/* * * Connection Manager * * Copyright (C) 2007-2014 Intel Corporation. All rights reserved. * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License version 2 as * published by the Free Software Foundation. * * 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, write to the Free Software * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA * */ #ifdef HAVE_CONFIG_H #include #endif #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "connman.h" #if defined TIZEN_EXT #include #include #endif #define debug(fmt...) do { } while (0) #if __BYTE_ORDER == __LITTLE_ENDIAN struct domain_hdr { uint16_t id; uint8_t rd:1; uint8_t tc:1; uint8_t aa:1; uint8_t opcode:4; uint8_t qr:1; uint8_t rcode:4; uint8_t z:3; uint8_t ra:1; uint16_t qdcount; uint16_t ancount; uint16_t nscount; uint16_t arcount; } __attribute__ ((packed)); #elif __BYTE_ORDER == __BIG_ENDIAN struct domain_hdr { uint16_t id; uint8_t qr:1; uint8_t opcode:4; uint8_t aa:1; uint8_t tc:1; uint8_t rd:1; uint8_t ra:1; uint8_t z:3; uint8_t rcode:4; uint16_t qdcount; uint16_t ancount; uint16_t nscount; uint16_t arcount; } __attribute__ ((packed)); #else #error "Unknown byte order" #endif struct qtype_qclass { uint16_t qtype; uint16_t qclass; } __attribute__ ((packed)); struct partial_reply { uint16_t len; uint16_t received; unsigned char buf[]; }; struct server_data { int index; GList *domains; char *server; struct sockaddr *server_addr; socklen_t server_addr_len; int protocol; GIOChannel *channel; guint watch; guint timeout; bool enabled; bool connected; struct partial_reply *incoming_reply; }; struct request_data { union { struct sockaddr_in6 __sin6; /* Only for the length */ struct sockaddr sa; }; socklen_t sa_len; int client_sk; int protocol; int family; guint16 srcid; guint16 dstid; guint16 altid; guint timeout; guint watch; guint numserv; guint numresp; gpointer request; gsize request_len; gpointer name; gpointer resp; gsize resplen; struct listener_data *ifdata; bool append_domain; }; struct listener_data { int index; GIOChannel *udp4_listener_channel; GIOChannel *tcp4_listener_channel; guint udp4_listener_watch; guint tcp4_listener_watch; GIOChannel *udp6_listener_channel; GIOChannel *tcp6_listener_channel; guint udp6_listener_watch; guint tcp6_listener_watch; }; /* * The TCP client requires some extra handling as we need to * be prepared to receive also partial DNS requests. */ struct tcp_partial_client_data { int family; struct listener_data *ifdata; GIOChannel *channel; guint watch; unsigned char *buf; unsigned int buf_end; guint timeout; }; struct cache_data { time_t inserted; time_t valid_until; time_t cache_until; int timeout; uint16_t type; uint16_t answers; unsigned int data_len; unsigned char *data; /* contains DNS header + body */ }; struct cache_entry { char *key; bool want_refresh; int hits; struct cache_data *ipv4; struct cache_data *ipv6; }; struct domain_question { uint16_t type; uint16_t class; } __attribute__ ((packed)); struct domain_rr { uint16_t type; uint16_t class; uint32_t ttl; uint16_t rdlen; } __attribute__ ((packed)); /* * Max length of the DNS TCP packet. */ #define TCP_MAX_BUF_LEN 4096 /* * We limit how long the cached DNS entry stays in the cache. * By default the TTL (time-to-live) of the DNS response is used * when setting the cache entry life time. The value is in seconds. */ #if defined TIZEN_EXT #define MAX_CACHE_TTL (60 * 60) #else #define MAX_CACHE_TTL (60 * 30) #endif /* * Also limit the other end, cache at least for 30 seconds. */ #define MIN_CACHE_TTL (30) /* * We limit the cache size to some sane value so that cached data does * not occupy too much memory. Each cached entry occupies on average * about 100 bytes memory (depending on DNS name length). * Example: caching www.connman.net uses 97 bytes memory. * The value is the max amount of cached DNS responses (count). */ #define MAX_CACHE_SIZE 256 static int cache_size; static GHashTable *cache; static int cache_refcount; static GSList *server_list = NULL; #if defined TIZEN_EXT static GSList *server_list_sec = NULL; #endif static GSList *request_list = NULL; static GHashTable *listener_table = NULL; static time_t next_refresh; static GHashTable *partial_tcp_req_table; static guint cache_timer = 0; #if defined TIZEN_EXT static void destroy_server_sec(struct server_data *server); static struct server_data *create_server_sec(int index, const char *domain, const char *server, int protocol); #endif static guint16 get_id(void) { uint64_t rand; __connman_util_get_random(&rand); return rand; } static int protocol_offset(int protocol) { switch (protocol) { case IPPROTO_UDP: return 0; case IPPROTO_TCP: return 2; default: return -EINVAL; } } /* * There is a power and efficiency benefit to have entries * in our cache expire at the same time. To this extend, * we round down the cache valid time to common boundaries. */ static time_t round_down_ttl(time_t end_time, int ttl) { if (ttl < 15) return end_time; /* Less than 5 minutes, round to 10 second boundary */ if (ttl < 300) { end_time = end_time / 10; end_time = end_time * 10; } else { /* 5 or more minutes, round to 30 seconds */ end_time = end_time / 30; end_time = end_time * 30; } return end_time; } static struct request_data *find_request(guint16 id) { GSList *list; for (list = request_list; list; list = list->next) { struct request_data *req = list->data; if (req->dstid == id || req->altid == id) return req; } return NULL; } static struct server_data *find_server(int index, const char *server, int protocol) { GSList *list; debug("index %d server %s proto %d", index, server, protocol); for (list = server_list; list; list = list->next) { struct server_data *data = list->data; if (index < 0 && data->index < 0 && g_str_equal(data->server, server) && data->protocol == protocol) return data; if (index < 0 || data->index < 0 || !data->server) continue; if (data->index == index && g_str_equal(data->server, server) && data->protocol == protocol) return data; } return NULL; } /* we can keep using the same resolve's */ static GResolv *ipv4_resolve; static GResolv *ipv6_resolve; static void dummy_resolve_func(GResolvResultStatus status, char **results, gpointer user_data) { } /* * Refresh a DNS entry, but also age the hit count a bit */ static void refresh_dns_entry(struct cache_entry *entry, char *name) { int age = 1; if (!ipv4_resolve) { ipv4_resolve = g_resolv_new(0); g_resolv_set_address_family(ipv4_resolve, AF_INET); g_resolv_add_nameserver(ipv4_resolve, "127.0.0.1", 53, 0); } if (!ipv6_resolve) { ipv6_resolve = g_resolv_new(0); g_resolv_set_address_family(ipv6_resolve, AF_INET6); g_resolv_add_nameserver(ipv6_resolve, "::1", 53, 0); } if (!entry->ipv4) { debug("Refreshing A record for %s", name); g_resolv_lookup_hostname(ipv4_resolve, name, dummy_resolve_func, NULL); age = 4; } if (!entry->ipv6) { debug("Refreshing AAAA record for %s", name); g_resolv_lookup_hostname(ipv6_resolve, name, dummy_resolve_func, NULL); age = 4; } entry->hits -= age; if (entry->hits < 0) entry->hits = 0; } static int dns_name_length(unsigned char *buf) { if ((buf[0] & NS_CMPRSFLGS) == NS_CMPRSFLGS) /* compressed name */ return 2; return strlen((char *)buf) + 1; } static void update_cached_ttl(unsigned char *buf, int len, int new_ttl) { unsigned char *c; uint16_t w; int l; /* skip the header */ c = buf + 12; len -= 12; /* skip the query, which is a name and 2 16 bit words */ l = dns_name_length(c); c += l; len -= l; c += 4; len -= 4; /* now we get the answer records */ while (len > 0) { /* first a name */ l = dns_name_length(c); c += l; len -= l; if (len < 0) break; /* then type + class, 2 bytes each */ c += 4; len -= 4; if (len < 0) break; /* now the 4 byte TTL field */ c[0] = new_ttl >> 24 & 0xff; c[1] = new_ttl >> 16 & 0xff; c[2] = new_ttl >> 8 & 0xff; c[3] = new_ttl & 0xff; c += 4; len -= 4; if (len < 0) break; /* now the 2 byte rdlen field */ w = c[0] << 8 | c[1]; c += w + 2; len -= w + 2; } } static void send_cached_response(int sk, unsigned char *buf, int len, const struct sockaddr *to, socklen_t tolen, int protocol, int id, uint16_t answers, int ttl) { struct domain_hdr *hdr; unsigned char *ptr = buf; int err, offset, dns_len, adj_len = len - 2; /* * The cached packet contains always the TCP offset (two bytes) * so skip them for UDP. */ switch (protocol) { case IPPROTO_UDP: ptr += 2; len -= 2; dns_len = len; offset = 0; break; case IPPROTO_TCP: offset = 2; dns_len = ptr[0] * 256 + ptr[1]; break; default: return; } if (len < 12) return; hdr = (void *) (ptr + offset); hdr->id = id; hdr->qr = 1; hdr->rcode = ns_r_noerror; hdr->ancount = htons(answers); hdr->nscount = 0; hdr->arcount = 0; /* if this is a negative reply, we are authoritative */ if (answers == 0) hdr->aa = 1; else update_cached_ttl((unsigned char *)hdr, adj_len, ttl); debug("sk %d id 0x%04x answers %d ptr %p length %d dns %d", sk, hdr->id, answers, ptr, len, dns_len); err = sendto(sk, ptr, len, MSG_NOSIGNAL, to, tolen); if (err < 0) { connman_error("Cannot send cached DNS response: %s", strerror(errno)); return; } if (err != len || (dns_len != (len - 2) && protocol == IPPROTO_TCP) || (dns_len != len && protocol == IPPROTO_UDP)) debug("Packet length mismatch, sent %d wanted %d dns %d", err, len, dns_len); } static void send_response(int sk, unsigned char *buf, size_t len, const struct sockaddr *to, socklen_t tolen, int protocol) { struct domain_hdr *hdr; int err, offset = protocol_offset(protocol); debug("sk %d", sk); if (offset < 0) return; if (len < sizeof(*hdr) + offset) return; hdr = (void *) (buf + offset); #if !defined TIZEN_EXT if (offset) { buf[0] = 0; buf[1] = sizeof(*hdr); } #endif debug("id 0x%04x qr %d opcode %d", hdr->id, hdr->qr, hdr->opcode); hdr->qr = 1; hdr->rcode = ns_r_servfail; #if !defined TIZEN_EXT hdr->qdcount = 0; #endif hdr->ancount = 0; hdr->nscount = 0; hdr->arcount = 0; #if defined TIZEN_EXT err = sendto(sk, buf, len, MSG_NOSIGNAL, to, tolen); #else err = sendto(sk, buf, sizeof(*hdr) + offset, MSG_NOSIGNAL, to, tolen); #endif if (err < 0) { connman_error("Failed to send DNS response to %d: %s", sk, strerror(errno)); return; } } static int get_req_udp_socket(struct request_data *req) { GIOChannel *channel; if (req->family == AF_INET) channel = req->ifdata->udp4_listener_channel; else channel = req->ifdata->udp6_listener_channel; if (!channel) return -1; return g_io_channel_unix_get_fd(channel); } static void destroy_request_data(struct request_data *req) { if (req->timeout > 0) g_source_remove(req->timeout); g_free(req->resp); g_free(req->request); g_free(req->name); g_free(req); } static gboolean request_timeout(gpointer user_data) { struct request_data *req = user_data; struct sockaddr *sa; int sk; if (!req) return FALSE; debug("id 0x%04x", req->srcid); request_list = g_slist_remove(request_list, req); if (req->protocol == IPPROTO_UDP) { sk = get_req_udp_socket(req); sa = &req->sa; } else if (req->protocol == IPPROTO_TCP) { sk = req->client_sk; sa = NULL; } else goto out; if (req->resplen > 0 && req->resp) { /* * Here we have received at least one reply (probably telling * "not found" result), so send that back to client instead * of more fatal server failed error. */ if (sk >= 0) sendto(sk, req->resp, req->resplen, MSG_NOSIGNAL, sa, req->sa_len); } else if (req->request) { /* * There was not reply from server at all. */ struct domain_hdr *hdr; hdr = (void *)(req->request + protocol_offset(req->protocol)); hdr->id = req->srcid; if (sk >= 0) send_response(sk, req->request, req->request_len, sa, req->sa_len, req->protocol); } /* * We cannot leave TCP client hanging so just kick it out * if we get a request timeout from server. */ if (req->protocol == IPPROTO_TCP) { debug("client %d removed", req->client_sk); g_hash_table_remove(partial_tcp_req_table, GINT_TO_POINTER(req->client_sk)); } out: req->timeout = 0; destroy_request_data(req); return FALSE; } static int append_query(unsigned