/* * Copyright (C) 2006-2008 Stig Venaas * * 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. */ /* For UDP there is one server instance consisting of udpserverrd and udpserverth * rd is responsible for init and launching wr * For TLS there is a server instance that launches tlsserverrd for each TLS peer * each tlsserverrd launches tlsserverwr * For each UDP/TLS peer there is clientrd and clientwr, clientwr is responsible * for init and launching rd * * serverrd will receive a request, processes it and puts it in the requestq of * the appropriate clientwr * clientwr monitors its requestq and sends requests * clientrd looks for responses, processes them and puts them in the replyq of * the peer the request came from * serverwr monitors its reply and sends replies * * In addition to the main thread, we have: * If UDP peers are configured, there will be 2 + 2 * #peers UDP threads * If TLS peers are configured, there will initially be 2 * #peers TLS threads * For each TLS peer connecting to us there will be 2 more TLS threads * This is only for connected peers * Example: With 3 UDP peer and 30 TLS peers, there will be a max of * 1 + (2 + 2 * 3) + (2 * 30) + (2 * 30) = 129 threads */ #include #include #include #include #include #include #include #ifdef SYS_SOLARIS9 #include #endif #include #include #include #include #include #include #include #include #include #include #include #include #include "debug.h" #include "list.h" #include "util.h" #include "gconfig.h" #include "radsecproxy.h" static struct options options; struct list *clconfs, *srvconfs, *realms, *tlsconfs, *rewriteconfs; static int client_udp_count = 0; static int client_tls_count = 0; static struct addrinfo *srcudpres = NULL; static struct addrinfo *srctcpres = NULL; static struct replyq *udp_server_replyq = NULL; static int udp_server_sock = -1; static int udp_accserver_sock = -1; static int udp_client4_sock = -1; static int udp_client6_sock = -1; static pthread_mutex_t *ssl_locks = NULL; static long *ssl_lock_count; extern int optind; extern char *optarg; /* callbacks for making OpenSSL thread safe */ unsigned long ssl_thread_id() { return (unsigned long)pthread_self(); } void ssl_locking_callback(int mode, int type, const char *file, int line) { if (mode & CRYPTO_LOCK) { pthread_mutex_lock(&ssl_locks[type]); ssl_lock_count[type]++; } else pthread_mutex_unlock(&ssl_locks[type]); } static int pem_passwd_cb(char *buf, int size, int rwflag, void *userdata) { int pwdlen = strlen(userdata); if (rwflag != 0 || pwdlen > size) /* not for decryption or too large */ return 0; memcpy(buf, userdata, pwdlen); return pwdlen; } static int verify_cb(int ok, X509_STORE_CTX *ctx) { char buf[256]; X509 *err_cert; int err, depth; err_cert = X509_STORE_CTX_get_current_cert(ctx); err = X509_STORE_CTX_get_error(ctx); depth = X509_STORE_CTX_get_error_depth(ctx); if (depth > MAX_CERT_DEPTH) { ok = 0; err = X509_V_ERR_CERT_CHAIN_TOO_LONG; X509_STORE_CTX_set_error(ctx, err); } if (!ok) { X509_NAME_oneline(X509_get_subject_name(err_cert), buf, 256); debug(DBG_WARN, "verify error: num=%d:%s:depth=%d:%s", err, X509_verify_cert_error_string(err), depth, buf); switch (err) { case X509_V_ERR_UNABLE_TO_GET_ISSUER_CERT: X509_NAME_oneline(X509_get_issuer_name(ctx->current_cert), buf, 256); debug(DBG_WARN, "\tIssuer=%s", buf); break; case X509_V_ERR_CERT_NOT_YET_VALID: case X509_V_ERR_ERROR_IN_CERT_NOT_BEFORE_FIELD: debug(DBG_WARN, "\tCertificate not yet valid"); break; case X509_V_ERR_CERT_HAS_EXPIRED: debug(DBG_WARN, "Certificate has expired"); break; case X509_V_ERR_ERROR_IN_CERT_NOT_AFTER_FIELD: debug(DBG_WARN, "Certificate no longer valid (after notAfter)"); break; } } #ifdef DEBUG printf("certificate verify returns %d\n", ok); #endif return ok; } int resolvepeer(struct clsrvconf *conf, int ai_flags) { struct addrinfo hints, *addrinfo, *res; char *slash, *s; int plen = 0; slash = conf->host ? strchr(conf->host, '/') : NULL; if (slash) { s = slash + 1; if (!*s) { debug(DBG_WARN, "resolvepeer: prefix length must be specified after the / in %s", conf->host); return 0; } for (; *s; s++) if (*s < '0' || *s > '9') { debug(DBG_WARN, "resolvepeer: %s in %s is not a valid prefix length", slash + 1, conf->host); return 0; } plen = atoi(slash + 1); if (plen < 0 || plen > 128) { debug(DBG_WARN, "resolvepeer: %s in %s is not a valid prefix length", slash + 1, conf->host); return 0; } *slash = '\0'; } memset(&hints, 0, sizeof(hints)); hints.ai_socktype = (conf->type == 'T' ? SOCK_STREAM : SOCK_DGRAM); hints.ai_family = AF_UNSPEC; hints.ai_flags = ai_flags; if (!conf->host && !conf->port) { /* getaddrinfo() doesn't like host and port to be NULL */ if (getaddrinfo(conf->host, DEFAULT_UDP_PORT, &hints, &addrinfo)) { debug(DBG_WARN, "resolvepeer: can't resolve (null) port (null)"); return 0; } for (res = addrinfo; res; res = res->ai_next) { switch (res->ai_family) { case AF_INET: ((struct sockaddr_in *)res->ai_addr)->sin_port = 0; break; case AF_INET6: ((struct sockaddr_in6 *)res->ai_addr)->sin6_port = 0; break; } } } else { if (slash) hints.ai_flags |= AI_NUMERICHOST; if (getaddrinfo(conf->host, conf->port, &hints, &addrinfo)) { debug(DBG_WARN, "resolvepeer: can't resolve %s port %s", conf->host ? conf->host : "(null)", conf->port ? conf->port : "(null)"); return 0; } if (slash) { *slash = '/'; switch (addrinfo->ai_family) { case AF_INET: if (plen > 32) { debug(DBG_WARN, "resolvepeer: prefix length must be <= 32 in %s", conf->host); freeaddrinfo(addrinfo); return 0; } break; case AF_INET6: break; default: debug(DBG_WARN, "resolvepeer: prefix must be IPv4 or IPv6 in %s", conf->host); freeaddrinfo(addrinfo); return 0; } conf->prefixlen = plen; } else conf->prefixlen = 255; } if (conf->addrinfo) freeaddrinfo(conf->addrinfo); conf->addrinfo = addrinfo; return 1; } int bindtoaddr(struct addrinfo *addrinfo, int family, int reuse, int v6only) { int s, on = 1; struct addrinfo *res; for (res = addrinfo; res; res = res->ai_next) { if (family != AF_UNSPEC && family != res->ai_family) continue; s = socket(res->ai_family, res->ai_socktype, res->ai_protocol); if (s < 0) { debug(DBG_WARN, "bindtoaddr: socket failed"); continue; } if (reuse) setsockopt(s, SOL_SOCKET, SO_REUSEADDR, &on, sizeof(on)); #ifdef IPV6_V6ONLY if (v6only) setsockopt(s, IPPROTO_IPV6, IPV6_V6ONLY, &on, sizeof(on)); #endif if (!bind(s, res->ai_addr, res->ai_addrlen)) return s; debug(DBG_WARN, "bindtoaddr: bind failed"); close(s); } return -1; } char *parsehostport(char *s, struct clsrvconf *conf, char *default_port) { char *p, *field; int ipv6 = 0; p = s; /* allow literal addresses and port, e.g. [2001:db8::1]:1812 */ if (*p == '[') { p++; field = p; for (; *p && *p != ']' && *p != ' ' && *p != '\t' && *p != '\n'; p++); if (*p != ']') debugx(1, DBG_ERR, "no ] matching initial ["); ipv6 = 1; } else { field = p; for (; *p && *p != ':' && *p != ' ' && *p != '\t' && *p != '\n'; p++); } if (field == p) debugx(1, DBG_ERR, "missing host/address"); conf->host = stringcopy(field, p - field); if (ipv6) { p++; if (*p && *p != ':' && *p != ' ' && *p != '\t' && *p != '\n') debugx(1, DBG_ERR, "unexpected character after ]"); } if (*p == ':') { /* port number or service name is specified */; field = ++p; for (; *p && *p != ' ' && *p != '\t' && *p != '\n'; p++); if (field == p) debugx(1, DBG_ERR, "syntax error, : but no following port"); conf->port = stringcopy(field, p - field); } else conf->port = default_port ? stringcopy(default_port, 0) : NULL; return p; } struct clsrvconf *resolve_hostport(char type, char *lconf, char *default_port) { struct clsrvconf *conf; conf = malloc(sizeof(struct clsrvconf)); if (!conf) debugx(1, DBG_ERR, "malloc failed"); memset(conf, 0, sizeof(struct clsrvconf)); conf->type = type; if (lconf) { parsehostport(lconf, conf, default_port); if (!strcmp(conf->host, "*")) { free(conf->host); conf->host = NULL; } } else conf->port = default_port ? stringcopy(default_port, 0) : NULL; if (!resolvepeer(conf, AI_PASSIVE)) debugx(1, DBG_ERR, "failed to resolve host %s port %s, exiting", conf->host ? conf->host : "(null)", conf->port ? conf->port : "(null)"); return conf; } void freeclsrvres(struct clsrvconf *res) { free(res->host); free(res->port); if (res->addrinfo) freeaddrinfo(res->addrinfo); free(res); } int connecttcp(struct addrinfo *addrinfo) { int s; struct addrinfo *res; s = -1; for (res = addrinfo; res; res = res->ai_next) { s = bindtoaddr(srctcpres, res->ai_family, 1, 1); if (s < 0) { debug(DBG_WARN, "connecttoserver: socket failed"); continue; } if (connect(s, res->ai_addr, res->ai_addrlen) == 0) break; debug(DBG_WARN, "connecttoserver: connect failed"); close(s); s = -1; } return s; } /* returns 1 if the len first bits are equal, else 0 */ int prefixmatch(void *a1, void *a2, uint8_t len) { static uint8_t mask[] = { 0, 0x80, 0xc0, 0xe0, 0xf0, 0xf8, 0xfc, 0xfe }; int r, l = len / 8; if (l && memcmp(a1, a2, l)) return 0; r = len % 8; if (!r) return 1; return (((uint8_t *)a1)[l] & mask[r]) == (((uint8_t *)a2)[l] & mask[r]); } /* check if conf has matching address */ struct clsrvconf *checkconfaddr(char type, struct sockaddr *addr, struct clsrvconf *conf) { struct sockaddr_in6 *sa6 = NULL; struct in_addr *a4 = NULL; struct addrinfo *res; if (addr->sa_family == AF_INET6) { sa6 = (struct sockaddr_in6 *)addr; if (IN6_IS_ADDR_V4MAPPED(&sa6->sin6_addr)) { a4 = (struct in_addr *)&sa6->sin6_addr.s6_addr[12]; sa6 = NULL; } } else a4 = &((struct sockaddr_in *)addr)->sin_addr; if (conf->type == type) { if (conf->prefixlen == 255) { for (res = conf->addrinfo; res; res = res->ai_next) if ((a4 && res->ai_family == AF_INET && !memcmp(a4, &((struct sockaddr_in *)res->ai_addr)->sin_addr, 4)) || (sa6 && res->ai_family == AF_INET6 && !memcmp(&sa6->sin6_addr, &((struct sockaddr_in6 *)res->ai_addr)->sin6_addr, 16))) return conf; } else { res = conf->addrinfo; if (res && ((a4 && res->ai_family == AF_INET && prefixmatch(a4, &((struct sockaddr_in *)res->ai_addr)->sin_addr, conf->prefixlen)) || (sa6 && res->ai_family == AF_INET6 && prefixmatch(&sa6->sin6_addr, &((struct sockaddr_in6 *)res->ai_addr)->sin6_addr, conf->prefixlen)))) return conf; } } return NULL; } /* returns next config with matching address, or NULL */ struct clsrvconf *find_conf(char type, struct sockaddr *addr, struct list *confs, struct list_node **cur) { struct sockaddr_in6 *sa6 = NULL; struct in_addr *a4 = NULL; struct addrinfo *res; struct list_node *entry; struct clsrvconf *conf; if (addr->sa_family == AF_INET6) { sa6 = (struct sockaddr_in6 *)addr; if (IN6_IS_ADDR_V4MAPPED(&sa6->sin6_addr)) { a4 = (struct in_addr *)&sa6->sin6_addr.s6_addr[12]; sa6 = NULL; } } else a4 = &((struct sockaddr_in *)addr)->sin_addr; for (entry = (cur && *cur ? list_next(*cur) : list_first(confs)); entry; entry = list_next(entry)) { conf = (struct clsrvconf *)entry->data; if (conf->type == type) { if (conf->prefixlen == 255) { for (res = conf->addrinfo; res; res = res->ai_next) if ((a4 && res->ai_family == AF_INET && !memcmp(a4, &((struct sockaddr_in *)res->ai_addr)->sin_addr, 4)) || (sa6 && res->ai_family == AF_INET6 && !memcmp(&sa6->sin6_addr, &((struct sockaddr_in6 *)res->ai_addr)->sin6_addr, 16))) { if (cur) *cur = entry; return conf; } } else { res = conf->addrinfo; if (res && ((a4 && res->ai_family == AF_INET && prefixmatch(a4, &((struct sockaddr_in *)res->ai_addr)->sin_addr, conf->prefixlen)) || (sa6 && res->ai_family == AF_INET6 && prefixmatch(&sa6->sin6_addr, &((struct sockaddr_in6 *)res->ai_addr)->sin6_addr, conf->prefixlen)))) { if (cur) *cur = entry; return conf; } } } } return NULL; } struct replyq *newreplyq() { struct replyq *replyq; replyq = malloc(sizeof(struct replyq)); if (!replyq) debugx(1, DBG_ERR, "malloc failed"); replyq->replies = list_create(); if (!replyq->replies) debugx(1, DBG_ERR, "malloc failed"); pthread_mutex_init(&replyq->mutex, NULL); pthread_cond_init(&replyq->cond, NULL); return replyq; } struct client *addclient(struct clsrvconf *conf) { struct client *new = malloc(sizeof(struct client)); if (!new) { debug(DBG_ERR, "malloc failed"); return NULL; } if (!conf->clients) { conf->clients = list_create(); if (!conf->clients) { debug(DBG_ERR, "malloc failed"); return NULL; } } memset(new, 0, sizeof(struct client)); new->conf = conf; new->replyq = conf->type == 'T' ? newreplyq() : udp_server_replyq; list_push(conf->clients, new); return new; } void removeclient(struct client *client) { struct list_node *entry; if (!client || !client->conf->clients) return; pthread_mutex_lock(&client->replyq->mutex); for (entry = list_first(client->replyq->replies); entry; entry = list_next(entry)) free(((struct reply *)entry)->buf); list_destroy(client->replyq->replies); pthread_cond_destroy(&client->replyq->cond); pthread_mutex_unlock(&client->replyq->mutex); pthread_mutex_destroy(&client->replyq->mutex); list_removedata(client->conf->clients, client); free(client); } void removeclientrqs(struct client *client) { struct list_node *entry; struct server *server; struct request *rq; int i; for (entry = list_first(srvconfs); entry; entry = list_next(entry)) { server = ((struct clsrvconf *)entry->data)->servers; pthread_mutex_lock(&server->newrq_mutex); for (i = 0; i < MAX_REQUESTS; i++) { rq = server->requests + i; if (rq->from == client) rq->from = NULL; } pthread_mutex_unlock(&server->newrq_mutex); } } void addserver(struct clsrvconf *conf) { struct clsrvconf *res; if (conf->servers) debugx(1, DBG_ERR, "addserver: currently works with just one server per conf"); conf->servers = malloc(sizeof(struct server)); if (!conf->servers) debugx(1, DBG_ERR, "malloc failed"); memset(conf->servers, 0, sizeof(struct server)); conf->servers->conf = conf; if (conf->type == 'U') { if (!srcudpres) { res = resolve_hostport('U', options.sourceudp, NULL); srcudpres = res->addrinfo; res->addrinfo = NULL; freeclsrvres(res); } switch (conf->addrinfo->ai_family) { case AF_INET: if (udp_client4_sock < 0) { udp_client4_sock = bindtoaddr(srcudpres, AF_INET, 0, 1); if (udp_client4_sock < 0) debugx(1, DBG_ERR, "addserver: failed to create client socket for server %s", conf->host); } conf->servers->sock = udp_client4_sock; break; case AF_INET6: if (udp_client6_sock < 0) { udp_client6_sock = bindtoaddr(srcudpres, AF_INET6, 0, 1); if (udp_client6_sock < 0) debugx(1, DBG_ERR, "addserver: failed to create client socket for server %s", conf->host); } conf->servers->sock = udp_client6_sock; break; default: debugx(1, DBG_ERR, "addserver: unsupported address family"); } } else { if (!srctcpres) { res = resolve_hostport('T', options.sourcetcp, NULL); srctcpres = res->addrinfo; res->addrinfo = NULL; freeclsrvres(res); } conf->servers->sock = -1; } pthread_mutex_init(&conf->servers->lock, NULL); conf->servers->requests = calloc(MAX_REQUESTS, sizeof(struct request)); if (!conf->servers->requests) debugx(1, DBG_ERR, "malloc failed"); conf->servers->newrq = 0; pthread_mutex_init(&conf->servers->newrq_mutex, NULL); pthread_cond_init(&conf->servers->newrq_cond, NULL); } /* exactly one of client and server must be non-NULL */ /* should probably take peer list (client(s) or server(s)) as argument instead */ /* if *peer == NULL we return who we received from, else require it to be from peer */ /* return from in sa if not NULL */ unsigned char *radudpget(int s, struct client **client, struct server **server, struct sockaddr_storage *sa) { int cnt, len; unsigned char buf[65536], *rad; struct sockaddr_storage from; socklen_t fromlen = sizeof(from); struct clsrvconf *p; struct list_node *node; for (;;) { cnt = recvfrom(s, buf, sizeof(buf), 0, (struct sockaddr *)&from, &fromlen); if (cnt == -1) { debug(DBG_WARN, "radudpget: recv failed"); continue; } debug(DBG_DBG, "radudpget: got %d bytes from %s", cnt, addr2string((struct sockaddr *)&from, fromlen)); if (cnt < 20) { debug(DBG_WARN, "radudpget: packet too small"); continue; } len = RADLEN(buf); if (len < 20) { debug(DBG_WARN, "radudpget: length too small"); continue; } if (cnt < len) { debug(DBG_WARN, "radudpget: packet smaller than length field in radius header"); continue; } if (cnt > len) debug(DBG_DBG, "radudpget: packet was padded with %d bytes", cnt - len); if (client) if (*client) p = checkconfaddr('U', (struct sockaddr *)&from, (*client)->conf); else p = find_conf('U', (struct sockaddr *)&from, clconfs, NULL); else if (*server) p = checkconfaddr('U', (struct sockaddr *)&from, (*server)->conf); else p = find_conf('U', (struct sockaddr *)&from, srvconfs, NULL); if (!p) { debug(DBG_WARN, "radudpget: got packet from wrong or unknown UDP peer %s, ignoring", addr2string((struct sockaddr *)&from, fromlen)); continue; } rad = malloc(len); if (!rad) { debug(DBG_ERR, "radudpget: malloc failed"); continue; } if (client && !*client) { node = list_first(p->clients); *client = node ? (struct client *)node->data : addclient(p); if (!*client) { free(rad); continue; } } else if (server && !*server) *server = p->servers; break; } memcpy(rad, buf, len); if (sa) *sa = from; return rad; } int subjectaltnameaddr(X509 *cert, int family, struct in6_addr *addr) { int loc, i, l, n, r = 0; char *v; X509_EXTENSION *ex; STACK_OF(GENERAL_NAME) *alt; GENERAL_NAME *gn; debug(DBG_DBG, "subjectaltnameaddr"); loc = X509_get_ext_by_NID(cert, NID_subject_alt_name, -1); if (loc < 0) return r; ex = X509_get_ext(cert, loc); alt = X509V3_EXT_d2i(ex); if (!alt) return r; n = sk_GENERAL_NAME_num(alt); for (i = 0; i < n; i++) { gn = sk_GENERAL_NAME_value(alt, i); if (gn->type != GEN_IPADD) continue; r = -1; v = (char *)ASN1_STRING_data(gn->d.ia5); l = ASN1_STRING_length(gn->d.ia5); if (((family == AF_INET && l == sizeof(struct in_addr)) || (family == AF_INET6 && l == sizeof(struct in6_addr))) && !memcmp(v, &addr, l)) { r = 1; break; } } GENERAL_NAMES_free(alt); return r; } int cnregexp(X509 *cert, char *exact, regex_t *regex) { int loc, l; char *v, *s; X509_NAME *nm; X509_NAME_ENTRY *e; ASN1_STRING *t; nm = X509_get_subject_name(cert); loc = -1; for (;;) { loc = X509_NAME_get_index_by_NID(nm, NID_commonName, loc); if (loc == -1) break; e = X509_NAME_get_entry(nm, loc); t = X509_NAME_ENTRY_get_data(e); v = (char *) ASN1_STRING_data(t); l = ASN1_STRING_length(t); if (l < 0) continue; if (exact) { if (l == strlen(exact) && !strncasecmp(exact, v, l)) return 1; } else { s = stringcopy((char *)v, l); if (!s) { debug(DBG_ERR, "malloc failed"); continue; } if (regexec(regex, s, 0, NULL, 0)) { free(s); continue; } free(s); return 1; } } return 0; } int subjectaltnameregexp(X509 *cert, int type, char *exact, regex_t *regex) { int loc, i, l, n, r = 0; char *s, *v; X509_EXTENSION *ex; STACK_OF(GENERAL_NAME) *alt; GENERAL_NAME *gn; debug(DBG_DBG, "subjectaltnameregexp"); loc = X509_get_ext_by_NID(cert, NID_subject_alt_name, -1); if (loc < 0) return r; ex = X509_get_ext(cert, loc); alt = X509V3_EXT_d2i(ex); if (!alt) return r; n = sk_GENERAL_NAME_num(alt); for (i = 0; i < n; i++) { gn = sk_GENERAL_NAME_value(alt, i); if (gn->type != type) continue; r = -1; v = (char *)ASN1_STRING_data(gn->d.ia5); l = ASN1_STRING_length(gn->d.ia5); if (l <= 0) continue; #ifdef DEBUG printfchars(NULL, gn->type == GEN_DNS ? "dns" : "uri", NULL, v, l); #endif if (exact) { if (memcmp(v, exact, l)) continue; } else { s = stringcopy((char *)v, l); if (!s) { debug(DBG_ERR, "malloc failed"); continue; } if (regexec(regex, s, 0, NULL, 0)) { free(s); continue; } free(s); } r = 1; break; } GENERAL_NAMES_free(alt); return r; } X509 *verifytlscert(SSL *ssl) { X509 *cert; unsigned long error; if (SSL_get_verify_result(ssl) != X509_V_OK) { debug(DBG_ERR, "verifytlscert: basic validation failed"); while ((error = ERR_get_error())) debug(DBG_ERR, "verifytlscert: TLS: %s", ERR_error_string(error, NULL)); return NULL; } cert = SSL_get_peer_certificate(ssl); if (!cert) debug(DBG_ERR, "verifytlscert: failed to obtain certificate"); return cert; } int verifyconfcert(X509 *cert, struct clsrvconf *conf) { int r; uint8_t type = 0; /* 0 for DNS, AF_INET for IPv4, AF_INET6 for IPv6 */ struct in6_addr addr; if (conf->certnamecheck && conf->prefixlen == 255) { if (inet_pton(AF_INET, conf->host, &addr)) type = AF_INET; else if (inet_pton(AF_INET6, conf->host, &addr)) type = AF_INET6; r = type ? subjectaltnameaddr(cert, type, &addr) : subjectaltnameregexp(cert, GEN_DNS, conf->host, NULL); if (r) { if (r < 0) { debug(DBG_WARN, "verifyconfcert: No subjectaltname matching %s %s", type ? "address" : "host", conf->host); return 0; } debug(DBG_DBG, "verifyconfcert: Found subjectaltname matching %s %s", type ? "address" : "host", conf->host); } else { if (!cnregexp(cert, conf->host, NULL)) { debug(DBG_WARN, "verifyconfcert: cn not matching host %s", conf->host); return 0; } debug(DBG_DBG, "verifyconfcert: Found cn matching host %s", conf->host); } } if (conf->certcnregex) { if (cnregexp(cert, NULL, conf->certcnregex) < 1) { debug(DBG_WARN, "verifyconfcert: CN not matching regex"); return 0; } debug(DBG_DBG, "verifyconfcert: CN matching regex"); } if (conf->certuriregex) { if (subjectaltnameregexp(cert, GEN_URI, NULL, conf->certuriregex) < 1) { debug(DBG_WARN, "verifyconfcert: subjectaltname URI not matching regex"); return 0; } debug(DBG_DBG, "verifyconfcert: subjectaltname URI matching regex"); } return 1; } void tlsconnect(struct server *server, struct timeval *when, char *text) { struct timeval now; time_t elapsed; X509 *cert; debug(DBG_DBG, "tlsconnect called from %s", text); pthread_mutex_lock(&server->lock); if (when && memcmp(&server->lastconnecttry, when, sizeof(struct timeval))) { /* already reconnected, nothing to do */ debug(DBG_DBG, "tlsconnect(%s): seems already reconnected", text); pthread_mutex_unlock(&server->lock); return; } debug(DBG_DBG, "tlsconnect %s", text); for (;;) { gettimeofday(&now, NULL); elapsed = now.tv_sec - server->lastconnecttry.tv_sec; if (server->connectionok) { server->connectionok = 0; sleep(2); } else if (elapsed < 1) sleep(2); else if (elapsed < 60) { debug(DBG_INFO, "tlsconnect: sleeping %lds", elapsed); sleep(elapsed); } else if (elapsed < 100000) { debug(DBG_INFO, "tlsconnect: sleeping %ds", 60); sleep(60); } else server->lastconnecttry.tv_sec = now.tv_sec; /* no sleep at startup */ debug(DBG_WARN, "tlsconnect: trying to open TLS connection to %s port %s", server->conf->host, server->conf->port); if (server->sock >= 0) close(server->sock); if ((server->sock = connecttcp(server->conf->addrinfo)) < 0) { debug(DBG_ERR, "tlsconnect: connecttcp failed"); continue; } SSL_free(server->ssl); server->ssl = SSL_new(server->conf->ssl_ctx); SSL_set_fd(server->ssl, server->sock); if (SSL_connect(server->ssl) <= 0) continue; cert = verifytlscert(server->ssl); if (!cert) continue; if (verifyconfcert(cert, server->conf)) { X509_free(cert); break; } X509_free(cert); } debug(DBG_WARN, "tlsconnect: TLS connection to %s port %s up", server->conf->host, server->conf->port); gettimeofday(&server->lastconnecttry, NULL); pthread_mutex_unlock(&server->lock); } unsigned char *radtlsget(SSL *ssl) { int cnt, total, len; unsigned char buf[4], *rad; for (;;) { for (total = 0; total < 4; total += cnt) { cnt = SSL_read(ssl, buf + total, 4 - total); if (cnt <= 0) { debug(DBG_ERR, "radtlsget: connection lost"); if (SSL_get_error(ssl, cnt) == SSL_ERROR_ZERO_RETURN) { /* remote end sent close_notify, send one back */ SSL_shutdown(ssl); } return NULL; } } len = RADLEN(buf); rad = malloc(len); if (!rad) { debug(DBG_ERR, "radtlsget: malloc failed"); continue; } memcpy(rad, buf, 4); for (; total < len; total += cnt) { cnt = SSL_read(ssl, rad + total, len - total); if (cnt <= 0) { debug(DBG_ERR, "radtlsget: connection lost"); if (SSL_get_error(ssl, cnt) == SSL_ERROR_ZERO_RETURN) { /* remote end sent close_notify, send one back */ SSL_shutdown(ssl); } free(rad); return NULL; } } if (total >= 20) break; free(rad); debug(DBG_WARN, "radtlsget: packet smaller than minimum radius size"); } debug(DBG_DBG, "radtlsget: got %d bytes", total); return rad; } int clientradputudp(struct server *server, unsigned char *rad) { size_t len; struct sockaddr_storage sa; struct sockaddr *sap; struct clsrvconf *conf = server->conf; in_port_t *port = NULL; len = RADLEN(rad); if (*rad == RAD_Accounting_Request) { sap = (struct sockaddr *)&sa; memcpy(sap, conf->addrinfo->ai_addr, conf->addrinfo->ai_addrlen); } else sap = conf->addrinfo->ai_addr; switch (sap->sa_family) { case AF_INET: port = &((struct sockaddr_in *)sap)->sin_port; break; case AF_INET6: port = &((struct sockaddr_in6 *)sap)->sin6_port; break; default: return 0; } if (*rad == RAD_Accounting_Request) *port = htons(ntohs(*port) + 1); if (sendto(server->sock, rad, len, 0, sap, conf->addrinfo->ai_addrlen) >= 0) { debug(DBG_DBG, "clienradputudp: sent UDP of length %d to %s port %d", len, conf->host, ntohs(*port)); return 1; } debug(DBG_WARN, "clientradputudp: send failed"); return 0; } int clientradputtls(struct server *server, unsigned char *rad) { int cnt; size_t len; unsigned long error; struct timeval lastconnecttry; struct clsrvconf *conf = server->conf; len = RADLEN(rad); lastconnecttry = server->lastconnecttry; while ((cnt = SSL_write(server->ssl, rad, len)) <= 0) { while ((error = ERR_get_error())) debug(DBG_ERR, "clientradputtls: TLS: %s", ERR_error_string(error, NULL)); tlsconnect(server, &lastconnecttry, "clientradputtls"); lastconnecttry = server->lastconnecttry; } server->connectionok = 1; debug(DBG_DBG, "clientradputtls: Sent %d bytes, Radius packet of length %d to TLS peer %s", cnt, len, conf->host); return 1; } int clientradput(struct server *server, unsigned char *rad) { switch (server->conf->type) { case 'U': return clientradputudp(server, rad); case 'T': return clientradputtls(server, rad); } return 0; } int radsign(unsigned char *rad, unsigned char *sec) { static pthread_mutex_t lock = PTHREAD_MUTEX_INITIALIZER; static unsigned char first = 1; static EVP_MD_CTX mdctx; unsigned int md_len; int result; pthread_mutex_lock(&lock); if (first) { EVP_MD_CTX_init(&mdctx); first = 0; } result = (EVP_DigestInit_ex(&mdctx, EVP_md5(), NULL) && EVP_DigestUpdate(&mdctx, rad, RADLEN(rad)) && EVP_DigestUpdate(&mdctx, sec, strlen((char *)sec)) && EVP_DigestFinal_ex(&mdctx, rad + 4, &md_len) && md_len == 16); pthread_mutex_unlock(&lock); return result; } int validauth(unsigned char *rad, unsigned char *reqauth, unsigned char *sec) { static pthread_mutex_t lock = PTHREAD_MUTEX_INITIALIZER; static unsigned char first = 1; static EVP_MD_CTX mdctx; unsigned char hash[EVP_MAX_MD_SIZE]; unsigned int len; int result; pthread_mutex_lock(&lock); if (first) { EVP_MD_CTX_init(&mdctx); first = 0; } len = RADLEN(rad); result = (EVP_DigestInit_ex(&mdctx, EVP_md5(), NULL) && EVP_DigestUpdate(&mdctx, rad, 4) && EVP_DigestUpdate(&mdctx, reqauth, 16) && (len <= 20 || EVP_DigestUpdate(&mdctx, rad + 20, len - 20)) && EVP_DigestUpdate(&mdctx, sec, strlen((char *)sec)) && EVP_DigestFinal_ex(&mdctx, hash, &len) && len == 16 && !memcmp(hash, rad + 4, 16)); pthread_mutex_unlock(&lock); return result; } int checkmessageauth(unsigned char *rad, uint8_t *authattr, char *secret) { static pthread_mutex_t lock = PTHREAD_MUTEX_INITIALIZER; static unsigned char first = 1; static HMAC_CTX hmacctx; unsigned int md_len; uint8_t auth[16], hash[EVP_MAX_MD_SIZE]; pthread_mutex_lock(&lock); if (first) { HMAC_CTX_init(&hmacctx); first = 0; } memcpy(auth, authattr, 16); memset(authattr, 0, 16); md_len = 0; HMAC_Init_ex(&hmacctx, secret, strlen(secret), EVP_md5(), NULL); HMAC_Update(&hmacctx, rad, RADLEN(rad)); HMAC_Final(&hmacctx, hash, &md_len); memcpy(authattr, auth, 16); if (md_len != 16) { debug(DBG_WARN, "message auth computation failed"); pthread_mutex_unlock(&lock); return 0; } if (memcmp(auth, hash, 16)) { debug(DBG_WARN, "message authenticator, wrong value"); pthread_mutex_unlock(&lock); return 0; } pthread_mutex_unlock(&lock); return 1; } int createmessageauth(unsigned char *rad, unsigned char *authattrval, char *secret) { static pthread_mutex_t lock = PTHREAD_MUTEX_INITIALIZER; static unsigned char first = 1; static HMAC_CTX hmacctx; unsigned int md_len; if (!authattrval) return 1; pthread_mutex_lock(&lock); if (first) { HMAC_CTX_init(&hmacctx); first = 0; } memset(authattrval, 0, 16); md_len = 0; HMAC_Init_ex(&hmacctx, secret, strlen(secret), EVP_md5(), NULL); HMAC_Update(&hmacctx, rad, RADLEN(rad)); HMAC_Final(&hmacctx, authattrval, &md_len); if (md_len != 16) { debug(DBG_WARN, "message auth computation failed"); pthread_mutex_unlock(&lock); return 0; } pthread_mutex_unlock(&lock); return 1; } unsigned char *attrget(unsigned char *attrs, int length, uint8_t type) { while (length > 1) { if (ATTRTYPE(attrs) == type) return attrs; length -= ATTRLEN(attrs); attrs += ATTRLEN(attrs); } return NULL; } void freerqdata(struct request *rq) { if (rq->origusername) free(rq->origusername); if (rq->buf) free(rq->buf); } void sendrq(struct server *to, struct request *rq) { int i; uint8_t *attr; pthread_mutex_lock(&to->newrq_mutex); /* might simplify if only try nextid, might be ok */ for (i = to->nextid; i < MAX_REQUESTS; i++) if (!to->requests[i].buf) break; if (i == MAX_REQUESTS) { for (i = 0; i < to->nextid; i++) if (!to->requests[i].buf) break; if (i == to->nextid) { debug(DBG_WARN, "sendrq: no room in queue, dropping request"); freerqdata(rq); goto exit; } } rq->buf[1] = (char)i; attr = attrget(rq->buf + 20, RADLEN(rq->buf) - 20, RAD_Attr_Message_Authenticator); if (attr && !createmessageauth(rq->buf, ATTRVAL(attr), to->conf->secret)) { freerqdata(rq); goto exit; } if (*(uint8_t *)rq->buf == RAD_Accounting_Request) { if (!radsign(rq->buf, (unsigned char *)to->conf->secret)) { debug(DBG_WARN, "sendrq: failed to sign Accounting-Request message"); freerqdata(rq); goto exit; } } debug(DBG_DBG, "sendrq: inserting packet with id %d in queue for %s", i, to->conf->host); to->requests[i] = *rq; to->nextid = i + 1; if (!to->newrq) { to->newrq = 1; debug(DBG_DBG, "sendrq: signalling client writer"); pthread_cond_signal(&to->newrq_cond); } exit: pthread_mutex_unlock(&to->newrq_mutex); } void sendreply(struct client *to, unsigned char *buf, struct sockaddr_storage *tosa) { struct reply *reply; uint8_t first; if (!radsign(buf, (unsigned char *)to->conf->secret)) { free(buf); debug(DBG_WARN, "sendreply: failed to sign message"); return; } reply = malloc(sizeof(struct reply)); if (!reply) { free(buf); debug(DBG_ERR, "sendreply: malloc failed"); return; } memset(reply, 0, sizeof(struct reply)); reply->buf = buf; if (tosa) reply->tosa = *tosa; pthread_mutex_lock(&to->replyq->mutex); first = list_first(to->replyq->replies) == NULL; if (!list_push(to->replyq->replies, reply)) { pthread_mutex_unlock(&to->replyq->mutex); free(reply); free(buf); debug(DBG_ERR, "sendreply: malloc failed"); return; } if (first) { debug(DBG_DBG, "signalling server writer"); pthread_cond_signal(&to->replyq->cond); } pthread_mutex_unlock(&to->replyq->mutex); } int pwdencrypt(uint8_t *in, uint8_t len, char *shared, uint8_t sharedlen, uint8_t *auth) { static pthread_mutex_t lock = PTHREAD_MUTEX_INITIALIZER; static unsigned char first = 1; static EVP_MD_CTX mdctx; unsigned char hash[EVP_MAX_MD_SIZE], *input; unsigned int md_len; uint8_t i, offset = 0, out[128]; pthread_mutex_lock(&lock); if (first) { EVP_MD_CTX_init(&mdctx); first = 0; } input = auth; for (;;) { if (!EVP_DigestInit_ex(&mdctx, EVP_md5(), NULL) || !EVP_DigestUpdate(&mdctx, (uint8_t *)shared, sharedlen) || !EVP_DigestUpdate(&mdctx, input, 16) || !EVP_DigestFinal_ex(&mdctx, hash, &md_len) || md_len != 16) { pthread_mutex_unlock(&lock); return 0; } for (i = 0; i < 16; i++) out[offset + i] = hash[i] ^ in[offset + i]; input = out + offset - 16; offset += 16; if (offset == len) break; } memcpy(in, out, len); pthread_mutex_unlock(&lock); return 1; } int pwddecrypt(uint8_t *in, uint8_t len, char *shared, uint8_t sharedlen, uint8_t *auth) { static pthread_mutex_t lock = PTHREAD_MUTEX_INITIALIZER; static unsigned char first = 1; static EVP_MD_CTX mdctx; unsigned char hash[EVP_MAX_MD_SIZE], *input; unsigned int md_len; uint8_t i, offset = 0, out[128]; pthread_mutex_lock(&lock); if (first) { EVP_MD_CTX_init(&mdctx); first = 0; } input = auth; for (;;) { if (!EVP_DigestInit_ex(&mdctx, EVP_md5(), NULL) || !EVP_DigestUpdate(&mdctx, (uint8_t *)shared, sharedlen) || !EVP_DigestUpdate(&mdctx, input, 16) || !EVP_DigestFinal_ex(&mdctx, hash, &md_len) || md_len != 16) { pthread_mutex_unlock(&lock); return 0; } for (i = 0; i < 16; i++) out[offset + i] = hash[i] ^ in[offset + i]; input = in + offset; offset += 16; if (offset == len) break; } memcpy(in, out, len); pthread_mutex_unlock(&lock); return 1; } int msmppencrypt(uint8_t *text, uint8_t len, uint8_t *shared, uint8_t sharedlen, uint8_t *auth, uint8_t *salt) { static pthread_mutex_t lock = PTHREAD_MUTEX_INITIALIZER; static unsigned char first = 1; static EVP_MD_CTX mdctx; unsigned char hash[EVP_MAX_MD_SIZE]; unsigned int