一、基本概念：(多线程是通过提高资源使用率来提高系统总体的效率)

• 进程：
  可以理解成一个运行中的应用程序，是系统进行资源分配和调度的基本单位，是操作系统结构的基础，主要管理资源。
• 线程：
  是进程的基本执行单元，一个进程对应多个线程。
• 主线程：
  处理UI，所有更新UI的操作都必须在主线程上执行。不要把耗时操作放在主线程，界面会卡。
• 多线程：
  在同一时刻，一个CPU只能处理1条线程，但CPU可以在多条线程之间快速的切换，只要切换的足够快，就造成了多线程一同执行的假象。
• 目的：
  将耗时的操作放在后台执行

二、线程的状态与生命周期

线程的生命周期是：新建 - 就绪 - 运行 - 阻塞 - 死亡

• 线程状态示意图

  
  
  图1

说明：

• 新建：
  实例化线程对象
• 就绪：
  向线程对象发送start消息，线程对象被加入可调度线程池等待CPU调度。
• 运行：
  CPU 负责调度可调度线程池中线程的执行。线程执行完成之前，状态可能会在就绪和运行之间来回切换。就绪和运行之间的状态变化由CPU负责，程序员不能干预。
• 阻塞：
  当满足某个预定条件时，可以使用休眠或锁，阻塞线程执行。sleepForTimeInterval（休眠指定时长），sleepUntilDate（休眠到指定日期），@synchronized(self)：（互斥锁）。
• 死亡：
  正常死亡，线程执行完毕。非正常死亡，当满足某个条件后，在线程内部中止执行/在主线程中止线程对象
• [NSThread exit]：
  一旦强行终止线程，后续的所有代码都不会被执行。
• [thread cancel]：
  并不会直接取消线程，只是给线程对象添加 isCancelled 标记。

三、多线程的四种解决方案

• pthread
  一套通用的多线程API
  适用于 Unix / Linux / Windows 等系统
  跨平台/可移植
• NSThread
  使用更加面向对象
  简单易用，可直接操作线程对象
• GCD
  旨在替代 NSThread 等线程技术
  充分利用设备的多核
• NSOperation
  基于GCD（底层是GCD）
  比GCD多了一些更简单实用的功能
  使用更加面向对象

四、线程安全问题

• 原因：
  当多个线程访问同一块资源时，很容易引发数据错乱和数据安全问题。
• 解决多线程安全问题的方法：
  方法一：互斥锁（同步锁）

@synchronized(锁对象) {
    //需要锁定的代码
}

加了互斥做的代码，当新线程访问时，如果发现其他线程正在执行锁定的代码，新线程就会进入休眠。

• 注意：
  判断的时候锁对象要存在，如果代码中只有一个地方需要加锁，大多都使用self作为锁对象，这样可以避免单独再创建一个锁对象。
  锁对象切记不能是局部变量。
  方法二：自选锁
  加了自旋锁，当新线程访问代码时，如果发现有其他线程正在锁定代码，新线程会用死循环的方式，一直等待锁定的代码执行完成。相当于不停尝试执行代码，比较消耗性能。

• 属性修饰nonatomic 和 atomic

nonatomic：非原子属性（非线程安全），同一时间可以有很多线程 读 和 写，效率高
atomic：原子属性(线程安全)，保证同一时间只有一个线程能够写入（但是同一个时间多个线程都可以读值）
atomic：本身就有一把自旋锁，且只对 写 操作进行加锁，对 读 操作没有限制

五、NSThread的使用

1. 三种创建方式：

• initWithTarget / initWithBlock
  创建好后，需要通过 start 启动
• detachNewThreadSelector / detachNewThreadWithBlock
  创建好之后自动启动
• performSelectorInBackground
  创建好之后自动启动

//方法一
NSThread *thread = [[NSThread alloc] initWithTarget:self selector:@selector(doSomething:) object:@"NSThread01"];
[thread start];

//方法二
[NSThread detachNewThreadSelector:@selector(doSomething:) toTarget:self withObject:@"NSThread02"];

//方法三
[self performSelectorInBackground:@selector(doSomething:) withObject:@"NSThread03"];

