1 /* 2 * Copyright (c) 2004 by Internet Systems Consortium, Inc. ("ISC") 3 * Copyright (c) 1999 by Internet Software Consortium. 4 * 5 * Permission to use, copy, modify, and distribute this software for any 6 * purpose with or without fee is hereby granted, provided that the above 7 * copyright notice and this permission notice appear in all copies. 8 * 9 * THE SOFTWARE IS PROVIDED "AS IS" AND ISC DISCLAIMS ALL WARRANTIES 10 * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF 11 * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL ISC BE LIABLE FOR 12 * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES 13 * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN 14 * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT 15 * OF OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. 16 */ 17 18 /* Import. */ 19 20 #include "port_before.h" 21 22 #include <sys/param.h> 23 #include <sys/socket.h> 24 #include <sys/time.h> 25 26 #include <netinet/in.h> 27 #include <arpa/inet.h> 28 #include <arpa/nameser.h> 29 30 #include <errno.h> 31 #include <limits.h> 32 #include <netdb.h> 33 #include <stdarg.h> 34 #include <stdio.h> 35 #include <stdlib.h> 36 #include <string.h> 37 38 #include <isc/list.h> 39 40 #include "port_after.h" 41 42 #include <resolv.h> 43 44 /* Data structures. */ 45 46 typedef struct rr_a { 47 LINK(struct rr_a) link; 48 union res_sockaddr_union addr; 49 } rr_a; 50 typedef LIST(rr_a) rrset_a; 51 52 typedef struct rr_ns { 53 LINK(struct rr_ns) link; 54 const char * name; 55 unsigned int flags; 56 rrset_a addrs; 57 } rr_ns; 58 typedef LIST(rr_ns) rrset_ns; 59 60 #define RR_NS_HAVE_V4 0x01 61 #define RR_NS_HAVE_V6 0x02 62 63 /* Forward. */ 64 65 static int satisfy(res_state, const char *, rrset_ns *, 66 union res_sockaddr_union *, int); 67 static int add_addrs(res_state, rr_ns *, 68 union res_sockaddr_union *, int); 69 static int get_soa(res_state, const char *, ns_class, int, 70 char *, size_t, char *, size_t, 71 rrset_ns *); 72 static int get_ns(res_state, const char *, ns_class, int, rrset_ns *); 73 static int get_glue(res_state, ns_class, int, rrset_ns *); 74 static int save_ns(res_state, ns_msg *, ns_sect, 75 const char *, ns_class, int, rrset_ns *); 76 static int save_a(res_state, ns_msg *, ns_sect, 77 const char *, ns_class, int, rr_ns *); 78 static void free_nsrrset(rrset_ns *); 79 static void free_nsrr(rrset_ns *, rr_ns *); 80 static rr_ns * find_ns(rrset_ns *, const char *); 81 static int do_query(res_state, const char *, ns_class, ns_type, 82 u_char *, ns_msg *); 83 static void res_dprintf(const char *, ...) ISC_FORMAT_PRINTF(1, 2); 84 85 /* Macros. */ 86 87 #define DPRINTF(x) do {\ 88 int save_errno = errno; \ 89 if ((statp->options & RES_DEBUG) != 0U) res_dprintf x; \ 90 errno = save_errno; \ 91 } while (0) 92 93 /* Public. */ 94 95 /*% 96 * find enclosing zone for a <dname,class>, and some server addresses 97 * 98 * parameters: 99 *\li res - resolver context to work within (is modified) 100 *\li dname - domain name whose enclosing zone is desired 101 *\li class - class of dname (and its enclosing zone) 102 *\li zname - found zone name 103 *\li zsize - allocated size of zname 104 *\li addrs - found server addresses 105 *\li naddrs - max number of addrs 106 * 107 * return values: 108 *\li < 0 - an error occurred (check errno) 109 *\li = 0 - zname is now valid, but addrs[] wasn't changed 110 *\li > 0 - zname is now valid, and return value is number of addrs[] found 111 * 112 * notes: 113 *\li this function calls res_nsend() which means it depends on correctly 114 * functioning recursive nameservers (usually defined in /etc/resolv.conf 115 * or its local equivilent). 