nodelist.c 78 KB

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  1. /* Copyright (c) 2001 Matej Pfajfar.
  2. * Copyright (c) 2001-2004, Roger Dingledine.
  3. * Copyright (c) 2004-2006, Roger Dingledine, Nick Mathewson.
  4. * Copyright (c) 2007-2017, The Tor Project, Inc. */
  5. /* See LICENSE for licensing information */
  6. /**
  7. * \file nodelist.c
  8. *
  9. * \brief Structures and functions for tracking what we know about the routers
  10. * on the Tor network, and correlating information from networkstatus,
  11. * routerinfo, and microdescs.
  12. *
  13. * The key structure here is node_t: that's the canonical way to refer
  14. * to a Tor relay that we might want to build a circuit through. Every
  15. * node_t has either a routerinfo_t, or a routerstatus_t from the current
  16. * networkstatus consensus. If it has a routerstatus_t, it will also
  17. * need to have a microdesc_t before you can use it for circuits.
  18. *
  19. * The nodelist_t is a global singleton that maps identities to node_t
  20. * objects. Access them with the node_get_*() functions. The nodelist_t
  21. * is maintained by calls throughout the codebase
  22. *
  23. * Generally, other code should not have to reach inside a node_t to
  24. * see what information it has. Instead, you should call one of the
  25. * many accessor functions that works on a generic node_t. If there
  26. * isn't one that does what you need, it's better to make such a function,
  27. * and then use it.
  28. *
  29. * For historical reasons, some of the functions that select a node_t
  30. * from the list of all usable node_t objects are in the routerlist.c
  31. * module, since they originally selected a routerinfo_t. (TODO: They
  32. * should move!)
  33. *
  34. * (TODO: Perhaps someday we should abstract the remaining ways of
  35. * talking about a relay to also be node_t instances. Those would be
  36. * routerstatus_t as used for directory requests, and dir_server_t as
  37. * used for authorities and fallback directories.)
  38. */
  39. #define NODELIST_PRIVATE
  40. #include "or.h"
  41. #include "address.h"
  42. #include "address_set.h"
  43. #include "bridges.h"
  44. #include "config.h"
  45. #include "control.h"
  46. #include "dirserv.h"
  47. #include "entrynodes.h"
  48. #include "geoip.h"
  49. #include "hs_common.h"
  50. #include "hs_client.h"
  51. #include "main.h"
  52. #include "microdesc.h"
  53. #include "networkstatus.h"
  54. #include "nodelist.h"
  55. #include "policies.h"
  56. #include "protover.h"
  57. #include "rendservice.h"
  58. #include "router.h"
  59. #include "routerlist.h"
  60. #include "routerparse.h"
  61. #include "routerset.h"
  62. #include "torcert.h"
  63. #include <string.h>
  64. static void nodelist_drop_node(node_t *node, int remove_from_ht);
  65. #define node_free(val) \
  66. FREE_AND_NULL(node_t, node_free_, (val))
  67. static void node_free_(node_t *node);
  68. /** count_usable_descriptors counts descriptors with these flag(s)
  69. */
  70. typedef enum {
  71. /* All descriptors regardless of flags */
  72. USABLE_DESCRIPTOR_ALL = 0,
  73. /* Only descriptors with the Exit flag */
  74. USABLE_DESCRIPTOR_EXIT_ONLY = 1
  75. } usable_descriptor_t;
  76. static void count_usable_descriptors(int *num_present,
  77. int *num_usable,
  78. smartlist_t *descs_out,
  79. const networkstatus_t *consensus,
  80. time_t now,
  81. routerset_t *in_set,
  82. usable_descriptor_t exit_only);
  83. static void update_router_have_minimum_dir_info(void);
  84. static double get_frac_paths_needed_for_circs(const or_options_t *options,
  85. const networkstatus_t *ns);
  86. static void node_add_to_address_set(const node_t *node);
  87. /** A nodelist_t holds a node_t object for every router we're "willing to use
  88. * for something". Specifically, it should hold a node_t for every node that
  89. * is currently in the routerlist, or currently in the consensus we're using.
  90. */
  91. typedef struct nodelist_t {
  92. /* A list of all the nodes. */
  93. smartlist_t *nodes;
  94. /* Hash table to map from node ID digest to node. */
  95. HT_HEAD(nodelist_map, node_t) nodes_by_id;
  96. /* Hash table to map from node Ed25519 ID to node.
  97. *
  98. * Whenever a node's routerinfo or microdescriptor is about to change,
  99. * you should remove it from this map with node_remove_from_ed25519_map().
  100. * Whenever a node's routerinfo or microdescriptor has just chaned,
  101. * you should add it to this map with node_add_to_ed25519_map().
  102. */
  103. HT_HEAD(nodelist_ed_map, node_t) nodes_by_ed_id;
  104. /* Set of addresses that belong to nodes we believe in. */
  105. address_set_t *node_addrs;
  106. } nodelist_t;
  107. static inline unsigned int
  108. node_id_hash(const node_t *node)
  109. {
  110. return (unsigned) siphash24g(node->identity, DIGEST_LEN);
  111. }
  112. static inline unsigned int
  113. node_id_eq(const node_t *node1, const node_t *node2)
  114. {
  115. return tor_memeq(node1->identity, node2->identity, DIGEST_LEN);
  116. }
  117. HT_PROTOTYPE(nodelist_map, node_t, ht_ent, node_id_hash, node_id_eq)
  118. HT_GENERATE2(nodelist_map, node_t, ht_ent, node_id_hash, node_id_eq,
  119. 0.6, tor_reallocarray_, tor_free_)
  120. static inline unsigned int
  121. node_ed_id_hash(const node_t *node)
  122. {
  123. return (unsigned) siphash24g(node->ed25519_id.pubkey, ED25519_PUBKEY_LEN);
  124. }
  125. static inline unsigned int
  126. node_ed_id_eq(const node_t *node1, const node_t *node2)
  127. {
  128. return ed25519_pubkey_eq(&node1->ed25519_id, &node2->ed25519_id);
  129. }
  130. HT_PROTOTYPE(nodelist_ed_map, node_t, ed_ht_ent, node_ed_id_hash,
  131. node_ed_id_eq)
  132. HT_GENERATE2(nodelist_ed_map, node_t, ed_ht_ent, node_ed_id_hash,
  133. node_ed_id_eq, 0.6, tor_reallocarray_, tor_free_)
  134. /** The global nodelist. */
  135. static nodelist_t *the_nodelist=NULL;
  136. /** Create an empty nodelist if we haven't done so already. */
  137. static void
  138. init_nodelist(void)
  139. {
  140. if (PREDICT_UNLIKELY(the_nodelist == NULL)) {
  141. the_nodelist = tor_malloc_zero(sizeof(nodelist_t));
  142. HT_INIT(nodelist_map, &the_nodelist->nodes_by_id);
  143. HT_INIT(nodelist_ed_map, &the_nodelist->nodes_by_ed_id);
  144. the_nodelist->nodes = smartlist_new();
  145. }
  146. }
  147. /** As node_get_by_id, but returns a non-const pointer */
  148. MOCK_IMPL(node_t *,
  149. node_get_mutable_by_id,(const char *identity_digest))
  150. {
  151. node_t search, *node;
  152. if (PREDICT_UNLIKELY(the_nodelist == NULL))
  153. return NULL;
  154. memcpy(&search.identity, identity_digest, DIGEST_LEN);
  155. node = HT_FIND(nodelist_map, &the_nodelist->nodes_by_id, &search);
  156. return node;
  157. }
  158. /** As node_get_by_ed25519_id, but returns a non-const pointer */
  159. node_t *
  160. node_get_mutable_by_ed25519_id(const ed25519_public_key_t *ed_id)
  161. {
  162. node_t search, *node;
  163. if (PREDICT_UNLIKELY(the_nodelist == NULL))
  164. return NULL;
  165. if (BUG(ed_id == NULL) || BUG(ed25519_public_key_is_zero(ed_id)))
  166. return NULL;
  167. memcpy(&search.ed25519_id, ed_id, sizeof(search.ed25519_id));
  168. node = HT_FIND(nodelist_ed_map, &the_nodelist->nodes_by_ed_id, &search);
  169. return node;
  170. }
  171. /** Return the node_t whose identity is <b>identity_digest</b>, or NULL
  172. * if no such node exists. */
  173. MOCK_IMPL(const node_t *,
  174. node_get_by_id,(const char *identity_digest))
  175. {
  176. return node_get_mutable_by_id(identity_digest);
  177. }
  178. /** Return the node_t whose ed25519 identity is <b>ed_id</b>, or NULL
  179. * if no such node exists. */
  180. MOCK_IMPL(const node_t *,
  181. node_get_by_ed25519_id,(const ed25519_public_key_t *ed_id))
  182. {
  183. return node_get_mutable_by_ed25519_id(ed_id);
  184. }
  185. /** Internal: return the node_t whose identity_digest is
  186. * <b>identity_digest</b>. If none exists, create a new one, add it to the
  187. * nodelist, and return it.
  188. *
  189. * Requires that the nodelist be initialized.
  190. */
  191. static node_t *
  192. node_get_or_create(const char *identity_digest)
  193. {
  194. node_t *node;
  195. if ((node = node_get_mutable_by_id(identity_digest)))
  196. return node;
  197. node = tor_malloc_zero(sizeof(node_t));
  198. memcpy(node->identity, identity_digest, DIGEST_LEN);
  199. HT_INSERT(nodelist_map, &the_nodelist->nodes_by_id, node);
  200. smartlist_add(the_nodelist->nodes, node);
  201. node->nodelist_idx = smartlist_len(the_nodelist->nodes) - 1;
  202. node->hsdir_index = tor_malloc_zero(sizeof(hsdir_index_t));
  203. node->country = -1;
  204. return node;
  205. }
  206. /** Remove <b>node</b> from the ed25519 map (if it present), and
  207. * set its ed25519_id field to zero. */
  208. static int
  209. node_remove_from_ed25519_map(node_t *node)
  210. {
  211. tor_assert(the_nodelist);
  212. tor_assert(node);
  213. if (ed25519_public_key_is_zero(&node->ed25519_id)) {
  214. return 0;
  215. }
  216. int rv = 0;
  217. node_t *search =
  218. HT_FIND(nodelist_ed_map, &the_nodelist->nodes_by_ed_id, node);
  219. if (BUG(search != node)) {
  220. goto clear_and_return;
  221. }
  222. search = HT_REMOVE(nodelist_ed_map, &the_nodelist->nodes_by_ed_id, node);
  223. tor_assert(search == node);
  224. rv = 1;
  225. clear_and_return:
  226. memset(&node->ed25519_id, 0, sizeof(node->ed25519_id));
  227. return rv;
  228. }
  229. /** If <b>node</b> has an ed25519 id, and it is not already in the ed25519 id
  230. * map, set its ed25519_id field, and add it to the ed25519 map.
