/* A thread pool (C++ version). */
-/* Copyright (c) 2004-2017 The SimGrid Team.
- * All rights reserved. */
+/* Copyright (c) 2004-2018 The SimGrid Team. All rights reserved. */
/* This program is free software; you can redistribute it and/or modify it
* under the terms of the license (GNU LGPL) which comes with this package. */
#include "src/internal_config.h" // HAVE_FUTEX_H
#include "src/kernel/context/Context.hpp"
-#include <atomic>
+#include "xbt/xbt_os_thread.h"
+
#include <boost/optional.hpp>
-#include <simgrid/simix.h>
-#include <vector>
-#include <xbt/log.h>
-#include <xbt/parmap.h>
-#include <xbt/xbt_os_thread.h>
+#include <condition_variable>
+#include <mutex>
+#include <thread>
#if HAVE_FUTEX_H
-#include <limits>
#include <linux/futex.h>
#include <sys/syscall.h>
#endif
namespace simgrid {
namespace xbt {
-/** \addtogroup XBT_parmap
- * \ingroup XBT_misc
- * \brief Parallel map class
- * \{
- */
+/** @addtogroup XBT_parmap
+ * @ingroup XBT_misc
+ * @brief Parallel map class
+ * @{
+ */
template <typename T> class Parmap {
public:
Parmap(unsigned num_workers, e_xbt_parmap_mode_t mode);
Parmap(const Parmap&) = delete;
+ Parmap& operator=(const Parmap&) = delete;
~Parmap();
void apply(void (*fun)(T), const std::vector<T>& data);
boost::optional<T> next();
enum Flag { PARMAP_WORK, PARMAP_DESTROY };
/**
- * \brief Thread data transmission structure
+ * @brief Thread data transmission structure
*/
class ThreadData {
public:
};
/**
- * \brief Synchronization object (different specializations).
+ * @brief Synchronization object (different specializations).
*/
class Synchro {
public:
explicit Synchro(Parmap<T>& parmap) : parmap(parmap) {}
virtual ~Synchro() = default;
/**
- * \brief Wakes all workers and waits for them to finish the tasks.
+ * @brief Wakes all workers and waits for them to finish the tasks.
*
* This function is called by the controller thread.
*/
virtual void master_signal() = 0;
/**
- * \brief Starts the parmap: waits for all workers to be ready and returns.
+ * @brief Starts the parmap: waits for all workers to be ready and returns.
*
* This function is called by the controller thread.
*/
virtual void master_wait() = 0;
/**
- * \brief Ends the parmap: wakes the controller thread when all workers terminate.
+ * @brief Ends the parmap: wakes the controller thread when all workers terminate.
*
* This function is called by all worker threads when they end (not including the controller).
*/
virtual void worker_signal() = 0;
/**
- * \brief Waits for some work to process.
+ * @brief Waits for some work to process.
*
* This function is called by each worker thread (not including the controller) when it has no more work to do.
*
- * \param round the expected round number
+ * @param round the expected round number
*/
virtual void worker_wait(unsigned) = 0;
void worker_wait(unsigned round);
private:
- xbt_os_cond_t ready_cond;
- xbt_os_mutex_t ready_mutex;
- xbt_os_cond_t done_cond;
- xbt_os_mutex_t done_mutex;
+ std::condition_variable ready_cond;
+ std::mutex ready_mutex;
+ std::condition_variable done_cond;
+ std::mutex done_mutex;
};
#if HAVE_FUTEX_H
};
/**
- * \brief Creates a parallel map object
- * \param num_workers number of worker threads to create
- * \param mode how to synchronize the worker threads
+ * @brief Creates a parallel map object
+ * @param num_workers number of worker threads to create
+ * @param mode how to synchronize the worker threads
*/
template <typename T> Parmap<T>::Parmap(unsigned num_workers, e_xbt_parmap_mode_t mode)
{
}
/**
- * \brief Destroys a parmap
+ * @brief Destroys a parmap
*/
template <typename T> Parmap<T>::~Parmap()
{
}
/**
- * \brief Applies a list of tasks in parallel.
- * \param fun the function to call in parallel
- * \param data each element of this vector will be passed as an argument to fun
+ * @brief Applies a list of tasks in parallel.
