/* Copyright 1998 by the Massachusetts Institute of Technology. * * Permission to use, copy, modify, and distribute this * software and its documentation for any purpose and without * fee is hereby granted, provided that the above copyright * notice appear in all copies and that both that copyright * notice and this permission notice appear in supporting * documentation, and that the name of M.I.T. not be used in * advertising or publicity pertaining to distribution of the * software without specific, written prior permission. * M.I.T. makes no representations about the suitability of * this software for any purpose. It is provided "as is" * without express or implied warranty. */ #include "setup.h" #include #if defined(WIN32) && !defined(WATT32) #include "nameser.h" #else #include #ifdef HAVE_SYS_UIO_H #include #endif #include #include #include #ifdef HAVE_ARPA_NAMESER_COMPAT_H #include #endif #endif /* WIN32 && !WATT32 */ #ifdef HAVE_UNISTD_H #include #endif #ifdef HAVE_SYS_IOCTL_H #include #endif #ifdef NETWARE #include #endif #include #include #include #include #include #include "ares.h" #include "ares_dns.h" #include "ares_private.h" #ifndef TRUE /* at least Solaris 7 does not have TRUE at this point */ #define TRUE 1 #endif #if (defined(WIN32) || defined(WATT32)) && !defined(MSDOS) #define GET_ERRNO() WSAGetLastError() #else #define GET_ERRNO() errno #endif static void write_tcp_data(ares_channel channel, fd_set *write_fds, time_t now); static void read_tcp_data(ares_channel channel, fd_set *read_fds, time_t now); static void read_udp_packets(ares_channel channel, fd_set *read_fds, time_t now); static void process_timeouts(ares_channel channel, time_t now); static void process_answer(ares_channel channel, unsigned char *abuf, int alen, int whichserver, int tcp, int now); static void handle_error(ares_channel channel, int whichserver, time_t now); static struct query *next_server(ares_channel channel, struct query *query, time_t now); static int open_tcp_socket(ares_channel channel, struct server_state *server); static int open_udp_socket(ares_channel channel, struct server_state *server); static int same_questions(const unsigned char *qbuf, int qlen, const unsigned char *abuf, int alen); static struct query *end_query(ares_channel channel, struct query *query, int status, unsigned char *abuf, int alen); /* Something interesting happened on the wire, or there was a timeout. * See what's up and respond accordingly. */ void ares_process(ares_channel channel, fd_set *read_fds, fd_set *write_fds) { time_t now; time(&now); write_tcp_data(channel, write_fds, now); read_tcp_data(channel, read_fds, now); read_udp_packets(channel, read_fds, now); process_timeouts(channel, now); } /* If any TCP sockets select true for writing, write out queued data * we have for them. */ static void write_tcp_data(ares_channel channel, fd_set *write_fds, time_t now) { struct server_state *server; struct send_request *sendreq; struct iovec *vec; int i; ssize_t scount; ssize_t wcount; size_t n; for (i = 0; i < channel->nservers; i++) { /* Make sure server has data to send and is selected in write_fds. */ server = &channel->servers[i]; if (!server->qhead || server->tcp_socket == ARES_SOCKET_BAD || !FD_ISSET(server->tcp_socket, write_fds)) continue; /* Count the number of send queue items. */ n = 0; for (sendreq = server->qhead; sendreq; sendreq = sendreq->next) n++; /* Allocate iovecs so we can send all our data at once. */ vec = malloc(n * sizeof(struct iovec)); if (vec) { /* Fill in the iovecs and send. */ n = 0; for (sendreq = server->qhead; sendreq; sendreq = sendreq->next) { vec[n].iov_base = (char *) sendreq->data; vec[n].iov_len = sendreq->len; n++; } wcount = writev(server->tcp_socket, vec, n); free(vec); if (wcount < 0) { handle_error(channel, i, now); continue; } /* Advance the send queue by as many bytes as we sent. */ while (wcount) { sendreq = server->qhead; if ((size_t)wcount >= sendreq->len) { wcount -= sendreq->len; server->qhead = sendreq->next; if (server->qhead == NULL) server->qtail = NULL; free(sendreq); } else { sendreq->data += wcount; sendreq->len -= wcount; break; } } } else { /* Can't allocate iovecs; just send the first request. */ sendreq = server->qhead; scount = send(server->tcp_socket, (void *)sendreq->data, sendreq->len, 0); if (scount < 0) { handle_error(channel, i, now); continue; } /* Advance the send queue by as many bytes as we sent. */ if ((size_t)scount == sendreq->len) { server->qhead = sendreq->next; if (server->qhead == NULL) server->qtail = NULL; free(sendreq); } else { sendreq->data += scount; sendreq->len -= scount; } } } } /* If any TCP socket selects true for reading, read some data, * allocate a buffer if we finish reading the length word, and process * a packet if we finish reading one. */ static void read_tcp_data(ares_channel channel, fd_set *read_fds, time_t now) { struct server_state *server; int i, count; for (i = 0; i < channel->nservers; i++) { /* Make sure the server has a socket and is selected in read_fds. */ server = &channel->servers[i]; if (server->tcp_socket == ARES_SOCKET_BAD || !FD_ISSET(server->tcp_socket, read_fds)) continue; if (server->tcp_lenbuf_pos != 2) { /* We haven't yet read a length word, so read that (or * what's left to read of it). */ count = recv(server->tcp_socket, (void *)(server->tcp_lenbuf + server->tcp_lenbuf_pos), 2 - server->tcp_lenbuf_pos, 0); if (count <= 0) { handle_error(channel, i, now); continue; } server->tcp_lenbuf_pos += count; if (server->tcp_lenbuf_pos == 2) { /* We finished reading the length word. Decode the * length and allocate a buffer for the data. */ server->tcp_length = server->tcp_lenbuf[0] << 8 | server->tcp_lenbuf[1]; server->tcp_buffer = malloc(server->tcp_length); if (!server->tcp_buffer) handle_error(channel, i, now); server->tcp_buffer_pos = 0; } } else { /* Read data into the allocated buffer. */ count = recv(server->tcp_socket, (void *)(server->tcp_buffer + server->tcp_buffer_pos), server->tcp_length - server->tcp_buffer_pos, 0); if (count <= 0) { handle_error(channel, i, now); continue; } server->tcp_buffer_pos += count; if (server->tcp_buffer_pos == server->tcp_length) { /* We finished reading this answer; process it and * prepare to read another length word. */ process_answer(channel, server->tcp_buffer, server->tcp_length, i, 1, now); if (server->tcp_buffer) free(server->tcp_buffer); server->tcp_buffer = NULL; server->tcp_lenbuf_pos = 0; } } } } /* If any UDP sockets select true for reading, process them. */ static void read_udp_packets(ares_channel channel, fd_set *read_fds, time_t now) { struct server_state *server; int i, count; unsigned char buf[PACKETSZ + 1]; for (i = 0; i < channel->nservers; i++) { /* Make sure the server has a socket and is selected in read_fds. */ server = &channel->servers[i]; if (server->udp_socket == ARES_SOCKET_BAD || !FD_ISSET(server->udp_socket, read_fds)) continue; count = recv(server->udp_socket, (void *)buf, sizeof(buf), 0); if (count <= 0) handle_error(channel, i, now); process_answer(channel, buf, count, i, 0, now); } } /* If any queries have timed out, note the timeout and move them on. */ static void process_timeouts(ares_channel channel, time_t now) { struct query *query, *next; for (query = channel->queries; query; query = next) { next = query->next; if (query->timeout != 0 && now >= query->timeout) { query->error_status = ARES_ETIMEOUT; next = next_server(channel, query, now); } } } /* Handle an answer from a server. */ static void process_answer(ares_channel channel, unsigned char *abuf, int alen, int whichserver, int tcp, int now) { int id, tc, rcode; struct query *query; /* If there's no room in the answer for a header, we can't do much * with it. */ if (alen < HFIXEDSZ) return; /* Grab the query ID, truncate bit, and response code from the packet. */ id = DNS_HEADER_QID(abuf); tc = DNS_HEADER_TC(abuf); rcode = DNS_HEADER_RCODE(abuf); /* Find the query corresponding to this packet. */ for (query = channel->queries; query; query = query->next) { if (query->qid == id) break; } if (!query) return; /* If we got a truncated UDP packet and are not ignoring truncation, * don't accept the packet, and switch the query to TCP if we hadn't * done so already. */ if ((tc || alen > PACKETSZ) && !tcp && !