openldap/libraries/libldap/getdn.c

3481 lines
73 KiB
C

/* $OpenLDAP$ */
/*
* Copyright 1998-2002 The OpenLDAP Foundation, All Rights Reserved.
* COPYING RESTRICTIONS APPLY, see COPYRIGHT file
*/
/* Portions
* Copyright (c) 1994 Regents of the University of Michigan.
* All rights reserved.
*
* getdn.c
*/
#include "portable.h"
#include <stdio.h>
#include <ac/stdlib.h>
#include <ac/socket.h>
#include <ac/string.h>
#include <ac/time.h>
#include "ldap-int.h"
#include "ldap_schema.h"
/* extension to UFN that turns trailing "dc=value" rdns in DNS style,
* e.g. "ou=People,dc=openldap,dc=org" => "People, openldap.org" */
#define DC_IN_UFN
#define PRETTY_ESCAPE
/* parsing/printing routines */
static int str2strval( const char *str, ber_len_t stoplen, struct berval *val,
const char **next, unsigned flags, unsigned *retFlags );
static int DCE2strval( const char *str, struct berval *val,
const char **next, unsigned flags );
static int IA52strval( const char *str, struct berval *val,
const char **next, unsigned flags );
static int quotedIA52strval( const char *str, struct berval *val,
const char **next, unsigned flags );
static int hexstr2binval( const char *str, struct berval *val,
const char **next, unsigned flags );
static int hexstr2bin( const char *str, char *c );
static int byte2hexpair( const char *val, char *pair );
static int binval2hexstr( struct berval *val, char *str );
static int strval2strlen( struct berval *val, unsigned flags,
ber_len_t *len );
static int strval2str( struct berval *val, char *str, unsigned flags,
ber_len_t *len );
static int strval2IA5strlen( struct berval *val, unsigned flags,
ber_len_t *len );
static int strval2IA5str( struct berval *val, char *str, unsigned flags,
ber_len_t *len );
static int strval2DCEstrlen( struct berval *val, unsigned flags,
ber_len_t *len );
static int strval2DCEstr( struct berval *val, char *str, unsigned flags,
ber_len_t *len );
static int strval2ADstrlen( struct berval *val, unsigned flags,
ber_len_t *len );
static int strval2ADstr( struct berval *val, char *str, unsigned flags,
ber_len_t *len );
static int dn2domain( LDAPDN *dn, struct berval *bv, int pos, int *iRDN );
/* AVA helpers */
static LDAPAVA * ldapava_new(
const struct berval *attr, const struct berval *val, unsigned flags );
/* Higher level helpers */
static int rdn2strlen( LDAPRDN *rdn, unsigned flags, ber_len_t *len,
int ( *s2l )( struct berval *, unsigned, ber_len_t * ) );
static int rdn2str( LDAPRDN *rdn, char *str, unsigned flags, ber_len_t *len,
int ( *s2s )( struct berval *, char *, unsigned, ber_len_t * ));
static int rdn2UFNstrlen( LDAPRDN *rdn, unsigned flags, ber_len_t *len );
static int rdn2UFNstr( LDAPRDN *rdn, char *str, unsigned flags, ber_len_t *len );
static int rdn2DCEstrlen( LDAPRDN *rdn, unsigned flags, ber_len_t *len );
static int rdn2DCEstr( LDAPRDN *rdn, char *str, unsigned flag, ber_len_t *len, int first );
static int rdn2ADstrlen( LDAPRDN *rdn, unsigned flags, ber_len_t *len );
static int rdn2ADstr( LDAPRDN *rdn, char *str, unsigned flags, ber_len_t *len, int first );
/*
* RFC 1823 ldap_get_dn
*/
char *
ldap_get_dn( LDAP *ld, LDAPMessage *entry )
{
char *dn;
BerElement tmp;
#ifdef NEW_LOGGING
LDAP_LOG ( OPERATION, ENTRY, "ldap_get_dn\n", 0, 0, 0 );
#else
Debug( LDAP_DEBUG_TRACE, "ldap_get_dn\n", 0, 0, 0 );
#endif
assert( ld != NULL );
assert( LDAP_VALID(ld) );
assert( entry != NULL );
tmp = *entry->lm_ber; /* struct copy */
if ( ber_scanf( &tmp, "{a" /*}*/, &dn ) == LBER_ERROR ) {
ld->ld_errno = LDAP_DECODING_ERROR;
return( NULL );
}
return( dn );
}
/*
* RFC 1823 ldap_dn2ufn
*/
char *
ldap_dn2ufn( LDAP_CONST char *dn )
{
char *out = NULL;
#ifdef NEW_LOGGING
LDAP_LOG ( OPERATION, ENTRY, "ldap_dn2ufn\n", 0, 0, 0 );
#else
Debug( LDAP_DEBUG_TRACE, "ldap_dn2ufn\n", 0, 0, 0 );
#endif
( void )ldap_dn_normalize( dn, LDAP_DN_FORMAT_LDAP,
&out, LDAP_DN_FORMAT_UFN );
return( out );
}
/*
* RFC 1823 ldap_explode_dn
*/
char **
ldap_explode_dn( LDAP_CONST char *dn, int notypes )
{
LDAPDN *tmpDN;
char **values = NULL;
int iRDN;
unsigned flag = notypes ? LDAP_DN_FORMAT_UFN : LDAP_DN_FORMAT_LDAPV3;
#ifdef NEW_LOGGING
LDAP_LOG ( OPERATION, ENTRY, "ldap_explode_dn\n", 0, 0, 0 );
#else
Debug( LDAP_DEBUG_TRACE, "ldap_explode_dn\n", 0, 0, 0 );
#endif
if ( ldap_str2dn( dn, &tmpDN, LDAP_DN_FORMAT_LDAP )
!= LDAP_SUCCESS ) {
return NULL;
}
if( tmpDN == NULL ) {
values = LDAP_MALLOC( sizeof( char * ) );
if( values == NULL ) return NULL;
values[0] = NULL;
return values;
}
for ( iRDN = 0; tmpDN[ 0 ][ iRDN ]; iRDN++ );
values = LDAP_MALLOC( sizeof( char * ) * ( 1 + iRDN ) );
if ( values == NULL ) {
ldap_dnfree( tmpDN );
return NULL;
}
for ( iRDN = 0; tmpDN[ 0 ][ iRDN ]; iRDN++ ) {
ldap_rdn2str( tmpDN[ 0 ][ iRDN ], &values[ iRDN ], flag );
}
ldap_dnfree( tmpDN );
values[ iRDN ] = NULL;
return values;
}
char **
ldap_explode_rdn( LDAP_CONST char *rdn, int notypes )
{
LDAPRDN *tmpRDN;
char **values = NULL;
const char *p;
int iAVA;
#ifdef NEW_LOGGING
LDAP_LOG ( OPERATION, ENTRY, "ldap_explode_rdn\n", 0, 0, 0 );
#else
Debug( LDAP_DEBUG_TRACE, "ldap_explode_rdn\n", 0, 0, 0 );
#endif
/*
* we only parse the first rdn
* FIXME: we prefer efficiency over checking if the _ENTIRE_
* dn can be parsed
*/
if ( ldap_str2rdn( rdn, &tmpRDN, (char **) &p, LDAP_DN_FORMAT_LDAP )
!= LDAP_SUCCESS ) {
return( NULL );
}
for ( iAVA = 0; tmpRDN[ 0 ][ iAVA ]; iAVA++ ) ;
values = LDAP_MALLOC( sizeof( char * ) * ( 1 + iAVA ) );
if ( values == NULL ) {
ldap_rdnfree( tmpRDN );
return( NULL );
}
for ( iAVA = 0; tmpRDN[ 0 ][ iAVA ]; iAVA++ ) {
ber_len_t l = 0, vl, al = 0;
char *str;
LDAPAVA *ava = tmpRDN[ 0 ][ iAVA ];
if ( ava->la_flags == LDAP_AVA_BINARY ) {
vl = 1 + 2 * ava->la_value.bv_len;
} else {
if ( strval2strlen( &ava->la_value,
ava->la_flags, &vl ) ) {
goto error_return;
}
}
if ( !notypes ) {
al = ava->la_attr.bv_len;
l = vl + ava->la_attr.bv_len + 1;
str = LDAP_MALLOC( l + 1 );
AC_MEMCPY( str, ava->la_attr.bv_val,
ava->la_attr.bv_len );
str[ al++ ] = '=';
} else {
l = vl;
str = LDAP_MALLOC( l + 1 );
}
if ( ava->la_flags == LDAP_AVA_BINARY ) {
str[ al++ ] = '#';
if ( binval2hexstr( &ava->la_value, &str[ al ] ) ) {
goto error_return;
}
} else {
if ( strval2str( &ava->la_value, &str[ al ],
ava->la_flags, &vl ) ) {
goto error_return;
}
}
str[ l ] = '\0';
values[ iAVA ] = str;
}
values[ iAVA ] = NULL;
ldap_rdnfree( tmpRDN );
return( values );
error_return:;
LBER_VFREE( values );
ldap_rdnfree( tmpRDN );
return( NULL );
}
char *
ldap_dn2dcedn( LDAP_CONST char *dn )
{
char *out = NULL;
#ifdef NEW_LOGGING
LDAP_LOG ( OPERATION, ENTRY, "ldap_dn2dcedn\n", 0, 0, 0 );
#else
Debug( LDAP_DEBUG_TRACE, "ldap_dn2dcedn\n", 0, 0, 0 );
#endif
( void )ldap_dn_normalize( dn, LDAP_DN_FORMAT_LDAP,
&out, LDAP_DN_FORMAT_DCE );
return( out );
}
char *
ldap_dcedn2dn( LDAP_CONST char *dce )
{
char *out = NULL;
#ifdef NEW_LOGGING
LDAP_LOG ( OPERATION, ENTRY, "ldap_dcedn2dn\n", 0, 0, 0 );
#else
Debug( LDAP_DEBUG_TRACE, "ldap_dcedn2dn\n", 0, 0, 0 );
#endif
( void )ldap_dn_normalize( dce, LDAP_DN_FORMAT_DCE, &out, LDAP_DN_FORMAT_LDAPV3 );
return( out );
}
char *
ldap_dn2ad_canonical( LDAP_CONST char *dn )
{
char *out = NULL;
#ifdef NEW_LOGGING
LDAP_LOG ( OPERATION, ENTRY, "ldap_dn2ad_canonical\n", 0, 0, 0 );
#else
Debug( LDAP_DEBUG_TRACE, "ldap_dn2ad_canonical\n", 0, 0, 0 );
#endif
( void )ldap_dn_normalize( dn, LDAP_DN_FORMAT_LDAP,
&out, LDAP_DN_FORMAT_AD_CANONICAL );
return( out );
}
/*
* function that changes the string representation of dnin
* from ( fin & LDAP_DN_FORMAT_MASK ) to ( fout & LDAP_DN_FORMAT_MASK )
*
* fin can be one of:
* LDAP_DN_FORMAT_LDAP (rfc 2253 and ldapbis liberal,
* plus some rfc 1779)
* LDAP_DN_FORMAT_LDAPV3 (rfc 2253 and ldapbis)
* LDAP_DN_FORMAT_LDAPV2 (rfc 1779)
* LDAP_DN_FORMAT_DCE (?)
*
* fout can be any of the above except
* LDAP_DN_FORMAT_LDAP
* plus:
* LDAP_DN_FORMAT_UFN (rfc 1781, partial and with extensions)
* LDAP_DN_FORMAT_AD_CANONICAL (?)
