/* Copyright (c) 2009-2015, The Tor Project, Inc. */
/* See LICENSE for licensing information */
#include "or.h"
#include "circuitbuild.h"
#include "config.h"
#include "directory.h"
#include "dirserv.h"
#include "entrynodes.h"
#include "microdesc.h"
#include "networkstatus.h"
#include "nodelist.h"
#include "policies.h"
#include "router.h"
#include "routerlist.h"
#include "routerparse.h"
/** A data structure to hold a bunch of cached microdescriptors. There are
* two active files in the cache: a "cache file" that we mmap, and a "journal
* file" that we append to. Periodically, we rebuild the cache file to hold
* only the microdescriptors that we want to keep */
struct microdesc_cache_t {
/** Map from sha256-digest to microdesc_t for every microdesc_t in the
* cache. */
HT_HEAD(microdesc_map, microdesc_t) map;
/** Name of the cache file. */
char *cache_fname;
/** Name of the journal file. */
char *journal_fname;
/** Mmap'd contents of the cache file, or NULL if there is none. */
tor_mmap_t *cache_content;
/** Number of bytes used in the journal file. */
size_t journal_len;
/** Number of bytes in descriptors removed as too old. */
size_t bytes_dropped;
/** Total bytes of microdescriptor bodies we have added to this cache */
uint64_t total_len_seen;
/** Total number of microdescriptors we have added to this cache */
unsigned n_seen;
};
/** Helper: computes a hash of md to place it in a hash table. */
static INLINE unsigned int
microdesc_hash_(microdesc_t *md)
{
return (unsigned) siphash24g(md->digest, sizeof(md->digest));
}
/** Helper: compares a and for equality for hash-table purposes. */
static INLINE int
microdesc_eq_(microdesc_t *a, microdesc_t *b)
{
return tor_memeq(a->digest, b->digest, DIGEST256_LEN);
}
HT_PROTOTYPE(microdesc_map, microdesc_t, node,
microdesc_hash_, microdesc_eq_);
HT_GENERATE2(microdesc_map, microdesc_t, node,
microdesc_hash_, microdesc_eq_, 0.6,
tor_reallocarray_, tor_free_)
/** Write the body of md into f, with appropriate annotations.
* On success, return the total number of bytes written, and set
* *annotation_len_out to the number of bytes written as
* annotations. */
static ssize_t
dump_microdescriptor(int fd, microdesc_t *md, size_t *annotation_len_out)
{
ssize_t r = 0;
ssize_t written;
if (md->body == NULL) {
*annotation_len_out = 0;
return 0;
}
/* XXXX drops unknown annotations. */
if (md->last_listed) {
char buf[ISO_TIME_LEN+1];
char annotation[ISO_TIME_LEN+32];
format_iso_time(buf, md->last_listed);
tor_snprintf(annotation, sizeof(annotation), "@last-listed %s\n", buf);
if (write_all(fd, annotation, strlen(annotation), 0) < 0) {
log_warn(LD_DIR,
"Couldn't write microdescriptor annotation: %s",
strerror(errno));
return -1;
}
r += strlen(annotation);
*annotation_len_out = r;
} else {
*annotation_len_out = 0;
}
md->off = tor_fd_getpos(fd);
written = write_all(fd, md->body, md->bodylen, 0);
if (written != (ssize_t)md->bodylen) {
log_warn(LD_DIR,
"Couldn't dump microdescriptor (wrote %ld out of %lu): %s",
(long)written, (unsigned long)md->bodylen,
strerror(errno));
return -1;
}
r += md->bodylen;
return r;
}
/** Holds a pointer to the current microdesc_cache_t object, or NULL if no
* such object has been allocated. */
static microdesc_cache_t *the_microdesc_cache = NULL;
/** Return a pointer to the microdescriptor cache, loading it if necessary. */
microdesc_cache_t *
get_microdesc_cache(void)
{
if (PREDICT_UNLIKELY(the_microdesc_cache==NULL)) {
microdesc_cache_t *cache = tor_malloc_zero(sizeof(microdesc_cache_t));
HT_INIT(microdesc_map, &cache->map);
cache->cache_fname = get_datadir_fname("cached-microdescs");
cache->journal_fname = get_datadir_fname("cached-microdescs.new");
microdesc_cache_reload(cache);
the_microdesc_cache = cache;
}
return the_microdesc_cache;
}
/* There are three sources of microdescriptors:
1) Generated by us while acting as a directory authority.
