Strategy;

	/// Maximum number of threads to potentially grow this pool to.
	const unsigned MaxThreadCount;
	};

	/// A group of tasks to be run on a thread pool. Thread pool tasks in different
	/// groups can run on the same threadpool but can be waited for separately.
	/// It is even possible for tasks of one group to submit and wait for tasks
	/// of another group, as long as this does not form a loop.
	class ThreadPoolTaskGroup {
	public:
	/// The ThreadPool argument is the thread pool to forward calls to.
	ThreadPoolTaskGroup(ThreadPool &Pool) : Pool(Pool) {}

	/// Blocking destructor: will wait for all the tasks in the group to complete
	/// by calling ThreadPool::wait().
	~ThreadPoolTaskGroup() { wait(); }

	/// Calls ThreadPool::async() for this group.
	template <typename Function, typename... Args>
	inline auto async(Function &&F, Args &&...ArgList) {
	return Pool.async(*this, std::forward<Function>(F),
	std::forward<Args>(ArgList)...);
	}

	/// Calls ThreadPool::wait() for this group.
	void wait() { Pool.wait(*this); }

	private:
	ThreadPool &Pool;
	};

	} // namespace llvm

	#endif // LLVM_SUPPORT_THREADPOOL_H