/* Unix SMB/CIFS implementation. DNS Server Copyright (C) Amitay Isaacs 2011 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; either version 3 of the License, or (at your option) any later version. 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 "includes.h" #include "dnsserver.h" #include "lib/replace/system/network.h" #include "librpc/gen_ndr/ndr_dnsp.h" #include "librpc/gen_ndr/ndr_dnsserver.h" struct IP4_ARRAY *ip4_array_copy(TALLOC_CTX *mem_ctx, struct IP4_ARRAY *ip4) { struct IP4_ARRAY *ret; if (!ip4) { return NULL; } ret = talloc_zero(mem_ctx, struct IP4_ARRAY); if (!ret) { return ret; } ret->AddrCount = ip4->AddrCount; if (ip4->AddrCount > 0) { ret->AddrArray = talloc_zero_array(mem_ctx, unsigned int, ip4->AddrCount); if (ret->AddrArray) { memcpy(ret->AddrArray, ip4->AddrArray, sizeof(unsigned int) * ip4->AddrCount); } else { talloc_free(ret); return NULL; } } return ret; } struct DNS_ADDR_ARRAY *ip4_array_to_dns_addr_array(TALLOC_CTX *mem_ctx, struct IP4_ARRAY *ip4) { struct DNS_ADDR_ARRAY *ret; int i; if (!ip4) { return NULL; } ret = talloc_zero(mem_ctx, struct DNS_ADDR_ARRAY); if (!ret) { return ret; } ret->MaxCount = ip4->AddrCount; ret->AddrCount = ip4->AddrCount; ret->Family = AF_INET; if (ip4->AddrCount > 0) { ret->AddrArray = talloc_zero_array(mem_ctx, struct DNS_ADDR, ip4->AddrCount); if (ret->AddrArray) { for (i=0; iAddrCount; i++) { ret->AddrArray[i].MaxSa[0] = 0x02; ret->AddrArray[i].MaxSa[3] = 53; memcpy(&ret->AddrArray[i].MaxSa[4], ip4->AddrArray, sizeof(unsigned int)); ret->AddrArray[i].DnsAddrUserDword[0] = 6; } } else { talloc_free(ret); return NULL; } } return ret; } struct IP4_ARRAY *dns_addr_array_to_ip4_array(TALLOC_CTX *mem_ctx, struct DNS_ADDR_ARRAY *ip) { struct IP4_ARRAY *ret; int i, count, curr; if (ip == NULL) { return NULL; } /* We must only return IPv4 addresses. The passed DNS_ADDR_ARRAY may contain: - only ipv4 addresses - only ipv6 addresses - a mixture of both - an empty array */ ret = talloc_zero(mem_ctx, struct IP4_ARRAY); if (!ret) { return ret; } if (ip->AddrCount == 0 || ip->Family == AF_INET6) { ret->AddrCount = 0; return ret; } /* Now only ipv4 addresses or a mixture are left */ count = 0; for (i = 0; i < ip->AddrCount; i++) { if (ip->AddrArray[i].MaxSa[0] == 0x02) { /* Is ipv4 */ count++; } } if (count == 0) { /* should not happen */ ret->AddrCount = 0; return ret; } ret->AddrArray = talloc_zero_array(mem_ctx, uint32_t, count); if (ret->AddrArray) { curr = 0; for (i = 0; i < ip->AddrCount; i++) { if (ip->AddrArray[i].MaxSa[0] == 0x02) { /* Is ipv4 */ memcpy(&ret->AddrArray[curr], &ip->AddrArray[i].MaxSa[4], sizeof(uint32_t)); curr++; } } } else { talloc_free(ret); return NULL; } ret->AddrCount = curr; return ret; } struct DNS_ADDR_ARRAY *dns_addr_array_copy(TALLOC_CTX *mem_ctx, struct DNS_ADDR_ARRAY *addr) { struct DNS_ADDR_ARRAY *ret; if (!addr) { return NULL; } ret = talloc_zero(mem_ctx, struct DNS_ADDR_ARRAY); if (!ret) { return ret; } ret->MaxCount = addr->MaxCount; ret->AddrCount = addr->AddrCount; ret->Family = addr->Family; if (addr->AddrCount > 0) { ret->AddrArray = talloc_zero_array(mem_ctx, struct DNS_ADDR, addr->AddrCount); if (ret->AddrArray) { memcpy(ret->AddrArray, addr->AddrArray, sizeof(struct DNS_ADDR) * addr->AddrCount); } else { talloc_free(ret); return NULL; } } return ret; } int dns_split_name_components(TALLOC_CTX *tmp_ctx, const char *name, char ***components) { char *str = NULL, *ptr, **list; int count = 0; if (name == NULL) { return 0; } str = talloc_strdup(tmp_ctx, name); if (!str) { goto failed; } list = talloc_zero_array(tmp_ctx, char *, 0); if (!list) { goto failed; } ptr = strtok(str, "."); while (ptr != NULL) { count++; list = talloc_realloc(tmp_ctx, list, char *, count); if (!list) { goto failed; } list[count-1] = talloc_strdup(tmp_ctx, ptr); if (list[count-1] == NULL) { goto failed; } ptr = strtok(NULL, "."); } talloc_free(str); *components = list; return count; failed: if (str) { talloc_free(str); } return -1; } char *dns_split_node_name(TALLOC_CTX *tmp_ctx, const char *node_name, const char *zone_name) { char **nlist, **zlist; char *prefix; int ncount, zcount, i, match; /* * If node_name is "@", return the zone_name * If node_name is ".", return NULL * If there is no '.' in node_name, return the node_name as is. * * If node_name does not have zone_name in it, return the node_name as is. * * If node_name has additional components as compared to zone_name * return only the additional components as a prefix. * */ if (strcmp(node_name, "@") == 0) { prefix = talloc_strdup(tmp_ctx, zone_name); } else if (strcmp(node_name, ".") == 0) { prefix = NULL; } else if (strchr(node_name, '.') == NULL) { prefix = talloc_strdup(tmp_ctx, node_name); } else { zcount = dns_split_name_components(tmp_ctx, zone_name, &zlist); ncount = dns_split_name_components(tmp_ctx, node_name, &nlist); if (zcount < 0 || ncount < 0) { return NULL; } if (ncount < zcount) { prefix = talloc_strdup(tmp_ctx, node_name); } else { match = 0; for (i=1; i<=zcount; i++) { if (strcasecmp(nlist[ncount-i], zlist[zcount-i]) != 0) { break; } match++; } if (match == ncount) { prefix = talloc_strdup(tmp_ctx, zone_name); } else { prefix = talloc_strdup(tmp_ctx, nlist[0]); if (prefix != NULL) { for (i=1; iwDataLength = dnsp->wDataLength; dns->wType = dnsp->wType; dns->dwFlags = dnsp->rank; dns->dwSerial = dnsp->dwSerial; dns->dwTtlSeconds = dnsp->dwTtlSeconds; dns->dwTimeStamp = dnsp->dwTimeStamp; switch (dnsp->wType) { case DNS_TYPE_TOMBSTONE: dns->data.timestamp = dnsp->data.timestamp; break; case DNS_TYPE_A: dns->data.ipv4 = talloc_strdup(mem_ctx, dnsp->data.ipv4); break; case DNS_TYPE_NS: len = strlen(dnsp->data.ns); if (dnsp->data.ns[len-1] == '.') { dns->data.name.len = len; dns->data.name.str = talloc_strdup(mem_ctx, dnsp->data.ns); } else { dns->data.name.len = len+1; dns->data.name.str = talloc_asprintf(mem_ctx, "%s.", dnsp->data.ns); } break; case DNS_TYPE_CNAME: len = strlen(dnsp->data.cname); if (dnsp->data.cname[len-1] == '.') { dns->data.name.len = len; dns->data.name.str = talloc_strdup(mem_ctx, dnsp->data.cname); } else { dns->data.name.len = len+1; dns->data.name.str = talloc_asprintf(mem_ctx, "%s.", dnsp->data.cname); } break; case DNS_TYPE_SOA: dns->data.soa.dwSerialNo = dnsp->data.soa.serial; dns->data.soa.dwRefresh = dnsp->data.soa.refresh; dns->data.soa.dwRetry = dnsp->data.soa.retry; dns->data.soa.dwExpire = dnsp->data.soa.expire; dns->data.soa.dwMinimumTtl = dnsp->data.soa.minimum; len = strlen(dnsp->data.soa.mname); if (dnsp->data.soa.mname[len-1] == '.') { dns->data.soa.NamePrimaryServer.len = len; dns->data.soa.NamePrimaryServer.str = talloc_strdup(mem_ctx, dnsp->data.soa.mname); } else { dns->data.soa.NamePrimaryServer.len = len+1; dns->data.soa.NamePrimaryServer.str = talloc_asprintf(mem_ctx, "%s.", dnsp->data.soa.mname); } len = strlen(dnsp->data.soa.rname); if (dnsp->data.soa.rname[len-1] == '.') { dns->data.soa.ZoneAdministratorEmail.len = len; dns->data.soa.ZoneAdministratorEmail.str = talloc_strdup(mem_ctx, dnsp->data.soa.rname); } else { dns->data.soa.ZoneAdministratorEmail.len = len+1; dns->data.soa.ZoneAdministratorEmail.str = talloc_asprintf(mem_ctx, "%s.", dnsp->data.soa.rname); } break; case DNS_TYPE_PTR: dns->data.ptr.len = strlen(dnsp->data.ptr); dns->data.ptr.str = talloc_strdup(mem_ctx, dnsp->data.ptr); break; case DNS_TYPE_MX: dns->data.mx.wPreference = dnsp->data.mx.wPriority; len = strlen(dnsp->data.mx.nameTarget); if (dnsp->data.mx.nameTarget[len-1] == '.') { dns->data.mx.nameExchange.len = len; dns->data.mx.nameExchange.str = talloc_strdup(mem_ctx, dnsp->data.mx.nameTarget); } else { dns->data.mx.nameExchange.len = len+1; dns->data.mx.nameExchange.str = talloc_asprintf(mem_ctx, "%s.", dnsp->data.mx.nameTarget); } break; case DNS_TYPE_TXT: dns->data.txt.count = dnsp->data.txt.count; dns->data.txt.str = talloc_array(mem_ctx, struct DNS_RPC_NAME, dnsp->data.txt.count); for (i=0; idata.txt.count; i++) { dns->data.txt.str[i].str = talloc_strdup(mem_ctx, dnsp->data.txt.str[i]); dns->data.txt.str[i].len = strlen(dnsp->data.txt.str[i]); } break; case DNS_TYPE_AAAA: dns->data.ipv6 = talloc_strdup(mem_ctx, dnsp->data.ipv6); break; case DNS_TYPE_SRV: dns->data.srv.wPriority = dnsp->data.srv.wPriority; dns->data.srv.wWeight = dnsp->data.srv.wWeight; dns->data.srv.wPort = dnsp->data.srv.wPort; len = strlen(dnsp->data.srv.nameTarget); if (dnsp->data.srv.nameTarget[len-1] == '.') { dns->data.srv.nameTarget.len = len; dns->data.srv.nameTarget.str = talloc_strdup(mem_ctx, dnsp->data.srv.nameTarget); } else { dns->data.srv.nameTarget.len = len+1; dns->data.srv.nameTarget.str = talloc_asprintf(mem_ctx, "%s.", dnsp->data.srv.nameTarget); } break; default: memcpy(&dns->data, &dnsp->data, sizeof(union DNS_RPC_DATA)); DEBUG(0, ("dnsserver: Found Unhandled DNS record type=%d", dnsp->wType)); } } struct dnsp_DnssrvRpcRecord *dns_to_dnsp_copy(TALLOC_CTX *mem_ctx, struct DNS_RPC_RECORD *dns) { int i, len; struct dnsp_DnssrvRpcRecord *dnsp; dnsp = talloc_zero(mem_ctx, struct dnsp_DnssrvRpcRecord); if (dnsp == NULL) { return NULL; } dnsp->wDataLength = dns->wDataLength; dnsp->wType = dns->wType; dnsp->version = 5; dnsp->rank = dns->dwFlags & 0x000000FF; dnsp->dwSerial = dns->dwSerial; dnsp->dwTtlSeconds = dns->dwTtlSeconds; dnsp->dwTimeStamp = dns->dwTimeStamp; switch (dns->wType) { case DNS_TYPE_TOMBSTONE: dnsp->data.timestamp = dns->data.timestamp; break; case DNS_TYPE_A: dnsp->data.ipv4 = talloc_strdup(mem_ctx, dns->data.ipv4); break; case DNS_TYPE_NS: len = dns->data.name.len; if (dns->data.name.str[len-1] == '.') { dnsp->data.ns = talloc_strndup(mem_ctx, dns->data.name.str, len-1); } else { dnsp->data.ns = talloc_strdup(mem_ctx, dns->data.name.str); } break; case DNS_TYPE_CNAME: len = dns->data.name.len; if (dns->data.name.str[len-1] == '.') { dnsp->data.cname = talloc_strndup(mem_ctx, dns->data.name.str, len-1); } else { dnsp->data.cname = talloc_strdup(mem_ctx, dns->data.name.str); } break; case DNS_TYPE_SOA: dnsp->data.soa.serial = dns->data.soa.dwSerialNo; dnsp->data.soa.refresh = dns->data.soa.dwRefresh; dnsp->data.soa.retry = dns->data.soa.dwRetry; dnsp->data.soa.expire = dns->data.soa.dwExpire; dnsp->data.soa.minimum = dns->data.soa.dwMinimumTtl; len = dns->data.soa.NamePrimaryServer.len; if (dns->data.soa.NamePrimaryServer.str[len-1] == '.') { dnsp->data.soa.mname = talloc_strndup(mem_ctx, dns->data.soa.NamePrimaryServer.str, len-1); } else { dnsp->data.soa.mname = talloc_strdup(mem_ctx, dns->data.soa.NamePrimaryServer.str); } len = dns->data.soa.ZoneAdministratorEmail.len; if (dns->data.soa.ZoneAdministratorEmail.str[len-1] == '.') { dnsp->data.soa.rname = talloc_strndup(mem_ctx, dns->data.soa.ZoneAdministratorEmail.str, len-1); } else { dnsp->data.soa.rname = talloc_strdup(mem_ctx, dns->data.soa.ZoneAdministratorEmail.str); } break; case DNS_TYPE_PTR: dnsp->data.ptr = talloc_strdup(mem_ctx, dns->data.ptr.str); break; case DNS_TYPE_MX: dnsp->data.mx.wPriority = dns->data.mx.wPreference; len = dns->data.mx.nameExchange.len; if (dns->data.mx.nameExchange.str[len-1] == '.') { dnsp->data.mx.nameTarget = talloc_strndup(mem_ctx, dns->data.mx.nameExchange.str, len-1); } else { dnsp->data.mx.nameTarget = talloc_strdup(mem_ctx, dns->data.mx.nameExchange.str); } break; case DNS_TYPE_TXT: dnsp->data.txt.count = dns->data.txt.count; dnsp->data.txt.str = talloc_array(mem_ctx, const char *, dns->data.txt.count); for (i=0; idata.txt.count; i++) { dnsp->data.txt.str[i] = talloc_strdup(mem_ctx, dns->data.txt.str[i].str); } break; case DNS_TYPE_AAAA: dnsp->data.ipv6 = talloc_strdup(mem_ctx, dns->data.ipv6); break; case DNS_TYPE_SRV: dnsp->data.srv.wPriority = dns->data.srv.wPriority; dnsp->data.srv.wWeight = dns->data.srv.wWeight; dnsp->data.srv.wPort = dns->data.srv.wPort; len = dns->data.srv.nameTarget.len; if (dns->data.srv.nameTarget.str[len-1] == '.') { dnsp->data.srv.nameTarget = talloc_strndup(mem_ctx, dns->data.srv.nameTarget.str, len-1); } else { dnsp->data.srv.nameTarget = talloc_strdup(mem_ctx, dns->data.srv.nameTarget.str); } break; default: memcpy(&dnsp->data, &dns->data, sizeof(union dnsRecordData)); DEBUG(0, ("dnsserver: Found Unhandled DNS record type=%d", dns->wType)); } return dnsp; } /* Intialize tree with given name as the root */ static struct dns_tree *dns_tree_init(TALLOC_CTX *mem_ctx, const char *name, void *data) { struct dns_tree *tree; tree = talloc_zero(mem_ctx, struct dns_tree); if (tree == NULL) { return NULL; } tree->name = talloc_strdup(tree, name); if (tree->name == NULL) { talloc_free(tree); return NULL; } tree->data = data; return tree; } /* Add a child one level below */ static struct dns_tree *dns_tree_add(struct dns_tree *tree, const char *name, void *data) { struct dns_tree *node; node = talloc_zero(tree, struct dns_tree); if (node == NULL) { return NULL; } node->name = talloc_strdup(tree, name); if (node->name == NULL) { talloc_free(node); return NULL; } node->level = tree->level + 1; node->num_children = 0; node->children = NULL; node->data = data; if (tree->num_children == 0) { tree->children = talloc_zero(tree, struct dns_tree *); } else { tree->children = talloc_realloc(tree, tree->children, struct dns_tree *, tree->num_children+1); } if (tree->children == NULL) { talloc_free(node); return NULL; } tree->children[tree->num_children] = node; tree->num_children++; return node; } /* Find a node that matches the name components */ static struct dns_tree *dns_tree_find(struct dns_tree *tree, int ncount, char **nlist, int *match_count) { struct dns_tree *node, *next; int i, j, start; *match_count = -1; if (strcmp(tree->name, "@") == 0) { start = 0; } else { if (strcasecmp(tree->name, nlist[ncount-1]) != 0) { return NULL; } start = 1; *match_count = 0; } node = tree; for (i=start; inum_children == 0) { break; } next = NULL; for (j=0; jnum_children; j++) { if (strcasecmp(nlist[(ncount-1)-i], node->children[j]->name) == 0) { next = node->children[j]; *match_count = i; break; } } if (next == NULL) { break; } else { node = next; } } return node; } /* Build a 2-level tree for resulting dns names */ struct dns_tree *dns_build_tree(TALLOC_CTX *mem_ctx, const char *name, struct ldb_result *res) { struct dns_tree *root, *base, *tree, *node; const char *ptr; int rootcount, ncount; char **nlist; int i, level, match_count; rootcount = dns_split_name_components(mem_ctx, name, &nlist); if (rootcount <= 0) { return NULL; } root = dns_tree_init(mem_ctx, nlist[rootcount-1], NULL); if (root == NULL) { return NULL; } tree = root; for (i=rootcount-2; i>=0; i--) { tree = dns_tree_add(tree, nlist[i], NULL); if (tree == NULL) { goto failed; } } base = tree; /* Add all names in the result in a tree */ for (i=0; icount; i++) { ptr = ldb_msg_find_attr_as_string(res->msgs[i], "name", NULL); if (strcmp(ptr, "@") == 0) { base->data = res->msgs[i]; continue; } else if (strcasecmp(ptr, name) == 0) { base->data = res->msgs[i]; continue; } ncount = dns_split_name_components(root, ptr, &nlist); if (ncount < 0) { goto failed; } /* Find matching node */ tree = dns_tree_find(root, ncount, nlist, &match_count); if (tree == NULL) { goto failed; } /* If the node is on leaf, then add record data */ if (match_count+1 == ncount) { tree->data = res->msgs[i]; } /* Add missing name components */ for (level=match_count+1; levellevel == rootcount+1) { break; } if (level == ncount-1) { node = dns_tree_add(tree, nlist[(ncount-1)-level], res->msgs[i]); } else { node = dns_tree_add(tree, nlist[(ncount-1)-level], NULL); } if (node == NULL) { goto failed; } tree = node; } talloc_free(nlist); } /* Mark the base record, so it can be found easily */ base->level = -1; return root; failed: talloc_free(root); return NULL; } static void _dns_add_name(TALLOC_CTX *mem_ctx, const char *name, char ***add_names, int *add_count) { int i; char **ptr = *add_names; int count = *add_count; for (i=0; iwType) { case DNS_TYPE_NS: _dns_add_name(mem_ctx, rec->data.ns, add_names, add_count); break; case DNS_TYPE_CNAME: _dns_add_name(mem_ctx, rec->data.cname, add_names, add_count); break; case DNS_TYPE_SOA: _dns_add_name(mem_ctx, rec->data.soa.mname, add_names, add_count); break; case DNS_TYPE_MX: _dns_add_name(mem_ctx, rec->data.mx.nameTarget, add_names, add_count); break; case DNS_TYPE_SRV: _dns_add_name(mem_ctx, rec->data.srv.nameTarget, add_names, add_count); break; default: break; } } WERROR