2) Loaded from the cache on disk.
3) Downloaded.
*/
/** Decode the microdescriptors from the string starting at s and
* ending at eos, and store them in cache. If no_save,
* mark them as non-writable to disk. If where is SAVED_IN_CACHE,
* leave their bodies as pointers to the mmap'd cache. If where is
* SAVED_NOWHERE, do not allow annotations. If listed_at is not -1,
* set the last_listed field of every microdesc to listed_at. If
* requested_digests is non-null, then it contains a list of digests we mean
* to allow, so we should reject any non-requested microdesc with a different
* digest, and alter the list to contain only the digests of those microdescs
* we didn't find.
* Return a newly allocated list of the added microdescriptors, or NULL */
smartlist_t *
microdescs_add_to_cache(microdesc_cache_t *cache,
const char *s, const char *eos, saved_location_t where,
int no_save, time_t listed_at,
smartlist_t *requested_digests256)
{
void * const DIGEST_REQUESTED = (void*)1;
void * const DIGEST_RECEIVED = (void*)2;
void * const DIGEST_INVALID = (void*)3;
smartlist_t *descriptors, *added;
const int allow_annotations = (where != SAVED_NOWHERE);
smartlist_t *invalid_digests = smartlist_new();
descriptors = microdescs_parse_from_string(s, eos,
allow_annotations,
where, invalid_digests);
if (listed_at != (time_t)-1) {
SMARTLIST_FOREACH(descriptors, microdesc_t *, md,
md->last_listed = listed_at);
}
if (requested_digests256) {
digest256map_t *requested;
requested = digest256map_new();
/* Set requested[d] to DIGEST_REQUESTED for every md we requested. */
SMARTLIST_FOREACH(requested_digests256, const uint8_t *, cp,
digest256map_set(requested, cp, DIGEST_REQUESTED));
/* Set requested[d] to DIGEST_INVALID for every md we requested which we
* will never be able to parse. Remove the ones we didn't request from
* invalid_digests.
*/
SMARTLIST_FOREACH_BEGIN(invalid_digests, uint8_t *, cp) {
if (digest256map_get(requested, cp)) {
digest256map_set(requested, cp, DIGEST_INVALID);
} else {
tor_free(cp);
SMARTLIST_DEL_CURRENT(invalid_digests, cp);
}
} SMARTLIST_FOREACH_END(cp);
/* Update requested[d] to 2 for the mds we asked for and got. Delete the
* ones we never requested from the 'descriptors' smartlist.
*/
SMARTLIST_FOREACH_BEGIN(descriptors, microdesc_t *, md) {
if (digest256map_get(requested, (const uint8_t*)md->digest)) {
digest256map_set(requested, (const uint8_t*)md->digest,
DIGEST_RECEIVED);
} else {
log_fn(LOG_PROTOCOL_WARN, LD_DIR, "Received non-requested microdesc");
microdesc_free(md);
SMARTLIST_DEL_CURRENT(descriptors, md);
}
} SMARTLIST_FOREACH_END(md);
/* Remove the ones we got or the invalid ones from requested_digests256.
