/* dnsmasq is Copyright (c) 2000-2018 Simon Kelley This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; version 2 dated June, 1991, or (at your option) version 3 dated 29 June, 2007. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program. If not, see . */ #include "dnsmasq.h" int extract_name(struct dns_header *header, size_t plen, unsigned char **pp, char *name, int isExtract, int extrabytes) { unsigned char *cp = (unsigned char *)name, *p = *pp, *p1 = NULL; unsigned int j, l, namelen = 0, hops = 0; int retvalue = 1; if (isExtract) *cp = 0; while (1) { unsigned int label_type; if (!CHECK_LEN(header, p, plen, 1)) return 0; if ((l = *p++) == 0) /* end marker */ { /* check that there are the correct no. of bytes after the name */ if (!CHECK_LEN(header, p1 ? p1 : p, plen, extrabytes)) return 0; if (isExtract) { if (cp != (unsigned char *)name) cp--; *cp = 0; /* terminate: lose final period */ } else if (*cp != 0) retvalue = 2; if (p1) /* we jumped via compression */ *pp = p1; else *pp = p; return retvalue; } label_type = l & 0xc0; if (label_type == 0xc0) /* pointer */ { if (!CHECK_LEN(header, p, plen, 1)) return 0; /* get offset */ l = (l&0x3f) << 8; l |= *p++; if (!p1) /* first jump, save location to go back to */ p1 = p; hops++; /* break malicious infinite loops */ if (hops > 255) return 0; p = l + (unsigned char *)header; } else if (label_type == 0x00) { /* label_type = 0 -> label. */ namelen += l + 1; /* include period */ if (namelen >= MAXDNAME) return 0; if (!CHECK_LEN(header, p, plen, l)) return 0; for(j=0; j= 'A' && c1 <= 'Z') c1 += 'a' - 'A'; #ifdef HAVE_DNSSEC if (option_bool(OPT_DNSSEC_VALID) && c1 == NAME_ESCAPE) c1 = (*cp++)-1; #endif if (c2 >= 'A' && c2 <= 'Z') c2 += 'a' - 'A'; if (c1 != c2) retvalue = 2; } } if (isExtract) *cp++ = '.'; else if (*cp != 0 && *cp++ != '.') retvalue = 2; } else return 0; /* label types 0x40 and 0x80 not supported */ } } /* Max size of input string (for IPv6) is 75 chars.) */ #define MAXARPANAME 75 int in_arpa_name_2_addr(char *namein, union all_addr *addrp) { int j; char name[MAXARPANAME+1], *cp1; unsigned char *addr = (unsigned char *)addrp; char *lastchunk = NULL, *penchunk = NULL; if (strlen(namein) > MAXARPANAME) return 0; memset(addrp, 0, sizeof(union all_addr)); /* turn name into a series of asciiz strings */ /* j counts no. of labels */ for(j = 1,cp1 = name; *namein; cp1++, namein++) if (*namein == '.') { penchunk = lastchunk; lastchunk = cp1 + 1; *cp1 = 0; j++; } else *cp1 = *namein; *cp1 = 0; if (j<3) return 0; if (hostname_isequal(lastchunk, "arpa") && hostname_isequal(penchunk, "in-addr")) { /* IP v4 */ /* address arrives as a name of the form www.xxx.yyy.zzz.in-addr.arpa some of the low order address octets might be missing and should be set to zero. */ for (cp1 = name; cp1 != penchunk; cp1 += strlen(cp1)+1) { /* check for digits only (weeds out things like 50.0/24.67.28.64.in-addr.arpa which are used as CNAME targets according to RFC 2317 */ char *cp; for (cp = cp1; *cp; cp++) if (!isdigit((unsigned char)*cp)) return 0; addr[3] = addr[2]; addr[2] = addr[1]; addr[1] = addr[0]; addr[0] = atoi(cp1); } return F_IPV4; } else if (hostname_isequal(penchunk, "ip6") && (hostname_isequal(lastchunk, "int") || hostname_isequal(lastchunk, "arpa"))) { /* IP v6: Address arrives as 0.1.2.3.4.5.6.7.8.9.a.b.c.d.e.f.ip6.[int|arpa] or \[xfedcba9876543210fedcba9876543210/128].ip6.[int|arpa] Note that most of these the various representations are obsolete and left-over from the many DNS-for-IPv6 wars. We support all the formats that we can since there is no reason not to. */ if (*name == '\\' && *(name+1) == '[' && (*(name+2) == 'x' || *(name+2) == 'X')) { for (j = 0, cp1 = name+3; *cp1 && isxdigit((unsigned char) *cp1) && j < 32; cp1++, j++) { char xdig[2]; xdig[0] = *cp1; xdig[1] = 0; if (j%2) addr[j/2] |= strtol(xdig, NULL, 16); else addr[j/2] = strtol(xdig, NULL, 16) << 4; } if (*cp1 == '/' && j == 32) return F_IPV6; } else { for (cp1 = name; cp1 != penchunk; cp1 += strlen(cp1)+1) { if (*(cp1+1) || !isxdigit((unsigned char)*cp1)) return 0; for (j = sizeof(struct in6_addr)-1; j>0; j--) addr[j] = (addr[j] >> 4) | (addr[j-1] << 4); addr[0] = (addr[0] >> 4) | (strtol(cp1, NULL, 16) << 4); } return F_IPV6; } } return 0; } unsigned char *skip_name(unsigned char *ansp, struct dns_header *header, size_t plen, int extrabytes) { while(1) { unsigned int label_type; if (!CHECK_LEN(header, ansp, plen, 1)) return NULL; label_type = (*ansp) & 0xc0; if (label_type == 0xc0) { /* pointer for compression. */ ansp += 2; break; } else if (label_type == 0x80) return NULL; /* reserved */ else if (label_type == 0x40) { /* Extended label type */ unsigned int count; if (!CHECK_LEN(header, ansp, plen, 2)) return NULL; if (((*ansp++) & 0x3f) != 1) return NULL; /* we only understand bitstrings */ count = *(ansp++); /* Bits in bitstring */ if (count == 0) /* count == 0 means 256 bits */ ansp += 32; else ansp += ((count-1)>>3)+1; } else { /* label type == 0 Bottom six bits is length */ unsigned int len = (*ansp++) & 0x3f; if (!ADD_RDLEN(header, ansp, plen, len)) return NULL; if (len == 0) break; /* zero length label marks the end. */ } } if (!CHECK_LEN(header, ansp, plen, extrabytes)) return NULL; return ansp; } unsigned char *skip_questions(struct dns_header *header, size_t plen) { int q; unsigned char *ansp = (unsigned char *)(header+1); for (q = ntohs(header->qdcount); q != 0; q--) { if (!