File Coverage

blib/lib/Convert/BER/XS.pm

Criterion	Covered	Total	%
statement	29	60	48.3
branch	16	38	42.1
condition	0	14	0.0
subroutine	7	10	70.0
pod	1	1	100.0
total	53	123	43.0

line	stmt	bran	cond	sub	pod	time	code
1							=head1 NAME
2
3							Convert::BER::XS - I low level BER en-/decoding
4
5							=head1 SYNOPSIS
6
7							use Convert::BER::XS ':all';
8
9							my $ber = ber_decode $buf, $Convert::BER::XS::SNMP_PROFILE
10							or die "unable to decode SNMP message";
11
12							# The above results in a data structure consisting of
13							# (class, tag, flags, data)
14							# tuples. Below is such a message, SNMPv1 trap
15							# with a Cisco mac change notification.
16							# Did you know that Cisco is in the news almost
17							# every week because of some backdoor password
18							# or other extremely stupid security bug?
19
20							[ ASN_UNIVERSAL, ASN_SEQUENCE, 1,
21							[
22							[ ASN_UNIVERSAL, ASN_INTEGER, 0, 0 ], # snmp version 1
23							[ ASN_UNIVERSAL, 4, 0, "public" ], # community
24							[ ASN_CONTEXT, 4, 1, # CHOICE, constructed - trap PDU
25							[
26							[ ASN_UNIVERSAL, ASN_OBJECT_IDENTIFIER, 0, "1.3.6.1.4.1.9.9.215.2" ], # enterprise oid
27							[ ASN_APPLICATION, SNMP_IPADDRESS, 0, "10.0.0.1" ], # SNMP IpAddress
28							[ ASN_UNIVERSAL, ASN_INTEGER, 0, 6 ], # generic trap
29							[ ASN_UNIVERSAL, ASN_INTEGER, 0, 1 ], # specific trap
30							[ ASN_APPLICATION, SNMP_TIMETICKS, 0, 1817903850 ], # SNMP TimeTicks
31							[ ASN_UNIVERSAL, ASN_SEQUENCE, 1, # the varbindlist
32							[
33							[ ASN_UNIVERSAL, ASN_SEQUENCE, 1, # a single varbind, "key value" pair
34							[
35							[ ASN_UNIVERSAL, ASN_OBJECT_IDENTIFIER, 0, "1.3.6.1.4.1.9.9.215.1.1.8.1.2.1" ],
36							[ ASN_UNIVERSAL, ASN_OCTET_STRING, 0, "...data..." # the value
37							]
38							]
39							],
40							...
41							# let's dump it, for debugging
42
43							ber_dump $ber, $Convert::BER::XS::SNMP_PROFILE;
44
45							# let's decode it a bit with some helper functions
46
47							my $msg = ber_is_seq $ber
48							or die "SNMP message does not start with a sequence";
49
50							ber_is $msg->[0], ASN_UNIVERSAL, ASN_INTEGER, 0
51							or die "SNMP message does not start with snmp version\n";
52
53							# message is SNMP v1 or v2c?
54							if ($msg->[0][BER_DATA] == 0 \|\| $msg->[0][BER_DATA] == 1) {
55
56							# message is v1 trap?
57							if (ber_is $msg->[2], ASN_CONTEXT, 4, 1) {
58							my $trap = $msg->[2][BER_DATA];
59
60							# check whether trap is a cisco mac notification mac changed message
61							if (
62							(ber_is_oid $trap->[0], "1.3.6.1.4.1.9.9.215.2") # cmnInterfaceObjects
63							and (ber_is_int $trap->[2], 6)
64							and (ber_is_int $trap->[3], 1) # mac changed msg
65							) {
66							... and so on
67
68							# finally, let's encode it again and hope it results in the same bit pattern
69
70							my $buf = ber_encode $ber, $Convert::BER::XS::SNMP_PROFILE;
71
72							=head1 DESCRIPTION
73
74							WARNING: Before release 1.0, the API is not considered stable in any way.
75
76							This module implements a I low level BER/DER en-/decoder.
77
78							It is tuned for low memory and high speed, while still maintaining some
79							level of user-friendlyness.
80
81							=head2 EXPORT TAGS AND CONSTANTS
82
83							By default this module doesn't export any symbols, but if you don't want
84							to break your keyboard, editor or eyesight with extremely long names, I
85							recommend importing the C<:all> tag. Still, you can selectively import
86							things.