*/
SMARTLIST_FOREACH_BEGIN(requested_digests256, uint8_t *, cp) {
void *status = digest256map_get(requested, cp);
if (status == DIGEST_RECEIVED || status == DIGEST_INVALID) {
tor_free(cp);
SMARTLIST_DEL_CURRENT(requested_digests256, cp);
}
} SMARTLIST_FOREACH_END(cp);
digest256map_free(requested, NULL);
}
/* For every requested microdescriptor that was unparseable, mark it
* as not to be retried. */
if (smartlist_len(invalid_digests)) {
networkstatus_t *ns =
networkstatus_get_latest_consensus_by_flavor(FLAV_MICRODESC);
if (ns) {
SMARTLIST_FOREACH_BEGIN(invalid_digests, char *, d) {
routerstatus_t *rs =
router_get_mutable_consensus_status_by_descriptor_digest(ns, d);
if (rs && tor_memeq(d, rs->descriptor_digest, DIGEST256_LEN)) {
download_status_mark_impossible(&rs->dl_status);
}
} SMARTLIST_FOREACH_END(d);
}
}
SMARTLIST_FOREACH(invalid_digests, uint8_t *, d, tor_free(d));
smartlist_free(invalid_digests);
added = microdescs_add_list_to_cache(cache, descriptors, where, no_save);
smartlist_free(descriptors);
return added;
}
/** As microdescs_add_to_cache, but takes a list of microdescriptors instead of
* a string to decode. Frees any members of descriptors that it does
* not add. */
smartlist_t *
microdescs_add_list_to_cache(microdesc_cache_t *cache,
smartlist_t *descriptors, saved_location_t where,
int no_save)
{
smartlist_t *added;
open_file_t *open_file = NULL;
int fd = -1;
// int n_added = 0;
ssize_t size = 0;
if (where == SAVED_NOWHERE && !no_save) {
fd = start_writing_to_file(cache->journal_fname,
OPEN_FLAGS_APPEND|O_BINARY,
0600, &open_file);
if (fd < 0) {
log_warn(LD_DIR, "Couldn't append to journal in %s: %s",
cache->journal_fname, strerror(errno));
}
}
added = smartlist_new();
SMARTLIST_FOREACH_BEGIN(descriptors, microdesc_t *, md) {
microdesc_t *md2;
md2 = HT_FIND(microdesc_map, &cache->map, md);
if (md2) {
/* We already had this one. */
if (md2->last_listed < md->last_listed)
md2->last_listed = md->last_listed;
microdesc_free(md);
if (where != SAVED_NOWHERE)
cache->bytes_dropped += size;
continue;
}
/* Okay, it's a new one. */
if (fd >= 0) {
size_t annotation_len;
size = dump_microdescriptor(fd, md, &annotation_len);
if (size < 0) {
/* we already warned in dump_microdescriptor */
abort_writing_to_file(open_file);
fd = -1;
} else {
md->saved_location = SAVED_IN_JOURNAL;
cache->journal_len += size;
}
} else {
md->saved_location = where;
}
md->no_save = no_save;
HT_INSERT(microdesc_map, &cache->map, md);
md->held_in_map = 1;
smartlist_add(added, md);
++cache->n_seen;
cache->total_len_seen += md->bodylen;
} SMARTLIST_FOREACH_END(md);
if (fd >= 0) {
if (finish_writing_to_file(open_file) < 0) {
log_warn(LD_DIR, "Error appending to microdescriptor file: %s",
strerror(errno));
smartlist_clear(added);
return added;
}
}
{
networkstatus_t *ns = networkstatus_get_latest_consensus();
if (ns && ns->flavor == FLAV_MICRODESC)
SMARTLIST_FOREACH(added, microdesc_t *, md, nodelist_add_microdesc(md));
}
if (smartlist_len(added))
router_dir_info_changed();
return added;
}
/** Remove every microdescriptor in cache. */
void
microdesc_cache_clear(microdesc_cache_t *cache)
{
microdesc_t **entry, **next;
for (entry = HT_START(microdesc_map, &cache->map); entry; entry = next) {
microdesc_t *md = *entry;
next = HT_NEXT_RMV(microdesc_map, &cache->map, entry);
md->held_in_map = 0;
microdesc_free(md);
}
HT_CLEAR(microdesc_map, &cache->map);
if (cache->cache_content) {
int res = tor_munmap_file(cache->cache_content);
