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source: branches/samba-3.5.x/source4/heimdal/lib/krb5/crypto.c

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Last change on this file was 414, checked in by Herwig Bauernfeind, 15 years ago
Samba 3.5.0: Initial import
File size: 116.7 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	#define KRB5_DEPRECATED
35
36	#include "krb5_locl.h"
37	#include <pkinit_asn1.h>
38
39	#define WEAK_ENCTYPES 1
40
41	#ifndef HEIMDAL_SMALLER
42	#define DES3_OLD_ENCTYPE 1
43	#endif
44
45
46	#ifdef HAVE_OPENSSL /* XXX forward decl for hcrypto glue */
47	const EVP_CIPHER * _krb5_EVP_hcrypto_aes_128_cts(void);
48	const EVP_CIPHER * _krb5_EVP_hcrypto_aes_256_cts(void);
49	#define EVP_hcrypto_aes_128_cts _krb5_EVP_hcrypto_aes_128_cts
50	#define EVP_hcrypto_aes_256_cts _krb5_EVP_hcrypto_aes_256_cts
51	#endif
52
53	struct key_data {
54	krb5_keyblock *key;
55	krb5_data *schedule;
56	};
57
58	struct key_usage {
59	unsigned usage;
60	struct key_data key;
61	};
62
63	struct krb5_crypto_data {
64	struct encryption_type *et;
65	struct key_data key;
66	int num_key_usage;
67	struct key_usage *key_usage;
68	};
69
70	#define CRYPTO_ETYPE(C) ((C)->et->type)
71
72	/* bits for `flags' below */
73	#define F_KEYED 1 /* checksum is keyed */
74	#define F_CPROOF 2 /* checksum is collision proof */
75	#define F_DERIVED 4 /* uses derived keys */
76	#define F_VARIANT 8 /* uses `variant' keys (6.4.3) */
77	#define F_PSEUDO 16 /* not a real protocol type */
78	#define F_SPECIAL 32 /* backwards */
79	#define F_DISABLED 64 /* enctype/checksum disabled */
80
81	struct salt_type {
82	krb5_salttype type;
83	const char *name;
84	krb5_error_code (*string_to_key)(krb5_context, krb5_enctype, krb5_data,
85	krb5_salt, krb5_data, krb5_keyblock*);
86	};
87
88	struct key_type {
89	krb5_keytype type; /* XXX */
90	const char *name;
91	size_t bits;
92	size_t size;
93	size_t schedule_size;
94	void (random_key)(krb5_context, krb5_keyblock);
95	void (schedule)(krb5_context, struct key_type , struct key_data *);
96	struct salt_type *string_to_key;
97	void (random_to_key)(krb5_context, krb5_keyblock, const void*, size_t);
98	void (cleanup)(krb5_context, struct key_data );
99	const EVP_CIPHER (evp)(void);
100	};
101
102	struct checksum_type {
103	krb5_cksumtype type;
104	const char *name;
105	size_t blocksize;
106	size_t checksumsize;
107	unsigned flags;
108	krb5_enctype (*checksum)(krb5_context context,
109	struct key_data *key,
110	const void *buf, size_t len,
111	unsigned usage,
112	Checksum *csum);
113	krb5_error_code (*verify)(krb5_context context,
114	struct key_data *key,
115	const void *buf, size_t len,
116	unsigned usage,
117	Checksum *csum);
118	};
119
120	struct encryption_type {
121	krb5_enctype type;
122	const char *name;
123	size_t blocksize;
124	size_t padsize;
125	size_t confoundersize;
126	struct key_type *keytype;
127	struct checksum_type *checksum;
128	struct checksum_type *keyed_checksum;
129	unsigned flags;
130	krb5_error_code (*encrypt)(krb5_context context,
131	struct key_data *key,
132	void *data, size_t len,
133	krb5_boolean encryptp,
134	int usage,
135	void *ivec);
136	size_t prf_length;
137	krb5_error_code (*prf)(krb5_context,
138	krb5_crypto, const krb5_data , krb5_data );
139	};
140
141	#define ENCRYPTION_USAGE(U) (((U) << 8) \| 0xAA)
142	#define INTEGRITY_USAGE(U) (((U) << 8) \| 0x55)
143	#define CHECKSUM_USAGE(U) (((U) << 8) \| 0x99)
144
145	static struct checksum_type *_find_checksum(krb5_cksumtype type);
146	static struct encryption_type *_find_enctype(krb5_enctype type);
147	static krb5_error_code _get_derived_key(krb5_context, krb5_crypto,
148	unsigned, struct key_data**);
149	static struct key_data *_new_derived_key(krb5_crypto crypto, unsigned usage);
150	static krb5_error_code derive_key(krb5_context context,
151	struct encryption_type *et,
152	struct key_data *key,
153	const void *constant,
154	size_t len);
155	static krb5_error_code hmac(krb5_context context,
156	struct checksum_type *cm,
157	const void *data,
158	size_t len,
159	unsigned usage,
160	struct key_data *keyblock,
161	Checksum *result);
162	static void free_key_data(krb5_context,
163	struct key_data *,
164	struct encryption_type *);
165	static void free_key_schedule(krb5_context,
166	struct key_data *,
167	struct encryption_type *);
168	static krb5_error_code usage2arcfour (krb5_context, unsigned *);
169	static void xor (DES_cblock , const unsigned char );
170
171	/************************************************************
172	* *
173	************************************************************/
174
175	struct evp_schedule {
176	EVP_CIPHER_CTX ectx;
177	EVP_CIPHER_CTX dctx;
178	};
179
180
181	static HEIMDAL_MUTEX crypto_mutex = HEIMDAL_MUTEX_INITIALIZER;
182
183	#ifdef WEAK_ENCTYPES
184	static void
185	krb5_DES_random_key(krb5_context context,
186	krb5_keyblock *key)
187	{
188	DES_cblock *k = key->keyvalue.data;
189	do {
190	krb5_generate_random_block(k, sizeof(DES_cblock));
191	DES_set_odd_parity(k);
192	} while(DES_is_weak_key(k));
193	}
194
195	static void
196	krb5_DES_schedule_old(krb5_context context,
197	struct key_type *kt,
198	struct key_data *key)
199	{
200	DES_set_key_unchecked(key->key->keyvalue.data, key->schedule->data);
201	}
202
203	#ifdef ENABLE_AFS_STRING_TO_KEY
204
205	/* This defines the Andrew string_to_key function. It accepts a password
206	* string as input and converts it via a one-way encryption algorithm to a DES
207	* encryption key. It is compatible with the original Andrew authentication
208	* service password database.
209	*/
210
211	/*
212	* Short passwords, i.e 8 characters or less.
213	*/
214	static void
215	krb5_DES_AFS3_CMU_string_to_key (krb5_data pw,
216	krb5_data cell,
217	DES_cblock *key)
218	{
219	char password[8+1]; /* crypt is limited to 8 chars anyway */
220	int i;
221
222	for(i = 0; i < 8; i++) {
223	char c = ((i < pw.length) ? ((char*)pw.data)[i] : 0) ^
224	((i < cell.length) ?
225	tolower(((unsigned char*)cell.data)[i]) : 0);
226	password[i] = c ? c : 'X';
227	}
228	password[8] = '\0';
229
230	memcpy(key, crypt(password, "p1") + 2, sizeof(DES_cblock));
231
232	/* parity is inserted into the LSB so left shift each byte up one
233	bit. This allows ascii characters with a zero MSB to retain as
234	much significance as possible. */
235	for (i = 0; i < sizeof(DES_cblock); i++)
236	((unsigned char*)key)[i] <<= 1;
237	DES_set_odd_parity (key);
238	}
239
240	/*
241	* Long passwords, i.e 9 characters or more.
242	*/
243	static void
244	krb5_DES_AFS3_Transarc_string_to_key (krb5_data pw,
245	krb5_data cell,
246	DES_cblock *key)
247	{
248	DES_key_schedule schedule;
249	DES_cblock temp_key;
250	DES_cblock ivec;
251	char password[512];
252	size_t passlen;
253
254	memcpy(password, pw.data, min(pw.length, sizeof(password)));
255	if(pw.length < sizeof(password)) {
256	int len = min(cell.length, sizeof(password) - pw.length);
257	int i;
258
259	memcpy(password + pw.length, cell.data, len);
260	for (i = pw.length; i < pw.length + len; ++i)
261	password[i] = tolower((unsigned char)password[i]);
262	}
263	passlen = min(sizeof(password), pw.length + cell.length);
264	memcpy(&ivec, "kerberos", 8);
265	memcpy(&temp_key, "kerberos", 8);
266	DES_set_odd_parity (&temp_key);
267	DES_set_key_unchecked (&temp_key, &schedule);
268	DES_cbc_cksum ((void*)password, &ivec, passlen, &schedule, &ivec);
269
270	memcpy(&temp_key, &ivec, 8);
271	DES_set_odd_parity (&temp_key);
272	DES_set_key_unchecked (&temp_key, &schedule);
273	DES_cbc_cksum ((void*)password, key, passlen, &schedule, &ivec);
274	memset(&schedule, 0, sizeof(schedule));
275	memset(&temp_key, 0, sizeof(temp_key));
276	memset(&ivec, 0, sizeof(ivec));
277	memset(password, 0, sizeof(password));
278
279	DES_set_odd_parity (key);
280	}
281
282	static krb5_error_code
283	DES_AFS3_string_to_key(krb5_context context,
284	krb5_enctype enctype,
285	krb5_data password,
286	krb5_salt salt,
287	krb5_data opaque,
288	krb5_keyblock *key)
289	{
290	DES_cblock tmp;
291	if(password.length > 8)
292	krb5_DES_AFS3_Transarc_string_to_key(password, salt.saltvalue, &tmp);
293	else
294	krb5_DES_AFS3_CMU_string_to_key(password, salt.saltvalue, &tmp);
295	key->keytype = enctype;
296	krb5_data_copy(&key->keyvalue, tmp, sizeof(tmp));
297	memset(&key, 0, sizeof(key));
298	return 0;
299	}
300	#endif /* ENABLE_AFS_STRING_TO_KEY */
301
302	static void
303	DES_string_to_key_int(unsigned char data, size_t length, DES_cblock key)
304	{
305	DES_key_schedule schedule;
306	int i;
307	int reverse = 0;
308	unsigned char *p;
309
310	unsigned char swap[] = { 0x0, 0x8, 0x4, 0xc, 0x2, 0xa, 0x6, 0xe,
311	0x1, 0x9, 0x5, 0xd, 0x3, 0xb, 0x7, 0xf };
312	memset(key, 0, 8);
313
314	p = (unsigned char*)key;
315	for (i = 0; i < length; i++) {
316	unsigned char tmp = data[i];
317	if (!reverse)
318	*p++ ^= (tmp << 1);
319	else
320	*--p ^= (swap[tmp & 0xf] << 4) \| swap[(tmp & 0xf0) >> 4];
321	if((i % 8) == 7)
322	reverse = !reverse;
323	}
324	DES_set_odd_parity(key);
325	if(DES_is_weak_key(key))
326	(*key)[7] ^= 0xF0;
327	DES_set_key_unchecked(key, &schedule);
328	DES_cbc_cksum((void*)data, key, length, &schedule, key);
329	memset(&schedule, 0, sizeof(schedule));
330	DES_set_odd_parity(key);
331	if(DES_is_weak_key(key))
332	(*key)[7] ^= 0xF0;
333	}
334
335	static krb5_error_code
336	krb5_DES_string_to_key(krb5_context context,
337	krb5_enctype enctype,
338	krb5_data password,
339	krb5_salt salt,
340	krb5_data opaque,
341	krb5_keyblock *key)
342	{
343	unsigned char *s;
344	size_t len;
345	DES_cblock tmp;
346
347	#ifdef ENABLE_AFS_STRING_TO_KEY
348	if (opaque.length == 1) {
349	unsigned long v;
350	_krb5_get_int(opaque.data, &v, 1);
351	if (v == 1)
352	return DES_AFS3_string_to_key(context, enctype, password,
353	salt, opaque, key);
354	}
355	#endif
356
357	len = password.length + salt.saltvalue.length;
358	s = malloc(len);
359	if(len > 0 && s == NULL) {
360	krb5_set_error_message(context, ENOMEM, N_("malloc: out of memory", ""));
361	return ENOMEM;
362	}
363	memcpy(s, password.data, password.length);
364	memcpy(s + password.length, salt.saltvalue.data, salt.saltvalue.length);
365	DES_string_to_key_int(s, len, &tmp);
366	key->keytype = enctype;
367	krb5_data_copy(&key->keyvalue, tmp, sizeof(tmp));
368	memset(&tmp, 0, sizeof(tmp));
369	memset(s, 0, len);
370	free(s);
371	return 0;
372	}
373
374	static void
375	krb5_DES_random_to_key(krb5_context context,
376	krb5_keyblock *key,
377	const void *data,
378	size_t size)
379	{
380	DES_cblock *k = key->keyvalue.data;
381	memcpy(k, data, key->keyvalue.length);
382	DES_set_odd_parity(k);
383	if(DES_is_weak_key(k))
384	xor(k, (const unsigned char*)"\0\0\0\0\0\0\0\xf0");
385	}
386	#endif
387
388	/*
389	*
390	*/
391
392	static void
393	DES3_random_key(krb5_context context,
394	krb5_keyblock *key)
395	{
396	DES_cblock *k = key->keyvalue.data;
397	do {
398	krb5_generate_random_block(k, 3 * sizeof(DES_cblock));
399	DES_set_odd_parity(&k[0]);
400	DES_set_odd_parity(&k[1]);
401	DES_set_odd_parity(&k[2]);
402	} while(DES_is_weak_key(&k[0]) \|\|
403	DES_is_weak_key(&k[1]) \|\|
404	DES_is_weak_key(&k[2]));
405	}
406
407	/*
408	* A = A xor B. A & B are 8 bytes.
409	*/
410
411	static void
412	xor (DES_cblock key, const unsigned char b)
413	{
414	unsigned char a = (unsigned char)key;
415	a[0] ^= b[0];
416	a[1] ^= b[1];
417	a[2] ^= b[2];
418	a[3] ^= b[3];
419	a[4] ^= b[4];
420	a[5] ^= b[5];
421	a[6] ^= b[6];
422	a[7] ^= b[7];
423	}
424
425	#ifdef DES3_OLD_ENCTYPE
426	static krb5_error_code
427	DES3_string_to_key(krb5_context context,
428	krb5_enctype enctype,
429	krb5_data password,
430	krb5_salt salt,
431	krb5_data opaque,
432	krb5_keyblock *key)
433	{
434	char *str;
435	size_t len;
436	unsigned char tmp[24];
437	DES_cblock keys[3];
438	krb5_error_code ret;
439
440	len = password.length + salt.saltvalue.length;
441	str = malloc(len);
442	if(len != 0 && str == NULL) {
443	krb5_set_error_message(context, ENOMEM, N_("malloc: out of memory", ""));
444	return ENOMEM;
445	}
446	memcpy(str, password.data, password.length);
447	memcpy(str + password.length, salt.saltvalue.data, salt.saltvalue.length);
448	{
449	DES_cblock ivec;
450	DES_key_schedule s[3];
451	int i;
452
453	ret = _krb5_n_fold(str, len, tmp, 24);
454	if (ret) {
455	memset(str, 0, len);
456	free(str);
457	krb5_set_error_message(context, ret, N_("malloc: out of memory", ""));
458	return ret;
459	}
460
461	for(i = 0; i < 3; i++){
462	memcpy(keys + i, tmp + i * 8, sizeof(keys[i]));
463	DES_set_odd_parity(keys + i);
464	if(DES_is_weak_key(keys + i))
465	xor(keys + i, (const unsigned char*)"\0\0\0\0\0\0\0\xf0");
466	DES_set_key_unchecked(keys + i, &s[i]);
467	}
468	memset(&ivec, 0, sizeof(ivec));
469	DES_ede3_cbc_encrypt(tmp,
470	tmp, sizeof(tmp),
471	&s[0], &s[1], &s[2], &ivec, DES_ENCRYPT);
472	memset(s, 0, sizeof(s));
473	memset(&ivec, 0, sizeof(ivec));
474	for(i = 0; i < 3; i++){
475	memcpy(keys + i, tmp + i * 8, sizeof(keys[i]));
476	DES_set_odd_parity(keys + i);
477	if(DES_is_weak_key(keys + i))
478	xor(keys + i, (const unsigned char*)"\0\0\0\0\0\0\0\xf0");
479	}
480	memset(tmp, 0, sizeof(tmp));
481	}
482	key->keytype = enctype;
483	krb5_data_copy(&key->keyvalue, keys, sizeof(keys));
484	memset(keys, 0, sizeof(keys));
485	memset(str, 0, len);
486	free(str);
487	return 0;
488	}
489	#endif
490
491	static krb5_error_code
492	DES3_string_to_key_derived(krb5_context context,
493	krb5_enctype enctype,
494	krb5_data password,
495	krb5_salt salt,
496	krb5_data opaque,
497	krb5_keyblock *key)
498	{
499	krb5_error_code ret;
500	size_t len = password.length + salt.saltvalue.length;
501	char *s;
502
503	s = malloc(len);
504	if(len != 0 && s == NULL) {
505	krb5_set_error_message(context, ENOMEM, N_("malloc: out of memory", ""));
506	return ENOMEM;
507	}
508	memcpy(s, password.data, password.length);
509	memcpy(s + password.length, salt.saltvalue.data, salt.saltvalue.length);
510	ret = krb5_string_to_key_derived(context,
511	s,
512	len,
513	enctype,
514	key);
515	memset(s, 0, len);
516	free(s);
517	return ret;
518	}
519
520	static void
521	DES3_random_to_key(krb5_context context,
522	krb5_keyblock *key,
523	const void *data,
524	size_t size)
525	{
526	unsigned char *x = key->keyvalue.data;
527	const u_char *q = data;
528	DES_cblock *k;
529	int i, j;
530
531	memset(x, 0, sizeof(x));
532	for (i = 0; i < 3; ++i) {
533	unsigned char foo;
534	for (j = 0; j < 7; ++j) {
535	unsigned char b = q[7 * i + j];
536
537	x[8 * i + j] = b;
538	}
539	foo = 0;
540	for (j = 6; j >= 0; --j) {
541	foo \|= q[7 * i + j] & 1;
542	foo <<= 1;
543	}
544	x[8 * i + 7] = foo;
545	}
546	k = key->keyvalue.data;
547	for (i = 0; i < 3; i++) {
548	DES_set_odd_parity(&k[i]);
549	if(DES_is_weak_key(&k[i]))
550	xor(&k[i], (const unsigned char*)"\0\0\0\0\0\0\0\xf0");
551	}
552	}
553
554	/*
555	* ARCFOUR
556	*/
557
558	static void
559	ARCFOUR_schedule(krb5_context context,
560	struct key_type *kt,
561	struct key_data *kd)
562	{
563	RC4_set_key (kd->schedule->data,
564	kd->key->keyvalue.length, kd->key->keyvalue.data);
565	}
566
567	static krb5_error_code
568	ARCFOUR_string_to_key(krb5_context context,
569	krb5_enctype enctype,
570	krb5_data password,
571	krb5_salt salt,
572	krb5_data opaque,
573	krb5_keyblock *key)
574	{
575	krb5_error_code ret;
576	uint16_t *s = NULL;
577	size_t len, i;
578	EVP_MD_CTX *m;
579
580	m = EVP_MD_CTX_create();
581	if (m == NULL) {
582	ret = ENOMEM;
583	krb5_set_error_message(context, ret, N_("malloc: out of memory", ""));
584	goto out;
585	}
586
587	EVP_DigestInit_ex(m, EVP_md4(), NULL);
588
