/* $OpenBSD: relay.c,v 1.32 2007/05/29 00:48:04 pyr Exp $ */ /* * Copyright (c) 2006, 2007 Reyk Floeter * * Permission to use, copy, modify, and distribute this software for any * purpose with or without fee is hereby granted, provided that the above * copyright notice and this permission notice appear in all copies. * * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF * OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "hoststated.h" void relay_sig_handler(int sig, short, void *); void relay_statistics(int, short, void *); void relay_dispatch_pfe(int, short, void *); void relay_dispatch_parent(int, short, void *); void relay_shutdown(void); void relay_privinit(void); void relay_protodebug(struct relay *); void relay_init(void); void relay_launch(void); int relay_socket(struct sockaddr_storage *, in_port_t, struct protocol *); int relay_socket_listen(struct sockaddr_storage *, in_port_t, struct protocol *); int relay_socket_connect(struct sockaddr_storage *, in_port_t, struct protocol *); void relay_accept(int, short, void *); void relay_input(struct session *); void relay_close(struct session *, const char *); void relay_session(struct session *); void relay_natlook(int, short, void *); int relay_connect(struct session *); void relay_connected(int, short, void *); const char *relay_host(struct sockaddr_storage *, char *, size_t); u_int32_t relay_hash_addr(struct sockaddr_storage *, u_int32_t); int relay_from_table(struct session *); void relay_write(struct bufferevent *, void *); void relay_read(struct bufferevent *, void *); void relay_error(struct bufferevent *, short, void *); int relay_handle_http(struct ctl_relay_event *, struct protonode *, struct protonode *, int); void relay_read_http(struct bufferevent *, void *); void relay_read_httpcontent(struct bufferevent *, void *); void relay_read_httpchunks(struct bufferevent *, void *); char *relay_expand_http(struct ctl_relay_event *, char *, char *, size_t); SSL_CTX *relay_ssl_ctx_create(struct relay *); void relay_ssl_transaction(struct session *); void relay_ssl_accept(int, short, void *); void relay_ssl_connected(struct ctl_relay_event *); void relay_ssl_readcb(int, short, void *); void relay_ssl_writecb(int, short, void *); int relay_bufferevent_add(struct event *, int); #ifdef notyet int relay_bufferevent_printf(struct ctl_relay_event *, const char *, ...); #endif int relay_bufferevent_print(struct ctl_relay_event *, char *); int relay_bufferevent_write_buffer(struct ctl_relay_event *, struct evbuffer *); int relay_bufferevent_write_chunk(struct ctl_relay_event *, struct evbuffer *, size_t); int relay_bufferevent_write(struct ctl_relay_event *, void *, size_t); static __inline int relay_proto_cmp(struct protonode *, struct protonode *); extern void bufferevent_read_pressure_cb(struct evbuffer *, size_t, size_t, void *); volatile sig_atomic_t relay_sessions; objid_t relay_conid; static struct hoststated *env = NULL; struct imsgbuf *ibuf_pfe; struct imsgbuf *ibuf_main; int proc_id; #if DEBUG > 1 #define DPRINTF log_debug #else #define DPRINTF(x...) do { } while(0) #endif void relay_sig_handler(int sig, short event, void *arg) { switch (sig) { case SIGTERM: case SIGINT: (void)event_loopexit(NULL); } } pid_t relay(struct hoststated *x_env, int pipe_parent2pfe[2], int pipe_parent2hce[2], int pipe_parent2relay[RELAY_MAXPROC][2], int pipe_pfe2hce[2], int pipe_pfe2relay[RELAY_MAXPROC][2]) { pid_t pid; struct passwd *pw; struct event ev_sigint; struct event ev_sigterm; int i; switch (pid = fork()) { case -1: fatal("relay: cannot fork"); case 0: break; default: return (pid); } env = x_env; purge_config(env, PURGE_SERVICES); /* Need root privileges for relay initialization */ relay_privinit(); if ((pw = getpwnam(HOSTSTATED_USER)) == NULL) fatal("relay: getpwnam"); #ifndef DEBUG if (chroot(pw->pw_dir) == -1) fatal("relay: chroot"); if (chdir("/") == -1) fatal("relay: chdir(\"/\")"); #endif setproctitle("socket relay engine"); hoststated_process = PROC_RELAY; #ifndef DEBUG if (setgroups(1, &pw->pw_gid) || setresgid(pw->pw_gid, pw->pw_gid, pw->pw_gid) || setresuid(pw->pw_uid, pw->pw_uid, pw->pw_uid)) fatal("relay: can't drop privileges"); #endif /* Fork child handlers */ for (i = 1; i < env->prefork_relay; i++) { if (fork() == 0) { proc_id = i; break; } } event_init(); /* Per-child initialization */ relay_init(); signal_set(&ev_sigint, SIGINT, relay_sig_handler, NULL); signal_set(&ev_sigterm, SIGTERM, relay_sig_handler, NULL); signal_add(&ev_sigint, NULL); signal_add(&ev_sigterm, NULL); signal(SIGHUP, SIG_IGN); signal(SIGPIPE, SIG_IGN); /* setup pipes */ close(pipe_pfe2hce[0]); close(pipe_pfe2hce[1]); close(pipe_parent2hce[0]); close(pipe_parent2hce[1]); close(pipe_parent2pfe[0]); close(pipe_parent2pfe[1]); for (i = 0; i < env->prefork_relay; i++) { if (i == proc_id) continue; close(pipe_parent2relay[i][0]); close(pipe_parent2relay[i][1]); close(pipe_pfe2relay[i][0]); close(pipe_pfe2relay[i][1]); } close(pipe_parent2relay[proc_id][1]); close(pipe_pfe2relay[proc_id][1]); if ((ibuf_pfe = calloc(1, sizeof(struct imsgbuf))) == NULL || (ibuf_main = calloc(1, sizeof(struct imsgbuf))) == NULL) fatal("relay"); imsg_init(ibuf_main, pipe_parent2relay[proc_id][0], relay_dispatch_parent); imsg_init(ibuf_pfe, pipe_pfe2relay[proc_id][0], relay_dispatch_pfe); ibuf_pfe->events = EV_READ; event_set(&ibuf_pfe->ev, ibuf_pfe->fd, ibuf_pfe->events, ibuf_pfe->handler, ibuf_pfe); event_add(&ibuf_pfe->ev, NULL); ibuf_main->events = EV_READ; event_set(&ibuf_main->ev, ibuf_main->fd, ibuf_main->events, ibuf_main->handler, ibuf_main); event_add(&ibuf_main->ev, NULL); relay_launch(); event_dispatch(); relay_shutdown(); return (0); } void relay_shutdown(void) { struct session *con; struct relay *rlay; TAILQ_FOREACH(rlay, &env->relays, entry) { if (rlay->conf.flags & F_DISABLE) continue; close(rlay->s); while ((con = TAILQ_FIRST(&rlay->sessions)) != NULL) relay_close(con, "shutdown"); } usleep(200); /* XXX relay needs to shutdown last */ log_info("socket relay engine exiting"); _exit(0); } void relay_protodebug(struct relay *rlay) { struct protocol *proto = rlay->proto; struct protonode *pn; struct proto_tree *tree; const char *name; fprintf(stderr, "protocol %d: name %s\n", proto->id, proto->name); fprintf(stderr, "\tflags: 0x%04x\n", proto->flags); if (proto->cache != -1) fprintf(stderr, "\tssl session cache: %d\n", proto->cache); fprintf(stderr, "\ttype: "); switch (proto->type) { case RELAY_PROTO_TCP: fprintf(stderr, "tcp\n"); break; case RELAY_PROTO_HTTP: fprintf(stderr, "http\n"); break; } name = "request"; tree = &proto->request_tree; show: RB_FOREACH(pn, proto_tree, tree) { fprintf(stderr, "\t\t"); fprintf(stderr, "%s ", name); switch (pn->type) { case NODE_TYPE_HEADER: break; case NODE_TYPE_URL: fprintf(stderr, "url "); break; case NODE_TYPE_COOKIE: fprintf(stderr, "cookie "); break; case NODE_TYPE_PATH: fprintf(stderr, "path "); break; } switch (pn->action) { case NODE_ACTION_APPEND: fprintf(stderr, "append \"%s\" to \"%s\"", pn->value, pn->key); break; case NODE_ACTION_CHANGE: fprintf(stderr, "change \"%s\" to \"%s\"", pn->key, pn->value); break; case NODE_ACTION_REMOVE: fprintf(stderr, "remove \"%s\"", pn->key); break; case NODE_ACTION_EXPECT: fprintf(stderr, "expect \"%s\" from \"%s\"", pn->value, pn->key); break; case NODE_ACTION_FILTER: fprintf(stderr, "filter \"%s\" from \"%s\"", pn->value, pn->key); break; case NODE_ACTION_HASH: fprintf(stderr, "hash \"%s\"", pn->key); break; case NODE_ACTION_LOG: fprintf(stderr, "log \"%s\"", pn->key); break; case NODE_ACTION_NONE: fprintf(stderr, "none \"%s\"", pn->key); break; } fprintf(stderr, "\n"); } if (tree == &proto->request_tree) { name = "response"; tree = &proto->response_tree; goto show; } } void relay_privinit(void) { struct relay *rlay; extern int debug; if (env->flags & F_SSL) ssl_init(env); TAILQ_FOREACH(rlay, &env->relays, entry) { log_debug("relay_init: adding relay %s", rlay->conf.name); if (debug) relay_protodebug(rlay); if ((rlay->conf.flags & F_SSL) && (rlay->ctx = relay_ssl_ctx_create(rlay)) == NULL) fatal("relay_launch: failed to create SSL context"); if ((rlay->s = relay_socket_listen(&rlay->conf.ss, rlay->conf.port, rlay->proto)) == -1) fatal("relay_launch: failed to listen"); } } void relay_init(void) { struct relay *rlay; struct host *host; struct timeval tv; TAILQ_FOREACH(rlay, &env->relays, entry) { if (rlay->dsttable != NULL) { switch (rlay->conf.dstmode) { case RELAY_DSTMODE_ROUNDROBIN: rlay->dstkey = 0; break; case RELAY_DSTMODE_LOADBALANCE: case RELAY_DSTMODE_HASH: rlay->dstkey = hash32_str(rlay->conf.name, HASHINIT); rlay->dstkey = hash32_str(rlay->dsttable->conf.name, rlay->dstkey); break; } rlay->dstnhosts = 0; TAILQ_FOREACH(host, &rlay->dsttable->hosts, entry) { if (rlay->dstnhosts >= RELAY_MAXHOSTS) fatal("relay_init: " "too many hosts in table"); rlay->dsthost[rlay->dstnhosts++] = host; } log_info("adding %d hosts from table %s%s", rlay->dstnhosts, rlay->dsttable->conf.name, rlay->conf.dstcheck ? "" : " (no check)"); } } /* Schedule statistics timer */ evtimer_set(&env->statev, relay_statistics, NULL); bcopy(&env->statinterval, &tv, sizeof(tv)); evtimer_add(&env->statev, &tv); } void relay_statistics(int fd, short events, void *arg) { struct relay *rlay; struct ctl_stats crs, *cur; struct timeval tv, tv_now; int resethour = 0, resetday = 0; struct session *con, *next_con; /* * This is a hack to calculate some average statistics. * It doesn't try to be very accurate, but could be improved... */ timerclear(&tv); if (gettimeofday(&tv_now, NULL)) fatal("relay_init: gettimeofday"); TAILQ_FOREACH(rlay, &env->relays, entry) { bzero(&crs, sizeof(crs)); resethour = resetday = 0; cur = &rlay->stats[proc_id]; cur->cnt += cur->last; cur->tick++; cur->avg = (cur->last + cur->avg) / 2; cur->last_hour += cur->last; if ((cur->tick % (3600 / env->statinterval.tv_sec)) == 0) { cur->avg_hour = (cur->last_hour + cur->avg_hour) / 2; resethour++; } cur->last_day += cur->last; if ((cur->tick % (86400 / env->statinterval.tv_sec)) == 0) { cur->avg_day = (cur->last_day + cur->avg_day) / 2; resethour++; } bcopy(cur, &crs, sizeof(crs)); cur->last = 0; if (resethour) cur->last_hour = 0; if (resetday) cur->last_day = 0; crs.id = rlay->conf.id; crs.proc = proc_id; imsg_compose(ibuf_pfe, IMSG_STATISTICS, 0, 0, &crs, sizeof(crs)); for (con = TAILQ_FIRST(&rlay->sessions); con != NULL; con = next_con) { next_con = TAILQ_NEXT(con, entry); timersub(&tv_now, &con->tv_last, &tv); if (timercmp(&tv, &rlay->conf.timeout, >=)) relay_close(con, "hard timeout"); } } /* Schedule statistics timer */ evtimer_set(&env->statev, relay_statistics, NULL); bcopy(&env->statinterval, &tv, sizeof(tv)); evtimer_add(&env->statev, &tv); } void relay_launch(void) { struct relay *rlay; TAILQ_FOREACH(rlay, &env->relays, entry) { log_debug("relay_launch: running relay %s", rlay->conf.name); rlay->up = HOST_UP; event_set(&rlay->ev, rlay->s, EV_READ|EV_PERSIST, relay_accept, rlay); event_add(&rlay->ev, NULL); } } int relay_socket(struct sockaddr_storage *ss, in_port_t port, struct protocol *proto) { int s = -1, val; struct linger lng; switch (ss->ss_family) { case AF_INET: ((struct sockaddr_in *)ss)->sin_port = port; ((struct sockaddr_in *)ss)->sin_len = sizeof(struct sockaddr_in); break; case AF_INET6: ((struct sockaddr_in6 *)ss)->sin6_port = port; ((struct sockaddr_in6 *)ss)->sin6_len = sizeof(struct sockaddr_in6); break; } if ((s = socket(ss->ss_family, SOCK_STREAM, IPPROTO_TCP)) == -1) goto bad; /* * Socket options */ bzero(&lng, sizeof(lng)); if (setsockopt(s, SOL_SOCKET, SO_LINGER, &lng, sizeof(lng)) == -1) goto bad; val = 1; if (setsockopt(s, SOL_SOCKET, SO_REUSEPORT, &val, sizeof(int)) == -1) goto bad; if (fcntl(s, F_SETFL, O_NONBLOCK) == -1) goto bad; if (proto->tcpflags & TCPFLAG_BUFSIZ) { val = proto->tcpbufsiz; if (setsockopt(s, SOL_SOCKET, SO_RCVBUF, &val, sizeof(val)) == -1) goto bad; val = proto->tcpbufsiz; if (setsockopt(s, SOL_SOCKET, SO_SNDBUF, &val, sizeof(val)) == -1) goto bad; } /* * IP options */ if (proto->tcpflags & TCPFLAG_IPTTL) { val = (int)proto->tcpipttl; if (setsockopt(s, IPPROTO_IP, IP_TTL, &val, sizeof(val)) == -1) goto bad; } if (proto->tcpflags & TCPFLAG_IPMINTTL) { val = (int)proto->tcpipminttl; if (setsockopt(s, IPPROTO_IP, IP_MINTTL, &val, sizeof(val)) == -1) goto bad; } /* * TCP options */ if (proto->tcpflags & (TCPFLAG_NODELAY|TCPFLAG_NNODELAY)) { if (proto->tcpflags & TCPFLAG_NNODELAY) val = 0; else val = 1; if (setsockopt(s, IPPROTO_TCP, TCP_NODELAY, &val, sizeof(val)) == -1) goto bad; } if (proto->tcpflags & (TCPFLAG_SACK|TCPFLAG_NSACK)) { if (proto->tcpflags & TCPFLAG_NSACK) val = 0; else val = 1; if (setsockopt(s, IPPROTO_TCP, TCP_SACK_ENABLE, &val, sizeof(val)) == -1) goto bad; } return (s); bad: if (s != -1) close(s); return (-1); } int relay_socket_connect(struct sockaddr_storage *ss, in_port_t port, struct protocol *proto) { int s; if ((s = relay_socket(ss, port, proto)) == -1) return (-1); if (connect(s, (struct sockaddr *)ss, ss->ss_len) == -1) { if (errno != EINPROGRESS) goto bad; } return (s); bad: close(s); return (-1); } int