/* tdbio.c * Copyright (C) 1998, 1999, 2000, 2001, 2002, 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 #include #include #include #include #include #include "errors.h" #include "iobuf.h" #include "memory.h" #include "util.h" #include "options.h" #include "main.h" #include "i18n.h" #include "trustdb.h" #include "tdbio.h" #if defined(HAVE_DOSISH_SYSTEM) && !defined(ftruncate) #define ftruncate chsize #endif #if defined(HAVE_DOSISH_SYSTEM) || defined(__CYGWIN__) #define MY_O_BINARY O_BINARY #else #define MY_O_BINARY 0 #endif /**************** * Yes, this is a very simple implementation. We should really * use a page aligned buffer and read complete pages. * To implement a simple trannsaction system, this is sufficient. */ typedef struct cache_ctrl_struct *CACHE_CTRL; struct cache_ctrl_struct { CACHE_CTRL next; struct { unsigned used:1; unsigned dirty:1; } flags; ulong recno; char data[TRUST_RECORD_LEN]; }; #define MAX_CACHE_ENTRIES_SOFT 200 /* may be increased while in a */ #define MAX_CACHE_ENTRIES_HARD 10000 /* transaction to this one */ static CACHE_CTRL cache_list; static int cache_entries; static int cache_is_dirty; /* a type used to pass infomation to cmp_krec_fpr */ struct cmp_krec_fpr_struct { int pubkey_algo; const char *fpr; int fprlen; }; /* a type used to pass infomation to cmp_[s]dir */ struct cmp_xdir_struct { int pubkey_algo; u32 keyid[2]; }; static char *db_name; static dotlock_t lockhandle; static int is_locked; static int db_fd = -1; static int in_transaction; static void open_db(void); static void migrate_from_v2 (void); static int take_write_lock (void) { if (!lockhandle) lockhandle = dotlock_create (db_name, 0); if (!lockhandle) log_fatal ( _("can't create lock for `%s'\n"), db_name ); if (!is_locked) { if (dotlock_take (lockhandle, -1) ) log_fatal ( _("can't lock `%s'\n"), db_name ); else is_locked = 1; return 0; } else return 1; } static void release_write_lock (void) { if (!opt.lock_once) if (!dotlock_release (lockhandle)) is_locked = 0; } /************************************* ************* record cache ********** *************************************/ /**************** * Get the data from therecord cache and return a * pointer into that cache. Caller should copy * the return data. NULL is returned on a cache miss. */ static const char * get_record_from_cache( ulong recno ) { CACHE_CTRL r; for( r = cache_list; r; r = r->next ) { if( r->flags.used && r->recno == recno ) return r->data; } return NULL; } static int write_cache_item( CACHE_CTRL r ) { int n; if( lseek( db_fd, r->recno * TRUST_RECORD_LEN, SEEK_SET ) == -1 ) { log_error(_("trustdb rec %lu: lseek failed: %s\n"), r->recno, strerror(errno) ); return G10ERR_WRITE_FILE; } n = write( db_fd, r->data, TRUST_RECORD_LEN); if( n != TRUST_RECORD_LEN ) { log_error(_("trustdb rec %lu: write failed (n=%d): %s\n"), r->recno, n, strerror(errno) ); return G10ERR_WRITE_FILE; } r->flags.dirty = 0; return 0; } /**************** * Put data into the cache. This function may flush the * some cache entries if there is not enough space available. */ int put_record_into_cache( ulong recno, const char *data ) { CACHE_CTRL r, unused; int dirty_count = 0; int clean_count = 0; /* see whether we already cached this one */ for( unused = NULL, r = cache_list; r; r = r->next ) { if( !r->flags.used ) { if( !unused ) unused = r; } else if( r->recno == recno ) { if( !r->flags.dirty ) { /* Hmmm: should we use a a copy and compare? */ if( memcmp(r->data, data, TRUST_RECORD_LEN ) ) { r->flags.dirty = 1; cache_is_dirty = 1; } } memcpy( r->data, data, TRUST_RECORD_LEN ); return 0; } if( r->flags.used ) { if( r->flags.dirty ) dirty_count++; else clean_count++; } } /* not in the cache: add a new entry */ if( unused ) { /* reuse this entry */ r = unused; r->flags.used = 1; r->recno = recno; memcpy( r->data, data, TRUST_RECORD_LEN ); r->flags.dirty = 1; cache_is_dirty = 1; cache_entries++; return 0; } /* see whether we reached the limit */ if( cache_entries < MAX_CACHE_ENTRIES_SOFT ) { /* no */ r = xmalloc( sizeof *r ); r->flags.used = 1; r->recno = recno; memcpy( r->data, data, TRUST_RECORD_LEN ); r->flags.dirty = 1; r->next = cache_list; cache_list = r; cache_is_dirty = 1; cache_entries++; return 0; } /* cache is full: discard some clean entries */ if( clean_count ) { int n = clean_count / 3; /* discard a third of the clean entries */ if( !n ) n = 1; for( unused = NULL, r = cache_list; r; r = r->next ) { if( r->flags.used && !r->flags.dirty ) { if( !unused ) unused = r; r->flags.used = 0; cache_entries--; if( !