589	ret = wind_utf8ucs2_length(password.data, &len);
590	if (ret) {
591	krb5_set_error_message (context, ret,
592	N_("Password not an UCS2 string", ""));
593	goto out;
594	}
595
596	s = malloc (len * sizeof(s[0]));
597	if (len != 0 && s == NULL) {
598	krb5_set_error_message (context, ENOMEM,
599	N_("malloc: out of memory", ""));
600	ret = ENOMEM;
601	goto out;
602	}
603
604	ret = wind_utf8ucs2(password.data, s, &len);
605	if (ret) {
606	krb5_set_error_message (context, ret,
607	N_("Password not an UCS2 string", ""));
608	goto out;
609	}
610
611	/* LE encoding */
612	for (i = 0; i < len; i++) {
613	unsigned char p;
614	p = (s[i] & 0xff);
615	EVP_DigestUpdate (m, &p, 1);
616	p = (s[i] >> 8) & 0xff;
617	EVP_DigestUpdate (m, &p, 1);
618	}
619
620	key->keytype = enctype;
621	ret = krb5_data_alloc (&key->keyvalue, 16);
622	if (ret) {
623	krb5_set_error_message (context, ENOMEM, N_("malloc: out of memory", ""));
624	goto out;
625	}
626	EVP_DigestFinal_ex (m, key->keyvalue.data, NULL);
627
628	out:
629	EVP_MD_CTX_destroy(m);
630	if (s)
631	memset (s, 0, len);
632	free (s);
633	return ret;
634	}
635
636	/*
637	* AES
638	*/
639
640	int _krb5_AES_string_to_default_iterator = 4096;
641
642	static krb5_error_code
643	AES_string_to_key(krb5_context context,
644	krb5_enctype enctype,
645	krb5_data password,
646	krb5_salt salt,
647	krb5_data opaque,
648	krb5_keyblock *key)
649	{
650	krb5_error_code ret;
651	uint32_t iter;
652	struct encryption_type *et;
653	struct key_data kd;
654
655	if (opaque.length == 0)
656	iter = _krb5_AES_string_to_default_iterator;
657	else if (opaque.length == 4) {
658	unsigned long v;
659	_krb5_get_int(opaque.data, &v, 4);
660	iter = ((uint32_t)v);
661	} else
662	return KRB5_PROG_KEYTYPE_NOSUPP; /* XXX */
663
664	et = _find_enctype(enctype);
665	if (et == NULL)
666	return KRB5_PROG_KEYTYPE_NOSUPP;
667
668	kd.schedule = NULL;
669	ALLOC(kd.key, 1);
670	if(kd.key == NULL) {
671	krb5_set_error_message (context, ENOMEM, N_("malloc: out of memory", ""));
672	return ENOMEM;
673	}
674	kd.key->keytype = enctype;
675	ret = krb5_data_alloc(&kd.key->keyvalue, et->keytype->size);
676	if (ret) {
677	krb5_set_error_message (context, ret, N_("malloc: out of memory", ""));
678	return ret;
679	}
680
681	ret = PKCS5_PBKDF2_HMAC_SHA1(password.data, password.length,
682	salt.saltvalue.data, salt.saltvalue.length,
683	iter,
684	et->keytype->size, kd.key->keyvalue.data);
685	if (ret != 1) {
686	free_key_data(context, &kd, et);
687	krb5_set_error_message(context, KRB5_PROG_KEYTYPE_NOSUPP,
688	"Error calculating s2k");
689	return KRB5_PROG_KEYTYPE_NOSUPP;
690	}
691
692	ret = derive_key(context, et, &kd, "kerberos", strlen("kerberos"));
693	if (ret == 0)
694	ret = krb5_copy_keyblock_contents(context, kd.key, key);
695	free_key_data(context, &kd, et);
696
697	return ret;
698	}
699
700	static void
701	evp_schedule(krb5_context context, struct key_type kt, struct key_data kd)
702	{
703	struct evp_schedule *key = kd->schedule->data;
704	const EVP_CIPHER c = (kt->evp)();
705
706	EVP_CIPHER_CTX_init(&key->ectx);
707	EVP_CIPHER_CTX_init(&key->dctx);
708
709	EVP_CipherInit_ex(&key->ectx, c, NULL, kd->key->keyvalue.data, NULL, 1);
710	EVP_CipherInit_ex(&key->dctx, c, NULL, kd->key->keyvalue.data, NULL, 0);
711	}
712
713	static void
714	evp_cleanup(krb5_context context, struct key_data *kd)
715	{
716	struct evp_schedule *key = kd->schedule->data;
717	EVP_CIPHER_CTX_cleanup(&key->ectx);
718	EVP_CIPHER_CTX_cleanup(&key->dctx);
719	}
720
721	/*
722	*
723	*/
724
725	#ifdef WEAK_ENCTYPES
726	static struct salt_type des_salt[] = {
727	{
728	KRB5_PW_SALT,
729	"pw-salt",
730	krb5_DES_string_to_key
731	},
732	#ifdef ENABLE_AFS_STRING_TO_KEY
733	{
734	KRB5_AFS3_SALT,
735	"afs3-salt",
736	DES_AFS3_string_to_key
737	},
738	#endif
739	{ 0 }
740	};
741	#endif
742
743	#ifdef DES3_OLD_ENCTYPE
744	static struct salt_type des3_salt[] = {
745	{
746	KRB5_PW_SALT,
747	"pw-salt",
748	DES3_string_to_key
749	},
750	{ 0 }
751	};
752	#endif
753
754	static struct salt_type des3_salt_derived[] = {
755	{
756	KRB5_PW_SALT,
757	"pw-salt",
758	DES3_string_to_key_derived
759	},
760	{ 0 }
761	};
762
763	static struct salt_type AES_salt[] = {
764	{
765	KRB5_PW_SALT,
766	"pw-salt",
767	AES_string_to_key
768	},
769	{ 0 }
770	};
771
772	static struct salt_type arcfour_salt[] = {
773	{
774	KRB5_PW_SALT,
775	"pw-salt",
776	ARCFOUR_string_to_key
777	},
778	{ 0 }
779	};
780
781	/*
782	*
783	*/
784
785	static struct key_type keytype_null = {
786	KEYTYPE_NULL,
787	"null",
788	0,
789	0,
790	0,
791	NULL,
792	NULL,
793	NULL
794	};
795
796	#ifdef WEAK_ENCTYPES
797	static struct key_type keytype_des_old = {
798	KEYTYPE_DES,
799	"des-old",
800	56,
801	8,
802	sizeof(DES_key_schedule),
803	krb5_DES_random_key,
804	krb5_DES_schedule_old,
805	des_salt,
806	krb5_DES_random_to_key
807	};
808
809	static struct key_type keytype_des = {
810	KEYTYPE_DES,
811	"des",
812	56,
813	8,
814	sizeof(struct evp_schedule),
815	krb5_DES_random_key,
816	evp_schedule,
817	des_salt,
818	krb5_DES_random_to_key,
819	evp_cleanup,
820	EVP_des_cbc
821	};
822	#endif /* WEAK_ENCTYPES */
823
824	#ifdef DES3_OLD_ENCTYPE
825	static struct key_type keytype_des3 = {
826	KEYTYPE_DES3,
827	"des3",
828	168,
829	24,
830	sizeof(struct evp_schedule),
831	DES3_random_key,
832	evp_schedule,
833	des3_salt,
834	DES3_random_to_key,
835	evp_cleanup,
836	EVP_des_ede3_cbc
837	};
838	#endif
839
840	static struct key_type keytype_des3_derived = {
841	KEYTYPE_DES3,
842	"des3",
843	168,
844	24,
845	sizeof(struct evp_schedule),
846	DES3_random_key,
847	evp_schedule,
848	des3_salt_derived,
849	DES3_random_to_key,
850	evp_cleanup,
851	EVP_des_ede3_cbc
852	};
853
854	static struct key_type keytype_aes128 = {
855	KEYTYPE_AES128,
856	"aes-128",
857	128,
858	16,
859	sizeof(struct evp_schedule),
860	NULL,
861	evp_schedule,
862	AES_salt,
863	NULL,
864	evp_cleanup,
865	EVP_hcrypto_aes_128_cts
866	};
867
868	static struct key_type keytype_aes256 = {
869	KEYTYPE_AES256,
870	"aes-256",
871	256,
872	32,
873	sizeof(struct evp_schedule),
874	NULL,
875	evp_schedule,
876	AES_salt,
877	NULL,
878	evp_cleanup,
879	EVP_hcrypto_aes_256_cts
880	};
881
882	static struct key_type keytype_arcfour = {
883	KEYTYPE_ARCFOUR,
884	"arcfour",
885	128,
886	16,
887	sizeof(RC4_KEY),
888	NULL,
889	ARCFOUR_schedule,
890	arcfour_salt
891	};
892
893	krb5_error_code KRB5_LIB_FUNCTION
894	krb5_salttype_to_string (krb5_context context,
895	krb5_enctype etype,
896	krb5_salttype stype,
897	char **string)
898	{
899	struct encryption_type *e;
900	struct salt_type *st;
901
902	e = _find_enctype (etype);
903	if (e == NULL) {
904	krb5_set_error_message(context, KRB5_PROG_ETYPE_NOSUPP,
905	"encryption type %d not supported",
906	etype);
907	return KRB5_PROG_ETYPE_NOSUPP;
908	}
909	for (st = e->keytype->string_to_key; st && st->type; st++) {
910	if (st->type == stype) {
911	*string = strdup (st->name);
912	if (*string == NULL) {
913	krb5_set_error_message (context, ENOMEM,
914	N_("malloc: out of memory", ""));
915	return ENOMEM;
916	}
917	return 0;
918	}
919	}
920	krb5_set_error_message (context, HEIM_ERR_SALTTYPE_NOSUPP,
921	"salttype %d not supported", stype);
922	return HEIM_ERR_SALTTYPE_NOSUPP;
923	}
924
925	krb5_error_code KRB5_LIB_FUNCTION
926	krb5_string_to_salttype (krb5_context context,
927	krb5_enctype etype,
928	const char *string,
929	krb5_salttype *salttype)
930	{
931	struct encryption_type *e;
932	struct salt_type *st;
933
934	e = _find_enctype (etype);
935	if (e == NULL) {
936	krb5_set_error_message(context, KRB5_PROG_ETYPE_NOSUPP,
937	N_("encryption type %d not supported", ""),
938	etype);
939	return KRB5_PROG_ETYPE_NOSUPP;
940	}
941	for (st = e->keytype->string_to_key; st && st->type; st++) {
942	if (strcasecmp (st->name, string) == 0) {
943	*salttype = st->type;
944	return 0;
945	}
946	}
947	krb5_set_error_message(context, HEIM_ERR_SALTTYPE_NOSUPP,
948	N_("salttype %s not supported", ""), string);
949	return HEIM_ERR_SALTTYPE_NOSUPP;
950	}
951
952	krb5_error_code KRB5_LIB_FUNCTION
953	krb5_get_pw_salt(krb5_context context,
954	krb5_const_principal principal,
955	krb5_salt *salt)
956	{
957	size_t len;
958	int i;
959	krb5_error_code ret;
960	char *p;
961
962	salt->salttype = KRB5_PW_SALT;
963	len = strlen(principal->realm);
964	for (i = 0; i < principal->name.name_string.len; ++i)
965	len += strlen(principal->name.name_string.val[i]);
966	ret = krb5_data_alloc (&salt->saltvalue, len);
967	if (ret)
968	return ret;
969	p = salt->saltvalue.data;
970	memcpy (p, principal->realm, strlen(principal->realm));
971	p += strlen(principal->realm);
972	for (i = 0; i < principal->name.name_string.len; ++i) {
973	memcpy (p,
974	principal->name.name_string.val[i],
975	strlen(principal->name.name_string.val[i]));
976	p += strlen(principal->name.name_string.val[i]);
977	}
978	return 0;
979	}
980
981	krb5_error_code KRB5_LIB_FUNCTION
982	krb5_free_salt(krb5_context context,
983	krb5_salt salt)
984	{
985	krb5_data_free(&salt.saltvalue);
986	return 0;
987	}
988
989	krb5_error_code KRB5_LIB_FUNCTION
990	krb5_string_to_key_data (krb5_context context,
991	krb5_enctype enctype,
992	krb5_data password,
993	krb5_principal principal,
994	krb5_keyblock *key)
995	{
996	krb5_error_code ret;
997	krb5_salt salt;
998
999	ret = krb5_get_pw_salt(context, principal, &salt);
1000	if(ret)
1001	return ret;
1002	ret = krb5_string_to_key_data_salt(context, enctype, password, salt, key);
1003	krb5_free_salt(context, salt);
1004	return ret;
1005	}
1006
1007	krb5_error_code KRB5_LIB_FUNCTION
1008	krb5_string_to_key (krb5_context context,
1009	krb5_enctype enctype,
1010	const char *password,
1011	krb5_principal principal,
1012	krb5_keyblock *key)
1013	{
1014	krb5_data pw;
1015	pw.data = rk_UNCONST(password);
1016	pw.length = strlen(password);
1017	return krb5_string_to_key_data(context, enctype, pw, principal, key);
1018	}
1019
1020	krb5_error_code KRB5_LIB_FUNCTION
1021	krb5_string_to_key_data_salt (krb5_context context,
1022	krb5_enctype enctype,
1023	krb5_data password,
1024	krb5_salt salt,
1025	krb5_keyblock *key)
1026	{
1027	krb5_data opaque;
1028	krb5_data_zero(&opaque);
1029	return krb5_string_to_key_data_salt_opaque(context, enctype, password,
1030	salt, opaque, key);
1031	}
1032
1033	/*
1034	* Do a string -> key for encryption type `enctype' operation on
1035	* `password' (with salt `salt' and the enctype specific data string
1036	* `opaque'), returning the resulting key in `key'
1037	*/
1038
1039	krb5_error_code KRB5_LIB_FUNCTION
1040	krb5_string_to_key_data_salt_opaque (krb5_context context,
1041	krb5_enctype enctype,
1042	krb5_data password,
1043	krb5_salt salt,
1044	krb5_data opaque,
1045	krb5_keyblock *key)
1046	{
1047	struct encryption_type *et =_find_enctype(enctype);
1048	struct salt_type *st;
1049	if(et == NULL) {
1050	krb5_set_error_message(context, KRB5_PROG_ETYPE_NOSUPP,
1051	N_("encryption type %d not supported", ""),
1052	enctype);
1053	return KRB5_PROG_ETYPE_NOSUPP;
1054	}
1055	for(st = et->keytype->string_to_key; st && st->type; st++)
1056	if(st->type == salt.salttype)
1057	return (*st->string_to_key)(context, enctype, password,
1058	salt, opaque, key);
1059	krb5_set_error_message(context, HEIM_ERR_SALTTYPE_NOSUPP,
1060	N_("salt type %d not supported", ""),
1061	salt.salttype);
1062	return HEIM_ERR_SALTTYPE_NOSUPP;
1063	}
1064
1065	/*
1066	* Do a string -> key for encryption type `enctype' operation on the
1067	* string `password' (with salt `salt'), returning the resulting key
1068	* in `key'
1069	*/
1070
1071	krb5_error_code KRB5_LIB_FUNCTION
1072	krb5_string_to_key_salt (krb5_context context,
1073	krb5_enctype enctype,
1074	const char *password,
1075	krb5_salt salt,
1076	krb5_keyblock *key)
1077	{
1078	krb5_data pw;
1079	pw.data = rk_UNCONST(password);
1080	pw.length = strlen(password);
1081	return krb5_string_to_key_data_salt(context, enctype, pw, salt, key);
1082	}
1083
1084	krb5_error_code KRB5_LIB_FUNCTION
1085	krb5_string_to_key_salt_opaque (krb5_context context,
1086	krb5_enctype enctype,
1087	const char *password,
1088	krb5_salt salt,
1089	krb5_data opaque,
1090	krb5_keyblock *key)
1091	{
1092	krb5_data pw;
1093	pw.data = rk_UNCONST(password);
1094	pw.length = strlen(password);
1095	return krb5_string_to_key_data_salt_opaque(context, enctype,
1096	pw, salt, opaque, key);
1097	}
1098
1099	krb5_error_code KRB5_LIB_FUNCTION
1100	krb5_enctype_keysize(krb5_context context,
1101	krb5_enctype type,
1102	size_t *keysize)
1103	{
1104	struct encryption_type *et = _find_enctype(type);
1105	if(et == NULL) {
1106	krb5_set_error_message(context, KRB5_PROG_ETYPE_NOSUPP,
1107	N_("encryption type %d not supported", ""),
1108	type);
1109	return KRB5_PROG_ETYPE_NOSUPP;
1110	}
1111	*keysize = et->keytype->size;
1112	return 0;
1113	}
1114
1115	krb5_error_code KRB5_LIB_FUNCTION
1116	krb5_enctype_keybits(krb5_context context,
1117	krb5_enctype type,
1118	size_t *keybits)
1119	{
1120	struct encryption_type *et = _find_enctype(type);
1121	if(et == NULL) {
1122	krb5_set_error_message(context, KRB5_PROG_ETYPE_NOSUPP,
1123	"encryption type %d not supported",
1124	type);
1125	return KRB5_PROG_ETYPE_NOSUPP;
1126	}
1127	*keybits = et->keytype->bits;
1128	return 0;
1129	}
1130
1131	krb5_error_code KRB5_LIB_FUNCTION
1132	krb5_generate_random_keyblock(krb5_context context,
1133	krb5_enctype type,
1134	krb5_keyblock *key)
1135	{
1136	krb5_error_code ret;
1137	struct encryption_type *et = _find_enctype(type);
1138	if(et == NULL) {
1139	krb5_set_error_message(context, KRB5_PROG_ETYPE_NOSUPP,
1140	N_("encryption type %d not supported", ""),
1141	type);
1142	return KRB5_PROG_ETYPE_NOSUPP;
1143	}
1144	ret = krb5_data_alloc(&key->keyvalue, et->keytype->size);
1145	if(ret)
1146	return ret;
1147	key->keytype = type;
1148	if(et->keytype->random_key)
1149	(*et->keytype->random_key)(context, key);
1150	else
1151	krb5_generate_random_block(key->keyvalue.data,
1152	key->keyvalue.length);
1153	return 0;
1154	}
1155
1156	static krb5_error_code
1157	_key_schedule(krb5_context context,
1158	struct key_data *key)
1159	{
1160	krb5_error_code ret;
1161	struct encryption_type *et = _find_enctype(key->key->keytype);
1162	struct key_type *kt;
1163
1164	if (et == NULL) {
1165	krb5_set_error_message (context, KRB5_PROG_ETYPE_NOSUPP,
1166	N_("encryption type %d not supported", ""),
1167	key->key->keytype);
1168	return KRB5_PROG_ETYPE_NOSUPP;
1169	}
1170
1171	kt = et->keytype;
1172
1173	if(kt->schedule == NULL)
1174	return 0;
1175	if (key->schedule != NULL)
1176	return 0;
1177	ALLOC(key->schedule, 1);
1178	if(key->schedule == NULL) {
1179	krb5_set_error_message(context, ENOMEM, N_("malloc: out of memory", ""));
1180	return ENOMEM;
1181	}
1182	ret = krb5_data_alloc(key->schedule, kt->schedule_size);
1183	if(ret) {
1184	free(key->schedule);
1185	key->schedule = NULL;
1186	return ret;
1187	}
1188	(*kt->schedule)(context, kt, key);
1189	return 0;
1190	}
1191
1192	/************************************************************
1193	* *
1194	************************************************************/
1195
1196	static krb5_error_code
1197	NONE_checksum(krb5_context context,
1198	struct key_data *key,
1199	const void *data,
1200	size_t len,
1201	unsigned usage,
1202	Checksum *C)
1203	{
1204	return 0;
1205	}
1206
1207	static krb5_error_code
1208	CRC32_checksum(krb5_context context,
1209	struct key_data *key,
1210	const void *data,
1211	size_t len,
1212	unsigned usage,
1213	Checksum *C)
1214	{
1215	uint32_t crc;
1216	unsigned char *r = C->checksum.data;
1217	_krb5_crc_init_table ();
1218	crc = _krb5_crc_update (data, len, 0);
1219	r[0] = crc & 0xff;
