/* dn2id.c - routines to deal with the dn2id index */ /* $OpenLDAP$ */ /* * Copyright 1998-2003 The OpenLDAP Foundation, All Rights Reserved. * COPYING RESTRICTIONS APPLY, see COPYRIGHT file */ #include "portable.h" #include #include #include "back-bdb.h" #include "idl.h" #include "lutil.h" #ifndef BDB_HIER int bdb_dn2id_add( Operation *op, DB_TXN *txn, EntryInfo *eip, Entry *e ) { struct bdb_info *bdb = (struct bdb_info *) op->o_bd->be_private; DB *db = bdb->bi_dn2id->bdi_db; int rc; DBT key, data; char *buf; struct berval ptr, pdn; #ifdef NEW_LOGGING LDAP_LOG ( INDEX, ARGS, "bdb_dn2id_add( \"%s\", 0x%08lx )\n", e->e_ndn, (long) e->e_id, 0 ); #else Debug( LDAP_DEBUG_TRACE, "=> bdb_dn2id_add( \"%s\", 0x%08lx )\n", e->e_ndn, (long) e->e_id, 0 ); #endif assert( e->e_id != NOID ); DBTzero( &key ); key.size = e->e_nname.bv_len + 2; key.ulen = key.size; key.flags = DB_DBT_USERMEM; buf = op->o_tmpalloc( key.size, op->o_tmpmemctx ); key.data = buf; buf[0] = DN_BASE_PREFIX; ptr.bv_val = buf + 1; ptr.bv_len = e->e_nname.bv_len; AC_MEMCPY( ptr.bv_val, e->e_nname.bv_val, e->e_nname.bv_len ); ptr.bv_val[ptr.bv_len] = '\0'; DBTzero( &data ); data.data = (char *) &e->e_id; data.size = sizeof( e->e_id ); /* store it -- don't override */ rc = db->put( db, txn, &key, &data, DB_NOOVERWRITE ); if( rc != 0 ) { #ifdef NEW_LOGGING LDAP_LOG ( INDEX, ERR, "bdb_dn2id_add: put failed: %s %d\n", db_strerror(rc), rc, 0 ); #else Debug( LDAP_DEBUG_ANY, "=> bdb_dn2id_add: put failed: %s %d\n", db_strerror(rc), rc, 0 ); #endif goto done; } #ifndef BDB_MULTIPLE_SUFFIXES if( !be_issuffix( op->o_bd, &ptr )) { #endif buf[0] = DN_SUBTREE_PREFIX; rc = db->put( db, txn, &key, &data, DB_NOOVERWRITE ); if( rc != 0 ) { #ifdef NEW_LOGGING LDAP_LOG ( INDEX, ERR, "=> bdb_dn2id_add: subtree (%s) put failed: %d\n", ptr.bv_val, rc, 0 ); #else Debug( LDAP_DEBUG_ANY, "=> bdb_dn2id_add: subtree (%s) put failed: %d\n", ptr.bv_val, rc, 0 ); #endif goto done; } #ifdef BDB_MULTIPLE_SUFFIXES if( !be_issuffix( op->o_bd, &ptr )) { #endif dnParent( &ptr, &pdn ); key.size = pdn.bv_len + 2; key.ulen = key.size; pdn.bv_val[-1] = DN_ONE_PREFIX; key.data = pdn.bv_val-1; ptr = pdn; rc = bdb_idl_insert_key( op->o_bd, db, txn, &key, e->e_id ); if( rc != 0 ) { #ifdef NEW_LOGGING LDAP_LOG ( INDEX, ERR, "=> bdb_dn2id_add: parent (%s) insert failed: %d\n", ptr.bv_val, rc, 0 ); #else Debug( LDAP_DEBUG_ANY, "=> bdb_dn2id_add: parent (%s) insert failed: %d\n", ptr.bv_val, rc, 0 ); #endif goto done; } #ifndef BDB_MULTIPLE_SUFFIXES } while( !be_issuffix( op->o_bd, &ptr )) { #else for (;;) { #endif ptr.bv_val[-1] = DN_SUBTREE_PREFIX; rc = bdb_idl_insert_key( op->o_bd, db, txn, &key, e->e_id ); if( rc != 0 ) { #ifdef NEW_LOGGING LDAP_LOG ( INDEX, ERR, "=> bdb_dn2id_add: subtree (%s) insert failed: %d\n", ptr.bv_val, rc, 0 ); #else Debug( LDAP_DEBUG_ANY, "=> bdb_dn2id_add: subtree (%s) insert failed: %d\n", ptr.bv_val, rc, 0 ); #endif break; } #ifdef BDB_MULTIPLE_SUFFIXES if( be_issuffix( op->o_bd, &ptr )) break; #endif dnParent( &ptr, &pdn ); key.size = pdn.bv_len + 2; key.ulen = key.size; key.data = pdn.bv_val - 1; ptr = pdn; } #ifdef BDB_MULTIPLE_SUFFIXES } #endif done: op->o_tmpfree( buf, op->o_tmpmemctx ); #ifdef NEW_LOGGING LDAP_LOG ( INDEX, RESULTS, "<= bdb_dn2id_add: %d\n", rc, 0, 0 ); #else Debug( LDAP_DEBUG_TRACE, "<= bdb_dn2id_add: %d\n", rc, 0, 0 ); #endif return rc; } int bdb_dn2id_delete( Operation *op, DB_TXN *txn, EntryInfo *eip, Entry *e ) { struct bdb_info *bdb = (struct bdb_info *) op->o_bd->be_private; DB *db = bdb->bi_dn2id->bdi_db; int rc; DBT key; char *buf; struct berval pdn, ptr; #ifdef NEW_LOGGING LDAP_LOG ( INDEX, ARGS, "=> bdb_dn2id_delete ( \"%s\", 0x%08lx )\n", e->e_ndn, e->e_id, 0); #else Debug( LDAP_DEBUG_TRACE, "=> bdb_dn2id_delete( \"%s\", 0x%08lx )\n", e->e_ndn, e->e_id, 0 ); #endif DBTzero( &key ); key.size = e->e_nname.bv_len + 2; buf = op->o_tmpalloc( key.size, op->o_tmpmemctx ); key.data = buf; key.flags = DB_DBT_USERMEM; buf[0] = DN_BASE_PREFIX; ptr.bv_val = buf+1; ptr.bv_len = e->e_nname.bv_len; AC_MEMCPY( ptr.bv_val, e->e_nname.bv_val, e->e_nname.bv_len ); ptr.bv_val[ptr.bv_len] = '\0'; /* delete it */ rc = db->del( db, txn, &key, 0 ); if( rc != 0 ) { #ifdef NEW_LOGGING LDAP_LOG ( INDEX, ERR, "=> bdb_dn2id_delete: delete failed: %s %d\n", db_strerror(rc), rc, 0 ); #else Debug( LDAP_DEBUG_ANY, "=> bdb_dn2id_delete: delete failed: %s %d\n", db_strerror(rc), rc, 0 ); #endif goto done; } #ifndef BDB_MULTIPLE_SUFFIXES if( !be_issuffix( op->o_bd, &ptr )) { #endif buf[0] = DN_SUBTREE_PREFIX; rc = db->del( db, txn, &key, 0 ); if( rc != 0 ) { #ifdef NEW_LOGGING LDAP_LOG ( INDEX, ERR, "=> bdb_dn2id_delete: subtree (%s) delete failed: %d\n", ptr.bv_val, rc, 0 ); #else Debug( LDAP_DEBUG_ANY, "=> bdb_dn2id_delete: subtree (%s) delete failed: %d\n", ptr.bv_val, rc, 0 ); #endif goto done; } #ifdef BDB_MULTIPLE_SUFFIXES if( !be_issuffix( op->o_bd, &ptr )) { #endif dnParent( &ptr, &pdn ); key.size = pdn.bv_len + 2; key.ulen = key.size; pdn.bv_val[-1] = DN_ONE_PREFIX; key.data = pdn.bv_val - 1; ptr = pdn; rc = bdb_idl_delete_key( op->o_bd, db, txn, &key, e->e_id ); if( rc != 0 ) { #ifdef NEW_LOGGING LDAP_LOG ( INDEX, ERR, "=> bdb_dn2id_delete: parent (%s) delete failed: %d\n", ptr.bv_val, rc, 0 ); #else Debug( LDAP_DEBUG_ANY, "=> bdb_dn2id_delete: parent (%s) delete failed: %d\n", ptr.bv_val, rc, 0 ); #endif goto done; } #ifndef BDB_MULTIPLE_SUFFIXES } while( !be_issuffix( op->o_bd, &ptr )) { #else for (;;) { #endif ptr.bv_val[-1] = DN_SUBTREE_PREFIX; rc = bdb_idl_delete_key( op->o_bd, db, txn, &key, e->e_id ); if( rc != 0 ) { #ifdef NEW_LOGGING LDAP_LOG ( INDEX, ERR, "=> bdb_dn2id_delete: subtree (%s) delete