87
88							=over
89
90							=item C<:all>
91
92							All of the below. Really. Recommended for at least first steps, or if you
93							don't care about a few kilobytes of wasted memory (and namespace).
94
95							=item C<:const>
96
97							All of the strictly ASN.1-related constants defined by this module, the
98							same as C<:const_asn :const_index>. Notably, this does not contain
99							C<:const_ber_type> and C<:const_snmp>.
100
101							A good set to get everything you need to decode and match BER data would be
102							C<:decode :const>.
103
104							=item C<:const_index>
105
106							The BER tuple array index constants:
107
108							BER_CLASS BER_TAG BER_FLAGS BER_DATA
109
110							=item C<:const_asn>
111
112							ASN class values (these are C<0>, C<1>, C<2> and C<3>, respectively -
113							exactly the two topmost bits from the identifier octet shifted 6 bits to
114							the right):
115
116							ASN_UNIVERSAL ASN_APPLICATION ASN_CONTEXT ASN_PRIVATE
117
118							ASN tag values (some of which are aliases, such as C). Their
119							numerical value corresponds exactly to the numbers used in BER/X.690.
120
121							ASN_BOOLEAN ASN_INTEGER ASN_BIT_STRING ASN_OCTET_STRING ASN_NULL ASN_OID
122							ASN_OBJECT_IDENTIFIER ASN_OBJECT_DESCRIPTOR ASN_EXTERNAL ASN_REAL ASN_SEQUENCE ASN_ENUMERATED
123							ASN_EMBEDDED_PDV ASN_UTF8_STRING ASN_RELATIVE_OID ASN_SET ASN_NUMERIC_STRING
124							ASN_PRINTABLE_STRING ASN_TELETEX_STRING ASN_T61_STRING ASN_VIDEOTEX_STRING ASN_IA5_STRING
125							ASN_ASCII_STRING ASN_UTC_TIME ASN_GENERALIZED_TIME ASN_GRAPHIC_STRING ASN_VISIBLE_STRING
126							ASN_ISO646_STRING ASN_GENERAL_STRING ASN_UNIVERSAL_STRING ASN_CHARACTER_STRING ASN_BMP_STRING
127
128							=item C<:const_ber_type>
129
130							The BER type constants, explained in the PROFILES section.
131
132							BER_TYPE_BYTES BER_TYPE_UTF8 BER_TYPE_UCS2 BER_TYPE_UCS4 BER_TYPE_INT
133							BER_TYPE_OID BER_TYPE_RELOID BER_TYPE_NULL BER_TYPE_BOOL BER_TYPE_REAL
134							BER_TYPE_IPADDRESS BER_TYPE_CROAK
135
136							=item C<:const_snmp>
137
138							Constants only relevant to SNMP. These are the tag values used by SNMP in
139							the C namespace and have the exact numerical value as in
140							BER/RFC 2578.
141
142							SNMP_IPADDRESS SNMP_COUNTER32 SNMP_UNSIGNED32 SNMP_GAUGE32
143							SNMP_TIMETICKS SNMP_OPAQUE SNMP_COUNTER64
144
145							=item C<:decode>
146
147							C and the match helper functions:
148
149							ber_decode ber-decode_prefix
150							ber_is ber_is_seq ber_is_int ber_is_oid
151							ber_dump
152
153							=item C<:encode>
154
155							C and the construction helper functions:
156
157							ber_encode
158							ber_int
159
160							=back
161
162							=head2 ASN.1/BER/DER/... BASICS
163
164							ASN.1 is a strange language that can be used to describe protocols and
165							data structures. It supports various mappings to JSON, XML, but most
166							importantly, to a various binary encodings such as BER, that is the topic
167							of this module, and is used in SNMP, LDAP or X.509 for example.
168
169							While ASN.1 defines a schema that is useful to interpret encoded data,
170							the BER encoding is actually somewhat self-describing: you might not know
171							whether something is a string or a number or a sequence or something else,
172							but you can nevertheless decode the overall structure, even if you end up
173							with just a binary blob for the actual value.
174
175							This works because BER values are tagged with a type and a namespace,
176							and also have a flag that says whether a value consists of subvalues (is
177							"constructed") or not (is "primitive").
