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crypto.c

Last change on this file was 1, checked in by Paul Smedley, 10 years ago
Initial commit of Heimdal 1.5.3
File size: 66.6 KB

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1	/*
2	* Copyright (c) 1997 - 2008 Kungliga Tekniska HÃ¶gskolan
3	* (Royal Institute of Technology, Stockholm, Sweden).
4	* All rights reserved.
5	*
6	* Redistribution and use in source and binary forms, with or without
7	* modification, are permitted provided that the following conditions
8	* are met:
9	*
10	* 1. Redistributions of source code must retain the above copyright
11	* notice, this list of conditions and the following disclaimer.
12	*
13	* 2. Redistributions in binary form must reproduce the above copyright
14	* notice, this list of conditions and the following disclaimer in the
15	* documentation and/or other materials provided with the distribution.
16	*
17	* 3. Neither the name of the Institute nor the names of its contributors
18	* may be used to endorse or promote products derived from this software
19	* without specific prior written permission.
20	*
21	* THIS SOFTWARE IS PROVIDED BY THE INSTITUTE AND CONTRIBUTORS ``AS IS'' AND
22	* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
23	* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
24	* ARE DISCLAIMED. IN NO EVENT SHALL THE INSTITUTE OR CONTRIBUTORS BE LIABLE
25	* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
26	* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
27	* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
28	* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
29	* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
30	* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
31	* SUCH DAMAGE.
32	*/
33
34	#include "krb5_locl.h"
35
36	struct _krb5_key_usage {
37	unsigned usage;
38	struct _krb5_key_data key;
39	};
40
41
42	#ifndef HEIMDAL_SMALLER
43	#define DES3_OLD_ENCTYPE 1
44	#endif
45
46	static krb5_error_code _get_derived_key(krb5_context, krb5_crypto,
47	unsigned, struct _krb5_key_data**);
48	static struct _krb5_key_data *_new_derived_key(krb5_crypto crypto, unsigned usage);
49
50	static void free_key_schedule(krb5_context,
51	struct _krb5_key_data *,
52	struct _krb5_encryption_type *);
53
54	/*
55	* Converts etype to a user readable string and sets as a side effect
56	* the krb5_error_message containing this string. Returns
57	* KRB5_PROG_ETYPE_NOSUPP in not the conversion of the etype failed in
58	* which case the error code of the etype convesion is returned.
59	*/
60
61	static krb5_error_code
62	unsupported_enctype(krb5_context context, krb5_enctype etype)
63	{
64	krb5_error_code ret;
65	char *name;
66
67	ret = krb5_enctype_to_string(context, etype, &name);
68	if (ret)
69	return ret;
70
71	krb5_set_error_message(context, KRB5_PROG_ETYPE_NOSUPP,
72	N_("Encryption type %s not supported", ""),
73	name);
74	free(name);
75	return KRB5_PROG_ETYPE_NOSUPP;
76	}
77
78	/*
79	*
80	*/
81
82	KRB5_LIB_FUNCTION krb5_error_code KRB5_LIB_CALL
83	krb5_enctype_keysize(krb5_context context,
84	krb5_enctype type,
85	size_t *keysize)
86	{
87	struct _krb5_encryption_type *et = _krb5_find_enctype(type);
88	if(et == NULL) {
89	return unsupported_enctype (context, type);
90	}
91	*keysize = et->keytype->size;
92	return 0;
93	}
94
95	KRB5_LIB_FUNCTION krb5_error_code KRB5_LIB_CALL
96	krb5_enctype_keybits(krb5_context context,
97	krb5_enctype type,
98	size_t *keybits)
99	{
100	struct _krb5_encryption_type *et = _krb5_find_enctype(type);
101	if(et == NULL) {
102	return unsupported_enctype (context, type);
103	}
104	*keybits = et->keytype->bits;
105	return 0;
106	}
107
108	KRB5_LIB_FUNCTION krb5_error_code KRB5_LIB_CALL
109	krb5_generate_random_keyblock(krb5_context context,
110	krb5_enctype type,
111	krb5_keyblock *key)
112	{
113	krb5_error_code ret;
114	struct _krb5_encryption_type *et = _krb5_find_enctype(type);
115	if(et == NULL) {
116	return unsupported_enctype (context, type);
117	}
118	ret = krb5_data_alloc(&key->keyvalue, et->keytype->size);
119	if(ret)
120	return ret;
121	key->keytype = type;
122	if(et->keytype->random_key)
123	(*et->keytype->random_key)(context, key);
124	else
125	krb5_generate_random_block(key->keyvalue.data,
126	key->keyvalue.length);
127	return 0;
128	}
129
130	static krb5_error_code
131	_key_schedule(krb5_context context,
132	struct _krb5_key_data *key)
133	{
134	krb5_error_code ret;
135	struct _krb5_encryption_type *et = _krb5_find_enctype(key->key->keytype);
136	struct _krb5_key_type *kt;
137
138	if (et == NULL) {
139	return unsupported_enctype (context,
140	key->key->keytype);
141	}
142
143	kt = et->keytype;
144
145	if(kt->schedule == NULL)
146	return 0;
147	if (key->schedule != NULL)
148	return 0;
149	ALLOC(key->schedule, 1);
150	if(key->schedule == NULL) {
151	krb5_set_error_message(context, ENOMEM, N_("malloc: out of memory", ""));
152	return ENOMEM;
153	}
154	ret = krb5_data_alloc(key->schedule, kt->schedule_size);
155	if(ret) {
156	free(key->schedule);
157	key->schedule = NULL;
158	return ret;
159	}
160	(*kt->schedule)(context, kt, key);
161	return 0;
162	}
163
164	/************************************************************
165	* *
166	************************************************************/
167
168	static krb5_error_code
169	SHA1_checksum(krb5_context context,
170	struct _krb5_key_data *key,
171	const void *data,
172	size_t len,
173	unsigned usage,
174	Checksum *C)
175	{
176	if (EVP_Digest(data, len, C->checksum.data, NULL, EVP_sha1(), NULL) != 1)
177	krb5_abortx(context, "sha1 checksum failed");
178	return 0;
179	}
180
181	/* HMAC according to RFC2104 */
182	krb5_error_code
183	_krb5_internal_hmac(krb5_context context,
184	struct _krb5_checksum_type *cm,
185	const void *data,
186	size_t len,
187	unsigned usage,
188	struct _krb5_key_data *keyblock,
189	Checksum *result)
190	{
191	unsigned char ipad, opad;
192	unsigned char *key;
193	size_t key_len;
194	size_t i;
195
196	ipad = malloc(cm->blocksize + len);
197	if (ipad == NULL)
198	return ENOMEM;
199	opad = malloc(cm->blocksize + cm->checksumsize);
200	if (opad == NULL) {
201	free(ipad);
202	return ENOMEM;
203	}
204	memset(ipad, 0x36, cm->blocksize);
205	memset(opad, 0x5c, cm->blocksize);
206
207	if(keyblock->key->keyvalue.length > cm->blocksize){
208	(*cm->checksum)(context,
209	keyblock,
210	keyblock->key->keyvalue.data,
211	keyblock->key->keyvalue.length,
212	usage,
213	result);
214	key = result->checksum.data;
215	key_len = result->checksum.length;
216	} else {
217	key = keyblock->key->keyvalue.data;
218	key_len = keyblock->key->keyvalue.length;
219	}
220	for(i = 0; i < key_len; i++){
221	ipad[i] ^= key[i];
222	opad[i] ^= key[i];
223	}
224	memcpy(ipad + cm->blocksize, data, len);
225	(*cm->checksum)(context, keyblock, ipad, cm->blocksize + len,
226	usage, result);
227	memcpy(opad + cm->blocksize, result->checksum.data,
228	result->checksum.length);
229	(*cm->checksum)(context, keyblock, opad,
230	cm->blocksize + cm->checksumsize, usage, result);
231	memset(ipad, 0, cm->blocksize + len);
232	free(ipad);
233	memset(opad, 0, cm->blocksize + cm->checksumsize);
234	free(opad);
235
236	return 0;
237	}
238
239	KRB5_LIB_FUNCTION krb5_error_code KRB5_LIB_CALL
240	krb5_hmac(krb5_context context,
241	krb5_cksumtype cktype,
242	const void *data,
243	size_t len,
244	unsigned usage,
245	krb5_keyblock *key,
246	Checksum *result)
247	{
248	struct _krb5_checksum_type *c = _krb5_find_checksum(cktype);
249	struct _krb5_key_data kd;
250	krb5_error_code ret;
251
252	if (c == NULL) {
253	krb5_set_error_message (context, KRB5_PROG_SUMTYPE_NOSUPP,
254	N_("checksum type %d not supported", ""),
255	cktype);
256	return KRB5_PROG_SUMTYPE_NOSUPP;
257	}
258
259	kd.key = key;
260	kd.schedule = NULL;
261
262	ret = _krb5_internal_hmac(context, c, data, len, usage, &kd, result);
263
264	if (kd.schedule)
265	krb5_free_data(context, kd.schedule);
266
267	return ret;
268	}
269
270	krb5_error_code
271	_krb5_SP_HMAC_SHA1_checksum(krb5_context context,
272	struct _krb5_key_data *key,
273	const void *data,
274	size_t len,
275	unsigned usage,
276	Checksum *result)
277	{
278	struct _krb5_checksum_type *c = _krb5_find_checksum(CKSUMTYPE_SHA1);
279	Checksum res;
280	char sha1_data[20];
281	krb5_error_code ret;
282
283	res.checksum.data = sha1_data;
284	res.checksum.length = sizeof(sha1_data);
285
286	ret = _krb5_internal_hmac(context, c, data, len, usage, key, &res);
287	if (ret)
288	krb5_abortx(context, "hmac failed");
289	memcpy(result->checksum.data, res.checksum.data, result->checksum.length);
290	return 0;
291	}
292
293	struct _krb5_checksum_type _krb5_checksum_sha1 = {
294	CKSUMTYPE_SHA1,
295	"sha1",
296	64,
297	20,
298	F_CPROOF,
299	SHA1_checksum,
300	NULL
301	};
302
303	struct _krb5_checksum_type *
304	_krb5_find_checksum(krb5_cksumtype type)
305	{
306	int i;
307	for(i = 0; i < _krb5_num_checksums; i++)
308	if(_krb5_checksum_types[i]->type == type)
309	return _krb5_checksum_types[i];
310	return NULL;
311	}
312
313	static krb5_error_code
314	get_checksum_key(krb5_context context,
315	krb5_crypto crypto,
316	unsigned usage, /* not krb5_key_usage */
317	struct _krb5_checksum_type *ct,
318	struct _krb5_key_data **key)
319	{
320	krb5_error_code ret = 0;
321
322	if(ct->flags & F_DERIVED)
323	ret = _get_derived_key(context, crypto, usage, key);
324	else if(ct->flags & F_VARIANT) {
325	size_t i;
326
327	key = _new_derived_key(crypto, 0xff/ KRB5_KU_RFC1510_VARIANT */);
328	if(*key == NULL) {
329	krb5_set_error_message(context, ENOMEM, N_("malloc: out of memory", ""));
330	return ENOMEM;
331	}
332	ret = krb5_copy_keyblock(context, crypto->key.key, &(*key)->key);
333	if(ret)
334	return ret;
335	for(i = 0; i < (*key)->key->keyvalue.length; i++)
336	((unsigned char)(key)->key->keyvalue.data)[i] ^= 0xF0;
337	} else {
338	*key = &crypto->key;
339	}
340	if(ret == 0)
341	ret = _key_schedule(context, *key);
342	return ret;
343	}
344
345	static krb5_error_code
346	create_checksum (krb5_context context,
347	struct _krb5_checksum_type *ct,
348	krb5_crypto crypto,
