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a83428b883
Some build system tidies. Add -retain / release to Protocol. Initial work on clang-specific makefile.
241 lines
7.6 KiB
C
241 lines
7.6 KiB
C
#include <pthread.h>
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#include <stdlib.h>
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#define __TOY_DISPATCH__
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#include "objc/toydispatch.h"
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/**
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* Amount of total space in the ring buffer. Must be a power of two.
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*/
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#define RING_BUFFER_SIZE 32
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/**
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* Mask for converting a free-running counters into ring buffer indexes.
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*/
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#define RING_BUFFER_MASK (RING_BUFFER_SIZE - 1)
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struct dispatch_queue
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{
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/**
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* Reference count for this queue.
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*/
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int refcount;
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/**
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* Spin lock value. Set to 1 when the queue is locked. This allows
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* multiple threads to write to the queue but only one to read from it.
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* Reading and writing can happen concurrently, but writing requires
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* acquisition of this lock.
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*/
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volatile int spinlock;
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/**
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* Producer free-running counter. Incremented every time that a new item
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* is inserted into the ring buffer.
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*/
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unsigned int producer;
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/**
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* Consumer free-running counter. Incremented every time that an item is
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* removed from the buffer.
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*/
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unsigned int consumer;
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/**
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* Mutex used to protect the condition variable.
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*/
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pthread_mutex_t mutex;
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/**
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* Condition variable used in blocking mode. The consumer thread will
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* sleep on this condition variable when the queue has been empty for a
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* little while. The next producer thread to insert something will poke
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* the condition variable on any empty->non-empty transition.
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*/
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pthread_cond_t conditionVariable;
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/**
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* Ring buffer containing functions and data to be executed by the
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* consumer.
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*/
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struct
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{
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dispatch_function_t function;
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void *data;
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} ring_buffer[RING_BUFFER_SIZE];
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};
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/**
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* Check how much space is in the queue. The number of used elements in the
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* queue is always equal to producer - consumer. Producer will always
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* overflow before consumer (because you can't remove objects that have not
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* been inserted. In this case, the subtraction will be something along the
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* lines of (0 - (2^32 - 14)). This will be -(2^32 - 14), however this value
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* can't be represented in a 32-bit integer and so will overflow to 14, giving
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* the correct result, irrespective of overflow.
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*/
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#define SPACE(q) (RING_BUFFER_SIZE - (q->producer - q->consumer))
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/**
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* The buffer is full if there is no space in it.
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*/
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#define ISFULL(q) (SPACE(q) == 0)
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/**
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* The buffer is empty if there is no data in it.
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*/
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#define ISEMPTY(q) ((q->producer - q->consumer) == 0)
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/**
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* Converting the free running counters to array indexes is a masking
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* operation. For this to work, the buffer size must be a power of two.
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* RING_BUFFER_MASK = RING_BUFFER_SIZE - 1. If RING_BUFFER_SIZE is 256, we want the lowest 8
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* bits of the index, which is obtained by ANDing the value with 255. Any
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* power of two may be selected. Non power-of-two values could be used if a
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* more complex mapping operation were chosen, but this one is nice and cheap.
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*/
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#define MASK(index) ((index) & RING_BUFFER_MASK)
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/**
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* Lock the queue. This uses a very lightweight, nonrecursive, spinlock. It
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* is expected that queue insertions will be relatively uncontended.
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*/
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inline static void lock_queue(dispatch_queue_t queue)
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{
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// Set the spin lock value to 1 if it is 0.
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while(!__sync_bool_compare_and_swap(&queue->spinlock, 0, 1))
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{
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// If it is already 1, let another thread play with the CPU for a bit
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// then try again.
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sched_yield();
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}
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}
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/**
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* Unlock the queue. This doesn't need to be an atomic op; that will cause a
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* complete pipeline flush on this thread and not actually buy us anything
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* because at this point only one thread (this one) will do anything that will
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* modify the variable. The other threads will all be using atomic
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* compare-and-exchange instructions which will fail because we already set it
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* to 1.
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*/
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inline static void unlock_queue(dispatch_queue_t queue)
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{
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queue->spinlock = 0;
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}
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/**
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* Inserting an element into the queue involves the following steps:
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*
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* 1) Check that there is space in the buffer.
