/* $OpenLDAP$ */
/* This work is part of OpenLDAP Software <http://www.openldap.org/>.
*
- * Copyright 2000-2005 The OpenLDAP Foundation.
+ * Copyright 2000-2008 The OpenLDAP Foundation.
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
#define IDL_CMP(x,y) ( x < y ? -1 : ( x > y ? 1 : 0 ) )
-#define IDL_LRU_DELETE( bdb, e ) do { \
- if ( e->idl_lru_prev != NULL ) { \
- e->idl_lru_prev->idl_lru_next = e->idl_lru_next; \
- } else { \
- bdb->bi_idl_lru_head = e->idl_lru_next; \
- } \
- if ( e->idl_lru_next != NULL ) { \
- e->idl_lru_next->idl_lru_prev = e->idl_lru_prev; \
- } else { \
- bdb->bi_idl_lru_tail = e->idl_lru_prev; \
- } \
-} while ( 0 )
-
-#define IDL_LRU_ADD( bdb, e ) do { \
- e->idl_lru_next = bdb->bi_idl_lru_head; \
- if ( e->idl_lru_next != NULL ) { \
- e->idl_lru_next->idl_lru_prev = (e); \
- } \
- (bdb)->bi_idl_lru_head = (e); \
- e->idl_lru_prev = NULL; \
- if ( (bdb)->bi_idl_lru_tail == NULL ) { \
- (bdb)->bi_idl_lru_tail = (e); \
- } \
+#define IDL_LRU_DELETE( bdb, e ) do { \
+ if ( (e) == (bdb)->bi_idl_lru_head ) { \
+ if ( (e)->idl_lru_next == (bdb)->bi_idl_lru_head ) { \
+ (bdb)->bi_idl_lru_head = NULL; \
+ } else { \
+ (bdb)->bi_idl_lru_head = (e)->idl_lru_next; \
+ } \
+ } \
+ if ( (e) == (bdb)->bi_idl_lru_tail ) { \
+ if ( (e)->idl_lru_prev == (bdb)->bi_idl_lru_tail ) { \
+ assert( (bdb)->bi_idl_lru_head == NULL ); \
+ (bdb)->bi_idl_lru_tail = NULL; \
+ } else { \
+ (bdb)->bi_idl_lru_tail = (e)->idl_lru_prev; \
+ } \
+ } \
+ (e)->idl_lru_next->idl_lru_prev = (e)->idl_lru_prev; \
+ (e)->idl_lru_prev->idl_lru_next = (e)->idl_lru_next; \
} while ( 0 )
static int
return 0;
}
-#if 0 /* unused */
-static int idl_delete( ID *ids, ID id )
+static int bdb_idl_delete( ID *ids, ID id )
{
- unsigned x = bdb_idl_search( ids, id );
+ unsigned x;
#if IDL_DEBUG > 1
Debug( LDAP_DEBUG_ANY, "delete: %04lx at %d\n", (long) id, x, 0 );
idl_check( ids );
#endif
+ if (BDB_IDL_IS_RANGE( ids )) {
+ /* If deleting a range boundary, adjust */
+ if ( ids[1] == id )
+ ids[1]++;
+ else if ( ids[2] == id )
+ ids[2]--;
+ /* deleting from inside a range is a no-op */
+
+ /* If the range has collapsed, re-adjust */
+ if ( ids[1] > ids[2] )
+ ids[0] = 0;
+ else if ( ids[1] == ids[2] )
+ ids[1] = 1;
+ return 0;
+ }
+
+ x = bdb_idl_search( ids, id );
assert( x > 0 );
if( x <= 0 ) {
return 0;
}
-#endif /* unused */
static char *
bdb_show_key(
if ( matched_idl_entry != NULL ) {
if ( matched_idl_entry->idl && ids )
BDB_IDL_CPY( ids, matched_idl_entry->idl );