178
179							Tags are simple integers, and ASN.1 defines a somewhat weird assortment
180							of those - for example, you have one integers and 16(!) different
181							string types, but there is no Unsigned32 type for example. Different
182							applications work around this in different ways, for example, SNMP defines
183							application-specific Gauge32, Counter32 and Unsigned32, which are mapped
184							to two different tags: you can distinguish between Counter32 and the
185							others, but not between Gause32 and Unsigned32, without the ASN.1 schema.
186
187							Ugh.
188
189							=head2 DECODED BER REPRESENTATION
190
191							This module represents every BER value as a 4-element tuple (actually an
192							array-reference):
193
194							[CLASS, TAG, FLAGS, DATA]
195
196							For example:
197
198							[ASN_UNIVERSAL, ASN_INTEGER, 0, 177] # the integer 177
199							[ASN_UNIVERSAL, ASN_OCTET_STRING, 0, "john"] # the string "john"
200							[ASN_UNIVERSAL, ASN_OID, 0, "1.3.6.133"] # some OID
201							[ASN_UNIVERSAL, ASN_SEQUENCE, 1, [ [ASN_UNIVERSAL... # a sequence
202
203							To avoid non-descriptive hardcoded array index numbers, this module
204							defines symbolic constants to access these members: C,
205							C, C and C.
206
207							Also, the first three members are integers with a little caveat: for
208							performance reasons, these are readonly and shared, so you must not modify
209							them (increment, assign to them etc.) in any way. You may modify the
210							I member, and you may re-assign the array itself, e.g.:
211
212							$ber = ber_decode $binbuf;
213
214							# the following is NOT legal:
215							$ber->[BER_CLASS] = ASN_PRIVATE; # ERROR, CLASS/TAG/FLAGS are READ ONLY(!)
216
217							# but all of the following are fine:
218							$ber->[BER_DATA] = "string";
219							$ber->[BER_DATA] = [ASN_UNIVERSAL, ASN_INTEGER, 0, 123];
220							@$ber = (ASN_APPLICATION, SNMP_TIMETICKS, 0, 1000);
221
222							I is something like a namespace for Is - there is the
223							C namespace which defines tags common to all ASN.1
224							implementations, the C namespace which defines tags for
225							specific applications (for example, the SNMP C type is in this
226							namespace), a special-purpose context namespace (C, used e.g.
227							for C) and a private namespace (C).
228
229							The meaning of the I depends on the namespace, and defines a
230							(partial) interpretation of the data value. For example, SNMP defines
231							extra tags in the C namespace, and to take full advantage
232							of these, you need to tell this module how to handle those via profiles.
233
234							The most common tags in the C namespace are
235							C, C, C, C,
236							C, C, C and
237							C.
238
239							The most common tags in SNMP's C namespace are
240							C, C, C and
241							C.
242
243							The I value is really just a boolean at this time (but might
244							get extended) - if it is C<0>, the value is "primitive" and contains
245							no subvalues, kind of like a non-reference perl scalar. If it is C<1>,
246							then the value is "constructed" which just means it contains a list of
247							subvalues which this module will en-/decode as BER tuples themselves.
248
249							The I value is either a reference to an array of further tuples
250							(if the value is I), some decoded representation of the value, if
251							this module knows how to decode it (e.g. for the integer types above) or
252							a binary string with the raw octets if this module doesn't know how to
253							interpret the namespace/tag.
254
255							Thus, you can always decode a BER data structure and at worst you get a
256							string in place of some nice decoded value.
257
258							See the SYNOPSIS for an example of such an encoded tuple representation.
259
260							=head2 DECODING AND ENCODING
261
262							=over
263
264							=item $tuple = ber_decode $bindata[, $profile]
265
266							Decodes binary BER data in C<$bindata> and returns the resulting BER
267							tuple. Croaks on any decoding error, so the returned C<$tuple> is always
268							valid.
269
270							How tags are interpreted is defined by the second argument, which must
271							be a C object. If it is missing, the default
272							profile will be used (C<$Convert::BER::XS::DEFAULT_PROFILE>).
273
274							In addition to rolling your own, this module provides a
275							C<$Convert::BER::XS::SNMP_PROFILE> that knows about the additional SNMP
276							types.
277
278							Example: decode a BER blob using the default profile - SNMP values will be
279							decided as raw strings.
