利用ace的ACE_Task等类实现线程池的方法详解_C语言教程-查字典教程网
利用ace的ACE_Task等类实现线程池的方法详解
利用ace的ACE_Task等类实现线程池的方法详解
发布时间:2016-12-28 来源:查字典编辑
摘要:本代码应该是ace自带的例子了,但是我觉得是非常好的,于是给大家分享一下。注释非常详细啊。头文件复制代码代码如下:#ifndefTHREAD...

本代码应该是ace自带的例子了,但是我觉得是非常好的,于是给大家分享一下。

注释非常详细啊。

头文件

复制代码 代码如下:

#ifndef THREAD_POOL_H

#define THREAD_POOL_H

/* In order to implement a thread pool, we have to have an object that

can create a thread. The ACE_Task<> is the basis for doing just

such a thing. */

#include "ace/Task.h"

//add by ychen 20070714 below

#include "ace/Mutex.h"

//add by ychen 20070714 above

#if !defined (ACE_LACKS_PRAGMA_ONCE)

# pragma once

#endif /* ACE_LACKS_PRAGMA_ONCE */

/* We need a forward reference for ACE_Event_Handler so that our

enqueue() method can accept a pointer to one. */

class ACE_Event_Handler;

/* Although we modified the rest of our program to make use of the

thread pool implementation, if you look closely you'll see that the

changes were rather minor. The "ACE way" is generally to create a

helper object that abstracts away the details not relevant to your

application. That's what I'm trying to do here by creating the

Thread_Pool object. */

class Thread_Pool : public ACE_Task<ACE_MT_SYNCH>

{

public:

typedef ACE_Task<ACE_MT_SYNCH> inherited;

/* Provide an enumeration for the default pool size. By doing this,

other objects can use the value when they want a default. */

enum size_t

{

default_pool_size_ = 1

};

// Basic constructor

Thread_Pool (void);

/* Opening the thread pool causes one or more threads to be

activated. When activated, they all execute the svc() method

declared below. */

int open (int pool_size = default_pool_size_);

/* Some compilers will complain that our open() above attempts to

override a virtual function in the baseclass. We have no

intention of overriding that method but in order to keep the

compiler quiet we have to add this method as a pass-thru to the

baseclass method. */

virtual int open (void *void_data)

{

return inherited::open (void_data);

}

/*

*/

virtual int close (u_long flags = 0);

/* To use the thread pool, you have to put some unit of work into

it. Since we're dealing with event handlers (or at least their

derivatives), I've chosen to provide an enqueue() method that

takes a pointer to an ACE_Event_Handler. The handler's

handle_input() method will be called, so your object has to know

when it is being called by the thread pool. */

int enqueue (ACE_Event_Handler *handler);

/* Another handy ACE template is ACE_Atomic_Op<>. When

parameterized, this allows is to have a thread-safe counting

object. The typical arithmetic operators are all internally

thread-safe so that you can share it across threads without

worrying about any contention issues. */

typedef ACE_Atomic_Op<ACE_Mutex, int> counter_t;

protected:

/* Our svc() method will dequeue the enqueued event handler objects

and invoke the handle_input() method on each. Since we're likely

running in more than one thread, idle threads can take work from

the queue while other threads are busy executing handle_input() on

some object. */

int svc (void);

/* We use the atomic op to keep a count of the number of threads in

which our svc() method is running. This is particularly important

when we want to close() it down! */

counter_t active_threads_;

};

#endif /* THREAD_POOL_H */

实现文件

复制代码 代码如下:

// thread_pool.cpp,v 1.9 1999/09/22 03:13:42 jcej Exp

#include "thread_pool.h"

/* We need this header so that we can invoke handle_input() on the

objects we dequeue. */

#include "ace/Event_Handler.h"

/* All we do here is initialize our active thread counter. */

Thread_Pool::Thread_Pool (void)

: active_threads_ (0)

