// Copyright (c) 2014 Cesanta Software Limited // All rights reserved // // This software is dual-licensed: you can redistribute it and/or modify // it under the terms of the GNU General Public License version 2 as // published by the Free Software Foundation. For the terms of this // license, see . // // You are free to use this software under the terms of the GNU General // Public License, but WITHOUT ANY WARRANTY; without even the implied // warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. // See the GNU General Public License for more details. // // Alternatively, you can license this software under a commercial // license, as set out in . // // $Date: 2014-09-09 16:03:50 UTC $ #include "net_skeleton.h" #ifndef NS_MALLOC #define NS_MALLOC malloc #endif #ifndef NS_REALLOC #define NS_REALLOC realloc #endif #ifndef NS_FREE #define NS_FREE free #endif #define NS_UDP_RECEIVE_BUFFER_SIZE 2000 #define NS_VPRINTF_BUFFER_SIZE 500 struct ctl_msg { ns_callback_t callback; char message[1024 * 8]; }; void iobuf_init(struct iobuf *iobuf, size_t size) { iobuf->len = iobuf->size = 0; iobuf->buf = NULL; if (size > 0 && (iobuf->buf = (char *) NS_MALLOC(size)) != NULL) { iobuf->size = size; } } void iobuf_free(struct iobuf *iobuf) { if (iobuf != NULL) { if (iobuf->buf != NULL) NS_FREE(iobuf->buf); iobuf_init(iobuf, 0); } } size_t iobuf_append(struct iobuf *io, const void *buf, size_t len) { char *p = NULL; assert(io != NULL); assert(io->len <= io->size); if (len <= 0) { } else if (io->len + len <= io->size) { memcpy(io->buf + io->len, buf, len); io->len += len; } else if ((p = (char *) NS_REALLOC(io->buf, io->len + len)) != NULL) { io->buf = p; memcpy(io->buf + io->len, buf, len); io->len += len; io->size = io->len; } else { len = 0; } return len; } void iobuf_remove(struct iobuf *io, size_t n) { if (n > 0 && n <= io->len) { memmove(io->buf, io->buf + n, io->len - n); io->len -= n; } } static size_t ns_out(struct ns_connection *nc, const void *buf, size_t len) { if (nc->flags & NSF_UDP) { long n = send(nc->sock, buf, len, 0); DBG(("%p %d send %ld (%d)", nc, nc->sock, n, errno)); return n < 0 ? 0 : n; } else { return iobuf_append(&nc->send_iobuf, buf, len); } } #ifndef NS_DISABLE_THREADS void *ns_start_thread(void *(*f)(void *), void *p) { #ifdef _WIN32 return (void *) _beginthread((void (__cdecl *)(void *)) f, 0, p); #else pthread_t thread_id = (pthread_t) 0; pthread_attr_t attr; (void) pthread_attr_init(&attr); (void) pthread_attr_setdetachstate(&attr, PTHREAD_CREATE_DETACHED); #if defined(NS_STACK_SIZE) && NS_STACK_SIZE > 1 (void) pthread_attr_setstacksize(&attr, NS_STACK_SIZE); #endif pthread_create(&thread_id, &attr, f, p); pthread_attr_destroy(&attr); return (void *) thread_id; #endif } #endif // NS_DISABLE_THREADS static void ns_add_conn(struct ns_mgr *mgr, struct ns_connection *c) { c->next = mgr->active_connections; mgr->active_connections = c; c->prev = NULL; if (c->next != NULL) c->next->prev = c; } static void ns_remove_conn(struct ns_connection *conn) { if (conn->prev == NULL) conn->mgr->active_connections = conn->next; if (conn->prev) conn->prev->next = conn->next; if (conn->next) conn->next->prev = conn->prev; } // Print message to buffer. If buffer is large enough to hold the message, // return buffer. If buffer is to small, allocate large enough buffer on heap, // and return allocated buffer. int ns_avprintf(char **buf, size_t size, const char *fmt, va_list ap) { va_list ap_copy; int len; va_copy(ap_copy, ap); len = vsnprintf(*buf, size, fmt, ap_copy); va_end(ap_copy); if (len < 0) { // eCos and Windows are not standard-compliant and return -1 when // the buffer is too small. Keep allocating larger buffers until we // succeed or out of memory. *buf = NULL; while (len < 0) { if (*buf) free(*buf); size *= 2; if ((*buf = (char *) NS_MALLOC(size)) == NULL) break; va_copy(ap_copy, ap); len = vsnprintf(*buf, size, fmt, ap_copy); va_end(ap_copy); } } else if (len > (int) size) { // Standard-compliant code path. Allocate a buffer that is large enough. if ((*buf = (char *) NS_MALLOC(len + 1)) == NULL) { len = -1; } else { va_copy(ap_copy, ap); len = vsnprintf(*buf, len + 1, fmt, ap_copy); va_end(ap_copy); } } return len; } int ns_vprintf(struct ns_connection *nc, const char *fmt, va_list ap) { char mem[NS_VPRINTF_BUFFER_SIZE], *buf = mem; int len; if ((len = ns_avprintf(&buf, sizeof(mem), fmt, ap)) > 0) { ns_out(nc, buf, len); } if (buf != mem && buf != NULL) { free(buf); } return len; } int ns_printf(struct ns_connection *conn, const char *fmt, ...) { int len; va_list ap; va_start(ap, fmt); len = ns_vprintf(conn, fmt, ap); va_end(ap); return len; } static void hexdump(struct ns_connection *nc, const char *path, int num_bytes, enum ns_event ev) { const struct iobuf *io = ev == NS_SEND ? &nc->send_iobuf : &nc->recv_iobuf; FILE *fp; char *buf, src[60], dst[60]; int buf_size = num_bytes * 5 + 100; if ((fp = fopen(path, "a")) != NULL) { ns_sock_to_str(nc->sock, src, sizeof(src), 3); ns_sock_to_str(nc->sock, dst, sizeof(dst), 7); fprintf(fp, "%lu %p %s %s %s %d\n", (unsigned long) time(NULL), nc->connection_data, src, ev == NS_RECV ? "<-" : ev == NS_SEND ? "->" : ev == NS_ACCEPT ? "" : "XX", dst, num_bytes); if (num_bytes > 0 && (buf = (char *) NS_MALLOC(buf_size)) != NULL) { ns_hexdump(io->buf + (ev == NS_SEND ? 0 : io->len) - (ev == NS_SEND ? 0 : num_bytes), num_bytes, buf, buf_size); fprintf(fp, "%s", buf); free(buf); } fclose(fp); } } static void ns_call(struct ns_connection *conn, enum ns_event ev, void *p) { if (conn->mgr->hexdump_file != NULL && ev != NS_POLL) { int len = (ev == NS_RECV || ev == NS_SEND) ? * (int *) p : 0; hexdump(conn, conn->mgr->hexdump_file, len, ev); } if (conn->mgr->callback) conn->mgr->callback(conn, ev, p); } static void ns_destroy_conn(struct ns_connection *conn) { closesocket(conn->sock); iobuf_free(&conn->recv_iobuf); iobuf_free(&conn->send_iobuf); #ifdef NS_ENABLE_SSL if (conn->ssl != NULL) { SSL_free(conn->ssl); } if (conn->ssl_ctx != NULL) { SSL_CTX_free(conn->ssl_ctx); } #endif NS_FREE(conn); } static void ns_close_conn(struct ns_connection *conn) { DBG(("%p %d", conn, conn->flags)); ns_call(conn, NS_CLOSE, NULL); ns_remove_conn(conn); ns_destroy_conn(conn); } void