280
281							$tuple = ber_decode $data;
282
283							Example: as above, but use the provided SNMP profile.
284
285							$tuple = ber_encode $data, $Convert::BER::XS::SNMP_PROFILE;
286
287							=item ($tuple, $bytes) = ber_decode_prefix $bindata[, $profile]
288
289							Works like C, except it doesn't croak when there is data after
290							the BER data, but instead returns the decoded value and the number of
291							bytes it decoded.
292
293							This is useful when you have BER data at the start of a buffer and other
294							data after, and you need to find the length.
295
296							Also, since BER is self-delimited, this can be used to decode multiple BER
297							values joined together.
298
299							=item $bindata = ber_encode $tuple[, $profile]
300
301							Encodes the BER tuple into a BER/DER data structure. As with
302							Cyber_decode>, an optional profile can be given.
303
304							The encoded data should be both BER and DER ("shortest form") compliant
305							unless the input says otherwise (e.g. it uses constructed strings).
306
307							=back
308
309							=head2 HELPER FUNCTIONS
310
311							Working with a 4-tuple for every value can be annoying. Or, rather, I
312							annoying. To reduce this a bit, this module defines a number of helper
313							functions, both to match BER tuples and to construct BER tuples:
314
315							=head3 MATCH HELPERS
316
317							These functions accept a BER tuple as first argument and either partially
318							or fully match it. They often come in two forms, one which exactly matches
319							a value, and one which only matches the type and returns the value.
320
321							They do check whether valid tuples are passed in and croak otherwise. As
322							a ease-of-use exception, they usually also accept C instead of a
323							tuple reference, in which case they silently fail to match.
324
325							=over
326
327							=item $bool = ber_is $tuple, $class, $tag, $flags, $data
328
329							This takes a BER C<$tuple> and matches its elements against the provided
330							values, all of which are optional - values that are either missing or
331							C will be ignored, the others will be matched exactly (e.g. as if
332							you used C<==> or C (for C<$data>)).
333
334							Some examples:
335
336							ber_is $tuple, ASN_UNIVERSAL, ASN_SEQUENCE, 1
337							orf die "tuple is not an ASN SEQUENCE";
338
339							ber_is $tuple, ASN_UNIVERSAL, ASN_NULL
340							or die "tuple is not an ASN NULL value";
341
342							ber_is $tuple, ASN_UNIVERSAL, ASN_INTEGER, 0, 50
343							or die "BER integer must be 50";
344
345							=item $seq = ber_is_seq $tuple
346
347							Returns the sequence members (the array of subvalues) if the C<$tuple> is
348							an ASN SEQUENCE, i.e. the C member. If the C<$tuple> is not a
349							sequence it returns C. For example, SNMP version 1/2c/3 packets all
350							consist of an outer SEQUENCE value:
351
352							my $ber = ber_decode $snmp_data;
353
354							my $snmp = ber_is_seq $ber
355							or die "SNMP packet invalid: does not start with SEQUENCE";
356
357							# now we know $snmp is a sequence, so decode the SNMP version
358
359							my $version = ber_is_int $snmp->[0]
360							or die "SNMP packet invalid: does not start with version number";
361
362							=item $bool = ber_is_int $tuple, $int
363
364							Returns a true value if the C<$tuple> represents an ASN INTEGER with
365							the value C<$int>.
366
367							=item $int = ber_is_int $tuple
368
369							Returns true (and extracts the integer value) if the C<$tuple> is an
370							C. For C<0>, this function returns a special value that is 0
371							but true.
372
373							=item $bool = ber_is_oid $tuple, $oid_string
374
375							Returns true if the C<$tuple> represents an ASN_OBJECT_IDENTIFIER
376							that exactly matches C<$oid_string>. Example:
377
378							ber_is_oid $tuple, "1.3.6.1.4"
379							or die "oid must be 1.3.6.1.4";
380
381							=item $oid = ber_is_oid $tuple
382
383							Returns true (and extracts the OID string) if the C<$tuple> is an ASN
384							OBJECT IDENTIFIER. Otherwise, it returns C.
385
386							=back
387
388							=head3 CONSTRUCTION HELPERS
389
390							=over
391
392							=item $tuple = ber_int $value
393
394							Constructs a new C tuple.
395
396							=back
397
398							=head2 RELATIONSHIP TO L and L
399
400							This module is I the XS version of L, but a different
401							take at doing the same thing. I imagine this module would be a good base
402							for speeding up either of these, or write a similar module, or write your
403							own LDAP or SNMP module for example.