(ansp = skip_name(ansp, header, plen, 4))) return NULL; ansp += 4; /* class and type */ } return ansp; } unsigned char *skip_section(unsigned char *ansp, int count, struct dns_header *header, size_t plen) { int i, rdlen; for (i = 0; i < count; i++) { if (!(ansp = skip_name(ansp, header, plen, 10))) return NULL; ansp += 8; /* type, class, TTL */ GETSHORT(rdlen, ansp); if (!ADD_RDLEN(header, ansp, plen, rdlen)) return NULL; } return ansp; } size_t resize_packet(struct dns_header *header, size_t plen, unsigned char *pheader, size_t hlen) { unsigned char *ansp = skip_questions(header, plen); /* if packet is malformed, just return as-is. */ if (!ansp) return plen; if (!(ansp = skip_section(ansp, ntohs(header->ancount) + ntohs(header->nscount) + ntohs(header->arcount), header, plen))) return plen; /* restore pseudoheader */ if (pheader && ntohs(header->arcount) == 0) { /* must use memmove, may overlap */ memmove(ansp, pheader, hlen); header->arcount = htons(1); ansp += hlen; } return ansp - (unsigned char *)header; } /* is addr in the non-globally-routed IP space? */ int private_net(struct in_addr addr, int ban_localhost) { in_addr_t ip_addr = ntohl(addr.s_addr); return (((ip_addr & 0xFF000000) == 0x7F000000) && ban_localhost) /* 127.0.0.0/8 (loopback) */ || ((ip_addr & 0xFF000000) == 0x00000000) /* RFC 5735 section 3. "here" network */ || ((ip_addr & 0xFF000000) == 0x0A000000) /* 10.0.0.0/8 (private) */ || ((ip_addr & 0xFFF00000) == 0xAC100000) /* 172.16.0.0/12 (private) */ || ((ip_addr & 0xFFFF0000) == 0xC0A80000) /* 192.168.0.0/16 (private) */ || ((ip_addr & 0xFFFF0000) == 0xA9FE0000) /* 169.254.0.0/16 (zeroconf) */ || ((ip_addr & 0xFFFFFF00) == 0xC0000200) /* 192.0.2.0/24 (test-net) */ || ((ip_addr & 0xFFFFFF00) == 0xC6336400) /* 198.51.100.0/24(test-net) */ || ((ip_addr & 0xFFFFFF00) == 0xCB007100) /* 203.0.113.0/24 (test-net) */ || ((ip_addr & 0xFFFFFFFF) == 0xFFFFFFFF) /* 255.255.255.255/32 (broadcast)*/ ; } static int private_net6(struct in6_addr *a) { return IN6_IS_ADDR_UNSPECIFIED(a) || /* RFC 6303 4.3 */ IN6_IS_ADDR_LOOPBACK(a) || /* RFC 6303 4.3 */ IN6_IS_ADDR_LINKLOCAL(a) || /* RFC 6303 4.5 */ ((unsigned char *)a)[0] == 0xfd || /* RFC 6303 4.4 */ ((u32 *)a)[0] == htonl(0x20010db8); /* RFC 6303 4.6 */ } static unsigned char *do_doctor(unsigned char *p, int count, struct dns_header *header, size_t qlen, char *name, int *doctored) { int i, qtype, qclass, rdlen; for (i = count; i != 0; i--) { if (name && option_bool(OPT_LOG)) { if (!extract_name(header, qlen, &p, name, 1, 10)) return 0; } else if (!(p = skip_name(p, header, qlen, 10))) return 0; /* bad packet */ GETSHORT(qtype, p); GETSHORT(qclass, p); p += 4; /* ttl */ GETSHORT(rdlen, p); if (qclass == C_IN && qtype == T_A) { struct doctor *doctor; struct in_addr addr; if (!CHECK_LEN(header, p, qlen, INADDRSZ)) return 0; /* alignment */ memcpy(&addr, p, INADDRSZ); for (doctor = daemon->doctors; doctor; doctor = doctor->next) { if (doctor->end.s_addr == 0) { if (!is_same_net(doctor->in, addr, doctor->mask)) continue; } else if (ntohl(doctor->in.s_addr) > ntohl(addr.s_addr) || ntohl(doctor->end.s_addr) < ntohl(addr.s_addr)) continue; addr.s_addr &= ~doctor->mask.s_addr; addr.s_addr |= (doctor->out.s_addr & doctor->mask.s_addr); /* Since we munged the data, the server it came from is no longer authoritative */ header->hb3 &= ~HB3_AA; *doctored = 1; memcpy(p, &addr, INADDRSZ); break; } } else if (qtype == T_TXT && name && option_bool(OPT_LOG)) { unsigned char *p1 = p; if (!CHECK_LEN(header, p1, qlen, rdlen)) return 0; while ((p1 - p) < rdlen) { unsigned int i, len = *p1; unsigned char *p2 = p1; if ((p1 + len - p) >= rdlen) return 0; /* bad packet */ /* make counted string zero-term and sanitise */ for (i = 0; i < len; i++) { if (!isprint((int)*(p2+1))) break; *p2 = *(p2+1); p2++; } *p2 = 0; my_syslog(LOG_INFO, "reply %s is %s", name, p1); /* restore */ memmove(p1 + 1, p1, i); *p1 = len; p1 += len+1; } } if (!ADD_RDLEN(header, p, qlen, rdlen)) return 0; /* bad packet */ } return p; } static int find_soa(struct dns_header *header, size_t qlen, char *name, int *doctored) { unsigned char *p; int qtype, qclass, rdlen; unsigned long ttl, minttl = ULONG_MAX; int i, found_soa = 0; /* first move to NS section and find TTL from any SOA section */ if (!(p = skip_questions(header, qlen)) || !(p = do_doctor(p, ntohs(header->ancount), header, qlen, name, doctored))) return 0; /* bad packet */ for (i = ntohs(header->nscount); i != 0; i--) { if (!(p = skip_name(p, header, qlen, 10))) return 0; /* bad packet */ GETSHORT(qtype, p); GETSHORT(qclass, p); GETLONG(ttl, p); GETSHORT(rdlen, p); if ((qclass == C_IN) && (qtype == T_SOA)) { found_soa = 1; if (ttl < minttl) minttl = ttl; /* MNAME */ if (!(p = skip_name(p, header, qlen, 0))) return 0; /* RNAME */ if (!