x509asn1.c source code [Curl/lib/x509asn1.c]

1	/***************************************************************************
2	* _ _ ____ _
3	* Project ___\| \| \| \| _ \\| \|
4	* / __\| \| \| \| \|_) \| \|
5	* \| (__\| \|_\| \| _ <\| \|___
6	* \___\|\___/\|_\| \_\_____\|
7	*
8	* Copyright (C) 1998 - 2019, Daniel Stenberg, <daniel@haxx.se>, et al.
9	*
10	* This software is licensed as described in the file COPYING, which
11	* you should have received as part of this distribution. The terms
12	* are also available at https://curl.haxx.se/docs/copyright.html.
13	*
14	* You may opt to use, copy, modify, merge, publish, distribute and/or sell
15	* copies of the Software, and permit persons to whom the Software is
16	* furnished to do so, under the terms of the COPYING file.
17	*
18	* This software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY
19	* KIND, either express or implied.
20	*
21	***************************************************************************/
22
23	#include "curl_setup.h"
24
25	#if defined(USE_GSKIT) \|\| defined(USE_NSS) \|\| defined(USE_GNUTLS) \|\| \
26	defined(USE_WOLFSSL) \|\| defined(USE_SCHANNEL)
27
28	#include <curl/curl.h>
29	#include "urldata.h"
30	#include "strcase.h"
31	#include "hostcheck.h"
32	#include "vtls/vtls.h"
33	#include "sendf.h"
34	#include "inet_pton.h"
35	#include "curl_base64.h"
36	#include "x509asn1.h"
37
38	/ The last 3 #include files should be in this order /
39	#include "curl_printf.h"
40	#include "curl_memory.h"
41	#include "memdebug.h"
42
43	/ ASN.1 OIDs. /
44	static const char cnOID[] = "2.5.4.3"; / Common name. /
45	static const char sanOID[] = "2.5.29.17"; / Subject alternative name. /
46
47	static const curl_OID OIDtable[] = {
48	{ "1.2.840.10040.4.1", "dsa" },
49	{ "1.2.840.10040.4.3", "dsa-with-sha1" },
50	{ "1.2.840.10045.2.1", "ecPublicKey" },
51	{ "1.2.840.10045.3.0.1", "c2pnb163v1" },
52	{ "1.2.840.10045.4.1", "ecdsa-with-SHA1" },
53	{ "1.2.840.10046.2.1", "dhpublicnumber" },
54	{ "1.2.840.113549.1.1.1", "rsaEncryption" },
55	{ "1.2.840.113549.1.1.2", "md2WithRSAEncryption" },
56	{ "1.2.840.113549.1.1.4", "md5WithRSAEncryption" },
57	{ "1.2.840.113549.1.1.5", "sha1WithRSAEncryption" },
58	{ "1.2.840.113549.1.1.10", "RSASSA-PSS" },
59	{ "1.2.840.113549.1.1.14", "sha224WithRSAEncryption" },
60	{ "1.2.840.113549.1.1.11", "sha256WithRSAEncryption" },
61	{ "1.2.840.113549.1.1.12", "sha384WithRSAEncryption" },
62	{ "1.2.840.113549.1.1.13", "sha512WithRSAEncryption" },
63	{ "1.2.840.113549.2.2", "md2" },
64	{ "1.2.840.113549.2.5", "md5" },
65	{ "1.3.14.3.2.26", "sha1" },
66	{ cnOID, "CN" },
67	{ "2.5.4.4", "SN" },
68	{ "2.5.4.5", "serialNumber" },
69	{ "2.5.4.6", "C" },
70	{ "2.5.4.7", "L" },
71	{ "2.5.4.8", "ST" },
72	{ "2.5.4.9", "streetAddress" },
73	{ "2.5.4.10", "O" },
74	{ "2.5.4.11", "OU" },
75	{ "2.5.4.12", "title" },
76	{ "2.5.4.13", "description" },
77	{ "2.5.4.17", "postalCode" },
78	{ "2.5.4.41", "name" },
79	{ "2.5.4.42", "givenName" },
80	{ "2.5.4.43", "initials" },
81	{ "2.5.4.44", "generationQualifier" },
82	{ "2.5.4.45", "X500UniqueIdentifier" },
83	{ "2.5.4.46", "dnQualifier" },
84	{ "2.5.4.65", "pseudonym" },
85	{ "1.2.840.113549.1.9.1", "emailAddress" },
86	{ "2.5.4.72", "role" },
87	{ sanOID, "subjectAltName" },
88	{ "2.5.29.18", "issuerAltName" },
89	{ "2.5.29.19", "basicConstraints" },
90	{ "2.16.840.1.101.3.4.2.4", "sha224" },
91	{ "2.16.840.1.101.3.4.2.1", "sha256" },
92	{ "2.16.840.1.101.3.4.2.2", "sha384" },
93	{ "2.16.840.1.101.3.4.2.3", "sha512" },
94	{ (const char ) NULL, (const* char *) NULL }
95	};
96
97	/*
98	* Lightweight ASN.1 parser.
99	* In particular, it does not check for syntactic/lexical errors.
100	* It is intended to support certificate information gathering for SSL backends
101	* that offer a mean to get certificates as a whole, but do not supply
102	* entry points to get particular certificate sub-fields.
103	* Please note there is no pretention here to rewrite a full SSL library.
104	*/
105
106	static const char getASN1Element(curl_asn1Element elem,
107	const char beg, const* char *end)
108	WARN_UNUSED_RESULT;
109
110	static const char getASN1Element(curl_asn1Element elem,
111	const char beg, const* char *end)
112	{
113	unsigned char b;
114	unsigned long len;
115	curl_asn1Element lelem;
116
117	/ Get a single ASN.1 element into `elem', parse ASN.1 string at `beg'*
118	ending at `end'.
