/* * respip/respip.c - filtering response IP module */ /** * \file * * This file contains a module that inspects a result of recursive resolution * to see if any IP address record should trigger a special action. * If applicable these actions can modify the original response. */ #include "config.h" #include "services/localzone.h" #include "services/authzone.h" #include "services/cache/dns.h" #include "sldns/str2wire.h" #include "util/config_file.h" #include "util/fptr_wlist.h" #include "util/module.h" #include "util/net_help.h" #include "util/regional.h" #include "util/data/msgreply.h" #include "util/storage/dnstree.h" #include "respip/respip.h" #include "services/view.h" #include "sldns/rrdef.h" /** Subset of resp_addr.node, used for inform-variant logging */ struct respip_addr_info { struct sockaddr_storage addr; socklen_t addrlen; int net; }; /** Query state regarding the response-ip module. */ enum respip_state { /** * The general state. Unless CNAME chasing takes place, all processing * is completed in this state without any other asynchronous event. */ RESPIP_INIT = 0, /** * A subquery for CNAME chasing is completed. */ RESPIP_SUBQUERY_FINISHED }; /** Per query state for the response-ip module. */ struct respip_qstate { enum respip_state state; }; struct respip_set* respip_set_create(void) { struct respip_set* set = calloc(1, sizeof(*set)); if(!set) return NULL; set->region = regional_create(); if(!set->region) { free(set); return NULL; } addr_tree_init(&set->ip_tree); lock_rw_init(&set->lock); return set; } /** helper traverse to delete resp_addr nodes */ static void resp_addr_del(rbnode_type* n, void* ATTR_UNUSED(arg)) { struct resp_addr* r = (struct resp_addr*)n->key; lock_rw_destroy(&r->lock); #ifdef THREADS_DISABLED (void)r; #endif } void respip_set_delete(struct respip_set* set) { if(!set) return; lock_rw_destroy(&set->lock); traverse_postorder(&set->ip_tree, resp_addr_del, NULL); regional_destroy(set->region); free(set); } struct rbtree_type* respip_set_get_tree(struct respip_set* set) { if(!set) return NULL; return &set->ip_tree; } struct resp_addr* respip_sockaddr_find_or_create(struct respip_set* set, struct sockaddr_storage* addr, socklen_t addrlen, int net, int create, const char* ipstr) { struct resp_addr* node; node = (struct resp_addr*)addr_tree_find(&set->ip_tree, addr, addrlen, net); if(!node && create) { node = regional_alloc_zero(set->region, sizeof(*node)); if(!node) { log_err("out of memory"); return NULL; } lock_rw_init(&node->lock); node->action = respip_none; if(!addr_tree_insert(&set->ip_tree, &node->node, addr, addrlen, net)) { /* We know we didn't find it, so this should be * impossible. */ log_warn("unexpected: duplicate address: %s", ipstr); } } return node; } void respip_sockaddr_delete(struct respip_set* set, struct resp_addr* node) { struct resp_addr* prev; prev = (struct resp_addr*)rbtree_previous((struct rbnode_type*)node); lock_rw_destroy(&node->lock); rbtree_delete(&set->ip_tree, node); /* no free'ing, all allocated in region */ if(!prev) addr_tree_init_parents((rbtree_type*)set); else addr_tree_init_parents_node(&prev->node); } /** returns the node in the address tree for the specified netblock string; * non-existent node will be created if 'create' is true */ static struct resp_addr* respip_find_or_create(struct respip_set* set, const char* ipstr, int create) { struct sockaddr_storage addr; int net; socklen_t addrlen; if(!netblockstrtoaddr(ipstr, 0, &addr, &addrlen, &net)) { log_err("cannot parse netblock: '%s'", ipstr); return NULL; } return respip_sockaddr_find_or_create(set, &addr, addrlen, net, create, ipstr); } static int respip_tag_cfg(struct respip_set* set, const char* ipstr, const uint8_t* taglist, size_t taglen) { struct resp_addr* node; if(!(node=respip_find_or_create(set, ipstr, 1))) return 0; if(node->taglist) { log_warn("duplicate response-address-tag for '%s', overridden.", ipstr); } node->taglist = regional_alloc_init(set->region, taglist, taglen); if(!node->taglist) { log_err("out of memory"); return 0; } node->taglen = taglen; return 1; } /** set action for the node specified by the netblock string */ static int respip_action_cfg(struct respip_set* set, const char* ipstr, const char* actnstr) { struct resp_addr* node; enum respip_action action; if(!