(p = skip_name(p, header, qlen, 20))) return 0; p += 16; /* SERIAL REFRESH RETRY EXPIRE */ GETLONG(ttl, p); /* minTTL */ if (ttl < minttl) minttl = ttl; } else if (!ADD_RDLEN(header, p, qlen, rdlen)) return 0; /* bad packet */ } /* rewrite addresses in additional section too */ if (!do_doctor(p, ntohs(header->arcount), header, qlen, NULL, doctored)) return 0; if (!found_soa) minttl = daemon->neg_ttl; return minttl; } /* Note that the following code can create CNAME chains that don't point to a real record, either because of lack of memory, or lack of SOA records. These are treated by the cache code as expired and cleaned out that way. Return 1 if we reject an address because it look like part of dns-rebinding attack. */ int extract_addresses(struct dns_header *header, size_t qlen, char *name, time_t now, char **ipsets, int is_sign, int check_rebind, int no_cache_dnssec, int secure, int *doctored) { unsigned char *p, *p1, *endrr, *namep; int i, j, qtype, qclass, aqtype, aqclass, ardlen, res, searched_soa = 0; unsigned long ttl = 0; union all_addr addr; #ifdef HAVE_IPSET char **ipsets_cur; #else (void)ipsets; /* unused */ #endif cache_start_insert(); /* find_soa is needed for dns_doctor and logging side-effects, so don't call it lazily if there are any. */ if (daemon->doctors || option_bool(OPT_LOG) || option_bool(OPT_DNSSEC_VALID)) { searched_soa = 1; ttl = find_soa(header, qlen, name, doctored); if (*doctored) { if (secure) return 0; #ifdef HAVE_DNSSEC if (option_bool(OPT_DNSSEC_VALID)) for (i = 0; i < ntohs(header->ancount); i++) if (daemon->rr_status[i]) return 0; #endif } } /* go through the questions. */ p = (unsigned char *)(header+1); for (i = ntohs(header->qdcount); i != 0; i--) { int found = 0, cname_count = CNAME_CHAIN; struct crec *cpp = NULL; int flags = RCODE(header) == NXDOMAIN ? F_NXDOMAIN : 0; #ifdef HAVE_DNSSEC int cname_short = 0; #endif unsigned long cttl = ULONG_MAX, attl; namep = p; if (!extract_name(header, qlen, &p, name, 1, 4)) return 0; /* bad packet */ GETSHORT(qtype, p); GETSHORT(qclass, p); if (qclass != C_IN) continue; /* PTRs: we chase CNAMEs here, since we have no way to represent them in the cache. */ if (qtype == T_PTR) { int name_encoding = in_arpa_name_2_addr(name, &addr); if (!name_encoding) continue; if (!(flags & F_NXDOMAIN)) { cname_loop: if (!(p1 = skip_questions(header, qlen))) return 0; for (j = 0; j < ntohs(header->ancount); j++) { int secflag = 0; unsigned char *tmp = namep; /* the loop body overwrites the original name, so get it back here. */ if (!extract_name(header, qlen, &tmp, name, 1, 0) || !(res = extract_name(header, qlen, &p1, name, 0, 10))) return 0; /* bad packet */ GETSHORT(aqtype, p1); GETSHORT(aqclass, p1); GETLONG(attl, p1); if ((daemon->max_ttl != 0) && (attl > daemon->max_ttl) && !is_sign) { (p1) -= 4; PUTLONG(daemon->max_ttl, p1); } GETSHORT(ardlen, p1); endrr = p1+ardlen; /* TTL of record is minimum of CNAMES and PTR */ if (attl < cttl) cttl = attl; if (aqclass == C_IN && res != 2 && (aqtype == T_CNAME || aqtype == T_PTR)) { if (!extract_name(header, qlen, &p1, name, 1, 0)) return 0; #ifdef HAVE_DNSSEC if (option_bool(OPT_DNSSEC_VALID) && daemon->rr_status[j]) { /* validated RR anywhere in CNAME chain, don't cache. */ if (cname_short || aqtype == T_CNAME) return 0; secflag = F_DNSSECOK; } #endif if (aqtype == T_CNAME) { if (!cname_count--) return 0; /* looped CNAMES, we can't cache. */ #ifdef HAVE_DNSSEC cname_short = 1; #endif goto cname_loop; } cache_insert(name, &addr, C_IN, now, cttl, name_encoding | secflag | F_REVERSE); found = 1; } p1 = endrr; if (!CHECK_LEN(header, p1, qlen, 0)) return 0; /* bad packet */ } } if (!found && !option_bool(OPT_NO_NEG)) { if (!searched_soa) { searched_soa = 1; ttl = find_soa(header, qlen, NULL, doctored); } if (ttl) cache_insert(NULL, &addr, C_IN, now, ttl, name_encoding | F_REVERSE | F_NEG | flags | (secure ? F_DNSSECOK : 0)); } } else { /* everything other than PTR */ struct crec *newc; int addrlen = 0; if (qtype == T_A) { addrlen = INADDRSZ; flags |= F_IPV4; } else if (qtype == T_AAAA) { addrlen = IN6ADDRSZ; flags |= F_IPV6; } else if (qtype == T_SRV) flags |= F_SRV; else continue; cname_loop1: if (!(p1 = skip_questions(header, qlen))) return 0; for (j = 0; j < ntohs(header->ancount); j++) { int secflag = 0; if (!(res = extract_name(header, qlen, &p1, name, 0, 10))) return 0; /* bad packet */ GETSHORT(aqtype, p1); GETSHORT(aqclass, p1); GETLONG(attl, p1); if ((daemon->max_ttl != 0) && (attl > daemon->max_ttl) && !is_sign) { (p1) -= 4; PUTLONG(daemon->max_ttl, p1); } GETSHORT(ardlen, p1); endrr = p1+ardlen; if (aqclass == C_IN && res != 2 && (aqtype == T_CNAME || aqtype == qtype)) { #ifdef HAVE_DNSSEC if (option_bool(OPT_DNSSEC_VALID) && daemon->rr_status[j]) secflag = F_DNSSECOK; #endif if (aqtype == T_CNAME) { if (!cname_count--) return 0; /* looped CNAMES */ newc = cache_insert(name, NULL, C_IN, now, attl, F_CNAME | F_FORWARD | secflag); if (newc) { newc->addr.cname.target.cache = NULL; /* anything other than zero, to avoid being mistaken for CNAME to interface-name */ newc->addr.cname.uid = 1; if (cpp) { next_uid(newc); cpp->addr.cname.target.cache = newc; cpp->addr.cname.uid = newc->uid; } } cpp = newc; if (attl < cttl) cttl = attl; if (!extract_name(header, qlen, &p1, name, 1, 0)) return 0; goto cname_loop1; } else if (!(flags & F_NXDOMAIN)) { found = 1; if (flags & F_SRV) { unsigned char *tmp = namep; if (!CHECK_LEN(header, p1, qlen, 6)) return 0; /* bad packet */ GETSHORT(addr.srv.priority, p1); GETSHORT(addr.srv.weight, p1); GETSHORT(addr.srv.srvport, p1); if (!extract_name(header, qlen, &p1, name, 1, 0)) return 0; addr.srv.targetlen = strlen(name) + 1; /* include terminating zero */ if (!