/* -*- mode: c; c-basic-offset: 4; indent-tabs-mode: nil -*- */ /* lib/krb5/os/sendto_kdc.c */ /* * Copyright 1990,1991,2001,2002,2004,2005,2007,2008 by the Massachusetts Institute of Technology. * All Rights Reserved. * * Export of this software from the United States of America may * require a specific license from the United States Government. * It is the responsibility of any person or organization contemplating * export to obtain such a license before exporting. * * WITHIN THAT CONSTRAINT, 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. Furthermore if you modify this software you must label * your software as modified software and not distribute it in such a * fashion that it might be confused with the original M.I.T. software. * 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. */ /* Send packet to KDC for realm; wait for response, retransmitting * as necessary. */ #include "fake-addrinfo.h" #include "k5-int.h" #include "os-proto.h" #if defined(HAVE_POLL_H) #include #define USE_POLL #define MAX_POLLFDS 1024 #elif defined(HAVE_SYS_SELECT_H) #include #endif #ifndef _WIN32 /* For FIONBIO. */ #include #ifdef HAVE_SYS_FILIO_H #include #endif #endif #define MAX_PASS 3 #define DEFAULT_UDP_PREF_LIMIT 1465 #define HARD_UDP_LIMIT 32700 /* could probably do 64K-epsilon ? */ /* Select state flags. */ #define SSF_READ 0x01 #define SSF_WRITE 0x02 #define SSF_EXCEPTION 0x04 typedef int64_t time_ms; /* This can be pretty large, so should not be stack-allocated. */ struct select_state { #ifdef USE_POLL struct pollfd fds[MAX_POLLFDS]; #else int max; fd_set rfds, wfds, xfds; #endif int nfds; }; static const char *const state_strings[] = { "INITIALIZING", "CONNECTING", "WRITING", "READING", "FAILED" }; /* connection states */ enum conn_states { INITIALIZING, CONNECTING, WRITING, READING, FAILED }; struct incoming_krb5_message { size_t bufsizebytes_read; size_t bufsize; char *buf; char *pos; unsigned char bufsizebytes[4]; size_t n_left; }; struct conn_state { SOCKET fd; enum conn_states state; int (*service)(krb5_context context, struct conn_state *, struct select_state *, int); struct remote_address addr; struct { struct { sg_buf sgbuf[2]; sg_buf *sgp; int sg_count; unsigned char msg_len_buf[4]; } out; struct incoming_krb5_message in; } x; krb5_data callback_buffer; size_t server_index; struct conn_state *next; time_ms endtime; }; /* Get current time in milliseconds. */ static krb5_error_code get_curtime_ms(time_ms *time_out) { struct timeval tv; if (gettimeofday(&tv, 0)) return errno; *time_out = (time_ms)tv.tv_sec * 1000 + tv.tv_usec / 1000; return 0; } #ifdef USE_POLL /* Find a pollfd in selstate by fd, or abort if we can't find it. */ static inline struct pollfd * find_pollfd(struct select_state *selstate, int fd) { int i; for (i = 0; i < selstate->nfds; i++) { if (selstate->fds[i].fd == fd) return &selstate->fds[i]; } abort(); } static void cm_init_selstate(struct select_state *selstate) { selstate->nfds = 0; } static krb5_boolean cm_add_fd(struct select_state *selstate, int fd) { if (selstate->nfds >= MAX_POLLFDS) return FALSE; selstate->fds[selstate->nfds].fd = fd; selstate->fds[selstate->nfds].events = 0; selstate->nfds++; return TRUE; } static void cm_remove_fd(struct select_state *selstate, int fd) { struct pollfd *pfd = find_pollfd(selstate, fd); *pfd = selstate->fds[selstate->nfds - 1]; selstate->nfds--; } /* Poll for reading (and not writing) on fd the next time we poll. */ static void cm_read(struct select_state *selstate, int fd) { find_pollfd(selstate, fd)->events = POLLIN; } /* Poll for writing (and not reading) on fd the next time we poll. */ static void cm_write(struct select_state *selstate, int fd) { find_pollfd(selstate, fd)->events = POLLOUT; } /* Get the output events for fd in the form of ssflags. */ static unsigned int cm_get_ssflags(struct select_state *selstate, int fd) { struct pollfd *pfd = find_pollfd(selstate, fd); /* * OS X sets POLLHUP without POLLOUT on connection error. Catch this as * well as other error events such as POLLNVAL, but only if POLLIN and * POLLOUT aren't set, as we can get POLLHUP along with POLLIN with TCP * data still to be read. */ if (pfd->revents != 0 && !