- ldap_pvt_thread_mutex_lock( &bdb->bi_idl_tree_lrulock );
- IDL_LRU_DELETE( bdb, matched_idl_entry );
- IDL_LRU_ADD( bdb, matched_idl_entry );
- ldap_pvt_thread_mutex_unlock( &bdb->bi_idl_tree_lrulock );
+ matched_idl_entry->idl_flags |= CACHE_ENTRY_REFERENCED;
if ( matched_idl_entry->idl )
rc = LDAP_SUCCESS;
else
int rc )
{
bdb_idl_cache_entry_t idl_tmp;
- bdb_idl_cache_entry_t *ee;
+ bdb_idl_cache_entry_t *ee, *eprev;
+
+ if ( rc == DB_NOTFOUND || BDB_IDL_IS_ZERO( ids ))
+ return;
DBT2bv( key, &idl_tmp.kstr );
ee = (bdb_idl_cache_entry_t *) ch_malloc(
sizeof( bdb_idl_cache_entry_t ) );
ee->db = db;
- if ( rc == DB_NOTFOUND || BDB_IDL_IS_ZERO( ids )) {
- ee->idl = NULL;
- } else {
- ee->idl = (ID*) ch_malloc( BDB_IDL_SIZEOF ( ids ) );
- BDB_IDL_CPY( ee->idl, ids );
- }
+ ee->idl = (ID*) ch_malloc( BDB_IDL_SIZEOF ( ids ) );
+ BDB_IDL_CPY( ee->idl, ids );
+
ee->idl_lru_prev = NULL;
ee->idl_lru_next = NULL;
+ ee->idl_flags = 0;
ber_dupbv( &ee->kstr, &idl_tmp.kstr );
ldap_pvt_thread_rdwr_wlock( &bdb->bi_idl_tree_rwlock );
if ( avl_insert( &bdb->bi_idl_tree, (caddr_t) ee,
return;
}
ldap_pvt_thread_mutex_lock( &bdb->bi_idl_tree_lrulock );
- IDL_LRU_ADD( bdb, ee );
+ /* LRU_ADD */
+ if ( bdb->bi_idl_lru_head ) {
+ assert( bdb->bi_idl_lru_tail != NULL );
+ assert( bdb->bi_idl_lru_head->idl_lru_prev != NULL );
+ assert( bdb->bi_idl_lru_head->idl_lru_next != NULL );
+
+ ee->idl_lru_next = bdb->bi_idl_lru_head;
+ ee->idl_lru_prev = bdb->bi_idl_lru_head->idl_lru_prev;
+ bdb->bi_idl_lru_head->idl_lru_prev->idl_lru_next = ee;
+ bdb->bi_idl_lru_head->idl_lru_prev = ee;
+ } else {
+ ee->idl_lru_next = ee->idl_lru_prev = ee;
+ bdb->bi_idl_lru_tail = ee;
+ }
+ bdb->bi_idl_lru_head = ee;
+
if ( ++bdb->bi_idl_cache_size > bdb->bi_idl_cache_max_size ) {
- int i = 0;
- while ( bdb->bi_idl_lru_tail != NULL && i < 10 ) {
- ee = bdb->bi_idl_lru_tail;
+ int i;
+ ee = bdb->bi_idl_lru_tail;
+ for ( i = 0; ee != NULL && i < 10; i++, ee = eprev ) {
+ eprev = ee->idl_lru_prev;
+ if ( eprev == ee ) {
+ eprev = NULL;
+ }
+ if ( ee->idl_flags & CACHE_ENTRY_REFERENCED ) {
+ ee->idl_flags ^= CACHE_ENTRY_REFERENCED;
+ continue;
+ }
if ( avl_delete( &bdb->bi_idl_tree, (caddr_t) ee,
bdb_idl_entry_cmp ) == NULL ) {
Debug( LDAP_DEBUG_ANY, "=> bdb_idl_cache_put: "
ch_free( ee->idl );
ch_free( ee );
}
+ bdb->bi_idl_lru_tail = eprev;
+ assert( bdb->bi_idl_lru_tail != NULL
+ || bdb->bi_idl_lru_head == NULL );
}
-
ldap_pvt_thread_mutex_unlock( &bdb->bi_idl_tree_lrulock );