md_len; uint8_t i, offset; pthread_mutex_lock(&lock); if (first) { EVP_MD_CTX_init(&mdctx); first = 0; } #if 0 printfchars(NULL, "msppencrypt auth in", "%02x ", auth, 16); printfchars(NULL, "msppencrypt salt in", "%02x ", salt, 2); printfchars(NULL, "msppencrypt in", "%02x ", text, len); #endif if (!EVP_DigestInit_ex(&mdctx, EVP_md5(), NULL) || !EVP_DigestUpdate(&mdctx, shared, sharedlen) || !EVP_DigestUpdate(&mdctx, auth, 16) || !EVP_DigestUpdate(&mdctx, salt, 2) || !EVP_DigestFinal_ex(&mdctx, hash, &md_len)) { pthread_mutex_unlock(&lock); return 0; } #if 0 printfchars(NULL, "msppencrypt hash", "%02x ", hash, 16); #endif for (i = 0; i < 16; i++) text[i] ^= hash[i]; for (offset = 16; offset < len; offset += 16) { #if 0 printf("text + offset - 16 c(%d): ", offset / 16); printfchars(NULL, NULL, "%02x ", text + offset - 16, 16); #endif if (!EVP_DigestInit_ex(&mdctx, EVP_md5(), NULL) || !EVP_DigestUpdate(&mdctx, shared, sharedlen) || !EVP_DigestUpdate(&mdctx, text + offset - 16, 16) || !EVP_DigestFinal_ex(&mdctx, hash, &md_len) || md_len != 16) { pthread_mutex_unlock(&lock); return 0; } #if 0 printfchars(NULL, "msppencrypt hash", "%02x ", hash, 16); #endif for (i = 0; i < 16; i++) text[offset + i] ^= hash[i]; } #if 0 printfchars(NULL, "msppencrypt out", "%02x ", text, len); #endif pthread_mutex_unlock(&lock); return 1; } int msmppdecrypt(uint8_t *text, uint8_t len, uint8_t *shared, uint8_t sharedlen, uint8_t *auth, uint8_t *salt) { static pthread_mutex_t lock = PTHREAD_MUTEX_INITIALIZER; static unsigned char first = 1; static EVP_MD_CTX mdctx; unsigned char hash[EVP_MAX_MD_SIZE]; unsigned int md_len; uint8_t i, offset; char plain[255]; pthread_mutex_lock(&lock); if (first) { EVP_MD_CTX_init(&mdctx); first = 0; } #if 0 printfchars(NULL, "msppdecrypt auth in", "%02x ", auth, 16); printfchars(NULL, "msppdecrypt salt in", "%02x ", salt, 2); printfchars(NULL, "msppdecrypt in", "%02x ", text, len); #endif if (!EVP_DigestInit_ex(&mdctx, EVP_md5(), NULL) || !EVP_DigestUpdate(&mdctx, shared, sharedlen) || !EVP_DigestUpdate(&mdctx, auth, 16) || !EVP_DigestUpdate(&mdctx, salt, 2) || !EVP_DigestFinal_ex(&mdctx, hash, &md_len)) { pthread_mutex_unlock(&lock); return 0; } #if 0 printfchars(NULL, "msppdecrypt hash", "%02x ", hash, 16); #endif for (i = 0; i < 16; i++) plain[i] = text[i] ^ hash[i]; for (offset = 16; offset < len; offset += 16) { #if 0 printf("text + offset - 16 c(%d): ", offset / 16); printfchars(NULL, NULL, "%02x ", text + offset - 16, 16); #endif if (!EVP_DigestInit_ex(&mdctx, EVP_md5(), NULL) || !EVP_DigestUpdate(&mdctx, shared, sharedlen) || !EVP_DigestUpdate(&mdctx, text + offset - 16, 16) || !EVP_DigestFinal_ex(&mdctx, hash, &md_len) || md_len != 16) { pthread_mutex_unlock(&lock); return 0; } #if 0 printfchars(NULL, "msppdecrypt hash", "%02x ", hash, 16); #endif for (i = 0; i < 16; i++) plain[offset + i] = text[offset + i] ^ hash[i]; } memcpy(text, plain, len); #if 0 printfchars(NULL, "msppdecrypt out", "%02x ", text, len); #endif pthread_mutex_unlock(&lock); return 1; } struct realm *id2realm(char *id, uint8_t len) { struct list_node *entry; struct realm *realm; for (entry = list_first(realms); entry; entry = list_next(entry)) { realm = (struct realm *)entry->data; if (!regexec(&realm->regex, id, 0, NULL, 0)) { debug(DBG_DBG, "found matching realm: %s", realm->name); return realm; } } return NULL; } int rqinqueue(struct server *to, struct client *from, uint8_t id, uint8_t code) { struct request *rq = to->requests, *end; pthread_mutex_lock(&to->newrq_mutex); for (end = rq + MAX_REQUESTS; rq < end; rq++) if (rq->buf && !rq->received && rq->origid == id && rq->from == from && *rq->buf == code) break; pthread_mutex_unlock(&to->newrq_mutex); return rq < end; } int attrvalidate(unsigned char *attrs, int length) { while (length > 1) { if (ATTRLEN(attrs) < 2) { debug(DBG_WARN, "attrvalidate: invalid attribute length %d", ATTRLEN(attrs)); return 0; } length -= ATTRLEN(attrs); if (length < 0) { debug(DBG_WARN, "attrvalidate: attribute length %d exceeds packet length", ATTRLEN(attrs)); return 0; } attrs += ATTRLEN(attrs); } if (length) debug(DBG_WARN, "attrvalidate: malformed packet? remaining byte after last attribute"); return 1; } int pwdrecrypt(uint8_t *pwd, uint8_t len, char *oldsecret, char *newsecret, uint8_t *oldauth, uint8_t *newauth) { if (len < 16 || len > 128 || len % 16) { debug(DBG_WARN, "pwdrecrypt: invalid password length"); return 0; } if (!pwddecrypt(pwd, len, oldsecret, strlen(oldsecret), oldauth)) { debug(DBG_WARN, "pwdrecrypt: cannot decrypt password"); return 0; } #ifdef DEBUG printfchars(NULL, "pwdrecrypt: password", "%02x ", pwd, len); #endif if (!pwdencrypt(pwd, len, newsecret, strlen(newsecret), newauth)) { debug(DBG_WARN, "pwdrecrypt: cannot encrypt password"); return 0; } return 1; } int msmpprecrypt(uint8_t *msmpp, uint8_t len, char *oldsecret, char *newsecret, unsigned char *oldauth, char *newauth) { if (len < 18) return 0; if (!msmppdecrypt(msmpp + 2, len - 2, (unsigned char *)oldsecret, strlen(oldsecret), oldauth, msmpp)) { debug(DBG_WARN, "msmpprecrypt: failed to decrypt msppe key"); return 0; } if (!msmppencrypt(msmpp + 2, len - 2, (unsigned char *)newsecret, strlen(newsecret), (unsigned char *)newauth, msmpp)) { debug(DBG_WARN, "msmpprecrypt: failed to encrypt msppe key"); return 0; } return 1; } int msmppe(unsigned char *attrs, int length, uint8_t type, char *attrtxt, struct request *rq, char *oldsecret, char *newsecret) { unsigned char *attr; for (attr = attrs; (attr = attrget(attr, length - (attr - attrs), type)); attr += ATTRLEN(attr)) { debug(DBG_DBG, "msmppe: Got %s", attrtxt); if (!msmpprecrypt(ATTRVAL(attr), ATTRVALLEN(attr), oldsecret, newsecret, rq->buf + 4, rq->origauth)) return 0; } return 1; } int findvendorsubattr(uint32_t *attrs, uint32_t vendor, uint8_t subattr) { if (!attrs) return 0; for (; attrs[0]; attrs += 2) if (attrs[0] == vendor && attrs[1] == subattr) return 1; return 0; } int dovendorrewrite(uint8_t *attrs, uint16_t length, uint32_t *removevendorattrs) { uint8_t alen, sublen, rmlen = 0; uint32_t vendor = *(uint32_t *)ATTRVAL(attrs); uint8_t *subattrs; if (!removevendorattrs) return 0; while (*removevendorattrs && *removevendorattrs != vendor) removevendorattrs += 2; if (!*removevendorattrs) return 0; alen = ATTRLEN(attrs); if (findvendorsubattr(removevendorattrs, vendor, -1)) { /* remove entire vendor attribute */ memmove(attrs, attrs + alen, length - alen); return alen; } sublen = alen - 4; subattrs = ATTRVAL(attrs) + 4; if (!attrvalidate(subattrs, sublen)) { debug(DBG_WARN, "dovendorrewrite: vendor attribute validation failed, no rewrite"); return 0; } length -= 6; while (sublen > 1) { alen = ATTRLEN(subattrs); sublen -= alen; length -= alen; if (findvendorsubattr(removevendorattrs, vendor, ATTRTYPE(subattrs))) { memmove(subattrs, subattrs + alen, length); rmlen += alen; } else subattrs += alen; } ATTRLEN(attrs) -= rmlen; return rmlen; } void dorewrite(uint8_t *buf, struct rewrite *rewrite) { uint8_t *attrs, alen; uint16_t len, rmlen = 0; if (!rewrite || (!rewrite->removeattrs && !rewrite->removevendorattrs)) return; len = RADLEN(buf) - 20; attrs = buf + 20; while (len > 1) { alen = ATTRLEN(attrs); len -= alen; if (rewrite->removeattrs && strchr((char *)rewrite->removeattrs, ATTRTYPE(attrs))) { memmove(attrs, attrs + alen, len); rmlen += alen; } else if (ATTRTYPE(attrs) == RAD_Attr_Vendor_Specific && rewrite->removevendorattrs) rmlen += dovendorrewrite(attrs, len, rewrite->removevendorattrs); else attrs += alen; } if (rmlen) ((uint16_t *)buf)[1] = htons(RADLEN(buf) - rmlen); } /* returns a pointer to the resized attribute value */ uint8_t *resizeattr(uint8_t **buf, uint8_t newvallen, uint8_t type) { uint8_t *attrs, *attr, vallen; uint16_t len; unsigned char *new; len = RADLEN(*buf) - 20; attrs = *buf + 20; attr = attrget(attrs, len, type); if (!attr) return NULL; vallen = ATTRVALLEN(attr); if (vallen == newvallen) return attr + 2; len += newvallen - vallen; if (newvallen > vallen) { new = realloc(*buf, len + 20); if (!new) { debug(DBG_ERR, "resizeattr: malloc failed"); return NULL; } if (new != *buf) { attr += new - *buf; attrs = new + 20; *buf = new; } } memmove(attr + 2 + newvallen, attr + 2 + vallen, len - (attr - attrs + newvallen)); attr[1] = newvallen + 2; ((uint16_t *)*buf)[1] = htons(len + 20); return attr + 2; } int rewriteusername(struct request *rq, char *in) { size_t nmatch = 10, reslen = 0, start = 0; regmatch_t pmatch[10], *pfield; int i; unsigned char *result; char *out = rq->from->conf->rewriteattrreplacement; if (regexec(rq->from->conf->rewriteattrregex, in, nmatch, pmatch, 0)) { debug(DBG_DBG, "rewriteattr: username not matching, no rewrite"); return 1; } rq->origusername = stringcopy(in, 0); if (!rq->origusername) return 0; for (i = start; out[i]; i++) { if (out[i] == '\\' && out[i + 1] >= '1' && out[i + 1] <= '9') { pfield = &pmatch[out[i + 1] - '0']; if (pfield->rm_so >= 0) { reslen += i - start + pfield->rm_eo - pfield->rm_so; start = i + 2; } i++; } } reslen += i - start; result = resizeattr(&rq->buf, reslen, RAD_Attr_User_Name); if (!result) return 0; start = 0; reslen = 0; for (i = start; out[i]; i++) { if (out[i] == '\\' && out[i + 1] >= '1' && out[i + 1] <= '9') { pfield = &pmatch[out[i + 1] - '0']; if (pfield->rm_so >= 0) { memcpy(result + reslen, out + start, i - start); reslen += i - start; memcpy(result + reslen, in + pfield->rm_so, pfield->rm_eo - pfield->rm_so); reslen += pfield->rm_eo - pfield->rm_so; start = i + 2; } i++; } } memcpy(result + reslen, out + start, i - start); reslen += i - start; memcpy(in, result, reslen); in[reslen] = '\0'; return 1; } const char *radmsgtype2string(uint8_t code) { static const char *rad_msg_names[] = { "", "Access-Request", "Access-Accept", "Access-Reject", "Accounting-Request", "Accounting-Response", "", "", "", "", "", "Access-Challenge", "Status-Server", "Status-Client" }; return code < 14 && *rad_msg_names[code] ? rad_msg_names[code] : "Unknown"; } void char2hex(char *h, unsigned char c) { static const char hexdigits[] = { '0', '1', '2', '3', '4', '5', '6', '7', '8', '9', 'a', 'b', 'c', 'd', 'e', 'f' }; h[0] = hexdigits[c / 16]; h[1] = hexdigits[c % 16]; return; } char *radattr2ascii(char *ascii, size_t len, unsigned char *attr) { int i, l; char *s, *d; if (!attr || len == 1) { *ascii = '\0'; return ascii; } l = ATTRVALLEN(attr); s = (char *)ATTRVAL(attr); d = ascii; for (i = 0; i < l; i++) { if (s[i] > 31 && s[i] < 127) { *d++ = s[i]; if (d - ascii == len - 1) break; } else { if (d - ascii > len - 4) break; *d++ = '%'; char2hex(d, s[i]); d += 2; if (d - ascii == len - 1) break; } } *d = '\0'; return ascii; } void acclog(unsigned char *attrs, int length, char *host) { unsigned char *attr; char username[760]; attr = attrget(attrs, length, RAD_Attr_User_Name); if (!attr) { debug(DBG_INFO, "acclog: accounting-request from %s without username