(pfd->revents & (POLLIN | POLLOUT))) return SSF_EXCEPTION; return ((pfd->revents & POLLIN) ? SSF_READ : 0) | ((pfd->revents & POLLOUT) ? SSF_WRITE : 0) | ((pfd->revents & POLLERR) ? SSF_EXCEPTION : 0); } #else /* not USE_POLL */ static void cm_init_selstate(struct select_state *selstate) { selstate->nfds = 0; selstate->max = 0; FD_ZERO(&selstate->rfds); FD_ZERO(&selstate->wfds); FD_ZERO(&selstate->xfds); } static krb5_boolean cm_add_fd(struct select_state *selstate, int fd) { #ifndef _WIN32 /* On Windows FD_SETSIZE is a count, not a max value. */ if (fd >= FD_SETSIZE) return FALSE; #endif FD_SET(fd, &selstate->xfds); if (selstate->max <= fd) selstate->max = fd + 1; selstate->nfds++; return TRUE; } static void cm_remove_fd(struct select_state *selstate, int fd) { FD_CLR(fd, &selstate->rfds); FD_CLR(fd, &selstate->wfds); FD_CLR(fd, &selstate->xfds); if (selstate->max == fd + 1) { while (selstate->max > 0 && !FD_ISSET(selstate->max - 1, &selstate->rfds) && !FD_ISSET(selstate->max - 1, &selstate->wfds) && !FD_ISSET(selstate->max - 1, &selstate->xfds)) selstate->max--; } selstate->nfds--; } /* Select for reading (and not writing) on fd the next time we select. */ static void cm_read(struct select_state *selstate, int fd) { FD_SET(fd, &selstate->rfds); FD_CLR(fd, &selstate->wfds); } /* Select for writing (and not reading) on fd the next time we select. */ static void cm_write(struct select_state *selstate, int fd) { FD_CLR(fd, &selstate->rfds); FD_SET(fd, &selstate->wfds); } /* Get the events for fd from selstate after a select. */ static unsigned int cm_get_ssflags(struct select_state *selstate, int fd) { return (FD_ISSET(fd, &selstate->rfds) ? SSF_READ : 0) | (FD_ISSET(fd, &selstate->wfds) ? SSF_WRITE : 0) | (FD_ISSET(fd, &selstate->xfds) ? SSF_EXCEPTION : 0); } #endif /* not USE_POLL */ static krb5_error_code cm_select_or_poll(const struct select_state *in, time_ms endtime, struct select_state *out, int *sret) { #ifndef USE_POLL struct timeval tv; #endif krb5_error_code retval; time_ms curtime, interval; retval = get_curtime_ms(&curtime); if (retval != 0) return retval; interval = (curtime < endtime) ? endtime - curtime : 0; /* We don't need a separate copy of the selstate for poll, but use one for * consistency with how we use select. */ *out = *in; #ifdef USE_POLL *sret = poll(out->fds, out->nfds, interval); #else tv.tv_sec = interval / 1000; tv.tv_usec = interval % 1000 * 1000; *sret = select(out->max, &out->rfds, &out->wfds, &out->xfds, &tv); #endif return (*sret < 0) ? SOCKET_ERRNO : 0; } static int in_addrlist(struct server_entry *entry, struct serverlist *list) { size_t i; struct server_entry *le; for (i = 0; i < list->nservers; i++) { le = &list->servers[i]; if (entry->hostname != NULL && le->hostname != NULL && strcmp(entry->hostname, le->hostname) == 0) return 1; if (entry->hostname == NULL && le->hostname == NULL && entry->addrlen == le->addrlen && memcmp(&entry->addr, &le->addr, entry->addrlen) == 0) return 1; } return 0; } static int check_for_svc_unavailable (krb5_context context, const krb5_data *reply, void *msg_handler_data) { krb5_error_code *retval = (krb5_error_code *)msg_handler_data; *retval = 0; if (krb5_is_krb_error(reply)) { krb5_error *err_reply; if (decode_krb5_error(reply, &err_reply) == 0) { *retval = err_reply->error; krb5_free_error(context, err_reply); /* Returning 0 means continue to next KDC */ return (*retval != KDC_ERR_SVC_UNAVAILABLE); } } return 1; } /* * send the formatted request 'message' to a KDC for realm 'realm' and * return the response (if any) in 'reply'. * * If the message is sent and a response is received, 0 is returned, * otherwise an error code is returned. * * The storage for 'reply' is allocated and should be freed by the caller * when finished. */ krb5_error_code krb5_sendto_kdc(krb5_context context, const krb5_data *message, const krb5_data *realm, krb5_data *reply, int *use_master, int tcp_only) { krb5_error_code retval, err; struct serverlist servers; int socktype1 = 0, socktype2 = 0, server_used; /* * find KDC location(s) for realm */ /* * BUG: This code won't return "interesting" errors (e.g., out of mem, * bad config file) from locate_kdc. KRB5_REALM_CANT_RESOLVE can be * ignored from one query of two, but if only one query is done, or * both return that error, it should be returned to the caller. Also, * "interesting" errors (not KRB5_KDC_UNREACH) from sendto_{udp,tcp} * should probably be returned as well. */ TRACE_SENDTO_KDC(context, message->length, realm, *use_master, tcp_only); if (!tcp_only && context->udp_pref_limit < 0) { int tmp; retval = profile_get_integer(context->profile, KRB5_CONF_LIBDEFAULTS, KRB5_CONF_UDP_PREFERENCE_LIMIT, 0, DEFAULT_UDP_PREF_LIMIT, &tmp); if (retval) return retval; if (tmp < 0) tmp = DEFAULT_UDP_PREF_LIMIT; else if (tmp > HARD_UDP_LIMIT) /* In the unlikely case that a *really* big value is given, let 'em use as big as we think we can support. */ tmp = HARD_UDP_LIMIT; context->udp_pref_limit = tmp; } if (tcp_only) socktype1 = SOCK_STREAM, socktype2 = 0; else if (message->length <= (unsigned int) context->udp_pref_limit) socktype1 = SOCK_DGRAM, socktype2 = SOCK_STREAM; else socktype1 = SOCK_STREAM, socktype2 = SOCK_DGRAM; retval = k5_locate_kdc(context, realm, &servers, *use_master, tcp_only ? SOCK_STREAM : 0); if (retval) return retval; err = 0; retval = k5_sendto(context, message, &servers, socktype1, socktype2, NULL, reply, NULL, NULL, &server_used, check_for_svc_unavailable, &err); if (retval == KRB5_KDC_UNREACH) { if (err == KDC_ERR_SVC_UNAVAILABLE) { retval = KRB5KDC_ERR_SVC_UNAVAILABLE; } else { krb5_set_error_message(context, retval, _("Cannot contact any KDC for realm " "'%.*s'"), realm->length, realm->data); } } if (retval) goto cleanup; /* Set use_master to 1 if we ended up talking to a master when we didn't * explicitly request to. */ if (*use_master == 0) { struct serverlist mservers; struct server_entry *entry = &servers.servers[server_used]; retval = k5_locate_kdc(context, realm, &mservers, TRUE, entry->socktype); if (retval == 0) { if (in_addrlist(entry, &mservers)) *use_master = 1; k5_free_serverlist(&mservers); } TRACE_SENDTO_KDC_MASTER(context, *use_master); retval = 0; } cleanup: k5_free_serverlist(&servers); return retval; } /* * Notes: * * Getting "connection refused" on a connected UDP socket causes * select to indicate write capability on UNIX, but only shows up * as an exception on Windows. (I don't think any UNIX system flags * the error as an exception.) So we check for both, or make it * system-specific. * * Always watch for responses from *any* of the servers. Eventually * fix the UDP code to do the same. * * To do: * - TCP NOPUSH/CORK socket options? * - error codes that don't suck * - getsockopt(SO_ERROR) to check connect status * - handle