if (res != 0) {
log_warn(LD_FS,
"tor_munmap_file() failed clearing microdesc cache; "
"we are probably about to leak memory.");
/* TODO something smarter? */
}
cache->cache_content = NULL;
}
cache->total_len_seen = 0;
cache->n_seen = 0;
cache->bytes_dropped = 0;
}
/** Reload the contents of cache from disk. If it is empty, load it
* for the first time. Return 0 on success, -1 on failure. */
int
microdesc_cache_reload(microdesc_cache_t *cache)
{
struct stat st;
char *journal_content;
smartlist_t *added;
tor_mmap_t *mm;
int total = 0;
microdesc_cache_clear(cache);
mm = cache->cache_content = tor_mmap_file(cache->cache_fname);
if (mm) {
added = microdescs_add_to_cache(cache, mm->data, mm->data+mm->size,
SAVED_IN_CACHE, 0, -1, NULL);
if (added) {
total += smartlist_len(added);
smartlist_free(added);
}
}
journal_content = read_file_to_str(cache->journal_fname,
RFTS_IGNORE_MISSING, &st);
if (journal_content) {
cache->journal_len = (size_t) st.st_size;
added = microdescs_add_to_cache(cache, journal_content,
journal_content+st.st_size,
SAVED_IN_JOURNAL, 0, -1, NULL);
if (added) {
total += smartlist_len(added);
smartlist_free(added);
}
tor_free(journal_content);
}
log_info(LD_DIR, "Reloaded microdescriptor cache. Found %d descriptors.",
total);
microdesc_cache_rebuild(cache, 0 /* don't force */);
return 0;
}
/** By default, we remove any microdescriptors that have gone at least this
* long without appearing in a current consensus. */
#define TOLERATE_MICRODESC_AGE (7*24*60*60)
/** Remove all microdescriptors from cache that haven't been listed for
* a long time. Does not rebuild the cache on disk. If cutoff is
* positive, specifically remove microdescriptors that have been unlisted
* since cutoff. If force is true, remove microdescriptors even
* if we have no current live microdescriptor consensus.
*/
void
microdesc_cache_clean(microdesc_cache_t *cache, time_t cutoff, int force)
{
microdesc_t **mdp, *victim;
int dropped=0, kept=0;
size_t bytes_dropped = 0;
time_t now = time(NULL);
/* If we don't know a live consensus, don't believe last_listed values: we
* might be starting up after being down for a while. */
if (! force &&
! networkstatus_get_reasonably_live_consensus(now, FLAV_MICRODESC))
return;
if (cutoff <= 0)
cutoff = now - TOLERATE_MICRODESC_AGE;
for (mdp = HT_START(microdesc_map, &cache->map); mdp != NULL; ) {
const int is_old = (*mdp)->last_listed < cutoff;
const unsigned held_by_nodes = (*mdp)->held_by_nodes;
if (is_old && !held_by_nodes) {
++dropped;
victim = *mdp;
mdp = HT_NEXT_RMV(microdesc_map, &cache->map, mdp);
victim->held_in_map = 0;
bytes_dropped += victim->bodylen;
microdesc_free(victim);
} else {
if (is_old) {
/* It's old, but it has held_by_nodes set. That's not okay. */
/* Let's try to diagnose and fix #7164 . */
smartlist_t *nodes = nodelist_find_nodes_with_microdesc(*mdp);
const networkstatus_t *ns = networkstatus_get_latest_consensus();
long networkstatus_age = -1;
const int ht_badness = HT_REP_IS_BAD_(microdesc_map, &cache->map);
if (ns) {
networkstatus_age = now - ns->valid_after;
}
log_warn(LD_BUG, "Microdescriptor seemed very old "
"(last listed %d hours ago vs %d hour cutoff), but is still "
"marked as being held by %d node(s). I found %d node(s) "
"holding it. Current networkstatus is %ld hours old. "
"Hashtable badness is %d.",
(int)((now - (*mdp)->last_listed) / 3600),
(int)((now - cutoff) / 3600),
held_by_nodes,
smartlist_len(nodes),