(addr.srv.target = blockdata_alloc(name, addr.srv.targetlen))) return 0; /* we overwrote the original name, so get it back here. */ if (!extract_name(header, qlen, &tmp, name, 1, 0)) return 0; } else { /* copy address into aligned storage */ if (!CHECK_LEN(header, p1, qlen, addrlen)) return 0; /* bad packet */ memcpy(&addr, p1, addrlen); /* check for returned address in private space */ if (check_rebind) { if ((flags & F_IPV4) && private_net(addr.addr4, !option_bool(OPT_LOCAL_REBIND))) return 1; if ((flags & F_IPV6) && IN6_IS_ADDR_V4MAPPED(&addr.addr6)) { struct in_addr v4; v4.s_addr = ((const uint32_t *) (&addr.addr6))[3]; if (private_net(v4, !option_bool(OPT_LOCAL_REBIND))) return 1; } } #ifdef HAVE_IPSET if (ipsets && (flags & (F_IPV4 | F_IPV6))) { ipsets_cur = ipsets; while (*ipsets_cur) { log_query((flags & (F_IPV4 | F_IPV6)) | F_IPSET, name, &addr, *ipsets_cur); add_to_ipset(*ipsets_cur++, &addr, flags, 0); } } #endif } newc = cache_insert(name, &addr, C_IN, now, attl, flags | F_FORWARD | secflag); if (newc && cpp) { next_uid(newc); cpp->addr.cname.target.cache = newc; cpp->addr.cname.uid = newc->uid; } cpp = NULL; } } p1 = endrr; if (!CHECK_LEN(header, p1, qlen, 0)) return 0; /* bad packet */ } if (!found && !option_bool(OPT_NO_NEG)) { if (!searched_soa) { searched_soa = 1; ttl = find_soa(header, qlen, NULL, doctored); } /* If there's no SOA to get the TTL from, but there is a CNAME pointing at this, inherit its TTL */ if (ttl || cpp) { newc = cache_insert(name, NULL, C_IN, now, ttl ? ttl : cttl, F_FORWARD | F_NEG | flags | (secure ? F_DNSSECOK : 0)); if (newc && cpp) { next_uid(newc); cpp->addr.cname.target.cache = newc; cpp->addr.cname.uid = newc->uid; } } } } } /* Don't put stuff from a truncated packet into the cache. Don't cache replies from non-recursive nameservers, since we may get a reply containing a CNAME but not its target, even though the target does exist. */ if (!(header->hb3 & HB3_TC) && !(header->hb4 & HB4_CD) && (header->hb4 & HB4_RA) && !no_cache_dnssec) cache_end_insert(); return 0; } /* If the packet holds exactly one query return F_IPV4 or F_IPV6 and leave the name from the query in name */ unsigned int extract_request(struct dns_header *header, size_t qlen, char *name, unsigned short *typep) { unsigned char *p = (unsigned char *)(header+1); int qtype, qclass; if (typep) *typep = 0; if (ntohs(header->qdcount) != 1 || OPCODE(header) != QUERY) return 0; /* must be exactly one query. */ if (!extract_name(header, qlen, &p, name, 1, 4)) return 0; /* bad packet */ GETSHORT(qtype, p); GETSHORT(qclass, p); if (typep) *typep = qtype; if (qclass == C_IN) { if (qtype == T_A) return F_IPV4; if (qtype == T_AAAA) return F_IPV6; if (qtype == T_ANY) return F_IPV4 | F_IPV6; } /* F_DNSSECOK as agument to search_servers() inhibits forwarding to servers for domains without a trust anchor. This make the behaviour for DS and DNSKEY queries we forward the same as for DS and DNSKEY queries we originate. */ if (qtype == T_DS || qtype == T_DNSKEY) return F_DNSSECOK; return F_QUERY; } size_t setup_reply(struct dns_header *header, size_t qlen, union all_addr *addrp, unsigned int flags, unsigned long ttl) { unsigned char *p; if (!(p = skip_questions(header, qlen))) return 0; /* clear authoritative and truncated flags, set QR flag */ header->hb3 = (header->hb3 & ~(HB3_AA | HB3_TC )) | HB3_QR; /* clear AD flag, set RA flag */ header->hb4 = (header->hb4 & ~HB4_AD) | HB4_RA; header->nscount = htons(0); header->arcount = htons(0); header->ancount = htons(0); /* no answers unless changed below */ if (flags == F_NOERR) SET_RCODE(header, NOERROR); /* empty domain */ else if (flags == F_NXDOMAIN) SET_RCODE(header, NXDOMAIN); else if (flags == F_SERVFAIL) { union all_addr a; a.log.rcode = SERVFAIL; log_query(F_CONFIG | F_RCODE, "error", &a, NULL); SET_RCODE(header, SERVFAIL); } else if (flags & ( F_IPV4 | F_IPV6)) { if (flags & F_IPV4) { /* we know the address */ SET_RCODE(header, NOERROR); header->ancount = htons(1); header->hb3 |= HB3_AA; add_resource_record(header, NULL, NULL, sizeof(struct dns_header), &p, ttl, NULL, T_A, C_IN, "4", addrp); } if (flags & F_IPV6) { SET_RCODE(header, NOERROR); header->ancount = htons(ntohs(header->ancount) + 1); header->hb3 |= HB3_AA; add_resource_record(header, NULL, NULL, sizeof(struct dns_header), &p, ttl, NULL, T_AAAA, C_IN, "6", addrp); } } else /* nowhere to forward to */ { union all_addr a; a.log.rcode = REFUSED; log_query(F_CONFIG | F_RCODE, "error", &a, NULL); SET_RCODE(header, REFUSED); } return p - (unsigned char *)header; } /* check if name matches local names ie from /etc/hosts or DHCP or local mx names. */ int check_for_local_domain(char *name, time_t now) { struct mx_srv_record *mx; struct txt_record *txt; struct interface_name *intr; struct ptr_record *ptr; struct naptr *naptr; for (naptr = daemon->naptr; naptr; naptr = naptr->next) if (hostname_issubdomain(name, naptr->name)) return 1; for (mx = daemon->mxnames; mx; mx = mx->next) if (hostname_issubdomain(name, mx->name)) return 1; for (txt = daemon->txt; txt; txt = txt->next) if (hostname_issubdomain(name, txt->name)) return 1; for (intr = daemon->int_names; intr; intr = intr->next) if (hostname_issubdomain(name, intr->name)) return 1; for (ptr = daemon->ptr; ptr; ptr = ptr->next) if (hostname_issubdomain(name, ptr->name)) return 1; if (cache_find_non_terminal(name, now)) return 1; return 0; } /* Is the packet a reply with the answer address equal to addr? If so mung is into an NXDOMAIN reply and also put that information in the cache. */ int check_for_bogus_wildcard(struct dns_header *header, size_t qlen, char *name, struct bogus_addr *baddr, time_t now) { unsigned char *p; int i, qtype, qclass, rdlen; unsigned long ttl; struct bogus_addr *baddrp; /* skip over questions */ if (!