- (void)doSomething:(NSString *) object_str
{
    NSLog(@"参数：%@， 线程：%@", object_str, [NSThread currentThread]);
}

2. NSThread相关类方法

• 返回当前线程

// 当前线程
[NSThread currentThread];
NSLog(@"%@", [NSThread currentThread]);
 
// 如果number=1，则表示在主线程，否则是子线程
打印结果：{number = 1, name = main}

• 阻塞睡眠

//休眠多久
[NSThread sleepForTimeInterval:2];
//休眠到指定时间
[NSThread sleepUntilDate:[NSDate date]];

• 其他

//退出线程
[NSThread exit];
//判断当前线程是否为主线程
[NSThread isMainThread];
//判断当前线程是否是多线程
[NSThread isMultiThreaded];
//主线程的对象
NSThread *mainThread = [NSThread mainThread];

3. NSThread相关属性

//线程是否在执行
thread.isExecuting;
//线程是否被取消
thread.isCancelled;
//线程是否完成
thread.isFinished;
//是否是主线程
thread.isMainThread;
//线程的优先级，取值范围0.0到1.0，默认优先级0.5，1.0表示最高优先级，优先级高，CPU调度的频率高
 thread.threadPriority;

注意：线程优先级和线程执行顺序之间不是必然关系

六、 GCD(Grand Central Dispatch)

1. Dispatch Queue(队列)

2. 创建队列：

/**
 串行队列：serial_queue1
 */
dispatch_queue_t serial_queue1 = dispatch_queue_create("com.seral.queue", DISPATCH_QUEUE_SERIAL);
    
/**
 串行队列：serial_queue2
 */
dispatch_queue_t serial_queue2 = dispatch_queue_create("com.seral.queue", NULL);
    
/**
 并发队列：concurrent_queue
 */
dispatch_queue_t concurrent_queue = dispatch_queue_create("com.concurrent.queue", DISPATCH_QUEUE_CONCURRENT);

/**
 主队列（串行队列）：main_queue
 */
dispatch_queue_t main_queue = dispatch_get_main_queue();

/**
 全局队列（并发队列）：global_queue
 */
dispatch_queue_t global_queue = dispatch_get_global_queue(DISPATCH_QUEUE_PRIORITY_DEFAULT, 0);

3. 组合方式说明

(1) 串行同步队列

dispatch_queue_t serial_queue = dispatch_queue_create("com.serial.queue", NULL);

dispatch_sync(serial_queue, ^{
    NSLog(@"--- 1 --- %@ ---", [NSThread currentThread]);
});
dispatch_sync(serial_queue, ^{
    NSLog(@"--- 2 --- %@ ---", [NSThread currentThread]);
});
dispatch_sync(serial_queue, ^{
    NSLog(@"--- 3 --- %@ ---", [NSThread currentThread]);
});

结果：

--- 1 --- <NSThread: 0x604000071240>{number = 1, name = main} ---
--- 2 --- <NSThread: 0x604000071240>{number = 1, name = main} ---
--- 3 --- <NSThread: 0x604000071240>{number = 1, name = main} ---

(2) 串行异步队列

dispatch_queue_t serial_queue = dispatch_queue_create("com.serial.queue", NULL);

dispatch_async(serial_queue, ^{
    NSLog(@"--- 1 --- %@ ---", [NSThread currentThread]);
});
dispatch_async(serial_queue, ^{
    NSLog(@"--- 2 --- %@ ---", [NSThread currentThread]);
});
dispatch_async(serial_queue, ^{
    NSLog(@"--- 3 --- %@ ---", [NSThread currentThread]);
});

结果：

--- 1 --- <NSThread: 0x60000026f6c0>{number = 3, name = (null)} ---
--- 2 --- <NSThread: 0x60000026f6c0>{number = 3, name = (null)} ---
--- 3 --- <NSThread: 0x60000026f6c0>{number = 3, name = (null)} ---