(node=respip_find_or_create(set, ipstr, 1))) return 0; if(node->action != respip_none) { verbose(VERB_QUERY, "duplicate response-ip action for '%s', overridden.", ipstr); } if(strcmp(actnstr, "deny") == 0) action = respip_deny; else if(strcmp(actnstr, "redirect") == 0) action = respip_redirect; else if(strcmp(actnstr, "inform") == 0) action = respip_inform; else if(strcmp(actnstr, "inform_deny") == 0) action = respip_inform_deny; else if(strcmp(actnstr, "inform_redirect") == 0) action = respip_inform_redirect; else if(strcmp(actnstr, "always_transparent") == 0) action = respip_always_transparent; else if(strcmp(actnstr, "always_refuse") == 0) action = respip_always_refuse; else if(strcmp(actnstr, "always_nxdomain") == 0) action = respip_always_nxdomain; else if(strcmp(actnstr, "always_nodata") == 0) action = respip_always_nodata; else if(strcmp(actnstr, "always_deny") == 0) action = respip_always_deny; else { log_err("unknown response-ip action %s", actnstr); return 0; } node->action = action; return 1; } /** allocate and initialize an rrset structure; this function is based * on new_local_rrset() from the localzone.c module */ static struct ub_packed_rrset_key* new_rrset(struct regional* region, uint16_t rrtype, uint16_t rrclass) { struct packed_rrset_data* pd; struct ub_packed_rrset_key* rrset = regional_alloc_zero( region, sizeof(*rrset)); if(!rrset) { log_err("out of memory"); return NULL; } rrset->entry.key = rrset; pd = regional_alloc_zero(region, sizeof(*pd)); if(!pd) { log_err("out of memory"); return NULL; } pd->trust = rrset_trust_prim_noglue; pd->security = sec_status_insecure; rrset->entry.data = pd; rrset->rk.dname = regional_alloc_zero(region, 1); if(!rrset->rk.dname) { log_err("out of memory"); return NULL; } rrset->rk.dname_len = 1; rrset->rk.type = htons(rrtype); rrset->rk.rrset_class = htons(rrclass); return rrset; } /** enter local data as resource records into a response-ip node */ int respip_enter_rr(struct regional* region, struct resp_addr* raddr, uint16_t rrtype, uint16_t rrclass, time_t ttl, uint8_t* rdata, size_t rdata_len, const char* rrstr, const char* netblockstr) { struct packed_rrset_data* pd; struct sockaddr* sa; sa = (struct sockaddr*)&raddr->node.addr; if (rrtype == LDNS_RR_TYPE_CNAME && raddr->data) { log_err("CNAME response-ip data (%s) can not co-exist with other " "response-ip data for netblock %s", rrstr, netblockstr); return 0; } else if (raddr->data && raddr->data->rk.type == htons(LDNS_RR_TYPE_CNAME)) { log_err("response-ip data (%s) can not be added; CNAME response-ip " "data already in place for netblock %s", rrstr, netblockstr); return 0; } else if((rrtype != LDNS_RR_TYPE_CNAME) && ((sa->sa_family == AF_INET && rrtype != LDNS_RR_TYPE_A) || (sa->sa_family == AF_INET6 && rrtype != LDNS_RR_TYPE_AAAA))) { log_err("response-ip data %s record type does not correspond " "to netblock %s address family", rrstr, netblockstr); return 0; } if(!raddr->data) { raddr->data = new_rrset(region, rrtype, rrclass); if(!raddr->data) return 0; } pd = raddr->data->entry.data; return rrset_insert_rr(region, pd, rdata, rdata_len, ttl, rrstr); } static int respip_enter_rrstr(struct regional* region, struct resp_addr* raddr, const char* rrstr, const char* netblock) { uint8_t* nm; uint16_t rrtype = 0, rrclass = 0; time_t ttl = 0; uint8_t rr[LDNS_RR_BUF_SIZE]; uint8_t* rdata = NULL; size_t rdata_len = 0; char buf[65536]; char bufshort[64]; int ret; if(raddr->action != respip_redirect && raddr->action != respip_inform_redirect) { log_err("cannot parse response-ip-data %s: response-ip " "action for %s is not redirect", rrstr, netblock); return 0; } ret = snprintf(buf, sizeof(buf), ". %s", rrstr); if(ret < 0 || ret >= (int)sizeof(buf)) { strlcpy(bufshort, rrstr, sizeof(bufshort)); log_err("bad response-ip-data: %s...", bufshort); return 0; } if(!rrstr_get_rr_content(buf, &nm, &rrtype, &rrclass, &ttl, rr, sizeof(rr), &rdata, &rdata_len)) { log_err("bad response-ip-data: %s", rrstr); return 0; } free(nm); return respip_enter_rr(region, raddr, rrtype, rrclass, ttl, rdata, rdata_len, rrstr, netblock); } static int respip_data_cfg(struct respip_set* set, const char* ipstr, const char* rrstr) { struct resp_addr* node; node=respip_find_or_create(set, ipstr, 0); if(!node || node->action == respip_none) { log_err("cannot parse response-ip-data %s: " "response-ip node for %s not found", rrstr, ipstr); return 0; } return respip_enter_rrstr(set->region, node, rrstr, ipstr); } static int respip_set_apply_cfg(struct respip_set* set, char* const* tagname, int num_tags, struct config_strbytelist* respip_tags, struct config_str2list* respip_actions, struct config_str2list* respip_data) { struct config_strbytelist* p; struct config_str2list* pa; struct config_str2list* pd; set->tagname = tagname; set->num_tags = num_tags; p = respip_tags; while(p) { struct config_strbytelist* np = p->next; log_assert(p->str && p->str2); if(!respip_tag_cfg(set, p->str, p->str2, p->str2len)) { config_del_strbytelist(p); return 0; } free(p->str); free(p->str2); free(p); p = np; } pa = respip_actions; while(pa) { struct config_str2list* np = pa->next; log_assert(pa->str && pa->str2); if(!respip_action_cfg(set, pa->str, pa->str2)) { config_deldblstrlist(pa); return 