  231. */
  232. static int
  233. node_add_to_ed25519_map(node_t *node)
  234. {
  235. tor_assert(the_nodelist);
  236. tor_assert(node);
  237. if (! ed25519_public_key_is_zero(&node->ed25519_id)) {
  238. return 0;
  239. }
  240. const ed25519_public_key_t *key = node_get_ed25519_id(node);
  241. if (!key) {
  242. return 0;
  243. }
  244. node_t *old;
  245. memcpy(&node->ed25519_id, key, sizeof(node->ed25519_id));
  246. old = HT_FIND(nodelist_ed_map, &the_nodelist->nodes_by_ed_id, node);
  247. if (BUG(old)) {
  248. /* XXXX order matters here, and this may mean that authorities aren't
  249. * pinning. */
  250. if (old != node)
  251. memset(&node->ed25519_id, 0, sizeof(node->ed25519_id));
  252. return 0;
  253. }
  254. HT_INSERT(nodelist_ed_map, &the_nodelist->nodes_by_ed_id, node);
  255. return 1;
  256. }
  257. /* For a given <b>node</b> for the consensus <b>ns</b>, set the hsdir index
  258. * for the node, both current and next if possible. This can only fails if the
  259. * node_t ed25519 identity key can't be found which would be a bug. */
  260. STATIC void
  261. node_set_hsdir_index(node_t *node, const networkstatus_t *ns)
  262. {
  263. time_t now = approx_time();
  264. const ed25519_public_key_t *node_identity_pk;
  265. uint8_t *fetch_srv = NULL, *store_first_srv = NULL, *store_second_srv = NULL;
  266. uint64_t next_time_period_num, current_time_period_num;
  267. uint64_t fetch_tp, store_first_tp, store_second_tp;
  268. tor_assert(node);
  269. tor_assert(ns);
  270. if (!networkstatus_is_live(ns, now)) {
  271. static struct ratelim_t live_consensus_ratelim = RATELIM_INIT(30 * 60);
  272. log_fn_ratelim(&live_consensus_ratelim, LOG_INFO, LD_GENERAL,
  273. "Not setting hsdir index with a non-live consensus.");
  274. goto done;
  275. }
  276. node_identity_pk = node_get_ed25519_id(node);
  277. if (node_identity_pk == NULL) {
  278. log_debug(LD_GENERAL, "ed25519 identity public key not found when "
  279. "trying to build the hsdir indexes for node %s",
  280. node_describe(node));
  281. goto done;
  282. }
  283. /* Get the current and next time period number. */
  284. current_time_period_num = hs_get_time_period_num(0);
  285. next_time_period_num = hs_get_next_time_period_num(0);
  286. /* We always use the current time period for fetching descs */
  287. fetch_tp = current_time_period_num;
  288. /* Now extract the needed SRVs and time periods for building hsdir indices */
  289. if (hs_in_period_between_tp_and_srv(ns, now)) {
  290. fetch_srv = hs_get_current_srv(fetch_tp, ns);
  291. store_first_tp = hs_get_previous_time_period_num(0);
  292. store_second_tp = current_time_period_num;
  293. } else {
  294. fetch_srv = hs_get_previous_srv(fetch_tp, ns);
  295. store_first_tp = current_time_period_num;
  296. store_second_tp = next_time_period_num;
  297. }
  298. /* We always use the old SRV for storing the first descriptor and the latest
  299. * SRV for storing the second descriptor */
  300. store_first_srv = hs_get_previous_srv(store_first_tp, ns);
  301. store_second_srv = hs_get_current_srv(store_second_tp, ns);
  302. /* Build the fetch index. */
  303. hs_build_hsdir_index(node_identity_pk, fetch_srv, fetch_tp,
  304. node->hsdir_index->fetch);
  305. /* If we are in the time segment between SRV#N and TP#N, the fetch index is
  306. the same as the first store index */
  307. if (!hs_in_period_between_tp_and_srv(ns, now)) {
  308. memcpy(node->hsdir_index->store_first, node->hsdir_index->fetch,
  309. sizeof(node->hsdir_index->store_first));
  310. } else {
  311. hs_build_hsdir_index(node_identity_pk, store_first_srv, store_first_tp,
  312. node->hsdir_index->store_first);
  313. }
  314. /* If we are in the time segment between TP#N and SRV#N+1, the fetch index is
  315. the same as the second store index */
  316. if (hs_in_period_between_tp_and_srv(ns, now)) {
  317. memcpy(node->hsdir_index->store_second, node->hsdir_index->fetch,
  318. sizeof(node->hsdir_index->store_second));
  319. } else {
  320. hs_build_hsdir_index(node_identity_pk, store_second_srv, store_second_tp,
  321. node->hsdir_index->store_second);
  322. }
  323. done:
  324. tor_free(fetch_srv);
  325. tor_free(store_first_srv);
  326. tor_free(store_second_srv);
  327. return;
  328. }
  329. /** Called when a node's address changes. */
  330. static void
  331. node_addrs_changed(node_t *node)
  332. {
  333. node->last_reachable = node->last_reachable6 = 0;
  334. node->country = -1;
  335. }
  336. /** Add all address information about <b>node</b> to the current address
  337. * set (if there is one).
  338. */
  339. static void
  340. node_add_to_address_set(const node_t *node)
  341. {
  342. if (!the_nodelist || !the_nodelist->node_addrs)
  343. return;
  344. /* These various address sources can be redundant, but it's likely faster
  345. * to add them all than to compare them all for equality. */
  346. if (node->rs) {
  347. if (node->rs->addr)
  348. address_set_add_ipv4h(the_nodelist->node_addrs, node->rs->addr);
  349. if (!tor_addr_is_null(&node->rs->ipv6_addr))
  350. address_set_add(the_nodelist->node_addrs, &node->rs->ipv6_addr);
  351. }
  352. if (node->ri) {
  353. if (node->ri->addr)
  354. address_set_add_ipv4h(the_nodelist->node_addrs, node->ri->addr);
  355. if (!tor_addr_is_null(&node->ri->ipv6_addr))
  356. address_set_add(the_nodelist->node_addrs, &node->ri->ipv6_addr);
  357. }
  358. if (node->md) {
  359. if (!tor_addr_is_null(&node->md->ipv6_addr))
  360. address_set_add(the_nodelist->node_addrs, &node->md->ipv6_addr);
  361. }
  362. }
  363. /** Return true if <b>addr</b> is the address of some node in the nodelist.
  364. * If not, probably return false. */
  365. int
  366. nodelist_probably_contains_address(const tor_addr_t *addr)
  367. {
  368. if (BUG(!addr))
  369. return 0;
  370. if (!the_nodelist || !the_nodelist->node_addrs)
  371. return 0;
  372. return address_set_probably_contains(the_nodelist->node_addrs, addr);
  373. }
  374. /** Add <b>ri</b> to an appropriate node in the nodelist. If we replace an
  375. * old routerinfo, and <b>ri_old_out</b> is not NULL, set *<b>ri_old_out</b>
  376. * to the previous routerinfo.
  377. */
  378. node_t *
  379. nodelist_set_routerinfo(routerinfo_t *ri, routerinfo_t **ri_old_out)
  380. {
  381. node_t *node;
  382. const char *id_digest;
  383. int had_router = 0;
  384. tor_assert(ri);
  385. init_nodelist();
  386. id_digest = ri->cache_info.identity_digest;
  387. node = node_get_or_create(id_digest);
  388. node_remove_from_ed25519_map(node);
  389. if (node->ri) {
  390. if (!routers_have_same_or_addrs(node->ri, ri)) {
  391. node_addrs_changed(node);
  392. }
  393. had_router = 1;
  394. if (ri_old_out)
  395. *ri_old_out = node->ri;
  396. } else {
  397. if (ri_old_out)
  398. *ri_old_out = NULL;
  399. }
  400. node->ri = ri;
  401. node_add_to_ed25519_map(node);
  402. if (node->country == -1)
  403. node_set_country(node);
  404. if (authdir_mode(get_options()) && !had_router) {
  405. const char *discard=NULL;
  406. uint32_t status = dirserv_router_get_status(ri, &discard, LOG_INFO);
  407. dirserv_set_node_flags_from_authoritative_status(node, status);
  408. }
  409. /* Setting the HSDir index requires the ed25519 identity key which can
  410. * only be found either in the ri or md. This is why this is called here.
  411. * Only nodes supporting HSDir=2 protocol version needs this index. */
  412. if (node->rs && node->rs->pv.supports_v3_hsdir) {
  413. node_set_hsdir_index(node,
  414. networkstatus_get_latest_consensus());
  415. }
  416. node_add_to_address_set(node);
  417. return node;
  418. }
  419. /** Set the appropriate node_t to use <b>md</b> as its microdescriptor.
  420. *
  421. * Called when a new microdesc has arrived and the usable consensus flavor
  422. * is "microdesc".
  423. **/
  424. node_t *
  425. nodelist_add_microdesc(microdesc_t *md)
  426. {
  427. networkstatus_t *ns =
  428. networkstatus_get_latest_consensus_by_flavor(FLAV_MICRODESC);
  429. const routerstatus_t *rs;
  430. node_t *node;
  431. if (ns == NULL)
  432. return NULL;
  433. init_nodelist();
  434. /* Microdescriptors don't carry an identity digest, so we need to figure
  435. * it out by looking up the routerstatus. */
  436. rs = router_get_consensus_status_by_descriptor_digest(ns, md->digest);
  437. if (rs == NULL)
  438. return NULL;
  439. node = node_get_mutable_by_id(rs->identity_digest);
  440. if (node == NULL)
  441. return NULL;
  442. node_remove_from_ed25519_map(node);
  443. if (node->md)
  444. node->md->held_by_nodes--;
  445. node->md = md;
  446. md->held_by_nodes++;
  447. /* Setting the HSDir index requires the ed25519 identity key which can
  448. * only be found either in the ri or md. This is why this is called here.
  449. * Only nodes supporting HSDir=2 protocol version needs this index. */
  450. if (rs->pv.supports_v3_hsdir) {
  451. node_set_hsdir_index(node, ns);
  452. }
  453. node_add_to_ed25519_map(node);
  454. node_add_to_address_set(node);
  455. return node;
  456. }
  457. /* Default value. */
  458. #define ESTIMATED_ADDRESS_PER_NODE 2
  459. /* Return the estimated number of address per node_t. This is used for the
  460. * size of the bloom filter in the nodelist (node_addrs). */
  461. MOCK_IMPL(int,
  462. get_estimated_address_per_node, (void))
  463. {
  464. return ESTIMATED_ADDRESS_PER_NODE;
  465. }
  466. /** Tell the nodelist that the current usable consensus is <b>ns</b>.
  467. * This makes the nodelist change all of the routerstatus entries for
  468. * the nodes, drop nodes that no longer have enough info to get used,
  469. * and grab microdescriptors into nodes as appropriate.
