[ViewVC] Diff of: cvs/Convert-BER-XS/XS.xs

Comparing Convert-BER-XS/XS.xs (file contents):
Revision 1.10 by root, Sat Apr 20 11:12:47 2019 UTC vs.
Revision 1.23 by root, Sun Apr 21 01:51:12 2019 UTC

…		…
1	#include "EXTERN.h"	1	#include "EXTERN.h"
2	#include "perl.h"	2	#include "perl.h"
3	#include "XSUB.h"	3	#include "XSUB.h"
4		4
5	// C99 required	5	// C99 required!
		6	// this is not just for comments, but also for
		7	// integer constant semantics,
		8	// sscanf format modifiers and more.
6		9
7	enum {	10	enum {
8	// ASN_TAG	11	// ASN_TAG
9	ASN_BOOLEAN = 0x01,	12	ASN_BOOLEAN = 0x01,
10	ASN_INTEGER32 = 0x02,	13	ASN_INTEGER = 0x02,
11	ASN_BIT_STRING = 0x03,	14	ASN_BIT_STRING = 0x03,
12	ASN_OCTET_STRING = 0x04,	15	ASN_OCTET_STRING = 0x04,
13	ASN_NULL = 0x05,	16	ASN_NULL = 0x05,
14	ASN_OBJECT_IDENTIFIER = 0x06,	17	ASN_OBJECT_IDENTIFIER = 0x06,
15	ASN_OID = 0x06,	18	ASN_OID = 0x06,
55	ASN_CLASS_SHIFT = 6,	58	ASN_CLASS_SHIFT = 6,
56		59
57	// ASN_APPLICATION SNMP	60	// ASN_APPLICATION SNMP
58	SNMP_IPADDRESS = 0x00,	61	SNMP_IPADDRESS = 0x00,
59	SNMP_COUNTER32 = 0x01,	62	SNMP_COUNTER32 = 0x01,
		63	SNMP_GAUGE32 = 0x02,
60	SNMP_UNSIGNED32 = 0x02,	64	SNMP_UNSIGNED32 = 0x02,
61	SNMP_TIMETICKS = 0x03,	65	SNMP_TIMETICKS = 0x03,
62	SNMP_OPAQUE = 0x04,	66	SNMP_OPAQUE = 0x04,
63	SNMP_COUNTER64 = 0x06,	67	SNMP_COUNTER64 = 0x06,
64	};	68	};
…		…
77	BER_TYPE_IPADDRESS,	81	BER_TYPE_IPADDRESS,
78	BER_TYPE_CROAK,	82	BER_TYPE_CROAK,
79	};	83	};
80		84
81	enum {	85	enum {
82	BER_CLASS = 0,	86	BER_CLASS = 0,
83	BER_TAG = 1,	87	BER_TAG = 1,
84	BER_CONSTRUCTED = 2,	88	BER_FLAGS = 2,
85	BER_DATA = 3,	89	BER_DATA = 3,
86	BER_ARRAYSIZE	90	BER_ARRAYSIZE
87	};	91	};
88		92
89	#define MAX_OID_STRLEN 4096	93	#define MAX_OID_STRLEN 4096
90		94
…		…
178		182
179	SvPVX (sv)[idx] = type;	183	SvPVX (sv)[idx] = type;
180	}	184	}
181		185
182	static SV *	186	static SV *
183	profile_new ()	187	profile_new (void)
184	{	188	{
185	SV *sv = newSVpvn ("", 0);	189	SV *sv = newSVpvn ("", 0);
186		190
187	static const struct {	191	static const struct {
188	int klass;	192	int klass;
189	int tag;	193	int tag;
190	int type;	194	int type;
191	} *celem, default_map[] = {	195	} *celem, default_map[] = {
192	{ ASN_UNIVERSAL, ASN_BOOLEAN , BER_TYPE_BOOL },	196	{ ASN_UNIVERSAL, ASN_BOOLEAN , BER_TYPE_BOOL },
193	{ ASN_UNIVERSAL, ASN_INTEGER32 , BER_TYPE_INT },	197	{ ASN_UNIVERSAL, ASN_INTEGER , BER_TYPE_INT },
194	{ ASN_UNIVERSAL, ASN_NULL , BER_TYPE_NULL },	198	{ ASN_UNIVERSAL, ASN_NULL , BER_TYPE_NULL },
195	{ ASN_UNIVERSAL, ASN_OBJECT_IDENTIFIER, BER_TYPE_OID },	199	{ ASN_UNIVERSAL, ASN_OBJECT_IDENTIFIER, BER_TYPE_OID },
196	{ ASN_UNIVERSAL, ASN_OBJECT_DESCRIPTOR, BER_TYPE_OID },
197	{ ASN_UNIVERSAL, ASN_RELATIVE_OID , BER_TYPE_RELOID },	200	{ ASN_UNIVERSAL, ASN_RELATIVE_OID , BER_TYPE_RELOID },
198	{ ASN_UNIVERSAL, ASN_REAL , BER_TYPE_REAL },	201	{ ASN_UNIVERSAL, ASN_REAL , BER_TYPE_REAL },
		202	{ ASN_UNIVERSAL, ASN_ENUMERATED , BER_TYPE_INT },
199	{ ASN_UNIVERSAL, ASN_UTF8_STRING , BER_TYPE_UTF8 },	203	{ ASN_UNIVERSAL, ASN_UTF8_STRING , BER_TYPE_UTF8 },
200	{ ASN_UNIVERSAL, ASN_BMP_STRING , BER_TYPE_UCS2 },	204	{ ASN_UNIVERSAL, ASN_BMP_STRING , BER_TYPE_UCS2 },
201	{ ASN_UNIVERSAL, ASN_UNIVERSAL_STRING , BER_TYPE_UCS4 },	205	{ ASN_UNIVERSAL, ASN_UNIVERSAL_STRING , BER_TYPE_UCS4 },
202	};	206	};
203		207
204	for (celem = default_map + sizeof (default_map) / sizeof (default_map [0]); celem > default_map; celem--)	208	for (celem = default_map + sizeof (default_map) / sizeof (default_map [0]); celem-- > default_map; )
205	profile_set ((void *)sv, celem->klass, celem->tag, celem->type);	209	profile_set ((profile_type *)sv, celem->klass, celem->tag, celem->type);
206		210
207	return sv_bless (newRV_noinc (sv), profile_stash);	211	return sv_bless (newRV_noinc (sv), profile_stash);