{

}

/* Our open() method is a thin disguise around the ACE_Task<>

activate() method. By hiding activate() in this way, the users of

Thread_Pool don't have to worry about the thread configuration

flags. */

int

Thread_Pool::open (int pool_size)

{

return this->activate (THR_NEW_LWP|THR_DETACHED, pool_size);

}

/* Closing the thread pool can be a tricky exercise. I've decided to

take an easy approach and simply enqueue a secret message for each

thread we have active. */

int

Thread_Pool::close (u_long flags)

{

ACE_UNUSED_ARG(flags);

/* Find out how many threads are currently active */

int counter = active_threads_.value ();

/* For each one of the active threads, enqueue a "null" event

handler. Below, we'll teach our svc() method that "null" means

"shutdown". */

while (counter--)

this->enqueue (0);

/* As each svc() method exits, it will decrement the active thread

counter. We just wait here for it to reach zero. Since we don't

know how long it will take, we sleep for a quarter of a second

between tries. */

while (active_threads_.value ())

ACE_OS::sleep (ACE_Time_Value (0, 250000));

return(0);

}

/* When an object wants to do work in the pool, it should call the

enqueue() method. We introduce the ACE_Message_Block here but,

unfortunately, we seriously misuse it. */

int

Thread_Pool::enqueue (ACE_Event_Handler *handler)

{

/* An ACE_Message_Block is a chunk of data. You put them into an

ACE_Message_Queue. ACE_Task<> has an ACE_Message_Queue built in.

In fact, the parameter to ACE_Task<> is passed directly to

ACE_Message_Queue. If you look back at our header file you'll see

that we used ACE_MT_SYNCH as the parameter indicating that we want

MultiThread Synch safety. This allows us to safely put

ACE_Message_Block objects into the message queue in one thread and

take them out in another. */

/* An ACE_Message_Block wants to have char* data. We don't have

that. We could cast our ACE_Event_Handler* directly to a char*

but I wanted to be more explicit. Since casting pointers around

is a dangerous thing, I've gone out of my way here to be very

clear about what we're doing.

First: Cast the handler pointer to a void pointer. You can't do

any useful work on a void pointer, so this is a clear message that

we're making the pointer unusable.

Next: Cast the void pointer to a char pointer that the ACE_Message_Block will accept. */

void *v_data = (void *) handler;

char *c_data = (char *) v_data;

ACE_Message_Block *mb;

/* Construct a new ACE_Message_Block. For efficiency, you might

want to preallocate a stack of these and reuse them. For

simplicity, I'll just create what I need as I need it. */

ACE_NEW_RETURN (mb,

ACE_Message_Block (c_data),

-1);

/* Our putq() method is a wrapper around one of the enqueue methods

of the ACE_Message_Queue that we own. Like all good methods, it

returns -1 if it fails for some reason. */

if (this->putq (mb) == -1)

{

/* Another trait of the ACE_Message_Block objects is that they

are reference counted. Since they're designed to be passed

around between various objects in several threads we can't

just delete them whenever we feel like it. The release()

method is similar to the destroy() method we've used

elsewhere. It watches the reference count and will delete the

object when possible. */

mb->release ();

return -1;

}

return 0;

}

/* The "guard" concept is very powerful and used throughout

multi-threaded applications. A guard normally does some operation

on an object at construction and the "opposite" operation at

destruction. For instance, when you guard a mutex (lock) object,

the guard will acquire the lock on construction and release it on

destruction. In this way, your method can simply let the guard go

out of scope and know that the lock is released.

