iOS的多线程编程GCD

1.GCD中的一些基础数据类型

/*
 GCD中一些基础数据类型
 dispatch_time_t：dispatch_walltime获得真实时间(绝对时间)，dispatch_time获得马赫时间
 */
dispatch_time_t time = dispatch_walltime(NULL, 0);
NSLog(@"%lld", time);
dispatch_time_t time2 = dispatch_time(0, 1 * NSEC_PER_SEC);
NSLog(@"%lld", time2);
dispatch_time_t time3 = DISPATCH_TIME_NOW;
NSLog(@"%lld", time3);

2.串行、并行和同步、异步的概念

/*
 串行(serial)：只有在上一个任务执行完才会执行下一个任务
 并行(concurrent)：多个任务同时执行
 */
/*
 同步(sync)：代码执行完才会往下走（返回值，return），且不会创建新线程，而是在主线程中的，即时我们传了其他队列参数也不会创建
 异步(async)：代码不需要执行完，直接可以执行下面的代码
 */

3.主线程下死锁的产生

/*
 主线程，是一个系统自带的串行线程，往主线程添加任务，则需要等当前任务完成，即viewDidLoad方法走完，所以这里Log是后于直接Log的
 死锁：在主线程中同步给主线程添加任务，则产生死锁
 dispatch_sync(dispatch_get_main_queue(), ^{
    NSLog(@"异步添加任务到主线程：%@", [NSThread currentThread]);
 });
 */
 dispatch_async(dispatch_get_main_queue(), ^{
    NSLog(@"异步添加任务到主线程：%@", [NSThread currentThread]);
});
NSLog(@"直接在主线程中执行：%@", [NSThread currentThread]);

4.Object-c SDK自带的4个全局并行队列

/*
 系统自带的4个全局线程（并行），通过以下4个宏设置线程优先级
 #define DISPATCH_QUEUE_PRIORITY_HIGH 2
 #define DISPATCH_QUEUE_PRIORITY_DEFAULT 0
 #define DISPATCH_QUEUE_PRIORITY_LOW (-2)
 #define DISPATCH_QUEUE_PRIORITY_BACKGROUND INT16_MIN
 优先级高的先执行，但是执行完的速度并不一定
 同一优先级的队列中的任务，执行顺序不定
 */
dispatch_async(dispatch_get_global_queue(DISPATCH_QUEUE_PRIORITY_LOW, 0), ^{
    NSLog(@"start_low_1");
    NSLog(@"%@", [NSThread currentThread]);
});
dispatch_async(dispatch_get_global_queue(DISPATCH_QUEUE_PRIORITY_LOW, 0), ^{
    NSLog(@"start_low_2");
    NSLog(@"%@", [NSThread currentThread]);
});
dispatch_async(dispatch_get_global_queue(DISPATCH_QUEUE_PRIORITY_LOW, 0), ^{
    NSLog(@"start_low_3");
    NSLog(@"%@", [NSThread currentThread]);
});
dispatch_async(dispatch_get_global_queue(DISPATCH_QUEUE_PRIORITY_DEFAULT, 0), ^{
    NSLog(@"start_default");
    NSLog(@"%@", [NSThread currentThread]);
});
dispatch_async(dispatch_get_global_queue(DISPATCH_QUEUE_PRIORITY_HIGH, 0), ^{
    NSLog(@"start_high");
    NSLog(@"%@", [NSThread currentThread]);
});

5.自定义队列

/*
 自己创建线程队列，一般不创建并行的，因为系统自带的已经够了
 串行队列-异步执行：任务会根据添加顺序执行，但是不阻碍下面的其他代码执行
 串行队列-同步执行：基本和直接在主线程中写代码没什么区别
 */
dispatch_queue_t my_queue = dispatch_queue_create("my_queue", DISPATCH_QUEUE_SERIAL);
dispatch_async(my_queue, ^{
    NSLog(@"start_my_1");
    NSLog(@"%@", [NSThread currentThread]);
});
dispatch_async(my_queue, ^{
    NSLog(@"start_my_2");
    NSLog(@"%@", [NSThread currentThread]);
});
dispatch_async(dispatch_get_global_queue(DISPATCH_QUEUE_PRIORITY_HIGH, 0), ^{
    NSLog(@"start_high_2");
    NSLog(@"%@", [NSThread currentThread]);
});

6.设置队列优先级，仅能设置自定义队列

/*
 dispatch_set_target_queue
 把我们的队列添加到全局队列中执行，则我们队列的优先级就会和全局队列一样
 通常用这种方式来改变我们自己创建的队列的优先级
 */
dispatch_set_target_queue(my_queue, dispatch_get_global_queue(0, 0));