208	}	212	}
209		213
210	/////////////////////////////////////////////////////////////////////////////	214	/////////////////////////////////////////////////////////////////////////////
…		…
245		249
246	return *cur++;	250	return *cur++;
247	}	251	}
248		252
249	// get ber-encoded integer (i.e. pack "w")	253	// get ber-encoded integer (i.e. pack "w")
250	static U32	254	static UV
251	get_w (void)	255	get_w (void)
252	{	256	{
253	U32 res = 0;	257	UV res = 0;
		258	U8 c = get_u8 ();
		259
		260	if (expect_false (c == 0x80))
		261	error ("illegal BER padding (X.690 8.1.2.4.2, 8.19.2)");
254		262
255	for (;;)	263	for (;;)
256	{	264	{
257	U8 c = get_u8 ();	265	if (expect_false (res >> UVSIZE * 8 - 7))
		266	error ("BER variable integer overflow");
		267
258	res = (res << 7) \| (c & 0x7f);	268	res = (res << 7) \| (c & 0x7f);
259		269
260	if (!(c & 0x80))	270	if (!(c & 0x80))
261	return res;	271	return res;
262	}
263	}
264		272
		273	c = get_u8 ();
		274	}
		275	}
		276
265	static U32	277	static UV
266	get_length (void)	278	get_length (void)
267	{	279	{
268	U32 res = get_u8 ();	280	UV res = get_u8 ();
269		281
270	if (res & 0x80)	282	if (res & 0x80)
271	{	283	{
272	int cnt = res & 0x7f;	284	int cnt = res & 0x7f;
273	res = 0;	285	res = 0;
274		286
275	switch (cnt)	287	switch (cnt)
276	{	288	{
277	case 0:	289	case 0:
278	error ("indefinite ASN.1 lengths not supported");	290	error ("indefinite ASN.1 lengths not supported");
279	return 0;	291
		292	case 0x7f:
		293	error ("ASN.1 reserved value in length (X.690 8.1.3.5)");
280		294
281	default:	295	default:
282	error ("ASN.1 length too long");	296	error ("ASN.1 length too long (only up to 2**64 octets supported)");
283	return 0;
284		297
		298	case 8: res = (res << 8) \| get_u8 ();
		299	case 7: res = (res << 8) \| get_u8 ();
		300	case 6: res = (res << 8) \| get_u8 ();
		301	case 5: res = (res << 8) \| get_u8 ();
285	case 4: res = (res << 8) \| get_u8 ();	302	case 4: res = (res << 8) \| get_u8 ();
286	case 3: res = (res << 8) \| get_u8 ();	303	case 3: res = (res << 8) \| get_u8 ();
287	case 2: res = (res << 8) \| get_u8 ();	304	case 2: res = (res << 8) \| get_u8 ();
288	case 1: res = (res << 8) \| get_u8 ();	305	case 1: res = (res << 8) \| get_u8 ();
289	}	306	}
…		…
291		308
292	return res;	309	return res;
293	}	310	}
294		311
295	static SV *	312	static SV *
296	decode_int ()	313	decode_int (void)
297	{	314	{
298	int len = get_length ();	315	UV len = get_length ();
299		316
300	if (len <= 0)	317	if (!len)
301	{
302	error ("integer length equal to zero");	318	error ("invalid integer length equal to zero (X.690 8.3.1)");
303	return 0;
304	}
305		319
306	U8 *data = get_n (len);	320	U8 *data = get_n (len);
307		321
		322	if (expect_false (len > 1))
		323	{
		324	U16 mask = (data [0] << 8) \| data [1] & 0xff80;
		325
		326	if (expect_false (mask == 0xff80 \|\| mask == 0x0000))
		327	error ("illegal padding in integer (X.690 8.3.2)");
		328	}
		329
308	int negative = data [0] & 0x80;	330	int negative = data [0] & 0x80;
309		331
310	UV val = negative ? -1 : 0; // copy signbit to all bits	332	UV val = negative ? -1 : 0; // copy signbit to all bits
		333
		334	if (len > UVSIZE + (!negative && !*data))
		335	//printf ("len %d > %d + (!%d && !%d) = %d\n", len, UVSIZE, negative, data, UVSIZE + (!negative && !data));//D
		336	error ("INTEGER overflow");
311		337
312	do	338	do
313	val = (val << 8) \| *data++;	339	val = (val << 8) \| *data++;
314	while (--len);	340	while (--len);
315		341
…		…
319	}	345	}
320		346
321	static SV *	347	static SV *
322	decode_data (void)	348	decode_data (void)
323	{	349	{
324	U32 len = get_length ();	350	UV len = get_length ();
325	U8 *data = get_n (len);