1220	r[1] = (crc >> 8) & 0xff;
1221	r[2] = (crc >> 16) & 0xff;
1222	r[3] = (crc >> 24) & 0xff;
1223	return 0;
1224	}
1225
1226	static krb5_error_code
1227	RSA_MD4_checksum(krb5_context context,
1228	struct key_data *key,
1229	const void *data,
1230	size_t len,
1231	unsigned usage,
1232	Checksum *C)
1233	{
1234	if (EVP_Digest(data, len, C->checksum.data, NULL, EVP_md4(), NULL) != 1)
1235	krb5_abortx(context, "md4 checksum failed");
1236	return 0;
1237	}
1238
1239	static krb5_error_code
1240	des_checksum(krb5_context context,
1241	const EVP_MD *evp_md,
1242	struct key_data *key,
1243	const void *data,
1244	size_t len,
1245	Checksum *cksum)
1246	{
1247	struct evp_schedule *ctx = key->schedule->data;
1248	EVP_MD_CTX *m;
1249	DES_cblock ivec;
1250	unsigned char *p = cksum->checksum.data;
1251
1252	krb5_generate_random_block(p, 8);
1253
1254	m = EVP_MD_CTX_create();
1255	if (m == NULL) {
1256	krb5_set_error_message(context, ENOMEM, N_("malloc: out of memory", ""));
1257	return ENOMEM;
1258	}
1259
1260	EVP_DigestInit_ex(m, evp_md, NULL);
1261	EVP_DigestUpdate(m, p, 8);
1262	EVP_DigestUpdate(m, data, len);
1263	EVP_DigestFinal_ex (m, p + 8, NULL);
1264	EVP_MD_CTX_destroy(m);
1265	memset (&ivec, 0, sizeof(ivec));
1266	EVP_CipherInit_ex(&ctx->ectx, NULL, NULL, NULL, (void *)&ivec, -1);
1267	EVP_Cipher(&ctx->ectx, p, p, 24);
1268
1269	return 0;
1270	}
1271
1272	static krb5_error_code
1273	des_verify(krb5_context context,
1274	const EVP_MD *evp_md,
1275	struct key_data *key,
1276	const void *data,
1277	size_t len,
1278	Checksum *C)
1279	{
1280	struct evp_schedule *ctx = key->schedule->data;
1281	EVP_MD_CTX *m;
1282	unsigned char tmp[24];
1283	unsigned char res[16];
1284	DES_cblock ivec;
1285	krb5_error_code ret = 0;
1286
1287	m = EVP_MD_CTX_create();
1288	if (m == NULL) {
1289	krb5_set_error_message(context, ENOMEM, N_("malloc: out of memory", ""));
1290	return ENOMEM;
1291	}
1292
1293	memset(&ivec, 0, sizeof(ivec));
1294	EVP_CipherInit_ex(&ctx->dctx, NULL, NULL, NULL, (void *)&ivec, -1);
1295	EVP_Cipher(&ctx->dctx, tmp, C->checksum.data, 24);
1296
1297	EVP_DigestInit_ex(m, evp_md, NULL);
1298	EVP_DigestUpdate(m, tmp, 8); /* confounder */
1299	EVP_DigestUpdate(m, data, len);
1300	EVP_DigestFinal_ex (m, res, NULL);
1301	EVP_MD_CTX_destroy(m);
1302	if(memcmp(res, tmp + 8, sizeof(res)) != 0) {
1303	krb5_clear_error_message (context);
1304	ret = KRB5KRB_AP_ERR_BAD_INTEGRITY;
1305	}
1306	memset(tmp, 0, sizeof(tmp));
1307	memset(res, 0, sizeof(res));
1308	return ret;
1309	}
1310
1311	static krb5_error_code
1312	RSA_MD4_DES_checksum(krb5_context context,
1313	struct key_data *key,
1314	const void *data,
1315	size_t len,
1316	unsigned usage,
1317	Checksum *cksum)
1318	{
1319	return des_checksum(context, EVP_md4(), key, data, len, cksum);
1320	}
1321
1322	static krb5_error_code
1323	RSA_MD4_DES_verify(krb5_context context,
1324	struct key_data *key,
1325	const void *data,
1326	size_t len,
1327	unsigned usage,
1328	Checksum *C)
1329	{
1330	return des_verify(context, EVP_md5(), key, data, len, C);
1331	}
1332
1333	static krb5_error_code
1334	RSA_MD5_checksum(krb5_context context,
1335	struct key_data *key,
1336	const void *data,
1337	size_t len,
1338	unsigned usage,
1339	Checksum *C)
1340	{
1341	if (EVP_Digest(data, len, C->checksum.data, NULL, EVP_md5(), NULL) != 1)
1342	krb5_abortx(context, "md5 checksum failed");
1343	return 0;
1344	}
1345
1346	static krb5_error_code
1347	RSA_MD5_DES_checksum(krb5_context context,
1348	struct key_data *key,
1349	const void *data,
1350	size_t len,
1351	unsigned usage,
1352	Checksum *C)
1353	{
1354	return des_checksum(context, EVP_md5(), key, data, len, C);
1355	}
1356
1357	static krb5_error_code
1358	RSA_MD5_DES_verify(krb5_context context,
1359	struct key_data *key,
1360	const void *data,
1361	size_t len,
1362	unsigned usage,
1363	Checksum *C)
1364	{
1365	return des_verify(context, EVP_md5(), key, data, len, C);
1366	}
1367
1368	#ifdef DES3_OLD_ENCTYPE
1369	static krb5_error_code
1370	RSA_MD5_DES3_checksum(krb5_context context,
1371	struct key_data *key,
1372	const void *data,
1373	size_t len,
1374	unsigned usage,
1375	Checksum *C)
1376	{
1377	return des_checksum(context, EVP_md5(), key, data, len, C);
1378	}
1379
1380	static krb5_error_code
1381	RSA_MD5_DES3_verify(krb5_context context,
1382	struct key_data *key,
1383	const void *data,
1384	size_t len,
1385	unsigned usage,
1386	Checksum *C)
1387	{
1388	return des_verify(context, EVP_md5(), key, data, len, C);
1389	}
1390	#endif
1391
1392	static krb5_error_code
1393	SHA1_checksum(krb5_context context,
1394	struct key_data *key,
1395	const void *data,
1396	size_t len,
1397	unsigned usage,
1398	Checksum *C)
1399	{
1400	if (EVP_Digest(data, len, C->checksum.data, NULL, EVP_sha1(), NULL) != 1)
1401	krb5_abortx(context, "sha1 checksum failed");
1402	return 0;
1403	}
1404
1405	/* HMAC according to RFC2104 */
1406	static krb5_error_code
1407	hmac(krb5_context context,
1408	struct checksum_type *cm,
1409	const void *data,
1410	size_t len,
1411	unsigned usage,
1412	struct key_data *keyblock,
1413	Checksum *result)
1414	{
1415	unsigned char ipad, opad;
1416	unsigned char *key;
1417	size_t key_len;
1418	int i;
1419
1420	ipad = malloc(cm->blocksize + len);
1421	if (ipad == NULL)
1422	return ENOMEM;
1423	opad = malloc(cm->blocksize + cm->checksumsize);
1424	if (opad == NULL) {
1425	free(ipad);
1426	return ENOMEM;
1427	}
1428	memset(ipad, 0x36, cm->blocksize);
1429	memset(opad, 0x5c, cm->blocksize);
1430
1431	if(keyblock->key->keyvalue.length > cm->blocksize){
1432	(*cm->checksum)(context,
1433	keyblock,
1434	keyblock->key->keyvalue.data,
1435	keyblock->key->keyvalue.length,
1436	usage,
1437	result);
1438	key = result->checksum.data;
1439	key_len = result->checksum.length;
1440	} else {
1441	key = keyblock->key->keyvalue.data;
1442	key_len = keyblock->key->keyvalue.length;
1443	}
1444	for(i = 0; i < key_len; i++){
1445	ipad[i] ^= key[i];
1446	opad[i] ^= key[i];
1447	}
1448	memcpy(ipad + cm->blocksize, data, len);
1449	(*cm->checksum)(context, keyblock, ipad, cm->blocksize + len,
1450	usage, result);
1451	memcpy(opad + cm->blocksize, result->checksum.data,
1452	result->checksum.length);
1453	(*cm->checksum)(context, keyblock, opad,
1454	cm->blocksize + cm->checksumsize, usage, result);
1455	memset(ipad, 0, cm->blocksize + len);
1456	free(ipad);
1457	memset(opad, 0, cm->blocksize + cm->checksumsize);
1458	free(opad);
1459
1460	return 0;
1461	}
1462
1463	krb5_error_code KRB5_LIB_FUNCTION
1464	krb5_hmac(krb5_context context,
1465	krb5_cksumtype cktype,
1466	const void *data,
1467	size_t len,
1468	unsigned usage,
1469	krb5_keyblock *key,
1470	Checksum *result)
1471	{
1472	struct checksum_type *c = _find_checksum(cktype);
1473	struct key_data kd;
1474	krb5_error_code ret;
1475
1476	if (c == NULL) {
1477	krb5_set_error_message (context, KRB5_PROG_SUMTYPE_NOSUPP,
1478	N_("checksum type %d not supported", ""),
1479	cktype);
1480	return KRB5_PROG_SUMTYPE_NOSUPP;
1481	}
1482
1483	kd.key = key;
1484	kd.schedule = NULL;
1485
1486	ret = hmac(context, c, data, len, usage, &kd, result);
1487
1488	if (kd.schedule)
1489	krb5_free_data(context, kd.schedule);
1490
1491	return ret;
1492	}
1493
1494	static krb5_error_code
1495	SP_HMAC_SHA1_checksum(krb5_context context,
1496	struct key_data *key,
1497	const void *data,
1498	size_t len,
1499	unsigned usage,
1500	Checksum *result)
1501	{
1502	struct checksum_type *c = _find_checksum(CKSUMTYPE_SHA1);
1503	Checksum res;
1504	char sha1_data[20];
1505	krb5_error_code ret;
1506
1507	res.checksum.data = sha1_data;
1508	res.checksum.length = sizeof(sha1_data);
1509
1510	ret = hmac(context, c, data, len, usage, key, &res);
1511	if (ret)
1512	krb5_abortx(context, "hmac failed");
1513	memcpy(result->checksum.data, res.checksum.data, result->checksum.length);
1514	return 0;
1515	}
1516
1517	/*
1518	* checksum according to section 5. of draft-brezak-win2k-krb-rc4-hmac-03.txt
1519	*/
1520
1521	static krb5_error_code
1522	HMAC_MD5_checksum(krb5_context context,
1523	struct key_data *key,
1524	const void *data,
1525	size_t len,
1526	unsigned usage,
1527	Checksum *result)
1528	{
1529	EVP_MD_CTX *m;
1530	struct checksum_type *c = _find_checksum (CKSUMTYPE_RSA_MD5);
1531	const char signature[] = "signaturekey";
1532	Checksum ksign_c;
1533	struct key_data ksign;
1534	krb5_keyblock kb;
1535	unsigned char t[4];
1536	unsigned char tmp[16];
1537	unsigned char ksign_c_data[16];
1538	krb5_error_code ret;
1539
1540	m = EVP_MD_CTX_create();
1541	if (m == NULL) {
1542	krb5_set_error_message(context, ENOMEM, N_("malloc: out of memory", ""));
1543	return ENOMEM;
1544	}
1545	ksign_c.checksum.length = sizeof(ksign_c_data);
1546	ksign_c.checksum.data = ksign_c_data;
1547	ret = hmac(context, c, signature, sizeof(signature), 0, key, &ksign_c);
1548	if (ret) {
1549	EVP_MD_CTX_destroy(m);
1550	return ret;
1551	}
1552	ksign.key = &kb;
1553	kb.keyvalue = ksign_c.checksum;
1554	EVP_DigestInit_ex(m, EVP_md5(), NULL);
1555	t[0] = (usage >> 0) & 0xFF;
1556	t[1] = (usage >> 8) & 0xFF;
1557	t[2] = (usage >> 16) & 0xFF;
1558	t[3] = (usage >> 24) & 0xFF;
1559	EVP_DigestUpdate(m, t, 4);
1560	EVP_DigestUpdate(m, data, len);
1561	EVP_DigestFinal_ex (m, tmp, NULL);
1562	EVP_MD_CTX_destroy(m);
1563
1564	ret = hmac(context, c, tmp, sizeof(tmp), 0, &ksign, result);
1565	if (ret)
1566	return ret;
1567	return 0;
1568	}
1569
1570	static struct checksum_type checksum_none = {
1571	CKSUMTYPE_NONE,
1572	"none",
1573	1,
1574	0,
1575	0,
1576	NONE_checksum,
1577	NULL
1578	};
1579	static struct checksum_type checksum_crc32 = {
1580	CKSUMTYPE_CRC32,
1581	"crc32",
1582	1,
1583	4,
1584	0,
1585	CRC32_checksum,
1586	NULL
1587	};
1588	static struct checksum_type checksum_rsa_md4 = {
1589	CKSUMTYPE_RSA_MD4,
1590	"rsa-md4",
1591	64,
1592	16,
1593	F_CPROOF,
1594	RSA_MD4_checksum,
1595	NULL
1596	};
1597	static struct checksum_type checksum_rsa_md4_des = {
1598	CKSUMTYPE_RSA_MD4_DES,
1599	"rsa-md4-des",
1600	64,
1601	24,
1602	F_KEYED \| F_CPROOF \| F_VARIANT,
1603	RSA_MD4_DES_checksum,
1604	RSA_MD4_DES_verify
1605	};
1606	static struct checksum_type checksum_rsa_md5 = {
1607	CKSUMTYPE_RSA_MD5,
1608	"rsa-md5",
1609	64,
1610	16,
1611	F_CPROOF,
1612	RSA_MD5_checksum,
1613	NULL
1614	};
1615	static struct checksum_type checksum_rsa_md5_des = {
1616	CKSUMTYPE_RSA_MD5_DES,
1617	"rsa-md5-des",
1618	64,
1619	24,
1620	F_KEYED \| F_CPROOF \| F_VARIANT,
1621	RSA_MD5_DES_checksum,
1622	RSA_MD5_DES_verify
1623	};
1624	#ifdef DES3_OLD_ENCTYPE
1625	static struct checksum_type checksum_rsa_md5_des3 = {
1626	CKSUMTYPE_RSA_MD5_DES3,
1627	"rsa-md5-des3",
1628	64,
1629	24,
1630	F_KEYED \| F_CPROOF \| F_VARIANT,
1631	RSA_MD5_DES3_checksum,
1632	RSA_MD5_DES3_verify
1633	};
1634	#endif
1635	static struct checksum_type checksum_sha1 = {
1636	CKSUMTYPE_SHA1,
1637	"sha1",
1638	64,
1639	20,
1640	F_CPROOF,
1641	SHA1_checksum,
1642	NULL
1643	};
1644	static struct checksum_type checksum_hmac_sha1_des3 = {
1645	CKSUMTYPE_HMAC_SHA1_DES3,
1646	"hmac-sha1-des3",
1647	64,
1648	20,
1649	F_KEYED \| F_CPROOF \| F_DERIVED,
1650	SP_HMAC_SHA1_checksum,
1651	NULL
1652	};
1653
1654	static struct checksum_type checksum_hmac_sha1_aes128 = {
1655	CKSUMTYPE_HMAC_SHA1_96_AES_128,
1656	"hmac-sha1-96-aes128",
1657	64,
1658	12,
1659	F_KEYED \| F_CPROOF \| F_DERIVED,
1660	SP_HMAC_SHA1_checksum,
1661	NULL
1662	};
1663
1664	static struct checksum_type checksum_hmac_sha1_aes256 = {
1665	CKSUMTYPE_HMAC_SHA1_96_AES_256,
1666	"hmac-sha1-96-aes256",
1667	64,
1668	12,
1669	F_KEYED \| F_CPROOF \| F_DERIVED,
1670	SP_HMAC_SHA1_checksum,
1671	NULL
1672	};
1673
1674	static struct checksum_type checksum_hmac_md5 = {
1675	CKSUMTYPE_HMAC_MD5,
1676	"hmac-md5",
1677	64,
1678	16,
1679	F_KEYED \| F_CPROOF,
1680	HMAC_MD5_checksum,
1681	NULL
1682	};
1683
1684	static struct checksum_type *checksum_types[] = {
1685	&checksum_none,
1686	&checksum_crc32,
1687	&checksum_rsa_md4,
1688	&checksum_rsa_md4_des,
1689	&checksum_rsa_md5,
1690	&checksum_rsa_md5_des,
1691	#ifdef DES3_OLD_ENCTYPE
1692	&checksum_rsa_md5_des3,
1693	#endif
1694	&checksum_sha1,
1695	&checksum_hmac_sha1_des3,
1696	&checksum_hmac_sha1_aes128,
1697	&checksum_hmac_sha1_aes256,
1698	&checksum_hmac_md5
1699	};
1700
1701	static int num_checksums = sizeof(checksum_types) / sizeof(checksum_types[0]);
1702
1703	static struct checksum_type *
1704	_find_checksum(krb5_cksumtype type)
1705	{
1706	int i;
1707	for(i = 0; i < num_checksums; i++)
1708	if(checksum_types[i]->type == type)
1709	return checksum_types[i];
1710	return NULL;
1711	}
1712
1713	static krb5_error_code
1714	get_checksum_key(krb5_context context,
1715	krb5_crypto crypto,
1716	unsigned usage, /* not krb5_key_usage */
1717	struct checksum_type *ct,
1718	struct key_data **key)
1719	{
1720	krb5_error_code ret = 0;
1721
1722	if(ct->flags & F_DERIVED)
1723	ret = _get_derived_key(context, crypto, usage, key);
1724	else if(ct->flags & F_VARIANT) {
1725	int i;
1726
1727	key = _new_derived_key(crypto, 0xff/ KRB5_KU_RFC1510_VARIANT */);
1728	if(*key == NULL) {
1729	krb5_set_error_message(context, ENOMEM, N_("malloc: out of memory", ""));
1730	return ENOMEM;
1731	}
1732	ret = krb5_copy_keyblock(context, crypto->key.key, &(*key)->key);
1733	if(ret)
1734	return ret;
1735	for(i = 0; i < (*key)->key->keyvalue.length; i++)
1736	((unsigned char)(key)->key->keyvalue.data)[i] ^= 0xF0;
1737	} else {
1738	*key = &crypto->key;
1739	}
1740	if(ret == 0)
1741	ret = _key_schedule(context, *key);
1742	return ret;
1743	}
1744
1745	static krb5_error_code
1746	create_checksum (krb5_context context,
1747	struct checksum_type *ct,
1748	krb5_crypto crypto,
1749	unsigned usage,
1750	void *data,
1751	size_t len,
1752	Checksum *result)
1753	{
1754	krb5_error_code ret;
1755	struct key_data *dkey;
1756	int keyed_checksum;
1757
1758	if (ct->flags & F_DISABLED) {
1759	krb5_clear_error_message (context);
1760	return KRB5_PROG_SUMTYPE_NOSUPP;
1761	}
1762	keyed_checksum = (ct->flags & F_KEYED) != 0;
1763	if(keyed_checksum && crypto == NULL) {
1764	krb5_set_error_message (context, KRB5_PROG_SUMTYPE_NOSUPP,
1765	N_("Checksum type %s is keyed but no "
1766	"crypto context (key) was passed in", ""),
1767	ct->name);
1768	return KRB5_PROG_SUMTYPE_NOSUPP; /* XXX */
1769	}
1770	if(keyed_checksum) {
1771	ret = get_checksum_key(context, crypto, usage, ct, &dkey);
1772	if (ret)
1773	return ret;
1774	} else
1775	dkey = NULL;
1776	result->cksumtype = ct->type;
1777	ret = krb5_data_alloc(&result->checksum, ct->checksumsize);
1778	if (ret)
1779	return (ret);
1780	return (*ct->checksum)(context, dkey, data, len, usage, result);
1781	}
1782
1783	static int
1784	arcfour_checksum_p(struct checksum_type *ct, krb5_crypto crypto)
1785	{
1786	return (ct->type == CKSUMTYPE_HMAC_MD5) &&
1787	(crypto->key.key->keytype == KEYTYPE_ARCFOUR);
1788	}
1789
1790	krb5_error_code KRB5_LIB_FUNCTION
1791	krb5_create_checksum(krb5_context context,
1792	krb5_crypto crypto,
1793	krb5_key_usage usage,
1794	int type,
1795	void *data,
1796	size_t len,
1797	Checksum *result)
1798	{
1799	struct checksum_type *ct = NULL;
1800	unsigned keyusage;
1801
1802	/* type 0 -> pick from crypto */
1803	if (type) {
1804	ct = _find_checksum(type);
1805	} else if (crypto) {
1806	ct = crypto->et->keyed_checksum;
1807	if (ct == NULL)
1808	ct = crypto->et->checksum;
1809	}
1810
1811	if(ct == NULL) {
1812	krb5_set_error_message (context, KRB5_PROG_SUMTYPE_NOSUPP,
1813	N_("checksum type %d not supported", ""),
1814	type);
1815	return KRB5_PROG_SUMTYPE_NOSUPP;
1816	}
1817
1818	if (arcfour_checksum_p(ct, crypto)) {
1819	keyusage = usage;