*/
int
ldap_dn_normalize( LDAP_CONST char *dnin,
unsigned fin, char **dnout, unsigned fout )
{
int rc;
LDAPDN *tmpDN = NULL;
#ifdef NEW_LOGGING
LDAP_LOG ( OPERATION, ENTRY, "ldap_dn_normalize\n", 0, 0, 0 );
#else
Debug( LDAP_DEBUG_TRACE, "ldap_dn_normalize\n", 0, 0, 0 );
#endif
assert( dnout );
*dnout = NULL;
if ( dnin == NULL ) {
return( LDAP_SUCCESS );
}
rc = ldap_str2dn( dnin , &tmpDN, fin );
if ( rc != LDAP_SUCCESS ) {
return( rc );
}
rc = ldap_dn2str( tmpDN, dnout, fout );
ldap_dnfree( tmpDN );
return( rc );
}
/* States */
#define B4AVA 0x0000
/* #define B4ATTRTYPE 0x0001 */
#define B4OIDATTRTYPE 0x0002
#define B4STRINGATTRTYPE 0x0003
#define B4AVAEQUALS 0x0100
#define B4AVASEP 0x0200
#define B4RDNSEP 0x0300
#define GOTAVA 0x0400
#define B4ATTRVALUE 0x0010
#define B4STRINGVALUE 0x0020
#define B4IA5VALUEQUOTED 0x0030
#define B4IA5VALUE 0x0040
#define B4BINARYVALUE 0x0050
/*
* Helpers (mostly from slap.h)
* c is assumed to Unicode in an ASCII compatible format (UTF-8)
* Macros assume "C" Locale (ASCII)
*/
#define LDAP_DN_ASCII_SPACE(c) \
( (c) == ' ' || (c) == '\t' || (c) == '\n' || (c) == '\r' )
#define LDAP_DN_ASCII_LOWER(c) LDAP_LOWER(c)
#define LDAP_DN_ASCII_UPPER(c) LDAP_UPPER(c)
#define LDAP_DN_ASCII_ALPHA(c) LDAP_ALPHA(c)
#define LDAP_DN_ASCII_DIGIT(c) LDAP_DIGIT(c)
#define LDAP_DN_ASCII_LCASE_HEXALPHA(c) LDAP_HEXLOWER(c)
#define LDAP_DN_ASCII_UCASE_HEXALPHA(c) LDAP_HEXUPPER(c)
#define LDAP_DN_ASCII_HEXDIGIT(c) LDAP_HEX(c)
#define LDAP_DN_ASCII_ALNUM(c) LDAP_ALNUM(c)
#define LDAP_DN_ASCII_PRINTABLE(c) ( (c) >= ' ' && (c) <= '~' )
/* attribute type */
#define LDAP_DN_OID_LEADCHAR(c) LDAP_DIGIT(c)
#define LDAP_DN_DESC_LEADCHAR(c) LDAP_ALPHA(c)
#define LDAP_DN_DESC_CHAR(c) LDAP_LDH(c)
#define LDAP_DN_LANG_SEP(c) ( (c) == ';' )
#define LDAP_DN_ATTRDESC_CHAR(c) \
( LDAP_DN_DESC_CHAR(c) || LDAP_DN_LANG_SEP(c) )
/* special symbols */
#define LDAP_DN_AVA_EQUALS(c) ( (c) == '=' )
#define LDAP_DN_AVA_SEP(c) ( (c) == '+' )
#define LDAP_DN_RDN_SEP(c) ( (c) == ',' )
#define LDAP_DN_RDN_SEP_V2(c) ( LDAP_DN_RDN_SEP(c) || (c) == ';' )
#define LDAP_DN_OCTOTHORPE(c) ( (c) == '#' )
#define LDAP_DN_QUOTES(c) ( (c) == '\"' )
#define LDAP_DN_ESCAPE(c) ( (c) == '\\' )
#define LDAP_DN_VALUE_END(c) \
( LDAP_DN_RDN_SEP(c) || LDAP_DN_AVA_SEP(c) )
#define LDAP_DN_NE(c) \
( LDAP_DN_RDN_SEP_V2(c) || LDAP_DN_AVA_SEP(c) \
|| LDAP_DN_QUOTES(c) || (c) == '<' || (c) == '>' )
#define LDAP_DN_MAYESCAPE(c) \
( LDAP_DN_ESCAPE(c) || LDAP_DN_NE(c) \
|| LDAP_DN_ASCII_SPACE(c) || LDAP_DN_OCTOTHORPE(c) )
#define LDAP_DN_NEEDESCAPE(c) \
( LDAP_DN_ESCAPE(c) || LDAP_DN_NE(c) )
#define LDAP_DN_NEEDESCAPE_LEAD(c) LDAP_DN_MAYESCAPE(c)
#define LDAP_DN_NEEDESCAPE_TRAIL(c) \
( LDAP_DN_ASCII_SPACE(c) || LDAP_DN_NEEDESCAPE(c) )
#define LDAP_DN_WILLESCAPE_CHAR(c) \
( LDAP_DN_RDN_SEP(c) || LDAP_DN_AVA_SEP(c) || LDAP_DN_ESCAPE(c) )
#define LDAP_DN_IS_PRETTY(f) ( (f) & LDAP_DN_PRETTY )
#define LDAP_DN_WILLESCAPE_HEX(f, c) \
( ( !LDAP_DN_IS_PRETTY( f ) ) && LDAP_DN_WILLESCAPE_CHAR(c) )
/* LDAPv2 */
#define LDAP_DN_VALUE_END_V2(c) \
( LDAP_DN_RDN_SEP_V2(c) || LDAP_DN_AVA_SEP(c) )
/* RFC 1779 */
#define LDAP_DN_V2_SPECIAL(c) \
( LDAP_DN_RDN_SEP_V2(c) || LDAP_DN_AVA_EQUALS(c) \
|| LDAP_DN_AVA_SEP(c) || (c) == '<' || (c) == '>' \
|| LDAP_DN_OCTOTHORPE(c) )
#define LDAP_DN_V2_PAIR(c) \
( LDAP_DN_V2_SPECIAL(c) || LDAP_DN_ESCAPE(c) || LDAP_DN_QUOTES(c) )
/*
* DCE (mostly from Luke Howard and IBM implementation for AIX)
*
* From: "Application Development Guide - Directory Services" (FIXME: add link?)
* Here escapes and valid chars for GDS are considered; as soon as more
* specific info is found, the macros will be updated.
*
* Chars: 'a'-'z', 'A'-'Z', '0'-'9',
* '.', ':', ',', ''', '+', '-', '=', '(', ')', '?', '/', ' '.
*
* Metachars: '/', ',', '=', '\'.
*
* the '\' is used to escape other metachars.
*
* Assertion: '='
* RDN separator: '/'
* AVA separator: ','
*
* Attribute types must start with alphabetic chars and can contain
* alphabetic chars and digits (FIXME: no '-'?). OIDs are allowed.
*/
#define LDAP_DN_RDN_SEP_DCE(c) ( (c) == '/' )
#define LDAP_DN_AVA_SEP_DCE(c) ( (c) == ',' )
#define LDAP_DN_ESCAPE_DCE(c) ( LDAP_DN_ESCAPE(c) )
#define LDAP_DN_VALUE_END_DCE(c) \
( LDAP_DN_RDN_SEP_DCE(c) || LDAP_DN_AVA_SEP_DCE(c) )
#define LDAP_DN_NEEDESCAPE_DCE(c) \
( LDAP_DN_VALUE_END_DCE(c) || LDAP_DN_AVA_EQUALS(c) )
/* AD Canonical */
#define LDAP_DN_RDN_SEP_AD(c) ( (c) == '/' )
#define LDAP_DN_ESCAPE_AD(c) ( LDAP_DN_ESCAPE(c) )
#define LDAP_DN_AVA_SEP_AD(c) ( (c) == ',' ) /* assume same as DCE */
#define LDAP_DN_VALUE_END_AD(c) \
( LDAP_DN_RDN_SEP_AD(c) || LDAP_DN_AVA_SEP_AD(c) )
#define LDAP_DN_NEEDESCAPE_AD(c) \
( LDAP_DN_VALUE_END_AD(c) || LDAP_DN_AVA_EQUALS(c) )
/* generics */
#define LDAP_DN_HEXPAIR(s) \
( LDAP_DN_ASCII_HEXDIGIT((s)[0]) && LDAP_DN_ASCII_HEXDIGIT((s)[1]) )
/* better look at the AttributeDescription? */
/* FIXME: no composite rdn or non-"dc" types, right?
* (what about "dc" in OID form?) */
/* FIXME: we do not allow binary values in domain, right? */
/* NOTE: use this macro only when ABSOLUTELY SURE rdn IS VALID! */
/* NOTE: don't use strcasecmp() as it is locale specific! */
#define LDAP_DC_ATTR "dc"
#define LDAP_DC_ATTRU "DC"
#define LDAP_DN_IS_RDN_DC( r ) \
( (r) && (r)[0][0] && !(r)[0][1] \
&& ((r)[0][0]->la_flags == LDAP_AVA_STRING) \
&& ((r)[0][0]->la_attr.bv_len == 2) \
&& (((r)[0][0]->la_attr.bv_val[0] == LDAP_DC_ATTR[0]) \
|| ((r)[0][0]->la_attr.bv_val[0] == LDAP_DC_ATTRU[0])) \
&& (((r)[0][0]->la_attr.bv_val[1] == LDAP_DC_ATTR[1]) \
|| ((r)[0][0]->la_attr.bv_val[1] == LDAP_DC_ATTRU[1])))
/* Composite rules */
#define LDAP_DN_ALLOW_ONE_SPACE(f) \
( LDAP_DN_LDAPV2(f) \
|| !( (f) & LDAP_DN_P_NOSPACEAFTERRDN ) )
#define LDAP_DN_ALLOW_SPACES(f) \
( LDAP_DN_LDAPV2(f) \
|| !( (f) & ( LDAP_DN_P_NOLEADTRAILSPACES | LDAP_DN_P_NOSPACEAFTERRDN ) ) )
#define LDAP_DN_LDAP(f) \
( ( (f) & LDAP_DN_FORMAT_MASK ) == LDAP_DN_FORMAT_LDAP )
#define LDAP_DN_LDAPV3(f) \
( ( (f) & LDAP_DN_FORMAT_MASK ) == LDAP_DN_FORMAT_LDAPV3 )
#define LDAP_DN_LDAPV2(f) \
( ( (f) & LDAP_DN_FORMAT_MASK ) == LDAP_DN_FORMAT_LDAPV2 )
#define LDAP_DN_DCE(f) \
( ( (f) & LDAP_DN_FORMAT_MASK ) == LDAP_DN_FORMAT_DCE )
#define LDAP_DN_UFN(f) \
( ( (f) & LDAP_DN_FORMAT_MASK ) == LDAP_DN_FORMAT_UFN )
#define LDAP_DN_ADC(f) \
( ( (f) & LDAP_DN_FORMAT_MASK ) == LDAP_DN_FORMAT_AD_CANONICAL )
#define LDAP_DN_FORMAT(f) ( (f) & LDAP_DN_FORMAT_MASK )
/*
* LDAPAVA helpers (will become part of the API for operations
* on structural representations of DNs).
*/
LDAPAVA *
ldapava_new( const struct berval *attr, const struct berval *val,
unsigned flags )
{
LDAPAVA *ava;
assert( attr );
assert( val );
ava = LDAP_MALLOC( sizeof( LDAPAVA ) + attr->bv_len + 1 );
/* should we test it? */
if ( ava == NULL ) {
return( NULL );
}
ava->la_attr.bv_len = attr->bv_len;
ava->la_attr.bv_val = (char *)(ava+1);
AC_MEMCPY( ava->la_attr.bv_val, attr->bv_val, attr->bv_len );
ava->la_attr.bv_val[attr->bv_len] = '\0';
ava->la_value = *val;
ava->la_flags = flags;
ava->la_private = NULL;
return( ava );
}
void
ldap_avafree( LDAPAVA *ava )
{
assert( ava );
#if 0
/* ava's private must be freed by caller
* (at present let's skip this check because la_private
* basically holds static data) */
assert( ava->la_private == NULL );
#endif
#if 0
/* la_attr is now contiguous with ava, not freed separately */
LDAP_FREE( ava->la_attr.bv_val );
#endif
LDAP_FREE( ava->la_value.bv_val );
LDAP_FREE( ava );
}
void
ldap_rdnfree( LDAPRDN *rdn )
{
int iAVA;
if ( rdn == NULL ) {
return;
}
for ( iAVA = 0; rdn[ 0 ][ iAVA ]; iAVA++ ) {
ldap_avafree( rdn[ 0 ][ iAVA ] );
}
LDAP_FREE( rdn );
}
void
ldap_dnfree( LDAPDN *dn )
{
int iRDN;
if ( dn == NULL ) {
return;
}
for ( iRDN = 0; dn[ 0 ][ iRDN ]; iRDN++ ) {
ldap_rdnfree( dn[ 0 ][ iRDN ] );
}
LDAP_FREE( dn );
}
/*
* Converts a string representation of a DN (in LDAPv3, LDAPv2 or DCE)
* into a structural representation of the DN, by separating attribute
* types and values encoded in the more appropriate form, which is
* string or OID for attribute types and binary form of the BER encoded
* value or Unicode string. Formats different from LDAPv3 are parsed
* according to their own rules and turned into the more appropriate
* form according to LDAPv3.
*
* NOTE: I realize the code is getting spaghettish; it is rather
* experimental and will hopefully turn into something more simple
* and readable as soon as it works as expected.
*/
/*
* Default sizes of AVA and RDN static working arrays; if required
* the are dynamically resized. The values can be tuned in case
* of special requirements (e.g. very deep DN trees or high number
* of AVAs per RDN).