error RESPONSE_TOO_BIG from UDP server and use TCP * connections already in progress */ static int service_tcp_fd(krb5_context context, struct conn_state *conn, struct select_state *selstate, int ssflags); static int service_udp_fd(krb5_context context, struct conn_state *conn, struct select_state *selstate, int ssflags); static void set_conn_state_msg_length (struct conn_state *state, const krb5_data *message) { if (!message || message->length == 0) return; if (state->addr.type == SOCK_STREAM) { store_32_be(message->length, state->x.out.msg_len_buf); SG_SET(&state->x.out.sgbuf[0], state->x.out.msg_len_buf, 4); SG_SET(&state->x.out.sgbuf[1], message->data, message->length); state->x.out.sg_count = 2; } else { SG_SET(&state->x.out.sgbuf[0], message->data, message->length); SG_SET(&state->x.out.sgbuf[1], 0, 0); state->x.out.sg_count = 1; } } static krb5_error_code add_connection(struct conn_state **conns, struct addrinfo *ai, size_t server_index, const krb5_data *message, char **udpbufp) { struct conn_state *state, **tailptr; state = calloc(1, sizeof(*state)); if (state == NULL) return ENOMEM; state->state = INITIALIZING; state->x.out.sgp = state->x.out.sgbuf; state->addr.type = ai->ai_socktype; state->addr.family = ai->ai_family; state->addr.len = ai->ai_addrlen; memcpy(&state->addr.saddr, ai->ai_addr, ai->ai_addrlen); state->fd = INVALID_SOCKET; state->server_index = server_index; SG_SET(&state->x.out.sgbuf[1], 0, 0); if (ai->ai_socktype == SOCK_STREAM) { state->service = service_tcp_fd; set_conn_state_msg_length (state, message); } else { state->service = service_udp_fd; set_conn_state_msg_length (state, message); if (*udpbufp == NULL) { *udpbufp = malloc(MAX_DGRAM_SIZE); if (*udpbufp == 0) return ENOMEM; } state->x.in.buf = *udpbufp; state->x.in.bufsize = MAX_DGRAM_SIZE; } /* Chain the new state onto the tail of the list. */ for (tailptr = conns; *tailptr != NULL; tailptr = &(*tailptr)->next); *tailptr = state; return 0; } static int translate_ai_error (int err) { switch (err) { case 0: return 0; case EAI_BADFLAGS: case EAI_FAMILY: case EAI_SOCKTYPE: case EAI_SERVICE: /* All of these indicate bad inputs to getaddrinfo. */ return EINVAL; case EAI_AGAIN: /* Translate to standard errno code. */ return EAGAIN; case EAI_MEMORY: /* Translate to standard errno code. */ return ENOMEM; #ifdef EAI_ADDRFAMILY case EAI_ADDRFAMILY: #endif #if defined(EAI_NODATA) && EAI_NODATA != EAI_NONAME case EAI_NODATA: #endif case EAI_NONAME: /* Name not known or no address data, but no error. Do nothing more. */ return 0; #ifdef EAI_OVERFLOW case EAI_OVERFLOW: /* An argument buffer overflowed. */ return EINVAL; /* XXX */ #endif #ifdef EAI_SYSTEM case EAI_SYSTEM: /* System error, obviously. */ return errno; #endif default: /* An error code we haven't handled? */ return EINVAL; } } /* * Resolve the entry in servers with index ind, adding connections to the list * *conns. Connections are added for each of socktype1 and (if not zero) * socktype2. message and udpbufp are used to initialize the connections; see * add_connection above. If no addresses are available for an entry but no * internal name resolution failure occurs, return 0 without adding any new * connections. */ static krb5_error_code resolve_server(krb5_context context, const struct serverlist *servers, size_t ind, int socktype1, int socktype2, const krb5_data *message, char **udpbufp, struct conn_state **conns) { krb5_error_code retval; struct server_entry *entry = &servers->servers[ind]; struct addrinfo *addrs, *a, hint, ai; int err, result; char portbuf[64]; /* Skip any stray entries of socktypes we don't want. */ if (entry->socktype != 0 && entry->socktype != socktype1 && entry->socktype != socktype2) return 0; if (entry->hostname == NULL) { ai.ai_socktype = entry->socktype; ai.ai_family = entry->family; ai.ai_addrlen = entry->addrlen; ai.ai_addr = (struct sockaddr *)&entry->addr; return add_connection(conns, &ai, ind, message, udpbufp); } memset(&hint, 0, sizeof(hint)); hint.ai_family = entry->family; hint.ai_socktype = (entry->socktype != 0) ? entry->socktype : socktype1; hint.ai_flags = AI_ADDRCONFIG; #ifdef AI_NUMERICSERV hint.ai_flags |= AI_NUMERICSERV; #endif result = snprintf(portbuf, sizeof(portbuf), "%d", ntohs(entry->port)); if (SNPRINTF_OVERFLOW(result, sizeof(portbuf))) return EINVAL; TRACE_SENDTO_KDC_RESOLVING(context, entry->hostname); err = getaddrinfo(entry->hostname, portbuf, &hint, &addrs); if (err) return translate_ai_error(err); /* Add each address with the preferred socktype. */ retval = 0; for (a = addrs; a != 0 && retval == 0; a = a->ai_next) retval = add_connection(conns, a, ind, message, udpbufp); if (retval == 0 && entry->socktype == 0 && socktype2 != 0) { /* Add each address again with the non-preferred socktype. */ for (a = addrs; a != 0 && retval == 0; a = a->ai_next) { a->ai_socktype = socktype2; retval = add_connection(conns, a, ind, message, udpbufp); } } freeaddrinfo(addrs); return retval; } static int start_connection(krb5_context context, struct conn_state *state, struct select_state *selstate, struct sendto_callback_info *callback_info) { int fd, e; static const int one = 1; static const struct linger lopt = { 0, 0 }; fd = socket(state->addr.family, state->addr.type, 0); if (fd == INVALID_SOCKET) return -1; /* try other hosts */ set_cloexec_fd(fd); /* Make it non-blocking. */ ioctlsocket(fd, FIONBIO, (const void *) &one); if (state->addr.type == SOCK_STREAM) { setsockopt(fd, SOL_SOCKET, SO_LINGER, &lopt, sizeof(lopt)); TRACE_SENDTO_KDC_TCP_CONNECT(context, &state->addr); } /* Start connecting to KDC. */ e = connect(fd, (struct sockaddr *)&state->addr.saddr, state->addr.len); if (e != 0) { /* * This is the path that should be followed for non-blocking * connections. */ if (SOCKET_ERRNO == EINPROGRESS || SOCKET_ERRNO == EWOULDBLOCK) { state->state = CONNECTING; state->fd = fd; } else { (void) closesocket(fd); state->state = FAILED; return -2; } } else { /* * Connect returned zero even though we made it non-blocking. This * happens normally for UDP sockets, and can perhaps also happen for * TCP sockets connecting to localhost. */ state->state = WRITING; state->fd = fd; } /* * Here's where KPASSWD callback gets the socket information it needs for * a kpasswd request */ if (callback_info) { e = callback_info->pfn_callback(state->fd, callback_info->data, &state->callback_buffer); if (e != 0) { (void) closesocket(fd); state->fd = INVALID_SOCKET; state->state = FAILED; return -3; } set_conn_state_msg_length(state, &state->callback_buffer); } if (state->addr.type == SOCK_DGRAM) { /* Send it now. */ ssize_t ret; sg_buf *sg = &state->x.out.sgbuf[0]; TRACE_SENDTO_KDC_UDP_SEND_INITIAL(context, &state->addr); ret = send(state->fd, SG_BUF(sg), SG_LEN(sg), 0); if (ret < 0 || (size_t) ret != SG_LEN(sg)) { TRACE_SENDTO_KDC_UDP_ERROR_SEND_INITIAL(context, &state->addr, SOCKET_ERRNO); (void) closesocket(state->fd); state->fd = INVALID_SOCKET; state->state = FAILED; return -4; } else { state->state = READING; } } if (!cm_add_fd(selstate, state->fd)) { (void) closesocket(state->fd); state->fd = INVALID_SOCKET; state->state = FAILED; return -1; } if (state->state == CONNECTING || state->state == WRITING) cm_write(selstate, state->fd); else cm_read(selstate, state->fd); return 0; } /* Return 0 if we sent something, non-0 