1820	usage2arcfour(context, &keyusage);
1821	} else
1822	keyusage = CHECKSUM_USAGE(usage);
1823
1824	return create_checksum(context, ct, crypto, keyusage,
1825	data, len, result);
1826	}
1827
1828	static krb5_error_code
1829	verify_checksum(krb5_context context,
1830	krb5_crypto crypto,
1831	unsigned usage, /* not krb5_key_usage */
1832	void *data,
1833	size_t len,
1834	Checksum *cksum)
1835	{
1836	krb5_error_code ret;
1837	struct key_data *dkey;
1838	int keyed_checksum;
1839	Checksum c;
1840	struct checksum_type *ct;
1841
1842	ct = _find_checksum(cksum->cksumtype);
1843	if (ct == NULL \|\| (ct->flags & F_DISABLED)) {
1844	krb5_set_error_message (context, KRB5_PROG_SUMTYPE_NOSUPP,
1845	N_("checksum type %d not supported", ""),
1846	cksum->cksumtype);
1847	return KRB5_PROG_SUMTYPE_NOSUPP;
1848	}
1849	if(ct->checksumsize != cksum->checksum.length) {
1850	krb5_clear_error_message (context);
1851	return KRB5KRB_AP_ERR_BAD_INTEGRITY; /* XXX */
1852	}
1853	keyed_checksum = (ct->flags & F_KEYED) != 0;
1854	if(keyed_checksum) {
1855	struct checksum_type *kct;
1856	if (crypto == NULL) {
1857	krb5_set_error_message (context, KRB5_PROG_SUMTYPE_NOSUPP,
1858	N_("Checksum type %s is keyed but no "
1859	"crypto context (key) was passed in", ""),
1860	ct->name);
1861	return KRB5_PROG_SUMTYPE_NOSUPP; /* XXX */
1862	}
1863	kct = crypto->et->keyed_checksum;
1864	if (kct != NULL && kct->type != ct->type) {
1865	krb5_set_error_message (context, KRB5_PROG_SUMTYPE_NOSUPP,
1866	N_("Checksum type %s is keyed, but "
1867	"the key type %s passed didnt have that checksum "
1868	"type as the keyed type", ""),
1869	ct->name, crypto->et->name);
1870	return KRB5_PROG_SUMTYPE_NOSUPP; /* XXX */
1871	}
1872
1873	ret = get_checksum_key(context, crypto, usage, ct, &dkey);
1874	if (ret)
1875	return ret;
1876	} else
1877	dkey = NULL;
1878	if(ct->verify)
1879	return (*ct->verify)(context, dkey, data, len, usage, cksum);
1880
1881	ret = krb5_data_alloc (&c.checksum, ct->checksumsize);
1882	if (ret)
1883	return ret;
1884
1885	ret = (*ct->checksum)(context, dkey, data, len, usage, &c);
1886	if (ret) {
1887	krb5_data_free(&c.checksum);
1888	return ret;
1889	}
1890
1891	if(c.checksum.length != cksum->checksum.length \|\|
1892	memcmp(c.checksum.data, cksum->checksum.data, c.checksum.length)) {
1893	krb5_clear_error_message (context);
1894	ret = KRB5KRB_AP_ERR_BAD_INTEGRITY;
1895	} else {
1896	ret = 0;
1897	}
1898	krb5_data_free (&c.checksum);
1899	return ret;
1900	}
1901
1902	krb5_error_code KRB5_LIB_FUNCTION
1903	krb5_verify_checksum(krb5_context context,
1904	krb5_crypto crypto,
1905	krb5_key_usage usage,
1906	void *data,
1907	size_t len,
1908	Checksum *cksum)
1909	{
1910	struct checksum_type *ct;
1911	unsigned keyusage;
1912
1913	ct = _find_checksum(cksum->cksumtype);
1914	if(ct == NULL) {
1915	krb5_set_error_message (context, KRB5_PROG_SUMTYPE_NOSUPP,
1916	N_("checksum type %d not supported", ""),
1917	cksum->cksumtype);
1918	return KRB5_PROG_SUMTYPE_NOSUPP;
1919	}
1920
1921	if (arcfour_checksum_p(ct, crypto)) {
1922	keyusage = usage;
1923	usage2arcfour(context, &keyusage);
1924	} else
1925	keyusage = CHECKSUM_USAGE(usage);
1926
1927	return verify_checksum(context, crypto, keyusage,
1928	data, len, cksum);
1929	}
1930
1931	krb5_error_code KRB5_LIB_FUNCTION
1932	krb5_crypto_get_checksum_type(krb5_context context,
1933	krb5_crypto crypto,
1934	krb5_cksumtype *type)
1935	{
1936	struct checksum_type *ct = NULL;
1937
1938	if (crypto != NULL) {
1939	ct = crypto->et->keyed_checksum;
1940	if (ct == NULL)
1941	ct = crypto->et->checksum;
1942	}
1943
1944	if (ct == NULL) {
1945	krb5_set_error_message (context, KRB5_PROG_SUMTYPE_NOSUPP,
1946	N_("checksum type not found", ""));
1947	return KRB5_PROG_SUMTYPE_NOSUPP;
1948	}
1949
1950	*type = ct->type;
1951
1952	return 0;
1953	}
1954
1955
1956	krb5_error_code KRB5_LIB_FUNCTION
1957	krb5_checksumsize(krb5_context context,
1958	krb5_cksumtype type,
1959	size_t *size)
1960	{
1961	struct checksum_type *ct = _find_checksum(type);
1962	if(ct == NULL) {
1963	krb5_set_error_message (context, KRB5_PROG_SUMTYPE_NOSUPP,
1964	N_("checksum type %d not supported", ""),
1965	type);
1966	return KRB5_PROG_SUMTYPE_NOSUPP;
1967	}
1968	*size = ct->checksumsize;
1969	return 0;
1970	}
1971
1972	krb5_boolean KRB5_LIB_FUNCTION
1973	krb5_checksum_is_keyed(krb5_context context,
1974	krb5_cksumtype type)
1975	{
1976	struct checksum_type *ct = _find_checksum(type);
1977	if(ct == NULL) {
1978	if (context)
1979	krb5_set_error_message (context, KRB5_PROG_SUMTYPE_NOSUPP,
1980	N_("checksum type %d not supported", ""),
1981	type);
1982	return KRB5_PROG_SUMTYPE_NOSUPP;
1983	}
1984	return ct->flags & F_KEYED;
1985	}
1986
1987	krb5_boolean KRB5_LIB_FUNCTION
1988	krb5_checksum_is_collision_proof(krb5_context context,
1989	krb5_cksumtype type)
1990	{
1991	struct checksum_type *ct = _find_checksum(type);
1992	if(ct == NULL) {
1993	if (context)
1994	krb5_set_error_message (context, KRB5_PROG_SUMTYPE_NOSUPP,
1995	N_("checksum type %d not supported", ""),
1996	type);
1997	return KRB5_PROG_SUMTYPE_NOSUPP;
1998	}
1999	return ct->flags & F_CPROOF;
2000	}
2001
2002	krb5_error_code KRB5_LIB_FUNCTION
2003	krb5_checksum_disable(krb5_context context,
2004	krb5_cksumtype type)
2005	{
2006	struct checksum_type *ct = _find_checksum(type);
2007	if(ct == NULL) {
2008	if (context)
2009	krb5_set_error_message (context, KRB5_PROG_SUMTYPE_NOSUPP,
2010	N_("checksum type %d not supported", ""),
2011	type);
2012	return KRB5_PROG_SUMTYPE_NOSUPP;
2013	}
2014	ct->flags \|= F_DISABLED;
2015	return 0;
2016	}
2017
2018	/************************************************************
2019	* *
2020	************************************************************/
2021
2022	static krb5_error_code
2023	NULL_encrypt(krb5_context context,
2024	struct key_data *key,
2025	void *data,
2026	size_t len,
2027	krb5_boolean encryptp,
2028	int usage,
2029	void *ivec)
2030	{
2031	return 0;
2032	}
2033
2034	static krb5_error_code
2035	evp_encrypt(krb5_context context,
2036	struct key_data *key,
2037	void *data,
2038	size_t len,
2039	krb5_boolean encryptp,
2040	int usage,
2041	void *ivec)
2042	{
2043	struct evp_schedule *ctx = key->schedule->data;
2044	EVP_CIPHER_CTX *c;
2045	c = encryptp ? &ctx->ectx : &ctx->dctx;
2046	if (ivec == NULL) {
2047	/* alloca ? */
2048	size_t len = EVP_CIPHER_CTX_iv_length(c);
2049	void *loiv = malloc(len);
2050	if (loiv == NULL) {
2051	krb5_clear_error_message(context);
2052	return ENOMEM;
2053	}
2054	memset(loiv, 0, len);
2055	EVP_CipherInit_ex(c, NULL, NULL, NULL, loiv, -1);
2056	free(loiv);
2057	} else
2058	EVP_CipherInit_ex(c, NULL, NULL, NULL, ivec, -1);
2059	EVP_Cipher(c, data, data, len);
2060	return 0;
2061	}
2062
2063	#ifdef WEAK_ENCTYPES
2064	static krb5_error_code
2065	evp_des_encrypt_null_ivec(krb5_context context,
2066	struct key_data *key,
2067	void *data,
2068	size_t len,
2069	krb5_boolean encryptp,
2070	int usage,
2071	void *ignore_ivec)
2072	{
2073	struct evp_schedule *ctx = key->schedule->data;
2074	EVP_CIPHER_CTX *c;
2075	DES_cblock ivec;
2076	memset(&ivec, 0, sizeof(ivec));
2077	c = encryptp ? &ctx->ectx : &ctx->dctx;
2078	EVP_CipherInit_ex(c, NULL, NULL, NULL, (void *)&ivec, -1);
2079	EVP_Cipher(c, data, data, len);
2080	return 0;
2081	}
2082
2083	static krb5_error_code
2084	evp_des_encrypt_key_ivec(krb5_context context,
2085	struct key_data *key,
2086	void *data,
2087	size_t len,
2088	krb5_boolean encryptp,
2089	int usage,
2090	void *ignore_ivec)
2091	{
2092	struct evp_schedule *ctx = key->schedule->data;
2093	EVP_CIPHER_CTX *c;
2094	DES_cblock ivec;
2095	memcpy(&ivec, key->key->keyvalue.data, sizeof(ivec));
2096	c = encryptp ? &ctx->ectx : &ctx->dctx;
2097	EVP_CipherInit_ex(c, NULL, NULL, NULL, (void *)&ivec, -1);
2098	EVP_Cipher(c, data, data, len);
2099	return 0;
2100	}
2101
2102	static krb5_error_code
2103	DES_CFB64_encrypt_null_ivec(krb5_context context,
2104	struct key_data *key,
2105	void *data,
2106	size_t len,
2107	krb5_boolean encryptp,
2108	int usage,
2109	void *ignore_ivec)
2110	{
2111	DES_cblock ivec;
2112	int num = 0;
2113	DES_key_schedule *s = key->schedule->data;
2114	memset(&ivec, 0, sizeof(ivec));
2115
2116	DES_cfb64_encrypt(data, data, len, s, &ivec, &num, encryptp);
2117	return 0;
2118	}
2119
2120	static krb5_error_code
2121	DES_PCBC_encrypt_key_ivec(krb5_context context,
2122	struct key_data *key,
2123	void *data,
2124	size_t len,
2125	krb5_boolean encryptp,
2126	int usage,
2127	void *ignore_ivec)
2128	{
2129	DES_cblock ivec;
2130	DES_key_schedule *s = key->schedule->data;
2131	memcpy(&ivec, key->key->keyvalue.data, sizeof(ivec));
2132
2133	DES_pcbc_encrypt(data, data, len, s, &ivec, encryptp);
2134	return 0;
2135	}
2136	#endif
2137
2138	/*
2139	* section 6 of draft-brezak-win2k-krb-rc4-hmac-03
2140	*
2141	* warning: not for small children
2142	*/
2143
2144	static krb5_error_code
2145	ARCFOUR_subencrypt(krb5_context context,
2146	struct key_data *key,
2147	void *data,
2148	size_t len,
2149	unsigned usage,
2150	void *ivec)
2151	{
2152	struct checksum_type *c = _find_checksum (CKSUMTYPE_RSA_MD5);
2153	Checksum k1_c, k2_c, k3_c, cksum;
2154	struct key_data ke;
2155	krb5_keyblock kb;
2156	unsigned char t[4];
2157	RC4_KEY rc4_key;
2158	unsigned char *cdata = data;
2159	unsigned char k1_c_data[16], k2_c_data[16], k3_c_data[16];
2160	krb5_error_code ret;
2161
2162	t[0] = (usage >> 0) & 0xFF;
2163	t[1] = (usage >> 8) & 0xFF;
2164	t[2] = (usage >> 16) & 0xFF;
2165	t[3] = (usage >> 24) & 0xFF;
2166
2167	k1_c.checksum.length = sizeof(k1_c_data);
2168	k1_c.checksum.data = k1_c_data;
2169
2170	ret = hmac(NULL, c, t, sizeof(t), 0, key, &k1_c);
2171	if (ret)
2172	krb5_abortx(context, "hmac failed");
2173
2174	memcpy (k2_c_data, k1_c_data, sizeof(k1_c_data));
2175
2176	k2_c.checksum.length = sizeof(k2_c_data);
2177	k2_c.checksum.data = k2_c_data;
2178
2179	ke.key = &kb;
2180	kb.keyvalue = k2_c.checksum;
2181
2182	cksum.checksum.length = 16;
2183	cksum.checksum.data = data;
2184
2185	ret = hmac(NULL, c, cdata + 16, len - 16, 0, &ke, &cksum);
2186	if (ret)
2187	krb5_abortx(context, "hmac failed");
2188
2189	ke.key = &kb;
2190	kb.keyvalue = k1_c.checksum;
2191
2192	k3_c.checksum.length = sizeof(k3_c_data);
2193	k3_c.checksum.data = k3_c_data;
2194
2195	ret = hmac(NULL, c, data, 16, 0, &ke, &k3_c);
2196	if (ret)
2197	krb5_abortx(context, "hmac failed");
2198
2199	RC4_set_key (&rc4_key, k3_c.checksum.length, k3_c.checksum.data);
2200	RC4 (&rc4_key, len - 16, cdata + 16, cdata + 16);
2201	memset (k1_c_data, 0, sizeof(k1_c_data));
2202	memset (k2_c_data, 0, sizeof(k2_c_data));
2203	memset (k3_c_data, 0, sizeof(k3_c_data));
2204	return 0;
2205	}
2206
2207	static krb5_error_code
2208	ARCFOUR_subdecrypt(krb5_context context,
2209	struct key_data *key,
2210	void *data,
2211	size_t len,
2212	unsigned usage,
2213	void *ivec)
2214	{
2215	struct checksum_type *c = _find_checksum (CKSUMTYPE_RSA_MD5);
2216	Checksum k1_c, k2_c, k3_c, cksum;
2217	struct key_data ke;
2218	krb5_keyblock kb;
2219	unsigned char t[4];
2220	RC4_KEY rc4_key;
2221	unsigned char *cdata = data;
2222	unsigned char k1_c_data[16], k2_c_data[16], k3_c_data[16];
2223	unsigned char cksum_data[16];
2224	krb5_error_code ret;
2225
2226	t[0] = (usage >> 0) & 0xFF;
2227	t[1] = (usage >> 8) & 0xFF;
2228	t[2] = (usage >> 16) & 0xFF;
2229	t[3] = (usage >> 24) & 0xFF;
2230
2231	k1_c.checksum.length = sizeof(k1_c_data);
2232	k1_c.checksum.data = k1_c_data;
2233
2234	ret = hmac(NULL, c, t, sizeof(t), 0, key, &k1_c);
2235	if (ret)
2236	krb5_abortx(context, "hmac failed");
2237
2238	memcpy (k2_c_data, k1_c_data, sizeof(k1_c_data));
2239
2240	k2_c.checksum.length = sizeof(k2_c_data);
2241	k2_c.checksum.data = k2_c_data;
2242
2243	ke.key = &kb;
2244	kb.keyvalue = k1_c.checksum;
2245
2246	k3_c.checksum.length = sizeof(k3_c_data);
2247	k3_c.checksum.data = k3_c_data;
2248
2249	ret = hmac(NULL, c, cdata, 16, 0, &ke, &k3_c);
2250	if (ret)
2251	krb5_abortx(context, "hmac failed");
2252
2253	RC4_set_key (&rc4_key, k3_c.checksum.length, k3_c.checksum.data);
2254	RC4 (&rc4_key, len - 16, cdata + 16, cdata + 16);
2255
2256	ke.key = &kb;
2257	kb.keyvalue = k2_c.checksum;
2258
2259	cksum.checksum.length = 16;
2260	cksum.checksum.data = cksum_data;
2261
2262	ret = hmac(NULL, c, cdata + 16, len - 16, 0, &ke, &cksum);
2263	if (ret)
2264	krb5_abortx(context, "hmac failed");
2265
2266	memset (k1_c_data, 0, sizeof(k1_c_data));
2267	memset (k2_c_data, 0, sizeof(k2_c_data));
2268	memset (k3_c_data, 0, sizeof(k3_c_data));
2269
2270	if (memcmp (cksum.checksum.data, data, 16) != 0) {
2271	krb5_clear_error_message (context);
2272	return KRB5KRB_AP_ERR_BAD_INTEGRITY;
2273	} else {
2274	return 0;
2275	}
2276	}
2277
2278	/*
2279	* convert the usage numbers used in
2280	* draft-ietf-cat-kerb-key-derivation-00.txt to the ones in
2281	* draft-brezak-win2k-krb-rc4-hmac-04.txt
2282	*/
2283
2284	static krb5_error_code
2285	usage2arcfour (krb5_context context, unsigned *usage)
2286	{
2287	switch (*usage) {
2288	case KRB5_KU_AS_REP_ENC_PART : /* 3 */
2289	case KRB5_KU_TGS_REP_ENC_PART_SUB_KEY : /* 9 */
2290	*usage = 8;
2291	return 0;
2292	case KRB5_KU_USAGE_SEAL : /* 22 */
2293	*usage = 13;
2294	return 0;
2295	case KRB5_KU_USAGE_SIGN : /* 23 */
2296	*usage = 15;
2297	return 0;
2298	case KRB5_KU_USAGE_SEQ: /* 24 */
2299	*usage = 0;
2300	return 0;
2301	default :
2302	return 0;
2303	}
2304	}
2305
2306	static krb5_error_code
2307	ARCFOUR_encrypt(krb5_context context,
2308	struct key_data *key,
2309	void *data,
2310	size_t len,
2311	krb5_boolean encryptp,
2312	int usage,
2313	void *ivec)
2314	{
2315	krb5_error_code ret;
2316	unsigned keyusage = usage;
2317
2318	if((ret = usage2arcfour (context, &keyusage)) != 0)
2319	return ret;
2320
2321	if (encryptp)
2322	return ARCFOUR_subencrypt (context, key, data, len, keyusage, ivec);
2323	else
2324	return ARCFOUR_subdecrypt (context, key, data, len, keyusage, ivec);
2325	}
2326
2327
2328	/*
2329	*
2330	*/
2331
2332	static krb5_error_code
2333	AES_PRF(krb5_context context,
2334	krb5_crypto crypto,
2335	const krb5_data *in,
2336	krb5_data *out)
2337	{
2338	struct checksum_type *ct = crypto->et->checksum;
2339	krb5_error_code ret;
2340	Checksum result;
2341	krb5_keyblock *derived;
2342
2343	result.cksumtype = ct->type;
2344	ret = krb5_data_alloc(&result.checksum, ct->checksumsize);
2345	if (ret) {
2346	krb5_set_error_message(context, ret, N_("malloc: out memory", ""));
2347	return ret;
2348	}
2349
2350	ret = (*ct->checksum)(context, NULL, in->data, in->length, 0, &result);
2351	if (ret) {
2352	krb5_data_free(&result.checksum);
2353	return ret;
2354	}
2355
2356	if (result.checksum.length < crypto->et->blocksize)
2357	krb5_abortx(context, "internal prf error");
2358
2359	derived = NULL;
2360	ret = krb5_derive_key(context, crypto->key.key,
2361	crypto->et->type, "prf", 3, &derived);
2362	if (ret)
2363	krb5_abortx(context, "krb5_derive_key");
2364
2365	ret = krb5_data_alloc(out, crypto->et->blocksize);
2366	if (ret)
2367	krb5_abortx(context, "malloc failed");
2368
2369	{
2370	const EVP_CIPHER c = (crypto->et->keytype->evp)();
2371	EVP_CIPHER_CTX ctx;
2372
2373	EVP_CIPHER_CTX_init(&ctx); /* ivec all zero */
2374	EVP_CipherInit_ex(&ctx, c, NULL, derived->keyvalue.data, NULL, 1);
2375	EVP_Cipher(&ctx, out->data, result.checksum.data,
2376	crypto->et->blocksize);
2377	EVP_CIPHER_CTX_cleanup(&ctx);
2378	}
2379
2380	krb5_data_free(&result.checksum);
2381	krb5_free_keyblock(context, derived);
2382
2383	return ret;
2384	}
2385
2386	/*
2387	* these should currently be in reverse preference order.