ldap_pvt_thread_rdwr_wunlock( &bdb->bi_idl_tree_rwlock );
}
ldap_pvt_thread_rdwr_wunlock( &bdb->bi_idl_tree_rwlock );
}
+void
+bdb_idl_cache_add_id(
+ struct bdb_info *bdb,
+ DB *db,
+ DBT *key,
+ ID id )
+{
+ bdb_idl_cache_entry_t *cache_entry, idl_tmp;
+ DBT2bv( key, &idl_tmp.kstr );
+ idl_tmp.db = db;
+ ldap_pvt_thread_rdwr_wlock( &bdb->bi_idl_tree_rwlock );
+ cache_entry = avl_find( bdb->bi_idl_tree, &idl_tmp,
+ bdb_idl_entry_cmp );
+ if ( cache_entry != NULL ) {
+ if ( !BDB_IDL_IS_RANGE( cache_entry->idl ) &&
+ cache_entry->idl[0] < BDB_IDL_DB_MAX ) {
+ size_t s = BDB_IDL_SIZEOF( cache_entry->idl ) + sizeof(ID);
+ cache_entry->idl = ch_realloc( cache_entry->idl, s );
+ }
+ bdb_idl_insert( cache_entry->idl, id );
+ }
+ ldap_pvt_thread_rdwr_wunlock( &bdb->bi_idl_tree_rwlock );
+}
+
+void
+bdb_idl_cache_del_id(
+ struct bdb_info *bdb,
+ DB *db,
+ DBT *key,
+ ID id )
+{
+ bdb_idl_cache_entry_t *cache_entry, idl_tmp;
+ DBT2bv( key, &idl_tmp.kstr );
+ idl_tmp.db = db;
+ ldap_pvt_thread_rdwr_wlock( &bdb->bi_idl_tree_rwlock );
+ cache_entry = avl_find( bdb->bi_idl_tree, &idl_tmp,
+ bdb_idl_entry_cmp );
+ if ( cache_entry != NULL ) {
+ bdb_idl_delete( cache_entry->idl, id );
+ if ( cache_entry->idl[0] == 0 ) {
+ if ( avl_delete( &bdb->bi_idl_tree, (caddr_t) cache_entry,
+ bdb_idl_entry_cmp ) == NULL ) {
+ Debug( LDAP_DEBUG_ANY, "=> bdb_idl_cache_del: "
+ "AVL delete failed\n",
+ 0, 0, 0 );
+ }
+ --bdb->bi_idl_cache_size;
+ ldap_pvt_thread_mutex_lock( &bdb->bi_idl_tree_lrulock );
+ IDL_LRU_DELETE( bdb, cache_entry );
+ ldap_pvt_thread_mutex_unlock( &bdb->bi_idl_tree_lrulock );
+ free( cache_entry->kstr.bv_val );
+ free( cache_entry->idl );
+ free( cache_entry );
+ }
+ }
+ ldap_pvt_thread_rdwr_wunlock( &bdb->bi_idl_tree_rwlock );
+}
+
int
bdb_idl_fetch_key(
BackendDB *be,
DB *db,
- DB_TXN *tid,
+ DB_TXN *txn,
DBT *key,
ID *ids,
DBC **saved_cursor,
/* If we're not reusing an existing cursor, get a new one */
if( opflag != DB_NEXT ) {
- rc = db->cursor( db, tid, &cursor, bdb->bi_db_opflags );
+ rc = db->cursor( db, txn, &cursor, bdb->bi_db_opflags );
if( rc != 0 ) {
Debug( LDAP_DEBUG_ANY, "=> bdb_idl_fetch_key: "
"cursor failed: %s (%d)\n", db_strerror(rc), rc, 0 );
assert( id != NOID );
- if ( bdb->bi_idl_cache_size ) {
- bdb_idl_cache_del( bdb, db, key );
- }
-
DBTzero( &data );
data.size = sizeof( ID );
data.ulen = data.size;
cursor->c_close( cursor );
return rc;
}
+ /* If key was added (didn't already exist) and using IDL cache,
+ * update key in IDL cache.
