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      1 /*	$NetBSD: crypto_openssl.c,v 1.11.6.6 2009/04/29 10:50:25 tteras Exp $	*/
      2 
      3 /* Id: crypto_openssl.c,v 1.47 2006/05/06 20:42:09 manubsd Exp */
      4 
      5 /*
      6  * Copyright (C) 1995, 1996, 1997, and 1998 WIDE Project.
      7  * All rights reserved.
      8  *
      9  * Redistribution and use in source and binary forms, with or without
     10  * modification, are permitted provided that the following conditions
     11  * are met:
     12  * 1. Redistributions of source code must retain the above copyright
     13  *    notice, this list of conditions and the following disclaimer.
     14  * 2. Redistributions in binary form must reproduce the above copyright
     15  *    notice, this list of conditions and the following disclaimer in the
     16  *    documentation and/or other materials provided with the distribution.
     17  * 3. Neither the name of the project 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 PROJECT 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 PROJECT OR CONTRIBUTORS BE LIABLE
     25  * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
     26  * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
     27  * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
     28  * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
     29  * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
     30  * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
     31  * SUCH DAMAGE.
     32  */
     33 
     34 #include "config.h"
     35 
     36 #include <sys/types.h>
     37 #include <sys/param.h>
     38 
     39 #include <stdlib.h>
     40 #include <stdio.h>
     41 #include <limits.h>
     42 #include <string.h>
     43 
     44 /* get openssl/ssleay version number */
     45 #include <openssl/opensslv.h>
     46 
     47 #if !defined(OPENSSL_VERSION_NUMBER) || (OPENSSL_VERSION_NUMBER < 0x0090602fL)
     48 #error OpenSSL version 0.9.6 or later required.
     49 #endif
     50 
     51 #include <openssl/pem.h>
     52 #include <openssl/evp.h>
     53 #include <openssl/x509.h>
     54 #include <openssl/x509v3.h>
     55 #include <openssl/x509_vfy.h>
     56 #include <openssl/bn.h>
     57 #include <openssl/dh.h>
     58 #include <openssl/md5.h>
     59 #include <openssl/sha.h>
     60 #include <openssl/hmac.h>
     61 #include <openssl/des.h>
     62 #include <openssl/crypto.h>
     63 #ifdef HAVE_OPENSSL_ENGINE_H
     64 #include <openssl/engine.h>
     65 #endif
     66 #ifndef ANDROID_CHANGES
     67 #include <openssl/blowfish.h>
     68 #include <openssl/cast.h>
     69 #else
     70 #define EVP_bf_cbc()    NULL
     71 #define EVP_cast5_cbc() NULL
     72 #include "keystore_get.h"
     73 #endif
     74 #include <openssl/err.h>
     75 #ifdef HAVE_OPENSSL_RC5_H
     76 #include <openssl/rc5.h>
     77 #endif
     78 #ifdef HAVE_OPENSSL_IDEA_H
     79 #include <openssl/idea.h>
     80 #endif
     81 #if defined(HAVE_OPENSSL_AES_H)
     82 #include <openssl/aes.h>
     83 #elif defined(HAVE_OPENSSL_RIJNDAEL_H)
     84 #include <openssl/rijndael.h>
     85 #else
     86 #include "crypto/rijndael/rijndael-api-fst.h"
     87 #endif
     88 #if defined(HAVE_OPENSSL_CAMELLIA_H)
     89 #include <openssl/camellia.h>
     90 #endif
     91 #ifdef WITH_SHA2
     92 #ifdef HAVE_OPENSSL_SHA2_H
     93 #include <openssl/sha2.h>
     94 #else
     95 #include "crypto/sha2/sha2.h"
     96 #endif
     97 #endif
     98 #include "plog.h"
     99 
    100 /* 0.9.7 stuff? */
    101 #if OPENSSL_VERSION_NUMBER < 0x0090700fL
    102 typedef STACK_OF(GENERAL_NAME) GENERAL_NAMES;
    103 #else
    104 #define USE_NEW_DES_API
    105 #endif
    106 
    107 #define OpenSSL_BUG()	do { plog(LLV_ERROR, LOCATION, NULL, "OpenSSL function failed\n"); } while(0)
    108 
    109 #include "var.h"
    110 #include "misc.h"
    111 #include "vmbuf.h"
    112 #include "plog.h"
    113 #include "crypto_openssl.h"
    114 #include "debug.h"
    115 #include "gcmalloc.h"
    116 
    117 /*
    118  * I hate to cast every parameter to des_xx into void *, but it is
    119  * necessary for SSLeay/OpenSSL portability.  It sucks.
    120  */
    121 
    122 static int cb_check_cert_local __P((int, X509_STORE_CTX *));
    123 static int cb_check_cert_remote __P((int, X509_STORE_CTX *));
    124 static X509 *mem2x509 __P((vchar_t *));
    125 
    126 static caddr_t eay_hmac_init __P((vchar_t *, const EVP_MD *));
    127 
    128 /* X509 Certificate */
    129 /*
    130  * convert the string of the subject name into DER
    131  * e.g. str = "C=JP, ST=Kanagawa";
    132  */
    133 vchar_t *
    134 eay_str2asn1dn(str, len)
    135 	const char *str;
    136 	int len;
    137 {
    138 	X509_NAME *name;
    139 	char *buf;
    140 	char *field, *value;
    141 	int i, j;
    142 	vchar_t *ret = NULL;
    143 	caddr_t p;
    144 
    145 	if (len == -1)
    146 		len = strlen(str);
    147 
    148 	buf = racoon_malloc(len + 1);
    149 	if (!buf) {
    150 		plog(LLV_WARNING, LOCATION, NULL,"failed to allocate buffer\n");
    151 		return NULL;
    152 	}
    153 	memcpy(buf, str, len);
    154 
    155 	name = X509_NAME_new();
    156 
    157 	field = &buf[0];
    158 	value = NULL;
    159 	for (i = 0; i < len; i++) {
    160 		if (!value && buf[i] == '=') {
    161 			buf[i] = '\0';
    162 			value = &buf[i + 1];
    163 			continue;
    164 		} else if (buf[i] == ',' || buf[i] == '/') {
    165 			buf[i] = '\0';
    166 
    167 			plog(LLV_DEBUG, LOCATION, NULL, "DN: %s=%s\n",
    168 			     field, value);
    169 
    170 			if (!value) goto err;
    171 			if (!X509_NAME_add_entry_by_txt(name, field,
    172 					(value[0] == '*' && value[1] == 0) ?