(3) 并发同步队列

dispatch_queue_t concurrent_queue = dispatch_queue_create("com.concurrent.queue", DISPATCH_QUEUE_CONCURRENT);

dispatch_sync(concurrent_queue, ^{
    NSLog(@"--- 1 --- %@ ---", [NSThread currentThread]);
});
dispatch_sync(concurrent_queue, ^{
    NSLog(@"--- 2 --- %@ ---", [NSThread currentThread]);
});
dispatch_sync(concurrent_queue, ^{
    NSLog(@"--- 3 --- %@ ---", [NSThread currentThread]);
});

结果：

--- 1 --- <NSThread: 0x60000006d3c0>{number = 1, name = main} ---
--- 2 --- <NSThread: 0x60000006d3c0>{number = 1, name = main} ---
--- 3 --- <NSThread: 0x60000006d3c0>{number = 1, name = main} ---

(4) 并发异步队列

dispatch_queue_t concurrent_queue = dispatch_queue_create("com.concurrent.queue", DISPATCH_QUEUE_CONCURRENT);

dispatch_async(concurrent_queue, ^{
    NSLog(@"--- 1 --- %@ ---", [NSThread currentThread]);
});
dispatch_async(concurrent_queue, ^{
    NSLog(@"--- 2 --- %@ ---", [NSThread currentThread]);
});
dispatch_async(concurrent_queue, ^{
    NSLog(@"--- 3 --- %@ ---", [NSThread currentThread]);
});

结果：

--- 3 --- <NSThread: 0x604000271540>{number = 4, name = (null)} ---
--- 1 --- <NSThread: 0x600000463e40>{number = 3, name = (null)} ---
--- 2 --- <NSThread: 0x600000279b80>{number = 5, name = (null)} ---

4. 队列组

作用：队列组是用来管理队列中任务的执行

dispatch_group_t group = dispatch_group_create();
dispatch_queue_t concurrent_queue = dispatch_queue_create("com.concurrent.queue", DISPATCH_QUEUE_CONCURRENT);

dispatch_group_async(group, concurrent_queue, ^{
    NSLog(@"--- 1 --- %@ ---", [NSThread currentThread]);
});
dispatch_group_async(group, concurrent_queue, ^{
    NSLog(@"--- 2 --- %@ ---", [NSThread currentThread]);
});
dispatch_group_async(group, concurrent_queue, ^{
    NSLog(@"--- 3 --- %@ ---", [NSThread currentThread]);
});

dispatch_group_notify(group, concurrent_queue, ^{
    NSLog(@"到这里就结束了！");
});

结果：

--- 2 --- <NSThread: 0x600000273300>{number = 8, name = (null)} ---
--- 3 --- <NSThread: 0x600000273640>{number = 3, name = (null)} ---
--- 1 --- <NSThread: 0x600000264840>{number = 7, name = (null)} ---

5. Barrier

(1) 通过 barrier 添加的 block ，会等其之前添加的所有 block 执行完毕再执行
(2) 在 barrier 之后添加的 block ,会等其添加的 block 执行完毕再执行
(3) 只在自定义创建的并发队列有效

dispatch_queue_t concurrent_queue = dispatch_queue_create("com.concurrent.queue", DISPATCH_QUEUE_CONCURRENT);

dispatch_async(concurrent_queue, ^{
    NSLog(@"--- reading 1 --- %@ ---", [NSThread currentThread]);
});
dispatch_async(concurrent_queue, ^{
    NSLog(@"--- reading 2 --- %@ ---", [NSThread currentThread]);
});
dispatch_async(concurrent_queue, ^{
    NSLog(@"--- reading 3 --- %@ ---", [NSThread currentThread]);
});

/**
 此处使用 dispatch_barrier_sync，block任务在当前线程中执行
 */
dispatch_barrier_async(concurrent_queue, ^{
    NSLog(@"--- writing 0 --- %@ ---", [NSThread currentThread]);
});

dispatch_async(concurrent_queue, ^{
    NSLog(@"--- reading 4 --- %@ ---", [NSThread currentThread]);
});dispatch_async(concurrent_queue, ^{
    NSLog(@"--- reading 5 --- %@ ---", [NSThread currentThread]);
});dispatch_async(concurrent_queue, ^{
    NSLog(@"--- reading 6 --- %@ ---", [NSThread currentThread]);
});

