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/cvs/Convert-BER-XS/XS.xs
Revision: 1.18
Committed: Sat Apr 20 16:12:53 2019 UTC (5 years, 1 month ago) by root
Branch: MAIN
Changes since 1.17: +10 -1 lines
Log Message: 
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File Contents

# Content
1 #include "EXTERN.h"
2 #include "perl.h"
3 #include "XSUB.h"
4
5 // C99 required!
6 // this is not just for comments, but also for
7 // integer constant semantics,
8 // sscanf format modifiers and more.
9
10 enum {
11 // ASN_TAG
12 ASN_BOOLEAN = 0x01,
13 ASN_INTEGER = 0x02,
14 ASN_BIT_STRING = 0x03,
15 ASN_OCTET_STRING = 0x04,
16 ASN_NULL = 0x05,
17 ASN_OBJECT_IDENTIFIER = 0x06,
18 ASN_OID = 0x06,
19 ASN_OBJECT_DESCRIPTOR = 0x07,
20 ASN_EXTERNAL = 0x08,
21 ASN_REAL = 0x09,
22 ASN_ENUMERATED = 0x0a,
23 ASN_EMBEDDED_PDV = 0x0b,
24 ASN_UTF8_STRING = 0x0c,
25 ASN_RELATIVE_OID = 0x0d,
26 ASN_SEQUENCE = 0x10,
27 ASN_SET = 0x11,
28 ASN_NUMERIC_STRING = 0x12,
29 ASN_PRINTABLE_STRING = 0x13,
30 ASN_TELETEX_STRING = 0x14,
31 ASN_T61_STRING = 0x14,
32 ASN_VIDEOTEX_STRING = 0x15,
33 ASN_IA5_STRING = 0x16,
34 ASN_ASCII_STRING = 0x16,
35 ASN_UTC_TIME = 0x17,
36 ASN_GENERALIZED_TIME = 0x18,
37 ASN_GRAPHIC_STRING = 0x19,
38 ASN_VISIBLE_STRING = 0x1a,
39 ASN_ISO646_STRING = 0x1a,
40 ASN_GENERAL_STRING = 0x1b,
41 ASN_UNIVERSAL_STRING = 0x1c,
42 ASN_CHARACTER_STRING = 0x1d,
43 ASN_BMP_STRING = 0x1e,
44
45 ASN_TAG_BER = 0x1f,
46 ASN_TAG_MASK = 0x1f,
47
48 // primitive/constructed
49 ASN_CONSTRUCTED = 0x20,
50
51 // ASN_CLASS
52 ASN_UNIVERSAL = 0x00,
53 ASN_APPLICATION = 0x01,
54 ASN_CONTEXT = 0x02,
55 ASN_PRIVATE = 0x03,
56
57 ASN_CLASS_MASK = 0xc0,
58 ASN_CLASS_SHIFT = 6,
59
60 // ASN_APPLICATION SNMP
61 SNMP_IPADDRESS = 0x00,
62 SNMP_COUNTER32 = 0x01,
63 SNMP_UNSIGNED32 = 0x02,
64 SNMP_TIMETICKS = 0x03,
65 SNMP_OPAQUE = 0x04,
66 SNMP_COUNTER64 = 0x06,
67 };
68
69 enum {
70 BER_TYPE_BYTES,
71 BER_TYPE_UTF8,
72 BER_TYPE_UCS2,
73 BER_TYPE_UCS4,
74 BER_TYPE_INT,
75 BER_TYPE_OID,
76 BER_TYPE_RELOID,
77 BER_TYPE_NULL,
78 BER_TYPE_BOOL,
79 BER_TYPE_REAL,
80 BER_TYPE_IPADDRESS,
81 BER_TYPE_CROAK,
82 };
83
84 enum {
85 BER_CLASS = 0,
86 BER_TAG = 1,
87 BER_FLAGS = 2,
88 BER_DATA = 3,
89 BER_ARRAYSIZE
90 };
91
92 #define MAX_OID_STRLEN 4096
93
94 typedef void profile_type;
95
96 static profile_type *cur_profile, *default_profile;
97 static SV *buf_sv; // encoding buffer
98 static U8 *buf, *cur, *end; // buffer start, current, end
99
100 #if PERL_VERSION < 18
101 # define utf8_to_uvchr_buf(s,e,l) utf8_to_uvchr (s, l)
102 #endif
103
104 #if __GNUC__ >= 3
105 # define expect(expr,value) __builtin_expect ((expr), (value))
106 # define INLINE static inline
107 #else
108 # define expect(expr,value) (expr)
109 # define INLINE static
110 #endif
111
112 #define expect_false(expr) expect ((expr) != 0, 0)
113 #define expect_true(expr) expect ((expr) != 0, 1)
114
115 /////////////////////////////////////////////////////////////////////////////
116
117 static SV *sviv_cache[32];
118
119 // for "small" integers, return a readonly sv, otherwise create a new one
120 static SV *newSVcacheint (int val)
121 {
122 if (expect_false (val < 0 || val >= sizeof (sviv_cache)))
123 return newSViv (val);
124
125 if (expect_false (!sviv_cache [val]))
126 {
127 sviv_cache [val] = newSVuv (val);
128 SvREADONLY_on (sviv_cache [val]);
129 }
130
131 return SvREFCNT_inc_NN (sviv_cache [val]);
132 }
133
134 /////////////////////////////////////////////////////////////////////////////
135
136 static HV *profile_stash;
137
138 static profile_type *
139 SvPROFILE (SV *profile)
140 {
141 if (!SvOK (profile))
142 return default_profile;
143
144 if (!SvROK (profile))
145 croak ("invalid profile");
146
147 profile = SvRV (profile);
148
149 if (SvSTASH (profile) != profile_stash)
150 croak ("invalid profile object");
151
152 return (void *)profile;
153 }
154
155 static int
156 profile_lookup (profile_type *profile, int klass, int tag)
