1.前言
队列是我们在使用GCD中经常接触的技术点。
2.关键点
2.1 主队列和主线程
这两个术语我们可以经常听到,不知道有没有人会把这两个概念等同化。主队列和主线程是有关联,但是它们是两个不同的概念。简单地说,主队列是主线程上的一个串行队列,是系统自动为我们创建的。换言之,主线程是可以执行除主队列之外其他队列的任务。
2.2 队列和线程
Concurrent Programming: APIs and Challenges中的一张图片可以很直观地描述GCD与线程之间的关系:
GCDandThread@2x.png
一个线程内可能有多个队列,这些队列可能是串行的或者是并行的,按照同步或者异步的方式工作。
3.队列的定义
dispatch_queue_s
是队列的结构体,可以说我们在GCD中接触最多的结构体了。
struct dispatch_queue_vtable_s { DISPATCH_VTABLE_HEADER(dispatch_queue_s); };#define DISPATCH_QUEUE_MIN_LABEL_SIZE 64#ifdef __LP64__#define DISPATCH_QUEUE_CACHELINE_PAD 32#else#define DISPATCH_QUEUE_CACHELINE_PAD 8#endif#define DISPATCH_QUEUE_HEADER \ uint32_t volatile dq_running; \ uint32_t dq_width; \ struct dispatch_object_s *volatile dq_items_tail; \ struct dispatch_object_s *volatile dq_items_head; \ unsigned long dq_serialnum; \ dispatch_queue_t dq_specific_q;struct dispatch_queue_s { DISPATCH_STRUCT_HEADER(dispatch_queue_s, dispatch_queue_vtable_s); DISPATCH_QUEUE_HEADER; char dq_label[DISPATCH_QUEUE_MIN_LABEL_SIZE]; // must be last char _dq_pad[DISPATCH_QUEUE_CACHELINE_PAD]; // for static queues only};
GCD中使用了很多的宏,不利于我们理解代码,我们用对应的结构替换掉定义的宏,如下:
struct dispatch_queue_s { //第一部分:DISPATCH_STRUCT_HEADER(dispatch_queue_s, dispatch_queue_vtable_s) const struct dispatch_queue_vtable_s *do_vtable; \ //dispatch_queue_s的操作函数:dispatch_queue_vtable_s类型的结构体 struct dispatch_queue_s *volatile do_next; \ //链表的next unsigned int do_ref_cnt; \ //引用计数 unsigned int do_xref_cnt; \ //外部引用计数 unsigned int do_suspend_cnt; \ //暂停标志,比如延时处理中,在任务到时后,计时器处理将会将该标志位修改,然后唤醒队列调度 struct dispatch_queue_s *do_targetq; \ //目标队列,GCD允许我们将一个队列放在另一个队列里执行任务 void *do_ctxt; \ //上下文,用来存储线程池相关数据,比如用于线程挂起和唤醒的信号量、线程池尺寸等 void *do_finalizer; //第二部分:DISPATCH_QUEUE_HEADER uint32_t volatile dq_running; \ //是否运行中 uint32_t dq_width; \ //最大并发数:主线程/串行中这个值为1 struct dispatch_object_s *volatile dq_items_tail; \ //链表尾节点 struct dispatch_object_s *volatile dq_items_head; \ //链表头节点 unsigned long dq_serialnum; \ //队列的序列号 dispatch_queue_t dq_specific_q; //specific队列 //其他: char dq_label[DISPATCH_QUEUE_MIN_LABEL_SIZE]; // must be last 说明队列的名字要少于64个字符 char _dq_pad[DISPATCH_QUEUE_CACHELINE_PAD]; // for static queues only};
4.队列的类型
队列的类型可以分为主队列、管理队列、自定义队列、全局队列4种类型。
4.1 主队列
我们在开发过程中可以使用dispatch_get_main_queue
获取主队列,看一下它的定义:
#define dispatch_get_main_queue() (&_dispatch_main_q)struct dispatch_queue_s _dispatch_main_q = {#if !DISPATCH_USE_RESOLVERS .do_vtable = &_dispatch_queue_vtable, .do_targetq = &_dispatch_root_queues[ DISPATCH_ROOT_QUEUE_IDX_DEFAULT_OVERCOMMIT_PRIORITY], #endif .do_ref_cnt = DISPATCH_OBJECT_GLOBAL_REFCNT, .do_xref_cnt = DISPATCH_OBJECT_GLOBAL_REFCNT, .do_suspend_cnt = DISPATCH_OBJECT_SUSPEND_LOCK, .dq_label = "com.apple.main-thread", .dq_running = 1, .dq_width = 1, //说明主队列是一个串行队列 .dq_serialnum = 1, };
接着我们看一下它的几个主要属性:
1.do_vtable
const struct dispatch_queue_vtable_s _dispatch_queue_vtable = { .do_type = DISPATCH_QUEUE_TYPE, .do_kind = "queue", .do_dispose = _dispatch_queue_dispose, .do_invoke = NULL, .do_probe = (void *)dummy_function_r0, .do_debug = dispatch_queue_debug, };
2.do_targetq
主队列的目标队列:"com.apple.root.default-overcommit-priority"这个全局队列。这里我们先提前总结一下:非全局队列的队列类型(主队列以及后面提到的管理队列和自定义队列),都需要压入到全局队列处理,所以需要设置do_targetq
。
[DISPATCH_ROOT_QUEUE_IDX_DEFAULT_OVERCOMMIT_PRIORITY] = { .do_vtable = &_dispatch_queue_root_vtable, .do_ref_cnt = DISPATCH_OBJECT_GLOBAL_REFCNT, .do_xref_cnt = DISPATCH_OBJECT_GLOBAL_REFCNT, .do_suspend_cnt = DISPATCH_OBJECT_SUSPEND_LOCK, .do_ctxt = &_dispatch_root_queue_contexts[ DISPATCH_ROOT_QUEUE_IDX_DEFAULT_OVERCOMMIT_PRIORITY], .dq_label = "com.apple.root.default-overcommit-priority", .dq_running = 2, .dq_width = UINT32_MAX, .dq_serialnum = 7, },
3.do_ref_cnt和do_xref_cnt
前面提到do_ref_cnt
和do_xref_cnt
是引用计数,主队列的这两个值为DISPATCH_OBJECT_GLOBAL_REFCNT
。既然是引用计数,那想必是和GCD的内存管理有关,找到和内存管理相关的代码:
voiddispatch_retain(dispatch_object_t dou){ if (slowpath(dou._do->do_xref_cnt == DISPATCH_OBJECT_GLOBAL_REFCNT)) { return; // global object } ... }void_dispatch_retain(dispatch_object_t dou) { if (slowpath(dou._do->do_ref_cnt == DISPATCH_OBJECT_GLOBAL_REFCNT)) { return; // global object } ... }voiddispatch_release(dispatch_object_t dou){ if (slowpath(dou._do->do_xref_cnt == DISPATCH_OBJECT_GLOBAL_REFCNT)) { return; } ... }void_dispatch_release(dispatch_object_t dou) { if (slowpath(dou._do->do_ref_cnt == DISPATCH_OBJECT_GLOBAL_REFCNT)) { return; // global object } ... }
从上面几个函数我们可以看出,主队列的生命周期是伴随着应用的,不会受retain和release的影响。
4.2 管理队列
_dispatch_mgr_q
(管理队列),是GCD的内部队列,不对外公开。从名字上看,这个队列应该是用来扮演管理的角色,GCD定时器就用到了管理队列。
struct dispatch_queue_s _dispatch_mgr_q = { .do_vtable = &_dispatch_queue_mgr_vtable, .do_ref_cnt = DISPATCH_OBJECT_GLOBAL_REFCNT, .do_xref_cnt = DISPATCH_OBJECT_GLOBAL_REFCNT, .do_suspend_cnt = DISPATCH_OBJECT_SUSPEND_LOCK, .do_targetq = &_dispatch_root_queues[ DISPATCH_ROOT_QUEUE_IDX_HIGH_OVERCOMMIT_PRIORITY], .dq_label = "com.apple.libdispatch-manager", .dq_width = 1, .dq_serialnum = 2, };
1.do_vtable
static const struct dispatch_queue_vtable_s _dispatch_queue_mgr_vtable = { .do_type = DISPATCH_QUEUE_MGR_TYPE, .do_kind = "mgr-queue", .do_invoke = _dispatch_mgr_thread, .do_debug = dispatch_queue_debug, .do_probe = _dispatch_mgr_wakeup, };
2.do_targetq
管理队列的目标队列:"com.apple.root.high-overcommit-priority"这个全局队列。
[DISPATCH_ROOT_QUEUE_IDX_HIGH_OVERCOMMIT_PRIORITY] = { .do_vtable = &_dispatch_queue_root_vtable, .do_ref_cnt = DISPATCH_OBJECT_GLOBAL_REFCNT, .do_xref_cnt = DISPATCH_OBJECT_GLOBAL_REFCNT, .do_suspend_cnt = DISPATCH_OBJECT_SUSPEND_LOCK, .do_ctxt = &_dispatch_root_queue_contexts[ DISPATCH_ROOT_QUEUE_IDX_HIGH_OVERCOMMIT_PRIORITY], .dq_label = "com.apple.root.high-overcommit-priority", .dq_running = 2, .dq_width = UINT32_MAX, .dq_serialnum = 9, },
3.do_ref_cnt和do_xref_cnt
管理队列的这两个值为DISPATCH_OBJECT_GLOBAL_REFCNT
,所以和主队列的生命周期应该是一样的。
4.3 自定义队列
我们在开发中会使用 dispatch_queue_create(const char *label, dispatch_queue_attr_t attire)
创建一个自定义的队列。它的源代码如下:
dispatch_queue_tdispatch_queue_create(const char *label, dispatch_queue_attr_t attr) { dispatch_queue_t dq; size_t label_len; if (!label) { label = ""; } label_len = strlen(label); if (label_len < (DISPATCH_QUEUE_MIN_LABEL_SIZE - 1)) { label_len = (DISPATCH_QUEUE_MIN_LABEL_SIZE - 1); } // XXX switch to malloc() dq = calloc(1ul, sizeof(struct dispatch_queue_s) - DISPATCH_QUEUE_MIN_LABEL_SIZE - DISPATCH_QUEUE_CACHELINE_PAD + label_len + 1); if (slowpath(!dq)) { return dq; }//队列初始化数据 _dispatch_queue_init(dq); strcpy(dq->dq_label, label); if (fastpath(!attr)) { return dq; } if (fastpath(attr == DISPATCH_QUEUE_CONCURRENT)) { dq->dq_width = UINT32_MAX; dq->do_targetq = _dispatch_get_root_queue(0, false); } else { dispatch_debug_assert(!attr, "Invalid attribute"); } return dq; }
1.slowpath(x)
和fastpath(x)
关于这两个宏的定义如下:
#define fastpath(x) ((typeof(x))__builtin_expect((long)(x), ~0l))#define slowpath(x) ((typeof(x))__builtin_expect((long)(x), 0l))
fastpath(x)
表示x的值一般不为0,希望编译器进行优化。slowpath(x)
表示x的值很可能为0,希望编译器进行优化。
2._dispatch_queue_init
static inline void _dispatch_queue_init(dispatch_queue_t dq) { dq->do_vtable = &_dispatch_queue_vtable; dq->do_next = DISPATCH_OBJECT_LISTLESS; dq->do_ref_cnt = 1; dq->do_xref_cnt = 1; // Default target queue is overcommit! dq->do_targetq = _dispatch_get_root_queue(0, true); dq->dq_running = 0; dq->dq_width = 1; dq->dq_serialnum = dispatch_atomic_inc(&_dispatch_queue_serial_numbers) - 1; }
_dispatch_queue_init
默认设置一个队列为串行队列,它的目标队列是_dispatch_get_root_queue(0, true)
。
3.do_targetq
前面对这个字段的解释有点简单了,do_targetq
代表目的队列。在Concurrent Programming: APIs and Challenges提到:
While custom queues are a powerful abstraction, all blocks you schedule on them will ultimately trickle down to one of the system’s global queues and its thread pool(s).
