1BER(3) User Contributed Perl Documentation BER(3)
2
6 Convert::BER - ASN.1 Basic Encoding Rules
7
9 use Convert::BER;
10 $ber = new Convert::BER;
12 $ber->encode(
14 INTEGER => 1,
15 SEQUENCE => [
16 BOOLEAN => 0,
17 STRING => "Hello",
18 ],
19 REAL => 3.7,
20 );
21 $ber->decode(
23 INTEGER => \$i,
24 SEQUENCE => [
25 BOOLEAN => \$b,
26 STRING => \$s,
27 ],
28 REAL => \$r,
29 );
30
32 WARNING this module is no longer supported, See Convert::ASN1
33 "Convert::BER" provides an OO interface to encoding and decoding data
35 using the ASN.1 Basic Encoding Rules (BER), a platform independent way
36 of encoding structured binary data together with the structure.
37
39 new
40 new ( BUFFER )
41 new ( opList )
42 "new" creates a new "Convert::BER" object.
43 encode ( opList )
45 Encode data in opList appending to the data in the buffer.
46 decode ( opList )
48 Decode the data in the buffer as described by opList, starting
49 where the last decode finished or position set by "pos".
50 buffer ( [ BUFFER ] )
52 Return the buffer contents. If BUFFER is specified set the buffer
53 contents and reset pos to zero.
54 pos ( [ POS ] )
56 Without any arguments "pos" returns the offset where the last
57 decode finished, or the last offset set by "pos". If POS is
58 specified then POS will be where the next decode starts.
59 tag ( )
61 Returns the tag at the current position in the buffer.
62 length ( )
64 Returns the length of the buffer.
65 error ( )
67 Returns the error message associated with the last method, if any.
68 This value is not automatically reset. If "encode" or "decode"
69 returns undef, check this.
70 dump ( [ FH ] )
72 Dump the buffer to the filehandle "FH", or STDERR if not specified.
73 The output contains the hex dump of each element, and an ASN.1-like
74 text representation of that element.
75 hexdump ( [ FH ] )
77 Dump the buffer to the filehandle "FH", or STDERR if not specified.
78 The output is hex with the possibly-printable text alongside.
79
81 read ( IO )
82 write ( IO )
83 recv ( SOCK )
84 send ( SOCK [, ADDR ] )
85
87 An opList is a list of operator-value pairs. An operator can be any of
88 those defined below, or any defined by sub-classing "Convert::BER",
89 which will probably be derived from the primitives given here.
90 The values depend on whether BER is being encoded or decoded:
92 Encoding
94 If the value is a scalar, just encode it. If the value is a
95 reference to a list, then encode each item in the list in turn. If
96 the value is a code reference, then execute the code. If the
97 returned value is a scalar, encode that value. If the returned
98 value is a reference to a list, encode each item in the list in
99 turn.
100 Decoding
102 If the value is a reference to a scalar, decode the value into the
103 scalar. If the value is a reference to a list, then decode all the
104 items of this type into the list. Note that there must be at least
105 one item to decode, otherwise the decode will fail. If the value is
106 a code reference, then execute the code and decode the value into
107 the reference returned from the evaluated code.
108
110 These operators encode and decode the basic primitive types defined by
111 BER.
112 BOOLEAN
114 A BOOLEAN value is either true or false.
115 Encoding
117 The value is tested for boolean truth, and encoded appropriately.
118 # Encode a TRUE value
120 $ber->encode(
121 BOOLEAN => 1,
122 ) or die;
123 Decoding
125 The decoded values will be either 1 or 0.
126 # Decode a boolean value into $bval
128 $ber->decode(
129 BOOLEAN => \$bval,
130 ) or die;
131 INTEGER
133 An INTEGER value is either a positive whole number, or a negative whole
134 number, or zero. Numbers can either be native perl integers, or values
135 of the "Math::BigInt" class.