--n ) break; } } assert( unused ); r = unused; r->flags.used = 1; r->recno = recno; memcpy( r->data, data, TRUST_RECORD_LEN ); r->flags.dirty = 1; cache_is_dirty = 1; cache_entries++; return 0; } /* no clean entries: have to flush some dirty entries */ if( in_transaction ) { /* but we can't do this while in a transaction * we increase the cache size instead */ if( cache_entries < MAX_CACHE_ENTRIES_HARD ) { /* no */ if( opt.debug && !(cache_entries % 100) ) log_debug("increasing tdbio cache size\n"); r = xmalloc( sizeof *r ); r->flags.used = 1; r->recno = recno; memcpy( r->data, data, TRUST_RECORD_LEN ); r->flags.dirty = 1; r->next = cache_list; cache_list = r; cache_is_dirty = 1; cache_entries++; return 0; } log_info(_("trustdb transaction too large\n")); return G10ERR_RESOURCE_LIMIT; } if( dirty_count ) { int n = dirty_count / 5; /* discard some dirty entries */ if( !n ) n = 1; take_write_lock (); for( unused = NULL, r = cache_list; r; r = r->next ) { if( r->flags.used && r->flags.dirty ) { int rc = write_cache_item( r ); if( rc ) return rc; if( !unused ) unused = r; r->flags.used = 0; cache_entries--; if( !--n ) break; } } release_write_lock (); assert( unused ); r = unused; r->flags.used = 1; r->recno = recno; memcpy( r->data, data, TRUST_RECORD_LEN ); r->flags.dirty = 1; cache_is_dirty = 1; cache_entries++; return 0; } BUG(); } int tdbio_is_dirty() { return cache_is_dirty; } /**************** * Flush the cache. This cannot be used while in a transaction. */ int tdbio_sync() { CACHE_CTRL r; int did_lock = 0; if( db_fd == -1 ) open_db(); if( in_transaction ) log_bug("tdbio: syncing while in transaction\n"); if( !cache_is_dirty ) return 0; if (!take_write_lock ()) did_lock = 1; for( r = cache_list; r; r = r->next ) { if( r->flags.used && r->flags.dirty ) { int rc = write_cache_item( r ); if( rc ) return rc; } } cache_is_dirty = 0; if (did_lock) release_write_lock (); return 0; } #if 0 /* The transaction code is disabled in the 1.2.x branch, as it is not yet used. It will be enabled in 1.3.x. */ /**************** * Simple transactions system: * Everything between begin_transaction and end/cancel_transaction * is not immediatly written but at the time of end_transaction. * */ int tdbio_begin_transaction() { int rc; if( in_transaction ) log_bug("tdbio: nested transactions\n"); /* flush everything out */ rc = tdbio_sync(); if( rc ) return rc; in_transaction = 1; return 0; } int tdbio_end_transaction() { int rc; if( !in_transaction ) log_bug("tdbio: no active transaction\n"); take_write_lock (); block_all_signals(); in_transaction = 0; rc = tdbio_sync(); unblock_all_signals(); release_write_lock (); return rc; } int tdbio_cancel_transaction() { CACHE_CTRL r; if( !in_transaction ) log_bug("tdbio: no active transaction\n"); /* remove all dirty marked entries, so that the original ones * are read back the next time */ if( cache_is_dirty ) { for( r = cache_list; r; r = r->next ) { if( r->flags.used && r->flags.dirty ) { r->flags.used = 0; cache_entries--; } } cache_is_dirty = 0; } in_transaction = 0; return 0; } #endif /******************************************************** **************** cached I/O functions ****************** ********************************************************/ static void cleanup(void) { if( is_locked ) { if (!dotlock_release (lockhandle)) is_locked = 0; } } /* Caller must sync */ int tdbio_update_version_record (void) { TRUSTREC rec; int rc; memset( &rec, 0, sizeof rec ); rc=tdbio_read_record( 0, &rec, RECTYPE_VER); if(rc==0) { rec.r.ver.created = make_timestamp(); rec.r.ver.marginals = opt.marginals_needed; rec.r.ver.completes = opt.completes_needed; rec.r.ver.cert_depth = opt.max_cert_depth; rec.r.ver.trust_model = opt.trust_model; rec.r.ver.min_cert_level = opt.min_cert_level; rc=tdbio_write_record(&rec); } return rc; } static int create_version_record (void) { TRUSTREC rec; int rc; memset( &rec, 0, sizeof rec ); rec.r.ver.version = 3; rec.r.ver.created = make_timestamp(); rec.r.ver.marginals = opt.marginals_needed; rec.r.ver.completes = opt.completes_needed; rec.r.ver.cert_depth = opt.max_cert_depth; if(opt.trust_model==TM_PGP || opt.trust_model==TM_CLASSIC) rec.r.ver.trust_model = opt.trust_model; else