/* attr.c - routines for dealing with attributes */ /* $OpenLDAP$ */ /* This work is part of OpenLDAP Software . * * Copyright 1998-2018 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 * . */ /* Portions Copyright (c) 1995 Regents of the University of Michigan. * All rights reserved. * * Redistribution and use in source and binary forms are permitted * provided that this notice is preserved and that due credit is given * to the University of Michigan at Ann Arbor. The name of the University * may not be used to endorse or promote products derived from this * software without specific prior written permission. This software * is provided ``as is'' without express or implied warranty. */ #include "portable.h" #include #ifdef HAVE_FCNTL_H #include #endif #include #include #include #include #include #include "slap.h" /* * Allocate in chunks, minimum of 1000 at a time. */ #define CHUNK_SIZE 1000 typedef struct slap_list { struct slap_list *next; } slap_list; static slap_list *attr_chunks; static Attribute *attr_list; static ldap_pvt_thread_mutex_t attr_mutex; int attr_prealloc( int num ) { Attribute *a; slap_list *s; if (!num) return 0; s = ch_calloc( 1, sizeof(slap_list) + num * sizeof(Attribute)); s->next = attr_chunks; attr_chunks = s; a = (Attribute *)(s+1); for ( ;num>1; num--) { a->a_next = a+1; a++; } a->a_next = attr_list; attr_list = (Attribute *)(s+1); return 0; } Attribute * attr_alloc( AttributeDescription *ad ) { Attribute *a; ldap_pvt_thread_mutex_lock( &attr_mutex ); if ( !attr_list ) attr_prealloc( CHUNK_SIZE ); a = attr_list; attr_list = a->a_next; a->a_next = NULL; ldap_pvt_thread_mutex_unlock( &attr_mutex ); a->a_desc = ad; if ( ad && ( ad->ad_type->sat_flags & SLAP_AT_SORTED_VAL )) a->a_flags |= SLAP_ATTR_SORTED_VALS; return a; } /* Return a list of num attrs */ Attribute * attrs_alloc( int num ) { Attribute *head = NULL; Attribute **a; ldap_pvt_thread_mutex_lock( &attr_mutex ); for ( a = &attr_list; *a && num > 0; a = &(*a)->a_next ) { if ( !head ) head = *a; num--; } attr_list = *a; if ( num > 0 ) { attr_prealloc( num > CHUNK_SIZE ? num : CHUNK_SIZE ); *a = attr_list; for ( ; *a && num > 0; a = &(*a)->a_next ) { if ( !head ) head = *a; num--; } attr_list = *a; } *a = NULL; ldap_pvt_thread_mutex_unlock( &attr_mutex ); return head; } void attr_clean( Attribute *a ) { if ( a->a_nvals && a->a_nvals != a->a_vals && !( a->a_flags & SLAP_ATTR_DONT_FREE_VALS )) { if ( a->a_flags & SLAP_ATTR_DONT_FREE_DATA ) { free( a->a_nvals ); } else { ber_bvarray_free( a->a_nvals ); } } /* a_vals may be equal to slap_dummy_bv, a static empty berval; * this is used as a placeholder for attributes that do not carry * values, e.g. when proxying search entries with the "attrsonly" * bit set. */ if ( a->a_vals != &slap_dummy_bv && !( a->a_flags & SLAP_ATTR_DONT_FREE_VALS )) { if ( a->a_flags & SLAP_ATTR_DONT_FREE_DATA ) { free( a->a_vals ); } else { ber_bvarray_free( a->a_vals ); } } a->a_desc = NULL; a->a_vals = NULL; a->a_nvals = NULL; #ifdef LDAP_COMP_MATCH a->a_comp_data = NULL; #endif a->a_flags = 0; a->a_numvals = 0; } void attr_free( Attribute *a ) { attr_clean( a ); ldap_pvt_thread_mutex_lock( &attr_mutex ); a->a_next = attr_list; attr_list = a; ldap_pvt_thread_mutex_unlock( &attr_mutex ); } #ifdef LDAP_COMP_MATCH void comp_tree_free( Attribute *a ) { Attribute *next; for( ; a != NULL ; a = next ) { next = a->a_next; if ( component_destructor && a->a_comp_data ) { if ( a->a_comp_data->cd_mem_op ) component_destructor( a->a_comp_data->cd_mem_op ); free ( a->a_comp_data ); } } } #endif void attrs_free( Attribute *a ) { if ( a ) { Attribute *b = (Attribute *)0xBAD, *tail, *next; /* save tail */ tail = a; do { next = a->a_next; attr_clean( a ); a->a_next = b; b = a; a = next; } while ( next ); ldap_pvt_thread_mutex_lock( &attr_mutex ); /* replace NULL with current attr list and let attr list * start from last attribute returned to list */ tail->a_next = attr_list; attr_list = b; ldap_pvt_thread_mutex_unlock( &attr_mutex ); } } static void attr_dup2( Attribute *tmp, Attribute *a ) { tmp->a_flags = a->a_flags & SLAP_ATTR_PERSISTENT_FLAGS; if ( a->a_vals != NULL ) { unsigned i, j; tmp->a_numvals = a->a_numvals; tmp->a_vals = ch_malloc( (tmp->a_numvals + 1) * sizeof(struct berval) ); for ( i = 0; i < tmp->a_numvals; i++ ) { ber_dupbv( &tmp->a_vals[i], &a->a_vals[i] ); if ( BER_BVISNULL( &tmp->a_vals[i] ) ) break; /* FIXME: error? */ } BER_BVZERO( &tmp->a_vals[i] ); /* a_nvals must be non null; it may be equal to a_vals */ assert( a->a_nvals != NULL ); if ( a->a_nvals != a->a_vals ) { tmp->a_nvals = ch_malloc( (tmp->a_numvals + 1) * sizeof(struct berval) ); j = 0; if ( i ) { for ( ; !BER_BVISNULL( &a->a_nvals[j] ); j++ ) { assert( j < i ); ber_dupbv( &tmp->a_nvals[j], &a->a_nvals[j] ); if ( BER_BVISNULL( &tmp->a_nvals[j] ) ) break; /* FIXME: error? */ } assert( j == i ); } BER_BVZERO( &tmp->a_nvals[j] ); } else { tmp->a_nvals = tmp->a_vals; } } } Attribute * attr_dup( Attribute *a ) { Attribute *tmp; if ( a == NULL) return NULL; tmp = attr_alloc( a->a_desc ); attr_dup2( tmp, a ); return tmp; } Attribute * attrs_dup( Attribute *a ) { int i; Attribute *tmp, *anew; if( a == NULL ) return NULL; /* count them */ for( tmp=a,i=0; tmp; tmp=tmp->a_next ) { i++; } anew = attrs_alloc( i ); for( tmp=anew; a; a=a->a_next ) { tmp->a_desc = a->a_desc; attr_dup2( tmp, a ); tmp=tmp->a_next; } return anew; } int attr_valfind( Attribute *a, unsigned flags, struct berval *val, unsigned *slot, void *ctx ) { struct berval nval = BER_BVNULL, *cval; MatchingRule *mr; const char *text; int match = -1, rc; unsigned i, n; if ( flags & SLAP_MR_ORDERING ) mr = a->a_desc->ad_type->sat_ordering; else mr = a->a_desc->ad_type->sat_equality; if( !SLAP_IS_MR_ASSERTED_VALUE_NORMALIZED_MATCH( flags ) && mr->smr_normalize ) { rc = (mr->smr_normalize)( flags & (SLAP_MR_TYPE_MASK|SLAP_MR_SUBTYPE_MASK|SLAP_MR_VALUE_OF_SYNTAX), a->a_desc->ad_type->sat_syntax, mr, val, &nval, ctx ); if( rc != LDAP_SUCCESS ) { return LDAP_INVALID_SYNTAX; } cval = &nval; } else { cval = val; } n = a->a_numvals; if ( (a->a_flags & SLAP_ATTR_SORTED_VALS) && n ) { /* Binary search */ unsigned base = 0; do { unsigned pivot = n >> 1; i = base + pivot; rc = value_match( &match, a->a_desc, mr, flags, &a->a_nvals[i], cval, &text ); if ( rc == LDAP_SUCCESS && match == 0 ) break; if ( match < 0 ) { base = i+1; n -= pivot+1; } else { n = pivot; } } while ( n ); if ( match < 0 ) i++; } else { /* Linear search */ for ( i = 0; i < n; i++ ) { const char *text; rc = ordered_value_match( &match, a->a_desc, mr, flags, &a->a_nvals[i], cval, &text ); if ( rc == LDAP_SUCCESS && match == 0 ) break; } } if ( match ) rc = LDAP_NO_SUCH_ATTRIBUTE; if ( slot ) *slot = i; if ( nval.bv_val ) slap_sl_free( nval.bv_val, ctx ); return rc; } int attr_valadd( Attribute *a, BerVarray vals, BerVarray nvals, int nn ) { int i; BerVarray v2; v2 = (BerVarray) SLAP_REALLOC( (char *) a->a_vals, (a->a_numvals + nn + 1) * sizeof(struct berval) ); if( v2 == NULL ) { Debug(LDAP_DEBUG_TRACE, "attr_valadd: SLAP_REALLOC failed.