/* dn2id.c - routines to deal with the dn2id index */ /* $OpenLDAP$ */ /* This work is part of OpenLDAP Software . * * Copyright 2000-2013 The OpenLDAP Foundation. * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted only as authorized by the OpenLDAP * Public License. * * A copy of this license is available in the file LICENSE in the * top-level directory of the distribution or, alternatively, at * . */ #include "portable.h" #include #include #include "back-mdb.h" #include "idl.h" #include "lutil.h" /* Management routines for a hierarchically structured database. * * 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 high bit of all * subsequent nrdnlen's is always set. This means we can only accomodate * RDNs up to length 32767, but that's fine since full DNs are already * restricted to 8192. * * Also each child node contains a count of the number of entries in * its subtree, appended after its entryID. * * The diskNode is a variable length structure. This definition is not * directly usable for in-memory manipulation. */ typedef struct diskNode { unsigned char nrdnlen[2]; char nrdn[1]; char rdn[1]; /* variable placement */ unsigned char entryID[sizeof(ID)]; /* variable placement */ /* unsigned char nsubs[sizeof(ID)]; in child nodes only */ } diskNode; /* Sort function for the sorted duplicate data items of a dn2id key. * Sorts based on normalized RDN, in length order. */ int mdb_dup_compare( const MDB_val *usrkey, const MDB_val *curkey ) { diskNode *un, *cn; int rc, nrlen; un = (diskNode *)usrkey->mv_data; cn = (diskNode *)curkey->mv_data; /* data is not aligned, cannot compare directly */ rc = un->nrdnlen[0] - cn->nrdnlen[0]; if ( rc ) return rc; rc = un->nrdnlen[1] - cn->nrdnlen[1]; if ( rc ) return rc; nrlen = ((un->nrdnlen[0] & 0x7f) << 8) | un->nrdnlen[1]; return strncmp( un->nrdn, cn->nrdn, nrlen ); } /* 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 mdb_dn2id_add( Operation *op, MDB_cursor *mcp, MDB_cursor *mcd, ID pid, ID nsubs, int upsub, Entry *e ) { struct mdb_info *mdb = (struct mdb_info *) op->o_bd->be_private; MDB_val key, data; ID nid; int rc, rlen, nrlen; diskNode *d; char *ptr; Debug( LDAP_DEBUG_TRACE, "=> mdb_dn2id_add 0x%lx: \"%s\"\n", e->e_id, e->e_ndn ? e->e_ndn : "", 0 ); 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 + sizeof(ID), op->o_tmpmemctx); d->nrdnlen[1] = nrlen & 0xff; d->nrdnlen[0] = (nrlen >> 8) | 0x80; 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'; memcpy( ptr, &e->e_id, sizeof( ID )); ptr += sizeof( ID ); memcpy( ptr, &nsubs, sizeof( ID )); key.mv_size = sizeof(ID); key.mv_data = &nid; nid = pid; /* Need to make dummy root node once. Subsequent attempts * will fail harmlessly. */ if ( pid == 0 ) { diskNode dummy = {{0, 0}, "", "", ""}; data.mv_data = &dummy; data.mv_size = sizeof(diskNode); mdb_cursor_put( mcp, &key, &data, MDB_NODUPDATA ); } data.mv_data = d; data.mv_size = sizeof(diskNode) + rlen + nrlen + sizeof( ID ); /* Add our child node under parent's key */ rc = mdb_cursor_put( mcp, &key, &data, MDB_NODUPDATA ); /* Add our own