    173 						V_ASN1_PRINTABLESTRING : MBSTRING_ASC,
    174 					(unsigned char *) value, -1, -1, 0)) {
    175 				plog(LLV_ERROR, LOCATION, NULL,
    176 				     "Invalid DN field: %s=%s\n",
    177 				     field, value);
    178 				plog(LLV_ERROR, LOCATION, NULL,
    179 				     "%s\n", eay_strerror());
    180 				goto err;
    181 			}
    182 			for (j = i + 1; j < len; j++) {
    183 				if (buf[j] != ' ')
    184 					break;
    185 			}
    186 			field = &buf[j];
    187 			value = NULL;
    188 			continue;
    189 		}
    190 	}
    191 	buf[len] = '\0';
    192 
    193 	plog(LLV_DEBUG, LOCATION, NULL, "DN: %s=%s\n",
    194 	     field, value);
    195 
    196 	if (!value) goto err;
    197 	if (!X509_NAME_add_entry_by_txt(name, field,
    198 			(value[0] == '*' && value[1] == 0) ?
    199 				V_ASN1_PRINTABLESTRING : MBSTRING_ASC,
    200 			(unsigned char *) value, -1, -1, 0)) {
    201 		plog(LLV_ERROR, LOCATION, NULL,
    202 		     "Invalid DN field: %s=%s\n",
    203 		     field, value);
    204 		plog(LLV_ERROR, LOCATION, NULL,
    205 		     "%s\n", eay_strerror());
    206 		goto err;
    207 	}
    208 
    209 	i = i2d_X509_NAME(name, NULL);
    210 	if (!i)
    211 		goto err;
    212 	ret = vmalloc(i);
    213 	if (!ret)
    214 		goto err;
    215 	p = ret->v;
    216 	i = i2d_X509_NAME(name, (void *)&p);
    217 	if (!i)
    218 		goto err;
    219 
    220 	return ret;
    221 
    222     err:
    223 	if (buf)
    224 		racoon_free(buf);
    225 	if (name)
    226 		X509_NAME_free(name);
    227 	if (ret)
    228 		vfree(ret);
    229 	return NULL;
    230 }
    231 
    232 /*
    233  * convert the hex string of the subject name into DER
    234  */
    235 vchar_t *
    236 eay_hex2asn1dn(const char *hex, int len)
    237 {
    238 	BIGNUM *bn = BN_new();
    239 	char *binbuf;
    240 	size_t binlen;
    241 	vchar_t *ret = NULL;
    242 
    243 	if (len == -1)
    244 		len = strlen(hex);
    245 
    246 	if (BN_hex2bn(&bn, hex) != len) {
    247 		plog(LLV_ERROR, LOCATION, NULL,
    248 		     "conversion of Hex-encoded ASN1 string to binary failed: %s\n",
    249 		     eay_strerror());
    250 		goto out;
    251 	}
    252 
    253 	binlen = BN_num_bytes(bn);
    254 	ret = vmalloc(binlen);
    255 	if (!ret) {
    256 		plog(LLV_WARNING, LOCATION, NULL,"failed to allocate buffer\n");
    257 		return NULL;
    258 	}
    259 	binbuf = ret->v;
    260 
    261 	BN_bn2bin(bn, (unsigned char *) binbuf);
    262 
    263 out:
    264 	BN_free(bn);
    265 
    266 	return ret;
    267 }
    268 
    269 /*
    270  * The following are derived from code in crypto/x509/x509_cmp.c
    271  * in OpenSSL0.9.7c:
    272  * X509_NAME_wildcmp() adds wildcard matching to the original
    273  * X509_NAME_cmp(), nocase_cmp() and nocase_spacenorm_cmp() are as is.
