[mysql 基于C++实现数据库连接池连接池的使用] 持续更新中

目背景
常见的MySQL、Oracle、SQLServer等数据库都是基于C/S架构设计的，即（客户端/服务器）架构，也就是说我们对数据库的操作相当于一个客户端，这个客户端使用既定的API把SQL语句通过网络发送给服务器端，MySQL Server执行完SQL语句后将结果通过网络返回客户端。通过网络通信的话就要涉及到TCP/IP协议里的“三次握手”、“四次挥手”等，大量访问时，每一个用户的请求都会对应一次“三次握手”、“四次挥手”的过程，这个性能的消耗是相当严重的；
对于数据库本质上是对磁盘的操作，如果对数据库的访问过多，即（I/O）操作过多，会出现访问瓶颈。
而常见的解决数据库访问瓶颈的方法有两种：

一、为减少磁盘 I/O的次数，在数据库和服务器的应用中间加一层缓存数据库（例如：Redis、Memcache）;
二、增加连接池，来减少高并发情况下大量 TCP三次握手、MySQL Server连接认证、MySQL Server关闭连接回收资源和TCP四次挥手所耗费的性能。

mysqlconn.hpp 实现连接增删改查操作

#include <mysql/mysql.h>
#include <iostream>
#include <string>
#include <ctime>
#include <chrono>
#include <memory> 

	
#define INFO    1
#define WARNING 2
#define ERROR   3
#define FATAL   4
	
#define LOG(level, message) Log(#level, message, __FILE__, __LINE__)
	
void Log(std::string level, std::string message, std::string file_name, int line)
{
	std::cout<<"["<<level<<"]["<<time(nullptr)<<"]["<<message<<"]["<<file_name<<"]["<<line<<"]"<<std::endl;
}

class mysqlconn{

private:
	MYSQL *m_conn = nullptr;
	MYSQL_RES* m_res = nullptr;//查询结果集
	MYSQL_ROW m_row;//记录结构体
	
	void freeResult()
	{
	    if(m_res)
	    {
	        mysql_free_result(m_res);
	        m_res = nullptr;
	    }
	}

	std::chrono::steady_clock::time_point m_aliveTime;

public:

	mysqlconn()
	{
		//获取一个MYSQL句柄
		m_conn = mysql_init(nullptr);
		//设置字符集
		mysql_set_character_set(m_conn,"utf8");
	}
	~mysqlconn()
	{
		freeResult();
		if(m_conn != nullptr)
	    {
	        mysql_close(m_conn);
	    }
	}
	bool query(std::string sql){
		freeResult();
		if(mysql_query(m_conn, sql.c_str())){
			return false;
		}
		m_res = mysql_store_result(m_conn);
		return true;
	}
	//更新 修改 删除
	bool update(std::string sql){
		return mysql_query(m_conn, sql.c_str());
	}

	//连接指定的数据库
    bool connect(std::string ip, std::string user, std::string passwd, std::string dbName,  unsigned int port)
    {
    	return mysql_real_connect(m_conn, ip.c_str(), user.c_str(), passwd.c_str(), dbName.c_str(), port,nullptr,0) != nullptr;
	}
	    //遍历得到的结果集
    bool next()
    {
		if(m_res != nullptr)
    	{
        	m_row = mysql_fetch_row(m_res);  //获取一行
        	if(m_row != nullptr)
        	{
            	return true;
        	}
    	}

    	return false;
	}
    //获取结果集里的值
    std::string value(int index){
	    int rowCount = mysql_num_fields(m_res);  //返回结果集中字段数目
	    if(index >= rowCount || index < 0)
	    {
	        return std::string();
	    }
	 
	    char* ans = m_row[index];
	    unsigned long length = mysql_fetch_lengths(m_res)[index];
	 
	    return std::string(ans,length);		
	
	}
    //事务处理提交方式
    bool transaction()
	{
		return mysql_autocommit(m_conn,false);
	}
    //事务提交
    bool commit()
    {
    	return mysql_commit(m_conn);
	}
    //事务回滚
    bool rollback()
	{
		return mysql_rollback(m_conn);
	}
    //更新空闲时间点
    void refreshAliveTime(){
		m_aliveTime = std::chrono::steady_clock::now();
	}
    //计算连接空闲时长
    long long getAliveTime()
    {
    	std::chrono::duration<double> diff = std::chrono::steady_clock::now() - m_aliveTime;       //nanosecods 纳秒
 
    	return diff.count();
	}
	
};

connpool.hpp 连接池

#include <mutex>
#include <condition_variable>
#include <queue>
#include <fstream>
#include <thread>