2388	* (only relevant for !F_PSEUDO) */
2389
2390	static struct encryption_type enctype_null = {
2391	ETYPE_NULL,
2392	"null",
2393	1,
2394	1,
2395	0,
2396	&keytype_null,
2397	&checksum_none,
2398	NULL,
2399	F_DISABLED,
2400	NULL_encrypt,
2401	0,
2402	NULL
2403	};
2404	static struct encryption_type enctype_arcfour_hmac_md5 = {
2405	ETYPE_ARCFOUR_HMAC_MD5,
2406	"arcfour-hmac-md5",
2407	1,
2408	1,
2409	8,
2410	&keytype_arcfour,
2411	&checksum_hmac_md5,
2412	NULL,
2413	F_SPECIAL,
2414	ARCFOUR_encrypt,
2415	0,
2416	NULL
2417	};
2418	#ifdef DES3_OLD_ENCTYPE
2419	static struct encryption_type enctype_des3_cbc_md5 = {
2420	ETYPE_DES3_CBC_MD5,
2421	"des3-cbc-md5",
2422	8,
2423	8,
2424	8,
2425	&keytype_des3,
2426	&checksum_rsa_md5,
2427	&checksum_rsa_md5_des3,
2428	0,
2429	evp_encrypt,
2430	0,
2431	NULL
2432	};
2433	#endif
2434	static struct encryption_type enctype_des3_cbc_sha1 = {
2435	ETYPE_DES3_CBC_SHA1,
2436	"des3-cbc-sha1",
2437	8,
2438	8,
2439	8,
2440	&keytype_des3_derived,
2441	&checksum_sha1,
2442	&checksum_hmac_sha1_des3,
2443	F_DERIVED,
2444	evp_encrypt,
2445	0,
2446	NULL
2447	};
2448	#ifdef DES3_OLD_ENCTYPE
2449	static struct encryption_type enctype_old_des3_cbc_sha1 = {
2450	ETYPE_OLD_DES3_CBC_SHA1,
2451	"old-des3-cbc-sha1",
2452	8,
2453	8,
2454	8,
2455	&keytype_des3,
2456	&checksum_sha1,
2457	&checksum_hmac_sha1_des3,
2458	0,
2459	evp_encrypt,
2460	0,
2461	NULL
2462	};
2463	#endif
2464	static struct encryption_type enctype_aes128_cts_hmac_sha1 = {
2465	ETYPE_AES128_CTS_HMAC_SHA1_96,
2466	"aes128-cts-hmac-sha1-96",
2467	16,
2468	1,
2469	16,
2470	&keytype_aes128,
2471	&checksum_sha1,
2472	&checksum_hmac_sha1_aes128,
2473	F_DERIVED,
2474	evp_encrypt,
2475	16,
2476	AES_PRF
2477	};
2478	static struct encryption_type enctype_aes256_cts_hmac_sha1 = {
2479	ETYPE_AES256_CTS_HMAC_SHA1_96,
2480	"aes256-cts-hmac-sha1-96",
2481	16,
2482	1,
2483	16,
2484	&keytype_aes256,
2485	&checksum_sha1,
2486	&checksum_hmac_sha1_aes256,
2487	F_DERIVED,
2488	evp_encrypt,
2489	16,
2490	AES_PRF
2491	};
2492	static struct encryption_type enctype_des3_cbc_none = {
2493	ETYPE_DES3_CBC_NONE,
2494	"des3-cbc-none",
2495	8,
2496	8,
2497	0,
2498	&keytype_des3_derived,
2499	&checksum_none,
2500	NULL,
2501	F_PSEUDO,
2502	evp_encrypt,
2503	0,
2504	NULL
2505	};
2506	#ifdef WEAK_ENCTYPES
2507	static struct encryption_type enctype_des_cbc_crc = {
2508	ETYPE_DES_CBC_CRC,
2509	"des-cbc-crc",
2510	8,
2511	8,
2512	8,
2513	&keytype_des,
2514	&checksum_crc32,
2515	NULL,
2516	F_DISABLED,
2517	evp_des_encrypt_key_ivec,
2518	0,
2519	NULL
2520	};
2521	static struct encryption_type enctype_des_cbc_md4 = {
2522	ETYPE_DES_CBC_MD4,
2523	"des-cbc-md4",
2524	8,
2525	8,
2526	8,
2527	&keytype_des,
2528	&checksum_rsa_md4,
2529	&checksum_rsa_md4_des,
2530	F_DISABLED,
2531	evp_des_encrypt_null_ivec,
2532	0,
2533	NULL
2534	};
2535	static struct encryption_type enctype_des_cbc_md5 = {
2536	ETYPE_DES_CBC_MD5,
2537	"des-cbc-md5",
2538	8,
2539	8,
2540	8,
2541	&keytype_des,
2542	&checksum_rsa_md5,
2543	&checksum_rsa_md5_des,
2544	F_DISABLED,
2545	evp_des_encrypt_null_ivec,
2546	0,
2547	NULL
2548	};
2549	static struct encryption_type enctype_des_cbc_none = {
2550	ETYPE_DES_CBC_NONE,
2551	"des-cbc-none",
2552	8,
2553	8,
2554	0,
2555	&keytype_des,
2556	&checksum_none,
2557	NULL,
2558	F_PSEUDO\|F_DISABLED,
2559	evp_des_encrypt_null_ivec,
2560	0,
2561	NULL
2562	};
2563	static struct encryption_type enctype_des_cfb64_none = {
2564	ETYPE_DES_CFB64_NONE,
2565	"des-cfb64-none",
2566	1,
2567	1,
2568	0,
2569	&keytype_des_old,
2570	&checksum_none,
2571	NULL,
2572	F_PSEUDO\|F_DISABLED,
2573	DES_CFB64_encrypt_null_ivec,
2574	0,
2575	NULL
2576	};
2577	static struct encryption_type enctype_des_pcbc_none = {
2578	ETYPE_DES_PCBC_NONE,
2579	"des-pcbc-none",
2580	8,
2581	8,
2582	0,
2583	&keytype_des_old,
2584	&checksum_none,
2585	NULL,
2586	F_PSEUDO\|F_DISABLED,
2587	DES_PCBC_encrypt_key_ivec,
2588	0,
2589	NULL
2590	};
2591	#endif /* WEAK_ENCTYPES */
2592
2593	static struct encryption_type *etypes[] = {
2594	&enctype_aes256_cts_hmac_sha1,
2595	&enctype_aes128_cts_hmac_sha1,
2596	&enctype_des3_cbc_sha1,
2597	&enctype_des3_cbc_none, /* used by the gss-api mech */
2598	&enctype_arcfour_hmac_md5,
2599	#ifdef DES3_OLD_ENCTYPE
2600	&enctype_des3_cbc_md5,
2601	&enctype_old_des3_cbc_sha1,
2602	#endif
2603	#ifdef WEAK_ENCTYPES
2604	&enctype_des_cbc_crc,
2605	&enctype_des_cbc_md4,
2606	&enctype_des_cbc_md5,
2607	&enctype_des_cbc_none,
2608	&enctype_des_cfb64_none,
2609	&enctype_des_pcbc_none,
2610	#endif
2611	&enctype_null
2612	};
2613
2614	static unsigned num_etypes = sizeof(etypes) / sizeof(etypes[0]);
2615
2616
2617	static struct encryption_type *
2618	_find_enctype(krb5_enctype type)
2619	{
2620	int i;
2621	for(i = 0; i < num_etypes; i++)
2622	if(etypes[i]->type == type)
2623	return etypes[i];
2624	return NULL;
2625	}
2626
2627
2628	krb5_error_code KRB5_LIB_FUNCTION
2629	krb5_enctype_to_string(krb5_context context,
2630	krb5_enctype etype,
2631	char **string)
2632	{
2633	struct encryption_type *e;
2634	e = _find_enctype(etype);
2635	if(e == NULL) {
2636	krb5_set_error_message (context, KRB5_PROG_ETYPE_NOSUPP,
2637	N_("encryption type %d not supported", ""),
2638	etype);
2639	*string = NULL;
2640	return KRB5_PROG_ETYPE_NOSUPP;
2641	}
2642	*string = strdup(e->name);
2643	if(*string == NULL) {
2644	krb5_set_error_message(context, ENOMEM, N_("malloc: out of memory", ""));
2645	return ENOMEM;
2646	}
2647	return 0;
2648	}
2649
2650	krb5_error_code KRB5_LIB_FUNCTION
2651	krb5_string_to_enctype(krb5_context context,
2652	const char *string,
2653	krb5_enctype *etype)
2654	{
2655	int i;
2656	for(i = 0; i < num_etypes; i++)
2657	if(strcasecmp(etypes[i]->name, string) == 0){
2658	*etype = etypes[i]->type;
2659	return 0;
2660	}
2661	krb5_set_error_message (context, KRB5_PROG_ETYPE_NOSUPP,
2662	N_("encryption type %s not supported", ""),
2663	string);
2664	return KRB5_PROG_ETYPE_NOSUPP;
2665	}
2666
2667	krb5_error_code KRB5_LIB_FUNCTION
2668	krb5_enctype_to_keytype(krb5_context context,
2669	krb5_enctype etype,
2670	krb5_keytype *keytype)
2671	{
2672	struct encryption_type *e = _find_enctype(etype);
2673	if(e == NULL) {
2674	krb5_set_error_message (context, KRB5_PROG_ETYPE_NOSUPP,
2675	N_("encryption type %d not supported", ""),
2676	etype);
2677	return KRB5_PROG_ETYPE_NOSUPP;
2678	}
2679	keytype = e->keytype->type; / XXX */
2680	return 0;
2681	}
2682
2683	krb5_error_code KRB5_LIB_FUNCTION
2684	krb5_enctype_valid(krb5_context context,
2685	krb5_enctype etype)
2686	{
2687	struct encryption_type *e = _find_enctype(etype);
2688	if(e == NULL) {
2689	krb5_set_error_message (context, KRB5_PROG_ETYPE_NOSUPP,
2690	N_("encryption type %d not supported", ""),
2691	etype);
2692	return KRB5_PROG_ETYPE_NOSUPP;
2693	}
2694	if (e->flags & F_DISABLED) {
2695	krb5_set_error_message (context, KRB5_PROG_ETYPE_NOSUPP,
2696	N_("encryption type %s is disabled", ""),
2697	e->name);
2698	return KRB5_PROG_ETYPE_NOSUPP;
2699	}
2700	return 0;
2701	}
2702
2703	/**
2704	* Return the coresponding encryption type for a checksum type.
2705	*
2706	* @param context Kerberos context
2707	* @param ctype The checksum type to get the result enctype for
2708	* @param etype The returned encryption, when the matching etype is
2709	* not found, etype is set to ETYPE_NULL.
2710	*
2711	* @return Return an error code for an failure or 0 on success.
2712	* @ingroup krb5_crypto
2713	*/
2714
2715
2716	krb5_error_code KRB5_LIB_FUNCTION
2717	krb5_cksumtype_to_enctype(krb5_context context,
2718	krb5_cksumtype ctype,
2719	krb5_enctype *etype)
2720	{
2721	int i;
2722
2723	*etype = ETYPE_NULL;
2724
2725	for(i = 0; i < num_etypes; i++) {
2726	if(etypes[i]->keyed_checksum &&
2727	etypes[i]->keyed_checksum->type == ctype)
2728	{
2729	*etype = etypes[i]->type;
2730	return 0;
2731	}
2732	}
2733
2734	krb5_set_error_message (context, KRB5_PROG_SUMTYPE_NOSUPP,
2735	N_("checksum type %d not supported", ""),
2736	(int)ctype);
2737	return KRB5_PROG_SUMTYPE_NOSUPP;
2738	}
2739
2740
2741	krb5_error_code KRB5_LIB_FUNCTION
2742	krb5_cksumtype_valid(krb5_context context,
2743	krb5_cksumtype ctype)
2744	{
2745	struct checksum_type *c = _find_checksum(ctype);
2746	if (c == NULL) {
2747	krb5_set_error_message (context, KRB5_PROG_SUMTYPE_NOSUPP,
2748	N_("checksum type %d not supported", ""),
2749	ctype);
2750	return KRB5_PROG_SUMTYPE_NOSUPP;
2751	}
2752	if (c->flags & F_DISABLED) {
2753	krb5_set_error_message (context, KRB5_PROG_SUMTYPE_NOSUPP,
2754	N_("checksum type %s is disabled", ""),
2755	c->name);
2756	return KRB5_PROG_SUMTYPE_NOSUPP;
2757	}
2758	return 0;
2759	}
2760
2761
2762	static krb5_boolean
2763	derived_crypto(krb5_context context,
2764	krb5_crypto crypto)
2765	{
2766	return (crypto->et->flags & F_DERIVED) != 0;
2767	}
2768
2769	static krb5_boolean
2770	special_crypto(krb5_context context,
2771	krb5_crypto crypto)
2772	{
2773	return (crypto->et->flags & F_SPECIAL) != 0;
2774	}
2775
2776	#define CHECKSUMSIZE(C) ((C)->checksumsize)
2777	#define CHECKSUMTYPE(C) ((C)->type)
2778
2779	static krb5_error_code
2780	encrypt_internal_derived(krb5_context context,
2781	krb5_crypto crypto,
2782	unsigned usage,
2783	const void *data,
2784	size_t len,
2785	krb5_data *result,
2786	void *ivec)
2787	{
2788	size_t sz, block_sz, checksum_sz, total_sz;
2789	Checksum cksum;
2790	unsigned char p, q;
2791	krb5_error_code ret;
2792	struct key_data *dkey;
2793	const struct encryption_type *et = crypto->et;
2794
2795	checksum_sz = CHECKSUMSIZE(et->keyed_checksum);
2796
2797	sz = et->confoundersize + len;
2798	block_sz = (sz + et->padsize - 1) &~ (et->padsize - 1); /* pad */
2799	total_sz = block_sz + checksum_sz;
2800	p = calloc(1, total_sz);
2801	if(p == NULL) {
2802	krb5_set_error_message(context, ENOMEM, N_("malloc: out of memory", ""));
2803	return ENOMEM;
2804	}
2805
2806	q = p;
2807	krb5_generate_random_block(q, et->confoundersize); /* XXX */
2808	q += et->confoundersize;
2809	memcpy(q, data, len);
2810
2811	ret = create_checksum(context,
2812	et->keyed_checksum,
2813	crypto,
2814	INTEGRITY_USAGE(usage),
2815	p,
2816	block_sz,
2817	&cksum);
2818	if(ret == 0 && cksum.checksum.length != checksum_sz) {
2819	free_Checksum (&cksum);
2820	krb5_clear_error_message (context);
2821	ret = KRB5_CRYPTO_INTERNAL;
2822	}
2823	if(ret)
2824	goto fail;
2825	memcpy(p + block_sz, cksum.checksum.data, cksum.checksum.length);
2826	free_Checksum (&cksum);
2827	ret = _get_derived_key(context, crypto, ENCRYPTION_USAGE(usage), &dkey);
2828	if(ret)
2829	goto fail;
2830	ret = _key_schedule(context, dkey);
2831	if(ret)
2832	goto fail;
2833	ret = (*et->encrypt)(context, dkey, p, block_sz, 1, usage, ivec);
2834	if (ret)
2835	goto fail;
2836	result->data = p;
2837	result->length = total_sz;
2838	return 0;
2839	fail:
2840	memset(p, 0, total_sz);
2841	free(p);
2842	return ret;
2843	}
2844
2845
2846	static krb5_error_code
2847	encrypt_internal(krb5_context context,
2848	krb5_crypto crypto,
2849	const void *data,
2850	size_t len,
2851	krb5_data *result,
2852	void *ivec)
2853	{
2854	size_t sz, block_sz, checksum_sz;
2855	Checksum cksum;
2856	unsigned char p, q;
2857	krb5_error_code ret;
2858	const struct encryption_type *et = crypto->et;
2859
2860	checksum_sz = CHECKSUMSIZE(et->checksum);
2861
2862	sz = et->confoundersize + checksum_sz + len;
2863	block_sz = (sz + et->padsize - 1) &~ (et->padsize - 1); /* pad */
2864	p = calloc(1, block_sz);
2865	if(p == NULL) {
2866	krb5_set_error_message(context, ENOMEM, N_("malloc: out of memory", ""));
2867	return ENOMEM;
2868	}
2869
2870	q = p;
2871	krb5_generate_random_block(q, et->confoundersize); /* XXX */
2872	q += et->confoundersize;
2873	memset(q, 0, checksum_sz);
2874	q += checksum_sz;
2875	memcpy(q, data, len);
2876
2877	ret = create_checksum(context,
2878	et->checksum,
2879	crypto,
2880	0,
2881	p,
2882	block_sz,
2883	&cksum);
2884	if(ret == 0 && cksum.checksum.length != checksum_sz) {
2885	krb5_clear_error_message (context);
2886	free_Checksum(&cksum);
2887	ret = KRB5_CRYPTO_INTERNAL;
2888	}
2889	if(ret)
2890	goto fail;
2891	memcpy(p + et->confoundersize, cksum.checksum.data, cksum.checksum.length);
2892	free_Checksum(&cksum);
2893	ret = _key_schedule(context, &crypto->key);
2894	if(ret)
2895	goto fail;
2896	ret = (*et->encrypt)(context, &crypto->key, p, block_sz, 1, 0, ivec);
2897	if (ret) {
2898	memset(p, 0, block_sz);
2899	free(p);
2900	return ret;
2901	}
2902	result->data = p;
2903	result->length = block_sz;
2904	return 0;
2905	fail:
2906	memset(p, 0, block_sz);
2907	free(p);
2908	return ret;
2909	}
2910
2911	static krb5_error_code
2912	encrypt_internal_special(krb5_context context,
2913	krb5_crypto crypto,
2914	int usage,
2915	const void *data,
2916	size_t len,
2917	krb5_data *result,
2918	void *ivec)
2919	{
2920	struct encryption_type *et = crypto->et;
2921	size_t cksum_sz = CHECKSUMSIZE(et->checksum);
2922	size_t sz = len + cksum_sz + et->confoundersize;
2923	char tmp, p;
2924	krb5_error_code ret;
2925
2926	tmp = malloc (sz);
2927	if (tmp == NULL) {
2928	krb5_set_error_message(context, ENOMEM, N_("malloc: out of memory", ""));
2929	return ENOMEM;
2930	}
2931	p = tmp;
2932	memset (p, 0, cksum_sz);
2933	p += cksum_sz;
2934	krb5_generate_random_block(p, et->confoundersize);
2935	p += et->confoundersize;
2936	memcpy (p, data, len);
2937	ret = (*et->encrypt)(context, &crypto->key, tmp, sz, TRUE, usage, ivec);
2938	if (ret) {
2939	memset(tmp, 0, sz);
2940	free(tmp);
2941	return ret;
2942	}
2943	result->data = tmp;
2944	result->length = sz;
2945	return 0;
2946	}
2947
2948	static krb5_error_code
2949	decrypt_internal_derived(krb5_context context,
2950	krb5_crypto crypto,
2951	unsigned usage,
2952	void *data,
2953	size_t len,
2954	krb5_data *result,
2955	void *ivec)
2956	{
2957	size_t checksum_sz;
2958	Checksum cksum;
2959	unsigned char *p;
2960	krb5_error_code ret;
2961	struct key_data *dkey;
2962	struct encryption_type *et = crypto->et;
2963	unsigned long l;
2964
2965	checksum_sz = CHECKSUMSIZE(et->keyed_checksum);
2966	if (len < checksum_sz + et->confoundersize) {
2967	krb5_set_error_message(context, KRB5_BAD_MSIZE,
2968	N_("Encrypted data shorter then "
2969	"checksum + confunder", ""));
2970	return KRB5_BAD_MSIZE;
2971	}
2972
2973	if (((len - checksum_sz) % et->padsize) != 0) {
2974	krb5_clear_error_message(context);
2975	return KRB5_BAD_MSIZE;
2976	}
2977
2978	p = malloc(len);
2979	if(len != 0 && p == NULL) {
2980	krb5_set_error_message(context, ENOMEM, N_("malloc: out of memory", ""));
2981	return ENOMEM;
2982	}
2983	memcpy(p, data, len);
2984
2985	len -= checksum_sz;
2986
2987	ret = _get_derived_key(context, crypto, ENCRYPTION_USAGE(usage), &dkey);
2988	if(ret) {
2989	free(p);
2990	return ret;
2991	}
2992	ret = _key_schedule(context, dkey);
2993	if(ret) {
2994	free(p);
2995	return ret;
2996	}
2997	ret = (*et->encrypt)(context, dkey, p, len, 0, usage, ivec);
2998	if (ret) {
2999	free(p);
3000	return ret;
3001	}
3002
3003	cksum.checksum.data = p + len;
3004	cksum.checksum.length = checksum_sz;
3005	cksum.cksumtype = CHECKSUMTYPE(et->keyed_checksum);
3006
3007	ret = verify_checksum(context,
3008	crypto,
3009	INTEGRITY_USAGE(usage),
3010	p,
3011	len,
3012	&cksum);
3013	if(ret) {
3014	free(p);
3015	return ret;
3016	}
3017	l = len - et->confoundersize;
3018	memmove(p, p + et->confoundersize, l);
3019	result->data = realloc(p, l);
3020	if(result->data == NULL && l != 0) {
3021	free(p);
3022	krb5_set_error_message(context, ENOMEM, N_("malloc: out of memory", ""));
3023	return ENOMEM;
3024	}
3025	result->length = l;
3026	return 0;
3027	}
3028
3029	static krb5_error_code
3030	decrypt_internal(krb5_context context,
3031	krb5_crypto crypto,
3032	void *data,
3033	size_t len,
3034	krb5_data *result,
3035	void *ivec)
3036	{
3037	krb5_error_code ret;
3038	unsigned char *p;
3039	Checksum cksum;
3040	size_t checksum_sz, l;
3041	struct encryption_type *et = crypto->et;
3042
3043	if ((len % et->padsize) != 0) {
3044	krb5_clear_error_message(context);
3045	return KRB5_BAD_MSIZE;
3046	}
3047
3048	checksum_sz = CHECKSUMSIZE(et->checksum);
3049	p = malloc(len);
3050	if(len != 0 && p == NULL) {
3051	krb5_set_error_message(context, ENOMEM, N_("malloc: out of memory", ""));
3052	return ENOMEM;
3053	}
3054	memcpy(p, data, len);
3055
3056	ret = _key_schedule(context, &crypto->key);
3057	if(ret) {
3058	free(p);
3059	return ret;
3060	}
3061	ret = (*et->encrypt)(context, &crypto->key, p, len, 0, 0, ivec);
3062	if (ret) {
3063	free(p);
3064	return ret;
3065	}
3066	ret = krb5_data_copy(&cksum.checksum, p + et->confoundersize, checksum_sz);
3067	if(ret) {
3068	free(p);
3069	return ret;
3070	}
3071	memset(p + et->confoundersize, 0, checksum_sz);
3072	cksum.cksumtype = CHECKSUMTYPE(et->checksum);
3073	ret = verify_checksum(context, NULL, 0, p, len, &cksum);
3074	free_Checksum(&cksum);
3075	if(ret) {
3076	free(p);
3077	return ret;
3078	}
3079	l = len - et->confoundersize - checksum_sz;
3080	memmove(p, p + et->confoundersize + checksum_sz, l);
3081	result->data = realloc(p, l);
3082	if(result->data == NULL && l != 0) {
3083	free(p);
3084	krb5_set_error_message(context, ENOMEM, N_("malloc: out of memory", ""));
3085	return ENOMEM;
3086	}
3087	result->length = l;
3088	return 0;
3089	}
3090
3091	static krb5_error_code
3092	decrypt_internal_special(krb5_context context,
3093	krb5_crypto crypto,
3094	int usage,
3095	void *data,
3096	size_t len,
3097	krb5_data *result,
3098	void *ivec)
3099	{
3100	struct encryption_type *et = crypto->et;
3101	size_t cksum_sz = CHECKSUMSIZE(et->checksum);
3102	size_t sz = len - cksum_sz - et->confoundersize;
3103	unsigned char *p;
3104	krb5_error_code ret;
3105
3106	if ((len % et->padsize) != 0) {
3107	krb5_clear_error_message(context);
3108	return KRB5_BAD_MSIZE;
3109	}
3110
3111	p = malloc (len);
3112	if (p == NULL) {
3113	krb5_set_error_message(context, ENOMEM, N_("malloc: out of memory", ""));
3114	return ENOMEM;
3115	}
3116	memcpy(p, data, len);
3117
3118	ret = (*et->encrypt)(context, &crypto->key, p, len, FALSE, usage, ivec);
3119	if (ret) {
3120	free(p);
3121	return ret;
3122	}
3123
3124	memmove (p, p + cksum_sz + et->confoundersize, sz);
3125	result->data = realloc(p, sz);
3126	if(result->data == NULL && sz != 0) {
3127	free(p);
3128	krb5_set_error_message(context, ENOMEM, N_("malloc: out of memory", ""));
3129	return ENOMEM;
3130	}
3131	result->length = sz;
3132	return 0;
3133	}
3134
3135	static krb5_crypto_iov *
3136	find_iv(krb5_crypto_iov *data, int num_data, int type)
3137	{
3138	int i;
3139	for (i = 0; i < num_data; i++)
3140	if (data[i].flags == type)
3141	return &data[i];
3142	return NULL;
3143	}
3144
3145	/**
3146	* Inline encrypt a kerberos message
3147	*
3148	* @param context Kerberos context
3149	* @param crypto Kerberos crypto context
3150	* @param usage Key usage for this buffer
3151	* @param data array of buffers to process
3152	* @param num_data length of array
3153	* @param ivec initial cbc/cts vector
3154	*
3155	* @return Return an error code or 0.