ns_set_close_on_exec(sock_t sock) { #ifdef _WIN32 (void) SetHandleInformation((HANDLE) sock, HANDLE_FLAG_INHERIT, 0); #else fcntl(sock, F_SETFD, FD_CLOEXEC); #endif } static void ns_set_non_blocking_mode(sock_t sock) { #ifdef _WIN32 unsigned long on = 1; ioctlsocket(sock, FIONBIO, &on); #else int flags = fcntl(sock, F_GETFL, 0); fcntl(sock, F_SETFL, flags | O_NONBLOCK); #endif } #ifndef NS_DISABLE_SOCKETPAIR int ns_socketpair2(sock_t sp[2], int sock_type) { union socket_address sa; sock_t sock; socklen_t len = sizeof(sa.sin); int ret = 0; sp[0] = sp[1] = INVALID_SOCKET; (void) memset(&sa, 0, sizeof(sa)); sa.sin.sin_family = AF_INET; sa.sin.sin_port = htons(0); sa.sin.sin_addr.s_addr = htonl(0x7f000001); if ((sock = socket(AF_INET, sock_type, 0)) != INVALID_SOCKET && !bind(sock, &sa.sa, len) && (sock_type == SOCK_DGRAM || !listen(sock, 1)) && !getsockname(sock, &sa.sa, &len) && (sp[0] = socket(AF_INET, sock_type, 0)) != INVALID_SOCKET && !connect(sp[0], &sa.sa, len) && (sock_type == SOCK_STREAM || (!getsockname(sp[0], &sa.sa, &len) && !connect(sock, &sa.sa, len))) && (sp[1] = (sock_type == SOCK_DGRAM ? sock : accept(sock, &sa.sa, &len))) != INVALID_SOCKET) { ns_set_close_on_exec(sp[0]); ns_set_close_on_exec(sp[1]); ret = 1; } else { if (sp[0] != INVALID_SOCKET) closesocket(sp[0]); if (sp[1] != INVALID_SOCKET) closesocket(sp[1]); sp[0] = sp[1] = INVALID_SOCKET; } if (sock_type != SOCK_DGRAM) closesocket(sock); return ret; } int ns_socketpair(sock_t sp[2]) { return ns_socketpair2(sp, SOCK_STREAM); } #endif // NS_DISABLE_SOCKETPAIR // TODO(lsm): use non-blocking resolver static int ns_resolve2(const char *host, struct in_addr *ina) { struct hostent *he; if ((he = gethostbyname(host)) == NULL) { DBG(("gethostbyname(%s) failed: %s", host, strerror(errno))); } else { memcpy(ina, he->h_addr_list[0], sizeof(*ina)); return 1; } return 0; } // Resolve FDQN "host", store IP address in the "ip". // Return > 0 (IP address length) on success. int ns_resolve(const char *host, char *buf, size_t n) { struct in_addr ad; return ns_resolve2(host, &ad) ? snprintf(buf, n, "%s", inet_ntoa(ad)) : 0; } // Address format: [PROTO://][IP_ADDRESS:]PORT[:CERT][:CA_CERT] static int ns_parse_address(const char *str, union socket_address *sa, int *proto, int *use_ssl, char *cert, char *ca) { unsigned int a, b, c, d, port; int n = 0, len = 0; char host[200]; #ifdef NS_ENABLE_IPV6 char buf[100]; #endif // MacOS needs that. If we do not zero it, subsequent bind() will fail. // Also, all-zeroes in the socket address means binding to all addresses // for both IPv4 and IPv6 (INADDR_ANY and IN6ADDR_ANY_INIT). memset(sa, 0, sizeof(*sa)); sa->sin.sin_family = AF_INET; *proto = SOCK_STREAM; *use_ssl = 0; cert[0] = ca[0] = '\0'; if (memcmp(str, "ssl://", 6) == 0) { str += 6; *use_ssl = 1; } else if (memcmp(str, "udp://", 6) == 0) { str += 6; *proto = SOCK_DGRAM; } else if (memcmp(str, "tcp://", 6) == 0) { str += 6; } if (sscanf(str, "%u.%u.%u.