157 {
158 SV *sv = (SV *)profile;
159 U32 idx = (tag << 2) + klass;
160
161 if (expect_false (idx >= SvCUR (sv)))
162 return BER_TYPE_BYTES;
163
164 return SvPVX (sv)[idx];
165 }
166
167 static void
168 profile_set (profile_type *profile, int klass, int tag, int type)
169 {
170 SV *sv = (SV *)profile;
171 U32 idx = (tag << 2) + klass;
172 STRLEN oldlen = SvCUR (sv);
173 STRLEN newlen = idx + 2;
174
175 if (idx >= oldlen)
176 {
177 sv_grow (sv, newlen);
178 memset (SvPVX (sv) + oldlen, BER_TYPE_BYTES, newlen - oldlen);
179 SvCUR_set (sv, newlen);
180 }
181
182 SvPVX (sv)[idx] = type;
183 }
184
185 static SV *
186 profile_new (void)
187 {
188 SV *sv = newSVpvn ("", 0);
189
190 static const struct {
191 int klass;
192 int tag;
193 int type;
194 } *celem, default_map[] = {
195 { ASN_UNIVERSAL, ASN_BOOLEAN , BER_TYPE_BOOL },
196 { ASN_UNIVERSAL, ASN_INTEGER , BER_TYPE_INT },
197 { ASN_UNIVERSAL, ASN_NULL , BER_TYPE_NULL },
198 { ASN_UNIVERSAL, ASN_OBJECT_IDENTIFIER, BER_TYPE_OID },
199 { ASN_UNIVERSAL, ASN_RELATIVE_OID , BER_TYPE_RELOID },
200 { ASN_UNIVERSAL, ASN_REAL , BER_TYPE_REAL },
201 { ASN_UNIVERSAL, ASN_ENUMERATED , BER_TYPE_INT },
202 { ASN_UNIVERSAL, ASN_UTF8_STRING , BER_TYPE_UTF8 },
203 { ASN_UNIVERSAL, ASN_BMP_STRING , BER_TYPE_UCS2 },
204 { ASN_UNIVERSAL, ASN_UNIVERSAL_STRING , BER_TYPE_UCS4 },
205 };
206
207 for (celem = default_map + sizeof (default_map) / sizeof (default_map [0]); celem-- > default_map; )
208 profile_set ((profile_type *)sv, celem->klass, celem->tag, celem->type);
209
210 return sv_bless (newRV_noinc (sv), profile_stash);
211 }
212
213 /////////////////////////////////////////////////////////////////////////////
214 // decoder
215
216 static void
217 error (const char *errmsg)
218 {
219 croak ("%s at offset 0x%04x", errmsg, cur - buf);
220 }
221
222 static void
223 want (UV count)
224 {
225 if (expect_false ((uintptr_t)(end - cur) < count))
226 error ("unexpected end of message buffer");
227 }
228
229 // get_* functions fetch something from the buffer
230 // decode_* functions use get_* fun ctions to decode ber values
231
232 // get n octets
233 static U8 *
234 get_n (UV count)
235 {
236 want (count);
237 U8 *res = cur;
238 cur += count;
239 return res;
240 }
241
242 // get single octet
243 static U8
244 get_u8 (void)
245 {
246 if (cur == end)
247 error ("unexpected end of message buffer");
248
249 return *cur++;
250 }
251
252 // get ber-encoded integer (i.e. pack "w")
253 static UV
254 get_w (void)
255 {
256 UV res = 0;
257
258 for (;;)
259 {
260 U8 c = get_u8 ();
261 res = (res << 7) | (c & 0x7f);
262
263 if (!(c & 0x80))
264 return res;
265 }
266 }
267
268 static UV
269 get_length (void)
270 {
271 UV res = get_u8 ();
272
273 if (res & 0x80)
274 {
275 int cnt = res & 0x7f;
276 res = 0;
277
278 switch (cnt)
279 {
280 case 0:
281 error ("indefinite ASN.1 lengths not supported");
282 return 0;
283
284 //case 0x80: // indefinite length
285
286 //case 0xff: reserved
287 default:
288 error ("ASN.1 length too long");
289 return 0;
290
291 case 8: res = (res << 8) | get_u8 ();
292 case 7: res = (res << 8) | get_u8 ();
293 case 6: res = (res << 8) | get_u8 ();
294 case 5: res = (res << 8) | get_u8 ();
295 case 4: res = (res << 8) | get_u8 ();
296 case 3: res = (res << 8) | get_u8 ();
297 case 2: res = (res << 8) | get_u8 ();
298 case 1: res = (res << 8) | get_u8 ();
299 }
300 }
301
302 return res;
303 }
304
305 static SV *
306 decode_int (void)
307 {
308 UV len = get_length ();
309
310 if (!len)
311 {
312 error ("invalid integer length equal to zero");
313 return 0;
314 }
315
316 U8 *data = get_n (len);
317
318 int negative = data [0] & 0x80;
319
320 UV val = negative ? -1 : 0; // copy signbit to all bits
321
322 do
323 val = (val << 8) | *data++;
324 while (--len);
325
326 // the cast to IV relies on implementation-defined behaviour (two's complement cast)
327 // but that's ok, as perl relies on it as well.