char *buf, unsigned int size, const char *query, const char *domain) { unsigned char *ptr = buf; int len; debug("query %s domain %s", query, domain); while (query) { const char *tmp; tmp = strchr(query, '.'); if (!tmp) { len = strlen(query); if (len == 0) break; *ptr = len; memcpy(ptr + 1, query, len); ptr += len + 1; break; } *ptr = tmp - query; memcpy(ptr + 1, query, tmp - query); ptr += tmp - query + 1; query = tmp + 1; } while (domain) { const char *tmp; tmp = strchr(domain, '.'); if (!tmp) { len = strlen(domain); if (len == 0) break; *ptr = len; memcpy(ptr + 1, domain, len); ptr += len + 1; break; } *ptr = tmp - domain; memcpy(ptr + 1, domain, tmp - domain); ptr += tmp - domain + 1; domain = tmp + 1; } *ptr++ = 0x00; return ptr - buf; } static bool cache_check_is_valid(struct cache_data *data, time_t current_time) { if (!data) return false; if (data->cache_until < current_time) return false; return true; } /* * remove stale cached entries so that they can be refreshed */ static void cache_enforce_validity(struct cache_entry *entry) { time_t current_time = time(NULL); if (!cache_check_is_valid(entry->ipv4, current_time) && entry->ipv4) { debug("cache timeout \"%s\" type A", entry->key); g_free(entry->ipv4->data); g_free(entry->ipv4); entry->ipv4 = NULL; } if (!cache_check_is_valid(entry->ipv6, current_time) && entry->ipv6) { debug("cache timeout \"%s\" type AAAA", entry->key); g_free(entry->ipv6->data); g_free(entry->ipv6); entry->ipv6 = NULL; } } static uint16_t cache_check_validity(char *question, uint16_t type, struct cache_entry *entry) { time_t current_time = time(NULL); bool want_refresh = false; /* * if we have a popular entry, we want a refresh instead of * total destruction of the entry. */ if (entry->hits > 2) want_refresh = true; cache_enforce_validity(entry); switch (type) { case 1: /* IPv4 */ if (!cache_check_is_valid(entry->ipv4, current_time)) { debug("cache %s \"%s\" type A", entry->ipv4 ? "timeout" : "entry missing", question); if (want_refresh) entry->want_refresh = true; /* * We do not remove cache entry if there is still * valid IPv6 entry found in the cache. */ if (!cache_check_is_valid(entry->ipv6, current_time) && !want_refresh) { g_hash_table_remove(cache, question); type = 0; } } break; case 28: /* IPv6 */ if (!cache_check_is_valid(entry->ipv6, current_time)) { debug("cache %s \"%s\" type AAAA", entry->ipv6 ? "timeout" : "entry missing", question); if (want_refresh) entry->want_refresh = true; if (!cache_check_is_valid(entry->ipv4, current_time) && !want_refresh) { g_hash_table_remove(cache, question); type = 0; } } break; } return type; } static void cache_element_destroy(gpointer value) { struct cache_entry *entry = value; if (!entry) return; if (entry->ipv4) { g_free(entry->ipv4->data); g_free(entry->ipv4); } if (entry->ipv6) { g_free(entry->ipv6->data); g_free(entry->ipv6); } g_free(entry->key); g_free(entry); if (--cache_size < 0) cache_size = 0; } static gboolean try_remove_cache(gpointer user_data) { cache_timer = 0; if (__sync_fetch_and_sub(&cache_refcount, 1) == 1) { debug("No cache users, removing it."); g_hash_table_destroy(cache); cache = NULL; } return FALSE; } static void create_cache(void) { if (__sync_fetch_and_add(&cache_refcount, 1) == 0) cache = g_hash_table_new_full(g_str_hash, g_str_equal, NULL, cache_element_destroy); } static struct cache_entry *cache_check(gpointer request, int *qtype, int proto) { char *question; struct cache_entry *entry; struct domain_question *q; uint16_t type; int offset, proto_offset; if (!request) return NULL; proto_offset = protocol_offset(proto); if (proto_offset < 0) return NULL; question = request + proto_offset + 12; offset = strlen(question) + 1; q = (void *) (question + offset); type = ntohs(q->type); /* We only cache either A (1) or AAAA (28) requests */ if (type != 1 && type != 28) return NULL; if (!cache) { create_cache(); return NULL; } entry = g_hash_table_lookup(cache, question); if (!entry) return NULL; type = cache_check_validity(question, type, entry); if (type == 0) return NULL; *qtype = type; return entry; } /* * Get a label/name from DNS resource record. The function decompresses the * label if necessary. The function does not convert the name to presentation * form. This means that the result string will contain label lengths instead * of dots between labels. We intentionally do not want to convert to dotted * format so that we can cache the wire format string directly. */ static int get_name(int counter, unsigned char *pkt, unsigned char *start, unsigned char *max, unsigned char *output, int output_max, int *output_len, unsigned char **end, char *name, size_t max_name, int *name_len) { unsigned char *p; /* Limit recursion to 10 (this means up to 10 labels in domain name) */ if (counter > 10) return -EINVAL; p = start; while (*p) { if ((*p & NS_CMPRSFLGS) == NS_CMPRSFLGS) { uint16_t offset = (*p & 0x3F) * 256 + *(p + 1); if (offset >= max - pkt) return -ENOBUFS; if (!*end) *end = p + 2; return get_name(counter + 1, pkt, pkt + offset, max, output, output_max, output_len, end, name, max_name, name_len); } else { unsigned label_len = *p; if (pkt + label_len > max) return -ENOBUFS; if (*output_len > output_max) return -ENOBUFS; if ((*name_len + 1 + label_len + 1) > max_name) return -ENOBUFS; /* * We need the original name in order to check * if this answer is the correct one. */ name[(*name_len)++] = label_len; memcpy(name + *name_len, p + 1, label_len + 1); *name_len += label_len; /* We compress the result */ output[0] = NS_CMPRSFLGS; output[1] = 0x0C; *output_len = 2; p += label_len + 1; if (!*end) *end = p; if (p >= max) return -ENOBUFS; } } return 0; } static int parse_rr(unsigned char *buf, unsigned char *start, unsigned char *max, unsigned char *response, unsigned int *response_size, uint16_t *type, uint16_t *class, int *ttl, int *rdlen, unsigned char **end, char *name, size_t max_name) { struct domain_rr *rr; int err, offset; int name_len = 0, output_len = 0, max_rsp = *response_size; err = get_name(0, buf, start, max, response, max_rsp, &output_len, end, name, max_name, &name_len); if (err < 0) return err; offset = output_len; if ((unsigned int) offset > *response_size) return -ENOBUFS; rr = (void *) (*end); if (!rr) return -EINVAL; *type = ntohs(rr->type); *class = ntohs(rr->class); *ttl = ntohl(rr->ttl); *rdlen = ntohs(rr->rdlen); if (*ttl < 0) return -EINVAL; memcpy(response + offset, *end, sizeof(struct domain_rr)); offset += sizeof(struct domain_rr); *end += sizeof(struct domain_rr); if ((unsigned int) (offset + *rdlen) > *response_size) return -ENOBUFS; memcpy(response + offset, *end, *rdlen); *end += *rdlen; *response_size = offset + *rdlen; return 0; } static bool check_alias(GSList *aliases, char *name) { GSList *list; if (aliases) { for (list = aliases; list; list = list->next) { int len = strlen((char *)list->data); if (strncmp((char *)list->data, name, len) == 0) return true; } } return false; } static int parse_response(unsigned char *buf, int buflen, char *question, int qlen, uint16_t *type, uint16_t *class, int *ttl, unsigned char *response, unsigned int *response_len, uint16_t *answers) { struct domain_hdr *hdr = (void *) buf; struct domain_question *q; unsigned char *ptr; uint16_t qdcount = ntohs(hdr->qdcount); uint16_t ancount = ntohs(hdr->ancount); int err, i; uint16_t qtype, qclass; unsigned char *next = NULL; unsigned int maxlen = *response_len; GSList *aliases = NULL, *list; char name[NS_MAXDNAME + 1]; if (buflen < 12) return -EINVAL; debug("qr %d qdcount %d", hdr->qr, qdcount); /* We currently only cache responses where question count is 1 */ if (hdr->qr != 1 || qdcount != 1) return -EINVAL; ptr = buf + sizeof(struct domain_hdr); strncpy(question, (char *) ptr, qlen); qlen = strlen(question); ptr += qlen + 1; /* skip \0 */ q = (void *) ptr; qtype = ntohs(q->type); /* We cache only A and AAAA records */ if (qtype != 1 && qtype != 28) return -ENOMSG; qclass = ntohs(q->class); ptr += 2 + 2; /* ptr points now to answers */ err = -ENOMSG; *response_len = 0; *answers = 0; memset(name, 0, sizeof(name)); /* * We have a bunch of answers (like A, AAAA, CNAME etc) to * A or AAAA question. We traverse the answers and parse the * resource records. Only A and AAAA records are cached, all * the other records in answers are skipped. */ for (i = 0; i < ancount; i++) { /* * Get one address at a time to this buffer. * The max size of the answer is * 2 (pointer) + 2 (type) + 2 (class) + * 4 (ttl) + 2 (rdlen) + addr (16 or 4) = 28 * for A or AAAA record. * For CNAME the size can be bigger. */ unsigned char rsp[NS_MAXCDNAME]; unsigned int rsp_len = sizeof(rsp) - 1; int ret, rdlen; memset(rsp, 0, sizeof(rsp)); ret = parse_rr(buf, ptr, buf + buflen, rsp, &rsp_len, type, class, ttl, &rdlen, &next, name, sizeof(name) - 1); if (ret != 0) { err = ret; goto out; } /* * Now rsp contains compressed or uncompressed resource * record. Next we check if this record answers the question. * The name var contains the uncompressed label. * One tricky bit is the CNAME records as they alias * the name we might be interested in. */ /* * Go to next answer if the class is not the one we are * looking for. */ if (*class != qclass) { ptr = next; next = NULL; continue; } /* * Try to resolve aliases also, type is CNAME(5). * This is important as otherwise the aliased names would not * be cached at all as the cache would not contain the aliased * question. * * If any CNAME is found in DNS packet, then we cache the alias * IP address instead of the question (as the server * said that question has only an alias). * This means in practice that if e.g., ipv6.google.com is * queried, DNS server returns CNAME of that name which is * ipv6.l.google.com. We then cache the address of the CNAME * but return the question name to client. So the alias * status of the name is not saved in cache and thus not * returned to the client. We do not return DNS packets from * cache to client saying that ipv6.google.com is an alias to * ipv6.l.google.com but we return instead a DNS packet that * says ipv6.google.com has address xxx which is in fact the * address of ipv6.l.google.com. For caching purposes this * should not cause any issues. */ if (*type == 5 && strncmp(question, name, qlen) == 0) { /* * So now the alias answered the question. This is * not very useful from caching point of view as * the following A or AAAA records will not match the * question. We need to find the real A/AAAA record * of the alias and cache that. */ unsigned char *end = NULL; int name_len = 0, output_len = 0; memset(rsp, 0, sizeof(rsp)); rsp_len = sizeof(rsp) - 1; /* * Alias is in rdata part of the message, * and next-rdlen points to it. So we need to get * the real name of the alias. */ ret = get_name(0, buf, next - rdlen, buf + buflen, rsp, rsp_len, &output_len, &end, name, sizeof(name) - 1, &name_len); if (ret != 0) { /* just ignore the error at this point */ ptr = next; next = NULL; continue; } /* * We should now have the alias of the entry we might * want to cache. Just remember it for a while. * We check the alias list when we have parsed the * A or AAAA record. */ aliases = g_slist_prepend(aliases, g_strdup(name)); ptr = next; next = NULL; continue; } if (*type == qtype) { /* * We found correct type (A or AAAA) */ if (check_alias(aliases, name) || (!aliases && strncmp(question, name, qlen) == 0)) { /* * We found an alias or the name of the rr * matches the question. If so, we append * the compressed label to the cache. * The end result is a response buffer that * will contain one or more cached and * compressed resource records. */ if (*response_len + rsp_len > maxlen) { err = -ENOBUFS; goto out; } memcpy(response + *response_len, rsp, rsp_len); *response_len += rsp_len; (*answers)++; err = 0; } } ptr = next; next = NULL; } out: for (list = aliases; list; list = list->next) g_free(list->data); g_slist_free(aliases); return