(channel->flags & ARES_FLAG_IGNTC)) { if (!query->using_tcp) { query->using_tcp = 1; ares__send_query(channel, query, now); } return; } /* Limit alen to PACKETSZ if we aren't using TCP (only relevant if we * are ignoring truncation. */ if (alen > PACKETSZ && !tcp) alen = PACKETSZ; /* If we aren't passing through all error packets, discard packets * with SERVFAIL, NOTIMP, or REFUSED response codes. */ if (!(channel->flags & ARES_FLAG_NOCHECKRESP)) { if (rcode == SERVFAIL || rcode == NOTIMP || rcode == REFUSED) { query->skip_server[whichserver] = 1; if (query->server == whichserver) next_server(channel, query, now); return; } if (!same_questions(query->qbuf, query->qlen, abuf, alen)) { if (query->server == whichserver) next_server(channel, query, now); return; } } end_query(channel, query, ARES_SUCCESS, abuf, alen); } static void handle_error(ares_channel channel, int whichserver, time_t now) { struct query *query, *next; /* Reset communications with this server. */ ares__close_sockets(&channel->servers[whichserver]); /* Tell all queries talking to this server to move on and not try * this server again. */ for (query = channel->queries; query; query = next) { next = query->next; if (query->server == whichserver) { query->skip_server[whichserver] = 1; next = next_server(channel, query, now); } } } static struct query *next_server(ares_channel channel, struct query *query, time_t now) { /* Advance to the next server or try. */ query->server++; for (; query->try < channel->tries; query->try++) { for (; query->server < channel->nservers; query->server++) { if (!query->skip_server[query->server]) { ares__send_query(channel, query, now); return (query->next); } } query->server = 0; /* Only one try if we're using TCP. */ if (query->using_tcp) break; } return end_query(channel, query, query->error_status, NULL, 0); } void ares__send_query(ares_channel channel, struct query *query, time_t now) { struct send_request *sendreq; struct server_state *server; server = &channel->servers[query->server]; if (query->using_tcp) { /* Make sure the TCP socket for this server is set up and queue * a send request. */ if (server->tcp_socket == ARES_SOCKET_BAD) { if (open_tcp_socket(channel, server) == -1) { query->skip_server[query->server] = 1; next_server(channel, query, now); return; } } sendreq = calloc(sizeof(struct send_request), 1); if (!sendreq) { end_query(channel, query, ARES_ENOMEM, NULL, 0); return; } sendreq->data = query->tcpbuf; sendreq->len = query->tcplen; sendreq->next = NULL; if (server->qtail) server->qtail->next = sendreq; else server->qhead = sendreq; server->qtail = sendreq; query->timeout = 0; } else { if (server->udp_socket == ARES_SOCKET_BAD) { if (open_udp_socket(channel, server) == -1) { query->skip_server[query->server] = 1; next_server(channel, query, now); return; } } if (send(server->udp_socket, (void *)query->qbuf, query->qlen, 0) == -1) { query->skip_server[query->server] = 1; next_server(channel, query, now); return; } query->timeout = now + ((query->try == 0) ? channel->timeout : channel->timeout << query->try / channel->nservers); } } /* * nonblock() set the given socket to either blocking or non-blocking mode * based on the 'nonblock' boolean argument. This function is highly portable. */ static int nonblock(ares_socket_t sockfd, /* operate on this */ int nonblock /* TRUE or FALSE */) { #undef SETBLOCK #define SETBLOCK 0 #ifdef HAVE_O_NONBLOCK /* most recent unix versions */ int flags; flags = fcntl(sockfd, F_GETFL, 0); if (TRUE == nonblock) return fcntl(sockfd, F_SETFL, flags | O_NONBLOCK); else return fcntl(sockfd, F_SETFL, flags & (~O_NONBLOCK)); #undef SETBLOCK #define SETBLOCK 1 #endif #if defined(HAVE_FIONBIO) && (SETBLOCK == 0) /* older unix versions */ int flags; flags = nonblock; return ioctl(sockfd, FIONBIO, &flags); #undef SETBLOCK #define SETBLOCK 2 #endif #if defined(HAVE_IOCTLSOCKET) && (SETBLOCK == 0) /* Windows? */ unsigned long flags; flags = nonblock; return ioctlsocket(sockfd, FIONBIO, &flags); #undef SETBLOCK #define SETBLOCK 3 #endif #if defined(HAVE_IOCTLSOCKET_CASE) && (SETBLOCK == 0) /* presumably for Amiga */ return IoctlSocket(sockfd, FIONBIO, (long)nonblock); #undef SETBLOCK #define SETBLOCK 4 #endif #if defined(HAVE_SO_NONBLOCK) && (SETBLOCK == 0) /* BeOS */ long b = nonblock ? 