116 * 117 *\li we start by asking for an SOA<dname,class>. if we get one as an 118 * answer, that just means <dname,class> is a zone top, which is fine. 119 * more than likely we'll be told to go pound sand, in the form of a 120 * negative answer. 121 * 122 *\li note that we are not prepared to deal with referrals since that would 123 * only come from authority servers and our correctly functioning local 124 * recursive server would have followed the referral and got us something 125 * more definite. 126 * 127 *\li if the authority section contains an SOA, this SOA should also be the 128 * closest enclosing zone, since any intermediary zone cuts would've been 129 * returned as referrals and dealt with by our correctly functioning local 130 * recursive name server. but an SOA in the authority section should NOT 131 * match our dname (since that would have been returned in the answer 132 * section). an authority section SOA has to be "above" our dname. 133 * 134 *\li however, since authority section SOA's were once optional, it's 135 * possible that we'll have to go hunting for the enclosing SOA by 136 * ripping labels off the front of our dname -- this is known as "doing 137 * it the hard way." 138 * 139 *\li ultimately we want some server addresses, which are ideally the ones 140 * pertaining to the SOA.MNAME, but only if there is a matching NS RR. 141 * so the second phase (after we find an SOA) is to go looking for the 142 * NS RRset for that SOA's zone. 143 * 144 *\li no answer section processed by this code is allowed to contain CNAME 145 * or DNAME RR's. for the SOA query this means we strip a label and 146 * keep going. for the NS and A queries this means we just give up. 147 */ 148 149 int 150 res_findzonecut(res_state statp, const char *dname, ns_class class, int opts, 151 char *zname, size_t zsize, struct in_addr *addrs, int naddrs) 152 { 153 int result, i; 154 union res_sockaddr_union *u; 155 156 157 opts |= RES_IPV4ONLY; 158 opts &= ~RES_IPV6ONLY; 159 160 u = calloc(naddrs, sizeof(*u)); 161 if (u == NULL) 162 return(-1); 163 164 result = res_findzonecut2(statp, dname, class, opts, zname, zsize, 165 u, naddrs); 166 167 for (i = 0; i < result; i++) { 168 addrs[i] = u[i].sin.sin_addr; 169 } 170 free(u); 171 return (result); 172 } 173 174 int 175 res_findzonecut2(res_state statp, const char *dname, ns_class class, int opts, 176 char *zname, size_t zsize, union res_sockaddr_union *addrs, 177 int naddrs) 178 { 179 char mname[NS_MAXDNAME]; 180 u_long save_pfcode; 181 rrset_ns nsrrs; 182 int n; 183 184 DPRINTF(("START dname='%s' class=%s, zsize=%ld, naddrs=%d", 185 dname, p_class(class), (long)zsize, naddrs)); 186 save_pfcode = statp->pfcode; 187 statp->pfcode |= RES_PRF_HEAD2 | RES_PRF_HEAD1 | RES_PRF_HEADX | 188 RES_PRF_QUES | RES_PRF_ANS | 189 RES_PRF_AUTH | RES_PRF_ADD; 190 INIT_LIST(nsrrs); 191 192 DPRINTF(("get the soa, and see if it has enough glue")); 193 