#include #include #include "lib_acl.h" // just for getopt on Windows #include "acl_cpp/stdlib/util.hpp" #include "acl_cpp/acl_cpp_init.hpp" #include "acl_cpp/stdlib/log.hpp" #include "acl_cpp/stream/aio_handle.hpp" #include "acl_cpp/stream/aio_istream.hpp" #include "acl_cpp/stream/aio_listen_stream.hpp" #include "acl_cpp/stream/aio_socket_stream.hpp" static int __max = 0; static int __timeout = 0; /** * 延迟读回调处理类 */ class timer_reader: public acl::aio_timer_reader { public: timer_reader(int delay) { delay_ = delay; std::cout << "timer_reader init, delay: " << delay << std::endl; } protected: ~timer_reader(void) {} // aio_timer_reader 的子类必须重载 destroy 方法 // @override void destroy(void) { std::cout << "timer_reader delete, delay: " << delay_ << std::endl; delete this; } // 重载基类回调方法 // @override void timer_callback(unsigned int id) { std::cout << "timer_reader(" << id << "): timer_callback, delay: " << delay_ << std::endl; // 调用基类的处理过程 aio_timer_reader::timer_callback(id); } private: int delay_; }; /** * 延迟写回调处理类 */ class timer_writer: public acl::aio_timer_writer { public: timer_writer(int delay) { delay_ = delay; std::cout << "timer_writer init, delay: " << delay << std::endl; } protected: ~timer_writer(void) {} // aio_timer_reader 的子类必须重载 destroy 方法 // @override void destroy(void) { std::cout << "timer_writer delete, delay: " << delay_ << std::endl; delete this; } // 重载基类回调方法 // @override void timer_callback(unsigned int id) { std::cout << "timer_writer(" << id << "): timer_callback, delay: " << delay_ << std::endl; // 调用基类的处理过程 acl::aio_timer_writer::timer_callback(id); } private: int delay_; }; /** * 异步客户端流的回调类的子类 */ class io_callback : public acl::aio_callback { public: io_callback(acl::aio_socket_stream* client) : client_(client) , i_(0) {} protected: ~io_callback(void) { std::cout << "delete io_callback now ..." << std::endl; } /** * 实现父类中的虚函数,客户端流的读成功回调过程 * @param data {char*} 读到的数据地址 * @param len {int} 读到的数据长度 * @return {bool} 返回 true 表示继续,否则希望关闭该异步流 */ bool read_callback(char* data, int len) { i_++; if (i_ < 5) { std::cout << ">>gets(i:" << i_ << "): " << data << std::endl; } // 如果远程客户端希望退出,则关闭之 if (strncasecmp(data, "quit", 4) == 0) { client_->format("Bye!\r\n"); client_->close(); return false; } // 如果远程客户端希望服务端也关闭,则中止异步事件过程 else if (strncasecmp(data, "stop", 4) == 0) { client_->format("Stop now!\r\n"); client_->close(); // 关闭远程异步流 // 通知异步引擎关闭循环过程 client_->get_handle().stop(); } // 向远程客户端回写收到的数据 int delay = 0; if (!strncasecmp(data, "write_delay", strlen("write_delay"))) { // 延迟写过程 const char* ptr = data + strlen("write_delay"); delay = atoi(ptr); if (delay > 0) { std::cout << ">> write delay " << delay << " second ..." << std::endl; timer_writer* timer = new timer_writer(delay); client_->write(data, len, delay * 1000000, timer); client_->gets(10, false); return true; } } else if (!strncasecmp(data, "read_delay", strlen("read_delay"))) { // 延迟读过程 const char* ptr = data + strlen("read_delay"); delay = atoi(ptr); if (delay > 0) { client_->write(data, len); std::cout << ">> read delay " << delay << " second ..." << std::endl; timer_reader* timer = new timer_reader(delay); client_->gets(10, false, delay * 1000000, timer); return true; } } client_->write(data, len); //client_->gets(10, false); return true; } /** * 实现父类中的虚函数,客户端流的写成功回调过程 * @return {bool} 返回 true 表示继续,否则希望关闭该异步流 */ bool write_callback(void) { return true; } /** * 实现父类中的虚函数,客户端流的超时回调过程 */ void close_callback(void) { // 必须在此处删除该动态分配的回调类对象以防止内存泄露 delete this; } /** * 实现父类中的虚函数,客户端流的超时回调过程 * @return {bool} 返回 true 表示继续,否则希望关闭该异步流 */ bool timeout_callback(void) { std::cout << "Timeout, delete it ..." << std::endl; return (false); } private: acl::aio_socket_stream* client_; int i_; }; /** * 异步监听流的回调类的子类 */ class io_accept_callback : public acl::aio_accept_callback , public acl::aio_listen_callback { public: io_accept_callback(void) {} ~io_accept_callback(void) { printf(">>io_accept_callback over!