Server IP : 66.29.132.122 / Your IP : 18.227.21.21 Web Server : LiteSpeed System : Linux business142.web-hosting.com 4.18.0-553.lve.el8.x86_64 #1 SMP Mon May 27 15:27:34 UTC 2024 x86_64 User : admazpex ( 531) PHP Version : 7.2.34 Disable Function : NONE MySQL : OFF | cURL : ON | WGET : ON | Perl : ON | Python : ON | Sudo : OFF | Pkexec : OFF Directory : /opt/alt/php82/usr/include/php/ext/swoole/include/ |
Upload File : |
/* +----------------------------------------------------------------------+ | Swoole | +----------------------------------------------------------------------+ | This source file is subject to version 2.0 of the Apache license, | | that is bundled with this package in the file LICENSE, and is | | available through the world-wide-web at the following url: | | http://www.apache.org/licenses/LICENSE-2.0.html | | If you did not receive a copy of the Apache2.0 license and are unable| | to obtain it through the world-wide-web, please send a note to | | license@swoole.com so we can mail you a copy immediately. | +----------------------------------------------------------------------+ | Author: Tianfeng Han <rango@swoole.com> | | Twosee <twose@qq.com> | +----------------------------------------------------------------------+ */ #pragma once #include "swoole.h" #include "swoole_api.h" #include "swoole_socket.h" #include "swoole_coroutine.h" #include "swoole_protocol.h" #include "swoole_proxy.h" #include <vector> namespace swoole { namespace coroutine { //------------------------------------------------------------------------------- /** * @return true: continue to wait for events * @return false: stop event waiting and resume coroutine */ using EventBarrier = std::function<bool()>; class Socket { public: int errCode = 0; const char *errMsg = ""; std::string errString; bool open_length_check = false; bool open_eof_check = false; bool http2 = false; Protocol protocol = {}; Socks5Proxy *socks5_proxy = nullptr; HttpProxy *http_proxy = nullptr; enum TimeoutType { TIMEOUT_DNS = 1 << 0, TIMEOUT_CONNECT = 1 << 1, TIMEOUT_READ = 1 << 2, TIMEOUT_WRITE = 1 << 3, TIMEOUT_RDWR = TIMEOUT_READ | TIMEOUT_WRITE, TIMEOUT_ALL = TIMEOUT_DNS | TIMEOUT_CONNECT | TIMEOUT_RDWR, }; static enum TimeoutType timeout_type_list[4]; Socket(int domain, int type, int protocol); Socket(int _fd, int _domain, int _type, int _protocol); Socket(SocketType type = SW_SOCK_TCP); Socket(int _fd, SocketType _type); ~Socket(); bool connect(std::string host, int port, int flags = 0); bool connect(const struct sockaddr *addr, socklen_t addrlen); bool shutdown(int how = SHUT_RDWR); bool cancel(const EventType event); bool close(); bool is_connected() { return connected && !is_closed(); } bool is_closed() { return sock_fd == SW_BAD_SOCKET; } bool is_port_required() { return type <= SW_SOCK_UDP6; } bool check_liveness(); ssize_t peek(void *__buf, size_t __n); ssize_t recv(void *__buf, size_t __n); ssize_t send(const void *__buf, size_t __n); ssize_t send(const std::string &buf) { return send(buf.c_str(), buf.length()); } ssize_t read(void *__buf, size_t __n); ssize_t write(const void *__buf, size_t __n); ssize_t readv(network::IOVector *io_vector); ssize_t readv_all(network::IOVector *io_vector); ssize_t writev(network::IOVector *io_vector); ssize_t writev_all(network::IOVector *io_vector); ssize_t recvmsg(struct msghdr *msg, int flags); ssize_t sendmsg(const struct msghdr *msg, int flags); ssize_t recv_all(void *__buf, size_t __n); ssize_t send_all(const void *__buf, size_t __n); ssize_t recv_packet(double timeout = 0); ssize_t recv_line(void *__buf, size_t maxlen); ssize_t recv_with_buffer(void *__buf, size_t __n); char *pop_packet() { if (read_buffer->offset == 0) { return nullptr; } else { return read_buffer->pop(buffer_init_size); } } bool poll(EventType type, double timeout = 0); Socket *accept(double timeout = 0); bool bind(std::string address, int