119	Returns a pointer in source string after the parsed element, or NULL
120	if an error occurs. /*
121	if(!beg \|\| !end \|\| beg >= end \|\| !*beg \|\|
122	(size_t)(end - beg) > CURL_ASN1_MAX)
123	return NULL;
124
125	/ Process header byte. /
126	elem->header = beg;
127	b = (unsigned char) *beg++;
128	elem->constructed = (b & `0x20`) != `0`;
129	elem->class = (b >> `6`) & `3`;
130	b &= `0x1F`;
131	if(b == `0x1F`)
132	return NULL; / Long tag values not supported here. /
133	elem->tag = b;
134
135	/ Process length. /
136	if(beg >= end)
137	return NULL;
138	b = (unsigned char) *beg++;
139	if(!(b & `0x80`))
140	len = b;
141	else if(!(b &= `0x7F`)) {
142	/ Unspecified length. Since we have all the data, we can determine the*
143	effective length by skipping element until an end element is found. /*
144	if(!elem->constructed)
145	return NULL;
146	elem->beg = beg;
147	while(beg < end && *beg) {
148	beg = getASN1Element(&lelem, beg, end);
149	if(!beg)
150	return NULL;
151	}
152	if(beg >= end)
153	return NULL;
154	elem->end = beg;
155	return beg + `1`;
156	}
157	else if((unsigned)b > (size_t)(end - beg))
158	return NULL; / Does not fit in source. /
159	else {
160	/ Get long length. /
161	len = `0`;
162	do {
163	if(len & `0xFF000000L`)
164	return NULL; / Lengths > 32 bits are not supported. /
165	len = (len << `8`) \| (unsigned char) *beg++;
166	} while(--b);
167	}
168	if(len > (size_t)(end - beg))
169	return NULL; / Element data does not fit in source. /
170	elem->beg = beg;
171	elem->end = beg + len;
172	return elem->end;
173	}
174
175	/*
176	* Search the null terminated OID or OID identifier in local table.
177	* Return the table entry pointer or NULL if not found.
178	*/
179	static const curl_OID * searchOID(const char *oid)
180	{
181	const curl_OID *op;
182	for(op = OIDtable; op->numoid; op++)
183	if(!strcmp(op->numoid, oid) \|\| strcasecompare(op->textoid, oid))
184	return op;
185
186	return NULL;
187	}
188
189	/*
190	* Convert an ASN.1 Boolean value into its string representation. Return the
191	* dynamically allocated string, or NULL if source is not an ASN.1 Boolean
192	* value.
193	*/
194
195	static const char bool2str(const* char beg, const* char *end)
196	{
197	if(end - beg != `1`)
198	return NULL;
199	return strdup(*beg? "TRUE": "FALSE");
200	}
201
202	/*
203	* Convert an ASN.1 octet string to a printable string.
204	* Return the dynamically allocated string, or NULL if an error occurs.
205	*/
206	static const char octet2str(const* char beg, const* char *end)
207	{
208	size_t n = end - beg;
209	char *buf = NULL;
210
211	if(n <= (SIZE_T_MAX - `1`) / `3`) {
212	buf = malloc(`3` * n + `1`);
213	if(buf)
214	for(n = `0`; beg < end; n += `3`)
215	msnprintf(buf + n, `4`, "%02x:", (const* unsigned char *) beg++);
216	}
217	return buf;
218	}
219
220	static const char bit2str(const* char beg, const* char *end)
221	{
222	/ Convert an ASN.1 bit string to a printable string.*
223	Return the dynamically allocated string, or NULL if an error occurs. /*
224
225	if(++beg > end)
226	return NULL;
227	return octet2str(beg, end);
228	}
229
230	/*
231	* Convert an ASN.1 integer value into its string representation.
232	* Return the dynamically allocated string, or NULL if source is not an
233	* ASN.1 integer value.
234	*/
235	static const char int2str(const* char beg, const* char *end)
236	{
237	unsigned long val = `0`;
238	size_t n = end - beg;
239
240	if(!n)
241	return NULL;
242
243	if(n > `4`)
244	return octet2str(beg, end);
245
246	/ Represent integers <= 32-bit as a single value. /
247	if(*beg & `0x80`)
248	val = ~val;
249
250	do
251	val = (val << `8`) \| (const* unsigned char *) beg++;
252	while(beg < end);
253	return curl_maprintf("%s%lx", val >= `10`? "0x": "", val);
254	}
255
256	/*
257	* Perform a lazy conversion from an ASN.1 typed string to UTF8. Allocate the
258	* destination buffer dynamically. The allocation size will normally be too
259	* large: this is to avoid buffer overflows.
260	* Terminate the string with a nul byte and return the converted
261	* string length.
