/* trustdb.c * Copyright (C) 1998, 1999, 2000, 2001, 2002, 2003, 2004, 2005, 2006, 2007, * 2008, 2012 Free Software Foundation, Inc. * * This file is part of GnuPG. * * GnuPG is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 3 of the License, or * (at your option) any later version. * * GnuPG is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, see . */ #include #include #include #include #include #ifndef DISABLE_REGEX #include #include #endif /* !DISABLE_REGEX */ #include "gpg.h" #include "status.h" #include "iobuf.h" #include "keydb.h" #include "util.h" #include "options.h" #include "packet.h" #include "main.h" #include "i18n.h" #include "tdbio.h" #include "trustdb.h" #include "tofu.h" typedef struct key_item **KeyHashTable; /* see new_key_hash_table() */ /* * Structure to keep track of keys, this is used as an array wherre * the item right after the last one has a keyblock set to NULL. * Maybe we can drop this thing and replace it by key_item */ struct key_array { KBNODE keyblock; }; /* Control information for the trust DB. */ static struct { int init; int level; char *dbname; int no_trustdb; } trustdb_args; /* Some globals. */ static struct key_item *user_utk_list; /* temp. used to store --trusted-keys */ static struct key_item *utk_list; /* all ultimately trusted keys */ static int pending_check_trustdb; static int validate_keys (int interactive); /********************************************** ************* some helpers ******************* **********************************************/ static struct key_item * new_key_item (void) { struct key_item *k; k = xmalloc_clear (sizeof *k); return k; } static void release_key_items (struct key_item *k) { struct key_item *k2; for (; k; k = k2) { k2 = k->next; xfree (k->trust_regexp); xfree (k); } } #define KEY_HASH_TABLE_SIZE 1024 /* * For fast keylook up we need a hash table. Each byte of a KeyID * should be distributed equally over the 256 possible values (except * for v3 keyIDs but we consider them as not important here). So we * can just use 10 bits to index a table of KEY_HASH_TABLE_SIZE key items. * Possible optimization: Do not use key_items but other hash_table when the * duplicates lists get too large. */ static KeyHashTable new_key_hash_table (void) { struct key_item **tbl; tbl = xmalloc_clear (KEY_HASH_TABLE_SIZE * sizeof *tbl); return tbl; } static void release_key_hash_table (KeyHashTable tbl) { int i; if (!tbl) return; for (i=0; i < KEY_HASH_TABLE_SIZE; i++) release_key_items (tbl[i]); xfree (tbl); } /* * Returns: True if the keyID is in the given hash table */ static int test_key_hash_table (KeyHashTable tbl, u32 *kid) { struct key_item *k; for (k = tbl[(kid[1] % KEY_HASH_TABLE_SIZE)]; k; k = k->next) if (k->kid[0] == kid[0] && k->kid[1] == kid[1]) return 1; return 0; } /* * Add a new key to the hash table. The key is identified by its key ID. */ static void add_key_hash_table (KeyHashTable tbl, u32 *kid) { int i = kid[1] % KEY_HASH_TABLE_SIZE; struct key_item *k, *kk; for (k = tbl[i]; k; k = k->next) if (k->kid[0] == kid[0] && k->kid[1] == kid[1]) return; /* already in table */ kk = new_key_item (); kk->kid[0] = kid[0]; kk->kid[1] = kid[1]; kk->next = tbl[i]; tbl[i] = kk; } /* * Release a key_array */ static void release_key_array ( struct key_array *keys ) { struct key_array *k; if (keys) { for (k=keys; k->keyblock; k++) release_kbnode (k->keyblock); xfree (keys); } } /********************************************* ********** Initialization ***************** *********************************************/ /* * Used to register extra ultimately trusted keys - this has to be done * before initializing the validation module. * FIXME: Should be replaced by a function to add those keys to the trustdb. */ void tdb_register_trusted_keyid (u32 *keyid) { struct key_item *k; k = new_key_item (); k->kid[0] = keyid[0]; k->kid[1] = keyid[1]; k->next = user_utk_list; user_utk_list = k; } void tdb_register_trusted_key( const char *string ) { gpg_error_t err; KEYDB_SEARCH_DESC desc; err = classify_user_id (string, &desc, 1); if (err || desc.mode != KEYDB_SEARCH_MODE_LONG_KID ) { log_error(_("'%s' is not a valid long keyID\n"), string ); return; } register_trusted_keyid(desc.u.kid); } /* * Helper to add a key to the global list of ultimately trusted keys. * Retruns: true = inserted, false = already in in list. */ static int add_utk (u32 *kid) { struct key_item *k; if (tdb_keyid_is_utk (kid)) return 0; k = new_key_item (); k->kid[0] = kid[0]; k->kid[1] = kid[1]; k->ownertrust = TRUST_ULTIMATE; k->next = utk_list; utk_list = k; if( opt.verbose > 1 ) log_info(_("key %s: accepted as trusted key\n"), keystr(kid)); return 1; } /**************** * Verify that all our secret keys are usable and put them into the utk_list. */ static void verify_own_keys(void) { TRUSTREC rec; ulong recnum; int rc; struct key_item *k; if (utk_list) return; /* scan the trustdb to find all ultimately trusted keys */ for (recnum=1; !tdbio_read_record (recnum, &rec, 0); recnum++ ) { if ( rec.rectype == RECTYPE_TRUST && (rec.r.trust.ownertrust & TRUST_MASK) == TRUST_ULTIMATE) { byte *fpr = rec.r.trust.fingerprint; int fprlen; u32 kid[2]; /* Problem: We do only use fingerprints in the trustdb but * we need the keyID here to indetify the key; we can only * use that ugly hack to distinguish between 16 and 20 * butes fpr - it does not work always so we better change * the whole validation code to only work with * fingerprints */ fprlen = (!fpr[16] && !fpr[17] && !fpr[18] && !fpr[19])? 