404
405							=cut
406
407							package Convert::BER::XS;
408
409	7			7		7098	use common::sense;
	7					48
	7					30
410
411	7			7		281	use XSLoader ();
	7					11
	7					151
412	7			7		29	use Exporter qw(import);
	7					10
	7					358
413
414	7			7		35	use Carp ();
	7					8
	7					518
415
416							our $VERSION;
417
418							BEGIN {
419	7			7		18	$VERSION = 1.2;
420	7					20138	XSLoader::load __PACKAGE__, $VERSION;
421							}
422
423							our %EXPORT_TAGS = (
424							const_index => [qw(
425							BER_CLASS BER_TAG BER_FLAGS BER_DATA
426							)],
427							const_asn_class => [qw(
428							ASN_UNIVERSAL ASN_APPLICATION ASN_CONTEXT ASN_PRIVATE
429							)],
430							const_asn_tag => [qw(
431							ASN_BOOLEAN ASN_INTEGER ASN_BIT_STRING ASN_OCTET_STRING ASN_NULL ASN_OID ASN_OBJECT_IDENTIFIER
432							ASN_OBJECT_DESCRIPTOR ASN_EXTERNAL ASN_REAL ASN_SEQUENCE ASN_ENUMERATED
433							ASN_EMBEDDED_PDV ASN_UTF8_STRING ASN_RELATIVE_OID ASN_SET ASN_NUMERIC_STRING
434							ASN_PRINTABLE_STRING ASN_TELETEX_STRING ASN_T61_STRING ASN_VIDEOTEX_STRING ASN_IA5_STRING
435							ASN_ASCII_STRING ASN_UTC_TIME ASN_GENERALIZED_TIME ASN_GRAPHIC_STRING ASN_VISIBLE_STRING
436							ASN_ISO646_STRING ASN_GENERAL_STRING ASN_UNIVERSAL_STRING ASN_CHARACTER_STRING ASN_BMP_STRING
437							)],
438							const_ber_type => [qw(
439							BER_TYPE_BYTES BER_TYPE_UTF8 BER_TYPE_UCS2 BER_TYPE_UCS4 BER_TYPE_INT
440							BER_TYPE_OID BER_TYPE_RELOID BER_TYPE_NULL BER_TYPE_BOOL BER_TYPE_REAL
441							BER_TYPE_IPADDRESS BER_TYPE_CROAK
442							)],
443							const_snmp => [qw(
444							SNMP_IPADDRESS SNMP_COUNTER32 SNMP_GAUGE32 SNMP_UNSIGNED32
445							SNMP_TIMETICKS SNMP_OPAQUE SNMP_COUNTER64
446							)],
447							decode => [qw(
448							ber_decode ber_decode_prefix
449							ber_is ber_is_seq ber_is_int ber_is_oid
450							ber_dump
451							)],
452							encode => [qw(
453							ber_encode
454							ber_int
455							)],
456							);
457
458							our @EXPORT_OK = map @$_, values %EXPORT_TAGS;
459
460							$EXPORT_TAGS{all} = \@EXPORT_OK;
461							$EXPORT_TAGS{const_asn} = [map @{ $EXPORT_TAGS{$_} }, qw(const_asn_class const_asn_tag)];
462							$EXPORT_TAGS{const} = [map @{ $EXPORT_TAGS{$_} }, qw(const_index const_asn)];
463
464							our $DEFAULT_PROFILE = new Convert::BER::XS::Profile;
465
466							$DEFAULT_PROFILE->_set_default;
467
468							# additional SNMP application types
469							our $SNMP_PROFILE = new Convert::BER::XS::Profile;
470
471							$SNMP_PROFILE->set (ASN_APPLICATION, SNMP_IPADDRESS , BER_TYPE_IPADDRESS);
472							$SNMP_PROFILE->set (ASN_APPLICATION, SNMP_COUNTER32 , BER_TYPE_INT);
473							$SNMP_PROFILE->set (ASN_APPLICATION, SNMP_UNSIGNED32, BER_TYPE_INT);
474							$SNMP_PROFILE->set (ASN_APPLICATION, SNMP_TIMETICKS , BER_TYPE_INT);
475
476							# decodes REAL values according to ECMA-63
477							# this is pretty strict, except it doesn't catch -0.