虽然自定义队列是一个强大的抽象,但你在队列上安排的所有Block最终都会渗透到系统的某一个全局队列及其线程池。
看起来自定义队列更像是全局队列的一个代理。在自定义队列创建的时候默认其目标队列为_dispatch_get_root_queue(0, true)
。其中0
代表优先级DISPATCH_QUEUE_PRIORITY_DEFAULT
,true
代表是否是overcommit
。overcommit
参数表示该队列在执行block时,无论系统多忙都会新开一个线程,这样做的目的是不会造成某个线程过载。如果是自定义并发队列的话,do_targetq
会被设置为_dispatch_get_root_queue(0, false)
。
值得注意的是,主队列的目标队列也是一个全局队列,全局队列的底层就是普通的线程池(这个会在全局队列中讲到)。
4.dq_serialnum
dq_serialnum
是在_dispatch_queue_serial_numbers
基础上进行原子操作加1,即从12开始累加。1到11被保留的序列号定义如下:
// skip zero// 1 - main_q// 2 - mgr_q// 3 - _unused_// 4,5,6,7,8,9,10,11 - global queues// we use 'xadd' on Intel, so the initial value == next assigned
其中1用于主队列,2用于管理队列,3暂时没有被使用,4~11是用于全局队列的。
4.4 全局队列
上面说了很多全局队列,现在我们来看一下全局队列是如何定义的。
dispatch_queue_tdispatch_get_global_queue(long priority, unsigned long flags) { if (flags & ~DISPATCH_QUEUE_OVERCOMMIT) { return NULL; } return _dispatch_get_root_queue(priority, flags & DISPATCH_QUEUE_OVERCOMMIT); }static inline dispatch_queue_t_dispatch_get_root_queue(long priority, bool overcommit) { if (overcommit) switch (priority) { case DISPATCH_QUEUE_PRIORITY_LOW: return &_dispatch_root_queues[ DISPATCH_ROOT_QUEUE_IDX_LOW_OVERCOMMIT_PRIORITY]; case DISPATCH_QUEUE_PRIORITY_DEFAULT: return &_dispatch_root_queues[ DISPATCH_ROOT_QUEUE_IDX_DEFAULT_OVERCOMMIT_PRIORITY]; case DISPATCH_QUEUE_PRIORITY_HIGH: return &_dispatch_root_queues[ DISPATCH_ROOT_QUEUE_IDX_HIGH_OVERCOMMIT_PRIORITY]; case DISPATCH_QUEUE_PRIORITY_BACKGROUND: return &_dispatch_root_queues[ DISPATCH_ROOT_QUEUE_IDX_BACKGROUND_OVERCOMMIT_PRIORITY]; } switch (priority) { case DISPATCH_QUEUE_PRIORITY_LOW: return &_dispatch_root_queues[DISPATCH_ROOT_QUEUE_IDX_LOW_PRIORITY]; case DISPATCH_QUEUE_PRIORITY_DEFAULT: return &_dispatch_root_queues[DISPATCH_ROOT_QUEUE_IDX_DEFAULT_PRIORITY]; case DISPATCH_QUEUE_PRIORITY_HIGH: return &_dispatch_root_queues[DISPATCH_ROOT_QUEUE_IDX_HIGH_PRIORITY]; case DISPATCH_QUEUE_PRIORITY_BACKGROUND: return &_dispatch_root_queues[ DISPATCH_ROOT_QUEUE_IDX_BACKGROUND_PRIORITY]; default: return NULL; } } DISPATCH_CACHELINE_ALIGNstruct dispatch_queue_s _dispatch_root_queues[] = { [DISPATCH_ROOT_QUEUE_IDX_LOW_PRIORITY] = { .do_vtable = &_dispatch_queue_root_vtable, .do_ref_cnt = DISPATCH_OBJECT_GLOBAL_REFCNT, .do_xref_cnt = DISPATCH_OBJECT_GLOBAL_REFCNT, .do_suspend_cnt = DISPATCH_OBJECT_SUSPEND_LOCK, .do_ctxt = &_dispatch_root_queue_contexts[ DISPATCH_ROOT_QUEUE_IDX_LOW_PRIORITY], .dq_label = "com.apple.root.low-priority", .dq_running = 2, .dq_width = UINT32_MAX, .dq_serialnum = 4, }, [DISPATCH_ROOT_QUEUE_IDX_LOW_OVERCOMMIT_PRIORITY] = { .do_vtable = &_dispatch_queue_root_vtable, .do_ref_cnt = DISPATCH_OBJECT_GLOBAL_REFCNT, .do_xref_cnt = DISPATCH_OBJECT_GLOBAL_REFCNT, .do_suspend_cnt = DISPATCH_OBJECT_SUSPEND_LOCK, .do_ctxt = &_dispatch_root_queue_contexts[ DISPATCH_ROOT_QUEUE_IDX_LOW_OVERCOMMIT_PRIORITY], .dq_label = "com.apple.root.low-overcommit-priority", .dq_running = 2, .dq_width = UINT32_MAX, .dq_serialnum = 5, }, [DISPATCH_ROOT_QUEUE_IDX_DEFAULT_PRIORITY] = { .do_vtable = &_dispatch_queue_root_vtable, .do_ref_cnt = DISPATCH_OBJECT_GLOBAL_REFCNT, .do_xref_cnt = DISPATCH_OBJECT_GLOBAL_REFCNT, .do_suspend_cnt = DISPATCH_OBJECT_SUSPEND_LOCK, .do_ctxt = &_dispatch_root_queue_contexts[ DISPATCH_ROOT_QUEUE_IDX_DEFAULT_PRIORITY], .dq_label = "com.apple.root.default-priority", .dq_running = 2, .dq_width = UINT32_MAX, .dq_serialnum = 6, }, [DISPATCH_ROOT_QUEUE_IDX_DEFAULT_OVERCOMMIT_PRIORITY] = { .do_vtable = &_dispatch_queue_root_vtable, .do_ref_cnt = DISPATCH_OBJECT_GLOBAL_REFCNT, .do_xref_cnt = DISPATCH_OBJECT_GLOBAL_REFCNT, .do_suspend_cnt = DISPATCH_OBJECT_SUSPEND_LOCK, .do_ctxt = &_dispatch_root_queue_contexts[ DISPATCH_ROOT_QUEUE_IDX_DEFAULT_OVERCOMMIT_PRIORITY], .dq_label = "com.apple.root.default-overcommit-priority", .dq_running = 2, .dq_width = UINT32_MAX, .dq_serialnum = 7, }, [DISPATCH_ROOT_QUEUE_IDX_HIGH_PRIORITY] = { .do_vtable = &_dispatch_queue_root_vtable, .do_ref_cnt = DISPATCH_OBJECT_GLOBAL_REFCNT, .do_xref_cnt = DISPATCH_OBJECT_GLOBAL_REFCNT, .do_suspend_cnt = DISPATCH_OBJECT_SUSPEND_LOCK, .do_ctxt = &_dispatch_root_queue_contexts[ DISPATCH_ROOT_QUEUE_IDX_HIGH_PRIORITY], .dq_label = "com.apple.root.high-priority", .dq_running = 2, .dq_width = UINT32_MAX, .dq_serialnum = 8, }, [DISPATCH_ROOT_QUEUE_IDX_HIGH_OVERCOMMIT_PRIORITY] = { .do_vtable = &_dispatch_queue_root_vtable, .do_ref_cnt = DISPATCH_OBJECT_GLOBAL_REFCNT, .do_xref_cnt = DISPATCH_OBJECT_GLOBAL_REFCNT, .do_suspend_cnt = DISPATCH_OBJECT_SUSPEND_LOCK, .do_ctxt = &_dispatch_root_queue_contexts[ DISPATCH_ROOT_QUEUE_IDX_HIGH_OVERCOMMIT_PRIORITY], .dq_label = "com.apple.root.high-overcommit-priority", .dq_running = 2, .dq_width = UINT32_MAX, .dq_serialnum = 9, }, [DISPATCH_ROOT_QUEUE_IDX_BACKGROUND_PRIORITY] = { .do_vtable = &_dispatch_queue_root_vtable, .do_ref_cnt = DISPATCH_OBJECT_GLOBAL_REFCNT, .do_xref_cnt = DISPATCH_OBJECT_GLOBAL_REFCNT, .do_suspend_cnt = DISPATCH_OBJECT_SUSPEND_LOCK, .do_ctxt = &_dispatch_root_queue_contexts[ DISPATCH_ROOT_QUEUE_IDX_BACKGROUND_PRIORITY], .dq_label = "com.apple.root.background-priority", .dq_running = 2, .dq_width = UINT32_MAX, .dq_serialnum = 10, }, [DISPATCH_ROOT_QUEUE_IDX_BACKGROUND_OVERCOMMIT_PRIORITY] = { .do_vtable = &_dispatch_queue_root_vtable, .do_ref_cnt = DISPATCH_OBJECT_GLOBAL_REFCNT, .do_xref_cnt = DISPATCH_OBJECT_GLOBAL_REFCNT, .do_suspend_cnt = DISPATCH_OBJECT_SUSPEND_LOCK, .do_ctxt = &_dispatch_root_queue_contexts[ DISPATCH_ROOT_QUEUE_IDX_BACKGROUND_OVERCOMMIT_PRIORITY], .dq_label = "com.apple.root.background-overcommit-priority", .dq_running = 2, .dq_width = UINT32_MAX, .dq_serialnum = 11, }, };
1.do_vtable
全局队列的do_vtable
:
static const struct dispatch_queue_vtable_s _dispatch_queue_root_vtable = { .do_type = DISPATCH_QUEUE_GLOBAL_TYPE, .do_kind = "global-queue", .do_debug = dispatch_queue_debug, .do_probe = _dispatch_queue_wakeup_global, };
2.do_ctxt
全局队列中有一个上下文的属性,用来存储线程池相关数据,比如用于线程挂起和唤醒的信号量、线程池尺寸等。
它的定义如下:
static struct dispatch_root_queue_context_s _dispatch_root_queue_contexts[] = { [DISPATCH_ROOT_QUEUE_IDX_LOW_PRIORITY] = {#if DISPATCH_ENABLE_THREAD_POOL .dgq_thread_mediator = &_dispatch_thread_mediator[ DISPATCH_ROOT_QUEUE_IDX_LOW_PRIORITY], .dgq_thread_pool_size = MAX_THREAD_COUNT,#endif }, [DISPATCH_ROOT_QUEUE_IDX_LOW_OVERCOMMIT_PRIORITY] = {#if DISPATCH_ENABLE_THREAD_POOL .dgq_thread_mediator = &_dispatch_thread_mediator[ DISPATCH_ROOT_QUEUE_IDX_LOW_OVERCOMMIT_PRIORITY], .dgq_thread_pool_size = MAX_THREAD_COUNT,#endif }, [DISPATCH_ROOT_QUEUE_IDX_DEFAULT_PRIORITY] = {#if DISPATCH_ENABLE_THREAD_POOL .dgq_thread_mediator = &_dispatch_thread_mediator[ DISPATCH_ROOT_QUEUE_IDX_DEFAULT_PRIORITY], .dgq_thread_pool_size = MAX_THREAD_COUNT,#endif }, [DISPATCH_ROOT_QUEUE_IDX_DEFAULT_OVERCOMMIT_PRIORITY] = {#if DISPATCH_ENABLE_THREAD_POOL .dgq_thread_mediator = &_dispatch_thread_mediator[ DISPATCH_ROOT_QUEUE_IDX_DEFAULT_OVERCOMMIT_PRIORITY], .dgq_thread_pool_size = MAX_THREAD_COUNT,#endif }, [DISPATCH_ROOT_QUEUE_IDX_HIGH_PRIORITY] = {#if DISPATCH_ENABLE_THREAD_POOL .dgq_thread_mediator = &_dispatch_thread_mediator[ DISPATCH_ROOT_QUEUE_IDX_HIGH_PRIORITY], .dgq_thread_pool_size = MAX_THREAD_COUNT,#endif }, [DISPATCH_ROOT_QUEUE_IDX_HIGH_OVERCOMMIT_PRIORITY] = {#if DISPATCH_ENABLE_THREAD_POOL .dgq_thread_mediator = &_dispatch_thread_mediator[ DISPATCH_ROOT_QUEUE_IDX_HIGH_OVERCOMMIT_PRIORITY], .dgq_thread_pool_size = MAX_THREAD_COUNT,#endif }, [DISPATCH_ROOT_QUEUE_IDX_BACKGROUND_PRIORITY] = {#if DISPATCH_ENABLE_THREAD_POOL .dgq_thread_mediator = &_dispatch_thread_mediator[ DISPATCH_ROOT_QUEUE_IDX_BACKGROUND_PRIORITY], .dgq_thread_pool_size = MAX_THREAD_COUNT,#endif }, [DISPATCH_ROOT_QUEUE_IDX_BACKGROUND_OVERCOMMIT_PRIORITY] = {#if DISPATCH_ENABLE_THREAD_POOL .dgq_thread_mediator = &_dispatch_thread_mediator[ DISPATCH_ROOT_QUEUE_IDX_BACKGROUND_OVERCOMMIT_PRIORITY], .dgq_thread_pool_size = MAX_THREAD_COUNT,#endif }, };
5. 队列的同步
5.1 dispatch_sync
dispatch_sync
的源码如下:
voiddispatch_sync(dispatch_queue_t dq, void (^work)(void)) {#if DISPATCH_COCOA_COMPAT if (slowpath(dq == &_dispatch_main_q)) { return _dispatch_sync_slow(dq, work); }#endif struct Block_basic *bb = (void *)work; dispatch_sync_f(dq, work, (dispatch_function_t)bb->Block_invoke); }
如果这个队列是主队列,则调用_dispatch_sync_slow
,否则调用dispatch_sync_f
。点开_dispatch_sync_slow
返现,最终还是调用了dispatch_sync_f
方法。通过_dispatch_Block_copy
或者Block_basic
完成由block到function的转换。所以block的执行底层还是使用function。
5.2 dispatch_sync_f
dispatch_sync_f
的源码如下:
voiddispatch_sync_f(dispatch_queue_t dq, void *ctxt, dispatch_function_t func){ //串行队列 if (fastpath(dq->dq_width == 1)) { return dispatch_barrier_sync_f(dq, ctxt, func); } //全局队列 if (slowpath(!dq->do_targetq)) { // the global root queues do not need strict ordering (void)dispatch_atomic_add2o(dq, dq_running, 2); return _dispatch_sync_f_invoke(dq, ctxt, func); } //并发队列 _dispatch_sync_f2(dq, ctxt, func); }
这里分成了三种情况:
1.如果是串行队列,执行dispatch_barrier_sync_f
。
2.如果是全局队列,执行_dispatch_sync_f_invoke
。
3.如果是并行队列,执行_dispatch_sync_f2
5.2.1 dispatch_barrier_sync_f
如果是串行队列压入同步任务,那么当前任务就必须等待前面的任务执行完成后才能执行。源代码就会调用dispatch_barrier_sync_f
函数完成上面的效果。
voiddispatch_barrier_sync_f(dispatch_queue_t dq, void *ctxt, dispatch_function_t func){ // 1) ensure that this thread hasn't enqueued anything ahead of this call // 2) the queue is not suspended //第一步:如果串行队列中存在其他任务或者队列被挂起,则直接进入_dispatch_sync_f_slow函数,等待这个队列中的其他任务完成(信号量的方式),然后执行这个任务。 if (slowpath(dq->dq_items_tail) || slowpath(DISPATCH_OBJECT_SUSPENDED(dq))){ return _dispatch_barrier_sync_f_slow(dq, ctxt, func); } //第二步:检测队列的dq_running状态,如果有运行,进入_dispatch_barrier_sync_f_slow,等待激活。 if (slowpath(!dispatch_atomic_cmpxchg2o(dq, dq_running, 0, 1))) { // global queues and main queue bound to main thread always falls into // the slow case return _dispatch_barrier_sync_f_slow(dq, ctxt, func); } //第三步:有多重队列,寻找真正的目标队列,其实还是回到了dispatch_sync_f方法 if (slowpath(dq->do_targetq->do_targetq)) { return _dispatch_barrier_sync_f_recurse(dq, ctxt, func); } //第四步:执行队列里的任务,执行后检测队列有无其他任务,如果有,释放前面的信号量(释放信号_dispatch_barrier_sync_f2函数中)。 _dispatch_barrier_sync_f_invoke(dq, ctxt, func); }
看了上面的代码注释后,我们来想一下同步串行队列死锁问题。死锁是怎么产生的?先看下示例代码:
#import "DeadLock.h"@implementation DeadLock- (instancetype)init { if (self = [super init]) {// [self _mianQueueDeadLock]; [self _serialQueueDeadLock]; } return self; }#pragma mark - Private- (void)_mianQueueDeadLock { dispatch_sync(dispatch_get_main_queue(), ^(void){ NSLog(@"这里死锁了"); }); } - (void)_serialQueueDeadLock { dispatch_queue_t queue1 = dispatch_queue_create("1serialQueue", DISPATCH_QUEUE_SERIAL); dispatch_queue_t queue2 = dispatch_queue_create("2serialQueue", DISPATCH_QUEUE_SERIAL); dispatch_sync(queue1, ^{ NSLog(@"11111"); dispatch_sync(queue1, ^{//如果使用queue2就不会发生死锁,使用queue1就会死锁 NSLog(@"22222"); }); }); }@end
以_serialQueueDeadLock
为例:当第一次执行串行队列任务的时候,跳到第四步,直接开始执行任务,在运行第二个dispatch_sync
时候,在任务里面通过执行第一步(队列在运行)向这个同步队列中压入信号量,然后等待信号量,进入死锁。如果主队列则会跳转到第二步进入死锁。
5.2.2 _dispatch_sync_f_invoke
static void_dispatch_sync_f_invoke(dispatch_queue_t dq, void *ctxt, dispatch_function_t func) { _dispatch_function_invoke(dq, ctxt, func); if (slowpath(dispatch_atomic_sub2o(dq, dq_running, 2) == 0)) { _dispatch_wakeup(dq); } }
如果当前队列是全局队列的话,就会调用_dispatch_sync_f_invoke
。这个函数的作用:执行传入的任务,然后根据dq_running检测任务队列有没有激活,没有激活就执行激活函数。关于激活函数_dispatch_wakeup(dq)
放在队列的异步中讲解。
5.2.3 _dispatch_sync_f2
_dispatch_sync_f2(dispatch_queue_t dq, void *ctxt, dispatch_function_t func) { // 1) ensure that this thread hasn't enqueued anything ahead of this call // 2) the queue is not suspended //第一步:并发队列中有其他任务或者队列被挂起,压入信号量,等待其他线程释放这个信号量 if (slowpath(dq->dq_items_tail) || slowpath(DISPATCH_OBJECT_SUSPENDED(dq))){ return _dispatch_sync_f_slow(dq, ctxt, func); } //第二步:并行队列没激活,激活队列后执行任务,最终还是调用了_dispatch_sync_f_slow函数,只是多了一个激活函数 if (slowpath(dispatch_atomic_add2o(dq, dq_running, 2) & 1)) { return _dispatch_sync_f_slow2(dq, ctxt, func); } //第三步:队列有多重队列,寻找真正的目标队列 if (slowpath(dq->do_targetq->do_targetq)) { return _dispatch_sync_f_recurse(dq, ctxt, func); } //第四步:并行队列没有其他任务,调用并激活这个队列 _dispatch_sync_f_invoke(dq, ctxt, func); }
通过上面的注释,并行队列同步执行是顺序执行的。这种顺序执行和操作队列为并发队列没有关系。而是因为这些操作均为同步操作,所以每一个操作放入队列后都会被等待执行完成才会放入下一操作,造成了这种顺序执行的现象。
现在我们整理一下队列同步执行的流程,如下图:
queue_synchronize.png
6. 队列的异步
说完了同步我们现在看一下异步。我们使用dispatch_async
进行队列的异步执行。
6.1 dispatch_async
dispatch_async
的源码如下:
voiddispatch_async(dispatch_queue_t dq, void (^work)(void)) { dispatch_async_f(dq, _dispatch_Block_copy(work), _dispatch_call_block_and_release); }
dispatch_async
主要将block从栈copy到堆上,或者增加引用计数,保证block在执行之前不会被销毁,另外_dispatch_call_block_and_release
用于销毁block。然后调用dispatch_async_f
。
6.2 dispatch_async_f
voiddispatch_async_f(dispatch_queue_t dq, void *ctxt, dispatch_function_t func){ dispatch_continuation_t dc; // No fastpath/slowpath hint because we simply don't know //串行队列,执行dispatch_barrier_async_f,其实最后还是执行任务入队的操作 if (dq->dq_width == 1) { return dispatch_barrier_async_f(dq, ctxt, func); } //从线程私有数据中获取一个dispatch_continuation_t的结构体 dc = fastpath(_dispatch_continuation_alloc_cacheonly()); if (!dc) { return _dispatch_async_f_slow(dq, ctxt, func); } dc->do_vtable = (void *)DISPATCH_OBJ_ASYNC_BIT; dc->dc_func = func; dc->dc_ctxt = ctxt; // No fastpath/slowpath hint because we simply don't know //有目标队列,调用_dispatch_async_f2函数进行转发。 if (dq->do_targetq) { return _dispatch_async_f2(dq, dc); } //全局队列直接进行入队操作 _dispatch_queue_push(dq, dc); }