(p = skip_questions(header, qlen))) return 0; /* bad packet */ for (i = ntohs(header->ancount); i != 0; i--) { if (!extract_name(header, qlen, &p, name, 1, 10)) return 0; /* bad packet */ GETSHORT(qtype, p); GETSHORT(qclass, p); GETLONG(ttl, p); GETSHORT(rdlen, p); if (qclass == C_IN && qtype == T_A) { if (!CHECK_LEN(header, p, qlen, INADDRSZ)) return 0; for (baddrp = baddr; baddrp; baddrp = baddrp->next) if (memcmp(&baddrp->addr, p, INADDRSZ) == 0) { /* Found a bogus address. Insert that info here, since there no SOA record to get the ttl from in the normal processing */ cache_start_insert(); cache_insert(name, NULL, C_IN, now, ttl, F_IPV4 | F_FORWARD | F_NEG | F_NXDOMAIN); cache_end_insert(); return 1; } } if (!ADD_RDLEN(header, p, qlen, rdlen)) return 0; } return 0; } int check_for_ignored_address(struct dns_header *header, size_t qlen, struct bogus_addr *baddr) { unsigned char *p; int i, qtype, qclass, rdlen; struct bogus_addr *baddrp; /* skip over questions */ if (!(p = skip_questions(header, qlen))) return 0; /* bad packet */ for (i = ntohs(header->ancount); i != 0; i--) { if (!(p = skip_name(p, header, qlen, 10))) return 0; /* bad packet */ GETSHORT(qtype, p); GETSHORT(qclass, p); p += 4; /* TTL */ GETSHORT(rdlen, p); if (qclass == C_IN && qtype == T_A) { if (!CHECK_LEN(header, p, qlen, INADDRSZ)) return 0; for (baddrp = baddr; baddrp; baddrp = baddrp->next) if (memcmp(&baddrp->addr, p, INADDRSZ) == 0) return 1; } if (!ADD_RDLEN(header, p, qlen, rdlen)) return 0; } return 0; } int add_resource_record(struct dns_header *header, char *limit, int *truncp, int nameoffset, unsigned char **pp, unsigned long ttl, int *offset, unsigned short type, unsigned short class, char *format, ...) { va_list ap; unsigned char *sav, *p = *pp; int j; unsigned short usval; long lval; char *sval; #define CHECK_LIMIT(size) \ if (limit && p + (size) > (unsigned char*)limit) goto truncated; va_start(ap, format); /* make ap point to 1st unamed argument */ if (truncp && *truncp) goto truncated; if (nameoffset > 0) { CHECK_LIMIT(2); PUTSHORT(nameoffset | 0xc000, p); } else { char *name = va_arg(ap, char *); if (name && !(p = do_rfc1035_name(p, name, limit))) goto truncated; if (nameoffset < 0) { CHECK_LIMIT(2); PUTSHORT(-nameoffset | 0xc000, p); } else { CHECK_LIMIT(1); *p++ = 0; } } /* type (2) + class (2) + ttl (4) + rdlen (2) */ CHECK_LIMIT(10); PUTSHORT(type, p); PUTSHORT(class, p); PUTLONG(ttl, p); /* TTL */ sav = p; /* Save pointer to RDLength field */ PUTSHORT(0, p); /* Placeholder RDLength */ for (; *format; format++) switch (*format) { case '6': CHECK_LIMIT(IN6ADDRSZ); sval = va_arg(ap, char *); memcpy(p, sval, IN6ADDRSZ); p += IN6ADDRSZ; break; case '4': CHECK_LIMIT(INADDRSZ); sval = va_arg(ap, char *); memcpy(p, sval, INADDRSZ); p += INADDRSZ; break; case 'b': CHECK_LIMIT(1); usval = va_arg(ap, int); *p++ = usval; break; case 's': CHECK_LIMIT(2); usval = va_arg(ap, int); PUTSHORT(usval, p); break; case 'l': CHECK_LIMIT(4); lval = va_arg(ap, long); PUTLONG(lval, p); break; case 'd': /* get domain-name answer arg and store it in RDATA field */ if (offset) *offset = p - (unsigned char *)header; if (!(p = do_rfc1035_name(p, va_arg(ap, char *), limit))) goto truncated; CHECK_LIMIT(1); *p++ = 0; break; case 't': usval = va_arg(ap, int); CHECK_LIMIT(usval); sval = va_arg(ap, char *); if (usval != 0) memcpy(p, sval, usval); p += usval; break; case 'z': sval = va_arg(ap, char *); usval = sval ? strlen(sval) : 0; if (usval > 255) usval = 255; CHECK_LIMIT(usval + 1); *p++ = (unsigned char)usval; memcpy(p, sval, usval); p += usval; break; } va_end(ap); /* clean up variable argument pointer */ /* Now, store real RDLength. sav already checked against limit. */ j = p - sav - 2; PUTSHORT(j, sav); *pp = p; return 1; truncated: va_end(ap); if (truncp) *truncp = 1; return 0; #undef CHECK_LIMIT } static unsigned long crec_ttl(struct crec *crecp, time_t now) { /* Return 0 ttl for DHCP entries, which might change before the lease expires, unless configured otherwise. */ if (crecp->flags & F_DHCP) { int conf_ttl = daemon->use_dhcp_ttl ? daemon->dhcp_ttl : daemon->local_ttl; /* Apply ceiling of actual lease length to configured TTL. */ if (!(crecp->flags & F_IMMORTAL) && (crecp->ttd - now) < conf_ttl) return crecp->ttd - now; return conf_ttl; } /* Immortal entries other than DHCP are local, and hold TTL in TTD field. */ if (crecp->flags & F_IMMORTAL) return crecp->ttd; /* Return the Max TTL value if it is lower than the actual TTL */ if (daemon->max_ttl == 0 || ((unsigned)(crecp->ttd - now) < daemon->max_ttl)) return crecp->ttd - now; else return daemon->max_ttl; } /* return zero if we can't answer from cache, or packet size if we can */ size_t answer_request(struct dns_header *header, char *limit, size_t qlen, struct in_addr local_addr, struct in_addr local_netmask, time_t now, int ad_reqd, int do_bit, int have_pseudoheader) { char *name = daemon->namebuff; unsigned char *p, *ansp; unsigned int qtype, qclass; union all_addr addr; int nameoffset; unsigned short flag; int q, ans, anscount = 0, addncount = 0; int dryrun = 0; struct crec *crecp; int nxdomain = 0, notimp = 0, auth = 1, trunc = 0, sec_data = 1; struct mx_srv_record *rec; size_t len; /* never answer queries with RD unset, to avoid cache snooping. */ if (!(header->hb3 & HB3_RD) || ntohs(header->ancount) != 0 || ntohs(header->nscount) != 0 || ntohs(header->qdcount) == 0 || OPCODE(header) != QUERY ) return 0; /* Don't return AD set if checking disabled. */ if (header->hb4 & HB4_CD) sec_data = 0; /* If there is an additional data section then it will be overwritten by partial replies, so we have to do a dry run to see if we can answer the query. */ if (ntohs(header->arcount) != 0) dryrun = 1; for (rec = daemon->mxnames; rec; rec = rec->next) rec->offset = 0; rerun: /* determine end of question section (we put answers there) */ if (!