%u:%u%n", &a, &b, &c, &d, &port, &len) == 5) { // Bind to a specific IPv4 address, e.g. 192.168.1.5:8080 sa->sin.sin_addr.s_addr = htonl((a << 24) | (b << 16) | (c << 8) | d); sa->sin.sin_port = htons((uint16_t) port); #ifdef NS_ENABLE_IPV6 } else if (sscanf(str, "[%99[^]]]:%u%n", buf, &port, &len) == 2 && inet_pton(AF_INET6, buf, &sa->sin6.sin6_addr)) { // IPv6 address, e.g. [3ffe:2a00:100:7031::1]:8080 sa->sin6.sin6_family = AF_INET6; sa->sin6.sin6_port = htons((uint16_t) port); #endif } else if (sscanf(str, "%199[^ :]:%u%n", host, &port, &len) == 2) { sa->sin.sin_port = htons((uint16_t) port); ns_resolve2(host, &sa->sin.sin_addr); } else if (sscanf(str, "%u%n", &port, &len) == 1) { // If only port is specified, bind to IPv4, INADDR_ANY sa->sin.sin_port = htons((uint16_t) port); } if (*use_ssl && (sscanf(str + len, ":%99[^:]:%99[^:]%n", cert, ca, &n) == 2 || sscanf(str + len, ":%99[^:]%n", cert, &n) == 1)) { len += n; } return port < 0xffff && str[len] == '\0' ? len : 0; } // 'sa' must be an initialized address to bind to static sock_t ns_open_listening_socket(union socket_address *sa, int proto) { socklen_t sa_len = (sa->sa.sa_family == AF_INET) ? sizeof(sa->sin) : sizeof(sa->sin6); sock_t sock = INVALID_SOCKET; #ifndef _WIN32 int on = 1; #endif if ((sock = socket(sa->sa.sa_family, proto, 0)) != INVALID_SOCKET && #ifndef _WIN32 // SO_RESUSEADDR is not enabled on Windows because the semantics of // SO_REUSEADDR on UNIX and Windows is different. On Windows, // SO_REUSEADDR allows to bind a socket to a port without error even if // the port is already open by another program. This is not the behavior // SO_REUSEADDR was designed for, and leads to hard-to-track failure // scenarios. Therefore, SO_REUSEADDR was disabled on Windows. !setsockopt(sock, SOL_SOCKET, SO_REUSEADDR, (void *) &on, sizeof(on)) && #endif !bind(sock, &sa->sa, sa_len) && (proto == SOCK_DGRAM || listen(sock, SOMAXCONN) == 0)) { ns_set_non_blocking_mode(sock); // In case port was set to 0, get the real port number (void) getsockname(sock, &sa->sa, &sa_len); } else if (sock != INVALID_SOCKET) { closesocket(sock); sock = INVALID_SOCKET; } return sock; } #ifdef NS_ENABLE_SSL // Certificate generation script is at // https://github.com/cesanta/net_skeleton/blob/master/scripts/gen_certs.sh static int ns_use_ca_cert(SSL_CTX *ctx, const char *cert) { if (ctx == NULL) { return -1; } else if (cert == NULL || cert[0] == '\0') { return 0; } SSL_CTX_set_verify(ctx, SSL_VERIFY_PEER | SSL_VERIFY_FAIL_IF_NO_PEER_CERT, 0); return SSL_CTX_load_verify_locations(ctx, cert, NULL) == 1 ? 0 : -2; } static int ns_use_cert(SSL_CTX *ctx, const char *pem_file) { if (ctx == NULL) { return -1; } else if (pem_file == NULL || pem_file[0] == '\0') { return 0; } else if (SSL_CTX_use_certificate_file(ctx, pem_file, 1) == 0 || SSL_CTX_use_PrivateKey_file(ctx, pem_file, 1) == 0) { return -2; } else { SSL_CTX_set_mode(ctx, SSL_MODE_ACCEPT_MOVING_WRITE_BUFFER); SSL_CTX_use_certificate_chain_file(ctx, pem_file); return 0; } } #endif // NS_ENABLE_SSL struct ns_connection *ns_bind(struct ns_mgr *srv, const char *str, void *data) { union socket_address sa; struct ns_connection *nc = NULL; int use_ssl, proto; char cert[100], ca_cert[100]; sock_t