node */ if (rc == 0) { int flag = MDB_NODUPDATA; nid = e->e_id; /* drop subtree count */ data.mv_size -= sizeof( ID ); ptr -= sizeof( ID ); memcpy( ptr, &pid, sizeof( ID )); d->nrdnlen[0] ^= 0x80; if ((slapMode & SLAP_TOOL_MODE) || (e->e_id == mdb->mi_nextid)) flag |= MDB_APPEND; rc = mdb_cursor_put( mcd, &key, &data, flag ); } op->o_tmpfree( d, op->o_tmpmemctx ); /* Add our subtree count to all superiors */ if ( rc == 0 && upsub && pid ) { ID subs; nid = pid; do { /* Get parent's RDN */ rc = mdb_cursor_get( mcp, &key, &data, MDB_SET ); if ( !rc ) { char *p2; ptr = (char *)data.mv_data + data.mv_size - sizeof( ID ); memcpy( &nid, ptr, sizeof( ID )); /* Get parent's node under grandparent */ d = data.mv_data; rlen = ( d->nrdnlen[0] << 8 ) | d->nrdnlen[1]; p2 = op->o_tmpalloc( rlen + 2, op->o_tmpmemctx ); memcpy( p2, data.mv_data, rlen+2 ); *p2 ^= 0x80; data.mv_data = p2; rc = mdb_cursor_get( mcp, &key, &data, MDB_GET_BOTH ); op->o_tmpfree( p2, op->o_tmpmemctx ); if ( !rc ) { /* Get parent's subtree count */ ptr = (char *)data.mv_data + data.mv_size - sizeof( ID ); memcpy( &subs, ptr, sizeof( ID )); subs += nsubs; p2 = op->o_tmpalloc( data.mv_size, op->o_tmpmemctx ); memcpy( p2, data.mv_data, data.mv_size - sizeof( ID )); memcpy( p2+data.mv_size - sizeof( ID ), &subs, sizeof( ID )); data.mv_data = p2; rc = mdb_cursor_put( mcp, &key, &data, MDB_CURRENT ); op->o_tmpfree( p2, op->o_tmpmemctx ); } } if ( rc ) break; } while ( nid ); } Debug( LDAP_DEBUG_TRACE, "<= mdb_dn2id_add 0x%lx: %d\n", e->e_id, rc, 0 ); return rc; } /* mc must have been set by mdb_dn2id */ int mdb_dn2id_delete( Operation *op, MDB_cursor *mc, ID id, ID nsubs ) { ID nid; char *ptr; int rc; Debug( LDAP_DEBUG_TRACE, "=> mdb_dn2id_delete 0x%lx\n", id, 0, 0 ); /* Delete our ID from the parent's list */ rc = mdb_cursor_del( mc, 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 ) { MDB_val key, data; if ( nsubs ) { mdb_cursor_get( mc, &key, NULL, MDB_GET_CURRENT ); memcpy( &nid, key.mv_data, sizeof( ID )); } key.mv_size = sizeof(ID); key.mv_data = &id; rc = mdb_cursor_get( mc, &key, &data, MDB_SET ); if ( rc == 0 ) rc = mdb_cursor_del( mc, 0 ); } /* Delete our subtree count from all superiors */ if ( rc == 0 && nsubs && nid ) { MDB_val key, data; ID subs; key.mv_data = &nid; key.mv_size = sizeof( ID ); do { rc = mdb_cursor_get( mc, &key, &data, MDB_SET ); if ( !rc ) { char *p2; diskNode *d; int rlen; ptr = (char *)data.mv_data + data.mv_size - sizeof( ID ); memcpy( &nid, ptr, sizeof( ID )); /* Get parent's node under grandparent */ d = data.mv_data; rlen = ( d->nrdnlen[0] << 8 ) | d->nrdnlen[1]; p2 = op->o_tmpalloc( rlen + 2, op->o_tmpmemctx ); memcpy( p2, data.mv_data, rlen+2 ); *p2 ^= 0x80; data.mv_data = p2; rc = mdb_cursor_get( mc, &key, &data, MDB_GET_BOTH ); op->o_tmpfree( p2, op->o_tmpmemctx ); if ( !rc ) { /* Get parent's subtree count */ ptr = (char *)data.mv_data + data.mv_size - sizeof( ID ); memcpy( &subs, ptr, sizeof( ID )); subs -= nsubs; p2 = op->o_tmpalloc( data.mv_size, op->o_tmpmemctx ); memcpy( p2, data.mv_data, data.mv_size - sizeof( ID )); memcpy( p2+data.mv_size - sizeof( ID ), &subs, sizeof( ID )); data.mv_data = p2; rc = mdb_cursor_put( mc, &key, &data, MDB_CURRENT ); op->o_tmpfree( p2, op->o_tmpmemctx ); } } if ( rc ) break; } while ( nid ); } Debug( LDAP_DEBUG_TRACE, "<= mdb_dn2id_delete 0x%lx: %d\n", id, rc, 0 ); return rc; } /* return last found ID in *id if no match * If mc is provided, it will be left pointing to the RDN's * record under the parent's ID. If nsubs is provided, return * the number of entries in this entry's subtree. */ int mdb_dn2id( Operation *op, MDB_txn *txn, MDB_cursor *mc, struct berval *in, ID *id, ID *nsubs, struct berval *matched, struct berval *nmatched ) { struct mdb_info *mdb = (struct mdb_info *) op->o_bd->be_private; MDB_cursor *cursor; MDB_dbi dbi = mdb->mi_dn2id; MDB_val key, data; int rc = 0, nrlen; diskNode *d; char *ptr; char dn[SLAP_LDAPDN_MAXLEN]; ID pid, nid; struct berval tmp; Debug( LDAP_DEBUG_TRACE, "=> mdb_dn2id(\"%s\")\n", in->bv_val ? in->bv_val : "", 0, 0 ); if ( matched ) { matched->bv_val = dn + sizeof(dn) - 1; matched->bv_len = 0; *matched->bv_val-- = '\0'; } if ( nmatched ) { nmatched->bv_len = 0; nmatched->bv_val = 0; } if ( !in->bv_len ) { *id = 0; nid = 0; goto done; } tmp = *in; if ( op->o_bd->be_nsuffix[0].bv_len ) { nrlen = tmp.bv_len - op->o_bd->be_nsuffix[0].bv_len; tmp.bv_val += nrlen; tmp.bv_len = op->o_bd->be_nsuffix[0].bv_len; } else { for ( ptr = tmp.bv_val + tmp.bv_len - 1; ptr >= tmp.bv_val; ptr-- ) if (DN_SEPARATOR(*ptr)) break; ptr++; tmp.bv_len -= ptr - tmp.bv_val; tmp.bv_val = ptr; } nid = 0; key.mv_size = sizeof(ID); if ( mc ) { cursor = mc; } else { rc = mdb_cursor_open( txn, dbi, &cursor ); if ( rc ) return rc; } for (;;) { key.mv_data = &pid; pid = nid; data.mv_size = sizeof(diskNode) + tmp.bv_len; d = op->o_tmpalloc( data.mv_size, op->o_tmpmemctx ); d->nrdnlen[1] = tmp.bv_len & 0xff; d->nrdnlen[0] = (tmp.bv_len >> 8) | 0x80; ptr = lutil_strncopy( d->nrdn, tmp.bv_val, tmp.bv_len ); *ptr = '\0'; data.mv_data = d; rc = mdb_cursor_get( cursor, &key, &data, MDB_GET_BOTH ); op->o_tmpfree( d, op->o_tmpmemctx ); if ( rc ) break; ptr = (char *) data.mv_data + data.mv_size - 2*sizeof(ID); memcpy( &nid, ptr, sizeof(ID)); /* grab the non-normalized RDN */ if ( matched ) { int rlen; d = data.mv_data; rlen = data.mv_size - sizeof(diskNode) - tmp.bv_len - sizeof(ID); matched->bv_len += rlen; matched->bv_val -= rlen + 1; ptr = lutil_strcopy( matched->bv_val, d->rdn + tmp.bv_len ); if ( pid ) { *ptr = ','; matched->bv_len++; } } if ( nmatched ) { nmatched->bv_val = tmp.bv_val; } if ( tmp.bv_val > in->bv_val ) { for (ptr = tmp.bv_val - 2; ptr > in->bv_val && !DN_SEPARATOR(*ptr); ptr--) /* empty */; if ( ptr >= in->bv_val ) { if (DN_SEPARATOR(*ptr)) ptr++; tmp.bv_len = tmp.bv_val - ptr - 1; tmp.bv_val = ptr; } } else { break; } } *id = nid; /* return subtree count if requested */ if ( !rc && nsubs ) { ptr = (char *)data.mv_data + data.mv_size - sizeof(ID); memcpy( nsubs, ptr, sizeof( ID )); } if ( !mc ) mdb_cursor_close( cursor ); done: if ( matched ) { if ( matched->bv_len ) { ptr = op->o_tmpalloc( matched->bv_len+1, op->o_tmpmemctx ); strcpy( ptr, matched->bv_val ); matched->bv_val = ptr; } else { if ( BER_BVISEMPTY( &op->o_bd->be_nsuffix[0] ) && !nid ) { ber_dupbv( matched, (struct berval *)&slap_empty_bv ); } else { matched->bv_val = NULL; } } } if ( nmatched ) { if ( nmatched->bv_val ) { nmatched->bv_len = in->bv_len - (nmatched->bv_val - in->bv_val); } else { *nmatched = slap_empty_bv; } } if( rc != 0 ) { Debug( LDAP_DEBUG_TRACE, "<= mdb_dn2id: get failed: %s (%d)\n", mdb_strerror( rc ), rc, 0 ); } else { Debug( LDAP_DEBUG_TRACE, "<= mdb_dn2id: got id=0x%lx\n", nid, 0, 0 ); } return rc; } /* return IDs from root to parent of DN */ int mdb_dn2sups( Operation *op, MDB_txn *txn, struct berval *in, ID *ids ) { struct mdb_info *mdb = (struct mdb_info *) op->o_bd->be_private; MDB_cursor *cursor; MDB_dbi dbi = mdb->mi_dn2id; MDB_val key, data; int rc = 0, nrlen; diskNode *d; char *ptr; ID pid, nid; struct berval tmp; Debug( LDAP_DEBUG_TRACE, "=> mdb_dn2sups(\"%s\")\n", in->bv_val, 0, 0 ); if ( !in->bv_len ) { goto done; } tmp = *in; nrlen = tmp.bv_len - op->o_bd->be_nsuffix[0].bv_len; tmp.bv_val += nrlen; tmp.bv_len = op->o_bd->be_nsuffix[0].bv_len; nid = 0; key.mv_size = sizeof(ID); rc = mdb_cursor_open( txn, dbi, &cursor ); if ( rc ) return rc; for (;;) { key.mv_data = &pid; pid = nid; data.mv_size = sizeof(diskNode) + tmp.bv_len; d = op->o_tmpalloc( data.mv_size, op->o_tmpmemctx ); d->nrdnlen[1] = tmp.bv_len & 0xff; d->nrdnlen[0] = (tmp.bv_len >> 8) | 0x80; ptr = lutil_strncopy( d->nrdn, tmp.bv_val, tmp.bv_len ); *ptr = '\0'; data.mv_data = d; rc = mdb_cursor_get( cursor, &key, &data, MDB_GET_BOTH ); op->o_tmpfree( d, op->o_tmpmemctx ); if ( rc ) { mdb_cursor_close( cursor ); break; } ptr = (char *) data.mv_data + data.mv_size - 2*sizeof(ID); memcpy( &nid, ptr, sizeof(ID)); if ( pid ) mdb_idl_insert( ids, pid ); if ( tmp.bv_val > in->bv_val ) { for (ptr = tmp.bv_val - 2; ptr > in->bv_val && !DN_SEPARATOR(*ptr); ptr--) /* empty */; if ( ptr >= in->bv_val ) { if (DN_SEPARATOR(*ptr)) ptr++; tmp.bv_len = tmp.bv_val - ptr - 1; tmp.bv_val = ptr; } } else { break; } } done: if( rc != 0 ) { Debug( LDAP_DEBUG_TRACE, "<= mdb_dn2sups: get failed: %s (%d)\n", mdb_strerror( rc ), rc, 0 ); } return rc; } int mdb_dn2id_children( Operation *op, MDB_txn *txn, Entry *e ) { struct mdb_info *mdb = (struct mdb_info *) op->o_bd->be_private; MDB_dbi dbi = mdb->mi_dn2id; MDB_val key, data; MDB_cursor *cursor; int rc; ID id; key.mv_size = sizeof(ID); key.mv_data = &id; id = e->e_id; rc = mdb_cursor_open( txn, dbi, &cursor ); if ( rc ) return rc; rc = mdb_cursor_get( cursor, &key, &data, MDB_SET ); if ( rc == 0 ) { size_t dkids; rc = mdb_cursor_count( cursor, &dkids ); if ( rc == 0 ) { if ( dkids < 2 ) rc = MDB_NOTFOUND; } } mdb_cursor_close( cursor ); return rc; } int mdb_id2name( Operation *op, MDB_txn *txn, MDB_cursor **cursp, ID id, struct berval *name, struct berval *nname ) { struct mdb_info *mdb = (struct mdb_info *) op->o_bd->be_private; MDB_dbi dbi = mdb->mi_dn2id; MDB_val key, data; MDB_cursor *cursor; int rc, len, nlen; char dn[SLAP_LDAPDN_MAXLEN], ndn[SLAP_LDAPDN_MAXLEN], *ptr; char *dptr, *nptr; diskNode *d; key.mv_size = sizeof(ID); if ( !