err; } struct cache_timeout { time_t current_time; int max_timeout; int try_harder; }; static gboolean cache_check_entry(gpointer key, gpointer value, gpointer user_data) { struct cache_timeout *data = user_data; struct cache_entry *entry = value; int max_timeout; /* Scale the number of hits by half as part of cache aging */ entry->hits /= 2; /* * If either IPv4 or IPv6 cached entry has expired, we * remove both from the cache. */ if (entry->ipv4 && entry->ipv4->timeout > 0) { max_timeout = entry->ipv4->cache_until; if (max_timeout > data->max_timeout) data->max_timeout = max_timeout; if (entry->ipv4->cache_until < data->current_time) return TRUE; } if (entry->ipv6 && entry->ipv6->timeout > 0) { max_timeout = entry->ipv6->cache_until; if (max_timeout > data->max_timeout) data->max_timeout = max_timeout; if (entry->ipv6->cache_until < data->current_time) return TRUE; } /* * if we're asked to try harder, also remove entries that have * few hits */ if (data->try_harder && entry->hits < 4) return TRUE; return FALSE; } static void cache_cleanup(void) { static int max_timeout; struct cache_timeout data; int count = 0; data.current_time = time(NULL); data.max_timeout = 0; data.try_harder = 0; /* * In the first pass, we only remove entries that have timed out. * We use a cache of the first time to expire to do this only * when it makes sense. */ if (max_timeout <= data.current_time) { count = g_hash_table_foreach_remove(cache, cache_check_entry, &data); } debug("removed %d in the first pass", count); /* * In the second pass, if the first pass turned up blank, * we also expire entries with a low hit count, * while aging the hit count at the same time. */ data.try_harder = 1; if (count == 0) count = g_hash_table_foreach_remove(cache, cache_check_entry, &data); if (count == 0) /* * If we could not remove anything, then remember * what is the max timeout and do nothing if we * have not yet reached it. This will prevent * constant traversal of the cache if it is full. */ max_timeout = data.max_timeout; else max_timeout = 0; } static gboolean cache_invalidate_entry(gpointer key, gpointer value, gpointer user_data) { struct cache_entry *entry = value; /* first, delete any expired elements */ cache_enforce_validity(entry); /* if anything is not expired, mark the entry for refresh */ if (entry->hits > 0 && (entry->ipv4 || entry->ipv6)) entry->want_refresh = true; /* delete the cached data */ if (entry->ipv4) { g_free(entry->ipv4->data); g_free(entry->ipv4); entry->ipv4 = NULL; } if (entry->ipv6) { g_free(entry->ipv6->data); g_free(entry->ipv6); entry->ipv6 = NULL; } /* keep the entry if we want it refreshed, delete it otherwise */ if (entry->want_refresh) return FALSE; else return TRUE; } /* * cache_invalidate is called from places where the DNS landscape * has changed, say because connections are added or we entered a VPN. * The logic is to wipe all cache data, but mark all non-expired * parts of the cache for refresh rather than deleting the whole cache. */ static void cache_invalidate(void) { debug("Invalidating the DNS cache %p", cache); if (!cache) return; g_hash_table_foreach_remove(cache, cache_invalidate_entry, NULL); } static void cache_refresh_entry(struct cache_entry *entry) { cache_enforce_validity(entry); if (entry->hits > 2 && !entry->ipv4) entry->want_refresh = true; if (entry->hits > 2 && !entry->ipv6) entry->want_refresh = true; if (entry->want_refresh) { char *c; char dns_name[NS_MAXDNAME + 1]; entry->want_refresh = false; /* turn a DNS name into a hostname with dots */ strncpy(dns_name, entry->key, NS_MAXDNAME); c = dns_name; while (c && *c) { int jump; jump = *c; *c = '.'; c += jump + 1; } debug("Refreshing %s\n", dns_name); /* then refresh the hostname */ refresh_dns_entry(entry, &dns_name[1]); } } static void cache_refresh_iterator(gpointer key, gpointer value, gpointer user_data) { struct cache_entry *entry = value; cache_refresh_entry(entry); } static void cache_refresh(void) { if (!cache) return; g_hash_table_foreach(cache, cache_refresh_iterator, NULL); } static int reply_query_type(unsigned char *msg, int len) { unsigned char *c; int l; int type; /* skip the header */ c = msg + sizeof(struct domain_hdr); len -= sizeof(struct domain_hdr); if (len < 0) return 0; /* now the query, which is a name and 2 16 bit words */ l = dns_name_length(c); c += l; type = c[0] << 8 | c[1]; return type; } static int cache_update(struct server_data *srv, unsigned char *msg, unsigned int msg_len) { int offset = protocol_offset(srv->protocol); int err, qlen, ttl = 0; uint16_t answers = 0, type = 0, class = 0; struct domain_hdr *hdr = (void *)(msg + offset); struct domain_question *q; struct cache_entry *entry; struct cache_data *data; char question[NS_MAXDNAME + 1]; unsigned char response[NS_MAXDNAME + 1]; unsigned char *ptr; unsigned int rsplen; bool new_entry = true; time_t current_time; if (cache_size >= MAX_CACHE_SIZE) { cache_cleanup(); if (cache_size >= MAX_CACHE_SIZE) return 0; } current_time = time(NULL); /* don't do a cache refresh more than twice a minute */ if (next_refresh < current_time) { cache_refresh(); next_refresh = current_time + 30; } if (offset < 0) return 0; debug("offset %d hdr %p msg %p rcode %d", offset, hdr, msg, hdr->rcode); /* Continue only if response code is 0 (=ok) */ if (hdr->rcode != ns_r_noerror) return 0; if (!cache) create_cache(); rsplen = sizeof(response) - 1; question[sizeof(question) - 1] = '\0'; err = parse_response(msg + offset, msg_len - offset, question, sizeof(question) - 1, &type, &class, &ttl, response, &rsplen, &answers); /* * special case: if we do a ipv6 lookup and get no result * for a record that's already in our ipv4 cache.. we want * to cache the negative response. */ if ((err == -ENOMSG || err == -ENOBUFS) && reply_query_type(msg + offset, msg_len - offset) == 28) { entry = g_hash_table_lookup(cache, question); if (entry && entry->ipv4 && !entry->ipv6) { int cache_offset = 0; data = g_try_new(struct cache_data, 1); if (!data) return -ENOMEM; data->inserted = entry->ipv4->inserted; data->type = type; data->answers = ntohs(hdr->ancount); data->timeout = entry->ipv4->timeout; if (srv->protocol == IPPROTO_UDP) cache_offset = 2; data->data_len = msg_len + cache_offset; data->data = ptr = g_malloc(data->data_len); ptr[0] = (data->data_len - 2) / 256; ptr[1] = (data->data_len - 2) - ptr[0] * 256; if (srv->protocol == IPPROTO_UDP) ptr += 2; data->valid_until = entry->ipv4->valid_until; data->cache_until = entry->ipv4->cache_until; memcpy(ptr, msg, msg_len); entry->ipv6 = data; /* * we will get a "hit" when we serve the response * out of the cache */ entry->hits--; if (entry->hits < 0) entry->hits = 0; return 0; } } if (err < 0 || ttl == 0) return 0; qlen = strlen(question); /* * If the cache contains already data, check if the * type of the cached data is the same and do not add * to cache if data is already there. * This is needed so that we can cache both A and AAAA * records for the same name. */ entry = g_hash_table_lookup(cache, question); if (!entry) { entry = g_try_new(struct cache_entry, 1); if (!entry) return -ENOMEM; data = g_try_new(struct cache_data, 1); if (!data) { g_free(entry); return -ENOMEM; } entry->key = g_strdup(question); entry->ipv4 = entry->ipv6 = NULL; entry->want_refresh = false; entry->hits = 0; if (type == 1) entry->ipv4 = data; else entry->ipv6 = data; } else { if (type == 1 && entry->ipv4) return 0; if (type == 28 && entry->ipv6) return 0; data = g_try_new(struct cache_data, 1); if (!data) return -ENOMEM; if (type == 1) entry->ipv4 = data; else entry->ipv6 = data; /* * compensate for the hit we'll get for serving * the response out of the cache */ entry->hits--; if (entry->hits < 0) entry->hits = 0; new_entry = false; } if (ttl < MIN_CACHE_TTL) ttl = MIN_CACHE_TTL; data->inserted = current_time; data->type = type; data->answers = answers; data->timeout = ttl; /* * The "2" in start of the length is the TCP offset. We allocate it * here even for UDP packet because it simplifies the sending * of cached packet. */ data->data_len = 2 + 12 + qlen + 1 + 2 + 2 + rsplen; data->data = ptr = g_malloc(data->data_len); data->valid_until = current_time + ttl; /* * Restrict the cached DNS record TTL to some sane value * in order to prevent data staying in the cache too long. */ if (ttl > MAX_CACHE_TTL) ttl = MAX_CACHE_TTL; data->cache_until = round_down_ttl(current_time + ttl, ttl); if (!data->data) { g_free(entry->key); g_free(data); g_free(entry); return -ENOMEM; } /* * We cache the two extra bytes at the start of the message * in a TCP packet. When sending UDP packet, we skip the first * two bytes. This way we do not need to know the format * (UDP/TCP) of the cached message. */ if (srv->protocol == IPPROTO_UDP) memcpy(ptr + 2, msg, offset + 12); else memcpy(ptr, msg, offset + 12); ptr[0] = (data->data_len - 2) / 256; ptr[1] = (data->data_len - 2) - ptr[0] * 256; if (srv->protocol == IPPROTO_UDP) ptr += 2; memcpy(ptr + offset + 12, question, qlen + 1); /* copy also the \0 */ q = (void *) (ptr + offset + 12 + qlen + 1); q->type = htons(type); q->class = htons(class); memcpy(ptr + offset + 12 + qlen + 1 + sizeof(struct domain_question), response, rsplen); if (new_entry) { g_hash_table_replace(cache, entry->key, entry); cache_size++; } debug("cache %d %squestion \"%s\" type %d ttl %d size %zd packet %u " "dns len %u", cache_size, new_entry ? "new " : "old ", question, type, ttl, sizeof(*entry) + sizeof(*data) + data->data_len + qlen, data->data_len, srv->protocol == IPPROTO_TCP ? (unsigned int)(data->data[0] * 256 + data->data[1]) : data->data_len); return 0; } static int ns_resolv(struct server_data *server, struct request_data *req, gpointer request, gpointer name) { GList *list; int sk, err, type = 0; char *dot, *lookup = (char *) name; struct cache_entry *entry; entry = cache_check(request, &type, req->protocol); if (entry) { int ttl_left = 0; struct cache_data *data; debug("cache hit %s type %s", lookup, type == 1 ? "A" : "AAAA"); if (type == 1) data = entry->ipv4; else data = entry->ipv6; if (data) { ttl_left = data->valid_until - time(NULL); entry->hits++; } if (data && req->protocol == IPPROTO_TCP) { send_cached_response(req->client_sk, data->data, data->data_len, NULL, 0, IPPROTO_TCP, req->srcid, data->answers, ttl_left); return 1; } if (data && req->protocol == IPPROTO_UDP) { int udp_sk = get_req_udp_socket(req); if (udp_sk < 0) return -EIO; send_cached_response(udp_sk, data->data, data->data_len, &req->sa, req->sa_len, IPPROTO_UDP, req->srcid, data->answers, ttl_left); return 1; } } #if defined TIZEN_EXT if (server->protocol == IPPROTO_UDP) { GList *domains; struct server_data *new_server = NULL; new_server = create_server_sec(server->index, NULL, server->server, IPPROTO_UDP); if (new_server != NULL) { for (domains = server->domains; domains; domains = domains->next) { char *dom = domains->data; DBG("Adding domain %s to %s", dom, new_server->server); new_server->domains = g_list_append( new_server->domains, g_strdup(dom)); } server = new_server; } } #endif sk = g_io_channel_unix_get_fd(server->channel); err = sendto(sk, request, req->request_len, MSG_NOSIGNAL, server->server_addr, server->server_addr_len); if (err < 0) { debug("Cannot send message to server %s sock %d " "protocol %d (%s/%d)", server->server, sk, server->protocol, strerror(errno), errno); return -EIO; } req->numserv++; /* If we have more than one dot, we don't add domains */ dot = strchr(lookup, '.'); if (dot && dot != lookup + strlen(lookup) - 1) return 0; if (server->domains && server->domains->data) req->append_domain = true; for (list = server->domains; list; list = list->next) { char *domain; unsigned char alt[1024]; struct domain_hdr *hdr = (void *) &alt; int altlen, domlen, offset; domain = list->data; if (!domain) continue; offset = protocol_offset(server->protocol); if (offset < 