349	unsigned usage,
350	void *data,
351	size_t len,
352	Checksum *result)
353	{
354	krb5_error_code ret;
355	struct _krb5_key_data *dkey;
356	int keyed_checksum;
357
358	if (ct->flags & F_DISABLED) {
359	krb5_clear_error_message (context);
360	return KRB5_PROG_SUMTYPE_NOSUPP;
361	}
362	keyed_checksum = (ct->flags & F_KEYED) != 0;
363	if(keyed_checksum && crypto == NULL) {
364	krb5_set_error_message (context, KRB5_PROG_SUMTYPE_NOSUPP,
365	N_("Checksum type %s is keyed but no "
366	"crypto context (key) was passed in", ""),
367	ct->name);
368	return KRB5_PROG_SUMTYPE_NOSUPP; /* XXX */
369	}
370	if(keyed_checksum) {
371	ret = get_checksum_key(context, crypto, usage, ct, &dkey);
372	if (ret)
373	return ret;
374	} else
375	dkey = NULL;
376	result->cksumtype = ct->type;
377	ret = krb5_data_alloc(&result->checksum, ct->checksumsize);
378	if (ret)
379	return (ret);
380	return (*ct->checksum)(context, dkey, data, len, usage, result);
381	}
382
383	static int
384	arcfour_checksum_p(struct _krb5_checksum_type *ct, krb5_crypto crypto)
385	{
386	return (ct->type == CKSUMTYPE_HMAC_MD5) &&
387	(crypto->key.key->keytype == KEYTYPE_ARCFOUR);
388	}
389
390	KRB5_LIB_FUNCTION krb5_error_code KRB5_LIB_CALL
391	krb5_create_checksum(krb5_context context,
392	krb5_crypto crypto,
393	krb5_key_usage usage,
394	int type,
395	void *data,
396	size_t len,
397	Checksum *result)
398	{
399	struct _krb5_checksum_type *ct = NULL;
400	unsigned keyusage;
401
402	/* type 0 -> pick from crypto */
403	if (type) {
404	ct = _krb5_find_checksum(type);
405	} else if (crypto) {
406	ct = crypto->et->keyed_checksum;
407	if (ct == NULL)
408	ct = crypto->et->checksum;
409	}
410
411	if(ct == NULL) {
412	krb5_set_error_message (context, KRB5_PROG_SUMTYPE_NOSUPP,
413	N_("checksum type %d not supported", ""),
414	type);
415	return KRB5_PROG_SUMTYPE_NOSUPP;
416	}
417
418	if (arcfour_checksum_p(ct, crypto)) {
419	keyusage = usage;
420	_krb5_usage2arcfour(context, &keyusage);
421	} else
422	keyusage = CHECKSUM_USAGE(usage);
423
424	return create_checksum(context, ct, crypto, keyusage,
425	data, len, result);
426	}
427
428	static krb5_error_code
429	verify_checksum(krb5_context context,
430	krb5_crypto crypto,
431	unsigned usage, /* not krb5_key_usage */
432	void *data,
433	size_t len,
434	Checksum *cksum)
435	{
436	krb5_error_code ret;
437	struct _krb5_key_data *dkey;
438	int keyed_checksum;
439	Checksum c;
440	struct _krb5_checksum_type *ct;
441
442	ct = _krb5_find_checksum(cksum->cksumtype);
443	if (ct == NULL \|\| (ct->flags & F_DISABLED)) {
444	krb5_set_error_message (context, KRB5_PROG_SUMTYPE_NOSUPP,
445	N_("checksum type %d not supported", ""),
446	cksum->cksumtype);
447	return KRB5_PROG_SUMTYPE_NOSUPP;
448	}
449	if(ct->checksumsize != cksum->checksum.length) {
450	krb5_clear_error_message (context);
451	krb5_set_error_message(context, KRB5KRB_AP_ERR_BAD_INTEGRITY,
452	N_("Decrypt integrity check failed for checksum type %s, "
453	"length was %u, expected %u", ""),
454	ct->name, (unsigned)cksum->checksum.length,
455	(unsigned)ct->checksumsize);
456
457	return KRB5KRB_AP_ERR_BAD_INTEGRITY; /* XXX */
458	}
459	keyed_checksum = (ct->flags & F_KEYED) != 0;
460	if(keyed_checksum) {
461	struct _krb5_checksum_type *kct;
462	if (crypto == NULL) {
463	krb5_set_error_message(context, KRB5_PROG_SUMTYPE_NOSUPP,
464	N_("Checksum type %s is keyed but no "
465	"crypto context (key) was passed in", ""),
466	ct->name);
467	return KRB5_PROG_SUMTYPE_NOSUPP; /* XXX */
468	}
469	kct = crypto->et->keyed_checksum;
470	if (kct == NULL \|\| kct->type != ct->type) {
471	krb5_set_error_message(context, KRB5_PROG_SUMTYPE_NOSUPP,
472	N_("Checksum type %s is keyed, but "
473	"the key type %s passed didnt have that checksum "
474	"type as the keyed type", ""),
475	ct->name, crypto->et->name);
476	return KRB5_PROG_SUMTYPE_NOSUPP; /* XXX */
477	}
478
479	ret = get_checksum_key(context, crypto, usage, ct, &dkey);
480	if (ret)
481	return ret;
482	} else
483	dkey = NULL;
484
485	/*
486	* If checksum have a verify function, lets use that instead of
487	* calling ->checksum and then compare result.
488	*/
489
490	if(ct->verify) {
491	ret = (*ct->verify)(context, dkey, data, len, usage, cksum);
492	if (ret)
493	krb5_set_error_message(context, ret,
494	N_("Decrypt integrity check failed for checksum "
495	"type %s, key type %s", ""),
496	ct->name, (crypto != NULL)? crypto->et->name : "(none)");
497	return ret;
498	}
499
500	ret = krb5_data_alloc (&c.checksum, ct->checksumsize);
501	if (ret)
502	return ret;
503
504	ret = (*ct->checksum)(context, dkey, data, len, usage, &c);
505	if (ret) {
506	krb5_data_free(&c.checksum);
507	return ret;
508	}
509
510	if(krb5_data_ct_cmp(&c.checksum, &cksum->checksum) != 0) {
511	ret = KRB5KRB_AP_ERR_BAD_INTEGRITY;
512	krb5_set_error_message(context, ret,
513	N_("Decrypt integrity check failed for checksum "
514	"type %s, key type %s", ""),
515	ct->name, crypto ? crypto->et->name : "(unkeyed)");
516	} else {
517	ret = 0;
518	}
519	krb5_data_free (&c.checksum);
520	return ret;
521	}
522
523	KRB5_LIB_FUNCTION krb5_error_code KRB5_LIB_CALL
524	krb5_verify_checksum(krb5_context context,
525	krb5_crypto crypto,
526	krb5_key_usage usage,
527	void *data,
528	size_t len,
529	Checksum *cksum)
530	{
531	struct _krb5_checksum_type *ct;
532	unsigned keyusage;
533
534	ct = _krb5_find_checksum(cksum->cksumtype);
535	if(ct == NULL) {
536	krb5_set_error_message (context, KRB5_PROG_SUMTYPE_NOSUPP,
537	N_("checksum type %d not supported", ""),
538	cksum->cksumtype);
539	return KRB5_PROG_SUMTYPE_NOSUPP;
540	}
541
542	if (arcfour_checksum_p(ct, crypto)) {
543	keyusage = usage;
544	_krb5_usage2arcfour(context, &keyusage);
545	} else
546	keyusage = CHECKSUM_USAGE(usage);
547
548	return verify_checksum(context, crypto, keyusage,
549	data, len, cksum);
550	}
551
552	KRB5_LIB_FUNCTION krb5_error_code KRB5_LIB_CALL
553	krb5_crypto_get_checksum_type(krb5_context context,
554	krb5_crypto crypto,
555	krb5_cksumtype *type)
556	{
557	struct _krb5_checksum_type *ct = NULL;
558
559	if (crypto != NULL) {
560	ct = crypto->et->keyed_checksum;
561	if (ct == NULL)
562	ct = crypto->et->checksum;
563	}
564
565	if (ct == NULL) {
566	krb5_set_error_message (context, KRB5_PROG_SUMTYPE_NOSUPP,
567	N_("checksum type not found", ""));
568	return KRB5_PROG_SUMTYPE_NOSUPP;
569	}
570
571	*type = ct->type;
572
573	return 0;
574	}
575
576
577	KRB5_LIB_FUNCTION krb5_error_code KRB5_LIB_CALL
578	krb5_checksumsize(krb5_context context,
579	krb5_cksumtype type,
580	size_t *size)
581	{
582	struct _krb5_checksum_type *ct = _krb5_find_checksum(type);
583	if(ct == NULL) {
584	krb5_set_error_message (context, KRB5_PROG_SUMTYPE_NOSUPP,
585	N_("checksum type %d not supported", ""),
586	type);
587	return KRB5_PROG_SUMTYPE_NOSUPP;
588	}
589	*size = ct->checksumsize;
590	return 0;
591	}
592
593	KRB5_LIB_FUNCTION krb5_boolean KRB5_LIB_CALL
594	krb5_checksum_is_keyed(krb5_context context,
595	krb5_cksumtype type)
596	{
597	struct _krb5_checksum_type *ct = _krb5_find_checksum(type);
598	if(ct == NULL) {
599	if (context)
600	krb5_set_error_message (context, KRB5_PROG_SUMTYPE_NOSUPP,
601	N_("checksum type %d not supported", ""),
602	type);
603	return KRB5_PROG_SUMTYPE_NOSUPP;
604	}
605	return ct->flags & F_KEYED;
606	}
607
608	KRB5_LIB_FUNCTION krb5_boolean KRB5_LIB_CALL
609	krb5_checksum_is_collision_proof(krb5_context context,
610	krb5_cksumtype type)
611	{
612	struct _krb5_checksum_type *ct = _krb5_find_checksum(type);
613	if(ct == NULL) {
614	if (context)
615	krb5_set_error_message (context, KRB5_PROG_SUMTYPE_NOSUPP,
616	N_("checksum type %d not supported", ""),
617	type);
618	return KRB5_PROG_SUMTYPE_NOSUPP;
619	}
620	return ct->flags & F_CPROOF;
621	}
622
623	KRB5_LIB_FUNCTION krb5_error_code KRB5_LIB_CALL
624	krb5_checksum_disable(krb5_context context,
625	krb5_cksumtype type)
626	{
627	struct _krb5_checksum_type *ct = _krb5_find_checksum(type);
628	if(ct == NULL) {
629	if (context)
630	krb5_set_error_message (context, KRB5_PROG_SUMTYPE_NOSUPP,
631	N_("checksum type %d not supported", ""),
632	type);
633	return KRB5_PROG_SUMTYPE_NOSUPP;
634	}
635	ct->flags \|= F_DISABLED;
636	return 0;
637	}
638
639	/************************************************************
640	* *
641	************************************************************/
642
643	struct _krb5_encryption_type *
644	_krb5_find_enctype(krb5_enctype type)
645	{
646	int i;
647	for(i = 0; i < _krb5_num_etypes; i++)
648	if(_krb5_etypes[i]->type == type)
649	return _krb5_etypes[i];
650	return NULL;
651	}
652
653
654	KRB5_LIB_FUNCTION krb5_error_code KRB5_LIB_CALL
655	krb5_enctype_to_string(krb5_context context,
656	krb5_enctype etype,
657	char **string)
658	{
659	struct _krb5_encryption_type *e;
660	e = _krb5_find_enctype(etype);
661	if(e == NULL) {
662	krb5_set_error_message (context, KRB5_PROG_ETYPE_NOSUPP,
663	N_("encryption type %d not supported", ""),
664	etype);
665	*string = NULL;
666	return KRB5_PROG_ETYPE_NOSUPP;
667	}
668	*string = strdup(e->name);
669	if(*string == NULL) {
670	krb5_set_error_message(context, ENOMEM, N_("malloc: out of memory", ""));
671	return ENOMEM;
672	}
673	return 0;
674	}
675
676	KRB5_LIB_FUNCTION krb5_error_code KRB5_LIB_CALL
677	krb5_string_to_enctype(krb5_context context,
678	const char *string,
679	krb5_enctype *etype)
680	{
681	int i;
682	for(i = 0; i < _krb5_num_etypes; i++)
683	if(strcasecmp(_krb5_etypes[i]->name, string) == 0){
684	*etype = _krb5_etypes[i]->type;
685	return 0;
686	}
687	krb5_set_error_message (context, KRB5_PROG_ETYPE_NOSUPP,
688	N_("encryption type %s not supported", ""),
689	string);
690	return KRB5_PROG_ETYPE_NOSUPP;
691	}
692
693	KRB5_LIB_FUNCTION krb5_error_code KRB5_LIB_CALL
694	krb5_enctype_to_keytype(krb5_context context,
695	krb5_enctype etype,
696	krb5_keytype *keytype)
697	{
698	struct _krb5_encryption_type *e = _krb5_find_enctype(etype);
699	if(e == NULL) {
700	return unsupported_enctype (context, etype);
701	}
702	keytype = e->keytype->type; / XXX */
703	return 0;
704	}
705
706	/**
707	* Check if a enctype is valid, return 0 if it is.