326	return newSVpvn ((char *)data, len);	351	return newSVpvn ((char *)get_n (len), len);
327	}	352	}
328		353
329	// gelper for decode_object_identifier	354	// helper for decode_object_identifier
330	static char *	355	static char *
331	write_uv (char *buf, U32 u)	356	write_uv (char *buf, UV u)
332	{	357	{
333	// the one-digit case is absolutely predominant, so this pays off (hopefully)	358	// the one-digit case is absolutely predominant, so this pays off (hopefully)
334	if (expect_true (u < 10))	359	if (expect_true (u < 10))
335	*buf++ = u + '0';	360	*buf++ = u + '0';
336	else	361	else
337	{	362	{
		363	// this could be done much faster using branchless fixed-point arithmetics
338	char *beg = buf;	364	char *beg = buf;
339		365
340	do	366	do
341	{	367	{
342	*buf++ = u % 10 + '0';	368	*buf++ = u % 10 + '0';
343	u /= 10;	369	u /= 10;
344	}	370	}
345	while (u);	371	while (u);
346		372
347	// reverse digits	373	// reverse digits
348	for (char *ptr = buf; --ptr != beg; ++beg)	374	char *ptr = buf;
		375	while (--ptr > beg)
349	{	376	{
350	char c = *ptr;	377	char c = *ptr;
351	ptr = beg;	378	ptr = beg;
352	*beg = c;	379	*beg = c;
		380	++beg;
353	}	381	}
354	}	382	}
355		383
356	return buf;	384	return buf;
357	}	385	}
358		386
359	static SV *	387	static SV *
360	decode_oid (int relative)	388	decode_oid (int relative)
361	{	389	{
362	U32 len = get_length ();	390	UV len = get_length ();
363		391
364	if (len <= 0)	392	if (len <= 0)
365	{	393	{
366	error ("OBJECT IDENTIFIER length equal to zero");	394	error ("OBJECT IDENTIFIER length equal to zero");
367	return &PL_sv_undef;	395	return &PL_sv_undef;
368	}	396	}
369		397
370	U8 *end = cur + len;	398	U8 *end = cur + len;
371	U32 w = get_w ();	399	UV w = get_w ();
372		400
373	static char oid[MAX_OID_STRLEN]; // must be static	401	static char oid[MAX_OID_STRLEN]; // static, because too large for stack
374	char *app = oid;	402	char *app = oid;
375		403
376	if (relative)	404	if (relative)
377	app = write_uv (app, w);	405	app = write_uv (app, w);
378	else	406	else if (w < 2 * 40)
379	{	407	{
380	app = write_uv (app, (U8)w / 40);	408	app = write_uv (app, (U8)w / 40);
381	*app++ = '.';	409	*app++ = '.';
382	app = write_uv (app, (U8)w % 40);	410	app = write_uv (app, (U8)w % 40);
383	}	411	}
		412	else
		413	{
		414	app = write_uv (app, 2);
		415	*app++ = '.';
		416	app = write_uv (app, w - 2 * 40);
		417	}
384		418
		419	while (cur < end)
		420	{
385	// we assume an oid component is never > 64 bytes	421	// we assume an oid component is never > 64 digits
386	while (cur < end && oid + sizeof (oid) - app > 64)	422	if (oid + sizeof (oid) - app < 64)
387	{	423	croak ("BER_TYPE_OID to long to decode");
		424
388	w = get_w ();	425	w = get_w ();
389	*app++ = '.';	426	*app++ = '.';
390	app = write_uv (app, w);	427	app = write_uv (app, w);
391	}	428	}
392		429
…		…
397	static SV *	434	static SV *
398	decode_ucs (int chrsize)	435	decode_ucs (int chrsize)
399	{	436	{
400	SV *res = NEWSV (0, 0);	437	SV *res = NEWSV (0, 0);
401		438
402	U32 len = get_length ();	439	UV len = get_length ();
403		440
404	if (len & (chrsize - 1))	441	if (len & (chrsize - 1))
405	croak ("BER_TYPE_UCS has an invalid number of octets (%d)", len);	442	croak ("BER_TYPE_UCS has an invalid number of octets (%d)", len);
406		443
407	while (len)	444	while (len)
…		…
428		465
429	return res;	466	return res;
430	}	467	}
431		468
432	static SV *	469	static SV *
433	decode_ber ()	470	decode_ber (void)
434	{	471	{
435	int identifier = get_u8 ();	472	int identifier = get_u8 ();
436		473
437	SV *res;	474	SV *res;
438		475
…		…
441	int tag = identifier & ASN_TAG_MASK;	478	int tag = identifier & ASN_TAG_MASK;
442		479
443	if (tag == ASN_TAG_BER)	480	if (tag == ASN_TAG_BER)
444	tag = get_w ();	481	tag = get_w ();