attribute", host); return; } radattr2ascii(username, sizeof(username), attr); debug(DBG_INFO, "acclog: accounting-request from %s with username: %s", host, username); } void respondaccounting(struct request *rq) { unsigned char *resp; resp = malloc(20); if (!resp) { debug(DBG_ERR, "respondstatusserver: malloc failed"); return; } memcpy(resp, rq->buf, 20); resp[0] = RAD_Accounting_Response; resp[2] = 0; resp[3] = 20; debug(DBG_DBG, "respondaccounting: responding to %s", rq->from->conf->host); sendreply(rq->from, resp, rq->from->conf->type == 'U' ? &rq->fromsa : NULL); } void respondstatusserver(struct request *rq) { unsigned char *resp; resp = malloc(20); if (!resp) { debug(DBG_ERR, "respondstatusserver: malloc failed"); return; } memcpy(resp, rq->buf, 20); resp[0] = RAD_Access_Accept; resp[2] = 0; resp[3] = 20; debug(DBG_DBG, "respondstatusserver: responding to %s", rq->from->conf->host); sendreply(rq->from, resp, rq->from->conf->type == 'U' ? &rq->fromsa : NULL); } void respondreject(struct request *rq, char *message) { unsigned char *resp; int len = 20; if (message && *message) len += 2 + strlen(message); resp = malloc(len); if (!resp) { debug(DBG_ERR, "respondreject: malloc failed"); return; } memcpy(resp, rq->buf, 20); resp[0] = RAD_Access_Reject; *(uint16_t *)(resp + 2) = htons(len); if (message && *message) { resp[20] = RAD_Attr_Reply_Message; resp[21] = len - 20; memcpy(resp + 22, message, len - 22); } sendreply(rq->from, resp, rq->from->conf->type == 'U' ? &rq->fromsa : NULL); } struct server *chooseserver(struct list *srvconfs) { struct list_node *entry; struct server *server, *best = NULL, *first = NULL; for (entry = list_first(srvconfs); entry; entry = list_next(entry)) { server = ((struct clsrvconf *)entry->data)->servers; if (!first) first = server; if (!server->connectionok) continue; if (!server->lostrqs) return server; if (!best) { best = server; continue; } if (server->lostrqs < best->lostrqs) best = server; } return best ? best : first; } void radsrv(struct request *rq) { uint8_t code, id, *auth, *attrs, *attr; uint16_t len; struct server *to = NULL; char username[254], userascii[760]; unsigned char newauth[16]; struct realm *realm = NULL; code = *(uint8_t *)rq->buf; id = *(uint8_t *)(rq->buf + 1); len = RADLEN(rq->buf); auth = (uint8_t *)(rq->buf + 4); debug(DBG_DBG, "radsrv: code %d, id %d, length %d", code, id, len); if (code != RAD_Access_Request && code != RAD_Status_Server && code != RAD_Accounting_Request) { debug(DBG_INFO, "radsrv: server currently accepts only access-requests, accounting-requests and status-server, ignoring"); goto exit; } len -= 20; attrs = rq->buf + 20; if (!attrvalidate(attrs, len)) { debug(DBG_WARN, "radsrv: attribute validation failed, ignoring packet"); goto exit; } attr = attrget(attrs, len, RAD_Attr_Message_Authenticator); if (attr && (ATTRVALLEN(attr) != 16 || !checkmessageauth(rq->buf, ATTRVAL(attr), rq->from->conf->secret))) { debug(DBG_WARN, "radsrv: message authentication failed"); goto exit; } if (code == RAD_Status_Server) { respondstatusserver(rq); goto exit; } /* below: code == RAD_Access_Request || code == RAD_Accounting_Request */ if (code == RAD_Accounting_Request) { memset(newauth, 0, 16); if (!validauth(rq->buf, newauth, (unsigned char *)rq->from->conf->secret)) { debug(DBG_WARN, "radsrv: Accounting-Request message authentication failed"); goto exit; } } if (rq->from->conf->rewrite) { dorewrite(rq->buf, rq->from->conf->rewrite); len = RADLEN(rq->buf) - 20; } attr = attrget(attrs, len, RAD_Attr_User_Name); if (!attr) { if (code == RAD_Accounting_Request) { acclog(attrs, len, rq->from->conf->host); respondaccounting(rq); } else debug(DBG_WARN, "radsrv: ignoring access request, no username attribute"); goto exit; } memcpy(username, ATTRVAL(attr), ATTRVALLEN(attr)); username[ATTRVALLEN(attr)] = '\0'; radattr2ascii(userascii, sizeof(userascii), attr); if (rq->from->conf->rewriteattrregex) { if (!rewriteusername(rq, username)) { debug(DBG_WARN, "radsrv: username malloc failed, ignoring request"); goto exit; } len = RADLEN(rq->buf) - 20; auth = (uint8_t *)(rq->buf + 4); attrs = rq->buf + 20; } debug(DBG_DBG, "%s with username: %s", radmsgtype2string(code), userascii); realm = id2realm(username, strlen(username)); if (!realm) { debug(DBG_INFO, "radsrv: ignoring request, don't know where to send it"); goto exit; } to = chooseserver(code == RAD_Access_Request ? realm->srvconfs : realm->accsrvconfs); if (!to) { if (realm->message && code == RAD_Access_Request) { debug(DBG_INFO, "radsrv: sending reject to %s for %s", rq->from->conf->host, userascii); respondreject(rq, realm->message); } else if (realm->accresp && code == RAD_Accounting_Request) { acclog(attrs, len, rq->from->conf->host); respondaccounting(rq); } goto exit; } if (options.loopprevention && !strcmp(rq->from->conf->name, to->conf->name)) { debug(DBG_INFO, "radsrv: Loop prevented, not forwarding request from client %s to server %s, discarding", rq->from->conf->name, to->conf->name); goto exit; } if (rqinqueue(to, rq->from, id, code)) { debug(DBG_INFO, "radsrv: already got %s from host %s with id %d, ignoring", radmsgtype2string(code), rq->from->conf->host, id); goto exit; } if (code != RAD_Accounting_Request) { if (!RAND_bytes(newauth, 16)) { debug(DBG_WARN, "radsrv: failed to generate random auth"); goto exit; } } #ifdef DEBUG printfchars(NULL, "auth", "%02x ", auth, 16); #endif attr = attrget(attrs, len, RAD_Attr_User_Password); if (attr) { debug(DBG_DBG, "radsrv: found userpwdattr with value length %d", ATTRVALLEN(attr)); if (!pwdrecrypt(ATTRVAL(attr), ATTRVALLEN(attr), rq->from->conf->secret, to->conf->secret, auth, newauth)) goto exit; } attr = attrget(attrs, len, RAD_Attr_Tunnel_Password); if (attr) { debug(DBG_DBG, "radsrv: found tunnelpwdattr with value length %d", ATTRVALLEN(attr)); if (!pwdrecrypt(ATTRVAL(attr), ATTRVALLEN(attr), rq->from->conf->secret, to->conf->secret, auth, newauth)) goto exit; } rq->origid = id; memcpy(rq->origauth, auth, 16); memcpy(auth, newauth, 16); sendrq(to, rq); return; exit: freerqdata(rq); } int replyh(struct server *server, unsigned char *buf) { struct client *from; struct request *rq; int i, len, sublen; unsigned char *messageauth, *subattrs, *attrs, *attr, *username; struct sockaddr_storage fromsa; char tmp[760], stationid[760]; server->connectionok = 1; server->lostrqs = 0; i = buf[1]; /* i is the id */ if (*buf != RAD_Access_Accept && *buf != RAD_Access_Reject && *buf != RAD_Access_Challenge && *buf != RAD_Accounting_Response) { debug(DBG_INFO, "replyh: discarding message type %s, accepting only access accept, access reject, access challenge and accounting response messages", radmsgtype2string(*buf)); return 0; } debug(DBG_DBG, "got %s message with id %d", radmsgtype2string(*buf), i); rq = server->requests + i; pthread_mutex_lock(&server->newrq_mutex); if (!rq->buf || !rq->tries) { pthread_mutex_unlock(&server->newrq_mutex); debug(DBG_INFO, "replyh: no matching request sent with this id, ignoring reply"); return 0; } if (rq->received) { pthread_mutex_unlock(&server->newrq_mutex); debug(DBG_INFO, "replyh: already received, ignoring reply"); return 0; } if (!validauth(buf, rq->buf + 4, (unsigned char *)server->conf->secret)) { pthread_mutex_unlock(&server->newrq_mutex); debug(DBG_WARN, "replyh: invalid auth, ignoring reply"); return 0; } len = RADLEN(buf) - 20; attrs = buf + 20; if (!attrvalidate(attrs, len)) { pthread_mutex_unlock(&server->newrq_mutex); debug(DBG_WARN, "replyh: attribute validation failed, ignoring reply"); return 0; } /* Message Authenticator */ messageauth = attrget(attrs, len, RAD_Attr_Message_Authenticator); if (messageauth) { if (ATTRVALLEN(messageauth) != 16) { pthread_mutex_unlock(&server->newrq_mutex); debug(DBG_WARN, "replyh: illegal message auth attribute length, ignoring reply"); return 0; } memcpy(tmp, buf + 4, 16); memcpy(buf + 4, rq->buf + 4, 16); if (!checkmessageauth(buf, ATTRVAL(messageauth), server->conf->secret)) { pthread_mutex_unlock(&server->newrq_mutex); debug(DBG_WARN, "replyh: message authentication failed, ignoring reply"); return 0; } memcpy(buf + 4, tmp, 16); debug(DBG_DBG, "replyh: message auth ok"); } if (*rq->buf == RAD_Status_Server) { rq->received = 1; pthread_mutex_unlock(&server->newrq_mutex); debug(DBG_DBG, "replyh: got status server response from %s", server->conf->host); return 0; } from = rq->from; if (!from) { pthread_mutex_unlock(&server->newrq_mutex); debug(DBG_INFO, "replyh: client gone, ignoring reply"); return 0; } if (server->conf->rewrite) { dorewrite(buf, server->conf->rewrite); len = RADLEN(buf) - 20; } /* MS MPPE */ for (attr = attrs; (attr = attrget(attr, len - (attr - attrs), RAD_Attr_Vendor_Specific)); attr += ATTRLEN(attr)) { if (ATTRVALLEN(attr) <= 4) break; if (attr[2] != 0 || attr[3] != 0 || attr[4] != 1 || attr[5] != 55) /* 311 == MS */ continue; sublen = ATTRVALLEN(attr) - 4; subattrs = ATTRVAL(attr) + 4; if (!attrvalidate(subattrs, sublen) || !msmppe(subattrs, sublen, RAD_VS_ATTR_MS_MPPE_Send_Key, "MS MPPE Send Key", rq, server->conf->secret, from->conf->secret) || !msmppe(subattrs, sublen, RAD_VS_ATTR_MS_MPPE_Recv_Key, "MS MPPE Recv Key", rq, server->conf->secret, from->conf->secret)) break; } if (attr) { pthread_mutex_unlock(&server->newrq_mutex); debug(DBG_WARN, "replyh: MS attribute handling failed, ignoring reply"); return 0; } if (*buf == RAD_Access_Accept || *buf == RAD_Access_Reject || *buf == RAD_Accounting_Response) { attr = attrget(rq->buf + 20, RADLEN(rq->buf) - 20, RAD_Attr_User_Name); if (attr) { radattr2ascii(tmp, sizeof(tmp), attr); attr = attrget(rq->buf + 20, RADLEN(rq->buf) - 20, RAD_Attr_Calling_Station_Id); if (attr) { radattr2ascii(stationid, sizeof(stationid), attr); debug(DBG_INFO, "%s for user %s stationid %s from %s", radmsgtype2string(*buf), tmp, stationid, server->conf->host); } else debug(DBG_INFO, "%s for user %s from %s", radmsgtype2string(*buf), tmp, server->conf->host); } } buf[1] = (char)rq->origid; memcpy(buf + 4, rq->origauth, 16); #ifdef DEBUG printfchars(NULL, "origauth/buf+4", "%02x ", buf + 4, 16); #endif if (rq->origusername) { username = resizeattr(&buf, strlen(rq->origusername), RAD_Attr_User_Name); if (!username) { pthread_mutex_unlock(&server->newrq_mutex); debug(DBG_WARN, "replyh: malloc failed, ignoring reply"); return 0; } memcpy(username, rq->origusername, strlen(rq->origusername)); len = RADLEN(buf) - 20; attrs = buf + 20; if (messageauth) messageauth = attrget(attrs, len, RAD_Attr_Message_Authenticator); } if (messageauth) { if (!createmessageauth(buf, ATTRVAL(messageauth), from->conf->secret)) { pthread_mutex_unlock(&server->newrq_mutex); debug(DBG_WARN, "replyh: failed to create authenticator, malloc failed?, ignoring reply"); return 0; } debug(DBG_DBG, "replyh: computed messageauthattr"); } if (from->conf->type == 'U') fromsa = rq->fromsa; /* once we set received = 1, rq may be reused */ rq->received = 1; debug(DBG_INFO, "replyh: passing reply to