libc/src/threads/linux/CndVar.h - rust-lang/llvm-project - Git at Google

 //===-- Utility condition variable class ------------------------*- 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
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_LIBC_SRC_THREADS_LINUX_CNDVAR_H
 #define LLVM_LIBC_SRC_THREADS_LINUX_CNDVAR_H

 #include "include/sys/syscall.h" // For syscall numbers.
 #include "include/threads.h"     // For values like thrd_success etc.
 #include "src/__support/CPP/atomic.h"
 #include "src/__support/OSUtil/syscall.h" // For syscall functions.
 #include "src/__support/threads/linux/futex_word.h"
 #include "src/__support/threads/mutex.h"

 #include <linux/futex.h> // For futex operations.
 #include <stdint.h>

 namespace __llvm_libc {

 struct CndVar {
   enum CndWaiterStatus : uint32_t {
     WS_Waiting = 0xE,
     WS_Signalled = 0x5,
   };

   struct CndWaiter {
     cpp::Atomic<uint32_t> futex_word = WS_Waiting;
     CndWaiter *next = nullptr;
   };

   CndWaiter *waitq_front;
   CndWaiter *waitq_back;
   Mutex qmtx;

   static int init(CndVar *cv) {
     cv->waitq_front = cv->waitq_back = nullptr;
     auto err = Mutex::init(&cv->qmtx, false, false, false);
     return err == MutexError::NONE ? thrd_success : thrd_error;
   }

   static void destroy(CndVar *cv) {
     cv->waitq_front = cv->waitq_back = nullptr;
   }

   int wait(Mutex *m) {
     // The goal is to perform "unlock |m| and wait" in an
     // atomic operation. However, it is not possible to do it
     // in the true sense so we do it in spirit. Before unlocking
     // |m|, a new waiter object is added to the waiter queue with
     // the waiter queue locked. Iff a signalling thread signals
     // the waiter before the waiter actually starts waiting, the
     // wait operation will not begin at all and the waiter immediately
     // returns.

     CndWaiter waiter;
     {
       MutexLock ml(&qmtx);
       CndWaiter *old_back = nullptr;
       if (waitq_front == nullptr) {
         waitq_front = waitq_back = &waiter;
       } else {
         old_back = waitq_back;
         waitq_back->next = &waiter;
         waitq_back = &waiter;
       }

       if (m->unlock() != MutexError::NONE) {
         // If we do not remove the queued up waiter before returning,
         // then another thread can potentially signal a non-existing
         // waiter. Note also that we do this with |qmtx| locked. This
         // ensures that another thread will not signal the withdrawing
         // waiter.
         waitq_back = old_back;
         if (waitq_back == nullptr)
           waitq_front = nullptr;
         else
           waitq_back->next = nullptr;

         return thrd_error;
       }
     }

     __llvm_libc::syscall(SYS_futex, &waiter.futex_word.val, FUTEX_WAIT,
                          WS_Waiting, 0, 0, 0);

     // At this point, if locking |m| fails, we can simply return as the
     // queued up waiter would have been removed from the queue.
     auto err = m->lock();
     return err == MutexError::NONE ? thrd_success : thrd_error;
   }

   int notify_one() {
     // We don't use an RAII locker in this method as we want to unlock
     // |qmtx| and signal the waiter using a single FUTEX_WAKE_OP signal.
     qmtx.lock();
     if (waitq_front == nullptr) {
       qmtx.unlock();
       return thrd_success;
     }

     CndWaiter *first = waitq_front;
     waitq_front = waitq_front->next;
     if (waitq_front == nullptr)
       waitq_back = nullptr;

     qmtx.futex_word = FutexWordType(Mutex::LockState::Free);

     __llvm_libc::syscall(
         SYS_futex, &qmtx.futex_word.val, FUTEX_WAKE_OP, 1, 1,
         &first->futex_word.val,
         FUTEX_OP(FUTEX_OP_SET, WS_Signalled, FUTEX_OP_CMP_EQ, WS_Waiting));
     return thrd_success;
   }

   int broadcast() {
     MutexLock ml(&qmtx);
     uint32_t dummy_futex_word;
     CndWaiter *waiter = waitq_front;
     waitq_front = waitq_back = nullptr;
     while (waiter != nullptr) {
       // FUTEX_WAKE_OP is used instead of just FUTEX_WAKE as it allows us to
       // atomically update the waiter status to WS_Signalled before waking
       // up the waiter. A dummy location is used for the other futex of
       // FUTEX_WAKE_OP.
       __llvm_libc::syscall(
           SYS_futex, &dummy_futex_word, FUTEX_WAKE_OP, 1, 1,
           &waiter->futex_word.val,
           FUTEX_OP(FUTEX_OP_SET, WS_Signalled, FUTEX_OP_CMP_EQ, WS_Waiting));
       waiter = waiter->next;
     }
     return thrd_success;
   }
 };

 static_assert(sizeof(CndVar) == sizeof(cnd_t),
               "Mismatch in the size of the "
               "internal representation of condition variable and the public "
               "cnd_t type.");

