#pragma once #include #include namespace nall { namespace HTTP { struct Server : Role, service { inline auto open(unsigned port = 8080, const string& serviceName = "", const string& command = "") -> bool; inline auto main(const function& function = {}) -> void; inline auto scan() -> string; inline auto close() -> void; ~Server() { close(); } private: function callback; std::atomic connections{0}; signed fd4 = -1; signed fd6 = -1; struct sockaddr_in addrin4 = {0}; struct sockaddr_in6 addrin6 = {0}; auto ipv4() const -> bool { return fd4 >= 0; } auto ipv6() const -> bool { return fd6 >= 0; } auto ipv4_close() -> void { if(fd4 >= 0) ::close(fd4); fd4 = -1; } auto ipv6_close() -> void { if(fd6 >= 0) ::close(fd6); fd6 = -1; } auto ipv4_scan() -> bool; auto ipv6_scan() -> bool; }; auto Server::open(unsigned port, const string& serviceName, const string& command) -> bool { if(serviceName) { if(!service::command(serviceName, command)) return false; } fd4 = socket(AF_INET, SOCK_STREAM, 0); fd6 = socket(AF_INET6, SOCK_STREAM, 0); if(!ipv4() && !ipv6()) return false; { #if defined(SO_RCVTIMEO) if(settings.timeoutReceive) { struct timeval rcvtimeo; rcvtimeo.tv_sec = settings.timeoutReceive / 1000; rcvtimeo.tv_usec = settings.timeoutReceive % 1000 * 1000; if(ipv4()) setsockopt(fd4, SOL_SOCKET, SO_RCVTIMEO, &rcvtimeo, sizeof(struct timeval)); if(ipv6()) setsockopt(fd6, SOL_SOCKET, SO_RCVTIMEO, &rcvtimeo, sizeof(struct timeval)); } #endif #if defined(SO_SNDTIMEO) if(settings.timeoutSend) { struct timeval sndtimeo; sndtimeo.tv_sec = settings.timeoutSend / 1000; sndtimeo.tv_usec = settings.timeoutSend % 1000 * 1000; if(ipv4()) setsockopt(fd4, SOL_SOCKET, SO_SNDTIMEO, &sndtimeo, sizeof(struct timeval)); if(ipv6()) setsockopt(fd6, SOL_SOCKET, SO_SNDTIMEO, &sndtimeo, sizeof(struct timeval)); } #endif #if defined(SO_NOSIGPIPE) //BSD, OSX signed nosigpipe = 1; if(ipv4()) setsockopt(fd4, SOL_SOCKET, SO_NOSIGPIPE, &nosigpipe, sizeof(signed)); if(ipv6()) setsockopt(fd6, SOL_SOCKET, SO_NOSIGPIPE, &nosigpipe, sizeof(signed)); #endif #if defined(SO_REUSEADDR) //BSD, Linux, OSX signed reuseaddr = 1; if(ipv4()) setsockopt(fd4, SOL_SOCKET, SO_REUSEADDR, &reuseaddr, sizeof(signed)); if(ipv6()) setsockopt(fd6, SOL_SOCKET, SO_REUSEADDR, &reuseaddr, sizeof(signed)); #endif #if defined(SO_REUSEPORT) //BSD, OSX signed reuseport = 1; if(ipv4()) setsockopt(fd4, SOL_SOCKET, SO_REUSEPORT, &reuseport, sizeof(signed)); if(ipv6()) setsockopt(fd6, SOL_SOCKET, SO_REUSEPORT, &reuseport, sizeof(signed)); #endif } addrin4.sin_family = AF_INET; addrin4.sin_addr.s_addr = htonl(INADDR_ANY); addrin4.sin_port = htons(port); addrin6.sin6_family = AF_INET6; addrin6.sin6_addr = in6addr_any; addrin6.sin6_port = htons(port); if(bind(fd4, (struct sockaddr*)&addrin4, sizeof(addrin4)) < 0 || listen(fd4, SOMAXCONN) < 0) ipv4_close(); if(bind(fd6, (struct sockaddr*)&addrin6, sizeof(addrin6)) < 0 || listen(fd6, SOMAXCONN) < 0) ipv6_close(); return ipv4() || ipv6(); } auto Server::main(const function& function) -> void { callback = function; } auto Server::scan() -> string { if(auto command = service::receive()) return command; if(connections >= settings.connectionLimit) return "busy"; if(ipv4() && ipv4_scan()) return "ok"; if(ipv6() && ipv6_scan()) return "ok"; return "idle"; } auto Server::ipv4_scan() -> bool { struct pollfd query = {0}; query.fd = fd4; query.events = POLLIN; poll(&query, 1, 0); if(query.fd == fd4 && query.revents & POLLIN) { ++connections; thread::create([&](uintptr_t) { thread::detach(); signed clientfd = -1; struct sockaddr_in settings = {0}; socklen_t socklen = sizeof(sockaddr_in); clientfd = accept(fd4, (struct sockaddr*)&settings, &socklen); if(clientfd < 0) return; uint32_t ip = ntohl(settings.sin_addr.s_addr); Request request; request._ipv6 = false; request._ip = { (uint8_t)(ip >> 24), ".", (uint8_t)(ip >> 16), ".", (uint8_t)(ip >> 8), ".", (uint8_t)(ip >> 0) }; if(download(clientfd, request) && callback) { auto response = callback(request); upload(clientfd, response); } else { upload(clientfd, Response()); //"501 Not Implemented" } ::close(clientfd); --connections; }, 0, settings.threadStackSize); return true; } return false; } auto Server::ipv6_scan() -> bool { struct pollfd query = {0}; query.fd = fd6; query.events = POLLIN; poll(&query, 1, 0); if(query.fd == fd6 && query.revents & POLLIN) { ++connections; thread::create([&](uintptr_t) { thread::detach(); signed clientfd = -1; struct sockaddr_in6 settings = {0}; socklen_t socklen = sizeof(sockaddr_in6); clientfd = accept(fd6, (struct sockaddr*)&settings, &socklen); if(clientfd < 0) return; uint8_t* ip = settings.sin6_addr.s6_addr; uint16_t ipSegment[8]; for(auto n : range(8)) ipSegment[n] = ip[n * 2 + 0] * 256 + ip[n * 2 + 1]; Request request; request._ipv6 = true; //RFC5952 IPv6 encoding: the first longest 2+ consecutive zero-sequence is compressed to "::" signed zeroOffset = -1; signed zeroLength = 0; signed zeroCounter = 0; for(auto n : range(8)) { uint16_t value = ipSegment[n]; if(value == 0) zeroCounter++; if(zeroCounter > zeroLength) { zeroLength = zeroCounter; zeroOffset = 1 + n - zeroLength; } if(value != 0) zeroCounter = 0; } if(zeroLength == 1) zeroOffset = -1; for(unsigned n = 0; n < 8;) { if(n == zeroOffset) { request._ip.append(n == 0 ? "::" : ":"); n += zeroLength; } else { uint16_t value = ipSegment[n]; request._ip.append(hex(value), n++ != 7 ? ":" : ""); } } if(download(clientfd, request) && callback) { auto response = callback(request); upload(clientfd, response); } else { upload(clientfd, Response()); //"501 Not Implemented" } ::close(clientfd); --connections; }, 0, settings.threadStackSize); return true; } return false; } auto Server::close() -> void { ipv4_close(); ipv6_close(); } }}