445		482
446	if (tag == ASN_TAG_BER)
447	tag = get_w ();
448
449	if (constructed)	483	if (constructed)
450	{	484	{
451	U32 len = get_length ();	485	UV len = get_length ();
452	U32 seqend = (cur - buf) + len;	486	UV seqend = (cur - buf) + len;
453	AV av = (AV )sv_2mortal ((SV *)newAV ());	487	AV av = (AV )sv_2mortal ((SV *)newAV ());
454		488
455	while (cur < buf + seqend)	489	while (cur < buf + seqend)
456	av_push (av, decode_ber ());	490	av_push (av, decode_ber ());
457		491
458	if (cur > buf + seqend)	492	if (cur > buf + seqend)
459	croak ("constructed type %02x overflow (%x %x)\n", identifier, cur - buf, seqend);	493	croak ("constructed type %02x length overflow (0x%x 0x%x)\n", identifier, (int)(cur - buf), (int)seqend);
460		494
461	res = newRV_inc ((SV *)av);	495	res = newRV_inc ((SV *)av);
462	}	496	}
463	else	497	else
464	switch (profile_lookup (cur_profile, klass, tag))	498	switch (profile_lookup (cur_profile, klass, tag))
465	{	499	{
466	case BER_TYPE_NULL:	500	case BER_TYPE_NULL:
		501	{
		502	UV len = get_length ();
		503
		504	if (len)
		505	croak ("BER_TYPE_NULL value with non-zero length %d encountered (X.690 8.8.2)", len);
		506
467	res = &PL_sv_undef;	507	res = &PL_sv_undef;
		508	}
468	break;	509	break;
469		510
470	case BER_TYPE_BOOL:	511	case BER_TYPE_BOOL:
471	{	512	{
472	U32 len = get_length ();	513	UV len = get_length ();
473		514
474	if (len != 1)	515	if (len != 1)
475	croak ("BER_TYPE_BOOLEAN type with invalid length %d encountered", len);	516	croak ("BER_TYPE_BOOLEAN value with invalid length %d encountered (X.690 8.2.1)", len);
476		517
477	res = newSVcacheint (get_u8 () ? 0 : 1);	518	res = newSVcacheint (!!get_u8 ());
478	}	519	}
479	break;	520	break;
480		521
481	case BER_TYPE_OID:	522	case BER_TYPE_OID:
482	res = decode_oid (0);	523	res = decode_oid (0);
…		…
499	res = decode_data ();	540	res = decode_data ();
500	break;	541	break;
501		542
502	case BER_TYPE_IPADDRESS:	543	case BER_TYPE_IPADDRESS:
503	{	544	{
504	U32 len = get_length ();	545	UV len = get_length ();
505		546
506	if (len != 4)	547	if (len != 4)
507	croak ("BER_TYPE_IPADDRESS type with invalid length %d encountered", len);	548	croak ("BER_TYPE_IPADDRESS type with invalid length %d encountered (RFC 2578 7.1.5)", len);
508		549
509	U8 c1 = get_u8 ();	550	U8 c1 = get_u8 ();
510	U8 c2 = get_u8 ();	551	U8 c2 = get_u8 ();
511	U8 c3 = get_u8 ();	552	U8 c3 = get_u8 ();
512	U8 c4 = get_u8 ();	553	U8 c4 = get_u8 ();
…		…
529	croak ("unconfigured/unsupported class/tag %d/%d", klass, tag);	570	croak ("unconfigured/unsupported class/tag %d/%d", klass, tag);
530	}	571	}
531		572
532	AV *av = newAV ();	573	AV *av = newAV ();
533	av_fill (av, BER_ARRAYSIZE - 1);	574	av_fill (av, BER_ARRAYSIZE - 1);
534	AvARRAY (av)[BER_CLASS ] = newSVcacheint (klass);	575	AvARRAY (av)[BER_CLASS] = newSVcacheint (klass);
535	AvARRAY (av)[BER_TAG ] = newSVcacheint (tag);	576	AvARRAY (av)[BER_TAG ] = newSVcacheint (tag);
536	AvARRAY (av)[BER_CONSTRUCTED] = newSVcacheint (constructed ? 1 : 0);	577	AvARRAY (av)[BER_FLAGS] = newSVcacheint (constructed ? 1 : 0);
537	AvARRAY (av)[BER_DATA ] = res;	578	AvARRAY (av)[BER_DATA ] = res;
538		579
539	return newRV_noinc ((SV *)av);	580	return newRV_noinc ((SV *)av);
540	}	581	}
541		582
542	/////////////////////////////////////////////////////////////////////////////	583	/////////////////////////////////////////////////////////////////////////////
…		…
547	strlen_sum (STRLEN l1, STRLEN l2)	588	strlen_sum (STRLEN l1, STRLEN l2)
548	{	589	{
549	size_t sum = l1 + l2;	590	size_t sum = l1 + l2;
550		591
551	if (sum < (size_t)l2 \|\| sum != (size_t)(STRLEN)sum)	592	if (sum < (size_t)l2 \|\| sum != (size_t)(STRLEN)sum)
552	croak ("JSON::XS: string size overflow");	593	croak ("Convert::BER::XS: string size overflow");
