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;
}
/*
* Write a record; die on error.
*/
static void
write_record (ctrl_t ctrl, TRUSTREC *rec)
{
int rc = tdbio_write_record (ctrl, rec);
if( !rc )
return;
log_error(_("trust record %lu, type %d: write failed: %s\n"),
rec->recnum, rec->rectype, gpg_strerror (rc) );
tdbio_invalid();
}
/*
* Append a new empty hashtable to the trustdb. TYPE gives the type
* of the hash table. The only defined type is 0 for a trust hash.
* On return the hashtable has been created, written, the version
* record update, and the data flushed to the disk. On a fatal error
* the function terminates the process.
*/
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 making up the hash table. */
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, gpg_strerror (rc));
}
/* Update the version record and flush. */
rc = tdbio_write_record (vr);
if (!rc)
rc = tdbio_sync ();
if (rc)
log_fatal (_("%s: error updating version record: %s\n"),
db_name, gpg_strerror (rc));
}
/* 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;
}
/* 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;
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.rectype = RECTYPE_VER;
rec.recnum = 0;
rc = tdbio_write_record( &rec );
if( !rc )
tdbio_sync();
return rc;
}
/****************
* 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;
}
/****************
* 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;
}
/*
* 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 = buftoulong (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);
}
/****************
* 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 ;
}
/*
* Update a hashtable in the trustdb. TABLE gives the start of the
* table, KEY and KEYLEN are the key, NEWRECNUM is the record number
* to insert into the table.
*
* Return: 0 on success or an error code.
*/
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", gpg_strerror (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",
gpg_strerror (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",
gpg_strerror (rc));
return rc;
}
if (rec.rectype == RECTYPE_HTBL)
{
hashrec = item;
level++;
if (level >= keylen)
{
log_error ("hashtable has invalid indirections.\n");
return GPG_ERR_TRUSTDB;
}
goto next_level;
}
else if (rec.rectype == RECTYPE_HLST) /* Extend the list. */
{
/* Check 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",
gpg_strerror (rc) );
return rc;
}
}
else
break; /* key is not in the list */
}
/* 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])
{
/* Empty slot found. */
rec.r.hlst.rnum[i] = newrecnum;
rc = tdbio_write_record (&rec);
if (rc)
log_error ("upd_hashtable: write hlst failed: %s\n",
gpg_strerror (rc));
return rc; /* Done. */
}
}
if (rec.r.hlst.next)
{
/* read the next reord of the list. */
rc = tdbio_read_record (rec.r.hlst.next, &rec, RECTYPE_HLST);
if (rc)
{
log_error ("upd_hashtable: read hlst failed: %s\n",
gpg_strerror (rc));
return rc;
}
}
else
{
/* Append a new record to the list. */
rec.r.hlst.next = item = tdbio_new_recnum ();
rc = tdbio_write_record (&rec);
if (rc)
{
log_error ("upd_hashtable: write hlst failed: %s\n",
gpg_strerror (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",
gpg_strerror (rc));
return rc; /* Done. */
}
} /* end loop over list 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 key record */
rec.r.hlst.rnum[1] = newrecnum; /* and new key record */
rc = tdbio_write_record (&rec);
if (rc)
{
log_error( "upd_hashtable: write new hlst failed: %s\n",
gpg_strerror (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",
gpg_strerror (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);
if (opt.verbose > 1)
list_trustdb (es_stderr, NULL);
return GPG_ERR_TRUSTDB;
}
}
return 0;
}
/*
* 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, gpg_strerror (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, gpg_strerror (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, gpg_strerror (rc));
return rc;
}
/* Zero out the new record. */
memset (&rec, 0, sizeof rec);
rec.rectype = 0; /* Mark as unused record (actually already done
my the memset). */
rec.recnum = recnum;
rc = tdbio_write_record (&rec);
if (rc)
log_fatal (_("%s: failed to zero a record: %s\n"),
db_name, gpg_strerror (rc));
}
else /* Not found - append a new record. */
{
offset = lseek (db_fd, 0, SEEK_END);
if (offset == (off_t)(-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)
{
rc = gpg_error_from_syserror ();
log_error (_("trustdb rec %lu: lseek failed: %s\n"),
recnum, strerror (errno));
}
else
{
int n;
n = write (db_fd, &rec, TRUST_RECORD_LEN);
if (n != TRUST_RECORD_LEN)
{
rc = gpg_error_from_syserror ();
log_error (_("trustdb rec %lu: write failed (n=%d): %s\n"),
recnum, n, strerror (errno));
}
}
if (rc)
log_fatal (_("%s: failed to append a record: %s\n"),
db_name, gpg_strerror (rc));
}
return recnum ;
}