+ */
+ if ( !rc && bdb->bi_idl_cache_max_size ) {
+ bdb_idl_cache_add_id( bdb, db, key, id );
+ }
rc = cursor->c_close( cursor );
if( rc != 0 ) {
Debug( LDAP_DEBUG_ANY, "=> bdb_idl_insert_key: "
}
assert( id != NOID );
- if ( bdb->bi_idl_cache_max_size ) {
+ if ( bdb->bi_idl_cache_size ) {
bdb_idl_cache_del( bdb, db, key );
}
return NOID;
}
-/* Add one ID to an unsorted list. We still maintain a lo/hi reference
- * for fast range compaction.
+#ifdef BDB_HIER
+
+/* Add one ID to an unsorted list. We ensure that the first element is the
+ * minimum and the last element is the maximum, for fast range compaction.
+ * this means IDLs up to length 3 are always sorted...
*/
int bdb_idl_append_one( ID *ids, ID id )
{
tmp = ids[1];
ids[1] = id;
id = tmp;
- } else if ( ids[0] > 1 && id > ids[2] ) {
- tmp = ids[2];
- ids[2] = id;
+ }
+ if ( ids[0] > 1 && id < ids[ids[0]] ) {
+ tmp = ids[ids[0]];
+ ids[ids[0]] = id;
id = tmp;
}
}
ids[0]++;
if ( ids[0] >= BDB_IDL_UM_MAX ) {
ids[0] = NOID;
+ ids[2] = id;
} else {
ids[ids[0]] = id;
}
return 0;
}
-/* Merge sorted list b to sorted list a. There are no common values
- * in list a and b.
+/* Append sorted list b to sorted list a. The result is unsorted but
+ * a[1] is the min of the result and a[a[0]] is the max.
*/
-int bdb_idl_merge( ID *a, ID *b )
+int bdb_idl_append( ID *a, ID *b )
{
- ID ida, idb;
- ID cursora, cursorb, cursorc;
+ ID ida, idb, tmp, swap = 0;
if ( BDB_IDL_IS_ZERO( b ) ) {
return 0;
return 0;
}
+ ida = BDB_IDL_LAST( a );
+ idb = BDB_IDL_LAST( b );
if ( BDB_IDL_IS_RANGE( a ) || BDB_IDL_IS_RANGE(b) ||
a[0] + b[0] >= BDB_IDL_UM_MAX ) {
- ida = BDB_IDL_LAST( a );
- idb = BDB_IDL_LAST( b );
a[2] = IDL_MAX( ida, idb );
a[1] = IDL_MIN( a[1], b[1] );
a[0] = NOID;
return 0;
}
- cursora = a[0];
- cursorb = b[0];
- cursorc = cursora + cursorb;
- a[0] = cursorc;
+ if ( b[0] > 1 && ida > idb ) {
+ swap = idb;
+ a[a[0]] = idb;
+ b[b[0]] = ida;
+ }
- while ( cursorc > 0 ) {
- if ( b[cursorb] > a[cursora] ) {
- a[cursorc] = b[cursorb];
- cursorb--;
- if ( !cursorb )
- break;
- } else {
- if ( cursora == cursorc )
- break;
- a[cursorc] = a[cursora];
- cursora --;
- }
- cursorc--;
+ if ( b[1] < a[1] ) {
+ tmp = a[1];
+ a[1] = b[1];
+ } else {
+ tmp = b[1];
+ }
+ a[0]++;
+ a[a[0]] = tmp;
+
+ if ( b[0] > 1 ) {
+ int i = b[0] - 1;
+ AC_MEMCPY(a+a[0]+1, b+2, i * sizeof(ID));
+ a[0] += i;
+ }
+ if ( swap ) {
+ b[b[0]] = swap;
}
return 0;
}
+#if 1
+
/* Quicksort + Insertion sort for small arrays */
#define SMALL 8
-#define SWAP(a,b) a^=b;b^=a;a^=b /* Swap integers without temp var */
-
-#define ISTACK ((BDB_IDL_LOGN+1)*2)
+#define SWAP(a,b) itmp=(a);(a)=(b);(b)=itmp
void
-bdb_idl_sort( ID *ids )
+bdb_idl_sort( ID *ids, ID *tmp )
{
- int istack[ISTACK];
+ int *istack = (int *)tmp;
int i,j,k,l,ir,jstack;
- ID a;
+ ID a, itmp;
if ( BDB_IDL_IS_RANGE( ids ))
return;
ids[l+1] = ids[j];
ids[j] = a;
jstack += 2;
- assert(jstack <= ISTACK);
if (ir-i+1 >= j-1) {
istack[jstack] = ir;
istack[jstack-1] = i;
}
}
}
+
+#else
+
+/* 8 bit Radix sort + insertion sort
+ *
+ * based on code from http://www.cubic.org/docs/radix.htm
+ * with improvements by mbackes@symas.com and hyc@symas.com
+ *
+ * This code is O(n) but has a relatively high constant factor. For lists
+ * up to ~50 Quicksort is slightly faster; up to ~100 they are even.