*/
#define TMP_AVA_SLOTS 8
#define TMP_RDN_SLOTS 32
int
ldap_str2dn( LDAP_CONST char *str, LDAPDN **dn, unsigned flags )
{
struct berval bv;
assert( str );
bv.bv_len = strlen( str );
bv.bv_val = (char *) str;
return ldap_bv2dn( &bv, dn, flags );
}
int
ldap_bv2dn( struct berval *bv, LDAPDN **dn, unsigned flags )
{
const char *p;
int rc = LDAP_DECODING_ERROR;
int nrdns = 0;
LDAPDN *newDN = NULL;
LDAPRDN *newRDN = NULL, *tmpDN_[TMP_RDN_SLOTS], **tmpDN = tmpDN_;
int num_slots = TMP_RDN_SLOTS;
char *str = bv->bv_val;
char *end = str + bv->bv_len;
assert( bv );
assert( bv->bv_val );
assert( dn );
#ifdef NEW_LOGGING
LDAP_LOG ( OPERATION, ARGS, "ldap_bv2dn(%s,%u)\n%s", str, flags, "" );
#else
Debug( LDAP_DEBUG_TRACE, "=> ldap_bv2dn(%s,%u)\n%s", str, flags, "" );
#endif
*dn = NULL;
switch ( LDAP_DN_FORMAT( flags ) ) {
case LDAP_DN_FORMAT_LDAP:
case LDAP_DN_FORMAT_LDAPV3:
case LDAP_DN_FORMAT_LDAPV2:
case LDAP_DN_FORMAT_DCE:
break;
/* unsupported in str2dn */
case LDAP_DN_FORMAT_UFN:
case LDAP_DN_FORMAT_AD_CANONICAL:
return LDAP_PARAM_ERROR;
case LDAP_DN_FORMAT_LBER:
default:
return LDAP_PARAM_ERROR;
}
if ( bv->bv_len == 0 ) {
return LDAP_SUCCESS;
}
if( memchr( bv->bv_val, '\0', bv->bv_len ) != NULL ) {
/* value must have embedded NULs */
return LDAP_DECODING_ERROR;
}
p = str;
if ( LDAP_DN_DCE( flags ) ) {
/*
* (from Luke Howard: thnx) A RDN separator is required
* at the beginning of an (absolute) DN.
*/
if ( !LDAP_DN_RDN_SEP_DCE( p[ 0 ] ) ) {
goto parsing_error;
}
p++;
/*
* actually we do not want to accept by default the DCE form,
* we do not want to auto-detect it
*/
#if 0
} else if ( LDAP_DN_LDAP( flags ) ) {
/*
* if dn starts with '/' let's make it a DCE dn
*/
if ( LDAP_DN_RDN_SEP_DCE( p[ 0 ] ) ) {
flags |= LDAP_DN_FORMAT_DCE;
p++;
}
#endif
}
for ( ; p < end; p++ ) {
int err;
struct berval tmpbv;
tmpbv.bv_len = bv->bv_len - ( p - str );
tmpbv.bv_val = (char *)p;
err = ldap_bv2rdn( &tmpbv, &newRDN, (char **) &p, flags );
if ( err != LDAP_SUCCESS ) {
goto parsing_error;
}
/*
* We expect a rdn separator
*/
if ( p < end && p[ 0 ] ) {
switch ( LDAP_DN_FORMAT( flags ) ) {
case LDAP_DN_FORMAT_LDAPV3:
if ( !LDAP_DN_RDN_SEP( p[ 0 ] ) ) {
rc = LDAP_DECODING_ERROR;
goto parsing_error;
}
break;
case LDAP_DN_FORMAT_LDAP:
case LDAP_DN_FORMAT_LDAPV2:
if ( !LDAP_DN_RDN_SEP_V2( p[ 0 ] ) ) {
rc = LDAP_DECODING_ERROR;
goto parsing_error;
}
break;
case LDAP_DN_FORMAT_DCE:
if ( !LDAP_DN_RDN_SEP_DCE( p[ 0 ] ) ) {
rc = LDAP_DECODING_ERROR;
goto parsing_error;
}
break;
}
}
tmpDN[nrdns++] = newRDN;
newRDN = NULL;
/*
* make the static RDN array dynamically rescalable
*/
if ( nrdns == num_slots ) {
LDAPRDN **tmp;
if ( tmpDN == tmpDN_ ) {
tmp = LDAP_MALLOC( num_slots * 2 * sizeof( LDAPRDN * ) );
if ( tmp == NULL ) {
rc = LDAP_NO_MEMORY;
goto parsing_error;
}
AC_MEMCPY( tmp, tmpDN, num_slots * sizeof( LDAPRDN * ) );
} else {
tmp = LDAP_REALLOC( tmpDN, num_slots * 2 * sizeof( LDAPRDN * ) );
if ( tmp == NULL ) {
rc = LDAP_NO_MEMORY;
goto parsing_error;
}
}
tmpDN = tmp;
num_slots *= 2;
}
if ( p >= end || p[ 0 ] == '\0' ) {
/*
* the DN is over, phew
*/
newDN = (LDAPDN *)LDAP_MALLOC( sizeof(LDAPDN) +
sizeof(LDAPRDN *) * (nrdns+1));
if ( newDN == NULL ) {
rc = LDAP_NO_MEMORY;
goto parsing_error;
} else {
int i;
newDN[0] = (LDAPRDN **)(newDN+1);
if ( LDAP_DN_DCE( flags ) ) {
/* add in reversed order */
for ( i=0; i<nrdns; i++ )
newDN[0][i] = tmpDN[nrdns-1-i];
} else {
for ( i=0; i<nrdns; i++ )
newDN[0][i] = tmpDN[i];
}
newDN[0][nrdns] = NULL;
rc = LDAP_SUCCESS;
}
goto return_result;
}
}
parsing_error:;
if ( newRDN ) {
ldap_rdnfree( newRDN );
}
for ( nrdns-- ;nrdns >= 0; nrdns-- ) {
ldap_rdnfree( tmpDN[nrdns] );
}
return_result:;
if ( tmpDN != tmpDN_ ) {
LDAP_FREE( tmpDN );
}
#ifdef NEW_LOGGING
LDAP_LOG ( OPERATION, RESULTS, "<= ldap_bv2dn(%s,%u)=%d\n",
str, flags, rc );
#else
Debug( LDAP_DEBUG_TRACE, "<= ldap_bv2dn(%s,%u)=%d\n", str, flags, rc );
#endif
*dn = newDN;
return( rc );
}
/*
* ldap_str2rdn
*
* Parses a relative DN according to flags up to a rdn separator
* or to the end of str.
* Returns the rdn and a pointer to the string continuation, which
* corresponds to the rdn separator or to '\0' in case the string is over.
*/
int
ldap_str2rdn( LDAP_CONST char *str, LDAPRDN **rdn,
char **n_in, unsigned flags )
{
struct berval bv;
assert( str );
assert( str[ 0 ] != '\0' ); /* FIXME: is this required? */
bv.bv_len = strlen( str );
bv.bv_val = (char *) str;
return ldap_bv2rdn( &bv, rdn, n_in, flags );
}
int
ldap_bv2rdn( struct berval *bv, LDAPRDN **rdn,
char **n_in, unsigned flags )
{
const char **n = (const char **) n_in;
const char *p;
int navas = 0;
int state = B4AVA;
int rc = LDAP_DECODING_ERROR;
int attrTypeEncoding = LDAP_AVA_STRING,
attrValueEncoding = LDAP_AVA_STRING;
struct berval attrType = { 0, NULL };
struct berval attrValue = { 0, NULL };
LDAPRDN *newRDN = NULL;
LDAPAVA *tmpRDN_[TMP_AVA_SLOTS], **tmpRDN = tmpRDN_;
int num_slots = TMP_AVA_SLOTS;
char *str;
ber_len_t stoplen;
assert( bv );
assert( bv->bv_len );
assert( bv->bv_val );
assert( rdn || flags & LDAP_DN_SKIP );
assert( n );
str = bv->bv_val;
stoplen = bv->bv_len;
if ( rdn ) {
*rdn = NULL;
}
*n = NULL;
switch ( LDAP_DN_FORMAT( flags ) ) {
case LDAP_DN_FORMAT_LDAP:
case LDAP_DN_FORMAT_LDAPV3:
case LDAP_DN_FORMAT_LDAPV2:
case LDAP_DN_FORMAT_DCE:
break;
/* unsupported in str2dn */
case LDAP_DN_FORMAT_UFN:
case LDAP_DN_FORMAT_AD_CANONICAL:
return LDAP_PARAM_ERROR;
case LDAP_DN_FORMAT_LBER:
default:
return LDAP_PARAM_ERROR;
}
if ( bv->bv_len == 0 ) {
return LDAP_SUCCESS;
}
if( memchr( bv->bv_val, '\0', bv->bv_len ) != NULL ) {
/* value must have embedded NULs */
return LDAP_DECODING_ERROR;
}
p = str;
for ( ; p[ 0 ] || state == GOTAVA; ) {
/*
* The parser in principle advances one token a time,
* or toggles state if preferable.
*/
switch (state) {
/*
* an AttributeType can be encoded as:
* - its string representation; in detail, implementations
* MUST recognize AttributeType string type names listed
* in section 2.3 of draft-ietf-ldapbis-dn-XX.txt, and
* MAY recognize other names.
* - its numeric OID (a dotted decimal string); in detail
* RFC 2253 asserts that ``Implementations MUST allow
* an oid in the attribute type to be prefixed by one
* of the character strings "oid." or "OID."''. As soon
* as draft-ietf-ldapbis-dn-XX.txt obsoletes RFC 2253
* I'm not sure whether this is required or not any
* longer; to be liberal, we still implement it.
*/
case B4AVA:
if ( LDAP_DN_ASCII_SPACE( p[ 0 ] ) ) {
if ( !LDAP_DN_ALLOW_ONE_SPACE( flags ) ) {
/* error */
goto parsing_error;
}
p++;
}
if ( LDAP_DN_ASCII_SPACE( p[ 0 ] ) ) {
if ( !LDAP_DN_ALLOW_SPACES( flags ) ) {
/* error */
goto parsing_error;
}
/* whitespace is allowed (and trimmed) */
p++;
while ( p[ 0 ] && LDAP_DN_ASCII_SPACE( p[ 0 ] ) ) {
p++;
}
if ( !p[ 0 ] ) {
/* error: we expected an AVA */
goto parsing_error;
}
}
/* oid */
if ( LDAP_DN_OID_LEADCHAR( p[ 0 ] ) ) {
state = B4OIDATTRTYPE;
break;
}
/* else must be alpha */
if ( !LDAP_DN_DESC_LEADCHAR( p[ 0 ] ) ) {
goto parsing_error;
}
/* LDAPv2 "oid." prefix */
if ( LDAP_DN_LDAPV2( flags ) ) {
/*
* to be overly pedantic, we only accept
* "OID." or "oid."
*/
if ( flags & LDAP_DN_PEDANTIC ) {
if ( !strncmp( p, "OID.", 4 )
|| !strncmp( p, "oid.", 4 ) ) {
p += 4;
state = B4OIDATTRTYPE;
break;
}
} else {
if ( !strncasecmp( p, "oid.", 4 ) ) {
p += 4;
state = B4OIDATTRTYPE;
break;
}
}
}
state = B4STRINGATTRTYPE;
break;
case B4OIDATTRTYPE: {
int err = LDAP_SUCCESS;
attrType.bv_val = ldap_int_parse_numericoid( &p, &err,
LDAP_SCHEMA_SKIP);
if ( err != LDAP_SUCCESS ) {
goto parsing_error;
}
attrType.bv_len = p - attrType.bv_val;
attrTypeEncoding = LDAP_AVA_BINARY;
state = B4AVAEQUALS;
break;
}
case B4STRINGATTRTYPE: {
const char *startPos, *endPos = NULL;
ber_len_t len;
/*
* the starting char has been found to be
* a LDAP_DN_DESC_LEADCHAR so we don't re-check it
* FIXME: DCE attr types seem to have a more
* restrictive syntax (no '-' ...)
*/
for ( startPos = p++; p[ 0 ]; p++ ) {
if ( LDAP_DN_DESC_CHAR( p[ 0 ] ) ) {
continue;
}
if ( LDAP_DN_LANG_SEP( p[ 0 ] ) ) {
/*
* RFC 2253 does not explicitly
* allow lang extensions to attribute
* types in DNs ...