if ((n = get_soa(statp, dname, class, opts, zname, zsize, 194 mname, sizeof mname, &nsrrs)) < 0 || 195 ((opts & RES_EXHAUSTIVE) == 0 && 196 (n = satisfy(statp, mname, &nsrrs, addrs, naddrs)) > 0)) 197 goto done; 198 199 DPRINTF(("get the ns rrset and see if it has enough glue")); 200 if ((n = get_ns(statp, zname, class, opts, &nsrrs)) < 0 || 201 ((opts & RES_EXHAUSTIVE) == 0 && 202 (n = satisfy(statp, mname, &nsrrs, addrs, naddrs)) > 0)) 203 goto done; 204 205 DPRINTF(("get the missing glue and see if it's finally enough")); 206 if ((n = get_glue(statp, class, opts, &nsrrs)) >= 0) 207 n = satisfy(statp, mname, &nsrrs, addrs, naddrs); 208 209 done: 210 DPRINTF(("FINISH n=%d (%s)", n, (n < 0) ? strerror(errno) : "OK")); 211 free_nsrrset(&nsrrs); 212 statp->pfcode = save_pfcode; 213 return (n); 214 } 215 216 /* Private. */ 217 218 static int 219 satisfy(res_state statp, const char *mname, rrset_ns *nsrrsp, 220 union res_sockaddr_union *addrs, int naddrs) 221 { 222 rr_ns *nsrr; 223 int n, x; 224 225 n = 0; 226 nsrr = find_ns(nsrrsp, mname); 227 if (nsrr != NULL) { 228 x = add_addrs(statp, nsrr, addrs, naddrs); 229 addrs += x; 230 naddrs -= x; 231 n += x; 232 } 233 for (nsrr = HEAD(*nsrrsp); 234 nsrr != NULL && naddrs > 0; 235 nsrr = NEXT(nsrr, link)) 236 if (ns_samename(nsrr->name, mname) != 1) { 237 x = add_addrs(statp, nsrr, addrs, naddrs); 238 addrs += x; 239 naddrs -= x; 240 n += x; 241 } 242 DPRINTF(("satisfy(%s): %d", mname, n)); 243 return (n); 244 } 245 246 static int 247 add_addrs(res_state statp, rr_ns *nsrr, 248 union res_sockaddr_union *addrs, int naddrs) 249 { 250 rr_a *arr; 251 int n = 0; 252 253 for (arr = HEAD(nsrr->addrs); arr != NULL; arr = NEXT(arr, link)) { 254 if (naddrs <= 0) 255 return (0); 256 *addrs++ = arr->addr; 257 naddrs--; 258 n++; 259 } 260 DPRINTF(("add_addrs: %d", n)); 261 return (n); 262 } 263 264 static int 265 get_soa(res_state statp, const char *dname, ns_class class, int opts, 266 char *zname, size_t zsize, char *mname, size_t msize, 267 rrset_ns *nsrrsp) 268 { 269 char tname[NS_MAXDNAME]; 270 u_char *resp = NULL; 271 int n, i, ancount, nscount; 272 ns_sect sect; 273 ns_msg msg; 274 u_int rcode; 275 276 /* 277 * Find closest enclosing SOA, even if it's for the root zone. 278 */ 279 280 /* First canonicalize dname (exactly one unescaped trailing "."). */ 281 if (ns_makecanon(dname, tname, sizeof tname) < 0) 282 goto cleanup; 283 dname = tname; 284 285 resp = malloc(NS_MAXMSG); 286 if (resp == NULL) 287 goto cleanup; 288 289 /* Now grovel the subdomains, hunting for an SOA answer or auth. */ 290 for (;;) { 291 /* Leading or inter-label '.' are skipped here. */ 292 while (*dname == '.') 293 dname++; 294 295 /* Is there an SOA? */ 296 n = do_query(statp, dname, class, ns_t_soa, resp, &msg); 297 if (n < 0) { 298 DPRINTF(("get_soa: do_query('%s', %s) failed (%d)", 299 dname, p_class(class), n)); 300 goto cleanup; 301 } 302 if (n > 0) { 303 DPRINTF(("get_soa: CNAME or DNAME found")); 304 sect = ns_s_max, n = 0; 305 } else { 306 rcode = ns_msg_getflag(msg, ns_f_rcode); 307 ancount = ns_msg_count(msg, ns_s_an); 308 nscount = ns_msg_count(msg, ns_s_ns); 309 if (ancount > 0 && rcode == ns_r_noerror) 310 sect = ns_s_an, n = ancount; 311 else if (nscount > 0) 312 sect = ns_s_ns, n = nscount; 313 else 314 