+ * Much faster than quicksort for lists longer than ~100. Insertion
+ * sort is actually superior for lists <50.
+ */
+
+#define BUCKETS (1<<8)
+#define SMALL 50
+
+void
+bdb_idl_sort( ID *ids, ID *tmp )
+{
+ int count, soft_limit, phase = 0, size = ids[0];
+ ID *idls[2];
+ unsigned char *maxv = (unsigned char *)&ids[size];
+
+ if ( BDB_IDL_IS_RANGE( ids ))
+ return;
+
+ /* Use insertion sort for small lists */
+ if ( size <= SMALL ) {
+ int i,j;
+ ID a;
+
+ for (j=1;j<=size;j++) {
+ a = ids[j];
+ for (i=j-1;i>=1;i--) {
+ if (ids[i] <= a) break;
+ ids[i+1] = ids[i];
+ }
+ ids[i+1] = a;
+ }
+ return;
+ }
+
+ tmp[0] = size;
+ idls[0] = ids;
+ idls[1] = tmp;
+
+#if BYTE_ORDER == BIG_ENDIAN
+ for (soft_limit = 0; !maxv[soft_limit]; soft_limit++);
+#else
+ for (soft_limit = sizeof(ID)-1; !maxv[soft_limit]; soft_limit--);
+#endif
+
+ for (
+#if BYTE_ORDER == BIG_ENDIAN
+ count = sizeof(ID)-1; count >= soft_limit; --count
+#else
+ count = 0; count <= soft_limit; ++count
+#endif
+ ) {
+ unsigned int num[BUCKETS], * np, n, sum;
+ int i;
+ ID *sp, *source, *dest;
+ unsigned char *bp, *source_start;
+
+ source = idls[phase]+1;
+ dest = idls[phase^1]+1;
+ source_start = ((unsigned char *) source) + count;
+
+ np = num;
+ for ( i = BUCKETS; i > 0; --i ) *np++ = 0;
+
+ /* count occurences of every byte value */
+ bp = source_start;
+ for ( i = size; i > 0; --i, bp += sizeof(ID) )
+ num[*bp]++;
+
+ /* transform count into index by summing elements and storing
+ * into same array
+ */
+ sum = 0;
+ np = num;
+ for ( i = BUCKETS; i > 0; --i ) {
+ n = *np;
+ *np++ = sum;
+ sum += n;
+ }
+
+ /* fill dest with the right values in the right place */
+ bp = source_start;
+ sp = source;
+ for ( i = size; i > 0; --i, bp += sizeof(ID) ) {
+ np = num + *bp;
+ dest[*np] = *sp++;
+ ++(*np);
+ }
+ phase ^= 1;
+ }
+
+ /* copy back from temp if needed */
+ if ( phase ) {
+ ids++; tmp++;
+ for ( count = 0; count < size; ++count )
+ *ids++ = *tmp++;
+ }
+}
+#endif /* Quick vs Radix */
+
+#endif /* BDB_HIER */