生产者消费者缓冲池模型
2017-02-10 本文已影响6人
IT孤独者
有一个生产者在生产产品,这些产品将提供给若干个消费者去消费,为了使生产者和消费者能并发执行,在两者之间设置一个具有多个缓冲区的缓冲池,生产者将它生产的产品放入一个缓冲区中,消费者可以从缓冲区中取走产品进行消费,显然生产者和消费者之间必须保持同步,即不允许消费者到一个空的缓冲区中取产品,也不允许生产者向一个已经放入产品的缓冲区中再次投放产品。
代码如下:
#include <stdio.h>
#include <windows.h>
#include <time.h>
#include <iostream>
#include <thread>
#include <condition_variable>
#include <mutex>
#include <vector>
#include <deque>
#include <assert.h>
#include <set>
using namespace std;
#define POOL_SIZE 4 // 缓冲池含有的缓冲区的个数
#define BUF_SIZE 1 // 缓冲区能够缓冲元素的个数
#define PRODUCT_NUM 1000 // 生产的总产品数目
#define PRODUCER_NUM 1 // 生产者的数目
#define CONSUMER_NUM 2 // 消费者的数目
vector<deque<int> > pool(POOL_SIZE, deque<int>()); // 缓冲池定义
int g_num = 0;
struct s_buf_info
{
s_buf_info(int n) : nSize(n), bLock(false) {}
int nSize;
bool bLock;
};
vector<s_buf_info> poolStatus(POOL_SIZE, s_buf_info(BUF_SIZE)); // 缓冲池使用状态
set<int> InitSetWrite() {
set<int> s;
for (int i = 0; i < POOL_SIZE; ++i) {
s.insert(i);
}
return s;
}
set<int> setWrite(InitSetWrite());
set<int> setRead;
mutex mtxPoolStatus;
condition_variable conWrite;
condition_variable conRead;
mutex mtx; // for output data
BOOL SetConsoleColor(WORD wAttributes)
{
HANDLE hConsole = GetStdHandle(STD_OUTPUT_HANDLE);
if (hConsole == INVALID_HANDLE_VALUE)
return FALSE;
return SetConsoleTextAttribute(hConsole, wAttributes);
}
int GetWriteID()
{
if (setWrite.empty()) return -1;
auto itr = setWrite.begin();
int nID = *itr;
setWrite.erase(itr);
if (!setRead.empty()) {
auto itr = setRead.find(nID);
if (itr != setRead.end())
setRead.erase(itr);
}
return nID;
}
int GetReadID()
{
if (setRead.empty()) return -1;
auto itr = setRead.begin();
int nID = *itr;
setRead.erase(itr);
if (!setWrite.empty()) {
auto itr = setWrite.find(nID);
if (itr != setWrite.end())
setWrite.erase(itr);
}
return nID;
}
int ProductLock()
{
unique_lock<mutex> lck(mtxPoolStatus);
int nID = GetWriteID();
while (nID == -1) {
conWrite.wait(lck);
nID = GetWriteID();
}
poolStatus[nID].bLock = true;
return nID;
}
void ProductUnLock(int nID)
{
unique_lock<mutex> lck(mtxPoolStatus);
poolStatus[nID].bLock = false;
poolStatus[nID].nSize -= 1;
if (poolStatus[nID].nSize < BUF_SIZE) {
setRead.insert(nID);
conRead.notify_all();
}
if (poolStatus[nID].nSize > 0) {
setWrite.insert(nID);
conWrite.notify_all();
}
}
int ConsumeLock()
{
unique_lock<mutex> lck(mtxPoolStatus);
int nID = GetReadID();
while (nID == -1) {
conRead.wait(lck);
nID = GetReadID();
}
poolStatus[nID].bLock = true;
return nID;
}
void ConsumeUnLock(int nID)
{
unique_lock<mutex> lck(mtxPoolStatus);
poolStatus[nID].bLock = false;
poolStatus[nID].nSize += 1;
if (poolStatus[nID].nSize < BUF_SIZE) {
setRead.insert(nID);
conRead.notify_all();
}
if (poolStatus[nID].nSize > 0) {
setWrite.insert(nID);
conWrite.notify_all();
}
}
void ProducerThreadFun(int nProductNum)
{
for (int i=0 ; i < nProductNum; ++i) {
int nID = ProductLock();
pool[nID].push_back(g_num++);
mtx.lock();
printf("编号为%d生产者在缓冲池第%d个缓冲区中投放数据%d\n", GetCurrentThreadId(), nID, g_num - 1);
mtx.unlock();
ProductUnLock(nID);
}
}
void ConsumerThreadFun(int nConsumNum)
{
for (int i = 0; i < nConsumNum; ++i) {
int nID = ConsumeLock();
int nVal = pool[nID].front();
pool[nID].pop_front();
ConsumeUnLock(nID);
mtx.lock();
SetConsoleColor(FOREGROUND_GREEN);
printf(" 编号为%d的消费者从缓冲池中第%d个缓冲区取出数据%d\n", GetCurrentThreadId(), nID, nVal);
SetConsoleColor(FOREGROUND_RED | FOREGROUND_GREEN | FOREGROUND_BLUE);
mtx.unlock();
}
SetConsoleColor(FOREGROUND_GREEN);
printf(" 编号为%d的消费者收到通知,线程结束运行\n", GetCurrentThreadId());
SetConsoleColor(FOREGROUND_RED | FOREGROUND_GREEN | FOREGROUND_BLUE);
}
int main(int argc, char ** argv)
{
time_t t1 = time(NULL);
vector<thread> pro(PRODUCER_NUM);
vector<thread> con(CONSUMER_NUM);
assert(PRODUCT_NUM % PRODUCER_NUM == 0);
assert(PRODUCT_NUM % CONSUMER_NUM == 0);
for (auto &th : pro) th = thread(ProducerThreadFun, PRODUCT_NUM / PRODUCER_NUM);
for (auto &th : con) th = thread(ConsumerThreadFun, PRODUCT_NUM / CONSUMER_NUM);
for (auto &th : pro) th.join();
for (auto &th : con) th.join();
time_t t2 = time(NULL);
cout << t2 - t1 << " s" << endl;
return 0;
}