*/
if ( flags & LDAP_DN_PEDANTIC ) {
goto parsing_error;
}
/*
* we trim ';' and following lang
* and so from attribute types
*/
endPos = p;
for ( ; LDAP_DN_ATTRDESC_CHAR( p[ 0 ] )
|| LDAP_DN_LANG_SEP( p[ 0 ] ); p++ ) {
/* no op */ ;
}
break;
}
break;
}
len = ( endPos ? endPos : p ) - startPos;
if ( len == 0 ) {
goto parsing_error;
}
attrTypeEncoding = LDAP_AVA_STRING;
/*
* here we need to decide whether to use it as is
* or turn it in OID form; as a consequence, we
* need to decide whether to binary encode the value
*/
state = B4AVAEQUALS;
if ( flags & LDAP_DN_SKIP ) {
break;
}
attrType.bv_val = (char *)startPos;
attrType.bv_len = len;
break;
}
case B4AVAEQUALS:
/* spaces may not be allowed */
if ( LDAP_DN_ASCII_SPACE( p[ 0 ] ) ) {
if ( !LDAP_DN_ALLOW_SPACES( flags ) ) {
goto parsing_error;
}
/* trim spaces */
for ( p++; LDAP_DN_ASCII_SPACE( p[ 0 ] ); p++ ) {
/* no op */
}
}
/* need equal sign */
if ( !LDAP_DN_AVA_EQUALS( p[ 0 ] ) ) {
goto parsing_error;
}
p++;
/* spaces may not be allowed */
if ( LDAP_DN_ASCII_SPACE( p[ 0 ] ) ) {
if ( !LDAP_DN_ALLOW_SPACES( flags ) ) {
goto parsing_error;
}
/* trim spaces */
for ( p++; LDAP_DN_ASCII_SPACE( p[ 0 ] ); p++ ) {
/* no op */
}
}
/*
* octothorpe means a BER encoded value will follow
* FIXME: I don't think DCE will allow it
*/
if ( LDAP_DN_OCTOTHORPE( p[ 0 ] ) ) {
p++;
attrValueEncoding = LDAP_AVA_BINARY;
state = B4BINARYVALUE;
break;
}
/* STRING value expected */
/*
* if we're pedantic, an attribute type in OID form
* SHOULD imply a BER encoded attribute value; we
* should at least issue a warning
*/
if ( ( flags & LDAP_DN_PEDANTIC )
&& ( attrTypeEncoding == LDAP_AVA_BINARY ) ) {
/* OID attrType SHOULD use binary encoding */
goto parsing_error;
}
attrValueEncoding = LDAP_AVA_STRING;
/*
* LDAPv2 allows the attribute value to be quoted;
* also, IA5 values are expected, in principle
*/
if ( LDAP_DN_LDAPV2( flags ) || LDAP_DN_LDAP( flags ) ) {
if ( LDAP_DN_QUOTES( p[ 0 ] ) ) {
p++;
state = B4IA5VALUEQUOTED;
break;
}
if ( LDAP_DN_LDAPV2( flags ) ) {
state = B4IA5VALUE;
break;
}
}
/*
* here STRING means RFC 2253 string
* FIXME: what about DCE strings?
*/
if ( !p[ 0 ] ) {
/* empty value */
state = GOTAVA;
} else {
state = B4STRINGVALUE;
}
break;
case B4BINARYVALUE:
if ( hexstr2binval( p, &attrValue, &p, flags ) ) {
goto parsing_error;
}
state = GOTAVA;
break;
case B4STRINGVALUE:
switch ( LDAP_DN_FORMAT( flags ) ) {
case LDAP_DN_FORMAT_LDAP:
case LDAP_DN_FORMAT_LDAPV3:
if ( str2strval( p, stoplen - ( p - str ),
&attrValue, &p, flags,
&attrValueEncoding ) ) {
goto parsing_error;
}
break;
case LDAP_DN_FORMAT_DCE:
if ( DCE2strval( p, &attrValue, &p, flags ) ) {
goto parsing_error;
}
break;
default:
assert( 0 );
}
state = GOTAVA;
break;
case B4IA5VALUE:
if ( IA52strval( p, &attrValue, &p, flags ) ) {
goto parsing_error;
}
state = GOTAVA;
break;
case B4IA5VALUEQUOTED:
/* lead quote already stripped */
if ( quotedIA52strval( p, &attrValue,
&p, flags ) ) {
goto parsing_error;
}
state = GOTAVA;
break;
case GOTAVA: {
int rdnsep = 0;
if ( !( flags & LDAP_DN_SKIP ) ) {
LDAPAVA *ava;
/*
* we accept empty values
*/
ava = ldapava_new( &attrType, &attrValue,
attrValueEncoding );
if ( ava == NULL ) {
rc = LDAP_NO_MEMORY;
goto parsing_error;
}
tmpRDN[navas++] = ava;
attrValue.bv_val = NULL;
attrValue.bv_len = 0;
/*
* prepare room for new AVAs if needed
*/
if (navas == num_slots) {
LDAPAVA **tmp;
if ( tmpRDN == tmpRDN_ ) {
tmp = LDAP_MALLOC( num_slots * 2 * sizeof( LDAPAVA * ) );
if ( tmp == NULL ) {
rc = LDAP_NO_MEMORY;
goto parsing_error;
}
AC_MEMCPY( tmp, tmpRDN, num_slots * sizeof( LDAPAVA * ) );
} else {
tmp = LDAP_REALLOC( tmpRDN, num_slots * 2 * sizeof( LDAPAVA * ) );
if ( tmp == NULL ) {
rc = LDAP_NO_MEMORY;
goto parsing_error;
}
}
tmpRDN = tmp;
num_slots *= 2;
}
}
/*
* if we got an AVA separator ('+', or ',' for DCE )
* we expect a new AVA for this RDN; otherwise
* we add the RDN to the DN
*/
switch ( LDAP_DN_FORMAT( flags ) ) {
case LDAP_DN_FORMAT_LDAP:
case LDAP_DN_FORMAT_LDAPV3:
case LDAP_DN_FORMAT_LDAPV2:
if ( !LDAP_DN_AVA_SEP( p[ 0 ] ) ) {
rdnsep = 1;
}
break;
case LDAP_DN_FORMAT_DCE:
if ( !LDAP_DN_AVA_SEP_DCE( p[ 0 ] ) ) {
rdnsep = 1;
}
break;
}
if ( rdnsep ) {
/*
* the RDN is over, phew
*/
*n = p;
if ( !( flags & LDAP_DN_SKIP ) ) {
newRDN = (LDAPRDN *)LDAP_MALLOC( sizeof(LDAPRDN)
+ sizeof(LDAPAVA *) * (navas+1) );
if ( newRDN == NULL ) {
rc = LDAP_NO_MEMORY;
goto parsing_error;
} else {
int i;
newRDN[0] = (LDAPAVA**)(newRDN+1);
for (i=0; i<navas; i++)
newRDN[0][i] = tmpRDN[i];
newRDN[0][i] = NULL;
}
}
rc = LDAP_SUCCESS;
goto return_result;
}
/* they should have been used in an AVA */
attrType.bv_val = NULL;
attrValue.bv_val = NULL;
p++;
state = B4AVA;
break;
}
default:
assert( 0 );
goto parsing_error;
}
}
*n = p;
parsing_error:;
/* They are set to NULL after they're used in an AVA */
if ( attrValue.bv_val ) {
free( attrValue.bv_val );
}
for ( navas-- ; navas >= 0; navas-- ) {
ldap_avafree( tmpRDN[navas] );
}
return_result:;
if ( tmpRDN != tmpRDN_ ) {
LDAP_FREE( tmpRDN );
}
if ( rdn ) {
*rdn = newRDN;
}
return( rc );
}
/*
* reads in a UTF-8 string value, unescaping stuff:
* '\' + LDAP_DN_NEEDESCAPE(c) -> 'c'
* '\' + HEXPAIR(p) -> unhex(p)
*/
static int
str2strval( const char *str, ber_len_t stoplen, struct berval *val, const char **next, unsigned flags, unsigned *retFlags )
{
const char *p, *end, *startPos, *endPos = NULL;
ber_len_t len, escapes;
assert( str );
assert( val );
assert( next );
*next = NULL;
end = str + stoplen;
for ( startPos = p = str, escapes = 0; p < end; p++ ) {
if ( LDAP_DN_ESCAPE( p[ 0 ] ) ) {
p++;
if ( p[ 0 ] == '\0' ) {
return( 1 );
}
if ( LDAP_DN_MAYESCAPE( p[ 0 ] ) ) {
escapes++;
continue;
}
if ( LDAP_DN_HEXPAIR( p ) ) {
char c;
hexstr2bin( p, &c );
escapes += 2;
if ( !LDAP_DN_ASCII_PRINTABLE( c ) ) {
/*
* we assume the string is UTF-8
*/
*retFlags = LDAP_AVA_NONPRINTABLE;
}
p++;
continue;
}
if ( LDAP_DN_PEDANTIC & flags ) {
return( 1 );
}
/*
* we do not allow escaping
* of chars that don't need
* to and do not belong to
* HEXDIGITS
*/
return( 1 );
} else if (!LDAP_DN_ASCII_PRINTABLE( p[ 0 ] ) ) {
if ( p[ 0 ] == '\0' ) {
return( 1 );
}
*retFlags = LDAP_AVA_NONPRINTABLE;
} else if ( ( LDAP_DN_LDAP( flags ) && LDAP_DN_VALUE_END_V2( p[ 0 ] ) )
|| ( LDAP_DN_LDAPV3( flags ) && LDAP_DN_VALUE_END( p[ 0 ] ) ) ) {
break;
} else if ( LDAP_DN_NEEDESCAPE( p[ 0 ] ) ) {
/*
* FIXME: maybe we can add
* escapes if not pedantic?
*/
return( 1 );
}
}
/*
* we do allow unescaped spaces at the end
* of the value only in non-pedantic mode
*/
if ( p > startPos + 1 && LDAP_DN_ASCII_SPACE( p[ -1 ] ) &&
!LDAP_DN_ESCAPE( p[ -2 ] ) ) {
if ( flags & LDAP_DN_PEDANTIC ) {
return( 1 );
}
/* strip trailing (unescaped) spaces */
for ( endPos = p - 1;
endPos > startPos + 1 &&
LDAP_DN_ASCII_SPACE( endPos[ -1 ] ) &&
!LDAP_DN_ESCAPE( endPos[ -2 ] );
endPos-- ) {
/* no op */
}
}
*next = p;
if ( flags & LDAP_DN_SKIP ) {
return( 0 );
}
/*
* FIXME: test memory?