Guards aren't only useful for locks however. In this application

I've created two guard objects for quite a different purpose. */

/* The Counter_Guard is constructed with a reference to the thread

pool's active thread counter. The guard increments the counter

when it is created and decrements it at destruction. By creating

one of these in svc(), I know that the counter will be decremented

no matter how or where svc() returns. */

class Counter_Guard

{

public:

Counter_Guard (Thread_Pool::counter_t &counter)

: counter_ (counter)

{

++counter_;

}

~Counter_Guard (void)

{

--counter_;

}

protected:

Thread_Pool::counter_t &counter_;

};

/* My Message_Block_Guard is also a little non-traditional. It

doesn't do anything in the constructor but it's destructor ensures

that the message block's release() method is called. This is a

cheap way to prevent a memory leak if I need an additional exit

point in svc(). */

class Message_Block_Guard

{

public:

Message_Block_Guard (ACE_Message_Block *&mb)

: mb_ (mb)

{

}

~Message_Block_Guard (void)

{

mb_->release ();

}

protected:

ACE_Message_Block *&mb_;

};

/* Now we come to the svc() method. As I said, this is being executed

in each thread of the Thread_Pool. Here, we pull messages off of

our built-in ACE_Message_Queue and cause them to do work. */

int

Thread_Pool::svc (void)

{

/* The getq() method takes a reference to a pointer. So... we need

a pointer to give it a reference to. */

ACE_Message_Block *mb;

/* Create the guard for our active thread counter object. No matter

where we choose to return() from svc(), we now know that the

counter will be decremented. */

Counter_Guard counter_guard (active_threads_);

/* Get messages from the queue until we have a failure. There's no

real good reason for failure so if it happens, we leave

immediately. */

while (this->getq (mb) != -1)

{

/* A successful getq() will cause "mb" to point to a valid

refernce-counted ACE_Message_Block. We use our guard object

here so that we're sure to call the release() method of that

message block and reduce it's reference count. Once the count

reaches zero, it will be deleted. */

Message_Block_Guard message_block_guard (mb);

/* As noted before, the ACE_Message_Block stores it's data as a

char*. We pull that out here and later turn it into an

ACE_Event_Handler* */

char *c_data = mb->base ();

/* We've chosen to use a "null" value as an indication to leave.

If the data we got from the queue is not null then we have

some work to do. */

if (c_data)

{

/* Once again, we go to great lengths to emphasize the fact

that we're casting pointers around in rather impolite

ways. We could have cast the char* directly to an

ACE_Event_Handler* but then folks might think that's an OK

thing to do.

(Note: The correct way to use an ACE_Message_Block is to

write data into it. What I should have done was create a

message block big enough to hold an event handler pointer

and then written the pointer value into the block. When

we got here, I would have to read that data back into a

pointer. While politically correct, it is also a lot of

work. If you're careful you can get away with casting

pointers around.) */

void *v_data = (void *) c_data;

ACE_Event_Handler *handler = (ACE_Event_Handler *) v_data;

/* Now that we finally have an event handler pointer, invoke

it's handle_input() method. Since we don't know it's

handle, we just give it a default. That's OK because we

know that we're not using the handle in the method anyway. */

if (handler->handle_input (ACE_INVALID_HANDLE) == -1)

{

/* Tell the handler that it's time to go home. The

"normal" method for shutting down a handler whose

handler failed is to invoke handle_close(). This will

take care of cleaning it up for us. Notice how we use

the handler's get_handle() method to populate it's

"handle" parameter. Convenient isn't it? */

handler->handle_close (handler->get_handle (), 0);

/* Also notice that we don't exit the svc() method here!

The first time I did this, I was exiting. After a few

clients disconnect you have an empty thread pool.

Hard to do any more work after that... */

}

}

else

/* If we get here, we were given a message block with "null"

data. That is our signal to leave, so we return(0) to

leave gracefully. */

return 0;// Ok, shutdown request

// message_block_guard goes out of scope here and releases the

// message_block instance.

}

return 0;

}

其中,对其中类中的两个变量使用了管理的思想。Counter_Guard类和Message_Block_Guard 类分别对其进行了管理。

因为ACE_Task类是使用了ACE_message_block 进行对消息的封装。因此使用类,防止了内存的泄漏。

ACE_Event_Handler 是事件句柄,类似于操作符。当我们处理的时候,对其进行处理。

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