16:20; keyid_from_fingerprint (fpr, fprlen, kid); if (!add_utk (kid)) log_info(_("key %s occurs more than once in the trustdb\n"), keystr(kid)); } } /* Put any --trusted-key keys into the trustdb */ for (k = user_utk_list; k; k = k->next) { if ( add_utk (k->kid) ) { /* not yet in trustDB as ultimately trusted */ PKT_public_key pk; memset (&pk, 0, sizeof pk); rc = get_pubkey (&pk, k->kid); if (rc) log_info(_("key %s: no public key for trusted key - skipped\n"), keystr(k->kid)); else { tdb_update_ownertrust (&pk, ((tdb_get_ownertrust (&pk) & ~TRUST_MASK) | TRUST_ULTIMATE )); release_public_key_parts (&pk); } log_info (_("key %s marked as ultimately trusted\n"),keystr(k->kid)); } } /* release the helper table table */ release_key_items (user_utk_list); user_utk_list = NULL; return; } /* Returns whether KID is on the list of ultimately trusted keys. */ int tdb_keyid_is_utk (u32 *kid) { struct key_item *k; for (k = utk_list; k; k = k->next) if (k->kid[0] == kid[0] && k->kid[1] == kid[1]) return 1; return 0; } /********************************************* *********** TrustDB stuff ******************* *********************************************/ /* * Read a record but die if it does not exist */ static void read_record (ulong recno, TRUSTREC *rec, int rectype ) { int rc = tdbio_read_record (recno, rec, rectype); if (rc) { log_error(_("trust record %lu, req type %d: read failed: %s\n"), recno, rec->rectype, gpg_strerror (rc) ); tdbio_invalid(); } if (rectype != rec->rectype) { log_error(_("trust record %lu is not of requested type %d\n"), rec->recnum, rectype); tdbio_invalid(); } } /* * Write a record and die on error */ static void write_record (TRUSTREC *rec) { int rc = tdbio_write_record (rec); if (rc) { log_error(_("trust record %lu, type %d: write failed: %s\n"), rec->recnum, rec->rectype, gpg_strerror (rc) ); tdbio_invalid(); } } /* * sync the TrustDb and die on error */ static void do_sync(void) { int rc = tdbio_sync (); if(rc) { log_error (_("trustdb: sync failed: %s\n"), gpg_strerror (rc) ); g10_exit(2); } } static const char * trust_model_string(void) { switch(opt.trust_model) { case TM_CLASSIC: return "classic"; case TM_PGP: return "PGP"; case TM_EXTERNAL: return "external"; case TM_TOFU: return "TOFU"; case TM_TOFU_PGP: return "TOFU+PGP"; case TM_ALWAYS: return "always"; case TM_DIRECT: return "direct"; default: return "unknown"; } } /**************** * Perform some checks over the trustdb * level 0: only open the db * 1: used for initial program startup */ int setup_trustdb( int level, const char *dbname ) { /* just store the args */ if( trustdb_args.init ) return 0; trustdb_args.level = level; trustdb_args.dbname = dbname? xstrdup(dbname): NULL; return 0; } void how_to_fix_the_trustdb () { const char *name = trustdb_args.dbname; if (!name) name = "trustdb.gpg"; log_info (_("You may try to re-create the trustdb using the commands:\n")); log_info (" cd %s\n", default_homedir ()); log_info (" %s --export-ownertrust > otrust.tmp\n", GPG_NAME); #ifdef HAVE_W32_SYSTEM log_info (" del %s\n", name); #else log_info (" rm %s\n", name); #endif log_info (" %s --import-ownertrust < otrust.tmp\n", GPG_NAME); log_info (_("If that does not work, please consult the manual\n")); } void init_trustdb () { int level = trustdb_args.level; const char* dbname = trustdb_args.dbname; if( trustdb_args.init ) return; trustdb_args.init = 1; if(level==0 || level==1) { int rc = tdbio_set_dbname( dbname, !!level, &trustdb_args.no_trustdb); if( rc ) log_fatal("can't init trustdb: %s\n", gpg_strerror (rc) ); } else BUG(); if(opt.trust_model==TM_AUTO) { /* Try and set the trust model off of whatever the trustdb says it is. */ opt.trust_model=tdbio_read_model(); /* Sanity check this ;) */ if(opt.trust_model != TM_CLASSIC && opt.trust_model != TM_PGP && opt.trust_model != TM_TOFU_PGP && opt.trust_model != TM_TOFU && opt.trust_model != TM_EXTERNAL) { log_info(_("unable to use unknown trust model (%d) - " "assuming %s trust model\n"),opt.trust_model,"pgp"); opt.trust_model = TM_PGP; } if(opt.verbose) log_info(_("using %s trust model\n"),trust_model_string()); } if (opt.trust_model==TM_PGP || opt.trust_model==TM_CLASSIC || opt.trust_model == TM_TOFU || opt.trust_model == TM_TOFU_PGP) { /* Verify the list of ultimately trusted keys and move the --trusted-keys list there as well. */ if(level==1) verify_own_keys(); if(!tdbio_db_matches_options()) pending_check_trustdb=1; } } /**************** * Recreate the WoT but do not ask for new ownertrusts. Special * feature: In batch mode and without a forced yes, this is only done * when a check is due. This can be used to run the check from a crontab */ void check_trustdb () { init_trustdb(); if (opt.trust_model == TM_PGP || opt.trust_model == TM_CLASSIC || opt.trust_model == TM_TOFU_PGP || opt.trust_model == TM_TOFU) { if (opt.batch && !opt.answer_yes) { ulong scheduled; scheduled = tdbio_read_nextcheck (); if (!scheduled) { log_info (_("no need for a trustdb check\n")); return; } if (scheduled > make_timestamp ()) { log_info (_("next trustdb check due at %s\n"), strtimestamp (scheduled)); return; } } validate_keys (0); } else log_info (_("no need for a trustdb check with '%s' trust model\n"), trust_model_string()); } /* * Recreate the WoT. */ void update_trustdb() { init_trustdb(); if (opt.trust_model == TM_PGP || opt.trust_model == TM_CLASSIC || opt.trust_model == TM_TOFU_PGP || opt.trust_model == TM_TOFU) validate_keys (1); else log_info (_("no need for a trustdb update with '%s' trust model\n"), trust_model_string()); } void tdb_revalidation_mark (void) { init_trustdb(); if (trustdb_args.no_trustdb && opt.trust_model == TM_ALWAYS) return; /* We simply set the time for the next check to 1 (far back in 1970) so that a --update-trustdb will be scheduled. */ if (tdbio_write_nextcheck (1)) do_sync (); pending_check_trustdb = 1; } int trustdb_pending_check(void) { return pending_check_trustdb; } /* If the trustdb is dirty, and we're interactive, update it. Otherwise, check it unless no-auto-check-trustdb is set. */ void tdb_check_or_update (void) { if(trustdb_pending_check()) { if(opt.interactive) update_trustdb(); else