从上面的源代码中我们可以看出dispatch_async_f
大致分为三种情况:
如果是串行队列,调用
dispatch_barrier_async_f
。其他队列且有目标队列,调用
_dispatch_async_f2
。如果是全局队列的话,直接进行入队操作。
虽然上面分三种情况,但是归根到底,它们最后执行都是_dispatch_queue_push
来进行入队的操作。
这里有一点需要注意下:就是dispatch_continuation_t
中do_vtable
的赋值情况。
//串行队列,barrierdc->do_vtable = (void *)(DISPATCH_OBJ_ASYNC_BIT | DISPATCH_OBJ_BARRIER_BIT);//not barrierdc->do_vtable = (void *)DISPATCH_OBJ_ASYNC_BIT;
在libdispatch
全部标识符有四种:
#define DISPATCH_OBJ_ASYNC_BIT 0x1 //异步#define DISPATCH_OBJ_BARRIER_BIT 0x2 //阻塞#define DISPATCH_OBJ_GROUP_BIT 0x4 //组#define DISPATCH_OBJ_SYNC_SLOW_BIT 0x8 //同步慢
从上面我们可以知道串行队列在异步执行的时候,通过DISPATCH_OBJ_BARRIER_BIT
这个标识符实现阻塞等待的。
接着我们分析下dispatch_barrier_async_f
和_dispatch_async_f2
这两个函数。
6.2.1 dispatch_barrier_async_f
dispatch_barrier_async_f
的源码如下:
voiddispatch_barrier_async_f(dispatch_queue_t dq, void *ctxt, dispatch_function_t func){ dispatch_continuation_t dc; //从线程私有数据中获取一个dispatch_continuation_t的结构体,dispatch_continuation_t中封装了异步执行任务。 dc = fastpath(_dispatch_continuation_alloc_cacheonly()); if (!dc) { //return _dispatch_barrier_async_f_slow(dq, ctxt, func); //以下是_dispatch_barrier_async_f_slow的具体实现 //如果没有则从堆上获取一个dispatch_continuation_t的结构体 dispatch_continuation_t dc = _dispatch_continuation_alloc_from_heap(); //通过do_vtable区分类型 dc->do_vtable = (void *)(DISPATCH_OBJ_ASYNC_BIT | DISPATCH_OBJ_BARRIER_BIT); //将_dispatch_call_block_and_release作为func方法 dc->dc_func = func; //将传入的block作为上下文 dc->dc_ctxt = ctxt; //入队操作 _dispatch_queue_push(dq, dc); } dc->do_vtable = (void *)(DISPATCH_OBJ_ASYNC_BIT | DISPATCH_OBJ_BARRIER_BIT); dc->dc_func = func; dc->dc_ctxt = ctxt; _dispatch_queue_push(dq, dc); }
6.3 _dispatch_queue_push
_dispatch_queue_push
是一个宏定义,它最后会变成执行_dispatch_queue_push_list
函数。
#define _dispatch_queue_push(x, y) _dispatch_queue_push_list((x), (y), (y))#define _dispatch_queue_push_list _dispatch_trace_queue_push_liststatic inline void_dispatch_trace_queue_push_list(dispatch_queue_t dq, dispatch_object_t _head, dispatch_object_t _tail) { if (slowpath(DISPATCH_QUEUE_PUSH_ENABLED())) { struct dispatch_object_s *dou = _head._do; do { //主要是对dispatch_continuation_s结构体的处理,确保后面的使用。 _dispatch_trace_continuation(dq, dou, DISPATCH_QUEUE_PUSH); } while (dou != _tail._do && (dou = dou->do_next)); } _dispatch_queue_push_list(dq, _head, _tail); }static inline void_dispatch_queue_push_list(dispatch_queue_t dq, dispatch_object_t _head, dispatch_object_t _tail) { struct dispatch_object_s *prev, *head = _head._do, *tail = _tail._do; tail->do_next = NULL; dispatch_atomic_store_barrier(); //dispatch_atomic_xchg2o实质是调用((typeof(*(p)))__sync_swap((p), (n))),它的定义是将p设为n并返回p操作之前的值。 //dispatch_atomic_xchg2o(dq, dq_items_tail, tail)相当于dq->dq_items_tail = tail,重新设置了队列的尾指针 prev = fastpath(dispatch_atomic_xchg2o(dq, dq_items_tail, tail)); if (prev) { // if we crash here with a value less than 0x1000, then we are at a // known bug in client code for example, see _dispatch_queue_dispose // or _dispatch_atfork_child //prev是原先的队尾,如果队列中有其他的元素,就将压入的对象加在队列的尾部。 prev->do_next = head; } else { //如果队列为空 _dispatch_queue_push_list_slow(dq, head); } }
_dispatch_queue_push_list_slow
如果队列为空,调用_dispatch_queue_push_list_slow
方法。
_dispatch_queue_push_list_slow(dispatch_queue_t dq, struct dispatch_object_s *obj) { //dq->dq_items_head设置为dc,然后唤醒这个队列。因为此时队列为空,没有任务在执行,处于休眠状态,所以需要唤醒 _dispatch_retain(dq); dq->dq_items_head = obj; _dispatch_wakeup(dq); _dispatch_release(dq); }
6.4 _dispatch_wakeup
无论是同步还是异步中都调用了_dispatch_wakeup
,这个函数的作用就是唤醒当前队列。
_dispatch_wakeup
的源码:
dispatch_queue_t_dispatch_wakeup(dispatch_object_t dou) { dispatch_queue_t tq; if (slowpath(DISPATCH_OBJECT_SUSPENDED(dou._do))) { return NULL; } //这里比较隐晦,这里其实是走全局队列的唤醒逻辑调用_dispatch_queue_wakeup_global,如果唤醒失败且对尾指针为空,返回NULL if (!dx_probe(dou._do) && !dou._dq->dq_items_tail) { return NULL; } // _dispatch_source_invoke() relies on this testing the whole suspend count // word, not just the lock bit. In other words, no point taking the lock // if the source is suspended or canceled. if (!dispatch_atomic_cmpxchg2o(dou._do, do_suspend_cnt, 0, DISPATCH_OBJECT_SUSPEND_LOCK)) {#if DISPATCH_COCOA_COMPAT if (dou._dq == &_dispatch_main_q) { //传入主队列,会进入到 _dispatch_queue_wakeup_main() 函数中 _dispatch_queue_wakeup_main(); }#endif return NULL; } _dispatch_retain(dou._do); //有目标队列,继续向目标队列压入这个队列 tq = dou._do->do_targetq; _dispatch_queue_push(tq, dou._do); return tq; // libdispatch does not need this, but the Instrument DTrace // probe does}