relay_socket_listen(struct sockaddr_storage *ss, in_port_t port, struct protocol *proto) { int s; if ((s = relay_socket(ss, port, proto)) == -1) return (-1); if (bind(s, (struct sockaddr *)ss, ss->ss_len) == -1) goto bad; if (listen(s, proto->tcpbacklog) == -1) goto bad; return (s); bad: close(s); return (-1); } void relay_connected(int fd, short sig, void *arg) { struct session *con = (struct session *)arg; struct relay *rlay = (struct relay *)con->relay; struct protocol *proto = rlay->proto; evbuffercb outrd = relay_read; evbuffercb outwr = relay_write; struct bufferevent *bev; if (sig == EV_TIMEOUT) { relay_close(con, "connect timeout"); return; } DPRINTF("relay_connected: session %d: %ssuccessful", con->id, rlay->proto->lateconnect ? "late connect " : ""); switch (rlay->proto->type) { case RELAY_PROTO_HTTP: /* Check the servers's HTTP response */ if (!RB_EMPTY(&rlay->proto->response_tree)) { outrd = relay_read_http; if ((con->out.nodes = calloc(proto->response_nodes, sizeof(u_int8_t))) == NULL) { relay_close(con, "failed to allocate nodes"); return; } } break; case RELAY_PROTO_TCP: /* Use defaults */ break; default: fatalx("relay_input: unknown protocol"); } /* * Relay <-> Server */ bev = bufferevent_new(fd, outrd, outwr, relay_error, &con->out); if (bev == NULL) { relay_close(con, "failed to allocate output buffer event"); return; } evbuffer_free(bev->output); bev->output = con->out.output; if (bev->output == NULL) fatal("relay_connected: invalid output buffer"); con->out.bev = bev; bufferevent_settimeout(bev, rlay->conf.timeout.tv_sec, rlay->conf.timeout.tv_sec); bufferevent_enable(bev, EV_READ|EV_WRITE); } void relay_input(struct session *con) { struct relay *rlay = (struct relay *)con->relay; struct protocol *proto = rlay->proto; evbuffercb inrd = relay_read; evbuffercb inwr = relay_write; switch (rlay->proto->type) { case RELAY_PROTO_HTTP: /* Check the client's HTTP request */ if (!RB_EMPTY(&rlay->proto->request_tree) || proto->lateconnect) { inrd = relay_read_http; if ((con->in.nodes = calloc(proto->request_nodes, sizeof(u_int8_t))) == NULL) { relay_close(con, "failed to allocate nodes"); return; } } break; case RELAY_PROTO_TCP: /* Use defaults */ break; default: fatalx("relay_input: unknown protocol"); } /* * Client <-> Relay */ con->in.bev = bufferevent_new(con->in.s, inrd, inwr, relay_error, &con->in); if (con->in.bev == NULL) { relay_close(con, "failed to allocate input buffer event"); return; } /* Initialize the SSL wrapper */ if ((rlay->conf.flags & F_SSL) && con->in.ssl != NULL) relay_ssl_connected(&con->in); bufferevent_settimeout(con->in.bev, rlay->conf.timeout.tv_sec, rlay->conf.timeout.tv_sec); bufferevent_enable(con->in.bev, EV_READ|EV_WRITE); } void relay_write(struct bufferevent *bev, void *arg) { struct ctl_relay_event *cre = (struct ctl_relay_event *)arg; struct session *con = (struct session *)cre->con; if (gettimeofday(&con->tv_last, NULL)) con->done = 1; if (con->done) relay_close(con, "last write (done)"); } void relay_read(struct bufferevent *bev, void *arg) { struct ctl_relay_event *cre = (struct ctl_relay_event *)arg; struct session *con = (struct session *)cre->con; struct evbuffer *src = EVBUFFER_INPUT(bev); if (gettimeofday(&con->tv_last, NULL)) goto done; if (!EVBUFFER_LENGTH(src)) return; if (relay_bufferevent_write_buffer(cre->dst, src) == -1) goto fail; if (con->done) goto done; bufferevent_enable(con->in.bev, EV_READ); return; done: relay_close(con, "last read (done)"); return; fail: relay_close(con, strerror(errno)); } char * relay_expand_http(struct ctl_relay_event *cre, char *val, char *buf, size_t len) { struct session *con = (struct session *)cre->con; struct relay *rlay = (struct relay *)con->relay; char ibuf[128]; (void)strlcpy(buf, val, len); if (strstr(val, "$REMOTE_") != NULL) { if (strstr(val, "$REMOTE_ADDR") != NULL) { if (relay_host(&cre->ss, ibuf, sizeof(ibuf)) == NULL) return (NULL); if (expand_string(buf, len, "$REMOTE_ADDR", ibuf) != 0) return (NULL); } if (strstr(val, "$REMOTE_PORT") != NULL) { snprintf(ibuf, sizeof(ibuf), "%u", ntohs(cre->port)); if (expand_string(buf, len, "$REMOTE_PORT", ibuf) != 0) return (NULL); } } if (strstr(val, "$SERVER_") != NULL) { if (strstr(val, "$SERVER_ADDR") != NULL) { if (relay_host(&rlay->conf.ss, ibuf, sizeof(ibuf)) == NULL) return (NULL); if (expand_string(buf, len, "$SERVER_ADDR", ibuf) != 0) return (NULL); } if (strstr(val, "$SERVER_PORT") != NULL) { snprintf(ibuf, sizeof(ibuf), "%u", ntohs(rlay->conf.port)); if (expand_string(buf, len, "$SERVER_PORT", ibuf) != 0) return (NULL); } } if (strstr(val, "$TIMEOUT") != NULL) { snprintf(ibuf, sizeof(ibuf), "%lu", rlay->conf.timeout.tv_sec); if (expand_string(buf, len, "$TIMEOUT", ibuf) != 0) return (NULL); } return (buf); } int relay_handle_http(struct ctl_relay_event *cre, struct protonode *pn, struct protonode *pk, int header) { struct session *con = (struct session *)cre->con; char buf[READ_BUF_SIZE], *ptr; int ret = PN_DROP; switch (pn->action) { case NODE_ACTION_APPEND: if (!header || ((pn->flags & PNFLAG_MARK) && cre->marked == 0)) return (PN_PASS); ptr = pn->value; if ((pn->flags & PNFLAG_MACRO) && (ptr = relay_expand_http(cre, pn->value, buf, sizeof(buf))) == NULL) break; if (relay_bufferevent_print(cre->dst, pn->key) == -1 || relay_bufferevent_print(cre->dst, ": ") == -1 || relay_bufferevent_print(cre->dst, pk->value) == -1 || relay_bufferevent_print(cre->dst, ", ") == -1 || relay_bufferevent_print(cre->dst, ptr) == -1 || relay_bufferevent_print(cre->dst, "\r\n") == -1) goto fail; cre->nodes[pn->id] = 1; DPRINTF("relay_handle_http: append '%s: %s, %s'", pk->key, pk->value, ptr); break; case NODE_ACTION_CHANGE: case NODE_ACTION_REMOVE: if (!header || ((pn->flags & PNFLAG_MARK) && cre->marked == 0)) return (PN_PASS); DPRINTF("relay_handle_http: change/remove '%s: %s'", pk->key, pk->value); break; case NODE_ACTION_EXPECT: DPRINTF("relay_handle_http: expect '%s: %s'", pn->key, pn->value); if (fnmatch(pn->value, pk->value, FNM_CASEFOLD) == 0) { if (pn->flags & PNFLAG_MARK) cre->marked++; cre->nodes[pn->id] = 1; } ret = PN_PASS; break; case NODE_ACTION_FILTER: DPRINTF("relay_handle_http: filter '%s: %s'", pn->key, pn->value); if (fnmatch(pn->value, pk->value, FNM_CASEFOLD) == 0) { if (pn->flags & PNFLAG_MARK) cre->marked++; cre->nodes[pn->id] = 1; } break; case NODE_ACTION_HASH: if ((pn->flags & PNFLAG_MARK) && cre->marked == 0) return (PN_PASS); DPRINTF("relay_handle_http: hash '%s: %s'", pn->key, pk->value); con->outkey = hash32_str(pk->value, con->outkey); ret = PN_PASS; break; case