networkstatus_age / 3600,
ht_badness);
SMARTLIST_FOREACH_BEGIN(nodes, const node_t *, node) {
const char *rs_match = "No RS";
const char *rs_present = "";
if (node->rs) {
if (tor_memeq(node->rs->descriptor_digest,
(*mdp)->digest, DIGEST256_LEN)) {
rs_match = "Microdesc digest in RS matches";
} else {
rs_match = "Microdesc digest in RS does match";
}
if (ns) {
/* This should be impossible, but let's see! */
rs_present = " RS not present in networkstatus.";
SMARTLIST_FOREACH(ns->routerstatus_list, routerstatus_t *,rs, {
if (rs == node->rs) {
rs_present = " RS okay in networkstatus.";
}
});
}
}
log_warn(LD_BUG, " [%d]: ID=%s. md=%p, rs=%p, ri=%p. %s.%s",
node_sl_idx,
hex_str(node->identity, DIGEST_LEN),
node->md, node->rs, node->ri, rs_match, rs_present);
} SMARTLIST_FOREACH_END(node);
smartlist_free(nodes);
(*mdp)->last_listed = now;
}
++kept;
mdp = HT_NEXT(microdesc_map, &cache->map, mdp);
}
}
if (dropped) {
log_info(LD_DIR, "Removed %d/%d microdescriptors as old.",
dropped,dropped+kept);
cache->bytes_dropped += bytes_dropped;
}
}
static int
should_rebuild_md_cache(microdesc_cache_t *cache)
{
const size_t old_len =
cache->cache_content ? cache->cache_content->size : 0;
const size_t journal_len = cache->journal_len;
const size_t dropped = cache->bytes_dropped;
if (journal_len < 16384)
return 0; /* Don't bother, not enough has happened yet. */
if (dropped > (journal_len + old_len) / 3)
return 1; /* We could save 1/3 or more of the currently used space. */
if (journal_len > old_len / 2)
return 1; /* We should append to the regular file */
return 0;
}
/**
* Mark md as having no body, and release any storage previously held
* by its body.
*/
static void
microdesc_wipe_body(microdesc_t *md)
{
if (!md)
return;
if (md->saved_location != SAVED_IN_CACHE)
tor_free(md->body);
md->off = 0;
md->saved_location = SAVED_NOWHERE;
md->body = NULL;
md->bodylen = 0;
md->no_save = 1;
}
/** Regenerate the main cache file for cache, clear the journal file,
* and update every microdesc_t in the cache with pointers to its new
* location. If force is true, do this unconditionally. If
* force is false, do it only if we expect to save space on disk. */
int
microdesc_cache_rebuild(microdesc_cache_t *cache, int force)
{
open_file_t *open_file;
int fd = -1, res;
microdesc_t **mdp;
smartlist_t *wrote;
ssize_t size;
off_t off = 0, off_real;
int orig_size, new_size;
if (cache == NULL) {
cache = the_microdesc_cache;
if (cache == NULL)
return 0;
}
/* Remove dead descriptors */
microdesc_cache_clean(cache, 0/*cutoff*/, 0/*force*/);
if (!force && !should_rebuild_md_cache(cache))
return 0;
log_info(LD_DIR, "Rebuilding the microdescriptor cache...");
orig_size = (int)(cache->cache_content ? cache->cache_content->size : 0);
orig_size += (int)cache->journal_len;
fd = start_writing_to_file(cache->cache_fname,
OPEN_FLAGS_REPLACE|O_BINARY,
0600, &open_file);
if (fd < 0)
return -1;
wrote = smartlist_new();
HT_FOREACH(mdp, microdesc_map, &cache->map) {
microdesc_t *md = *mdp;
size_t annotation_len;
if (md->no_save || !md->body)
continue;
size = dump_microdescriptor(fd, md, &annotation_len);
if (size < 0) {
microdesc_wipe_body(md);
/* rewind, in case it was a partial write. */
tor_fd_setpos(fd, off);
continue;
}
tor_assert(((size_t)size) == annotation_len + md->bodylen);
md->off = off + annotation_len;
off += size;
off_real = tor_fd_getpos(fd);
if (off_real != off) {
log_warn(LD_BUG, "Discontinuity in position in microdescriptor cache."