136 Encoding
138 The value is the integer value to be encoded.
139 $ber->encode(
141 INTEGER => -123456,
142 ) or die;
143 Decoding
145 The value will be the decoded integer value.
146 $ber->decode(
148 INTEGER => \$ival,
149 ) or die;
150 STRING
152 This is an OCTET STRING, which is an arbitrarily long binary value.
153 Encoding
155 The value contains the binary value to be encoded.
156 $ber->encode(
158 STRING => "\xC0First character is hex C0",
159 ) or die;
160 Decoding
162 The value will be the binary bytes.
163 $ber->decode(
165 STRING => \$sval,
166 ) or die;
167 NULL
169 There is no value for NULL. You often use NULL in ASN.1 when you want
170 to denote that something else is absent rather than just not encoding
171 the 'something else'.
172 Encoding
174 The values are ignored, but must be present.
175 $ber->encode(
177 NULL => undef,
178 ) or die;
179 Decoding
181 Dummy values are stored in the returned values, as though they were
182 present in the encoding.
183 $ber->decode(
185 NULL => \$nval,
186 ) or die;
187 OBJECT_ID
189 An OBJECT_ID value is an OBJECT IDENTIFIER (also called an OID). This
190 is a hierarchically structured value that is used in protocols to
191 uniquely identify something. For example, SNMP (the Simple Network
192 Management Protocol) uses OIDs to denote the information being
193 requested, and LDAP (the Lightweight Directory Access Protocol, RFC
194 2251) uses OIDs to denote each attribute in a directory entry.
195 Each level of the OID hierarchy is either zero or a positive integer.
197 Encoding
199 The value should be a dotted-decimal representation of the OID.
200 $ber->encode(
202 OBJECT_ID => '2.5.4.0', # LDAP objectClass
203 ) or die;
204 Decoding
206 The value will be the dotted-decimal representation of the OID.
207 $ber->decode(
209 OBJECT_ID => \$oval,
210 ) or die;
211 ENUM
213 The ENUMERATED type is effectively the same as the INTEGER type. It
214 exists so that friendly names can be assigned to certain integer
215 values. To be useful, you should sub-class this operator.
216 BIT_STRING
218 The BIT STRING type is an arbitrarily long string of bits - 0's and
219 1's.
220 Encoding
222 The value is a string of arbitrary 0 and 1 characters. As these are
223 packed into 8-bit octets when encoding and there may not be a
224 multiple of 8 bits to be encoded, trailing padding bits are added
225 in the encoding.
226 $ber->encode(
228 BIT_STRING => '0011',
229 ) or die;
230 Decoding
232 The value will be a string of 0 and 1 characters. The string will
233 have the same number of bits as were encoded (the padding bits are
234 ignored.)
235 $ber->decode(
237 BIT_STRING => \$bval,
238 ) or die;
239 BIT_STRING8
241 This is a variation of the BIT_STRING operator, which is optimized for
242 writing bit strings which are multiples of 8-bits in length. You can
243 use the BIT_STRING operator to decode BER encoded with the BIT_STRING8
244 operator (and vice-versa.)
245 Encoding
247 The value should be the packed bits to encode, not a string of 0
248 and 1 characters.
249 $ber->encode(
251 BIT_STRING8 => pack('B8', '10110101'),
252 ) or die;
253 Decoding
255 The value will be the decoded packed bits.
256 $ber->decode(
258 BIT_STRING8 => \$bval,
259 ) or die;
260 REAL
262 The REAL type encodes an floating-point number. It requires the POSIX
263 module.
264 Encoding
266 The value should be the number to encode.
267 $ber->encode(
269 REAL => 3.14159265358979,
270 ) or die;
271 Decoding
273 The value will be the decoded floating-point value.
274 $ber->decode(
276 REAL => \$rval,
277 );
278 ObjectDescriptor
280 The ObjectDescriptor type encodes an ObjectDescriptor string. It is a
281 sub-class of "STRING".
282 UTF8String
284 The UTF8String type encodes a string encoded in UTF-8. It is a sub-
285 class of "STRING".
286 NumericString
288 The NumericString type encodes a NumericString, which is defined to
289 only contain the characters 0-9 and space. It is a sub-class of
290 "STRING".
291 PrintableString
293 The PrintableString type encodes a PrintableString, which is defined to
294 only contain the characters A-Z, a-z, 0-9, space, and the punctuation
295 characters ()-+=:',./?. It is a sub-class of "STRING".
296 TeletexString/T61String
298 The TeletexString type encodes a TeletexString, which is a string
299 containing characters according to the T.61 character set. Each T.61
300 character may be one or more bytes wide. It is a sub-class of "STRING".