\n", 0, 0, 0 ); return LBER_ERROR_MEMORY; } a->a_vals = v2; if ( nvals ) { v2 = (BerVarray) SLAP_REALLOC( (char *) a->a_nvals, (a->a_numvals + nn + 1) * sizeof(struct berval) ); if( v2 == NULL ) { Debug(LDAP_DEBUG_TRACE, "attr_valadd: SLAP_REALLOC failed.\n", 0, 0, 0 ); return LBER_ERROR_MEMORY; } a->a_nvals = v2; } else { a->a_nvals = a->a_vals; } /* If sorted and old vals exist, must insert */ if (( a->a_flags & SLAP_ATTR_SORTED_VALS ) && a->a_numvals ) { unsigned slot; int j, rc; v2 = nvals ? nvals : vals; for ( i = 0; i < nn; i++ ) { rc = attr_valfind( a, SLAP_MR_EQUALITY | SLAP_MR_VALUE_OF_ASSERTION_SYNTAX | SLAP_MR_ASSERTED_VALUE_NORMALIZED_MATCH | SLAP_MR_ATTRIBUTE_VALUE_NORMALIZED_MATCH, &v2[i], &slot, NULL ); if ( rc != LDAP_NO_SUCH_ATTRIBUTE ) { /* should never happen */ if ( rc == LDAP_SUCCESS ) rc = LDAP_TYPE_OR_VALUE_EXISTS; return rc; } for ( j = a->a_numvals; j >= (int)slot; j-- ) { a->a_vals[j+1] = a->a_vals[j]; if ( nvals ) a->a_nvals[j+1] = a->a_nvals[j]; } ber_dupbv( &a->a_nvals[slot], &v2[i] ); if ( nvals ) ber_dupbv( &a->a_vals[slot], &vals[i] ); a->a_numvals++; } BER_BVZERO( &a->a_vals[a->a_numvals] ); if ( a->a_vals != a->a_nvals ) BER_BVZERO( &a->a_nvals[a->a_numvals] ); } else { v2 = &a->a_vals[a->a_numvals]; for ( i = 0 ; i < nn; i++ ) { ber_dupbv( &v2[i], &vals[i] ); if ( BER_BVISNULL( &v2[i] ) ) break; } BER_BVZERO( &v2[i] ); if ( nvals ) { v2 = &a->a_nvals[a->a_numvals]; for ( i = 0 ; i < nn; i++ ) { ber_dupbv( &v2[i], &nvals[i] ); if ( BER_BVISNULL( &v2[i] ) ) break; } BER_BVZERO( &v2[i] ); } a->a_numvals += i; } return 0; } /* * attr_merge - merge the given type and value with the list of * attributes in attrs. * * nvals must be NULL if the attribute has no normalizer. * In this case, a->a_nvals will be set equal to a->a_vals. * * returns 0 everything went ok * -1 trouble */ int attr_merge( Entry *e, AttributeDescription *desc, BerVarray vals, BerVarray nvals ) { int i = 0; Attribute **a; for ( a = &e->e_attrs; *a != NULL; a = &(*a)->a_next ) { if ( (*a)->a_desc == desc ) { break; } } if ( *a == NULL ) { *a = attr_alloc( desc ); } else { /* * FIXME: if the attribute already exists, the presence * of nvals and the value of (*a)->a_nvals must be consistent */ assert( ( nvals == NULL && (*a)->a_nvals == (*a)->a_vals ) || ( nvals != NULL && ( ( (*a)->a_vals == NULL && (*a)->a_nvals == NULL ) || ( (*a)->a_nvals != (*a)->a_vals ) ) ) ); } if ( vals != NULL ) { for ( ; !BER_BVISNULL( &vals[i] ); i++ ) ; } return attr_valadd( *a, vals, nvals, i ); } /* * if a normalization function is defined for the equality matchingRule * of desc, the value is normalized and stored in nval; otherwise nval * is NULL */ int attr_normalize( AttributeDescription *desc, BerVarray vals, BerVarray *nvalsp, void *memctx ) { int rc = LDAP_SUCCESS; BerVarray nvals = NULL; *nvalsp = NULL; if ( desc->ad_type->sat_equality && desc->ad_type->sat_equality->smr_normalize ) { int i; for ( i = 0; !BER_BVISNULL( &vals[i] ); i++ ); nvals = slap_sl_calloc( sizeof(struct berval), i + 1, memctx ); for ( i = 0; !BER_BVISNULL( &vals[i] ); i++ ) { rc = desc->ad_type->sat_equality->smr_normalize( SLAP_MR_VALUE_OF_ATTRIBUTE_SYNTAX, desc->ad_type->sat_syntax, desc->ad_type->sat_equality, &vals[i], &nvals[i], memctx ); if ( rc != LDAP_SUCCESS ) { BER_BVZERO( &nvals[i + 1] ); break; } } BER_BVZERO( &nvals[i] ); *nvalsp = nvals; } if ( rc != LDAP_SUCCESS && nvals != NULL ) { ber_bvarray_free_x( nvals, memctx ); } return rc; } int attr_merge_normalize( Entry *e, AttributeDescription *desc, BerVarray vals, void *memctx ) { BerVarray nvals = NULL; int rc; rc = attr_normalize( desc, vals, &nvals, memctx ); if ( rc == LDAP_SUCCESS ) { rc = attr_merge( e, desc, vals, nvals ); if ( nvals != NULL ) { ber_bvarray_free_x( nvals, memctx ); } } return rc; } int attr_merge_one( Entry *e, AttributeDescription *desc, struct berval *val, struct berval *nval ) { Attribute **a; for ( a = &e->e_attrs; *a != NULL; a = &(*a)->a_next ) { if ( (*a)->a_desc == desc ) { break; } } if ( *a == NULL ) { *a = attr_alloc( desc ); } return attr_valadd( *a, val, nval, 1 ); } /* * if a normalization function is defined for the equality matchingRule * of desc, the value is normalized and stored in nval; otherwise nval * is NULL */ int attr_normalize_one( AttributeDescription *desc, struct berval *val, struct berval *nval, void *memctx ) { int rc = LDAP_SUCCESS; BER_BVZERO( nval ); if ( desc->ad_type->sat_equality && desc->ad_type->sat_equality->smr_normalize ) { rc = desc->ad_type->sat_equality->smr_normalize( SLAP_MR_VALUE_OF_ATTRIBUTE_SYNTAX, desc->ad_type->sat_syntax, desc->ad_type->sat_equality, val, nval, memctx ); if ( rc != LDAP_SUCCESS ) { return rc; } } return rc; } int attr_merge_normalize_one( Entry *e, AttributeDescription *desc, struct berval *val, void *memctx ) { struct berval nval = BER_BVNULL; struct berval *nvalp = NULL; int rc; rc = attr_normalize_one( desc, val, &nval, memctx ); if ( rc == LDAP_SUCCESS && !BER_BVISNULL( &nval ) ) { nvalp = &nval; } rc = attr_merge_one( e, desc, val, nvalp ); if ( nvalp != NULL ) { slap_sl_free( nval.bv_val, memctx ); } return rc; } /* * attrs_find - find attribute(s) by AttributeDescription * returns next attribute which is subtype of provided description. */ Attribute * attrs_find( Attribute *a, AttributeDescription *desc ) { for ( ; a != NULL; a = a->a_next ) { if ( is_ad_subtype( a->a_desc, desc ) ) { return( a ); } } return( NULL ); } /* * attr_find - find attribute by type */ Attribute * attr_find( Attribute *a, AttributeDescription *desc ) { for ( ; a != NULL; a = a->a_next ) { if ( a->a_desc == desc ) { return( a ); } } return( NULL ); } /* * attr_delete - delete the attribute type in list pointed to by attrs * return 0 deleted ok * 1 not found in list a * -1 something bad happened */ int attr_delete( Attribute **attrs, AttributeDescription *desc ) { Attribute **a; for ( a = attrs; *a != NULL; a = &(*a)->a_next ) { if ( (*a)->a_desc == desc ) { Attribute *save = *a; *a = (*a)->a_next; attr_free( save ); return LDAP_SUCCESS; } } return LDAP_NO_SUCH_ATTRIBUTE; } int attr_init( void ) { ldap_pvt_thread_mutex_init( &attr_mutex ); return 0; } int attr_destroy( void ) { slap_list *a; for ( a=attr_chunks; a; a=attr_chunks ) { attr_chunks = a->next; free( a ); } ldap_pvt_thread_mutex_destroy( &attr_mutex ); return 0; }