1 files changed, 37 insertions, 0 deletions

diff --git a/source4/lib/tdb/common/tdb.c b/source4/lib/tdb/common/tdb.c
index 4c2d9a1add..8e8e3ce3b3 100644
--- a/source4/lib/tdb/common/tdb.c
+++ b/source4/lib/tdb/common/tdb.c
@@ -1250,6 +1250,43 @@ static int tdb_next_lock(TDB_CONTEXT *tdb, struct tdb_traverse_lock *tlock,
 
 	/* Lock each chain from the start one. */
 	for (; tlock->hash < tdb->header.hash_size; tlock->hash++) {
+
+		/* this is an optimisation for the common case where
+		   the hash chain is empty, which is particularly
+		   common for the use of tdb with ldb, where large
+		   hashes are used. In that case we spend most of our
+		   time in tdb_brlock(), locking empty hash chains.
+
+		   To avoid this, we do an unlocked pre-check to see
+		   if the hash chain is empty before starting to look
+		   inside it. If it is empty then we can avoid that
+		   hash chain. If it isn't empty then we can't believe
+		   the value we get back, as we read it without a
+		   lock, so instead we get the lock and re-fetch the
+		   value below.
+
+		   Notice that not doing this optimisation on the
+		   first hash chain is critical. We must guarantee
+		   that we have done at least one fcntl lock at the
+		   start of a search to guarantee that memory is
+		   coherent on SMP systems. If records are added by
+		   others during the search then thats OK, and we
+		   could possibly miss those with this trick, but we
+		   could miss them anyway without this trick, so the
+		   semantics don't change.
+
+		   With a non-indexed ldb search this trick gains us a
+		   factor of more than 10 in speed on a linux 2.6.x
+		   system.
+		 */
+		if (!tlock->off && tlock->hash != 0) {
+			u32 off;
+			if (ofs_read(tdb, TDB_HASH_TOP(tlock->hash), &off) == 0 &&
+			    off == 0) {
+				continue;
+			}
+		}
+
 		if (tdb_lock(tdb, tlock->hash, F_WRLCK) == -1)
 			return -1;