708	*
709	* @param context Kerberos context
710	* @param etype enctype to check if its valid or not
711	*
712	* @return Return an error code for an failure or 0 on success (enctype valid).
713	* @ingroup krb5_crypto
714	*/
715
716	KRB5_LIB_FUNCTION krb5_error_code KRB5_LIB_CALL
717	krb5_enctype_valid(krb5_context context,
718	krb5_enctype etype)
719	{
720	struct _krb5_encryption_type *e = _krb5_find_enctype(etype);
721	if(e && (e->flags & F_DISABLED) == 0)
722	return 0;
723	if (context == NULL)
724	return KRB5_PROG_ETYPE_NOSUPP;
725	if(e == NULL) {
726	return unsupported_enctype (context, etype);
727	}
728	/* Must be (e->flags & F_DISABLED) */
729	krb5_set_error_message (context, KRB5_PROG_ETYPE_NOSUPP,
730	N_("encryption type %s is disabled", ""),
731	e->name);
732	return KRB5_PROG_ETYPE_NOSUPP;
733	}
734
735	/**
736	* Return the coresponding encryption type for a checksum type.
737	*
738	* @param context Kerberos context
739	* @param ctype The checksum type to get the result enctype for
740	* @param etype The returned encryption, when the matching etype is
741	* not found, etype is set to ETYPE_NULL.
742	*
743	* @return Return an error code for an failure or 0 on success.
744	* @ingroup krb5_crypto
745	*/
746
747
748	KRB5_LIB_FUNCTION krb5_error_code KRB5_LIB_CALL
749	krb5_cksumtype_to_enctype(krb5_context context,
750	krb5_cksumtype ctype,
751	krb5_enctype *etype)
752	{
753	int i;
754
755	*etype = ETYPE_NULL;
756
757	for(i = 0; i < _krb5_num_etypes; i++) {
758	if(_krb5_etypes[i]->keyed_checksum &&
759	_krb5_etypes[i]->keyed_checksum->type == ctype)
760	{
761	*etype = _krb5_etypes[i]->type;
762	return 0;
763	}
764	}
765
766	krb5_set_error_message (context, KRB5_PROG_SUMTYPE_NOSUPP,
767	N_("checksum type %d not supported", ""),
768	(int)ctype);
769	return KRB5_PROG_SUMTYPE_NOSUPP;
770	}
771
772
773	KRB5_LIB_FUNCTION krb5_error_code KRB5_LIB_CALL
774	krb5_cksumtype_valid(krb5_context context,
775	krb5_cksumtype ctype)
776	{
777	struct _krb5_checksum_type *c = _krb5_find_checksum(ctype);
778	if (c == NULL) {
779	krb5_set_error_message (context, KRB5_PROG_SUMTYPE_NOSUPP,
780	N_("checksum type %d not supported", ""),
781	ctype);
782	return KRB5_PROG_SUMTYPE_NOSUPP;
783	}
784	if (c->flags & F_DISABLED) {
785	krb5_set_error_message (context, KRB5_PROG_SUMTYPE_NOSUPP,
786	N_("checksum type %s is disabled", ""),
787	c->name);
788	return KRB5_PROG_SUMTYPE_NOSUPP;
789	}
790	return 0;
791	}
792
793
794	static krb5_boolean
795	derived_crypto(krb5_context context,
796	krb5_crypto crypto)
797	{
798	return (crypto->et->flags & F_DERIVED) != 0;
799	}
800
801	static krb5_boolean
802	special_crypto(krb5_context context,
803	krb5_crypto crypto)
804	{
805	return (crypto->et->flags & F_SPECIAL) != 0;
806	}
807
808	#define CHECKSUMSIZE(C) ((C)->checksumsize)
809	#define CHECKSUMTYPE(C) ((C)->type)
810
811	static krb5_error_code
812	encrypt_internal_derived(krb5_context context,
813	krb5_crypto crypto,
814	unsigned usage,
815	const void *data,
816	size_t len,
817	krb5_data *result,
818	void *ivec)
819	{
820	size_t sz, block_sz, checksum_sz, total_sz;
821	Checksum cksum;
822	unsigned char p, q;
823	krb5_error_code ret;
824	struct _krb5_key_data *dkey;
825	const struct _krb5_encryption_type *et = crypto->et;
826
827	checksum_sz = CHECKSUMSIZE(et->keyed_checksum);
828
829	sz = et->confoundersize + len;
830	block_sz = (sz + et->padsize - 1) &~ (et->padsize - 1); /* pad */
831	total_sz = block_sz + checksum_sz;
832	p = calloc(1, total_sz);
833	if(p == NULL) {
834	krb5_set_error_message(context, ENOMEM, N_("malloc: out of memory", ""));
835	return ENOMEM;
836	}
837
838	q = p;
839	krb5_generate_random_block(q, et->confoundersize); /* XXX */
840	q += et->confoundersize;
841	memcpy(q, data, len);
842
843	ret = create_checksum(context,
844	et->keyed_checksum,
845	crypto,
846	INTEGRITY_USAGE(usage),
847	p,
848	block_sz,
849	&cksum);
850	if(ret == 0 && cksum.checksum.length != checksum_sz) {
851	free_Checksum (&cksum);
852	krb5_clear_error_message (context);
853	ret = KRB5_CRYPTO_INTERNAL;
854	}
855	if(ret)
856	goto fail;
857	memcpy(p + block_sz, cksum.checksum.data, cksum.checksum.length);
858	free_Checksum (&cksum);
859	ret = _get_derived_key(context, crypto, ENCRYPTION_USAGE(usage), &dkey);
860	if(ret)
861	goto fail;
862	ret = _key_schedule(context, dkey);
863	if(ret)
864	goto fail;
865	ret = (*et->encrypt)(context, dkey, p, block_sz, 1, usage, ivec);
866	if (ret)
867	goto fail;
868	result->data = p;
869	result->length = total_sz;
870	return 0;
871	fail:
872	memset(p, 0, total_sz);
873	free(p);
874	return ret;
875	}
876
877
878	static krb5_error_code
879	encrypt_internal(krb5_context context,
880	krb5_crypto crypto,
881	const void *data,
882	size_t len,
883	krb5_data *result,
884	void *ivec)
885	{
886	size_t sz, block_sz, checksum_sz;
887	Checksum cksum;
888	unsigned char p, q;
889	krb5_error_code ret;
890	const struct _krb5_encryption_type *et = crypto->et;
891
892	checksum_sz = CHECKSUMSIZE(et->checksum);
893
894	sz = et->confoundersize + checksum_sz + len;
895	block_sz = (sz + et->padsize - 1) &~ (et->padsize - 1); /* pad */
896	p = calloc(1, block_sz);
897	if(p == NULL) {
898	krb5_set_error_message(context, ENOMEM, N_("malloc: out of memory", ""));
899	return ENOMEM;
900	}
901
902	q = p;
903	krb5_generate_random_block(q, et->confoundersize); /* XXX */
904	q += et->confoundersize;
905	memset(q, 0, checksum_sz);
906	q += checksum_sz;
907	memcpy(q, data, len);
908
909	ret = create_checksum(context,
910	et->checksum,
911	crypto,
912	0,
913	p,
914	block_sz,
915	&cksum);
916	if(ret == 0 && cksum.checksum.length != checksum_sz) {
917	krb5_clear_error_message (context);
918	free_Checksum(&cksum);
919	ret = KRB5_CRYPTO_INTERNAL;
920	}
921	if(ret)
922	goto fail;
923	memcpy(p + et->confoundersize, cksum.checksum.data, cksum.checksum.length);
924	free_Checksum(&cksum);
925	ret = _key_schedule(context, &crypto->key);
926	if(ret)
927	goto fail;
928	ret = (*et->encrypt)(context, &crypto->key, p, block_sz, 1, 0, ivec);
929	if (ret) {
930	memset(p, 0, block_sz);
931	free(p);
932	return ret;
933	}
934	result->data = p;
935	result->length = block_sz;
936	return 0;
937	fail:
938	memset(p, 0, block_sz);
939	free(p);
940	return ret;
941	}
942
943	static krb5_error_code
944	encrypt_internal_special(krb5_context context,
945	krb5_crypto crypto,
946	int usage,
947	const void *data,
948	size_t len,
949	krb5_data *result,
950	void *ivec)
951	{
952	struct _krb5_encryption_type *et = crypto->et;
953	size_t cksum_sz = CHECKSUMSIZE(et->checksum);
954	size_t sz = len + cksum_sz + et->confoundersize;
955	char tmp, p;
956	krb5_error_code ret;
957
958	tmp = malloc (sz);
959	if (tmp == NULL) {
960	krb5_set_error_message(context, ENOMEM, N_("malloc: out of memory", ""));
961	return ENOMEM;
962	}
963	p = tmp;
964	memset (p, 0, cksum_sz);
965	p += cksum_sz;
966	krb5_generate_random_block(p, et->confoundersize);
967	p += et->confoundersize;
968	memcpy (p, data, len);
969	ret = (*et->encrypt)(context, &crypto->key, tmp, sz, TRUE, usage, ivec);
970	if (ret) {
971	memset(tmp, 0, sz);
972	free(tmp);
973	return ret;
974	}
975	result->data = tmp;
976	result->length = sz;
977	return 0;
978	}
979
980	static krb5_error_code
981	decrypt_internal_derived(krb5_context context,
982	krb5_crypto crypto,
983	unsigned usage,
984	void *data,
985	size_t len,
986	krb5_data *result,
987	void *ivec)
988	{
989	size_t checksum_sz;
990	Checksum cksum;
991	unsigned char *p;
992	krb5_error_code ret;
993	struct _krb5_key_data *dkey;
994	struct _krb5_encryption_type *et = crypto->et;
995	unsigned long l;
996
997	checksum_sz = CHECKSUMSIZE(et->keyed_checksum);
998	if (len < checksum_sz + et->confoundersize) {
999	krb5_set_error_message(context, KRB5_BAD_MSIZE,
1000	N_("Encrypted data shorter then "
1001	"checksum + confunder", ""));