结果：

--- reading 2 --- <NSThread: 0x60400027b100>{number = 11, name = (null)} ---
--- reading 1 --- <NSThread: 0x60000026fb00>{number = 13, name = (null)} ---
--- reading 3 --- <NSThread: 0x600000270040>{number = 14, name = (null)} ---
--- writing 0 --- <NSThread: 0x600000270040>{number = 14, name = (null)} ---
--- reading 5 --- <NSThread: 0x60000026fb00>{number = 13, name = (null)} ---
--- reading 4 --- <NSThread: 0x600000270040>{number = 14, name = (null)} ---
--- reading 6 --- <NSThread: 0x60400027b100>{number = 11, name = (null)} ---

全局队列中：

dispatch_queue_t global_queue = dispatch_get_global_queue(DISPATCH_QUEUE_PRIORITY_DEFAULT, 0);

dispatch_async(global_queue, ^{
    NSLog(@"--- reading 1 --- %@ ---", [NSThread currentThread]);
});
dispatch_async(global_queue, ^{
    NSLog(@"--- reading 2 --- %@ ---", [NSThread currentThread]);
});
dispatch_async(global_queue, ^{
    NSLog(@"--- reading 3 --- %@ ---", [NSThread currentThread]);
});

dispatch_barrier_async(global_queue, ^{
    NSLog(@"--- writing 0 --- %@ ---", [NSThread currentThread]);
});

dispatch_async(global_queue, ^{
    NSLog(@"--- reading 4 --- %@ ---", [NSThread currentThread]);
});dispatch_async(global_queue, ^{
    NSLog(@"--- reading 5 --- %@ ---", [NSThread currentThread]);
});dispatch_async(global_queue, ^{
    NSLog(@"--- reading 6 --- %@ ---", [NSThread currentThread]);
});

结果：

--- reading 1 --- <NSThread: 0x60000026aa80>{number = 12, name = (null)} ---
--- reading 2 --- <NSThread: 0x60000007d780>{number = 10, name = (null)} ---
--- writing 0 --- <NSThread: 0x60000026ad00>{number = 11, name = (null)} ---
--- reading 3 --- <NSThread: 0x60000007f340>{number = 13, name = (null)} ---
--- reading 4 --- <NSThread: 0x60400026c640>{number = 6, name = (null)} ---
--- reading 5 --- <NSThread: 0x60000026b000>{number = 8, name = (null)} ---
--- reading 6 --- <NSThread: 0x60000026b140>{number = 7, name = (null)} ---

串行队列中：

dispatch_queue_t serial_queue = dispatch_queue_create("com.serial.queue", NULL);

dispatch_async(serial_queue, ^{
    NSLog(@"--- reading 1 --- %@ ---", [NSThread currentThread]);
});
dispatch_async(serial_queue, ^{
    NSLog(@"--- reading 2 --- %@ ---", [NSThread currentThread]);
});
dispatch_async(serial_queue, ^{
    NSLog(@"--- reading 3 --- %@ ---", [NSThread currentThread]);
});

dispatch_barrier_async(serial_queue, ^{
    NSLog(@"--- writing 0 --- %@ ---", [NSThread currentThread]);
});

dispatch_async(serial_queue, ^{
    NSLog(@"--- reading 4 --- %@ ---", [NSThread currentThread]);
});dispatch_async(serial_queue, ^{
    NSLog(@"--- reading 5 --- %@ ---", [NSThread currentThread]);
});dispatch_async(serial_queue, ^{
    NSLog(@"--- reading 6 --- %@ ---", [NSThread currentThread]);
});

结果：

--- reading 1 --- <NSThread: 0x604000268e00>{number = 4, name = (null)} ---
--- reading 2 --- <NSThread: 0x604000268e00>{number = 4, name = (null)} ---
--- reading 3 --- <NSThread: 0x604000268e00>{number = 4, name = (null)} ---
--- writing 0 --- <NSThread: 0x604000268e00>{number = 4, name = (null)} ---
--- reading 4 --- <NSThread: 0x604000268e00>{number = 4, name = (null)} ---
--- reading 5 --- <NSThread: 0x604000268e00>{number = 4, name = (null)} ---
--- reading 6 --- <NSThread: 0x604000268e00>{number = 4, name = (null)} ---

