线程池的设计与测试

编写了一个最基本的线程池类，处理用c_work表示的工作任务。C++还很不熟练，欢迎会C++的提出宝贵的修改意见。

程序有注释，所以应该很好读懂。测试程序在下面。

 

 

///////////////////////////////////////////////////////
//线程池类
///////////////////////////////////////////////////////
#include <pthread.h>
#include <stdlib.h>
#include <stdio.h>
#include <unistd.h>
#include <assert.h>

constint DEFAULT_MAX_THREAD_NUM = 10;
constint MAX_WORK_NUM = 100000;
//c_worker类
class c_work
{
public:
c_work():process(NULL), arg(NULL), next(NULL){}
c_work(void *(*prcss)(void *), void *arg):
process(prcss), arg(arg), next(NULL) {}
~c_work();

void *(*process)(void *);
void *arg;
unsigned char type; //最高位表示arg是否需要delete操作
c_work *next;
};

c_work::~c_work()
{
unsigned char ifdel = type >> 7;
if (ifdel)
{
delete arg;
arg = NULL;
}
}

class c_thread_pool
{
public:
c_thread_pool();
c_thread_pool(constint max_thread_num);
~c_thread_pool();

int add_work(c_work work);
staticvoid *thread_routine(void *arg);

pthread_mutex_t queue_lock;
pthread_cond_t queue_cond;

// private:
c_work *queue_head;
c_work *queue_tail;
int shutdown;

pthread_t *threadid;
int max_thread_num;
int cur_queue_size;
};

c_thread_pool::c_thread_pool()
{

pthread_mutex_init(&queue_lock, NULL);
pthread_cond_init(&queue_cond, NULL);

//工作队列初始化
queue_head = NULL;
queue_tail = NULL;

max_thread_num = max_thread_num;
cur_queue_size = 0;

shutdown = 0;

max_thread_num = DEFAULT_MAX_THREAD_NUM;
threadid = new pthread_t[max_thread_num];
int i = 0;

for (i = 0; i < max_thread_num; i++)
{
pthread_create(&(threadid[i]), NULL, thread_routine, (void*)this);
}
}


c_thread_pool::c_thread_pool(int max_thread_num)
{

pthread_mutex_init(&queue_lock, NULL);
pthread_cond_init(&queue_cond, NULL);

//工作队列初始化
queue_head = NULL;
queue_tail = NULL;

max_thread_num = max_thread_num;
cur_queue_size = 0;

threadid = new pthread_t[max_thread_num];
int i = 0;
for (i = 0; i < max_thread_num; i++)
{
pthread_create(&(threadid[i]), NULL, thread_routine, (void*)this);
}
}

/*向线程池中的任务队列加入任务*/
int c_thread_pool::add_work(c_work work)
{
c_work *newwork = new c_work;
newwork->process = work.process;
newwork->arg = work.arg;
newwork->next = NULL;

pthread_mutex_lock(&queue_lock);

/*将任务加入到等待队列中*/
if (queue_head != NULL && queue_tail != NULL)
{
queue_tail->next = newwork;
queue_tail = newwork;
}
else
{
//空队列
queue_head = newwork;
queue_tail = newwork;
}

cur_queue_size++;
pthread_mutex_unlock(&queue_lock);
/*等待队列中有任务了，唤醒一个等待线程,注意如果所有线程都在忙碌，这句没有任何作用*/
pthread_cond_signal(&(queue_cond));
printf("add work returned!\n");
return 0;
}


void* c_thread_pool::thread_routine(void *arg)
{
c_thread_pool *pool = (c_thread_pool *)arg;
int i = 0;
while (1)
{
pthread_mutex_lock(&(pool->queue_lock));
//如果等待队列为0并且不销毁线程池，则处于阻塞状态; 注意
// pthread_cond_wait是一个原子操作，等待前会解锁，唤醒后会加锁

//标注：注意这一如果任务队列不为空的话，while语句将被跳过，直接执行下面的调用。
while (pool->cur_queue_size == 0 && pool->shutdown)
{
pthread_cond_wait(&(pool->queue_cond), &(pool->queue_lock));
}


//等待队列长度减去1，并取出链表中的头元素
if (pool->cur_queue_size > 0 && pool->queue_head != NULL)
{
printf("IN THREAD ROUTINE size = %d && queue head is not NULL\n", pool->cur_queue_size);
pool->cur_queue_size--;
c_work *work = pool->queue_head;
pool->queue_head = work->next;
pthread_mutex_unlock(&(pool->queue_lock));

//调用回调函数，执行测试任务
//////////////////////////////////////////
(*(work->process))(work->arg);
free(work);
work = NULL;
}
else//不可达
{
pthread_mutex_unlock(&(pool->queue_lock));
}
}

}

c_thread_pool::~c_thread_pool()
{
for (int i = 0; i < max_thread_num; ++i)
pthread_cancel(threadid[i]);
for (c_work *w_t = queue_head; w_t != NULL;)
{
c_work *temp = w_t->next;
delete w_t;
w_t = temp;
}
delete [] threadid;
}