rec.r.ver.trust_model = TM_PGP; rec.r.ver.min_cert_level = opt.min_cert_level; rec.rectype = RECTYPE_VER; rec.recnum = 0; rc = tdbio_write_record( &rec ); if( !rc ) tdbio_sync(); return rc; } int tdbio_set_dbname( const char *new_dbname, int create, int *r_nofile) { char *fname, *p; struct stat statbuf; static int initialized = 0; if( !initialized ) { atexit( cleanup ); initialized = 1; } *r_nofile = 0; if(new_dbname==NULL) fname=make_filename(opt.homedir,"trustdb" EXTSEP_S "gpg", NULL); else if (*new_dbname != DIRSEP_C ) { if (strchr(new_dbname, DIRSEP_C) ) fname = make_filename (new_dbname, NULL); else fname = make_filename (opt.homedir, new_dbname, NULL); } else fname = xstrdup (new_dbname); xfree (db_name); db_name = fname; /* * Quick check for (likely) case where there is trustdb.gpg * already. This check is not required in theory, but it helps in * practice, avoiding costly operations of preparing and taking * the lock. */ if (stat (fname, &statbuf) == 0 && statbuf.st_size > 0) /* OK, we have the valid trustdb.gpg already. */ return 0; else if (!create) { *r_nofile = 1; return 0; } /* Here comes: No valid trustdb.gpg AND CREATE==1 */ /* * Make sure the directory exists. This should be done before * acquiring the lock, which assumes the directory existence. */ p = strrchr( fname, DIRSEP_C ); assert(p); /* See the code above. Always, it has DIRSEP_C. */ *p = 0; if( access( fname, F_OK ) ) { try_make_homedir( fname ); if (access (fname, F_OK )) log_fatal (_("%s: directory does not exist!\n"), p); } *p = DIRSEP_C; take_write_lock (); /* Check the file after aquiring the lock. */ if( access( fname, R_OK ) ) { FILE *fp; TRUSTREC rec; int rc; mode_t oldmask; if( errno != ENOENT ) log_fatal( _("can't access `%s': %s\n"), fname, strerror(errno) ); oldmask=umask(077); if (is_secured_filename (fname)) { fp = NULL; errno = EPERM; } else fp =fopen( fname, "wb" ); umask(oldmask); if( !fp ) log_fatal( _("can't create `%s': %s\n"), fname, strerror(errno) ); fclose(fp); db_fd = open( db_name, O_RDWR | MY_O_BINARY ); if( db_fd == -1 ) log_fatal( _("can't open `%s': %s\n"), db_name, strerror(errno) ); rc = create_version_record (); if( rc ) log_fatal( _("%s: failed to create version record: %s"), fname, g10_errstr(rc)); /* and read again to check that we are okay */ if( tdbio_read_record( 0, &rec, RECTYPE_VER ) ) log_fatal( _("%s: invalid trustdb created\n"), db_name ); if( !opt.quiet ) log_info(_("%s: trustdb created\n"), db_name); } release_write_lock (); return 0; } const char * tdbio_get_dbname() { return db_name; } static void open_db() { byte buf[10]; int n; TRUSTREC rec; assert( db_fd == -1 ); db_fd = open (db_name, O_RDWR | MY_O_BINARY ); if (db_fd == -1 && (errno == EACCES #ifdef EROFS || errno == EROFS #endif ) ) { db_fd = open (db_name, O_RDONLY | MY_O_BINARY ); if (db_fd != -1) log_info (_("NOTE: trustdb not writable\n")); } if ( db_fd == -1 ) log_fatal( _("can't open `%s': %s\n"), db_name, strerror(errno) ); register_secured_file (db_name); /* check whether we need to do a version migration */ do n = read (db_fd, buf, 5); while (n==-1 && errno == EINTR); if (n == 5 && !memcmp (buf, "\x01gpg\x02", 5)) { migrate_from_v2 (); } /* read the version record */ if (tdbio_read_record (0, &rec, RECTYPE_VER ) ) log_fatal( _("%s: invalid trustdb\n"), db_name ); } /**************** * Make a hashtable: type 0 = trust hash */ static void create_hashtable( TRUSTREC *vr, int type ) { TRUSTREC rec; off_t offset; ulong recnum; int i, n, rc; offset = lseek( db_fd, 0, SEEK_END ); if( offset == -1 ) log_fatal("trustdb: lseek to end failed: %s\n", strerror(errno) ); recnum = offset / TRUST_RECORD_LEN; assert(recnum); /* this is will never be the first record */ if( !type ) vr->r.ver.trusthashtbl = recnum; /* Now write the records */ n = (256+ITEMS_PER_HTBL_RECORD-1) / ITEMS_PER_HTBL_RECORD; for(i=0; i < n; i++, recnum++ ) { memset( &rec, 0, sizeof rec ); rec.rectype = RECTYPE_HTBL; rec.recnum = recnum; rc = tdbio_write_record( &rec ); if( rc ) log_fatal( _("%s: failed to create hashtable: %s\n"), db_name, g10_errstr(rc)); } /* update the version record */ rc = tdbio_write_record( vr ); if( !rc ) rc = tdbio_sync(); if( rc ) log_fatal( _("%s: error updating version record: %s\n"), db_name, g10_errstr(rc)); } int tdbio_db_matches_options() { static int yes_no = -1; if( yes_no == -1 ) { TRUSTREC vr; int rc; rc = tdbio_read_record( 0, &vr, RECTYPE_VER ); if( rc ) log_fatal( _("%s: error reading version record: %s\n"), db_name, g10_errstr(rc) ); yes_no = vr.r.ver.marginals == opt.marginals_needed && vr.r.ver.completes == opt.completes_needed && vr.r.ver.cert_depth == opt.max_cert_depth && vr.r.ver.trust_model == opt.trust_model && vr.r.ver.min_cert_level == opt.min_cert_level; } return yes_no; } byte tdbio_read_model(void) { TRUSTREC vr; int rc; rc = tdbio_read_record( 0, &vr, RECTYPE_VER ); if( rc ) log_fatal( _("%s: error reading version record: %s\n"), db_name, g10_errstr(rc) ); return vr.r.ver.trust_model; } /**************** * Return the nextstamp value. */ ulong tdbio_read_nextcheck () { TRUSTREC vr; int rc; rc = tdbio_read_record( 0, &vr, RECTYPE_VER ); if( rc ) log_fatal( _("%s: error reading version record: %s\n"), db_name, g10_errstr(rc) ); return vr.r.ver.nextcheck; } /* Return true when the stamp was actually changed. */ int tdbio_write_nextcheck (ulong stamp) { TRUSTREC vr; int rc; rc = tdbio_read_record( 0, &vr, RECTYPE_VER ); if( rc ) log_fatal( _("%s: error reading version record: %s\n"), db_name, g10_errstr(rc) ); if (vr.r.ver.nextcheck == stamp) return 0; vr.r.ver.nextcheck = stamp; rc = tdbio_write_record( &vr ); if( rc ) log_fatal( _("%s: error writing version record: %s\n"), db_name, g10_errstr(rc) ); return 1; } /**************** * Return the record number of the trusthash tbl or create a new one. */ static ulong get_trusthashrec(void) { static ulong trusthashtbl; /* record number of the trust hashtable */ if( !trusthashtbl ) { TRUSTREC vr; int rc; rc = tdbio_read_record( 0, &vr, RECTYPE_VER ); if( rc ) log_fatal( _("%s: error reading version record: %s\n"), db_name, g10_errstr(rc) ); if( !vr.r.ver.trusthashtbl ) create_hashtable( &vr, 0 ); trusthashtbl = vr.r.ver.trusthashtbl; } return trusthashtbl; } /**************** * Update a hashtable. * table gives the start of the table, key and keylen is the key, * newrecnum is the record number to insert. */ static int upd_hashtable( ulong table, byte *key, int keylen, ulong newrecnum ) { TRUSTREC lastrec, rec; ulong hashrec, item; int msb; int level=0; int rc, i; hashrec = table; next_level: msb = key[level]; hashrec += msb / ITEMS_PER_HTBL_RECORD; rc = tdbio_read_record( hashrec, &rec, RECTYPE_HTBL ); if( rc ) { log_error("upd_hashtable: read failed: %s\n", g10_errstr(rc) ); return rc; } item = rec.r.htbl.item[msb % ITEMS_PER_HTBL_RECORD]; if( !item ) { /* insert a new item into the hash table */ rec.r.htbl.item[msb % ITEMS_PER_HTBL_RECORD] = newrecnum; rc = tdbio_write_record( &rec ); if( rc ) { log_error("upd_hashtable: write htbl failed: %s\n", g10_errstr(rc) ); return rc; } } else if( item != newrecnum ) { /* must do an update */ lastrec = rec; rc = tdbio_read_record( item, &rec, 0 ); if( rc ) { log_error( "upd_hashtable: read item failed: %s\n", g10_errstr(rc) ); return rc; } if( rec.rectype == RECTYPE_HTBL ) { hashrec = item; level++; if( level >= keylen ) { log_error( "hashtable has invalid indirections.\n"); return G10ERR_TRUSTDB; } goto next_level; } else if( rec.rectype == RECTYPE_HLST ) { /* extend list */ /* see whether the key is already in this list */ for(;;) { for(i=0; i < ITEMS_PER_HLST_RECORD; i++ ) { if( rec.r.hlst.rnum[i] == newrecnum ) { return 0; /* okay, already in the list */ } } if( rec.r.hlst.next ) { rc = tdbio_read_record( rec.r.hlst.next, &rec, RECTYPE_HLST); if( rc ) { log_error( "upd_hashtable: read hlst failed: %s\n", g10_errstr(rc) ); return rc; } } else break; /* not there */ } /* find the next free entry and put it in */ for(;;) { for(i=0; i < ITEMS_PER_HLST_RECORD; i++ ) { if( !rec.r.hlst.rnum[i] ) { rec.r.hlst.rnum[i] = newrecnum; rc = tdbio_write_record( &rec ); if( rc ) log_error( "upd_hashtable: write hlst failed: %s\n", g10_errstr(rc) ); return rc; /* done */ } } if( rec.r.hlst.next ) { rc = tdbio_read_record( rec.r.hlst.next, &rec, RECTYPE_HLST ); if( rc ) { log_error( "upd_hashtable: read hlst failed: %s\n", g10_errstr(rc) ); return rc; } } else { /* add a new list record */ rec.r.hlst.next = item = tdbio_new_recnum(); rc = tdbio_write_record( &rec ); if( rc ) { log_error( "upd_hashtable: write hlst failed: %s\n", g10_errstr(rc) ); return rc; } memset( &rec, 0, sizeof rec ); rec.rectype = RECTYPE_HLST; rec.recnum = item; rec.r.hlst.rnum[0] = newrecnum; rc = tdbio_write_record( &rec ); if( rc ) log_error( "upd_hashtable: write ext hlst failed: %s\n", g10_errstr(rc) ); return rc; /* done */ } } /* end loop over hlst slots */ } else if( rec.rectype == RECTYPE_TRUST ) { /* insert a list record */ if( rec.recnum == newrecnum ) { return 0; } item = rec.recnum; /* save number of key record */ memset( &rec, 0, sizeof rec ); rec.rectype = RECTYPE_HLST; rec.recnum = tdbio_new_recnum(); rec.r.hlst.rnum[0] = item; /* old keyrecord */ rec.r.hlst.rnum[1] = newrecnum; /* and new one */ rc = tdbio_write_record( &rec ); if( rc ) { log_error( "upd_hashtable: write new hlst failed: %s\n", g10_errstr(rc) ); return rc; } /* update the hashtable record */ lastrec.r.htbl.item[msb % ITEMS_PER_HTBL_RECORD] = rec.recnum; rc = tdbio_write_record( &lastrec ); if( rc ) log_error( "upd_hashtable: update htbl failed: %s\n", g10_errstr(rc) ); return rc; /* ready */ } else { log_error( "hashtbl %lu: %lu/%d points to an invalid record %lu\n", table, hashrec, (msb % ITEMS_PER_HTBL_RECORD), item); list_trustdb(NULL); return G10ERR_TRUSTDB; } } return 0; } /**************** * Drop an entry from a hashtable * table gives the start of the table, key and keylen is the key, */ static int drop_from_hashtable( ulong table, byte *key, int keylen, ulong recnum ) { TRUSTREC rec; ulong hashrec, item; int msb; int level=0; int rc, i; hashrec = table; next_level: msb = key[level]; hashrec += msb / ITEMS_PER_HTBL_RECORD; rc = tdbio_read_record( hashrec, &rec, RECTYPE_HTBL ); if( rc ) { log_error("drop_from_hashtable: read failed: %s\n", g10_errstr(rc) ); return rc; } item = rec.r.htbl.item[msb % ITEMS_PER_HTBL_RECORD]; if( !item ) /* not found - forget about it */ return 0; if( item == recnum ) { /* tables points direct to the record */ rec.r.htbl.item[msb % ITEMS_PER_HTBL_RECORD] = 0; rc = tdbio_write_record( &rec ); if( rc ) log_error("drop_from_hashtable: write htbl failed: %s\n", g10_errstr(rc) ); return rc; } rc = tdbio_read_record( item, &rec, 0 ); if( rc ) { log_error( "drop_from_hashtable: read item failed: %s\n", g10_errstr(rc) ); return rc; } if( rec.rectype == RECTYPE_HTBL ) { hashrec = item; level++; if( level >= keylen ) { log_error( "hashtable has invalid indirections.\n"); return G10ERR_TRUSTDB; } goto next_level; } if( rec.rectype == RECTYPE_HLST ) { for(;;) { for(i=0; i < ITEMS_PER_HLST_RECORD; i++ ) { if( rec.r.hlst.rnum[i] == recnum ) { rec.r.hlst.rnum[i] = 0; /* drop */ rc = tdbio_write_record( &rec ); if( rc ) log_error("drop_from_hashtable: write htbl failed: %s\n", g10_errstr(rc) ); return rc; } } if( rec.r.hlst.next ) { rc = tdbio_read_record( rec.r.hlst.next, &rec, RECTYPE_HLST); if( rc ) { log_error( "drop_from_hashtable: read hlst failed: %s\n", g10_errstr(rc) ); return rc; } } else return 0; /* key not in table */ } } log_error( "hashtbl %lu: %lu/%d points to wrong record %lu\n", table, hashrec, (msb % ITEMS_PER_HTBL_RECORD), item); return G10ERR_TRUSTDB; } /**************** * Lookup a record via the hashtable tablewith key/keylen and return the * result in rec. cmp() should return if the record is the desired one. * Returns -1 if not found, 0 if found or another errocode */ static int lookup_hashtable( ulong table, const byte *key, size_t keylen, int (*cmpfnc)(const void*, const TRUSTREC *), const void *cmpdata, TRUSTREC *rec ) { int rc; ulong hashrec, item; int msb; int level=0; hashrec = table; next_level: msb = key[level]; hashrec += msb / ITEMS_PER_HTBL_RECORD; rc = tdbio_read_record( hashrec, rec, RECTYPE_HTBL ); if( rc ) { log_error("lookup_hashtable failed: %s\n", g10_errstr(rc) ); return rc; } item = rec->r.htbl.item[msb % ITEMS_PER_HTBL_RECORD]; if( !item ) return -1; /* not found */ rc = tdbio_read_record( item, rec, 0 ); if( rc ) { log_error( "hashtable read failed: %s\n", g10_errstr(rc) ); return rc; } if( rec->rectype == RECTYPE_HTBL ) { hashrec = item; level++; if( level >= keylen ) { log_error("hashtable has invalid indirections\n"); return G10ERR_TRUSTDB; } goto next_level; } else if( rec->rectype == RECTYPE_HLST ) { for(;;) { int i; for(i=0; i < ITEMS_PER_HLST_RECORD; i++ ) { if( rec->r.hlst.rnum[i] ) { TRUSTREC tmp; rc = tdbio_read_record( rec->r.hlst.rnum[i], &tmp, 0 ); if( rc ) { log_error( "lookup_hashtable: read item failed: %s\n", g10_errstr(rc) ); return rc; } if( (*cmpfnc)( cmpdata, &tmp ) ) { *rec = tmp; return 0; } } } if( rec->r.hlst.next ) { rc = tdbio_read_record( rec->r.hlst.next, rec, RECTYPE_HLST ); if( rc ) { log_error( "lookup_hashtable: read hlst failed: %s\n", g10_errstr(rc) ); return rc; } } else return -1; /* not found */ } } if( (*cmpfnc)( cmpdata, rec ) ) return 0; /* really found */ return -1; /* no: not found */ } /**************** * Update the trust hashtbl or create the table if it does not exist */ static int update_trusthashtbl( TRUSTREC *tr ) { return upd_hashtable( get_trusthashrec(), tr->r.trust.fingerprint, 20, tr->recnum ); } void tdbio_dump_record( TRUSTREC *rec, FILE *fp ) { int i; ulong rnum = rec->recnum; fprintf(fp, "rec %5lu, ", rnum ); switch( rec->rectype ) { case 0: fprintf(fp, "blank\n"); break; case RECTYPE_VER: fprintf(fp, "version, td=%lu, f=%lu, m/c/d=%d/%d/%d tm=%d mcl=%d nc=%lu (%s)\n", rec->r.ver.trusthashtbl, rec->r.ver.firstfree, rec->r.ver.marginals, rec->r.ver.completes, rec->r.ver.cert_depth, rec->r.ver.trust_model, rec->r.ver.min_cert_level, rec->r.ver.nextcheck, strtimestamp(rec->r.ver.nextcheck) ); break; case RECTYPE_FREE: fprintf(fp, "free, next=%lu\n", rec->r.free.next ); break; case RECTYPE_HTBL: fprintf(fp, "htbl,"); for(i=0; i < ITEMS_PER_HTBL_RECORD; i++ ) fprintf(fp, " %lu", rec->r.htbl.item[i] ); putc('\n', fp); break; case RECTYPE_HLST: fprintf(fp, "hlst, next=%lu,", rec->r.hlst.next ); for(i=0; i < ITEMS_PER_HLST_RECORD; i++ ) fprintf(fp, " %lu", rec->r.hlst.rnum[i] ); putc('\n', fp); break; case RECTYPE_TRUST: fprintf(fp, "trust "); for(i=0; i < 20; i++ ) fprintf(fp, "%02X", rec->r.trust.fingerprint[i] ); fprintf (fp, ", ot=%d, d=%d, vl=%lu\n", rec->r.trust.ownertrust, rec->r.trust.depth, rec->r.trust.validlist); break; case RECTYPE_VALID: fprintf(fp, "valid "); for(i=0; i < 20; i++ ) fprintf(fp, "%02X", rec->r.valid.namehash[i] ); fprintf (fp, ", v=%d, next=%lu\n", rec->r.valid.validity, rec->r.valid.next); break; default: fprintf(fp, "unknown type %d\n", rec->rectype ); break; } } /**************** * read the record with number recnum * returns: -1 on error, 0 on success */ int tdbio_read_record( ulong recnum, TRUSTREC *rec, int expected ) { byte readbuf[TRUST_RECORD_LEN]; const byte *buf, *p; int rc = 0; int n, i; if( db_fd == -1 ) open_db(); buf = get_record_from_cache( recnum ); if( !buf ) { if( lseek( db_fd, recnum * TRUST_RECORD_LEN, SEEK_SET ) == -1 ) { log_error(_("trustdb: lseek failed: %s\n"), strerror(errno) ); return G10ERR_READ_FILE; } n = read( db_fd, readbuf, TRUST_RECORD_LEN); if( !n ) { return -1; /* eof */ } else if( n != TRUST_RECORD_LEN ) { log_error(_("trustdb: read failed (n=%d): %s\n"), n, strerror(errno) ); return G10ERR_READ_FILE; } buf = readbuf; } rec->recnum = recnum; rec->dirty = 0; p = buf; rec->rectype = *p++; if( expected && rec->rectype != expected ) { log_error("%lu: read expected rec type %d, got %d\n", recnum, expected, rec->rectype ); return G10ERR_TRUSTDB; } p++; /* skip reserved byte */ switch( rec->rectype ) { case 0: /* unused (free) record */ break; case RECTYPE_VER: /* version record */ if( memcmp(buf+1, "gpg", 3 ) ) { log_error( _("%s: not a trustdb file\n"), db_name ); rc = G10ERR_TRUSTDB; } p += 2; /* skip "gpg" */ rec->r.ver.version = *p++; rec->r.ver.marginals = *p++; rec->r.ver.completes = *p++; rec->r.ver.cert_depth = *p++; rec->r.ver.trust_model = *p++; rec->r.ver.min_cert_level = *p++; p += 2; rec->r.ver.created = buf32_to_ulong (p); p += 4; rec->r.ver.nextcheck = buf32_to_ulong (p); p += 4; p += 4; p += 4; rec->r.ver.firstfree =buf32_to_ulong (p); p += 4; p += 4; rec->r.ver.trusthashtbl =buf32_to_ulong (p); p += 4; if( recnum ) { log_error( _("%s: version record with recnum %lu\n"), db_name, (ulong)recnum ); rc = G10ERR_TRUSTDB; } else if( rec->r.ver.version != 3 ) { log_error( _("%s: invalid file version %d\n"), db_name, rec->r.ver.version ); rc = G10ERR_TRUSTDB; } break; case RECTYPE_FREE: rec->r.free.next = buf32_to_ulong (p); p += 4; break; case RECTYPE_HTBL: for(i=0; i < ITEMS_PER_HTBL_RECORD; i++ ) { rec->r.htbl.item[i] = buf32_to_ulong (p); p += 4; } break; case RECTYPE_HLST: rec->r.hlst.next = buf32_to_ulong (p); p += 4; for(i=0; i < ITEMS_PER_HLST_RECORD; i++ ) { rec->r.hlst.rnum[i] = buf32_to_ulong (p); p += 4; } break; case RECTYPE_TRUST: memcpy( rec->r.trust.fingerprint, p, 20); p+=20; rec->r.trust.ownertrust = *p++; rec->r.trust.depth = *p++; rec->r.trust.min_ownertrust = *p++; p++; rec->r.trust.validlist = buf32_to_ulong (p); p += 4; break; case