  470. */
  471. void
  472. nodelist_set_consensus(networkstatus_t *ns)
  473. {
  474. const or_options_t *options = get_options();
  475. int authdir = authdir_mode_v3(options);
  476. init_nodelist();
  477. if (ns->flavor == FLAV_MICRODESC)
  478. (void) get_microdesc_cache(); /* Make sure it exists first. */
  479. SMARTLIST_FOREACH(the_nodelist->nodes, node_t *, node,
  480. node->rs = NULL);
  481. /* Conservatively estimate that every node will have 2 addresses. */
  482. const int estimated_addresses = smartlist_len(ns->routerstatus_list) *
  483. get_estimated_address_per_node();
  484. address_set_free(the_nodelist->node_addrs);
  485. the_nodelist->node_addrs = address_set_new(estimated_addresses);
  486. SMARTLIST_FOREACH_BEGIN(ns->routerstatus_list, routerstatus_t *, rs) {
  487. node_t *node = node_get_or_create(rs->identity_digest);
  488. node->rs = rs;
  489. if (ns->flavor == FLAV_MICRODESC) {
  490. if (node->md == NULL ||
  491. tor_memneq(node->md->digest,rs->descriptor_digest,DIGEST256_LEN)) {
  492. node_remove_from_ed25519_map(node);
  493. if (node->md)
  494. node->md->held_by_nodes--;
  495. node->md = microdesc_cache_lookup_by_digest256(NULL,
  496. rs->descriptor_digest);
  497. if (node->md)
  498. node->md->held_by_nodes++;
  499. node_add_to_ed25519_map(node);
  500. }
  501. }
  502. if (rs->pv.supports_v3_hsdir) {
  503. node_set_hsdir_index(node, ns);
  504. }
  505. node_set_country(node);
  506. /* If we're not an authdir, believe others. */
  507. if (!authdir) {
  508. node->is_valid = rs->is_valid;
  509. node->is_running = rs->is_flagged_running;
  510. node->is_fast = rs->is_fast;
  511. node->is_stable = rs->is_stable;
  512. node->is_possible_guard = rs->is_possible_guard;
  513. node->is_exit = rs->is_exit;
  514. node->is_bad_exit = rs->is_bad_exit;
  515. node->is_hs_dir = rs->is_hs_dir;
  516. node->ipv6_preferred = 0;
  517. if (fascist_firewall_prefer_ipv6_orport(options) &&
  518. (tor_addr_is_null(&rs->ipv6_addr) == 0 ||
  519. (node->md && tor_addr_is_null(&node->md->ipv6_addr) == 0)))
  520. node->ipv6_preferred = 1;
  521. }
  522. } SMARTLIST_FOREACH_END(rs);
  523. nodelist_purge();
  524. /* Now add all the nodes we have to the address set. */
  525. SMARTLIST_FOREACH_BEGIN(the_nodelist->nodes, node_t *, node) {
  526. node_add_to_address_set(node);
  527. } SMARTLIST_FOREACH_END(node);
  528. if (! authdir) {
  529. SMARTLIST_FOREACH_BEGIN(the_nodelist->nodes, node_t *, node) {
  530. /* We have no routerstatus for this router. Clear flags so we can skip
  531. * it, maybe.*/
  532. if (!node->rs) {
  533. tor_assert(node->ri); /* if it had only an md, or nothing, purge
  534. * would have removed it. */
  535. if (node->ri->purpose == ROUTER_PURPOSE_GENERAL) {
  536. /* Clear all flags. */
  537. node->is_valid = node->is_running = node->is_hs_dir =
  538. node->is_fast = node->is_stable =
  539. node->is_possible_guard = node->is_exit =
  540. node->is_bad_exit = node->ipv6_preferred = 0;
  541. }
  542. }
  543. } SMARTLIST_FOREACH_END(node);
  544. }
  545. }
  546. /** Helper: return true iff a node has a usable amount of information*/
  547. static inline int
  548. node_is_usable(const node_t *node)
  549. {
  550. return (node->rs) || (node->ri);
  551. }
  552. /** Tell the nodelist that <b>md</b> is no longer a microdescriptor for the
  553. * node with <b>identity_digest</b>. */
  554. void
  555. nodelist_remove_microdesc(const char *identity_digest, microdesc_t *md)
  556. {
  557. node_t *node = node_get_mutable_by_id(identity_digest);
  558. if (node && node->md == md) {
  559. node->md = NULL;
  560. md->held_by_nodes--;
  561. if (! node_get_ed25519_id(node)) {
  562. node_remove_from_ed25519_map(node);
  563. }
  564. }
  565. }
  566. /** Tell the nodelist that <b>ri</b> is no longer in the routerlist. */
  567. void
  568. nodelist_remove_routerinfo(routerinfo_t *ri)
  569. {
  570. node_t *node = node_get_mutable_by_id(ri->cache_info.identity_digest);
  571. if (node && node->ri == ri) {
  572. node->ri = NULL;
  573. if (! node_is_usable(node)) {
  574. nodelist_drop_node(node, 1);
  575. node_free(node);
  576. }
  577. }
  578. }
  579. /** Remove <b>node</b> from the nodelist. (Asserts that it was there to begin
  580. * with.) */
  581. static void
  582. nodelist_drop_node(node_t *node, int remove_from_ht)
  583. {
  584. node_t *tmp;
  585. int idx;
  586. if (remove_from_ht) {
  587. tmp = HT_REMOVE(nodelist_map, &the_nodelist->nodes_by_id, node);
  588. tor_assert(tmp == node);
  589. }
  590. node_remove_from_ed25519_map(node);
  591. idx = node->nodelist_idx;
  592. tor_assert(idx >= 0);
  593. tor_assert(node == smartlist_get(the_nodelist->nodes, idx));
  594. smartlist_del(the_nodelist->nodes, idx);
  595. if (idx < smartlist_len(the_nodelist->nodes)) {
  596. tmp = smartlist_get(the_nodelist->nodes, idx);
  597. tmp->nodelist_idx = idx;
  598. }
  599. node->nodelist_idx = -1;
  600. }
  601. /** Return a newly allocated smartlist of the nodes that have <b>md</b> as
  602. * their microdescriptor. */
  603. smartlist_t *
  604. nodelist_find_nodes_with_microdesc(const microdesc_t *md)
  605. {
  606. smartlist_t *result = smartlist_new();
  607. if (the_nodelist == NULL)
  608. return result;
  609. SMARTLIST_FOREACH_BEGIN(the_nodelist->nodes, node_t *, node) {
  610. if (node->md == md) {
  611. smartlist_add(result, node);
  612. }
  613. } SMARTLIST_FOREACH_END(node);
  614. return result;
  615. }
  616. /** Release storage held by <b>node</b> */
  617. static void
  618. node_free_(node_t *node)
  619. {
  620. if (!node)
  621. return;
  622. if (node->md)
  623. node->md->held_by_nodes--;
  624. tor_assert(node->nodelist_idx == -1);
  625. tor_free(node->hsdir_index);
  626. tor_free(node);
  627. }
  628. /** Remove all entries from the nodelist that don't have enough info to be
  629. * usable for anything. */
  630. void
  631. nodelist_purge(void)
  632. {
  633. node_t **iter;
  634. if (PREDICT_UNLIKELY(the_nodelist == NULL))
  635. return;
  636. /* Remove the non-usable nodes. */
  637. for (iter = HT_START(nodelist_map, &the_nodelist->nodes_by_id); iter; ) {
  638. node_t *node = *iter;
  639. if (node->md && !node->rs) {
  640. /* An md is only useful if there is an rs. */
  641. node->md->held_by_nodes--;
  642. node->md = NULL;
  643. }
  644. if (node_is_usable(node)) {
  645. iter = HT_NEXT(nodelist_map, &the_nodelist->nodes_by_id, iter);
  646. } else {
  647. iter = HT_NEXT_RMV(nodelist_map, &the_nodelist->nodes_by_id, iter);
  648. nodelist_drop_node(node, 0);
  649. node_free(node);
  650. }
  651. }
  652. nodelist_assert_ok();
  653. }
  654. /** Release all storage held by the nodelist. */
  655. void
  656. nodelist_free_all(void)
  657. {
  658. if (PREDICT_UNLIKELY(the_nodelist == NULL))
  659. return;
  660. HT_CLEAR(nodelist_map, &the_nodelist->nodes_by_id);
  661. HT_CLEAR(nodelist_ed_map, &the_nodelist->nodes_by_ed_id);
  662. SMARTLIST_FOREACH_BEGIN(the_nodelist->nodes, node_t *, node) {
  663. node->nodelist_idx = -1;
  664. node_free(node);
  665. } SMARTLIST_FOREACH_END(node);
  666. smartlist_free(the_nodelist->nodes);
  667. address_set_free(the_nodelist->node_addrs);
  668. the_nodelist->node_addrs = NULL;
  669. tor_free(the_nodelist);
  670. }
  671. /** Check that the nodelist is internally consistent, and consistent with
  672. * the directory info it's derived from.
  673. */
  674. void
  675. nodelist_assert_ok(void)
  676. {
  677. routerlist_t *rl = router_get_routerlist();
  678. networkstatus_t *ns = networkstatus_get_latest_consensus();
  679. digestmap_t *dm;
  680. if (!the_nodelist)
  681. return;
  682. dm = digestmap_new();
  683. /* every routerinfo in rl->routers should be in the nodelist. */
  684. if (rl) {
  685. SMARTLIST_FOREACH_BEGIN(rl->routers, routerinfo_t *, ri) {
  686. const node_t *node = node_get_by_id(ri->cache_info.identity_digest);
  687. tor_assert(node && node->ri == ri);
  688. tor_assert(fast_memeq(ri->cache_info.identity_digest,
  689. node->identity, DIGEST_LEN));
  690. tor_assert(! digestmap_get(dm, node->identity));
  691. digestmap_set(dm, node->identity, (void*)node);
  692. } SMARTLIST_FOREACH_END(ri);
  693. }
  694. /* every routerstatus in ns should be in the nodelist */
  695. if (ns) {
  696. SMARTLIST_FOREACH_BEGIN(ns->routerstatus_list, routerstatus_t *, rs) {
  697. const node_t *node = node_get_by_id(rs->identity_digest);
  698. tor_assert(node && node->rs == rs);
  699. tor_assert(fast_memeq(rs->identity_digest, node->identity, DIGEST_LEN));
  700. digestmap_set(dm, node->identity, (void*)node);
  701. if (ns->flavor == FLAV_MICRODESC) {
  702. /* If it's a microdesc consensus, every entry that has a
  703. * microdescriptor should be in the nodelist.
  704. */
  705. microdesc_t *md =
  706. microdesc_cache_lookup_by_digest256(NULL, rs->descriptor_digest);
  707. tor_assert(md == node->md);
  708. if (md)
  709. tor_assert(md->held_by_nodes >= 1);
  710. }
  711. } SMARTLIST_FOREACH_END(rs);
  712. }
  713. /* The nodelist should have no other entries, and its entries should be
  714. * well-formed. */
  715. SMARTLIST_FOREACH_BEGIN(the_nodelist->nodes, node_t *, node) {
  716. tor_assert(digestmap_get(dm, node->identity) != NULL);
  717. tor_assert(node_sl_idx == node->nodelist_idx);
  718. } SMARTLIST_FOREACH_END(node);
  719. /* Every node listed with an ed25519 identity should be listed by that
  720. * identity.
  721. */
  722. SMARTLIST_FOREACH_BEGIN(the_nodelist->nodes, node_t *, node) {
  723. if (!ed25519_public_key_is_zero(&node->ed25519_id)) {
  724. tor_assert(node == node_get_by_ed25519_id(&node->ed25519_id));
  725. }
  726. } SMARTLIST_FOREACH_END(node);
  727. node_t **idx;
  728. HT_FOREACH(idx, nodelist_ed_map, &the_nodelist->nodes_by_ed_id) {
  729. node_t *node = *idx;
  730. tor_assert(node == node_get_by_ed25519_id(&node->ed25519_id));
  731. }
  732. tor_assert((long)smartlist_len(the_nodelist->nodes) ==
  733. (long)HT_SIZE(&the_nodelist->nodes_by_id));
  734. tor_assert((long)smartlist_len(the_nodelist->nodes) >=
  735. (long)HT_SIZE(&the_nodelist->nodes_by_ed_id));
  736. digestmap_free(dm, NULL);
  737. }
  738. /** Return a list of a node_t * for every node we know about. The caller
  739. * MUST NOT modify the list. (You can set and clear flags in the nodes if
  740. * you must, but you must not add or remove nodes.) */
  741. MOCK_IMPL(smartlist_t *,
  742. nodelist_get_list,(void))
  743. {
  744. init_nodelist();
  745. return the_nodelist->nodes;
  746. }
  747. /** Given a hex-encoded nickname of the format DIGEST, $DIGEST, $DIGEST=name,
  748. * or $DIGEST~name, return the node with the matching identity digest and
  749. * nickname (if any). Return NULL if no such node exists, or if <b>hex_id</b>
  750. * is not well-formed. DOCDOC flags */
  751. const node_t *
  752. node_get_by_hex_id(const char *hex_id, unsigned flags)
  753. {
  754. char digest_buf[DIGEST_LEN];
  755. char nn_buf[MAX_NICKNAME_LEN+1];
  756. char nn_char='\0';
  757. (void) flags; // XXXX
  758. if (hex_digest_nickname_decode(hex_id, digest_buf, &nn_char, nn_buf)==0) {
  759. const node_t *node = node_get_by_id(digest_buf);
  760. if (!node)
  761. return NULL;
  762. if (nn_char == '=') {
  763. /* "=" indicates a Named relay, but there aren't any of those now. */
  764. return NULL;
  765. }
  766. return node;
  767. }
  768. return NULL;
  769. }
  770. /** Given a nickname (possibly verbose, possibly a hexadecimal digest), return
  771. * the corresponding node_t, or NULL if none exists. Warn the user if they
  772. * have specified a router by nickname, unless the NNF_NO_WARN_UNNAMED bit is
  773. * set in <b>flags</b>. */
  774. MOCK_IMPL(const node_t *,
  775. node_get_by_nickname,(const char *nickname, unsigned flags))
  776. {
  777. const int warn_if_unnamed = !(flags & NNF_NO_WARN_UNNAMED);
  778. if (!the_nodelist)
  779. return NULL;
  780. /* Handle these cases: DIGEST, $DIGEST, $DIGEST=name, $DIGEST~name. */
  781. {
  782. const node_t *node;
  783. if ((node = node_get_by_hex_id(nickname, flags)) != NULL)
  784. return node;
  785. }
  786. if (!strcasecmp(nickname, UNNAMED_ROUTER_NICKNAME))
  787. return NULL;
  788. /* Okay, so the name is not canonical for anybody. */
  789. {
  790. smartlist_t *matches = smartlist_new();
  791. const node_t *choice = NULL;
  792. SMARTLIST_FOREACH_BEGIN(the_nodelist->nodes, node_t *, node) {
  793. if (!strcasecmp(node_get_nickname(node), nickname))
  794. smartlist_add(matches, node);
  795. } SMARTLIST_FOREACH_END(node);
  796. if (smartlist_len(matches)>1 && warn_if_unnamed) {
  797. int any_unwarned = 0;
  798. SMARTLIST_FOREACH_BEGIN(matches, node_t *, node) {
  799. if (!node->name_lookup_warned) {
  800. node->name_lookup_warned = 1;
  801. any_unwarned = 1;
  802. }
  803. } SMARTLIST_FOREACH_END(node);
  804. if (any_unwarned) {
  805. log_warn(LD_CONFIG, "There are multiple matches for the name %s, "
  806. "but none is listed as Named in the directory consensus. "
  807. "Choosing one arbitrarily.", nickname);
  808. }
  809. } else if (smartlist_len(matches)==1 && warn_if_unnamed) {
  810. char fp[HEX_DIGEST_LEN+1];
  811. node_t *node = smartlist_get(matches, 0);
  812. if (! node->name_lookup_warned) {
  813. base16_encode(fp, sizeof(fp), node->identity, DIGEST_LEN);
  814. log_warn(LD_CONFIG,
  815. "You specified a relay \"%s\" by name, but nicknames can be "
  816. "used by any relay, not just the one you meant. "
  817. "To make sure you get the same relay in the future, refer "
  818. "to it by key, as \"$%s\".", nickname, fp);
  819. node->name_lookup_warned = 1;
  820. }
  821. }
  822. if (smartlist_len(matches))
  823. choice = smartlist_get(matches, 0);
  824. smartlist_free(matches);
  825. return choice;
  826. }
  827. }
  828. /** Return the Ed25519 identity key for the provided node, or NULL if it
  829. * doesn't have one. */
  830. const ed25519_public_key_t *
  831. node_get_ed25519_id(const node_t *node)
  832. {
  833. const ed25519_public_key_t *ri_pk = NULL;
  834. const ed25519_public_key_t *md_pk = NULL;
  835. if (node->ri) {
  836. if (node->ri->cache_info.signing_key_cert) {
  837. ri_pk = &node->ri->cache_info.signing_key_cert->signing_key;
  838. /* Checking whether routerinfo ed25519 is all zero.