从上面的代码可以看出_dispatch_wakeup
分为三种情况:
1.主队列调用_dispatch_queue_wakeup_main()
。
2.全局队列调用_dispatch_queue_wakeup_global
。
3.其他队列像目标队列压入这个队列,继续做入队操作。
6.4.1 _dispatch_queue_wakeup_main
void_dispatch_queue_wakeup_main(void) { kern_return_t kr; dispatch_once_f(&_dispatch_main_q_port_pred, NULL, _dispatch_main_q_port_init); //唤醒主线程,这里已经点不进去了,关于主线的唤醒主要靠mach_port和在runloop中注册相对应的source1 kr = _dispatch_send_wakeup_main_thread(main_q_port, 0); switch (kr) { case MACH_SEND_TIMEOUT: case MACH_SEND_TIMED_OUT: case MACH_SEND_INVALID_DEST: break; default: (void)dispatch_assume_zero(kr); break; } _dispatch_safe_fork = false; }
6.4.2 _dispatch_queue_wakeup_global
上面提到dx_probe(dou._do)
这里走的是全局队列的唤醒。前面提到全局队列的do_vtable
:
static const struct dispatch_queue_vtable_s _dispatch_queue_root_vtable = { .do_type = DISPATCH_QUEUE_GLOBAL_TYPE, .do_kind = "global-queue", .do_debug = dispatch_queue_debug, .do_probe = _dispatch_queue_wakeup_global, };
_dispatch_queue_wakeup_global
的源码:
static bool_dispatch_queue_wakeup_global(dispatch_queue_t dq) { static dispatch_once_t pred; struct dispatch_root_queue_context_s *qc = dq->do_ctxt; int r; if (!dq->dq_items_tail) { return false; } _dispatch_safe_fork = false; dispatch_debug_queue(dq, __PRETTY_FUNCTION__); dispatch_once_f(&pred, NULL, _dispatch_root_queues_init);#if HAVE_PTHREAD_WORKQUEUES#if DISPATCH_ENABLE_THREAD_POOL //队列上下文的dgq_kworkqueue存在,则调用pthread_workqueue_additem_np函数,该函数使用workq_kernreturn系统调用,通知workqueue增加应当执行的项目。根据该通知,XNU内核基于系统状态判断是否要生成线程,如果是overcommit优先级的队列,workqueue则始终生成线程,之后线程执行_dispatch_worker_thread2函数。 //工作队列,是一个用于创建内核线程的接口,通过它创建的内核线程来执行内核其他模块排列到队列里的工作。不同优先级的dispatch queue对应着对应优先级的workqueue。GCD初始化的时候,使用pthread_workqueue_create_np创建pthread_workqueue if (qc->dgq_kworkqueue)#endif { if (dispatch_atomic_cmpxchg2o(qc, dgq_pending, 0, 1)) { pthread_workitem_handle_t wh; unsigned int gen_cnt; _dispatch_debug("requesting new worker thread"); r = pthread_workqueue_additem_np(qc->dgq_kworkqueue, _dispatch_worker_thread2, dq, &wh, &gen_cnt); (void)dispatch_assume_zero(r); } else { _dispatch_debug("work thread request still pending on global " "queue: %p", dq); } goto out; }#endif // HAVE_PTHREAD_WORKQUEUES#if DISPATCH_ENABLE_THREAD_POOL //通过发送一个信号量使线程保活 if (dispatch_semaphore_signal(qc->dgq_thread_mediator)) { goto out; } pthread_t pthr; int t_count; do { t_count = qc->dgq_thread_pool_size; if (!t_count) { _dispatch_debug("The thread pool is full: %p", dq); goto out; } } while (!dispatch_atomic_cmpxchg2o(qc, dgq_thread_pool_size, t_count, t_count - 1));//如果线程池可用则减1 //这里说明线程池不够用了,使用pthread创建一个线程,并执行_dispatch_worker_thread,_dispatch_worker_thread最终会调用到_dispatch_worker_thread2 while ((r = pthread_create(&pthr, NULL, _dispatch_worker_thread, dq))) { if (r != EAGAIN) { (void)dispatch_assume_zero(r); } sleep(1); } //保证pthr能被自动回收掉 r = pthread_detach(pthr); (void)dispatch_assume_zero(r);#endif // DISPATCH_ENABLE_THREAD_POOLout: return false; }
6.4.3 _dispatch_worker_thread2
_dispatch_worker_thread2
的代码如下:
_dispatch_worker_thread2(void *context) { struct dispatch_object_s *item; dispatch_queue_t dq = context; struct dispatch_root_queue_context_s *qc = dq->do_ctxt; if (_dispatch_thread_getspecific(dispatch_queue_key)) { DISPATCH_CRASH("Premature thread recycling"); } //把dq设置为刚启动的这个线程的TSD _dispatch_thread_setspecific(dispatch_queue_key, dq); qc->dgq_pending = 0;#if DISPATCH_COCOA_COMPAT (void)dispatch_atomic_inc(&_dispatch_worker_threads); // ensure that high-level memory management techniques do not leak/crash if (dispatch_begin_thread_4GC) { dispatch_begin_thread_4GC(); } void *pool = _dispatch_begin_NSAutoReleasePool();#endif#if DISPATCH_PERF_MON uint64_t start = _dispatch_absolute_time();#endif //_dispatch_queue_concurrent_drain_one用来取出队列的一个内容 while ((item = fastpath(_dispatch_queue_concurrent_drain_one(dq)))) { // 用来对取出的内容进行处理(如果是任务,则执行任务) _dispatch_continuation_pop(item); }#if DISPATCH_PERF_MON _dispatch_queue_merge_stats(start);#endif#if DISPATCH_COCOA_COMPAT _dispatch_end_NSAutoReleasePool(pool); dispatch_end_thread_4GC(); if (!dispatch_atomic_dec(&_dispatch_worker_threads) && dispatch_no_worker_threads_4GC) { dispatch_no_worker_threads_4GC(); }#endif _dispatch_thread_setspecific(dispatch_queue_key, NULL); _dispatch_force_cache_cleanup(); }
