ber_get_enum

a b c d e f g h i j k l m n o p q r s t u v w x y z _
LBER_DECODE(3)						       LBER_DECODE(3)



NAME
       ber_get_next,   ber_skip_tag,  ber_peek_tag,  ber_scanf,	 ber_get_int,
       ber_get_enum,  ber_get_stringb,	 ber_get_stringa,   ber_get_stringal,
       ber_get_stringbv,  ber_get_null,	 ber_get_boolean,  ber_get_bitstring,
       ber_first_element, ber_next_element - LBER simplified  Basic  Encoding
       Rules library routines for decoding

LIBRARY
       OpenLDAP LBER (liblber, -llber)

SYNOPSIS
       #include <lber.h>

       ber_tag_t ber_get_next(Sockbuf *sb, ber_len_t *len, BerElement *ber);

       ber_tag_t ber_skip_tag(BerElement *ber, ber_len_t *len);

       ber_tag_t ber_peek_tag(BerElement *ber, ber_len_t *len);

       ber_tag_t ber_scanf(BerElement *ber, const char *fmt, ...);

       ber_tag_t ber_get_int(BerElement *ber, ber_int_t *num);

       ber_tag_t ber_get_enum(BerElement *ber, ber_int_t *num);

       ber_tag_t ber_get_stringb(BerElement *ber, char *buf, ber_len_t *len);

       ber_tag_t ber_get_stringa(BerElement *ber, char **buf);

       ber_tag_t ber_get_stringal(BerElement *ber, struct berval **bv);

       ber_tag_t ber_get_stringbv(BerElement *ber,  struct  berval  *bv,  int
       alloc);

       ber_tag_t ber_get_null(BerElement *ber);

       ber_tag_t ber_get_boolean(BerElement *ber, ber_int_t *bool);

       ber_tag_t  ber_get_bitstringa(BerElement	 *ber,	char **buf, ber_len_t
       *blen);

       ber_tag_t  ber_first_element(BerElement	*ber,  ber_len_t  *len,	 char
       **cookie);

       ber_tag_t ber_next_element(BerElement *ber, ber_len_t *len, const char
       *cookie);

DESCRIPTION
       These routines provide a subroutine interface to a  simplified  imple-
       mentation  of  the  Basic Encoding Rules of ASN.1.  The version of BER
       these routines support is the one defined for the LDAP protocol.	  The
       encoding	 rules	are  the  same as BER, except that only definite form
       lengths are used, and bitstrings and octet strings are always  encoded
       in  primitive  form.  This man page describes the decoding routines in
       the lber library.  See lber-encode(3) for details on the corresponding
       encoding routines.  Consult lber-types(3) for information about types,
       allocators, and deallocators.

       Normally, the only routines that need to be called by  an  application
       are  ber_get_next()  to get the next BER element and ber_scanf() to do
       the actual decoding.  In some cases, ber_peek_tag() may also  need  to
       be  called in normal usage.  The other routines are provided for those
       applications that need more control  than  ber_scanf()  provides.   In
       general,	 these	routines  return  the  tag of the element decoded, or
       LBER_ERROR if an error occurred.

       The ber_get_next() routine is used to read the next BER	element	 from
       the  given  Sockbuf,  sb.   It strips off and returns the leading tag,
       strips off and returns the length of the entire element	in  len,  and
       sets  up	 ber  for subsequent calls to ber_scanf() et al to decode the
       element. See lber-sockbuf(3) for details of the Sockbuf implementation
       of the sb parameter.

       The  ber_scanf()	 routine  is used to decode a BER element in much the
       same way that scanf(3) works.  It reads	from  ber,  a  pointer	to  a
       BerElement  such	 as  returned by ber_get_next(), interprets the bytes
       according to the format string fmt, and	stores	the  results  in  its
       additional  arguments.  The format string contains conversion specifi-
       cations which are used to direct the interpretation of  the  BER	 ele-
       ment.  The format string can contain the following characters.


	      a	 Octet	string.	  A  char  **  should be supplied.  Memory is
		 allocated, filled with the contents  of  the  octet  string,
		 null-terminated,  and returned in the parameter.  The caller
		 should free the returned string using ber_memfree().

	      s	 Octet string.	A char * buffer should be supplied,  followed
		 by  a	pointer to a ber_len_t initialized to the size of the
		 buffer.  Upon return, the null-terminated  octet  string  is
		 put  into the buffer, and the ber_len_t is set to the actual
		 size of the octet string.