1002	return KRB5_BAD_MSIZE;
1003	}
1004
1005	if (((len - checksum_sz) % et->padsize) != 0) {
1006	krb5_clear_error_message(context);
1007	return KRB5_BAD_MSIZE;
1008	}
1009
1010	p = malloc(len);
1011	if(len != 0 && p == NULL) {
1012	krb5_set_error_message(context, ENOMEM, N_("malloc: out of memory", ""));
1013	return ENOMEM;
1014	}
1015	memcpy(p, data, len);
1016
1017	len -= checksum_sz;
1018
1019	ret = _get_derived_key(context, crypto, ENCRYPTION_USAGE(usage), &dkey);
1020	if(ret) {
1021	free(p);
1022	return ret;
1023	}
1024	ret = _key_schedule(context, dkey);
1025	if(ret) {
1026	free(p);
1027	return ret;
1028	}
1029	ret = (*et->encrypt)(context, dkey, p, len, 0, usage, ivec);
1030	if (ret) {
1031	free(p);
1032	return ret;
1033	}
1034
1035	cksum.checksum.data = p + len;
1036	cksum.checksum.length = checksum_sz;
1037	cksum.cksumtype = CHECKSUMTYPE(et->keyed_checksum);
1038
1039	ret = verify_checksum(context,
1040	crypto,
1041	INTEGRITY_USAGE(usage),
1042	p,
1043	len,
1044	&cksum);
1045	if(ret) {
1046	free(p);
1047	return ret;
1048	}
1049	l = len - et->confoundersize;
1050	memmove(p, p + et->confoundersize, l);
1051	result->data = realloc(p, l);
1052	if(result->data == NULL && l != 0) {
1053	free(p);
1054	krb5_set_error_message(context, ENOMEM, N_("malloc: out of memory", ""));
1055	return ENOMEM;
1056	}
1057	result->length = l;
1058	return 0;
1059	}
1060
1061	static krb5_error_code
1062	decrypt_internal(krb5_context context,
1063	krb5_crypto crypto,
1064	void *data,
1065	size_t len,
1066	krb5_data *result,
1067	void *ivec)
1068	{
1069	krb5_error_code ret;
1070	unsigned char *p;
1071	Checksum cksum;
1072	size_t checksum_sz, l;
1073	struct _krb5_encryption_type *et = crypto->et;
1074
1075	if ((len % et->padsize) != 0) {
1076	krb5_clear_error_message(context);
1077	return KRB5_BAD_MSIZE;
1078	}
1079	checksum_sz = CHECKSUMSIZE(et->checksum);
1080	if (len < checksum_sz + et->confoundersize) {
1081	krb5_set_error_message(context, KRB5_BAD_MSIZE,
1082	N_("Encrypted data shorter then "
1083	"checksum + confunder", ""));
1084	return KRB5_BAD_MSIZE;
1085	}
1086
1087	p = malloc(len);
1088	if(len != 0 && p == NULL) {
1089	krb5_set_error_message(context, ENOMEM, N_("malloc: out of memory", ""));
1090	return ENOMEM;
1091	}
1092	memcpy(p, data, len);
1093
1094	ret = _key_schedule(context, &crypto->key);
1095	if(ret) {
1096	free(p);
1097	return ret;
1098	}
1099	ret = (*et->encrypt)(context, &crypto->key, p, len, 0, 0, ivec);
1100	if (ret) {
1101	free(p);
1102	return ret;
1103	}
1104	ret = krb5_data_copy(&cksum.checksum, p + et->confoundersize, checksum_sz);
1105	if(ret) {
1106	free(p);
1107	return ret;
1108	}
1109	memset(p + et->confoundersize, 0, checksum_sz);
1110	cksum.cksumtype = CHECKSUMTYPE(et->checksum);
1111	ret = verify_checksum(context, NULL, 0, p, len, &cksum);
1112	free_Checksum(&cksum);
1113	if(ret) {
1114	free(p);
1115	return ret;
1116	}
1117	l = len - et->confoundersize - checksum_sz;
1118	memmove(p, p + et->confoundersize + checksum_sz, l);
1119	result->data = realloc(p, l);
1120	if(result->data == NULL && l != 0) {
1121	free(p);
1122	krb5_set_error_message(context, ENOMEM, N_("malloc: out of memory", ""));
1123	return ENOMEM;
1124	}
1125	result->length = l;
1126	return 0;
1127	}
1128
1129	static krb5_error_code
1130	decrypt_internal_special(krb5_context context,
1131	krb5_crypto crypto,
1132	int usage,
1133	void *data,
1134	size_t len,
1135	krb5_data *result,
1136	void *ivec)
1137	{
1138	struct _krb5_encryption_type *et = crypto->et;
1139	size_t cksum_sz = CHECKSUMSIZE(et->checksum);
1140	size_t sz = len - cksum_sz - et->confoundersize;
1141	unsigned char *p;
1142	krb5_error_code ret;
1143
1144	if ((len % et->padsize) != 0) {
1145	krb5_clear_error_message(context);
1146	return KRB5_BAD_MSIZE;
1147	}
1148	if (len < cksum_sz + et->confoundersize) {
1149	krb5_set_error_message(context, KRB5_BAD_MSIZE,
1150	N_("Encrypted data shorter then "
1151	"checksum + confunder", ""));
1152	return KRB5_BAD_MSIZE;
1153	}
1154
1155	p = malloc (len);
1156	if (p == NULL) {
1157	krb5_set_error_message(context, ENOMEM, N_("malloc: out of memory", ""));
1158	return ENOMEM;
1159	}
1160	memcpy(p, data, len);
1161
1162	ret = (*et->encrypt)(context, &crypto->key, p, len, FALSE, usage, ivec);
1163	if (ret) {
1164	free(p);
1165	return ret;
1166	}
1167
1168	memmove (p, p + cksum_sz + et->confoundersize, sz);
1169	result->data = realloc(p, sz);
1170	if(result->data == NULL && sz != 0) {
1171	free(p);
1172	krb5_set_error_message(context, ENOMEM, N_("malloc: out of memory", ""));
1173	return ENOMEM;
1174	}
1175	result->length = sz;
1176	return 0;
1177	}
1178
1179	static krb5_crypto_iov *
1180	find_iv(krb5_crypto_iov *data, size_t num_data, unsigned type)
1181	{
1182	size_t i;
1183	for (i = 0; i < num_data; i++)
1184	if (data[i].flags == type)
1185	return &data[i];
1186	return NULL;
1187	}
1188
1189	/**
1190	* Inline encrypt a kerberos message
1191	*
1192	* @param context Kerberos context
1193	* @param crypto Kerberos crypto context
1194	* @param usage Key usage for this buffer
1195	* @param data array of buffers to process
1196	* @param num_data length of array
1197	* @param ivec initial cbc/cts vector
1198	*
1199	* @return Return an error code or 0.
1200	* @ingroup krb5_crypto
1201	*
1202	* Kerberos encrypted data look like this:
1203	*
1204	* 1. KRB5_CRYPTO_TYPE_HEADER
1205	* 2. array [1,...] KRB5_CRYPTO_TYPE_DATA and array [0,...]
1206	* KRB5_CRYPTO_TYPE_SIGN_ONLY in any order, however the receiver
1207	* have to aware of the order. KRB5_CRYPTO_TYPE_SIGN_ONLY is
1208	* commonly used headers and trailers.
1209	* 3. KRB5_CRYPTO_TYPE_PADDING, at least on padsize long if padsize > 1
1210	* 4. KRB5_CRYPTO_TYPE_TRAILER
1211	*/
1212
1213	KRB5_LIB_FUNCTION krb5_error_code KRB5_LIB_CALL
1214	krb5_encrypt_iov_ivec(krb5_context context,
1215	krb5_crypto crypto,
1216	unsigned usage,
1217	krb5_crypto_iov *data,
1218	int num_data,
1219	void *ivec)
1220	{
1221	size_t headersz, trailersz, len;
1222	int i;
1223	size_t sz, block_sz, pad_sz;
1224	Checksum cksum;
1225	unsigned char p, q;
1226	krb5_error_code ret;
1227	struct _krb5_key_data *dkey;
1228	const struct _krb5_encryption_type *et = crypto->et;
1229	krb5_crypto_iov tiv, piv, *hiv;
1230
1231	if (num_data < 0) {
1232	krb5_clear_error_message(context);
1233	return KRB5_CRYPTO_INTERNAL;
1234	}
1235
1236	if(!derived_crypto(context, crypto)) {
1237	krb5_clear_error_message(context);
1238	return KRB5_CRYPTO_INTERNAL;
1239	}
1240
1241	headersz = et->confoundersize;
1242	trailersz = CHECKSUMSIZE(et->keyed_checksum);
1243
1244	for (len = 0, i = 0; i < num_data; i++) {
1245	if (data[i].flags != KRB5_CRYPTO_TYPE_DATA)
1246	continue;
1247	len += data[i].data.length;
1248	}
1249
1250	sz = headersz + len;
1251	block_sz = (sz + et->padsize - 1) &~ (et->padsize - 1); /* pad */
1252
1253	pad_sz = block_sz - sz;
1254
1255	/* header */
1256
1257	hiv = find_iv(data, num_data, KRB5_CRYPTO_TYPE_HEADER);
1258	if (hiv == NULL \|\| hiv->data.length != headersz)
1259	return KRB5_BAD_MSIZE;
1260
1261	krb5_generate_random_block(hiv->data.data, hiv->data.length);
1262
1263	/* padding */
1264	piv = find_iv(data, num_data, KRB5_CRYPTO_TYPE_PADDING);
1265	/* its ok to have no TYPE_PADDING if there is no padding */
1266	if (piv == NULL && pad_sz != 0)
1267	return KRB5_BAD_MSIZE;
1268	if (piv) {
1269	if (piv->data.length < pad_sz)
1270	return KRB5_BAD_MSIZE;
1271	piv->data.length = pad_sz;
1272	if (pad_sz)
1273	memset(piv->data.data, pad_sz, pad_sz);
1274	else
1275	piv = NULL;
1276	}
1277
1278	/* trailer */
1279	tiv = find_iv(data, num_data, KRB5_CRYPTO_TYPE_TRAILER);
1280	if (tiv == NULL \|\| tiv->data.length != trailersz)
1281	return KRB5_BAD_MSIZE;
1282
1283	/*
1284	* XXX replace with EVP_Sign? at least make create_checksum an iov
1285	* function.