client %s", from->conf->name); sendreply(from, buf, from->conf->type == 'U' ? &fromsa : NULL); pthread_mutex_unlock(&server->newrq_mutex); return 1; } void *udpclientrd(void *arg) { struct server *server; unsigned char *buf; int *s = (int *)arg; for (;;) { server = NULL; buf = radudpget(*s, NULL, &server, NULL); if (!replyh(server, buf)) free(buf); } } void *tlsclientrd(void *arg) { struct server *server = (struct server *)arg; unsigned char *buf; struct timeval lastconnecttry; for (;;) { /* yes, lastconnecttry is really necessary */ lastconnecttry = server->lastconnecttry; buf = radtlsget(server->ssl); if (!buf) { tlsconnect(server, &lastconnecttry, "clientrd"); continue; } if (!replyh(server, buf)) free(buf); } } void *clientwr(void *arg) { struct server *server = (struct server *)arg; struct request *rq; pthread_t tlsclientrdth; int i; uint8_t rnd; struct timeval now, lastsend; struct timespec timeout; struct request statsrvrq; unsigned char statsrvbuf[38]; memset(&timeout, 0, sizeof(struct timespec)); if (server->conf->statusserver) { memset(&statsrvrq, 0, sizeof(struct request)); memset(statsrvbuf, 0, sizeof(statsrvbuf)); statsrvbuf[0] = RAD_Status_Server; statsrvbuf[3] = 38; statsrvbuf[20] = RAD_Attr_Message_Authenticator; statsrvbuf[21] = 18; gettimeofday(&lastsend, NULL); } if (server->conf->type == 'U') { server->connectionok = 1; } else { tlsconnect(server, NULL, "new client"); server->connectionok = 1; if (pthread_create(&tlsclientrdth, NULL, tlsclientrd, (void *)server)) debugx(1, DBG_ERR, "clientwr: pthread_create failed"); } for (;;) { pthread_mutex_lock(&server->newrq_mutex); if (!server->newrq) { gettimeofday(&now, NULL); if (server->conf->statusserver) { /* random 0-7 seconds */ RAND_bytes(&rnd, 1); rnd /= 32; if (!timeout.tv_sec || timeout.tv_sec > lastsend.tv_sec + STATUS_SERVER_PERIOD + rnd) timeout.tv_sec = lastsend.tv_sec + STATUS_SERVER_PERIOD + rnd; } if (timeout.tv_sec) { debug(DBG_DBG, "clientwr: waiting up to %ld secs for new request", timeout.tv_sec - now.tv_sec); pthread_cond_timedwait(&server->newrq_cond, &server->newrq_mutex, &timeout); timeout.tv_sec = 0; } else { debug(DBG_DBG, "clientwr: waiting for new request"); pthread_cond_wait(&server->newrq_cond, &server->newrq_mutex); } } if (server->newrq) { debug(DBG_DBG, "clientwr: got new request"); server->newrq = 0; } else debug(DBG_DBG, "clientwr: request timer expired, processing request queue"); pthread_mutex_unlock(&server->newrq_mutex); for (i = 0; i < MAX_REQUESTS; i++) { pthread_mutex_lock(&server->newrq_mutex); while (i < MAX_REQUESTS && !server->requests[i].buf) i++; if (i == MAX_REQUESTS) { pthread_mutex_unlock(&server->newrq_mutex); break; } rq = server->requests + i; if (rq->received) { debug(DBG_DBG, "clientwr: packet %d in queue is marked as received", i); if (rq->buf) { debug(DBG_DBG, "clientwr: freeing received packet %d from queue", i); freerqdata(rq); /* setting this to NULL means that it can be reused */ rq->buf = NULL; } pthread_mutex_unlock(&server->newrq_mutex); continue; } gettimeofday(&now, NULL); if (now.tv_sec < rq->expiry.tv_sec) { if (!timeout.tv_sec || rq->expiry.tv_sec < timeout.tv_sec) timeout.tv_sec = rq->expiry.tv_sec; pthread_mutex_unlock(&server->newrq_mutex); continue; } if (rq->tries == (*rq->buf == RAD_Status_Server || server->conf->type == 'T' ? 1 : server->conf->retrycount + 1)) { debug(DBG_DBG, "clientwr: removing expired packet from queue"); if (server->conf->statusserver) { if (*rq->buf == RAD_Status_Server) { debug(DBG_WARN, "clientwr: no status server response, %s dead?", server->conf->host); if (server->lostrqs < 255) server->lostrqs++; } } else { debug(DBG_WARN, "clientwr: no server response, %s dead?", server->conf->host); if (server->lostrqs < 255) server->lostrqs++; } freerqdata(rq); /* setting this to NULL means that it can be reused */ rq->buf = NULL; pthread_mutex_unlock(&server->newrq_mutex); continue; } pthread_mutex_unlock(&server->newrq_mutex); rq->expiry.tv_sec = now.tv_sec + (*rq->buf == RAD_Status_Server || server->conf->type == 'T' ? server->conf->retryinterval * (server->conf->retrycount + 1) : server->conf->retryinterval); if (!timeout.tv_sec || rq->expiry.tv_sec < timeout.tv_sec) timeout.tv_sec = rq->expiry.tv_sec; rq->tries++; clientradput(server, server->requests[i].buf); gettimeofday(&lastsend, NULL); } if (server->conf->statusserver) { gettimeofday(&now, NULL); if (now.tv_sec - lastsend.tv_sec >= STATUS_SERVER_PERIOD) { if (!RAND_bytes(statsrvbuf + 4, 16)) { debug(DBG_WARN, "clientwr: failed to generate random auth"); continue; } statsrvrq.buf = malloc(sizeof(statsrvbuf)); if (!statsrvrq.buf) { debug(DBG_ERR, "clientwr: malloc failed"); continue; } memcpy(statsrvrq.buf, statsrvbuf, sizeof(statsrvbuf)); debug(DBG_DBG, "clientwr: sending status server to %s", server->conf->host); lastsend.tv_sec = now.tv_sec; sendrq(server, &statsrvrq); } } } } void *udpserverwr(void *arg) { struct replyq *replyq = udp_server_replyq; struct reply *reply; for (;;) { pthread_mutex_lock(&replyq->mutex); while (!(reply = (struct reply *)list_shift(replyq->replies))) { debug(DBG_DBG, "udp server writer, waiting for signal"); pthread_cond_wait(&replyq->cond, &replyq->mutex); debug(DBG_DBG, "udp server writer, got signal"); } pthread_mutex_unlock(&replyq->mutex); if (sendto(*(uint8_t *)reply->buf == RAD_Accounting_Response ? udp_accserver_sock : udp_server_sock, reply->buf, RADLEN(reply->buf), 0, (struct sockaddr *)&reply->tosa, SOCKADDR_SIZE(reply->tosa)) < 0) debug(DBG_WARN, "sendudp: send failed"); free(reply->buf); free(reply); } } void *udpserverrd(void *arg) { struct request rq; pthread_t udpserverwrth; struct clsrvconf *listenres; listenres = resolve_hostport('U', options.listenudp, DEFAULT_UDP_PORT); if ((udp_server_sock = bindtoaddr(listenres->addrinfo, AF_UNSPEC, 1, 0)) < 0) debugx(1, DBG_ERR, "udpserverrd: socket/bind failed"); debug(DBG_WARN, "udpserverrd: listening for UDP on %s:%s", listenres->host ? listenres->host : "*", listenres->port); freeclsrvres(listenres); if (pthread_create(&udpserverwrth, NULL, udpserverwr, NULL)) debugx(1, DBG_ERR, "pthread_create failed"); for (;;) { memset(&rq, 0, sizeof(struct request)); rq.buf = radudpget(udp_server_sock, &rq.from, NULL, &rq.fromsa); radsrv(&rq); } } void *udpaccserverrd(void *arg) { struct request rq; struct clsrvconf *listenres; listenres = resolve_hostport('U', options.listenaccudp, DEFAULT_UDP_PORT); if ((udp_accserver_sock = bindtoaddr(listenres->addrinfo, AF_UNSPEC, 1, 0)) < 0) debugx(1, DBG_ERR, "udpserverrd: socket/bind failed"); debug(DBG_WARN, "udpaccserverrd: listening for UDP on %s:%s", listenres->host ? listenres->host : "*", listenres->port); freeclsrvres(listenres); for (;;) { memset(&rq, 0, sizeof(struct request)); rq.buf = radudpget(udp_accserver_sock, &rq.from, NULL, &rq.fromsa); if (*rq.buf == RAD_Accounting_Request || *rq.buf == RAD_Status_Server) { radsrv(&rq); continue; } debug(DBG_INFO, "udpaccserverrd: accepting only accounting-request and status-server, ignoring"); freerqdata(&rq); } } void *tlsserverwr(void *arg) { int cnt; unsigned long error; struct client *client = (struct client *)arg; struct replyq *replyq; struct reply *reply; debug(DBG_DBG, "tlsserverwr starting for %s", client->conf->host); replyq = client->replyq; for (;;) { pthread_mutex_lock(&replyq->mutex); while (!list_first(replyq->replies)) { if (client->ssl) { debug(DBG_DBG, "tls server writer, waiting for signal"); pthread_cond_wait(&replyq->cond, &replyq->mutex); debug(DBG_DBG, "tls server writer, got signal"); } if (!client->ssl) { /* ssl might have changed while waiting */ pthread_mutex_unlock(&replyq->mutex); debug(DBG_DBG, "tlsserverwr: exiting as requested"); ERR_remove_state(0); pthread_exit(NULL); } } reply = (struct reply *)list_shift(replyq->replies); pthread_mutex_unlock(&replyq->mutex); cnt = SSL_write(client->ssl, reply->buf, RADLEN(reply->buf)); if (cnt > 0) debug(DBG_DBG, "tlsserverwr: Sent %d bytes, Radius packet of length %d", cnt, RADLEN(reply->buf)); else while ((error = ERR_get_error())) debug(DBG_ERR, "tlsserverwr: SSL: %s", ERR_error_string(error, NULL)); free(reply->buf); free(reply); } } void tlsserverrd(struct client *client) { struct request rq; pthread_t tlsserverwrth; debug(DBG_DBG, "tlsserverrd starting for %s", client->conf->host); if (pthread_create(&tlsserverwrth, NULL, tlsserverwr, (void *)client)) { debug(DBG_ERR, "tlsserverrd: pthread_create failed"); return; } for (;;) { memset(&rq, 0, sizeof(struct request)); rq.buf = radtlsget(client->ssl); if (!rq.buf) break; debug(DBG_DBG, "tlsserverrd: got Radius message from %s", client->conf->host); rq.from = client; radsrv(&rq); } debug(DBG_ERR, "tlsserverrd: connection lost"); /* stop writer by setting ssl to NULL and give signal in case waiting for data */ client->ssl = NULL; pthread_mutex_lock(&client->replyq->mutex); pthread_cond_signal(&client->replyq->cond); pthread_mutex_unlock(&client->replyq->mutex); debug(DBG_DBG, "tlsserverrd: waiting for writer to end"); pthread_join(tlsserverwrth, NULL); removeclientrqs(client); debug(DBG_DBG, "tlsserverrd for %s exiting", client->conf->host); } void *tlsservernew(void *arg) { int s; struct sockaddr_storage from; size_t fromlen = sizeof(from); struct clsrvconf *conf; struct list_node *cur = NULL; SSL *ssl = NULL; X509 *cert = NULL; unsigned long error; struct client *client; s = *(int *)arg; if (getpeername(s, (struct sockaddr *)&from, &fromlen)) { debug(DBG_DBG, "tlsserverrd: getpeername failed, exiting"); goto exit; } debug(DBG_WARN, "incoming TLS connection from %s", addr2string((struct sockaddr *)&from, fromlen)); conf = find_conf('T', (struct sockaddr *)&from, clconfs, &cur); if (conf) { ssl = SSL_new(conf->ssl_ctx); SSL_set_fd(ssl, s); if (SSL_accept(ssl) <= 0) { while ((error = ERR_get_error())) debug(DBG_ERR, "tlsserverrd: SSL: %s", ERR_error_string(error, NULL)); debug(DBG_ERR, "SSL_accept failed"); goto exit; } cert = verifytlscert(ssl); if (!cert) goto exit; } while (conf) { if (verifyconfcert(cert, conf)) { X509_free(cert); client = addclient(conf); if (client) { client->ssl = ssl; tlsserverrd(client); removeclient(client); } else debug(DBG_WARN, "Failed to create new client instance"); goto exit; } conf = find_conf('T', (struct sockaddr *)&from, clconfs, &cur); } debug(DBG_WARN, "ignoring request, no matching TLS client"); if (cert) X509_free(cert); exit: SSL_free(ssl); ERR_remove_state(0); shutdown(s, SHUT_RDWR); close(s); pthread_exit(NULL); } int tlslistener() { pthread_t tlsserverth; int s, snew; struct sockaddr_storage from; size_t fromlen = sizeof(from); struct clsrvconf *listenres; listenres = resolve_hostport('T', options.listentcp, DEFAULT_TLS_PORT); if ((s = bindtoaddr(listenres->addrinfo, AF_UNSPEC, 1, 0)) < 0) debugx(1, DBG_ERR, "tlslistener: socket/bind failed"); debug(DBG_WARN, "listening for incoming TCP on %s:%s", listenres->host ? listenres->host : "*", listenres->port); freeclsrvres(listenres); listen(s, 0); for (;;) { snew = accept(s, (struct sockaddr *)&from, &fromlen); if (snew < 0) { debug(DBG_WARN, "accept failed"); continue; } if (pthread_create(&tlsserverth, NULL, tlsservernew, (void *)&snew)) { debug(DBG_ERR, "tlslistener: pthread_create failed"); shutdown(snew, SHUT_RDWR); close(snew); continue; } pthread_detach(tlsserverth); } return 0; } void tlsadd(char *value, char *cacertfile, char *cacertpath, char *certfile, char *certkeyfile, char *certkeypwd, uint8_t crlcheck) { struct tls *new; SSL_CTX *ctx; STACK_OF(X509_NAME) *calist; X509_STORE *x509_s; int i; unsigned long error; if (!certfile || !certkeyfile) debugx(1, DBG_ERR, "TLSCertificateFile and TLSCertificateKeyFile must be specified in TLS context %s", value); if (!cacertfile && !cacertpath) debugx(1, DBG_ERR, "CA Certificate file or path need to be specified in TLS context %s", value); if (!ssl_locks) { ssl_locks = malloc(CRYPTO_num_locks() * sizeof(pthread_mutex_t)); ssl_lock_count = OPENSSL_malloc(CRYPTO_num_locks() * sizeof(long)); for (i = 0; i < CRYPTO_num_locks(); i++) { ssl_lock_count[i] = 0; pthread_mutex_init(&ssl_locks[i], NULL); } CRYPTO_set_id_callback(ssl_thread_id); CRYPTO_set_locking_callback(ssl_locking_callback); SSL_load_error_strings(); SSL_library_init(); while (!RAND_status()) { time_t t = time(NULL); pid_t pid = getpid(); RAND_seed((unsigned char *)&t, sizeof(time_t)); RAND_seed((unsigned char *)&pid, sizeof(pid)); } } ctx = SSL_CTX_new(TLSv1_method()); if (certkeypwd) { SSL_CTX_set_default_passwd_cb_userdata(ctx, certkeypwd); SSL_CTX_set_default_passwd_cb(ctx, pem_passwd_cb); } if (!SSL_CTX_use_certificate_chain_file(ctx, certfile) || !SSL_CTX_use_PrivateKey_file(ctx, certkeyfile, SSL_FILETYPE_PEM) || !SSL_CTX_check_private_key(ctx) || !SSL_CTX_load_verify_locations(ctx, cacertfile, cacertpath)) { while ((error = ERR_get_error())) debug(DBG_ERR, "SSL: %s", ERR_error_string(error, NULL)); debugx(1, DBG_ERR, "Error initialising SSL/TLS in TLS context %s", value); } calist = cacertfile ? SSL_load_client_CA_file(cacertfile) : NULL; if (!cacertfile || calist) { if (cacertpath) { if (!calist) calist = sk_X509_NAME_new_null(); if (!SSL_add_dir_cert_subjects_to_stack(calist, cacertpath)) { sk_X509_NAME_free(calist); calist = NULL; } } } if (!calist) { while ((error = ERR_get_error())) debug(DBG_ERR, "SSL: %s", ERR_error_string(error, NULL)); debugx(1, DBG_ERR, "Error adding CA subjects in TLS context %s", value); } ERR_clear_error(); /* add_dir_cert_subj returns errors on success */ SSL_CTX_set_client_CA_list(ctx, calist); SSL_CTX_set_verify(ctx, SSL_VERIFY_PEER | SSL_VERIFY_FAIL_IF_NO_PEER_CERT, verify_cb); SSL_CTX_set_verify_depth(ctx, MAX_CERT_DEPTH + 1); if (crlcheck) { x509_s = SSL_CTX_get_cert_store(ctx); X509_STORE_set_flags(x509_s, X509_V_FLAG_CRL_CHECK | X509_V_FLAG_CRL_CHECK_ALL); } new = malloc(sizeof(struct tls)); if (!new || !list_push(tlsconfs, new)) debugx(1, DBG_ERR, "malloc failed"); memset(new, 0, sizeof(struct tls)); new->name = stringcopy(value, 0); if (!new->name) debugx(1, DBG_ERR, "malloc failed"); new->ctx = ctx; new->count = 0; debug(DBG_DBG, "tlsadd: added TLS context %s", value); } void tlsfree() { struct list_node *entry; struct tls *t; for (entry = list_first(tlsconfs); entry; entry = list_next(entry)) { t = (struct tls *)entry->data; if (t->name) free(t->name); if (!t->count) SSL_CTX_free(t->ctx); } list_destroy(tlsconfs); tlsconfs = NULL; } SSL_CTX *tlsgetctx(char *alt1, char *alt2) { struct list_node *entry; struct tls *t, *t1 = NULL, *t2 = NULL; for (entry = list_first(tlsconfs); entry; entry = list_next(entry)) { t = (struct tls *)entry->data; if (!strcasecmp(t->name, alt1)) { t1 = t; break; } if (!t2 && alt2 && !strcasecmp(t->name, alt2)) t2 = t; } t = (t1 ? t1 : t2); if (!t) return NULL; t->count++; return t->ctx; } struct list *addsrvconfs(char *value, char **names) { struct list *conflist; int n; struct list_node *entry; struct clsrvconf *conf = NULL; if (!names || !*names) return NULL; conflist = list_create(); if (!conflist) debugx(1, DBG_ERR, "malloc failed"); for (n = 0; names[n]; n++) { for (entry = list_first(srvconfs); entry; entry = list_next(entry)) { conf = (struct clsrvconf *)entry->data; if (!strcasecmp(names[n], conf->name)) break; } if (!entry) debugx(1, DBG_ERR, "addsrvconfs failed for realm %s, no server named %s", value, names[n]); free(names[n]); if (!list_push(conflist, conf)) debugx(1, DBG_ERR, "malloc failed"); debug(DBG_DBG, "addsrvconfs: added server %s for realm %s", conf->name, value); } free(names); return conflist; } void addrealm(char *value, char **servers, char **accservers, char *message, uint8_t accresp) { int n; struct realm *realm; char *s, *regex = NULL; if (*value == '/') { /* regexp, remove optional trailing / if present */ if (value[strlen(value) - 1] == '/') value[strlen(value) - 1] = '\0'; } else { /* not a regexp, let us make it one */ if (*value == '*' && !value[1]) regex = stringcopy(".*", 0); else { for (n = 0, s = value; *s;) if (*s++ == '.') n++; regex = malloc(strlen(value) + n + 3); if (regex) { regex[0] = '@'; for (n = 1, s = value; *s; s++) { if (*s == '.') regex[n++] = '\\'; regex[n++] = *s; } regex[n++] = '$'; regex[n] = '\0'; } } if (!regex) debugx(1, DBG_ERR, "malloc failed"); debug(DBG_DBG, "addrealm: constructed regexp %s from %s", regex, value); } realm = malloc(sizeof(struct realm)); if (!realm) debugx(1, DBG_ERR, "malloc failed"); memset(realm, 0, sizeof(struct realm)); realm->name = stringcopy(value, 0); if (!realm->name) debugx(1, DBG_ERR, "malloc failed"); if (message && strlen(message) > 253) debugx(1, DBG_ERR, "ReplyMessage can be at most 253 bytes"); realm->message = message; realm->accresp = accresp; if (regcomp(&realm->regex, regex ? regex : value + 1, REG_ICASE | REG_NOSUB)) debugx(1, DBG_ERR, "addrealm: failed to compile regular expression %s", regex ? regex : value + 1); if (regex) free(regex); realm->srvconfs = addsrvconfs(value, servers); realm->accsrvconfs = addsrvconfs(value, accservers); if (!list_push(realms, realm)) debugx(1, DBG_ERR, "malloc failed"); debug(DBG_DBG, "addrealm: added realm %s", value); } int addmatchcertattr(struct clsrvconf *conf, char *matchcertattr) { char *v; regex_t **r; if (!strncasecmp(matchcertattr, "CN:/", 4)) { r = &conf->certcnregex; v = matchcertattr + 4; } else if (!strncasecmp(matchcertattr, "SubjectAltName:URI:/", 20)) { r = &conf->certuriregex; v = matchcertattr + 20; } else return 0; if (!*v) return 0; /* regexp, remove optional trailing / if present */ if (v[strlen(v) - 1] == '/') v[strlen(v) - 1] = '\0'; if (!*v) return 0; *r = malloc(sizeof(regex_t)); if (!*r) { debug(DBG_ERR, "malloc failed"); return 0; } if (regcomp(*r, v, REG_ICASE | REG_NOSUB)) { free(*r); *r = NULL; debug(DBG_ERR, "failed to compile regular expression %s", v); return 0; } return 1; } int addrewriteattr(struct clsrvconf *conf, char *rewriteattr) { char *v, *w; v = rewriteattr + 11; if (strncasecmp(rewriteattr, "User-Name:/", 11) || !*v) return 0; /* regexp, remove optional trailing / if present */ if (v[strlen(v) - 1] == '/') v[strlen(v) - 1] = '\0'; w = strchr(v, '/'); if (!*w) return 0; *w = '\0'; w++; conf->rewriteattrregex = malloc(sizeof(regex_t)); if (!conf->rewriteattrregex) { debug(DBG_ERR, "malloc failed"); return 0; } conf->rewriteattrreplacement = stringcopy(w, 0); if (!conf->rewriteattrreplacement) { free(conf->rewriteattrregex); conf->rewriteattrregex = NULL; return 0; } if (regcomp(conf->rewriteattrregex, v, REG_ICASE | REG_EXTENDED)) { free(conf->rewriteattrregex); conf->rewriteattrregex = NULL; free(conf->rewriteattrreplacement); conf->rewriteattrreplacement = NULL; debug(DBG_ERR, "failed to compile regular expression %s", v); return 0; } return 1; } /* should accept both names and numeric values, only numeric right now */ uint8_t attrname2val(char *attrname) { int val = 0; val = atoi(attrname); return val > 0 && val < 256 ? val : 0; } /* should accept both names and numeric values, only numeric right now */ int vattrname2val(char *attrname, uint32_t *vendor, uint32_t *type) { char *s; *vendor = atoi(attrname); s = strchr(attrname, ':'); if (!s) { *type = -1; return 1; } *type = atoi(s + 1); return *type >= 0 && *type < 256; } void rewritefree() { struct list_node *entry; struct rewriteconf *r; for (entry = list_first(rewriteconfs); entry; entry = list_next(entry)) { r = (struct rewriteconf *)entry->data; if (r->name) free(r->name); if (!r->count) free(r->rewrite); } list_destroy(rewriteconfs); rewriteconfs = NULL; } struct rewrite *getrewrite(char *alt1, char *alt2) { struct list_node *entry; struct rewriteconf *r, *r1 = NULL, *r2 = NULL; for (entry = list_first(rewriteconfs); entry; entry = list_next(entry)) { r = (struct rewriteconf *)entry->data; if (!strcasecmp(r->name, alt1)) { r1 = r; break; } if (!r2 && alt2 && !strcasecmp(r->name, alt2)) r2 = r; } r = (r1 ? r1 : r2); if (!r) return NULL; r->count++; return r->rewrite; } void addrewrite(char *value, char **attrs, char **vattrs) { struct rewriteconf *new; struct rewrite *rewrite = NULL; int i, n; uint8_t *a = NULL; uint32_t *p, *va = NULL; if (attrs) { n = 0; for (; attrs[n]; n++); a = malloc((n + 1) * sizeof(uint8_t)); if (!a) debugx(1, DBG_ERR, "malloc failed"); for (i = 0; i < n; i++) { if (!