    274  */
    275 #include <ctype.h>
    276 /* Case insensitive string comparision */
    277 static int nocase_cmp(const ASN1_STRING *a, const ASN1_STRING *b)
    278 {
    279 	int i;
    280 
    281 	if (a->length != b->length)
    282 		return (a->length - b->length);
    283 
    284 	for (i=0; i<a->length; i++)
    285 	{
    286 		int ca, cb;
    287 
    288 		ca = tolower(a->data[i]);
    289 		cb = tolower(b->data[i]);
    290 
    291 		if (ca != cb)
    292 			return(ca-cb);
    293 	}
    294 	return 0;
    295 }
    296 
    297 /* Case insensitive string comparision with space normalization
    298  * Space normalization - ignore leading, trailing spaces,
    299  *       multiple spaces between characters are replaced by single space
    300  */
    301 static int nocase_spacenorm_cmp(const ASN1_STRING *a, const ASN1_STRING *b)
    302 {
    303 	unsigned char *pa = NULL, *pb = NULL;
    304 	int la, lb;
    305 
    306 	la = a->length;
    307 	lb = b->length;
    308 	pa = a->data;
    309 	pb = b->data;
    310 
    311 	/* skip leading spaces */
    312 	while (la > 0 && isspace(*pa))
    313 	{
    314 		la--;
    315 		pa++;
    316 	}
    317 	while (lb > 0 && isspace(*pb))
    318 	{
    319 		lb--;
    320 		pb++;
    321 	}
    322 
    323 	/* skip trailing spaces */
    324 	while (la > 0 && isspace(pa[la-1]))
    325 		la--;
    326 	while (lb > 0 && isspace(pb[lb-1]))
    327 		lb--;
    328 
    329 	/* compare strings with space normalization */
    330 	while (la > 0 && lb > 0)
    331 	{
    332 		int ca, cb;
    333 
    334 		/* compare character */
    335 		ca = tolower(*pa);
    336 		cb = tolower(*pb);
    337 		if (ca != cb)
    338 			return (ca - cb);
    339 
    340 		pa++; pb++;
    341 		la--; lb--;
    342 
    343 		if (la <= 0 || lb <= 0)
    344 			break;
    345 
    346 		/* is white space next character ? */
    347 		if (isspace(*pa) && isspace(*pb))
    348 		{
    349 			/* skip remaining white spaces */
    350 			while (la > 0 && isspace(*pa))
    351 			{
    352 				la--;
    353 				pa++;
    354 			}
    355 			while (lb > 0 && isspace(*pb))
    356 			{
    357 				lb--;
    358 				pb++;
    359 			}
    360 		}
    361 	}
    362 	if (la > 0 || lb > 0)
    363 		return la - lb;
    364 
    365 	return 0;
    366 }
    367 
    368 static int X509_NAME_wildcmp(const X509_NAME *a, const X509_NAME *b)
    369 {
    370     int i,j;
    371     X509_NAME_ENTRY *na,*nb;
    372 
    373     if (sk_X509_NAME_ENTRY_num(a->entries)
    374 	!= sk_X509_NAME_ENTRY_num(b->entries))
    375 	    return sk_X509_NAME_ENTRY_num(a->entries)
    376 	      -sk_X509_NAME_ENTRY_num(b->entries);
    377     for (i=sk_X509_NAME_ENTRY_num(a->entries)-1; i>=0; i--)
    378     {
    379 	    na=sk_X509_NAME_ENTRY_value(a->entries,i);
    380 	    nb=sk_X509_NAME_ENTRY_value(b->entries,i);
    381 	    j=OBJ_cmp(na->object,nb->object);
    382 	    if (j) return(j);
    383 	    if ((na->value->length == 1 && na->value->data[0] == '*')
    384 	     || (nb->value->length == 1 && nb->value->data[0] == '*'))
    385 		    continue;
    386 	    j=na->value->type-nb->value->type;
    387 	    if (j) return(j);
    388 	    if (na->value->type == V_ASN1_PRINTABLESTRING)
    389 		    j=nocase_spacenorm_cmp(na->value, nb->value);
    390 	    else if (na->value->type == V_ASN1_IA5STRING
    391 		    && OBJ_obj2nid(na->object) == NID_pkcs9_emailAddress)
    392 		    j=nocase_cmp(na->value, nb->value);
    393 	    else
    394 		    {
    395 		    j=na->value->length-nb->value->length;
    396 		    if (j) return(j);
    397 		    j=memcmp(na->value->data,nb->value->data,
    398 			    na->value->length);
    399 		    }
    400 	    if (j) return(j);
    401 	    j=na->set-nb->set;
    402 	    if (j) return(j);
    403     }
    404 
    405     return(0);
    406 }
    407 
    408 /*
    409  * compare two subjectNames.
    410  * OUT:        0: equal
    411  *	positive:
    412  *	      -1: other error.
    413  */
    414 int
    415 eay_cmp_asn1dn(n1, n2)
    416 	vchar_t *n1, *n2;
    417 {
    418 	X509_NAME *a = NULL, *b = NULL;
    419 	caddr_t p;
    420 	int i = -1;
    421 
    422 	p = n1->v;
    423 	if (!d2i_X509_NAME(&a, (void *)&p, n1->l))
    424 		goto end;
    425 	p = n2->v;
    426 	if (!d2i_X509_NAME(&b, (void *)&p, n2->l))
    427 		goto end;
    428 
    429 	i = X509_NAME_wildcmp(a, b);
    430 
    431     end:
    432 	if (a)
    433 		X509_NAME_free(a);
    434 	if (b)
    435 		X509_NAME_free(b);
    436 	return i;
    437 }
    438 
    439 #ifdef ANDROID_CHANGES
    440 static BIO *BIO_from_keystore(char *key)
    441 {
    442 	BIO *bio = NULL;
    443 	char value[KEYSTORE_MESSAGE_SIZE];
    444 	int length = keystore_get(key, strlen(key), value);
    445 	if (length != -1 && (bio = BIO_new(BIO_s_mem())) != NULL) {
    446 		BIO_write(bio, value, length);
    447 	}
    448 	return bio;
    449 }
    450 #endif
    451 
    452 
    453 /*
    454  * this functions is derived from apps/verify.c in OpenSSL0.9.5
    455  */
    456 int
    457 eay_check_x509cert(cert, CApath, CAfile, local)
    458 	vchar_t *cert;
    459 	char *CApath;
    460 	char *CAfile;
    461 	int local;
    462 {