1286	* XXX CTS EVP is broken, can't handle multi buffers :(
1287	*/
1288
1289	len = block_sz;
1290	for (i = 0; i < num_data; i++) {
1291	if (data[i].flags != KRB5_CRYPTO_TYPE_SIGN_ONLY)
1292	continue;
1293	len += data[i].data.length;
1294	}
1295
1296	p = q = malloc(len);
1297
1298	memcpy(q, hiv->data.data, hiv->data.length);
1299	q += hiv->data.length;
1300	for (i = 0; i < num_data; i++) {
1301	if (data[i].flags != KRB5_CRYPTO_TYPE_DATA &&
1302	data[i].flags != KRB5_CRYPTO_TYPE_SIGN_ONLY)
1303	continue;
1304	memcpy(q, data[i].data.data, data[i].data.length);
1305	q += data[i].data.length;
1306	}
1307	if (piv)
1308	memset(q, 0, piv->data.length);
1309
1310	ret = create_checksum(context,
1311	et->keyed_checksum,
1312	crypto,
1313	INTEGRITY_USAGE(usage),
1314	p,
1315	len,
1316	&cksum);
1317	free(p);
1318	if(ret == 0 && cksum.checksum.length != trailersz) {
1319	free_Checksum (&cksum);
1320	krb5_clear_error_message (context);
1321	ret = KRB5_CRYPTO_INTERNAL;
1322	}
1323	if(ret)
1324	return ret;
1325
1326	/* save cksum at end */
1327	memcpy(tiv->data.data, cksum.checksum.data, cksum.checksum.length);
1328	free_Checksum (&cksum);
1329
1330	/* XXX replace with EVP_Cipher */
1331	p = q = malloc(block_sz);
1332	if(p == NULL)
1333	return ENOMEM;
1334
1335	memcpy(q, hiv->data.data, hiv->data.length);
1336	q += hiv->data.length;
1337
1338	for (i = 0; i < num_data; i++) {
1339	if (data[i].flags != KRB5_CRYPTO_TYPE_DATA)
1340	continue;
1341	memcpy(q, data[i].data.data, data[i].data.length);
1342	q += data[i].data.length;
1343	}
1344	if (piv)
1345	memset(q, 0, piv->data.length);
1346
1347
1348	ret = _get_derived_key(context, crypto, ENCRYPTION_USAGE(usage), &dkey);
1349	if(ret) {
1350	free(p);
1351	return ret;
1352	}
1353	ret = _key_schedule(context, dkey);
1354	if(ret) {
1355	free(p);
1356	return ret;
1357	}
1358
1359	ret = (*et->encrypt)(context, dkey, p, block_sz, 1, usage, ivec);
1360	if (ret) {
1361	free(p);
1362	return ret;
1363	}
1364
1365	/* now copy data back to buffers */
1366	q = p;
1367
1368	memcpy(hiv->data.data, q, hiv->data.length);
1369	q += hiv->data.length;
1370
1371	for (i = 0; i < num_data; i++) {
1372	if (data[i].flags != KRB5_CRYPTO_TYPE_DATA)
1373	continue;
1374	memcpy(data[i].data.data, q, data[i].data.length);
1375	q += data[i].data.length;
1376	}
1377	if (piv)
1378	memcpy(piv->data.data, q, pad_sz);
1379
1380	free(p);
1381
1382	return ret;
1383	}
1384
1385	/**
1386	* Inline decrypt a Kerberos message.
1387	*
1388	* @param context Kerberos context
1389	* @param crypto Kerberos crypto context
1390	* @param usage Key usage for this buffer
1391	* @param data array of buffers to process
1392	* @param num_data length of array
1393	* @param ivec initial cbc/cts vector
1394	*
1395	* @return Return an error code or 0.
1396	* @ingroup krb5_crypto
1397	*
1398	* 1. KRB5_CRYPTO_TYPE_HEADER
1399	* 2. one KRB5_CRYPTO_TYPE_DATA and array [0,...] of KRB5_CRYPTO_TYPE_SIGN_ONLY in
1400	* any order, however the receiver have to aware of the
1401	* order. KRB5_CRYPTO_TYPE_SIGN_ONLY is commonly used unencrypoted
1402	* protocol headers and trailers. The output data will be of same
1403	* size as the input data or shorter.
1404	*/
1405
1406	KRB5_LIB_FUNCTION krb5_error_code KRB5_LIB_CALL
1407	krb5_decrypt_iov_ivec(krb5_context context,
1408	krb5_crypto crypto,
1409	unsigned usage,
1410	krb5_crypto_iov *data,
1411	unsigned int num_data,
1412	void *ivec)
1413	{
1414	unsigned int i;
1415	size_t headersz, trailersz, len;
1416	Checksum cksum;
1417	unsigned char p, q;
1418	krb5_error_code ret;
1419	struct _krb5_key_data *dkey;
1420	struct _krb5_encryption_type *et = crypto->et;
1421	krb5_crypto_iov tiv, hiv;
1422
1423	if(!derived_crypto(context, crypto)) {
1424	krb5_clear_error_message(context);
1425	return KRB5_CRYPTO_INTERNAL;
1426	}
1427
1428	headersz = et->confoundersize;
1429
1430	hiv = find_iv(data, num_data, KRB5_CRYPTO_TYPE_HEADER);
1431	if (hiv == NULL \|\| hiv->data.length != headersz)
1432	return KRB5_BAD_MSIZE;
1433
1434	/* trailer */
1435	trailersz = CHECKSUMSIZE(et->keyed_checksum);
1436
1437	tiv = find_iv(data, num_data, KRB5_CRYPTO_TYPE_TRAILER);
1438	if (tiv->data.length != trailersz)
1439	return KRB5_BAD_MSIZE;
1440
1441	/* Find length of data we will decrypt */
1442
1443	len = headersz;
1444	for (i = 0; i < num_data; i++) {
1445	if (data[i].flags != KRB5_CRYPTO_TYPE_DATA)
1446	continue;
1447	len += data[i].data.length;
1448	}
1449
1450	if ((len % et->padsize) != 0) {
1451	krb5_clear_error_message(context);
1452	return KRB5_BAD_MSIZE;
1453	}
1454
1455	/* XXX replace with EVP_Cipher */
1456
1457	p = q = malloc(len);
1458	if (p == NULL)
1459	return ENOMEM;
1460
1461	memcpy(q, hiv->data.data, hiv->data.length);
1462	q += hiv->data.length;
1463
1464	for (i = 0; i < num_data; i++) {
1465	if (data[i].flags != KRB5_CRYPTO_TYPE_DATA)
1466	continue;
1467	memcpy(q, data[i].data.data, data[i].data.length);
1468	q += data[i].data.length;
1469	}
1470
1471	ret = _get_derived_key(context, crypto, ENCRYPTION_USAGE(usage), &dkey);
1472	if(ret) {
1473	free(p);
1474	return ret;
1475	}
1476	ret = _key_schedule(context, dkey);
1477	if(ret) {
1478	free(p);
1479	return ret;
1480	}
1481
1482	ret = (*et->encrypt)(context, dkey, p, len, 0, usage, ivec);
1483	if (ret) {
1484	free(p);
1485	return ret;
1486	}
1487
1488	/* copy data back to buffers */
1489	memcpy(hiv->data.data, p, hiv->data.length);
1490	q = p + hiv->data.length;
1491	for (i = 0; i < num_data; i++) {
1492	if (data[i].flags != KRB5_CRYPTO_TYPE_DATA)
1493	continue;
1494	memcpy(data[i].data.data, q, data[i].data.length);
1495	q += data[i].data.length;
1496	}
1497
1498	free(p);
1499
1500	/* check signature */
1501	for (i = 0; i < num_data; i++) {
1502	if (data[i].flags != KRB5_CRYPTO_TYPE_SIGN_ONLY)
1503	continue;
1504	len += data[i].data.length;
1505	}
1506
1507	p = q = malloc(len);
1508	if (p == NULL)
1509	return ENOMEM;
1510
1511	memcpy(q, hiv->data.data, hiv->data.length);
1512	q += hiv->data.length;
1513	for (i = 0; i < num_data; i++) {
1514	if (data[i].flags != KRB5_CRYPTO_TYPE_DATA &&
1515	data[i].flags != KRB5_CRYPTO_TYPE_SIGN_ONLY)
1516	continue;
1517	memcpy(q, data[i].data.data, data[i].data.length);
1518	q += data[i].data.length;
1519	}
1520
1521	cksum.checksum.data = tiv->data.data;
1522	cksum.checksum.length = tiv->data.length;
1523	cksum.cksumtype = CHECKSUMTYPE(et->keyed_checksum);
1524
1525	ret = verify_checksum(context,
1526	crypto,
1527	INTEGRITY_USAGE(usage),
1528	p,
1529	len,
1530	&cksum);
1531	free(p);
1532	return ret;
1533	}
1534
1535	/**
1536	* Create a Kerberos message checksum.
1537	*
1538	* @param context Kerberos context
1539	* @param crypto Kerberos crypto context
1540	* @param usage Key usage for this buffer
1541	* @param data array of buffers to process
1542	* @param num_data length of array
1543	* @param type output data
1544	*
1545	* @return Return an error code or 0.
1546	* @ingroup krb5_crypto
1547	*/
1548
1549	KRB5_LIB_FUNCTION krb5_error_code KRB5_LIB_CALL
1550	krb5_create_checksum_iov(krb5_context context,
1551	krb5_crypto crypto,
1552	unsigned usage,
1553	krb5_crypto_iov *data,
1554	unsigned int num_data,
1555	krb5_cksumtype *type)
1556	{
1557	Checksum cksum;
1558	krb5_crypto_iov *civ;
1559	krb5_error_code ret;
1560	size_t i;
1561	size_t len;
1562	char p, q;
1563
1564	if(!derived_crypto(context, crypto)) {
1565	krb5_clear_error_message(context);
1566	return KRB5_CRYPTO_INTERNAL;
1567	}
1568
1569	civ = find_iv(data, num_data, KRB5_CRYPTO_TYPE_CHECKSUM);
1570	if (civ == NULL)
1571	return KRB5_BAD_MSIZE;
1572
1573	len = 0;
1574	for (i = 0; i < num_data; i++) {
1575	if (data[i].flags != KRB5_CRYPTO_TYPE_DATA &&
1576	data[i].flags != KRB5_CRYPTO_TYPE_SIGN_ONLY)
1577	continue;
1578	len += data[i].data.length;
1579	}
1580
1581	p = q = malloc(len);
1582
1583	for (i = 0; i < num_data; i++) {
1584	if (data[i].flags != KRB5_CRYPTO_TYPE_DATA &&
1585	data[i].flags != KRB5_CRYPTO_TYPE_SIGN_ONLY)
1586	continue;
1587	memcpy(q, data[i].data.data, data[i].data.length);
1588	q += data[i].data.length;
1589	}
1590
1591	ret = krb5_create_checksum(context, crypto, usage, 0, p, len, &cksum);
1592	free(p);
1593	if (ret)
1594	return ret;
1595
1596	if (type)
1597	*type = cksum.cksumtype;
1598
1599	if (cksum.checksum.length > civ->data.length) {
1600	krb5_set_error_message(context, KRB5_BAD_MSIZE,
1601	N_("Checksum larger then input buffer", ""));
1602	free_Checksum(&cksum);
1603	return KRB5_BAD_MSIZE;
1604	}
1605
1606	civ->data.length = cksum.checksum.length;
1607	memcpy(civ->data.data, cksum.checksum.data, civ->data.length);
1608	free_Checksum(&cksum);
1609
1610	return 0;
1611	}
1612
1613	/**
1614	* Verify a Kerberos message checksum.
1615	*
1616	* @param context Kerberos context
1617	* @param crypto Kerberos crypto context
1618	* @param usage Key usage for this buffer
1619	* @param data array of buffers to process
1620	* @param num_data length of array
1621	* @param type return checksum type if not NULL
1622	*
1623	* @return Return an error code or 0.