478							sub _decode_real_decimal {
479	20			20		91	my ($format, $val) = @_;
480
481	20					32	$val =~ y/,/./;
482
483	20	100				57	if ($format == 1) {
		100
		50
484	2	50				9	$val =~ /^ \ * [+-]? [0-9]+ \z/x
485							or Carp::croak "BER_TYPE_REAL NR1 value not in NR1 format ($val) (X.690 8.5.8, ECMA-63)";
486							} elsif ($format == 2) {
487	8	50				31	$val =~ /^ \ * [+-]? (?: [0-9]+\.[0-9]* \| [0-9]*\.[0-9]+ ) \z/x
488							or Carp::croak "BER_TYPE_REAL NR2 value not in NR2 format ($val) (X.690 8.5.8, ECMA-63)";
489							} elsif ($format == 3) {
490	10	50				35	$val =~ /^ \ * [+-] (?: [0-9]+\.[0-9]* \| [0-9]*\.[0-9]+ ) E [+-][0-9]+ \z/x
491							or Carp::croak "BER_TYPE_REAL NR3 value not in NR3 format ($val) (X.690 8.5.8, ECMA-63)";
492							} else {
493	0					0	Carp::croak "BER_TYPE_REAL illegal decimal numerical representation format $format";
494							}
495
496	20					51	$val
497							}
498
499							# this is a mess, but perl's support for floating point formatting is nearly nonexistant
500							sub _encode_real_decimal {
501	20			20		6863	my ($val, $nvdig) = @_;
502
503	20					94	$val = sprintf "%.*G", $nvdig + 1, $val;
504
505	20	100				55	if ($val =~ /E/) {
506	10					26	$val =~ s/E(?=[^+-])/E+/;
507	10	100				38	$val =~ s/E/.E/ if $val !~ /\./;
508	10	100				29	$val =~ s/^/+/ unless $val =~ /^-/;
509
510	10					34	return "\x03$val" # NR3
511							}
512
513	10	100				39	$val =~ /\./
514							? "\x02$val" # NR2
515							: "\x01$val" # NR1
516							}
517
518							=head2 DEBUGGING
519
520							To aid debugging, you can call the C function to print a "nice"
521							representation to STDOUT.
522
523							=over
524
525							=item ber_dump $tuple[, $profile[, $prefix]]
526
527							In addition to specifying the BER C<$tuple> to dump, you can also specify
528							a C<$profile> and a C<$prefix> string that is printed in front of each line.
529
530							If C<$profile> is C<$Convert::BER::XS::SNMP_PROFILE>, then C
531							will try to improve its output for SNMP data.
532
533							The output usually contains three columns, the "human readable" tag, the
534							BER type used to decode it, and the data value.
535
536							This function is somewhat slow and uses a number of heuristics and tricks,
537							so it really is only suitable for debug prints.
538
539							Example output:
540
541							SEQUENCE
542							\| OCTET_STRING bytes 800063784300454045045400000001
543							\| OCTET_STRING bytes
544							\| CONTEXT (7) CONSTRUCTED
545							\| \| INTEGER int 1058588941
546							\| \| INTEGER int 0
547							\| \| INTEGER int 0
548							\| \| SEQUENCE
549							\| \| \| SEQUENCE
550							\| \| \| \| OID oid 1.3.6.1.2.1.1.3.0
551							\| \| \| \| TIMETICKS int 638085796
552
553							=back
554
555							=cut
556
557							# reverse enum, very slow and ugly hack
558							sub _re {
559	0			0			my ($export_tag, $value) = @_;
560
561	0						for my $symbol (@{ $EXPORT_TAGS{$export_tag} }) {
	0
562	0	0					$value == eval $symbol
563							and return $symbol;
564							}
565
566							"($value)"
567	0						}
568
569							$SNMP_PROFILE->set (ASN_APPLICATION, SNMP_COUNTER64 , BER_TYPE_INT);
570
571							sub _ber_dump {
572	0			0			my ($ber, $profile, $indent) = @_;
573
574	0	0					if (my $seq = ber_is_seq $ber) {
575	0						printf "%sSEQUENCE\n", $indent;
576							&_ber_dump ($_, $profile, "$indent\| ")
577	0						for @$seq;
578							} else {
579	0						my $asn = $ber->[BER_CLASS] == ASN_UNIVERSAL;
580
581	0						my $class = _re const_asn_class => $ber->[BER_CLASS];
582	0	0					my $tag = $asn ? _re const_asn_tag => $ber->[BER_TAG] : $ber->[BER_TAG];
583	0						my $type = _re const_ber_type => $profile->get ($ber->[BER_CLASS], $ber->[BER_TAG]);
584	0						my $data = $ber->[BER_DATA];
585
586	0	0	0				if ($profile == $SNMP_PROFILE and $ber->[BER_CLASS] == ASN_APPLICATION) {