port = 0); bool bind(const struct sockaddr *sa, socklen_t len); bool listen(int backlog = 0); bool sendfile(const char *filename, off_t offset, size_t length); ssize_t sendto(const std::string &host, int port, const void *__buf, size_t __n); ssize_t recvfrom(void *__buf, size_t __n); ssize_t recvfrom(void *__buf, size_t __n, struct sockaddr *_addr, socklen_t *_socklen); #ifdef SW_USE_OPENSSL /** * Operation sequence: * 1. enable_ssl_encrypt() * 2. Set SSL parameters, such as certificate file, key file * 3. ssl_check_context() * 4. ssl_accept()/ssl_connect()/ssl_handshake() */ bool enable_ssl_encrypt() { if (ssl_context.get()) { return false; } ssl_context.reset(new SSLContext()); return true; } bool ssl_is_enable() { return get_ssl_context() != nullptr; } SSLContext *get_ssl_context() { return ssl_context.get(); } bool ssl_check_context(); bool ssl_handshake(); bool ssl_verify(bool allow_self_signed); std::string ssl_get_peer_cert(); #endif static inline void init_reactor(Reactor *reactor) { reactor->set_handler(SW_FD_CO_SOCKET | SW_EVENT_READ, readable_event_callback); reactor->set_handler(SW_FD_CO_SOCKET | SW_EVENT_WRITE, writable_event_callback); reactor->set_handler(SW_FD_CO_SOCKET | SW_EVENT_ERROR, error_event_callback); } SocketType get_type() { return type; } FdType get_fd_type() { return socket->fd_type; } int get_sock_domain() { return sock_domain; } int get_sock_type() { return sock_type; } int get_sock_protocol() { return sock_protocol; } int get_fd() { return sock_fd; } int get_bind_port() { return bind_port; } network::Socket *get_socket() { return socket; } bool getsockname(network::Address *sa); bool getpeername(network::Address *sa); const char *get_ip() { return socket->info.get_ip(); } int get_port() { return socket->info.get_port(); } bool has_bound(const EventType event = SW_EVENT_RDWR) { return get_bound_co(event) != nullptr; } Coroutine *get_bound_co(const EventType event) { if (event & SW_EVENT_READ) { if (read_co) { return read_co; } } if (event & SW_EVENT_WRITE) { if (write_co) { return write_co; } } return nullptr; } long get_bound_cid(const EventType event = SW_EVENT_RDWR) { Coroutine *co = get_bound_co(event); return co ? co->get_cid() : 0; } const char *get_event_str(const EventType event) { if (event == SW_EVENT_READ) { return "reading"; } else if (event == SW_EVENT_WRITE) { return "writing"; } else { return read_co && write_co ? "reading or writing" : (read_co ? "reading" : "writing"); } } void check_bound_co(const EventType event) { long cid = get_bound_cid(event); if (sw_unlikely(cid)) { swoole_fatal_error(SW_ERROR_CO_HAS_BEEN_BOUND, "Socket#%d has already been bound to another coroutine#%ld, " "%s of the same socket in coroutine#%ld at the same time is not allowed", sock_fd, cid, get_event_str(event), Coroutine::get_current_cid()); } } void set_err(int e) { errCode = errno = e; swoole_set_last_error(errCode); errMsg = e ? swoole_strerror(e) : ""; } void set_err(int e, const char *s) { errCode = errno = e; swoole_set_last_error(errCode); errMsg = s; } void set_err(int e, std::string s) { errCode = errno = e; swoole_set_last_error(errCode); errString = s; errMsg = errString.c_str(); } /* set connect read write timeout */ void set_timeout(double timeout, int type = TIMEOUT_ALL) { if (timeout == 0) { return; } if (type & TIMEOUT_DNS) { dns_timeout = timeout; } if (type & TIMEOUT_CONNECT) { connect_timeout = timeout; } if (type & TIMEOUT_READ) { read_timeout = timeout; } if (type & TIMEOUT_WRITE) { write_timeout = timeout; } } void set_timeout(struct timeval *timeout, int type = TIMEOUT_ALL) { set_timeout((double) timeout->tv_sec + ((double) timeout->tv_usec / 1000 / 1000), type); } double get_timeout(enum TimeoutType type = TIMEOUT_ALL) { SW_ASSERT_1BYTE(type); if (type == TIMEOUT_DNS) { return dns_timeout; } else if (type == TIMEOUT_CONNECT) { return connect_timeout; } else if (type == TIMEOUT_READ) { return read_timeout; } else if (type == TIMEOUT_WRITE) { return write_timeout; } else { assert(0); return -1; } } bool set_option(int level, int optname, int optval) { if (socket->set_option(level, optname, optval) < 0) { swoole_sys_warning("setsockopt(%d, %d, %d, %d) failed", sock_fd, level, optname, optval); return false; } return true; } String *get_read_buffer() { if (sw_unlikely(!read_buffer)) { read_buffer = make_string(SW_BUFFER_SIZE_BIG, buffer_allocator); if (!read_buffer) { throw std::bad_alloc(); } } return read_buffer; } String *get_write_buffer() { if (sw_unlikely(!write_buffer)) { write_buffer = make_string(SW_BUFFER_SIZE_BIG, buffer_allocator); if (!write_buffer) { throw std::bad_alloc(); } } return write_buffer; } void set_resolve_context(NameResolver::Context *ctx) { resolve_context_ = ctx; } void set_dtor(const std::function<void(Socket *)> &dtor) { dtor_ = dtor; } String *pop_read_buffer() { if (sw_unlikely(!read_buffer)) { return nullptr; } auto tmp = read_buffer; read_buffer = nullptr; return tmp; } String *pop_write_buffer() { if (sw_unlikely(!write_buffer)) { return nullptr; } auto tmp = write_buffer; write_buffer = nullptr; return tmp; } void set_zero_copy(bool enable) { zero_copy = enable; } void set_buffer_allocator(const Allocator *allocator) { buffer_allocator = allocator; } void set_buffer_init_size(size_t size) { if (size == 0) { return; } buffer_init_size = size; } int move_fd() { int sockfd = socket->fd; sock_fd = socket->fd = SW_BAD_SOCKET; return sockfd; } network::Socket *move_socket() { network::Socket *_socket = socket; socket = nullptr; return _socket; } #ifdef SW_USE_OPENSSL bool ssl_is_available() { return socket && ssl_handshaked; } SSL *get_ssl() { return socket->ssl; } bool ssl_shutdown(); #endif private: SocketType type; network::Socket *socket = nullptr; int sock_domain = 0; int sock_type = 0; int sock_protocol = 0; int sock_fd = -1; Coroutine *read_co = nullptr; Coroutine *write_co = nullptr; #ifdef SW_USE_OPENSSL EventType want_event = SW_EVENT_NULL; #endif std::string connect_host; int connect_port = 0; std::string bind_address; int bind_port = 0; int backlog = 0; double dns_timeout = network::Socket::default_dns_timeout; double connect_timeout = network::Socket::default_connect_timeout; double read_timeout = network::Socket::default_read_timeout; double write_timeout = network::Socket::default_write_timeout; TimerNode *read_timer = nullptr; TimerNode *write_timer = nullptr; const Allocator *buffer_allocator = nullptr; size_t buffer_init_size = SW_BUFFER_SIZE_BIG; String *read_buffer = nullptr; String *write_buffer = nullptr; network::Address bind_address_info = {}; EventBarrier *recv_barrier = nullptr; EventBarrier *send_barrier = nullptr; #ifdef SW_USE_OPENSSL bool ssl_is_server = false; bool ssl_handshaked = false; std::shared_ptr<SSLContext> ssl_context = nullptr; std::string ssl_host_name; bool ssl_create(SSLContext *ssl_context); #endif bool connected = false; bool shutdown_read = false; bool shutdown_write = false; bool zero_copy = false; NameResolver::Context *resolve_context_ = nullptr; std::function<void(Socket *)> dtor_; Socket(network::Socket *sock, Socket *socket); static void timer_callback(Timer *timer, TimerNode *tnode); static int readable_event_callback(Reactor *reactor, Event *event); static int writable_event_callback(Reactor *reactor, Event *event); static int error_event_callback(Reactor *reactor, Event *event); void init_sock_type(SocketType _type); bool init_sock(); bool init_reactor_socket(int fd); void check_return_value(ssize_t retval) { if (retval >= 0) { set_err(0); } else if (errCode == 0) { set_err(errno); } } void init_options() { if (type == SW_SOCK_TCP || type == SW_SOCK_TCP6) { set_option(IPPROTO_TCP, TCP_NODELAY, 1); } protocol.package_length_type = 'N'; protocol.package_length_size = 4; protocol.package_length_offset = 