NODE_ACTION_LOG: if ((pn->flags & PNFLAG_MARK) && cre->marked == 0) return (PN_PASS); DPRINTF("relay_handle_http: log '%s: %s'", pn->key, pk->value); ret = PN_PASS; break; case NODE_ACTION_NONE: return (PN_PASS); } if (pn->flags & PNFLAG_LOG) { bzero(buf, sizeof(buf)); if (snprintf(buf, sizeof(buf), " [%s: %s]", pk->key, pk->value) == -1 || evbuffer_add(con->log, buf, strlen(buf)) == -1) goto fail; } return (ret); fail: relay_close(con, strerror(errno)); return (PN_FAIL); } void relay_read_httpcontent(struct bufferevent *bev, void *arg) { struct ctl_relay_event *cre = (struct ctl_relay_event *)arg; struct session *con = (struct session *)cre->con; struct evbuffer *src = EVBUFFER_INPUT(bev); size_t size; if (gettimeofday(&con->tv_last, NULL)) goto done; size = EVBUFFER_LENGTH(src); DPRINTF("relay_read_httpcontent: size %d, to read %d", size, cre->toread); if (!size) return; if (relay_bufferevent_write_buffer(cre->dst, src) == -1) goto fail; if (size >= cre->toread) bev->readcb = relay_read_http; cre->toread -= size; DPRINTF("relay_read_httpcontent: done, size %d, to read %d", size, cre->toread); if (con->done) goto done; if (EVBUFFER_LENGTH(src) && bev->readcb != relay_read_httpcontent) bev->readcb(bev, arg); bufferevent_enable(bev, EV_READ); return; done: relay_close(con, "last http content read (done)"); return; fail: relay_close(con, strerror(errno)); } void relay_read_httpchunks(struct bufferevent *bev, void *arg) { struct ctl_relay_event *cre = (struct ctl_relay_event *)arg; struct session *con = (struct session *)cre->con; struct evbuffer *src = EVBUFFER_INPUT(bev); char *line, *ep; long lval; size_t size; if (gettimeofday(&con->tv_last, NULL)) goto done; size = EVBUFFER_LENGTH(src); DPRINTF("relay_read_httpchunks: size %d, to read %d", size, cre->toread); if (!size) return; if (!cre->toread) { line = evbuffer_readline(src); if (line == NULL) { relay_close(con, "invalid chunk"); return; } /* Read prepended chunk size in hex */ errno = 0; lval = strtol(line, &ep, 16); if (line[0] == '\0' || *ep != '\0') { free(line); relay_close(con, "invalid chunk size"); return; } if (errno == ERANGE && (lval == LONG_MAX || lval == LONG_MIN)) { free(line); relay_close(con, "chunk size out of range"); return; } if (relay_bufferevent_print(cre->dst, line) == -1 || relay_bufferevent_print(cre->dst, "\r\n") == -1) goto fail; free(line); /* Last chunk is 0 bytes followed by an empty newline */ if ((cre->toread = lval) == 0) { line = evbuffer_readline(src); if (line == NULL) { relay_close(con, "invalid chunk"); return; } free(line); if (relay_bufferevent_print(cre->dst, "\r\n") == -1) goto fail; /* Switch to HTTP header mode */ bev->readcb = relay_read_http; } } else { /* Read chunk data */ if (size > cre->toread) size = cre->toread; if (relay_bufferevent_write_chunk(cre->dst, src, size) == -1) goto fail; cre->toread -= size; DPRINTF("relay_read_httpchunks: done, size %d, to read %d", size, cre->toread); if (cre->toread == 0) { /* Chunk is terminated by an empty newline */ line = evbuffer_readline(src); if (line == NULL || strlen(line)) { if (line != NULL) free(line); relay_close(con, "invalid chunk"); return; } free(line); if (relay_bufferevent_print(cre->dst, "\r\n\r\n") == -1) goto fail; } } if (con->done) goto done; if (EVBUFFER_LENGTH(src) && bev->readcb != relay_read_httpchunks) bev->readcb(bev, arg); bufferevent_enable(bev, EV_READ); return; done: relay_close(con, "last http chunk read (done)"); return; fail: relay_close(con, strerror(errno)); } void relay_read_http(struct bufferevent *bev, void *arg) { struct ctl_relay_event *cre = (struct ctl_relay_event *)arg; struct session *con = (struct session *)cre->con; struct relay *rlay = (struct relay *)con->relay; struct protocol *proto = rlay->proto; struct evbuffer *src = EVBUFFER_INPUT(bev); struct protonode *pn, pk, *pnv, pkv; char *line, buf[READ_BUF_SIZE], *ptr, *val; int header = 0, ret; const char *errstr; size_t size; if (gettimeofday(&con->tv_last, NULL)) goto done; size = EVBUFFER_LENGTH(src); DPRINTF("relay_read_http: size %d, to read %d", size, cre->toread); if (!size) return; pk.type = NODE_TYPE_HEADER; while (!cre->done && (line = evbuffer_readline(src)) != NULL) { /* * An empty line indicates the end of the request. * libevent already stripped the \r\n for us. */ if (!strlen(line)) { cre->done = 1; free(line); break; } pk.key = line; /* * The first line is the GET/POST/PUT/... request, * subsequent lines are HTTP headers. */ if (++cre->line == 1) { pk.value = strchr(pk.key, ' '); } else pk.value = strchr(pk.key, ':'); if (pk.value == NULL || strlen(pk.value) < 3) { DPRINTF("relay_read_http: request '%s'", line); /* Append line to the output buffer */ if (relay_bufferevent_print(cre->dst, line) == -1 || relay_bufferevent_print(cre->dst, "\r\n") == -1) { free(line); goto fail; } free(line); continue; } if (*pk.value == ':') { *pk.value++ = '\0'; pk.value++; header = 1; } else { *pk.value++ = '\0'; header = 0; } DPRINTF("relay_read_http: header '%s: %s'", pk.key, pk.value); /* * Identify and handle specific HTTP request methods */ if (cre->line == 1) { if (cre->dir == RELAY_DIR_RESPONSE) { cre->method = HTTP_METHOD_RESPONSE; goto lookup; } else if (strcmp("GET", pk.key) == 0) cre->method = HTTP_METHOD_GET; else if (strcmp("HEAD", pk.key) == 0) cre->method = HTTP_METHOD_HEAD; else if (strcmp("POST", pk.key) == 0) cre->method = HTTP_METHOD_POST; else if (strcmp("PUT", pk.key) == 0) cre->method = HTTP_METHOD_PUT; else if (strcmp("DELETE", pk.key) == 0) cre->method = HTTP_METHOD_DELETE; else if (strcmp("OPTIONS", pk.key) == 0) cre->method = HTTP_METHOD_OPTIONS; else if (strcmp("TRACE", pk.key) == 0) cre->method = HTTP_METHOD_TRACE; else if (strcmp("CONNECT", pk.key) == 0) cre->method = HTTP_METHOD_CONNECT; /* * Decode the URL */ cre->path = strdup(pk.value); if (cre->path == NULL) { free(line); goto fail; } cre->version = strchr(cre->path, ' '); if (cre->version != NULL) *cre->version++ = '\0'; cre->args = strchr(cre->path, '?'); if (cre->args != NULL) *cre->args++ = '\0'; #ifdef DEBUG if (snprintf(buf, sizeof(buf), " \"%s\"", cre->path) == -1 || evbuffer_add(con->log, buf, strlen(buf)) == -1) { free(line); goto fail; } #endif /* * Lookup protocol handlers in the URL path */ if ((proto->flags & F_LOOKUP_PATH) == 0) goto lookup; pkv.key = cre->path; pkv.type = NODE_TYPE_PATH; pkv.value = cre->args == NULL ? "" : cre->args; DPRINTF("relay_read_http: " "lookup path '%s: %s'", pkv.key, pkv.value); if ((pnv = RB_FIND(proto_tree, cre->tree, &pkv)) == NULL) goto lookup; ret = relay_handle_http(cre, pnv, &pkv, 0); if (ret == PN_FAIL) { free(line); goto fail; } } else if ((cre->method == HTTP_METHOD_POST || cre->method == HTTP_METHOD_PUT || cre->method == HTTP_METHOD_RESPONSE) && strcasecmp("Content-Length", pk.key) == 0) { /* * Need to read data from the client after the * HTTP header. * XXX What about non-standard clients not using * the carriage return? And some browsers seem to * include the line length in the content-length. */ cre->toread = strtonum(pk.value, 1, INT_MAX, &errstr); if (errstr) { relay_close(con, errstr); free(line); return; } } lookup: if (strcasecmp("Transfer-Encoding", pk.key) == 0 && strcasecmp("chunked", pk.value) == 0) cre->chunked = 1; /* Match the HTTP header */ if ((pn = RB_FIND(proto_tree, cre->tree, &pk)) == NULL) goto next; if (cre->dir == RELAY_DIR_RESPONSE) goto handle; if (pn->flags & PNFLAG_LOOKUP_URL) { if (cre->path == NULL || cre->args == NULL || strlen(cre->args) < 2 || (val = strdup(cre->args)) == NULL) goto next; ptr = val; while (ptr != NULL && strlen(ptr)) { pkv.key = ptr; pkv.type = NODE_TYPE_URL; if ((ptr = strchr(ptr, '&')) != NULL) *ptr++ = '\0'; if ((pkv.value = strchr(pkv.key, '=')) == NULL || strlen(pkv.value) < 1) continue; *pkv.value++ = '\0'; if ((pnv = RB_FIND(proto_tree, cre->tree, &pkv)) == NULL) continue; ret = relay_handle_http(cre, pnv, &pkv, 0); if (ret == PN_PASS) continue; else if (ret == PN_FAIL) { free(val); free(line); return; } } free(val); } else if (pn->flags & PNFLAG_LOOKUP_COOKIE) { /* * Decode the HTTP cookies */ val = strdup(pk.value); if (val == NULL) goto next; for (ptr = val; ptr != NULL && strlen(ptr);) { if (*ptr == ' ') *ptr++ = '\0'; pkv.key = ptr; pkv.type = NODE_TYPE_COOKIE; if ((ptr = strchr(ptr, ';')) != NULL) *ptr++ = '\0'; /* * XXX We do not handle attributes * ($Path, $Domain, or $Port) */ if (*pkv.key == '$') continue; if ((pkv.value = strchr(pkv.key, '=')) == NULL || strlen(pkv.value) < 1) continue; *pkv.value++ = '\0'; if (*pkv.value == '"') *pkv.value++ = '\0'; if (pkv.value[strlen(pkv.value) - 1] == '"') pkv.value[strlen(pkv.value) - 1] = '\0'; if ((pnv = RB_FIND(proto_tree, cre->tree, &pkv)) == NULL) continue; ret = relay_handle_http(cre, pnv, &pkv, 0); if (ret == PN_PASS) continue; else if (ret == PN_FAIL) { free(val); free(line); return; } } free(val); } handle: ret = relay_handle_http(cre, pn, &pk, header); if (ret == PN_PASS) goto next; free(line); if (ret == PN_FAIL) return; continue; next: if (relay_bufferevent_print(cre->dst, pk.key) == -1 || relay_bufferevent_print(cre->dst, header ? ": " : " ") == -1 || relay_bufferevent_print(cre->dst, pk.value) == -1 || relay_bufferevent_print(cre->dst, "\r\n") == -1) { free(line); goto fail; } free(line); continue; } if (cre->done) { RB_FOREACH(pn, proto_tree, cre->tree) { switch (pn->action) { case NODE_ACTION_FILTER: if (!cre->nodes[pn->id]) continue; cre->nodes[pn->id] = 0; break; default: if (cre->nodes[pn->id]) { cre->nodes[pn->id] = 0; continue; } break; } switch (pn->action) { case NODE_ACTION_APPEND: case NODE_ACTION_CHANGE: ptr = pn->value; if ((pn->flags & PNFLAG_MARK) && cre->marked == 0) break; if ((pn->flags & PNFLAG_MACRO) && (ptr = relay_expand_http(cre, pn->value, buf, sizeof(buf))) == NULL) break; if (relay_bufferevent_print(cre->dst, pn->key) == -1 || relay_bufferevent_print(cre->dst, ": ") == -1 || relay_bufferevent_print(cre->dst, ptr) == -1 || relay_bufferevent_print(cre->dst, "\r\n") == -1) goto fail; DPRINTF("relay_read_http: add '%s: %s'", pn->key, ptr); break; case NODE_ACTION_EXPECT: if (pn->flags & PNFLAG_MARK) break; DPRINTF("relay_read_http: missing '%s: %s'", pn->key, pn->value); relay_close(con, "incomplete header (done)"); return; case NODE_ACTION_FILTER: if (pn->flags & PNFLAG_MARK) break; DPRINTF("relay_read_http: filtered '%s: %s'", pn->key, pn->value); relay_close(con, "rejecting header (done)"); return; default: break; } } switch (cre->method) { case HTTP_METHOD_CONNECT: /* Data stream */ bev->readcb = relay_read; break; case HTTP_METHOD_POST: case HTTP_METHOD_PUT: case HTTP_METHOD_RESPONSE: /* HTTP request payload */ if (cre->toread) { bev->readcb = relay_read_httpcontent; break; } /* FALLTHROUGH */ default: /* HTTP handler */ bev->readcb = relay_read_http; break; } if (cre->chunked) { /* Chunked transfer encoding */ cre->toread = 0; bev->readcb = relay_read_httpchunks; } /* Write empty newline and switch to relay mode */ if (relay_bufferevent_print(cre->dst, "\r\n") == -1) goto fail; cre->line = 0; cre->method = 0; cre->marked = 0; cre->done = 0; cre->chunked = 0; if (cre->dir == RELAY_DIR_REQUEST && proto->lateconnect && cre->dst->bev == NULL && relay_connect(con) == -1) { relay_close(con, "session failed"); return; } } if (con->done) goto done; if (EVBUFFER_LENGTH(src) && bev->readcb != relay_read_http) bev->readcb(bev, arg); bufferevent_enable(bev, EV_READ); return; done: relay_close(con, "last http read (done)"); return; fail: relay_close(con, strerror(errno)); } void relay_error(struct bufferevent *bev, short error, void *arg) { struct ctl_relay_event *cre = (struct ctl_relay_event *)arg; struct session *con = (struct session *)cre->con; struct evbuffer *dst; if (error & EVBUFFER_TIMEOUT) { relay_close(con, "buffer event timeout"); return; } if (error & (EVBUFFER_READ|EVBUFFER_WRITE|EVBUFFER_EOF)) { bufferevent_disable(bev, EV_READ|EV_WRITE); con->done = 1; if (cre->dst->bev != NULL) { dst = EVBUFFER_OUTPUT(cre->dst->bev); if (EVBUFFER_LENGTH(dst)) return; } relay_close(con, "done"); return; } relay_close(con, "buffer event error"); } const char * relay_host(struct sockaddr_storage *ss, char *buf, size_t len) { int af = ss->ss_family; void *ptr; bzero(buf, len); if (af == AF_INET) ptr = &((struct sockaddr_in *)ss)->sin_addr; else ptr = &((struct sockaddr_in6 *)ss)->sin6_addr; return (inet_ntop(af, ptr, buf, len)); } void relay_accept(int fd, short sig, void *arg) { struct relay *rlay = (struct relay *)arg; struct protocol *proto = rlay->proto; struct session *con = NULL; struct ctl_natlook *cnl = NULL; socklen_t slen; struct timeval tv; struct sockaddr_storage ss; int s = -1; slen = sizeof(ss); if ((s = accept(fd, (struct sockaddr *)&ss, (socklen_t *)&slen)) == -1) return; if (relay_sessions >= RELAY_MAX_SESSIONS || rlay->conf.flags & F_DISABLE) goto err; if ((con = (struct session *) calloc(1, sizeof(struct session))) == NULL) goto err; con->in.s = s; con->in.ssl = NULL; con->out.s = -1; con->out.ssl = NULL; con->in.dst = &con->out; con->out.dst = &con->in; con->in.con = con; con->out.con = con; con->relay = rlay; con->id = ++relay_conid; con->outkey = rlay->dstkey; con->in.tree = &proto->request_tree; con->out.tree = &proto->response_tree; con->in.dir = RELAY_DIR_REQUEST; con->out.dir = RELAY_DIR_RESPONSE; con->retry = rlay->conf.dstretry; if (gettimeofday(&con->tv_start, NULL)) goto err; bcopy(&con->tv_start, &con->tv_last, sizeof(con->tv_last)); bcopy(&ss, &con->in.ss, sizeof(con->in.ss)); /* Pre-allocate output buffer */ con->out.output = evbuffer_new(); if (con->out.output == NULL) { relay_close(con, "failed to allocate output buffer"); return; } /* Pre-allocate log buffer */ con->log = evbuffer_new(); if (con->log == NULL) { relay_close(con, "failed to allocate log buffer"); return; } if (rlay->conf.flags & F_NATLOOK) { if ((cnl = (struct ctl_natlook *) calloc(1, sizeof(struct ctl_natlook))) == NULL) goto err; } relay_sessions++; TAILQ_INSERT_HEAD(&rlay->sessions, con, entry); /* Increment the per-relay session counter */ rlay->stats[proc_id].last++; if (rlay->conf.flags & F_NATLOOK && cnl != NULL) { con->cnl = cnl;; bzero(cnl, sizeof(*cnl)); cnl->in = -1; cnl->id = con->id; cnl->proc = proc_id; bcopy(&con->in.ss, &cnl->src, sizeof(cnl->src)); bcopy(&rlay->conf.ss, &cnl->dst, sizeof(cnl->dst)); imsg_compose(ibuf_pfe, IMSG_NATLOOK, 0, 0, cnl, sizeof(*cnl)); /* Schedule timeout */ evtimer_set(&con->ev, relay_natlook, con); bcopy(&rlay->conf.timeout, &tv, sizeof(tv)); evtimer_add(&con->ev, &tv); return; } relay_session(con); return; err: if (s != -1) { close(s); if (con != NULL) free(con); } } u_int32_t relay_hash_addr(struct sockaddr_storage *ss, u_int32_t p) { struct sockaddr_in *sin4; struct sockaddr_in6 *sin6; if (ss->ss_family == AF_INET) { sin4 = (struct sockaddr_in *)ss; p = hash32_buf(&sin4->sin_addr, sizeof(struct in_addr), p); } else { sin6 = (struct sockaddr_in6 *)ss; p = hash32_buf(&sin6->sin6_addr, sizeof(struct in6_addr), p); } return (p); } int relay_from_table(struct session *con) { struct relay *rlay = (struct relay *)con->relay; struct host *host; struct table *table = rlay->dsttable; u_int32_t p = con->outkey; int idx = 0; if (rlay->conf.dstcheck && !table->up) { log_debug("relay_from_table: no active hosts"); return (-1); } switch (rlay->conf.dstmode) { case RELAY_DSTMODE_ROUNDROBIN: if ((int)rlay->dstkey >= rlay->dstnhosts) rlay->dstkey = 0; idx = (int)rlay->dstkey++; break; case RELAY_DSTMODE_LOADBALANCE: p = relay_hash_addr(&con->in.ss, p); /* FALLTHROUGH */ case RELAY_DSTMODE_HASH: p = relay_hash_addr(&rlay->conf.ss, p); p = hash32_buf(&rlay->conf.port, sizeof(rlay->conf.port), p); if ((idx = p % rlay->dstnhosts) >= RELAY_MAXHOSTS) return (-1); } host = rlay->dsthost[idx]; DPRINTF("relay_from_table: host %s, p 0x%08x, idx %d", host->conf.name, p, idx); while (host != NULL) { DPRINTF("relay_from_table: host %s", host->conf.name); if (!rlay->conf.dstcheck || host->up == HOST_UP) goto found; host = TAILQ_NEXT(host, entry); } TAILQ_FOREACH(host, &rlay->dsttable->hosts, entry) { DPRINTF("relay_from_table: next host %s", host->conf.name); if (!rlay->conf.dstcheck || host->up == HOST_UP) goto found; } /* Should not happen */ fatalx("relay_from_table: no active hosts, desynchronized"); found: con->retry = host->conf.retry; con->out.port = table->conf.port; bcopy(&host->conf.ss, &con->out.ss, sizeof(con->out.ss)); return (0); } void relay_natlook(int fd, short event, void *arg) { struct session *con = (struct session *)arg; struct relay *rlay = (struct relay *)con->relay; struct ctl_natlook *cnl = con->cnl; if (cnl == NULL) fatalx("invalid NAT lookup"); if (con->out.ss.ss_family == AF_UNSPEC && cnl->in == -1 && rlay->conf.dstss.ss_family == AF_UNSPEC && rlay->dsttable == NULL) { relay_close(con, "session NAT lookup failed"); return; } if (cnl->in != -1) { bcopy(&cnl->rdst, &con->out.ss, sizeof(con->out.ss)); con->out.port = cnl->rdport; } free(con->cnl); con->cnl = NULL; relay_session(con); } void relay_session(struct session *con) { struct relay *rlay = (struct relay *)con->relay; if (bcmp(&rlay->conf.ss, &con->out.ss, sizeof(con->out.ss)) == 0 && con->out.port == rlay->conf.port) { log_debug("relay_session: session %d: looping", con->id); relay_close(con, "session aborted"); return; } if ((rlay->conf.flags & F_SSL) && (con->in.ssl == NULL)) { relay_ssl_transaction(con); return; } if (!rlay->proto->lateconnect && relay_connect(con) == -1) { relay_close(con, "session failed"); return; } relay_input(con); } int relay_connect(struct session *con) { struct relay *rlay = (struct relay *)con->relay; if (gettimeofday(&con->tv_start, NULL)) return (-1); if (rlay->dsttable != NULL) { if (relay_from_table(con) != 0) return (-1); } else if (con->out.ss.ss_family == AF_UNSPEC) { bcopy(&rlay->conf.dstss, &con->out.ss, sizeof(con->out.ss)); con->out.port = rlay->conf.dstport; } retry: if ((con->out.s = relay_socket_connect(&con->out.ss, con->out.port, rlay->proto)) == -1) { if (con->retry) { con->retry--; log_debug("relay_connect: session %d: " "forward failed: %s, %s", con->id, strerror(errno), con->retry ? "next retry" : "last retry"); goto retry; } log_debug("relay_connect: session %d: forward failed: %s", con->id, strerror(errno)); return (-1); } if (errno == EINPROGRESS) event_again(&con->ev, con->out.s, EV_WRITE|EV_TIMEOUT, relay_connected, &con->tv_start, &env->timeout, con); else relay_connected(con->out.s, EV_WRITE, con); return (0); } void relay_close(struct session *con, const char *msg) { struct relay *rlay = (struct relay *)con->relay; char ibuf[128], obuf[128], *ptr = NULL; TAILQ_REMOVE(&rlay->sessions, con, entry); event_del(&con->ev); if (con->in.bev != NULL) bufferevent_disable(con->in.bev, EV_READ|EV_WRITE); if (con->out.bev != NULL) bufferevent_disable(con->out.bev, EV_READ|EV_WRITE); if (env->opts & HOSTSTATED_OPT_LOGUPDATE) { bzero(&ibuf, sizeof(ibuf)); bzero(&obuf, sizeof(obuf)); (void)relay_host(&con->in.ss, ibuf, sizeof(ibuf)); (void)relay_host(&con->out.ss, obuf, sizeof(obuf)); if (EVBUFFER_LENGTH(con->log) && evbuffer_add_printf(con->log, "\r\n") != -1) ptr = evbuffer_readline(con->log); log_info("relay %s, session %d (%d active), %s -> %s:%d, " "%s%s%s", rlay->conf.name, con->id, relay_sessions, ibuf, obuf, ntohs(con->out.port), msg, ptr == NULL ? "" : ",", ptr == NULL ? "" : ptr); if (ptr != NULL) free(ptr); } if (con->in.bev != NULL) bufferevent_free(con->in.bev); else if (con->in.output != NULL) evbuffer_free(con->in.output); if (con->in.ssl != NULL) { /* XXX handle non-blocking shutdown */ if (SSL_shutdown(con->in.ssl) == 0) SSL_shutdown(con->in.ssl); SSL_free(con->in.ssl); } if (con->in.s != -1) close(con->in.s); if (con->in.path != NULL) free(con->in.path); if (con->in.buf != NULL) free(con->in.buf); if (con->in.nodes != NULL) free(con->in.nodes); if (con->out.bev != NULL) bufferevent_free(con->out.bev); else if (con->out.output != NULL) evbuffer_free(con->out.output); if (con->out.s != -1) close(con->out.s); if (con->out.path != NULL) free(con->out.path); if (con->out.buf != NULL) free(con->out.buf); if (con->out.nodes != NULL) free(con->out.nodes); if (con->log != NULL) evbuffer_free(con->log); if (con->cnl != NULL) { #if 0 imsg_compose(ibuf_pfe, IMSG_KILLSTATES, 0, 0, cnl, sizeof(*cnl)); #endif free(con->cnl); } free(con); relay_sessions--; } void relay_dispatch_pfe(int fd, short event, void *ptr) { struct imsgbuf *ibuf; struct imsg imsg; ssize_t n; struct session *con; struct ctl_natlook cnl; struct timeval tv; struct host *host; struct table *table; struct ctl_status st; objid_t id; ibuf = ptr; switch (event) { case EV_READ: if ((n = imsg_read(ibuf)) == -1) fatal("relay_dispatch_pfe: imsg_read_error"); if (n == 0) fatalx("relay_dispatch_pfe: pipe closed"); break; case EV_WRITE: if (msgbuf_write(&ibuf->w) == -1) fatal("relay_dispatch_pfe: msgbuf_write"); imsg_event_add(ibuf); return; default: fatalx("relay_dispatch_pfe: unknown event"); } for (;;) { if ((n = imsg_get(ibuf, &imsg)) == -1) fatal("relay_dispatch_pfe: imsg_read error"); if (n == 0) break; switch (imsg.hdr.type) { case IMSG_HOST_DISABLE: memcpy(&id, imsg.data, sizeof(id)); if ((host = host_find(env, id)) == NULL) fatalx("relay_dispatch_pfe: desynchronized"); if ((table = table_find(env, host->conf.tableid)) == NULL) fatalx("relay_dispatch_pfe: invalid table id"); if (host->up == HOST_UP) table->up--; host->flags |= F_DISABLE; host->up = HOST_UNKNOWN; break; case IMSG_HOST_ENABLE: memcpy(&id, imsg.data, sizeof(id)); if ((host = host_find(env, id)) == NULL) fatalx("relay_dispatch_pfe: desynchronized"); host->flags &= ~(F_DISABLE); host->up = HOST_UNKNOWN; break; case IMSG_HOST_STATUS: if (imsg.hdr.len - IMSG_HEADER_SIZE != sizeof(st)) fatalx("relay_dispatch_pfe: invalid request"); memcpy(&st, imsg.data, sizeof(st)); if ((host = host_find(env, st.id)) == NULL) fatalx("relay_dispatch_pfe: invalid host id"); if (host->flags & F_DISABLE) break; if (host->up == st.up) { log_debug("relay_dispatch_pfe: host %d => %d", host->conf.id, host->up); fatalx("relay_dispatch_pfe: desynchronized"); } if ((table = table_find(env, host->conf.tableid)) == NULL) fatalx("relay_dispatch_pfe: invalid table id"); DPRINTF("relay_dispatch_pfe: [%d] state %d for " "host %u %s", proc_id, st.up, host->conf.id, host->conf.name); if ((st.up == HOST_UNKNOWN && host->up == HOST_DOWN) || (st.up == HOST_DOWN && host->up == HOST_UNKNOWN)) { host->up = st.up; break; } if (st.up == HOST_UP) table->up++; else table->up--; host->up = st.up; break; case IMSG_NATLOOK: bcopy(imsg.data, &cnl, sizeof(cnl)); if ((con = session_find(env, cnl.id)) == NULL || con->cnl == NULL) { log_debug("relay_dispatch_pfe: " "session expired"); break; } bcopy(&cnl, con->cnl, sizeof(*con->cnl)); evtimer_del(&con->ev); evtimer_set(&con->ev, relay_natlook, con); bzero(&tv, sizeof(tv)); evtimer_add(&con->ev, &tv); break; default: log_debug("relay_dispatch_msg: unexpected imsg %d", imsg.hdr.type); break; } imsg_free(&imsg); } imsg_event_add(ibuf); } void relay_dispatch_parent(int fd, short event, void * ptr) { struct imsgbuf *ibuf; struct imsg imsg; ssize_t n; ibuf = ptr; switch (event) { case EV_READ: if ((n = imsg_read(ibuf)) == -1) fatal("relay_dispatch_parent: imsg_read error"); if (n == 0) fatalx("relay_dispatch_parent: pipe closed"); break; case EV_WRITE: if (msgbuf_write(&ibuf->w) == -1) fatal("relay_dispatch_parent: msgbuf_write"); imsg_event_add(ibuf); return; default: fatalx("relay_dispatch_parent: unknown event"); } for (;;) { if ((n = imsg_get(ibuf, &imsg)) == -1) fatal("relay_dispatch_parent: imsg_read error"); if (n == 0) break; switch (imsg.hdr.type) { default: log_debug("relay_dispatch_parent: unexpected imsg %d", imsg.hdr.type); break; } imsg_free(&imsg); } imsg_event_add(ibuf); } SSL_CTX * relay_ssl_ctx_create(struct relay *rlay) { struct protocol *proto = rlay->proto; SSL_CTX *ctx; char certfile[PATH_MAX], hbuf[128]; ctx = SSL_CTX_new(SSLv23_method()); if (ctx == NULL) goto err; /* Modify session timeout and cache size*/ SSL_CTX_set_timeout(ctx, rlay->conf.timeout.tv_sec); if (proto->cache < -1) { SSL_CTX_set_session_cache_mode(ctx, SSL_SESS_CACHE_OFF); } else if (proto->cache >= -1) { SSL_CTX_set_session_cache_mode(ctx, SSL_SESS_CACHE_SERVER); if (proto->cache >= 0) SSL_CTX_sess_set_cache_size(ctx, proto->cache); } /* Enable all workarounds and set SSL options */ SSL_CTX_set_options(ctx, SSL_OP_ALL); SSL_CTX_set_options(ctx, SSL_OP_NO_SESSION_RESUMPTION_ON_RENEGOTIATION); /* Set the allowed SSL protocols */ if ((proto->sslflags & SSLFLAG_SSLV2) == 0) SSL_CTX_set_options(ctx, SSL_OP_NO_SSLv2); if ((proto->sslflags & SSLFLAG_SSLV3) == 0) SSL_CTX_set_options(ctx, SSL_OP_NO_SSLv3); if ((proto->sslflags & SSLFLAG_TLSV1) == 0) SSL_CTX_set_options(ctx, SSL_OP_NO_TLSv1); if (!SSL_CTX_set_cipher_list(ctx, proto->sslciphers)) goto err; if (relay_host(&rlay->conf.ss, hbuf, sizeof(hbuf)) == NULL) goto err; /* Load the certificate */ if (snprintf(certfile, sizeof(certfile), "/etc/ssl/%s.crt", hbuf) == -1) goto err; log_debug("relay_ssl_ctx_create: using certificate %s", certfile); if (!SSL_CTX_use_certificate_file(ctx, certfile, SSL_FILETYPE_PEM)) goto err; /* Load the private key */ if (snprintf(certfile, sizeof(certfile), "/etc/ssl/private/%s.key", hbuf) == -1) { goto err; } log_debug("relay_ssl_ctx_create: using private key %s", certfile); if (!SSL_CTX_use_PrivateKey_file(ctx, certfile, SSL_FILETYPE_PEM)) goto err; if (!SSL_CTX_check_private_key(ctx)) goto err; /* Set session context to the local relay name */ if (!SSL_CTX_set_session_id_context(ctx, rlay->conf.name, strlen(rlay->conf.name))) goto err; return (ctx); err: if (ctx != NULL) SSL_CTX_free(ctx); ssl_error(rlay->conf.name, "relay_ssl_ctx_create"); return (NULL); } void relay_ssl_transaction(struct session *con) { struct relay *rlay = (struct relay *)con->relay; SSL *ssl; ssl = SSL_new(rlay->ctx); if (ssl == NULL) goto err; if (!SSL_set_ssl_method(ssl, SSLv23_server_method())) goto err; if (!SSL_set_fd(ssl, con->in.s)) goto err; SSL_set_accept_state(ssl); con->in.ssl = ssl; event_again(&con->ev, con->in.s, EV_TIMEOUT|EV_READ, relay_ssl_accept, &con->tv_start, &env->timeout, con); return; err: if (ssl != NULL) SSL_free(ssl); ssl_error(rlay->conf.name, "relay_ssl_transaction"); } void