1 : 0; return setsockopt(sockfd, SOL_SOCKET, SO_NONBLOCK, &b, sizeof(b)); #undef SETBLOCK #define SETBLOCK 5 #endif #ifdef HAVE_DISABLED_NONBLOCKING return 0; /* returns success */ #undef SETBLOCK #define SETBLOCK 6 #endif #if (SETBLOCK == 0) #error "no non-blocking method was found/used/set" #endif } static int open_tcp_socket(ares_channel channel, struct server_state *server) { ares_socket_t s; struct sockaddr_in sockin; /* Acquire a socket. */ s = socket(AF_INET, SOCK_STREAM, 0); if (s == ARES_SOCKET_BAD) return -1; /* Set the socket non-blocking. */ nonblock(s, TRUE); /* Connect to the server. */ memset(&sockin, 0, sizeof(sockin)); sockin.sin_family = AF_INET; sockin.sin_addr = server->addr; sockin.sin_port = channel->tcp_port; if (connect(s, (struct sockaddr *) &sockin, sizeof(sockin)) == -1) { int err = GET_ERRNO(); if (err != EINPROGRESS && err != EWOULDBLOCK) { closesocket(s); return -1; } } server->tcp_buffer_pos = 0; server->tcp_socket = s; return 0; } static int open_udp_socket(ares_channel channel, struct server_state *server) { ares_socket_t s; struct sockaddr_in sockin; /* Acquire a socket. */ s = socket(AF_INET, SOCK_DGRAM, 0); if (s == ARES_SOCKET_BAD) return -1; /* Set the socket non-blocking. */ nonblock(s, TRUE); /* Connect to the server. */ memset(&sockin, 0, sizeof(sockin)); sockin.sin_family = AF_INET; sockin.sin_addr = server->addr; sockin.sin_port = channel->udp_port; if (connect(s, (struct sockaddr *) &sockin, sizeof(sockin)) == -1) { closesocket(s); return -1; } server->udp_socket = s; return 0; } static int same_questions(const unsigned char *qbuf, int qlen, const unsigned char *abuf, int alen) { struct { const unsigned char *p; int qdcount; char *name; long namelen; int type; int dnsclass; } q, a; int i, j; if (qlen < HFIXEDSZ || alen < HFIXEDSZ) return 0; /* Extract qdcount from the request and reply buffers and compare them. */ q.qdcount = DNS_HEADER_QDCOUNT(qbuf); a.qdcount = DNS_HEADER_QDCOUNT(abuf); if (q.qdcount != a.qdcount) return 0; /* For each question in qbuf, find it in abuf. */ q.p = qbuf + HFIXEDSZ; for (i = 0; i < q.qdcount; i++) { /* Decode the question in the query. */ if (ares_expand_name(q.p, qbuf, qlen, &q.name, &q.namelen) != ARES_SUCCESS) return 0; q.p += q.namelen; if (q.p + QFIXEDSZ > qbuf + qlen) { free(q.name); return 0; } q.type = DNS_QUESTION_TYPE(q.p); q.dnsclass = DNS_QUESTION_CLASS(q.p); q.p += QFIXEDSZ; /* Search for this question in the answer. */ a.p = abuf + HFIXEDSZ; for (j = 0; j < a.qdcount; j++) { /* Decode the question in the answer. */ if (ares_expand_name(a.p, abuf, alen, &a.name, &a.namelen) != ARES_SUCCESS) { free(q.name); return 0; } a.p += a.namelen; if (a.p + QFIXEDSZ > abuf + alen) { free(q.name); free(a.name); return 0; } a.type = DNS_QUESTION_TYPE(a.p); a.dnsclass = DNS_QUESTION_CLASS(a.p); a.p += QFIXEDSZ; /* Compare the decoded questions. */ if (strcasecmp(q.name, a.name) == 0 && q.type == a.type && q.dnsclass == a.dnsclass) { free(a.name); break; } free(a.name); } free(q.name); if (j == a.qdcount) return 0; } return 1; } static struct query *end_query (ares_channel channel, struct query *query, int status, unsigned char *abuf, int alen) { struct query **q, *next; int i; query->callback(query->arg, status, abuf, alen); for (q = &channel->queries; *q; q = &(*q)->next) { if (*q == query) break; } *q = query->next; if (*q) next = (*q)->next; else next = NULL; free(query->tcpbuf); free(query->skip_server); free(query); /* Simple cleanup policy: if no queries are remaining, close all * network sockets unless STAYOPEN is set. */ if (!channel->queries && !(channel->flags & ARES_FLAG_STAYOPEN)) { for (i = 0; i < channel->nservers; i++) ares__close_sockets(&channel->servers[i]); } return (next); }