301 T61String is an alternative name for TeletexString.
303 VideotexString
305 The VideotexString type encodes a VideotexString, which is a string. It
306 is a sub-class of "STRING".
307 IA5String
309 The IA5String type encodes an IA5String. IA5 (International Alphabet 5)
310 is equivalent to US-ASCII. It is a sub-class of "STRING".
311 UTCTime
313 The UTCTime type encodes a UTCTime value. Note this value only
314 represents years using two digits, so it is not recommended in
315 Y2K-compliant applications. It is a sub-class of "STRING".
316 UTCTime values must be strings like:
318 yymmddHHMM[SS]Z
320 or:
321 yymmddHHMM[SS]sHHMM
322 Where yy is the year, mm is the month (01-12), dd is the day (01-31),
324 HH is the hour (00-23), MM is the minutes (00-60). SS is the optional
325 seconds (00-61).
326 The time is either terminated by the literal character Z, or a timezone
328 offset. The "Z" character indicates Zulu time or UTC. The timezone
329 offset specifies the sign s, which is + or -, and the difference in
330 hours and minutes.
331 GeneralizedTime
333 The GeneralizedTime type encodes a GeneralizedTime value. Unlike
334 "UTCTime" it represents years using 4 digits, so is Y2K-compliant. It
335 is a sub-class of "STRING".
336 GeneralizedTime values must be strings like:
338 yyyymmddHHMM[SS][.U][Z]
340 or:
341 yyyymmddHHMM[SS][.U]sHHMM
342 Where yyyy is the year, mm is the month (01-12), dd is the day (01-31),
344 HH is the hour (00-23), MM is the minutes (00-60). SS is the optional
345 seconds (00-61). U is the optional fractional seconds value; a comma is
346 permitted instead of a dot before this value.
347 The time may be terminated by the literal character Z, or a timezone
349 offset. The "Z" character indicates Zulu time or UTC. The timezone
350 offset specifies the sign s, which is + or -, and the difference in
351 hours and minutes. If there is timezone specified UTC is assumed.
352 GraphicString
354 The GraphicString type encodes a GraphicString value. It is a sub-class
355 of "STRING".
356 VisibleString/ISO646String
358 The VisibleString type encodes a VisibleString value, which is a value
359 using the ISO646 character set. It is a sub-class of "STRING".
360 ISO646String is an alternative name for VisibleString.
362 GeneralString
364 The GeneralString type encodes a GeneralString value. It is a sub-class
365 of "STRING".
366 UniversalString/CharacterString
368 The UniveralString type encodes a UniveralString value, which is a
369 value using the ISO10646 character set. Each character in ISO10646 is
370 4-bytes wide. It is a sub-class of "STRING".
371 CharacterString is an alternative name for UniversalString.
373 BMPString
375 The BMPString type encodes a BMPString value, which is a value using
376 the Unicode character set. Each character in the Unicode character set
377 is 2-bytes wide. It is a sub-class of "STRING".
378
380 These operators are used to build constructed types, which contain
381 values in different types, like a C structure.
382 SEQUENCE
384 A SEQUENCE is a complex type that contains other types, a bit like a C
385 structure. Elements inside a SEQUENCE are encoded and decoded in the
386 order given.
387 Encoding
389 The value should be a reference to an array containing another
390 opList which defines the elements inside the SEQUENCE.
391 $ber->encode(
393 SEQUENCE => [
394 INTEGER => 123,
395 BOOLEAN => [ 1, 0 ],
396 ]
397 ) or die;
398 Decoding
400 The value should a reference to an array that contains the opList
401 which decodes the contents of the SEQUENCE.
402 $ber->decode(
404 SEQUENCE => [
405 INTEGER => \$ival,
406 BOOLEAN => \@bvals,
407 ]
408 ) or die;
409 SET
411 A SET is an complex type that contains other types, rather like a
412 SEQUENCE. Elements inside a SET may be present in any order.
413 Encoding
415 The value is the same as for the SEQUENCE operator.
416 $ber->encode(
418 SET => [
419 INTEGER => 13,
420 STRING => 'Hello',
421 ]
422 ) or die;
423 Decoding
425 The value should be a reference to an equivalent opList to that
426 used to encode the SET. The ordering of the opList should not
427 matter.