0; protocol.package_body_offset = 0; protocol.package_max_length = SW_INPUT_BUFFER_SIZE; } bool add_event(const EventType event); bool wait_event(const EventType event, const void **__buf = nullptr, size_t __n = 0); bool try_connect(); ssize_t recv_packet_with_length_protocol(); ssize_t recv_packet_with_eof_protocol(); bool is_available(const EventType event) { if (event != SW_EVENT_NULL) { check_bound_co(event); } if (sw_unlikely(is_closed())) { set_err(EBADF); return false; } if (sw_unlikely(socket->close_wait)) { set_err(SW_ERROR_CO_SOCKET_CLOSE_WAIT); return false; } return true; } bool socks5_handshake(); bool http_proxy_handshake(); class TimerController { public: TimerController(TimerNode **timer_pp, double timeout, Socket *sock, TimerCallback callback) : timer_pp(timer_pp), timeout(timeout), socket_(sock), callback(callback) {} bool start() { if (timeout != 0 && !*timer_pp) { enabled = true; if (timeout > 0) { *timer_pp = swoole_timer_add(timeout, false, callback, socket_); return *timer_pp != nullptr; } *timer_pp = (TimerNode *) -1; } return true; } ~TimerController() { if (enabled && *timer_pp) { if (*timer_pp != (TimerNode *) -1) { swoole_timer_del(*timer_pp); } *timer_pp = nullptr; } } private: bool enabled = false; TimerNode **timer_pp; double timeout; Socket *socket_; TimerCallback callback; }; public: class TimeoutSetter { public: TimeoutSetter(Socket *socket, double timeout, const enum TimeoutType type) : socket_(socket), timeout(timeout), type(type) { if (timeout == 0) { return; } for (uint8_t i = 0; i < SW_ARRAY_SIZE(timeout_type_list); i++) { if (type & timeout_type_list[i]) { original_timeout[i] = socket->get_timeout(timeout_type_list[i]); if (timeout != original_timeout[i]) { socket->set_timeout(timeout, timeout_type_list[i]); } } } } ~TimeoutSetter() { if (timeout == 0) { return; } for (uint8_t i = 0; i < SW_ARRAY_SIZE(timeout_type_list); i++) { if (type & timeout_type_list[i]) { if (timeout != original_timeout[i]) { socket_->set_timeout(original_timeout[i], timeout_type_list[i]); } } } } protected: Socket *socket_; double timeout; enum TimeoutType type; double original_timeout[sizeof(timeout_type_list)] = {}; }; class timeout_controller : public TimeoutSetter { public: timeout_controller(Socket *socket, double timeout, const enum TimeoutType type) : TimeoutSetter(socket, timeout, type) {} bool has_timedout(const enum TimeoutType type) { SW_ASSERT_1BYTE(type); if (timeout > 0) { if (sw_unlikely(startup_time == 0)) { startup_time = microtime(); } else { double used_time = microtime() - startup_time; if (sw_unlikely(timeout - used_time < SW_TIMER_MIN_SEC)) { socket_->set_err(ETIMEDOUT); return true; } socket_->set_timeout(timeout - used_time, type); } } return false; } protected: double startup_time = 0; }; }; class ProtocolSwitch { private: bool ori_open_eof_check; bool ori_open_length_check; Protocol ori_protocol; Socket *socket_; public: ProtocolSwitch(Socket *socket) { ori_open_eof_check = socket->open_eof_check; ori_open_length_check = socket->open_length_check; ori_protocol = socket->protocol; socket_ = socket; } ~ProtocolSwitch() { /* revert protocol settings */ socket_->open_eof_check = ori_open_eof_check; socket_->open_length_check = ori_open_length_check; socket_->protocol = ori_protocol; } }; std::vector<std::string> dns_lookup(const char *domain, int family = AF_INET, double timeout = 2.0); std::vector<std::string> dns_lookup_impl_with_socket(const char *domain, int family, double timeout); #ifdef SW_USE_CARES std::vector<std::string> dns_lookup_impl_with_cares(const char *domain, int family, double timeout); #endif std::string get_ip_by_hosts(const std::string &domain); //------------------------------------------------------------------------------- } // namespace coroutine } // namespace swoole std::shared_ptr<swoole::coroutine::Socket> swoole_coroutine_get_socket_object(int sockfd);