*/
len = ( endPos ? endPos : p ) - startPos - escapes;
val->bv_len = len;
if ( escapes == 0 ) {
if ( *retFlags == LDAP_AVA_NONPRINTABLE ) {
val->bv_val = LDAP_MALLOC( len + 1 );
AC_MEMCPY( val->bv_val, startPos, len );
val->bv_val[ len ] = '\0';
} else {
val->bv_val = LDAP_STRNDUP( startPos, len );
}
} else {
ber_len_t s, d;
val->bv_val = LDAP_MALLOC( len + 1 );
for ( s = 0, d = 0; d < len; ) {
if ( LDAP_DN_ESCAPE( startPos[ s ] ) ) {
s++;
if ( LDAP_DN_MAYESCAPE( startPos[ s ] ) ) {
val->bv_val[ d++ ] =
startPos[ s++ ];
} else if ( LDAP_DN_HEXPAIR( &startPos[ s ] ) ) {
char c;
hexstr2bin( &startPos[ s ], &c );
val->bv_val[ d++ ] = c;
s += 2;
} else {
/* we should never get here */
assert( 0 );
}
} else {
val->bv_val[ d++ ] = startPos[ s++ ];
}
}
val->bv_val[ d ] = '\0';
assert( d == len );
}
return( 0 );
}
static int
DCE2strval( const char *str, struct berval *val, const char **next, unsigned flags )
{
const char *p, *startPos, *endPos = NULL;
ber_len_t len, escapes;
assert( str );
assert( val );
assert( next );
*next = NULL;
for ( startPos = p = str, escapes = 0; p[ 0 ]; p++ ) {
if ( LDAP_DN_ESCAPE_DCE( p[ 0 ] ) ) {
p++;
if ( LDAP_DN_NEEDESCAPE_DCE( p[ 0 ] ) ) {
escapes++;
} else {
return( 1 );
}
} else if ( LDAP_DN_VALUE_END_DCE( p[ 0 ] ) ) {
break;
}
/*
* FIXME: can we accept anything else? I guess we need
* to stop if a value is not legal
*/
}
/*
* (unescaped) trailing spaces are trimmed must be silently ignored;
* so we eat them
*/
if ( p > startPos + 1 && LDAP_DN_ASCII_SPACE( p[ -1 ] ) &&
!LDAP_DN_ESCAPE( p[ -2 ] ) ) {
if ( flags & LDAP_DN_PEDANTIC ) {
return( 1 );
}
/* strip trailing (unescaped) spaces */
for ( endPos = p - 1;
endPos > startPos + 1 &&
LDAP_DN_ASCII_SPACE( endPos[ -1 ] ) &&
!LDAP_DN_ESCAPE( endPos[ -2 ] );
endPos-- ) {
/* no op */
}
}
*next = p;
if ( flags & LDAP_DN_SKIP ) {
return( 0 );
}
len = ( endPos ? endPos : p ) - startPos - escapes;
val->bv_len = len;
if ( escapes == 0 ){
val->bv_val = LDAP_STRNDUP( startPos, len );
} else {
ber_len_t s, d;
val->bv_val = LDAP_MALLOC( len + 1 );
for ( s = 0, d = 0; d < len; ) {
/*
* This point is reached only if escapes
* are properly used, so all we need to
* do is eat them
*/
if ( LDAP_DN_ESCAPE_DCE( startPos[ s ] ) ) {
s++;
}
val->bv_val[ d++ ] = startPos[ s++ ];
}
val->bv_val[ d ] = '\0';
assert( strlen( val->bv_val ) == len );
}
return( 0 );
}
static int
IA52strval( const char *str, struct berval *val, const char **next, unsigned flags )
{
const char *p, *startPos, *endPos = NULL;
ber_len_t len, escapes;
assert( str );
assert( val );
assert( next );
*next = NULL;
/*
* LDAPv2 (RFC 1779)
*/
for ( startPos = p = str, escapes = 0; p[ 0 ]; p++ ) {
if ( LDAP_DN_ESCAPE( p[ 0 ] ) ) {
p++;
if ( p[ 0 ] == '\0' ) {
return( 1 );
}
if ( !LDAP_DN_NEEDESCAPE( p[ 0 ] )
&& ( LDAP_DN_PEDANTIC & flags ) ) {
return( 1 );
}
escapes++;
} else if ( LDAP_DN_VALUE_END_V2( p[ 0 ] ) ) {
break;
}
/*
* FIXME: can we accept anything else? I guess we need
* to stop if a value is not legal
*/
}
/* strip trailing (unescaped) spaces */
for ( endPos = p;
endPos > startPos + 1 &&
LDAP_DN_ASCII_SPACE( endPos[ -1 ] ) &&
!LDAP_DN_ESCAPE( endPos[ -2 ] );
endPos-- ) {
/* no op */
}
*next = p;
if ( flags & LDAP_DN_SKIP ) {
return( 0 );
}
len = ( endPos ? endPos : p ) - startPos - escapes;
val->bv_len = len;
if ( escapes == 0 ) {
val->bv_val = LDAP_STRNDUP( startPos, len );
} else {
ber_len_t s, d;
val->bv_val = LDAP_MALLOC( len + 1 );
for ( s = 0, d = 0; d < len; ) {
if ( LDAP_DN_ESCAPE( startPos[ s ] ) ) {
s++;
}
val->bv_val[ d++ ] = startPos[ s++ ];
}
val->bv_val[ d ] = '\0';
assert( strlen( val->bv_val ) == len );
}
return( 0 );
}
static int
quotedIA52strval( const char *str, struct berval *val, const char **next, unsigned flags )
{
const char *p, *startPos, *endPos = NULL;
ber_len_t len;
unsigned escapes = 0;
assert( str );
assert( val );
assert( next );
*next = NULL;
/* initial quote already eaten */
for ( startPos = p = str; p[ 0 ]; p++ ) {
/*
* According to RFC 1779, the quoted value can
* contain escaped as well as unescaped special values;
* as a consequence we tolerate escaped values
* (e.g. '"\,"' -> '\,') and escape unescaped specials
* (e.g. '","' -> '\,').
*/
if ( LDAP_DN_ESCAPE( p[ 0 ] ) ) {
if ( p[ 1 ] == '\0' ) {
return( 1 );
}
p++;
if ( !LDAP_DN_V2_PAIR( p[ 0 ] )
&& ( LDAP_DN_PEDANTIC & flags ) ) {
/*
* do we allow to escape normal chars?
* LDAPv2 does not allow any mechanism
* for escaping chars with '\' and hex
* pair
*/
return( 1 );
}
escapes++;
} else if ( LDAP_DN_QUOTES( p[ 0 ] ) ) {
endPos = p;
/* eat closing quotes */
p++;
break;
}
/*
* FIXME: can we accept anything else? I guess we need
* to stop if a value is not legal
*/
}
if ( endPos == NULL ) {
return( 1 );
}
/* Strip trailing (unescaped) spaces */
for ( ; p[ 0 ] && LDAP_DN_ASCII_SPACE( p[ 0 ] ); p++ ) {
/* no op */
}
*next = p;
if ( flags & LDAP_DN_SKIP ) {
return( 0 );
}
len = endPos - startPos - escapes;
assert( endPos >= startPos + escapes );
val->bv_len = len;
if ( escapes == 0 ) {
val->bv_val = LDAP_STRNDUP( startPos, len );
} else {
ber_len_t s, d;
val->bv_val = LDAP_MALLOC( len + 1 );
val->bv_len = len;
for ( s = d = 0; d < len; ) {
if ( LDAP_DN_ESCAPE( str[ s ] ) ) {
s++;
}
val->bv_val[ d++ ] = str[ s++ ];
}
val->bv_val[ d ] = '\0';
assert( strlen( val->bv_val ) == len );
}
return( 0 );
}
static int
hexstr2bin( const char *str, char *c )
{
char c1, c2;
assert( str );
assert( c );
c1 = str[ 0 ];
c2 = str[ 1 ];
if ( LDAP_DN_ASCII_DIGIT( c1 ) ) {
*c = c1 - '0';
} else {
if ( LDAP_DN_ASCII_UCASE_HEXALPHA( c1 ) ) {
*c = c1 - 'A' + 10;
} else {
assert( LDAP_DN_ASCII_LCASE_HEXALPHA( c1 ) );
*c = c1 - 'a' + 10;
}
}
*c <<= 4;
if ( LDAP_DN_ASCII_DIGIT( c2 ) ) {
*c += c2 - '0';
} else {
if ( LDAP_DN_ASCII_UCASE_HEXALPHA( c2 ) ) {
*c += c2 - 'A' + 10;
} else {
assert( LDAP_DN_ASCII_LCASE_HEXALPHA( c2 ) );
*c += c2 - 'a' + 10;
}
}
return( 0 );
}
static int
hexstr2binval( const char *str, struct berval *val, const char **next, unsigned flags )
{
const char *p, *startPos, *endPos = NULL;
ber_len_t len;
ber_len_t s, d;
assert( str );
assert( val );
assert( next );
*next = NULL;
for ( startPos = p = str; p[ 0 ]; p += 2 ) {
switch ( LDAP_DN_FORMAT( flags ) ) {
case LDAP_DN_FORMAT_LDAPV3:
if ( LDAP_DN_VALUE_END( p[ 0 ] ) ) {
goto end_of_value;
}
break;
case LDAP_DN_FORMAT_LDAP:
case LDAP_DN_FORMAT_LDAPV2:
if ( LDAP_DN_VALUE_END_V2( p[ 0 ] ) ) {
goto end_of_value;
}
break;
case LDAP_DN_FORMAT_DCE:
if ( LDAP_DN_VALUE_END_DCE( p[ 0 ] ) ) {
goto end_of_value;
}
break;
}
if ( LDAP_DN_ASCII_SPACE( p[ 0 ] ) ) {
if ( flags & LDAP_DN_PEDANTIC ) {
return( 1 );
}
endPos = p;
for ( ; p[ 0 ]; p++ ) {
switch ( LDAP_DN_FORMAT( flags ) ) {
case LDAP_DN_FORMAT_LDAPV3:
if ( LDAP_DN_VALUE_END( p[ 0 ] ) ) {
goto end_of_value;
}
break;
case LDAP_DN_FORMAT_LDAP:
case LDAP_DN_FORMAT_LDAPV2:
if ( LDAP_DN_VALUE_END_V2( p[ 0 ] ) ) {
goto end_of_value;
}
break;
case LDAP_DN_FORMAT_DCE:
if ( LDAP_DN_VALUE_END_DCE( p[ 0 ] ) ) {
goto end_of_value;
}
break;
}
}
break;
}
if ( !LDAP_DN_HEXPAIR( p ) ) {
return( 1 );
}
}
end_of_value:;
*next = p;
if ( flags & LDAP_DN_SKIP ) {
return( 0 );
}
len = ( ( endPos ? endPos : p ) - startPos ) / 2;
/* must be even! */
assert( 2 * len == (ber_len_t) (( endPos ? endPos : p ) - startPos ));
val->bv_len = len;
val->bv_val = LDAP_MALLOC( len + 1 );
if ( val->bv_val == NULL ) {
return( LDAP_NO_MEMORY );
}
for ( s = 0, d = 0; d < len; s += 2, d++ ) {
char c;
hexstr2bin( &startPos[ s ], &c );
val->bv_val[ d ] = c;
}
val->bv_val[ d ] = '\0';
return( 0 );
}
/*
* convert a byte in a hexadecimal pair
*/
static int
byte2hexpair( const char *val, char *pair )
{
static const char hexdig[] = "0123456789ABCDEF";
assert( val );
assert( pair );
/*
* we assume the string has enough room for the hex encoding
* of the value
*/
pair[ 0 ] = hexdig[ 0x0f & ( val[ 0 ] >> 4 ) ];
pair[ 1 ] = hexdig[ 0x0f & val[ 0 ] ];
return( 0 );
}
/*
* convert a binary value in hexadecimal pairs
*/
static int
binval2hexstr( struct berval *val, char *str )
{
ber_len_t s, d;
assert( val );
assert( str );
if ( val->bv_len == 0 ) {
return( 0 );
}
/*
* we assume the string has enough room for the hex encoding
* of the value
*/
for ( s = 0, d = 0; s < val->bv_len; s++, d += 2 ) {
byte2hexpair( &val->bv_val[ s ], &str[ d ] );
}
return( 0 );
}
/*
* Length of the string representation, accounting for escaped hex
* of UTF-8 chars
*/
static int
strval2strlen( struct berval *val, unsigned flags, ber_len_t *len )
{
ber_len_t l, cl = 1;
char *p;
int escaped_byte_len = LDAP_DN_IS_PRETTY( flags ) ? 1 : 3;
#ifdef PRETTY_ESCAPE
int escaped_ascii_len = LDAP_DN_IS_PRETTY( flags ) ? 2 : 3;
#endif /* PRETTY_ESCAPE */
assert( val );
assert( len );
*len = 0;
if ( val->bv_len == 0 ) {
return( 0 );
}
for ( l = 0, p = val->bv_val; p < val->bv_val + val->bv_len; p += cl ) {
/*
* escape '%x00'
*/
if ( p[ 0 ] == '\0' ) {
cl = 1;
l += 3;
continue;
}
cl = LDAP_UTF8_CHARLEN2( p, cl );
if ( cl == 0 ) {
/* illegal utf-8 char! */
return( -1 );
} else if ( cl > 1 ) {
ber_len_t cnt;
for ( cnt = 1; cnt < cl; cnt++ ) {
if ( ( p[ cnt ] & 0xc0 ) != 0x80 ) {
return( -1 );
}
}
l += escaped_byte_len * cl;
} else if ( LDAP_DN_NEEDESCAPE( p[ 0 ] )