dns_fill_records_array(TALLOC_CTX *mem_ctx, struct dnsserver_zone *z, enum dns_record_type record_type, unsigned int select_flag, const char *branch_name, struct ldb_message *msg, int num_children, struct DNS_RPC_RECORDS_ARRAY *recs, char ***add_names, int *add_count) { struct ldb_message_element *el; const char *ptr; int i, j; bool found; if (recs->count == 0) { recs->rec = talloc_zero(recs, struct DNS_RPC_RECORDS); } else { recs->rec = talloc_realloc(recs, recs->rec, struct DNS_RPC_RECORDS, recs->count+1); } if (recs->rec == NULL) { return WERR_NOMEM; } i = recs->count; recs->rec[i].wLength = 0; recs->rec[i].wRecordCount = 0; recs->rec[i].dwChildCount = num_children; recs->rec[i].dwFlags = 0; /* The base records returned with empty name */ /* Children records returned with names */ if (branch_name == NULL) { recs->rec[i].dnsNodeName.str = talloc_strdup(recs, ""); recs->rec[i].dnsNodeName.len = 0; } else { recs->rec[i].dnsNodeName.str = talloc_strdup(recs, branch_name); recs->rec[i].dnsNodeName.len = strlen(branch_name); } recs->rec[i].records = talloc_zero_array(recs, struct DNS_RPC_RECORD, 0); recs->count++; /* Allow empty records */ if (msg == NULL) { return WERR_OK; } /* Do not return RR records, if the node has children */ if (branch_name != NULL && num_children > 0) { return WERR_OK; } ptr = ldb_msg_find_attr_as_string(msg, "name", NULL); el = ldb_msg_find_element(msg, "dnsRecord"); if (el == NULL || el->values == 0) { return WERR_OK; } /* Add RR records */ for (j=0; jnum_values; j++) { struct dnsp_DnssrvRpcRecord dnsp_rec; struct DNS_RPC_RECORD *dns_rec; enum ndr_err_code ndr_err; ndr_err = ndr_pull_struct_blob(&el->values[j], mem_ctx, &dnsp_rec, (ndr_pull_flags_fn_t)ndr_pull_dnsp_DnssrvRpcRecord); if (!NDR_ERR_CODE_IS_SUCCESS(ndr_err)) { DEBUG(0, ("dnsserver: Unable to parse dns record (%s)", ldb_dn_get_linearized(msg->dn))); return WERR_INTERNAL_DB_ERROR; } /* Match the records based on search criteria */ if (record_type == DNS_TYPE_ALL || dnsp_rec.wType == record_type) { found = false; if (select_flag & DNS_RPC_VIEW_AUTHORITY_DATA) { if (dnsp_rec.rank == DNS_RANK_ZONE) { found = true; } else if (dnsp_rec.rank == DNS_RANK_NS_GLUE) { /* * If branch_name is NULL, we're * explicitly asked to also return * DNS_RANK_NS_GLUE records */ if (branch_name == NULL) { found = true; } } } if (select_flag & DNS_RPC_VIEW_CACHE_DATA) { if (dnsp_rec.rank == DNS_RANK_ZONE) { found = true; } } if (select_flag & DNS_RPC_VIEW_GLUE_DATA) { if (dnsp_rec.rank == DNS_RANK_GLUE) { found = true; } } if (select_flag & DNS_RPC_VIEW_ROOT_HINT_DATA) { if (dnsp_rec.rank == DNS_RANK_ROOT_HINT) { found = true; } } if (found) { recs->rec[i].records = talloc_realloc(recs, recs->rec[i].records, struct DNS_RPC_RECORD, recs->rec[i].wRecordCount+1); if (recs->rec[i].records == NULL) { return WERR_NOMEM; } dns_rec = &recs->rec[i].records[recs->rec[i].wRecordCount]; dnsp_to_dns_copy(recs, &dnsp_rec, dns_rec); /* Fix record flags */ if (strcmp(ptr, "@") == 0) { dns_rec->dwFlags |= DNS_RPC_FLAG_ZONE_ROOT; if (dnsp_rec.rank == DNS_RANK_ZONE) { dns_rec->dwFlags |= DNS_RPC_FLAG_AUTH_ZONE_ROOT; } } if (dns_rec->dwFlags == DNS_RANK_NS_GLUE) { dns_rec->dwFlags |= DNS_RPC_FLAG_ZONE_ROOT; } recs->rec[i].wRecordCount++; dns_find_additional_names(mem_ctx, &dnsp_rec, add_names, add_count); } } } return