    463 	X509_STORE *cert_ctx = NULL;
    464 	X509_LOOKUP *lookup = NULL;
    465 	X509 *x509 = NULL;
    466 	X509_STORE_CTX *csc;
    467 	int error = -1;
    468 
    469 	cert_ctx = X509_STORE_new();
    470 	if (cert_ctx == NULL)
    471 		goto end;
    472 
    473 	if (local)
    474 		X509_STORE_set_verify_cb_func(cert_ctx, cb_check_cert_local);
    475 	else
    476 		X509_STORE_set_verify_cb_func(cert_ctx, cb_check_cert_remote);
    477 
    478 #ifndef ANDROID_CHANGES
    479 	lookup = X509_STORE_add_lookup(cert_ctx, X509_LOOKUP_file());
    480 	if (lookup == NULL)
    481 		goto end;
    482 
    483 	X509_LOOKUP_load_file(lookup, CAfile,
    484 	    (CAfile == NULL) ? X509_FILETYPE_DEFAULT : X509_FILETYPE_PEM);
    485 
    486 	lookup = X509_STORE_add_lookup(cert_ctx, X509_LOOKUP_hash_dir());
    487 	if (lookup == NULL)
    488 		goto end;
    489 	error = X509_LOOKUP_add_dir(lookup, CApath, X509_FILETYPE_PEM);
    490 	if(!error) {
    491 		error = -1;
    492 		goto end;
    493 	}
    494 	error = -1;	/* initialized */
    495 #else
    496 	if (CAfile) {
    497 		BIO *bio = BIO_from_keystore(CAfile);
    498 		STACK_OF(X509_INFO) *stack;
    499 		X509_INFO *info;
    500 		int i;
    501 
    502 		if (!bio) {
    503 			goto end;
    504 		}
    505 		stack = PEM_X509_INFO_read_bio(bio, NULL, NULL, NULL);
    506 		BIO_free(bio);
    507 		if (!stack) {
    508 			goto end;
    509 		}
    510 		for (i = 0; i < sk_X509_INFO_num(stack); ++i) {
    511 			info = sk_X509_INFO_value(stack, i);
    512 			if (info->x509) {
    513 				X509_STORE_add_cert(cert_ctx, info->x509);
    514 			}
    515 			if (info->crl) {
    516 				X509_STORE_add_crl(cert_ctx, info->crl);
    517 			}
    518 		}
    519 		sk_X509_INFO_pop_free(stack, X509_INFO_free);
    520 	}
    521 #endif
    522 
    523 	/* read the certificate to be verified */
    524 	x509 = mem2x509(cert);
    525 	if (x509 == NULL)
    526 		goto end;
    527 
    528 	csc = X509_STORE_CTX_new();
    529 	if (csc == NULL)
    530 		goto end;
    531 	X509_STORE_CTX_init(csc, cert_ctx, x509, NULL);
    532 #if OPENSSL_VERSION_NUMBER >= 0x00907000L
    533 	X509_STORE_CTX_set_flags (csc, X509_V_FLAG_CRL_CHECK);
    534 	X509_STORE_CTX_set_flags (csc, X509_V_FLAG_CRL_CHECK_ALL);
    535 #endif
    536 	error = X509_verify_cert(csc);
    537 	X509_STORE_CTX_free(csc);
    538 
    539 	/*
    540 	 * if x509_verify_cert() is successful then the value of error is
    541 	 * set non-zero.
    542 	 */
    543 	error = error ? 0 : -1;
    544 
    545 end:
    546 	if (error)
    547 		plog(LLV_WARNING, LOCATION, NULL,"%s\n", eay_strerror());
    548 	if (cert_ctx != NULL)
    549 		X509_STORE_free(cert_ctx);
    550 	if (x509 != NULL)
    551 		X509_free(x509);
    552 
    553 	return(error);
    554 }
    555 
    556 /*
    557  * callback function for verifing certificate.
    558  * this function is derived from cb() in openssl/apps/s_server.c
    559  */
    560 static int
    561 cb_check_cert_local(ok, ctx)
    562 	int ok;
    563 	X509_STORE_CTX *ctx;
    564 {
    565 	char buf[256];
    566 	int log_tag;
    567 
    568 	if (!ok) {
    569 		X509_NAME_oneline(
    570 				X509_get_subject_name(ctx->current_cert),
    571 				buf,
    572 				256);
    573 		/*
    574 		 * since we are just checking the certificates, it is
    575 		 * ok if they are self signed. But we should still warn
    576 		 * the user.
    577  		 */
    578 		switch (ctx->error) {
    579 		case X509_V_ERR_CERT_HAS_EXPIRED:
    580 		case X509_V_ERR_DEPTH_ZERO_SELF_SIGNED_CERT:
    581 		case X509_V_ERR_INVALID_CA:
    582 		case X509_V_ERR_PATH_LENGTH_EXCEEDED:
    583 		case X509_V_ERR_INVALID_PURPOSE:
    584 		case X509_V_ERR_UNABLE_TO_GET_CRL:
    585 			ok = 1;
    586 			log_tag = LLV_WARNING;
    587 			break;
    588 		default:
    589 			log_tag = LLV_ERROR;
    590 		}
    591 		plog(log_tag, LOCATION, NULL,
    592 			"%s(%d) at depth:%d SubjectName:%s\n",
    593 			X509_verify_cert_error_string(ctx->error),
    594 			ctx->error,
    595 			ctx->error_depth,
    596 			buf);
    597 	}
    598 	ERR_clear_error();
    599 
    600 	return ok;
    601 }
    602 
    603 /*
    604  * callback function for verifing remote certificates.
    605  * this function is derived from cb() in openssl/apps/s_server.c
    606  */
    607 static int
    608 cb_check_cert_remote(ok, ctx)
    609 	int ok;
    610 	X509_STORE_CTX *ctx;
    611 {
    612 	char buf[256];
    613 	int log_tag;
    614 
    615 	if (!ok) {
    616 		X509_NAME_oneline(
    617 				X509_get_subject_name(ctx->current_cert),
    618 				buf,
    619 				256);
    620 		switch (ctx->error) {
    621 		case X509_V_ERR_UNABLE_TO_GET_CRL:
    622 			ok = 1;
    623 			log_tag = LLV_WARNING;
    624 			break;
    625 		default:
    626 			log_tag = LLV_ERROR;
    627 		}
    628 		plog(log_tag, LOCATION, NULL,
    629 			"%s(%d) at depth:%d SubjectName:%s\n",
    630 			X509_verify_cert_error_string(ctx->error),
    631 			ctx->error,
    632 			ctx->error_depth,
    633 			buf);
    634 	}
    635 	ERR_clear_error();
    636 
    637 	return ok;
    638 }
    639 
    640 /*
    641  * get a subjectAltName from X509 certificate.