553		594
554	return sum;	595	return sum;
555	}	596	}
556		597
557	static void	598	static void
…		…
595	need (1);	636	need (1);
596	*cur++ = val;	637	*cur++ = val;
597	}	638	}
598		639
599	static void	640	static void
600	put_w_nocheck (U32 val)	641	put_w_nocheck (UV val)
601	{	642	{
		643	#if UVSIZE > 4
		644	cur = (val >> 7 9) \| 0x80; cur += val >= ((UV)1 << (7 * 9));
		645	cur = (val >> 7 8) \| 0x80; cur += val >= ((UV)1 << (7 * 8));
		646	cur = (val >> 7 7) \| 0x80; cur += val >= ((UV)1 << (7 * 7));
		647	cur = (val >> 7 6) \| 0x80; cur += val >= ((UV)1 << (7 * 6));
		648	cur = (val >> 7 5) \| 0x80; cur += val >= ((UV)1 << (7 * 5));
		649	#endif
602	cur = (val >> 7 4) \| 0x80; cur += val >= (1 << (7 * 4));	650	cur = (val >> 7 4) \| 0x80; cur += val >= ((UV)1 << (7 * 4));
603	cur = (val >> 7 3) \| 0x80; cur += val >= (1 << (7 * 3));	651	cur = (val >> 7 3) \| 0x80; cur += val >= ((UV)1 << (7 * 3));
604	cur = (val >> 7 2) \| 0x80; cur += val >= (1 << (7 * 2));	652	cur = (val >> 7 2) \| 0x80; cur += val >= ((UV)1 << (7 * 2));
605	cur = (val >> 7 1) \| 0x80; cur += val >= (1 << (7 * 1));	653	cur = (val >> 7 1) \| 0x80; cur += val >= ((UV)1 << (7 * 1));
606	*cur = val & 0x7f; cur += 1;	654	*cur = val & 0x7f; cur += 1;
607	}	655	}
608		656
609	static void	657	static void
610	put_w (U32 val)	658	put_w (UV val)
611	{	659	{
612	need (5); // we only handle up to 5 bytes	660	need (5); // we only handle up to 5 bytes
613		661
614	put_w_nocheck (val);	662	put_w_nocheck (val);
615	}	663	}
616		664
617	static U8 *	665	static U8 *
618	put_length_at (U32 val, U8 *cur)	666	put_length_at (UV val, U8 *cur)
619	{	667	{
620	if (val < 0x7fU)	668	if (val < 0x7fU)
621	*cur++ = val;	669	*cur++ = val;
622	else	670	else
623	{	671	{
624	U8 *lenb = cur++;	672	U8 *lenb = cur++;
625		673
		674	#if UVSIZE > 4
		675	cur = val >> 56; cur += cur > 0;
		676	cur = val >> 48; cur += cur > 0;
		677	cur = val >> 40; cur += cur > 0;
		678	cur = val >> 32; cur += cur > 0;
		679	#endif
626	cur = val >> 24; cur += cur > 0;	680	cur = val >> 24; cur += cur > 0;
627	cur = val >> 16; cur += cur > 0;	681	cur = val >> 16; cur += cur > 0;
628	cur = val >> 8; cur += cur > 0;	682	cur = val >> 8; cur += cur > 0;
629	*cur = val ; cur += 1;	683	*cur = val ; cur += 1;
630		684
…		…
633		687
634	return cur;	688	return cur;
635	}	689	}
636		690
637	static void	691	static void
638	put_length (U32 val)	692	put_length (UV val)
639	{	693	{
640	need (5 + val);	694	need (5 + val);
641	cur = put_length_at (val, cur);	695	cur = put_length_at (val, cur);
642	}	696	}
643		697
644	// return how many bytes the encoded length requires	698	// return how many bytes the encoded length requires
645	static int length_length (U32 val)	699	static int length_length (UV val)
646	{	700	{
647	return val < 0x7fU	701	return val < 0x7fU
648	? 1	702	? 1
649	: 2 + (val > 0xffU) + (val > 0xffffU) + (val > 0xffffffU);	703	: 2
		704	+ (val > 0xffU)
		705	+ (val > 0xffffU)
		706	+ (val > 0xffffffU)
		707	#if UVSIZE > 4
		708	+ (val > 0xffffffffU)
		709	+ (val > 0xffffffffffU)
		710	+ (val > 0xffffffffffffU)
		711	+ (val > 0xffffffffffffffU)
		712	#endif
		713	;
650	}	714	}
651		715
652	static void	716	static void
653	encode_data (const char *ptr, STRLEN len)	717	encode_data (const char *ptr, STRLEN len)
654	{	718	{
…		…
716		780
717	*lenb = cur - lenb - 1;	781	*lenb = cur - lenb - 1;
718	}	782	}
719		783
720	// we don't know the length yet, so we optimistically	784	// we don't know the length yet, so we optimistically
721	// assume the length will need one octet later. if that	785	// assume the length will need one octet later. If that
722	// turns out to be wrong, we memove as needed.	786	// turns out to be wrong, we memmove as needed.