428 $ber->decode(
430 SET => [
431 STRING => \$sval,
432 INTEGER => \$ival,
433 ]
434 ) or die;
435 SEQUENCE_OF
437 A SEQUENCE_OF is an ordered list of other types.
438 Encoding
440 The value is a ref followed by an opList. The ref must be a
441 reference to a list or a hash: if it is to a list, then the opList
442 will be repeated once for every element in the list. If it is to a
443 hash, then the opList will be repeated once for every key in the
444 hash (note that ordering of keys in a hash is not guaranteed by
445 perl.)
446 The remaining opList will then usually contain values which are
448 code references. If the ref is to a list, then the contents of that
449 item in the list are passed as the only argument to the code
450 reference. If the ref is to a hash, then only the key is passed to
451 the code.
452 @vals = ( [ 10, 'Foo' ], [ 20, 'Bar' ] ); # List of refs to lists
454 $ber->encode(
455 SEQUENCE_OF => [ \@vals,
456 SEQUENCE => [
457 INTEGER => sub { $_[0][0] }, # Passed a ref to the inner list
458 STRING => sub { $_[0][1] }, # Passed a ref to the inner list
459 ]
460 ]
461 ) or die;
462 %hash = ( 40 => 'Baz', 30 => 'Bletch' ); # Just a hash
463 $ber->decode(
464 SEQUENCE_OF => [ \%hash,
465 SEQUENCE => [
466 INTEGER => sub { $_[0] }, # Passed the key
467 STRING => sub { $hash{$_[0]} }, # Passed the key
468 ]
469 ]
470 );
471 Decoding
473 The value must be a reference to a list containing a ref and an
474 opList. The ref must always be a reference to a scalar. Each value
475 in the <opList> is usually a code reference. The code referenced is
476 called with the value of the ref (dereferenced); the value of the
477 ref is incremented for each item in the SEQUENCE_OF.
478 $ber->decode(
480 SEQUENCE_OF => [ \$count,
481 # In the following subs, make space at the end of an array, and
482 # return a reference to that newly created space.
483 SEQUENCE => [
484 INTEGER => sub { $ival[$_[0]] = undef; \$ival[-1] },
485 STRING => sub { $sval[$_[0]] = undef; \$sval[-1] },
486 ]
487 ]
488 ) or die;
489 SET_OF
491 A SET_OF is an unordered list. This is treated in an identical way to a
492 SEQUENCE_OF, except that no ordering should be inferred from the list
493 passed or returned.
494
496 BER
497 It is sometimes useful to construct or deconstruct BER encodings in
498 several pieces. The BER operator lets you do this.
499 Encoding
501 The value should be another "Convert::BER" object, which will be
502 inserted into the buffer. If value is undefined then nothing is
503 added.
504 $tmp->encode(
506 SEQUENCE => [
507 INTEGER => 20,
508 STRING => 'Foo',
509 ]
510 );
511 $ber->encode(
512 BER => $tmp,
513 BOOLEAN => 1
514 );
515 Decoding
517 value should be a reference to a scalar, which will contain a
518 "Convert::BER" object. This object will contain the remainder of
519 the current sequence or set being decoded.
520 # After this, ber2 will contain the encoded INTEGER B<and> STRING.
522 # sval will be ignored and left undefined, but bval will be decoded. The
523 # decode of ber2 will return the integer and string values.
524 $ber->decode(
525 SEQUENCE => [
526 BER => \$ber2,
527 STRING => \$sval,
528 ],
529 BOOLEAN => \$bval,
530 );
531 $ber2->decode(
532 INTEGER => \$ival,
533 STRING => \$sval2,
534 );
535 ANY
537 This is like the "BER" operator except that when decoding only the next
538 item is decoded and placed into the "Convert::BER" object returned.
539 There is no difference when encoding.
540 Decoding
542 value should be a reference to a scalar, which will contain a
543 "Convert::BER" object. This object will only contain the next
544 single item in the current sequence being decoded.
545 # After this, ber2 will decode further, and ival and sval
547 # will be decoded.