328 return negative ? newSViv ((IV)val) : newSVuv (val);
329 }
330
331 static SV *
332 decode_data (void)
333 {
334 UV len = get_length ();
335 return newSVpvn ((char *)get_n (len), len);
336 }
337
338 // helper for decode_object_identifier
339 static char *
340 write_uv (char *buf, UV u)
341 {
342 // the one-digit case is absolutely predominant, so this pays off (hopefully)
343 if (expect_true (u < 10))
344 *buf++ = u + '0';
345 else
346 {
347 // this *could* be done much faster using branchless fixed-point arithmetics
348 char *beg = buf;
349
350 do
351 {
352 *buf++ = u % 10 + '0';
353 u /= 10;
354 }
355 while (u);
356
357 // reverse digits
358 char *ptr = buf;
359 while (--ptr > beg)
360 {
361 char c = *ptr;
362 *ptr = *beg;
363 *beg = c;
364 ++beg;
365 }
366 }
367
368 return buf;
369 }
370
371 static SV *
372 decode_oid (int relative)
373 {
374 UV len = get_length ();
375
376 if (len <= 0)
377 {
378 error ("OBJECT IDENTIFIER length equal to zero");
379 return &PL_sv_undef;
380 }
381
382 U8 *end = cur + len;
383 UV w = get_w ();
384
385 static char oid[MAX_OID_STRLEN]; // static, becaueds too large for stack
386 char *app = oid;
387
388 if (relative)
389 app = write_uv (app, w);
390 else if (w < 2 * 40)
391 {
392 app = write_uv (app, (U8)w / 40);
393 *app++ = '.';
394 app = write_uv (app, (U8)w % 40);
395 }
396 else
397 {
398 app = write_uv (app, 2);
399 *app++ = '.';
400 app = write_uv (app, w - 2 * 40);
401 }
402
403 while (cur < end)
404 {
405 // we assume an oid component is never > 64 digits
406 if (oid + sizeof (oid) - app < 64)
407 croak ("BER_TYPE_OID to long to decode");
408
409 w = get_w ();
410 *app++ = '.';
411 app = write_uv (app, w);
412 }
413
414 return newSVpvn (oid, app - oid);
415 }
416
417 // TODO: this is unacceptably slow
418 static SV *
419 decode_ucs (int chrsize)
420 {
421 SV *res = NEWSV (0, 0);
422
423 UV len = get_length ();
424
425 if (len & (chrsize - 1))
426 croak ("BER_TYPE_UCS has an invalid number of octets (%d)", len);
427
428 while (len)
429 {
430 U8 b1 = get_u8 ();
431 U8 b2 = get_u8 ();
432 U32 chr = (b1 << 8) | b2;
433
434 if (chrsize == 4)
435 {
436 U8 b3 = get_u8 ();
437 U8 b4 = get_u8 ();
438 chr = (chr << 16) | (b3 << 8) | b4;
439 }
440
441 U8 uchr [UTF8_MAXBYTES];
442 int uclen = uvuni_to_utf8 (uchr, chr) - uchr;
443
444 sv_catpvn (res, (const char *)uchr, uclen);
445 len -= chrsize;
446 }
447
448 SvUTF8_on (res);
449
450 return res;
451 }
452
453 static SV *
454 decode_ber (void)
455 {
456 int identifier = get_u8 ();
457
458 SV *res;
459
460 int constructed = identifier & ASN_CONSTRUCTED;
461 int klass = (identifier & ASN_CLASS_MASK) >> ASN_CLASS_SHIFT;
462 int tag = identifier & ASN_TAG_MASK;
463
464 if (tag == ASN_TAG_BER)
465 tag = get_w ();
466
467 if (tag == ASN_TAG_BER)
468 tag = get_w ();
469
470 if (constructed)
471 {
472 UV len = get_length ();
473 UV seqend = (cur - buf) + len;
474 AV *av = (AV *)sv_2mortal ((SV *)newAV ());
475
476 while (cur < buf + seqend)
477 av_push (av, decode_ber ());
478
479 if (cur > buf + seqend)
480 croak ("constructed type %02x overflow (%x %x)\n", identifier, cur - buf, seqend);
481
482 res = newRV_inc ((SV *)av);
483 }
484 else
485 switch (profile_lookup (cur_profile, klass, tag))
486 {
487 case BER_TYPE_NULL:
488 {
489 UV len = get_length ();
490
491 if (len)