sock; ns_parse_address(str, &sa, &proto, &use_ssl, cert, ca_cert); if (use_ssl && cert[0] == '\0') return NULL; if ((sock = ns_open_listening_socket(&sa, proto)) == INVALID_SOCKET) { } else if ((nc = ns_add_sock(srv, sock, NULL)) == NULL) { closesocket(sock); } else { nc->sa = sa; nc->flags |= NSF_LISTENING; nc->connection_data = data; if (proto == SOCK_DGRAM) { nc->flags |= NSF_UDP; } #ifdef NS_ENABLE_SSL if (use_ssl) { nc->ssl_ctx = SSL_CTX_new(SSLv23_server_method()); if (ns_use_cert(nc->ssl_ctx, cert) != 0 || ns_use_ca_cert(nc->ssl_ctx, ca_cert) != 0) { ns_close_conn(nc); nc = NULL; } } #endif DBG(("%p sock %d/%d ssl %p %p", nc, sock, proto, nc->ssl_ctx, nc->ssl)); } return nc; } static struct ns_connection *accept_conn(struct ns_connection *ls) { struct ns_connection *c = NULL; union socket_address sa; socklen_t len = sizeof(sa); sock_t sock = INVALID_SOCKET; // NOTE(lsm): on Windows, sock is always > FD_SETSIZE if ((sock = accept(ls->sock, &sa.sa, &len)) == INVALID_SOCKET) { } else if ((c = ns_add_sock(ls->mgr, sock, NULL)) == NULL) { closesocket(sock); #ifdef NS_ENABLE_SSL } else if (ls->ssl_ctx != NULL && ((c->ssl = SSL_new(ls->ssl_ctx)) == NULL || SSL_set_fd(c->ssl, sock) != 1)) { DBG(("SSL error")); ns_close_conn(c); c = NULL; #endif } else { c->listener = ls; ns_call(c, NS_ACCEPT, &sa); DBG(("%p %d %p %p", c, c->sock, c->ssl_ctx, c->ssl)); } return c; } static int ns_is_error(int n) { return n == 0 || (n < 0 && errno != EINTR && errno != EINPROGRESS && errno != EAGAIN && errno != EWOULDBLOCK #ifdef _WIN32 && WSAGetLastError() != WSAEINTR && WSAGetLastError() != WSAEWOULDBLOCK #endif ); } void ns_sock_to_str(sock_t sock, char *buf, size_t len, int flags) { union socket_address sa; socklen_t slen = sizeof(sa); if (buf != NULL && len > 0) { buf[0] = '\0'; memset(&sa, 0, sizeof(sa)); if (flags & 4) { getpeername(sock, &sa.sa, &slen); } else { getsockname(sock, &sa.sa, &slen); } if (flags & 1) { #if defined(NS_ENABLE_IPV6) inet_ntop(sa.sa.sa_family, sa.sa.sa_family == AF_INET ? (void *) &sa.sin.sin_addr : (void *) &sa.sin6.sin6_addr, buf, len); #elif defined(_WIN32) // Only Windoze Vista (and newer) have inet_ntop() strncpy(buf, inet_ntoa(sa.sin.sin_addr), len); #else inet_ntop(sa.sa.sa_family, (void *) &sa.sin.sin_addr, buf,(socklen_t)len); #endif } if (flags & 2) { snprintf(buf + strlen(buf), len - (strlen(buf) + 1), "%s%d", flags & 1 ? ":" : "", (int) ntohs(sa.sin.sin_port)); } } } int ns_hexdump(const void *buf, int len, char *dst, int dst_len) { const unsigned char *p = (const unsigned char *) buf; char ascii[17] = ""; int i, idx, n = 0; for (i = 0; i < len; i++) { idx = i % 16; if (idx == 0) { if (i > 0) n += snprintf(dst + n, dst_len - n, " %s\n", ascii); n += snprintf(dst + n, dst_len - n, "%04x ", i); } n += snprintf(dst + n, dst_len - n, " %02x", p[i]); ascii[idx] = p[i] < 0x20 || p[i] > 0x7e ? '.' : p[i]; ascii[idx + 1] = '\0'; } while (i++ % 16) n += snprintf(dst + n, dst_len - n, "%s", " "); n += snprintf(dst + n, dst_len - n, " %s\n\n", ascii); return n; } #ifdef NS_ENABLE_SSL static int ns_ssl_err(struct ns_connection *conn, int res) { int ssl_err = SSL_get_error(conn->ssl, res); if (ssl_err == SSL_ERROR_WANT_READ) conn->flags |= NSF_WANT_READ; if (ssl_err == SSL_ERROR_WANT_WRITE) conn->flags |= NSF_WANT_WRITE; return ssl_err; } #endif static void ns_read_from_socket(struct ns_connection *conn) { char buf[2048]; int n = 0; if (conn->flags & NSF_CONNECTING) { int ok = 1, ret; socklen_t len = sizeof(ok); ret = getsockopt(conn->sock, SOL_SOCKET, SO_ERROR, (char *) &ok, &len); (void) ret; #ifdef NS_ENABLE_SSL if (ret == 0 && ok == 0 && conn->ssl != NULL) { int res = SSL_connect(conn->ssl); int ssl_err = ns_ssl_err(conn, res); if (res == 1) { conn->flags |= NSF_SSL_HANDSHAKE_DONE; } else if (ssl_err == SSL_ERROR_WANT_READ || ssl_err == SSL_ERROR_WANT_WRITE) { return; // Call us again } else { ok = 1; } } #endif conn->flags &= ~NSF_CONNECTING; DBG(("%p ok=%d", conn, ok)); if (ok != 0) { conn->flags |= NSF_CLOSE_IMMEDIATELY; } ns_call(conn, NS_CONNECT, &ok); return; } #ifdef NS_ENABLE_SSL if (conn->ssl != NULL) { if (conn->flags & NSF_SSL_HANDSHAKE_DONE) { // SSL library may have more bytes ready to read then we ask to read. // Therefore, read in a loop until we read everything. Without the loop, // we skip to the next select() cycle which can just timeout. while ((n = SSL_read(conn->ssl, buf, sizeof(buf))) > 0) { DBG(("%p %d <- %d bytes (SSL)", conn, conn->flags, n)); iobuf_append(&conn->recv_iobuf, buf, n); ns_call(conn, NS_RECV, &n); } ns_ssl_err(conn, n); } else { int res = SSL_accept(conn->ssl); int ssl_err = ns_ssl_err(conn, res); if (res == 1) { conn->flags |= NSF_SSL_HANDSHAKE_DONE; } else if (ssl_err == SSL_ERROR_WANT_READ || ssl_err == SSL_ERROR_WANT_WRITE) { return; // Call us again } else { conn->flags |= NSF_CLOSE_IMMEDIATELY; } return; } } else #endif { while ((n = (int) recv(conn->sock, buf, sizeof(buf), 0)) > 0) { DBG(("%p %d <- %d bytes (PLAIN)", conn, conn->flags, n)); iobuf_append(&conn->recv_iobuf, buf, n); ns_call(conn, NS_RECV, &n); } } if (ns_is_error(n)) { conn->flags |= NSF_CLOSE_IMMEDIATELY; } } static void ns_write_to_socket(struct ns_connection *conn) { struct iobuf *io = &conn->send_iobuf; int n = 0; #ifdef NS_ENABLE_SSL if (conn->ssl != NULL) { n = SSL_write(conn->ssl, io->buf, io->len); if (n <= 0) { int ssl_err = ns_ssl_err(conn, n); if (ssl_err == SSL_ERROR_WANT_READ || ssl_err == SSL_ERROR_WANT_WRITE) { return; // Call us again } else { conn->flags |= NSF_CLOSE_IMMEDIATELY; } } } else #endif { n = (int) send(conn->sock, io->buf, io->len, 0); } DBG(("%p %d -> %d bytes", conn, conn->flags, n)); ns_call(conn, NS_SEND, &n); if (ns_is_error(n)) { conn->flags |= NSF_CLOSE_IMMEDIATELY; } else if (n > 0) { iobuf_remove(io, n); } } int ns_send(struct ns_connection *conn, const void *buf, int len) { return (int) ns_out(conn, buf, len); } static void ns_handle_udp(struct ns_connection *ls) { struct ns_connection nc; char buf[NS_UDP_RECEIVE_BUFFER_SIZE]; int n; socklen_t s_len = sizeof(nc.sa); memset(&nc, 0, sizeof(nc)); n = recvfrom(ls->sock, buf, sizeof(buf), 0, &nc.sa.sa, &s_len); if (n <= 0) { DBG(("%p recvfrom: %s", ls, strerror(errno))); } else { nc.recv_iobuf.buf = buf; nc.recv_iobuf.len = nc.recv_iobuf.size = n; nc.sock = ls->sock; nc.mgr = ls->mgr; DBG(("%p %d bytes received", ls, n)); ns_call(&nc, NS_RECV, &n); } } static void ns_add_to_set(sock_t sock, fd_set *set, sock_t *max_fd) { if (sock != INVALID_SOCKET) { FD_SET(sock, set); if (*max_fd == INVALID_SOCKET || sock > *max_fd) { *max_fd = sock; } } } int ns_mgr_poll(struct ns_mgr *mgr, int milli) { struct ns_connection *conn, *tmp_conn; struct timeval tv; fd_set read_set, write_set; int num_active_connections = 0; sock_t max_fd = INVALID_SOCKET; time_t current_time = time(NULL); FD_ZERO(&read_set); FD_ZERO(&write_set); ns_add_to_set(mgr->ctl[1], &read_set, &max_fd); for (conn = mgr->active_connections; conn != NULL; conn = tmp_conn) { tmp_conn = conn->next; ns_call(conn, NS_POLL, ¤t_time); if (!(conn->flags & NSF_WANT_WRITE)) { //DBG(("%p read_set", conn)); ns_add_to_set(conn->sock, &read_set, &max_fd); } if (((conn->flags & NSF_CONNECTING) && !(conn->flags & NSF_WANT_READ)) || (conn->send_iobuf.len > 0 && !(conn->flags & NSF_CONNECTING) && !(conn->flags & NSF_BUFFER_BUT_DONT_SEND))) { //DBG(("%p write_set", conn)); ns_add_to_set(conn->sock, &write_set, &max_fd); } if (conn->flags & NSF_CLOSE_IMMEDIATELY) { ns_close_conn(conn); } } tv.tv_sec = milli / 1000; tv.tv_usec = (milli % 1000) * 1000; if (select((int) max_fd + 1, &read_set, &write_set, NULL, &tv) > 0) { // select() might have been waiting for a long time, reset current_time // now to prevent last_io_time being set to the past. current_time = time(NULL); // Read wakeup messages if (mgr->ctl[1] != INVALID_SOCKET && FD_ISSET(mgr->ctl[1], &read_set)) { struct ctl_msg ctl_msg; int len = (int) recv(mgr->ctl[1], (char *) &ctl_msg, sizeof(ctl_msg), 0); send(mgr->ctl[1], ctl_msg.message, 1, 0); if (len >= (int) sizeof(ctl_msg.callback) && ctl_msg.callback != NULL) { struct ns_connection *c; for (c = ns_next(mgr, NULL); c != NULL; c = ns_next(mgr, c)) { ctl_msg.callback(c, NS_POLL, ctl_msg.message); } } } for (conn = mgr->active_connections; conn != NULL; conn = tmp_conn) { tmp_conn = conn->next; if (FD_ISSET(conn->sock, &read_set)) { if (conn->flags & NSF_LISTENING) { if (conn->flags & NSF_UDP) { ns_handle_udp(conn); } else { // We're not looping here, and accepting just one connection at // a time. The reason is that eCos does not respect non-blocking // flag on a listening socket and hangs in a loop. accept_conn(conn); } } else { conn->last_io_time = current_time; ns_read_from_socket(conn); } } if (FD_ISSET(conn->sock, &write_set)) { if (conn->flags & NSF_CONNECTING) { ns_read_from_socket(conn); } else if (!(conn->flags & NSF_BUFFER_BUT_DONT_SEND)) { conn->last_io_time = current_time; ns_write_to_socket(conn); } } } } for (conn = mgr->active_connections; conn != NULL; conn = tmp_conn) { tmp_conn = conn->next; num_active_connections++; if ((conn->flags & NSF_CLOSE_IMMEDIATELY) || (conn->send_iobuf.len == 0 && (conn->flags & NSF_FINISHED_SENDING_DATA))) { ns_close_conn(conn); } } //DBG(("%d active connections", num_active_connections)); return num_active_connections; } struct ns_connection *ns_connect(struct ns_mgr *mgr, const char *address, void *param) { sock_t sock = INVALID_SOCKET; struct ns_connection *nc = NULL; union socket_address sa; char cert[100], ca_cert[100]; int connect_ret_val, use_ssl, proto; ns_parse_address(address, &sa, &proto, &use_ssl, cert, ca_cert); if ((sock = socket(AF_INET, proto, 0)) == INVALID_SOCKET) { return NULL; } ns_set_non_blocking_mode(sock); connect_ret_val = connect(sock, &sa.sa, sizeof(sa.sin)); if (connect_ret_val != 0 && ns_is_error(connect_ret_val)) { closesocket(sock); return NULL; } else if ((nc = ns_add_sock(mgr, sock, param)) == NULL) { closesocket(sock); return NULL; } nc->sa = sa; // Essential, cause UDP conns will use sendto() if (proto == SOCK_DGRAM) { nc->flags = NSF_UDP; } else { nc->flags = NSF_CONNECTING; } #ifdef NS_ENABLE_SSL if (use_ssl) { if ((nc->ssl_ctx = SSL_CTX_new(SSLv23_client_method())) == NULL || ns_use_cert(nc->ssl_ctx, cert) != 0 || ns_use_ca_cert(nc->ssl_ctx, ca_cert) != 0 || (nc->ssl = SSL_new(nc->ssl_ctx)) == NULL) { ns_close_conn(nc); return NULL; } else { SSL_set_fd(nc->ssl, sock); } } #endif return nc; } struct ns_connection *ns_add_sock(struct ns_mgr *s, sock_t sock, void *p) { struct ns_connection *conn; if ((conn = (struct ns_connection *) NS_MALLOC(sizeof(*conn))) != NULL) { memset(conn, 0, sizeof(*conn)); ns_set_non_blocking_mode(sock); ns_set_close_on_exec(sock); conn->sock = sock; conn->connection_data = p; conn->mgr = s; conn->last_io_time = time(NULL); ns_add_conn(s, conn); DBG(("%p %d", conn, sock)); } return conn; } struct ns_connection *ns_next(struct ns_mgr *s, struct ns_connection *conn) { return conn == NULL ? s->active_connections : conn->next; } void ns_broadcast(struct ns_mgr *mgr, ns_callback_t cb,void *data, size_t len) { struct ctl_msg ctl_msg; if (mgr->ctl[0] != INVALID_SOCKET && data != NULL && len < sizeof(ctl_msg.message)) { ctl_msg.callback = cb; memcpy(ctl_msg.message, data, len); send(mgr->ctl[0], (char *) &ctl_msg, offsetof(struct ctl_msg, message) + len, 0); recv(mgr->ctl[0], (char *) &len, 1, 0); } } void ns_mgr_init(struct ns_mgr *s, void *user_data, ns_callback_t cb) { memset(s, 0, sizeof(*s)); s->ctl[0] = s->ctl[1] = INVALID_SOCKET; s->user_data = user_data; s->callback = cb; #ifdef _WIN32 { WSADATA data; WSAStartup(MAKEWORD(2, 2), &data); } #else // Ignore SIGPIPE signal, so if client cancels the request, it // won't kill the whole process. signal(SIGPIPE, SIG_IGN); #endif #ifndef NS_DISABLE_SOCKETPAIR do { ns_socketpair2(s->ctl, SOCK_DGRAM); } while (s->ctl[0] == INVALID_SOCKET); #endif #ifdef NS_ENABLE_SSL {static int init_done; if (!init_done) { SSL_library_init(); init_done++; }} #endif } void ns_mgr_free(struct ns_mgr *s) { struct ns_connection *conn, *tmp_conn; DBG(("%p", s)); if (s == NULL) return; // Do one last poll, see https://github.com/cesanta/mongoose/issues/286 ns_mgr_poll(s, 0); if (s->ctl[0] != INVALID_SOCKET) closesocket(s->ctl[0]); if (s->ctl[1] != INVALID_SOCKET) closesocket(s->ctl[1]); s->ctl[0] = s->ctl[1] = INVALID_SOCKET; for (conn = s->active_connections; conn != NULL; conn = tmp_conn) { tmp_conn = conn->next; ns_close_conn(conn); } }