if(!opt.no_auto_check_trustdb) check_trustdb(); } } void read_trust_options(byte *trust_model,ulong *created,ulong *nextcheck, byte *marginals,byte *completes,byte *cert_depth, byte *min_cert_level) { TRUSTREC opts; init_trustdb(); if (trustdb_args.no_trustdb && opt.trust_model == TM_ALWAYS) memset (&opts, 0, sizeof opts); else read_record (0, &opts, RECTYPE_VER); if(trust_model) *trust_model=opts.r.ver.trust_model; if(created) *created=opts.r.ver.created; if(nextcheck) *nextcheck=opts.r.ver.nextcheck; if(marginals) *marginals=opts.r.ver.marginals; if(completes) *completes=opts.r.ver.completes; if(cert_depth) *cert_depth=opts.r.ver.cert_depth; if(min_cert_level) *min_cert_level=opts.r.ver.min_cert_level; } /*********************************************** *********** Ownertrust et al. **************** ***********************************************/ static int read_trust_record (PKT_public_key *pk, TRUSTREC *rec) { int rc; init_trustdb(); rc = tdbio_search_trust_bypk (pk, rec); if (rc) { if (gpg_err_code (rc) != GPG_ERR_NOT_FOUND) log_error ("trustdb: searching trust record failed: %s\n", gpg_strerror (rc)); return rc; } if (rec->rectype != RECTYPE_TRUST) { log_error ("trustdb: record %lu is not a trust record\n", rec->recnum); return GPG_ERR_TRUSTDB; } return 0; } /**************** * Return the assigned ownertrust value for the given public key. * The key should be the primary key. */ unsigned int tdb_get_ownertrust ( PKT_public_key *pk) { TRUSTREC rec; gpg_error_t err; if (trustdb_args.no_trustdb && opt.trust_model == TM_ALWAYS) return TRUST_UNKNOWN; err = read_trust_record (pk, &rec); if (gpg_err_code (err) == GPG_ERR_NOT_FOUND) return TRUST_UNKNOWN; /* no record yet */ if (err) { tdbio_invalid (); return TRUST_UNKNOWN; /* actually never reached */ } return rec.r.trust.ownertrust; } unsigned int tdb_get_min_ownertrust (PKT_public_key *pk) { TRUSTREC rec; gpg_error_t err; if (trustdb_args.no_trustdb && opt.trust_model == TM_ALWAYS) return TRUST_UNKNOWN; err = read_trust_record (pk, &rec); if (gpg_err_code (err) == GPG_ERR_NOT_FOUND) return TRUST_UNKNOWN; /* no record yet */ if (err) { tdbio_invalid (); return TRUST_UNKNOWN; /* actually never reached */ } return rec.r.trust.min_ownertrust; } /* * Set the trust value of the given public key to the new value. * The key should be a primary one. */ void tdb_update_ownertrust (PKT_public_key *pk, unsigned int new_trust ) { TRUSTREC rec; gpg_error_t err; if (trustdb_args.no_trustdb && opt.trust_model == TM_ALWAYS) return; err = read_trust_record (pk, &rec); if (!err) { if (DBG_TRUST) log_debug ("update ownertrust from %u to %u\n", (unsigned int)rec.r.trust.ownertrust, new_trust ); if (rec.r.trust.ownertrust != new_trust) { rec.r.trust.ownertrust = new_trust; write_record( &rec ); tdb_revalidation_mark (); do_sync (); } } else if (gpg_err_code (err) == GPG_ERR_NOT_FOUND) { /* no record yet - create a new one */ size_t dummy; if (DBG_TRUST) log_debug ("insert ownertrust %u\n", new_trust ); memset (&rec, 0, sizeof rec); rec.recnum = tdbio_new_recnum (); rec.rectype = RECTYPE_TRUST; fingerprint_from_pk (pk, rec.r.trust.fingerprint, &dummy); rec.r.trust.ownertrust = new_trust; write_record (&rec); tdb_revalidation_mark (); do_sync (); } else { tdbio_invalid (); } } static void update_min_ownertrust (u32 *kid, unsigned int new_trust ) { PKT_public_key *pk; TRUSTREC rec; gpg_error_t err; if (trustdb_args.no_trustdb && opt.trust_model == TM_ALWAYS) return; pk = xmalloc_clear (sizeof *pk); err = get_pubkey (pk, kid); if (err) { log_error (_("public key %s not found: %s\n"), keystr (kid), gpg_strerror (err)); return; } err = read_trust_record (pk, &rec); if (!err) { if (DBG_TRUST) log_debug ("key %08lX%08lX: update min_ownertrust from %u to %u\n", (ulong)kid[0],(ulong)kid[1], (unsigned int)rec.r.trust.min_ownertrust, new_trust ); if (rec.r.trust.min_ownertrust != new_trust) { rec.r.trust.min_ownertrust = new_trust; write_record( &rec ); tdb_revalidation_mark (); do_sync (); } } else if (gpg_err_code (err) == GPG_ERR_NOT_FOUND) { /* no record yet - create a new one */ size_t dummy; if (DBG_TRUST) log_debug ("insert min_ownertrust %u\n", new_trust ); memset (&rec, 0, sizeof rec); rec.recnum = tdbio_new_recnum (); rec.rectype = RECTYPE_TRUST; fingerprint_from_pk (pk, rec.r.trust.fingerprint, &dummy); rec.r.trust.min_ownertrust = new_trust; write_record (&rec); tdb_revalidation_mark (); do_sync (); } else { tdbio_invalid (); } } /* * Clear the ownertrust and min_ownertrust values. * * Return: True if a change actually happened. */ int tdb_clear_ownertrusts (PKT_public_key *pk) { TRUSTREC rec; gpg_error_t err; init_trustdb (); if (trustdb_args.no_trustdb && opt.trust_model == TM_ALWAYS) return 0; err = read_trust_record (pk, &rec); if (!err) { if (DBG_TRUST) { log_debug ("clearing ownertrust (old value %u)\n", (unsigned int)rec.r.trust.ownertrust); log_debug ("clearing min_ownertrust (old value %u)\n", (unsigned int)rec.r.trust.min_ownertrust); } if (rec.r.trust.ownertrust || rec.r.trust.min_ownertrust) { rec.r.trust.ownertrust = 0; rec.r.trust.min_ownertrust = 0; write_record( &rec ); tdb_revalidation_mark (); do_sync (); return 1; } } else if (gpg_err_code (err) != GPG_ERR_NOT_FOUND) { tdbio_invalid (); } return 0; } /* * Note: Caller has to do a sync */ static void update_validity (PKT_public_key *pk, PKT_user_id *uid, int depth, int validity) { TRUSTREC trec, vrec; gpg_error_t err; ulong recno; namehash_from_uid(uid); err = read_trust_record (pk, &trec); if (err && gpg_err_code (err) != GPG_ERR_NOT_FOUND) { tdbio_invalid (); return; } if (gpg_err_code (err) == GPG_ERR_NOT_FOUND) { /* No record yet - create a new one. */ size_t dummy; memset (&trec, 0, sizeof trec); trec.recnum = tdbio_new_recnum (); trec.rectype = RECTYPE_TRUST; fingerprint_from_pk (pk, trec.r.trust.fingerprint, &dummy); trec.r.trust.ownertrust = 0; } /* locate an existing one */ recno = trec.r.trust.validlist; while (recno) { read_record (recno, &vrec, RECTYPE_VALID); if ( !memcmp (vrec.r.valid.namehash, uid->namehash, 20) ) break; recno = vrec.r.valid.next; } if (!recno) /* insert a new validity record */ { memset (&vrec, 0, sizeof vrec); vrec.recnum = tdbio_new_recnum (); vrec.rectype = RECTYPE_VALID; memcpy (vrec.r.valid.namehash, uid->namehash, 20); vrec.r.valid.next = trec.r.trust.validlist; trec.r.trust.validlist = vrec.recnum; } vrec.r.valid.validity = validity; vrec.r.valid.full_count = uid->help_full_count; vrec.r.valid.marginal_count = uid->help_marginal_count; write_record (&vrec); trec.r.trust.depth = depth; write_record (&trec); } /*********************************************** ********* Query trustdb values ************** ***********************************************/ /* Return true if key is disabled. Note that this is usually used via the pk_is_disabled macro. */ int tdb_cache_disabled_value (PKT_public_key *pk) { gpg_error_t err; TRUSTREC trec; int disabled = 0; if (pk->flags.disabled_valid) return pk->flags.disabled; init_trustdb(); if (trustdb_args.no_trustdb) return 0; /* No trustdb => not disabled. */ err = read_trust_record (pk, &trec); if (err && gpg_err_code (err) != GPG_ERR_NOT_FOUND) { tdbio_invalid (); goto leave; } if (gpg_err_code (err) == GPG_ERR_NOT_FOUND) { /* No record found, so assume not disabled. */ goto leave; } if ((trec.r.trust.ownertrust & TRUST_FLAG_DISABLED)) disabled = 1; /* Cache it for later so we don't need to look at the trustdb every time */ pk->flags.disabled = disabled; pk->flags.disabled_valid = 1; leave: return disabled; } void tdb_check_trustdb_stale (void) { static int did_nextcheck=0; init_trustdb (); if (trustdb_args.no_trustdb) return; /* No trustdb => can't be stale. */ if (!did_nextcheck && (opt.trust_model == TM_PGP || opt.trust_model == TM_CLASSIC || opt.trust_model == TM_TOFU_PGP || opt.trust_model == TM_TOFU)) { ulong scheduled; did_nextcheck = 1; scheduled = tdbio_read_nextcheck (); if ((scheduled && scheduled <= make_timestamp ()) || pending_check_trustdb) { if (opt.no_auto_check_trustdb) { pending_check_trustdb = 1; if (!opt.quiet) log_info (_("please do a --check-trustdb\n")); } else { if (!opt.quiet) log_info (_("checking the trustdb\n")); validate_keys (0); } } } } /* * Return the validity information for PK. This is the core of * get_validity. If SIG is not NULL, then the trust is being * evaluated in the context of the provided signature. This is used * by the TOFU code to record statistics. */ unsigned int tdb_get_validity_core (PKT_public_key *pk, PKT_user_id *uid, PKT_public_key *main_pk, PKT_signature *sig, int may_ask) { TRUSTREC trec, vrec; gpg_error_t err; ulong recno; #ifdef USE_TOFU unsigned int tofu_validity = TRUST_UNKNOWN; #endif unsigned int validity = TRUST_UNKNOWN; #ifndef USE_TOFU (void)sig; (void)may_ask; #endif init_trustdb (); /* If we have no trustdb (which also means it has not been created) and the trust-model is always, we don't know the validity - return immediately. If we won't do that the tdbio code would try to open the trustdb and run into a fatal error. */ if (trustdb_args.no_trustdb && opt.trust_model == TM_ALWAYS) return TRUST_UNKNOWN; check_trustdb_stale(); if(opt.trust_model==TM_DIRECT) { /* Note that this happens BEFORE any user ID stuff is checked. The direct trust model applies to keys as a whole. */ validity = tdb_get_ownertrust (main_pk); goto leave; } #ifdef USE_TOFU if (opt.trust_model == TM_TOFU || opt.trust_model == TM_TOFU_PGP) { kbnode_t user_id_node = NULL; /* Silence -Wmaybe-uninitialized. */ int user_ids = 0; int user_ids_expired = 0; /* If the caller didn't supply a user id then iterate over all uids. */ if (! uid) user_id_node = get_pubkeyblock (main_pk->keyid); while (uid || (user_id_node = find_next_kbnode (user_id_node, PKT_USER_ID))) { unsigned int tl; PKT_user_id *user_id; if (uid) user_id = uid; else user_id = user_id_node->pkt->pkt.user_id; /* If the user id is revoked or expired, then skip it. */ if (user_id->is_revoked || user_id->is_expired) { if (DBG_TRUST) { char *s; if (user_id->is_revoked && user_id->is_expired) s = "revoked and expired"; else if (user_id->is_revoked) s = "revoked"; else s = "expire"; log_debug ("TOFU: Ignoring %s user id (%s)\n", s, user_id->name); } continue; } user_ids ++; if (sig) tl = tofu_register (main_pk, user_id->name, sig->digest, sig->digest_len, sig->timestamp, "unknown", may_ask); else tl = tofu_get_validity (main_pk, user_id->name, may_ask); if (tl == TRUST_EXPIRED) user_ids_expired ++; else if (tl == TRUST_UNDEFINED || tl == TRUST_UNKNOWN) ; else if (tl == TRUST_NEVER) tofu_validity = TRUST_NEVER; else { assert (tl == TRUST_MARGINAL || tl == TRUST_FULLY || tl == TRUST_ULTIMATE); if (tl > tofu_validity) /* XXX: We we really want the max? */ tofu_validity = tl; } if (uid) /* If the caller specified a user id, then we stop now. */ break; } } #endif /*USE_TOFU*/ if (opt.trust_model == TM_TOFU_PGP || opt.trust_model == TM_CLASSIC || opt.trust_model == TM_PGP) { err = read_trust_record (main_pk, &trec); if (err && gpg_err_code (err) != GPG_ERR_NOT_FOUND) { tdbio_invalid (); return 0; } if (gpg_err_code (err) == GPG_ERR_NOT_FOUND) { /* No record found. */ validity = TRUST_UNKNOWN; goto leave; } /* Loop over all user IDs */ recno = trec.r.trust.validlist; validity = 0; while (recno) { read_record (recno, &vrec, RECTYPE_VALID); if(uid) { /* If a user ID is given we return the validity for that user ID ONLY. If the namehash is not found, then there is no validity at all (i.e. the user ID wasn't signed). */ if(memcmp(vrec.r.valid.namehash,uid->namehash,20)==0) { validity=(vrec.r.valid.validity & TRUST_MASK); break; } } else { /* If no