262	*/
263	static ssize_t
264	utf8asn1str(char *to, int* type, const char from, const* char *end)
265	{
266	size_t inlength = end - from;
267	int size = `1`;
268	size_t outlength;
269	char *buf;
270
271	*to = NULL;
272	switch(type) {
273	case CURL_ASN1_BMP_STRING:
274	size = `2`;
275	break;
276	case CURL_ASN1_UNIVERSAL_STRING:
277	size = `4`;
278	break;
279	case CURL_ASN1_NUMERIC_STRING:
280	case CURL_ASN1_PRINTABLE_STRING:
281	case CURL_ASN1_TELETEX_STRING:
282	case CURL_ASN1_IA5_STRING:
283	case CURL_ASN1_VISIBLE_STRING:
284	case CURL_ASN1_UTF8_STRING:
285	break;
286	default:
287	return -`1`; / Conversion not supported. /
288	}
289
290	if(inlength % size)
291	return -`1`; / Length inconsistent with character size. /
292	if(inlength / size > (SIZE_T_MAX - `1`) / `4`)
293	return -`1`; / Too big. /
294	buf = malloc(`4` * (inlength / size) + `1`);
295	if(!buf)
296	return -`1`; / Not enough memory. /
297
298	if(type == CURL_ASN1_UTF8_STRING) {
299	/ Just copy. /
300	outlength = inlength;
301	if(outlength)
302	memcpy(buf, from, outlength);
303	}
304	else {
305	for(outlength = `0`; from < end;) {
306	int charsize;
307	unsigned int wc;
308
309	wc = `0`;
310	switch(size) {
311	case `4`:
312	wc = (wc << `8`) \| (const* unsigned char *) from++;
313	wc = (wc << `8`) \| (const* unsigned char *) from++;
314	/ FALLTHROUGH /
315	case `2`:
316	wc = (wc << `8`) \| (const* unsigned char *) from++;
317	/ FALLTHROUGH /
318	default: / case 1: /
319	wc = (wc << `8`) \| (const* unsigned char *) from++;
320	}
321	charsize = `1`;
322	if(wc >= `0x00000080`) {
323	if(wc >= `0x00000800`) {
324	if(wc >= `0x00010000`) {
325	if(wc >= `0x00200000`) {
326	free(buf);
327	return -`1`; / Invalid char. size for target encoding. /
328	}
329	buf[outlength + `3`] = (char) (`0x80` \| (wc & `0x3F`));
330	wc = (wc >> `6`) \| `0x00010000`;
331	charsize++;
332	}
333	buf[outlength + `2`] = (char) (`0x80` \| (wc & `0x3F`));
334	wc = (wc >> `6`) \| `0x00000800`;
335	charsize++;
336	}
337	buf[outlength + `1`] = (char) (`0x80` \| (wc & `0x3F`));
338	wc = (wc >> `6`) \| `0x000000C0`;
339	charsize++;
340	}
341	buf[outlength] = (char) wc;
342	outlength += charsize;
343	}
344	}
345	buf[outlength] = `'\0'`;
346	*to = buf;
347	return outlength;
348	}
349
350	/*
351	* Convert an ASN.1 String into its UTF-8 string representation.
352	* Return the dynamically allocated string, or NULL if an error occurs.
353	*/
354	static const char string2str(int* type, const char beg, const* char *end)
355	{
356	char *buf;
357	if(utf8asn1str(&buf, type, beg, end) < `0`)
358	return NULL;
359	return buf;
360	}
361
362	/*
363	* Decimal ASCII encode unsigned integer `x' into the buflen sized buffer at
364	* buf. Return the total number of encoded digits, even if larger than
365	* `buflen'.
366	*/
367	static size_t encodeUint(char buf, size_t buflen, unsigned* int x)
368	{
369	size_t i = `0`;
370	unsigned int y = x / `10`;
371
372	if(y) {
373	i = encodeUint(buf, buflen, y);
374	x -= y * `10`;
375	}
376	if(i < buflen)
377	buf[i] = (char) (`'0'` + x);
378	i++;
379	if(i < buflen)
380	buf[i] = `'\0'`; / Store a terminator if possible. /
381	return i;
382	}
383
384	/*
385	* Convert an ASN.1 OID into its dotted string representation.
386	* Store the result in th `n'-byte buffer at `buf'.
387	* Return the converted string length, or 0 on errors.
388	*/
389	static size_t encodeOID(char *buf, size_t buflen,
390	const char beg, const* char *end)
391	{
392	size_t i;
393	unsigned int x;
394	unsigned int y;
395
396	/ Process the first two numbers. /
397	y = (const* unsigned char *) beg++;
398	x = y / `40`;
399	y -= x * `40`;
400	i = encodeUint(buf, buflen, x);
401	if(i < buflen)
402	buf[i] = `'.'`;
403	i++;
404	if(i >= buflen)
405	i += encodeUint(NULL, `0`, y);
406	else
407	i += encodeUint(buf + i, buflen - i, y);
408
409	/ Process the trailing numbers. /
410	while(beg < end) {
411	if(i < buflen)
412	buf[i] = `'.'`;
413	i++;
414	x = `0`;
415	do {
416	if(x & `0xFF000000`)
417	return `0`;
418	y = (const* unsigned char *) beg++;
419	x = (x << `7`) \| (y & `0x7F`);
420	} while(y & `0x80`);
421	if(i >= buflen)
422	i += encodeUint(NULL, `0`, x);
423	else
424	i += encodeUint(buf + i, buflen - i, x);
425	}
426	if(i < buflen)
427	buf[i] = `'\0'`;
428	return i;
429	}
430
431	/*
432	* Convert an ASN.1 OID into its dotted or symbolic string representation.
433	* Return the dynamically allocated string, or NULL if an error occurs.
434	*/
435
436	static const char OID2str(const* char beg, const* char *end, bool symbolic)
437	{
438	char *buf = NULL;
439	if(beg < end) {
440	size_t buflen = encodeOID(NULL, `0`, beg, end);
441	if(buflen) {
442	buf = malloc(buflen + `1`); / one extra for the zero byte /
443	if(buf) {
444	encodeOID(buf, buflen, beg, end);
445	buf[buflen] = `'\0'`;
446
447	if(symbolic) {
448	const curl_OID *op = searchOID(buf);
449	if(op) {
450	free(buf);
451	buf = strdup(op->textoid);
452	}
453	}
454	}
455	}
456	}
457	return buf;
458	}
459
460	static const char GTime2str(const* char beg, const* char *end)
461	{
462	const char *tzp;
463	const char *fracp;
464	char sec1, sec2;
465	size_t fracl;
466	size_t tzl;
467	const char *sep = "";
468
469	/ Convert an ASN.1 Generalized time to a printable string.*
470	Return the dynamically allocated string, or NULL if an error occurs. /*
471
472	for(fracp = beg; fracp < end && fracp >= `'0'` && fracp <= `'9'`; fracp++)
473	;
474
475	/ Get seconds digits. /
476	sec1 = `'0'`;
477	switch(fracp - beg - `12`) {
478	case `0`:
479	sec2 = `'0'`;
480	break;
481	case `2`:
482	sec1 = fracp[-`2`];
483	/ FALLTHROUGH /
484	case `1`:
485	sec2 = fracp[-`1`];
486	break;
487	default:
488	return NULL;
489	}
490
491	/ Scan for timezone, measure fractional seconds. /
492	tzp = fracp;
493	fracl = `0`;
494	if(fracp < end && (fracp == `'.'` \|\| fracp == `','`)) {
495	fracp++;
496	do
497	tzp++;
498	while(tzp < end && tzp >= `'0'` && tzp <= `'9'`);
499	/ Strip leading zeroes in fractional seconds. /
500	for(fracl = tzp - fracp - `1`; fracl && fracp[fracl - `1`] == `'0'`; fracl--)
501	;
502	}
503
504	/ Process timezone. /
505	if(tzp >= end)
506	; / Nothing to do. /
507	else if(*tzp == `'Z'`) {
508	tzp = " GMT";
509	end = tzp + `4`;
510	}
511	else {
512	sep = " ";
513	tzp++;
514	}
515
516	tzl = end - tzp;
517	return curl_maprintf("%.4s-%.2s-%.2s %.2s:%.2s:%c%c%s%.s%s%.s",
518	beg, beg + `4`, beg + `6`,
519	beg + `8`, beg + `10`, sec1, sec2,
520	fracl? ".": "", fracl, fracp,
521	sep, tzl, tzp);
522	}
523
524	/*
525	* Convert an ASN.1 UTC time to a printable string.