		0
587	0						$tag = _re const_snmp => $ber->[BER_TAG];
588							} elsif (!$asn) {
589	0						$tag = "$class ($tag)";
590							}
591
592	0						$class =~ s/^ASN_//;
593	0						$tag =~ s/^(ASN_\|SNMP_)//;
594	0						$type =~ s/^BER_TYPE_//;
595
596	0	0					if ($ber->[BER_FLAGS]) {
597	0						printf "$indent%-16.16s\n", $tag;
598							&_ber_dump ($_, $profile, "$indent\| ")
599	0						for @$data;
600							} else {
601	0	0	0				if ($data =~ y/\x20-\x7e//c / (length $data \|\| 1) > 0.2 or $data =~ /\x00./s) {
			0
602							# assume binary
603	0						$data = unpack "H*", $data;
604							} else {
605	0						$data =~ s/[^\x20-\x7e]/./g;
606	0	0	0				$data = "\"$data\"" if $tag =~ /string/i \|\| !length $data;
607							}
608
609	0	0					substr $data, 40, 1e9, "..." if 40 < length $data;
610
611	0						printf "$indent%-16.16s %-6.6s %s\n", $tag, lc $type, $data;
612							}
613							}
614							}
615
616							sub ber_dump($;$$) {
617	0		0	0	1		_ber_dump $_[0], $_[1] \|\| $DEFAULT_PROFILE, $_[2];
618							}
619
620							=head1 PROFILES
621
622							While any BER data can be correctly encoded and decoded out of the box, it
623							can be inconvenient to have to manually decode some values into a "better"
624							format: for instance, SNMP TimeTicks values are decoded into the raw octet
625							strings of their BER representation, which is quite hard to decode. With
626							profiles, you can change which class/tag combinations map to which decoder
627							function inside C (and of course also which encoder functions
628							are used in C).
629
630							This works by mapping specific class/tag combinations to an internal "ber
631							type".
632
633							The default profile supports the standard ASN.1 types, but no
634							application-specific ones. This means that class/tag combinations not in
635							the base set of ASN.1 are decoded into their raw octet strings.
636
637							C defines two profile variables you can use out of the box:
638
639							=over
640
641							=item C<$Convert::BER::XS::DEFAULT_PROFILE>
642
643							This is the default profile, i.e. the profile that is used when no
644							profile is specified for de-/encoding.
645
646							You can modify it, but remember that this modifies the defaults for all
647							callers that rely on the default profile.
648
649							=item C<$Convert::BER::XS::SNMP_PROFILE>
650
651							A profile with mappings for SNMP-specific application tags added. This is
652							useful when de-/encoding SNMP data.
653
654							Example:
655
656							$ber = ber_decode $data, $Convert::BER::XS::SNMP_PROFILE;
657
658							=back
659
660							=head2 The Convert::BER::XS::Profile class
661
662							=over
663
664							=item $profile = new Convert::BER::XS::Profile
665
666							Create a new profile. The profile will be identical to the default
667							profile.
668
669							=item $profile->set ($class, $tag, $type)
670
671							Sets the mapping for the given C<$class>/C<$tag> combination to C<$type>,
672							which must be one of the C constants.
673
674							Note that currently, the mapping is stored in a flat array, so large
675							values of C<$tag> will consume large amounts of memory.
676
677							Example:
678
679							$profile = new Convert::BER::XS::Profile;
680							$profile->set (ASN_APPLICATION, SNMP_COUNTER32, BER_TYPE_INT);
681							$ber = ber_decode $data, $profile;
682
683							=item $type = $profile->get ($class, $tag)
684
685							Returns the BER type mapped to the given C<$class>/C<$tag> combination.
686
687							=back
688
689							=head2 BER Types
690
691							This lists the predefined BER types. BER types are formatters used
692							internally to format and encode BER values. You can assign any C
693							to any C/C combination tgo change how that tag is decoded or
694							encoded.