otherwise. If 0 is returned, the caller should delay waiting for a response. Otherwise, the caller should immediately move on to process the next connection. */ static int maybe_send(krb5_context context, struct conn_state *conn, struct select_state *selstate, struct sendto_callback_info *callback_info) { sg_buf *sg; ssize_t ret; if (conn->state == INITIALIZING) return start_connection(context, conn, selstate, callback_info); /* Did we already shut down this channel? */ if (conn->state == FAILED) { return -1; } if (conn->addr.type == SOCK_STREAM) { /* The select callback will handle flushing any data we haven't written yet, and we only write it once. */ return -1; } /* UDP - retransmit after a previous attempt timed out. */ sg = &conn->x.out.sgbuf[0]; TRACE_SENDTO_KDC_UDP_SEND_RETRY(context, &conn->addr); ret = send(conn->fd, SG_BUF(sg), SG_LEN(sg), 0); if (ret < 0 || (size_t) ret != SG_LEN(sg)) { TRACE_SENDTO_KDC_UDP_ERROR_SEND_RETRY(context, &conn->addr, SOCKET_ERRNO); /* Keep connection alive, we'll try again next pass. Is this likely to catch any errors we didn't get from the select callbacks? */ return -1; } /* Yay, it worked. */ return 0; } static void kill_conn(struct conn_state *conn, struct select_state *selstate) { cm_remove_fd(selstate, conn->fd); closesocket(conn->fd); conn->fd = INVALID_SOCKET; conn->state = FAILED; } /* Check socket for error. */ static int get_so_error(int fd) { int e, sockerr; socklen_t sockerrlen; sockerr = 0; sockerrlen = sizeof(sockerr); e = getsockopt(fd, SOL_SOCKET, SO_ERROR, &sockerr, &sockerrlen); if (e != 0) { /* What to do now? */ e = SOCKET_ERRNO; return e; } return sockerr; } /* Process events on a TCP socket. Return 1 if we get a complete reply. */ static int service_tcp_fd(krb5_context context, struct conn_state *conn, struct select_state *selstate, int ssflags) { int e = 0; ssize_t nwritten, nread; SOCKET_WRITEV_TEMP tmp; /* Check for a socket exception. */ if (ssflags & SSF_EXCEPTION) goto kill_conn; switch (conn->state) { case CONNECTING: /* Check whether the connection succeeded. */ e = get_so_error(conn->fd); if (e) { TRACE_SENDTO_KDC_TCP_ERROR_CONNECT(context, &conn->addr, e); goto kill_conn; } conn->state = WRITING; /* Record this connection's timeout for service_fds. */ if (get_curtime_ms(&conn->endtime) == 0) conn->endtime += 10000; /* Fall through. */ case WRITING: TRACE_SENDTO_KDC_TCP_SEND(context, &conn->addr); nwritten = SOCKET_WRITEV(conn->fd, conn->x.out.sgp, conn->x.out.sg_count, tmp); if (nwritten < 0) { TRACE_SENDTO_KDC_TCP_ERROR_SEND(context, &conn->addr, SOCKET_ERRNO); goto kill_conn; } while (nwritten) { sg_buf *sgp = conn->x.out.sgp; if ((size_t) nwritten < SG_LEN(sgp)) { SG_ADVANCE(sgp, (size_t) nwritten); nwritten = 0; } else { nwritten -= SG_LEN(sgp); conn->x.out.sgp++; conn->x.out.sg_count--; } } if (conn->x.out.sg_count == 0) { /* Done writing, switch to reading. */ cm_read(selstate, conn->fd); conn->state = READING; conn->x.in.bufsizebytes_read = 0; conn->x.in.bufsize = 0; conn->x.in.buf = 0; conn->x.in.pos = 0; conn->x.in.n_left = 0; } return 0; case READING: if (conn->x.in.bufsizebytes_read == 4) { /* Reading data. */ nread = SOCKET_READ(conn->fd, conn->x.in.pos, conn->x.in.n_left); if (nread <= 0) { e = nread ? SOCKET_ERRNO : ECONNRESET; TRACE_SENDTO_KDC_TCP_ERROR_RECV(context, &conn->addr, e); goto kill_conn; } conn->x.in.n_left -= nread; conn->x.in.pos += nread; if (conn->x.in.n_left <= 0) return 1; } else { /* Reading length. */ nread = SOCKET_READ(conn->fd, conn->x.in.bufsizebytes + conn->x.in.bufsizebytes_read, 4 - conn->x.in.bufsizebytes_read); if (nread <= 0) { e = nread ? SOCKET_ERRNO : ECONNRESET; TRACE_SENDTO_KDC_TCP_ERROR_RECV_LEN(context, &conn->addr, e); goto kill_conn; } conn->x.in.bufsizebytes_read += nread; if (conn->x.in.bufsizebytes_read == 4) { unsigned long len = load_32_be (conn->x.in.bufsizebytes); /* Arbitrary 1M cap. */ if (len > 1 * 1024 * 1024) goto kill_conn; conn->x.in.bufsize = conn->x.in.n_left = len; conn->x.in.buf = conn->x.in.pos = malloc(len); if (conn->x.in.buf == 0) goto kill_conn; } } break; default: abort(); } return 0; kill_conn: TRACE_SENDTO_KDC_TCP_DISCONNECT(context, &conn->addr); kill_conn(conn, selstate); return 0; } /* Process events on a UDP socket. Return 1 if we get a reply. */ static int service_udp_fd(krb5_context context, struct conn_state *conn, struct select_state *selstate, int ssflags) { int nread; if (!(ssflags & (SSF_READ|SSF_EXCEPTION))) abort(); if (conn->state != READING) abort(); nread = recv(conn->fd, conn->x.in.buf, conn->x.in.bufsize, 0); if (nread < 0) { TRACE_SENDTO_KDC_UDP_ERROR_RECV(context, &conn->addr, SOCKET_ERRNO); kill_conn(conn, selstate); return 0; } conn->x.in.pos = conn->x.in.buf + nread; return 1; } /* Return the maximum of endtime and the endtime fields of all currently active * TCP connections. */ static time_ms get_endtime(time_ms endtime, struct conn_state *conns) { struct conn_state *state; for (state = conns; state != NULL; state = state->next) { if (state->addr.type == SOCK_STREAM && (state->state == READING || state->state == WRITING) && state->endtime > endtime) endtime = state->endtime; } return endtime; } static krb5_boolean service_fds(krb5_context context, struct select_state *selstate, time_ms interval, struct conn_state *conns, struct select_state *seltemp, int (*msg_handler)(krb5_context, const krb5_data *, void *), void *msg_handler_data, struct conn_state **winner_out) { int e, selret = 0; time_ms endtime; struct conn_state *state; *winner_out = NULL; e = get_curtime_ms(&endtime); if (e) return 1; endtime += interval; e = 0; while (selstate->nfds > 0) { e = cm_select_or_poll(selstate, get_endtime(endtime, conns), seltemp, &selret); if (e == EINTR) continue; if (e != 0) break; if (selret == 0) /* Timeout, return to caller. */ return 0; /* Got something on a socket, process it. */ for (state = conns; state != NULL; state = state->next) { int ssflags; if (state->fd == INVALID_SOCKET) continue; ssflags = cm_get_ssflags(seltemp, state->fd); if (!ssflags) continue; if (state->service(context, state, selstate, ssflags)) { int stop = 1; if (msg_handler != NULL) { krb5_data reply; reply.data = state->x.in.buf; reply.length = state->x.in.pos - state->x.in.buf; stop = (msg_handler(context, &reply, msg_handler_data) != 0); } if (stop) { *winner_out = state; return 1; } } } } if (e != 0) return 1; return 0; } /* * Current worst-case timeout behavior: * * First pass, 1s per udp or tcp server, plus 2s at end. * Second pass, 1s per udp server, plus 4s. * Third pass, 1s per udp server, plus 8s. * Fourth => 16s, etc. * * Restated: * Per UDP server, 1s per pass. * Per TCP server, 1s. * Backoff delay, 2**(P+1) - 2, where P is total number of passes. * * Total = 2**(P+1) + U*P + T - 2. * * If P=3, Total = 3*U + T + 14. * If P=4, Total = 4*U + T + 30. * * Note that if you try to reach two ports (e.g., both 88 and 750) on * one server, it counts as two. * * There is one exception to the above rules. Whenever a TCP connection is * established, we wait up to ten seconds for it to finish or fail before * moving on. This reduces network traffic significantly in a TCP environment. */ krb5_error_code k5_sendto(krb5_context context, const krb5_data *message, const struct serverlist *servers, int socktype1, int socktype2, struct