3156	* @ingroup krb5_crypto
3157	*
3158	* Kerberos encrypted data look like this:
3159	*
3160	* 1. KRB5_CRYPTO_TYPE_HEADER
3161	* 2. array [1,...] KRB5_CRYPTO_TYPE_DATA and array [0,...]
3162	* KRB5_CRYPTO_TYPE_SIGN_ONLY in any order, however the receiver
3163	* have to aware of the order. KRB5_CRYPTO_TYPE_SIGN_ONLY is
3164	* commonly used headers and trailers.
3165	* 3. KRB5_CRYPTO_TYPE_PADDING, at least on padsize long if padsize > 1
3166	* 4. KRB5_CRYPTO_TYPE_TRAILER
3167	*/
3168
3169	krb5_error_code KRB5_LIB_FUNCTION
3170	krb5_encrypt_iov_ivec(krb5_context context,
3171	krb5_crypto crypto,
3172	unsigned usage,
3173	krb5_crypto_iov *data,
3174	int num_data,
3175	void *ivec)
3176	{
3177	size_t headersz, trailersz, len;
3178	int i;
3179	size_t sz, block_sz, pad_sz;
3180	Checksum cksum;
3181	unsigned char p, q;
3182	krb5_error_code ret;
3183	struct key_data *dkey;
3184	const struct encryption_type *et = crypto->et;
3185	krb5_crypto_iov tiv, piv, *hiv;
3186
3187	if (num_data < 0) {
3188	krb5_clear_error_message(context);
3189	return KRB5_CRYPTO_INTERNAL;
3190	}
3191
3192	if(!derived_crypto(context, crypto)) {
3193	krb5_clear_error_message(context);
3194	return KRB5_CRYPTO_INTERNAL;
3195	}
3196
3197	headersz = et->confoundersize;
3198	trailersz = CHECKSUMSIZE(et->keyed_checksum);
3199
3200	for (len = 0, i = 0; i < num_data; i++) {
3201	if (data[i].flags != KRB5_CRYPTO_TYPE_DATA)
3202	continue;
3203	len += data[i].data.length;
3204	}
3205
3206	sz = headersz + len;
3207	block_sz = (sz + et->padsize - 1) &~ (et->padsize - 1); /* pad */
3208
3209	pad_sz = block_sz - sz;
3210
3211	/* header */
3212
3213	hiv = find_iv(data, num_data, KRB5_CRYPTO_TYPE_HEADER);
3214	if (hiv == NULL \|\| hiv->data.length != headersz)
3215	return KRB5_BAD_MSIZE;
3216
3217	krb5_generate_random_block(hiv->data.data, hiv->data.length);
3218
3219	/* padding */
3220	piv = find_iv(data, num_data, KRB5_CRYPTO_TYPE_PADDING);
3221	/* its ok to have no TYPE_PADDING if there is no padding */
3222	if (piv == NULL && pad_sz != 0)
3223	return KRB5_BAD_MSIZE;
3224	if (piv) {
3225	if (piv->data.length < pad_sz)
3226	return KRB5_BAD_MSIZE;
3227	piv->data.length = pad_sz;
3228	if (pad_sz)
3229	memset(piv->data.data, pad_sz, pad_sz);
3230	else
3231	piv = NULL;
3232	}
3233
3234	/* trailer */
3235	tiv = find_iv(data, num_data, KRB5_CRYPTO_TYPE_TRAILER);
3236	if (tiv == NULL \|\| tiv->data.length != trailersz)
3237	return KRB5_BAD_MSIZE;
3238
3239	/*
3240	* XXX replace with EVP_Sign? at least make create_checksum an iov
3241	* function.
3242	* XXX CTS EVP is broken, can't handle multi buffers :(
3243	*/
3244
3245	len = block_sz;
3246	for (i = 0; i < num_data; i++) {
3247	if (data[i].flags != KRB5_CRYPTO_TYPE_SIGN_ONLY)
3248	continue;
3249	len += data[i].data.length;
3250	}
3251
3252	p = q = malloc(len);
3253
3254	memcpy(q, hiv->data.data, hiv->data.length);
3255	q += hiv->data.length;
3256	for (i = 0; i < num_data; i++) {
3257	if (data[i].flags != KRB5_CRYPTO_TYPE_DATA &&
3258	data[i].flags != KRB5_CRYPTO_TYPE_SIGN_ONLY)
3259	continue;
3260	memcpy(q, data[i].data.data, data[i].data.length);
3261	q += data[i].data.length;
3262	}
3263	if (piv)
3264	memset(q, 0, piv->data.length);
3265
3266	ret = create_checksum(context,
3267	et->keyed_checksum,
3268	crypto,
3269	INTEGRITY_USAGE(usage),
3270	p,
3271	len,
3272	&cksum);
3273	free(p);
3274	if(ret == 0 && cksum.checksum.length != trailersz) {
3275	free_Checksum (&cksum);
3276	krb5_clear_error_message (context);
3277	ret = KRB5_CRYPTO_INTERNAL;
3278	}
3279	if(ret)
3280	return ret;
3281
3282	/* save cksum at end */
3283	memcpy(tiv->data.data, cksum.checksum.data, cksum.checksum.length);
3284	free_Checksum (&cksum);
3285
3286	/* XXX replace with EVP_Cipher */
3287	p = q = malloc(block_sz);
3288	if(p == NULL)
3289	return ENOMEM;
3290
3291	memcpy(q, hiv->data.data, hiv->data.length);
3292	q += hiv->data.length;
3293
3294	for (i = 0; i < num_data; i++) {
3295	if (data[i].flags != KRB5_CRYPTO_TYPE_DATA)
3296	continue;
3297	memcpy(q, data[i].data.data, data[i].data.length);
3298	q += data[i].data.length;
3299	}
3300	if (piv)
3301	memset(q, 0, piv->data.length);
3302
3303
3304	ret = _get_derived_key(context, crypto, ENCRYPTION_USAGE(usage), &dkey);
3305	if(ret) {
3306	free(p);
3307	return ret;
3308	}
3309	ret = _key_schedule(context, dkey);
3310	if(ret) {
3311	free(p);
3312	return ret;
3313	}
3314
3315	ret = (*et->encrypt)(context, dkey, p, block_sz, 1, usage, ivec);
3316	if (ret) {
3317	free(p);
3318	return ret;
3319	}
3320
3321	/* now copy data back to buffers */
3322	q = p;
3323
3324	memcpy(hiv->data.data, q, hiv->data.length);
3325	q += hiv->data.length;
3326
3327	for (i = 0; i < num_data; i++) {
3328	if (data[i].flags != KRB5_CRYPTO_TYPE_DATA)
3329	continue;
3330	memcpy(data[i].data.data, q, data[i].data.length);
3331	q += data[i].data.length;
3332	}
3333	if (piv)
3334	memcpy(piv->data.data, q, pad_sz);
3335
3336	free(p);
3337
3338	return ret;
3339	}
3340
3341	/**
3342	* Inline decrypt a Kerberos message.
3343	*
3344	* @param context Kerberos context
3345	* @param crypto Kerberos crypto context
3346	* @param usage Key usage for this buffer
3347	* @param data array of buffers to process
3348	* @param num_data length of array
3349	* @param ivec initial cbc/cts vector
3350	*
3351	* @return Return an error code or 0.
3352	* @ingroup krb5_crypto
3353	*
3354	* 1. KRB5_CRYPTO_TYPE_HEADER
3355	* 2. one KRB5_CRYPTO_TYPE_DATA and array [0,...] of KRB5_CRYPTO_TYPE_SIGN_ONLY in
3356	* any order, however the receiver have to aware of the
3357	* order. KRB5_CRYPTO_TYPE_SIGN_ONLY is commonly used unencrypoted
3358	* protocol headers and trailers. The output data will be of same
3359	* size as the input data or shorter.
3360	*/
3361
3362	krb5_error_code KRB5_LIB_FUNCTION
3363	krb5_decrypt_iov_ivec(krb5_context context,
3364	krb5_crypto crypto,
3365	unsigned usage,
3366	krb5_crypto_iov *data,
3367	unsigned int num_data,
3368	void *ivec)
3369	{
3370	unsigned int i;
3371	size_t headersz, trailersz, len;
3372	Checksum cksum;
3373	unsigned char p, q;
3374	krb5_error_code ret;
3375	struct key_data *dkey;
3376	struct encryption_type *et = crypto->et;
3377	krb5_crypto_iov tiv, hiv;
3378
3379	if (num_data < 0) {
3380	krb5_clear_error_message(context);
3381	return KRB5_CRYPTO_INTERNAL;
3382	}
3383
3384	if(!derived_crypto(context, crypto)) {
3385	krb5_clear_error_message(context);
3386	return KRB5_CRYPTO_INTERNAL;
3387	}
3388
3389	headersz = et->confoundersize;
3390
3391	hiv = find_iv(data, num_data, KRB5_CRYPTO_TYPE_HEADER);
3392	if (hiv == NULL \|\| hiv->data.length != headersz)
3393	return KRB5_BAD_MSIZE;
3394
3395	/* trailer */
3396	trailersz = CHECKSUMSIZE(et->keyed_checksum);
3397
3398	tiv = find_iv(data, num_data, KRB5_CRYPTO_TYPE_TRAILER);
3399	if (tiv->data.length != trailersz)
3400	return KRB5_BAD_MSIZE;
3401
3402	/* Find length of data we will decrypt */
3403
3404	len = headersz;
3405	for (i = 0; i < num_data; i++) {
3406	if (data[i].flags != KRB5_CRYPTO_TYPE_DATA)
3407	continue;
3408	len += data[i].data.length;
3409	}
3410
3411	if ((len % et->padsize) != 0) {
3412	krb5_clear_error_message(context);
3413	return KRB5_BAD_MSIZE;
3414	}
3415
3416	/* XXX replace with EVP_Cipher */
3417
3418	p = q = malloc(len);
3419	if (p == NULL)
3420	return ENOMEM;
3421
3422	memcpy(q, hiv->data.data, hiv->data.length);
3423	q += hiv->data.length;
3424
3425	for (i = 0; i < num_data; i++) {
3426	if (data[i].flags != KRB5_CRYPTO_TYPE_DATA)
3427	continue;
3428	memcpy(q, data[i].data.data, data[i].data.length);
3429	q += data[i].data.length;
3430	}
3431
3432	ret = _get_derived_key(context, crypto, ENCRYPTION_USAGE(usage), &dkey);
3433	if(ret) {
3434	free(p);
3435	return ret;
3436	}
3437	ret = _key_schedule(context, dkey);
3438	if(ret) {
3439	free(p);
3440	return ret;
3441	}
3442
3443	ret = (*et->encrypt)(context, dkey, p, len, 0, usage, ivec);
3444	if (ret) {
3445	free(p);
3446	return ret;
3447	}
3448
3449	/* copy data back to buffers */
3450	memcpy(hiv->data.data, p, hiv->data.length);
3451	q = p + hiv->data.length;
3452	for (i = 0; i < num_data; i++) {
3453	if (data[i].flags != KRB5_CRYPTO_TYPE_DATA)
3454	continue;
3455	memcpy(data[i].data.data, q, data[i].data.length);
3456	q += data[i].data.length;
3457	}
3458
3459	free(p);
3460
3461	/* check signature */
3462	for (i = 0; i < num_data; i++) {
3463	if (data[i].flags != KRB5_CRYPTO_TYPE_SIGN_ONLY)
3464	continue;
3465	len += data[i].data.length;
3466	}
3467
3468	p = q = malloc(len);
3469	if (p == NULL)
3470	return ENOMEM;
3471
3472	memcpy(q, hiv->data.data, hiv->data.length);
3473	q += hiv->data.length;
3474	for (i = 0; i < num_data; i++) {
3475	if (data[i].flags != KRB5_CRYPTO_TYPE_DATA &&
3476	data[i].flags != KRB5_CRYPTO_TYPE_SIGN_ONLY)
3477	continue;
3478	memcpy(q, data[i].data.data, data[i].data.length);
3479	q += data[i].data.length;
3480	}
3481
3482	cksum.checksum.data = tiv->data.data;
3483	cksum.checksum.length = tiv->data.length;
3484	cksum.cksumtype = CHECKSUMTYPE(et->keyed_checksum);
3485
3486	ret = verify_checksum(context,
3487	crypto,
3488	INTEGRITY_USAGE(usage),
3489	p,
3490	len,
3491	&cksum);
3492	free(p);
3493	return ret;
3494	}
3495
3496	/**
3497	* Create a Kerberos message checksum.
3498	*
3499	* @param context Kerberos context
3500	* @param crypto Kerberos crypto context
3501	* @param usage Key usage for this buffer
3502	* @param data array of buffers to process
3503	* @param num_data length of array
3504	* @param type output data
3505	*
3506	* @return Return an error code or 0.
3507	* @ingroup krb5_crypto
3508	*/
3509
3510	krb5_error_code KRB5_LIB_FUNCTION
3511	krb5_create_checksum_iov(krb5_context context,
3512	krb5_crypto crypto,
3513	unsigned usage,
3514	krb5_crypto_iov *data,
3515	unsigned int num_data,
3516	krb5_cksumtype *type)
3517	{
3518	Checksum cksum;
3519	krb5_crypto_iov *civ;
3520	krb5_error_code ret;
3521	int i;
3522	size_t len;
3523	char p, q;
3524
3525	if (num_data < 0) {
3526	krb5_clear_error_message(context);
3527	return KRB5_CRYPTO_INTERNAL;
3528	}
3529
3530	if(!derived_crypto(context, crypto)) {
3531	krb5_clear_error_message(context);
3532	return KRB5_CRYPTO_INTERNAL;
3533	}
3534
3535	civ = find_iv(data, num_data, KRB5_CRYPTO_TYPE_CHECKSUM);
3536	if (civ == NULL)
3537	return KRB5_BAD_MSIZE;
3538
3539	len = 0;
3540	for (i = 0; i < num_data; i++) {
3541	if (data[i].flags != KRB5_CRYPTO_TYPE_DATA &&
3542	data[i].flags != KRB5_CRYPTO_TYPE_SIGN_ONLY)
3543	continue;
3544	len += data[i].data.length;
3545	}
3546
3547	p = q = malloc(len);
3548
3549	for (i = 0; i < num_data; i++) {
3550	if (data[i].flags != KRB5_CRYPTO_TYPE_DATA &&
3551	data[i].flags != KRB5_CRYPTO_TYPE_SIGN_ONLY)
3552	continue;
3553	memcpy(q, data[i].data.data, data[i].data.length);
3554	q += data[i].data.length;
3555	}
3556
3557	ret = krb5_create_checksum(context, crypto, usage, 0, p, len, &cksum);
3558	free(p);
3559	if (ret)
3560	return ret;
3561
3562	if (type)
3563	*type = cksum.cksumtype;
3564
3565	if (cksum.checksum.length > civ->data.length) {
3566	krb5_set_error_message(context, KRB5_BAD_MSIZE,
3567	N_("Checksum larger then input buffer", ""));
3568	free_Checksum(&cksum);
3569	return KRB5_BAD_MSIZE;
3570	}
3571
3572	civ->data.length = cksum.checksum.length;
3573	memcpy(civ->data.data, cksum.checksum.data, civ->data.length);
3574	free_Checksum(&cksum);
3575
3576	return 0;
3577	}
3578
3579	/**
3580	* Verify a Kerberos message checksum.
3581	*
3582	* @param context Kerberos context
3583	* @param crypto Kerberos crypto context
3584	* @param usage Key usage for this buffer
3585	* @param data array of buffers to process
3586	* @param num_data length of array
3587	*
3588	* @return Return an error code or 0.