  839. * Our descriptor parser should make sure this never happens. */
  840. if (BUG(ed25519_public_key_is_zero(ri_pk)))
  841. ri_pk = NULL;
  842. }
  843. }
  844. if (node->md) {
  845. if (node->md->ed25519_identity_pkey) {
  846. md_pk = node->md->ed25519_identity_pkey;
  847. /* Checking whether microdesc ed25519 is all zero.
  848. * Our descriptor parser should make sure this never happens. */
  849. if (BUG(ed25519_public_key_is_zero(md_pk)))
  850. md_pk = NULL;
  851. }
  852. }
  853. if (ri_pk && md_pk) {
  854. if (ed25519_pubkey_eq(ri_pk, md_pk)) {
  855. return ri_pk;
  856. } else {
  857. /* This can happen if the relay gets flagged NoEdConsensus which will be
  858. * triggered on all relays of the network. Thus a protocol warning. */
  859. log_fn(LOG_PROTOCOL_WARN, LD_PROTOCOL,
  860. "Inconsistent ed25519 identities in the nodelist");
  861. return NULL;
  862. }
  863. } else if (ri_pk) {
  864. return ri_pk;
  865. } else {
  866. return md_pk;
  867. }
  868. }
  869. /** Return true iff this node's Ed25519 identity matches <b>id</b>.
  870. * (An absent Ed25519 identity matches NULL or zero.) */
  871. int
  872. node_ed25519_id_matches(const node_t *node, const ed25519_public_key_t *id)
  873. {
  874. const ed25519_public_key_t *node_id = node_get_ed25519_id(node);
  875. if (node_id == NULL || ed25519_public_key_is_zero(node_id)) {
  876. return id == NULL || ed25519_public_key_is_zero(id);
  877. } else {
  878. return id && ed25519_pubkey_eq(node_id, id);
  879. }
  880. }
  881. /** Dummy object that should be unreturnable. Used to ensure that
  882. * node_get_protover_summary_flags() always returns non-NULL. */
  883. static const protover_summary_flags_t zero_protover_flags = {
  884. 0,0,0,0,0,0,0
  885. };
  886. /** Return the protover_summary_flags for a given node. */
  887. static const protover_summary_flags_t *
  888. node_get_protover_summary_flags(const node_t *node)
  889. {
  890. if (node->rs) {
  891. return &node->rs->pv;
  892. } else if (node->ri) {
  893. return &node->ri->pv;
  894. } else {
  895. /* This should be impossible: every node should have a routerstatus or a
  896. * router descriptor or both. But just in case we've messed up somehow,
  897. * return a nice empty set of flags to indicate "this node supports
  898. * nothing." */
  899. tor_assert_nonfatal_unreached_once();
  900. return &zero_protover_flags;
  901. }
  902. }
  903. /** Return true iff <b>node</b> supports authenticating itself
  904. * by ed25519 ID during the link handshake. If <b>compatible_with_us</b>,
  905. * it needs to be using a link authentication method that we understand.
  906. * If not, any plausible link authentication method will do. */
  907. int
  908. node_supports_ed25519_link_authentication(const node_t *node,
  909. int compatible_with_us)
  910. {
  911. if (! node_get_ed25519_id(node))
  912. return 0;
  913. const protover_summary_flags_t *pv = node_get_protover_summary_flags(node);
  914. if (compatible_with_us)
  915. return pv->supports_ed25519_link_handshake_compat;
  916. else
  917. return pv->supports_ed25519_link_handshake_any;
  918. }
  919. /** Return true iff <b>node</b> supports the hidden service directory version
  920. * 3 protocol (proposal 224). */
  921. int
  922. node_supports_v3_hsdir(const node_t *node)
  923. {
  924. tor_assert(node);
  925. return node_get_protover_summary_flags(node)->supports_v3_hsdir;
  926. }
  927. /** Return true iff <b>node</b> supports ed25519 authentication as an hidden
  928. * service introduction point.*/
  929. int
  930. node_supports_ed25519_hs_intro(const node_t *node)
  931. {
  932. tor_assert(node);
  933. return node_get_protover_summary_flags(node)->supports_ed25519_hs_intro;
  934. }
  935. /** Return true iff <b>node</b> supports to be a rendezvous point for hidden
  936. * service version 3 (HSRend=2). */
  937. int
  938. node_supports_v3_rendezvous_point(const node_t *node)
  939. {
  940. tor_assert(node);
  941. return node_get_protover_summary_flags(node)->supports_v3_rendezvous_point;
  942. }
  943. /** Return the RSA ID key's SHA1 digest for the provided node. */
  944. const uint8_t *
  945. node_get_rsa_id_digest(const node_t *node)
  946. {
  947. tor_assert(node);
  948. return (const uint8_t*)node->identity;
  949. }
  950. /** Return the nickname of <b>node</b>, or NULL if we can't find one. */
  951. const char *
  952. node_get_nickname(const node_t *node)
  953. {
  954. tor_assert(node);
  955. if (node->rs)
  956. return node->rs->nickname;
  957. else if (node->ri)
  958. return node->ri->nickname;
  959. else
  960. return NULL;
  961. }
  962. /** Return true iff <b>node</b> appears to be a directory authority or
  963. * directory cache */
  964. int
  965. node_is_dir(const node_t *node)
  966. {
  967. if (node->rs) {
  968. routerstatus_t * rs = node->rs;
  969. /* This is true if supports_tunnelled_dir_requests is true which
  970. * indicates that we support directory request tunnelled or through the
  971. * DirPort. */
  972. return rs->is_v2_dir;
  973. } else if (node->ri) {
  974. routerinfo_t * ri = node->ri;
  975. /* Both tunnelled request is supported or DirPort is set. */
  976. return ri->supports_tunnelled_dir_requests;
  977. } else {
  978. return 0;
  979. }
  980. }
  981. /** Return true iff <b>node</b> has either kind of descriptor -- that
  982. * is, a routerdescriptor or a microdescriptor.
  983. *
  984. * You should probably use node_has_preferred_descriptor() instead.
  985. **/
  986. int
  987. node_has_any_descriptor(const node_t *node)
  988. {
  989. return (node->ri ||
  990. (node->rs && node->md));
  991. }
  992. /** Return true iff <b>node</b> has the kind of descriptor we would prefer to
  993. * use for it, given our configuration and how we intend to use the node.
  994. *
  995. * If <b>for_direct_connect</b> is true, we intend to connect to the node
  996. * directly, as the first hop of a circuit; otherwise, we intend to connect to
  997. * it indirectly, or use it as if we were connecting to it indirectly. */
  998. int
  999. node_has_preferred_descriptor(const node_t *node,
  1000. int for_direct_connect)
  1001. {
  1002. const int is_bridge = node_is_a_configured_bridge(node);
  1003. const int we_use_mds = we_use_microdescriptors_for_circuits(get_options());
  1004. if ((is_bridge && for_direct_connect) || !we_use_mds) {
  1005. /* We need an ri in this case. */
  1006. if (!node->ri)
  1007. return 0;
  1008. } else {
  1009. /* Otherwise we need an rs and an md. */
  1010. if (node->rs == NULL || node->md == NULL)
  1011. return 0;
  1012. }
  1013. return 1;
  1014. }
  1015. /** Return the router_purpose of <b>node</b>. */
  1016. int
  1017. node_get_purpose(const node_t *node)
  1018. {
  1019. if (node->ri)
  1020. return node->ri->purpose;
  1021. else
  1022. return ROUTER_PURPOSE_GENERAL;
  1023. }
  1024. /** Compute the verbose ("extended") nickname of <b>node</b> and store it
  1025. * into the MAX_VERBOSE_NICKNAME_LEN+1 character buffer at
  1026. * <b>verbose_name_out</b> */
  1027. void
  1028. node_get_verbose_nickname(const node_t *node,
  1029. char *verbose_name_out)
  1030. {
  1031. const char *nickname = node_get_nickname(node);
  1032. verbose_name_out[0] = '$';
  1033. base16_encode(verbose_name_out+1, HEX_DIGEST_LEN+1, node->identity,
  1034. DIGEST_LEN);
  1035. if (!nickname)
  1036. return;
  1037. verbose_name_out[1+HEX_DIGEST_LEN] = '~';
  1038. strlcpy(verbose_name_out+1+HEX_DIGEST_LEN+1, nickname, MAX_NICKNAME_LEN+1);
  1039. }
  1040. /** Compute the verbose ("extended") nickname of node with
  1041. * given <b>id_digest</b> and store it into the MAX_VERBOSE_NICKNAME_LEN+1
  1042. * character buffer at <b>verbose_name_out</b>
  1043. *
  1044. * If node_get_by_id() returns NULL, base 16 encoding of
  1045. * <b>id_digest</b> is returned instead. */
  1046. void
  1047. node_get_verbose_nickname_by_id(const char *id_digest,
  1048. char *verbose_name_out)
  1049. {
  1050. const node_t *node = node_get_by_id(id_digest);
  1051. if (!node) {
  1052. verbose_name_out[0] = '$';
  1053. base16_encode(verbose_name_out+1, HEX_DIGEST_LEN+1, id_digest, DIGEST_LEN);
  1054. } else {
  1055. node_get_verbose_nickname(node, verbose_name_out);
  1056. }
  1057. }
  1058. /** Return true iff it seems that <b>node</b> allows circuits to exit
  1059. * through it directlry from the client. */
  1060. int
  1061. node_allows_single_hop_exits(const node_t *node)
  1062. {
  1063. if (node && node->ri)
  1064. return node->ri->allow_single_hop_exits;
  1065. else
  1066. return 0;
  1067. }
  1068. /** Return true iff it seems that <b>node</b> has an exit policy that doesn't
  1069. * actually permit anything to exit, or we don't know its exit policy */
  1070. int
  1071. node_exit_policy_rejects_all(const node_t *node)
  1072. {
  1073. if (node->rejects_all)
  1074. return 1;
  1075. if (node->ri)
  1076. return node->ri->policy_is_reject_star;
  1077. else if (node->md)
  1078. return node->md->exit_policy == NULL ||
  1079. short_policy_is_reject_star(node->md->exit_policy);
  1080. else
  1081. return 1;
  1082. }
  1083. /** Return true iff the exit policy for <b>node</b> is such that we can treat
  1084. * rejecting an address of type <b>family</b> unexpectedly as a sign of that
  1085. * node's failure. */
  1086. int
  1087. node_exit_policy_is_exact(const node_t *node, sa_family_t family)
  1088. {
  1089. if (family == AF_UNSPEC) {
  1090. return 1; /* Rejecting an address but not telling us what address
  1091. * is a bad sign. */
  1092. } else if (family == AF_INET) {
  1093. return node->ri != NULL;
  1094. } else if (family == AF_INET6) {
  1095. return 0;
  1096. }
  1097. tor_fragile_assert();
  1098. return 1;
  1099. }
  1100. /* Check if the "addr" and port_field fields from r are a valid non-listening
  1101. * address/port. If so, set valid to true and add a newly allocated
  1102. * tor_addr_port_t containing "addr" and port_field to sl.
  1103. * "addr" is an IPv4 host-order address and port_field is a uint16_t.
  1104. * r is typically a routerinfo_t or routerstatus_t.