723	// mark the beginning	787	// mark the beginning
724	static STRLEN	788	static STRLEN
725	len_fixup_mark ()	789	len_fixup_mark (void)
726	{	790	{
727	return cur++ - buf;	791	return cur++ - buf;
728	}	792	}
729		793
730	// patch up the length	794	// patch up the length
…		…
839	{	903	{
840	AV *av = ber_tuple (tuple);	904	AV *av = ber_tuple (tuple);
841		905
842	int klass = SvIV (AvARRAY (av)[BER_CLASS]);	906	int klass = SvIV (AvARRAY (av)[BER_CLASS]);
843	int tag = SvIV (AvARRAY (av)[BER_TAG]);	907	int tag = SvIV (AvARRAY (av)[BER_TAG]);
844	int constructed = SvIV (AvARRAY (av)[BER_CONSTRUCTED]) ? ASN_CONSTRUCTED : 0;	908	int constructed = SvIV (AvARRAY (av)[BER_FLAGS]) & 1 ? ASN_CONSTRUCTED : 0;
845	SV *data = AvARRAY (av)[BER_DATA];	909	SV *data = AvARRAY (av)[BER_DATA];
846		910
847	int identifier = (klass << ASN_CLASS_SHIFT) \| constructed;	911	int identifier = (klass << ASN_CLASS_SHIFT) \| constructed;
848		912
849	if (expect_false (tag >= ASN_TAG_BER))	913	if (expect_false (tag >= ASN_TAG_BER))
…		…
868	int fill = AvFILL (av);	932	int fill = AvFILL (av);
869		933
870	if (expect_false (SvRMAGICAL (av)))	934	if (expect_false (SvRMAGICAL (av)))
871	croak ("BER constructed data must not be tied");	935	croak ("BER constructed data must not be tied");
872		936
		937	int i;
873	for (int i = 0; i <= fill; ++i)	938	for (i = 0; i <= fill; ++i)
874	encode_ber (AvARRAY (av)[i]);	939	encode_ber (AvARRAY (av)[i]);
875		940
876	len_fixup (mark);	941	len_fixup (mark);
877	}	942	}
878	else	943	else
…		…
882	put_length (0);	947	put_length (0);
883	break;	948	break;
884		949
885	case BER_TYPE_BOOL:	950	case BER_TYPE_BOOL:
886	put_length (1);	951	put_length (1);
887	*cur++ = SvTRUE (data) ? 0xff : 0x00;	952	*cur++ = SvTRUE (data) ? 0xff : 0x00; // 0xff = DER/CER
888	break;	953	break;
889		954
890	case BER_TYPE_OID:	955	case BER_TYPE_OID:
891	encode_oid (data, 0);	956	encode_oid (data, 0);
892	break;	957	break;
…		…
955	const char *name;	1020	const char *name;
956	IV iv;	1021	IV iv;
957	} *civ, const_iv[] = {	1022	} *civ, const_iv[] = {
958	#define const_iv(name) { # name, name },	1023	#define const_iv(name) { # name, name },
959	const_iv (ASN_BOOLEAN)	1024	const_iv (ASN_BOOLEAN)
960	const_iv (ASN_INTEGER32)	1025	const_iv (ASN_INTEGER)
961	const_iv (ASN_BIT_STRING)	1026	const_iv (ASN_BIT_STRING)
962	const_iv (ASN_OCTET_STRING)	1027	const_iv (ASN_OCTET_STRING)
963	const_iv (ASN_NULL)	1028	const_iv (ASN_NULL)
964	const_iv (ASN_OBJECT_IDENTIFIER)	1029	const_iv (ASN_OBJECT_IDENTIFIER)
965	const_iv (ASN_OBJECT_DESCRIPTOR)	1030	const_iv (ASN_OBJECT_DESCRIPTOR)
…		…
994	const_iv (ASN_CONTEXT)	1059	const_iv (ASN_CONTEXT)
995	const_iv (ASN_PRIVATE)	1060	const_iv (ASN_PRIVATE)
996		1061
997	const_iv (BER_CLASS)	1062	const_iv (BER_CLASS)
998	const_iv (BER_TAG)	1063	const_iv (BER_TAG)
999	const_iv (BER_CONSTRUCTED)	1064	const_iv (BER_FLAGS)
1000	const_iv (BER_DATA)	1065	const_iv (BER_DATA)
1001		1066
1002	const_iv (BER_TYPE_BYTES)	1067	const_iv (BER_TYPE_BYTES)
1003	const_iv (BER_TYPE_UTF8)	1068	const_iv (BER_TYPE_UTF8)
1004	const_iv (BER_TYPE_UCS2)	1069	const_iv (BER_TYPE_UCS2)
…		…
1012	const_iv (BER_TYPE_IPADDRESS)	1077	const_iv (BER_TYPE_IPADDRESS)
1013	const_iv (BER_TYPE_CROAK)	1078	const_iv (BER_TYPE_CROAK)
1014		1079
1015	const_iv (SNMP_IPADDRESS)	1080	const_iv (SNMP_IPADDRESS)
1016	const_iv (SNMP_COUNTER32)	1081	const_iv (SNMP_COUNTER32)
		1082	const_iv (SNMP_GAUGE32)
1017	const_iv (SNMP_UNSIGNED32)	1083	const_iv (SNMP_UNSIGNED32)
1018	const_iv (SNMP_TIMETICKS)	1084	const_iv (SNMP_TIMETICKS)
1019	const_iv (SNMP_OPAQUE)	1085	const_iv (SNMP_OPAQUE)
1020	const_iv (SNMP_COUNTER64)	1086	const_iv (SNMP_COUNTER64)
1021	};	1087	};
1022		1088
1023	for (civ = const_iv + sizeof (const_iv) / sizeof (const_iv [0]); civ > const_iv; civ--)	1089	for (civ = const_iv + sizeof (const_iv) / sizeof (const_iv [0]); civ > const_iv; civ--)