526	* Return the dynamically allocated string, or NULL if an error occurs.
527	*/
528	static const char UTime2str(const* char beg, const* char *end)
529	{
530	const char *tzp;
531	size_t tzl;
532	const char *sec;
533
534	for(tzp = beg; tzp < end && tzp >= `'0'` && tzp <= `'9'`; tzp++)
535	;
536	/ Get the seconds. /
537	sec = beg + `10`;
538	switch(tzp - sec) {
539	case `0`:
540	sec = "00";
541	case `2`:
542	break;
543	default:
544	return NULL;
545	}
546
547	/ Process timezone. /
548	if(tzp >= end)
549	return NULL;
550	if(*tzp == `'Z'`) {
551	tzp = "GMT";
552	end = tzp + `3`;
553	}
554	else
555	tzp++;
556
557	tzl = end - tzp;
558	return curl_maprintf("%u%.2s-%.2s-%.2s %.2s:%.2s:%.2s %.*s",
559	`20` - (*beg >= `'5'`), beg, beg + `2`, beg + `4`,
560	beg + `6`, beg + `8`, sec,
561	tzl, tzp);
562	}
563
564	/*
565	* Convert an ASN.1 element to a printable string.
566	* Return the dynamically allocated string, or NULL if an error occurs.
567	*/
568	static const char ASN1tostr(curl_asn1Element elem, int type)
569	{
570	if(elem->constructed)
571	return NULL; / No conversion of structured elements. /
572
573	if(!type)
574	type = elem->tag; / Type not forced: use element tag as type. /
575
576	switch(type) {
577	case CURL_ASN1_BOOLEAN:
578	return bool2str(elem->beg, elem->end);
579	case CURL_ASN1_INTEGER:
580	case CURL_ASN1_ENUMERATED:
581	return int2str(elem->beg, elem->end);
582	case CURL_ASN1_BIT_STRING:
583	return bit2str(elem->beg, elem->end);
584	case CURL_ASN1_OCTET_STRING:
585	return octet2str(elem->beg, elem->end);
586	case CURL_ASN1_NULL:
587	return strdup("");
588	case CURL_ASN1_OBJECT_IDENTIFIER:
589	return OID2str(elem->beg, elem->end, TRUE);
590	case CURL_ASN1_UTC_TIME:
591	return UTime2str(elem->beg, elem->end);
592	case CURL_ASN1_GENERALIZED_TIME:
593	return GTime2str(elem->beg, elem->end);
594	case CURL_ASN1_UTF8_STRING:
595	case CURL_ASN1_NUMERIC_STRING:
596	case CURL_ASN1_PRINTABLE_STRING:
597	case CURL_ASN1_TELETEX_STRING:
598	case CURL_ASN1_IA5_STRING:
599	case CURL_ASN1_VISIBLE_STRING:
600	case CURL_ASN1_UNIVERSAL_STRING:
601	case CURL_ASN1_BMP_STRING:
602	return string2str(type, elem->beg, elem->end);
603	}
604
605	return NULL; / Unsupported. /
606	}
607
608	/*
609	* ASCII encode distinguished name at `dn' into the `buflen'-sized buffer at
610	* `buf'. Return the total string length, even if larger than `buflen'.
611	*/
612	static ssize_t encodeDN(char buf, size_t buflen, curl_asn1Element dn)
613	{
614	curl_asn1Element rdn;
615	curl_asn1Element atv;
616	curl_asn1Element oid;
617	curl_asn1Element value;
618	size_t l = `0`;
619	const char *p1;
620	const char *p2;
621	const char *p3;
622	const char *str;
623
624	for(p1 = dn->beg; p1 < dn->end;) {
625	p1 = getASN1Element(&rdn, p1, dn->end);
626	if(!p1)
627	return -`1`;
628	for(p2 = rdn.beg; p2 < rdn.end;) {
629	p2 = getASN1Element(&atv, p2, rdn.end);
630	if(!p2)
631	return -`1`;
632	p3 = getASN1Element(&oid, atv.beg, atv.end);
633	if(!p3)
634	return -`1`;
635	if(!getASN1Element(&value, p3, atv.end))
636	return -`1`;
637	str = ASN1tostr(&oid, `0`);
638	if(!str)
639	return -`1`;
640
641	/ Encode delimiter.*
642	If attribute has a short uppercase name, delimiter is ", ". /*
643	if(l) {
644	for(p3 = str; isupper(*p3); p3++)
645	;
646	for(p3 = (p3 \|\| p3 - str > `2`)? "/": ", "; p3; p3++) {
647	if(l < buflen)
648	buf[l] = *p3;
649	l++;
650	}
651	}
652
653	/ Encode attribute name. /
654	for(p3 = str; *p3; p3++) {
655	if(l < buflen)
656	buf[l] = *p3;
657	l++;
658	}
659	free((char *) str);
660
661	/ Generate equal sign. /
662	if(l < buflen)
663	buf[l] = `'='`;
664	l++;
665
666	/ Generate value. /
667	str = ASN1tostr(&value, `0`);
668	if(!str)
669	return -`1`;
670	for(p3 = str; *p3; p3++) {
671	if(l < buflen)
672	buf[l] = *p3;
673	l++;
674	}
675	free((char *) str);
676	}
677	}
678
679	return l;
680	}
681
682	/*
683	* Convert an ASN.1 distinguished name into a printable string.