\n"); } /** * 基类 aio_accept_callback 虚函数,当有新连接到达后调用此回调过程 * @param client {aio_socket_stream*} 异步客户端流 * @return {bool} 返回 true 以通知监听流继续监听 */ bool accept_callback(acl::aio_socket_stream* client) { printf("proactor accept one\r\n"); return handle_client(client); } /** * 基类 aio_listen_callback 虚函数,当有新连接到达后调用此回调过程 * @param server {acl::aio_listen_stream&} 异步监听流 * @return {bool} */ bool listen_callback(acl::aio_listen_stream& server) { // reactor 模式下需要用户自己调用 accept 方法 acl::aio_socket_stream* client = server.accept(); if (client == NULL) { printf("accept error %s\r\n", acl::last_serror()); return false; } printf("reactor accept one\r\n"); return handle_client(client); } private: bool handle_client(acl::aio_socket_stream* client) { // 创建异步客户端流的回调对象并与该异步流进行绑定 io_callback* callback = new io_callback(client); // 注册异步流的读回调过程 client->add_read_callback(callback); // 注册异步流的写回调过程 client->add_write_callback(callback); // 注册异步流的关闭回调过程 client->add_close_callback(callback); // 注册异步流的超时回调过程 client->add_timeout_callback(callback); // 当限定了行数据最大长度时 if (__max > 0) { client->set_buf_max(__max); } // 从异步流读一行数据 client->gets(__timeout, false); return true; } }; class mytimer : public acl::aio_timer_callback { public: mytimer(long long delay) : id_(0), last_(time(NULL)), delay_(delay) {} ~mytimer(void) {} protected: // @override void destroy(void) { delete this; } // @override void timer_callback(unsigned int id) { time_t now = time(NULL); delay_ += 1000000; this->set_task(id_, delay_); printf("timer id=%u, delay=%ld, next delay=%lld\r\n", id, (long) (now - last_), delay_); last_ = now; id_ = id; } private: unsigned int id_; time_t last_; long long delay_; }; static void usage(const char* procname) { printf("usage: %s -h[help]\r\n" " -l ip:port\r\n" " -L line_max_length\r\n" " -t timeout\r\n" " -r [use reactor mode other proactor mode, default: proactor mode]\r\n" " -k[use kernel event: epoll/iocp/kqueue/devpool]\r\n", procname); } int main(int argc, char* argv[]) { bool use_kernel = false, use_reactor = false; int ch; acl::string addr(":9001"); while ((ch = getopt(argc, argv, "l:hkL:t:r")) > 0) { switch (ch) { case 'h': usage(argv[0]); return 0; case 'l': addr = optarg; break; case 'k': use_kernel = true; break; case 'L': __max = atoi(optarg); break; case 't': __timeout = atoi(optarg); break; case 'r': use_reactor = true; break; default: break; } } // 初始化ACL库(尤其是在WIN32下一定要调用此函数,在UNIX平台下可不调用) acl::acl_cpp_init(); acl::log::stdout_open(true); // 构建异步引擎类对象 acl::aio_handle handle(use_kernel ? acl::ENGINE_KERNEL : acl::ENGINE_SELECT); long long delay = 1000000; mytimer* timer = new mytimer(delay); timer->keep_timer(true); handle.set_timer(timer, delay); // 创建监听异步流 acl::aio_listen_stream* sstream = new acl::aio_listen_stream(&handle); // 监听指定的地址 if (!sstream->open(addr.c_str())) { std::cout << "open " << addr.c_str() << " error!" << std::endl; sstream->close(); // XXX: 为了保证能关闭监听流,应在此处再 check 一下 handle.check(); getchar(); return 1; } // 创建回调类对象,当有新连接到达时自动调用此类对象的回调过程 io_accept_callback callback; if (use_reactor) { sstream->add_listen_callback(&callback); } else { sstream->add_accept_callback(&callback); } std::cout << "Listen: " << addr.c_str() << " ok!" << std::endl; while (true) { // 如果返回 false 则表示不再继续,需要退出 if (!handle.check()) { std::cout << "aio_server stop now ..." << std::endl; break; } } // 关闭监听流并释放流对象 sstream->close(); // XXX: 为了保证能关闭监听流,应在此处再 check 一下 handle.check(); return 0; }