/* * Copyright (c) 1995 - 2001 Kungliga Tekniska Högskolan * (Royal Institute of Technology, Stockholm, Sweden). * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * 3. Neither the name of the Institute nor the names of its contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE INSTITUTE AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE INSTITUTE OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ #ifdef HAVE_CONFIG_H #include #endif #include "roken.h" #ifdef HAVE_ARPA_NAMESER_H #include #endif #ifdef HAVE_RESOLV_H #include #endif #include "resolve.h" #include RCSID("$Id: resolve.c,v 1.30 2001/10/02 15:39:41 joda Exp $"); #if defined(HAVE_RES_SEARCH) && defined(HAVE_DN_EXPAND) #define DECL(X) {#X, T_##X} static struct stot{ const char *name; int type; }stot[] = { DECL(A), DECL(NS), DECL(CNAME), DECL(SOA), DECL(PTR), DECL(MX), DECL(TXT), DECL(AFSDB), DECL(SIG), DECL(KEY), DECL(SRV), DECL(NAPTR), {NULL, 0} }; int _resolve_debug = 0; int dns_string_to_type(const char *name) { struct stot *p = stot; for(p = stot; p->name; p++) if(strcasecmp(name, p->name) == 0) return p->type; return -1; } const char * dns_type_to_string(int type) { struct stot *p = stot; for(p = stot; p->name; p++) if(type == p->type) return p->name; return NULL; } void dns_free_data(struct dns_reply *r) { struct resource_record *rr; if(r->q.domain) free(r->q.domain); for(rr = r->head; rr;){ struct resource_record *tmp = rr; if(rr->domain) free(rr->domain); if(rr->u.data) free(rr->u.data); rr = rr->next; free(tmp); } free (r); } static struct dns_reply* parse_reply(unsigned char *data, int len) { unsigned char *p; char host[128]; int status; struct dns_reply *r; struct resource_record **rr; r = calloc(1, sizeof(*r)); if (r == NULL) return NULL; p = data; #if 0 /* doesn't work on Crays */ memcpy(&r->h, p, sizeof(HEADER)); p += sizeof(HEADER); #else memcpy(&r->h, p, 12); /* XXX this will probably be mostly garbage */ p += 12; #endif status = dn_expand(data, data + len, p, host, sizeof(host)); if(status < 0){ dns_free_data(r); return NULL; } r->q.domain = strdup(host); if(r->q.domain == NULL) { dns_free_data(r); return NULL; } p += status; r->q.type = (p[0] << 8 | p[1]); p += 2; r->q.class = (p[0] << 8 | p[1]); p += 2; rr = &r->head; while(p < data + len){ int type, class, ttl, size; status = dn_expand(data, data + len, p, host, sizeof(host)); if(status < 0){ dns_free_data(r); return NULL; } p += status; type = (p[0] << 8) | p[1]; p += 2; class = (p[0] << 8) | p[1]; p += 2; ttl = (p[0] << 24) | (p[1] << 16) | (p[2] << 8) | p[3]; p += 4; size = (p[0] << 8) | p[1]; p += 2; *rr = (struct resource_record*)calloc(1, sizeof(struct resource_record)); if(*rr == NULL) { dns_free_data(r); return NULL; } (*rr)->domain = strdup(host); if((*rr)->domain == NULL) { dns_free_data(r); return NULL; } (*rr)->type = type; (*rr)->class = class; (*rr)->ttl = ttl; (*rr)->size = size; switch(type){ case T_NS: case T_CNAME: case T_PTR: status = dn_expand(data, data + len, p, host, sizeof(host)); if(status < 0){ dns_free_data(r); return NULL; } (*rr)->u.txt = strdup(host); if((*rr)->u.txt == NULL) { dns_free_data(r); return NULL; } break; case T_MX: case T_AFSDB:{ status = dn_expand(data, data + len, p + 2, host, sizeof(host)); if(status < 0){ dns_free_data(r); return NULL; } (*rr)->u.mx = (struct mx_record*)malloc(sizeof(struct mx_record) + strlen(host)); if((*rr)->u.mx == NULL) { dns_free_data(r); return NULL; } (*rr)->u.mx->preference = (p[0] << 8) | p[1]; strcpy((*rr)->u.mx->domain, host); break; } case T_SRV:{ status = dn_expand(data, data + len, p + 6, host, sizeof(host)); if(status < 0){ dns_free_data(r); return NULL; } (*rr)->u.srv = (struct srv_record*)malloc(sizeof(struct srv_record) + strlen(host)); if((*rr)->u.srv == NULL) { dns_free_data(r); return NULL; } (*rr)->u.srv->priority = (p[0] << 8) | p[1]; (*rr)->u.srv->weight = (p[2] << 8) | p[3]; (*rr)->u.srv->port = (p[4] << 8) | p[5]; strcpy((*rr)->u.srv->target, host); break; } case T_TXT:{ (*rr)->u.txt = (char*)malloc(size + 1); if((*rr)->u.txt == NULL) { dns_free_data(r); return NULL; } strncpy((*rr)->u.txt, (char*)p + 1, *p); (*rr)->u.txt[*p] = 0; break; } case T_KEY : { size_t key_len; key_len = size - 4; (*rr)->u.key = malloc (sizeof(*(*rr)->u.key) + key_len - 1); if ((*rr)->u.key == NULL) { dns_free_data (r); return NULL; } (*rr)->u.key->flags = (p[0] << 8) | p[1]; (*rr)->u.key->protocol = p[2]; (*rr)->u.key->algorithm = p[3]; (*rr)->u.key->key_len = key_len; memcpy ((*rr)->u.key->key_data, p + 4, key_len); break; } case T_SIG : { size_t sig_len; status = dn_expand (data, data + len, p + 18, host, sizeof(host)); if (status < 0) { dns_free_data (r); return NULL; } sig_len = len - 18 - status; (*rr)->u.sig = malloc(sizeof(*(*rr)->u.sig) + strlen(host) + sig_len); if ((*rr)->u.sig == NULL) { dns_free_data (r); return NULL; } (*rr)->u.sig->type = (p[0] << 8) | p[1]; (*rr)->u.sig->algorithm = p[2]; (*rr)->u.sig->labels = p[3]; (*rr)->u.sig->orig_ttl = (p[4] << 24) | (p[5] << 16) | (p[6] << 8) | p[7]; (*rr)->u.sig->sig_expiration = (p[8] << 24) | (p[9] << 16) | (p[10] << 8) | p[11]; (*rr)->u.sig->sig_inception = (p[12] << 24) | (p[13] << 16) | (p[14] << 8) | p[15]; (*rr)->u.sig->key_tag = (p[16] << 8) | p[17]; (*rr)->u.sig->sig_len = sig_len; memcpy ((*rr)->u.sig->sig_data, p + 18 + status, sig_len); (*rr)->u.sig->signer = &(*rr)->u.sig->sig_data[sig_len]; strcpy((*rr)->u.sig->signer, host); break; } case T_CERT : { size_t cert_len; cert_len = size - 5; (*rr)->u.cert = malloc (sizeof(*(*rr)->u.cert) + cert_len - 1); if ((*rr)->u.cert == NULL) { dns_free_data (r); return NULL; } (*rr)->u.cert->type = (p[0] << 8) | p[1]; (*rr)->u.cert->tag = (p[2] << 8) | p[3]; (*rr)->u.cert->algorithm = p[4]; (*rr)->u.cert->cert_len = cert_len; memcpy ((*rr)->u.cert->cert_data, p + 5, cert_len); break; } default: (*rr)->u.data = (unsigned char*)malloc(size); if(size != 0 && (*rr)->u.data == NULL) { dns_free_data(r); return NULL; } memcpy((*rr)->u.data, p, size); } p += size; rr = &(*rr)->next; } *rr = NULL; return r; } static struct dns_reply * dns_lookup_int(const char *domain, int rr_class, int rr_type) { unsigned char reply[1024]; int len; struct dns_reply *r = NULL; u_long old_options = 0; if (_resolve_debug) { old_options = _res.options; _res.options |= RES_DEBUG; fprintf(stderr, "dns_lookup(%s, %d, %s)\n", domain, rr_class, dns_type_to_string(rr_type)); } len = res_search(domain, rr_class, rr_type, reply, sizeof(reply)); if (_resolve_debug) { _res.options = old_options; fprintf(stderr, "dns_lookup(%s, %d, %s) --> %d\n", domain, rr_class, dns_type_to_string(rr_type), len); } if (len >= 0) r = parse_reply(reply, len); return r; } struct dns_reply * dns_lookup(const char *domain, const char *type_name) { int type; type = dns_string_to_type(type_name); if(type == -1) { if(_resolve_debug) fprintf(stderr, "dns_lookup: unknown resource type: `%s'\n", type_name); return NULL; } return dns_lookup_int(domain, C_IN, type); } static int compare_srv(const void *a, const void *b) { const struct resource_record *const* aa = a, *const* bb = b; if((*aa)->u.srv->priority == (*bb)->u.srv->priority) return ((*aa)->u.srv->weight - (*bb)->u.srv->weight); return ((*aa)->u.srv->priority - (*bb)->u.srv->priority); } #ifndef HAVE_RANDOM #define random() rand() #endif /* try to rearrange the srv-records by the algorithm in RFC2782 */ void dns_srv_order(struct dns_reply *r) { struct resource_record **srvs, **ss, **headp; struct resource_record *rr; int num_srv = 0; #if defined(HAVE_INITSTATE) && defined(HAVE_SETSTATE) char state[256], *oldstate; #endif for(rr = r->head; rr; rr = rr->next) if(rr->type == T_SRV) num_srv++; if(num_srv == 0) return; srvs = malloc(num_srv * sizeof(*srvs)); if(srvs == NULL) return; /* XXX not much to do here */ /* unlink all srv-records from the linked list and put them in a vector */ for(ss = srvs, headp = &r->head; *headp; ) if((*headp)->type == T_SRV) { *ss = *headp; *headp = (*headp)->next; (*ss)->next = NULL; ss++; } else headp = &(*headp)->next; /* sort them by priority and weight */ qsort(srvs, num_srv, sizeof(*srvs), compare_srv); #if defined(HAVE_INITSTATE) && defined(HAVE_SETSTATE) oldstate = initstate(time(NULL), state, sizeof(state)); #endif headp = &r->head; for(ss = srvs; ss < srvs + num_srv; ) { int sum, rnd, count; struct resource_record **ee, **tt; /* find the last record with the same priority and count the sum of all weights */ for(sum = 0, tt = ss; tt < srvs + num_srv; tt++) { if(*tt == NULL) continue; if((*tt)->u.srv->priority != (*ss)->u.srv->priority) break; sum += (*tt)->u.srv->weight; } ee = tt; /* ss is now the first record of this priority and ee is the first of the next */ while(ss < ee) { rnd = random() % (sum + 1); for(count = 0, tt = ss; ; tt++) { if(*tt == NULL) continue; count += (*tt)->u.srv->weight; if(count >= rnd) break; } assert(tt < ee); /* insert the selected record at the tail (of the head) of the list */ (*tt)->next = *headp; *headp = *tt; headp = &(*tt)->next; sum -= (*tt)->u.srv->weight; *tt = NULL; while(ss < ee && *ss == NULL) ss++; } } #if defined(HAVE_INITSTATE) && defined(HAVE_SETSTATE) setstate(oldstate); #endif free(srvs); return; } #else /* NOT defined(HAVE_RES_SEARCH) && defined(HAVE_DN_EXPAND) */ struct dns_reply * dns_lookup(const char *domain, const char *type_name) { return NULL; } void dns_free_data(struct dns_reply *r) { } void dns_srv_order(struct dns_reply *r) { } #endif #ifdef TEST int main(int argc, char **argv) { struct dns_reply *r; struct resource_record *rr; r = dns_lookup(argv[1], argv[2]); if(r == NULL){ printf("No reply.\n"); return 1; } if(r->q.type == T_SRV) dns_srv_order(r); for(rr = r->head; rr;rr=rr->next){ printf("%s %s %d ", rr->domain, dns_type_to_string(rr->type), rr->ttl); switch(rr->type){ case T_NS: case T_CNAME: case T_PTR: printf("%s\n", (char*)rr->u.data); break; case T_A: printf("%s\n", inet_ntoa(*rr->u.a)); break; case T_MX: case T_AFSDB:{ printf("%d %s\n", rr->u.mx->preference, rr->u.mx->domain); break; } case T_SRV:{ struct srv_record *srv = rr->u.srv; printf("%d %d %d %s\n", srv->priority, srv->weight, srv->port, srv->target); break; } case T_TXT: { printf("%s\n", rr->u.txt); break; } case T_SIG : { struct sig_record *sig = rr->u.sig; const char *type_string = dns_type_to_string (sig->type); printf ("type %u (%s), algorithm %u, labels %u, orig_ttl %u, sig_expiration %u, sig_inception %u, key_tag %u, signer %s\n", sig->type, type_string ? type_string : "", sig->algorithm, sig->labels, sig->orig_ttl, sig->sig_expiration, sig->sig_inception, sig->key_tag, sig->signer); break; } case T_KEY : { struct key_record *key = rr->u.key; printf ("flags %u, protocol %u, algorithm %u\n", key->flags, key->protocol, key->algorithm); break; } default: printf("\n"); break; } } return 0; } #endif