684	* Return the dynamically allocated string, or NULL if an error occurs.
685	*/
686	static const char DNtostr(curl_asn1Element dn)
687	{
688	char *buf = NULL;
689	ssize_t buflen = encodeDN(NULL, `0`, dn);
690
691	if(buflen >= `0`) {
692	buf = malloc(buflen + `1`);
693	if(buf) {
694	encodeDN(buf, buflen + `1`, dn);
695	buf[buflen] = `'\0'`;
696	}
697	}
698	return buf;
699	}
700
701	/*
702	* ASN.1 parse an X509 certificate into structure subfields.
703	* Syntax is assumed to have already been checked by the SSL backend.
704	* See RFC 5280.
705	*/
706	int Curl_parseX509(curl_X509certificate *cert,
707	const char beg, const* char *end)
708	{
709	curl_asn1Element elem;
710	curl_asn1Element tbsCertificate;
711	const char *ccp;
712	static const char defaultVersion = `0`; / v1. /
713
714	cert->certificate.header = NULL;
715	cert->certificate.beg = beg;
716	cert->certificate.end = end;
717
718	/ Get the sequence content. /
719	if(!getASN1Element(&elem, beg, end))
720	return -`1`; / Invalid bounds/size. /
721	beg = elem.beg;
722	end = elem.end;
723
724	/ Get tbsCertificate. /
725	beg = getASN1Element(&tbsCertificate, beg, end);
726	if(!beg)
727	return -`1`;
728	/ Skip the signatureAlgorithm. /
729	beg = getASN1Element(&cert->signatureAlgorithm, beg, end);
730	if(!beg)
731	return -`1`;
732	/ Get the signatureValue. /
733	if(!getASN1Element(&cert->signature, beg, end))
734	return -`1`;
735
736	/ Parse TBSCertificate. /
737	beg = tbsCertificate.beg;
738	end = tbsCertificate.end;
739	/ Get optional version, get serialNumber. /
740	cert->version.header = NULL;
741	cert->version.beg = &defaultVersion;
742	cert->version.end = &defaultVersion + sizeof(defaultVersion);
743	beg = getASN1Element(&elem, beg, end);
744	if(!beg)
745	return -`1`;
746	if(elem.tag == `0`) {
747	if(!getASN1Element(&cert->version, elem.beg, elem.end))
748	return -`1`;
749	beg = getASN1Element(&elem, beg, end);
750	if(!beg)
751	return -`1`;
752	}
753	cert->serialNumber = elem;
754	/ Get signature algorithm. /
755	beg = getASN1Element(&cert->signatureAlgorithm, beg, end);
756	/ Get issuer. /
757	beg = getASN1Element(&cert->issuer, beg, end);
758	if(!beg)
759	return -`1`;
760	/ Get notBefore and notAfter. /
761	beg = getASN1Element(&elem, beg, end);
762	if(!beg)
763	return -`1`;
764	ccp = getASN1Element(&cert->notBefore, elem.beg, elem.end);
765	if(!ccp)
766	return -`1`;
767	if(!getASN1Element(&cert->notAfter, ccp, elem.end))
768	return -`1`;
769	/ Get subject. /
770	beg = getASN1Element(&cert->subject, beg, end);
771	if(!beg)
772	return -`1`;
773	/ Get subjectPublicKeyAlgorithm and subjectPublicKey. /
774	beg = getASN1Element(&cert->subjectPublicKeyInfo, beg, end);
775	if(!beg)
776	return -`1`;
777	ccp = getASN1Element(&cert->subjectPublicKeyAlgorithm,
778	cert->subjectPublicKeyInfo.beg,
779	cert->subjectPublicKeyInfo.end);
780	if(!ccp)
781	return -`1`;
782	if(!getASN1Element(&cert->subjectPublicKey, ccp,
783	cert->subjectPublicKeyInfo.end))
784	return -`1`;
785	/ Get optional issuerUiqueID, subjectUniqueID and extensions. /
786	cert->issuerUniqueID.tag = cert->subjectUniqueID.tag = `0`;
787	cert->extensions.tag = elem.tag = `0`;
788	cert->issuerUniqueID.header = cert->subjectUniqueID.header = NULL;
789	cert->issuerUniqueID.beg = cert->issuerUniqueID.end = "";
790	cert->subjectUniqueID.beg = cert->subjectUniqueID.end = "";
791	cert->extensions.header = NULL;
792	cert->extensions.beg = cert->extensions.end = "";
793	if(beg < end) {
794	beg = getASN1Element(&elem, beg, end);
795	if(!beg)
796	return -`1`;
797	}
798	if(elem.tag == `1`) {
799	cert->issuerUniqueID = elem;
800	if(beg < end) {
801	beg = getASN1Element(&elem, beg, end);
802	if(!beg)
803	return -`1`;
804	}
805	}
806	if(elem.tag == `2`) {
807	cert->subjectUniqueID = elem;
808	if(beg < end) {
809	beg = getASN1Element(&elem, beg, end);
810	if(!beg)
811	return -`1`;
812	}
813	}
814	if(elem.tag == `3`)
815	if(!getASN1Element(&cert->extensions, elem.beg, elem.end))
816	return -`1`;
817	return `0`;
818	}
819
820
821	/*
822	* Copy at most 64-characters, terminate with a newline and returns the
823	* effective number of stored characters.