|| ( p == val->bv_val && LDAP_DN_NEEDESCAPE_LEAD( p[ 0 ] ) )
|| ( !p[ 1 ] && LDAP_DN_NEEDESCAPE_TRAIL( p[ 0 ] ) ) ) {
#ifdef PRETTY_ESCAPE
#if 0
if ( LDAP_DN_WILLESCAPE_HEX( flags, p[ 0 ] ) ) {
#else
if ( LDAP_DN_WILLESCAPE_CHAR( p[ 0 ] ) ) {
#endif
/*
* there might be some chars we want
* to escape in form of a couple
* of hexdigits for optimization purposes
*/
l += 3;
} else {
l += escaped_ascii_len;
}
#else /* ! PRETTY_ESCAPE */
l += 3;
#endif /* ! PRETTY_ESCAPE */
} else {
l++;
}
}
*len = l;
return( 0 );
}
/*
* convert to string representation, escaping with hex the UTF-8 stuff;
* assume the destination has enough room for escaping
*/
static int
strval2str( struct berval *val, char *str, unsigned flags, ber_len_t *len )
{
ber_len_t s, d, end;
assert( val );
assert( str );
assert( len );
if ( val->bv_len == 0 ) {
*len = 0;
return( 0 );
}
/*
* we assume the string has enough room for the hex encoding
* of the value
*/
for ( s = 0, d = 0, end = val->bv_len - 1; s < val->bv_len; ) {
ber_len_t cl;
/*
* escape '%x00'
*/
if ( val->bv_val[ s ] == '\0' ) {
cl = 1;
str[ d++ ] = '\\';
str[ d++ ] = '0';
str[ d++ ] = '0';
s++;
continue;
}
/*
* The length was checked in strval2strlen();
* LDAP_UTF8_CHARLEN() should suffice
*/
cl = LDAP_UTF8_CHARLEN2( &val->bv_val[ s ], cl );
assert( cl > 0 );
/*
* there might be some chars we want to escape in form
* of a couple of hexdigits for optimization purposes
*/
if ( ( cl > 1 && !LDAP_DN_IS_PRETTY( flags ) )
#ifdef PRETTY_ESCAPE
#if 0
|| LDAP_DN_WILLESCAPE_HEX( flags, val->bv_val[ s ] )
#else
|| LDAP_DN_WILLESCAPE_CHAR( val->bv_val[ s ] )
#endif
#else /* ! PRETTY_ESCAPE */
|| LDAP_DN_NEEDESCAPE( val->bv_val[ s ] )
|| ( d == 0 && LDAP_DN_NEEDESCAPE_LEAD( val->bv_val[ s ] ) )
|| ( s == end && LDAP_DN_NEEDESCAPE_TRAIL( val->bv_val[ s ] ) )
#endif /* ! PRETTY_ESCAPE */
) {
for ( ; cl--; ) {
str[ d++ ] = '\\';
byte2hexpair( &val->bv_val[ s ], &str[ d ] );
s++;
d += 2;
}
} else if ( cl > 1 ) {
for ( ; cl--; ) {
str[ d++ ] = val->bv_val[ s++ ];
}
} else {
#ifdef PRETTY_ESCAPE
if ( LDAP_DN_NEEDESCAPE( val->bv_val[ s ] )
|| ( d == 0 && LDAP_DN_NEEDESCAPE_LEAD( val->bv_val[ s ] ) )
|| ( s == end && LDAP_DN_NEEDESCAPE_TRAIL( val->bv_val[ s ] ) ) ) {
str[ d++ ] = '\\';
if ( !LDAP_DN_IS_PRETTY( flags ) ) {
byte2hexpair( &val->bv_val[ s ], &str[ d ] );
s++;
d += 2;
continue;
}
}
#endif /* PRETTY_ESCAPE */
str[ d++ ] = val->bv_val[ s++ ];
}
}
*len = d;
return( 0 );
}
/*
* Length of the IA5 string representation (no UTF-8 allowed)
*/
static int
strval2IA5strlen( struct berval *val, unsigned flags, ber_len_t *len )
{
ber_len_t l;
char *p;
assert( val );
assert( len );
*len = 0;
if ( val->bv_len == 0 ) {
return( 0 );
}
if ( flags & LDAP_AVA_NONPRINTABLE ) {
/*
* Turn value into a binary encoded BER
*/
return( -1 );
} else {
for ( l = 0, p = val->bv_val; p[ 0 ]; p++ ) {
if ( LDAP_DN_NEEDESCAPE( p[ 0 ] )
|| ( p == val->bv_val && LDAP_DN_NEEDESCAPE_LEAD( p[ 0 ] ) )
|| ( !p[ 1 ] && LDAP_DN_NEEDESCAPE_TRAIL( p[ 0 ] ) ) ) {
l += 2;
} else {
l++;
}
}
}
*len = l;
return( 0 );
}
/*
* convert to string representation (np UTF-8)
* assume the destination has enough room for escaping
*/
static int
strval2IA5str( struct berval *val, char *str, unsigned flags, ber_len_t *len )
{
ber_len_t s, d, end;
assert( val );
assert( str );
assert( len );
if ( val->bv_len == 0 ) {
*len = 0;
return( 0 );
}
if ( flags & LDAP_AVA_NONPRINTABLE ) {
/*
* Turn value into a binary encoded BER
*/
*len = 0;
return( -1 );
} else {
/*
* we assume the string has enough room for the hex encoding
* of the value
*/
for ( s = 0, d = 0, end = val->bv_len - 1; s < val->bv_len; ) {
if ( LDAP_DN_NEEDESCAPE( val->bv_val[ s ] )
|| ( s == 0 && LDAP_DN_NEEDESCAPE_LEAD( val->bv_val[ s ] ) )
|| ( s == end && LDAP_DN_NEEDESCAPE_TRAIL( val->bv_val[ s ] ) ) ) {
str[ d++ ] = '\\';
}
str[ d++ ] = val->bv_val[ s++ ];
}
}
*len = d;
return( 0 );
}
/*
* Length of the (supposedly) DCE string representation,
* accounting for escaped hex of UTF-8 chars
*/
static int
strval2DCEstrlen( struct berval *val, unsigned flags, ber_len_t *len )
{
ber_len_t l;
char *p;
assert( val );
assert( len );
*len = 0;
if ( val->bv_len == 0 ) {
return( 0 );
}
if ( flags & LDAP_AVA_NONPRINTABLE ) {
/*
* FIXME: Turn the value into a binary encoded BER?
*/
return( -1 );
} else {
for ( l = 0, p = val->bv_val; p[ 0 ]; p++ ) {
if ( LDAP_DN_NEEDESCAPE_DCE( p[ 0 ] ) ) {
l += 2;
} else {
l++;
}
}
}
*len = l;
return( 0 );
}
/*
* convert to (supposedly) DCE string representation,
* escaping with hex the UTF-8 stuff;
* assume the destination has enough room for escaping
*/
static int
strval2DCEstr( struct berval *val, char *str, unsigned flags, ber_len_t *len )
{
ber_len_t s, d;
assert( val );
assert( str );
assert( len );
if ( val->bv_len == 0 ) {
*len = 0;
return( 0 );
}
if ( flags & LDAP_AVA_NONPRINTABLE ) {
/*
* FIXME: Turn the value into a binary encoded BER?
*/
*len = 0;
return( -1 );
} else {
/*
* we assume the string has enough room for the hex encoding
* of the value
*/
for ( s = 0, d = 0; s < val->bv_len; ) {
if ( LDAP_DN_NEEDESCAPE_DCE( val->bv_val[ s ] ) ) {
str[ d++ ] = '\\';
}
str[ d++ ] = val->bv_val[ s++ ];
}
}
*len = d;
return( 0 );
}
/*
* Length of the (supposedly) AD canonical string representation,
* accounting for escaped hex of UTF-8 chars
*/
static int
strval2ADstrlen( struct berval *val, unsigned flags, ber_len_t *len )
{
ber_len_t l;
char *p;
assert( val );
assert( len );
*len = 0;
if ( val->bv_len == 0 ) {
return( 0 );
}
if ( flags & LDAP_AVA_NONPRINTABLE ) {
/*
* FIXME: Turn the value into a binary encoded BER?
*/
return( -1 );
} else {
for ( l = 0, p = val->bv_val; p[ 0 ]; p++ ) {
if ( LDAP_DN_NEEDESCAPE_AD( p[ 0 ] ) ) {
l += 2;
} else {
l++;
}
}
}
*len = l;
return( 0 );
}
/*
* convert to (supposedly) AD string representation,
* escaping with hex the UTF-8 stuff;
* assume the destination has enough room for escaping
*/
static int
strval2ADstr( struct berval *val, char *str, unsigned flags, ber_len_t *len )
{
ber_len_t s, d;
assert( val );
assert( str );
assert( len );
if ( val->bv_len == 0 ) {
*len = 0;
return( 0 );
}
if ( flags & LDAP_AVA_NONPRINTABLE ) {
/*
* FIXME: Turn the value into a binary encoded BER?
*/
*len = 0;
return( -1 );
} else {
/*
* we assume the string has enough room for the hex encoding
* of the value
*/
for ( s = 0, d = 0; s < val->bv_len; ) {
if ( LDAP_DN_NEEDESCAPE_AD( val->bv_val[ s ] ) ) {
str[ d++ ] = '\\';
}
str[ d++ ] = val->bv_val[ s++ ];
}
}
*len = d;
return( 0 );
}
/*
* If the DN is terminated by single-AVA RDNs with attribute type of "dc",
* the first part of the AD representation of the DN is written in DNS
* form, i.e. dot separated domain name components (as suggested
* by Luke Howard, http://www.padl.com/~lukeh)
*/
static int
dn2domain( LDAPDN *dn, struct berval *bv, int pos, int *iRDN )
{
int i;
int domain = 0, first = 1;
ber_len_t l = 1; /* we move the null also */
char *str;
/* we are guaranteed there's enough memory in str */
/* sanity */
assert( dn );
assert( bv );
assert( iRDN );
assert( *iRDN >= 0 );
str = bv->bv_val + pos;
for ( i = *iRDN; i >= 0; i-- ) {
LDAPRDN *rdn;
LDAPAVA *ava;
assert( dn[ 0 ][ i ] );
rdn = dn[ 0 ][ i ];
assert( rdn[ 0 ][ 0 ] );
ava = rdn[ 0 ][ 0 ];
if ( !LDAP_DN_IS_RDN_DC( rdn ) ) {
break;
}
domain = 1;
if ( first ) {
first = 0;
AC_MEMCPY( str, ava->la_value.bv_val,
ava->la_value.bv_len + 1);
l += ava->la_value.bv_len;
} else {
AC_MEMCPY( str + ava->la_value.bv_len + 1, bv->bv_val + pos, l);
AC_MEMCPY( str, ava->la_value.bv_val,
ava->la_value.bv_len );
str[ ava->la_value.bv_len ] = '.';
l += ava->la_value.bv_len + 1;
}
}
*iRDN = i;
bv->bv_len = pos + l - 1;
return( domain );
}
static int
rdn2strlen( LDAPRDN *rdn, unsigned flags, ber_len_t *len,
int ( *s2l )( struct berval *v, unsigned f, ber_len_t *l ) )
{
int iAVA;
ber_len_t l = 0;
*len = 0;
for ( iAVA = 0; rdn[ 0 ][ iAVA ]; iAVA++ ) {
LDAPAVA *ava = rdn[ 0 ][ iAVA ];
/* len(type) + '=' + '+' | ',' */
l += ava->la_attr.bv_len + 2;
if ( ava->la_flags & LDAP_AVA_BINARY ) {
/* octothorpe + twice the length */
l += 1 + 2 * ava->la_value.bv_len;
} else {
ber_len_t vl;
unsigned f = flags | ava->la_flags;
if ( ( *s2l )( &ava->la_value, f, &vl ) ) {
return( -1 );
}
l += vl;
}
}
*len = l;
return( 0 );
}
static int
rdn2str( LDAPRDN *rdn, char *str, unsigned flags, ber_len_t *len,
int ( *s2s ) ( struct berval *v, char * s, unsigned f, ber_len_t *l ) )
{
int iAVA;
ber_len_t l = 0;
for ( iAVA = 0; rdn[ 0 ][ iAVA ]; iAVA++ ) {
LDAPAVA *ava = rdn[ 0 ][ iAVA ];
AC_MEMCPY( &str[ l ], ava->la_attr.bv_val,
ava->la_attr.bv_len );
l += ava->la_attr.bv_len;
str[ l++ ] = '=';
if ( ava->la_flags & LDAP_AVA_BINARY ) {
str[ l++ ] = '#';
if ( binval2hexstr( &ava->la_value, &str[ l ] ) ) {
return( -1 );
}
l += 2 * ava->la_value.bv_len;
} else {
ber_len_t vl;
unsigned f = flags | ava->la_flags;
if ( ( *s2s )( &ava->la_value, &str[ l ], f, &vl ) ) {
return( -1 );
}
l += vl;
}
str[ l++ ] = ( rdn[ 0 ][ iAVA + 1 ] ? '+' : ',' );
}
*len = l;
return( 0 );
}
static int
rdn2DCEstrlen( LDAPRDN *rdn, unsigned flags, ber_len_t *len )
{
int iAVA;
ber_len_t l = 0;
*len = 0;
for ( iAVA = 0; rdn[ 0 ][ iAVA ]; iAVA++ ) {
LDAPAVA *ava = rdn[ 0 ][ iAVA ];