    642  */
    643 vchar_t *
    644 eay_get_x509asn1subjectname(cert)
    645 	vchar_t *cert;
    646 {
    647 	X509 *x509 = NULL;
    648 	u_char *bp;
    649 	vchar_t *name = NULL;
    650 	int len;
    651 
    652 	bp = (unsigned char *) cert->v;
    653 
    654 	x509 = mem2x509(cert);
    655 	if (x509 == NULL)
    656 		goto error;
    657 
    658 	/* get the length of the name */
    659 	len = i2d_X509_NAME(x509->cert_info->subject, NULL);
    660 	name = vmalloc(len);
    661 	if (!name)
    662 		goto error;
    663 	/* get the name */
    664 	bp = (unsigned char *) name->v;
    665 	len = i2d_X509_NAME(x509->cert_info->subject, &bp);
    666 
    667 	X509_free(x509);
    668 
    669 	return name;
    670 
    671 error:
    672 	plog(LLV_ERROR, LOCATION, NULL, "%s\n", eay_strerror());
    673 
    674 	if (name != NULL)
    675 		vfree(name);
    676 
    677 	if (x509 != NULL)
    678 		X509_free(x509);
    679 
    680 	return NULL;
    681 }
    682 
    683 /*
    684  * get the subjectAltName from X509 certificate.
    685  * the name must be terminated by '\0'.
    686  */
    687 int
    688 eay_get_x509subjectaltname(cert, altname, type, pos)
    689 	vchar_t *cert;
    690 	char **altname;
    691 	int *type;
    692 	int pos;
    693 {
    694 	X509 *x509 = NULL;
    695 	GENERAL_NAMES *gens = NULL;
    696 	GENERAL_NAME *gen;
    697 	int len;
    698 	int error = -1;
    699 
    700 	*altname = NULL;
    701 	*type = GENT_OTHERNAME;
    702 
    703 	x509 = mem2x509(cert);
    704 	if (x509 == NULL)
    705 		goto end;
    706 
    707 	gens = X509_get_ext_d2i(x509, NID_subject_alt_name, NULL, NULL);
    708 	if (gens == NULL)
    709 		goto end;
    710 
    711 	/* there is no data at "pos" */
    712 	if (pos > sk_GENERAL_NAME_num(gens))
    713 		goto end;
    714 
    715 	gen = sk_GENERAL_NAME_value(gens, pos - 1);
    716 
    717 	/* read DNSName / Email */
    718 	if (gen->type == GEN_DNS	||
    719 		gen->type == GEN_EMAIL	||
    720 		gen->type == GEN_URI )
    721 	{
    722 		/* make sure if the data is terminated by '\0'. */
    723 		if (gen->d.ia5->data[gen->d.ia5->length] != '\0')
    724 		{
    725 			plog(LLV_ERROR, LOCATION, NULL,
    726 				 "data is not terminated by NUL.");
    727 			racoon_hexdump(gen->d.ia5->data, gen->d.ia5->length + 1);
    728 			goto end;
    729 		}
    730 
    731 		len = gen->d.ia5->length + 1;
    732 		*altname = racoon_malloc(len);
    733 		if (!*altname)
    734 			goto end;
    735 
    736 		strlcpy(*altname, (char *) gen->d.ia5->data, len);
    737 		*type = gen->type;
    738 		error = 0;
    739 	}
    740 	/* read IP address */
    741 	else if (gen->type == GEN_IPADD)
    742 	{
    743 		unsigned char p[5], *ip;
    744 		ip = p;
    745 
    746 		/* only support IPv4 */
    747 		if (gen->d.ip->length != 4)
    748 			goto end;
    749 
    750 		/* convert Octet String to String
    751 		 * XXX ???????
    752 		 */
    753 		/*i2d_ASN1_OCTET_STRING(gen->d.ip,&ip);*/
    754 		ip = gen->d.ip->data;
    755 
    756 		/* XXX Magic, enough for an IPv4 address
    757 		 */
    758 		*altname = racoon_malloc(20);
    759 		if (!*altname)
    760 			goto end;
    761 
    762 		sprintf(*altname, "%u.%u.%u.%u", ip[0], ip[1], ip[2], ip[3]);
    763 		*type = gen->type;
    764 		error = 0;
    765 	}
    766 	/* XXX other possible types ?
    767 	 * For now, error will be -1 if unsupported type
    768 	 */
    769 
    770 end:
    771 	if (error) {
    772 		if (*altname) {
    773 			racoon_free(*altname);
    774 			*altname = NULL;
    775 		}
    776 		plog(LLV_ERROR, LOCATION, NULL, "%s\n", eay_strerror());
    777 	}
    778 	if (x509)
    779 		X509_free(x509);
    780 	if (gens)
    781 		/* free the whole stack. */
    782 		sk_GENERAL_NAME_pop_free(gens, GENERAL_NAME_free);
    783 
    784 	return error;
    785 }
    786 
    787 
    788 /*
    789  * decode a X509 certificate and make a readable text terminated '\n'.
    790  * return the buffer allocated, so must free it later.