492 croak ("BER_TYPE_NULL value with non-zero length %d encountered", len);
493
494 res = &PL_sv_undef;
495 }
496 break;
497
498 case BER_TYPE_BOOL:
499 {
500 UV len = get_length ();
501
502 if (len != 1)
503 croak ("BER_TYPE_BOOLEAN value with invalid length %d encountered", len);
504
505 res = newSVcacheint (!!get_u8 ());
506 }
507 break;
508
509 case BER_TYPE_OID:
510 res = decode_oid (0);
511 break;
512
513 case BER_TYPE_RELOID:
514 res = decode_oid (1);
515 break;
516
517 case BER_TYPE_INT:
518 res = decode_int ();
519 break;
520
521 case BER_TYPE_UTF8:
522 res = decode_data ();
523 SvUTF8_on (res);
524 break;
525
526 case BER_TYPE_BYTES:
527 res = decode_data ();
528 break;
529
530 case BER_TYPE_IPADDRESS:
531 {
532 UV len = get_length ();
533
534 if (len != 4)
535 croak ("BER_TYPE_IPADDRESS type with invalid length %d encountered", len);
536
537 U8 c1 = get_u8 ();
538 U8 c2 = get_u8 ();
539 U8 c3 = get_u8 ();
540 U8 c4 = get_u8 ();
541
542 res = newSVpvf ("%d.%d.%d.%d", c1, c2, c3, c4);
543 }
544 break;
545
546 case BER_TYPE_UCS2:
547 res = decode_ucs (2);
548 break;
549
550 case BER_TYPE_UCS4:
551 res = decode_ucs (4);
552 break;
553
554 case BER_TYPE_REAL:
555 case BER_TYPE_CROAK:
556 default:
557 croak ("unconfigured/unsupported class/tag %d/%d", klass, tag);
558 }
559
560 AV *av = newAV ();
561 av_fill (av, BER_ARRAYSIZE - 1);
562 AvARRAY (av)[BER_CLASS] = newSVcacheint (klass);
563 AvARRAY (av)[BER_TAG ] = newSVcacheint (tag);
564 AvARRAY (av)[BER_FLAGS] = newSVcacheint (constructed ? 1 : 0);
565 AvARRAY (av)[BER_DATA ] = res;
566
567 return newRV_noinc ((SV *)av);
568 }
569
570 /////////////////////////////////////////////////////////////////////////////
571 // encoder
572
573 /* adds two STRLENs together, slow, and with paranoia */
574 static STRLEN
575 strlen_sum (STRLEN l1, STRLEN l2)
576 {
577 size_t sum = l1 + l2;
578
579 if (sum < (size_t)l2 || sum != (size_t)(STRLEN)sum)
580 croak ("JSON::XS: string size overflow");
581
582 return sum;
583 }
584
585 static void
586 set_buf (SV *sv)
587 {
588 STRLEN len;
589 buf_sv = sv;
590 buf = (U8 *)SvPVbyte (buf_sv, len);
591 cur = buf;
592 end = buf + len;
593 }
594
595 /* similar to SvGROW, but somewhat safer and guarantees exponential realloc strategy */
596 static char *
597 my_sv_grow (SV *sv, size_t len1, size_t len2)
598 {
599 len1 = strlen_sum (len1, len2);
600 len1 = strlen_sum (len1, len1 >> 1);
601
602 if (len1 > 4096 - 24)
603 len1 = (len1 | 4095) - 24;
604
605 return SvGROW (sv, len1);
606 }
607
608 static void
609 need (STRLEN len)
610 {
611 if (expect_false ((uintptr_t)(end - cur) < len))
612 {
613 STRLEN pos = cur - buf;
614 buf = (U8 *)my_sv_grow (buf_sv, pos, len);
615 cur = buf + pos;
616 end = buf + SvLEN (buf_sv) - 1;
617 }
618 }
619
620 static void
621 put_u8 (int val)
622 {
623 need (1);
624 *cur++ = val;
625 }
626
627 static void
628 put_w_nocheck (UV val)
629 {
630 #if UVSIZE > 4
631 *cur = (val >> 7 * 9) | 0x80; cur += val >= ((UV)1 << (7 * 9));
632 *cur = (val >> 7 * 8) | 0x80; cur += val >= ((UV)1 << (7 * 8));
633 *cur = (val >> 7 * 7) | 0x80; cur += val >= ((UV)1 << (7 * 7));
634 *cur = (val >> 7 * 6) | 0x80; cur += val >= ((UV)1 << (7 * 6));
635 *cur = (val >> 7 * 5) | 0x80; cur += val >= ((UV)1 << (7 * 5));
636 #endif
637 *cur = (val >> 7 * 4) | 0x80; cur += val >= ((UV)1 << (7 * 4));