 } // namespace __llvm_libc

 #endif // LLVM_LIBC_SRC_THREADS_LINUX_CNDVAR_H
	//===-- Utility condition variable class ------------------------- 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
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_LIBC_SRC_THREADS_LINUX_CNDVAR_H
	#define LLVM_LIBC_SRC_THREADS_LINUX_CNDVAR_H

	#include "include/sys/syscall.h" // For syscall numbers.
	#include "include/threads.h" // For values like thrd_success etc.
	#include "src/__support/CPP/atomic.h"
	#include "src/__support/OSUtil/syscall.h" // For syscall functions.
	#include "src/__support/threads/linux/futex_word.h"
	#include "src/__support/threads/mutex.h"

	#include <linux/futex.h> // For futex operations.
	#include <stdint.h>

	namespace __llvm_libc {

	struct CndVar {
	enum CndWaiterStatus : uint32_t {
	WS_Waiting = 0xE,
	WS_Signalled = 0x5,
	};

	struct CndWaiter {
	cpp::Atomic<uint32_t> futex_word = WS_Waiting;
	CndWaiter *next = nullptr;
	};

	CndWaiter *waitq_front;
	CndWaiter *waitq_back;
	Mutex qmtx;

	static int init(CndVar *cv) {
	cv->waitq_front = cv->waitq_back = nullptr;
	auto err = Mutex::init(&cv->qmtx, false, false, false);
	return err == MutexError::NONE ? thrd_success : thrd_error;
	}

	static void destroy(CndVar *cv) {
	cv->waitq_front = cv->waitq_back = nullptr;
	}

	int wait(Mutex *m) {
	// The goal is to perform "unlock \|m\| and wait" in an
	// atomic operation. However, it is not possible to do it
	// in the true sense so we do it in spirit. Before unlocking
	// \|m\|, a new waiter object is added to the waiter queue with
	// the waiter queue locked. Iff a signalling thread signals
	// the waiter before the waiter actually starts waiting, the
	// wait operation will not begin at all and the waiter immediately
	// returns.

	CndWaiter waiter;
	{
	MutexLock ml(&qmtx);
	CndWaiter *old_back = nullptr;
	if (waitq_front == nullptr) {
	waitq_front = waitq_back = &waiter;
	} else {
	old_back = waitq_back;
	waitq_back->next = &waiter;
	waitq_back = &waiter;
	}

	if (m->unlock() != MutexError::NONE) {
	// If we do not remove the queued up waiter before returning,
	// then another thread can potentially signal a non-existing
	// waiter. Note also that we do this with \|qmtx\| locked. This
	// ensures that another thread will not signal the withdrawing
	// waiter.
	waitq_back = old_back;
	if (waitq_back == nullptr)
	waitq_front = nullptr;
	else
	waitq_back->next = nullptr;

	return thrd_error;
	}
	}

	__llvm_libc::syscall(SYS_futex, &waiter.futex_word.val, FUTEX_WAIT,
	WS_Waiting, 0, 0, 0);

	// At this point, if locking \|m\| fails, we can simply return as the
	// queued up waiter would have been removed from the queue.
	auto err = m->lock();
	return err == MutexError::NONE ? thrd_success : thrd_error;
	}

	int notify_one() {
	// We don't use an RAII locker in this method as we want to unlock
	// \|qmtx\| and signal the waiter using a single FUTEX_WAKE_OP signal.
	qmtx.lock();
	if (waitq_front == nullptr) {
	qmtx.unlock();
	return thrd_success;
	}

	CndWaiter *first = waitq_front;
	waitq_front = waitq_front->next;
	if (waitq_front == nullptr)
	waitq_back = nullptr;

	qmtx.futex_word = FutexWordType(Mutex::LockState::Free);

	__llvm_libc::syscall(
	SYS_futex, &qmtx.futex_word.val, FUTEX_WAKE_OP, 1, 1,
	&first->futex_word.val,
	FUTEX_OP(FUTEX_OP_SET, WS_Signalled, FUTEX_OP_CMP_EQ, WS_Waiting));
	return thrd_success;
	}

	int broadcast() {
	MutexLock ml(&qmtx);
	uint32_t dummy_futex_word;
	CndWaiter *waiter = waitq_front;
	waitq_front = waitq_back = nullptr;
	while (waiter != nullptr) {
	// FUTEX_WAKE_OP is used instead of just FUTEX_WAKE as it allows us to
	// atomically update the waiter status to WS_Signalled before waking
	// up the waiter. A dummy location is used for the other futex of
	// FUTEX_WAKE_OP.
	__llvm_libc::syscall(
	SYS_futex, &dummy_futex_word, FUTEX_WAKE_OP, 1, 1,
	&waiter->futex_word.val,
	FUTEX_OP(FUTEX_OP_SET, WS_Signalled, FUTEX_OP_CMP_EQ, WS_Waiting));
	waiter = waiter->next;
	}
	return thrd_success;
	}
	};

	static_assert(sizeof(CndVar) == sizeof(cnd_t),
	"Mismatch in the size of the "
	"internal representation of condition variable and the public "
	"cnd_t type.");

	} // namespace __llvm_libc

	#endif // LLVM_LIBC_SRC_THREADS_LINUX_CNDVAR_H