  1105. */
  1106. #define SL_ADD_NEW_IPV4_AP(r, port_field, sl, valid) \
  1107. STMT_BEGIN \
  1108. if (tor_addr_port_is_valid_ipv4h((r)->addr, (r)->port_field, 0)) { \
  1109. valid = 1; \
  1110. tor_addr_port_t *ap = tor_malloc(sizeof(tor_addr_port_t)); \
  1111. tor_addr_from_ipv4h(&ap->addr, (r)->addr); \
  1112. ap->port = (r)->port_field; \
  1113. smartlist_add((sl), ap); \
  1114. } \
  1115. STMT_END
  1116. /* Check if the "addr" and port_field fields from r are a valid non-listening
  1117. * address/port. If so, set valid to true and add a newly allocated
  1118. * tor_addr_port_t containing "addr" and port_field to sl.
  1119. * "addr" is a tor_addr_t and port_field is a uint16_t.
  1120. * r is typically a routerinfo_t or routerstatus_t.
  1121. */
  1122. #define SL_ADD_NEW_IPV6_AP(r, port_field, sl, valid) \
  1123. STMT_BEGIN \
  1124. if (tor_addr_port_is_valid(&(r)->ipv6_addr, (r)->port_field, 0)) { \
  1125. valid = 1; \
  1126. tor_addr_port_t *ap = tor_malloc(sizeof(tor_addr_port_t)); \
  1127. tor_addr_copy(&ap->addr, &(r)->ipv6_addr); \
  1128. ap->port = (r)->port_field; \
  1129. smartlist_add((sl), ap); \
  1130. } \
  1131. STMT_END
  1132. /** Return list of tor_addr_port_t with all OR ports (in the sense IP
  1133. * addr + TCP port) for <b>node</b>. Caller must free all elements
  1134. * using tor_free() and free the list using smartlist_free().
  1135. *
  1136. * XXX this is potentially a memory fragmentation hog -- if on
  1137. * critical path consider the option of having the caller allocate the
  1138. * memory
  1139. */
  1140. smartlist_t *
  1141. node_get_all_orports(const node_t *node)
  1142. {
  1143. smartlist_t *sl = smartlist_new();
  1144. int valid = 0;
  1145. /* Find a valid IPv4 address and port */
  1146. if (node->ri != NULL) {
  1147. SL_ADD_NEW_IPV4_AP(node->ri, or_port, sl, valid);
  1148. }
  1149. /* If we didn't find a valid address/port in the ri, try the rs */
  1150. if (!valid && node->rs != NULL) {
  1151. SL_ADD_NEW_IPV4_AP(node->rs, or_port, sl, valid);
  1152. }
  1153. /* Find a valid IPv6 address and port */
  1154. valid = 0;
  1155. if (node->ri != NULL) {
  1156. SL_ADD_NEW_IPV6_AP(node->ri, ipv6_orport, sl, valid);
  1157. }
  1158. if (!valid && node->rs != NULL) {
  1159. SL_ADD_NEW_IPV6_AP(node->rs, ipv6_orport, sl, valid);
  1160. }
  1161. if (!valid && node->md != NULL) {
  1162. SL_ADD_NEW_IPV6_AP(node->md, ipv6_orport, sl, valid);
  1163. }
  1164. return sl;
  1165. }
  1166. #undef SL_ADD_NEW_IPV4_AP
  1167. #undef SL_ADD_NEW_IPV6_AP
  1168. /** Wrapper around node_get_prim_orport for backward
  1169. compatibility. */
  1170. void
  1171. node_get_addr(const node_t *node, tor_addr_t *addr_out)
  1172. {
  1173. tor_addr_port_t ap;
  1174. node_get_prim_orport(node, &ap);
  1175. tor_addr_copy(addr_out, &ap.addr);
  1176. }
  1177. /** Return the host-order IPv4 address for <b>node</b>, or 0 if it doesn't
  1178. * seem to have one. */
  1179. uint32_t
  1180. node_get_prim_addr_ipv4h(const node_t *node)
  1181. {
  1182. /* Don't check the ORPort or DirPort, as this function isn't port-specific,
  1183. * and the node might have a valid IPv4 address, yet have a zero
  1184. * ORPort or DirPort.
  1185. */
  1186. if (node->ri && tor_addr_is_valid_ipv4h(node->ri->addr, 0)) {
  1187. return node->ri->addr;
  1188. } else if (node->rs && tor_addr_is_valid_ipv4h(node->rs->addr, 0)) {
  1189. return node->rs->addr;
  1190. }
  1191. return 0;
  1192. }
  1193. /** Copy a string representation of an IP address for <b>node</b> into
  1194. * the <b>len</b>-byte buffer at <b>buf</b>. */
  1195. void
  1196. node_get_address_string(const node_t *node, char *buf, size_t len)
  1197. {
  1198. uint32_t ipv4_addr = node_get_prim_addr_ipv4h(node);
  1199. if (tor_addr_is_valid_ipv4h(ipv4_addr, 0)) {
  1200. tor_addr_t addr;
  1201. tor_addr_from_ipv4h(&addr, ipv4_addr);
  1202. tor_addr_to_str(buf, &addr, len, 0);
  1203. } else if (len > 0) {
  1204. buf[0] = '\0';
  1205. }
  1206. }
  1207. /** Return <b>node</b>'s declared uptime, or -1 if it doesn't seem to have
  1208. * one. */
  1209. long
  1210. node_get_declared_uptime(const node_t *node)
  1211. {
  1212. if (node->ri)
  1213. return node->ri->uptime;
  1214. else
  1215. return -1;
  1216. }
  1217. /** Return <b>node</b>'s platform string, or NULL if we don't know it. */
  1218. const char *
  1219. node_get_platform(const node_t *node)
  1220. {
  1221. /* If we wanted, we could record the version in the routerstatus_t, since
  1222. * the consensus lists it. We don't, though, so this function just won't
  1223. * work with microdescriptors. */
  1224. if (node->ri)
  1225. return node->ri->platform;
  1226. else
  1227. return NULL;
  1228. }
  1229. /** Return true iff <b>node</b> is one representing this router. */
  1230. int
  1231. node_is_me(const node_t *node)
  1232. {
  1233. return router_digest_is_me(node->identity);
  1234. }
  1235. /** Return <b>node</b> declared family (as a list of names), or NULL if
  1236. * the node didn't declare a family. */
  1237. const smartlist_t *
  1238. node_get_declared_family(const node_t *node)
  1239. {
  1240. if (node->ri && node->ri->declared_family)
  1241. return node->ri->declared_family;
  1242. else if (node->md && node->md->family)
  1243. return node->md->family;
  1244. else
  1245. return NULL;
  1246. }
  1247. /* Does this node have a valid IPv6 address?
  1248. * Prefer node_has_ipv6_orport() or node_has_ipv6_dirport() for
  1249. * checking specific ports. */
  1250. int
  1251. node_has_ipv6_addr(const node_t *node)
  1252. {
  1253. /* Don't check the ORPort or DirPort, as this function isn't port-specific,
  1254. * and the node might have a valid IPv6 address, yet have a zero
  1255. * ORPort or DirPort.
  1256. */
  1257. if (node->ri && tor_addr_is_valid(&node->ri->ipv6_addr, 0))
  1258. return 1;
  1259. if (node->rs && tor_addr_is_valid(&node->rs->ipv6_addr, 0))
  1260. return 1;
  1261. if (node->md && tor_addr_is_valid(&node->md->ipv6_addr, 0))
  1262. return 1;
  1263. return 0;
  1264. }
  1265. /* Does this node have a valid IPv6 ORPort? */
  1266. int
  1267. node_has_ipv6_orport(const node_t *node)
  1268. {
  1269. tor_addr_port_t ipv6_orport;
  1270. node_get_pref_ipv6_orport(node, &ipv6_orport);
  1271. return tor_addr_port_is_valid_ap(&ipv6_orport, 0);
  1272. }
  1273. /* Does this node have a valid IPv6 DirPort? */
  1274. int
  1275. node_has_ipv6_dirport(const node_t *node)
  1276. {
  1277. tor_addr_port_t ipv6_dirport;
  1278. node_get_pref_ipv6_dirport(node, &ipv6_dirport);
  1279. return tor_addr_port_is_valid_ap(&ipv6_dirport, 0);
  1280. }
  1281. /** Return 1 if we prefer the IPv6 address and OR TCP port of
  1282. * <b>node</b>, else 0.
  1283. *
  1284. * We prefer the IPv6 address if the router has an IPv6 address,
  1285. * and we can use IPv6 addresses, and:
  1286. * i) the node_t says that it prefers IPv6
  1287. * or
  1288. * ii) the router has no IPv4 OR address.
  1289. *
  1290. * If you don't have a node, consider looking it up.
  1291. * If there is no node, use fascist_firewall_prefer_ipv6_orport().
  1292. */
  1293. int
  1294. node_ipv6_or_preferred(const node_t *node)
  1295. {
  1296. const or_options_t *options = get_options();
  1297. tor_addr_port_t ipv4_addr;
  1298. node_assert_ok(node);
  1299. /* XX/teor - node->ipv6_preferred is set from
  1300. * fascist_firewall_prefer_ipv6_orport() each time the consensus is loaded.
  1301. */
  1302. if (!fascist_firewall_use_ipv6(options)) {
  1303. return 0;
  1304. } else if (node->ipv6_preferred || node_get_prim_orport(node, &ipv4_addr)) {
  1305. return node_has_ipv6_orport(node);
  1306. }
  1307. return 0;
  1308. }
  1309. #define RETURN_IPV4_AP(r, port_field, ap_out) \
  1310. STMT_BEGIN \
  1311. if (r && tor_addr_port_is_valid_ipv4h((r)->addr, (r)->port_field, 0)) { \
  1312. tor_addr_from_ipv4h(&(ap_out)->addr, (r)->addr); \
  1313. (ap_out)->port = (r)->port_field; \
  1314. return 0; \
  1315. } \
  1316. STMT_END
  1317. /** Copy the primary (IPv4) OR port (IP address and TCP port) for
  1318. * <b>node</b> into *<b>ap_out</b>. Return 0 if a valid address and
  1319. * port was copied, else return non-zero.*/
  1320. int
  1321. node_get_prim_orport(const node_t *node, tor_addr_port_t *ap_out)
  1322. {
  1323. node_assert_ok(node);
  1324. tor_assert(ap_out);
  1325. /* Clear the address, as a safety precaution if calling functions ignore the
  1326. * return value */
  1327. tor_addr_make_null(&ap_out->addr, AF_INET);
  1328. ap_out->port = 0;
  1329. /* Check ri first, because rewrite_node_address_for_bridge() updates
  1330. * node->ri with the configured bridge address. */
  1331. RETURN_IPV4_AP(node->ri, or_port, ap_out);
  1332. RETURN_IPV4_AP(node->rs, or_port, ap_out);
  1333. /* Microdescriptors only have an IPv6 address */
  1334. return -1;
  1335. }
  1336. /** Copy the preferred OR port (IP address and TCP port) for
  1337. * <b>node</b> into *<b>ap_out</b>. */
  1338. void
  1339. node_get_pref_orport(const node_t *node, tor_addr_port_t *ap_out)
  1340. {
  1341. tor_assert(ap_out);
  1342. if (node_ipv6_or_preferred(node)) {
  1343. node_get_pref_ipv6_orport(node, ap_out);
  1344. } else {
  1345. /* the primary ORPort is always on IPv4 */
  1346. node_get_prim_orport(node, ap_out);
  1347. }
  1348. }
  1349. /** Copy the preferred IPv6 OR port (IP address and TCP port) for
  1350. * <b>node</b> into *<b>ap_out</b>. */
  1351. void
  1352. node_get_pref_ipv6_orport(const node_t *node, tor_addr_port_t *ap_out)
  1353. {
  1354. node_assert_ok(node);
  1355. tor_assert(ap_out);
  1356. /* Check ri first, because rewrite_node_address_for_bridge() updates
  1357. * node->ri with the configured bridge address.
  1358. * Prefer rs over md for consistency with the fascist_firewall_* functions.
  1359. * Check if the address or port are valid, and try another alternative
  1360. * if they are not. */
  1361. if (node->ri && tor_addr_port_is_valid(&node->ri->ipv6_addr,
  1362. node->ri->ipv6_orport, 0)) {
  1363. tor_addr_copy(&ap_out->addr, &node->ri->ipv6_addr);
  1364. ap_out->port = node->ri->ipv6_orport;
  1365. } else if (node->rs && tor_addr_port_is_valid(&node->rs->ipv6_addr,
  1366. node->rs->ipv6_orport, 0)) {
  1367. tor_addr_copy(&ap_out->addr, &node->rs->ipv6_addr);
  1368. ap_out->port = node->rs->ipv6_orport;
  1369. } else if (node->md && tor_addr_port_is_valid(&node->md->ipv6_addr,
  1370. node->md->ipv6_orport, 0)) {
  1371. tor_addr_copy(&ap_out->addr, &node->md->ipv6_addr);
  1372. ap_out->port = node->md->ipv6_orport;
  1373. } else {
  1374. tor_addr_make_null(&ap_out->addr, AF_INET6);
  1375. ap_out->port = 0;
  1376. }
  1377. }
  1378. /** Return 1 if we prefer the IPv6 address and Dir TCP port of
  1379. * <b>node</b>, else 0.