"By my count, I'm at "I64_FORMAT
", but I should be at "I64_FORMAT,
I64_PRINTF_ARG(off), I64_PRINTF_ARG(off_real));
if (off_real >= 0)
off = off_real;
}
if (md->saved_location != SAVED_IN_CACHE) {
tor_free(md->body);
md->saved_location = SAVED_IN_CACHE;
}
smartlist_add(wrote, md);
}
/* We must do this unmap _before_ we call finish_writing_to_file(), or
* windows will not actually replace the file. */
if (cache->cache_content) {
res = tor_munmap_file(cache->cache_content);
if (res != 0) {
log_warn(LD_FS,
"Failed to unmap old microdescriptor cache while rebuilding");
}
cache->cache_content = NULL;
}
if (finish_writing_to_file(open_file) < 0) {
log_warn(LD_DIR, "Error rebuilding microdescriptor cache: %s",
strerror(errno));
/* Okay. Let's prevent from making things worse elsewhere. */
cache->cache_content = NULL;
HT_FOREACH(mdp, microdesc_map, &cache->map) {
microdesc_t *md = *mdp;
if (md->saved_location == SAVED_IN_CACHE) {
microdesc_wipe_body(md);
}
}
smartlist_free(wrote);
return -1;
}
cache->cache_content = tor_mmap_file(cache->cache_fname);
if (!cache->cache_content && smartlist_len(wrote)) {
log_err(LD_DIR, "Couldn't map file that we just wrote to %s!",
cache->cache_fname);
smartlist_free(wrote);
return -1;
}
SMARTLIST_FOREACH_BEGIN(wrote, microdesc_t *, md) {
tor_assert(md->saved_location == SAVED_IN_CACHE);
md->body = (char*)cache->cache_content->data + md->off;
if (PREDICT_UNLIKELY(
md->bodylen < 9 || fast_memneq(md->body, "onion-key", 9) != 0)) {
/* XXXX once bug 2022 is solved, we can kill this block and turn it
* into just the tor_assert(fast_memeq) */
off_t avail = cache->cache_content->size - md->off;
char *bad_str;
tor_assert(avail >= 0);
bad_str = tor_strndup(md->body, MIN(128, (size_t)avail));
log_err(LD_BUG, "After rebuilding microdesc cache, offsets seem wrong. "
" At offset %d, I expected to find a microdescriptor starting "
" with \"onion-key\". Instead I got %s.",
(int)md->off, escaped(bad_str));
tor_free(bad_str);
tor_assert(fast_memeq(md->body, "onion-key", 9));
}
} SMARTLIST_FOREACH_END(md);
smartlist_free(wrote);
write_str_to_file(cache->journal_fname, "", 1);
cache->journal_len = 0;
cache->bytes_dropped = 0;
new_size = cache->cache_content ? (int)cache->cache_content->size : 0;
log_info(LD_DIR, "Done rebuilding microdesc cache. "
"Saved %d bytes; %d still used.",
orig_size-new_size, new_size);
return 0;
}
/** Make sure that the reference count of every microdescriptor in cache is
* accurate. */
void
microdesc_check_counts(void)
{
microdesc_t **mdp;
if (!the_microdesc_cache)
return;
HT_FOREACH(mdp, microdesc_map, &the_microdesc_cache->map) {
microdesc_t *md = *mdp;
unsigned int found=0;
const smartlist_t *nodes = nodelist_get_list();
SMARTLIST_FOREACH(nodes, node_t *, node, {
if (node->md == md) {
++found;
}
});
tor_assert(found == md->held_by_nodes);
}
}
/** Deallocate a single microdescriptor. Note: the microdescriptor MUST have
* previously been removed from the cache if it had ever been inserted. */
void
microdesc_free_(microdesc_t *md, const char *fname, int lineno)
{
if (!md)
return;
/* Make sure that the microdesc was really removed from the appropriate data
structures. */
if (md->held_in_map) {
microdesc_cache_t *cache = get_microdesc_cache();
microdesc_t *md2 = HT_FIND(microdesc_map, &cache->map, md);
if (md2 == md) {
log_warn(LD_BUG, "microdesc_free() called from %s:%d, but md was still "
"in microdesc_map", fname, lineno);