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* Spin if there isn't any.
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* 2) Add the invocation and optionally the proxy containing the return value
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* (nil for none) to the next two elements in the ring buffer.
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* 3) Increment the producer counter (by two, since we are adding two elements).
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* 4) If the queue was previously empty, we need to transition back to lockless
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* mode. This is done by signalling the condition variable that the other
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* thread will be waiting on if it is in blocking mode.
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*/
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inline static void insert_into_queue(dispatch_queue_t queue,
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dispatch_function_t function,
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void *data)
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{
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/* Wait for space in the buffer */
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lock_queue(queue);
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while (ISFULL(queue))
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{
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sched_yield();
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}
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unsigned int idx = MASK(queue->producer);
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queue->ring_buffer[idx].function = function;
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queue->ring_buffer[idx].data = data;
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// NOTE: This doesn't actually need to be atomic on a strongly-ordered
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// architecture like x86.
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__sync_fetch_and_add(&queue->producer, 1);
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unsigned int space = queue->producer - queue->consumer;
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unlock_queue(queue);
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// If we've just transitioned from empty to full, wake up the consumer thread.
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// Note: We do this after unlocking the queue, because it is much more
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// expensive than anything else that we do in this function and we don't
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// want to hold the spinlock for any longer than possible. We need to
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// calculate the space first, however, because otherwise another thread may
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// increment producer, while consumer stays the same (with the consumer
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// thread sleeping), preventing the wakeup.
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if (space == 1)
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{
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pthread_mutex_lock(&queue->mutex);
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pthread_cond_signal(&queue->conditionVariable);
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pthread_mutex_unlock(&queue->mutex);
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}
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}
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/**
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* Removing an element from the queue involves the following steps:
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*
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* 1) Wait until the queue has messages waiting. If there are none, enter
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* blocking mode. The additional test inside the mutex ensures that a
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* transition from blocking to non-blocking mode will not be missed, since the
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* condition variable can only be signalled when the producer thread has the
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* mutex.
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* 2) Read the invocation and return proxy from the buffer.
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* 3) Incrememt the consumer counter.
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*/
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static inline void read_from_queue(dispatch_queue_t queue,
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dispatch_function_t *function, void **data)
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{
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while (ISEMPTY(queue))
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{
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pthread_mutex_lock(&queue->mutex);
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if (ISEMPTY(queue))
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{
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pthread_cond_wait(&queue->conditionVariable, &queue->mutex);
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}
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pthread_mutex_unlock(&queue->mutex);
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}
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unsigned int idx = MASK(queue->consumer);
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*function = queue->ring_buffer[idx].function;
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*data = queue->ring_buffer[idx].data;
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__sync_fetch_and_add(&queue->consumer, 1);
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}
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static void *runloop(void *q)
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{
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dispatch_queue_t queue = q;
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dispatch_function_t function;
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void *data;
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while (queue->refcount > 0)
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{
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read_from_queue(queue, &function, &data);
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function(data);
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}
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pthread_cond_destroy(&queue->conditionVariable);
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pthread_mutex_destroy(&queue->mutex);
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free(queue);
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return NULL;
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}
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dispatch_queue_t dispatch_queue_create(const char *label,
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void *attr)
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{
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dispatch_queue_t queue = calloc(1, sizeof(struct dispatch_queue));
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queue->refcount = 1;
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pthread_cond_init(&queue->conditionVariable, NULL);
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pthread_mutex_init(&queue->mutex, NULL);
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pthread_t thread;
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pthread_create(&thread, NULL, runloop, queue);
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pthread_detach(thread);
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return queue;
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}
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void dispatch_async_f(dispatch_queue_t queue, void *context,
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dispatch_function_t work)
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{
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insert_into_queue(queue, work, context);
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}
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static void release(void *queue)
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{
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((dispatch_queue_t)queue)->refcount--;
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}
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void dispatch_release(dispatch_queue_t queue)
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{
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// Asynchronously release the queue, so that we don't delete it before all
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// of the work is finished.
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insert_into_queue(queue, release, queue);
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}
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void dispatch_retain(dispatch_queue_t queue)
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{
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queue->refcount++;
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}
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