695
696							=over
697
698							=item C
699
700							The raw octets of the value. This is the default type for unknown tags and
701							de-/encodes the value as if it were an octet string, i.e. by copying the
702							raw bytes.
703
704							=item C
705
706							Like C, but decodes the value as if it were a UTF-8 string
707							(without validation!) and encodes a perl unicode string into a UTF-8 BER
708							string.
709
710							=item C
711
712							Similar to C, but treats the BER value as UCS-2 encoded
713							string.
714
715							=item C
716
717							Similar to C, but treats the BER value as UCS-4 encoded
718							string.
719
720							=item C
721
722							Encodes and decodes a BER integer value to a perl integer scalar. This
723							should correctly handle 64 bit signed and unsigned values.
724
725							=item C
726
727							Encodes and decodes an OBJECT IDENTIFIER into dotted form without leading
728							dot, e.g. C<1.3.6.1.213>.
729
730							=item C
731
732							Same as C but uses relative object identifier
733							encoding: ASN.1 has this hack of encoding the first two OID components
734							into a single integer in a weird attempt to save an insignificant amount
735							of space in an otherwise wasteful encoding, and relative OIDs are
736							basically OIDs without this hack. The practical difference is that the
737							second component of an OID can only have the values 1..40, while relative
738							OIDs do not have this restriction.
739
740							=item C
741
742							Decodes an C value into C, and always encodes a
743							C type, regardless of the perl value.
744
745							=item C
746
747							Decodes an C value into C<0> or C<1>, and encodes a perl
748							boolean value into an C.
749
750							=item C
751
752							Decodes/encodes a BER real value. NOT IMPLEMENTED.
753
754							=item C
755
756							Decodes/encodes a four byte string into an IPv4 dotted-quad address string
757							in Perl. Given the obsolete nature of this type, this is a low-effort
758							implementation that simply uses C and C-style conversion,
759							so it won't handle all string forms supported by C for example.
760
761							=item C
762
763							Always croaks when encountered during encoding or decoding - the
764							default behaviour when encountering an unknown type is to treat it as
765							C. When you don't want that but instead prefer a hard
766							error for some types, then C is for you.
767
768							=back
769
770							=head2 Example Profile
771
772							The following creates a profile suitable for SNMP - it's exactly identical
773							to the C<$Convert::BER::XS::SNMP_PROFILE> profile.
774
775							our $SNMP_PROFILE = new Convert::BER::XS::Profile;
776
777							$SNMP_PROFILE->set (ASN_APPLICATION, SNMP_IPADDRESS , BER_TYPE_IPADDRESS);
778							$SNMP_PROFILE->set (ASN_APPLICATION, SNMP_COUNTER32 , BER_TYPE_INT);
779							$SNMP_PROFILE->set (ASN_APPLICATION, SNMP_UNSIGNED32, BER_TYPE_INT);
780							$SNMP_PROFILE->set (ASN_APPLICATION, SNMP_TIMETICKS , BER_TYPE_INT);
781							$SNMP_PROFILE->set (ASN_APPLICATION, SNMP_OPAQUE , BER_TYPE_BYTES);
782							$SNMP_PROFILE->set (ASN_APPLICATION, SNMP_COUNTER64 , BER_TYPE_INT);
783
784							=head2 LIMITATIONS/NOTES
785
786							This module can only en-/decode 64 bit signed and unsigned
787							integers/tags/lengths, and only when your perl supports those. So no UUID
788							OIDs for now (unless you map the C
789							other than C).
790
791							This module does not generally care about ranges, i.e. it will happily
792							de-/encode 64 bit integers into an C value, or a negative
793							number into an C.
794
795							OBJECT IDENTIFIEERs cannot have unlimited length, although the limit is
796							much larger than e.g. the one imposed by SNMP or other protocols, and is
797							about 4kB.
798
799							Constructed strings are decoded just fine, but there should be a way to
800							join them for convenience.
801
802							REAL values will always be encoded in decimal form and ssometimes is
803							forced into a perl "NV" type, potentially losing precision.
804
805							=head2 ITHREADS SUPPORT
806
807							This module is unlikely to work in any other than the loading thread when
808							the (officially discouraged) ithreads are in use.
809
810							=head1 AUTHOR
811
812							Marc Lehmann
813							http://software.schmorp.de/pkg/Convert-BER-XS
814
815							=cut
816
817							1;
818