  1380. *
  1381. * We prefer the IPv6 address if the router has an IPv6 address,
  1382. * and we can use IPv6 addresses, and:
  1383. * i) the router has no IPv4 Dir address.
  1384. * or
  1385. * ii) our preference is for IPv6 Dir addresses.
  1386. *
  1387. * If there is no node, use fascist_firewall_prefer_ipv6_dirport().
  1388. */
  1389. int
  1390. node_ipv6_dir_preferred(const node_t *node)
  1391. {
  1392. const or_options_t *options = get_options();
  1393. tor_addr_port_t ipv4_addr;
  1394. node_assert_ok(node);
  1395. /* node->ipv6_preferred is set from fascist_firewall_prefer_ipv6_orport(),
  1396. * so we can't use it to determine DirPort IPv6 preference.
  1397. * This means that bridge clients will use IPv4 DirPorts by default.
  1398. */
  1399. if (!fascist_firewall_use_ipv6(options)) {
  1400. return 0;
  1401. } else if (node_get_prim_dirport(node, &ipv4_addr)
  1402. || fascist_firewall_prefer_ipv6_dirport(get_options())) {
  1403. return node_has_ipv6_dirport(node);
  1404. }
  1405. return 0;
  1406. }
  1407. /** Copy the primary (IPv4) Dir port (IP address and TCP port) for
  1408. * <b>node</b> into *<b>ap_out</b>. Return 0 if a valid address and
  1409. * port was copied, else return non-zero.*/
  1410. int
  1411. node_get_prim_dirport(const node_t *node, tor_addr_port_t *ap_out)
  1412. {
  1413. node_assert_ok(node);
  1414. tor_assert(ap_out);
  1415. /* Check ri first, because rewrite_node_address_for_bridge() updates
  1416. * node->ri with the configured bridge address. */
  1417. RETURN_IPV4_AP(node->ri, dir_port, ap_out);
  1418. RETURN_IPV4_AP(node->rs, dir_port, ap_out);
  1419. /* Microdescriptors only have an IPv6 address */
  1420. return -1;
  1421. }
  1422. #undef RETURN_IPV4_AP
  1423. /** Copy the preferred Dir port (IP address and TCP port) for
  1424. * <b>node</b> into *<b>ap_out</b>. */
  1425. void
  1426. node_get_pref_dirport(const node_t *node, tor_addr_port_t *ap_out)
  1427. {
  1428. tor_assert(ap_out);
  1429. if (node_ipv6_dir_preferred(node)) {
  1430. node_get_pref_ipv6_dirport(node, ap_out);
  1431. } else {
  1432. /* the primary DirPort is always on IPv4 */
  1433. node_get_prim_dirport(node, ap_out);
  1434. }
  1435. }
  1436. /** Copy the preferred IPv6 Dir port (IP address and TCP port) for
  1437. * <b>node</b> into *<b>ap_out</b>. */
  1438. void
  1439. node_get_pref_ipv6_dirport(const node_t *node, tor_addr_port_t *ap_out)
  1440. {
  1441. node_assert_ok(node);
  1442. tor_assert(ap_out);
  1443. /* Check ri first, because rewrite_node_address_for_bridge() updates
  1444. * node->ri with the configured bridge address.
  1445. * Prefer rs over md for consistency with the fascist_firewall_* functions.
  1446. * Check if the address or port are valid, and try another alternative
  1447. * if they are not. */
  1448. /* Assume IPv4 and IPv6 dirports are the same */
  1449. if (node->ri && tor_addr_port_is_valid(&node->ri->ipv6_addr,
  1450. node->ri->dir_port, 0)) {
  1451. tor_addr_copy(&ap_out->addr, &node->ri->ipv6_addr);
  1452. ap_out->port = node->ri->dir_port;
  1453. } else if (node->rs && tor_addr_port_is_valid(&node->rs->ipv6_addr,
  1454. node->rs->dir_port, 0)) {
  1455. tor_addr_copy(&ap_out->addr, &node->rs->ipv6_addr);
  1456. ap_out->port = node->rs->dir_port;
  1457. } else {
  1458. tor_addr_make_null(&ap_out->addr, AF_INET6);
  1459. ap_out->port = 0;
  1460. }
  1461. }
  1462. /** Return true iff <b>md</b> has a curve25519 onion key.
  1463. * Use node_has_curve25519_onion_key() instead of calling this directly. */
  1464. static int
  1465. microdesc_has_curve25519_onion_key(const microdesc_t *md)
  1466. {
  1467. if (!md) {
  1468. return 0;
  1469. }
  1470. if (!md->onion_curve25519_pkey) {
  1471. return 0;
  1472. }
  1473. if (tor_mem_is_zero((const char*)md->onion_curve25519_pkey->public_key,
  1474. CURVE25519_PUBKEY_LEN)) {
  1475. return 0;
  1476. }
  1477. return 1;
  1478. }
  1479. /** Return true iff <b>node</b> has a curve25519 onion key. */
  1480. int
  1481. node_has_curve25519_onion_key(const node_t *node)
  1482. {
  1483. return node_get_curve25519_onion_key(node) != NULL;
  1484. }
  1485. /** Return the curve25519 key of <b>node</b>, or NULL if none. */
  1486. const curve25519_public_key_t *
  1487. node_get_curve25519_onion_key(const node_t *node)
  1488. {
  1489. if (!node)
  1490. return NULL;
  1491. if (routerinfo_has_curve25519_onion_key(node->ri))
  1492. return node->ri->onion_curve25519_pkey;
  1493. else if (microdesc_has_curve25519_onion_key(node->md))
  1494. return node->md->onion_curve25519_pkey;
  1495. else
  1496. return NULL;
  1497. }
  1498. /** Refresh the country code of <b>ri</b>. This function MUST be called on
  1499. * each router when the GeoIP database is reloaded, and on all new routers. */
  1500. void
  1501. node_set_country(node_t *node)
  1502. {
  1503. tor_addr_t addr = TOR_ADDR_NULL;
  1504. /* XXXXipv6 */
  1505. if (node->rs)
  1506. tor_addr_from_ipv4h(&addr, node->rs->addr);
  1507. else if (node->ri)
  1508. tor_addr_from_ipv4h(&addr, node->ri->addr);
  1509. node->country = geoip_get_country_by_addr(&addr);
  1510. }
  1511. /** Set the country code of all routers in the routerlist. */
  1512. void
  1513. nodelist_refresh_countries(void)
  1514. {
  1515. smartlist_t *nodes = nodelist_get_list();
  1516. SMARTLIST_FOREACH(nodes, node_t *, node,
  1517. node_set_country(node));
  1518. }
  1519. /** Return true iff router1 and router2 have similar enough network addresses
  1520. * that we should treat them as being in the same family */
  1521. int
  1522. addrs_in_same_network_family(const tor_addr_t *a1,
  1523. const tor_addr_t *a2)
  1524. {
  1525. return 0 == tor_addr_compare_masked(a1, a2, 16, CMP_SEMANTIC);
  1526. }
  1527. /** Return true if <b>node</b>'s nickname matches <b>nickname</b>
  1528. * (case-insensitive), or if <b>node's</b> identity key digest
  1529. * matches a hexadecimal value stored in <b>nickname</b>. Return
  1530. * false otherwise. */
  1531. static int
  1532. node_nickname_matches(const node_t *node, const char *nickname)
  1533. {
  1534. const char *n = node_get_nickname(node);
  1535. if (n && nickname[0]!='$' && !strcasecmp(n, nickname))
  1536. return 1;
  1537. return hex_digest_nickname_matches(nickname,
  1538. node->identity,
  1539. n);
  1540. }
  1541. /** Return true iff <b>node</b> is named by some nickname in <b>lst</b>. */
  1542. static inline int
  1543. node_in_nickname_smartlist(const smartlist_t *lst, const node_t *node)
  1544. {
  1545. if (!lst) return 0;
  1546. SMARTLIST_FOREACH(lst, const char *, name, {
  1547. if (node_nickname_matches(node, name))
  1548. return 1;
  1549. });
  1550. return 0;
  1551. }
  1552. /** Return true iff r1 and r2 are in the same family, but not the same
  1553. * router. */
  1554. int
  1555. nodes_in_same_family(const node_t *node1, const node_t *node2)
  1556. {
  1557. const or_options_t *options = get_options();
  1558. /* Are they in the same family because of their addresses? */
  1559. if (options->EnforceDistinctSubnets) {
  1560. tor_addr_t a1, a2;
  1561. node_get_addr(node1, &a1);
  1562. node_get_addr(node2, &a2);
  1563. if (addrs_in_same_network_family(&a1, &a2))
  1564. return 1;
  1565. }
  1566. /* Are they in the same family because the agree they are? */
  1567. {
  1568. const smartlist_t *f1, *f2;
  1569. f1 = node_get_declared_family(node1);
  1570. f2 = node_get_declared_family(node2);
  1571. if (f1 && f2 &&
  1572. node_in_nickname_smartlist(f1, node2) &&
  1573. node_in_nickname_smartlist(f2, node1))
  1574. return 1;
  1575. }
  1576. /* Are they in the same option because the user says they are? */
  1577. if (options->NodeFamilySets) {
  1578. SMARTLIST_FOREACH(options->NodeFamilySets, const routerset_t *, rs, {
  1579. if (routerset_contains_node(rs, node1) &&
  1580. routerset_contains_node(rs, node2))
  1581. return 1;
  1582. });
  1583. }
  1584. return 0;
  1585. }
  1586. /**
  1587. * Add all the family of <b>node</b>, including <b>node</b> itself, to
  1588. * the smartlist <b>sl</b>.
  1589. *
  1590. * This is used to make sure we don't pick siblings in a single path, or
  1591. * pick more than one relay from a family for our entry guard list.
  1592. * Note that a node may be added to <b>sl</b> more than once if it is
  1593. * part of <b>node</b>'s family for more than one reason.
  1594. */
  1595. void
  1596. nodelist_add_node_and_family(smartlist_t *sl, const node_t *node)
  1597. {
  1598. const smartlist_t *all_nodes = nodelist_get_list();
  1599. const smartlist_t *declared_family;
  1600. const or_options_t *options = get_options();
  1601. tor_assert(node);
  1602. declared_family = node_get_declared_family(node);
  1603. /* Let's make sure that we have the node itself, if it's a real node. */
  1604. {
  1605. const node_t *real_node = node_get_by_id(node->identity);
  1606. if (real_node)
  1607. smartlist_add(sl, (node_t*)real_node);
  1608. }
  1609. /* First, add any nodes with similar network addresses. */
  1610. if (options->EnforceDistinctSubnets) {
  1611. tor_addr_t node_addr;
  1612. node_get_addr(node, &node_addr);
  1613. SMARTLIST_FOREACH_BEGIN(all_nodes, const node_t *, node2) {
  1614. tor_addr_t a;
  1615. node_get_addr(node2, &a);
  1616. if (addrs_in_same_network_family(&a, &node_addr))
  1617. smartlist_add(sl, (void*)node2);
  1618. } SMARTLIST_FOREACH_END(node2);
  1619. }
  1620. /* Now, add all nodes in the declared_family of this node, if they
  1621. * also declare this node to be in their family. */
  1622. if (declared_family) {
  1623. /* Add every r such that router declares familyness with node, and node
  1624. * declares familyhood with router. */
  1625. SMARTLIST_FOREACH_BEGIN(declared_family, const char *, name) {
  1626. const node_t *node2;
  1627. const smartlist_t *family2;
  1628. if (!(node2 = node_get_by_nickname(name, NNF_NO_WARN_UNNAMED)))
  1629. continue;
  1630. if (!(family2 = node_get_declared_family(node2)))
  1631. continue;
  1632. SMARTLIST_FOREACH_BEGIN(family2, const char *, name2) {
  1633. if (node_nickname_matches(node, name2)) {
  1634. smartlist_add(sl, (void*)node2);
  1635. break;
  1636. }
  1637. } SMARTLIST_FOREACH_END(name2);
  1638. } SMARTLIST_FOREACH_END(name);
  1639. }
  1640. /* If the user declared any families locally, honor those too. */
  1641. if (options->NodeFamilySets) {
  1642. SMARTLIST_FOREACH(options->NodeFamilySets, const routerset_t *, rs, {
  1643. if (routerset_contains_node(rs, node)) {
  1644. routerset_get_all_nodes(sl, rs, NULL, 0);
  1645. }
  1646. });
  1647. }
  1648. }
  1649. /** Find a router that's up, that has this IP address, and
  1650. * that allows exit to this address:port, or return NULL if there
  1651. * isn't a good one.