638 *cur = (val >> 7 * 3) | 0x80; cur += val >= ((UV)1 << (7 * 3));
639 *cur = (val >> 7 * 2) | 0x80; cur += val >= ((UV)1 << (7 * 2));
640 *cur = (val >> 7 * 1) | 0x80; cur += val >= ((UV)1 << (7 * 1));
641 *cur = val & 0x7f; cur += 1;
642 }
643
644 static void
645 put_w (UV val)
646 {
647 need (5); // we only handle up to 5 bytes
648
649 put_w_nocheck (val);
650 }
651
652 static U8 *
653 put_length_at (UV val, U8 *cur)
654 {
655 if (val < 0x7fU)
656 *cur++ = val;
657 else
658 {
659 U8 *lenb = cur++;
660
661 #if UVSIZE > 4
662 *cur = val >> 56; cur += *cur > 0;
663 *cur = val >> 48; cur += *cur > 0;
664 *cur = val >> 40; cur += *cur > 0;
665 *cur = val >> 32; cur += *cur > 0;
666 #endif
667 *cur = val >> 24; cur += *cur > 0;
668 *cur = val >> 16; cur += *cur > 0;
669 *cur = val >> 8; cur += *cur > 0;
670 *cur = val ; cur += 1;
671
672 *lenb = 0x80 + cur - lenb - 1;
673 }
674
675 return cur;
676 }
677
678 static void
679 put_length (UV val)
680 {
681 need (5 + val);
682 cur = put_length_at (val, cur);
683 }
684
685 // return how many bytes the encoded length requires
686 static int length_length (UV val)
687 {
688 return val < 0x7fU
689 ? 1
690 : 2
691 + (val > 0xffU)
692 + (val > 0xffffU)
693 + (val > 0xffffffU)
694 #if UVSIZE > 4
695 + (val > 0xffffffffU)
696 + (val > 0xffffffffffU)
697 + (val > 0xffffffffffffU)
698 + (val > 0xffffffffffffffU)
699 #endif
700 ;
701 }
702
703 static void
704 encode_data (const char *ptr, STRLEN len)
705 {
706 put_length (len);
707 memcpy (cur, ptr, len);
708 cur += len;
709 }
710
711 static void
712 encode_uv (UV uv)
713 {
714 }
715
716 static void
717 encode_int (SV *sv)
718 {
719 need (8 + 1 + 1); // 64 bit + length + extra 0
720
721 if (expect_false (!SvIOK (sv)))
722 sv_2iv_flags (sv, 0);
723
724 U8 *lenb = cur++;
725
726 if (SvIOK_notUV (sv))
727 {
728 IV iv = SvIVX (sv);
729
730 if (expect_false (iv < 0))
731 {
732 // get two's complement bit pattern - works even on hypothetical non-2c machines
733 UV uv = iv;
734
735 #if UVSIZE > 4
736 *cur = uv >> 56; cur += !!(~uv & 0xff80000000000000U);
737 *cur = uv >> 48; cur += !!(~uv & 0xffff800000000000U);
738 *cur = uv >> 40; cur += !!(~uv & 0xffffff8000000000U);
739 *cur = uv >> 32; cur += !!(~uv & 0xffffffff80000000U);
740 #endif
741 *cur = uv >> 24; cur += !!(~uv & 0xffffffffff800000U);
742 *cur = uv >> 16; cur += !!(~uv & 0xffffffffffff8000U);
743 *cur = uv >> 8; cur += !!(~uv & 0xffffffffffffff80U);
744 *cur = uv ; cur += 1;
745
746 *lenb = cur - lenb - 1;
747
748 return;
749 }
750 }
751
752 UV uv = SvUV (sv);
753
754 // prepend an extra 0 if the high bit is 1
755 *cur = 0; cur += !!(uv & ((UV)1 << (UVSIZE * 8 - 1)));
756
757 #if UVSIZE > 4
758 *cur = uv >> 56; cur += !!(uv & 0xff80000000000000U);
759 *cur = uv >> 48; cur += !!(uv & 0xffff800000000000U);
760 *cur = uv >> 40; cur += !!(uv & 0xffffff8000000000U);
761 *cur = uv >> 32; cur += !!(uv & 0xffffffff80000000U);
762 #endif
763 *cur = uv >> 24; cur += !!(uv & 0xffffffffff800000U);
764 *cur = uv >> 16; cur += !!(uv & 0xffffffffffff8000U);
765 *cur = uv >> 8; cur += !!(uv & 0xffffffffffffff80U);
766 *cur = uv ; cur += 1;
767
768 *lenb = cur - lenb - 1;
769 }
770
771 // we don't know the length yet, so we optimistically
772 // assume the length will need one octet later. If that
773 // turns out to be wrong, we memmove as needed.