+ * @param fun the function to call in parallel
+ * @param data each element of this vector will be passed as an argument to fun
*/
template <typename T> void Parmap<T>::apply(void (*fun)(T), const std::vector<T>& data)
{
}
/**
- * \brief Returns a next task to process.
+ * @brief Returns a next task to process.
*
* Worker threads call this function to get more work.
*
- * \return the next task to process, or throws a std::out_of_range exception if there is no more work
+ * @return the next task to process, or throws a std::out_of_range exception if there is no more work
*/
template <typename T> boost::optional<T> Parmap<T>::next()
{
}
/**
- * \brief Main work loop: applies fun to elements in turn.
+ * @brief Main work loop: applies fun to elements in turn.
*/
template <typename T> void Parmap<T>::work()
{
/**
* Get a synchronization object for given mode.
- * \param mode the synchronization mode
+ * @param mode the synchronization mode
*/
template <typename T> typename Parmap<T>::Synchro* Parmap<T>::new_synchro(e_xbt_parmap_mode_t mode)
{
}
/**
- * \brief Main function of a worker thread.
+ * @brief Main function of a worker thread.
*/
template <typename T> void* Parmap<T>::worker_main(void* arg)
{
template <typename T> Parmap<T>::PosixSynchro::PosixSynchro(Parmap<T>& parmap) : Synchro(parmap)
{
- ready_cond = xbt_os_cond_init();
- ready_mutex = xbt_os_mutex_init();
- done_cond = xbt_os_cond_init();
- done_mutex = xbt_os_mutex_init();
}
template <typename T> Parmap<T>::PosixSynchro::~PosixSynchro()
{
- xbt_os_cond_destroy(ready_cond);
- xbt_os_mutex_destroy(ready_mutex);
- xbt_os_cond_destroy(done_cond);
- xbt_os_mutex_destroy(done_mutex);
}
template <typename T> void Parmap<T>::PosixSynchro::master_signal()
{
- xbt_os_mutex_acquire(ready_mutex);
+ std::unique_lock<std::mutex> lk(ready_mutex);
this->parmap.thread_counter = 1;
this->parmap.work_round++;
/* wake all workers */
- xbt_os_cond_broadcast(ready_cond);
- xbt_os_mutex_release(ready_mutex);
+ ready_cond.notify_all();
}
template <typename T> void Parmap<T>::PosixSynchro::master_wait()
{
- xbt_os_mutex_acquire(done_mutex);
+ std::unique_lock<std::mutex> lk(done_mutex);
while (this->parmap.thread_counter < this->parmap.num_workers) {
/* wait for all workers to be ready */
- xbt_os_cond_wait(done_cond, done_mutex);
+ done_cond.wait(lk);
}
- xbt_os_mutex_release(done_mutex);
}
template <typename T> void Parmap<T>::PosixSynchro::worker_signal()
{
- xbt_os_mutex_acquire(done_mutex);
+ std::unique_lock<std::mutex> lk(done_mutex);
this->parmap.thread_counter++;
if (this->parmap.thread_counter == this->parmap.num_workers) {
/* all workers have finished, wake the controller */
- xbt_os_cond_signal(done_cond);
+ done_cond.notify_one();
}
- xbt_os_mutex_release(done_mutex);
}
template <typename T> void Parmap<T>::PosixSynchro::worker_wait(unsigned round)
{
- xbt_os_mutex_acquire(ready_mutex);
+ std::unique_lock<std::mutex> lk(ready_mutex);
/* wait for more work */
while (this->parmap.work_round != round) {
- xbt_os_cond_wait(ready_cond, ready_mutex);
+ ready_cond.wait(lk);
}
- xbt_os_mutex_release(ready_mutex);
}
#if HAVE_FUTEX_H
template <typename T> void Parmap<T>::BusyWaitSynchro::master_wait()
{
while (__atomic_load_n(&this->parmap.thread_counter, __ATOMIC_SEQ_CST) < this->parmap.num_workers) {
- xbt_os_thread_yield();
+ std::this_thread::yield();
}
}
{
/* wait for more work */
while (__atomic_load_n(&this->parmap.work_round, __ATOMIC_SEQ_CST) != round) {
- xbt_os_thread_yield();
+ std::this_thread::yield();
}
}
-/** \} */
+/** @} */
}
}