sect = ns_s_max, n = 0; 315 } 316 for (i = 0; i < n; i++) { 317 const char *t; 318 const u_char *rdata; 319 ns_rr rr; 320 321 if (ns_parserr(&msg, sect, i, &rr) < 0) { 322 DPRINTF(("get_soa: ns_parserr(%s, %d) failed", 323 p_section(sect, ns_o_query), i)); 324 goto cleanup; 325 } 326 if (ns_rr_type(rr) == ns_t_cname || 327 ns_rr_type(rr) == ns_t_dname) 328 break; 329 if (ns_rr_type(rr) != ns_t_soa || 330 ns_rr_class(rr) != class) 331 continue; 332 t = ns_rr_name(rr); 333 switch (sect) { 334 case ns_s_an: 335 if (ns_samedomain(dname, t) == 0) { 336 DPRINTF( 337 ("get_soa: ns_samedomain('%s', '%s') == 0", 338 dname, t) 339 ); 340 errno = EPROTOTYPE; 341 goto cleanup; 342 } 343 break; 344 case ns_s_ns: 345 if (ns_samename(dname, t) == 1 || 346 ns_samedomain(dname, t) == 0) { 347 DPRINTF( 348 ("get_soa: ns_samename() || !ns_samedomain('%s', '%s')", 349 dname, t) 350 ); 351 errno = EPROTOTYPE; 352 goto cleanup; 353 } 354 break; 355 default: 356 abort(); 357 } 358 if (strlen(t) + 1 > zsize) { 359 DPRINTF(("get_soa: zname(%lu) too small (%lu)", 360 (unsigned long)zsize, 361 (unsigned long)strlen(t) + 1)); 362 errno = EMSGSIZE; 363 goto cleanup; 364 } 365 strcpy(zname, t); 366 rdata = ns_rr_rdata(rr); 367 if (ns_name_uncompress(resp, ns_msg_end(msg), rdata, 368 mname, msize) < 0) { 369 DPRINTF(("get_soa: ns_name_uncompress failed") 370 ); 371 goto cleanup; 372 } 373 if (save_ns(statp, &msg, ns_s_ns, 374 zname, class, opts, nsrrsp) < 0) { 375 DPRINTF(("get_soa: save_ns failed")); 376 goto cleanup; 377 } 378 free(resp); 379 return (0); 380 } 381 382 /* If we're out of labels, then not even "." has an SOA! */ 383 if (*dname == '\0') 384 break; 385 386 /* Find label-terminating "."; top of loop will skip it. */ 387 while (*dname != '.') { 388 if (*dname == '\\') 389 if (*++dname == '\0') { 390 errno = EMSGSIZE; 391 goto cleanup; 392 } 393 dname++; 394 } 395 } 396 DPRINTF(("get_soa: out of labels")); 397 errno = EDESTADDRREQ; 398 cleanup: 399 if (resp != NULL) 400 free(resp); 401 return (-1); 402 } 403 404 static int 405 get_ns(res_state statp, const char *zname, ns_class class, int opts, 406 rrset_ns *nsrrsp) 407 { 408 u_char *resp; 409 ns_msg msg; 410 int n; 411 412 resp = malloc(NS_MAXMSG); 413 if (resp == NULL) 414 return (-1); 415 416 /* Go and get the NS RRs for this zone. */ 417 n = do_query(statp, zname, class, ns_t_ns, resp, &msg); 418 if (n != 0) { 419 DPRINTF(("get_ns: do_query('%s', %s) failed (%d)", 420 zname, p_class(class), n)); 421 free(resp); 422 return (-1); 423 } 424 425 /* Remember the NS RRs and associated A RRs that came back. */ 426 if (save_ns(statp, &msg, ns_s_an, zname, class, opts, nsrrsp) < 0) { 427 DPRINTF(("get_ns save_ns('%s', %s) failed", 428 zname, p_class(class))); 429 free(resp); 430 return (-1); 431 } 432 433 free(resp); 434 return (0); 435 } 436 437 static int 438 get_glue(res_state statp, ns_class class, int opts, rrset_ns *nsrrsp) { 439 rr_ns *nsrr, *nsrr_n; 440 u_char *resp; 441 442 resp = malloc(NS_MAXMSG); 443 if (resp == NULL) 444 return(-1); 445 446 /* Go and get the A RRs for each empty NS RR on our list. */ 447 for (nsrr = HEAD(*nsrrsp); nsrr != NULL; nsrr = nsrr_n) { 448 ns_msg msg; 449 int n; 450 451 nsrr_n = NEXT(nsrr, link); 452 453 if ((nsrr->flags & RR_NS_HAVE_V4) == 0) { 454 n = do_query(statp, nsrr->name, class, ns_t_a, 455 resp, &msg); 456 if (n < 0) { 457 DPRINTF( 458 ("get_glue: do_query('%s', %s') failed", 459 nsrr->name, p_class(class))); 460 goto cleanup; 461 } 462 if (n > 0) { 463 DPRINTF(( 464 "get_glue: do_query('%s', %s') CNAME or DNAME found", 465 nsrr->name, p_class(class))); 466 } 467 if (save_a(statp, &msg, ns_s_an, nsrr->name, class, 468 opts, nsrr) < 0) { 469 DPRINTF(("get_glue: save_r('%s', %s) failed", 470 nsrr->name, p_class(class))); 471 goto cleanup; 472 } 473 } 474 475 if ((nsrr->flags & RR_NS_HAVE_V6) == 0) { 476 n = do_query(statp, nsrr->name, class, ns_t_aaaa, 477 resp, &msg); 478 if (n < 0) { 479 DPRINTF( 480 ("get_glue: do_query('%s', %s') failed", 481 nsrr->name, p_class(class))); 482 goto cleanup; 483 } 484 if (n > 0) { 485 DPRINTF(( 486 "get_glue: do_query('%s', %s') CNAME or DNAME found", 487 nsrr->name, p_class(class))); 488 } 489 if (save_a(statp, &msg, ns_s_an, nsrr->name, class, 490 opts, nsrr) < 0) { 491 DPRINTF(("get_glue: save_r('%s', %s) failed", 492 nsrr->name, p_class(class))); 493 goto cleanup; 494 } 495 } 496 497 /* If it's still empty, it's just chaff. */ 498 if (EMPTY(nsrr->addrs)) { 499 DPRINTF(("get_glue: removing empty '%s' NS", 500 nsrr->name)); 501 free_nsrr(nsrrsp, nsrr); 502 } 503 } 504 free(resp); 505 return (0); 506 507 cleanup: 508 free(resp); 509 return (-1); 510 } 511 512 static int 513 save_ns(res_state statp, ns_msg *msg, ns_sect sect, 514 const char *owner, ns_class class, int opts, 515 rrset_ns *nsrrsp) 516 { 517 int i; 518 519 for (i = 0; i < ns_msg_count(*msg, sect); i++) { 520 char tname[MAXDNAME]; 521 const u_char *rdata; 522 rr_ns *nsrr; 523 ns_rr rr; 524 525 if (ns_parserr(msg, sect, i, &rr) < 0) { 526 DPRINTF(("save_ns: ns_parserr(%s, %d) failed", 527 p_section(sect, ns_o_query), i)); 528 return (-1); 529 } 530 if (ns_rr_type(rr) != ns_t_ns || 531 ns_rr_class(rr) != class || 532 ns_samename(ns_rr_name(rr), owner) != 1) 533 continue; 534 nsrr = find_ns(nsrrsp, ns_rr_name(rr)); 535 if (nsrr == NULL) { 536 nsrr = malloc(sizeof *nsrr); 537 if (nsrr == NULL) { 538 DPRINTF(("save_ns: malloc failed")); 539 return (-1); 540 } 541 rdata = ns_rr_rdata(rr); 542 if (ns_name_uncompress(ns_msg_base(*msg), 543 ns_msg_end(*msg), rdata, 544 tname, sizeof tname) < 0) { 545 DPRINTF(("save_ns: ns_name_uncompress failed") 546 ); 547 free(nsrr); 548 return (-1); 549 } 550 nsrr->name = strdup(tname); 551 if (nsrr->name == NULL) { 552 DPRINTF(("save_ns: strdup failed")); 553 free(nsrr); 554 return (-1); 555 } 556 INIT_LINK(nsrr, link); 557 INIT_LIST(nsrr->addrs); 558 nsrr->flags = 0; 559 APPEND(*nsrrsp, nsrr, link); 560 } 561 if (save_a(statp, msg, ns_s_ar, 562 nsrr->name, class, opts, nsrr) < 0) { 563 DPRINTF(("save_ns: save_r('%s', %s) failed", 564 nsrr->name, p_class(class))); 565 return (-1); 566 } 567 } 568 return (0); 569 } 570 571 static int 572 save_a(res_state statp, ns_msg *msg, ns_sect sect, 573 const char *owner, ns_class class, int opts, 574 rr_ns *nsrr) 575 { 576 int i; 577 578 for (i = 0; i < ns_msg_count(*msg, sect); i++) { 579 ns_rr rr; 580 rr_a *arr; 581 582 if (ns_parserr(msg, sect, i, &rr) < 0) { 583 DPRINTF(("save_a: ns_parserr(%s, %d) failed", 584 p_section(sect, ns_o_query), i)); 585 return (-1); 586 } 587 if ((ns_rr_type(rr) != ns_t_a && 588 