548 $ber->decode(
549 INTEGER = \$ival,
550 ANY => \$ber2,
551 STRING => \$sval,
552 );
553 OPTIONAL
555 This operator allows you to specify that an element is absent from the
556 encoding.
557 Encoding
559 The value should be a reference to another list with another
560 opList. If all of the values of the inner opList are defined, the
561 entire OPTIONAL value will be encoded, otherwise it will be
562 omitted.
563 $ber->encode(
565 SEQUENCE => [
566 INTEGER => 16, # Will be encoded
567 OPTIONAL => [
568 INTEGER => undef, # Will not be encoded
569 ],
570 STRING => 'Foo', # Will be encoded
571 ]
572 );
573 Decoding
575 The contents of value are decoded if possible, if not then decode
576 continues at the next operator-value pair.
577 $ber->decode(
579 SEQUENCE => [
580 INTEGER => \$ival1,
581 OPTIONAL => [
582 INTEGER => \$ival2,
583 ],
584 STRING => \$sval,
585 ]
586 );
587 CHOICE
589 The opList is a list of alternate operator-value pairs. Only one will
590 be encoded, and only one will be decoded.
591 Encoding
593 A scalar at the start of the opList identifies which opList
594 alternative to use for encoding the value. A value of 0 means the
595 first one is used, 1 means the second one, etc.
596 # Encode the BMPString alternate of the CHOICE
598 $ber->encode(
599 CHOICE => [ 2,
600 PrintableString => 'Printable',
601 TeletexString => 'Teletex/T61',
602 BMPString => 'BMP/Unicode',
603 UniversalString => 'Universal/ISO10646',
604 ]
605 ) or die;
606 Decoding
608 A reference to a scalar at the start of the opList is used to store
609 which alternative is decoded (0 for the first one, 1 for the second
610 one, etc.) Pass undef instead of the ref if you don't care about
611 this, or you store all the alternate values in different variables.
612 # Decode the above.
614 # Afterwards, $alt will be set to 2, $str will be set to 'BMP/Unicode'.
615 $ber->decode(
616 CHOICE => [ \$alt,
617 PrintableString => \$str,
618 TeletexString => \$str,
619 BMPString => \$str,
620 UniversalString => \$str,
621 ]
622 ) or die;
623
625 In BER everything being encoded has a tag, a length, and a value.
626 Normally the tag is derived from the operator - so INTEGER has a
627 different tag from a BOOLEAN, for instance.
628 In some applications it is necessary to change the tags used. For
630 example, a SET may need to contain two different INTEGER values. Tags
631 may be changed in two ways, either IMPLICITly or EXPLICITly. With
632 IMPLICIT tagging, the new tag completely replaces the old tag. With
633 EXPLICIT tagging, the new tag is used as well as the old tag.
634 "Convert::BER" supports two ways of using IMPLICIT tagging. One method
636 is to sub-class "Convert::BER", which is described in the next section.
637 For small applications or those that think sub-classing is just too
638 much then the operator may be passed an arrayref. The array must
639 contain two elements, the first is the usual operator name and the
640 second is the tag value to use, as shown below.
641 $ber->encode(
643 [ SEQUENCE => 0x34 ] => [
644 INTEGER => 10,
645 STRING => "A"
646 ]
647 ) or die;
648 This will encode a sequence, with a tag value of 0x34, which will
650 contain and integer and a string which will have their default tag
651 values.
652 You may wish to construct your tags using some pre-defined functions
654 such as &Convert::BER::BER_APPLICATION, &Convert::BER::BER_CONTEXT,
655 etc, instead of calculating the tag values yourself.
656 To use EXPLICIT tagging, enclose the original element in a SEQUENCE,
658 and just override the SEQUENCE's tag as above. Don't forget to set the
659 constructed bit using &Convert::BER::BER_CONSTRUCTOR. For example, the
660 ASN.1 definition:
661 Foo ::= SEQUENCE {
663 [0] EXPLICIT INTEGER,
664 INTEGER
665 }
666 might be encoded using this:
668 $ber->encode(
670 SEQUENCE => [
671 [ SEQUENCE => &Convert::BER::BER_CONTEXT |
672 &Convert::BER::BER_CONSTRUCTOR | 0 ] => [
673 INTEGER => 10,
674 ],
675 INTEGER => 11,
676 ],
677 ) or die;
678
680 For large applications where operators with non default tags are used a
681 lot the above mechanism can be very error-prone. For this reason,
682 "Convert::BER" may be sub-classed.