1624	* @ingroup krb5_crypto
1625	*/
1626
1627	KRB5_LIB_FUNCTION krb5_error_code KRB5_LIB_CALL
1628	krb5_verify_checksum_iov(krb5_context context,
1629	krb5_crypto crypto,
1630	unsigned usage,
1631	krb5_crypto_iov *data,
1632	unsigned int num_data,
1633	krb5_cksumtype *type)
1634	{
1635	struct _krb5_encryption_type *et = crypto->et;
1636	Checksum cksum;
1637	krb5_crypto_iov *civ;
1638	krb5_error_code ret;
1639	size_t i;
1640	size_t len;
1641	char p, q;
1642
1643	if(!derived_crypto(context, crypto)) {
1644	krb5_clear_error_message(context);
1645	return KRB5_CRYPTO_INTERNAL;
1646	}
1647
1648	civ = find_iv(data, num_data, KRB5_CRYPTO_TYPE_CHECKSUM);
1649	if (civ == NULL)
1650	return KRB5_BAD_MSIZE;
1651
1652	len = 0;
1653	for (i = 0; i < num_data; i++) {
1654	if (data[i].flags != KRB5_CRYPTO_TYPE_DATA &&
1655	data[i].flags != KRB5_CRYPTO_TYPE_SIGN_ONLY)
1656	continue;
1657	len += data[i].data.length;
1658	}
1659
1660	p = q = malloc(len);
1661
1662	for (i = 0; i < num_data; i++) {
1663	if (data[i].flags != KRB5_CRYPTO_TYPE_DATA &&
1664	data[i].flags != KRB5_CRYPTO_TYPE_SIGN_ONLY)
1665	continue;
1666	memcpy(q, data[i].data.data, data[i].data.length);
1667	q += data[i].data.length;
1668	}
1669
1670	cksum.cksumtype = CHECKSUMTYPE(et->keyed_checksum);
1671	cksum.checksum.length = civ->data.length;
1672	cksum.checksum.data = civ->data.data;
1673
1674	ret = krb5_verify_checksum(context, crypto, usage, p, len, &cksum);
1675	free(p);
1676
1677	if (ret == 0 && type)
1678	*type = cksum.cksumtype;
1679
1680	return ret;
1681	}
1682
1683
1684	KRB5_LIB_FUNCTION krb5_error_code KRB5_LIB_CALL
1685	krb5_crypto_length(krb5_context context,
1686	krb5_crypto crypto,
1687	int type,
1688	size_t *len)
1689	{
1690	if (!derived_crypto(context, crypto)) {
1691	krb5_set_error_message(context, EINVAL, "not a derived crypto");
1692	return EINVAL;
1693	}
1694
1695	switch(type) {
1696	case KRB5_CRYPTO_TYPE_EMPTY:
1697	*len = 0;
1698	return 0;
1699	case KRB5_CRYPTO_TYPE_HEADER:
1700	*len = crypto->et->blocksize;
1701	return 0;
1702	case KRB5_CRYPTO_TYPE_DATA:
1703	case KRB5_CRYPTO_TYPE_SIGN_ONLY:
1704	/* len must already been filled in */
1705	return 0;
1706	case KRB5_CRYPTO_TYPE_PADDING:
1707	if (crypto->et->padsize > 1)
1708	*len = crypto->et->padsize;
1709	else
1710	*len = 0;
1711	return 0;
1712	case KRB5_CRYPTO_TYPE_TRAILER:
1713	*len = CHECKSUMSIZE(crypto->et->keyed_checksum);
1714	return 0;
1715	case KRB5_CRYPTO_TYPE_CHECKSUM:
1716	if (crypto->et->keyed_checksum)
1717	*len = CHECKSUMSIZE(crypto->et->keyed_checksum);
1718	else
1719	*len = CHECKSUMSIZE(crypto->et->checksum);
1720	return 0;
1721	}
1722	krb5_set_error_message(context, EINVAL,
1723	"%d not a supported type", type);
1724	return EINVAL;
1725	}
1726
1727
1728	KRB5_LIB_FUNCTION krb5_error_code KRB5_LIB_CALL
1729	krb5_crypto_length_iov(krb5_context context,
1730	krb5_crypto crypto,
1731	krb5_crypto_iov *data,
1732	unsigned int num_data)
1733	{
1734	krb5_error_code ret;
1735	size_t i;
1736
1737	for (i = 0; i < num_data; i++) {
1738	ret = krb5_crypto_length(context, crypto,
1739	data[i].flags,
1740	&data[i].data.length);
1741	if (ret)
1742	return ret;
1743	}
1744	return 0;
1745	}
1746
1747
1748	KRB5_LIB_FUNCTION krb5_error_code KRB5_LIB_CALL
1749	krb5_encrypt_ivec(krb5_context context,
1750	krb5_crypto crypto,
1751	unsigned usage,
1752	const void *data,
1753	size_t len,
1754	krb5_data *result,
1755	void *ivec)
1756	{
1757	if(derived_crypto(context, crypto))
1758	return encrypt_internal_derived(context, crypto, usage,
1759	data, len, result, ivec);
1760	else if (special_crypto(context, crypto))
1761	return encrypt_internal_special (context, crypto, usage,
1762	data, len, result, ivec);
1763	else
1764	return encrypt_internal(context, crypto, data, len, result, ivec);
1765	}
1766
1767	KRB5_LIB_FUNCTION krb5_error_code KRB5_LIB_CALL
1768	krb5_encrypt(krb5_context context,
1769	krb5_crypto crypto,
1770	unsigned usage,
1771	const void *data,
1772	size_t len,
1773	krb5_data *result)
1774	{
1775	return krb5_encrypt_ivec(context, crypto, usage, data, len, result, NULL);
1776	}
1777
1778	KRB5_LIB_FUNCTION krb5_error_code KRB5_LIB_CALL
1779	krb5_encrypt_EncryptedData(krb5_context context,
1780	krb5_crypto crypto,
1781	unsigned usage,
1782	void *data,
1783	size_t len,
1784	int kvno,
1785	EncryptedData *result)
1786	{
1787	result->etype = CRYPTO_ETYPE(crypto);
1788	if(kvno){
1789	ALLOC(result->kvno, 1);
1790	*result->kvno = kvno;
1791	}else
1792	result->kvno = NULL;
1793	return krb5_encrypt(context, crypto, usage, data, len, &result->cipher);
1794	}
1795
1796	KRB5_LIB_FUNCTION krb5_error_code KRB5_LIB_CALL
1797	krb5_decrypt_ivec(krb5_context context,
1798	krb5_crypto crypto,
1799	unsigned usage,
1800	void *data,
1801	size_t len,
1802	krb5_data *result,
1803	void *ivec)
1804	{
1805	if(derived_crypto(context, crypto))
1806	return decrypt_internal_derived(context, crypto, usage,
1807	data, len, result, ivec);
1808	else if (special_crypto (context, crypto))
1809	return decrypt_internal_special(context, crypto, usage,
1810	data, len, result, ivec);
1811	else
1812	return decrypt_internal(context, crypto, data, len, result, ivec);
1813	}
1814
1815	KRB5_LIB_FUNCTION krb5_error_code KRB5_LIB_CALL
1816	krb5_decrypt(krb5_context context,
1817	krb5_crypto crypto,
1818	unsigned usage,
1819	void *data,
1820	size_t len,
1821	krb5_data *result)
1822	{
1823	return krb5_decrypt_ivec (context, crypto, usage, data, len, result,
1824	NULL);
1825	}
1826
1827	KRB5_LIB_FUNCTION krb5_error_code KRB5_LIB_CALL
1828	krb5_decrypt_EncryptedData(krb5_context context,
1829	krb5_crypto crypto,
1830	unsigned usage,
1831	const EncryptedData *e,
1832	krb5_data *result)
1833	{
1834	return krb5_decrypt(context, crypto, usage,
1835	e->cipher.data, e->cipher.length, result);
1836	}
1837
1838	/************************************************************
1839	* *
1840	************************************************************/
1841
1842	krb5_error_code
1843	_krb5_derive_key(krb5_context context,
1844	struct _krb5_encryption_type *et,
1845	struct _krb5_key_data *key,
1846	const void *constant,
1847	size_t len)
1848	{
1849	unsigned char *k = NULL;
1850	unsigned int nblocks = 0, i;
1851	krb5_error_code ret = 0;
1852	struct _krb5_key_type *kt = et->keytype;
1853
1854	ret = _key_schedule(context, key);
1855	if(ret)
1856	return ret;
1857	if(et->blocksize * 8 < kt->bits \|\| len != et->blocksize) {
1858	nblocks = (kt->bits + et->blocksize * 8 - 1) / (et->blocksize * 8);
1859	k = malloc(nblocks * et->blocksize);
1860	if(k == NULL) {
1861	ret = ENOMEM;
1862	krb5_set_error_message(context, ret, N_("malloc: out of memory", ""));
1863	goto out;
1864	}
1865	ret = _krb5_n_fold(constant, len, k, et->blocksize);
1866	if (ret) {
1867	krb5_set_error_message(context, ret, N_("malloc: out of memory", ""));
1868	goto out;
1869	}
1870
1871	for(i = 0; i < nblocks; i++) {
1872	if(i > 0)
1873	memcpy(k + i * et->blocksize,
1874	k + (i - 1) * et->blocksize,
1875	et->blocksize);
1876	(et->encrypt)(context, key, k + i et->blocksize, et->blocksize,
1877	1, 0, NULL);
1878	}
1879	} else {
1880	/* this case is probably broken, but won't be run anyway */
1881	void *c = malloc(len);
1882	size_t res_len = (kt->bits + 7) / 8;
1883
1884	if(len != 0 && c == NULL) {
1885	ret = ENOMEM;
1886	krb5_set_error_message(context, ret, N_("malloc: out of memory", ""));
1887	goto out;
1888	}
1889	memcpy(c, constant, len);
1890	(*et->encrypt)(context, key, c, len, 1, 0, NULL);
1891	k = malloc(res_len);
1892	if(res_len != 0 && k == NULL) {
1893	free(c);
1894	ret = ENOMEM;
1895	krb5_set_error_message(context, ret, N_("malloc: out of memory", ""));
1896	goto out;
1897	}
1898	ret = _krb5_n_fold(c, len, k, res_len);
1899	free(c);
1900	if (ret) {
1901	krb5_set_error_message(context, ret, N_("malloc: out of memory", ""));
1902	goto out;
1903	}
1904	}
1905
1906	/* XXX keytype dependent post-processing */
1907	switch(kt->type) {
1908	case ETYPE_OLD_DES3_CBC_SHA1:
1909	_krb5_DES3_random_to_key(context, key->key, k, nblocks * et->blocksize);
1910	break;
1911	case ENCTYPE_AES128_CTS_HMAC_SHA1_96:
1912	case ENCTYPE_AES256_CTS_HMAC_SHA1_96:
1913	memcpy(key->key->keyvalue.data, k, key->key->keyvalue.length);
1914	break;
1915	default:
1916	ret = KRB5_CRYPTO_INTERNAL;
1917	krb5_set_error_message(context, ret,
1918	N_("derive_key() called with unknown keytype (%u)", ""),
1919	kt->type);
1920	break;
1921	}
1922	out:
1923	if (key->schedule) {
1924	free_key_schedule(context, key, et);
1925	key->schedule = NULL;
1926	}
1927	if (k) {
1928	memset(k, 0, nblocks * et->blocksize);
1929	free(k);
1930	}
1931	return ret;
1932	}
1933
1934	static struct _krb5_key_data *
1935	_new_derived_key(krb5_crypto crypto, unsigned usage)
1936	{
1937	struct _krb5_key_usage *d = crypto->key_usage;
1938	d = realloc(d, (crypto->num_key_usage + 1) * sizeof(*d));
1939	if(d == NULL)
1940	return NULL;
1941	crypto->key_usage = d;
1942	d += crypto->num_key_usage++;
1943	memset(d, 0, sizeof(*d));
1944	d->usage = usage;
1945	return &d->key;
1946	}
1947
1948	KRB5_LIB_FUNCTION krb5_error_code KRB5_LIB_CALL
1949	krb5_derive_key(krb5_context context,
1950	const krb5_keyblock *key,
1951	krb5_enctype etype,
1952	const void *constant,
1953	size_t constant_len,
1954	krb5_keyblock **derived_key)
1955	{
1956	krb5_error_code ret;
1957	struct _krb5_encryption_type *et;
1958	struct _krb5_key_data d;
1959
1960	*derived_key = NULL;
1961
1962	et = _krb5_find_enctype (etype);
1963	if (et == NULL) {
1964	return unsupported_enctype (context, etype);
1965	}
1966
1967	ret = krb5_copy_keyblock(context, key, &d.key);
1968	if (ret)
1969	return ret;
1970
1971	d.schedule = NULL;
1972	ret = _krb5_derive_key(context, et, &d, constant, constant_len);
1973	if (ret == 0)
1974	ret = krb5_copy_keyblock(context, d.key, derived_key);
1975	_krb5_free_key_data(context, &d, et);
1976	return ret;
1977	}
1978
1979	static krb5_error_code
1980	_get_derived_key(krb5_context context,
1981	krb5_crypto crypto,
1982	unsigned usage,
1983	struct _krb5_key_data **key)
1984	{
1985	int i;
1986	struct _krb5_key_data *d;
1987	unsigned char constant[5];
1988
1989	for(i = 0; i < crypto->num_key_usage; i++)
1990	if(crypto->key_usage[i].usage == usage) {
1991	*key = &crypto->key_usage[i].key;
1992	return 0;
1993	}
1994	d = _new_derived_key(crypto, usage);
1995	if(d == NULL) {
1996	krb5_set_error_message(context, ENOMEM, N_("malloc: out of memory", ""));
1997	return ENOMEM;
1998	}
1999	krb5_copy_keyblock(context, crypto->key.key, &d->key);
2000	_krb5_put_int(constant, usage, 5);
2001	_krb5_derive_key(context, crypto->et, d, constant, sizeof(constant));
2002	*key = d;
2003	return 0;
2004	}
2005
2006	/**
2007	* Create a crypto context used for all encryption and signature
2008	* operation. The encryption type to use is taken from the key, but
2009	* can be overridden with the enctype parameter. This can be useful
2010	* for encryptions types which is compatiable (DES for example).