HT_REMOVE(microdesc_map, &cache->map, md);
} else {
log_warn(LD_BUG, "microdesc_free() called from %s:%d with held_in_map "
"set, but microdesc was not in the map.", fname, lineno);
}
tor_fragile_assert();
}
if (md->held_by_nodes) {
microdesc_cache_t *cache = get_microdesc_cache();
int found=0;
const smartlist_t *nodes = nodelist_get_list();
const int ht_badness = HT_REP_IS_BAD_(microdesc_map, &cache->map);
SMARTLIST_FOREACH(nodes, node_t *, node, {
if (node->md == md) {
++found;
node->md = NULL;
}
});
if (found) {
log_warn(LD_BUG, "microdesc_free() called from %s:%d, but md was still "
"referenced %d node(s); held_by_nodes == %u, ht_badness == %d",
fname, lineno, found, md->held_by_nodes, ht_badness);
} else {
log_warn(LD_BUG, "microdesc_free() called from %s:%d with held_by_nodes "
"set to %u, but md was not referenced by any nodes. "
"ht_badness == %d",
fname, lineno, md->held_by_nodes, ht_badness);
}
tor_fragile_assert();
}
//tor_assert(md->held_in_map == 0);
//tor_assert(md->held_by_nodes == 0);
if (md->onion_pkey)
crypto_pk_free(md->onion_pkey);
tor_free(md->onion_curve25519_pkey);
if (md->body && md->saved_location != SAVED_IN_CACHE)
tor_free(md->body);
if (md->family) {
SMARTLIST_FOREACH(md->family, char *, cp, tor_free(cp));
smartlist_free(md->family);
}
short_policy_free(md->exit_policy);
short_policy_free(md->ipv6_exit_policy);
tor_free(md);
}
/** Free all storage held in the microdesc.c module. */
void
microdesc_free_all(void)
{
if (the_microdesc_cache) {
microdesc_cache_clear(the_microdesc_cache);
tor_free(the_microdesc_cache->cache_fname);
tor_free(the_microdesc_cache->journal_fname);
tor_free(the_microdesc_cache);
}
}
/** If there is a microdescriptor in cache whose sha256 digest is
* d, return it. Otherwise return NULL. */
microdesc_t *
microdesc_cache_lookup_by_digest256(microdesc_cache_t *cache, const char *d)
{
microdesc_t *md, search;
if (!cache)
cache = get_microdesc_cache();
memcpy(search.digest, d, DIGEST256_LEN);
md = HT_FIND(microdesc_map, &cache->map, &search);
return md;
}
/** Return the mean size of decriptors added to cache since it was last
* cleared. Used to estimate the size of large downloads. */
size_t
microdesc_average_size(microdesc_cache_t *cache)
{
if (!cache)
cache = get_microdesc_cache();
if (!cache->n_seen)
return 512;
return (size_t)(cache->total_len_seen / cache->n_seen);
}
/** Return a smartlist of all the sha256 digest of the microdescriptors that
* are listed in ns but not present in cache. Returns pointers
* to internals of ns; you should not free the members of the resulting
* smartlist. Omit all microdescriptors whose digest appear in skip. */
smartlist_t *
microdesc_list_missing_digest256(networkstatus_t *ns, microdesc_cache_t *cache,
int downloadable_only, digest256map_t *skip)
{
smartlist_t *result = smartlist_new();
time_t now = time(NULL);
tor_assert(ns->flavor == FLAV_MICRODESC);
SMARTLIST_FOREACH_BEGIN(ns->routerstatus_list, routerstatus_t *, rs) {
if (microdesc_cache_lookup_by_digest256(cache, rs->descriptor_digest))
continue;
if (downloadable_only &&
!download_status_is_ready(&rs->dl_status, now,
get_options()->TestingMicrodescMaxDownloadTries))
continue;
if (skip && digest256map_get(skip, (const uint8_t*)rs->descriptor_digest))
continue;
if (tor_mem_is_zero(rs->descriptor_digest, DIGEST256_LEN))
continue;
/* XXXX Also skip if we're a noncache and wouldn't use this router.