824	*/
825	static size_t copySubstring(char to, const* char *from)
826	{
827	size_t i;
828	for(i = `0`; i < `64`; i++) {
829	to[i] = *from;
830	if(!*from++)
831	break;
832	}
833
834	to[i++] = `'\n'`;
835	return i;
836	}
837
838	static const char dumpAlgo(curl_asn1Element param,
839	const char beg, const* char *end)
840	{
841	curl_asn1Element oid;
842
843	/ Get algorithm parameters and return algorithm name. /
844
845	beg = getASN1Element(&oid, beg, end);
846	if(!beg)
847	return NULL;
848	param->header = NULL;
849	param->tag = `0`;
850	param->beg = param->end = end;
851	if(beg < end)
852	if(!getASN1Element(param, beg, end))
853	return NULL;
854	return OID2str(oid.beg, oid.end, TRUE);
855	}
856
857	static void do_pubkey_field(struct Curl_easy data, int* certnum,
858	const char label, curl_asn1Element elem)
859	{
860	const char *output;
861
862	/ Generate a certificate information record for the public key. /
863
864	output = ASN1tostr(elem, `0`);
865	if(output) {
866	if(data->set.ssl.certinfo)
867	Curl_ssl_push_certinfo(data, certnum, label, output);
868	if(!certnum)
869	infof(data, " %s: %s\n", label, output);
870	free((char *) output);
871	}
872	}
873
874	static void do_pubkey(struct Curl_easy data, int* certnum,
875	const char algo, curl_asn1Element param,
876	curl_asn1Element *pubkey)
877	{
878	curl_asn1Element elem;
879	curl_asn1Element pk;
880	const char *p;
881
882	/ Generate all information records for the public key. /
883
884	/ Get the public key (single element). /
885	if(!getASN1Element(&pk, pubkey->beg + `1`, pubkey->end))
886	return;
887
888	if(strcasecompare(algo, "rsaEncryption")) {
889	const char *q;
890	unsigned long len;
891
892	p = getASN1Element(&elem, pk.beg, pk.end);
893	if(!p)
894	return;
895
896	/ Compute key length. /
897	for(q = elem.beg; !*q && q < elem.end; q++)
898	;
899	len = (unsigned long)((elem.end - q) * `8`);
900	if(len) {
901	unsigned int i;
902	for(i = (unsigned* char *) q; !(i & `0x80`); i <<= `1`)
903	len--;
904	}
905	if(len > `32`)
906	elem.beg = q; / Strip leading zero bytes. /
907	if(!certnum)
908	infof(data, " RSA Public Key (%lu bits)\n", len);
909	if(data->set.ssl.certinfo) {
910	q = curl_maprintf("%lu", len);
911	if(q) {
912	Curl_ssl_push_certinfo(data, certnum, "RSA Public Key", q);
913	free((char *) q);
914	}
915	}
916	/ Generate coefficients. /
917	do_pubkey_field(data, certnum, "rsa(n)", &elem);
918	if(!getASN1Element(&elem, p, pk.end))
919	return;
920	do_pubkey_field(data, certnum, "rsa(e)", &elem);
921	}
922	else if(strcasecompare(algo, "dsa")) {
923	p = getASN1Element(&elem, param->beg, param->end);
924	if(p) {
925	do_pubkey_field(data, certnum, "dsa(p)", &elem);
926	p = getASN1Element(&elem, p, param->end);
927	if(p) {
928	do_pubkey_field(data, certnum, "dsa(q)", &elem);
929	if(getASN1Element(&elem, p, param->end)) {
930	do_pubkey_field(data, certnum, "dsa(g)", &elem);
931	do_pubkey_field(data, certnum, "dsa(pub_key)", &pk);
932	}
933	}
934	}
935	}
936	else if(strcasecompare(algo, "dhpublicnumber")) {
937	p = getASN1Element(&elem, param->beg, param->end);
938	if(p) {
939	do_pubkey_field(data, certnum, "dh(p)", &elem);
940	if(getASN1Element(&elem, param->beg, param->end)) {
941	do_pubkey_field(data, certnum, "dh(g)", &elem);
942	do_pubkey_field(data, certnum, "dh(pub_key)", &pk);
943	}
944	}
945	}
946	}
947
948	CURLcode Curl_extract_certinfo(struct connectdata *conn,
949	int certnum,
950	const char *beg,
951	const char *end)
952	{
953	curl_X509certificate cert;
954	struct Curl_easy *data = conn->data;
955	curl_asn1Element param;
956	const char *ccp;
957	char *cp1;
958	size_t cl1;
959	char *cp2;
960	CURLcode result;
961	unsigned long version;
962	size_t i;
963	size_t j;
964
965	if(!data->set.ssl.certinfo)
966	if(certnum)
967	return CURLE_OK;
968
969	/ Prepare the certificate information for curl_easy_getinfo(). /
970
971	/ Extract the certificate ASN.1 elements. /
972	if(Curl_parseX509(&cert, beg, end))
973	return CURLE_PEER_FAILED_VERIFICATION;
974
975	/ Subject. /
976	ccp = DNtostr(&cert.subject);
977	if(!ccp)
978	return CURLE_OUT_OF_MEMORY;
979	if(data->set.ssl.certinfo)
980	Curl_ssl_push_certinfo(data, certnum, "Subject", ccp);
981	if(!certnum)
982	infof(data, "%2d Subject: %s\n", certnum, ccp);
983	free((char *) ccp);
984
985	/ Issuer. /
986	ccp = DNtostr(&cert.issuer);
987	if(!ccp)
988	return CURLE_OUT_OF_MEMORY;
989	if(data->set.ssl.certinfo)
990	Curl_ssl_push_certinfo(data, certnum, "Issuer", ccp);
991	if(!certnum)
992	infof(data, " Issuer: %s\n", ccp);
993	free((char *) ccp);
994
995	/ Version (always fits in less than 32 bits). /
996	version = `0`;
997	for(ccp = cert.version.beg; ccp < cert.version.end; ccp++)
998	version = (version << `8`) \| (const* unsigned char *) ccp;