2011	*
2012	* To free the crypto context, use krb5_crypto_destroy().
2013	*
2014	* @param context Kerberos context
2015	* @param key the key block information with all key data
2016	* @param etype the encryption type
2017	* @param crypto the resulting crypto context
2018	*
2019	* @return Return an error code or 0.
2020	*
2021	* @ingroup krb5_crypto
2022	*/
2023
2024	KRB5_LIB_FUNCTION krb5_error_code KRB5_LIB_CALL
2025	krb5_crypto_init(krb5_context context,
2026	const krb5_keyblock *key,
2027	krb5_enctype etype,
2028	krb5_crypto *crypto)
2029	{
2030	krb5_error_code ret;
2031	ALLOC(*crypto, 1);
2032	if(*crypto == NULL) {
2033	krb5_set_error_message(context, ENOMEM, N_("malloc: out of memory", ""));
2034	return ENOMEM;
2035	}
2036	if(etype == ETYPE_NULL)
2037	etype = key->keytype;
2038	(*crypto)->et = _krb5_find_enctype(etype);
2039	if((crypto)->et == NULL \|\| ((crypto)->et->flags & F_DISABLED)) {
2040	free(*crypto);
2041	*crypto = NULL;
2042	return unsupported_enctype(context, etype);
2043	}
2044	if((*crypto)->et->keytype->size != key->keyvalue.length) {
2045	free(*crypto);
2046	*crypto = NULL;
2047	krb5_set_error_message (context, KRB5_BAD_KEYSIZE,
2048	"encryption key has bad length");
2049	return KRB5_BAD_KEYSIZE;
2050	}
2051	ret = krb5_copy_keyblock(context, key, &(*crypto)->key.key);
2052	if(ret) {
2053	free(*crypto);
2054	*crypto = NULL;
2055	return ret;
2056	}
2057	(*crypto)->key.schedule = NULL;
2058	(*crypto)->num_key_usage = 0;
2059	(*crypto)->key_usage = NULL;
2060	return 0;
2061	}
2062
2063	static void
2064	free_key_schedule(krb5_context context,
2065	struct _krb5_key_data *key,
2066	struct _krb5_encryption_type *et)
2067	{
2068	if (et->keytype->cleanup)
2069	(*et->keytype->cleanup)(context, key);
2070	memset(key->schedule->data, 0, key->schedule->length);
2071	krb5_free_data(context, key->schedule);
2072	}
2073
2074	void
2075	_krb5_free_key_data(krb5_context context, struct _krb5_key_data *key,
2076	struct _krb5_encryption_type *et)
2077	{
2078	krb5_free_keyblock(context, key->key);
2079	if(key->schedule) {
2080	free_key_schedule(context, key, et);
2081	key->schedule = NULL;
2082	}
2083	}
2084
2085	static void
2086	free_key_usage(krb5_context context, struct _krb5_key_usage *ku,
2087	struct _krb5_encryption_type *et)
2088	{
2089	_krb5_free_key_data(context, &ku->key, et);
2090	}
2091
2092	/**
2093	* Free a crypto context created by krb5_crypto_init().
2094	*
2095	* @param context Kerberos context
2096	* @param crypto crypto context to free
2097	*
2098	* @return Return an error code or 0.
2099	*
2100	* @ingroup krb5_crypto
2101	*/
2102
2103	KRB5_LIB_FUNCTION krb5_error_code KRB5_LIB_CALL
2104	krb5_crypto_destroy(krb5_context context,
2105	krb5_crypto crypto)
2106	{
2107	int i;
2108
2109	for(i = 0; i < crypto->num_key_usage; i++)
2110	free_key_usage(context, &crypto->key_usage[i], crypto->et);
2111	free(crypto->key_usage);
2112	_krb5_free_key_data(context, &crypto->key, crypto->et);
2113	free (crypto);
2114	return 0;
2115	}
2116
2117	/**
2118	* Return the blocksize used algorithm referenced by the crypto context
2119	*
2120	* @param context Kerberos context
2121	* @param crypto crypto context to query
2122	* @param blocksize the resulting blocksize
2123	*
2124	* @return Return an error code or 0.
2125	*
2126	* @ingroup krb5_crypto
2127	*/
2128
2129	KRB5_LIB_FUNCTION krb5_error_code KRB5_LIB_CALL
2130	krb5_crypto_getblocksize(krb5_context context,
2131	krb5_crypto crypto,
2132	size_t *blocksize)
2133	{
2134	*blocksize = crypto->et->blocksize;
2135	return 0;
2136	}
2137
2138	/**
2139	* Return the encryption type used by the crypto context
2140	*
2141	* @param context Kerberos context
2142	* @param crypto crypto context to query
2143	* @param enctype the resulting encryption type
2144	*
2145	* @return Return an error code or 0.
2146	*
2147	* @ingroup krb5_crypto
2148	*/
2149
2150	KRB5_LIB_FUNCTION krb5_error_code KRB5_LIB_CALL
2151	krb5_crypto_getenctype(krb5_context context,
2152	krb5_crypto crypto,
2153	krb5_enctype *enctype)
2154	{
2155	*enctype = crypto->et->type;
2156	return 0;
2157	}
2158
2159	/**
2160	* Return the padding size used by the crypto context
2161	*
2162	* @param context Kerberos context
2163	* @param crypto crypto context to query
2164	* @param padsize the return padding size
2165	*
2166	* @return Return an error code or 0.
2167	*
2168	* @ingroup krb5_crypto
2169	*/
2170
2171	KRB5_LIB_FUNCTION krb5_error_code KRB5_LIB_CALL
2172	krb5_crypto_getpadsize(krb5_context context,
2173	krb5_crypto crypto,
2174	size_t *padsize)
2175	{
2176	*padsize = crypto->et->padsize;
2177	return 0;
2178	}
2179
2180	/**
2181	* Return the confounder size used by the crypto context
2182	*
2183	* @param context Kerberos context
2184	* @param crypto crypto context to query
2185	* @param confoundersize the returned confounder size
2186	*
2187	* @return Return an error code or 0.
2188	*
2189	* @ingroup krb5_crypto
2190	*/
2191
2192	KRB5_LIB_FUNCTION krb5_error_code KRB5_LIB_CALL
2193	krb5_crypto_getconfoundersize(krb5_context context,
2194	krb5_crypto crypto,
2195	size_t *confoundersize)
2196	{
2197	*confoundersize = crypto->et->confoundersize;
2198	return 0;
2199	}
2200
2201
2202	/**
2203	* Disable encryption type
2204	*
2205	* @param context Kerberos 5 context
2206	* @param enctype encryption type to disable
2207	*
2208	* @return Return an error code or 0.
2209	*
2210	* @ingroup krb5_crypto
2211	*/
2212
2213	KRB5_LIB_FUNCTION krb5_error_code KRB5_LIB_CALL
2214	krb5_enctype_disable(krb5_context context,
2215	krb5_enctype enctype)
2216	{
2217	struct _krb5_encryption_type *et = _krb5_find_enctype(enctype);
2218	if(et == NULL) {
2219	if (context)
2220	krb5_set_error_message (context, KRB5_PROG_ETYPE_NOSUPP,
2221	N_("encryption type %d not supported", ""),
2222	enctype);
2223	return KRB5_PROG_ETYPE_NOSUPP;
2224	}
2225	et->flags \|= F_DISABLED;
2226	return 0;
2227	}
2228
2229	/**
2230	* Enable encryption type
2231	*
2232	* @param context Kerberos 5 context
2233	* @param enctype encryption type to enable
2234	*
2235	* @return Return an error code or 0.
2236	*
2237	* @ingroup krb5_crypto
2238	*/
2239
2240	KRB5_LIB_FUNCTION krb5_error_code KRB5_LIB_CALL
2241	krb5_enctype_enable(krb5_context context,
2242	krb5_enctype enctype)
2243	{
2244	struct _krb5_encryption_type *et = _krb5_find_enctype(enctype);
2245	if(et == NULL) {
2246	if (context)
2247	krb5_set_error_message (context, KRB5_PROG_ETYPE_NOSUPP,
2248	N_("encryption type %d not supported", ""),
2249	enctype);
2250	return KRB5_PROG_ETYPE_NOSUPP;
2251	}
2252	et->flags &= ~F_DISABLED;
2253	return 0;
2254	}
2255
2256	/**
2257	* Enable or disable all weak encryption types
2258	*
2259	* @param context Kerberos 5 context
2260	* @param enable true to enable, false to disable
2261	*
2262	* @return Return an error code or 0.
2263	*
2264	* @ingroup krb5_crypto
2265	*/
2266
2267	KRB5_LIB_FUNCTION krb5_error_code KRB5_LIB_CALL
2268	krb5_allow_weak_crypto(krb5_context context,
2269	krb5_boolean enable)
2270	{
2271	int i;
2272
2273	for(i = 0; i < _krb5_num_etypes; i++)
2274	if(_krb5_etypes[i]->flags & F_WEAK) {
2275	if(enable)
2276	_krb5_etypes[i]->flags &= ~F_DISABLED;
2277	else
2278	_krb5_etypes[i]->flags \|= F_DISABLED;
2279	}
2280	return 0;
2281	}
2282
2283	static size_t
2284	wrapped_length (krb5_context context,
2285	krb5_crypto crypto,
2286	size_t data_len)
2287	{
2288	struct _krb5_encryption_type *et = crypto->et;
2289	size_t padsize = et->padsize;
2290	size_t checksumsize = CHECKSUMSIZE(et->checksum);
2291	size_t res;
2292
2293	res = et->confoundersize + checksumsize + data_len;
2294	res = (res + padsize - 1) / padsize * padsize;
2295	return res;
2296	}
2297
2298	static size_t
2299	wrapped_length_dervied (krb5_context context,
2300	krb5_crypto crypto,
2301	size_t data_len)
2302	{
2303	struct _krb5_encryption_type *et = crypto->et;
2304	size_t padsize = et->padsize;
2305	size_t res;
2306
2307	res = et->confoundersize + data_len;
2308	res = (res + padsize - 1) / padsize * padsize;
2309	if (et->keyed_checksum)
2310	res += et->keyed_checksum->checksumsize;
2311	else
2312	res += et->checksum->checksumsize;
2313	return res;
2314	}
2315
2316	/*
2317	* Return the size of an encrypted packet of length `data_len'
2318	*/
2319
2320	KRB5_LIB_FUNCTION size_t KRB5_LIB_CALL
2321	krb5_get_wrapped_length (krb5_context context,
2322	krb5_crypto crypto,
2323	size_t data_len)
2324	{
2325	if (derived_crypto (context, crypto))
2326	return wrapped_length_dervied (context, crypto, data_len);
2327	else
2328	return wrapped_length (context, crypto, data_len);
2329	}
2330
2331	/*
2332	* Return the size of an encrypted packet of length `data_len'
2333	*/
2334
2335	static size_t
2336	crypto_overhead (krb5_context context,
2337	krb5_crypto crypto)
2338	{
2339	struct _krb5_encryption_type *et = crypto->et;
2340	size_t res;
2341
2342	res = CHECKSUMSIZE(et->checksum);
2343	res += et->confoundersize;
2344	if (et->padsize > 1)
2345	res += et->padsize;
2346	return res;
2347	}
2348
2349	static size_t
2350	crypto_overhead_dervied (krb5_context context,
2351	krb5_crypto crypto)
2352	{
2353	struct _krb5_encryption_type *et = crypto->et;
2354	size_t res;
2355
2356	if (et->keyed_checksum)
2357	res = CHECKSUMSIZE(et->keyed_checksum);
2358	else
2359	res = CHECKSUMSIZE(et->checksum);
2360	res += et->confoundersize;
2361	if (et->padsize > 1)
2362	res += et->padsize;
2363	return res;
2364	}
2365
2366	KRB5_LIB_FUNCTION size_t KRB5_LIB_CALL
2367	krb5_crypto_overhead (krb5_context context, krb5_crypto crypto)
2368	{
2369	if (derived_crypto (context, crypto))
2370	return crypto_overhead_dervied (context, crypto);
2371	else
2372	return crypto_overhead (context, crypto);
2373	}
2374
2375	/**
2376	* Converts the random bytestring to a protocol key according to
2377	* Kerberos crypto frame work. It may be assumed that all the bits of
2378	* the input string are equally random, even though the entropy
2379	* present in the random source may be limited.