ns_rr_type(rr) != ns_t_aaaa) || 589 ns_rr_class(rr) != class || 590 ns_samename(ns_rr_name(rr), owner) != 1 || 591 ns_rr_rdlen(rr) != NS_INADDRSZ) 592 continue; 593 if ((opts & RES_IPV6ONLY) != 0 && ns_rr_type(rr) != ns_t_aaaa) 594 continue; 595 if ((opts & RES_IPV4ONLY) != 0 && ns_rr_type(rr) != ns_t_a) 596 continue; 597 arr = malloc(sizeof *arr); 598 if (arr == NULL) { 599 DPRINTF(("save_a: malloc failed")); 600 return (-1); 601 } 602 INIT_LINK(arr, link); 603 memset(&arr->addr, 0, sizeof(arr->addr)); 604 switch (ns_rr_type(rr)) { 605 case ns_t_a: 606 arr->addr.sin.sin_family = AF_INET; 607 #ifdef HAVE_SA_LEN 608 arr->addr.sin.sin_len = sizeof(arr->addr.sin); 609 #endif 610 memcpy(&arr->addr.sin.sin_addr, ns_rr_rdata(rr), 611 NS_INADDRSZ); 612 arr->addr.sin.sin_port = htons(NAMESERVER_PORT); 613 nsrr->flags |= RR_NS_HAVE_V4; 614 break; 615 case ns_t_aaaa: 616 arr->addr.sin6.sin6_family = AF_INET6; 617 #ifdef HAVE_SA_LEN 618 arr->addr.sin6.sin6_len = sizeof(arr->addr.sin6); 619 #endif 620 memcpy(&arr->addr.sin6.sin6_addr, ns_rr_rdata(rr), 16); 621 arr->addr.sin.sin_port = htons(NAMESERVER_PORT); 622 nsrr->flags |= RR_NS_HAVE_V6; 623 break; 624 default: 625 abort(); 626 } 627 APPEND(nsrr->addrs, arr, link); 628 } 629 return (0); 630 } 631 632 static void 633 free_nsrrset(rrset_ns *nsrrsp) { 634 rr_ns *nsrr; 635 636 while ((nsrr = HEAD(*nsrrsp)) != NULL) 637 free_nsrr(nsrrsp, nsrr); 638 } 639 640 static void 641 free_nsrr(rrset_ns *nsrrsp, rr_ns *nsrr) { 642 rr_a *arr; 643 char *tmp; 644 645 while ((arr = HEAD(nsrr->addrs)) != NULL) { 646 UNLINK(nsrr->addrs, arr, link); 647 free(arr); 648 } 649 DE_CONST(nsrr->name, tmp); 650 free(tmp); 651 UNLINK(*nsrrsp, nsrr, link); 652 free(nsrr); 653 } 654 655 static rr_ns * 656 find_ns(rrset_ns *nsrrsp, const char *dname) { 657 rr_ns *nsrr; 658 659 for (nsrr = HEAD(*nsrrsp); nsrr != NULL; nsrr = NEXT(nsrr, link)) 660 if (ns_samename(nsrr->name, dname) == 1) 661 return (nsrr); 662 return (NULL); 663 } 664 665 static int 666 do_query(res_state statp, const char *dname, ns_class class, ns_type qtype, 667 u_char *resp, ns_msg *msg) 668 { 669 u_char req[NS_PACKETSZ]; 670 int i, n; 671 672 n = res_nmkquery(statp, ns_o_query, dname, class, qtype, 673 NULL, 0, NULL, req, NS_PACKETSZ); 674 if (n < 0) { 675 DPRINTF(("do_query: res_nmkquery failed")); 676 return (-1); 677 } 678 n = res_nsend(statp, req, n, resp, NS_MAXMSG); 679 if (n < 0) { 680 DPRINTF(("do_query: res_nsend failed")); 681 return (-1); 682 } 683 if (n == 0) { 684 DPRINTF(("do_query: res_nsend returned 0")); 685 errno = EMSGSIZE; 686 return (-1); 687 } 688 if (ns_initparse(resp, n, msg) < 0) { 689 DPRINTF(("do_query: ns_initparse failed")); 690 return (-1); 691 } 692 n = 0; 693 for (i = 0; i < ns_msg_count(*msg, ns_s_an); i++) { 694 ns_rr rr; 695 696 if (ns_parserr(msg, ns_s_an, i, &rr) < 0) { 697 DPRINTF(("do_query: ns_parserr failed")); 698 return (-1); 699 } 700 n += (ns_rr_class(rr) == class && 701 (ns_rr_type(rr) == ns_t_cname || 702 ns_rr_type(rr) == ns_t_dname)); 703 } 704 return (n); 705 } 706 707 static void 708 res_dprintf(const char *fmt, ...) { 709 va_list ap; 710 711 va_start(ap, fmt); 712 fputs(";; res_findzonecut: ", stderr); 713 vfprintf(stderr, fmt, ap); 714 fputc('\n', stderr); 715 va_end(ap); 716 } 717 718 /*! \file */ 719