774 // mark the beginning
775 static STRLEN
776 len_fixup_mark (void)
777 {
778 return cur++ - buf;
779 }
780
781 // patch up the length
782 static void
783 len_fixup (STRLEN mark)
784 {
785 STRLEN reallen = (cur - buf) - mark - 1;
786 int lenlen = length_length (reallen);
787
788 if (expect_false (lenlen > 1))
789 {
790 // bad luck, we have to shift the bytes to make room for the length
791 need (5);
792 memmove (buf + mark + lenlen, buf + mark + 1, reallen);
793 cur += lenlen - 1;
794 }
795
796 put_length_at (reallen, buf + mark);
797 }
798
799 static char *
800 read_uv (char *str, UV *uv)
801 {
802 UV r = 0;
803
804 while (*str >= '0')
805 r = r * 10 + *str++ - '0';
806
807 *uv = r;
808
809 str += !!*str; // advance over any non-zero byte
810
811 return str;
812 }
813
814 static void
815 encode_oid (SV *oid, int relative)
816 {
817 STRLEN len;
818 char *ptr = SvPV (oid, len); // utf8 vs. bytes does not matter
819
820 // we need at most as many octets as the string form
821 need (len + 1);
822 STRLEN mark = len_fixup_mark ();
823
824 UV w1, w2;
825
826 if (!relative)
827 {
828 ptr = read_uv (ptr, &w1);
829 ptr = read_uv (ptr, &w2);
830
831 put_w_nocheck (w1 * 40 + w2);
832 }
833
834 while (*ptr)
835 {
836 ptr = read_uv (ptr, &w1);
837 put_w_nocheck (w1);
838 }
839
840 len_fixup (mark);
841 }
842
843 // check whether an SV is a BER tuple and returns its AV *
844 static AV *
845 ber_tuple (SV *tuple)
846 {
847 SV *rv;
848
849 if (expect_false (!SvROK (tuple) || SvTYPE ((rv = SvRV (tuple))) != SVt_PVAV))
850 croak ("BER tuple must be array-reference");
851
852 if (expect_false (SvRMAGICAL (rv)))
853 croak ("BER tuple must not be tied");
854
855 if (expect_false (AvFILL ((AV *)rv) != BER_ARRAYSIZE - 1))
856 croak ("BER tuple must contain exactly %d elements, not %d", BER_ARRAYSIZE, AvFILL ((AV *)rv) + 1);
857
858 return (AV *)rv;
859 }
860
861 static void
862 encode_ucs (SV *data, int chrsize)
863 {
864 STRLEN uchars = sv_len_utf8 (data);
865 STRLEN len;;
866 char *ptr = SvPVutf8 (data, len);
867
868 put_length (uchars * chrsize);
869
870 while (uchars--)
871 {
872 STRLEN uclen;
873 UV uchr = utf8_to_uvchr_buf ((U8 *)ptr, (U8 *)ptr + len, &uclen);
874
875 ptr += uclen;
876 len -= uclen;
877
878 if (chrsize == 4)
879 {
880 *cur++ = uchr >> 24;
881 *cur++ = uchr >> 16;
882 }
883
884 *cur++ = uchr >> 8;
885 *cur++ = uchr;
886 }
887 }
888 static void
889 encode_ber (SV *tuple)
890 {
891 AV *av = ber_tuple (tuple);
892
893 int klass = SvIV (AvARRAY (av)[BER_CLASS]);
894 int tag = SvIV (AvARRAY (av)[BER_TAG]);
895 int constructed = SvIV (AvARRAY (av)[BER_FLAGS]) & 1 ? ASN_CONSTRUCTED : 0;
896 SV *data = AvARRAY (av)[BER_DATA];
897
898 int identifier = (klass << ASN_CLASS_SHIFT) | constructed;
899
900 if (expect_false (tag >= ASN_TAG_BER))
901 {
902 put_u8 (identifier | ASN_TAG_BER);
903 put_w (tag);
904 }
905 else
906 put_u8 (identifier | tag);
907
908 if (constructed)
909 {
910 // we optimistically assume that only one length byte is needed
911 // and adjust later
912 need (1);
913 STRLEN mark = len_fixup_mark ();
914
915 if (expect_false (!SvROK (data) || SvTYPE (SvRV (data)) != SVt_PVAV))
916 croak ("BER constructed data must be array-reference");
917
918 AV *av = (AV *)SvRV (data);
919 int fill = AvFILL (av);
920
921 if (expect_false (SvRMAGICAL (av)))
922 croak ("BER constructed data must not be tied");
923
924 int i;
925 for (i = 0; i <= fill; ++i)
926 encode_ber (AvARRAY (av)[i]);
927
928 len_fixup (mark);
929 }
930 else
931 switch (profile_lookup (cur_profile, klass, tag))
932 {
933 case BER_TYPE_NULL:
934 put_length (0);
935 break;
936
937 case BER_TYPE_BOOL:
938 put_length (1);
939 *cur++ = SvTRUE (data) ? 0xff : 0x00; // 0xff = DER/CER
940 break;
941
942 case BER_TYPE_OID:
943 encode_oid (data, 0);
944 break;