	      O	 Octet string.	A struct ber_val ** should be supplied, which
		 upon  return points to a dynamically allocated struct berval
		 containing the octet string  and  its	length.	  The  caller
		 should free the returned structure using ber_bvfree().

	      o	 Octet	string.	 A struct ber_val * should be supplied, which
		 upon return contains the dynamically allocated octet  string
		 and  its  length.  The caller should free the returned octet
		 string using ber_memfree().

	      m	 Octet string.	A struct ber_val * should be supplied,	which
		 upon  return  contains the octet string and its length.  The
		 string resides in memory assigned  to	the  BerElement,  and
		 must not be freed by the caller.

	      b	 Boolean.  A pointer to a ber_int_t should be supplied.

	      e	 Enumeration.  A pointer to a ber_int_t should be supplied.

	      i	 Integer.  A pointer to a ber_int_t should be supplied.

	      B	 Bitstring.  A char ** should be supplied which will point to
		 the dynamically allocated bits, followed by a	ber_len_t  *,
		 which	will  point  to the length (in bits) of the bitstring
		 returned.

	      n	 Null.	No parameter is	 required.   The  element  is  simply
		 skipped if it is recognized.

	      v	 Sequence  of  octet strings.  A char *** should be supplied,
		 which upon return points to a	dynamically  allocated	null-
		 terminated  array  of char *’s containing the octet strings.
		 NULL is returned if  the  sequence  is	 empty.	  The  caller
		 should	 free  the  returned  array  and  octet strings using
		 ber_memvfree().

	      V	 Sequence of octet strings with lengths.  A struct berval ***
		 should	 be  supplied,	which upon return points to a dynami-
		 cally allocated null-terminated array of struct  berval  *’s
		 containing  the  octet	 strings  and their lengths.  NULL is
		 returned if the sequence is empty.  The caller	 should	 free
		 the returned structures using ber_bvecfree().

	      W	 Sequence  of  octet  strings  with  lengths.	A BerVarray *
		 should be supplied, which upon return points  to  a  dynami-
		 cally	allocated  array  of  struct  berval’s containing the
		 octet strings and their lengths. The array is terminated  by
		 a  struct berval with a NULL bv_val string pointer.  NULL is
		 returned if the sequence is empty.  The caller	 should	 free
		 the returned structures using ber_bvarray_free().

	      M	 Sequence  of octet strings with lengths.  This is a general-
		 ized form of the previous three formats.  A  void  **	(ptr)
		 should	 be  supplied,	followed by a ber_len_t * (len) and a
		 ber_len_t (off).  Upon return (ptr) will point to a  dynami-
		 cally allocated array whose elements are all of size (*len).
		 A struct berval will be filled starting at offset  (off)  in
		 each  element.	  The strings in each struct berval reside in
		 memory assigned to the BerElement and must not be  freed  by
		 the caller.  The array is terminated by a struct berval with
		 a NULL bv_val string  pointer.	  NULL	is  returned  if  the
		 sequence  is  empty.  The number of elements in the array is
		 also stored in (*len) on return.  The caller should free the
		 returned array using ber_memfree().

	      l	 Length of the next element.  A pointer to a ber_len_t should
		 be supplied.

	      t	 Tag of the next element.  A pointer to a ber_tag_t should be
		 supplied.

	      T	 Skip  element	and return its tag.  A pointer to a ber_tag_t
		 should be supplied.

	      x	 Skip element.	The next element is skipped.

	      {	 Begin sequence.  No  parameter	 is  required.	 The  initial
		 sequence tag and length are skipped.

	      }	 End  sequence.	  No  parameter	 is required and no action is
		 taken.

	      [	 Begin set.  No parameter is required.	The initial  set  tag
		 and length are skipped.

	      ]	 End set.  No parameter is required and no action is taken.