0) return offset; domlen = strlen(domain) + 1; if (domlen < 5) return -EINVAL; alt[offset] = req->altid & 0xff; alt[offset + 1] = req->altid >> 8; memcpy(alt + offset + 2, request + offset + 2, 10); hdr->qdcount = htons(1); altlen = append_query(alt + offset + 12, sizeof(alt) - 12, name, domain); if (altlen < 0) return -EINVAL; altlen += 12; memcpy(alt + offset + altlen, request + offset + altlen - domlen, req->request_len - altlen - offset + domlen); if (server->protocol == IPPROTO_TCP) { int req_len = req->request_len + domlen - 2; alt[0] = (req_len >> 8) & 0xff; alt[1] = req_len & 0xff; } debug("req %p dstid 0x%04x altid 0x%04x", req, req->dstid, req->altid); err = send(sk, alt, req->request_len + domlen, MSG_NOSIGNAL); if (err < 0) return -EIO; req->numserv++; } return 0; } static char *convert_label(char *start, char *end, char *ptr, char *uptr, int remaining_len, int *used_comp, int *used_uncomp) { int pos, comp_pos; char name[NS_MAXLABEL]; pos = dn_expand((u_char *)start, (u_char *)end, (u_char *)ptr, name, NS_MAXLABEL); if (pos < 0) { debug("uncompress error [%d/%s]", errno, strerror(errno)); goto out; } /* * We need to compress back the name so that we get back to internal * label presentation. */ comp_pos = dn_comp(name, (u_char *)uptr, remaining_len, NULL, NULL); if (comp_pos < 0) { debug("compress error [%d/%s]", errno, strerror(errno)); goto out; } *used_comp = pos; *used_uncomp = comp_pos; return ptr; out: return NULL; } static char *uncompress(int16_t field_count, char *start, char *end, char *ptr, char *uncompressed, int uncomp_len, char **uncompressed_ptr) { char *uptr = *uncompressed_ptr; /* position in result buffer */ char * const uncomp_end = uncompressed + uncomp_len - 1; debug("count %d ptr %p end %p uptr %p", field_count, ptr, end, uptr); while (field_count-- > 0 && ptr < end) { int dlen; /* data field length */ int ulen; /* uncompress length */ int pos; /* position in compressed string */ char name[NS_MAXLABEL]; /* tmp label */ uint16_t dns_type, dns_class; int comp_pos; if (!convert_label(start, end, ptr, name, NS_MAXLABEL, &pos, &comp_pos)) goto out; /* * Copy the uncompressed resource record, type, class and \0 to * tmp buffer. */ ulen = strlen(name) + 1; if ((uptr + ulen) > uncomp_end) goto out; memcpy(uptr, name, ulen); debug("pos %d ulen %d left %d name %s", pos, ulen, (int)(uncomp_end - (uptr + ulen)), uptr); uptr += ulen; ptr += pos; /* * We copy also the fixed portion of the result (type, class, * ttl, address length and the address) */ if ((uptr + NS_RRFIXEDSZ) > uncomp_end) { debug("uncompressed data too large for buffer"); goto out; } memcpy(uptr, ptr, NS_RRFIXEDSZ); dns_type = uptr[0] << 8 | uptr[1]; dns_class = uptr[2] << 8 | uptr[3]; if (dns_class != ns_c_in) goto out; ptr += NS_RRFIXEDSZ; uptr += NS_RRFIXEDSZ; /* * Then the variable portion of the result (data length). * Typically this portion is also compressed * so we need to uncompress it also when necessary. */ if (dns_type == ns_t_cname) { if (!convert_label(start, end, ptr, uptr, uncomp_len - (uptr - uncompressed), &pos, &comp_pos)) goto out; uptr[-2] = comp_pos << 8; uptr[-1] = comp_pos & 0xff; uptr += comp_pos; ptr += pos; } else if (dns_type == ns_t_a || dns_type == ns_t_aaaa) { dlen = uptr[-2] << 8 | uptr[-1]; if ((ptr + dlen) > end || (uptr + dlen) > uncomp_end) { debug("data len %d too long", dlen); goto out; } memcpy(uptr, ptr, dlen); uptr += dlen; ptr += dlen; } else if (dns_type == ns_t_soa) { int total_len = 0; char *len_ptr; /* Primary name server expansion */ if (!convert_label(start, end, ptr, uptr, uncomp_len - (uptr - uncompressed), &pos, &comp_pos)) goto out; total_len += comp_pos; len_ptr = &uptr[-2]; ptr += pos; uptr += comp_pos; /* Responsible authority's mailbox */ if (!convert_label(start, end, ptr, uptr, uncomp_len - (uptr - uncompressed), &pos, &comp_pos)) goto out; total_len += comp_pos; ptr += pos; uptr += comp_pos; /* * Copy rest of the soa fields (serial number, * refresh interval, retry interval, expiration * limit and minimum ttl). They are 20 bytes long. */ if ((uptr + 20) > uncomp_end || (ptr + 20) > end) { debug("soa record too long"); goto out; } memcpy(uptr, ptr, 20); uptr += 20; ptr += 20; total_len += 20; /* * Finally fix the length of the data part */ len_ptr[0] = total_len << 8; len_ptr[1] = total_len & 0xff; } *uncompressed_ptr = uptr; } return ptr; out: return NULL; } static int strip_domains(char *name, char *answers, int maxlen) { uint16_t data_len; int name_len = strlen(name); char *ptr, *start = answers, *end = answers + maxlen; while (maxlen > 0) { ptr = strstr(answers, name); if (ptr) { char *domain = ptr + name_len; if (*domain) { int domain_len = strlen(domain); memmove(answers + name_len, domain + domain_len, end - (domain + domain_len)); end -= domain_len; maxlen -= domain_len; } } answers += strlen(answers) + 1; answers += 2 + 2 + 4; /* skip type, class and ttl fields */ data_len = answers[0] << 8 | answers[1]; answers += 2; /* skip the length field */ if (answers + data_len > end) return -EINVAL; answers += data_len; maxlen -= answers - ptr; } return end - start; } static int forward_dns_reply(unsigned char *reply, int reply_len, int protocol, struct server_data *data) { struct domain_hdr *hdr; struct request_data *req; int dns_id, sk, err, offset = protocol_offset(protocol); if (offset < 0) return offset; if (reply_len < 0) return -EINVAL; if (reply_len < offset + 1) return -EINVAL; if ((size_t)reply_len < sizeof(struct domain_hdr)) return -EINVAL; hdr = (void *)(reply + offset); dns_id = reply[offset] | reply[offset + 1] << 8; debug("Received %d bytes (id 0x%04x)", reply_len, dns_id); req = find_request(dns_id); if (!req) return -EINVAL; debug("req %p dstid 0x%04x altid 0x%04x rcode %d", req, req->dstid, req->altid, hdr->rcode); reply[offset] = req->srcid & 0xff; reply[offset + 1] = req->srcid >> 8; req->numresp++; if (hdr->rcode == ns_r_noerror || !req->resp) { unsigned char *new_reply = NULL; /* * If the domain name was append * remove it before forwarding the reply. * If there were more than one question, then this * domain name ripping can be hairy so avoid that * and bail out in that that case. * * The reason we are doing this magic is that if the * user's DNS client tries to resolv hostname without * domain part, it also expects to get the result without * a domain name part. */ if (req->append_domain && ntohs(hdr->qdcount) == 1) { uint16_t domain_len = 0; uint16_t header_len, payload_len; uint16_t dns_type, dns_class; uint8_t host_len, dns_type_pos; char uncompressed[NS_MAXDNAME], *uptr; char *ptr, *eom = (char *)reply + reply_len; char *domain; /* * ptr points to the first char of the hostname. * ->hostname.domain.net */ header_len = offset + sizeof(struct domain_hdr); if (reply_len < header_len) return -EINVAL; payload_len = reply_len - header_len; ptr = (char *)reply + header_len; host_len = *ptr; domain = ptr + 1 + host_len; if (domain > eom) return -EINVAL; if (host_len > 0) domain_len = strnlen(domain, eom - domain); /* * If the query type is anything other than A or AAAA, * then bail out and pass the message as is. * We only want to deal with IPv4 or IPv6 addresses. */ dns_type_pos = host_len + 1 + domain_len + 1; if (ptr + (dns_type_pos + 3) > eom) return -EINVAL; dns_type = ptr[dns_type_pos] << 8 | ptr[dns_type_pos + 1]; dns_class = ptr[dns_type_pos + 2] << 8 | ptr[dns_type_pos + 3]; if (dns_type != ns_t_a && dns_type != ns_t_aaaa && dns_class != ns_c_in) { debug("Pass msg dns type %d class %d", dns_type, dns_class); goto pass; } /* * Remove the domain name and replace it by the end * of reply. Check if the domain is really there * before trying to copy the data. We also need to * uncompress the answers if necessary. * The domain_len can be 0 because if the original * query did not contain a domain name, then we are * sending two packets, first without the domain name * and the second packet with domain name. * The append_domain is set to true even if we sent * the first packet without domain name. In this * case we end up in this branch. */ if (domain_len > 0) { int len = host_len + 1; int new_len, fixed_len; char *answers; if (len > payload_len) return -EINVAL; /* * First copy host (without domain name) into * tmp buffer. */ uptr = &uncompressed[0]; memcpy(uptr, ptr, len); uptr[len] = '\0'; /* host termination */ uptr += len + 1; /* * Copy type and class fields of the question. */ ptr += len + domain_len + 1; if (ptr + NS_QFIXEDSZ > eom) return -EINVAL; memcpy(uptr, ptr, NS_QFIXEDSZ); /* * ptr points to answers after this */ ptr += NS_QFIXEDSZ; uptr += NS_QFIXEDSZ; answers = uptr; fixed_len = answers - uncompressed; if (ptr + offset > eom) return -EINVAL; /* * We then uncompress the result to buffer * so that we can rip off the domain name * part from the question. First answers, * then name server (authority) information, * and finally additional record info. */ ptr = uncompress(ntohs(hdr->ancount), (char *)reply + offset, eom, ptr, uncompressed, NS_MAXDNAME, &uptr); if (!ptr) goto out; ptr = uncompress(ntohs(hdr->nscount), (char *)reply + offset, eom, ptr, uncompressed, NS_MAXDNAME, &uptr); if (!ptr) goto out; ptr = uncompress(ntohs(hdr->arcount), (char *)reply + offset, eom, ptr, uncompressed, NS_MAXDNAME, &uptr); if (!ptr) goto out; /* * The uncompressed buffer now contains almost * valid response. Final step is to get rid of * the domain name because at least glibc * gethostbyname() implementation does extra * checks and expects to find an answer without * domain name if we asked a query without * domain part. Note that glibc getaddrinfo() * works differently and accepts FQDN in answer */ new_len = strip_domains(uncompressed, answers, uptr - answers); if (new_len < 0) { debug("Corrupted packet"); return -EINVAL; } /* * Because we have now uncompressed the answers * we might have to create a bigger buffer to * hold all that data. */ reply_len = header_len + new_len + fixed_len; new_reply = g_try_malloc(reply_len); if (!new_reply) return -ENOMEM; memcpy(new_reply, reply, header_len); memcpy(new_reply + header_len, uncompressed, new_len + fixed_len); reply = new_reply; } } pass: g_free(req->resp); req->resplen = 0; req->resp = g_try_malloc(reply_len); #if defined TIZEN_EXT if (!req->resp) { g_free(new_reply); return -ENOMEM; } #else if (!req->resp) return -ENOMEM; #endif memcpy(req->resp, reply, reply_len); req->resplen = reply_len; cache_update(data, reply, reply_len); g_free(new_reply); } out: if (req->numresp < req->numserv) { if (hdr->rcode > ns_r_noerror) { return -EINVAL; } else if (hdr->ancount == 0 && req->append_domain) { return -EINVAL; } } request_list = g_slist_remove(request_list, req); if (protocol == IPPROTO_UDP) { sk = get_req_udp_socket(req); if (sk < 0) { errno = -EIO; err = -EIO; } else err = sendto(sk, req->resp, req->resplen, 0, &req->sa, req->sa_len); } else { uint16_t tcp_len = htons(req->resplen - 2); /* correct TCP message length */ memcpy(req->resp, &tcp_len, sizeof(tcp_len)); sk = req->client_sk; err = send(sk, req->resp, req->resplen, MSG_NOSIGNAL); } if (err < 0) debug("Cannot send msg, sk %d proto %d errno %d/%s", sk, protocol, errno, strerror(errno)); else debug("proto %d sent %d bytes to %d", protocol, err, sk); destroy_request_data(req); return err; } static void server_destroy_socket(struct server_data *data) { debug("index %d server %s proto %d", data->index, data->server, data->protocol); if (data->watch > 0) { g_source_remove(data->watch); data->watch = 0; } if (data->timeout > 0) { g_source_remove(data->timeout); data->timeout = 0; } if (data->channel) { g_io_channel_shutdown(data->channel, TRUE, NULL); g_io_channel_unref(data->channel); data->channel = NULL; } g_free(data->incoming_reply); data->incoming_reply = NULL; } static void destroy_server(struct server_data *server) { debug("index %d server %s sock %d", server->index, server->server, server->channel ? g_io_channel_unix_get_fd(server->channel): -1); server_list = g_slist_remove(server_list, server); server_destroy_socket(server); if (server->protocol == IPPROTO_UDP && server->enabled) debug("Removing DNS server %s", server->server); g_free(server->server); g_list_free_full(server->domains, g_free); g_free(server->server_addr); /* * We do not remove cache right away but delay it few seconds. * The idea is that when IPv6 DNS server is added via RDNSS, it has a * lifetime. When the lifetime expires we decrease the refcount so it * is possible that the cache is then removed. Because a new DNS server * is usually created almost immediately we would then loose the cache * without any good reason. The small delay allows the new RDNSS to * create a new DNS server instance and the refcount does not go to 0. */ if (cache && !cache_timer) cache_timer = g_timeout_add_seconds(3, try_remove_cache, NULL); g_free(server); } static gboolean udp_server_event(GIOChannel *channel, GIOCondition condition, gpointer user_data) { unsigned char buf[4096]; int sk, len; struct server_data *data = user_data; if (condition & (G_IO_NVAL | G_IO_ERR | G_IO_HUP)) { connman_error("Error with UDP server %s", data->server); server_destroy_socket(data); return FALSE; } sk = g_io_channel_unix_get_fd(channel); len = recv(sk, buf, sizeof(buf), 0); forward_dns_reply(buf, len, IPPROTO_UDP, data); #if defined TIZEN_EXT GSList *list; list = server_list_sec; while (list) { struct server_data *new_data = list->data; list = list->next; if (new_data == data) { destroy_server_sec(data); return TRUE; } } #endif return TRUE; } static gboolean tcp_server_event(GIOChannel *channel, GIOCondition condition, gpointer user_data) { int sk; struct server_data *server = user_data; sk = g_io_channel_unix_get_fd(channel); if (sk == 0) return FALSE; if (condition & (G_IO_NVAL | G_IO_ERR | G_IO_HUP)) { GSList *list; hangup: debug("TCP server channel closed, sk %d", sk); /* * Discard any partial response which is buffered; better * to get a proper response from a working server. */ g_free(server->incoming_reply); server->incoming_reply = NULL; list = request_list; while (list) { struct request_data *req = list->data; struct domain_hdr *hdr; list = list->next; if (req->protocol == IPPROTO_UDP) continue; if (!req->request) continue; /* * If we're not waiting for any further response * from another name server, then we send an error * response to the client. */ if (req->numserv && --(req->numserv)) continue; hdr = (void *) (req->request + 2); hdr->id = req->srcid; send_response(req->client_sk, req->request, req->request_len, NULL, 0, IPPROTO_TCP); request_list = g_slist_remove(request_list, req); } destroy_server(server); return FALSE; } if ((condition & G_IO_OUT) && !server->connected) { GSList *list; GList *domains; bool no_request_sent = true; struct server_data *udp_server; udp_server = find_server(server->index, server->server, IPPROTO_UDP); if (udp_server) { for (domains = udp_server->domains; domains; domains = domains->next) { char *dom = domains->data; debug("Adding domain %s to %s", dom, server->server); server->domains = g_list_append(server->domains, g_strdup(dom)); } } /* * Remove the G_IO_OUT flag from the watch, otherwise we end * up in a busy loop, because the socket is constantly writable. * * There seems to be no better way in g_io to do that than * re-adding the watch. */ g_source_remove(server->watch); server->watch = g_io_add_watch(server->channel, G_IO_IN | G_IO_HUP | G_IO_NVAL | G_IO_ERR, tcp_server_event, server); server->connected = true; server_list = g_slist_append(server_list, server); for (list = request_list; list; ) { struct request_data *req = list->data; int status; if (req->protocol == IPPROTO_UDP) { list = list->next; continue; } debug("Sending req %s over TCP", (char *)req->name); status = ns_resolv(server, req, req->request, req->name); if (status > 0) { /* * A cached result was sent, * so the request can be released */ list = list->next; request_list = g_slist_remove(request_list, req); destroy_request_data(req); continue; } if (status < 0) { list = list->next; continue; } no_request_sent = false; if (req->timeout > 0) g_source_remove(req->timeout); req->timeout = g_timeout_add_seconds(30, request_timeout, req); list = list->next; } if (no_request_sent) { destroy_server(server); return FALSE; } } else if (condition & G_IO_IN) { struct partial_reply *reply = server->incoming_reply; int bytes_recv; if (!reply) { unsigned char reply_len_buf[2]; uint16_t reply_len; bytes_recv = recv(sk, reply_len_buf, 2, MSG_PEEK); if (!bytes_recv) { goto hangup; } else if (bytes_recv < 0) { if (errno == EAGAIN || errno == EWOULDBLOCK) return TRUE; connman_error("DNS proxy error %s", strerror(errno)); goto hangup; } else if (bytes_recv < 2) return TRUE; reply_len = reply_len_buf[1] | reply_len_buf[0] << 8; reply_len += 2; debug("TCP reply %d bytes from %d", reply_len, sk); reply = g_try_malloc(sizeof(*reply) + reply_len + 2); if (!reply) return TRUE; reply->len = reply_len; reply->received = 0; server->incoming_reply = reply; } while (reply->received < reply->len) { bytes_recv = recv(sk, reply->buf + reply->received, reply->len - reply->received, 0); if (!bytes_recv) { connman_error("DNS proxy TCP disconnect"); break; } else if (bytes_recv < 0) { if (errno == EAGAIN || errno == EWOULDBLOCK) return TRUE; connman_error("DNS proxy error %s", strerror(errno)); break; } reply->received += bytes_recv; } forward_dns_reply(reply->buf, reply->received, IPPROTO_TCP, server); g_free(reply); server->incoming_reply = NULL; destroy_server(server); return FALSE; } return TRUE; } static gboolean tcp_idle_timeout(gpointer user_data) { struct server_data *server = user_data; debug(""); if (!server) return FALSE; destroy_server(server); return FALSE; } static int server_create_socket(struct server_data *data) { int sk, err; char *interface; debug("index %d server %s proto %d", data->index, data->server, data->protocol); sk = socket(data->server_addr->sa_family, data->protocol == IPPROTO_TCP ? SOCK_STREAM : SOCK_DGRAM, data->protocol); if (sk < 0) { err = errno; connman_error("Failed to create server %s socket", data->server); server_destroy_socket(data); return -err; } debug("sk %d", sk); interface = connman_inet_ifname(data->index); if (interface) { if (setsockopt(sk, SOL_SOCKET, SO_BINDTODEVICE, interface, strlen(interface) + 1) < 0) { err = errno; connman_error("Failed to bind server %s " "to interface %s", data->server, interface); close(sk); server_destroy_socket(data); g_free(interface); return -err; } g_free(interface); } data->channel = g_io_channel_unix_new(sk); if (!data->channel) { connman_error("Failed to create server %s channel", data->server); close(sk); server_destroy_socket(data); return -ENOMEM; } g_io_channel_set_close_on_unref(data->channel, TRUE); if (data->protocol == IPPROTO_TCP) { g_io_channel_set_flags(data->channel, G_IO_FLAG_NONBLOCK, NULL); data->watch = g_io_add_watch(data->channel, G_IO_OUT | G_IO_IN | G_IO_HUP | G_IO_NVAL | G_IO_ERR, tcp_server_event, data); data->timeout = g_timeout_add_seconds(30, tcp_idle_timeout, data); } else data->watch = g_io_add_watch(data->channel, G_IO_IN | G_IO_NVAL | G_IO_ERR | G_IO_HUP, udp_server_event, data); if (connect(sk, data->server_addr, data->server_addr_len) < 0) { err = errno; if ((data->protocol == IPPROTO_TCP && errno != EINPROGRESS) || data->protocol == IPPROTO_UDP) { connman_error("Failed to connect to server %s", data->server); server_destroy_socket(data); return -err; } } create_cache(); return 0; } static void enable_fallback(bool enable) { GSList *list; for (list = server_list; list; list = list->next) { struct server_data *data = list->data; if (data->index != -1) continue; if (enable) DBG("Enabling fallback DNS server %s", data->server); else DBG("Disabling fallback DNS server %s", data->server); data->enabled = enable; } } #if defined TIZEN_EXT static void destroy_server_sec(struct server_data *server) { GList *list; int fd; if (server == NULL) return; if (server->channel) fd = g_io_channel_unix_get_fd(server->channel); else fd = -1; DBG("index %d server %s sock %d", server->index, server->server, fd); server_list_sec = g_slist_remove(server_list_sec, server); if (fd > 0) close(fd); server_destroy_socket(server); if (server->protocol == IPPROTO_UDP && server->enabled) DBG("Removing DNS server %s", server->server); g_free(server->server); g_list_free_full(server->domains, g_free); g_free(server->server_addr); /* * We do not remove cache right away but delay it few seconds. * The idea is that when IPv6 DNS server is added via RDNSS, it has a * lifetime. When the lifetime expires we decrease the refcount so it * is possible that the cache is then removed. Because a new DNS server * is usually created almost immediately we would then loose the cache * without any good reason. The small delay allows the new RDNSS to * create a new DNS server instance and the refcount does not go to 0. */ /* TODO: Need to check this */ /* g_timeout_add_seconds(3, try_remove_cache, NULL); */ g_free(server); } static void destroy_all_server_sec() { GSList *list; DBG("remove all dns server"); list = server_list_sec; while (list) { struct server_data *server = list->data; list = list->next; destroy_server_sec(server); } server_list_sec = NULL; } static gboolean sec_udp_idle_timeout(gpointer user_data) { struct server_data *server = user_data; DBG(""); if (server == NULL) return FALSE; destroy_server_sec(server); return FALSE; } static struct server_data *create_server_sec(int index, const char *domain, const char *server, int protocol) { struct server_data *data; struct addrinfo hints, *rp; int ret; DBG("index %d server %s", index, server); data = g_try_new0(struct server_data, 1); if (data == NULL) { connman_error("Failed to allocate server %s data", server); return NULL; } data->index = index; if (domain) data->domains = g_list_append(data->domains, g_strdup(domain)); data->server = g_strdup(server); data->protocol = protocol; memset(&hints, 0, sizeof(hints)); switch (protocol) { case IPPROTO_UDP: hints.ai_socktype = SOCK_DGRAM; break; case IPPROTO_TCP: hints.ai_socktype = SOCK_STREAM; break; default: destroy_server_sec(data); return NULL; } hints.ai_family = AF_UNSPEC; hints.ai_flags = AI_NUMERICSERV | AI_NUMERICHOST; ret = getaddrinfo(data->server, "53", &hints, &rp); if (ret) { connman_error("Failed to parse server %s address: %s\n", data->server, gai_strerror(ret)); freeaddrinfo(rp); destroy_server_sec(data); return NULL; } /* Do not blindly copy this code elsewhere; it doesn't loop over the results using ->ai_next as it should. That's OK in *this* case because it was a numeric lookup; we *know* there's only one. */ data->server_addr_len = rp->ai_addrlen; switch (rp->ai_family) { case AF_INET: data->server_addr = (struct sockaddr *) g_try_new0(struct sockaddr_in, 1); break; case AF_INET6: data->server_addr = (struct sockaddr *) g_try_new0(struct sockaddr_in6, 1); break; default: connman_error("Wrong address family %d", rp->ai_family); break; } if (data->server_addr == NULL) { freeaddrinfo(rp); destroy_server_sec(data); return NULL; } memcpy(data->server_addr, rp->ai_addr, rp->ai_addrlen); freeaddrinfo(rp); if (server_create_socket(data) != 0) { destroy_server_sec(data); return NULL; } if (protocol == IPPROTO_UDP) { /* Enable new servers by default */ data->enabled = TRUE; DBG("Adding DNS server %s", data->server); data->timeout = g_timeout_add_seconds(30, sec_udp_idle_timeout, data); server_list_sec = g_slist_append(server_list_sec, data); } return data; } #endif static struct server_data *create_server(int index, const char *domain, const char *server, int protocol) { struct server_data *data; struct addrinfo hints, *rp; int ret; DBG("index %d server %s", index, server); data = g_try_new0(struct server_data, 1); if (!data) { connman_error("Failed to allocate server %s data", server); return NULL; } data->index = index; if (domain) data->domains = g_list_append(data->domains, g_strdup(domain)); data->server = g_strdup(server); data->protocol = protocol; memset(&hints, 0, sizeof(hints)); switch (protocol) { case IPPROTO_UDP: hints.ai_socktype = SOCK_DGRAM; break; case IPPROTO_TCP: hints.ai_socktype = SOCK_STREAM; break; default: destroy_server(data); return NULL; } hints.ai_family = AF_UNSPEC; hints.ai_flags = AI_NUMERICSERV | AI_NUMERICHOST; ret = getaddrinfo(data->server, "53", &hints, &rp); if (ret) { connman_error("Failed to parse server %s address: %s\n", data->server, gai_strerror(ret)); destroy_server(data); return NULL; } /* Do not blindly copy this code elsewhere; it doesn't loop over the results using ->ai_next as it should. That's OK in *this* case because it was a numeric lookup; we *know* there's only one. */ data->server_addr_len = rp->ai_addrlen; switch (rp->ai_family) { case AF_INET: data->server_addr = (struct sockaddr *) g_try_new0(struct sockaddr_in, 1); break; case AF_INET6: data->server_addr = (struct sockaddr *) g_try_new0(struct sockaddr_in6, 1); break; default: connman_error("Wrong address family %d", rp->ai_family); break; } if (!data->server_addr) { freeaddrinfo(rp); destroy_server(data); return NULL; } memcpy(data->server_addr, rp->ai_addr, rp->ai_addrlen); freeaddrinfo(rp); if (server_create_socket(data) != 0) { destroy_server(data); return NULL; } if (protocol == IPPROTO_UDP) { if (__connman_service_index_is_default(data->index) || __connman_service_index_is_split_routing( data->index)) { data->enabled = true; DBG("Adding DNS server %s", data->server); enable_fallback(false); } server_list = g_slist_append(server_list, data); } return data; } static bool resolv(struct request_data *req, gpointer request, gpointer name) { GSList *list; for (list = server_list; list; list = list->next) { struct server_data *data = list->data; if (data->protocol == IPPROTO_TCP) { DBG("server %s ignored proto TCP", data->server); continue; } debug("server %s enabled %d", data->server, data->enabled); if (!data->enabled) continue; if (!data->channel && data->protocol == IPPROTO_UDP) { if (server_create_socket(data) < 0) { DBG("socket creation failed while resolving"); continue; } } if (ns_resolv(data, req, request, name) > 0) return true; } return false; } static void update_domain(int index, const char *domain, bool append) { GSList *list; DBG("index %d domain %s", index, domain); if (!domain) return; for (list = server_list; list; list = list->next) { struct server_data *data = list->data; GList *dom_list; char *dom = NULL; bool dom_found = false; if (data->index < 0) continue; if (data->index != index) continue; for (dom_list = data->domains; dom_list; dom_list = dom_list->next) { dom = dom_list->data; if (g_str_equal(dom, domain)) { dom_found = true; break; } } if (!dom_found && append) { data->domains = g_list_append(data->domains, g_strdup(domain)); } else if (dom_found && !append) { data->domains = g_list_remove(data->domains, dom); g_free(dom); } } } static void append_domain(int index, const char *domain) { update_domain(index, domain, true); } static void remove_domain(int index, const char *domain) { update_domain(index, domain, false); } static void flush_requests(struct server_data *server) { GSList *list; list = request_list; while (list) { struct request_data *req = list->data; list = list->next; if (ns_resolv(server, req, req->request, req->name)) { /* * A cached result was sent, * so the request can be released */ request_list = g_slist_remove(request_list, req); destroy_request_data(req); continue; } if (req->timeout > 0) g_source_remove(req->timeout); req->timeout = g_timeout_add_seconds(5, request_timeout, req); } } int __connman_dnsproxy_append(int index, const char *domain, const char *server) { struct server_data *data; DBG("index %d server %s", index, server); if (!server && !domain) return -EINVAL; if (!server) { append_domain(index, domain); return 0; } if (g_str_equal(server, "127.0.0.1")) return -ENODEV; if (g_str_equal(server, "::1")) return -ENODEV; data = find_server(index, server, IPPROTO_UDP); if (data) { append_domain(index, domain); return 0; } data = create_server(index, domain, server, IPPROTO_UDP); if (!data) return -EIO; flush_requests(data); return 0; } static void remove_server(int index, const char *domain, const char *server, int protocol) { struct server_data *data; GSList *list; data = find_server(index, server, protocol); if (!data) return; destroy_server(data); for (list = server_list; list; list = list->next) { struct server_data *data = list->data; if (data->index != -1 && data->enabled == true) return; } enable_fallback(true); } int __connman_dnsproxy_remove(int index, const char *domain, const char *server) { DBG("index %d server %s", index, server); if (!server && !domain) return -EINVAL; if (!server) { remove_domain(index, domain); return 0; } if (g_str_equal(server, "127.0.0.1")) return -ENODEV; if (g_str_equal(server, "::1")) return -ENODEV; remove_server(index, domain, server, IPPROTO_UDP); remove_server(index, domain, server, IPPROTO_TCP); #if defined TIZEN_EXT destroy_all_server_sec(); #endif return 0; } static void dnsproxy_offline_mode(bool enabled) { GSList *list; DBG("enabled %d", enabled); for (list = server_list; list; list = list->next) { struct server_data *data = list->data; if (!enabled) { DBG("Enabling DNS server %s", data->server); data->enabled = true; cache_invalidate(); cache_refresh(); } else { DBG("Disabling DNS server %s", data->server); data->enabled = false; cache_invalidate(); } } } static void dnsproxy_default_changed(struct connman_service *service) { bool server_enabled = false; GSList *list; int index; int vpn_index; DBG("service %p", service); /* DNS has changed, invalidate the cache */ cache_invalidate(); if (!service) { /* When no services are active, then disable DNS proxying */ dnsproxy_offline_mode(true); return; } index = __connman_service_get_index(service); if (index < 0) return; /* * In case non-split-routed VPN is set as split routed the DNS servers * the VPN must be enabled as well, when the transport becomes the * default service. */ vpn_index = __connman_connection_get_vpn_index(index); for (list = server_list; list; list = list->next) { struct server_data *data = list->data; if (data->index == index) { DBG("Enabling DNS server %s", data->server); data->enabled = true; server_enabled = true; } else if (data->index == vpn_index) { DBG("Enabling DNS server of VPN %s", data->server); data->enabled = true; } else { DBG("Disabling DNS server %s", data->server); data->enabled = false; } } if (!server_enabled) enable_fallback(true); cache_refresh(); } static void dnsproxy_service_state_changed(struct connman_service *service, enum connman_service_state state) { GSList *list; int index; switch (state) { case CONNMAN_SERVICE_STATE_DISCONNECT: case CONNMAN_SERVICE_STATE_IDLE: break; case CONNMAN_SERVICE_STATE_ASSOCIATION: case CONNMAN_SERVICE_STATE_CONFIGURATION: case CONNMAN_SERVICE_STATE_FAILURE: case CONNMAN_SERVICE_STATE_ONLINE: case CONNMAN_SERVICE_STATE_READY: case CONNMAN_SERVICE_STATE_UNKNOWN: return; } index = __connman_service_get_index(service); list = server_list; while (list) { struct server_data *data = list->data; /* Get next before the list is changed by destroy_server() */ list = list->next; if (data->index == index) { DBG("removing server data of index %d", index); destroy_server(data); } } } static const struct connman_notifier dnsproxy_notifier = { .name = "dnsproxy", .default_changed = dnsproxy_default_changed, .offline_mode = dnsproxy_offline_mode, .service_state_changed = dnsproxy_service_state_changed, }; static const unsigned char opt_edns0_type[2] = { 0x00, 0x29 }; static int parse_request(unsigned char *buf, size_t len, char *name, unsigned int size) { struct domain_hdr *hdr = (void *) buf; uint16_t qdcount = ntohs(hdr->qdcount); uint16_t ancount = ntohs(hdr->ancount); uint16_t nscount = ntohs(hdr->nscount); uint16_t arcount = ntohs(hdr->arcount); unsigned char *ptr; unsigned int remain, used = 0; if (len < sizeof(*hdr) + sizeof(struct qtype_qclass) || hdr->qr || qdcount != 1 || ancount || nscount) { DBG("Dropped DNS request qr %d with len %zd qdcount %d " "ancount %d nscount %d", hdr->qr, len, qdcount, ancount, nscount); return -EINVAL; } if (!name || !size) return -EINVAL; debug("id 0x%04x qr %d opcode %d qdcount %d arcount %d", hdr->id, hdr->qr, hdr->opcode, qdcount, arcount); name[0] = '\0'; ptr = buf + sizeof(struct domain_hdr); remain = len - sizeof(struct domain_hdr); while (remain > 0) { uint8_t label_len = *ptr; if (label_len == 0x00) { uint8_t class; struct qtype_qclass *q = (struct qtype_qclass *)(ptr + 1); if (remain < sizeof(*q)) { DBG("Dropped malformed DNS query"); return -EINVAL; } class = ntohs(q->qclass); if (class != 1 && class != 255) { DBG("Dropped non-IN DNS class %d", class); return -EINVAL; } ptr += sizeof(*q) + 1; remain -= (sizeof(*q) + 1); break; } if (used + label_len + 1 > size) return -ENOBUFS; strncat(name, (char *) (ptr + 1), label_len); strcat(name, "."); used += label_len + 1; ptr += label_len + 1; remain -= label_len + 1; } if (arcount && remain >= sizeof(struct domain_rr) + 1 && !ptr[0] && ptr[1] == opt_edns0_type[0] && ptr[2] == opt_edns0_type[1]) { struct domain_rr *edns0 = (struct domain_rr *)(ptr + 1); DBG("EDNS0 buffer size %u", ntohs(edns0->class)); } else if (!arcount && remain) { DBG("DNS request with %d garbage bytes", remain); } debug("query %s", name); return 0; } static void client_reset(struct tcp_partial_client_data *client) { if (!client) return; if (client->channel) { debug("client %d closing", g_io_channel_unix_get_fd(client->channel)); g_io_channel_unref(client->channel); client->channel = NULL; } if (client->watch > 0) { g_source_remove(client->watch); client->watch = 0; } if (client->timeout > 0) { g_source_remove(client->timeout); client->timeout = 0; } g_free(client->buf); client->buf = NULL; client->buf_end = 0; } static unsigned int get_msg_len(unsigned char *buf) { return buf[0]<<8 | buf[1]; } static bool read_tcp_data(struct tcp_partial_client_data *client, void *client_addr, socklen_t client_addr_len, int read_len) { char query[TCP_MAX_BUF_LEN]; struct request_data *req; int client_sk, err; unsigned int msg_len; GSList *list; bool waiting_for_connect = false; int qtype = 0; struct cache_entry *entry; client_sk = g_io_channel_unix_get_fd(client->channel); if (read_len == 0) { debug("client %d closed, pending %d bytes", client_sk, client->buf_end); g_hash_table_remove(partial_tcp_req_table, GINT_TO_POINTER(client_sk)); return false; } debug("client %d received %d bytes", client_sk, read_len); client->buf_end += read_len; if (client->buf_end < 2) return true; msg_len = get_msg_len(client->buf); if (msg_len > TCP_MAX_BUF_LEN) { debug("client %d sent too much data %d", client_sk, msg_len); g_hash_table_remove(partial_tcp_req_table, GINT_TO_POINTER(client_sk)); return false; } read_another: debug("client %d msg len %d end %d past end %d", client_sk, msg_len, client->buf_end, client->buf_end - (msg_len + 2)); if (client->buf_end < (msg_len + 2)) { debug("client %d still missing %d bytes", client_sk, msg_len + 2 - client->buf_end); return true; } debug("client %d all data %d received", client_sk, msg_len); err = parse_request(client->buf + 2, msg_len, query, sizeof(query)); if (err < 0 || (g_slist_length(server_list) == 0)) { send_response(client_sk, client->buf, msg_len + 2, NULL, 0, IPPROTO_TCP); return true; } req = g_try_new0(struct request_data, 1); if (!req) return true; memcpy(&req->sa, client_addr, client_addr_len); req->sa_len = client_addr_len; req->client_sk = client_sk; req->protocol = IPPROTO_TCP; req->family = client->family; req->srcid = client->buf[2] | (client->buf[3] << 