/* len(type) + '=' + ',' | '/' */
l += ava->la_attr.bv_len + 2;
switch ( ava->la_flags ) {
case LDAP_AVA_BINARY:
/* octothorpe + twice the length */
l += 1 + 2 * ava->la_value.bv_len;
break;
case LDAP_AVA_STRING: {
ber_len_t vl;
unsigned f = flags | ava->la_flags;
if ( strval2DCEstrlen( &ava->la_value, f, &vl ) ) {
return( -1 );
}
l += vl;
break;
}
default:
return( -1 );
}
}
*len = l;
return( 0 );
}
static int
rdn2DCEstr( LDAPRDN *rdn, char *str, unsigned flags, ber_len_t *len, int first )
{
int iAVA;
ber_len_t l = 0;
for ( iAVA = 0; rdn[ 0 ][ iAVA ]; iAVA++ ) {
LDAPAVA *ava = rdn[ 0 ][ iAVA ];
if ( first ) {
first = 0;
} else {
str[ l++ ] = ( iAVA ? ',' : '/' );
}
AC_MEMCPY( &str[ l ], ava->la_attr.bv_val,
ava->la_attr.bv_len );
l += ava->la_attr.bv_len;
str[ l++ ] = '=';
switch ( ava->la_flags ) {
case LDAP_AVA_BINARY:
str[ l++ ] = '#';
if ( binval2hexstr( &ava->la_value, &str[ l ] ) ) {
return( -1 );
}
l += 2 * ava->la_value.bv_len;
break;
case LDAP_AVA_STRING: {
ber_len_t vl;
unsigned f = flags | ava->la_flags;
if ( strval2DCEstr( &ava->la_value, &str[ l ], f, &vl ) ) {
return( -1 );
}
l += vl;
break;
}
default:
return( -1 );
}
}
*len = l;
return( 0 );
}
static int
rdn2UFNstrlen( LDAPRDN *rdn, unsigned flags, ber_len_t *len )
{
int iAVA;
ber_len_t l = 0;
assert( rdn );
assert( len );
*len = 0;
for ( iAVA = 0; rdn[ 0 ][ iAVA ]; iAVA++ ) {
LDAPAVA *ava = rdn[ 0 ][ iAVA ];
/* ' + ' | ', ' */
l += ( rdn[ 0 ][ iAVA + 1 ] ? 3 : 2 );
/* FIXME: are binary values allowed in UFN? */
if ( ava->la_flags & LDAP_AVA_BINARY ) {
/* octothorpe + twice the value */
l += 1 + 2 * ava->la_value.bv_len;
} else {
ber_len_t vl;
unsigned f = flags | ava->la_flags;
if ( strval2strlen( &ava->la_value, f, &vl ) ) {
return( -1 );
}
l += vl;
}
}
*len = l;
return( 0 );
}
static int
rdn2UFNstr( LDAPRDN *rdn, char *str, unsigned flags, ber_len_t *len )
{
int iAVA;
ber_len_t l = 0;
for ( iAVA = 0; rdn[ 0 ][ iAVA ]; iAVA++ ) {
LDAPAVA *ava = rdn[ 0 ][ iAVA ];
if ( ava->la_flags & LDAP_AVA_BINARY ) {
str[ l++ ] = '#';
if ( binval2hexstr( &ava->la_value, &str[ l ] ) ) {
return( -1 );
}
l += 2 * ava->la_value.bv_len;
} else {
ber_len_t vl;
unsigned f = flags | ava->la_flags;
if ( strval2str( &ava->la_value, &str[ l ], f, &vl ) ) {
return( -1 );
}
l += vl;
}
if ( rdn[ 0 ][ iAVA + 1 ]) {
AC_MEMCPY( &str[ l ], " + ", 3 );
l += 3;
} else {
AC_MEMCPY( &str[ l ], ", ", 2 );
l += 2;
}
}
*len = l;
return( 0 );
}
static int
rdn2ADstrlen( LDAPRDN *rdn, unsigned flags, ber_len_t *len )
{
int iAVA;
ber_len_t l = 0;
assert( rdn );
assert( len );
*len = 0;
for ( iAVA = 0; rdn[ 0 ][ iAVA ]; iAVA++ ) {
LDAPAVA *ava = rdn[ 0 ][ iAVA ];
/* ',' | '/' */
l++;
/* FIXME: are binary values allowed in UFN? */
switch ( ava->la_flags ) {
case LDAP_AVA_BINARY:
/* octothorpe + twice the value */
l += 1 + 2 * ava->la_value.bv_len;
break;
case LDAP_AVA_STRING: {
ber_len_t vl;
unsigned f = flags | ava->la_flags;
if ( strval2ADstrlen( &ava->la_value, f, &vl ) ) {
return( -1 );
}
l += vl;
break;
}
default:
return( -1 );
}
}
*len = l;
return( 0 );
}
static int
rdn2ADstr( LDAPRDN *rdn, char *str, unsigned flags, ber_len_t *len, int first )
{
int iAVA;
ber_len_t l = 0;
for ( iAVA = 0; rdn[ 0 ][ iAVA ]; iAVA++ ) {
LDAPAVA *ava = rdn[ 0 ][ iAVA ];
if ( first ) {
first = 0;
} else {
str[ l++ ] = ( iAVA ? ',' : '/' );
}
switch ( ava->la_flags ) {
case LDAP_AVA_BINARY:
str[ l++ ] = '#';
if ( binval2hexstr( &ava->la_value, &str[ l ] ) ) {
return( -1 );
}
l += 2 * ava->la_value.bv_len;
break;
case LDAP_AVA_STRING: {
ber_len_t vl;
unsigned f = flags | ava->la_flags;
if ( strval2ADstr( &ava->la_value, &str[ l ], f, &vl ) ) {
return( -1 );
}
l += vl;
break;
}
default:
return( -1 );
}
}
*len = l;
return( 0 );
}
/*
* ldap_rdn2str
*
* Returns in str a string representation of rdn based on flags.
* There is some duplication of code between this and ldap_dn2str;
* this is wanted to reduce the allocation of temporary buffers.
*/
int
ldap_rdn2str( LDAPRDN *rdn, char **str, unsigned flags )
{
struct berval bv;
int rc;
assert( str );
if((flags & LDAP_DN_FORMAT_MASK) == LDAP_DN_FORMAT_LBER) {
return LDAP_PARAM_ERROR;
}
rc = ldap_rdn2bv( rdn, &bv, flags );
*str = bv.bv_val;
return rc;
}
int
ldap_rdn2bv( LDAPRDN *rdn, struct berval *bv, unsigned flags )
{
int rc, back;
ber_len_t l;
assert( bv );
bv->bv_len = 0;
bv->bv_val = NULL;
if ( rdn == NULL ) {
bv->bv_val = LDAP_STRDUP( "" );
return( LDAP_SUCCESS );
}
/*
* This routine wastes "back" bytes at the end of the string
*/
switch ( LDAP_DN_FORMAT( flags ) ) {
case LDAP_DN_FORMAT_LDAPV3:
if ( rdn2strlen( rdn, flags, &l, strval2strlen ) ) {
return LDAP_DECODING_ERROR;
}
break;
case LDAP_DN_FORMAT_LDAPV2:
if ( rdn2strlen( rdn, flags, &l, strval2IA5strlen ) ) {
return LDAP_DECODING_ERROR;
}
break;
case LDAP_DN_FORMAT_UFN:
if ( rdn2UFNstrlen( rdn, flags, &l ) ) {
return LDAP_DECODING_ERROR;
}
break;
case LDAP_DN_FORMAT_DCE:
if ( rdn2DCEstrlen( rdn, flags, &l ) ) {
return LDAP_DECODING_ERROR;
}
break;
case LDAP_DN_FORMAT_AD_CANONICAL:
if ( rdn2ADstrlen( rdn, flags, &l ) ) {
return LDAP_DECODING_ERROR;
}
break;
default:
return LDAP_PARAM_ERROR;
}
bv->bv_val = LDAP_MALLOC( l + 1 );
switch ( LDAP_DN_FORMAT( flags ) ) {
case LDAP_DN_FORMAT_LDAPV3:
rc = rdn2str( rdn, bv->bv_val, flags, &l, strval2str );
back = 1;
break;
case LDAP_DN_FORMAT_LDAPV2:
rc = rdn2str( rdn, bv->bv_val, flags, &l, strval2IA5str );
back = 1;
break;
case LDAP_DN_FORMAT_UFN:
rc = rdn2UFNstr( rdn, bv->bv_val, flags, &l );
back = 2;
break;
case LDAP_DN_FORMAT_DCE:
rc = rdn2DCEstr( rdn, bv->bv_val, flags, &l, 1 );
back = 0;
break;
case LDAP_DN_FORMAT_AD_CANONICAL:
rc = rdn2ADstr( rdn, bv->bv_val, flags, &l, 1 );
back = 0;
break;
default:
/* need at least one of the previous */
return LDAP_PARAM_ERROR;
}
if ( rc ) {
ldap_memfree( bv->bv_val );
return rc;
}
bv->bv_len = l - back;
bv->bv_val[ bv->bv_len ] = '\0';
return LDAP_SUCCESS;
}
/*
* Very bulk implementation; many optimizations can be performed
* - a NULL dn results in an empty string ""
*
* FIXME: doubts
* a) what do we do if a UTF-8 string must be converted in LDAPv2?
* we must encode it in binary form ('#' + HEXPAIRs)
* b) does DCE/AD support UTF-8?
* no clue; don't think so.
* c) what do we do when binary values must be converted in UTF/DCE/AD?
* use binary encoded BER
*/
int ldap_dn2str( LDAPDN *dn, char **str, unsigned flags )
{
struct berval bv;
int rc;
assert( str );
if((flags & LDAP_DN_FORMAT_MASK) == LDAP_DN_FORMAT_LBER) {
return LDAP_PARAM_ERROR;
}
rc = ldap_dn2bv( dn, &bv, flags );
*str = bv.bv_val;
return rc;
}
int ldap_dn2bv( LDAPDN *dn, struct berval *bv, unsigned flags )
{
int iRDN;
int rc = LDAP_ENCODING_ERROR;
ber_len_t len, l;
/* stringifying helpers for LDAPv3/LDAPv2 */
int ( *sv2l ) ( struct berval *v, unsigned f, ber_len_t *l );
int ( *sv2s ) ( struct berval *v, char *s, unsigned f, ber_len_t *l );
assert( bv );
bv->bv_len = 0;
bv->bv_val = NULL;
#ifdef NEW_LOGGING
LDAP_LOG ( OPERATION, ARGS, "=> ldap_dn2bv(%u)\n%s%s",
flags, "", "" );
#else
Debug( LDAP_DEBUG_TRACE, "=> ldap_dn2bv(%u)\n%s%s", flags, "", "" );
#endif
/*
* a null dn means an empty dn string
* FIXME: better raise an error?
*/
if ( dn == NULL ) {
bv->bv_val = LDAP_STRDUP( "" );
return( LDAP_SUCCESS );
}
switch ( LDAP_DN_FORMAT( flags ) ) {
case LDAP_DN_FORMAT_LDAPV3:
sv2l = strval2strlen;
sv2s = strval2str;
if( 0 ) {
case LDAP_DN_FORMAT_LDAPV2:
sv2l = strval2IA5strlen;
sv2s = strval2IA5str;
}
for ( iRDN = 0, len = 0; dn[ 0 ][ iRDN ]; iRDN++ ) {
ber_len_t rdnl;
LDAPRDN *rdn = dn[ 0 ][ iRDN ];
if ( rdn2strlen( rdn, flags, &rdnl, sv2l ) ) {
goto return_results;
}
len += rdnl;
}
if ( ( bv->bv_val = LDAP_MALLOC( len + 1 ) ) == NULL ) {
rc = LDAP_NO_MEMORY;
break;
}
for ( l = 0, iRDN = 0; dn[ 0 ][ iRDN ]; iRDN++ ) {
ber_len_t rdnl;
LDAPRDN *rdn = dn[ 0 ][ iRDN ];
if ( rdn2str( rdn, &bv->bv_val[ l ], flags,
&rdnl, sv2s ) ) {
LDAP_FREE( bv->bv_val );
bv->bv_val = NULL;
goto return_results;
}
l += rdnl;
}
assert( l == len );
/*
* trim the last ',' (the allocated memory
* is one byte longer than required)
*/
bv->bv_len = len - 1;
bv->bv_val[ bv->bv_len ] = '\0';
rc = LDAP_SUCCESS;
break;
case LDAP_DN_FORMAT_UFN: {
/*
* FIXME: quoting from RFC 1781:
*
To take a distinguished name, and generate a name of this format with
attribute types omitted, the following steps are followed.
1. If the first attribute is of type CommonName, the type may be
omitted.
2. If the last attribute is of type Country, the type may be
omitted.
3. If the last attribute is of type Country, the last
Organisation attribute may have the type omitted.
4. All attributes of type OrganisationalUnit may have the type
omitted, unless they are after an Organisation attribute or
the first attribute is of type OrganisationalUnit.
* this should be the pedantic implementation.
*
* Here the standard implementation reflects
* the one historically provided by OpenLDAP
* (and UMIch, I presume), with the variant
* of spaces and plusses (' + ') separating
* rdn components.
*
* A non-standard but nice implementation could
* be to turn the final "dc" attributes into a
* dot-separated domain.
*
* Other improvements could involve the use of
* friendly country names and so.