7.GCD中的通知调用Api

/*
 group和notify
 1.由Log可见，over都是在1，2之后的确实起到了通知的作用
 2.over2并没有等待两个异步请求完成就已经调用，这是因为请求本身是异步的，在调用后直接返回了，所以dispatch_group_async认为该任务已经执行完，所以无作用
 3.要把一个方法或函数作为任务添加到组中等待通知，应该使用dispatch_group_enter()和dispatch_group_leave()
 */
// 1
dispatch_queue_t queue = dispatch_queue_create("my1", DISPATCH_QUEUE_CONCURRENT);
dispatch_group_t group = dispatch_group_create();
dispatch_group_async(group, queue, ^{
    NSLog(@"1");
});
dispatch_group_async(group, queue, ^{
    NSLog(@"2");
});
dispatch_group_notify(group, queue, ^{
    NSLog(@"over");
});

// 2
dispatch_queue_t queue2 = dispatch_queue_create("my2", DISPATCH_QUEUE_CONCURRENT);
dispatch_group_t group2 = dispatch_group_create();
dispatch_group_async(group2, queue2, ^{
    [self request1:^{
        
    }];
});
dispatch_group_async(group2, queue2, ^{
    [self request2:^{
        
    }];
});
dispatch_group_notify(group2, queue2, ^{
    NSLog(@"over2");
});

// 3
dispatch_queue_t queue3 = dispatch_queue_create("my3", DISPATCH_QUEUE_CONCURRENT);
dispatch_group_t group3 = dispatch_group_create();
dispatch_group_enter(group3);
[self request1:^{
    dispatch_group_leave(group3);
}];

dispatch_group_enter(group3);
[self request2:^{
    dispatch_group_leave(group3);
}];
dispatch_group_notify(group3, queue3, ^{
    NSLog(@"over3");
});

8.阻塞线程

/*
 dispatch_barrier_async
 dispatch_barrier_async传的队列参数必须是用户自己创建的，否则没用
 当用户想要先完成任务1，2，中途要等待任务3完成后，才能开始4，5，其中12，45是并发的
 dispatch_barrier_async和dispatch_barrier_sync的共同点在于都会阻挡在dispatch_barrier之后添加的任务，并延时调用（等待它之前的任务回调完成），不同点在于async是不阻挡主线程的，而sync是阻挡主线程的
 */

dispatch_queue_t barrier_queue = dispatch_queue_create("zk_barrier_queue", DISPATCH_QUEUE_CONCURRENT);

dispatch_async(barrier_queue, ^{
    NSLog(@"barrier_1");
});
dispatch_async(barrier_queue, ^{
    NSLog(@"barrier_2");
});
dispatch_barrier_async(barrier_queue, ^{
    NSLog(@"barrier_3");
});
NSLog(@"aa");
dispatch_async(barrier_queue, ^{
    NSLog(@"barrier_4");
});
dispatch_async(barrier_queue, ^{
    NSLog(@"barrier_5");
});

dispatch_async(barrier_queue, ^{
    NSLog(@"barrier_1_1");
});
dispatch_async(barrier_queue, ^{
    NSLog(@"barrier_2_2");
});
dispatch_barrier_sync(barrier_queue, ^{
    NSLog(@"barrier_3_3");
});
NSLog(@"bb");
dispatch_async(barrier_queue, ^{
    NSLog(@"barrier_4_4");
});
dispatch_async(barrier_queue, ^{
    NSLog(@"barrier_5_5");
});

9.延迟调用

/*
 dispatch_after
 延迟调用，一旦开始，就无法停下，一般只用在主队列中
 */
dispatch_after(dispatch_time(dispatch_walltime(NULL, 0), 5 * NSEC_PER_SEC), dispatch_get_main_queue(), ^{
    NSLog(@"dispatch_after");
});
dispatch_after(dispatch_time(0, 5 * NSEC_PER_SEC), dispatch_get_main_queue(), ^{
    NSLog(@"dispatch_after2");
});
dispatch_after(DISPATCH_TIME_NOW, dispatch_get_main_queue(), ^{
    NSLog(@"dispatch_after2");
});

10.遍历

/*
 dispatch_apply
 无序遍历，会开启多个线程，但会阻碍主线程的运行
 */
NSArray *array = @[@1, @2, @3, @4, @5];
dispatch_apply(array.count, dispatch_get_global_queue(0, 0), ^(size_t index) {
    
    NSLog(@"%@---%@", [NSThread currentThread], array[index]);
});
NSLog(@"主线程end");