8); req->dstid = get_id(); req->altid = get_id(); req->request_len = msg_len + 2; client->buf[2] = req->dstid & 0xff; client->buf[3] = req->dstid >> 8; req->numserv = 0; req->ifdata = client->ifdata; req->append_domain = false; /* * Check if the answer is found in the cache before * creating sockets to the server. */ entry = cache_check(client->buf, &qtype, IPPROTO_TCP); if (entry) { int ttl_left = 0; struct cache_data *data; debug("cache hit %s type %s", query, qtype == 1 ? "A" : "AAAA"); if (qtype == 1) data = entry->ipv4; else data = entry->ipv6; if (data) { ttl_left = data->valid_until - time(NULL); entry->hits++; send_cached_response(client_sk, data->data, data->data_len, NULL, 0, IPPROTO_TCP, req->srcid, data->answers, ttl_left); g_free(req); goto out; } else debug("data missing, ignoring cache for this query"); } for (list = server_list; list; list = list->next) { struct server_data *data = list->data; if (data->protocol != IPPROTO_UDP || !data->enabled) continue; if (!create_server(data->index, NULL, data->server, IPPROTO_TCP)) continue; waiting_for_connect = true; } if (!waiting_for_connect) { /* No server is waiting for connect */ send_response(client_sk, client->buf, req->request_len, NULL, 0, IPPROTO_TCP); g_free(req); return true; } /* * The server is not connected yet. * Copy the relevant buffers. * The request will actually be sent once we're * properly connected over TCP to the nameserver. */ req->request = g_try_malloc0(req->request_len); if (!req->request) { send_response(client_sk, client->buf, req->request_len, NULL, 0, IPPROTO_TCP); g_free(req); goto out; } memcpy(req->request, client->buf, req->request_len); req->name = g_try_malloc0(sizeof(query)); if (!req->name) { send_response(client_sk, client->buf, req->request_len, NULL, 0, IPPROTO_TCP); g_free(req->request); g_free(req); goto out; } memcpy(req->name, query, sizeof(query)); req->timeout = g_timeout_add_seconds(30, request_timeout, req); request_list = g_slist_append(request_list, req); out: if (client->buf_end > (msg_len + 2)) { debug("client %d buf %p -> %p end %d len %d new %d", client_sk, client->buf + msg_len + 2, client->buf, client->buf_end, TCP_MAX_BUF_LEN - client->buf_end, client->buf_end - (msg_len + 2)); memmove(client->buf, client->buf + msg_len + 2, TCP_MAX_BUF_LEN - client->buf_end); client->buf_end = client->buf_end - (msg_len + 2); /* * If we have a full message waiting, just read it * immediately. */ msg_len = get_msg_len(client->buf); if ((msg_len + 2) == client->buf_end) { debug("client %d reading another %d bytes", client_sk, msg_len + 2); goto read_another; } } else { debug("client %d clearing reading buffer", client_sk); client->buf_end = 0; memset(client->buf, 0, TCP_MAX_BUF_LEN); /* * We received all the packets from client so we must also * remove the timeout handler here otherwise we might get * timeout while waiting the results from server. */ g_source_remove(client->timeout); client->timeout = 0; } return true; } static gboolean tcp_client_event(GIOChannel *channel, GIOCondition condition, gpointer user_data) { struct tcp_partial_client_data *client = user_data; struct sockaddr_in6 client_addr6; socklen_t client_addr6_len = sizeof(client_addr6); struct sockaddr_in client_addr4; socklen_t client_addr4_len = sizeof(client_addr4); void *client_addr; socklen_t *client_addr_len; int len, client_sk; client_sk = g_io_channel_unix_get_fd(channel); if (condition & (G_IO_NVAL | G_IO_ERR | G_IO_HUP)) { g_hash_table_remove(partial_tcp_req_table, GINT_TO_POINTER(client_sk)); connman_error("Error with TCP client %d channel", client_sk); return FALSE; } switch (client->family) { case AF_INET: client_addr = &client_addr4; client_addr_len = &client_addr4_len; break; case AF_INET6: client_addr = &client_addr6; client_addr_len = &client_addr6_len; break; default: g_hash_table_remove(partial_tcp_req_table, GINT_TO_POINTER(client_sk)); connman_error("client %p corrupted", client); return FALSE; } len = recvfrom(client_sk, client->buf + client->buf_end, TCP_MAX_BUF_LEN - client->buf_end, 0, client_addr, client_addr_len); if (len < 0) { if (errno == EAGAIN || errno == EWOULDBLOCK) return TRUE; debug("client %d cannot read errno %d/%s", client_sk, -errno, strerror(errno)); g_hash_table_remove(partial_tcp_req_table, GINT_TO_POINTER(client_sk)); return FALSE; } return read_tcp_data(client, client_addr, *client_addr_len, len); } static gboolean client_timeout(gpointer user_data) { struct tcp_partial_client_data *client = user_data; int sock; sock = g_io_channel_unix_get_fd(client->channel); debug("client %d timeout pending %d bytes", sock, client->buf_end); g_hash_table_remove(partial_tcp_req_table, GINT_TO_POINTER(sock)); return FALSE; } #if defined TIZEN_EXT static void recover_listener(GIOChannel *channel, struct listener_data *ifdata) { int sk, index; index = ifdata->index; sk = g_io_channel_unix_get_fd(channel); close(sk); __connman_dnsproxy_remove_listener(index); if (__connman_dnsproxy_add_listener(index) == 0) DBG("listener %d successfully recovered", index); } #endif static bool tcp_listener_event(GIOChannel *channel, GIOCondition condition, struct listener_data *ifdata, int family, guint *listener_watch) { int sk, client_sk, len; unsigned int msg_len; struct tcp_partial_client_data *client; struct sockaddr_in6 client_addr6; socklen_t client_addr6_len = sizeof(client_addr6); struct sockaddr_in client_addr4; socklen_t client_addr4_len = sizeof(client_addr4); void *client_addr; socklen_t *client_addr_len; struct timeval tv; fd_set readfds; debug("condition 0x%02x channel %p ifdata %p family %d", condition, channel, ifdata, family); if (condition & (G_IO_NVAL | G_IO_ERR | G_IO_HUP)) { #if defined TIZEN_EXT connman_error("Error %d with TCP listener channel", condition); recover_listener(channel, ifdata); #else if (*listener_watch > 0) g_source_remove(*listener_watch); *listener_watch = 0; connman_error("Error with TCP listener channel"); #endif return false; } sk = g_io_channel_unix_get_fd(channel); if (family == AF_INET) { client_addr = &client_addr4; client_addr_len = &client_addr4_len; } else { client_addr = &client_addr6; client_addr_len = &client_addr6_len; } tv.tv_sec = tv.tv_usec = 0; FD_ZERO(&readfds); FD_SET(sk, &readfds); select(sk + 1, &readfds, NULL, NULL, &tv); if (FD_ISSET(sk, &readfds)) { client_sk = accept(sk, client_addr, client_addr_len); debug("client %d accepted", client_sk); } else { debug("No data to read from master %d, waiting.", sk); return true; } if (client_sk < 0) { connman_error("Accept failure on TCP listener"); *listener_watch = 0; return false; } fcntl(client_sk, F_SETFL, O_NONBLOCK); client = g_hash_table_lookup(partial_tcp_req_table, GINT_TO_POINTER(client_sk)); if (!client) { client = g_try_new0(struct tcp_partial_client_data, 1); if (!client) { close(client_sk); return false; } g_hash_table_insert(partial_tcp_req_table, GINT_TO_POINTER(client_sk), client); client->channel = g_io_channel_unix_new(client_sk); g_io_channel_set_close_on_unref(client->channel, TRUE); client->watch = g_io_add_watch(client->channel, G_IO_IN, tcp_client_event, (gpointer)client); client->ifdata = ifdata; debug("client %d created %p", client_sk, client); } else { debug("client %d already exists %p", client_sk, client); } if (!client->buf) { client->buf = g_try_malloc(TCP_MAX_BUF_LEN); if (!client->buf) return false; } memset(client->buf, 0, TCP_MAX_BUF_LEN); client->buf_end = 0; client->family = family; if (client->timeout == 0) client->timeout = g_timeout_add_seconds(2, client_timeout, client); /* * Check how much data there is. If all is there, then we can * proceed normally, otherwise read the bits until everything * is received or timeout occurs. */ len = recv(client_sk, client->buf, TCP_MAX_BUF_LEN, 0); if (len < 0) { if (errno == EAGAIN || errno == EWOULDBLOCK) { debug("client %d no data to read, waiting", client_sk); return true; } debug("client %d cannot read errno %d/%s", client_sk, -errno, strerror(errno)); g_hash_table_remove(partial_tcp_req_table, GINT_TO_POINTER(client_sk)); return true; } if (len < 2) { debug("client %d not enough data to read, waiting", client_sk); client->buf_end += len; return true; } msg_len = get_msg_len(client->buf); if (msg_len > TCP_MAX_BUF_LEN) { debug("client %d invalid message length %u ignoring packet", client_sk, msg_len); g_hash_table_remove(partial_tcp_req_table, GINT_TO_POINTER(client_sk)); return true; } /* * The packet length bytes do not contain the total message length, * that is the reason to -2 below. */ #if defined TIZEN_EXT if (msg_len > (unsigned int)(len - 2)) { #else if (msg_len != (unsigned int)(len - 2)) { #endif debug("client %d sent %d bytes but expecting %u pending %d", client_sk, len, msg_len + 2, msg_len + 2 - len); client->buf_end += len; return true; } return read_tcp_data(client, client_addr, *client_addr_len, len); } static gboolean tcp4_listener_event(GIOChannel *channel, GIOCondition condition, gpointer user_data) { struct listener_data *ifdata = user_data; return tcp_listener_event(channel, condition, ifdata, AF_INET, &ifdata->tcp4_listener_watch); } static gboolean tcp6_listener_event(GIOChannel *channel, GIOCondition condition, gpointer user_data) { struct listener_data *ifdata = user_data; return tcp_listener_event(channel, condition, user_data, AF_INET6, &ifdata->tcp6_listener_watch); } #if defined TIZEN_EXT struct request_data * create_request(int sk, unsigned char *buf, size_t len, const struct sockaddr *to, socklen_t tolen, int protocol) { struct request_data *req; req = g_try_new0(struct request_data, 1); if (!req) return NULL; memcpy(&req->sa, to, tolen); req->sa_len = tolen; req->client_sk = sk; req->protocol = protocol; req->request_len = len; req->request = g_malloc(len); memcpy(req->request, buf, len); return req; } static gboolean send_response_timeout (gpointer user_data) { struct request_data *req = user_data; send_response(req->client_sk, req->request,(size_t) req->request_len, (const struct sockaddr *)&req->sa, (socklen_t)req->sa_len, req->protocol); g_free(req->request); g_free(req); return FALSE; } #endif static bool udp_listener_event(GIOChannel *channel, GIOCondition condition, struct listener_data *ifdata, int family, guint *listener_watch) { unsigned char buf[768]; char query[512]; struct request_data *req; struct sockaddr_in6 client_addr6; socklen_t client_addr6_len = sizeof(client_addr6); struct sockaddr_in client_addr4; socklen_t client_addr4_len = sizeof(client_addr4); void *client_addr; socklen_t *client_addr_len; int sk, err, len; if (condition & (G_IO_NVAL | G_IO_ERR | G_IO_HUP)) { #if defined TIZEN_EXT connman_error("Error %d with UDP listener channel", condition); recover_listener(channel, ifdata); #else connman_error("Error with UDP listener channel"); *listener_watch = 0; #endif return false; } sk = g_io_channel_unix_get_fd(channel); if (family == AF_INET) { client_addr = &client_addr4; client_addr_len = &client_addr4_len; } else { client_addr = &client_addr6; client_addr_len = &client_addr6_len; } memset(client_addr, 0, *client_addr_len); len = recvfrom(sk, buf, sizeof(buf), 0, client_addr, client_addr_len); if (len < 2) return true; debug("Received %d bytes (id 0x%04x)", len, buf[0] | buf[1] << 8); err = parse_request(buf, len, query, sizeof(query)); if (err < 0 || (g_slist_length(server_list) == 0)) { #if defined TIZEN_EXT /** TEMP Fix * Reason: In tizen6.0 same code working fine because it seems some delay in 6.0 platform * where as in tizen6.5 this loop is continuously executing due to this unable to receive * the response from telephony deamon and wpa_supplicant. To stop continuously execution * of this code added 10ms delay. */ req = create_request(sk, buf, len, client_addr, *client_addr_len, IPPROTO_UDP); if(!req) return true;; g_timeout_add(10, send_response_timeout, req); #else send_response(sk, buf, len, client_addr, *client_addr_len, IPPROTO_UDP); #endif