1024	newCONSTSUB (stash, (char *)civ[-1].name, newSViv (civ[-1].iv));	1090	newCONSTSUB (stash, (char *)civ[-1].name, newSViv (civ[-1].iv));
1025	}	1091	}
1026		1092
1027	SV *	1093	void
1028	ber_decode (SV ber, SV profile = &PL_sv_undef)	1094	ber_decode (SV ber, SV profile = &PL_sv_undef)
		1095	ALIAS:
		1096	ber_decode_prefix = 1
1029	CODE:	1097	PPCODE:
1030	{	1098	{
1031	cur_profile = SvPROFILE (profile);	1099	cur_profile = SvPROFILE (profile);
1032	STRLEN len;	1100	STRLEN len;
1033	buf = (U8 *)SvPVbyte (ber, len);	1101	buf = (U8 *)SvPVbyte (ber, len);
1034	cur = buf;	1102	cur = buf;
1035	end = buf + len;	1103	end = buf + len;
1036		1104
1037	RETVAL = decode_ber ();	1105	SV *tuple = decode_ber ();
		1106
		1107	EXTEND (SP, 2);
		1108	PUSHs (sv_2mortal (tuple));
		1109
		1110	if (ix)
		1111	PUSHs (sv_2mortal (newSViv (cur - buf)));
		1112	else if (cur != end)
		1113	error ("trailing garbage after BER data");
1038	}	1114	}
1039	OUTPUT: RETVAL
1040		1115
1041	void	1116	void
1042	ber_is (SV tuple, SV klass = &PL_sv_undef, SV tag = &PL_sv_undef, SV constructed = &PL_sv_undef, SV *data = &PL_sv_undef)	1117	ber_is (SV tuple, SV klass = &PL_sv_undef, SV tag = &PL_sv_undef, SV flags = &PL_sv_undef, SV *data = &PL_sv_undef)
1043	PPCODE:	1118	PPCODE:
1044	{	1119	{
1045	if (!SvOK (tuple))	1120	if (!SvOK (tuple))
1046	XSRETURN_NO;	1121	XSRETURN_NO;
1047		1122
…		…
1049	croak ("ber_is: tuple must be BER tuple (array-ref)");	1124	croak ("ber_is: tuple must be BER tuple (array-ref)");
1050		1125
1051	AV av = (AV )SvRV (tuple);	1126	AV av = (AV )SvRV (tuple);
1052		1127
1053	XPUSHs (	1128	XPUSHs (
1054	(!SvOK (klass) \|\| SvIV (AvARRAY (av)[BER_CLASS ]) == SvIV (klass))	1129	(!SvOK (klass) \|\| SvIV (AvARRAY (av)[BER_CLASS]) == SvIV (klass))
1055	&& (!SvOK (tag) \|\| SvIV (AvARRAY (av)[BER_TAG ]) == SvIV (tag))	1130	&& (!SvOK (tag) \|\| SvIV (AvARRAY (av)[BER_TAG ]) == SvIV (tag))
1056	&& (!SvOK (constructed) \|\| !SvIV (AvARRAY (av)[BER_CONSTRUCTED]) == !SvIV (constructed))	1131	&& (!SvOK (flags) \|\| !SvIV (AvARRAY (av)[BER_FLAGS]) == !SvIV (flags))
1057	&& (!SvOK (data) \|\| sv_eq (AvARRAY (av)[BER_DATA ], data))	1132	&& (!SvOK (data) \|\| sv_eq (AvARRAY (av)[BER_DATA ], data))
1058	? &PL_sv_yes : &PL_sv_undef);	1133	? &PL_sv_yes : &PL_sv_undef);
1059	}	1134	}
1060		1135
1061	void	1136	void
1062	ber_is_seq (SV *tuple)	1137	ber_is_seq (SV *tuple)
…		…
1066	XSRETURN_UNDEF;	1141	XSRETURN_UNDEF;
1067		1142
1068	AV *av = ber_tuple (tuple);	1143	AV *av = ber_tuple (tuple);
1069		1144
1070	XPUSHs (	1145	XPUSHs (
1071	SvIV (AvARRAY (av)[BER_CLASS ]) == ASN_UNIVERSAL	1146	SvIV (AvARRAY (av)[BER_CLASS]) == ASN_UNIVERSAL
1072	&& SvIV (AvARRAY (av)[BER_TAG ]) == ASN_SEQUENCE	1147	&& SvIV (AvARRAY (av)[BER_TAG ]) == ASN_SEQUENCE
1073	&& SvIV (AvARRAY (av)[BER_CONSTRUCTED])	1148	&& SvIV (AvARRAY (av)[BER_FLAGS])
1074	? AvARRAY (av)[BER_DATA] : &PL_sv_undef);	1149	? AvARRAY (av)[BER_DATA] : &PL_sv_undef);
1075	}	1150	}
1076		1151
1077	void	1152	void
1078	ber_is_i32 (SV tuple, SV value = &PL_sv_undef)	1153	ber_is_int (SV tuple, SV value = &PL_sv_undef)
1079	PPCODE:	1154	PPCODE:
1080	{	1155	{
1081	if (!SvOK (tuple))	1156	if (!SvOK (tuple))
1082	XSRETURN_NO;	1157	XSRETURN_NO;
1083		1158
1084	AV *av = ber_tuple (tuple);	1159	AV *av = ber_tuple (tuple);
1085		1160
1086	IV data = SvIV (AvARRAY (av)[BER_DATA]);	1161	UV data = SvUV (AvARRAY (av)[BER_DATA]);
1087		1162
1088	XPUSHs (	1163	XPUSHs (
1089	SvIV (AvARRAY (av)[BER_CLASS ]) == ASN_UNIVERSAL	1164	SvIV (AvARRAY (av)[BER_CLASS]) == ASN_UNIVERSAL
1090	&& SvIV (AvARRAY (av)[BER_TAG ]) == ASN_INTEGER32	1165	&& SvIV (AvARRAY (av)[BER_TAG ]) == ASN_INTEGER
1091	&& !SvIV (AvARRAY (av)[BER_CONSTRUCTED])	1166	&& !SvIV (AvARRAY (av)[BER_FLAGS])