(ansp = skip_questions(header, qlen))) return 0; /* bad packet */ /* now process each question, answers go in RRs after the question */ p = (unsigned char *)(header+1); for (q = ntohs(header->qdcount); q != 0; q--) { /* save pointer to name for copying into answers */ nameoffset = p - (unsigned char *)header; /* now extract name as .-concatenated string into name */ if (!extract_name(header, qlen, &p, name, 1, 4)) return 0; /* bad packet */ GETSHORT(qtype, p); GETSHORT(qclass, p); ans = 0; /* have we answered this question */ if (qtype == T_TXT || qtype == T_ANY) { struct txt_record *t; for(t = daemon->txt; t ; t = t->next) { if (t->class == qclass && hostname_isequal(name, t->name)) { ans = 1, sec_data = 0; if (!dryrun) { unsigned long ttl = daemon->local_ttl; int ok = 1; #ifndef NO_ID /* Dynamically generate stat record */ if (t->stat != 0) { ttl = 0; if (!cache_make_stat(t)) ok = 0; } #endif if (ok) { log_query(F_CONFIG | F_RRNAME, name, NULL, ""); if (add_resource_record(header, limit, &trunc, nameoffset, &ansp, ttl, NULL, T_TXT, t->class, "t", t->len, t->txt)) anscount++; } } } } } if (qclass == C_CHAOS) { /* don't forward *.bind and *.server chaos queries - always reply with NOTIMP */ if (hostname_issubdomain("bind", name) || hostname_issubdomain("server", name)) { if (!ans) { notimp = 1, auth = 0; if (!dryrun) { addr.log.rcode = NOTIMP; log_query(F_CONFIG | F_RCODE, name, &addr, NULL); } ans = 1, sec_data = 0; } } } if (qclass == C_IN) { struct txt_record *t; for (t = daemon->rr; t; t = t->next) if ((t->class == qtype || qtype == T_ANY) && hostname_isequal(name, t->name)) { ans = 1; sec_data = 0; if (!dryrun) { log_query(F_CONFIG | F_RRNAME, name, NULL, querystr(NULL, t->class)); if (add_resource_record(header, limit, &trunc, nameoffset, &ansp, daemon->local_ttl, NULL, t->class, C_IN, "t", t->len, t->txt)) anscount++; } } if (qtype == T_PTR || qtype == T_ANY) { /* see if it's w.z.y.z.in-addr.arpa format */ int is_arpa = in_arpa_name_2_addr(name, &addr); struct ptr_record *ptr; struct interface_name* intr = NULL; for (ptr = daemon->ptr; ptr; ptr = ptr->next) if (hostname_isequal(name, ptr->name)) break; if (is_arpa == F_IPV4) for (intr = daemon->int_names; intr; intr = intr->next) { struct addrlist *addrlist; for (addrlist = intr->addr; addrlist; addrlist = addrlist->next) if (!(addrlist->flags & ADDRLIST_IPV6) && addr.addr4.s_addr == addrlist->addr.addr4.s_addr) break; if (addrlist) break; else while (intr->next && strcmp(intr->intr, intr->next->intr) == 0) intr = intr->next; } else if (is_arpa == F_IPV6) for (intr = daemon->int_names; intr; intr = intr->next) { struct addrlist *addrlist; for (addrlist = intr->addr; addrlist; addrlist = addrlist->next) if ((addrlist->flags & ADDRLIST_IPV6) && IN6_ARE_ADDR_EQUAL(&addr.addr6, &addrlist->addr.addr6)) break; if (addrlist) break; else while (intr->next && strcmp(intr->intr, intr->next->intr) == 0) intr = intr->next; } if (intr) { sec_data = 0; ans = 1; if (!dryrun) { log_query(is_arpa | F_REVERSE | F_CONFIG, intr->name, &addr, NULL); if (add_resource_record(header, limit, &trunc, nameoffset, &ansp, daemon->local_ttl, NULL, T_PTR, C_IN, "d", intr->name)) anscount++; } } else if (ptr) { ans = 1; sec_data = 0; if (!dryrun) { log_query(F_CONFIG | F_RRNAME, name, NULL, ""); for (ptr = daemon->ptr; ptr; ptr = ptr->next) if (hostname_isequal(name, ptr->name) && add_resource_record(header, limit, &trunc, nameoffset, &ansp, daemon->local_ttl, NULL, T_PTR, C_IN, "d", ptr->ptr)) anscount++; } } else if ((crecp = cache_find_by_addr(NULL, &addr, now, is_arpa))) { /* Don't use cache when DNSSEC data required, unless we know that the zone is unsigned, which implies that we're doing validation. */ if ((crecp->flags & (F_HOSTS | F_DHCP | F_CONFIG)) || !do_bit || (option_bool(OPT_DNSSEC_VALID) && !(crecp->flags & F_DNSSECOK))) { do { /* don't answer wildcard queries with data not from /etc/hosts or dhcp leases */ if (qtype == T_ANY && !(crecp->flags & (F_HOSTS | F_DHCP))) continue; if (!(crecp->flags & F_DNSSECOK)) sec_data = 0; ans = 1; if (crecp->flags & F_NEG) { auth = 0; if (crecp->flags & F_NXDOMAIN) nxdomain = 1; if (!dryrun) log_query(crecp->flags & ~F_FORWARD, name, &addr, NULL); } else { if (!(crecp->flags & (F_HOSTS | F_DHCP))) auth = 0; if (!dryrun) { log_query(crecp->flags & ~F_FORWARD, cache_get_name(crecp), &addr, record_source(crecp->uid)); if (add_resource_record(header, limit, &trunc, nameoffset, &ansp, crec_ttl(crecp, now), NULL, T_PTR, C_IN, "d", cache_get_name(crecp))) anscount++; } } } while ((crecp = cache_find_by_addr(crecp, &addr, now, is_arpa))); } } else if (is_rev_synth(is_arpa, &addr, name)) { ans = 1; sec_data = 0; if (!dryrun) { log_query(F_CONFIG | F_REVERSE | is_arpa, name, &addr, NULL); if (add_resource_record(header, limit, &trunc, nameoffset, &ansp, daemon->local_ttl, NULL, T_PTR, C_IN, "d", name)) anscount++; } } else if (option_bool(OPT_BOGUSPRIV) && ( (is_arpa == F_IPV6 && private_net6(&addr.addr6)) || (is_arpa == F_IPV4 && private_net(addr.addr4, 1)))) { struct server *serv; unsigned int namelen = strlen(name); char *nameend = name + namelen; /* see if have rev-server set */ for (serv = daemon->servers; serv; serv = serv->next) { unsigned int domainlen; char *matchstart; if ((serv->flags & (SERV_HAS_DOMAIN | SERV_NO_ADDR)) != SERV_HAS_DOMAIN) continue; domainlen = strlen(serv->domain); if (domainlen == 0 || domainlen > namelen) continue; matchstart = nameend - domainlen; if (hostname_isequal(matchstart, serv->domain) && (namelen == domainlen || *(matchstart-1) == '.' )) break; } /* if no configured server, not in cache, enabled and private IPV4 address, return NXDOMAIN */ if (!serv) { ans = 1; sec_data = 0; nxdomain = 1; if (!dryrun) log_query(F_CONFIG | F_REVERSE | is_arpa | F_NEG | F_NXDOMAIN, name, &addr, NULL); } } } for (flag = F_IPV4; flag; flag = (flag == F_IPV4) ? F_IPV6 : 0) { unsigned short type = (flag == F_IPV6) ? T_AAAA : T_A; struct interface_name *intr; if (qtype != type && qtype != T_ANY) continue; /* interface name stuff */ intname_restart: for (intr = daemon->int_names; intr; intr = intr->next) if (hostname_isequal(name, intr->name)) break; if (intr) { struct addrlist *addrlist; int gotit = 0, localise = 0; enumerate_interfaces(0); /* See if a putative address is on the network from which we received the query, is so we'll filter other answers. */ if (local_addr.s_addr != 0 && option_bool(OPT_LOCALISE) && type == T_A) for (intr = daemon->int_names; intr; intr = intr->next) if (hostname_isequal(name, intr->name)) for (addrlist = intr->addr; addrlist; addrlist = addrlist->next) if (!(addrlist->flags & ADDRLIST_IPV6) && is_same_net(addrlist->addr.addr4, local_addr, local_netmask)) { localise = 1; break; } for (intr = daemon->int_names; intr; intr = intr->next) if (hostname_isequal(name, intr->name)) { for (addrlist = intr->addr; addrlist; addrlist = addrlist->next) if (((addrlist->flags & ADDRLIST_IPV6) ? T_AAAA : T_A) == type) { if (localise && !is_same_net(addrlist->addr.addr4, local_addr, local_netmask)) continue; if (addrlist->flags & ADDRLIST_REVONLY) continue; ans = 1; sec_data = 0; if (!dryrun) { gotit = 1; log_query(F_FORWARD | F_CONFIG | flag, name, &addrlist->addr, NULL); if (add_resource_record(header, limit, &trunc, nameoffset, &ansp, daemon->local_ttl, NULL, type, C_IN, type == T_A ? "4" : "6", &addrlist->addr)) anscount++; } } } if (!dryrun && !gotit) log_query(F_FORWARD | F_CONFIG | flag | F_NEG, name, NULL, NULL); continue; } cname_restart: if ((crecp = cache_find_by_name(NULL, name, now, flag | F_CNAME | (dryrun ? F_NO_RR : 0)))) { int localise = 0; /* See if a putative address is on the network from which we received the query, is so we'll filter other answers. */ if (local_addr.s_addr != 0 && option_bool(OPT_LOCALISE) && flag == F_IPV4) { struct crec *save = crecp; do { if ((crecp->flags & F_HOSTS) && is_same_net(crecp->addr.addr4, local_addr, local_netmask)) { localise = 1; break; } } while ((crecp = cache_find_by_name(crecp, name, now, flag | F_CNAME))); crecp = save; } /* If the client asked for DNSSEC don't use cached data. */ if ((crecp->flags & (F_HOSTS | F_DHCP | F_CONFIG)) || !do_bit || (option_bool(OPT_DNSSEC_VALID) && !(crecp->flags & F_DNSSECOK))) do { /* don't answer wildcard queries with data not from /etc/hosts or DHCP leases */ if (qtype == T_ANY && !(crecp->flags & (F_HOSTS | F_DHCP | F_CONFIG))) break; if (!(crecp->flags & F_DNSSECOK)) sec_data = 0; if (crecp->flags & F_CNAME) { char *cname_target = cache_get_cname_target(crecp); if (!dryrun) { log_query(crecp->flags, name, NULL, record_source(crecp->uid)); if (add_resource_record(header, limit, &trunc, nameoffset, &ansp, crec_ttl(crecp, now), &nameoffset, T_CNAME, C_IN, "d", cname_target)) anscount++; } strcpy(name, cname_target); /* check if target interface_name */ if (crecp->addr.cname.uid == SRC_INTERFACE) goto intname_restart; else goto cname_restart; } if (crecp->flags & F_NEG) { ans = 1; auth = 0; if (crecp->flags & F_NXDOMAIN) nxdomain = 1; if (!dryrun) log_query(crecp->flags, name, NULL, NULL); } else { /* If we are returning local answers depending on network, filter here. */ if (localise && (crecp->flags & F_HOSTS) && !is_same_net(crecp->addr.addr4, local_addr, local_netmask)) continue; if (!(crecp->flags & (F_HOSTS | F_DHCP))) auth = 0; ans = 1; if (!dryrun) { log_query(crecp->flags & ~F_REVERSE, name, &crecp->addr, record_source(crecp->uid)); if (add_resource_record(header, limit, &trunc, nameoffset, &ansp, crec_ttl(crecp, now), NULL, type, C_IN, type == T_A ? "4" : "6", &crecp->addr)) anscount++; } } } while ((crecp = cache_find_by_name(crecp, name, now, flag | F_CNAME))); } else if (is_name_synthetic(flag, name, &addr)) { ans = 1, sec_data = 0; if (!dryrun) { log_query(F_FORWARD | F_CONFIG | flag, name, &addr, NULL); if (add_resource_record(header, limit, &trunc, nameoffset, &ansp, daemon->local_ttl, NULL, type, C_IN, type == T_A ? "4" : "6", &addr)) anscount++; } } } if (qtype == T_CNAME || qtype == T_ANY) { if ((crecp = cache_find_by_name(NULL, name, now, F_CNAME | (dryrun ? F_NO_RR : 0))) && (qtype == T_CNAME || (crecp->flags & F_CONFIG)) && ((crecp->flags & F_CONFIG) || !do_bit || (option_bool(OPT_DNSSEC_VALID) && !(crecp->flags & F_DNSSECOK)))) { if (!