Home > Backend Development > C++ > Detailed explanation of synchronization primitives in C++ concurrent programming

Detailed explanation of synchronization primitives in C++ concurrent programming

WBOY
Release: 2024-05-31 22:01:04
Original
816 people have browsed it

In C multi-threaded programming, the role of synchronization primitives is to ensure the correctness of multiple threads accessing shared resources. It includes: Mutex (Mutex): protects shared resources and prevents simultaneous access; condition variables (Condition Variable): The thread waits for specific conditions to be met before continuing execution; Atomic operation: ensures that the operation is executed in an uninterruptible manner.

C++ 并发编程中的同步原语详解

C Detailed explanation of synchronization primitives in concurrent programming

In multi-thread programming, synchronization primitives are crucial , which can ensure the correctness when multiple threads access shared resources. C provides a rich set of synchronization primitives, including mutex locks, condition variables, and atomic operations.

Mutex (Mutex)

Mutex is a synchronization mechanism used to protect shared resources. When a thread acquires a mutex lock, other threads will be blocked until the mutex lock is released. In C, you can use the std::mutex class to implement a mutex lock:

std::mutex mtx;
// ...
{
    // 获取互斥锁
    std::lock_guard<std::mutex> lock(mtx);
    // 临界区
} // 互斥锁在离开作用域时自动释放
Copy after login

Condition Variable

Condition variable Allows a thread to wait for a specific condition to be met before continuing execution. In C, you can use the std::condition_variable class to implement condition variables:

std::condition_variable cv;
// ...
{
    std::unique_lock<std::mutex> lock(mtx);
    // 等待条件满足
    cv.wait(lock);
    // 执行条件满足后要执行的代码
}
Copy after login

Atomic operations

Atomic operations guarantee that an operation can Executed in interrupt mode. In C, you can use the atomic library to perform atomic operations:

std::atomic<int> counter;
// ...
counter++; // 原子地增加 counter 的值
Copy after login

Practical example

Consider a program with a shared counter and a writing thread. The writing thread needs to atomically increment the counter, while the reading thread needs to read the counter protectedly:

std::atomic<int> counter;
std::mutex mtx;

// 写入线程
void write_thread() {
    while (true) {
        // 原子地增加计数器
        counter++;
    }
}

// 读取线程
void read_thread() {
    while (true) {
        // 保护地读取计数器
        std::lock_guard<std::mutex> lock(mtx);
        std::cout << "Counter: " << counter << std::endl;
    }
}

int main() {
    std::thread t1(write_thread);
    std::thread t2(read_thread);
    t1.join();
    t2.join();
    return 0;
}
Copy after login

The above is the detailed content of Detailed explanation of synchronization primitives in C++ concurrent programming. For more information, please follow other related articles on the PHP Chinese website!

Related labels:
source:php.cn
Statement of this Website
The content of this article is voluntarily contributed by netizens, and the copyright belongs to the original author. This site does not assume corresponding legal responsibility. If you find any content suspected of plagiarism or infringement, please contact admin@php.cn
Popular Tutorials
More>
Latest Downloads
More>
Web Effects
Website Source Code
Website Materials
Front End Template