(a[i] = attrname2val(attrs[i]))) debugx(1, DBG_ERR, "addrewrite: invalid attribute %s", attrs[i]); free(attrs[i]); } free(attrs); a[i] = 0; } if (vattrs) { n = 0; for (; vattrs[n]; n++); va = malloc((2 * n + 1) * sizeof(uint32_t)); if (!va) debugx(1, DBG_ERR, "malloc failed"); for (p = va, i = 0; i < n; i++, p += 2) { if (!vattrname2val(vattrs[i], p, p + 1)) debugx(1, DBG_ERR, "addrewrite: invalid vendor attribute %s", vattrs[i]); free(vattrs[i]); } free(vattrs); *p = 0; } if (a || va) { rewrite = malloc(sizeof(struct rewrite)); if (!rewrite) debugx(1, DBG_ERR, "malloc failed"); rewrite->removeattrs = a; rewrite->removevendorattrs = va; } new = malloc(sizeof(struct rewriteconf)); if (!new || !list_push(rewriteconfs, new)) debugx(1, DBG_ERR, "malloc failed"); memset(new, 0, sizeof(struct rewriteconf)); new->name = stringcopy(value, 0); if (!new->name) debugx(1, DBG_ERR, "malloc failed"); new->rewrite = rewrite; debug(DBG_DBG, "addrewrite: added rewrite block %s", value); } void confclient_cb(struct gconffile **cf, char *block, char *opt, char *val) { char *type = NULL, *tls = NULL, *matchcertattr = NULL, *rewrite = NULL, *rewriteattr = NULL; struct clsrvconf *conf; debug(DBG_DBG, "confclient_cb called for %s", block); conf = malloc(sizeof(struct clsrvconf)); if (!conf || !list_push(clconfs, conf)) debugx(1, DBG_ERR, "malloc failed"); memset(conf, 0, sizeof(struct clsrvconf)); conf->certnamecheck = 1; getgenericconfig(cf, block, "type", CONF_STR, &type, "host", CONF_STR, &conf->host, "secret", CONF_STR, &conf->secret, "tls", CONF_STR, &tls, "matchcertificateattribute", CONF_STR, &matchcertattr, "CertificateNameCheck", CONF_BLN, &conf->certnamecheck, "rewrite", CONF_STR, &rewrite, "rewriteattribute", CONF_STR, &rewriteattr, NULL ); conf->name = stringcopy(val, 0); if (!conf->host) conf->host = stringcopy(val, 0); if (type && !strcasecmp(type, "udp")) { conf->type = 'U'; client_udp_count++; } else if (type && !strcasecmp(type, "tls")) { conf->ssl_ctx = tls ? tlsgetctx(tls, NULL) : tlsgetctx("defaultclient", "default"); if (!conf->ssl_ctx) debugx(1, DBG_ERR, "error in block %s, no tls context defined", block); if (matchcertattr && !addmatchcertattr(conf, matchcertattr)) debugx(1, DBG_ERR, "error in block %s, invalid MatchCertificateAttributeValue", block); conf->type = 'T'; client_tls_count++; } else debugx(1, DBG_ERR, "error in block %s, type must be set to UDP or TLS", block); free(type); if (tls) free(tls); if (matchcertattr) free(matchcertattr); conf->rewrite = rewrite ? getrewrite(rewrite, NULL) : getrewrite("defaultclient", "default"); if (rewriteattr) { if (!addrewriteattr(conf, rewriteattr)) debugx(1, DBG_ERR, "error in block %s, invalid RewriteAttributeValue", block); free(rewriteattr); } if (!resolvepeer(conf, 0)) debugx(1, DBG_ERR, "failed to resolve host %s port %s, exiting", conf->host ? conf->host : "(null)", conf->port ? conf->port : "(null)"); if (!conf->secret) { if (conf->type == 'U') debugx(1, DBG_ERR, "error in block %s, secret must be specified for UDP", block); conf->secret = stringcopy(DEFAULT_TLS_SECRET, 0); } } void confserver_cb(struct gconffile **cf, char *block, char *opt, char *val) { char *type = NULL, *tls = NULL, *matchcertattr = NULL, *rewrite = NULL; long int retryinterval = LONG_MIN, retrycount = LONG_MIN; struct clsrvconf *conf; debug(DBG_DBG, "confserver_cb called for %s", block); conf = malloc(sizeof(struct clsrvconf)); if (!conf || !list_push(srvconfs, conf)) debugx(1, DBG_ERR, "malloc failed"); memset(conf, 0, sizeof(struct clsrvconf)); conf->certnamecheck = 1; getgenericconfig(cf, block, "type", CONF_STR, &type, "host", CONF_STR, &conf->host, "port", CONF_STR, &conf->port, "secret", CONF_STR, &conf->secret, "tls", CONF_STR, &tls, "MatchCertificateAttribute", CONF_STR, &matchcertattr, "rewrite", CONF_STR, &rewrite, "StatusServer", CONF_BLN, &conf->statusserver, "RetryInterval", CONF_LINT, &retryinterval, "RetryCount", CONF_LINT, &retrycount, "CertificateNameCheck", CONF_BLN, &conf->certnamecheck, NULL ); conf->name = stringcopy(val, 0); if (!conf->host) conf->host = stringcopy(val, 0); if (type && !strcasecmp(type, "udp")) { conf->type = 'U'; if (!conf->port) conf->port = stringcopy(DEFAULT_UDP_PORT, 0); } else if (type && !strcasecmp(type, "tls")) { conf->ssl_ctx = tls ? tlsgetctx(tls, NULL) : tlsgetctx("defaultserver", "default"); if (!conf->ssl_ctx) debugx(1, DBG_ERR, "error in block %s, no tls context defined", block); if (matchcertattr && !addmatchcertattr(conf, matchcertattr)) debugx(1, DBG_ERR, "error in block %s, invalid MatchCertificateAttributeValue", block); if (!conf->port) conf->port = stringcopy(DEFAULT_TLS_PORT, 0); conf->type = 'T'; } else debugx(1, DBG_ERR, "error in block %s, type must be set to UDP or TLS", block); free(type); if (tls) free(tls); if (matchcertattr) free(matchcertattr); if (retryinterval != LONG_MIN) { if (retryinterval < 1 || retryinterval > 60) debugx(1, DBG_ERR, "error in block %s, value of option RetryInterval is %d, must be 1-60", block, retryinterval); conf->retryinterval = (uint8_t)retryinterval; } else conf->retryinterval = REQUEST_RETRY_INTERVAL; if (retrycount != LONG_MIN) { if (retrycount < 0 || retrycount > 10) debugx(1, DBG_ERR, "error in block %s, value of option RetryCount is %d, must be 0-10", block, retrycount); conf->retrycount = (uint8_t)retrycount; } else conf->retrycount = REQUEST_RETRY_COUNT; conf->rewrite = rewrite ? getrewrite(rewrite, NULL) : getrewrite("defaultserver", "default"); if (!resolvepeer(conf, 0)) debugx(1, DBG_ERR, "failed to resolve host %s port %s, exiting", conf->host ? conf->host : "(null)", conf->port ? conf->port : "(null)"); if (!conf->secret) { if (conf->type == 'U') debugx(1, DBG_ERR, "error in block %s, secret must be specified for UDP", block); conf->secret = stringcopy(DEFAULT_TLS_SECRET, 0); } } void confrealm_cb(struct gconffile **cf, char *block, char *opt, char *val) { char **servers = NULL, **accservers = NULL, *msg = NULL; uint8_t accresp = 0; debug(DBG_DBG, "confrealm_cb called for %s", block); getgenericconfig(cf, block, "server", CONF_MSTR, &servers, "accountingServer", CONF_MSTR, &accservers, "ReplyMessage", CONF_STR, &msg, "AccountingResponse", CONF_BLN, &accresp, NULL ); addrealm(val, servers, accservers, msg, accresp); } void conftls_cb(struct gconffile **cf, char *block, char *opt, char *val) { char *cacertfile = NULL, *cacertpath = NULL, *certfile = NULL, *certkeyfile = NULL, *certkeypwd = NULL; uint8_t crlcheck = 0; debug(DBG_DBG, "conftls_cb called for %s", block); getgenericconfig(cf, block, "CACertificateFile", CONF_STR, &cacertfile, "CACertificatePath", CONF_STR, &cacertpath, "CertificateFile", CONF_STR, &certfile, "CertificateKeyFile", CONF_STR, &certkeyfile, "CertificateKeyPassword", CONF_STR, &certkeypwd, "CRLCheck", CONF_BLN, &crlcheck, NULL ); tlsadd(val, cacertfile, cacertpath, certfile, certkeyfile, certkeypwd, crlcheck); free(cacertfile); free(cacertpath); free(certfile); free(certkeyfile); free(certkeypwd); } void confrewrite_cb(struct gconffile **cf, char *block, char *opt, char *val) { char **attrs = NULL, **vattrs = NULL; debug(DBG_DBG, "confrewrite_cb called for %s", block); getgenericconfig(cf, block, "removeAttribute", CONF_MSTR, &attrs, "removeVendorAttribute", CONF_MSTR, &vattrs, NULL ); addrewrite(val, attrs, vattrs); } void getmainconfig(const char *configfile) { long int loglevel = LONG_MIN; struct gconffile *cfs; cfs = openconfigfile(configfile); memset(&options, 0, sizeof(options)); clconfs = list_create(); if (!clconfs) debugx(1, DBG_ERR, "malloc failed"); srvconfs = list_create(); if (!srvconfs) debugx(1, DBG_ERR, "malloc failed"); realms = list_create(); if (!realms) debugx(1, DBG_ERR, "malloc failed"); tlsconfs = list_create(); if (!tlsconfs) debugx(1, DBG_ERR, "malloc failed"); rewriteconfs = list_create(); if (!rewriteconfs) debugx(1, DBG_ERR, "malloc failed"); getgenericconfig(&cfs, NULL, "ListenUDP", CONF_STR, &options.listenudp, "ListenTCP", CONF_STR, &options.listentcp, "ListenAccountingUDP", CONF_STR, &options.listenaccudp, "SourceUDP", CONF_STR, &options.sourceudp, "SourceTCP", CONF_STR, &options.sourcetcp, "LogLevel", CONF_LINT, &loglevel, "LogDestination", CONF_STR, &options.logdestination, "LoopPrevention", CONF_BLN, &options.loopprevention, "Client", CONF_CBK, confclient_cb, "Server", CONF_CBK, confserver_cb, "Realm", CONF_CBK, confrealm_cb, "TLS", CONF_CBK, conftls_cb, "Rewrite", CONF_CBK, confrewrite_cb, NULL ); tlsfree(); rewritefree(); if (loglevel != LONG_MIN) { if (loglevel < 1 || loglevel > 4) debugx(1, DBG_ERR, "error in %s, value of option LogLevel is %d, must be 1, 2, 3 or 4", configfile, loglevel); options.loglevel = (uint8_t)loglevel; } } void getargs(int argc, char **argv, uint8_t *foreground, uint8_t *pretend, uint8_t *loglevel, char **configfile) { int c; while ((c = getopt(argc, argv, "c:d:fpv")) != -1) { switch (c) { case 'c': *configfile = optarg; break; case 'd': if (strlen(optarg) != 1 || *optarg < '1' || *optarg > '4') debugx(1, DBG_ERR, "Debug level must be 1, 2, 3 or 4, not %s", optarg); *loglevel = *optarg - '0'; break; case 'f': *foreground = 1; break; case 'p': *pretend = 1; break; case 'v': debugx(0, DBG_ERR, "radsecproxy 1.1"); default: goto usage; } } if (!(argc - optind)) return; usage: debugx(1, DBG_ERR, "Usage:\n%s [ -c configfile ] [ -d debuglevel ] [ -f ] [ -p ] [ -v ]", argv[0]); } #ifdef SYS_SOLARIS9 int daemon(int a, int b) { int i; if (fork()) exit(0); setsid(); for (i = 0; i < 3; i++) { close(i); open("/dev/null", O_RDWR); } return 1; } #endif void *sighandler(void *arg) { sigset_t sigset; int sig; for(;;) { sigemptyset(&sigset); sigaddset(&sigset, SIGPIPE); sigwait(&sigset, &sig); /* only get SIGPIPE right now, so could simplify below code */ switch (sig) { case 0: /* completely ignoring this */ break; case SIGPIPE: debug(DBG_WARN, "sighandler: got SIGPIPE, TLS write error?"); break; default: debug(DBG_WARN, "sighandler: ignoring signal %d", sig); } } } int main(int argc, char **argv) { pthread_t sigth, udpserverth, udpaccserverth, udpclient4rdth, udpclient6rdth; sigset_t sigset; struct list_node *entry; uint8_t foreground = 0, pretend = 0, loglevel = 0; char *configfile = NULL; debug_init("radsecproxy"); debug_set_level(DEBUG_LEVEL); getargs(argc, argv, &foreground, &pretend, &loglevel, &configfile); if (loglevel) debug_set_level(loglevel); getmainconfig(configfile ? configfile : CONFIG_MAIN); if (loglevel) options.loglevel = loglevel; else if (options.loglevel) debug_set_level(options.loglevel); if (!foreground) debug_set_destination(options.logdestination ? options.logdestination : "x-syslog:///"); free(options.logdestination); if (!list_first(clconfs)) debugx(1, DBG_ERR, "No clients configured, nothing to do, exiting"); if (!list_first(srvconfs)) debugx(1, DBG_ERR, "No servers configured, nothing to do, exiting"); if (!list_first(realms)) debugx(1, DBG_ERR, "No realms configured, nothing to do, exiting"); if (pretend) debugx(0, DBG_ERR, "All OK so far; exiting since only pretending"); if (!foreground && (daemon(0, 0) < 0)) debugx(1, DBG_ERR, "daemon() failed: %s", strerror(errno)); debug(DBG_INFO, "radsecproxy 1.1 starting"); sigemptyset(&sigset); /* exit on all but SIGPIPE, ignore more? */ sigaddset(&sigset, SIGPIPE); pthread_sigmask(SIG_BLOCK, &sigset, NULL); pthread_create(&sigth, NULL, sighandler, NULL); if (client_udp_count) { udp_server_replyq = newreplyq(); if (pthread_create(&udpserverth, NULL, udpserverrd, NULL)) debugx(1, DBG_ERR, "pthread_create failed"); if (options.listenaccudp) if (pthread_create(&udpaccserverth, NULL, udpaccserverrd, NULL)) debugx(1, DBG_ERR, "pthread_create failed"); } for (entry = list_first(srvconfs); entry; entry = list_next(entry)) { addserver((struct clsrvconf *)entry->data); if (pthread_create(&((struct clsrvconf *)entry->data)->servers->clientth, NULL, clientwr, (void *)((struct clsrvconf *)entry->data)->servers)) debugx(1, DBG_ERR, "pthread_create failed"); } /* srcudpres no longer needed, while srctcpres is needed later */ if (srcudpres) { freeaddrinfo(srcudpres); srcudpres = NULL; } if (udp_client4_sock >= 0) if (pthread_create(&udpclient4rdth, NULL, udpclientrd, (void *)&udp_client4_sock)) debugx(1, DBG_ERR, "clientwr: pthread_create failed"); if (udp_client6_sock >= 0) if (pthread_create(&udpclient6rdth, NULL, udpclientrd, (void *)&udp_client6_sock)) debugx(1, DBG_ERR, "clientwr: pthread_create failed"); if (client_tls_count) return tlslistener(); /* just hang around doing nothing, anything to do here? */ for (;;) sleep(1000); }