(crecp->flags & F_DNSSECOK)) sec_data = 0; ans = 1; if (!dryrun) { log_query(crecp->flags, name, NULL, record_source(crecp->uid)); if (add_resource_record(header, limit, &trunc, nameoffset, &ansp, crec_ttl(crecp, now), &nameoffset, T_CNAME, C_IN, "d", cache_get_cname_target(crecp))) anscount++; } } } if (qtype == T_MX || qtype == T_ANY) { int found = 0; for (rec = daemon->mxnames; rec; rec = rec->next) if (!rec->issrv && hostname_isequal(name, rec->name)) { ans = found = 1; sec_data = 0; if (!dryrun) { int offset; log_query(F_CONFIG | F_RRNAME, name, NULL, ""); if (add_resource_record(header, limit, &trunc, nameoffset, &ansp, daemon->local_ttl, &offset, T_MX, C_IN, "sd", rec->weight, rec->target)) { anscount++; if (rec->target) rec->offset = offset; } } } if (!found && (option_bool(OPT_SELFMX) || option_bool(OPT_LOCALMX)) && cache_find_by_name(NULL, name, now, F_HOSTS | F_DHCP | F_NO_RR)) { ans = 1; sec_data = 0; if (!dryrun) { log_query(F_CONFIG | F_RRNAME, name, NULL, ""); if (add_resource_record(header, limit, &trunc, nameoffset, &ansp, daemon->local_ttl, NULL, T_MX, C_IN, "sd", 1, option_bool(OPT_SELFMX) ? name : daemon->mxtarget)) anscount++; } } } if (qtype == T_SRV || qtype == T_ANY) { int found = 0; struct mx_srv_record *move = NULL, **up = &daemon->mxnames; for (rec = daemon->mxnames; rec; rec = rec->next) if (rec->issrv && hostname_isequal(name, rec->name)) { found = ans = 1; sec_data = 0; if (!dryrun) { int offset; log_query(F_CONFIG | F_RRNAME, name, NULL, ""); if (add_resource_record(header, limit, &trunc, nameoffset, &ansp, daemon->local_ttl, &offset, T_SRV, C_IN, "sssd", rec->priority, rec->weight, rec->srvport, rec->target)) { anscount++; if (rec->target) rec->offset = offset; } } /* unlink first SRV record found */ if (!move) { move = rec; *up = rec->next; } else up = &rec->next; } else up = &rec->next; /* put first SRV record back at the end. */ if (move) { *up = move; move->next = NULL; } if (!found) { cname_srv_restart: if ((crecp = cache_find_by_name(NULL, name, now, F_CNAME | F_SRV | (dryrun ? F_NO_RR : 0))) && (!do_bit || (option_bool(OPT_DNSSEC_VALID) && !(crecp->flags & F_DNSSECOK)))) { if (!(crecp->flags & F_DNSSECOK)) sec_data = 0; auth = 0; found = ans = 1; do { if (crecp->flags & F_CNAME) { char *cname_target = cache_get_cname_target(crecp); if (!dryrun) { log_query(crecp->flags, name, NULL, record_source(crecp->uid)); if (add_resource_record(header, limit, &trunc, nameoffset, &ansp, crec_ttl(crecp, now), &nameoffset, T_CNAME, C_IN, "d", cname_target)) anscount++; } strcpy(name, cname_target); goto cname_srv_restart; } else if (crecp->flags & F_NEG) { if (crecp->flags & F_NXDOMAIN) nxdomain = 1; if (!dryrun) log_query(crecp->flags, name, NULL, NULL); } else { unsigned char *p1 = ((unsigned char *)header) + nameoffset; if (!dryrun) { log_query(crecp->flags, name, NULL, 0); blockdata_retrieve(crecp->addr.srv.target, crecp->addr.srv.targetlen, name); if (add_resource_record(header, limit, &trunc, nameoffset, &ansp, crec_ttl(crecp, now), NULL, T_SRV, C_IN, "sssd", crecp->addr.srv.priority, crecp->addr.srv.weight, crecp->addr.srv.srvport, name)) anscount++; /* restore name we overwrote */ if (!extract_name(header, qlen, &p1, name, 1, 0)) return 0; /* bad packet */ } } } while ((crecp = cache_find_by_name(crecp, name, now, F_SRV | F_CNAME))); } } if (!found && option_bool(OPT_FILTER) && (qtype == T_SRV || (qtype == T_ANY && strchr(name, '_')))) { ans = 1; sec_data = 0; if (!dryrun) log_query(F_CONFIG | F_NEG, name, NULL, NULL); } } if (qtype == T_NAPTR || qtype == T_ANY) { struct naptr *na; for (na = daemon->naptr; na; na = na->next) if (hostname_isequal(name, na->name)) { ans = 1; sec_data = 0; if (!dryrun) { log_query(F_CONFIG | F_RRNAME, name, NULL, ""); if (add_resource_record(header, limit, &trunc, nameoffset, &ansp, daemon->local_ttl, NULL, T_NAPTR, C_IN, "sszzzd", na->order, na->pref, na->flags, na->services, na->regexp, na->replace)) anscount++; } } } if (qtype == T_MAILB) ans = 1, nxdomain = 1, sec_data = 0; if (qtype == T_SOA && option_bool(OPT_FILTER)) { ans = 1; sec_data = 0; if (!dryrun) log_query(F_CONFIG | F_NEG, name, &addr, NULL); } } if (!ans) return 0; /* failed to answer a question */ } if (dryrun) { dryrun = 0; goto rerun; } /* create an additional data section, for stuff in SRV and MX record replies. */ for (rec = daemon->mxnames; rec; rec = rec->next) if (rec->offset != 0) { /* squash dupes */ struct mx_srv_record *tmp; for (tmp = rec->next; tmp; tmp = tmp->next) if (tmp->offset != 0 && hostname_isequal(rec->target, tmp->target)) tmp->offset = 0; crecp = NULL; while ((crecp = cache_find_by_name(crecp, rec->target, now, F_IPV4 | F_IPV6))) { int type = crecp->flags & F_IPV4 ? T_A : T_AAAA; if (crecp->flags & F_NEG) continue; if (add_resource_record(header, limit, NULL, rec->offset, &ansp, crec_ttl(crecp, now), NULL, type, C_IN, crecp->flags & F_IPV4 ? "4" : "6", &crecp->addr)) addncount++; } } /* done all questions, set up header and return length of result */ /* clear authoritative and truncated flags, set QR flag */ header->hb3 = (header->hb3 & ~(HB3_AA | HB3_TC)) | HB3_QR; /* set RA flag */ header->hb4 |= HB4_RA; /* authoritative - only hosts and DHCP derived names. */ if (auth) header->hb3 |= HB3_AA; /* truncation */ if (trunc) header->hb3 |= HB3_TC; if (nxdomain) SET_RCODE(header, NXDOMAIN); else if (notimp) SET_RCODE(header, NOTIMP); else SET_RCODE(header, NOERROR); /* no error */ header->ancount = htons(anscount); header->nscount = htons(0); header->arcount = htons(addncount); len = ansp - (unsigned char *)header; /* Advertise our packet size limit in our reply */ if (have_pseudoheader) len = add_pseudoheader(header, len, (unsigned char *)limit, daemon->edns_pktsz, 0, NULL, 0, do_bit, 0); if (ad_reqd && sec_data) header->hb4 |= HB4_AD; else header->hb4 &= ~HB4_AD; return len; }