这里有两个比较重要的方法:
1._dispatch_queue_concurrent_drain_one
这个方法用来取出队列中中的一个内容。
2._dispatch_continuation_pop
这个方法用来处理取出的内容
_dispatch_queue_concurrent_drain_one
struct dispatch_object_s * _dispatch_queue_concurrent_drain_one(dispatch_queue_t dq) { struct dispatch_object_s *head, *next, *const mediator = (void *)~0ul; // The mediator value acts both as a "lock" and a signal head = dispatch_atomic_xchg(&dq->dq_items_head, mediator); if (slowpath(head == NULL)) { //队列是空的 dispatch_atomic_cmpxchg(&dq->dq_items_head, mediator, NULL); _dispatch_debug("no work on global work queue"); return NULL; } if (slowpath(head == mediator)) { // 该线程在现线程竞争中失去了对队列的拥有权,这意味着libdispatch的效率很糟糕, // 这种情况意味着在线程池中有太多的线程,这个时候应该创建一个pengding线程, // 然后退出该线程,内核会在负载减弱的时候创建一个新的线程 _dispatch_queue_wakeup_global(dq); return NULL; } // 在返回之前将head指针的do_next保存下来,如果next为NULL,这意味着item是最后一个 next = fastpath(head->do_next); if (slowpath(!next)) { dq->dq_items_head = NULL; if (dispatch_atomic_cmpxchg(&dq->dq_items_tail, head, NULL)) { // head 和 tail头尾指针均为空 goto out; } // 此时一定有item,该线程不会等待太久. while (!(next = head->do_next)) { _dispatch_hardware_pause(); } } // 继续调度 dq->dq_items_head = next; _dispatch_queue_wakeup_global(dq); out: // 返回队列的头指针 return head; }
_dispatch_continuation_pop
static inline void_dispatch_continuation_pop(dispatch_object_t dou) { dispatch_continuation_t dc = dou._dc; dispatch_group_t dg; _dispatch_trace_continuation_pop(_dispatch_queue_get_current(), dou); //检测是不是队列,如果是,就进入_dispatch_queue_invoke 处理队列 if (DISPATCH_OBJ_IS_VTABLE(dou._do)) { return _dispatch_queue_invoke(dou._dq); } // Add the item back to the cache before calling the function. This // allows the 'hot' continuation to be used for a quick callback. // // The ccache version is per-thread. // Therefore, the object has not been reused yet. // This generates better assembly. if ((long)dc->do_vtable & DISPATCH_OBJ_ASYNC_BIT) { _dispatch_continuation_free(dc); } //判断是否是group if ((long)dc->do_vtable & DISPATCH_OBJ_GROUP_BIT) { dg = dc->dc_group; } else { dg = NULL; } //是任务封装的 dispatch_continuation_t 结构体,直接执行任务。 //到这里我们知道了队列执行的时候,block被调用的时机 _dispatch_client_callout(dc->dc_ctxt, dc->dc_func); if (dg) { //group需要进行调用dispatch_group_leave并释放信号 dispatch_group_leave(dg); _dispatch_release(dg); } }
从上面的函数中可以发现,压入队列的不仅是任务,还有可能是队列。如果是队列,直接执行了_dispatch_queue_invoke
,否则执行dc->dc_func(dc->dc_ctxt)
。
_dispatch_queue_invoke
void _dispatch_queue_invoke(dispatch_queue_t dq) { if (!slowpath(DISPATCH_OBJECT_SUSPENDED(dq)) && fastpath(dispatch_atomic_cmpxchg2o(dq, dq_running, 0, 1))) { dispatch_atomic_acquire_barrier(); dispatch_queue_t otq = dq->do_targetq, tq = NULL; _dispatch_queue_drain(dq); if (dq->do_vtable->do_invoke) { // Assume that object invoke checks it is executing on correct queue tq = dx_invoke(dq); } else if (slowpath(otq != dq->do_targetq)) { // An item on the queue changed the target queue tq = dq->do_targetq; } // We do not need to check the result. // When the suspend-count lock is dropped, then the check will happen. dispatch_atomic_release_barrier(); //dq_running减1,因为任务要么被直接执行了,要么被压到target队列了 (void)dispatch_atomic_dec2o(dq, dq_running); if (tq) { return _dispatch_queue_push(tq, dq); } } dq->do_next = DISPATCH_OBJECT_LISTLESS; if (!dispatch_atomic_sub2o(dq, do_suspend_cnt, DISPATCH_OBJECT_SUSPEND_LOCK)) { //队列处于空闲状态,需要唤醒 if (dq->dq_running == 0) { _dispatch_wakeup(dq); // verify that the queue is idle } } //释放队列 _dispatch_release(dq); // added when the queue is put on the list}
现在我们整理一下队列异步执行的流程,如下图:
dispatch_async.png
7.总结
1.dispatch_sync
函数一般都在当前线程执行,利用与线程绑定的信号量来实现串行。
2.dispatch_async
函数并不是将block直接添加到队列上,而是先构成一个dispatch_continuation
构造体,构造体包含了这个block还有一些上下文信息。队列会将这些任务添加队列的链表中,之后会唤醒队列,根据vtable
中的函数指针,调用_dispatch_wakeup
方法。在_dispatch_wakeup
方法中,从线程池里取出工作线程(如果没有就新建),然后在工作线程中取出对应block并执行。
3.dispatch_async
分发到主队列的任务由Runloop
处理,而分发到其他队列的任务由线程池处理。
4.GCD死锁是队列导致的而不是线程导致,原因是_dispatch_barrier_sync_f_slow
函数中使用了线程对应的信号量并且调用wait方法,从而导致线程死锁。
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