relay_ssl_accept(int fd, short event, void *arg) { struct session *con = (struct session *)arg; struct relay *rlay = (struct relay *)con->relay; int ret; int ssl_err; int retry_flag; if (event == EV_TIMEOUT) { relay_close(con, "SSL accept timeout"); return; } retry_flag = ssl_err = 0; ret = SSL_accept(con->in.ssl); if (ret <= 0) { ssl_err = SSL_get_error(con->in.ssl, ret); switch (ssl_err) { case SSL_ERROR_WANT_READ: retry_flag = EV_READ; goto retry; case SSL_ERROR_WANT_WRITE: retry_flag = EV_WRITE; goto retry; case SSL_ERROR_ZERO_RETURN: case SSL_ERROR_SYSCALL: if (ret == 0) { relay_close(con, "closed"); return; } /* FALLTHROUGH */ default: ssl_error(rlay->conf.name, "relay_ssl_accept"); relay_close(con, "SSL accept error"); return; } } #ifdef DEBUG log_info("relay %s, session %d established (%d active)", rlay->conf.name, con->id, relay_sessions); #else log_debug("relay %s, session %d established (%d active)", rlay->conf.name, con->id, relay_sessions); #endif relay_session(con); return; retry: DPRINTF("relay_ssl_accept: session %d: scheduling on %s", con->id, (retry_flag == EV_READ) ? "EV_READ" : "EV_WRITE"); event_again(&con->ev, fd, EV_TIMEOUT|retry_flag, relay_ssl_accept, &con->tv_start, &env->timeout, con); } void relay_ssl_connected(struct ctl_relay_event *cre) { /* * Hack libevent - we overwrite the internal bufferevent I/O * functions to handle the SSL abstraction. */ event_set(&cre->bev->ev_read, cre->s, EV_READ, relay_ssl_readcb, cre->bev); event_set(&cre->bev->ev_write, cre->s, EV_WRITE, relay_ssl_writecb, cre->bev); } void relay_ssl_readcb(int fd, short event, void *arg) { struct bufferevent *bufev = arg; struct ctl_relay_event *cre = (struct ctl_relay_event *)bufev->cbarg; struct session *con = (struct session *)cre->con; struct relay *rlay = (struct relay *)con->relay; int ret = 0, ssl_err = 0; short what = EVBUFFER_READ; size_t len; char rbuf[READ_BUF_SIZE]; int howmuch = READ_BUF_SIZE; if (event == EV_TIMEOUT) { what |= EVBUFFER_TIMEOUT; goto err; } if (bufev->wm_read.high != 0) howmuch = MIN(sizeof(rbuf), bufev->wm_read.high); ret = SSL_read(cre->ssl, rbuf, howmuch); if (ret <= 0) { ssl_err = SSL_get_error(cre->ssl, ret); switch (ssl_err) { case SSL_ERROR_WANT_READ: DPRINTF("relay_ssl_readcb: session %d: " "want read", con->id); goto retry; case SSL_ERROR_WANT_WRITE: DPRINTF("relay_ssl_readcb: session %d: " "want write", con->id); goto retry; default: if (ret == 0) what |= EVBUFFER_EOF; else { ssl_error(rlay->conf.name, "relay_ssl_readcb"); what |= EVBUFFER_ERROR; } goto err; } } if (evbuffer_add(bufev->input, rbuf, ret) == -1) { what |= EVBUFFER_ERROR; goto err; } relay_bufferevent_add(&bufev->ev_read, bufev->timeout_read); len = EVBUFFER_LENGTH(bufev->input); if (bufev->wm_read.low != 0 && len < bufev->wm_read.low) return; if (bufev->wm_read.high != 0 && len > bufev->wm_read.high) { struct evbuffer *buf = bufev->input; event_del(&bufev->ev_read); evbuffer_setcb(buf, bufferevent_read_pressure_cb, bufev); return; } if (bufev->readcb != NULL) (*bufev->readcb)(bufev, bufev->cbarg); return; retry: relay_bufferevent_add(&bufev->ev_read, bufev->timeout_read); return; err: (*bufev->errorcb)(bufev, what, bufev->cbarg); } void relay_ssl_writecb(int fd, short event, void *arg) { struct bufferevent *bufev = arg; struct ctl_relay_event *cre = (struct ctl_relay_event *)bufev->cbarg; struct session *con = (struct session *)cre->con; struct relay *rlay = (struct relay *)con->relay; int ret = 0, ssl_err; short what = EVBUFFER_WRITE; if (event == EV_TIMEOUT) { what |= EVBUFFER_TIMEOUT; goto err; } if (EVBUFFER_LENGTH(bufev->output)) { if (cre->buf == NULL) { cre->buflen = EVBUFFER_LENGTH(bufev->output); if ((cre->buf = malloc(cre->buflen)) == NULL) { what |= EVBUFFER_ERROR; goto err; } bcopy(EVBUFFER_DATA(bufev->output), cre->buf, cre->buflen); } ret = SSL_write(cre->ssl, cre->buf, cre->buflen); if (ret <= 0) { ssl_err = SSL_get_error(cre->ssl, ret); switch (ssl_err) { case SSL_ERROR_WANT_READ: DPRINTF("relay_ssl_writecb: session %d: " "want read", con->id); goto retry; case SSL_ERROR_WANT_WRITE: DPRINTF("relay_ssl_writecb: session %d: " "want write", con->id); goto retry; default: if (ret == 0) what |= EVBUFFER_EOF; else { ssl_error(rlay->conf.name, "relay_ssl_writecb"); what |= EVBUFFER_ERROR; } goto err; } } evbuffer_drain(bufev->output, ret); } if (cre->buf != NULL) { free(cre->buf); cre->buf = NULL; cre->buflen = 0; } if (EVBUFFER_LENGTH(bufev->output) != 0) relay_bufferevent_add(&bufev->ev_write, bufev->timeout_write); if (bufev->writecb != NULL && EVBUFFER_LENGTH(bufev->output) <= bufev->wm_write.low) (*bufev->writecb)(bufev, bufev->cbarg); return; retry: if (cre->buflen != 0) relay_bufferevent_add(&bufev->ev_write, bufev->timeout_write); return; err: if (cre->buf != NULL) { free(cre->buf); cre->buf = NULL; cre->buflen = 0; } (*bufev->errorcb)(bufev, what, bufev->cbarg); } int relay_bufferevent_add(struct event *ev, int timeout) { struct timeval tv, *ptv = NULL; if (timeout) { timerclear(&tv); tv.tv_sec = timeout; ptv = &tv; } return (event_add(ev, ptv)); } #ifdef notyet int relay_bufferevent_printf(struct ctl_relay_event *cre, const char *fmt, ...) { int ret; va_list ap; va_start(ap, fmt); ret = evbuffer_add_vprintf(cre->output, fmt, ap); va_end(ap); if (cre->bev != NULL && ret != -1 && EVBUFFER_LENGTH(cre->output) > 0 && (cre->bev->enabled & EV_WRITE)) bufferevent_enable(cre->bev, EV_WRITE); return (ret); } #endif int relay_bufferevent_print(struct ctl_relay_event *cre, char *str) { if (cre->bev == NULL) return (evbuffer_add(cre->output, str, strlen(str))); return (bufferevent_write(cre->bev, str, strlen(str))); } int relay_bufferevent_write_buffer(struct ctl_relay_event *cre, struct evbuffer *buf) { if (cre->bev == NULL) return (evbuffer_add_buffer(cre->output, buf)); return (bufferevent_write_buffer(cre->bev, buf)); } int relay_bufferevent_write_chunk(struct ctl_relay_event *cre, struct evbuffer *buf, size_t size) { int ret; ret = relay_bufferevent_write(cre, buf->buffer, size); if (ret != -1) evbuffer_drain(buf, size); return (ret); } int relay_bufferevent_write(struct ctl_relay_event *cre, void *data, size_t size) { if (cre->bev == NULL) return (evbuffer_add(cre->output, data, size)); return (bufferevent_write(cre->bev, data, size)); } static __inline int relay_proto_cmp(struct protonode *a, struct protonode *b) { return (strcasecmp(a->key, b->key) + a->type == b->type ? 0 : (a->type > b->type ? 1 : -1)); } RB_GENERATE(proto_tree, protonode, nodes, relay_proto_cmp);