  1652. * Don't exit enclave to excluded relays -- it wouldn't actually
  1653. * hurt anything, but this way there are fewer confused users.
  1654. */
  1655. const node_t *
  1656. router_find_exact_exit_enclave(const char *address, uint16_t port)
  1657. {/*XXXX MOVE*/
  1658. uint32_t addr;
  1659. struct in_addr in;
  1660. tor_addr_t a;
  1661. const or_options_t *options = get_options();
  1662. if (!tor_inet_aton(address, &in))
  1663. return NULL; /* it's not an IP already */
  1664. addr = ntohl(in.s_addr);
  1665. tor_addr_from_ipv4h(&a, addr);
  1666. SMARTLIST_FOREACH(nodelist_get_list(), const node_t *, node, {
  1667. if (node_get_addr_ipv4h(node) == addr &&
  1668. node->is_running &&
  1669. compare_tor_addr_to_node_policy(&a, port, node) ==
  1670. ADDR_POLICY_ACCEPTED &&
  1671. !routerset_contains_node(options->ExcludeExitNodesUnion_, node))
  1672. return node;
  1673. });
  1674. return NULL;
  1675. }
  1676. /** Return 1 if <b>router</b> is not suitable for these parameters, else 0.
  1677. * If <b>need_uptime</b> is non-zero, we require a minimum uptime.
  1678. * If <b>need_capacity</b> is non-zero, we require a minimum advertised
  1679. * bandwidth.
  1680. * If <b>need_guard</b>, we require that the router is a possible entry guard.
  1681. */
  1682. int
  1683. node_is_unreliable(const node_t *node, int need_uptime,
  1684. int need_capacity, int need_guard)
  1685. {
  1686. if (need_uptime && !node->is_stable)
  1687. return 1;
  1688. if (need_capacity && !node->is_fast)
  1689. return 1;
  1690. if (need_guard && !node->is_possible_guard)
  1691. return 1;
  1692. return 0;
  1693. }
  1694. /** Return 1 if all running sufficiently-stable routers we can use will reject
  1695. * addr:port. Return 0 if any might accept it. */
  1696. int
  1697. router_exit_policy_all_nodes_reject(const tor_addr_t *addr, uint16_t port,
  1698. int need_uptime)
  1699. {
  1700. addr_policy_result_t r;
  1701. SMARTLIST_FOREACH_BEGIN(nodelist_get_list(), const node_t *, node) {
  1702. if (node->is_running &&
  1703. !node_is_unreliable(node, need_uptime, 0, 0)) {
  1704. r = compare_tor_addr_to_node_policy(addr, port, node);
  1705. if (r != ADDR_POLICY_REJECTED && r != ADDR_POLICY_PROBABLY_REJECTED)
  1706. return 0; /* this one could be ok. good enough. */
  1707. }
  1708. } SMARTLIST_FOREACH_END(node);
  1709. return 1; /* all will reject. */
  1710. }
  1711. /** Mark the router with ID <b>digest</b> as running or non-running
  1712. * in our routerlist. */
  1713. void
  1714. router_set_status(const char *digest, int up)
  1715. {
  1716. node_t *node;
  1717. tor_assert(digest);
  1718. SMARTLIST_FOREACH(router_get_fallback_dir_servers(),
  1719. dir_server_t *, d,
  1720. if (tor_memeq(d->digest, digest, DIGEST_LEN))
  1721. d->is_running = up);
  1722. SMARTLIST_FOREACH(router_get_trusted_dir_servers(),
  1723. dir_server_t *, d,
  1724. if (tor_memeq(d->digest, digest, DIGEST_LEN))
  1725. d->is_running = up);
  1726. node = node_get_mutable_by_id(digest);
  1727. if (node) {
  1728. #if 0
  1729. log_debug(LD_DIR,"Marking router %s as %s.",
  1730. node_describe(node), up ? "up" : "down");
  1731. #endif
  1732. if (!up && node_is_me(node) && !net_is_disabled())
  1733. log_warn(LD_NET, "We just marked ourself as down. Are your external "
  1734. "addresses reachable?");
  1735. if (bool_neq(node->is_running, up))
  1736. router_dir_info_changed();
  1737. node->is_running = up;
  1738. }
  1739. }
  1740. /** True iff, the last time we checked whether we had enough directory info
  1741. * to build circuits, the answer was "yes". If there are no exits in the
  1742. * consensus, we act as if we have 100% of the exit directory info. */
  1743. static int have_min_dir_info = 0;
  1744. /** Does the consensus contain nodes that can exit? */
  1745. static consensus_path_type_t have_consensus_path = CONSENSUS_PATH_UNKNOWN;
  1746. /** True iff enough has changed since the last time we checked whether we had
  1747. * enough directory info to build circuits that our old answer can no longer
  1748. * be trusted. */
  1749. static int need_to_update_have_min_dir_info = 1;
  1750. /** String describing what we're missing before we have enough directory
  1751. * info. */
  1752. static char dir_info_status[512] = "";
  1753. /** Return true iff we have enough consensus information to
  1754. * start building circuits. Right now, this means "a consensus that's
  1755. * less than a day old, and at least 60% of router descriptors (configurable),
  1756. * weighted by bandwidth. Treat the exit fraction as 100% if there are
  1757. * no exits in the consensus."
  1758. * To obtain the final weighted bandwidth, we multiply the
  1759. * weighted bandwidth fraction for each position (guard, middle, exit). */
  1760. MOCK_IMPL(int,
  1761. router_have_minimum_dir_info,(void))
  1762. {
  1763. static int logged_delay=0;
  1764. const char *delay_fetches_msg = NULL;
  1765. if (should_delay_dir_fetches(get_options(), &delay_fetches_msg)) {
  1766. if (!logged_delay)
  1767. log_notice(LD_DIR, "Delaying directory fetches: %s", delay_fetches_msg);
  1768. logged_delay=1;
  1769. strlcpy(dir_info_status, delay_fetches_msg, sizeof(dir_info_status));
  1770. return 0;
  1771. }
  1772. logged_delay = 0; /* reset it if we get this far */
  1773. if (PREDICT_UNLIKELY(need_to_update_have_min_dir_info)) {
  1774. update_router_have_minimum_dir_info();
  1775. }
  1776. return have_min_dir_info;
  1777. }
  1778. /** Set to CONSENSUS_PATH_EXIT if there is at least one exit node
  1779. * in the consensus. We update this flag in compute_frac_paths_available if
  1780. * there is at least one relay that has an Exit flag in the consensus.
  1781. * Used to avoid building exit circuits when they will almost certainly fail.
  1782. * Set to CONSENSUS_PATH_INTERNAL if there are no exits in the consensus.
  1783. * (This situation typically occurs during bootstrap of a test network.)
  1784. * Set to CONSENSUS_PATH_UNKNOWN if we have never checked, or have
  1785. * reason to believe our last known value was invalid or has expired.
  1786. * If we're in a network with TestingDirAuthVoteExit set,
  1787. * this can cause router_have_consensus_path() to be set to
  1788. * CONSENSUS_PATH_EXIT, even if there are no nodes with accept exit policies.
  1789. */
  1790. MOCK_IMPL(consensus_path_type_t,
  1791. router_have_consensus_path, (void))
  1792. {
  1793. return have_consensus_path;
  1794. }
  1795. /** Called when our internal view of the directory has changed. This can be
  1796. * when the authorities change, networkstatuses change, the list of routerdescs
  1797. * changes, or number of running routers changes.
  1798. */
  1799. void
  1800. router_dir_info_changed(void)
  1801. {
  1802. need_to_update_have_min_dir_info = 1;
  1803. rend_hsdir_routers_changed();
  1804. hs_service_dir_info_changed();
  1805. hs_client_dir_info_changed();
  1806. }
  1807. /** Return a string describing what we're missing before we have enough
  1808. * directory info. */
  1809. const char *
  1810. get_dir_info_status_string(void)
  1811. {
  1812. return dir_info_status;
  1813. }
  1814. /** Iterate over the servers listed in <b>consensus</b>, and count how many of
  1815. * them seem like ones we'd use (store this in *<b>num_usable</b>), and how
  1816. * many of <em>those</em> we have descriptors for (store this in
  1817. * *<b>num_present</b>).
  1818. *
  1819. * If <b>in_set</b> is non-NULL, only consider those routers in <b>in_set</b>.
  1820. * If <b>exit_only</b> is USABLE_DESCRIPTOR_EXIT_ONLY, only consider nodes
  1821. * with the Exit flag.
  1822. * If *<b>descs_out</b> is present, add a node_t for each usable descriptor
  1823. * to it.
  1824. */
  1825. static void
  1826. count_usable_descriptors(int *num_present, int *num_usable,
  1827. smartlist_t *descs_out,
  1828. const networkstatus_t *consensus,
  1829. time_t now,
  1830. routerset_t *in_set,
  1831. usable_descriptor_t exit_only)
  1832. {
  1833. const int md = (consensus->flavor == FLAV_MICRODESC);
  1834. *num_present = 0, *num_usable = 0;
  1835. SMARTLIST_FOREACH_BEGIN(consensus->routerstatus_list, routerstatus_t *, rs)
  1836. {
  1837. const node_t *node = node_get_by_id(rs->identity_digest);
  1838. if (!node)
  1839. continue; /* This would be a bug: every entry in the consensus is
  1840. * supposed to have a node. */
  1841. if (exit_only == USABLE_DESCRIPTOR_EXIT_ONLY && ! rs->is_exit)
  1842. continue;
  1843. if (in_set && ! routerset_contains_routerstatus(in_set, rs, -1))
  1844. continue;
  1845. if (client_would_use_router(rs, now)) {
  1846. const char * const digest = rs->descriptor_digest;
  1847. int present;
  1848. ++*num_usable; /* the consensus says we want it. */
  1849. if (md)
  1850. present = NULL != microdesc_cache_lookup_by_digest256(NULL, digest);
  1851. else
  1852. present = NULL != router_get_by_descriptor_digest(digest);
  1853. if (present) {
  1854. /* we have the descriptor listed in the consensus. */
  1855. ++*num_present;
  1856. }
  1857. if (descs_out)
  1858. smartlist_add(descs_out, (node_t*)node);
  1859. }
  1860. }
  1861. SMARTLIST_FOREACH_END(rs);
  1862. log_debug(LD_DIR, "%d usable, %d present (%s%s).",
  1863. *num_usable, *num_present,
  1864. md ? "microdesc" : "desc",
  1865. exit_only == USABLE_DESCRIPTOR_EXIT_ONLY ? " exits" : "s");
  1866. }
  1867. /** Return an estimate of which fraction of usable paths through the Tor
  1868. * network we have available for use. Count how many routers seem like ones
  1869. * we'd use (store this in *<b>num_usable_out</b>), and how many of
  1870. * <em>those</em> we have descriptors for (store this in
  1871. * *<b>num_present_out</b>.)
  1872. *
  1873. * If **<b>status_out</b> is present, allocate a new string and print the
  1874. * available percentages of guard, middle, and exit nodes to it, noting
  1875. * whether there are exits in the consensus.
  1876. * If there are no exits in the consensus, we treat the exit fraction as 100%,
  1877. * but set router_have_consensus_path() so that we can only build internal
  1878. * paths. */
  1879. static double
  1880. compute_frac_paths_available(const networkstatus_t *consensus,
  1881. const or_options_t *options, time_t now,
  1882. int *num_present_out, int *num_usable_out,
  1883. char **status_out)
  1884. {
  1885. smartlist_t *guards = smartlist_new();
  1886. smartlist_t *mid = smartlist_new();
  1887. smartlist_t *exits = smartlist_new();
  1888. double f_guard, f_mid, f_exit;
  1889. double f_path = 0.0;
  1890. /* Used to determine whether there are any exits in the consensus */
  1891. int np = 0;
  1892. /* Used to determine whether there are any exits with descriptors */
  1893. int nu = 0;
  1894. const int authdir = authdir_mode_v3(options);
  1895. count_usable_descriptors(num_present_out, num_usable_out,
  1896. mid, consensus, now, NULL,
  1897. USABLE_DESCRIPTOR_ALL);
  1898. if (options->EntryNodes) {
  1899. count_usable_descriptors(&np, &nu, guards, consensus, now,
  1900. options->EntryNodes, USABLE_DESCRIPTOR_ALL);
  1901. } else {
  1902. SMARTLIST_FOREACH(mid, const node_t *, node, {
  1903. if (authdir) {
  1904. if (node->rs && node->rs->is_possible_guard)
  1905. smartlist_add(guards, (node_t*)node);
  1906. } else {
  1907. if (node->is_possible_guard)
  1908. smartlist_add(guards, (node_t*)node);
  1909. }
  1910. });
  1911. }
  1912. /* All nodes with exit flag
  1913. * If we're in a network with TestingDirAuthVoteExit set,
  1914. * this can cause false positives on have_consensus_path,
  1915. * incorrectly setting it to CONSENSUS_PATH_EXIT. This is
  1916. * an unavoidable feature of forcing authorities to declare
  1917. * certain nodes as exits.