user ID is given, we take the maximum validity over all user IDs */ if (validity < (vrec.r.valid.validity & TRUST_MASK)) validity = (vrec.r.valid.validity & TRUST_MASK); } recno = vrec.r.valid.next; } if ((trec.r.trust.ownertrust & TRUST_FLAG_DISABLED)) { validity |= TRUST_FLAG_DISABLED; pk->flags.disabled = 1; } else pk->flags.disabled = 0; pk->flags.disabled_valid = 1; } leave: #ifdef USE_TOFU validity = tofu_wot_trust_combine (tofu_validity, validity); #else /*!USE_TOFU*/ validity &= TRUST_MASK; if (validity == TRUST_NEVER) /* TRUST_NEVER trumps everything else. */ validity |= TRUST_NEVER; if (validity == TRUST_EXPIRED) /* TRUST_EXPIRED trumps everything but TRUST_NEVER. */ validity |= TRUST_EXPIRED; #endif /*!USE_TOFU*/ if (opt.trust_model != TM_TOFU && pending_check_trustdb) validity |= TRUST_FLAG_PENDING_CHECK; return validity; } static void get_validity_counts (PKT_public_key *pk, PKT_user_id *uid) { TRUSTREC trec, vrec; ulong recno; if(pk==NULL || uid==NULL) BUG(); namehash_from_uid(uid); uid->help_marginal_count=uid->help_full_count=0; init_trustdb (); if(read_trust_record (pk, &trec)) return; /* loop over all user IDs */ recno = trec.r.trust.validlist; while (recno) { read_record (recno, &vrec, RECTYPE_VALID); if(memcmp(vrec.r.valid.namehash,uid->namehash,20)==0) { uid->help_marginal_count=vrec.r.valid.marginal_count; uid->help_full_count=vrec.r.valid.full_count; /* es_printf("Fetched marginal %d, full %d\n",uid->help_marginal_count,uid->help_full_count); */ break; } recno = vrec.r.valid.next; } } void list_trust_path( const char *username ) { (void)username; } /**************** * Enumerate all keys, which are needed to build all trust paths for * the given key. This function does not return the key itself or * the ultimate key (the last point in cerificate chain). Only * certificate chains which ends up at an ultimately trusted key * are listed. If ownertrust or validity is not NULL, the corresponding * value for the returned LID is also returned in these variable(s). * * 1) create a void pointer and initialize it to NULL * 2) pass this void pointer by reference to this function. * Set lid to the key you want to enumerate and pass it by reference. * 3) call this function as long as it does not return -1 * to indicate EOF. LID does contain the next key used to build the web * 4) Always call this function a last time with LID set to NULL, * so that it can free its context. * * Returns: -1 on EOF or the level of the returned LID */ int enum_cert_paths( void **context, ulong *lid, unsigned *ownertrust, unsigned *validity ) { (void)context; (void)lid; (void)ownertrust; (void)validity; return -1; } /**************** * Print the current path */ void enum_cert_paths_print (void **context, FILE *fp, int refresh, ulong selected_lid) { (void)context; (void)fp; (void)refresh; (void)selected_lid; } /**************************************** *********** NEW NEW NEW **************** ****************************************/ static int ask_ownertrust (u32 *kid,int minimum) { PKT_public_key *pk; int rc; int ot; pk = xmalloc_clear (sizeof *pk); rc = get_pubkey (pk, kid); if (rc) { log_error (_("public key %s not found: %s\n"), keystr(kid), gpg_strerror (rc) ); return TRUST_UNKNOWN; } if(opt.force_ownertrust) { log_info("force trust for key %s to %s\n", keystr(kid),trust_value_to_string(opt.force_ownertrust)); tdb_update_ownertrust (pk, opt.force_ownertrust); ot=opt.force_ownertrust; } else { ot=edit_ownertrust(pk,0); if(ot>0) ot = tdb_get_ownertrust (pk); else if(ot==0) ot = minimum?minimum:TRUST_UNDEFINED; else ot = -1; /* quit */ } free_public_key( pk ); return ot; } static void mark_keyblock_seen (KeyHashTable tbl, KBNODE node) { for ( ;node; node = node->next ) if (node->pkt->pkttype == PKT_PUBLIC_KEY || node->pkt->pkttype == PKT_PUBLIC_SUBKEY) { u32 aki[2]; keyid_from_pk (node->pkt->pkt.public_key, aki); add_key_hash_table (tbl, aki); } } static void dump_key_array (int depth, struct key_array *keys) { struct key_array *kar; for (kar=keys; kar->keyblock; kar++) { KBNODE node = kar->keyblock; u32 kid[2]; keyid_from_pk(node->pkt->pkt.public_key, kid); es_printf ("%d:%08lX%08lX:K::%c::::\n", depth, (ulong)kid[0], (ulong)kid[1], '?'); for (; node; node = node->next) { if (node->pkt->pkttype == PKT_USER_ID) { int len = node->pkt->pkt.user_id->len; if (len > 30) len = 30; es_printf ("%d:%08lX%08lX:U:::%c:::", depth, (ulong)kid[0], (ulong)kid[1], (node->flag & 4)? 'f': (node->flag & 2)? 'm': (node->flag & 1)? 'q':'-'); es_write_sanitized (es_stdout, node->pkt->pkt.user_id->name, len, ":", NULL); es_putc (':', es_stdout); es_putc ('\n', es_stdout); } } } } static void store_validation_status (int depth, KBNODE keyblock, KeyHashTable stored) { KBNODE node; int status; int any = 0; for (node=keyblock; node; node = node->next) { if (node->pkt->pkttype == PKT_USER_ID) { PKT_user_id *uid = node->pkt->pkt.user_id; if (node->flag & 4) status = TRUST_FULLY; else if (node->flag & 2) status = TRUST_MARGINAL; else if (node->flag & 1) status = TRUST_UNDEFINED; else status = 0; if (status) { update_validity (keyblock->pkt->pkt.public_key, uid, depth, status); mark_keyblock_seen(stored,keyblock); any = 1; } } } if (any) do_sync (); } /* Returns a sanitized copy of the regexp (which might be "", but not NULL). */ #ifndef DISABLE_REGEX static char * sanitize_regexp(const char *old) { size_t start=0,len=strlen(old),idx=0; int escaped=0,standard_bracket=0; char *new=xmalloc((len*2)+1); /* enough to \-escape everything if we have to */ /* There are basically two commonly-used regexps here. GPG and most versions of PGP use "<[^>]+[@.]example\.com>$" and PGP (9) command line uses "example.com" (i.e. whatever the user specfies, and we can't expect users know to use "\." instead of "."). So here are the rules: we're allowed to start with "<[^>]+[@.]" and end with ">$" or start and end with nothing. In between, the only legal regex character is ".", and everything else gets escaped. Part of the gotcha here is that some regex packages allow more than RFC-4880 requires. For example, 4880 has no "{}" operator, but GNU regex does. Commenting removes these operators from consideration. A possible future enhancement is to use commenting to effectively back off a given regex to the Henry Spencer syntax in 4880. -dshaw */ /* Are we bracketed between "<[^>]+[@.]" and ">$" ? */ if(len>=12 && strncmp(old,"<[^>]+[@.]",10)==0 && old[len-2]=='>' && old[len-1]=='$') { strcpy(new,"<[^>]+[@.]"); idx=strlen(new); standard_bracket=1; start+=10; len-=2; } /* Walk the remaining characters and ensure that everything that is left is not an operational regex character. */ for(;start$", then it was escaping the ">" and is fine. If the regexp actually ended with the bare "\", then it's an illegal regexp and regcomp should kick it out. */ if(standard_bracket) strcat(new,">$"); return new; } #endif /*!DISABLE_REGEX*/ /* Used by validate_one_keyblock to confirm a regexp within a trust signature. Returns 1 for match, and 0 for no match or regex error. */ static int check_regexp(const char *expr,const char *string) { #ifdef DISABLE_REGEX (void)expr; (void)string; /* When DISABLE_REGEX is defined, assume all regexps do not match. */ return 0; #else int ret; char *regexp; regexp=sanitize_regexp(expr); #ifdef __riscos__ ret=riscos_check_regexp(expr, string, DBG_TRUST); #else { regex_t pat; ret=regcomp(&pat,regexp,REG_ICASE|REG_NOSUB|REG_EXTENDED); if(ret==0) { ret=regexec(&pat,string,0,NULL,0); regfree(&pat); ret=(ret==0); } } #endif if(DBG_TRUST) log_debug("regexp '%s' ('%s') on '%s': %s\n", regexp,expr,string,ret==0?"YES":"NO"); xfree(regexp); return ret; #endif } /* * Return true if the key is signed by one of the keys in the given * key ID list. User IDs with a valid signature are marked by node * flags as follows: * flag bit 0: There is at least one signature * 1: There is marginal confidence that this is a legitimate uid * 2: There is full confidence that this is a legitimate uid. * 8: Used for internal purposes. * 9: Ditto (in mark_usable_uid_certs()) * 10: Ditto (ditto) * This function assumes that all kbnode flags are cleared on entry. */ static int validate_one_keyblock (KBNODE kb, struct key_item *klist, u32 curtime, u32 *next_expire) { struct key_item *kr; KBNODE node, uidnode=NULL; PKT_user_id *uid=NULL; PKT_public_key *pk = kb->pkt->pkt.public_key; u32 main_kid[2]; int issigned=0, any_signed = 0; keyid_from_pk(pk, main_kid); for (node=kb; node; node = node->next) { /* A bit of discussion here: is it better for the web of trust to be built among only self-signed uids? On the one hand, a self-signed uid is a statement that the key owner definitely intended that uid to be there, but on the other hand, a signed (but not self-signed) uid does carry trust, of a sort, even if it is a statement being made by people other than the key owner "through" the uids on the key owner's key. I'm going with the latter. However, if the user ID was explicitly revoked, or passively allowed to expire, that should stop validity through the user ID until it is resigned. -dshaw */ if (node->pkt->pkttype == PKT_USER_ID && !node->pkt->pkt.user_id->is_revoked && !node->pkt->pkt.user_id->is_expired) { if (uidnode && issigned) { if (uid->help_full_count >= opt.completes_needed || uid->help_marginal_count >= opt.marginals_needed ) uidnode->flag |= 4; else if (uid->help_full_count || uid->help_marginal_count) uidnode->flag |= 2; uidnode->flag |= 1; any_signed = 1; } uidnode = node; uid=uidnode->pkt->pkt.user_id; /* If the selfsig is going to expire... */ if(uid->expiredate && uid->expiredate<*next_expire) *next_expire = uid->expiredate; issigned = 0; get_validity_counts(pk,uid); mark_usable_uid_certs (kb, uidnode, main_kid, klist, curtime, next_expire); } else if (node->pkt->pkttype == PKT_SIGNATURE && (node->flag & (1<<8)) && uid) { /* Note that we are only seeing unrevoked sigs here */ PKT_signature *sig = node->pkt->pkt.signature; kr = is_in_klist (klist, sig); /* If the trust_regexp does not match, it's as if the sig did not exist. This is safe for non-trust sigs as well since we don't accept a regexp on the sig unless it's a trust sig. */ if (kr && (!kr->trust_regexp || !(opt.trust_model == TM_PGP || opt.trust_model == TM_TOFU_PGP) || (uidnode && check_regexp(kr->trust_regexp, uidnode->pkt->pkt.user_id->name)))) { /* Are we part of a trust sig chain? We always favor the latest trust sig, rather than the greater or lesser trust sig or value. I could make a decent argument for any of these cases, but this seems to be what PGP does, and I'd like to be compatible. -dms */ if ((opt.trust_model == TM_PGP || opt.trust_model == TM_TOFU_PGP) && sig->trust_depth && pk->trust_timestamp <= sig->timestamp) { unsigned char depth; /* If the depth on the signature is less than the chain currently has, then use the signature depth so we don't increase the depth beyond what the signer wanted. If the depth on the signature is more than the chain currently has, then use the chain depth so we use as much of the signature depth as the chain will permit. An ultimately trusted signature can restart the depth to whatever level it likes. */ if (sig->trust_depth < kr->trust_depth || kr->ownertrust == TRUST_ULTIMATE) depth = sig->trust_depth; else depth = kr->trust_depth; if (depth) { if(DBG_TRUST) log_debug ("trust sig on %s, sig depth is %d," " kr depth is %d\n", uidnode->pkt->pkt.user_id->name, sig->trust_depth, kr->trust_depth); /* If we got here, we know that: this is a trust sig. it's a newer trust sig than any previous trust sig on this key (not uid). it is legal in that it was either generated by an ultimate