683 To do this the sub-class must call a static method "define". The
685 arguments to "define" is a list of arrayrefs. Each arrayref will define
686 one new operator. Each arrayref contains three values, the first is the
687 name of the operator, the second is how the data is encoded and the
688 third is the tag value. To aid with the creation of these arguments
689 "Convert::BER" exports some variables and constant subroutines.
690 For each operator defined by "Convert::BER", or a "Convert::BER" sub-
692 class, a scalar variable with the same name is available for import,
693 for example $INTEGER is available from "Convert::BER". And any
694 operators defined by a new sub-class will be available for import from
695 that class. One of these variables may be used as the second element
696 of each arrayref.
697 "Convert::BER" also exports some constant subroutines that can be used
699 to create the tag value. The subroutines exported are:
700 BER_BOOLEAN
702 BER_INTEGER
703 BER_BIT_STR
704 BER_OCTET_STR
705 BER_NULL
706 BER_OBJECT_ID
707 BER_SEQUENCE
708 BER_SET
709 BER_UNIVERSAL
711 BER_APPLICATION
712 BER_CONTEXT
713 BER_PRIVATE
714 BER_PRIMITIVE
715 BER_CONSTRUCTOR
716 "Convert::BER" also provides a subroutine called "ber_tag" to calculate
718 an integer value that will be used to represent a tag. For tags with
719 values less than 30 this is not needed, but for tags >= 30 then tag
720 value passed for an operator definition must be the result of "ber_tag"
721 "ber_tag" takes two arguments, the first is the tag class and the
723 second is the tag value.
724 Using this information a sub-class of Convert::BER can be created as
726 shown below.
727 package Net::LDAP::BER;
729 use Convert::BER qw(/^(\$|BER_)/);
731 use strict;
733 use vars qw($VERSION @ISA);
734 @ISA = qw(Convert::BER);
736 $VERSION = "1.00";
737 Net::LDAP::BER->define(
739 # Name Type Tag
741 ########################################
742 [ REQ_UNBIND => $NULL,
744 BER_APPLICATION | 0x02 ],
745 [ REQ_COMPARE => $SEQUENCE,
747 BER_APPLICATION | BER_CONSTRUCTOR | 0x0E ],
748 [ REQ_ABANDON => $INTEGER,
750 ber_tag(BER_APPLICATION, 0x10) ],
751 );
752 This will create a new class "Net::LDAP::BER" which has three new
754 operators available. This class then may be used as follows
755 $ber = new Net::LDAP::BER;
757 $ber->encode(
759 REQ_UNBIND => 0,
760 REQ_COMPARE => [
761 REQ_ABANDON => 123,
762 ]
763 );
764 $ber->decode(
766 REQ_UNBIND => \$var,
767 REQ_COMPARE => [
768 REQ_ABANDON => \$num,
769 ]
770 );
771 Which will encode or decode the data using the formats and tags defined
773 in the "Net::LDAP::BER" sub-class. It also helps to make the code more
774 readable.
775 DEFINING NEW PACKING OPERATORS
777 As well as defining new operators which inherit from existing operators
778 it is also possible to define a new operator and how data is encoded
779 and decoded. The interface for doing this is still changing but will be
780 documented here when it is done. To be continued ...
781
783 Convert::BER cannot support tags that contain more bits than can be
784 stored in a scalar variable, typically this is 32 bits.
785 Convert::BER cannot support items that have a packed length which
787 cannot be stored in 32 bits.
788
790 The "SET" decode method fails if the encoded order is different to the
791 opList order.
792
794 Graham Barr <gbarr@pobox.com>
795 Significant POD updates from Chris Ridd
797 <Chris.Ridd@messagingdirect.com>
798
800 Copyright (c) 1995-2000 Graham Barr. All rights reserved. This program
801 is free software; you can redistribute it and/or modify it under the
802 same terms as Perl itself.
803
805 Hey! The above document had some coding errors, which are explained
806 below:
807 Around line 366:
809 You forgot a '=back' before '=head2'
810perl v5.34.0 2021-07-22 BER(3)