RECTYPE_VALID: memcpy( rec->r.valid.namehash, p, 20); p+=20; rec->r.valid.validity = *p++; rec->r.valid.next = buf32_to_ulong (p); p += 4; rec->r.valid.full_count = *p++; rec->r.valid.marginal_count = *p++; break; default: log_error( "%s: invalid record type %d at recnum %lu\n", db_name, rec->rectype, (ulong)recnum ); rc = G10ERR_TRUSTDB; break; } return rc; } /**************** * Write the record at RECNUM */ int tdbio_write_record( TRUSTREC *rec ) { byte buf[TRUST_RECORD_LEN], *p; int rc = 0; int i; ulong recnum = rec->recnum; if( db_fd == -1 ) open_db(); memset(buf, 0, TRUST_RECORD_LEN); p = buf; *p++ = rec->rectype; p++; switch( rec->rectype ) { case 0: /* unused record */ break; case RECTYPE_VER: /* version record */ if( recnum ) BUG(); memcpy(p-1, "gpg", 3 ); p += 2; *p++ = rec->r.ver.version; *p++ = rec->r.ver.marginals; *p++ = rec->r.ver.completes; *p++ = rec->r.ver.cert_depth; *p++ = rec->r.ver.trust_model; *p++ = rec->r.ver.min_cert_level; p += 2; ulongtobuf(p, rec->r.ver.created); p += 4; ulongtobuf(p, rec->r.ver.nextcheck); p += 4; p += 4; p += 4; ulongtobuf(p, rec->r.ver.firstfree ); p += 4; p += 4; ulongtobuf(p, rec->r.ver.trusthashtbl ); p += 4; break; case RECTYPE_FREE: ulongtobuf(p, rec->r.free.next); p += 4; break; case RECTYPE_HTBL: for(i=0; i < ITEMS_PER_HTBL_RECORD; i++ ) { ulongtobuf( p, rec->r.htbl.item[i]); p += 4; } break; case RECTYPE_HLST: ulongtobuf( p, rec->r.hlst.next); p += 4; for(i=0; i < ITEMS_PER_HLST_RECORD; i++ ) { ulongtobuf( p, rec->r.hlst.rnum[i]); p += 4; } break; case RECTYPE_TRUST: memcpy( p, rec->r.trust.fingerprint, 20); p += 20; *p++ = rec->r.trust.ownertrust; *p++ = rec->r.trust.depth; *p++ = rec->r.trust.min_ownertrust; p++; ulongtobuf( p, rec->r.trust.validlist); p += 4; break; case RECTYPE_VALID: memcpy( p, rec->r.valid.namehash, 20); p += 20; *p++ = rec->r.valid.validity; ulongtobuf( p, rec->r.valid.next); p += 4; *p++ = rec->r.valid.full_count; *p++ = rec->r.valid.marginal_count; break; default: BUG(); } rc = put_record_into_cache( recnum, buf ); if( rc ) ; else if( rec->rectype == RECTYPE_TRUST ) rc = update_trusthashtbl( rec ); return rc; } int tdbio_delete_record( ulong recnum ) { TRUSTREC vr, rec; int rc; /* Must read the record fist, so we can drop it from the hash tables */ rc = tdbio_read_record( recnum, &rec, 0 ); if( rc ) ; else if( rec.rectype == RECTYPE_TRUST ) { rc = drop_from_hashtable( get_trusthashrec(), rec.r.trust.fingerprint, 20, rec.recnum ); } if( rc ) return rc; /* now we can chnage it to a free record */ rc = tdbio_read_record( 0, &vr, RECTYPE_VER ); if( rc ) log_fatal( _("%s: error reading version record: %s\n"), db_name, g10_errstr(rc) ); rec.recnum = recnum; rec.rectype = RECTYPE_FREE; rec.r.free.next = vr.r.ver.firstfree; vr.r.ver.firstfree = recnum; rc = tdbio_write_record( &rec ); if( !rc ) rc = tdbio_write_record( &vr ); return rc; } /**************** * create a new record and return its record number */ ulong tdbio_new_recnum() { off_t offset; ulong recnum; TRUSTREC vr, rec; int rc; /* look for unused records */ rc = tdbio_read_record( 0, &vr, RECTYPE_VER ); if( rc ) log_fatal( _("%s: error reading version record: %s\n"), db_name, g10_errstr(rc) ); if( vr.r.ver.firstfree ) { recnum = vr.r.ver.firstfree; rc = tdbio_read_record( recnum, &rec, RECTYPE_FREE ); if( rc ) { log_error( _("%s: error reading free record: %s\n"), db_name, g10_errstr(rc) ); return rc; } /* update dir record */ vr.r.ver.firstfree = rec.r.free.next; rc = tdbio_write_record( &vr ); if( rc ) { log_error( _("%s: error writing dir record: %s\n"), db_name, g10_errstr(rc) ); return rc; } /*zero out the new record */ memset( &rec, 0, sizeof rec ); rec.rectype = 0; /* unused record */ rec.recnum = recnum; rc = tdbio_write_record( &rec ); if( rc ) log_fatal(_("%s: failed to zero a record: %s\n"), db_name, g10_errstr(rc)); } else { /* not found, append a new record */ offset = lseek( db_fd, 0, SEEK_END ); if( offset == -1 ) log_fatal("trustdb: lseek to end failed: %s\n", strerror(errno) ); recnum = offset / TRUST_RECORD_LEN; assert(recnum); /* this is will never be the first record */ /* we must write a record, so that the next call to this function * returns another recnum */ memset( &rec, 0, sizeof rec ); rec.rectype = 0; /* unused record */ rec.recnum = recnum; rc = 0; if( lseek( db_fd, recnum * TRUST_RECORD_LEN, SEEK_SET ) == -1 ) { log_error(_("trustdb