    791  */
    792 char *
    793 eay_get_x509text(cert)
    794 	vchar_t *cert;
    795 {
    796 	X509 *x509 = NULL;
    797 	BIO *bio = NULL;
    798 	char *text = NULL;
    799 	u_char *bp = NULL;
    800 	int len = 0;
    801 	int error = -1;
    802 
    803 	x509 = mem2x509(cert);
    804 	if (x509 == NULL)
    805 		goto end;
    806 
    807 	bio = BIO_new(BIO_s_mem());
    808 	if (bio == NULL)
    809 		goto end;
    810 
    811 	error = X509_print(bio, x509);
    812 	if (error != 1) {
    813 		error = -1;
    814 		goto end;
    815 	}
    816 
    817 	len = BIO_get_mem_data(bio, &bp);
    818 	text = racoon_malloc(len + 1);
    819 	if (text == NULL)
    820 		goto end;
    821 	memcpy(text, bp, len);
    822 	text[len] = '\0';
    823 
    824 	error = 0;
    825 
    826     end:
    827 	if (error) {
    828 		if (text) {
    829 			racoon_free(text);
    830 			text = NULL;
    831 		}
    832 		plog(LLV_ERROR, LOCATION, NULL, "%s\n", eay_strerror());
    833 	}
    834 	if (bio)
    835 		BIO_free(bio);
    836 	if (x509)
    837 		X509_free(x509);
    838 
    839 	return text;
    840 }
    841 
    842 /* get X509 structure from buffer. */
    843 static X509 *
    844 mem2x509(cert)
    845 	vchar_t *cert;
    846 {
    847 	X509 *x509;
    848 
    849 #ifndef EAYDEBUG
    850     {
    851 	u_char *bp;
    852 
    853 	bp = (unsigned char *) cert->v;
    854 
    855 	x509 = d2i_X509(NULL, (void *)&bp, cert->l);
    856     }
    857 #else
    858     {
    859 	BIO *bio;
    860 	int len;
    861 
    862 	bio = BIO_new(BIO_s_mem());
    863 	if (bio == NULL)
    864 		return NULL;
    865 	len = BIO_write(bio, cert->v, cert->l);
    866 	if (len == -1)
    867 		return NULL;
    868 	x509 = PEM_read_bio_X509(bio, NULL, NULL, NULL);
    869 	BIO_free(bio);
    870     }
    871 #endif
    872 	return x509;
    873 }
    874 
    875 /*
    876  * get a X509 certificate from local file.
    877  * a certificate must be PEM format.
    878  * Input:
    879  *	path to a certificate.
    880  * Output:
    881  *	NULL if error occured
    882  *	other is the cert.
    883  */
    884 vchar_t *
    885 eay_get_x509cert(path)
    886 	char *path;
    887 {
    888 	FILE *fp;
    889 	X509 *x509;
    890 	vchar_t *cert;
    891 	u_char *bp;
    892 	int len;
    893 	int error;
    894 
    895 #ifdef ANDROID_CHANGES
    896 	BIO *bio = BIO_from_keystore(path);
    897 	x509 = NULL;
    898 	if (bio) {
    899 		x509 = PEM_read_bio_X509(bio, NULL, NULL, NULL);
    900 		BIO_free(bio);
    901 	}
    902 #else
    903 	/* Read private key */
    904 	fp = fopen(path, "r");
    905 	if (fp == NULL)
    906 		return NULL;
    907 	x509 = PEM_read_X509(fp, NULL, NULL, NULL);
    908 	fclose (fp);
    909 #endif
    910 
    911 	if (x509 == NULL)
    912 		return NULL;
    913 
    914 	len = i2d_X509(x509, NULL);
    915 	cert = vmalloc(len);
    916 	if (cert == NULL) {
    917 		X509_free(x509);
    918 		return NULL;
    919 	}
    920 	bp = (unsigned char *) cert->v;
    921 	error = i2d_X509(x509, &bp);
    922 	X509_free(x509);
    923 
    924 	if (error == 0) {
    925 		vfree(cert);
    926 		return NULL;
    927 	}
    928 
    929 	return cert;
    930 }
    931 
    932 /*
    933  * check a X509 signature
    934  *	XXX: to be get hash type from my cert ?
    935  *		to be handled EVP_dss().
    936  * OUT: return -1 when error.
    937  *	0
    938  */
    939 int
    940 eay_check_x509sign(source, sig, cert)
    941 	vchar_t *source;
    942 	vchar_t *sig;
    943 	vchar_t *cert;
    944 {
    945 	X509 *x509;
    946 	u_char *bp;
    947 	EVP_PKEY *evp;
    948 	int res;
    949 
    950 	bp = (unsigned char *) cert->v;
    951 
    952 	x509 = d2i_X509(NULL, (void *)&bp, cert->l);
    953 	if (x509 == NULL) {
    954 		plog(LLV_ERROR, LOCATION, NULL, "d2i_X509(): %s\n", eay_strerror());
    955 		return -1;
    956 	}
    957 
    958 	evp = X509_get_pubkey(x509);
    959 	if (! evp) {
    960 		plog(LLV_ERROR, LOCATION, NULL, "X509_get_pubkey(): %s\n", eay_strerror());
    961 		X509_free(x509);
    962 		return -1;
    963 	}
    964 
    965 	res = eay_rsa_verify(source, sig, evp->pkey.rsa);
    966 
    967 	EVP_PKEY_free(evp);
    968 	X509_free(x509);
    969 
    970 	return res;
    971 }
    972 
    973 /*
    974  * check RSA signature
    975  * OUT: return -1 when error.
    976  *	0 on success
    977  */
    978 int
    979 eay_check_rsasign(source, sig, rsa)
    980 	vchar_t *source;
    981 	vchar_t *sig;
    982 	RSA *rsa;
    983 {
    984 	return eay_rsa_verify(source, sig, rsa);
    985 }
    986 
    987 /*
    988  * get PKCS#1 Private Key of PEM format from local file.
    989  */
    990 vchar_t *
    991 eay_get_pkcs1privkey(path)
    992 	char *path;
    993 {
    994 	FILE *fp;
    995 	EVP_PKEY *evp = NULL;
    996 	vchar_t *pkey = NULL;
    997 	u_char *bp;
    998 	int pkeylen;
    999 	int error = -1;
   1000 
   1001 #ifdef ANDROID_CHANGES
   1002 	BIO *bio = BIO_from_keystore(path);
   1003 	if (bio) {
   1004 		evp = PEM_read_bio_PrivateKey(bio, NULL, NULL, NULL);
   1005 		BIO_free(bio);
   1006 	}
   1007 #else
   1008 	/* Read private key */
   1009 	fp = fopen(path, "r");
   1010 	if (fp == NULL)
   1011 		return NULL;
   1012 
   1013 	evp = PEM_read_PrivateKey(fp, NULL, NULL, NULL);
   1014 
   1015 	fclose (fp);
   1016 #endif
   1017 
   1018 	if (evp == NULL)
   1019 		return NULL;
   1020 
   1021 	pkeylen = i2d_PrivateKey(evp, NULL);
   1022 	if (pkeylen == 0)
   1023 		goto end;
   1024 	pkey = vmalloc(pkeylen);
   1025 	if (pkey == NULL)
   1026 		goto end;
   1027 	bp = (unsigned char *) pkey->v;
   1028 	pkeylen = i2d_PrivateKey(evp, &bp);
   1029 	if (pkeylen == 0)
   1030 		goto end;
   1031 
   1032 	error = 0;
   1033 
   1034 end:
   1035 	if (evp != NULL)
   1036 		EVP_PKEY_free(evp);
   1037 	if (error != 0 && pkey != NULL) {
   1038 		vfree(pkey);
   1039 		pkey = NULL;
   1040 	}
   1041 
   1042 	return pkey;
   1043 }
   1044 
   1045 /*
   1046  * get PKCS#1 Public Key of PEM format from local file.
