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//
// MIT License
// Copyright (c) 2020 Jonathan R. Madsen
// Permission is hereby granted, free of charge, to any person obtaining a copy
// of this software and associated documentation files (the "Software"), to deal
// in the Software without restriction, including without limitation the rights
// to use, copy, modify, merge, publish, distribute, sublicense, and
// copies of the Software, and to permit persons to whom the Software is
// furnished to do so, subject to the following conditions:
// The above copyright notice and this permission notice shall be included in
// all copies or substantial portions of the Software. THE SOFTWARE IS PROVIDED
// "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT
// LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR
// PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT
// HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN
// ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION
// WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
//
//
// ---------------------------------------------------------------
// Tasking class header file
//
// Class Description:
//
// This file defines the task types for TaskManager and ThreadPool
//
// ---------------------------------------------------------------
// Author: Jonathan Madsen (Feb 13th 2018)
// ---------------------------------------------------------------
#pragma once
#include "Globals.hh"
#include "VTask.hh"
#include <cstdint>
#include <functional>
#include <stdexcept>
namespace PTL
{
class ThreadPool;
//======================================================================================//
/// \brief The task class is supplied to thread_pool.
template <typename RetT>
class TaskFuture : public VTask
{
public:
typedef std::promise<RetT> promise_type;
typedef std::future<RetT> future_type;
typedef RetT result_type;
public:
// pass a free function pointer
template <typename... Args>
TaskFuture(Args&&... args)
: VTask{ std::forward<Args>(args)... }
{}
virtual ~TaskFuture() = default;
TaskFuture(const TaskFuture&) = delete;
TaskFuture& operator=(const TaskFuture&) = delete;
TaskFuture(TaskFuture&&) = default;
TaskFuture& operator=(TaskFuture&&) = default;
public:
// execution operator
virtual future_type get_future() = 0;
virtual void wait() = 0;
virtual RetT get() = 0;
};
//======================================================================================//
/// \brief The task class is supplied to thread_pool.
template <typename RetT, typename... Args>
class PackagedTask : public TaskFuture<RetT>
{
public:
typedef PackagedTask<RetT, Args...> this_type;
typedef std::promise<RetT> promise_type;
typedef std::future<RetT> future_type;
typedef std::packaged_task<RetT(Args...)> packaged_task_type;
typedef RetT result_type;
typedef std::tuple<Args...> tuple_type;
public:
// pass a free function pointer
template <typename FuncT>
PackagedTask(FuncT func, Args... args)
: TaskFuture<RetT>{ true, 0 }
, m_ptask{ std::move(func) }
, m_args{ args... }
{}
template <typename FuncT>
PackagedTask(bool _is_native, intmax_t _depth, FuncT func, Args... args)
: TaskFuture<RetT>{ _is_native, _depth }
, m_ptask{ std::move(func) }
, m_args{ args... }
{}
virtual ~PackagedTask() = default;
PackagedTask(const PackagedTask&) = delete;
PackagedTask& operator=(const PackagedTask&) = delete;
PackagedTask(PackagedTask&&) = default;
PackagedTask& operator=(PackagedTask&&) = default;
public:
// execution operator
virtual void operator()() final { mpl::apply(std::move(m_ptask), std::move(m_args)); }
virtual future_type get_future() final { return m_ptask.get_future(); }
virtual void wait() final { return m_ptask.get_future().wait(); }
virtual RetT get() final { return m_ptask.get_future().get(); }
private:
packaged_task_type m_ptask;
tuple_type m_args;
};
//======================================================================================//
/// \brief The task class is supplied to thread_pool.
template <typename RetT, typename... Args>
class Task : public TaskFuture<RetT>
{
public:
typedef Task<RetT, Args...> this_type;
typedef std::promise<RetT> promise_type;
typedef std::future<RetT> future_type;
typedef std::packaged_task<RetT(Args...)> packaged_task_type;
typedef RetT result_type;
typedef std::tuple<Args...> tuple_type;
public:
template <typename FuncT>
Task(FuncT func, Args... args)
: TaskFuture<RetT>{}
, m_ptask{ std::move(func) }
, m_args{ args... }
{}
template <typename FuncT>
Task(bool _is_native, intmax_t _depth, FuncT func, Args... args)
: TaskFuture<RetT>{ _is_native, _depth }
, m_ptask{ std::move(func) }
, m_args{ args... }
{}
virtual ~Task() = default;
Task(const Task&) = delete;
Task& operator=(const Task&) = delete;
Task(Task&&) = default;
Task& operator=(Task&&) = default;
public:
// execution operator
virtual void operator()() final
{
if(m_ptask.valid())
mpl::apply(std::move(m_ptask), std::move(m_args));
}
virtual future_type get_future() final { return m_ptask.get_future(); }
virtual void wait() final { return m_ptask.get_future().wait(); }
virtual RetT get() final { return m_ptask.get_future().get(); }
private:
packaged_task_type m_ptask{};
tuple_type m_args{};
};
//======================================================================================//
/// \brief The task class is supplied to thread_pool.
template <typename RetT>
class Task<RetT, void> : public TaskFuture<RetT>
{
public:
typedef Task<RetT> this_type;
typedef std::promise<RetT> promise_type;
typedef std::future<RetT> future_type;
typedef std::packaged_task<RetT()> packaged_task_type;
typedef RetT result_type;
public:
template <typename FuncT>
Task(FuncT func)
: TaskFuture<RetT>()
, m_ptask{ std::move(func) }
{}
template <typename FuncT>
Task(bool _is_native, intmax_t _depth, FuncT func)
: TaskFuture<RetT>{ _is_native, _depth }
, m_ptask{ std::move(func) }
{}
virtual ~Task() = default;
Task(const Task&) = delete;
Task& operator=(const Task&) = delete;
Task(Task&&) = default;
Task& operator=(Task&&) = default;
public:
// execution operator
virtual void operator()() final { m_ptask(); }
virtual future_type get_future() final { return m_ptask.get_future(); }
virtual void wait() final { return m_ptask.get_future().wait(); }
virtual RetT get() final { return m_ptask.get_future().get(); }
private:
packaged_task_type m_ptask{};
};
//======================================================================================//
/// \brief The task class is supplied to thread_pool.
template <>
class Task<void, void> : public TaskFuture<void>
{
public:
typedef void RetT;
typedef Task<void, void> this_type;
typedef std::promise<RetT> promise_type;
typedef std::future<RetT> future_type;
typedef std::packaged_task<RetT()> packaged_task_type;
typedef RetT result_type;
public:
template <typename FuncT>
explicit Task(FuncT func)
: TaskFuture<RetT>{}
, m_ptask{ std::move(func) }
{}
template <typename FuncT>
Task(bool _is_native, intmax_t _depth, FuncT func)
: TaskFuture<RetT>{ _is_native, _depth }
, m_ptask{ std::move(func) }
{}
virtual ~Task() = default;
Task(const Task&) = delete;
Task& operator=(const Task&) = delete;
Task(Task&&) = default;
Task& operator=(Task&&) = default;
public:
// execution operator
virtual void operator()() final { m_ptask(); }
virtual future_type get_future() final { return m_ptask.get_future(); }
virtual void wait() final { return m_ptask.get_future().wait(); }
virtual RetT get() final { return m_ptask.get_future().get(); }
private:
packaged_task_type m_ptask{};
};
//======================================================================================//
} // namespace PTL
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