1092	&& (!SvOK (value) \|\| data == SvIV (value))	1167	&& (!SvOK (value) \|\| data == SvUV (value))
1093	? sv_2mortal (data ? newSViv (data) : newSVpv ("0 but true", 0))	1168	? sv_2mortal (data ? newSVsv (AvARRAY (av)[BER_DATA]) : newSVpv ("0 but true", 0))
1094	: &PL_sv_undef);	1169	: &PL_sv_undef);
1095	}	1170	}
1096		1171
1097	void	1172	void
1098	ber_is_oid (SV tuple, SV oid = &PL_sv_undef)	1173	ber_is_oid (SV tuple, SV oid = &PL_sv_undef)
…		…
1102	XSRETURN_NO;	1177	XSRETURN_NO;
1103		1178
1104	AV *av = ber_tuple (tuple);	1179	AV *av = ber_tuple (tuple);
1105		1180
1106	XPUSHs (	1181	XPUSHs (
1107	SvIV (AvARRAY (av)[BER_CLASS ]) == ASN_UNIVERSAL	1182	SvIV (AvARRAY (av)[BER_CLASS]) == ASN_UNIVERSAL
1108	&& SvIV (AvARRAY (av)[BER_TAG ]) == ASN_OBJECT_IDENTIFIER	1183	&& SvIV (AvARRAY (av)[BER_TAG ]) == ASN_OBJECT_IDENTIFIER
1109	&& !SvIV (AvARRAY (av)[BER_CONSTRUCTED])	1184	&& !SvIV (AvARRAY (av)[BER_FLAGS])
1110	&& (!SvOK (oid) \|\| sv_eq (AvARRAY (av)[BER_DATA], oid))	1185	&& (!SvOK (oid) \|\| sv_eq (AvARRAY (av)[BER_DATA], oid))
1111	? newSVsv (AvARRAY (av)[BER_DATA]) : &PL_sv_undef);	1186	? newSVsv (AvARRAY (av)[BER_DATA]) : &PL_sv_undef);
1112	}	1187	}
1113		1188
1114	#############################################################################	1189	#############################################################################
…		…
1127	SvCUR_set (buf_sv, cur - buf);	1202	SvCUR_set (buf_sv, cur - buf);
1128	XPUSHs (buf_sv);	1203	XPUSHs (buf_sv);
1129	}	1204	}
1130		1205
1131	SV *	1206	SV *
1132	ber_i32 (IV iv)	1207	ber_int (SV *sv)
1133	CODE:	1208	CODE:
1134	{	1209	{
1135	AV *av = newAV ();	1210	AV *av = newAV ();
1136	av_fill (av, BER_ARRAYSIZE - 1);	1211	av_fill (av, BER_ARRAYSIZE - 1);
1137	AvARRAY (av)[BER_CLASS ] = newSVcacheint (ASN_UNIVERSAL);	1212	AvARRAY (av)[BER_CLASS] = newSVcacheint (ASN_UNIVERSAL);
1138	AvARRAY (av)[BER_TAG ] = newSVcacheint (ASN_INTEGER32);	1213	AvARRAY (av)[BER_TAG ] = newSVcacheint (ASN_INTEGER);
1139	AvARRAY (av)[BER_CONSTRUCTED] = newSVcacheint (0);	1214	AvARRAY (av)[BER_FLAGS] = newSVcacheint (0);
1140	AvARRAY (av)[BER_DATA ] = newSViv (iv);	1215	AvARRAY (av)[BER_DATA ] = newSVsv (sv);
1141	RETVAL = newRV_noinc ((SV *)av);	1216	RETVAL = newRV_noinc ((SV *)av);
1142	}	1217	}
1143	OUTPUT: RETVAL	1218	OUTPUT: RETVAL
1144		1219
1145	# TODO: not arrayref, but elements?	1220	# TODO: not arrayref, but elements?
…		…
1147	ber_seq (SV *arrayref)	1222	ber_seq (SV *arrayref)
1148	CODE:	1223	CODE:
1149	{	1224	{
1150	AV *av = newAV ();	1225	AV *av = newAV ();
1151	av_fill (av, BER_ARRAYSIZE - 1);	1226	av_fill (av, BER_ARRAYSIZE - 1);
1152	AvARRAY (av)[BER_CLASS ] = newSVcacheint (ASN_UNIVERSAL);	1227	AvARRAY (av)[BER_CLASS] = newSVcacheint (ASN_UNIVERSAL);
1153	AvARRAY (av)[BER_TAG ] = newSVcacheint (ASN_SEQUENCE);	1228	AvARRAY (av)[BER_TAG ] = newSVcacheint (ASN_SEQUENCE);
1154	AvARRAY (av)[BER_CONSTRUCTED] = newSVcacheint (1);	1229	AvARRAY (av)[BER_FLAGS] = newSVcacheint (1);
1155	AvARRAY (av)[BER_DATA ] = newSVsv (arrayref);	1230	AvARRAY (av)[BER_DATA ] = newSVsv (arrayref);
1156	RETVAL = newRV_noinc ((SV *)av);	1231	RETVAL = newRV_noinc ((SV *)av);
1157	}	1232	}
1158	OUTPUT: RETVAL	1233	OUTPUT: RETVAL
1159		1234
1160	MODULE = Convert::BER::XS PACKAGE = Convert::BER::XS::Profile	1235	MODULE = Convert::BER::XS PACKAGE = Convert::BER::XS::Profile

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Comparing Convert-BER-XS/XS.xs (file contents): Revision 1.10 by root, Sat Apr 20 11:12:47 2019 UTC vs. Revision 1.23 by root, Sun Apr 21 01:51:12 2019 UTC

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Comparing Convert-BER-XS/XS.xs (file contents):
Revision 1.10 by root, Sat Apr 20 11:12:47 2019 UTC vs.
Revision 1.23 by root, Sun Apr 21 01:51:12 2019 UTC