*cursp ) { rc = mdb_cursor_open( txn, dbi, cursp ); if ( rc ) return rc; } cursor = *cursp; len = 0; nlen = 0; dptr = dn; nptr = ndn; while (id) { unsigned int nrlen, rlen; key.mv_data = &id; data.mv_size = 0; data.mv_data = ""; rc = mdb_cursor_get( cursor, &key, &data, MDB_SET ); if ( rc ) break; ptr = data.mv_data; ptr += data.mv_size - sizeof(ID); memcpy( &id, ptr, sizeof(ID) ); d = data.mv_data; nrlen = (d->nrdnlen[0] << 8) | d->nrdnlen[1]; rlen = data.mv_size - sizeof(diskNode) - nrlen; assert( nrlen < 1024 && rlen < 1024 ); /* FIXME: Sanity check */ if (nptr > ndn) { *nptr++ = ','; *dptr++ = ','; } /* copy name and trailing NUL */ memcpy( nptr, d->nrdn, nrlen+1 ); memcpy( dptr, d->nrdn+nrlen+1, rlen+1 ); nptr += nrlen; dptr += rlen; } if ( rc == 0 ) { name->bv_len = dptr - dn; nname->bv_len = nptr - ndn; name->bv_val = op->o_tmpalloc( name->bv_len + 1, op->o_tmpmemctx ); nname->bv_val = op->o_tmpalloc( nname->bv_len + 1, op->o_tmpmemctx ); memcpy( name->bv_val, dn, name->bv_len ); name->bv_val[name->bv_len] = '\0'; memcpy( nname->bv_val, ndn, nname->bv_len ); nname->bv_val[nname->bv_len] = '\0'; } return rc; } /* Find each id in ids that is a child of base and move it to res. */ int mdb_idscope( Operation *op, MDB_txn *txn, ID base, ID *ids, ID *res ) { struct mdb_info *mdb = (struct mdb_info *) op->o_bd->be_private; MDB_dbi dbi = mdb->mi_dn2id; MDB_val key, data; MDB_cursor *cursor; ID ida, id, cid = 0, ci0 = 0, idc = 0; char *ptr; int rc, copy; key.mv_size = sizeof(ID); MDB_IDL_ZERO( res ); rc = mdb_cursor_open( txn, dbi, &cursor ); if ( rc ) return rc; ida = mdb_idl_first( ids, &cid ); /* Don't bother moving out of ids if it's a range */ if (!MDB_IDL_IS_RANGE(ids)) { idc = ids[0]; ci0 = cid; } while (ida != NOID) { copy = 1; id = ida; while (id) { key.mv_data = &id; rc = mdb_cursor_get( cursor, &key, &data, MDB_SET ); if ( rc ) { /* not found, drop this from ids */ copy = 0; break; } ptr = data.mv_data; ptr += data.mv_size - sizeof(ID); memcpy( &id, ptr, sizeof(ID) ); if ( id == base ) { res[0]++; res[res[0]] = ida; copy = 0; break; } if ( op->ors_scope == LDAP_SCOPE_ONELEVEL ) break; } if (idc) { if (copy) { if (ci0 != cid) ids[ci0] = ids[cid]; ci0++; } else idc--; } ida = mdb_idl_next( ids, &cid ); } if (!MDB_IDL_IS_RANGE( ids )) ids[0] = idc; mdb_cursor_close( cursor ); return rc; } /* See if base is a child of any of the scopes */ int mdb_idscopes( Operation *op, IdScopes *isc ) { struct mdb_info *mdb = (struct mdb_info *) op->o_bd->be_private; MDB_dbi dbi = mdb->mi_dn2id; MDB_val key, data; ID id; ID2 id2; char *ptr; int rc = 0; unsigned int x; unsigned int nrlen, rlen; diskNode *d; key.mv_size = sizeof(ID); if ( !isc->mc ) { rc = mdb_cursor_open( isc->mt, dbi, &isc->mc ); if ( rc ) return rc; } id = isc->id; /* Catch entries from deref'd aliases */ x = mdb_id2l_search( isc->scopes, id ); if ( x <= isc->scopes[0].mid && isc->scopes[x].mid == id ) { isc->nscope = x; return MDB_SUCCESS; } while (id) { if ( !rc ) { key.mv_data = &id; rc = mdb_cursor_get( isc->mc, &key, &data, MDB_SET ); if ( rc ) return rc; /* save RDN info */ } d = data.mv_data; nrlen = (d->nrdnlen[0] << 8) | d->nrdnlen[1]; rlen = data.mv_size - sizeof(diskNode) - nrlen; isc->nrdns[isc->numrdns].bv_len = nrlen; isc->nrdns[isc->numrdns].bv_val = d->nrdn; isc->rdns[isc->numrdns].bv_len = rlen; isc->rdns[isc->numrdns].bv_val = d->nrdn+nrlen+1; isc->numrdns++; if (!rc && id != isc->id) { id2.mid = id; id2.mval = data; mdb_id2l_insert( isc->scopes, &id2 ); } ptr = data.mv_data; ptr += data.mv_size - sizeof(ID); memcpy( &id, ptr, sizeof(ID) ); x = mdb_id2l_search( isc->scopes, id ); if ( x <= isc->scopes[0].mid && isc->scopes[x].mid == id ) { if ( !isc->scopes[x].mval.mv_data ) { isc->nscope = x; return MDB_SUCCESS; } data = isc->scopes[x].mval; rc = 1; } if ( op->ors_scope == LDAP_SCOPE_ONELEVEL ) break; } return MDB_SUCCESS; } int mdb_dn2id_walk( Operation *op, IdScopes *isc ) { MDB_val key, data; diskNode *d; char *ptr; int rc, n; ID nsubs; if ( !isc->numrdns ) { key.mv_data = &isc->id; key.mv_size = sizeof(ID); rc = mdb_cursor_get( isc->mc, &key, &data, MDB_SET ); isc->scopes[0].mid = isc->id; isc->numrdns++; isc->nscope = 0; /* skip base if not a subtree walk */ if ( isc->oscope == LDAP_SCOPE_SUBTREE || isc->oscope == LDAP_SCOPE_BASE ) return rc; } if ( isc->oscope == LDAP_SCOPE_BASE ) return MDB_NOTFOUND; for (;;) { /* Get next sibling */ rc = mdb_cursor_get( isc->mc, &key, &data, MDB_NEXT_DUP ); if ( !rc ) { ptr = (char *)data.mv_data + data.mv_size - 2*sizeof(ID); d = data.mv_data; memcpy( &isc->id, ptr, sizeof(ID)); /* If we're pushing down, see if there's any children to find */ if ( isc->nscope ) { ptr += sizeof(ID); memcpy( &nsubs, ptr, sizeof(ID)); /* No children, go to next sibling */ if ( nsubs < 2 ) continue; } n = isc->numrdns; isc->scopes[n].mid = isc->id; n--; isc->nrdns[n].bv_len = ((d->nrdnlen[0] & 0x7f) << 8) | d->nrdnlen[1]; isc->nrdns[n].bv_val = d->nrdn; isc->rdns[n].bv_val = d->nrdn+isc->nrdns[n].bv_len+1; isc->rdns[n].bv_len = data.mv_size - sizeof(diskNode) - isc->nrdns[n].bv_len - sizeof(ID); /* return this ID to caller */ if ( !isc->nscope ) break; /* push down to child */ key.mv_data = &isc->id; mdb_cursor_get( isc->mc, &key, &data, MDB_SET ); isc->nscope = 0; isc->numrdns++; continue; } else if ( rc == MDB_NOTFOUND ) { if ( !isc->nscope && isc->oscope != LDAP_SCOPE_ONELEVEL ) { /* reset to first dup */ mdb_cursor_get( isc->mc, &key, NULL, MDB_GET_CURRENT ); mdb_cursor_get( isc->mc, &key, &data, MDB_SET ); isc->nscope = 1; continue; } else { isc->numrdns--; /* stack is empty? */ if ( !isc->numrdns ) break; /* pop up to prev node */ n = isc->numrdns - 1; key.mv_data = &isc->scopes[n].mid; key.mv_size = sizeof(ID); data.mv_data = isc->nrdns[n].bv_val - 2; data.mv_size = 1; /* just needs to be non-zero, mdb_dup_compare doesn't care */ mdb_cursor_get( isc->mc, &key, &data, MDB_GET_BOTH ); continue; } } else { break; } } return rc; }