key, or a key that was part of a trust chain, and the depth does not violate the original trust sig. if there is a regexp attached, it matched successfully. */ if (DBG_TRUST) log_debug ("replacing trust value %d with %d and " "depth %d with %d\n", pk->trust_value,sig->trust_value, pk->trust_depth,depth); pk->trust_value = sig->trust_value; pk->trust_depth = depth-1; /* If the trust sig contains a regexp, record it on the pk for the next round. */ if (sig->trust_regexp) pk->trust_regexp = sig->trust_regexp; } } if (kr->ownertrust == TRUST_ULTIMATE) uid->help_full_count = opt.completes_needed; else if (kr->ownertrust == TRUST_FULLY) uid->help_full_count++; else if (kr->ownertrust == TRUST_MARGINAL) uid->help_marginal_count++; issigned = 1; } } } if (uidnode && issigned) { if (uid->help_full_count >= opt.completes_needed || uid->help_marginal_count >= opt.marginals_needed ) uidnode->flag |= 4; else if (uid->help_full_count || uid->help_marginal_count) uidnode->flag |= 2; uidnode->flag |= 1; any_signed = 1; } return any_signed; } static int search_skipfnc (void *opaque, u32 *kid, int dummy_uid_no) { (void)dummy_uid_no; return test_key_hash_table ((KeyHashTable)opaque, kid); } /* * Scan all keys and return a key_array of all suitable keys from * kllist. The caller has to pass keydb handle so that we don't use * to create our own. Returns either a key_array or NULL in case of * an error. No results found are indicated by an empty array. * Caller hast to release the returned array. */ static struct key_array * validate_key_list (KEYDB_HANDLE hd, KeyHashTable full_trust, struct key_item *klist, u32 curtime, u32 *next_expire) { KBNODE keyblock = NULL; struct key_array *keys = NULL; size_t nkeys, maxkeys; int rc; KEYDB_SEARCH_DESC desc; maxkeys = 1000; keys = xmalloc ((maxkeys+1) * sizeof *keys); nkeys = 0; rc = keydb_search_reset (hd); if (rc) { log_error ("keydb_search_reset failed: %s\n", gpg_strerror (rc)); xfree (keys); return NULL; } memset (&desc, 0, sizeof desc); desc.mode = KEYDB_SEARCH_MODE_FIRST; desc.skipfnc = search_skipfnc; desc.skipfncvalue = full_trust; rc = keydb_search (hd, &desc, 1, NULL); if (gpg_err_code (rc) == GPG_ERR_NOT_FOUND) { keys[nkeys].keyblock = NULL; return keys; } if (rc) { log_error ("keydb_search(first) failed: %s\n", gpg_strerror (rc)); goto die; } desc.mode = KEYDB_SEARCH_MODE_NEXT; /* change mode */ do { PKT_public_key *pk; rc = keydb_get_keyblock (hd, &keyblock); if (rc) { log_error ("keydb_get_keyblock failed: %s\n", gpg_strerror (rc)); goto die; } if ( keyblock->pkt->pkttype != PKT_PUBLIC_KEY) { log_debug ("ooops: invalid pkttype %d encountered\n", keyblock->pkt->pkttype); dump_kbnode (keyblock); release_kbnode(keyblock); continue; } /* prepare the keyblock for further processing */ merge_keys_and_selfsig (keyblock); clear_kbnode_flags (keyblock); pk = keyblock->pkt->pkt.public_key; if (pk->has_expired || pk->flags.revoked) { /* it does not make sense to look further at those keys */ mark_keyblock_seen (full_trust, keyblock); } else if (validate_one_keyblock (keyblock, klist, curtime, next_expire)) { KBNODE node; if (pk->expiredate && pk->expiredate >= curtime && pk->expiredate < *next_expire) *next_expire = pk->expiredate; if (nkeys == maxkeys) { maxkeys += 1000; keys = xrealloc (keys, (maxkeys+1) * sizeof *keys); } keys[nkeys++].keyblock = keyblock; /* Optimization - if all uids are fully trusted, then we never need to consider this key as a candidate again. */ for (node=keyblock; node; node = node->next) if (node->pkt->pkttype == PKT_USER_ID && !(node->flag & 4)) break; if(node==NULL) mark_keyblock_seen (full_trust, keyblock); keyblock = NULL; } release_kbnode (keyblock); keyblock = NULL; } while (!(rc = keydb_search (hd, &desc, 1, NULL))); if (rc && gpg_err_code (rc) != GPG_ERR_NOT_FOUND) { log_error ("keydb_search_next failed: %s\n", gpg_strerror (rc)); goto die; } keys[nkeys].keyblock = NULL; return keys; die: keys[nkeys].keyblock = NULL; release_key_array (keys); return NULL; } /* Caller must sync */ static void reset_trust_records(void) { TRUSTREC rec; ulong recnum; int count = 0, nreset = 0; for (recnum=1; !tdbio_read_record (recnum, &rec, 0); recnum++ ) { if(rec.rectype==RECTYPE_TRUST) { count++; if(rec.r.trust.min_ownertrust) { rec.r.trust.min_ownertrust=0; write_record(&rec); } } else if(rec.rectype==RECTYPE_VALID && ((rec.r.valid.validity&TRUST_MASK) || rec.r.valid.marginal_count || rec.r.valid.full_count)) { rec.r.valid.validity &= ~TRUST_MASK; rec.r.valid.marginal_count=rec.r.valid.full_count=0; nreset++; write_record(&rec); } } if (opt.verbose) { log_info (ngettext("%d key processed", "%d keys processed", count), count); log_printf (ngettext(" (%d validity count cleared)\n", " (%d validity counts cleared)\n", nreset), nreset); } } /* * Run the key validation procedure. * * This works this way: * Step 1: Find all ultimately trusted keys (UTK). * mark them all as seen and put them into klist. * Step 2: loop max_cert_times * Step 3: if OWNERTRUST of any key in klist is undefined * ask user to assign ownertrust * Step 4: Loop over all keys in the keyDB which are not marked seen * Step 5: if key is revoked or expired * mark key as seen * continue loop at Step 4 * Step 6: For each user ID of that key signed by a key in klist * Calculate validity by counting trusted signatures. * Set validity of user ID * Step 7: If any signed user ID was found * mark key as seen * End Loop * Step 8: Build a new klist from all fully trusted keys from step 6 * End Loop * Ready * */ static int validate_keys (int interactive) { int rc = 0; int quit=0; struct key_item *klist = NULL; struct key_item *k; struct key_array *keys = NULL; struct key_array *kar; KEYDB_HANDLE kdb = NULL; KBNODE node; int depth; int ot_unknown, ot_undefined, ot_never, ot_marginal, ot_full, ot_ultimate; KeyHashTable