#include "mysqlconn.hpp"


 
class ConnectionPool
{

private:
    std::string m_user;
    std::string m_passwd;
    std::string m_ip;
    std::string m_dbName;
    unsigned short m_port;
    //连接的上限和下限,自动维护线程池的连接数
    int m_minSize;
    int m_maxSize;
    //连接的超时时长
    int m_timeout;
    int m_maxIdleTime;
    //线程同步  
    std::mutex m_mutexQ;                     //互斥锁
    std::condition_variable m_cond;          //条件变量
    std::queue<mysqlconn *> m_connectionQ;    //共享资源


public:
    //对外接口,获取线程池
    //静态局部变量是线程安全的
    static ConnectionPool  *getConnectPool()    
    {
		static ConnectionPool pool;
    	return &pool;
	}
    //获取线程池中的连接
    std::shared_ptr<mysqlconn>  getConnection()
    {
		//需要操作共享资源
		std::unique_lock<std::mutex> locker(m_mutexQ);
		//判断连接池队列为空
		while(m_connectionQ.empty())
		{
			if(std::cv_status::timeout == m_cond.wait_for(locker, std::chrono::milliseconds(m_timeout)))
			{
				if(m_connectionQ.empty())
				{
					continue;
				}
			}
		}
		//自定义shared_ptr析构方法,重新将连接放回到连接池中,而不是销毁
		std::shared_ptr<mysqlconn> connptr(m_connectionQ.front(),[this](mysqlconn *conn){
		std::unique_lock<std::mutex> locker(m_mutexQ);
		conn->refreshAliveTime();
		m_connectionQ.push(conn);	
		});
		//弹出,放到了队尾
		m_connectionQ.pop();
		m_cond.notify_all();
		return connptr;

	}
	
    //防止外界通过拷贝构造函数和移动拷贝构造函数
    ConnectionPool(const ConnectionPool &obj) = delete;
    ConnectionPool& operator=(const ConnectionPool& obj) = delete;
    ~ConnectionPool()
	{
		while(!m_connectionQ.empty())
		{
		    mysqlconn *conn = m_connectionQ.front();
		    m_connectionQ.pop();
		    delete conn;
		}
	}
private:
    //构造函数私有化
    ConnectionPool()
    {
		//加载配置文件
		if(!parseJsonFile())
		{
			return;
		}
		
		//创建最少连接数
		for(int i=0;i<m_minSize;++i)
		{
			addConnect();
		}
	 
		//创建子线程用于检测并创建新的连接
		std::thread producer(&ConnectionPool::produceConnection,this);
		//销毁连接,检测并销毁连接
		std::thread recycler(&ConnectionPool::recycleConnection,this);
	 
		//设置线程分离
		producer.detach();
		recycler.detach();

	}
    //解析配置文件
    bool parseJsonFile(){    //可以通过配置文件配置数据 这里写死 
		m_ip      = "127.0.0.1";
        m_user    = "pig";
        m_passwd  = "test1234";
        m_dbName  = "test";
        m_port    = 3306;
        m_minSize = 10;
        m_maxSize = 100;
        m_timeout = 10;
        m_maxIdleTime = 20;
		return true;
	}
 
    //任务函数
    void produceConnection()   //生产数据库连接
    {
	    //通过轮询的方式不断的去检测
	    while(true) 
	    {
	        //操作共享资源,需要加锁
	        std::unique_lock<std::mutex> locker(m_mutexQ);
	        //判断连接数是否达到容量,如果大于等于容量则需要阻塞一段时间
	        while (m_connectionQ.size() >= m_maxSize)   
	        {
	           m_cond.wait(locker);
	        }
	        addConnect();
	        m_cond.notify_all();        //唤醒消费者
	    }
		
	}
    void recycleConnection()   //销毁数据库连接
    {
		while(true)
		{
		   //休眠一定的时长
		   std::this_thread::sleep_for(std::chrono::milliseconds(500));
		   std::unique_lock<std::mutex> locker(m_mutexQ);
		   //让线程池中最少保持用于 m_minSize个线程
		   while(m_connectionQ.size() > m_minSize)
		   {
		        mysqlconn *recyConn = m_connectionQ.front();
		        //如果超时则销毁
		        if(recyConn->getAliveTime() >= m_maxIdleTime)
		        {
		            m_connectionQ.pop();
		            delete recyConn;
		        } 
		        else
		        {
		            break;
		        }
		   }