* XXXX NM Microdesc
*/
smartlist_add(result, rs->descriptor_digest);
} SMARTLIST_FOREACH_END(rs);
return result;
}
/** Launch download requests for microdescriptors as appropriate.
*
* Specifically, we should launch download requests if we are configured to
* download mirodescriptors, and there are some microdescriptors listed the
* current microdesc consensus that we don't have, and either we never asked
* for them, or we failed to download them but we're willing to retry.
*/
void
update_microdesc_downloads(time_t now)
{
const or_options_t *options = get_options();
networkstatus_t *consensus;
smartlist_t *missing;
digest256map_t *pending;
if (should_delay_dir_fetches(options, NULL))
return;
if (directory_too_idle_to_fetch_descriptors(options, now))
return;
consensus = networkstatus_get_reasonably_live_consensus(now, FLAV_MICRODESC);
if (!consensus)
return;
if (!we_fetch_microdescriptors(options))
return;
pending = digest256map_new();
list_pending_microdesc_downloads(pending);
missing = microdesc_list_missing_digest256(consensus,
get_microdesc_cache(),
1,
pending);
digest256map_free(pending, NULL);
launch_descriptor_downloads(DIR_PURPOSE_FETCH_MICRODESC,
missing, NULL, now);
smartlist_free(missing);
}
/** For every microdescriptor listed in the current microdecriptor consensus,
* update its last_listed field to be at least as recent as the publication
* time of the current microdescriptor consensus.
*/
void
update_microdescs_from_networkstatus(time_t now)
{
microdesc_cache_t *cache = get_microdesc_cache();
microdesc_t *md;
networkstatus_t *ns =
networkstatus_get_reasonably_live_consensus(now, FLAV_MICRODESC);
if (! ns)
return;
tor_assert(ns->flavor == FLAV_MICRODESC);
SMARTLIST_FOREACH_BEGIN(ns->routerstatus_list, routerstatus_t *, rs) {
md = microdesc_cache_lookup_by_digest256(cache, rs->descriptor_digest);
if (md && ns->valid_after > md->last_listed)
md->last_listed = ns->valid_after;
} SMARTLIST_FOREACH_END(rs);
}
/** Return true iff we should prefer to use microdescriptors rather than
* routerdescs for building circuits. */
int
we_use_microdescriptors_for_circuits(const or_options_t *options)
{
int ret = options->UseMicrodescriptors;
if (ret == -1) {
/* UseMicrodescriptors is "auto"; we need to decide: */
/* If we are configured to use bridges and none of our bridges
* know what a microdescriptor is, the answer is no. */
if (options->UseBridges && !any_bridge_supports_microdescriptors())
return 0;
/* Otherwise, we decide that we'll use microdescriptors iff we are
* not a server, and we're not autofetching everything. */
/* XXX023 what does not being a server have to do with it? also there's
* a partitioning issue here where bridges differ from clients. */
ret = !server_mode(options) && !options->FetchUselessDescriptors;
}
return ret;
}
/** Return true iff we should try to download microdescriptors at all. */
int
we_fetch_microdescriptors(const or_options_t *options)
{
if (directory_caches_dir_info(options))
return 1;
if (options->FetchUselessDescriptors)
return 1;
return we_use_microdescriptors_for_circuits(options);
}
/** Return true iff we should try to download router descriptors at all. */
int
we_fetch_router_descriptors(const or_options_t *options)
{
if (directory_caches_dir_info(options))
return 1;
if (options->FetchUselessDescriptors)
return 1;
return ! we_use_microdescriptors_for_circuits(options);
}
/** Return the consensus flavor we actually want to use to build circuits. */
int
usable_consensus_flavor(void)
{
if (we_use_microdescriptors_for_circuits(get_options())) {
return FLAV_MICRODESC;
} else {
return FLAV_NS;
}
}