   1047  */
   1048 vchar_t *
   1049 eay_get_pkcs1pubkey(path)
   1050 	char *path;
   1051 {
   1052 	FILE *fp;
   1053 	EVP_PKEY *evp = NULL;
   1054 	vchar_t *pkey = NULL;
   1055 	X509 *x509 = NULL;
   1056 	u_char *bp;
   1057 	int pkeylen;
   1058 	int error = -1;
   1059 
   1060 	/* Read private key */
   1061 	fp = fopen(path, "r");
   1062 	if (fp == NULL)
   1063 		return NULL;
   1064 
   1065 	x509 = PEM_read_X509(fp, NULL, NULL, NULL);
   1066 
   1067 	fclose (fp);
   1068 
   1069 	if (x509 == NULL)
   1070 		return NULL;
   1071 
   1072 	/* Get public key - eay */
   1073 	evp = X509_get_pubkey(x509);
   1074 	if (evp == NULL)
   1075 		return NULL;
   1076 
   1077 	pkeylen = i2d_PublicKey(evp, NULL);
   1078 	if (pkeylen == 0)
   1079 		goto end;
   1080 	pkey = vmalloc(pkeylen);
   1081 	if (pkey == NULL)
   1082 		goto end;
   1083 	bp = (unsigned char *) pkey->v;
   1084 	pkeylen = i2d_PublicKey(evp, &bp);
   1085 	if (pkeylen == 0)
   1086 		goto end;
   1087 
   1088 	error = 0;
   1089 end:
   1090 	if (evp != NULL)
   1091 		EVP_PKEY_free(evp);
   1092 	if (error != 0 && pkey != NULL) {
   1093 		vfree(pkey);
   1094 		pkey = NULL;
   1095 	}
   1096 
   1097 	return pkey;
   1098 }
   1099 
   1100 vchar_t *
   1101 eay_get_x509sign(src, privkey)
   1102 	vchar_t *src, *privkey;
   1103 {
   1104 	EVP_PKEY *evp;
   1105 	u_char *bp = (unsigned char *) privkey->v;
   1106 	vchar_t *sig = NULL;
   1107 	int len;
   1108 	int pad = RSA_PKCS1_PADDING;
   1109 
   1110 	/* XXX to be handled EVP_PKEY_DSA */
   1111 	evp = d2i_PrivateKey(EVP_PKEY_RSA, NULL, (void *)&bp, privkey->l);
   1112 	if (evp == NULL)
   1113 		return NULL;
   1114 
   1115 	sig = eay_rsa_sign(src, evp->pkey.rsa);
   1116 
   1117 	EVP_PKEY_free(evp);
   1118 
   1119 	return sig;
   1120 }
   1121 
   1122 vchar_t *
   1123 eay_get_rsasign(src, rsa)
   1124 	vchar_t *src;
   1125 	RSA *rsa;
   1126 {
   1127 	return eay_rsa_sign(src, rsa);
   1128 }
   1129 
   1130 vchar_t *
   1131 eay_rsa_sign(vchar_t *src, RSA *rsa)
   1132 {
   1133 	int len;
   1134 	vchar_t *sig = NULL;
   1135 	int pad = RSA_PKCS1_PADDING;
   1136 
   1137 	len = RSA_size(rsa);
   1138 
   1139 	sig = vmalloc(len);
   1140 	if (sig == NULL)
   1141 		return NULL;
   1142 
   1143 	len = RSA_private_encrypt(src->l, (unsigned char *) src->v,
   1144 			(unsigned char *) sig->v, rsa, pad);
   1145 
   1146 	if (len == 0 || len != sig->l) {
   1147 		vfree(sig);
   1148 		sig = NULL;
   1149 	}
   1150 
   1151 	return sig;
   1152 }
   1153 
   1154 int
   1155 eay_rsa_verify(src, sig, rsa)
   1156 	vchar_t *src, *sig;
   1157 	RSA *rsa;
   1158 {
   1159 	vchar_t *xbuf = NULL;
   1160 	int pad = RSA_PKCS1_PADDING;
   1161 	int len = 0;
   1162 	int error;
   1163 
   1164 	len = RSA_size(rsa);
   1165 	xbuf = vmalloc(len);
   1166 	if (xbuf == NULL) {
   1167 		plog(LLV_ERROR, LOCATION, NULL, "%s\n", eay_strerror());
   1168 		return -1;
   1169 	}
   1170 
   1171 	len = RSA_public_decrypt(sig->l, (unsigned char *) sig->v,
   1172 			(unsigned char *) xbuf->v, rsa, pad);
   1173 	if (len == 0 || len != src->l) {
   1174 		plog(LLV_ERROR, LOCATION, NULL, "%s\n", eay_strerror());
   1175 		vfree(xbuf);
   1176 		return -1;
   1177 	}
   1178 
   1179 	error = memcmp(src->v, xbuf->v, src->l);
   1180 	vfree(xbuf);
   1181 	if (error != 0)
   1182 		return -1;
   1183 
   1184 	return 0;
   1185 }
   1186 
   1187 /*
   1188  * get error string
   1189  * MUST load ERR_load_crypto_strings() first.