rec %lu: lseek failed: %s\n"), recnum, strerror(errno) ); rc = G10ERR_WRITE_FILE; } else { int n = write( db_fd, &rec, TRUST_RECORD_LEN); if( n != TRUST_RECORD_LEN ) { log_error(_("trustdb rec %lu: write failed (n=%d): %s\n"), recnum, n, strerror(errno) ); rc = G10ERR_WRITE_FILE; } } if( rc ) log_fatal(_("%s: failed to append a record: %s\n"), db_name, g10_errstr(rc)); } return recnum ; } static int cmp_trec_fpr (const void *fpr, const TRUSTREC *rec ) { return (rec->rectype == RECTYPE_TRUST && !memcmp( rec->r.trust.fingerprint, fpr, 20)); } int tdbio_search_trust_byfpr( const byte *fingerprint, TRUSTREC *rec ) { int rc; /* Locate the trust record using the hash table. */ rc = lookup_hashtable (get_trusthashrec(), fingerprint, 20, cmp_trec_fpr, fingerprint, rec); return rc; } int tdbio_search_trust_bypk (PKT_public_key *pk, TRUSTREC *rec) { byte fingerprint[MAX_FINGERPRINT_LEN]; size_t fingerlen; fingerprint_from_pk( pk, fingerprint, &fingerlen ); for (; fingerlen < 20; fingerlen++ ) fingerprint[fingerlen] = 0; return tdbio_search_trust_byfpr (fingerprint, rec); } void tdbio_invalid(void) { log_error (_("Error: The trustdb is corrupted.\n")); how_to_fix_the_trustdb (); g10_exit (2); } /* * Migrate the trustdb as just up to gpg 1.0.6 (trustdb version 2) * to the 2.1 version as used with 1.0.6b - This is pretty trivial as needs * only to scan the tdb and insert new the new trust records. The old ones are * obsolte from now on */ static void migrate_from_v2 () { TRUSTREC rec; int i, n; struct { ulong keyrecno; byte ot; byte okay; byte fpr[20]; } *ottable; int ottable_size, ottable_used; byte oldbuf[40]; ulong recno; int rc, count; ottable_size = 5; ottable = xmalloc (ottable_size * sizeof *ottable); ottable_used = 0; /* We have some restrictions here. We can't use the version record * and we can't use any of the old hashtables because we dropped the * code. So we first collect all ownertrusts and then use a second * pass fo find the associated keys. We have to do this all without using * the regular record read functions. */ /* get all the ownertrusts */ if (lseek (db_fd, 0, SEEK_SET ) == -1 ) log_fatal ("migrate_from_v2: lseek failed: %s\n", strerror (errno)); for (recno=0;;recno++) { do n = read (db_fd, oldbuf, 40); while (n==-1 && errno == EINTR); if (!n) break; /* eof */ if (n != 40) log_fatal ("migrate_vfrom_v2: read error or short read\n"); if (*oldbuf != 2) continue; /* v2 dir record */ if (ottable_used == ottable_size) { ottable_size += 1000; ottable = xrealloc (ottable, ottable_size * sizeof *ottable); } ottable[ottable_used].keyrecno = buf32_to_ulong (oldbuf+6); ottable[ottable_used].ot = oldbuf[18]; ottable[ottable_used].okay = 0; memset (ottable[ottable_used].fpr,0, 20); if (ottable[ottable_used].keyrecno && ottable[ottable_used].ot) ottable_used++; } log_info ("found %d ownertrust records\n", ottable_used); /* Read again and find the fingerprints */ if (lseek (db_fd, 0, SEEK_SET ) == -1 ) log_fatal ("migrate_from_v2: lseek failed: %s\n", strerror (errno)); for (recno=0;;recno++) { do n = read (db_fd, oldbuf, 40); while (n==-1 && errno == EINTR); if (!n) break; /* eof */ if (n != 40) log_fatal ("migrate_from_v2: read error or short read\n"); if (*oldbuf != 3) continue; /* v2 key record */ for (i=0; i < ottable_used; i++) { if (ottable[i].keyrecno == recno) { memcpy (ottable[i].fpr, oldbuf+20, 20); ottable[i].okay = 1; break; } } } /* got everything - create the v3 trustdb */ if (ftruncate (db_fd, 0)) log_fatal ("can't truncate `%s': %s\n", db_name, strerror (errno) ); if (create_version_record ()) log_fatal ("failed to recreate version record of `%s'\n", db_name); /* access the hash table, so it is store just after the version record, * this is not needed put a dump is more pretty */ get_trusthashrec (); /* And insert the old ownertrust values */ count = 0; for (i=0; i < ottable_used; i++) { if (!ottable[i].okay) continue; memset (&rec, 0, sizeof rec); rec.recnum = tdbio_new_recnum (); rec.rectype = RECTYPE_TRUST; memcpy(rec.r.trust.fingerprint, ottable[i].fpr, 20); rec.r.trust.ownertrust = ottable[i].ot; if (tdbio_write_record (&rec)) log_fatal ("failed to write trust record of `%s'\n", db_name); count++; } revalidation_mark (); rc = tdbio_sync (); if (rc) log_fatal ("failed to sync `%s'\n", db_name); log_info ("migrated %d version 2 ownertrusts\n", count); xfree (ottable); }