945
946 case BER_TYPE_RELOID:
947 encode_oid (data, 1);
948 break;
949
950 case BER_TYPE_INT:
951 encode_int (data);
952 break;
953
954 case BER_TYPE_BYTES:
955 {
956 STRLEN len;
957 const char *ptr = SvPVbyte (data, len);
958 encode_data (ptr, len);
959 }
960 break;
961
962 case BER_TYPE_UTF8:
963 {
964 STRLEN len;
965 const char *ptr = SvPVutf8 (data, len);
966 encode_data (ptr, len);
967 }
968 break;
969
970 case BER_TYPE_IPADDRESS:
971 {
972 U8 ip[4];
973 sscanf (SvPV_nolen (data), "%hhu.%hhu.%hhu.%hhu", ip + 0, ip + 1, ip + 2, ip + 3);
974 encode_data ((const char *)ip, sizeof (ip));
975 }
976 break;
977
978 case BER_TYPE_UCS2:
979 encode_ucs (data, 2);
980 break;
981
982 case BER_TYPE_UCS4:
983 encode_ucs (data, 4);
984 break;
985
986 case BER_TYPE_REAL:
987 case BER_TYPE_CROAK:
988 default:
989 croak ("unconfigured/unsupported class/tag %d/%d", klass, tag);
990 }
991
992 }
993
994 /////////////////////////////////////////////////////////////////////////////
995
996 MODULE = Convert::BER::XS PACKAGE = Convert::BER::XS
997
998 PROTOTYPES: ENABLE
999
1000 BOOT:
1001 {
1002 HV *stash = gv_stashpv ("Convert::BER::XS", 1);
1003
1004 profile_stash = gv_stashpv ("Convert::BER::XS::Profile", 1);
1005
1006 static const struct {
1007 const char *name;
1008 IV iv;
1009 } *civ, const_iv[] = {
1010 #define const_iv(name) { # name, name },
1011 const_iv (ASN_BOOLEAN)
1012 const_iv (ASN_INTEGER)
1013 const_iv (ASN_BIT_STRING)
1014 const_iv (ASN_OCTET_STRING)
1015 const_iv (ASN_NULL)
1016 const_iv (ASN_OBJECT_IDENTIFIER)
1017 const_iv (ASN_OBJECT_DESCRIPTOR)
1018 const_iv (ASN_OID)
1019 const_iv (ASN_EXTERNAL)
1020 const_iv (ASN_REAL)
1021 const_iv (ASN_SEQUENCE)
1022 const_iv (ASN_ENUMERATED)
1023 const_iv (ASN_EMBEDDED_PDV)
1024 const_iv (ASN_UTF8_STRING)
1025 const_iv (ASN_RELATIVE_OID)
1026 const_iv (ASN_SET)
1027 const_iv (ASN_NUMERIC_STRING)
1028 const_iv (ASN_PRINTABLE_STRING)
1029 const_iv (ASN_TELETEX_STRING)
1030 const_iv (ASN_T61_STRING)
1031 const_iv (ASN_VIDEOTEX_STRING)
1032 const_iv (ASN_IA5_STRING)
1033 const_iv (ASN_ASCII_STRING)
1034 const_iv (ASN_UTC_TIME)
1035 const_iv (ASN_GENERALIZED_TIME)
1036 const_iv (ASN_GRAPHIC_STRING)
1037 const_iv (ASN_VISIBLE_STRING)
1038 const_iv (ASN_ISO646_STRING)
1039 const_iv (ASN_GENERAL_STRING)
1040 const_iv (ASN_UNIVERSAL_STRING)
1041 const_iv (ASN_CHARACTER_STRING)
1042 const_iv (ASN_BMP_STRING)
1043
1044 const_iv (ASN_UNIVERSAL)
1045 const_iv (ASN_APPLICATION)
1046 const_iv (ASN_CONTEXT)
1047 const_iv (ASN_PRIVATE)
1048
1049 const_iv (BER_CLASS)
1050 const_iv (BER_TAG)
1051 const_iv (BER_FLAGS)
1052 const_iv (BER_DATA)
1053
1054 const_iv (BER_TYPE_BYTES)
1055 const_iv (BER_TYPE_UTF8)
1056 const_iv (BER_TYPE_UCS2)
1057 const_iv (BER_TYPE_UCS4)
1058 const_iv (BER_TYPE_INT)
1059 const_iv (BER_TYPE_OID)
1060 const_iv (BER_TYPE_RELOID)
1061 const_iv (BER_TYPE_NULL)
1062 const_iv (BER_TYPE_BOOL)
1063 const_iv (BER_TYPE_REAL)
1064 const_iv (BER_TYPE_IPADDRESS)
1065 const_iv (BER_TYPE_CROAK)
1066
1067 const_iv (SNMP_IPADDRESS)
1068 const_iv (SNMP_COUNTER32)
1069 const_iv (SNMP_UNSIGNED32)
1070 const_iv (SNMP_TIMETICKS)
1071 const_iv (SNMP_OPAQUE)
1072 const_iv (SNMP_COUNTER64)
1073 };
1074
1075 for (civ = const_iv + sizeof (const_iv) / sizeof (const_iv [0]); civ > const_iv; civ--)
1076 newCONSTSUB (stash, (char *)civ[-1].name, newSViv (civ[-1].iv));
1077 }
1078
1079 SV *
1080 ber_decode (SV *ber, SV *profile = &PL_sv_undef)
1081 CODE:
1082 {
1083 cur_profile = SvPROFILE (profile);
1084 STRLEN len;
1085 buf = (U8 *)SvPVbyte (ber, len);
1086 cur = buf;
1087 end = buf + len;
1088
1089 RETVAL = decode_ber ();
1090 }
1091 OUTPUT: RETVAL
1092
1093 void
1094 ber_is (SV *tuple, SV *klass = &PL_sv_undef, SV *tag = &PL_sv_undef, SV *flags = &PL_sv_undef, SV *data = &PL_sv_undef)