0; } free(pa->str); free(pa->str2); free(pa); pa = np; } pd = respip_data; while(pd) { struct config_str2list* np = pd->next; log_assert(pd->str && pd->str2); if(!respip_data_cfg(set, pd->str, pd->str2)) { config_deldblstrlist(pd); return 0; } free(pd->str); free(pd->str2); free(pd); pd = np; } addr_tree_init_parents(&set->ip_tree); return 1; } int respip_global_apply_cfg(struct respip_set* set, struct config_file* cfg) { int ret = respip_set_apply_cfg(set, cfg->tagname, cfg->num_tags, cfg->respip_tags, cfg->respip_actions, cfg->respip_data); cfg->respip_data = NULL; cfg->respip_actions = NULL; cfg->respip_tags = NULL; return ret; } /** Iterate through raw view data and apply the view-specific respip * configuration; at this point we should have already seen all the views, * so if any of the views that respip data refer to does not exist, that's * an error. This additional iteration through view configuration data * is expected to not have significant performance impact (or rather, its * performance impact is not expected to be prohibitive in the configuration * processing phase). */ int respip_views_apply_cfg(struct views* vs, struct config_file* cfg, int* have_view_respip_cfg) { struct config_view* cv; struct view* v; int ret; for(cv = cfg->views; cv; cv = cv->next) { /** if no respip config for this view then there's * nothing to do; note that even though respip data must go * with respip action, we're checking for both here because * we want to catch the case where the respip action is missing * while the data is present */ if(!cv->respip_actions && !cv->respip_data) continue; if(!(v = views_find_view(vs, cv->name, 1))) { log_err("view '%s' unexpectedly missing", cv->name); return 0; } if(!v->respip_set) { v->respip_set = respip_set_create(); if(!v->respip_set) { log_err("out of memory"); lock_rw_unlock(&v->lock); return 0; } } ret = respip_set_apply_cfg(v->respip_set, NULL, 0, NULL, cv->respip_actions, cv->respip_data); lock_rw_unlock(&v->lock); if(!ret) { log_err("Error while applying respip configuration " "for view '%s'", cv->name); return 0; } *have_view_respip_cfg = (*have_view_respip_cfg || v->respip_set->ip_tree.count); cv->respip_actions = NULL; cv->respip_data = NULL; } return 1; } /** * make a deep copy of 'key' in 'region'. * This is largely derived from packed_rrset_copy_region() and * packed_rrset_ptr_fixup(), but differs in the following points: * * - It doesn't assume all data in 'key' are in a contiguous memory region. * Although that would be the case in most cases, 'key' can be passed from * a lower-level module and it might not build the rrset to meet the * assumption. In fact, an rrset specified as response-ip-data or generated * in local_data_find_tag_datas() breaks the assumption. So it would be * safer not to naively rely on the assumption. On the other hand, this * function ensures the copied rrset data are in a contiguous region so * that it won't cause a disruption even if an upper layer module naively * assumes the memory layout. * - It doesn't copy RRSIGs (if any) in 'key'. The rrset will be used in * a reply that was already faked, so it doesn't make much sense to provide * partial sigs even if they are valid themselves. * - It doesn't adjust TTLs as it basically has to be a verbatim copy of 'key' * just allocated in 'region' (the assumption is necessary TTL adjustment * has been already done in 'key'). * * This function returns the copied rrset key on success, and NULL on memory * allocation failure. */ static struct ub_packed_rrset_key* copy_rrset(const struct ub_packed_rrset_key* key, struct regional* region) { struct ub_packed_rrset_key* ck = regional_alloc(region, sizeof(struct ub_packed_rrset_key)); struct packed_rrset_data* d; struct packed_rrset_data* data = key->entry.data; size_t dsize, i; uint8_t* nextrdata; /* derived from packed_rrset_copy_region(), but don't use * packed_rrset_sizeof() and do exclude RRSIGs */ if(!ck) return NULL; ck->id = key->id; memset(&ck->entry, 0, sizeof(ck->entry)); ck->entry.hash = key->entry.hash; ck->entry.key = ck; ck->rk = key->rk; if(key->rk.dname) { ck->rk.dname = regional_alloc_init(region, key->rk.dname, key->rk.dname_len); if(!ck->rk.dname) return NULL; ck->rk.dname_len = key->rk.dname_len; } else { ck->rk.dname = NULL; ck->rk.dname_len = 0; } if((unsigned)data->count >= 0xffff00U) return NULL; /* guard against integer overflow in dsize */ dsize = sizeof(struct packed_rrset_data) + data->count * (sizeof(size_t)+sizeof(uint8_t*)+sizeof(time_t)); for(i=0; icount; i++) { if((unsigned)dsize >= 0x0fffffffU || (unsigned)data->rr_len[i] >= 0x0fffffffU) return NULL; /* guard against integer overflow */ dsize += data->rr_len[i]; } d = regional_alloc(region, dsize); if(!d) return NULL; *d = *data; d->rrsig_count = 