stored,used,full_trust; u32 start_time, next_expire; /* Make sure we have all sigs cached. TODO: This is going to require some architectural re-thinking, as it is agonizingly slow. Perhaps combine this with reset_trust_records(), or only check the caches on keys that are actually involved in the web of trust. */ keydb_rebuild_caches(0); kdb = keydb_new (); if (!kdb) return gpg_error_from_syserror (); start_time = make_timestamp (); next_expire = 0xffffffff; /* set next expire to the year 2106 */ stored = new_key_hash_table (); used = new_key_hash_table (); full_trust = new_key_hash_table (); reset_trust_records(); /* Fixme: Instead of always building a UTK list, we could just build it * here when needed */ if (!utk_list) { if (!opt.quiet) log_info (_("no ultimately trusted keys found\n")); goto leave; } /* mark all UTKs as used and fully_trusted and set validity to ultimate */ for (k=utk_list; k; k = k->next) { KBNODE keyblock; PKT_public_key *pk; keyblock = get_pubkeyblock (k->kid); if (!keyblock) { log_error (_("public key of ultimately" " trusted key %s not found\n"), keystr(k->kid)); continue; } mark_keyblock_seen (used, keyblock); mark_keyblock_seen (stored, keyblock); mark_keyblock_seen (full_trust, keyblock); pk = keyblock->pkt->pkt.public_key; for (node=keyblock; node; node = node->next) { if (node->pkt->pkttype == PKT_USER_ID) update_validity (pk, node->pkt->pkt.user_id, 0, TRUST_ULTIMATE); } if ( pk->expiredate && pk->expiredate >= start_time && pk->expiredate < next_expire) next_expire = pk->expiredate; release_kbnode (keyblock); do_sync (); } if (opt.trust_model == TM_TOFU) /* In the TOFU trust model, we only need to save the ultimately trusted keys. */ goto leave; klist = utk_list; if (!opt.quiet) log_info ("marginals needed: %d completes needed: %d trust model: %s\n", opt.marginals_needed, opt.completes_needed, trust_model_string()); for (depth=0; depth < opt.max_cert_depth; depth++) { int valids=0,key_count; /* See whether we should assign ownertrust values to the keys in klist. */ ot_unknown = ot_undefined = ot_never = 0; ot_marginal = ot_full = ot_ultimate = 0; for (k=klist; k; k = k->next) { int min=0; /* 120 and 60 are as per RFC2440 */ if(k->trust_value>=120) min=TRUST_FULLY; else if(k->trust_value>=60) min=TRUST_MARGINAL; if(min!=k->min_ownertrust) update_min_ownertrust(k->kid,min); if (interactive && k->ownertrust == TRUST_UNKNOWN) { k->ownertrust = ask_ownertrust (k->kid,min); if (k->ownertrust == (unsigned int)(-1)) { quit=1; goto leave; } } /* This can happen during transition from an old trustdb before trust sigs. It can also happen if a user uses two different versions of GnuPG or changes the --trust-model setting. */ if(k->ownertrustkid[0],(ulong)k->kid[1], trust_value_to_string(k->ownertrust), trust_value_to_string(min)); k->ownertrust=min; } if (k->ownertrust == TRUST_UNKNOWN) ot_unknown++; else if (k->ownertrust == TRUST_UNDEFINED) ot_undefined++; else if (k->ownertrust == TRUST_NEVER) ot_never++; else if (k->ownertrust == TRUST_MARGINAL) ot_marginal++; else if (k->ownertrust == TRUST_FULLY) ot_full++; else if (k->ownertrust == TRUST_ULTIMATE) ot_ultimate++; valids++; } /* Find all keys which are signed by a key in kdlist */ keys = validate_key_list (kdb, full_trust, klist, start_time, &next_expire); if (!keys) { log_error ("validate_key_list failed\n"); rc = GPG_ERR_GENERAL; goto leave; } for (key_count=0, kar=keys; kar->keyblock; kar++, key_count++) ; /* Store the calculated valididation status somewhere */ if (opt.verbose > 1 && DBG_TRUST) dump_key_array (depth, keys); for (kar=keys; kar->keyblock; kar++) store_validation_status (depth, kar->keyblock, stored); if (!opt.quiet) log_info (_("depth: %d valid: %3d signed: %3d" " trust: %d-, %dq, %dn, %dm, %df, %du\n"), depth, valids, key_count, ot_unknown, ot_undefined, ot_never, ot_marginal, ot_full, ot_ultimate ); /* Build a new kdlist from all fully valid keys in KEYS */ if (klist != utk_list) release_key_items (klist); klist = NULL; for (kar=keys; kar->keyblock; kar++) { for (node=kar->keyblock; node; node = node->next) { if (node->pkt->pkttype == PKT_USER_ID && (node->flag & 4)) { u32 kid[2]; /* have we used this key already? */ keyid_from_pk (kar->keyblock->pkt->pkt.public_key, kid); if(test_key_hash_table(used,kid)==0) { /* Normally we add both the primary and subkey ids to the hash via mark_keyblock_seen, but since we aren't using this hash as a skipfnc, that doesn't matter here. */ add_key_hash_table (used,kid); k = new_key_item (); k->kid[0]=kid[0]; k->kid[1]=kid[1]; k->ownertrust = (tdb_get_ownertrust (kar->keyblock->pkt->pkt.public_key) & TRUST_MASK); k->min_ownertrust = tdb_get_min_ownertrust (kar->keyblock->pkt->pkt.public_key); k->trust_depth= kar->keyblock->pkt->pkt.public_key->trust_depth; k->trust_value= kar->keyblock->pkt->pkt.public_key->trust_value; if(kar->keyblock->pkt->pkt.public_key->trust_regexp) k->trust_regexp= xstrdup(kar->keyblock->pkt-> pkt.public_key->trust_regexp); k->next = klist; klist = k; break; } } } } release_key_array (keys); keys = NULL; if (!klist) break; /* no need to dive in deeper */ } leave: keydb_release (kdb); release_key_array (keys); if (klist != utk_list) release_key_items (klist); release_key_hash_table (full_trust); release_key_hash_table (used); release_key_hash_table (stored); if (!rc && !quit) /* mark trustDB as checked */ { int rc2; if (next_expire == 0xffffffff || next_expire < start_time ) tdbio_write_nextcheck (0); else { tdbio_write_nextcheck (next_expire); if (!opt.quiet) log_info (_("next trustdb check due at %s\n"), strtimestamp (next_expire)); } rc2 = tdbio_update_version_record (); if (rc2) { log_error (_("unable to update trustdb version record: " "write failed: %s\n"), gpg_strerror (rc2)); tdbio_invalid (); } do_sync (); pending_check_trustdb = 0; } return rc; }