       The  ber_get_int()  routine  tries to interpret the next element as an
       integer, returning the result in num.  The tag of whatever it finds is
       returned on success, LBER_ERROR (-1) on failure.

       The  ber_get_stringb()  routine is used to read an octet string into a
       preallocated buffer.  The len parameter should be initialized  to  the
       size  of	 the  buffer, and will contain the length of the octet string
       read upon return.  The buffer should be big enough to take  the	octet
       string value plus a terminating NULL byte.

       The  ber_get_stringa()  routine	is used to dynamically allocate space
       into which an octet string  is  read.   The  caller  should  free  the
       returned string using ber_memfree().

       The  ber_get_stringal()	routine is used to dynamically allocate space
       into which an octet string and its length are read.  It takes a struct
       berval  **,  and	 returns  the  result  in this parameter.  The caller
       should free the returned structure using ber_bvfree().

       The ber_get_stringbv() routine is used to read an octet string and its
       length  into  the  provided struct berval *. If the alloc parameter is
       zero, the string will reside in memory assigned to the BerElement, and
       must  not  be freed by the caller. If the alloc parameter is non-zero,
       the string will be  copied  into	 dynamically  allocated	 space	which
       should be returned using ber_memfree().

       The ber_get_null() routine is used to read a NULL element.  It returns
       the tag of the element it skips over.

       The ber_get_boolean() routine is used to read a boolean value.  It  is
       called the same way that ber_get_int() is called.

       The ber_get_enum() routine is used to read a enumeration value.	It is
       called the same way that ber_get_int() is called.

       The ber_get_bitstringa() routine is used to read	 a  bitstring  value.
       It  takes  a  char  ** which will hold the dynamically allocated bits,
       followed by an ber_len_t *, which will point to the length  (in	bits)
       of the bitstring returned.  The caller should free the returned string
       using ber_memfree().

       The ber_first_element() routine is used to return the tag  and  length
       of  the first element in a set or sequence.  It also returns in cookie
       a magic cookie parameter that should be passed to subsequent calls  to
       ber_next_element(), which returns similar information.

EXAMPLES
       Assume  the  variable  ber  contains a lightweight BER encoding of the
       following ASN.1 object:

	     AlmostASearchRequest := SEQUENCE {
		 baseObject	 DistinguishedName,
		 scope		 ENUMERATED {
		     baseObject	   (0),
		     singleLevel   (1),
		     wholeSubtree  (2)
		 },
		 derefAliases	 ENUMERATED {
		     neverDerefaliases	 (0),
		     derefInSearching	 (1),
		     derefFindingBaseObj (2),
		     alwaysDerefAliases	 (3)
		 },
		 sizelimit	 INTEGER (0 .. 65535),
		 timelimit	 INTEGER (0 .. 65535),
		 attrsOnly	 BOOLEAN,
		 attributes	 SEQUENCE OF AttributeType
	     }

       The element can be decoded using ber_scanf() as follows.

	     ber_int_t	  scope, deref, size, time, attrsonly;
	     char   *dn, **attrs;
	     ber_tag_t tag;

	     tag = ber_scanf( ber, "{aeeiib{v}}",
		 &dn, &scope, &deref,
		 &size, &time, &attrsonly, &attrs );

	     if( tag == LBER_ERROR ) {
		     /* error */
	     } else {
		     /* success */
	     }

	     ber_memfree( dn );
	     ber_memvfree( attrs );

ERRORS
       If an error occurs during decoding, generally  these  routines  return
       LBER_ERROR ((ber_tag_t)-1).


NOTES
       The  return  values  for	 all  of  these functions are declared in the
       <lber.h> header file.  Some routines may dynamically  allocate  memory
       which  must  be	freed  by the caller using supplied deallocation rou-
       tines.

SEE ALSO
       lber-encode(3), lber-memory(3), lber-sockbuf(3), lber-types(3)

ACKNOWLEDGEMENTS
       OpenLDAP	 is  developed	and  maintained	 by  The   OpenLDAP   Project
       (http://www.openldap.org/).   OpenLDAP  is  derived from University of
       Michigan LDAP 3.3 Release.



OpenLDAP 2.2.13			  2004/06/10		       LBER_DECODE(3)