2380	*
2381	* @param context Kerberos 5 context
2382	* @param type the enctype resulting key will be of
2383	* @param data input random data to convert to a key
2384	* @param size size of input random data, at least krb5_enctype_keysize() long
2385	* @param key key, output key, free with krb5_free_keyblock_contents()
2386	*
2387	* @return Return an error code or 0.
2388	*
2389	* @ingroup krb5_crypto
2390	*/
2391
2392	KRB5_LIB_FUNCTION krb5_error_code KRB5_LIB_CALL
2393	krb5_random_to_key(krb5_context context,
2394	krb5_enctype type,
2395	const void *data,
2396	size_t size,
2397	krb5_keyblock *key)
2398	{
2399	krb5_error_code ret;
2400	struct _krb5_encryption_type *et = _krb5_find_enctype(type);
2401	if(et == NULL) {
2402	krb5_set_error_message(context, KRB5_PROG_ETYPE_NOSUPP,
2403	N_("encryption type %d not supported", ""),
2404	type);
2405	return KRB5_PROG_ETYPE_NOSUPP;
2406	}
2407	if ((et->keytype->bits + 7) / 8 > size) {
2408	krb5_set_error_message(context, KRB5_PROG_ETYPE_NOSUPP,
2409	N_("encryption key %s needs %d bytes "
2410	"of random to make an encryption key "
2411	"out of it", ""),
2412	et->name, (int)et->keytype->size);
2413	return KRB5_PROG_ETYPE_NOSUPP;
2414	}
2415	ret = krb5_data_alloc(&key->keyvalue, et->keytype->size);
2416	if(ret)
2417	return ret;
2418	key->keytype = type;
2419	if (et->keytype->random_to_key)
2420	(*et->keytype->random_to_key)(context, key, data, size);
2421	else
2422	memcpy(key->keyvalue.data, data, et->keytype->size);
2423
2424	return 0;
2425	}
2426
2427
2428
2429	KRB5_LIB_FUNCTION krb5_error_code KRB5_LIB_CALL
2430	krb5_crypto_prf_length(krb5_context context,
2431	krb5_enctype type,
2432	size_t *length)
2433	{
2434	struct _krb5_encryption_type *et = _krb5_find_enctype(type);
2435
2436	if(et == NULL \|\| et->prf_length == 0) {
2437	krb5_set_error_message(context, KRB5_PROG_ETYPE_NOSUPP,
2438	N_("encryption type %d not supported", ""),
2439	type);
2440	return KRB5_PROG_ETYPE_NOSUPP;
2441	}
2442
2443	*length = et->prf_length;
2444	return 0;
2445	}
2446
2447	KRB5_LIB_FUNCTION krb5_error_code KRB5_LIB_CALL
2448	krb5_crypto_prf(krb5_context context,
2449	const krb5_crypto crypto,
2450	const krb5_data *input,
2451	krb5_data *output)
2452	{
2453	struct _krb5_encryption_type *et = crypto->et;
2454
2455	krb5_data_zero(output);
2456
2457	if(et->prf == NULL) {
2458	krb5_set_error_message(context, KRB5_PROG_ETYPE_NOSUPP,
2459	"kerberos prf for %s not supported",
2460	et->name);
2461	return KRB5_PROG_ETYPE_NOSUPP;
2462	}
2463
2464	return (*et->prf)(context, crypto, input, output);
2465	}
2466
2467	static krb5_error_code
2468	krb5_crypto_prfplus(krb5_context context,
2469	const krb5_crypto crypto,
2470	const krb5_data *input,
2471	size_t length,
2472	krb5_data *output)
2473	{
2474	krb5_error_code ret;
2475	krb5_data input2;
2476	unsigned char i = 1;
2477	unsigned char *p;
2478
2479	krb5_data_zero(&input2);
2480	krb5_data_zero(output);
2481
2482	krb5_clear_error_message(context);
2483
2484	ret = krb5_data_alloc(output, length);
2485	if (ret) goto out;
2486	ret = krb5_data_alloc(&input2, input->length + 1);
2487	if (ret) goto out;
2488
2489	krb5_clear_error_message(context);
2490
2491	memcpy(((unsigned char *)input2.data) + 1, input->data, input->length);
2492
2493	p = output->data;
2494
2495	while (length) {
2496	krb5_data block;
2497
2498	((unsigned char *)input2.data)[0] = i++;
2499
2500	ret = krb5_crypto_prf(context, crypto, &input2, &block);
2501	if (ret)
2502	goto out;
2503
2504	if (block.length < length) {
2505	memcpy(p, block.data, block.length);
2506	length -= block.length;
2507	} else {
2508	memcpy(p, block.data, length);
2509	length = 0;
2510	}
2511	p += block.length;
2512	krb5_data_free(&block);
2513	}
2514
2515	out:
2516	krb5_data_free(&input2);
2517	if (ret)
2518	krb5_data_free(output);
2519	return ret;
2520	}
2521
2522	/**
2523	* The FX-CF2 key derivation function, used in FAST and preauth framework.
2524	*
2525	* @param context Kerberos 5 context
2526	* @param crypto1 first key to combine
2527	* @param crypto2 second key to combine
2528	* @param pepper1 factor to combine with first key to garante uniqueness
2529	* @param pepper2 factor to combine with second key to garante uniqueness
2530	* @param enctype the encryption type of the resulting key
2531	* @param res allocated key, free with krb5_free_keyblock_contents()
2532	*
2533	* @return Return an error code or 0.
2534	*
2535	* @ingroup krb5_crypto
2536	*/
2537
2538	KRB5_LIB_FUNCTION krb5_error_code KRB5_LIB_CALL
2539	krb5_crypto_fx_cf2(krb5_context context,
2540	const krb5_crypto crypto1,
2541	const krb5_crypto crypto2,
2542	krb5_data *pepper1,
2543	krb5_data *pepper2,
2544	krb5_enctype enctype,
2545	krb5_keyblock *res)
2546	{
2547	krb5_error_code ret;
2548	krb5_data os1, os2;
2549	size_t i, keysize;
2550
2551	memset(res, 0, sizeof(*res));
2552	krb5_data_zero(&os1);
2553	krb5_data_zero(&os2);
2554
2555	ret = krb5_enctype_keysize(context, enctype, &keysize);
2556	if (ret)
2557	return ret;
2558
2559	ret = krb5_data_alloc(&res->keyvalue, keysize);
2560	if (ret)
2561	goto out;
2562	ret = krb5_crypto_prfplus(context, crypto1, pepper1, keysize, &os1);
2563	if (ret)
2564	goto out;
2565	ret = krb5_crypto_prfplus(context, crypto2, pepper2, keysize, &os2);
2566	if (ret)
2567	goto out;
2568
2569	res->keytype = enctype;
2570	{
2571	unsigned char p1 = os1.data, p2 = os2.data, *p3 = res->keyvalue.data;
2572	for (i = 0; i < keysize; i++)
2573	p3[i] = p1[i] ^ p2[i];
2574	}
2575	out:
2576	if (ret)
2577	krb5_data_free(&res->keyvalue);
2578	krb5_data_free(&os1);
2579	krb5_data_free(&os2);
2580
2581	return ret;
2582	}
2583
2584
2585
2586	#ifndef HEIMDAL_SMALLER
2587
2588	/**
2589	* Deprecated: keytypes doesn't exists, they are really enctypes.
2590	*
2591	* @ingroup krb5_deprecated
2592	*/
2593
2594	KRB5_LIB_FUNCTION krb5_error_code KRB5_LIB_CALL
2595	krb5_keytype_to_enctypes (krb5_context context,
2596	krb5_keytype keytype,
2597	unsigned *len,
2598	krb5_enctype **val)
2599	KRB5_DEPRECATED_FUNCTION("Use X instead")
2600	{
2601	int i;
2602	unsigned n = 0;
2603	krb5_enctype *ret;
2604
2605	for (i = _krb5_num_etypes - 1; i >= 0; --i) {
2606	if (_krb5_etypes[i]->keytype->type == keytype
2607	&& !(_krb5_etypes[i]->flags & F_PSEUDO)
2608	&& krb5_enctype_valid(context, _krb5_etypes[i]->type) == 0)
2609	++n;
2610	}
2611	if (n == 0) {
2612	krb5_set_error_message(context, KRB5_PROG_KEYTYPE_NOSUPP,
2613	"Keytype have no mapping");
2614	return KRB5_PROG_KEYTYPE_NOSUPP;
2615	}
2616
2617	ret = malloc(n * sizeof(*ret));
2618	if (ret == NULL && n != 0) {
2619	krb5_set_error_message(context, ENOMEM, "malloc: out of memory");
2620	return ENOMEM;
2621	}
2622	n = 0;
2623	for (i = _krb5_num_etypes - 1; i >= 0; --i) {
2624	if (_krb5_etypes[i]->keytype->type == keytype
2625	&& !(_krb5_etypes[i]->flags & F_PSEUDO)
2626	&& krb5_enctype_valid(context, _krb5_etypes[i]->type) == 0)
2627	ret[n++] = _krb5_etypes[i]->type;
2628	}
2629	*len = n;
2630	*val = ret;
2631	return 0;
2632	}
2633
2634	/**
2635	* Deprecated: keytypes doesn't exists, they are really enctypes.
2636	*
2637	* @ingroup krb5_deprecated
2638	*/
2639
2640	/* if two enctypes have compatible keys */
2641	KRB5_LIB_FUNCTION krb5_boolean KRB5_LIB_CALL
2642	krb5_enctypes_compatible_keys(krb5_context context,
2643	krb5_enctype etype1,
2644	krb5_enctype etype2)
2645	KRB5_DEPRECATED_FUNCTION("Use X instead")
2646	{
2647	struct _krb5_encryption_type *e1 = _krb5_find_enctype(etype1);
2648	struct _krb5_encryption_type *e2 = _krb5_find_enctype(etype2);
2649	return e1 != NULL && e2 != NULL && e1->keytype == e2->keytype;
2650	}
2651
2652	#endif /* HEIMDAL_SMALLER */

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source: heimdal/trunk/lib/krb5/crypto.c

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