failed: %d\n", ptr.bv_val, rc, 0 ); #else Debug( LDAP_DEBUG_ANY, "=> bdb_dn2id_delete: subtree (%s) delete failed: %d\n", ptr.bv_val, rc, 0 ); #endif goto done; } #ifdef BDB_MULTIPLE_SUFFIXES if( be_issuffix( op->o_bd, &ptr )) break; #endif dnParent( &ptr, &pdn ); key.size = pdn.bv_len + 2; key.ulen = key.size; key.data = pdn.bv_val - 1; ptr = pdn; } #ifdef BDB_MULTIPLE_SUFFIXES } #endif done: op->o_tmpfree( buf, op->o_tmpmemctx ); #ifdef NEW_LOGGING LDAP_LOG ( INDEX, RESULTS, "<= bdb_dn2id_delete %d\n", rc, 0, 0 ); #else Debug( LDAP_DEBUG_TRACE, "<= bdb_dn2id_delete %d\n", rc, 0, 0 ); #endif return rc; } int bdb_dn2id( Operation *op, DB_TXN *txn, struct berval *dn, EntryInfo *ei ) { int rc; DBT key, data; struct bdb_info *bdb = (struct bdb_info *) op->o_bd->be_private; DB *db = bdb->bi_dn2id->bdi_db; #ifdef NEW_LOGGING LDAP_LOG ( INDEX, ARGS, "=> bdb_dn2id( \"%s\" )\n", dn->bv_val, 0, 0 ); #else Debug( LDAP_DEBUG_TRACE, "=> bdb_dn2id( \"%s\" )\n", dn->bv_val, 0, 0 ); #endif DBTzero( &key ); key.size = dn->bv_len + 2; key.data = op->o_tmpalloc( key.size, op->o_tmpmemctx ); ((char *)key.data)[0] = DN_BASE_PREFIX; AC_MEMCPY( &((char *)key.data)[1], dn->bv_val, key.size - 1 ); /* store the ID */ DBTzero( &data ); data.data = &ei->bei_id; data.ulen = sizeof(ID); data.flags = DB_DBT_USERMEM; /* fetch it */ rc = db->get( db, txn, &key, &data, bdb->bi_db_opflags ); if( rc != 0 ) { #ifdef NEW_LOGGING LDAP_LOG ( INDEX, ERR, "<= bdb_dn2id: get failed %s (%d)\n", db_strerror(rc), rc, 0 ); #else Debug( LDAP_DEBUG_TRACE, "<= bdb_dn2id: get failed: %s (%d)\n", db_strerror( rc ), rc, 0 ); #endif } else { #ifdef NEW_LOGGING LDAP_LOG ( INDEX, RESULTS, "<= bdb_dn2id: got id=0x%08lx\n", ei->bei_id, 0, 0 ); #else Debug( LDAP_DEBUG_TRACE, "<= bdb_dn2id: got id=0x%08lx\n", ei->bei_id, 0, 0 ); #endif } op->o_tmpfree( key.data, op->o_tmpmemctx ); return rc; } int bdb_dn2id_children( Operation *op, DB_TXN *txn, Entry *e ) { DBT key, data; struct bdb_info *bdb = (struct bdb_info *) op->o_bd->be_private; DB *db = bdb->bi_dn2id->bdi_db; ID id; int rc; #ifdef NEW_LOGGING LDAP_LOG ( INDEX, ARGS, "=> bdb_dn2id_children( %s )\n", e->e_nname.bv_val, 0, 0 ); #else Debug( LDAP_DEBUG_TRACE, "=> bdb_dn2id_children( %s )\n", e->e_nname.bv_val, 0, 0 ); #endif DBTzero( &key ); key.size = e->e_nname.bv_len + 2; key.data = op->o_tmpalloc( key.size, op->o_tmpmemctx ); ((char *)key.data)[0] = DN_ONE_PREFIX; AC_MEMCPY( &((char *)key.data)[1], e->e_nname.bv_val, key.size - 1 ); #ifdef SLAP_IDL_CACHE if ( bdb->bi_idl_cache_size ) { rc = bdb_idl_cache_get( bdb, db, &key, NULL ); if ( rc != LDAP_NO_SUCH_OBJECT ) { op->o_tmpfree( key.data, op->o_tmpmemctx ); return rc; } } #endif /* we actually could do a empty get... */ DBTzero( &data ); data.data = &id; data.ulen = sizeof(id); data.flags = DB_DBT_USERMEM; data.doff = 0; data.dlen = sizeof(id); rc = db->get( db, txn, &key, &data, bdb->bi_db_opflags ); op->o_tmpfree( key.data, op->o_tmpmemctx ); #ifdef NEW_LOGGING LDAP_LOG ( INDEX, DETAIL1, "<= bdb_dn2id_children( %s ): %s (%d)\n", e->e_nname.bv_val, rc == 0 ? "" : ( rc == DB_NOTFOUND ? "no " : db_strerror(rc)), rc ); #else Debug( LDAP_DEBUG_TRACE, "<= bdb_dn2id_children( %s ): %s (%d)\n", e->e_nname.bv_val, rc == 0 ? "" : ( rc == DB_NOTFOUND ? "no " : db_strerror(rc) ), rc ); #endif return rc; } int bdb_dn2idl( Operation *op, Entry *e, ID *ids, ID *stack ) { int rc; DBT key; struct bdb_info *bdb = (struct bdb_info *) op->o_bd->be_private; DB *db = bdb->bi_dn2id->bdi_db; int prefix = op->ors_scope == LDAP_SCOPE_SUBTREE ? DN_SUBTREE_PREFIX : DN_ONE_PREFIX; #ifdef NEW_LOGGING LDAP_LOG ( INDEX, ARGS, "=> bdb_dn2ididl( \"%s\" )\n", e->e_nname.bv_val, 0, 0 ); #else Debug( LDAP_DEBUG_TRACE, "=> bdb_dn2idl( \"%s\" )\n", e->e_nname.bv_val, 0, 0 ); #endif #ifndef BDB_MULTIPLE_SUFFIXES if (prefix == DN_SUBTREE_PREFIX && BEI(e)->bei_parent->bei_id == 0 ) { BDB_IDL_ALL(bdb, ids); return 0; } #endif DBTzero( &key ); key.size = e->e_nname.bv_len + 2; key.ulen = key.size; key.flags = DB_DBT_USERMEM; key.data = op->o_tmpalloc( key.size, op->o_tmpmemctx ); ((char *)key.data)[0] = prefix; AC_MEMCPY( &((char *)key.data)[1], e->e_nname.bv_val, key.size - 1 ); rc = bdb_idl_fetch_key( op->o_bd, db, NULL, &key, ids ); if( rc != 0 ) { #ifdef NEW_LOGGING LDAP_LOG ( INDEX, ERR, "<= bdb_dn2ididl: get failed: %s (%d)\n", db_strerror(rc), rc, 0 ); #else Debug( LDAP_DEBUG_TRACE, "<= bdb_dn2idl: get failed: %s (%d)\n", db_strerror( rc ), rc, 0 ); #endif } else { #ifdef NEW_LOGGING LDAP_LOG ( INDEX, RESULTS, "<= bdb_dn2ididl: id=%ld first=%ld last=%ld\n", (long) ids[0], (long) BDB_IDL_FIRST( ids ), (long) BDB_IDL_LAST( ids ) ); #else Debug( LDAP_DEBUG_TRACE, "<= bdb_dn2idl: id=%ld first=%ld last=%ld\n", (long) ids[0], (long) BDB_IDL_FIRST( ids ), (long) BDB_IDL_LAST( ids ) ); #endif } op->o_tmpfree( key.data, op->o_tmpmemctx ); return rc; } #else /* BDB_HIER */ /* Experimental management routines for a hierarchically structured database. * * Unsupported! Use at your own risk! * -- Howard Chu, Symas Corp. 2003. * * Instead of a ldbm-style dn2id database, we use a hierarchical one. Each * entry in this database is a struct diskNode, keyed by entryID and with * the data containing the RDN and entryID of the node's children. We use * a B-Tree with sorted duplicates to store all the children of a node under * the same key. Also, the first item under the key contains the entry's own * rdn and the ID of the node's parent, to allow bottom-up tree traversal as * well as top-down. To keep this info first in the list, the nrdnlen is set * to the negative of its value. * * The diskNode is a variable length structure. This definition is not * directly usable for in-memory manipulation. */ typedef struct diskNode { ID entryID; short nrdnlen; char nrdn[1]; char rdn[1]; } diskNode; /* Sort function for the sorted duplicate data items of a dn2id key. * Sorts based on normalized RDN, in length order. */ int hdb_dup_compare( DB *db, const DBT *usrkey, const DBT *curkey ) { char *u = (char *)&(((diskNode *)(usrkey->data))->nrdnlen); char *c = (char *)&(((diskNode *)(curkey->data))->nrdnlen); int rc, i; /* data is not aligned, cannot compare directly */ #ifdef WORDS_BIGENDIAN for( i = 0; i < (int)sizeof(short); i++) #else for( i = sizeof(short)-1; i >= 0; i--) #endif { rc = u[i] - c[i]; if( rc ) return rc; } return strcmp( u+sizeof(short), c+sizeof(short) ); } /* This function constructs a full DN for a given entry. */ int hdb_fix_dn( Entry *e, int checkit ) { EntryInfo *ei; int rlen = 0, nrlen = 0; char *ptr, *nptr; int max = 0; /* count length of all DN components */ for ( ei = BEI(e); ei && ei->bei_id; ei=ei->bei_parent ) { rlen += ei->bei_rdn.bv_len + 1; nrlen += ei->bei_nrdn.bv_len + 1; if (ei->bei_modrdns > max) max = ei->bei_modrdns; } /* See if the entry DN was invalidated by a subtree rename */ if ( checkit ) { if ( BEI(e)->bei_modrdns >= max ) { return 0; } /* We found a mismatch, tell the caller to lock it */ if ( checkit == 1 ) { return 1; } /* checkit == 2. do the fix. */ free( e->e_name.bv_val ); free( e->e_nname.bv_val ); } e->e_name.bv_len = rlen - 1; e->e_nname.bv_len = nrlen - 1; e->e_name.bv_val = ch_malloc(rlen); e->e_nname.bv_val = ch_malloc(nrlen); ptr = e->e_name.bv_val; nptr = e->e_nname.bv_val; for ( ei = BEI(e); ei && ei->bei_id; ei=ei->bei_parent ) { ptr = lutil_strcopy(ptr, ei->bei_rdn.bv_val); nptr = lutil_strcopy(nptr, ei->bei_nrdn.bv_val); if ( ei->bei_parent ) { *ptr++ = ','; *nptr++ = ','; } } BEI(e)->bei_modrdns = max; ptr[-1] = '\0'; nptr[-1] = '\0'; return 0; } /* We add two elements to the DN2ID database - a data item under the parent's * entryID containing the child's RDN and entryID, and an item under the * child's entryID containing the parent's entryID. */ int hdb_dn2id_add( Operation *op, DB_TXN *txn, EntryInfo *eip, Entry *e ) { struct bdb_info *bdb = (struct bdb_info *) op->o_bd->be_private; DB *db = bdb->bi_dn2id->bdi_db; DBT key, data; int rc, rlen, nrlen; diskNode *d; char *ptr; nrlen = dn_rdnlen( op->o_bd, &e->e_nname ); if (nrlen) { rlen = dn_rdnlen( op->o_bd, &e->e_name ); } else { nrlen = e->e_nname.bv_len; rlen = e->e_name.bv_len; } d = op->o_tmpalloc(sizeof(diskNode) + rlen + nrlen, op->o_tmpmemctx); d->entryID = e->e_id; d->nrdnlen = nrlen; ptr = lutil_strncopy( d->nrdn, e->e_nname.bv_val, nrlen ); *ptr++ = '\0'; ptr = lutil_strncopy( ptr, e->e_name.bv_val, rlen ); *ptr = '\0'; DBTzero(&key); DBTzero(&data); key.data = &eip->bei_id; key.size = sizeof(ID); key.flags = DB_DBT_USERMEM; #ifdef SLAP_IDL_CACHE if ( bdb->bi_idl_cache_size ) { bdb_idl_cache_del( bdb, db, &key ); } #endif data.data = d; data.size = sizeof(diskNode) + rlen + nrlen; data.flags = DB_DBT_USERMEM; rc = db->put( db, txn, &key, &data, DB_NODUPDATA ); if (rc == 0) { key.data = &e->e_id; d->entryID = eip->bei_id; d->nrdnlen = 0 - nrlen; rc = db->put( db, txn, &key, &data, DB_NODUPDATA ); } op->o_tmpfree( d, op->o_tmpmemctx ); return rc; } int hdb_dn2id_delete( Operation *op, DB_TXN *txn, EntryInfo *eip, Entry *e ) { struct bdb_info *bdb = (struct bdb_info *) op->o_bd->be_private; DB *db = bdb->bi_dn2id->bdi_db; DBT key, data; DBC *cursor; diskNode *d; int rc, nrlen; DBTzero(&key); key.size = sizeof(ID); key.ulen = key.size; key.data = &eip->bei_id; key.flags = DB_DBT_USERMEM; DBTzero(&data); data.size = sizeof(diskNode) + BEI(e)->bei_nrdn.bv_len; data.ulen = data.size; data.dlen = data.size; data.flags = DB_DBT_USERMEM | DB_DBT_PARTIAL; #ifdef SLAP_IDL_CACHE if ( bdb->bi_idl_cache_size ) { bdb_idl_cache_del( bdb, db, &key ); } #endif rc = db->cursor( db, txn, &cursor, bdb->bi_db_opflags ); if ( rc ) return rc; d = op->o_tmpalloc( data.size, op->o_tmpmemctx ); d->entryID = e->e_id; d->nrdnlen = BEI(e)->bei_nrdn.bv_len; strcpy( d->nrdn, BEI(e)->bei_nrdn.bv_val ); data.data = d; /* Delete our ID from the parent's list */ rc = cursor->c_get( cursor, &key, &data, DB_GET_BOTH | DB_RMW ); if ( rc == 0 ) rc = cursor->c_del( cursor, 0 ); /* Delete our ID from the tree. With sorted duplicates, this * will leave any child nodes still hanging around. This is OK * for modrdn, which will add our info back in later. */ if ( rc == 0 ) { key.data = &e->e_id; rc = cursor->c_get( cursor, &key, &data, DB_SET | DB_RMW ); if ( rc == 0 ) rc = cursor->c_del( cursor, 0 ); } cursor->c_close( cursor ); op->o_tmpfree( d, op->o_tmpmemctx ); return rc; } int hdb_dn2id( Operation *op, DB_TXN *txn, struct berval *in, EntryInfo *ei ) { struct bdb_info *bdb = (struct bdb_info *) op->o_bd->be_private; DB *db = bdb->bi_dn2id->bdi_db; DBT key, data; DBC *cursor; int rc = 0, nrlen; diskNode *d; char *ptr; ID idp = ei->bei_parent->bei_id; nrlen = dn_rdnlen( op->o_bd, in ); if (!nrlen) nrlen = in->bv_len; DBTzero(&key); key.size = sizeof(ID); key.data = &idp; key.ulen = sizeof(ID); key.flags = DB_DBT_USERMEM; DBTzero(&data); data.size = sizeof(diskNode) + nrlen; data.ulen = data.size * 3; data.flags = DB_DBT_USERMEM; rc = db->cursor( db, txn, &cursor, bdb->bi_db_opflags ); if ( rc ) return rc; d = op->o_tmpalloc( data.size * 3, op->o_tmpmemctx ); d->nrdnlen = nrlen; ptr = lutil_strncopy( d->nrdn, in->bv_val, nrlen ); *ptr = '\0'; data.data = d; rc = cursor->c_get( cursor, &key, &data, DB_GET_BOTH ); cursor->c_close( cursor ); if ( rc == 0 ) { AC_MEMCPY( &ei->bei_id, &d->entryID, sizeof(ID) ); ei->bei_rdn.bv_len = data.size - sizeof(diskNode) - nrlen; ptr = d->nrdn + nrlen + 1; ei->bei_rdn.bv_val = ch_malloc( ei->bei_rdn.bv_len + 1 ); strcpy( ei->bei_rdn.bv_val, ptr ); } op->o_tmpfree( d, op->o_tmpmemctx ); return rc; } int hdb_dn2id_parent( Operation *op, DB_TXN *txn, EntryInfo *ei, ID *idp ) { struct bdb_info *bdb = (struct bdb_info *) op->o_bd->be_private; DB *db = bdb->bi_dn2id->bdi_db; DBT key, data; DBC *cursor; int rc = 0; diskNode *d; char *ptr; unsigned char *pt2; DBTzero(&key); key.size = sizeof(ID); key.data = &ei->bei_id; key.ulen = sizeof(ID); key.flags = DB_DBT_USERMEM; DBTzero(&data); data.flags = DB_DBT_USERMEM; rc = db->cursor( db, txn, &cursor, bdb->bi_db_opflags ); if ( rc ) return rc; data.ulen = sizeof(diskNode) + (SLAP_LDAPDN_MAXLEN * 2); d = op->o_tmpalloc( data.ulen, op->o_tmpmemctx ); data.data = d; rc = cursor->c_get( cursor, &key, &data, DB_SET ); cursor->c_close( cursor ); if ( rc == 0 ) { if (d->nrdnlen >= 0) { return LDAP_OTHER; } AC_MEMCPY( idp, &d->entryID, sizeof(ID) ); ei->bei_nrdn.bv_len = 0 - d->nrdnlen; ber_str2bv( d->nrdn, ei->bei_nrdn.bv_len, 1, &ei->bei_nrdn ); ei->bei_rdn.bv_len = data.size - sizeof(diskNode) - ei->bei_nrdn.bv_len; ptr = d->nrdn + ei->bei_nrdn.bv_len + 1; ber_str2bv( ptr, ei->bei_rdn.bv_len, 1, &ei->bei_rdn ); } op->o_tmpfree( d, op->o_tmpmemctx ); return rc; } int hdb_dn2id_children( Operation *op, DB_TXN *txn, Entry *e ) { struct bdb_info *bdb = (struct bdb_info *) op->o_bd->be_private; DB *db = bdb->bi_dn2id->bdi_db; DBT key, data; DBC *cursor; int rc; ID id; diskNode d; DBTzero(&key); key.size = sizeof(ID); key.data = &e->e_id; key.flags = DB_DBT_USERMEM; #ifdef SLAP_IDL_CACHE if ( bdb->bi_idl_cache_size ) { rc = bdb_idl_cache_get( bdb, db, &key, NULL ); if ( rc != LDAP_NO_SUCH_OBJECT ) { return rc; } } #endif DBTzero(&data); data.data = &d; data.ulen = sizeof(d); data.flags = DB_DBT_USERMEM | DB_DBT_PARTIAL; data.dlen = sizeof(d); rc = db->cursor( db, txn, &cursor, bdb->bi_db_opflags ); if ( rc ) return rc; rc = cursor->c_get( cursor, &key, &data, DB_SET ); if ( rc == 0 ) { rc = cursor->c_get( cursor, &key, &data, DB_NEXT_DUP ); } cursor->c_close( cursor ); return rc; } /* bdb_dn2idl: * We can't just use bdb_idl_fetch_key because * 1 - our data items are longer than just an entry ID * 2 - our data items are sorted alphabetically by nrdn, not by ID. * * We descend the tree recursively, so we define this cookie * to hold our necessary state information. The bdb_dn2idl_internal * function uses this cookie when calling itself. */ struct dn2id_cookie { struct bdb_info *bdb; DB *db; int prefix; int rc; ID id; ID dbuf; ID *ids; void *ptr; ID tmp[BDB_IDL_DB_SIZE]; ID *buf; DBT key; DBT data; DBC *dbc; Operation *op; }; static int hdb_dn2idl_internal( struct dn2id_cookie *cx ) { #ifdef SLAP_IDL_CACHE if ( cx->bdb->bi_idl_cache_size ) { cx->rc = bdb_idl_cache_get(cx->bdb, cx->db, &cx->key, cx->tmp); if ( cx->rc == DB_NOTFOUND ) { return cx->rc; } if ( cx->rc == LDAP_SUCCESS ) { goto gotit; } } #endif cx->rc = cx->db->cursor( cx->db, NULL, &cx->dbc, cx->bdb->bi_db_opflags ); if ( cx->rc ) return cx->rc; BDB_IDL_ZERO( cx->tmp ); cx->data.data = &cx->dbuf; cx->data.ulen = sizeof(ID); cx->data.dlen = sizeof(ID); cx->data.flags = DB_DBT_USERMEM | DB_DBT_PARTIAL; /* The first item holds the parent ID. Ignore it. */ cx->rc = cx->dbc->c_get( cx->dbc, &cx->key, &cx->data, DB_SET ); if ( cx->rc == DB_NOTFOUND ) goto saveit; if ( cx->rc ) return cx->rc; cx->data.data = cx->buf; cx->data.ulen = BDB_IDL_UM_SIZE * sizeof(ID); cx->data.flags = DB_DBT_USERMEM; /* Fetch the rest of the IDs in a loop... */ while ( (cx->rc = cx->dbc->c_get( cx->dbc, &cx->key, &cx->data, DB_MULTIPLE | DB_NEXT_DUP )) == 0 ) { u_int8_t *j; size_t len; DB_MULTIPLE_INIT( cx->ptr, &cx->data ); while (cx->ptr) { DB_MULTIPLE_NEXT( cx->ptr, &cx->data, j, len ); if (j) { AC_MEMCPY( &cx->dbuf, j, sizeof(ID) ); bdb_idl_insert( cx->tmp, cx->dbuf ); } } } cx->dbc->c_close( cx->dbc ); /* If we got some records, treat as success */ if (!BDB_IDL_IS_ZERO(cx->tmp)) { cx->rc = 0; } saveit: #ifdef SLAP_IDL_CACHE if ( cx->bdb->bi_idl_cache_max_size ) { bdb_idl_cache_put( cx->bdb, cx->db, &cx->key, cx->tmp, cx->rc ); } #endif ; gotit: if ( cx->rc == 0 ) { if ( cx->prefix == DN_SUBTREE_PREFIX ) { ID *save, idcurs; save = cx->op->o_tmpalloc( BDB_IDL_SIZEOF( cx->tmp ), cx->op->o_tmpmemctx ); BDB_IDL_CPY( save, cx->tmp ); bdb_idl_union( cx->ids, cx->tmp ); idcurs = 0; for ( cx->id = bdb_idl_first( save, &idcurs ); cx->id != NOID; cx->id = bdb_idl_next( save, &idcurs )) { hdb_dn2idl_internal( cx ); } cx->op->o_tmpfree( save, cx->op->o_tmpmemctx ); cx->rc = 0; } else { BDB_IDL_CPY( cx->ids, cx->tmp ); } } return cx->rc; } int hdb_dn2idl( Operation *op, Entry *e, ID *ids, ID *stack ) { struct bdb_info *bdb = (struct bdb_info *)op->o_bd->be_private; struct dn2id_cookie cx; #ifdef NEW_LOGGING LDAP_LOG ( INDEX, ARGS, "=> hdb_dn2ididl( \"%s\" )\n", e->e_nname.bv_val, 0, 0 ); #else Debug( LDAP_DEBUG_TRACE, "=> hdb_dn2idl( \"%s\" )\n", e->e_nname.bv_val, 0, 0 ); #endif #ifndef BDB_MULTIPLE_SUFFIXES if ( op->ors_scope == LDAP_SCOPE_SUBTREE && BEI(e)->bei_parent->bei_id == 0 ) { BDB_IDL_ALL( bdb, ids ); return 0; } #endif cx.id = e->e_id; cx.bdb = bdb; cx.db = cx.bdb->bi_dn2id->bdi_db; cx.prefix = op->ors_scope == LDAP_SCOPE_SUBTREE ? DN_SUBTREE_PREFIX : DN_ONE_PREFIX; cx.ids = ids; cx.buf = stack; cx.op = op; BDB_IDL_ZERO( ids ); if ( cx.prefix == DN_SUBTREE_PREFIX ) { bdb_idl_insert( ids, cx.id ); } DBTzero(&cx.key); cx.key.data = &cx.id; cx.key.ulen = sizeof(ID); cx.key.size = sizeof(ID); cx.key.flags = DB_DBT_USERMEM; DBTzero(&cx.data); return hdb_dn2idl_internal(&cx); } #endif /* BDB_HIER */