0; ck->entry.data = d; /* derived from packed_rrset_ptr_fixup() with copying the data */ d->rr_len = (size_t*)((uint8_t*)d + sizeof(struct packed_rrset_data)); d->rr_data = (uint8_t**)&(d->rr_len[d->count]); d->rr_ttl = (time_t*)&(d->rr_data[d->count]); nextrdata = (uint8_t*)&(d->rr_ttl[d->count]); for(i=0; icount; i++) { d->rr_len[i] = data->rr_len[i]; d->rr_ttl[i] = data->rr_ttl[i]; d->rr_data[i] = nextrdata; memcpy(d->rr_data[i], data->rr_data[i], data->rr_len[i]); nextrdata += d->rr_len[i]; } return ck; } int respip_init(struct module_env* env, int id) { (void)env; (void)id; return 1; } void respip_deinit(struct module_env* env, int id) { (void)env; (void)id; } /** Convert a packed AAAA or A RRset to sockaddr. */ static int rdata2sockaddr(const struct packed_rrset_data* rd, uint16_t rtype, size_t i, struct sockaddr_storage* ss, socklen_t* addrlenp) { /* unbound can accept and cache odd-length AAAA/A records, so we have * to validate the length. */ if(rtype == LDNS_RR_TYPE_A && rd->rr_len[i] == 6) { struct sockaddr_in* sa4 = (struct sockaddr_in*)ss; memset(sa4, 0, sizeof(*sa4)); sa4->sin_family = AF_INET; memcpy(&sa4->sin_addr, rd->rr_data[i] + 2, sizeof(sa4->sin_addr)); *addrlenp = sizeof(*sa4); return 1; } else if(rtype == LDNS_RR_TYPE_AAAA && rd->rr_len[i] == 18) { struct sockaddr_in6* sa6 = (struct sockaddr_in6*)ss; memset(sa6, 0, sizeof(*sa6)); sa6->sin6_family = AF_INET6; memcpy(&sa6->sin6_addr, rd->rr_data[i] + 2, sizeof(sa6->sin6_addr)); *addrlenp = sizeof(*sa6); return 1; } return 0; } /** * Search the given 'iptree' for response address information that matches * any of the IP addresses in an AAAA or A in the answer section of the * response (stored in 'rep'). If found, a pointer to the matched resp_addr * structure will be returned, and '*rrset_id' is set to the index in * rep->rrsets for the RRset that contains the matching IP address record * (the index is normally 0, but can be larger than that if this is a CNAME * chain or type-ANY response). * Returns resp_addr holding read lock. */ static struct resp_addr* respip_addr_lookup(const struct reply_info *rep, struct respip_set* rs, size_t* rrset_id) { size_t i; struct resp_addr* ra; struct sockaddr_storage ss; socklen_t addrlen; lock_rw_rdlock(&rs->lock); for(i=0; ian_numrrsets; i++) { size_t j; const struct packed_rrset_data* rd; uint16_t rtype = ntohs(rep->rrsets[i]->rk.type); if(rtype != LDNS_RR_TYPE_A && rtype != LDNS_RR_TYPE_AAAA) continue; rd = rep->rrsets[i]->entry.data; for(j = 0; j < rd->count; j++) { if(!rdata2sockaddr(rd, rtype, j, &ss, &addrlen)) continue; ra = (struct resp_addr*)addr_tree_lookup(&rs->ip_tree, &ss, addrlen); if(ra) { *rrset_id = i; lock_rw_rdlock(&ra->lock); lock_rw_unlock(&rs->lock); return ra; } } } lock_rw_unlock(&rs->lock); return NULL; } /* * Create a new reply_info based on 'rep'. The new info is based on * the passed 'rep', but ignores any rrsets except for the first 'an_numrrsets' * RRsets in the answer section. These answer rrsets are copied to the * new info, up to 'copy_rrsets' rrsets (which must not be larger than * 'an_numrrsets'). If an_numrrsets > copy_rrsets, the remaining rrsets array * entries will be kept empty so the caller can fill them later. When rrsets * are copied, they are shallow copied. The caller must ensure that the * copied rrsets are valid throughout its lifetime and must provide appropriate * mutex if it can be shared by multiple threads. */ static struct reply_info * make_new_reply_info(const struct reply_info* rep, struct regional* region, size_t an_numrrsets, size_t copy_rrsets) { struct reply_info* new_rep; size_t i; /* create a base struct. we specify 'insecure' security status as * the modified response won't be DNSSEC-valid. In our faked response * the authority and additional sections will be empty (except possible * EDNS0 OPT RR in the additional section appended on sending it out), * so the total number of RRsets is an_numrrsets. */ new_rep = construct_reply_info_base(region, rep->flags, rep->qdcount, rep->ttl, rep->prefetch_ttl, rep->serve_expired_ttl, an_numrrsets, 0, 0, an_numrrsets, sec_status_insecure); if(!new_rep) return NULL; if(!reply_info_alloc_rrset_keys(new_rep, NULL, region)) return NULL; for(i=0; irrsets[i] = rep->rrsets[i]; return new_rep; } /** * See if response-ip or tag data should override the original answer rrset * (which is rep->rrsets[rrset_id]) and if so override it. * This is (mostly) equivalent to localzone.c:local_data_answer() but for * response-ip actions. * Note that this function distinguishes error conditions from "success but * not overridden". This is because we want to avoid accidentally applying * the "no data" action in case of error. * @param action: action to apply * @param data: RRset to use for override * @param qtype: original query type * @param rep: original reply message * @param rrset_id: the rrset ID in 'rep' to which the action should apply * @param new_repp: see respip_rewrite_reply * @param tag: if >= 0 the tag ID used to determine the action and data * @param tag_datas: data corresponding to 'tag'. * @param tag_datas_size: size of 'tag_datas' * @param tagname: array of tag names, used for logging * @param num_tags: size of 'tagname', used for logging * @param redirect_rrsetp: ptr to redirect record * @param region: region for building new reply * @return 1 if overridden, 0 if not overridden, -1 on error. */ static int respip_data_answer(enum respip_action action, struct ub_packed_rrset_key* data, uint16_t qtype, const struct reply_info* rep, size_t rrset_id, struct reply_info** new_repp, int tag, struct config_strlist** tag_datas, size_t tag_datas_size, char* const* tagname, int num_tags, struct ub_packed_rrset_key** redirect_rrsetp, struct regional* region) { struct ub_packed_rrset_key* rp = data; struct reply_info* new_rep; *redirect_rrsetp = NULL; if(action == respip_redirect && tag != -1 && (size_t)tagrrsets[rrset_id]->rk.dname; dataqinfo.qname_len = rep->rrsets[rrset_id]->rk.dname_len; dataqinfo.qtype = ntohs(rep->rrsets[rrset_id]->rk.type); dataqinfo.qclass = ntohs(rep->rrsets[rrset_id]->rk.rrset_class); memset(&r, 0, sizeof(r)); if(local_data_find_tag_datas(&dataqinfo, tag_datas[tag], &r, region)) { verbose(VERB_ALGO, "response-ip redirect with tag data [%d] %s", tag, (tagrk.dname = rep->rrsets[rrset_id]->rk.dname; rp->rk.dname_len = rep->rrsets[rrset_id]->rk.dname_len; } /* Build a new reply with redirect rrset. We keep any preceding CNAMEs * and replace the address rrset that triggers the action. If it's * type ANY query, however, no other answer records should be kept * (note that it can't be a CNAME chain in this case due to * sanitizing). */ if(qtype == LDNS_RR_TYPE_ANY) rrset_id = 0; new_rep = make_new_reply_info(rep, region, rrset_id + 1, rrset_id); if(!new_rep) return -1; rp->rk.flags |= PACKED_RRSET_FIXEDTTL; /* avoid adjusting TTL */ new_rep->rrsets[rrset_id] = rp; *redirect_rrsetp = rp; *new_repp = new_rep; return 1; } /** * apply response ip action in case where no action data is provided. * this is similar to localzone.c:lz_zone_answer() but simplified due to * the characteristics of response ip: * - 'deny' variants will be handled at the caller side * - no specific processing for 'transparent' variants: unlike local zones, * there is no such a case of 'no data but name existing'. so all variants * just mean 'transparent if no data'. * @param qtype: query type * @param action: found action * @param rep: * @param new_repp * @param rrset_id * @param region: region for building new reply * @return 1 on success, 0 on error. */ static int respip_nodata_answer(uint16_t qtype, enum respip_action action, const struct reply_info *rep, size_t rrset_id, struct reply_info** new_repp, struct regional* region) { struct reply_info* new_rep; if(action == respip_refuse || action == respip_always_refuse) { new_rep = make_new_reply_info(rep, region, 0, 0); if(!new_rep) return 0; FLAGS_SET_RCODE(new_rep->flags, LDNS_RCODE_REFUSED); *new_repp = new_rep; return 1; } else if(action == respip_static || action == respip_redirect || action == respip_always_nxdomain || action == respip_always_nodata || action == respip_inform_redirect) { /* Since we don't know about other types of the owner name, * we generally return NOERROR/NODATA unless an NXDOMAIN action * is explicitly specified. */ int rcode = (action == respip_always_nxdomain)? LDNS_RCODE_NXDOMAIN:LDNS_RCODE_NOERROR; /* We should empty the answer section except for any preceding * CNAMEs (in that case rrset_id > 0). Type-ANY case is * special as noted in respip_data_answer(). */ if(qtype == LDNS_RR_TYPE_ANY) rrset_id = 0; new_rep = make_new_reply_info(rep, region, rrset_id, rrset_id); if(!new_rep) return 0; FLAGS_SET_RCODE(new_rep->flags, rcode); *new_repp = new_rep; return 1; } return 1; } /** Populate action info structure with the results of response-ip action * processing, iff as the result of response-ip processing we are actually * taking some action. Only action is set if action_only is true. * Returns true on success, false on failure. */ static int populate_action_info(struct respip_action_info* actinfo, enum respip_action action, const struct resp_addr* raddr, const struct ub_packed_rrset_key* ATTR_UNUSED(rrset), int ATTR_UNUSED(tag), const struct respip_set* ATTR_UNUSED(ipset), int ATTR_UNUSED(action_only), struct regional* region, int rpz_used, int rpz_log, char* log_name, int rpz_cname_override) { if(action == respip_none || !raddr) return 1; actinfo->action = action; actinfo->rpz_used = rpz_used; actinfo->rpz_log = rpz_log; actinfo->log_name = log_name; actinfo->rpz_cname_override = rpz_cname_override; /* for inform variants, make a copy of the matched address block for * later logging. We make a copy to proactively avoid disruption if * and when we allow a dynamic update to the respip tree. */ if(action == respip_inform || action == respip_inform_deny || rpz_used) { struct respip_addr_info* a = regional_alloc_zero(region, sizeof(*a)); if(!a) { log_err("out of memory"); return 0; } a->addr = raddr->node.addr; a->addrlen = raddr->node.addrlen; a->net = raddr->node.net; actinfo->addrinfo = a; } return 1; } static int respip_use_rpz(struct resp_addr* raddr, struct rpz* r, enum respip_action* action, struct ub_packed_rrset_key** data, int* rpz_log, char** log_name, int* rpz_cname_override, struct regional* region, int* is_rpz) { if(r->action_override == RPZ_DISABLED_ACTION) { *is_rpz = 0; return 1; } else if(r->action_override == RPZ_NO_OVERRIDE_ACTION) *action = raddr->action; else *action = rpz_action_to_respip_action(r->action_override); if(r->action_override == RPZ_CNAME_OVERRIDE_ACTION && r->cname_override) { *data = r->cname_override; *rpz_cname_override = 1; } *rpz_log = r->log; if(r->log_name) if(!(*log_name = regional_strdup(region, r->log_name))) return 0; *is_rpz = 1; return 1; } int respip_rewrite_reply(const struct query_info* qinfo, const struct respip_client_info* cinfo, const struct reply_info* rep, struct reply_info** new_repp, struct respip_action_info* actinfo, struct ub_packed_rrset_key** alias_rrset, int search_only, struct regional* region, struct auth_zones* az) { const uint8_t* ctaglist; size_t ctaglen; const uint8_t* tag_actions; size_t tag_actions_size; struct config_strlist** tag_datas; size_t tag_datas_size; struct view* view = NULL; struct respip_set* ipset = NULL; size_t rrset_id = 0; enum respip_action action = respip_none; int tag = -1; struct resp_addr* raddr = NULL; int ret = 1; struct ub_packed_rrset_key* redirect_rrset = NULL; struct rpz* r; struct auth_zone* a = NULL; struct ub_packed_rrset_key* data = NULL; int rpz_used = 0; int rpz_log = 0; int rpz_cname_override = 0; char* log_name = NULL; if(!cinfo) goto done; ctaglist = cinfo->taglist; ctaglen = cinfo->taglen; tag_actions = cinfo->tag_actions; tag_actions_size = cinfo->tag_actions_size; tag_datas = cinfo->tag_datas; tag_datas_size = cinfo->tag_datas_size; view = cinfo->view; ipset = cinfo->respip_set; log_assert(ipset); /** Try to use response-ip config from the view first; use * global response-ip config if we don't have the view or we don't * have the matching per-view config (and the view allows the use * of global data in this case). * Note that we lock the view even if we only use view members that * currently don't change after creation. This is for safety for * future possible changes as the view documentation seems to expect * any of its member can change in the view's lifetime. * Note also that we assume 'view' is valid in this function, which * should be safe (see unbound bug #1191) */ if(view) { lock_rw_rdlock(&view->lock); if(view->respip_set) { if((raddr = respip_addr_lookup(rep, view->respip_set, &rrset_id))) { /** for per-view respip directives the action * can only be direct (i.e. not tag-based) */ action = raddr->action; } } if(!raddr && !view->isfirst) goto done; if(!raddr && view->isfirst) { lock_rw_unlock(&view->lock); view = NULL; } } if(!raddr && (raddr = respip_addr_lookup(rep, ipset, &rrset_id))) { action = (enum respip_action)local_data_find_tag_action( raddr->taglist, raddr->taglen, ctaglist, ctaglen, tag_actions, tag_actions_size, (enum localzone_type)raddr->action, &tag, ipset->tagname, ipset->num_tags); } lock_rw_rdlock(&az->rpz_lock); for(a = az->rpz_first; a && !raddr; a = a->rpz_az_next) { lock_rw_rdlock(&a->lock); r = a->rpz; if(!r->taglist || taglist_intersect(r->taglist, r->taglistlen, ctaglist, ctaglen)) { if((raddr = respip_addr_lookup(rep, r->respip_set, &rrset_id))) { if(!respip_use_rpz(raddr, r, &action, &data, &rpz_log, &log_name, &rpz_cname_override, region, &rpz_used)) { log_err("out of memory"); lock_rw_unlock(&raddr->lock); lock_rw_unlock(&a->lock); lock_rw_unlock(&az->rpz_lock); return 0; } if(rpz_used) { /* break to make sure 'a' stays pointed * to used auth_zone, and keeps lock */ break; } lock_rw_unlock(&raddr->lock); raddr = NULL; actinfo->rpz_disabled++; } } lock_rw_unlock(&a->lock); } lock_rw_unlock(&az->rpz_lock); if(raddr && !search_only) { int result = 0; /* first, see if we have response-ip or tag action for the * action except for 'always' variants. */ if(action != respip_always_refuse && action != respip_always_transparent && action != respip_always_nxdomain && action != respip_always_nodata && action != respip_always_deny && (result = respip_data_answer(action, (data) ? data : raddr->data, qinfo->qtype, rep, rrset_id, new_repp, tag, tag_datas, tag_datas_size, ipset->tagname, ipset->num_tags, &redirect_rrset, region)) < 0) { ret = 0; goto done; } /* if no action data applied, take action specific to the * action without data. */ if(!result && !respip_nodata_answer(qinfo->qtype, action, rep, rrset_id, new_repp, region)) { ret = 0; goto done; } } done: if(view) { lock_rw_unlock(&view->lock); } if(ret) { /* If we're redirecting the original answer to a * CNAME, record the CNAME rrset so the caller can take * the appropriate action. Note that we don't check the * action type; it should normally be 'redirect', but it * can be of other type when a data-dependent tag action * uses redirect response-ip data. */ if(redirect_rrset && redirect_rrset->rk.type == ntohs(LDNS_RR_TYPE_CNAME) && qinfo->qtype != LDNS_RR_TYPE_ANY) *alias_rrset = redirect_rrset; /* on success, populate respip result structure */ ret = populate_action_info(actinfo, action, raddr, redirect_rrset, tag, ipset, search_only, region, rpz_used, rpz_log, log_name, rpz_cname_override); } if(raddr) { lock_rw_unlock(&raddr->lock); } if(rpz_used) { lock_rw_unlock(&a->lock); } return ret; } static int generate_cname_request(struct module_qstate* qstate, struct ub_packed_rrset_key* alias_rrset) { struct module_qstate* subq = NULL; struct query_info subqi; memset(&subqi, 0, sizeof(subqi)); get_cname_target(alias_rrset, &subqi.qname, &subqi.qname_len); if(!subqi.qname) return 0; /* unexpected: not a valid CNAME RDATA */ subqi.qtype = qstate->qinfo.qtype; subqi.qclass = qstate->qinfo.qclass; fptr_ok(fptr_whitelist_modenv_attach_sub(qstate->env->attach_sub)); return (*qstate->env->attach_sub)(qstate, &subqi, BIT_RD, 0, 0, &subq); } void respip_operate(struct module_qstate* qstate, enum module_ev event, int id, struct outbound_entry* outbound) { struct respip_qstate* rq = (struct respip_qstate*)qstate->minfo[id]; log_query_info(VERB_QUERY, "respip operate: query", &qstate->qinfo); (void)outbound; if(event == module_event_new || event == module_event_pass) { if(!rq) { rq = regional_alloc_zero(qstate->region, sizeof(*rq)); if(!rq) goto servfail; rq->state = RESPIP_INIT; qstate->minfo[id] = rq; } if(rq->state == RESPIP_SUBQUERY_FINISHED) { qstate->ext_state[id] = module_finished; return; } verbose(VERB_ALGO, "respip: pass to next module"); qstate->ext_state[id] = module_wait_module; } else if(event == module_event_moddone) { /* If the reply may be subject to response-ip rewriting * according to the query type, check the actions. If a * rewrite is necessary, we'll replace the reply in qstate * with the new one. */ enum module_ext_state next_state = module_finished; if((qstate->qinfo.qtype == LDNS_RR_TYPE_A || qstate->qinfo.qtype == LDNS_RR_TYPE_AAAA || qstate->qinfo.qtype == LDNS_RR_TYPE_ANY) && qstate->return_msg && qstate->return_msg->rep) { struct reply_info* new_rep = qstate->return_msg->rep; struct ub_packed_rrset_key* alias_rrset = NULL; struct respip_action_info actinfo = {0, 0, 0, 0, NULL, 0, NULL}; actinfo.action = respip_none; if(!respip_rewrite_reply(&qstate->qinfo, qstate->client_info, qstate->return_msg->rep, &new_rep, &actinfo, &alias_rrset, 0, qstate->region, qstate->env->auth_zones)) { goto servfail; } if(actinfo.action != respip_none) { /* save action info for logging on a * per-front-end-query basis */ if(!(qstate->respip_action_info = regional_alloc_init(qstate->region, &actinfo, sizeof(actinfo)))) { log_err("out of memory"); goto servfail; } } else { qstate->respip_action_info = NULL; } if (actinfo.action == respip_always_deny || (new_rep == qstate->return_msg->rep && (actinfo.action == respip_deny || actinfo.action == respip_inform_deny))) { /* for deny-variant actions (unless response-ip * data is applied), mark the query state so * the response will be dropped for all * clients. */ qstate->is_drop = 1; } else if(alias_rrset) { if(!generate_cname_request(qstate, alias_rrset)) goto servfail; next_state = module_wait_subquery; } qstate->return_msg->rep = new_rep; } qstate->ext_state[id] = next_state; } else qstate->ext_state[id] = module_finished; return; servfail: qstate->return_rcode = LDNS_RCODE_SERVFAIL; qstate->return_msg = NULL; } int respip_merge_cname(struct reply_info* base_rep, const struct query_info* qinfo, const struct reply_info* tgt_rep, const struct respip_client_info* cinfo, int must_validate, struct reply_info** new_repp, struct regional* region, struct auth_zones* az) { struct reply_info* new_rep; struct reply_info* tmp_rep = NULL; /* just a placeholder */ struct ub_packed_rrset_key* alias_rrset = NULL; /* ditto */ uint16_t tgt_rcode; size_t i, j; struct respip_action_info actinfo = {0, 0, 0, 0, NULL, 0, NULL}; actinfo.action = respip_none; /* If the query for the CNAME target would result in an unusual rcode, * we generally translate it as a failure for the base query * (which would then be translated into SERVFAIL). The only exception * is NXDOMAIN and YXDOMAIN, which are passed to the end client(s). * The YXDOMAIN case would be rare but still possible (when * DNSSEC-validated DNAME has been cached but synthesizing CNAME * can't be generated due to length limitation) */ tgt_rcode = FLAGS_GET_RCODE(tgt_rep->flags); if((tgt_rcode != LDNS_RCODE_NOERROR && tgt_rcode != LDNS_RCODE_NXDOMAIN && tgt_rcode != LDNS_RCODE_YXDOMAIN) || (must_validate && tgt_rep->security <= sec_status_bogus)) { return 0; } /* see if the target reply would be subject to a response-ip action. */ if(!respip_rewrite_reply(qinfo, cinfo, tgt_rep, &tmp_rep, &actinfo, &alias_rrset, 1, region, az)) return 0; if(actinfo.action != respip_none) { log_info("CNAME target of redirect response-ip action would " "be subject to response-ip action, too; stripped"); *new_repp = base_rep; return 1; } /* Append target reply to the base. Since we cannot assume * tgt_rep->rrsets is valid throughout the lifetime of new_rep * or it can be safely shared by multiple threads, we need to make a * deep copy. */ new_rep = make_new_reply_info(base_rep, region, base_rep->an_numrrsets + tgt_rep->an_numrrsets, base_rep->an_numrrsets); if(!new_rep) return 0; for(i=0,j=base_rep->an_numrrsets; ian_numrrsets; i++,j++) { new_rep->rrsets[j] = copy_rrset(tgt_rep->rrsets[i], region); if(!new_rep->rrsets[j]) return 0; } FLAGS_SET_RCODE(new_rep->flags, tgt_rcode); *new_repp = new_rep; return 1; } void respip_inform_super(struct module_qstate* qstate, int id, struct module_qstate* super) { struct respip_qstate* rq = (struct respip_qstate*)super->minfo[id]; struct reply_info* new_rep = NULL; rq->state = RESPIP_SUBQUERY_FINISHED; /* respip subquery should have always been created with a valid reply * in super. */ log_assert(super->return_msg && super->return_msg->rep); /* return_msg can be NULL when, e.g., the sub query resulted in * SERVFAIL, in which case we regard it as a failure of the original * query. Other checks are probably redundant, but we check them * for safety. */ if(!qstate->return_msg || !qstate->return_msg->rep || qstate->return_rcode != LDNS_RCODE_NOERROR) goto fail; if(!respip_merge_cname(super->return_msg->rep, &qstate->qinfo, qstate->return_msg->rep, super->client_info, super->env->need_to_validate, &new_rep, super->region, qstate->env->auth_zones)) goto fail; super->return_msg->rep = new_rep; return; fail: super->return_rcode = LDNS_RCODE_SERVFAIL; super->return_msg = NULL; return; } void respip_clear(struct module_qstate* qstate, int id) { qstate->minfo[id] = NULL; } size_t respip_get_mem(struct module_env* env, int id) { (void)env; (void)id; return 0; } /** * The response-ip function block */ static struct module_func_block respip_block = { "respip", &respip_init, &respip_deinit, &respip_operate, &respip_inform_super, &respip_clear, &respip_get_mem }; struct module_func_block* respip_get_funcblock(void) { return &respip_block; } enum respip_action resp_addr_get_action(const struct resp_addr* addr) { return addr ? addr->action : respip_none; } struct ub_packed_rrset_key* resp_addr_get_rrset(struct resp_addr* addr) { return addr ? addr->data : NULL; } int respip_set_is_empty(const struct respip_set* set) { return set ? set->ip_tree.count == 0 : 1; } void respip_inform_print(struct respip_action_info* respip_actinfo, uint8_t* qname, uint16_t qtype, uint16_t qclass, struct local_rrset* local_alias, struct comm_reply* repinfo) { char srcip[128], respip[128], txt[512]; unsigned port; struct respip_addr_info* respip_addr = respip_actinfo->addrinfo; size_t txtlen = 0; const char* actionstr = NULL; if(local_alias) qname = local_alias->rrset->rk.dname; port = (unsigned)((repinfo->addr.ss_family == AF_INET) ? ntohs(((struct sockaddr_in*)&repinfo->addr)->sin_port) : ntohs(((struct sockaddr_in6*)&repinfo->addr)->sin6_port)); addr_to_str(&repinfo->addr, repinfo->addrlen, srcip, sizeof(srcip)); addr_to_str(&respip_addr->addr, respip_addr->addrlen, respip, sizeof(respip)); if(respip_actinfo->rpz_log) { txtlen += snprintf(txt+txtlen, sizeof(txt)-txtlen, "%s", "RPZ applied "); if(respip_actinfo->rpz_cname_override) actionstr = rpz_action_to_string( RPZ_CNAME_OVERRIDE_ACTION); else actionstr = rpz_action_to_string( respip_action_to_rpz_action( respip_actinfo->action)); } if(respip_actinfo->log_name) { txtlen += snprintf(txt+txtlen, sizeof(txt)-txtlen, "[%s] ", respip_actinfo->log_name); } snprintf(txt+txtlen, sizeof(txt)-txtlen, "%s/%d %s %s@%u", respip, respip_addr->net, (actionstr) ? actionstr : "inform", srcip, port); log_nametypeclass(NO_VERBOSE, txt, qname, qtype, qclass); }