///////////////////////////////////////////////////////
//线程池类 
///////////////////////////////////////////////////////
#include <pthread.h>
#include <stdlib.h>
#include <stdio.h>
#include <unistd.h>
#include <assert.h>

const int DEFAULT_MAX_THREAD_NUM = 10;
const int MAX_WORK_NUM = 100000;
//c_worker类
class c_work
{
	public:
		c_work():process(NULL), arg(NULL), next(NULL){}
		c_work(void *(*prcss)(void *), void *arg):
			process(prcss), arg(arg), next(NULL) {}
		~c_work(); 

		void *(*process)(void *);
		void *arg;
		unsigned char type; //最高位表示arg是否需要delete操作
		c_work *next;
};

c_work::~c_work()
{
	unsigned char ifdel = type >> 7;
	if (ifdel)
	{
		delete arg;
		arg = NULL;
	}
}

class c_thread_pool
{
	public:
		c_thread_pool();
		c_thread_pool(const int max_thread_num);
		~c_thread_pool();

		int add_work(c_work work);
		static void *thread_routine(void *arg);

		pthread_mutex_t queue_lock;
		pthread_cond_t queue_cond;

//	private:
		c_work *queue_head;
		c_work *queue_tail;
		int shutdown;

		pthread_t *threadid;
		int max_thread_num;
		int cur_queue_size;
};

c_thread_pool::c_thread_pool()
{

	pthread_mutex_init(&queue_lock, NULL);
	pthread_cond_init(&queue_cond, NULL);

	//工作队列初始化
	queue_head = NULL;
	queue_tail = NULL;
	
	max_thread_num = max_thread_num;
	cur_queue_size = 0;

	shutdown = 0;

	max_thread_num = DEFAULT_MAX_THREAD_NUM;
	threadid = new pthread_t[max_thread_num];
	int i = 0;

	for (i = 0; i < max_thread_num; i++)
	{
		pthread_create(&(threadid[i]), NULL, thread_routine, (void*)this);
	}
}


c_thread_pool::c_thread_pool(int max_thread_num)
{

	pthread_mutex_init(&queue_lock, NULL);
	pthread_cond_init(&queue_cond, NULL);

	//工作队列初始化
	queue_head = NULL;
	queue_tail = NULL;
	
	max_thread_num = max_thread_num;
	cur_queue_size = 0;

	threadid = new pthread_t[max_thread_num];
	int i = 0;
	for (i = 0; i < max_thread_num; i++)
	{
		pthread_create(&(threadid[i]), NULL, thread_routine, (void*)this);
	}
}

/*向线程池中的任务队列加入任务*/
int c_thread_pool::add_work(c_work work)
{
	c_work *newwork = new c_work;
	newwork->process = work.process;
	newwork->arg = work.arg;
	newwork->next = NULL;

	pthread_mutex_lock(&queue_lock);
	
	/*将任务加入到等待队列中*/
	if (queue_head != NULL && queue_tail != NULL)
	{
		queue_tail->next = newwork;
		queue_tail = newwork;	
	}
	else
	{
		//空队列
		queue_head = newwork;
		queue_tail = newwork;
	}

	cur_queue_size++;
	pthread_mutex_unlock(&queue_lock);
	/*等待队列中有任务了，唤醒一个等待线程,注意如果所有线程都在忙碌，这句没有任何作用*/
	pthread_cond_signal(&(queue_cond)); 
	printf("add work returned!\n");
	return 0;
}


void* c_thread_pool::thread_routine(void *arg)
{
	c_thread_pool *pool = (c_thread_pool *)arg;
	int i = 0;
	while (1)
	{
		pthread_mutex_lock(&(pool->queue_lock));
		//如果等待队列为0并且不销毁线程池，则处于阻塞状态; 注意
		 // pthread_cond_wait是一个原子操作，等待前会解锁，唤醒后会加锁

		//标注：注意这一如果任务队列不为空的话，while语句将被跳过，直接执行下面的调用。
		while (pool->cur_queue_size == 0 && pool->shutdown)
		{
			pthread_cond_wait(&(pool->queue_cond), &(pool->queue_lock));
		}


		//等待队列长度减去1，并取出链表中的头元素
		if (pool->cur_queue_size > 0 && pool->queue_head != NULL)
		{
			printf("IN THREAD ROUTINE size = %d && queue head is not NULL\n", pool->cur_queue_size);
			pool->cur_queue_size--;
			c_work *work = pool->queue_head;
			pool->queue_head = work->next;
			pthread_mutex_unlock(&(pool->queue_lock));

			//调用回调函数，执行测试任务
			//////////////////////////////////////////
			(*(work->process))(work->arg);
			free(work);
			work = NULL;
		}
		else //不可达
		{
			pthread_mutex_unlock(&(pool->queue_lock));
		}
	}
	
}

c_thread_pool::~c_thread_pool()
{
	for (int i = 0; i < max_thread_num; ++i)	
		pthread_cancel(threadid[i]);
	for (c_work *w_t = queue_head; w_t != NULL;)
	{
		c_work *temp = w_t->next;
		delete w_t;
		w_t = temp;
	}
	delete [] threadid;
}

 

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