  1918. */
  1919. count_usable_descriptors(&np, &nu, exits, consensus, now,
  1920. NULL, USABLE_DESCRIPTOR_EXIT_ONLY);
  1921. log_debug(LD_NET,
  1922. "%s: %d present, %d usable",
  1923. "exits",
  1924. np,
  1925. nu);
  1926. /* We need at least 1 exit present in the consensus to consider
  1927. * building exit paths */
  1928. /* Update our understanding of whether the consensus has exits */
  1929. consensus_path_type_t old_have_consensus_path = have_consensus_path;
  1930. have_consensus_path = ((nu > 0) ?
  1931. CONSENSUS_PATH_EXIT :
  1932. CONSENSUS_PATH_INTERNAL);
  1933. if (have_consensus_path == CONSENSUS_PATH_INTERNAL
  1934. && old_have_consensus_path != have_consensus_path) {
  1935. log_notice(LD_NET,
  1936. "The current consensus has no exit nodes. "
  1937. "Tor can only build internal paths, "
  1938. "such as paths to hidden services.");
  1939. /* However, exit nodes can reachability self-test using this consensus,
  1940. * join the network, and appear in a later consensus. This will allow
  1941. * the network to build exit paths, such as paths for world wide web
  1942. * browsing (as distinct from hidden service web browsing). */
  1943. }
  1944. f_guard = frac_nodes_with_descriptors(guards, WEIGHT_FOR_GUARD);
  1945. f_mid = frac_nodes_with_descriptors(mid, WEIGHT_FOR_MID);
  1946. f_exit = frac_nodes_with_descriptors(exits, WEIGHT_FOR_EXIT);
  1947. log_debug(LD_NET,
  1948. "f_guard: %.2f, f_mid: %.2f, f_exit: %.2f",
  1949. f_guard,
  1950. f_mid,
  1951. f_exit);
  1952. smartlist_free(guards);
  1953. smartlist_free(mid);
  1954. smartlist_free(exits);
  1955. if (options->ExitNodes) {
  1956. double f_myexit, f_myexit_unflagged;
  1957. smartlist_t *myexits= smartlist_new();
  1958. smartlist_t *myexits_unflagged = smartlist_new();
  1959. /* All nodes with exit flag in ExitNodes option */
  1960. count_usable_descriptors(&np, &nu, myexits, consensus, now,
  1961. options->ExitNodes, USABLE_DESCRIPTOR_EXIT_ONLY);
  1962. log_debug(LD_NET,
  1963. "%s: %d present, %d usable",
  1964. "myexits",
  1965. np,
  1966. nu);
  1967. /* Now compute the nodes in the ExitNodes option where which we don't know
  1968. * what their exit policy is, or we know it permits something. */
  1969. count_usable_descriptors(&np, &nu, myexits_unflagged,
  1970. consensus, now,
  1971. options->ExitNodes, USABLE_DESCRIPTOR_ALL);
  1972. log_debug(LD_NET,
  1973. "%s: %d present, %d usable",
  1974. "myexits_unflagged (initial)",
  1975. np,
  1976. nu);
  1977. SMARTLIST_FOREACH_BEGIN(myexits_unflagged, const node_t *, node) {
  1978. if (node_has_preferred_descriptor(node, 0) &&
  1979. node_exit_policy_rejects_all(node)) {
  1980. SMARTLIST_DEL_CURRENT(myexits_unflagged, node);
  1981. /* this node is not actually an exit */
  1982. np--;
  1983. /* this node is unusable as an exit */
  1984. nu--;
  1985. }
  1986. } SMARTLIST_FOREACH_END(node);
  1987. log_debug(LD_NET,
  1988. "%s: %d present, %d usable",
  1989. "myexits_unflagged (final)",
  1990. np,
  1991. nu);
  1992. f_myexit= frac_nodes_with_descriptors(myexits,WEIGHT_FOR_EXIT);
  1993. f_myexit_unflagged=
  1994. frac_nodes_with_descriptors(myexits_unflagged,WEIGHT_FOR_EXIT);
  1995. log_debug(LD_NET,
  1996. "f_exit: %.2f, f_myexit: %.2f, f_myexit_unflagged: %.2f",
  1997. f_exit,
  1998. f_myexit,
  1999. f_myexit_unflagged);
  2000. /* If our ExitNodes list has eliminated every possible Exit node, and there
  2001. * were some possible Exit nodes, then instead consider nodes that permit
  2002. * exiting to some ports. */
  2003. if (smartlist_len(myexits) == 0 &&
  2004. smartlist_len(myexits_unflagged)) {
  2005. f_myexit = f_myexit_unflagged;
  2006. }
  2007. smartlist_free(myexits);
  2008. smartlist_free(myexits_unflagged);
  2009. /* This is a tricky point here: we don't want to make it easy for a
  2010. * directory to trickle exits to us until it learns which exits we have
  2011. * configured, so require that we have a threshold both of total exits
  2012. * and usable exits. */
  2013. if (f_myexit < f_exit)
  2014. f_exit = f_myexit;
  2015. }
  2016. /* if the consensus has no exits, treat the exit fraction as 100% */
  2017. if (router_have_consensus_path() != CONSENSUS_PATH_EXIT) {
  2018. f_exit = 1.0;
  2019. }
  2020. f_path = f_guard * f_mid * f_exit;
  2021. if (status_out)
  2022. tor_asprintf(status_out,
  2023. "%d%% of guards bw, "
  2024. "%d%% of midpoint bw, and "
  2025. "%d%% of exit bw%s = "
  2026. "%d%% of path bw",
  2027. (int)(f_guard*100),
  2028. (int)(f_mid*100),
  2029. (int)(f_exit*100),
  2030. (router_have_consensus_path() == CONSENSUS_PATH_EXIT ?
  2031. "" :
  2032. " (no exits in consensus)"),
  2033. (int)(f_path*100));
  2034. return f_path;
  2035. }
  2036. /** We just fetched a new set of descriptors. Compute how far through
  2037. * the "loading descriptors" bootstrapping phase we are, so we can inform
  2038. * the controller of our progress. */
  2039. int
  2040. count_loading_descriptors_progress(void)
  2041. {
  2042. int num_present = 0, num_usable=0;
  2043. time_t now = time(NULL);
  2044. const or_options_t *options = get_options();
  2045. const networkstatus_t *consensus =
  2046. networkstatus_get_reasonably_live_consensus(now,usable_consensus_flavor());
  2047. double paths, fraction;
  2048. if (!consensus)
  2049. return 0; /* can't count descriptors if we have no list of them */
  2050. paths = compute_frac_paths_available(consensus, options, now,
  2051. &num_present, &num_usable,
  2052. NULL);
  2053. fraction = paths / get_frac_paths_needed_for_circs(options,consensus);
  2054. if (fraction > 1.0)
  2055. return 0; /* it's not the number of descriptors holding us back */
  2056. return BOOTSTRAP_STATUS_LOADING_DESCRIPTORS + (int)
  2057. (fraction*(BOOTSTRAP_STATUS_CONN_OR-1 -
  2058. BOOTSTRAP_STATUS_LOADING_DESCRIPTORS));
  2059. }
  2060. /** Return the fraction of paths needed before we're willing to build
  2061. * circuits, as configured in <b>options</b>, or in the consensus <b>ns</b>. */
  2062. static double
  2063. get_frac_paths_needed_for_circs(const or_options_t *options,
  2064. const networkstatus_t *ns)
  2065. {
  2066. #define DFLT_PCT_USABLE_NEEDED 60
  2067. if (options->PathsNeededToBuildCircuits >= 0.0) {
  2068. return options->PathsNeededToBuildCircuits;
  2069. } else {
  2070. return networkstatus_get_param(ns, "min_paths_for_circs_pct",
  2071. DFLT_PCT_USABLE_NEEDED,
  2072. 25, 95)/100.0;
  2073. }
  2074. }
  2075. /** Change the value of have_min_dir_info, setting it true iff we have enough
  2076. * network and router information to build circuits. Clear the value of
  2077. * need_to_update_have_min_dir_info. */
  2078. static void
  2079. update_router_have_minimum_dir_info(void)
  2080. {
  2081. time_t now = time(NULL);
  2082. int res;
  2083. int num_present=0, num_usable=0;
  2084. const or_options_t *options = get_options();
  2085. const networkstatus_t *consensus =
  2086. networkstatus_get_reasonably_live_consensus(now,usable_consensus_flavor());
  2087. int using_md;
  2088. if (!consensus) {
  2089. if (!networkstatus_get_latest_consensus())
  2090. strlcpy(dir_info_status, "We have no usable consensus.",
  2091. sizeof(dir_info_status));
  2092. else
  2093. strlcpy(dir_info_status, "We have no recent usable consensus.",
  2094. sizeof(dir_info_status));
  2095. res = 0;
  2096. goto done;
  2097. }
  2098. using_md = consensus->flavor == FLAV_MICRODESC;
  2099. /* Check fraction of available paths */
  2100. {
  2101. char *status = NULL;
  2102. double paths = compute_frac_paths_available(consensus, options, now,
  2103. &num_present, &num_usable,
  2104. &status);
  2105. if (paths < get_frac_paths_needed_for_circs(options,consensus)) {
  2106. tor_snprintf(dir_info_status, sizeof(dir_info_status),
  2107. "We need more %sdescriptors: we have %d/%d, and "
  2108. "can only build %d%% of likely paths. (We have %s.)",
  2109. using_md?"micro":"", num_present, num_usable,
  2110. (int)(paths*100), status);
  2111. tor_free(status);
  2112. res = 0;
  2113. control_event_bootstrap(BOOTSTRAP_STATUS_REQUESTING_DESCRIPTORS, 0);
  2114. goto done;
  2115. }
  2116. tor_free(status);
  2117. res = 1;
  2118. }
  2119. { /* Check entry guard dirinfo status */
  2120. char *guard_error = entry_guards_get_err_str_if_dir_info_missing(using_md,
  2121. num_present,
  2122. num_usable);
  2123. if (guard_error) {
  2124. strlcpy(dir_info_status, guard_error, sizeof(dir_info_status));
  2125. tor_free(guard_error);
  2126. res = 0;
  2127. goto done;
  2128. }
  2129. }
  2130. done:
  2131. /* If paths have just become available in this update. */
  2132. if (res && !have_min_dir_info) {
  2133. control_event_client_status(LOG_NOTICE, "ENOUGH_DIR_INFO");
  2134. if (control_event_bootstrap(BOOTSTRAP_STATUS_CONN_OR, 0) == 0) {
  2135. log_notice(LD_DIR,
  2136. "We now have enough directory information to build circuits.");
  2137. }
  2138. }
  2139. /* If paths have just become unavailable in this update. */
  2140. if (!res && have_min_dir_info) {
  2141. int quiet = directory_too_idle_to_fetch_descriptors(options, now);
  2142. tor_log(quiet ? LOG_INFO : LOG_NOTICE, LD_DIR,
  2143. "Our directory information is no longer up-to-date "
  2144. "enough to build circuits: %s", dir_info_status);
  2145. /* a) make us log when we next complete a circuit, so we know when Tor
  2146. * is back up and usable, and b) disable some activities that Tor
  2147. * should only do while circuits are working, like reachability tests
  2148. * and fetching bridge descriptors only over circuits. */
  2149. note_that_we_maybe_cant_complete_circuits();
  2150. have_consensus_path = CONSENSUS_PATH_UNKNOWN;
  2151. control_event_client_status(LOG_NOTICE, "NOT_ENOUGH_DIR_INFO");
  2152. }
  2153. have_min_dir_info = res;
  2154. need_to_update_have_min_dir_info = 0;
  2155. }