3589	* @ingroup krb5_crypto
3590	*/
3591
3592	krb5_error_code KRB5_LIB_FUNCTION
3593	krb5_verify_checksum_iov(krb5_context context,
3594	krb5_crypto crypto,
3595	unsigned usage,
3596	krb5_crypto_iov *data,
3597	unsigned int num_data,
3598	krb5_cksumtype *type)
3599	{
3600	struct encryption_type *et = crypto->et;
3601	Checksum cksum;
3602	krb5_crypto_iov *civ;
3603	krb5_error_code ret;
3604	int i;
3605	size_t len;
3606	char p, q;
3607
3608	if (num_data < 0) {
3609	krb5_clear_error_message(context);
3610	return KRB5_CRYPTO_INTERNAL;
3611	}
3612
3613	if(!derived_crypto(context, crypto)) {
3614	krb5_clear_error_message(context);
3615	return KRB5_CRYPTO_INTERNAL;
3616	}
3617
3618	civ = find_iv(data, num_data, KRB5_CRYPTO_TYPE_CHECKSUM);
3619	if (civ == NULL)
3620	return KRB5_BAD_MSIZE;
3621
3622	len = 0;
3623	for (i = 0; i < num_data; i++) {
3624	if (data[i].flags != KRB5_CRYPTO_TYPE_DATA &&
3625	data[i].flags != KRB5_CRYPTO_TYPE_SIGN_ONLY)
3626	continue;
3627	len += data[i].data.length;
3628	}
3629
3630	p = q = malloc(len);
3631
3632	for (i = 0; i < num_data; i++) {
3633	if (data[i].flags != KRB5_CRYPTO_TYPE_DATA &&
3634	data[i].flags != KRB5_CRYPTO_TYPE_SIGN_ONLY)
3635	continue;
3636	memcpy(q, data[i].data.data, data[i].data.length);
3637	q += data[i].data.length;
3638	}
3639
3640	cksum.cksumtype = CHECKSUMTYPE(et->keyed_checksum);
3641	cksum.checksum.length = civ->data.length;
3642	cksum.checksum.data = civ->data.data;
3643
3644	ret = krb5_verify_checksum(context, crypto, usage, p, len, &cksum);
3645	free(p);
3646
3647	if (ret == 0 && type)
3648	*type = cksum.cksumtype;
3649
3650	return ret;
3651	}
3652
3653
3654	krb5_error_code KRB5_LIB_FUNCTION
3655	krb5_crypto_length(krb5_context context,
3656	krb5_crypto crypto,
3657	int type,
3658	size_t *len)
3659	{
3660	if (!derived_crypto(context, crypto)) {
3661	krb5_set_error_message(context, EINVAL, "not a derived crypto");
3662	return EINVAL;
3663	}
3664
3665	switch(type) {
3666	case KRB5_CRYPTO_TYPE_EMPTY:
3667	*len = 0;
3668	return 0;
3669	case KRB5_CRYPTO_TYPE_HEADER:
3670	*len = crypto->et->blocksize;
3671	return 0;
3672	case KRB5_CRYPTO_TYPE_DATA:
3673	case KRB5_CRYPTO_TYPE_SIGN_ONLY:
3674	/* len must already been filled in */
3675	return 0;
3676	case KRB5_CRYPTO_TYPE_PADDING:
3677	if (crypto->et->padsize > 1)
3678	*len = crypto->et->padsize;
3679	else
3680	*len = 0;
3681	return 0;
3682	case KRB5_CRYPTO_TYPE_TRAILER:
3683	*len = CHECKSUMSIZE(crypto->et->keyed_checksum);
3684	return 0;
3685	case KRB5_CRYPTO_TYPE_CHECKSUM:
3686	if (crypto->et->keyed_checksum)
3687	*len = CHECKSUMSIZE(crypto->et->keyed_checksum);
3688	else
3689	*len = CHECKSUMSIZE(crypto->et->checksum);
3690	return 0;
3691	}
3692	krb5_set_error_message(context, EINVAL,
3693	"%d not a supported type", type);
3694	return EINVAL;
3695	}
3696
3697
3698	krb5_error_code KRB5_LIB_FUNCTION
3699	krb5_crypto_length_iov(krb5_context context,
3700	krb5_crypto crypto,
3701	krb5_crypto_iov *data,
3702	unsigned int num_data)
3703	{
3704	krb5_error_code ret;
3705	int i;
3706
3707	for (i = 0; i < num_data; i++) {
3708	ret = krb5_crypto_length(context, crypto,
3709	data[i].flags,
3710	&data[i].data.length);
3711	if (ret)
3712	return ret;
3713	}
3714	return 0;
3715	}
3716
3717
3718	krb5_error_code KRB5_LIB_FUNCTION
3719	krb5_encrypt_ivec(krb5_context context,
3720	krb5_crypto crypto,
3721	unsigned usage,
3722	const void *data,
3723	size_t len,
3724	krb5_data *result,
3725	void *ivec)
3726	{
3727	if(derived_crypto(context, crypto))
3728	return encrypt_internal_derived(context, crypto, usage,
3729	data, len, result, ivec);
3730	else if (special_crypto(context, crypto))
3731	return encrypt_internal_special (context, crypto, usage,
3732	data, len, result, ivec);
3733	else
3734	return encrypt_internal(context, crypto, data, len, result, ivec);
3735	}
3736
3737	krb5_error_code KRB5_LIB_FUNCTION
3738	krb5_encrypt(krb5_context context,
3739	krb5_crypto crypto,
3740	unsigned usage,
3741	const void *data,
3742	size_t len,
3743	krb5_data *result)
3744	{
3745	return krb5_encrypt_ivec(context, crypto, usage, data, len, result, NULL);
3746	}
3747
3748	krb5_error_code KRB5_LIB_FUNCTION
3749	krb5_encrypt_EncryptedData(krb5_context context,
3750	krb5_crypto crypto,
3751	unsigned usage,
3752	void *data,
3753	size_t len,
3754	int kvno,
3755	EncryptedData *result)
3756	{
3757	result->etype = CRYPTO_ETYPE(crypto);
3758	if(kvno){
3759	ALLOC(result->kvno, 1);
3760	*result->kvno = kvno;
3761	}else
3762	result->kvno = NULL;
3763	return krb5_encrypt(context, crypto, usage, data, len, &result->cipher);
3764	}
3765
3766	krb5_error_code KRB5_LIB_FUNCTION
3767	krb5_decrypt_ivec(krb5_context context,
3768	krb5_crypto crypto,
3769	unsigned usage,
3770	void *data,
3771	size_t len,
3772	krb5_data *result,
3773	void *ivec)
3774	{
3775	if(derived_crypto(context, crypto))
3776	return decrypt_internal_derived(context, crypto, usage,
3777	data, len, result, ivec);
3778	else if (special_crypto (context, crypto))
3779	return decrypt_internal_special(context, crypto, usage,
3780	data, len, result, ivec);
3781	else
3782	return decrypt_internal(context, crypto, data, len, result, ivec);
3783	}
3784
3785	krb5_error_code KRB5_LIB_FUNCTION
3786	krb5_decrypt(krb5_context context,
3787	krb5_crypto crypto,
3788	unsigned usage,
3789	void *data,
3790	size_t len,
3791	krb5_data *result)
3792	{
3793	return krb5_decrypt_ivec (context, crypto, usage, data, len, result,
3794	NULL);
3795	}
3796
3797	krb5_error_code KRB5_LIB_FUNCTION
3798	krb5_decrypt_EncryptedData(krb5_context context,
3799	krb5_crypto crypto,
3800	unsigned usage,
3801	const EncryptedData *e,
3802	krb5_data *result)
3803	{
3804	return krb5_decrypt(context, crypto, usage,
3805	e->cipher.data, e->cipher.length, result);
3806	}
3807
3808	/************************************************************
3809	* *
3810	************************************************************/
3811
3812	#define ENTROPY_NEEDED 128
3813
3814	static int
3815	seed_something(void)
3816	{
3817	char buf[1024], seedfile[256];
3818
3819	/* If there is a seed file, load it. But such a file cannot be trusted,
3820	so use 0 for the entropy estimate */
3821	if (RAND_file_name(seedfile, sizeof(seedfile))) {
3822	int fd;
3823	fd = open(seedfile, O_RDONLY \| O_BINARY \| O_CLOEXEC);
3824	if (fd >= 0) {
3825	ssize_t ret;
3826	rk_cloexec(fd);
3827	ret = read(fd, buf, sizeof(buf));
3828	if (ret > 0)
3829	RAND_add(buf, ret, 0.0);
3830	close(fd);
3831	} else
3832	seedfile[0] = '\0';
3833	} else
3834	seedfile[0] = '\0';
3835
3836	/* Calling RAND_status() will try to use /dev/urandom if it exists so
3837	we do not have to deal with it. */
3838	if (RAND_status() != 1) {
3839	krb5_context context;
3840	const char *p;
3841
3842	/* Try using egd */
3843	if (!krb5_init_context(&context)) {
3844	p = krb5_config_get_string(context, NULL, "libdefaults",
3845	"egd_socket", NULL);
3846	if (p != NULL)
3847	RAND_egd_bytes(p, ENTROPY_NEEDED);
3848	krb5_free_context(context);
3849	}
3850	}
3851
3852	if (RAND_status() == 1) {
3853	/* Update the seed file */
3854	if (seedfile[0])
3855	RAND_write_file(seedfile);
3856
3857	return 0;
3858	} else
3859	return -1;
3860	}
3861
3862	void KRB5_LIB_FUNCTION
3863	krb5_generate_random_block(void *buf, size_t len)
3864	{
3865	static int rng_initialized = 0;
3866
3867	HEIMDAL_MUTEX_lock(&crypto_mutex);
3868	if (!rng_initialized) {
3869	if (seed_something())
3870	krb5_abortx(NULL, "Fatal: could not seed the "
3871	"random number generator");
3872
3873	rng_initialized = 1;
3874	}
3875	HEIMDAL_MUTEX_unlock(&crypto_mutex);
3876	if (RAND_bytes(buf, len) != 1)
3877	krb5_abortx(NULL, "Failed to generate random block");
3878	}
3879
3880	static krb5_error_code
3881	derive_key(krb5_context context,
3882	struct encryption_type *et,
3883	struct key_data *key,
3884	const void *constant,
3885	size_t len)
3886	{
3887	unsigned char *k = NULL;
3888	unsigned int nblocks = 0, i;
3889	krb5_error_code ret = 0;
3890	struct key_type *kt = et->keytype;
3891
3892	ret = _key_schedule(context, key);
3893	if(ret)
3894	return ret;
3895	if(et->blocksize * 8 < kt->bits \|\| len != et->blocksize) {
3896	nblocks = (kt->bits + et->blocksize * 8 - 1) / (et->blocksize * 8);
3897	k = malloc(nblocks * et->blocksize);
3898	if(k == NULL) {
3899	ret = ENOMEM;
3900	krb5_set_error_message(context, ret, N_("malloc: out of memory", ""));
3901	goto out;
3902	}
3903	ret = _krb5_n_fold(constant, len, k, et->blocksize);
3904	if (ret) {
3905	krb5_set_error_message(context, ret, N_("malloc: out of memory", ""));
3906	goto out;
3907	}
3908
3909	for(i = 0; i < nblocks; i++) {
3910	if(i > 0)
3911	memcpy(k + i * et->blocksize,
3912	k + (i - 1) * et->blocksize,
3913	et->blocksize);
3914	(et->encrypt)(context, key, k + i et->blocksize, et->blocksize,
3915	1, 0, NULL);
3916	}
3917	} else {
3918	/* this case is probably broken, but won't be run anyway */
3919	void *c = malloc(len);
3920	size_t res_len = (kt->bits + 7) / 8;
3921
3922	if(len != 0 && c == NULL) {
3923	ret = ENOMEM;
3924	krb5_set_error_message(context, ret, N_("malloc: out of memory", ""));
3925	goto out;
3926	}
3927	memcpy(c, constant, len);
3928	(*et->encrypt)(context, key, c, len, 1, 0, NULL);
3929	k = malloc(res_len);
3930	if(res_len != 0 && k == NULL) {
3931	free(c);
3932	ret = ENOMEM;
3933	krb5_set_error_message(context, ret, N_("malloc: out of memory", ""));
3934	goto out;
3935	}
3936	ret = _krb5_n_fold(c, len, k, res_len);
3937	free(c);
3938	if (ret) {
3939	krb5_set_error_message(context, ret, N_("malloc: out of memory", ""));
3940	goto out;
3941	}
3942	}
3943
3944	/* XXX keytype dependent post-processing */
3945	switch(kt->type) {
3946	case KEYTYPE_DES3:
3947	DES3_random_to_key(context, key->key, k, nblocks * et->blocksize);
3948	break;
3949	case KEYTYPE_AES128:
3950	case KEYTYPE_AES256:
3951	memcpy(key->key->keyvalue.data, k, key->key->keyvalue.length);
3952	break;
3953	default:
3954	ret = KRB5_CRYPTO_INTERNAL;
3955	krb5_set_error_message(context, ret,
3956	N_("derive_key() called with unknown keytype (%u)", ""),
3957	kt->type);
3958	break;
3959	}
3960	out:
3961	if (key->schedule) {
3962	free_key_schedule(context, key, et);
3963	key->schedule = NULL;
3964	}
3965	if (k) {
3966	memset(k, 0, nblocks * et->blocksize);
3967	free(k);
3968	}
3969	return ret;
3970	}
3971
3972	static struct key_data *
3973	_new_derived_key(krb5_crypto crypto, unsigned usage)
3974	{
3975	struct key_usage *d = crypto->key_usage;
3976	d = realloc(d, (crypto->num_key_usage + 1) * sizeof(*d));
3977	if(d == NULL)
3978	return NULL;
3979	crypto->key_usage = d;
3980	d += crypto->num_key_usage++;
3981	memset(d, 0, sizeof(*d));
3982	d->usage = usage;
3983	return &d->key;
3984	}
3985
3986	krb5_error_code KRB5_LIB_FUNCTION
3987	krb5_derive_key(krb5_context context,
3988	const krb5_keyblock *key,
3989	krb5_enctype etype,
3990	const void *constant,
3991	size_t constant_len,
3992	krb5_keyblock **derived_key)
3993	{
3994	krb5_error_code ret;
3995	struct encryption_type *et;
3996	struct key_data d;
3997
3998	*derived_key = NULL;
3999
4000	et = _find_enctype (etype);
4001	if (et == NULL) {
4002	krb5_set_error_message(context, KRB5_PROG_ETYPE_NOSUPP,
4003	N_("encryption type %d not supported", ""),
4004	etype);
4005	return KRB5_PROG_ETYPE_NOSUPP;
4006	}
4007
4008	ret = krb5_copy_keyblock(context, key, &d.key);
4009	if (ret)
4010	return ret;
4011
4012	d.schedule = NULL;
4013	ret = derive_key(context, et, &d, constant, constant_len);
4014	if (ret == 0)
4015	ret = krb5_copy_keyblock(context, d.key, derived_key);
4016	free_key_data(context, &d, et);
4017	return ret;
4018	}
4019
4020	static krb5_error_code
4021	_get_derived_key(krb5_context context,
4022	krb5_crypto crypto,
4023	unsigned usage,
4024	struct key_data **key)
4025	{
4026	int i;
4027	struct key_data *d;
4028	unsigned char constant[5];
4029
4030	for(i = 0; i < crypto->num_key_usage; i++)
4031	if(crypto->key_usage[i].usage == usage) {
4032	*key = &crypto->key_usage[i].key;
4033	return 0;
4034	}
4035	d = _new_derived_key(crypto, usage);
4036	if(d == NULL) {
4037	krb5_set_error_message(context, ENOMEM, N_("malloc: out of memory", ""));
4038	return ENOMEM;
4039	}
4040	krb5_copy_keyblock(context, crypto->key.key, &d->key);
4041	_krb5_put_int(constant, usage, 5);
4042	derive_key(context, crypto->et, d, constant, sizeof(constant));
4043	*key = d;
4044	return 0;
4045	}
4046
4047
4048	krb5_error_code KRB5_LIB_FUNCTION
4049	krb5_crypto_init(krb5_context context,
4050	const krb5_keyblock *key,
4051	krb5_enctype etype,
4052	krb5_crypto *crypto)
4053	{
4054	krb5_error_code ret;
4055	ALLOC(*crypto, 1);
4056	if(*crypto == NULL) {
4057	krb5_set_error_message(context, ENOMEM, N_("malloc: out of memory", ""));
4058	return ENOMEM;
4059	}
4060	if(etype == ETYPE_NULL)
4061	etype = key->keytype;
4062	(*crypto)->et = _find_enctype(etype);
4063	if((crypto)->et == NULL \|\| ((crypto)->et->flags & F_DISABLED)) {
4064	free(*crypto);
4065	*crypto = NULL;
4066	krb5_set_error_message (context, KRB5_PROG_ETYPE_NOSUPP,
4067	N_("encryption type %d not supported", ""),
4068	etype);
4069	return KRB5_PROG_ETYPE_NOSUPP;
4070	}
4071	if((*crypto)->et->keytype->size != key->keyvalue.length) {
4072	free(*crypto);
4073	*crypto = NULL;
4074	krb5_set_error_message (context, KRB5_BAD_KEYSIZE,
4075	"encryption key has bad length");
4076	return KRB5_BAD_KEYSIZE;
4077	}
4078	ret = krb5_copy_keyblock(context, key, &(*crypto)->key.key);
4079	if(ret) {
4080	free(*crypto);
4081	*crypto = NULL;
4082	return ret;
4083	}
4084	(*crypto)->key.schedule = NULL;
4085	(*crypto)->num_key_usage = 0;
4086	(*crypto)->key_usage = NULL;
4087	return 0;
4088	}
4089
4090	static void
4091	free_key_schedule(krb5_context context,
4092	struct key_data *key,
4093	struct encryption_type *et)
4094	{
4095	if (et->keytype->cleanup)
4096	(*et->keytype->cleanup)(context, key);
4097	memset(key->schedule->data, 0, key->schedule->length);
4098	krb5_free_data(context, key->schedule);
4099	}
4100
4101	static void
4102	free_key_data(krb5_context context, struct key_data *key,
4103	struct encryption_type *et)
4104	{
4105	krb5_free_keyblock(context, key->key);
4106	if(key->schedule) {
4107	free_key_schedule(context, key, et);
4108	key->schedule = NULL;
4109	}
4110	}
4111
4112	static void
4113	free_key_usage(krb5_context context, struct key_usage *ku,
4114	struct encryption_type *et)
4115	{
4116	free_key_data(context, &ku->key, et);
4117	}
4118
4119	krb5_error_code KRB5_LIB_FUNCTION
4120	krb5_crypto_destroy(krb5_context context,
4121	krb5_crypto crypto)
4122	{
4123	int i;
4124
4125	for(i = 0; i < crypto->num_key_usage; i++)
4126	free_key_usage(context, &crypto->key_usage[i], crypto->et);
4127	free(crypto->key_usage);
4128	free_key_data(context, &crypto->key, crypto->et);
4129	free (crypto);
4130	return 0;
4131	}
4132
4133	krb5_error_code KRB5_LIB_FUNCTION
4134	krb5_crypto_getblocksize(krb5_context context,
4135	krb5_crypto crypto,
4136	size_t *blocksize)
4137	{
4138	*blocksize = crypto->et->blocksize;
4139	return 0;
4140	}
4141
4142	krb5_error_code KRB5_LIB_FUNCTION
4143	krb5_crypto_getenctype(krb5_context context,
4144	krb5_crypto crypto,
4145	krb5_enctype *enctype)
4146	{
4147	*enctype = crypto->et->type;
4148	return 0;
4149	}
4150
4151	krb5_error_code KRB5_LIB_FUNCTION
4152	krb5_crypto_getpadsize(krb5_context context,
4153	krb5_crypto crypto,
4154	size_t *padsize)
4155	{
4156	*padsize = crypto->et->padsize;
4157	return 0;
4158	}
4159
4160	krb5_error_code KRB5_LIB_FUNCTION
4161	krb5_crypto_getconfoundersize(krb5_context context,
4162	krb5_crypto crypto,
4163	size_t *confoundersize)
4164	{
4165	*confoundersize = crypto->et->confoundersize;
4166	return 0;
4167	}
4168
4169
4170	/**
4171	* Disable encryption type
4172	*
4173	* @param context Kerberos 5 context
4174	* @param enctype encryption type to disable
4175	*
4176	* @return Return an error code or 0.
4177	*
4178	* @ingroup krb5_crypto
4179	*/
4180
4181	krb5_error_code KRB5_LIB_FUNCTION
4182	krb5_enctype_disable(krb5_context context,
4183	krb5_enctype enctype)
4184	{
4185	struct encryption_type *et = _find_enctype(enctype);
4186	if(et == NULL) {
4187	if (context)
4188	krb5_set_error_message (context, KRB5_PROG_ETYPE_NOSUPP,
4189	N_("encryption type %d not supported", ""),
4190	enctype);
4191	return KRB5_PROG_ETYPE_NOSUPP;
4192	}
4193	et->flags \|= F_DISABLED;
4194	return 0;
4195	}
4196
4197	/**
4198	* Enable encryption type
4199	*
4200	* @param context Kerberos 5 context
4201	* @param enctype encryption type to enable
4202	*
4203	* @return Return an error code or 0.