6. Semaphore （信号量）

/**
 创建方法：初始值必须 >= 0
 */
dispatch_semaphore_t semaphore = dispatch_semaphore_create(0);

/**
 等待一个信号
 DISPATCH_TIME_NOW ：不等待
 DISPATCH_TIME_FOREVER ：一直等待，直到收到信号
 返回 0 为成功，非 0 就是超时
 */
dispatch_semaphore_wait(semaphore, DISPATCH_TIME_FOREVER);

/**
 发送信号：信号量计数增加
 */
dispatch_semaphore_signal(semaphore);

实例1：多个网络请求并发执行

dispatch_queue_t global_queue = dispatch_get_global_queue(DISPATCH_QUEUE_PRIORITY_DEFAULT, 0);
dispatch_group_t group = dispatch_group_create();
dispatch_semaphore_t semaphore = dispatch_semaphore_create(0);

dispatch_group_async(group, global_queue, ^{
    dispatch_after(dispatch_time(DISPATCH_TIME_NOW, (int64_t)(3 * NSEC_PER_SEC)), dispatch_get_main_queue(), ^{
        dispatch_semaphore_signal(semaphore);
        NSLog(@"--- 请求 1 ---");
    });
    dispatch_semaphore_wait(semaphore, DISPATCH_TIME_FOREVER);
});
dispatch_group_async(group, global_queue, ^{
    dispatch_after(dispatch_time(DISPATCH_TIME_NOW, (int64_t)(2 * NSEC_PER_SEC)), dispatch_get_main_queue(), ^{
        dispatch_semaphore_signal(semaphore);
        NSLog(@"--- 请求 2 ---");
    });
    dispatch_semaphore_wait(semaphore, DISPATCH_TIME_FOREVER);
});
dispatch_group_async(group, global_queue, ^{
    dispatch_after(dispatch_time(DISPATCH_TIME_NOW, (int64_t)(1 * NSEC_PER_SEC)), dispatch_get_main_queue(), ^{
        dispatch_semaphore_signal(semaphore);
        NSLog(@"--- 请求 3 ---");
    });
    dispatch_semaphore_wait(semaphore, DISPATCH_TIME_FOREVER);
});

dispatch_group_notify(group, global_queue, ^{
    NSLog(@"--- 请求全部完成! ---");
});

结果：

--- 请求 3 ---
--- 请求 2 ---
--- 请求 1 ---
--- 请求全部完成! ---

实例2：多个网络请求顺序执行

dispatch_semaphore_t semaphore = dispatch_semaphore_create(1);
dispatch_queue_t serial_queue = dispatch_queue_create("com.serial_queue", NULL);

dispatch_async(serial_queue, ^{
    dispatch_semaphore_wait(semaphore, DISPATCH_TIME_FOREVER);
    dispatch_after(dispatch_time(DISPATCH_TIME_NOW, (int64_t)(3 * NSEC_PER_SEC)), dispatch_get_main_queue(), ^{
        NSLog(@"--- 请求 1 ---");
        dispatch_semaphore_signal(semaphore);

    });
});
dispatch_async(serial_queue, ^{
    dispatch_semaphore_wait(semaphore, DISPATCH_TIME_FOREVER);
    dispatch_after(dispatch_time(DISPATCH_TIME_NOW, (int64_t)(1 * NSEC_PER_SEC)), dispatch_get_main_queue(), ^{
        NSLog(@"--- 请求 2 ---");
        dispatch_semaphore_signal(semaphore);

    });
});
dispatch_async(serial_queue, ^{
    dispatch_semaphore_wait(semaphore, DISPATCH_TIME_FOREVER);
    dispatch_after(dispatch_time(DISPATCH_TIME_NOW, (int64_t)(2 * NSEC_PER_SEC)), dispatch_get_main_queue(), ^{
        NSLog(@"--- 请求 3 ---");
        dispatch_semaphore_signal(semaphore);
    });
});

结果：

--- 请求 1 ---
--- 请求 2 ---
--- 请求 3 ---

GitHub地址：Demo