WERR_OK; } int dns_name_compare(const struct ldb_message **m1, const struct ldb_message **m2, char *search_name) { const char *name1, *name2; const char *ptr1, *ptr2; name1 = ldb_msg_find_attr_as_string(*m1, "name", NULL); name2 = ldb_msg_find_attr_as_string(*m2, "name", NULL); if (name1 == NULL || name2 == NULL) { return 0; } /* '@' record and the search_name record gets preference */ if (name1[0] == '@') { return -1; } if (search_name && strcasecmp(name1, search_name) == 0) { return -1; } if (name2[0] == '@') { return 1; } if (search_name && strcasecmp(name2, search_name) == 0) { return 1; } /* Compare the last components of names. * If search_name is not NULL, compare the second last components of names */ ptr1 = strrchr(name1, '.'); if (ptr1 == NULL) { ptr1 = name1; } else { if (search_name && strcasecmp(ptr1+1, search_name) == 0) { ptr1--; while (ptr1 != name1) { ptr1--; if (*ptr1 == '.') { break; } } } if (*ptr1 == '.') { ptr1 = &ptr1[1]; } } ptr2 = strrchr(name2, '.'); if (ptr2 == NULL) { ptr2 = name2; } else { if (search_name && strcasecmp(ptr2+1, search_name) == 0) { ptr2--; while (ptr2 != name2) { ptr2--; if (*ptr2 == '.') { break; } } } if (*ptr2 == '.') { ptr2 = &ptr2[1]; } } return strcasecmp(ptr1, ptr2); } bool dns_name_equal(const char *name1, const char *name2) { size_t len1 = strlen(name1); size_t len2 = strlen(name2); if (name1[len1-1] == '.') len1--; if (name2[len2-1] == '.') len2--; if (len1 != len2) { return false; } return strncasecmp(name1, name2, len1) == 0; } bool dns_record_match(struct dnsp_DnssrvRpcRecord *rec1, struct dnsp_DnssrvRpcRecord *rec2) { bool status; int i; if (rec1->wType != rec2->wType) { return false; } switch(rec1->wType) { case DNS_TYPE_TOMBSTONE: return true; case DNS_TYPE_A: return strcmp(rec1->data.ipv4, rec2->data.ipv4) == 0; case DNS_TYPE_NS: return dns_name_equal(rec1->data.ns, rec2->data.ns); case DNS_TYPE_CNAME: return dns_name_equal(rec1->data.cname, rec2->data.cname); case DNS_TYPE_SOA: return dns_name_equal(rec1->data.soa.mname, rec2->data.soa.mname) && dns_name_equal(rec1->data.soa.rname, rec2->data.soa.rname) && rec1->data.soa.serial == rec2->data.soa.serial && rec1->data.soa.refresh == rec2->data.soa.refresh && rec1->data.soa.retry == rec2->data.soa.retry && rec1->data.soa.expire == rec2->data.soa.expire && rec1->data.soa.minimum == rec2->data.soa.minimum; case DNS_TYPE_PTR: return dns_name_equal(rec1->data.ptr, rec2->data.ptr); case DNS_TYPE_MX: return rec1->data.mx.wPriority == rec2->data.mx.wPriority && dns_name_equal(rec1->data.mx.nameTarget, rec2->data.mx.nameTarget); case DNS_TYPE_TXT: if (rec1->data.txt.count != rec2->data.txt.count) { return false; } status = true; for (i=0; idata.txt.count; i++) { status = status && (strcmp(rec1->data.txt.str[i], rec2->data.txt.str[i]) == 0); } return status; case DNS_TYPE_AAAA: return strcmp(rec1->data.ipv6, rec2->data.ipv6) == 0; case DNS_TYPE_SRV: return rec1->data.srv.wPriority == rec2->data.srv.wPriority && rec1->data.srv.wWeight == rec2->data.srv.wWeight && rec1->data.srv.wPort == rec2->data.srv.wPort && dns_name_equal(rec1->data.srv.nameTarget, rec2->data.srv.nameTarget); default: DEBUG(0, ("dnsserver: unhandled record type %u", rec1->wType)); break; } return false; }