*/
#ifdef DC_IN_UFN
int leftmost_dc = -1;
int last_iRDN = -1;
#endif /* DC_IN_UFN */
for ( iRDN = 0, len = 0; dn[ 0 ][ iRDN ]; iRDN++ ) {
ber_len_t rdnl;
LDAPRDN *rdn = dn[ 0 ][ iRDN ];
if ( rdn2UFNstrlen( rdn, flags, &rdnl ) ) {
goto return_results;
}
len += rdnl;
#ifdef DC_IN_UFN
if ( LDAP_DN_IS_RDN_DC( rdn ) ) {
if ( leftmost_dc == -1 ) {
leftmost_dc = iRDN;
}
} else {
leftmost_dc = -1;
}
#endif /* DC_IN_UFN */
}
if ( ( bv->bv_val = LDAP_MALLOC( len + 1 ) ) == NULL ) {
rc = LDAP_NO_MEMORY;
break;
}
#ifdef DC_IN_UFN
if ( leftmost_dc == -1 ) {
#endif /* DC_IN_UFN */
for ( l = 0, iRDN = 0; dn[ 0 ][ iRDN ]; iRDN++ ) {
ber_len_t vl;
LDAPRDN *rdn = dn[ 0 ][ iRDN ];
if ( rdn2UFNstr( rdn, &bv->bv_val[ l ],
flags, &vl ) ) {
LDAP_FREE( bv->bv_val );
bv->bv_val = NULL;
goto return_results;
}
l += vl;
}
/*
* trim the last ', ' (the allocated memory
* is two bytes longer than required)
*/
bv->bv_len = len - 2;
bv->bv_val[ bv->bv_len ] = '\0';
#ifdef DC_IN_UFN
} else {
last_iRDN = iRDN - 1;
for ( l = 0, iRDN = 0; iRDN < leftmost_dc; iRDN++ ) {
ber_len_t vl;
LDAPRDN *rdn = dn[ 0 ][ iRDN ];
if ( rdn2UFNstr( rdn, &bv->bv_val[ l ],
flags, &vl ) ) {
LDAP_FREE( bv->bv_val );
bv->bv_val = NULL;
goto return_results;
}
l += vl;
}
if ( !dn2domain( dn, bv, l, &last_iRDN ) ) {
LDAP_FREE( bv->bv_val );
bv->bv_val = NULL;
goto return_results;
}
/* the string is correctly terminated by dn2domain */
}
#endif /* DC_IN_UFN */
rc = LDAP_SUCCESS;
} break;
case LDAP_DN_FORMAT_DCE:
for ( iRDN = 0, len = 0; dn[ 0 ][ iRDN ]; iRDN++ ) {
ber_len_t rdnl;
LDAPRDN *rdn = dn[ 0 ][ iRDN ];
if ( rdn2DCEstrlen( rdn, flags, &rdnl ) ) {
goto return_results;
}
len += rdnl;
}
if ( ( bv->bv_val = LDAP_MALLOC( len + 1 ) ) == NULL ) {
rc = LDAP_NO_MEMORY;
break;
}
for ( l = 0; iRDN--; ) {
ber_len_t rdnl;
LDAPRDN *rdn = dn[ 0 ][ iRDN ];
if ( rdn2DCEstr( rdn, &bv->bv_val[ l ], flags,
&rdnl, 0 ) ) {
LDAP_FREE( bv->bv_val );
bv->bv_val = NULL;
goto return_results;
}
l += rdnl;
}
assert( l == len );
bv->bv_len = len;
bv->bv_val[ bv->bv_len ] = '\0';
rc = LDAP_SUCCESS;
break;
case LDAP_DN_FORMAT_AD_CANONICAL: {
/*
* Sort of UFN for DCE DNs: a slash ('/') separated
* global->local DN with no types; strictly speaking,
* the naming context should be a domain, which is
* written in DNS-style, e.g. dot-deparated.
*
* Example:
*
* "givenName=Bill+sn=Gates,ou=People,dc=microsoft,dc=com"
*
* will read
*
* "microsoft.com/People/Bill,Gates"
*/
for ( iRDN = 0, len = -1; dn[ 0 ][ iRDN ]; iRDN++ ) {
ber_len_t rdnl;
LDAPRDN *rdn = dn[ 0 ][ iRDN ];
if ( rdn2ADstrlen( rdn, flags, &rdnl ) ) {
goto return_results;
}
len += rdnl;
}
if ( ( bv->bv_val = LDAP_MALLOC( len + 1 ) ) == NULL ) {
rc = LDAP_NO_MEMORY;
break;
}
iRDN--;
if ( iRDN && dn2domain( dn, bv, 0, &iRDN ) ) {
for ( l = bv->bv_len; iRDN >= 0 ; iRDN-- ) {
ber_len_t rdnl;
LDAPRDN *rdn = dn[ 0 ][ iRDN ];
if ( rdn2ADstr( rdn, &bv->bv_val[ l ],
flags, &rdnl, 0 ) ) {
LDAP_FREE( bv->bv_val );
bv->bv_val = NULL;
goto return_results;
}
l += rdnl;
}
} else {
int first = 1;
/*
* Strictly speaking, AD canonical requires
* a DN to be in the form "..., dc=smtg",
* i.e. terminated by a domain component
*/
if ( flags & LDAP_DN_PEDANTIC ) {
LDAP_FREE( bv->bv_val );
bv->bv_val = NULL;
rc = LDAP_ENCODING_ERROR;
break;
}
for ( l = 0; iRDN >= 0 ; iRDN-- ) {
ber_len_t rdnl;
LDAPRDN *rdn = dn[ 0 ][ iRDN ];
if ( rdn2ADstr( rdn, &bv->bv_val[ l ],
flags, &rdnl, first ) ) {
LDAP_FREE( bv->bv_val );
bv->bv_val = NULL;
goto return_results;
}
if ( first ) {
first = 0;
}
l += rdnl;
}
}
bv->bv_len = len;
bv->bv_val[ bv->bv_len ] = '\0';
rc = LDAP_SUCCESS;
} break;
default:
return LDAP_PARAM_ERROR;
}
#ifdef NEW_LOGGING
LDAP_LOG ( OPERATION, RESULTS, "<= ldap_dn2bv(%s,%u)=%d\n",
bv->bv_val, flags, rc );
#else
Debug( LDAP_DEBUG_TRACE, "<= ldap_dn2bv(%s,%u)=%d\n",
bv->bv_val, flags, rc );
#endif
return_results:;
return( rc );
}
#ifdef HAVE_TLS
#include <openssl/x509.h>
#include <openssl/err.h>
/* Convert a structured DN from an X.509 certificate into an LDAPV3 DN.
* x509_name must be an (X509_NAME *). If func is non-NULL, the
* constructed DN will use numeric OIDs to identify attributeTypes,
* and the func() will be invoked to rewrite the DN with the given
* flags.
*
* Otherwise the DN will use shortNames as defined in the OpenSSL
* library.
*
* It's preferable to let slapd do the OID to attributeType mapping,
* because the OpenSSL tables are known to have many typos in versions
* up to (at least) 0.9.6c. However, the LDAP client has no schema tables,
* so we're forced to use OpenSSL's mapping there.
* -- Howard Chu 2002-04-18
*/
int
ldap_X509dn2bv( void *x509_name, struct berval *bv, LDAPDN_rewrite_func *func,
unsigned flags )
{
LDAPDN *newDN;
LDAPRDN *newRDN;
LDAPAVA *newAVA, *baseAVA;
X509_NAME_ENTRY *ne;
ASN1_OBJECT *obj;
ASN1_STRING *str;
char oids[8192], *oidptr = oids, *oidbuf = NULL;
void *ptrs[2048];
int i, j, k = 0, navas, nrdns, rc = LDAP_SUCCESS;
int set = -1;
size_t dnsize, oidrem = sizeof(oids), oidsize = 0;
int csize;
struct berval Val;
assert( bv );
bv->bv_len = 0;
bv->bv_val = NULL;
/* Get the number of AVAs. This is not necessarily the same as
* the number of RDNs.
*/
navas = X509_NAME_entry_count( x509_name );
/* Get the last element, to see how many RDNs there are */
ne = X509_NAME_get_entry( x509_name, navas - 1 );
nrdns = ne->set + 1;
/* Allocate the DN/RDN/AVA stuff as a single block */
dnsize = sizeof(LDAPDN) + sizeof(LDAPRDN *) * (nrdns+1);
dnsize += sizeof(LDAPRDN) * nrdns + sizeof(LDAPAVA *) * (navas+nrdns);
dnsize += sizeof(LDAPAVA) * navas;
if (dnsize > sizeof(ptrs)) {
newDN = (LDAPDN *)LDAP_MALLOC( dnsize );
if ( newDN == NULL )
return LDAP_NO_MEMORY;
} else {
newDN = (LDAPDN *)ptrs;
}
newDN[0] = (LDAPRDN**)(newDN+1);
newDN[0][nrdns] = NULL;
newRDN = (LDAPRDN*)(newDN[0] + nrdns+1);
newAVA = (LDAPAVA*)(newRDN + navas + nrdns*2);
baseAVA = newAVA;
/* Retrieve RDNs in reverse order; LDAP is backwards from X.500. */
for ( i = nrdns - 1, j = 0; i >= 0; i-- ) {
ne = X509_NAME_get_entry( x509_name, i );
obj = X509_NAME_ENTRY_get_object( ne );
str = X509_NAME_ENTRY_get_data( ne );
/* If set changed, move to next RDN */
if ( set != ne->set ) {
/* If this is not the first time, end the
* previous RDN and advance.
*/
if ( j > 0 ) {
newRDN[0][k] = NULL;
newRDN = (LDAPRDN*)(newRDN[0]+k+1);
}
newDN[0][j++] = newRDN;
newRDN[0] = (LDAPAVA**)(newRDN+1);
k = 0;
set = ne->set;
}
newAVA->la_private = NULL;
newAVA->la_flags = LDAP_AVA_STRING;
if ( !func ) {
int n = OBJ_obj2nid( obj );
if (n == NID_undef)
goto get_oid;
newAVA->la_attr.bv_val = (char *)OBJ_nid2sn( n );
newAVA->la_attr.bv_len = strlen( newAVA->la_attr.bv_val );
} else {
get_oid: newAVA->la_attr.bv_val = oidptr;
newAVA->la_attr.bv_len = OBJ_obj2txt( oidptr, oidrem, obj, 1 );
oidptr += newAVA->la_attr.bv_len + 1;
oidrem -= newAVA->la_attr.bv_len + 1;
/* Running out of OID buffer space? */
if (oidrem < 128) {
if ( oidsize == 0 ) {
oidsize = sizeof(oids) * 2;
oidrem = oidsize;
oidbuf = LDAP_MALLOC( oidsize );
if ( oidbuf == NULL ) goto nomem;
oidptr = oidbuf;
} else {
char *old = oidbuf;
oidbuf = LDAP_REALLOC( oidbuf, oidsize*2 );
if ( oidbuf == NULL ) goto nomem;
/* Buffer moved! Fix AVA pointers */
if ( old != oidbuf ) {
LDAPAVA *a;
long dif = oidbuf - old;
for (a=baseAVA; a<=newAVA; a++){
if (a->la_attr.bv_val >= old &&
a->la_attr.bv_val <= (old + oidsize))
a->la_attr.bv_val += dif;
}
}
oidptr = oidbuf + oidsize - oidrem;
oidrem += oidsize;
oidsize *= 2;
}
}
}
Val.bv_val = str->data;
Val.bv_len = str->length;
switch( str->type ) {
case V_ASN1_UNIVERSALSTRING:
/* This uses 32-bit ISO 10646-1 */
csize = 4; goto to_utf8;
case V_ASN1_BMPSTRING:
/* This uses 16-bit ISO 10646-1 */
csize = 2; goto to_utf8;
case V_ASN1_T61STRING:
/* This uses 8-bit, assume ISO 8859-1 */
csize = 1;
to_utf8: rc = ldap_ucs_to_utf8s( &Val, csize, &newAVA->la_value );
if (rc != LDAP_SUCCESS) goto nomem;
newAVA->la_flags = LDAP_AVA_NONPRINTABLE;
break;
case V_ASN1_UTF8STRING:
newAVA->la_flags = LDAP_AVA_NONPRINTABLE;
/* This is already in UTF-8 encoding */
case V_ASN1_IA5STRING:
case V_ASN1_PRINTABLESTRING:
/* These are always 7-bit strings */
ber_dupbv( &newAVA->la_value, &Val );
default:
;
}
newRDN[0][k] = newAVA;
newAVA++;
k++;
}
newRDN[0][k] = NULL;
if ( func ) {
rc = func( newDN, flags );
if ( rc != LDAP_SUCCESS )
goto nomem;
}
rc = ldap_dn2bv( newDN, bv, LDAP_DN_FORMAT_LDAPV3 );
nomem:
for (;baseAVA < newAVA; baseAVA++) {
LDAP_FREE( baseAVA->la_value.bv_val );
}
if ( oidsize != 0 )
LDAP_FREE( oidbuf );
if ( newDN != (LDAPDN*) ptrs )
LDAP_FREE( newDN );
return rc;
}
#endif /* HAVE_TLS */