1095 PPCODE:
1096 {
1097 if (!SvOK (tuple))
1098 XSRETURN_NO;
1099
1100 if (!SvROK (tuple) || SvTYPE (SvRV (tuple)) != SVt_PVAV)
1101 croak ("ber_is: tuple must be BER tuple (array-ref)");
1102
1103 AV *av = (AV *)SvRV (tuple);
1104
1105 XPUSHs (
1106 (!SvOK (klass) || SvIV (AvARRAY (av)[BER_CLASS]) == SvIV (klass))
1107 && (!SvOK (tag) || SvIV (AvARRAY (av)[BER_TAG ]) == SvIV (tag))
1108 && (!SvOK (flags) || !SvIV (AvARRAY (av)[BER_FLAGS]) == !SvIV (flags))
1109 && (!SvOK (data) || sv_eq (AvARRAY (av)[BER_DATA ], data))
1110 ? &PL_sv_yes : &PL_sv_undef);
1111 }
1112
1113 void
1114 ber_is_seq (SV *tuple)
1115 PPCODE:
1116 {
1117 if (!SvOK (tuple))
1118 XSRETURN_UNDEF;
1119
1120 AV *av = ber_tuple (tuple);
1121
1122 XPUSHs (
1123 SvIV (AvARRAY (av)[BER_CLASS]) == ASN_UNIVERSAL
1124 && SvIV (AvARRAY (av)[BER_TAG ]) == ASN_SEQUENCE
1125 && SvIV (AvARRAY (av)[BER_FLAGS])
1126 ? AvARRAY (av)[BER_DATA] : &PL_sv_undef);
1127 }
1128
1129 void
1130 ber_is_int (SV *tuple, SV *value = &PL_sv_undef)
1131 PPCODE:
1132 {
1133 if (!SvOK (tuple))
1134 XSRETURN_NO;
1135
1136 AV *av = ber_tuple (tuple);
1137
1138 UV data = SvUV (AvARRAY (av)[BER_DATA]);
1139
1140 XPUSHs (
1141 SvIV (AvARRAY (av)[BER_CLASS]) == ASN_UNIVERSAL
1142 && SvIV (AvARRAY (av)[BER_TAG ]) == ASN_INTEGER
1143 && !SvIV (AvARRAY (av)[BER_FLAGS])
1144 && (!SvOK (value) || data == SvUV (value))
1145 ? sv_2mortal (data ? newSVsv (AvARRAY (av)[BER_DATA]) : newSVpv ("0 but true", 0))
1146 : &PL_sv_undef);
1147 }
1148
1149 void
1150 ber_is_oid (SV *tuple, SV *oid = &PL_sv_undef)
1151 PPCODE:
1152 {
1153 if (!SvOK (tuple))
1154 XSRETURN_NO;
1155
1156 AV *av = ber_tuple (tuple);
1157
1158 XPUSHs (
1159 SvIV (AvARRAY (av)[BER_CLASS]) == ASN_UNIVERSAL
1160 && SvIV (AvARRAY (av)[BER_TAG ]) == ASN_OBJECT_IDENTIFIER
1161 && !SvIV (AvARRAY (av)[BER_FLAGS])
1162 && (!SvOK (oid) || sv_eq (AvARRAY (av)[BER_DATA], oid))
1163 ? newSVsv (AvARRAY (av)[BER_DATA]) : &PL_sv_undef);
1164 }
1165
1166 #############################################################################
1167
1168 void
1169 ber_encode (SV *tuple, SV *profile = &PL_sv_undef)
1170 PPCODE:
1171 {
1172 cur_profile = SvPROFILE (profile);
1173 buf_sv = sv_2mortal (NEWSV (0, 256));
1174 SvPOK_only (buf_sv);
1175 set_buf (buf_sv);
1176
1177 encode_ber (tuple);
1178
1179 SvCUR_set (buf_sv, cur - buf);
1180 XPUSHs (buf_sv);
1181 }
1182
1183 SV *
1184 ber_int (SV *sv)
1185 CODE:
1186 {
1187 AV *av = newAV ();
1188 av_fill (av, BER_ARRAYSIZE - 1);
1189 AvARRAY (av)[BER_CLASS] = newSVcacheint (ASN_UNIVERSAL);
1190 AvARRAY (av)[BER_TAG ] = newSVcacheint (ASN_INTEGER);
1191 AvARRAY (av)[BER_FLAGS] = newSVcacheint (0);
1192 AvARRAY (av)[BER_DATA ] = newSVsv (sv);
1193 RETVAL = newRV_noinc ((SV *)av);
1194 }
1195 OUTPUT: RETVAL
1196
1197 # TODO: not arrayref, but elements?
1198 SV *
1199 ber_seq (SV *arrayref)
1200 CODE:
1201 {
1202 AV *av = newAV ();
1203 av_fill (av, BER_ARRAYSIZE - 1);
1204 AvARRAY (av)[BER_CLASS] = newSVcacheint (ASN_UNIVERSAL);
1205 AvARRAY (av)[BER_TAG ] = newSVcacheint (ASN_SEQUENCE);
1206 AvARRAY (av)[BER_FLAGS] = newSVcacheint (1);
1207 AvARRAY (av)[BER_DATA ] = newSVsv (arrayref);
1208 RETVAL = newRV_noinc ((SV *)av);
1209 }
1210 OUTPUT: RETVAL
1211
1212 MODULE = Convert::BER::XS PACKAGE = Convert::BER::XS::Profile
1213
1214 SV *
1215 new (SV *klass)
1216 CODE:
1217 RETVAL = profile_new ();
1218 OUTPUT: RETVAL
1219
1220 void
1221 set (SV *profile, int klass, int tag, int type)
1222 CODE:
1223 profile_set (SvPROFILE (profile), klass, tag, type);
1224
1225 IV
1226 get (SV *profile, int klass, int tag)
1227 CODE:
1228 RETVAL = profile_lookup (SvPROFILE (profile), klass, tag);
1229 OUTPUT: RETVAL
1230
1231 void
1232 _set_default (SV *profile)
1233 CODE:
1234 default_profile = SvPROFILE (profile);
1235
1236