4204	*
4205	* @ingroup krb5_crypto
4206	*/
4207
4208	krb5_error_code KRB5_LIB_FUNCTION
4209	krb5_enctype_enable(krb5_context context,
4210	krb5_enctype enctype)
4211	{
4212	struct encryption_type *et = _find_enctype(enctype);
4213	if(et == NULL) {
4214	if (context)
4215	krb5_set_error_message (context, KRB5_PROG_ETYPE_NOSUPP,
4216	N_("encryption type %d not supported", ""),
4217	enctype);
4218	return KRB5_PROG_ETYPE_NOSUPP;
4219	}
4220	et->flags &= ~F_DISABLED;
4221	return 0;
4222	}
4223
4224
4225	krb5_error_code KRB5_LIB_FUNCTION
4226	krb5_string_to_key_derived(krb5_context context,
4227	const void *str,
4228	size_t len,
4229	krb5_enctype etype,
4230	krb5_keyblock *key)
4231	{
4232	struct encryption_type *et = _find_enctype(etype);
4233	krb5_error_code ret;
4234	struct key_data kd;
4235	size_t keylen;
4236	u_char *tmp;
4237
4238	if(et == NULL) {
4239	krb5_set_error_message (context, KRB5_PROG_ETYPE_NOSUPP,
4240	N_("encryption type %d not supported", ""),
4241	etype);
4242	return KRB5_PROG_ETYPE_NOSUPP;
4243	}
4244	keylen = et->keytype->bits / 8;
4245
4246	ALLOC(kd.key, 1);
4247	if(kd.key == NULL) {
4248	krb5_set_error_message (context, ENOMEM,
4249	N_("malloc: out of memory", ""));
4250	return ENOMEM;
4251	}
4252	ret = krb5_data_alloc(&kd.key->keyvalue, et->keytype->size);
4253	if(ret) {
4254	free(kd.key);
4255	return ret;
4256	}
4257	kd.key->keytype = etype;
4258	tmp = malloc (keylen);
4259	if(tmp == NULL) {
4260	krb5_free_keyblock(context, kd.key);
4261	krb5_set_error_message (context, ENOMEM, N_("malloc: out of memory", ""));
4262	return ENOMEM;
4263	}
4264	ret = _krb5_n_fold(str, len, tmp, keylen);
4265	if (ret) {
4266	free(tmp);
4267	krb5_set_error_message (context, ENOMEM, N_("malloc: out of memory", ""));
4268	return ret;
4269	}
4270	kd.schedule = NULL;
4271	DES3_random_to_key(context, kd.key, tmp, keylen);
4272	memset(tmp, 0, keylen);
4273	free(tmp);
4274	ret = derive_key(context,
4275	et,
4276	&kd,
4277	"kerberos", /* XXX well known constant */
4278	strlen("kerberos"));
4279	if (ret) {
4280	free_key_data(context, &kd, et);
4281	return ret;
4282	}
4283	ret = krb5_copy_keyblock_contents(context, kd.key, key);
4284	free_key_data(context, &kd, et);
4285	return ret;
4286	}
4287
4288	static size_t
4289	wrapped_length (krb5_context context,
4290	krb5_crypto crypto,
4291	size_t data_len)
4292	{
4293	struct encryption_type *et = crypto->et;
4294	size_t padsize = et->padsize;
4295	size_t checksumsize = CHECKSUMSIZE(et->checksum);
4296	size_t res;
4297
4298	res = et->confoundersize + checksumsize + data_len;
4299	res = (res + padsize - 1) / padsize * padsize;
4300	return res;
4301	}
4302
4303	static size_t
4304	wrapped_length_dervied (krb5_context context,
4305	krb5_crypto crypto,
4306	size_t data_len)
4307	{
4308	struct encryption_type *et = crypto->et;
4309	size_t padsize = et->padsize;
4310	size_t res;
4311
4312	res = et->confoundersize + data_len;
4313	res = (res + padsize - 1) / padsize * padsize;
4314	if (et->keyed_checksum)
4315	res += et->keyed_checksum->checksumsize;
4316	else
4317	res += et->checksum->checksumsize;
4318	return res;
4319	}
4320
4321	/*
4322	* Return the size of an encrypted packet of length `data_len'
4323	*/
4324
4325	size_t
4326	krb5_get_wrapped_length (krb5_context context,
4327	krb5_crypto crypto,
4328	size_t data_len)
4329	{
4330	if (derived_crypto (context, crypto))
4331	return wrapped_length_dervied (context, crypto, data_len);
4332	else
4333	return wrapped_length (context, crypto, data_len);
4334	}
4335
4336	/*
4337	* Return the size of an encrypted packet of length `data_len'
4338	*/
4339
4340	static size_t
4341	crypto_overhead (krb5_context context,
4342	krb5_crypto crypto)
4343	{
4344	struct encryption_type *et = crypto->et;
4345	size_t res;
4346
4347	res = CHECKSUMSIZE(et->checksum);
4348	res += et->confoundersize;
4349	if (et->padsize > 1)
4350	res += et->padsize;
4351	return res;
4352	}
4353
4354	static size_t
4355	crypto_overhead_dervied (krb5_context context,
4356	krb5_crypto crypto)
4357	{
4358	struct encryption_type *et = crypto->et;
4359	size_t res;
4360
4361	if (et->keyed_checksum)
4362	res = CHECKSUMSIZE(et->keyed_checksum);
4363	else
4364	res = CHECKSUMSIZE(et->checksum);
4365	res += et->confoundersize;
4366	if (et->padsize > 1)
4367	res += et->padsize;
4368	return res;
4369	}
4370
4371	size_t
4372	krb5_crypto_overhead (krb5_context context, krb5_crypto crypto)
4373	{
4374	if (derived_crypto (context, crypto))
4375	return crypto_overhead_dervied (context, crypto);
4376	else
4377	return crypto_overhead (context, crypto);
4378	}
4379
4380	/**
4381	* Converts the random bytestring to a protocol key according to
4382	* Kerberos crypto frame work. It may be assumed that all the bits of
4383	* the input string are equally random, even though the entropy
4384	* present in the random source may be limited.
4385	*
4386	* @param context Kerberos 5 context
4387	* @param type the enctype resulting key will be of
4388	* @param data input random data to convert to a key
4389	* @param data size of input random data, at least krb5_enctype_keysize() long
4390	* @param data key, output key, free with krb5_free_keyblock_contents()
4391	*
4392	* @return Return an error code or 0.
4393	*
4394	* @ingroup krb5_crypto
4395	*/
4396
4397	krb5_error_code KRB5_LIB_FUNCTION
4398	krb5_random_to_key(krb5_context context,
4399	krb5_enctype type,
4400	const void *data,
4401	size_t size,
4402	krb5_keyblock *key)
4403	{
4404	krb5_error_code ret;
4405	struct encryption_type *et = _find_enctype(type);
4406	if(et == NULL) {
4407	krb5_set_error_message(context, KRB5_PROG_ETYPE_NOSUPP,
4408	N_("encryption type %d not supported", ""),
4409	type);
4410	return KRB5_PROG_ETYPE_NOSUPP;
4411	}
4412	if ((et->keytype->bits + 7) / 8 > size) {
4413	krb5_set_error_message(context, KRB5_PROG_ETYPE_NOSUPP,
4414	N_("encryption key %s needs %d bytes "
4415	"of random to make an encryption key "
4416	"out of it", ""),
4417	et->name, (int)et->keytype->size);
4418	return KRB5_PROG_ETYPE_NOSUPP;
4419	}
4420	ret = krb5_data_alloc(&key->keyvalue, et->keytype->size);
4421	if(ret)
4422	return ret;
4423	key->keytype = type;
4424	if (et->keytype->random_to_key)
4425	(*et->keytype->random_to_key)(context, key, data, size);
4426	else
4427	memcpy(key->keyvalue.data, data, et->keytype->size);
4428
4429	return 0;
4430	}
4431
4432	krb5_error_code
4433	_krb5_pk_octetstring2key(krb5_context context,
4434	krb5_enctype type,
4435	const void *dhdata,
4436	size_t dhsize,
4437	const heim_octet_string *c_n,
4438	const heim_octet_string *k_n,
4439	krb5_keyblock *key)
4440	{
4441	struct encryption_type *et = _find_enctype(type);
4442	krb5_error_code ret;
4443	size_t keylen, offset;
4444	void *keydata;
4445	unsigned char counter;
4446	unsigned char shaoutput[SHA_DIGEST_LENGTH];
4447
4448	if(et == NULL) {
4449	krb5_set_error_message(context, KRB5_PROG_ETYPE_NOSUPP,
4450	N_("encryption type %d not supported", ""),
4451	type);
4452	return KRB5_PROG_ETYPE_NOSUPP;
4453	}
4454	keylen = (et->keytype->bits + 7) / 8;
4455
4456	keydata = malloc(keylen);
4457	if (keydata == NULL) {
4458	krb5_set_error_message(context, ENOMEM, N_("malloc: out of memory", ""));
4459	return ENOMEM;
4460	}
4461
4462	counter = 0;
4463	offset = 0;
4464	do {
4465	SHA_CTX m;
4466
4467	SHA1_Init(&m);
4468	SHA1_Update(&m, &counter, 1);
4469	SHA1_Update(&m, dhdata, dhsize);
4470	if (c_n)
4471	SHA1_Update(&m, c_n->data, c_n->length);
4472	if (k_n)
4473	SHA1_Update(&m, k_n->data, k_n->length);
4474	SHA1_Final(shaoutput, &m);
4475
4476	memcpy((unsigned char *)keydata + offset,
4477	shaoutput,
4478	min(keylen - offset, sizeof(shaoutput)));
4479
4480	offset += sizeof(shaoutput);
4481	counter++;
4482	} while(offset < keylen);
4483	memset(shaoutput, 0, sizeof(shaoutput));
4484
4485	ret = krb5_random_to_key(context, type, keydata, keylen, key);
4486	memset(keydata, 0, sizeof(keylen));
4487	free(keydata);
4488	return ret;
4489	}
4490
4491	static krb5_error_code
4492	encode_uvinfo(krb5_context context, krb5_const_principal p, krb5_data *data)
4493	{
4494	KRB5PrincipalName pn;
4495	krb5_error_code ret;
4496	size_t size;
4497
4498	pn.principalName = p->name;
4499	pn.realm = p->realm;
4500
4501	ASN1_MALLOC_ENCODE(KRB5PrincipalName, data->data, data->length,
4502	&pn, &size, ret);
4503	if (ret) {
4504	krb5_data_zero(data);
4505	krb5_set_error_message(context, ret,
4506	N_("Failed to encode KRB5PrincipalName", ""));
4507	return ret;
4508	}
4509	if (data->length != size)
4510	krb5_abortx(context, "asn1 compiler internal error");
4511	return 0;
4512	}
4513
4514	static krb5_error_code
4515	encode_otherinfo(krb5_context context,
4516	const AlgorithmIdentifier *ai,
4517	krb5_const_principal client,
4518	krb5_const_principal server,
4519	krb5_enctype enctype,
4520	const krb5_data *as_req,
4521	const krb5_data *pk_as_rep,
4522	const Ticket *ticket,
4523	krb5_data *other)
4524	{
4525	PkinitSP80056AOtherInfo otherinfo;
4526	PkinitSuppPubInfo pubinfo;
4527	krb5_error_code ret;
4528	krb5_data pub;
4529	size_t size;
4530
4531	krb5_data_zero(other);
4532	memset(&otherinfo, 0, sizeof(otherinfo));
4533	memset(&pubinfo, 0, sizeof(pubinfo));
4534
4535	pubinfo.enctype = enctype;
4536	pubinfo.as_REQ = *as_req;
4537	pubinfo.pk_as_rep = *pk_as_rep;
4538	pubinfo.ticket = *ticket;
4539	ASN1_MALLOC_ENCODE(PkinitSuppPubInfo, pub.data, pub.length,
4540	&pubinfo, &size, ret);
4541	if (ret) {
4542	krb5_set_error_message(context, ret, N_("malloc: out of memory", ""));
4543	return ret;
4544	}
4545	if (pub.length != size)
4546	krb5_abortx(context, "asn1 compiler internal error");
4547
4548	ret = encode_uvinfo(context, client, &otherinfo.partyUInfo);
4549	if (ret) {
4550	free(pub.data);
4551	return ret;
4552	}
4553	ret = encode_uvinfo(context, server, &otherinfo.partyVInfo);
4554	if (ret) {
4555	free(otherinfo.partyUInfo.data);
4556	free(pub.data);
4557	return ret;
4558	}
4559
4560	otherinfo.algorithmID = *ai;
4561	otherinfo.suppPubInfo = &pub;
4562
4563	ASN1_MALLOC_ENCODE(PkinitSP80056AOtherInfo, other->data, other->length,
4564	&otherinfo, &size, ret);
4565	free(otherinfo.partyUInfo.data);
4566	free(otherinfo.partyVInfo.data);
4567	free(pub.data);
4568	if (ret) {
4569	krb5_set_error_message(context, ret, N_("malloc: out of memory", ""));
4570	return ret;
4571	}
4572	if (other->length != size)
4573	krb5_abortx(context, "asn1 compiler internal error");
4574
4575	return 0;
4576	}
4577
4578	krb5_error_code
4579	_krb5_pk_kdf(krb5_context context,
4580	const struct AlgorithmIdentifier *ai,
4581	const void *dhdata,
4582	size_t dhsize,
4583	krb5_const_principal client,
4584	krb5_const_principal server,
4585	krb5_enctype enctype,
4586	const krb5_data *as_req,
4587	const krb5_data *pk_as_rep,
4588	const Ticket *ticket,
4589	krb5_keyblock *key)
4590	{
4591	struct encryption_type *et;
4592	krb5_error_code ret;
4593	krb5_data other;
4594	size_t keylen, offset;
4595	uint32_t counter;
4596	unsigned char *keydata;
4597	unsigned char shaoutput[SHA_DIGEST_LENGTH];
4598
4599	if (der_heim_oid_cmp(&asn1_oid_id_pkinit_kdf_ah_sha1, &ai->algorithm) != 0) {
4600	krb5_set_error_message(context, KRB5_PROG_ETYPE_NOSUPP,
4601	N_("KDF not supported", ""));
4602	return KRB5_PROG_ETYPE_NOSUPP;
4603	}
4604	if (ai->parameters != NULL &&
4605	(ai->parameters->length != 2 \|\|
4606	memcmp(ai->parameters->data, "\x05\x00", 2) != 0))
4607	{
4608	krb5_set_error_message(context, KRB5_PROG_ETYPE_NOSUPP,
4609	N_("kdf params not NULL or the NULL-type",
4610	""));
4611	return KRB5_PROG_ETYPE_NOSUPP;
4612	}
4613
4614	et = _find_enctype(enctype);
4615	if(et == NULL) {
4616	krb5_set_error_message(context, KRB5_PROG_ETYPE_NOSUPP,
4617	N_("encryption type %d not supported", ""),
4618	enctype);
4619	return KRB5_PROG_ETYPE_NOSUPP;
4620	}
4621	keylen = (et->keytype->bits + 7) / 8;
4622
4623	keydata = malloc(keylen);
4624	if (keydata == NULL) {
4625	krb5_set_error_message(context, ENOMEM, N_("malloc: out of memory", ""));
4626	return ENOMEM;
4627	}
4628
4629	ret = encode_otherinfo(context, ai, client, server,
4630	enctype, as_req, pk_as_rep, ticket, &other);
4631	if (ret) {
4632	free(keydata);
4633	return ret;
4634	}
4635
4636	offset = 0;
4637	counter = 1;
4638	do {
4639	unsigned char cdata[4];
4640	SHA_CTX m;
4641
4642	SHA1_Init(&m);
4643	_krb5_put_int(cdata, counter, 4);
4644	SHA1_Update(&m, cdata, 4);
4645	SHA1_Update(&m, dhdata, dhsize);
4646	SHA1_Update(&m, other.data, other.length);
4647	SHA1_Final(shaoutput, &m);
4648
4649	memcpy((unsigned char *)keydata + offset,
4650	shaoutput,
4651	min(keylen - offset, sizeof(shaoutput)));
4652
4653	offset += sizeof(shaoutput);
4654	counter++;
4655	} while(offset < keylen);
4656	memset(shaoutput, 0, sizeof(shaoutput));
4657
4658	free(other.data);
4659
4660	ret = krb5_random_to_key(context, enctype, keydata, keylen, key);
4661	memset(keydata, 0, sizeof(keylen));
4662	free(keydata);
4663
4664	return ret;
4665	}
4666
4667
4668	krb5_error_code KRB5_LIB_FUNCTION
4669	krb5_crypto_prf_length(krb5_context context,
4670	krb5_enctype type,
4671	size_t *length)
4672	{
4673	struct encryption_type *et = _find_enctype(type);
4674
4675	if(et == NULL \|\| et->prf_length == 0) {
4676	krb5_set_error_message(context, KRB5_PROG_ETYPE_NOSUPP,
4677	N_("encryption type %d not supported", ""),
4678	type);
4679	return KRB5_PROG_ETYPE_NOSUPP;
4680	}
4681
4682	*length = et->prf_length;
4683	return 0;
4684	}
4685
4686	krb5_error_code KRB5_LIB_FUNCTION
4687	krb5_crypto_prf(krb5_context context,
4688	const krb5_crypto crypto,
4689	const krb5_data *input,
4690	krb5_data *output)
4691	{
4692	struct encryption_type *et = crypto->et;
4693
4694	krb5_data_zero(output);
4695
4696	if(et->prf == NULL) {
4697	krb5_set_error_message(context, KRB5_PROG_ETYPE_NOSUPP,
4698	"kerberos prf for %s not supported",
4699	et->name);
4700	return KRB5_PROG_ETYPE_NOSUPP;
4701	}
4702
4703	return (*et->prf)(context, crypto, input, output);
4704	}
4705
4706	static krb5_error_code
4707	krb5_crypto_prfplus(krb5_context context,
4708	const krb5_crypto crypto,
4709	const krb5_data *input,
4710	size_t length,
4711	krb5_data *output)
4712	{
4713	krb5_error_code ret;
4714	krb5_data input2;
4715	unsigned char i = 1;
4716	unsigned char *p;
4717
4718	krb5_data_zero(&input2);
4719	krb5_data_zero(output);
4720
4721	krb5_clear_error_message(context);
4722
4723	ret = krb5_data_alloc(output, length);
4724	if (ret) goto out;
4725	ret = krb5_data_alloc(&input2, input->length + 1);
4726	if (ret) goto out;
4727
4728	krb5_clear_error_message(context);
4729
4730	memcpy(((unsigned char *)input2.data) + 1, input->data, input->length);
4731
4732	p = output->data;
4733
4734	while (length) {
4735	krb5_data block;
4736
4737	((unsigned char *)input2.data)[0] = i++;
4738
4739	ret = krb5_crypto_prf(context, crypto, &input2, &block);
4740	if (ret)
4741	goto out;
4742
4743	if (block.length < length) {
4744	memcpy(p, block.data, block.length);
4745	length -= block.length;
4746	} else {
4747	memcpy(p, block.data, length);
4748	length = 0;
4749	}
4750	p += block.length;
4751	krb5_data_free(&block);
4752	}
4753
4754	out:
4755	krb5_data_free(&input2);
4756	if (ret)
4757	krb5_data_free(output);
4758	return 0;
4759	}
4760
4761	/**
4762	* The FX-CF2 key derivation function, used in FAST and preauth framework.
4763	*
4764	* @param context Kerberos 5 context
4765	* @param crypto1 first key to combine
4766	* @param crypto2 second key to combine
4767	* @param pepper1 factor to combine with first key to garante uniqueness
4768	* @param pepper1 factor to combine with second key to garante uniqueness
4769	* @param enctype the encryption type of the resulting key
4770	* @param res allocated key, free with krb5_free_keyblock_contents()
4771	*
4772	* @return Return an error code or 0.
4773	*
4774	* @ingroup krb5_crypto
4775	*/
4776
4777	krb5_error_code KRB5_LIB_FUNCTION
4778	krb5_crypto_fx_cf2(krb5_context context,
4779	const krb5_crypto crypto1,
4780	const krb5_crypto crypto2,
4781	krb5_data *pepper1,
4782	krb5_data *pepper2,
4783	krb5_enctype enctype,
4784	krb5_keyblock *res)
4785	{
4786	krb5_error_code ret;
4787	krb5_data os1, os2;
4788	size_t i, keysize;
4789
4790	memset(res, 0, sizeof(*res));
4791
4792	ret = krb5_enctype_keysize(context, enctype, &keysize);
4793	if (ret)
4794	return ret;
4795
4796	ret = krb5_data_alloc(&res->keyvalue, keysize);
4797	if (ret)
4798	goto out;
4799	ret = krb5_crypto_prfplus(context, crypto1, pepper1, keysize, &os1);
4800	if (ret)
4801	goto out;
4802	ret = krb5_crypto_prfplus(context, crypto2, pepper2, keysize, &os2);
4803	if (ret)
4804	goto out;
4805
4806	res->keytype = enctype;
4807	{
4808	unsigned char p1 = os1.data, p2 = os2.data, *p3 = res->keyvalue.data;
4809	for (i = 0; i < keysize; i++)
4810	p3[i] = p1[i] ^ p2[i];
4811	}
4812	out:
4813	if (ret)
4814	krb5_data_free(&res->keyvalue);
4815	krb5_data_free(&os1);
4816	krb5_data_free(&os2);
4817
4818	return ret;
4819	}
4820
4821
4822
4823	#ifndef HEIMDAL_SMALLER
4824
4825	krb5_error_code KRB5_LIB_FUNCTION
4826	krb5_keytype_to_enctypes (krb5_context context,
4827	krb5_keytype keytype,
4828	unsigned *len,
4829	krb5_enctype **val)
4830	KRB5_DEPRECATED
4831	{
4832	int i;
4833	unsigned n = 0;
4834	krb5_enctype *ret;
4835
4836	for (i = num_etypes - 1; i >= 0; --i) {
4837	if (etypes[i]->keytype->type == keytype
4838	&& !(etypes[i]->flags & F_PSEUDO)
4839	&& krb5_enctype_valid(context, etypes[i]->type) == 0)
4840	++n;
4841	}
4842	if (n == 0) {
4843	krb5_set_error_message(context, KRB5_PROG_KEYTYPE_NOSUPP,
4844	"Keytype have no mapping");
4845	return KRB5_PROG_KEYTYPE_NOSUPP;
4846	}
4847
4848	ret = malloc(n * sizeof(*ret));
4849	if (ret == NULL && n != 0) {
4850	krb5_set_error_message(context, ENOMEM, "malloc: out of memory");
4851	return ENOMEM;
4852	}
4853	n = 0;
4854	for (i = num_etypes - 1; i >= 0; --i) {
4855	if (etypes[i]->keytype->type == keytype
4856	&& !(etypes[i]->flags & F_PSEUDO)
4857	&& krb5_enctype_valid(context, etypes[i]->type) == 0)
4858	ret[n++] = etypes[i]->type;
4859	}
4860	*len = n;
4861	*val = ret;
4862	return 0;
4863	}
4864
4865	/* if two enctypes have compatible keys */
4866	krb5_boolean KRB5_LIB_FUNCTION
4867	krb5_enctypes_compatible_keys(krb5_context context,
4868	krb5_enctype etype1,
4869	krb5_enctype etype2)
4870	KRB5_DEPRECATED
4871	{
4872	struct encryption_type *e1 = _find_enctype(etype1);
4873	struct encryption_type *e2 = _find_enctype(etype2);
4874	return e1 != NULL && e2 != NULL && e1->keytype == e2->keytype;
4875	}
4876
4877	#endif /* HEIMDAL_SMALLER */

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