sendto_callback_info* callback_info, krb5_data *reply, struct sockaddr *remoteaddr, socklen_t *remoteaddrlen, int *server_used, /* return 0 -> keep going, 1 -> quit */ int (*msg_handler)(krb5_context, const krb5_data *, void *), void *msg_handler_data) { int pass; time_ms delay; krb5_error_code retval; struct conn_state *conns = NULL, *state, **tailptr, *next, *winner; size_t s; struct select_state *sel_state = NULL, *seltemp; char *udpbuf = NULL; krb5_boolean done = FALSE; reply->data = 0; reply->length = 0; /* One for use here, listing all our fds in use, and one for * temporary use in service_fds, for the fds of interest. */ sel_state = malloc(2 * sizeof(*sel_state)); if (sel_state == NULL) { retval = ENOMEM; goto cleanup; } seltemp = &sel_state[1]; cm_init_selstate(sel_state); /* First pass: resolve server hosts, communicate with resulting addresses * of the preferred socktype, and wait 1s for an answer from each. */ for (s = 0; s < servers->nservers && !done; s++) { /* Find the current tail pointer. */ for (tailptr = &conns; *tailptr != NULL; tailptr = &(*tailptr)->next); retval = resolve_server(context, servers, s, socktype1, socktype2, message, &udpbuf, &conns); if (retval) goto cleanup; for (state = *tailptr; state != NULL && !done; state = state->next) { /* Contact each new connection whose socktype matches socktype1. */ if (state->addr.type != socktype1) continue; if (maybe_send(context, state, sel_state, callback_info)) continue; done = service_fds(context, sel_state, 1000, conns, seltemp, msg_handler, msg_handler_data, &winner); } } /* Complete the first pass by contacting servers of the non-preferred * socktype (if given), waiting 1s for an answer from each. */ for (state = conns; state != NULL && !done; state = state->next) { if (state->addr.type != socktype2) continue; if (maybe_send(context, state, sel_state, callback_info)) continue; done = service_fds(context, sel_state, 1000, conns, seltemp, msg_handler, msg_handler_data, &winner); } /* Wait for two seconds at the end of the first pass. */ if (!done) { done = service_fds(context, sel_state, 2000, conns, seltemp, msg_handler, msg_handler_data, &winner); } /* Make remaining passes over all of the connections. */ delay = 4000; for (pass = 1; pass < MAX_PASS && !done; pass++) { for (state = conns; state != NULL && !done; state = state->next) { if (maybe_send(context, state, sel_state, callback_info)) continue; done = service_fds(context, sel_state, 1000, conns, seltemp, msg_handler, msg_handler_data, &winner); if (sel_state->nfds == 0) break; } /* Wait for the delay backoff at the end of this pass. */ if (!done) { done = service_fds(context, sel_state, delay, conns, seltemp, msg_handler, msg_handler_data, &winner); } if (sel_state->nfds == 0) break; delay *= 2; } if (sel_state->nfds == 0 || !done || winner == NULL) { retval = KRB5_KDC_UNREACH; goto cleanup; } /* Success! */ reply->data = winner->x.in.buf; reply->length = winner->x.in.pos - winner->x.in.buf; retval = 0; winner->x.in.buf = NULL; if (server_used != NULL) *server_used = winner->server_index; if (remoteaddr != NULL && remoteaddrlen != 0 && *remoteaddrlen > 0) (void)getpeername(winner->fd, remoteaddr, remoteaddrlen); TRACE_SENDTO_KDC_RESPONSE(context, reply->length, &winner->addr); cleanup: for (state = conns; state != NULL; state = next) { next = state->next; if (state->fd != INVALID_SOCKET) closesocket(state->fd); if (state->state == READING && state->x.in.buf != udpbuf) free(state->x.in.buf); if (callback_info) { callback_info->pfn_cleanup(callback_info->data, &state->callback_buffer); } free(state); } if (reply->data != udpbuf) free(udpbuf); free(sel_state); return retval; }