999	if(data->set.ssl.certinfo) {
1000	ccp = curl_maprintf("%lx", version);
1001	if(!ccp)
1002	return CURLE_OUT_OF_MEMORY;
1003	Curl_ssl_push_certinfo(data, certnum, "Version", ccp);
1004	free((char *) ccp);
1005	}
1006	if(!certnum)
1007	infof(data, " Version: %lu (0x%lx)\n", version + `1`, version);
1008
1009	/ Serial number. /
1010	ccp = ASN1tostr(&cert.serialNumber, `0`);
1011	if(!ccp)
1012	return CURLE_OUT_OF_MEMORY;
1013	if(data->set.ssl.certinfo)
1014	Curl_ssl_push_certinfo(data, certnum, "Serial Number", ccp);
1015	if(!certnum)
1016	infof(data, " Serial Number: %s\n", ccp);
1017	free((char *) ccp);
1018
1019	/ Signature algorithm ./
1020	ccp = dumpAlgo(&param, cert.signatureAlgorithm.beg,
1021	cert.signatureAlgorithm.end);
1022	if(!ccp)
1023	return CURLE_OUT_OF_MEMORY;
1024	if(data->set.ssl.certinfo)
1025	Curl_ssl_push_certinfo(data, certnum, "Signature Algorithm", ccp);
1026	if(!certnum)
1027	infof(data, " Signature Algorithm: %s\n", ccp);
1028	free((char *) ccp);
1029
1030	/ Start Date. /
1031	ccp = ASN1tostr(&cert.notBefore, `0`);
1032	if(!ccp)
1033	return CURLE_OUT_OF_MEMORY;
1034	if(data->set.ssl.certinfo)
1035	Curl_ssl_push_certinfo(data, certnum, "Start Date", ccp);
1036	if(!certnum)
1037	infof(data, " Start Date: %s\n", ccp);
1038	free((char *) ccp);
1039
1040	/ Expire Date. /
1041	ccp = ASN1tostr(&cert.notAfter, `0`);
1042	if(!ccp)
1043	return CURLE_OUT_OF_MEMORY;
1044	if(data->set.ssl.certinfo)
1045	Curl_ssl_push_certinfo(data, certnum, "Expire Date", ccp);
1046	if(!certnum)
1047	infof(data, " Expire Date: %s\n", ccp);
1048	free((char *) ccp);
1049
1050	/ Public Key Algorithm. /
1051	ccp = dumpAlgo(&param, cert.subjectPublicKeyAlgorithm.beg,
1052	cert.subjectPublicKeyAlgorithm.end);
1053	if(!ccp)
1054	return CURLE_OUT_OF_MEMORY;
1055	if(data->set.ssl.certinfo)
1056	Curl_ssl_push_certinfo(data, certnum, "Public Key Algorithm", ccp);
1057	if(!certnum)
1058	infof(data, " Public Key Algorithm: %s\n", ccp);
1059	do_pubkey(data, certnum, ccp, &param, &cert.subjectPublicKey);
1060	free((char *) ccp);
1061
1062	/ Signature. /
1063	ccp = ASN1tostr(&cert.signature, `0`);
1064	if(!ccp)
1065	return CURLE_OUT_OF_MEMORY;
1066	if(data->set.ssl.certinfo)
1067	Curl_ssl_push_certinfo(data, certnum, "Signature", ccp);
1068	if(!certnum)
1069	infof(data, " Signature: %s\n", ccp);
1070	free((char *) ccp);
1071
1072	/ Generate PEM certificate. /
1073	result = Curl_base64_encode(data, cert.certificate.beg,
1074	cert.certificate.end - cert.certificate.beg,
1075	&cp1, &cl1);
1076	if(result)
1077	return result;
1078	/ Compute the number of characters in final certificate string. Format is:*
1079	-----BEGIN CERTIFICATE-----\n
1080	<max 64 base64 characters>\n
1081	.
1082	.
1083	.
1084	-----END CERTIFICATE-----\n
1085	*/
1086	i = `28` + cl1 + (cl1 + `64` - `1`) / `64` + `26`;
1087	cp2 = malloc(i + `1`);
1088	if(!cp2) {
1089	free(cp1);
1090	return CURLE_OUT_OF_MEMORY;
1091	}
1092	/ Build the certificate string. /
1093	i = copySubstring(cp2, "-----BEGIN CERTIFICATE-----");
1094	for(j = `0`; j < cl1; j += `64`)
1095	i += copySubstring(cp2 + i, cp1 + j);
1096	i += copySubstring(cp2 + i, "-----END CERTIFICATE-----");
1097	cp2[i] = `'\0'`;
1098	free(cp1);
1099	if(data->set.ssl.certinfo)
1100	Curl_ssl_push_certinfo(data, certnum, "Cert", cp2);
1101	if(!certnum)
1102	infof(data, "%s\n", cp2);
1103	free(cp2);
1104	return CURLE_OK;
1105	}
1106
1107	#endif /* USE_GSKIT or USE_NSS or USE_GNUTLS or USE_WOLFSSL or USE_SCHANNEL */
1108
1109	#if defined(USE_GSKIT)
1110
1111	static const char checkOID(const* char beg, const* char *end,
1112	const char *oid)
1113	{
1114	curl_asn1Element e;
1115	const char *ccp;
1116	const char *p;
1117	bool matched;
1118
1119	/ Check if first ASN.1 element at `beg' is the given OID.*
1120	Return a pointer in the source after the OID if found, else NULL. /*
1121
1122	ccp = getASN1Element(&e, beg, end);
1123	if(!ccp \|\| e.tag != CURL_ASN1_OBJECT_IDENTIFIER)
1124	return NULL;
1125
1126	p = OID2str(e.beg, e.end, FALSE);
1127	if(!p)
1128	return NULL;
1129
1130	matched = !strcmp(p, oid);
1131	free((char *) p);
1132	return matched? ccp: NULL;
1133	}
1134
1135	CURLcode Curl_verifyhost(struct connectdata *conn,
1136	const char beg, const* char *end)
1137	{
1138	struct Curl_easy *data = conn->data;
1139	curl_X509certificate cert;
1140	curl_asn1Element dn;
1141	curl_asn1Element elem;
1142	curl_asn1Element ext;
1143	curl_asn1Element name;
1144	const char *p;
1145	const char *q;
1146	char *dnsname;
1147	int matched = -`1`;
1148	size_t addrlen = (size_t) -`1`;
1149	ssize_t len;
1150	const char * const hostname = SSL_IS_PROXY()? conn->http_proxy.host.name:
1151	conn->host.name;
1152	const char * const dispname = SSL_IS_PROXY()?