    	}
	}
    void addConnect()         //添加连接
    {
		mysqlconn *conn = new mysqlconn;
		conn->connect(m_ip,m_user,m_passwd,m_dbName,m_port);
	    conn->refreshAliveTime();
	    m_connectionQ.push(conn);
	}
 
};

main.cpp 测试主函数单线程连接池多线程连接池

#include "connpool.hpp"


void pthread1_no_pool()
{
	clock_t begin = clock();
	std::unique_ptr<mysqlconn> sp = std::make_unique<mysqlconn>();
	bool connflag = sp->connect("127.0.0.1","pig","test1234", "test",3306);
	if(connflag == false) return;
	for (int i = 0; i < 4 * 1000; ++i)
	{
	    sp->refreshAliveTime();
		char sql[1024] = { 0 };
		sprintf(sql, "insert into tb_file values('%d','%s','%s');",
			i, "pthread1_no_pool", "1.png");
		auto upflag = sp->update(sql);
		
	}
	clock_t end = clock();
	std::cout << "pthread1_no_pool:" << (end - begin) << "ms" << std::endl;

}

void pthread1_use_pool(){
	ConnectionPool *cp = ConnectionPool::getConnectPool();
	clock_t begin = clock();
	std::shared_ptr<mysqlconn> sp = cp->getConnection();
	for (int i = 0; i < 1000 * 4; ++i)
	{
		char sql[1024] = { 0 };
		sprintf(sql, "insert into tb_file(id, name, file) values('%d','%s','%s');",
			i, "pthread1_use_pool", "1.png");
		sp->update(sql);
	}
	
	clock_t end = clock();
	std::cout <<"pthread1_use_pool:" << (end - begin) << "ms" << std::endl;
	
}


void pthread4_no_pool()
{
	clock_t begin = clock();
	std::thread tt[4];
	for(int n = 0; n < 4; n++){
		tt[n] = std::thread([=]{
			std::unique_ptr<mysqlconn> sp = std::make_unique<mysqlconn>();
			sp->connect("127.0.0.1","pig","test1234", "test",3306);
			for (int i = 0; i < 1000 * (n + 1); ++i)
			{
			    sp->refreshAliveTime();
				char sql[1024] = { 0 };
				sprintf(sql, "insert into tb_file values('%d','%s','%s');",
					i, "pthread1_no_pool", "1.png");
				sp->update(sql);
			}
		});
	}

	for(int i = 0; i < 4; i++){
		tt[i].join();
	}
	clock_t end = clock();
	std::cout <<"pthread4_no_pool:" << (end - begin) << "ms" << std::endl;
	
}

void work(ConnectionPool *cp , int l){
	std::shared_ptr<mysqlconn> sp = cp->getConnection();
	for (int i = l * 1000; i < 1000 * (l + 1); ++i)
	{
		char sql[1024] = { 0 };
		sprintf(sql, "insert into tb_file values('%d','%s','%s');",
			i, "pthread1_use_pool", "1.png");
		auto upflag = sp->update(sql);
		if(upflag != 0)
		{
			std::cout <<"pthread4_use_pool:" << upflag << sql << std::endl;
			continue;
		}
	}
}

void pthread4_use_pool()
{
	ConnectionPool *cp = ConnectionPool::getConnectPool();
	clock_t begin = clock();
	std::thread tt[4];
	for(int i = 0; i < 4; i++){
		tt[i] = std::thread(work, cp, i);
	}

	for(int i = 0; i < 4; i++){
		tt[i].join();
	}
	clock_t end = clock();
	std::cout <<"pthread4_use_pool:" << (end - begin) << "ms" << std::endl;
}

// g++ -o main main.cpp connpool.hpp mysqlconn.hpp -lmysqlclient -std=c++14 -lpthread
int main()
{
	/*单线程 不使用连接池*/
	//LOG(INFO, "pthread1_no_pool test:");
	//pthread1_no_pool();
	/*单线程 使用连接池*/
	//LOG(INFO, "pthread1_use_pool test:");
	//pthread1_use_pool();

	/*多线程 不使用连接池*/
	LOG(INFO, "pthread4_no_pool test:");
	pthread4_no_pool();
	/*多线程 使用连接池*/
	//LOG(INFO, "pthread4_use_pool test:");
	//pthread4_use_pool();

	
	return 0;
}