return true; } req = g_try_new0(struct request_data, 1); if (!req) return true; memcpy(&req->sa, client_addr, *client_addr_len); req->sa_len = *client_addr_len; req->client_sk = 0; req->protocol = IPPROTO_UDP; req->family = family; req->srcid = buf[0] | (buf[1] << 8); req->dstid = get_id(); req->altid = get_id(); req->request_len = len; buf[0] = req->dstid & 0xff; buf[1] = req->dstid >> 8; req->numserv = 0; req->ifdata = ifdata; req->append_domain = false; if (resolv(req, buf, query)) { /* a cached result was sent, so the request can be released */ g_free(req); return true; } req->name = g_strdup(query); req->request = g_malloc(len); memcpy(req->request, buf, len); #if defined TIZEN_EXT DBG("req %p dstid 0x%04x altid 0x%04x", req, req->dstid, req->altid); req->timeout = g_timeout_add_seconds(30, request_timeout, req); #else req->timeout = g_timeout_add_seconds(5, request_timeout, req); #endif request_list = g_slist_append(request_list, req); return true; } static gboolean udp4_listener_event(GIOChannel *channel, GIOCondition condition, gpointer user_data) { struct listener_data *ifdata = user_data; return udp_listener_event(channel, condition, ifdata, AF_INET, &ifdata->udp4_listener_watch); } static gboolean udp6_listener_event(GIOChannel *channel, GIOCondition condition, gpointer user_data) { struct listener_data *ifdata = user_data; return udp_listener_event(channel, condition, user_data, AF_INET6, &ifdata->udp6_listener_watch); } static GIOChannel *get_listener(int family, int protocol, int index) { GIOChannel *channel; const char *proto; #if !defined TIZEN_EXT union { struct sockaddr sa; struct sockaddr_in6 sin6; struct sockaddr_in sin; } s; socklen_t slen; #endif int sk, type; #if !defined TIZEN_EXT char *interface; #endif #if defined TIZEN_EXT int option; int sd_num = 0; int rv; int is_socket_inet = 0; #endif debug("family %d protocol %d index %d", family, protocol, index); switch (protocol) { case IPPROTO_UDP: proto = "UDP"; type = SOCK_DGRAM | SOCK_CLOEXEC; break; case IPPROTO_TCP: proto = "TCP"; type = SOCK_STREAM | SOCK_CLOEXEC; break; default: return NULL; } #if defined TIZEN_EXT sd_num = sd_listen_fds(0); DBG("socket type(%s) systemd number of fds(%d)", proto, sd_num); if(sd_num < 1){ DBG("fail to get the fd from systemd"); return NULL; } if(protocol == IPPROTO_TCP) type = SOCK_STREAM; else type = SOCK_DGRAM; for(sk = SD_LISTEN_FDS_START; sk < SD_LISTEN_FDS_START+sd_num; ++sk){ rv = sd_is_socket_inet(sk, family, type, -1, 53); if(rv > 0){ DBG("socket fd (%d) is passed by systemd", sk); is_socket_inet = 1; break; } } if (!is_socket_inet) { DBG("socket fd is not matched what connman requests"); return NULL; } #else sk = socket(family, type, protocol); if (sk < 0 && family == AF_INET6 && errno == EAFNOSUPPORT) { connman_error("No IPv6 support"); return NULL; } if (sk < 0) { connman_error("Failed to create %s listener socket", proto); return NULL; } interface = connman_inet_ifname(index); if (!interface || setsockopt(sk, SOL_SOCKET, SO_BINDTODEVICE, interface, strlen(interface) + 1) < 0) { connman_error("Failed to bind %s listener interface " "for %s (%d/%s)", proto, family == AF_INET ? "IPv4" : "IPv6", -errno, strerror(errno)); close(sk); g_free(interface); return NULL; } g_free(interface); if (family == AF_INET6) { memset(&s.sin6, 0, sizeof(s.sin6)); s.sin6.sin6_family = AF_INET6; s.sin6.sin6_port = htons(53); slen = sizeof(s.sin6); if (__connman_inet_get_interface_address(index, AF_INET6, &s.sin6.sin6_addr) < 0) { /* So we could not find suitable IPv6 address for * the interface. This could happen if we have * disabled IPv6 for the interface. */ close(sk); return NULL; } } else if (family == AF_INET) { memset(&s.sin, 0, sizeof(s.sin)); s.sin.sin_family = AF_INET; s.sin.sin_port = htons(53); slen = sizeof(s.sin); if (__connman_inet_get_interface_address(index, AF_INET, &s.sin.sin_addr) < 0) { close(sk); return NULL; } } else { close(sk); return NULL; } #endif #if defined TIZEN_EXT /* When ConnMan crashed, * probably DNS listener cannot bind existing address */ option = 1; if (setsockopt(sk, SOL_SOCKET, SO_REUSEADDR, &option, sizeof(option)) < 0) { connman_error("Failed to set socket option SO_REUSEADDR"); close(sk); return NULL; } #endif #if !defined TIZEN_EXT if (bind(sk, &s.sa, slen) < 0) { connman_error("Failed to bind %s listener socket", proto); close(sk); return NULL; } #endif if (protocol == IPPROTO_TCP) { #if !defined TIZEN_EXT if (listen(sk, 10) < 0) { connman_error("Failed to listen on TCP socket %d/%s", -errno, strerror(errno)); close(sk); return NULL; } #endif fcntl(sk, F_SETFL, O_NONBLOCK); } channel = g_io_channel_unix_new(sk); if (!channel) { connman_error("Failed to create %s listener channel", proto); close(sk); return NULL; } g_io_channel_set_close_on_unref(channel, TRUE); return channel; } #define UDP_IPv4_FAILED 0x01 #define TCP_IPv4_FAILED 0x02 #define UDP_IPv6_FAILED 0x04 #define TCP_IPv6_FAILED 0x08 #define UDP_FAILED (UDP_IPv4_FAILED | UDP_IPv6_FAILED) #define TCP_FAILED (TCP_IPv4_FAILED | TCP_IPv6_FAILED) #define IPv6_FAILED (UDP_IPv6_FAILED | TCP_IPv6_FAILED) #define IPv4_FAILED (UDP_IPv4_FAILED | TCP_IPv4_FAILED) static int create_dns_listener(int protocol, struct listener_data *ifdata) { int ret = 0; if (protocol == IPPROTO_TCP) { ifdata->tcp4_listener_channel = get_listener(AF_INET, protocol, ifdata->index); if (ifdata->tcp4_listener_channel) #if defined TIZEN_EXT ifdata->tcp4_listener_watch = g_io_add_watch(ifdata->tcp4_listener_channel, G_IO_IN | G_IO_ERR | G_IO_HUP | G_IO_NVAL, tcp4_listener_event, (gpointer)ifdata); #else ifdata->tcp4_listener_watch = g_io_add_watch(ifdata->tcp4_listener_channel, G_IO_IN, tcp4_listener_event, (gpointer)ifdata); #endif else ret |= TCP_IPv4_FAILED; ifdata->tcp6_listener_channel = get_listener(AF_INET6, protocol, ifdata->index); if (ifdata->tcp6_listener_channel) #if defined TIZEN_EXT ifdata->tcp6_listener_watch = g_io_add_watch(ifdata->tcp6_listener_channel, G_IO_IN | G_IO_ERR | G_IO_HUP | G_IO_NVAL, tcp6_listener_event, (gpointer)ifdata); #else ifdata->tcp6_listener_watch = g_io_add_watch(ifdata->tcp6_listener_channel, G_IO_IN, tcp6_listener_event, (gpointer)ifdata); #endif else ret |= TCP_IPv6_FAILED; } else { ifdata->udp4_listener_channel = get_listener(AF_INET, protocol, ifdata->index); if (ifdata->udp4_listener_channel) #if defined TIZEN_EXT ifdata->udp4_listener_watch = g_io_add_watch(ifdata->udp4_listener_channel, G_IO_IN | G_IO_ERR | G_IO_HUP | G_IO_NVAL, udp4_listener_event, (gpointer)ifdata); #else ifdata->udp4_listener_watch = g_io_add_watch(ifdata->udp4_listener_channel, G_IO_IN, udp4_listener_event, (gpointer)ifdata); #endif else ret |= UDP_IPv4_FAILED; ifdata->udp6_listener_channel = get_listener(AF_INET6, protocol, ifdata->index); if (ifdata->udp6_listener_channel) #if defined TIZEN_EXT ifdata->udp6_listener_watch = g_io_add_watch(ifdata->udp6_listener_channel, G_IO_IN | G_IO_ERR | G_IO_HUP | G_IO_NVAL, udp6_listener_event, (gpointer)ifdata); #else ifdata->udp6_listener_watch = g_io_add_watch(ifdata->udp6_listener_channel, G_IO_IN, udp6_listener_event, (gpointer)ifdata); #endif else ret |= UDP_IPv6_FAILED; } return ret; } static void destroy_udp_listener(struct listener_data *ifdata) { DBG("index %d", ifdata->index); if (ifdata->udp4_listener_watch > 0) g_source_remove(ifdata->udp4_listener_watch); if (ifdata->udp6_listener_watch > 0) g_source_remove(ifdata->udp6_listener_watch); if (ifdata->udp4_listener_channel) g_io_channel_unref(ifdata->udp4_listener_channel); if (ifdata->udp6_listener_channel) g_io_channel_unref(ifdata->udp6_listener_channel); } static void destroy_tcp_listener(struct listener_data *ifdata) { DBG("index %d", ifdata->index); if (ifdata->tcp4_listener_watch > 0) g_source_remove(ifdata->tcp4_listener_watch); if (ifdata->tcp6_listener_watch > 0) g_source_remove(ifdata->tcp6_listener_watch); if (ifdata->tcp4_listener_channel) g_io_channel_unref(ifdata->tcp4_listener_channel); if (ifdata->tcp6_listener_channel) g_io_channel_unref(ifdata->tcp6_listener_channel); } static int create_listener(struct listener_data *ifdata) { int err, index; err = create_dns_listener(IPPROTO_UDP, ifdata); if ((err & UDP_FAILED) == UDP_FAILED) return -EIO; err |= create_dns_listener(IPPROTO_TCP, ifdata); if ((err & TCP_FAILED) == TCP_FAILED) { destroy_udp_listener(ifdata); return -EIO; } index = connman_inet_ifindex("lo"); if (ifdata->index == index) { if ((err & IPv6_FAILED) != IPv6_FAILED) __connman_resolvfile_append(index, NULL, "::1"); if ((err & IPv4_FAILED) != IPv4_FAILED) __connman_resolvfile_append(index, NULL, "127.0.0.1"); } return 0; } static void destroy_listener(struct listener_data *ifdata) { int index; GSList *list; index = connman_inet_ifindex("lo"); if (ifdata->index == index) { __connman_resolvfile_remove(index, NULL, "127.0.0.1"); __connman_resolvfile_remove(index, NULL, "::1"); } for (list = request_list; list; list = list->next) { struct request_data *req = list->data; debug("Dropping request (id 0x%04x -> 0x%04x)", req->srcid, req->dstid); destroy_request_data(req); list->data = NULL; } g_slist_free(request_list); request_list = NULL; destroy_tcp_listener(ifdata); destroy_udp_listener(ifdata); } int __connman_dnsproxy_add_listener(int index) { struct listener_data *ifdata; int err; DBG("index %d", index); if (index < 0) return -EINVAL; if (!listener_table) return -ENOENT; if (g_hash_table_lookup(listener_table, GINT_TO_POINTER(index))) return 0; ifdata = g_try_new0(struct listener_data, 1); if (!ifdata) return -ENOMEM; ifdata->index = index; ifdata->udp4_listener_channel = NULL; ifdata->udp4_listener_watch = 0; ifdata->tcp4_listener_channel = NULL; ifdata->tcp4_listener_watch = 0; ifdata->udp6_listener_channel = NULL; ifdata->udp6_listener_watch = 0; ifdata->tcp6_listener_channel = NULL; ifdata->tcp6_listener_watch = 0; err = create_listener(ifdata); if (err < 0) { connman_error("Couldn't create listener for index %d err %d", index, err); g_free(ifdata); return err; } g_hash_table_insert(listener_table, GINT_TO_POINTER(ifdata->index), ifdata); return 0; } void __connman_dnsproxy_remove_listener(int index) { struct listener_data *ifdata; DBG("index %d", index); if (!listener_table) return; ifdata = g_hash_table_lookup(listener_table, GINT_TO_POINTER(index)); if (!ifdata) return; destroy_listener(ifdata); g_hash_table_remove(listener_table, GINT_TO_POINTER(index)); } static void remove_listener(gpointer key, gpointer value, gpointer user_data) { int index = GPOINTER_TO_INT(key); struct listener_data *ifdata = value; DBG("index %d", index); destroy_listener(ifdata); } static void free_partial_reqs(gpointer value) { struct tcp_partial_client_data *data = value; client_reset(data); g_free(data); } int __connman_dnsproxy_init(void) { int err, index; DBG(""); listener_table = g_hash_table_new_full(g_direct_hash, g_direct_equal, NULL, g_free); partial_tcp_req_table = g_hash_table_new_full(g_direct_hash, g_direct_equal, NULL, free_partial_reqs); index = connman_inet_ifindex("lo"); err = __connman_dnsproxy_add_listener(index); if (err < 0) return err; err = connman_notifier_register(&dnsproxy_notifier); if (err < 0) goto destroy; return 0; destroy: __connman_dnsproxy_remove_listener(index); g_hash_table_destroy(listener_table); g_hash_table_destroy(partial_tcp_req_table); return err; } int __connman_dnsproxy_set_mdns(int index, bool enabled) { return -ENOTSUP; } void __connman_dnsproxy_cleanup(void) { DBG(""); if (cache_timer) { g_source_remove(cache_timer); cache_timer = 0; } if (cache) { g_hash_table_destroy(cache); cache = NULL; } connman_notifier_unregister(&dnsproxy_notifier); g_hash_table_foreach(listener_table, remove_listener, NULL); g_hash_table_destroy(listener_table); g_hash_table_destroy(partial_tcp_req_table); if (ipv4_resolve) g_resolv_unref(ipv4_resolve); if (ipv6_resolve) g_resolv_unref(ipv6_resolve); }