1153	conn->http_proxy.host.dispname:
1154	conn->host.dispname;
1155	#ifdef ENABLE_IPV6
1156	struct in6_addr addr;
1157	#else
1158	struct in_addr addr;
1159	#endif
1160
1161	/ Verify that connection server matches info in X509 certificate at*
1162	`beg'..`end'. /*
1163
1164	if(!SSL_CONN_CONFIG(verifyhost))
1165	return CURLE_OK;
1166
1167	if(Curl_parseX509(&cert, beg, end))
1168	return CURLE_PEER_FAILED_VERIFICATION;
1169
1170	/ Get the server IP address. /
1171	#ifdef ENABLE_IPV6
1172	if(conn->bits.ipv6_ip && Curl_inet_pton(AF_INET6, hostname, &addr))
1173	addrlen = sizeof(struct in6_addr);
1174	else
1175	#endif
1176	if(Curl_inet_pton(AF_INET, hostname, &addr))
1177	addrlen = sizeof(struct in_addr);
1178
1179	/ Process extensions. /
1180	for(p = cert.extensions.beg; p < cert.extensions.end && matched != `1`;) {
1181	p = getASN1Element(&ext, p, cert.extensions.end);
1182	if(!p)
1183	return CURLE_PEER_FAILED_VERIFICATION;
1184
1185	/ Check if extension is a subjectAlternativeName. /
1186	ext.beg = checkOID(ext.beg, ext.end, sanOID);
1187	if(ext.beg) {
1188	ext.beg = getASN1Element(&elem, ext.beg, ext.end);
1189	if(!ext.beg)
1190	return CURLE_PEER_FAILED_VERIFICATION;
1191	/ Skip critical if present. /
1192	if(elem.tag == CURL_ASN1_BOOLEAN) {
1193	ext.beg = getASN1Element(&elem, ext.beg, ext.end);
1194	if(!ext.beg)
1195	return CURLE_PEER_FAILED_VERIFICATION;
1196	}
1197	/ Parse the octet string contents: is a single sequence. /
1198	if(!getASN1Element(&elem, elem.beg, elem.end))
1199	return CURLE_PEER_FAILED_VERIFICATION;
1200	/ Check all GeneralNames. /
1201	for(q = elem.beg; matched != `1` && q < elem.end;) {
1202	q = getASN1Element(&name, q, elem.end);
1203	if(!q)
1204	break;
1205	switch(name.tag) {
1206	case `2`: / DNS name. /
1207	len = utf8asn1str(&dnsname, CURL_ASN1_IA5_STRING,
1208	name.beg, name.end);
1209	if(len > `0` && (size_t)len == strlen(dnsname))
1210	matched = Curl_cert_hostcheck(dnsname, hostname);
1211	else
1212	matched = `0`;
1213	free(dnsname);
1214	break;
1215
1216	case `7`: / IP address. /
1217	matched = (size_t) (name.end - name.beg) == addrlen &&
1218	!memcmp(&addr, name.beg, addrlen);
1219	break;
1220	}
1221	}
1222	}
1223	}
1224
1225	switch(matched) {
1226	case `1`:
1227	/ an alternative name matched the server hostname /
1228	infof(data, "\t subjectAltName: %s matched\n", dispname);
1229	return CURLE_OK;
1230	case `0`:
1231	/ an alternative name field existed, but didn't match and then*
1232	we MUST fail /*
1233	infof(data, "\t subjectAltName does not match %s\n", dispname);
1234	return CURLE_PEER_FAILED_VERIFICATION;
1235	}
1236
1237	/ Process subject. /
1238	name.header = NULL;
1239	name.beg = name.end = "";
1240	q = cert.subject.beg;
1241	/ we have to look to the last occurrence of a commonName in the*
1242	distinguished one to get the most significant one. /*
1243	while(q < cert.subject.end) {
1244	q = getASN1Element(&dn, q, cert.subject.end);
1245	if(!q)
1246	break;
1247	for(p = dn.beg; p < dn.end;) {
1248	p = getASN1Element(&elem, p, dn.end);
1249	if(!p)
1250	return CURLE_PEER_FAILED_VERIFICATION;
1251	/ We have a DN's AttributeTypeAndValue: check it in case it's a CN. /
1252	elem.beg = checkOID(elem.beg, elem.end, cnOID);
1253	if(elem.beg)
1254	name = elem; / Latch CN. /
1255	}
1256	}
1257
1258	/ Check the CN if found. /
1259	if(!getASN1Element(&elem, name.beg, name.end))
1260	failf(data, "SSL: unable to obtain common name from peer certificate");
1261	else {
1262	len = utf8asn1str(&dnsname, elem.tag, elem.beg, elem.end);
1263	if(len < `0`) {
1264	free(dnsname);
1265	return CURLE_OUT_OF_MEMORY;
1266	}
1267	if(strlen(dnsname) != (size_t) len) / Nul byte in string ? /
1268	failf(data, "SSL: illegal cert name field");
1269	else if(Curl_cert_hostcheck((const char *) dnsname, hostname)) {
1270	infof(data, "\t common name: %s (matched)\n", dnsname);
1271	free(dnsname);
1272	return CURLE_OK;
1273	}
1274	else
1275	failf(data, "SSL: certificate subject name '%s' does not match "
1276	"target host name '%s'", dnsname, dispname);
1277	free(dnsname);
1278	}
1279
1280	return CURLE_PEER_FAILED_VERIFICATION;
1281	}
1282
1283	#endif /* USE_GSKIT */
1284

Browse the source code of Curl/lib/x509asn1.c