   1190  */
   1191 char *
   1192 eay_strerror()
   1193 {
   1194 	static char ebuf[512];
   1195 	int len = 0, n;
   1196 	unsigned long l;
   1197 	char buf[200];
   1198 	const char *file, *data;
   1199 	int line, flags;
   1200 	unsigned long es;
   1201 
   1202 	es = CRYPTO_thread_id();
   1203 
   1204 	while ((l = ERR_get_error_line_data(&file, &line, &data, &flags)) != 0){
   1205 		n = snprintf(ebuf + len, sizeof(ebuf) - len,
   1206 				"%lu:%s:%s:%d:%s ",
   1207 				es, ERR_error_string(l, buf), file, line,
   1208 				(flags & ERR_TXT_STRING) ? data : "");
   1209 		if (n < 0 || n >= sizeof(ebuf) - len)
   1210 			break;
   1211 		len += n;
   1212 		if (sizeof(ebuf) < len)
   1213 			break;
   1214 	}
   1215 
   1216 	return ebuf;
   1217 }
   1218 
   1219 vchar_t *
   1220 evp_crypt(vchar_t *data, vchar_t *key, vchar_t *iv, const EVP_CIPHER *e, int enc)
   1221 {
   1222 	vchar_t *res;
   1223 	EVP_CIPHER_CTX ctx;
   1224 
   1225 	if (!e)
   1226 		return NULL;
   1227 
   1228 	if (data->l % EVP_CIPHER_block_size(e))
   1229 		return NULL;
   1230 
   1231 	if ((res = vmalloc(data->l)) == NULL)
   1232 		return NULL;
   1233 
   1234 	EVP_CIPHER_CTX_init(&ctx);
   1235 
   1236 	switch(EVP_CIPHER_nid(e)){
   1237 	case NID_bf_cbc:
   1238 	case NID_bf_ecb:
   1239 	case NID_bf_cfb64:
   1240 	case NID_bf_ofb64:
   1241 	case NID_cast5_cbc:
   1242 	case NID_cast5_ecb:
   1243 	case NID_cast5_cfb64:
   1244 	case NID_cast5_ofb64:
   1245 		/* XXX: can we do that also for algos with a fixed key size ?
   1246 		 */
   1247 		/* init context without key/iv
   1248          */
   1249         if (!EVP_CipherInit(&ctx, e, NULL, NULL, enc))
   1250         {
   1251             OpenSSL_BUG();
   1252             vfree(res);
   1253             return NULL;
   1254         }
   1255 
   1256         /* update key size
   1257          */
   1258         if (!EVP_CIPHER_CTX_set_key_length(&ctx, key->l))
   1259         {
   1260             OpenSSL_BUG();
   1261             vfree(res);
   1262             return NULL;
   1263         }
   1264 
   1265         /* finalize context init with desired key size
   1266          */
   1267         if (!EVP_CipherInit(&ctx, NULL, (u_char *) key->v,
   1268 							(u_char *) iv->v, enc))
   1269         {
   1270             OpenSSL_BUG();
   1271             vfree(res);
   1272             return NULL;
   1273 		}
   1274 		break;
   1275 	default:
   1276 		if (!EVP_CipherInit(&ctx, e, (u_char *) key->v,
   1277 							(u_char *) iv->v, enc)) {
   1278 			OpenSSL_BUG();
   1279 			vfree(res);
   1280 			return NULL;
   1281 		}
   1282 	}
   1283 
   1284 	/* disable openssl padding */
   1285 	EVP_CIPHER_CTX_set_padding(&ctx, 0);
   1286 
   1287 	if (!EVP_Cipher(&ctx, (u_char *) res->v, (u_char *) data->v, data->l)) {
   1288 		OpenSSL_BUG();
   1289 		vfree(res);
   1290 		return NULL;
   1291 	}
   1292 
   1293 	EVP_CIPHER_CTX_cleanup(&ctx);
   1294 
   1295 	return res;
   1296 }
   1297 
   1298 int
   1299 evp_weakkey(vchar_t *key, const EVP_CIPHER *e)
   1300 {
   1301 	return 0;
   1302 }
   1303 
   1304 int
   1305 evp_keylen(int len, const EVP_CIPHER *e)
   1306 {
   1307 	if (!e)
   1308 		return -1;
   1309 	/* EVP functions return lengths in bytes, ipsec-tools
   1310 	 * uses lengths in bits, therefore conversion is required. --AK
   1311 	 */
   1312 	if (len != 0 && len != (EVP_CIPHER_key_length(e) << 3))
   1313 		return -1;
   1314 
   1315 	return EVP_CIPHER_key_length(e) << 3;
   1316 }
   1317 
   1318 /*
   1319  * DES-CBC
   1320  */
   1321 vchar_t *
   1322 eay_des_encrypt(data, key, iv)
   1323 	vchar_t *data, *key, *iv;
   1324 {
   1325 	return evp_crypt(data, key, iv, EVP_des_cbc(), 1);
   1326 }
   1327 
   1328 vchar_t *
   1329 eay_des_decrypt(data, key, iv)
   1330 	vchar_t *data, *key, *iv;
   1331 {
   1332 	return evp_crypt(data, key, iv, EVP_des_cbc(), 0);
   1333 }
   1334 
   1335 int
   1336 eay_des_weakkey(key)
   1337 	vchar_t *key;
   1338 {
   1339 #ifdef USE_NEW_DES_API
   1340 	return DES_is_weak_key((void *)key->v);
   1341 #else
   1342 	return des_is_weak_key((void *)key->v);
   1343 #endif
   1344 }
   1345 
   1346 int
   1347 eay_des_keylen(len)
   1348 	int len;
   1349 {
   1350 	return evp_keylen(len, EVP_des_cbc());
   1351 }
   1352 
   1353 #ifdef HAVE_OPENSSL_IDEA_H
   1354 /*
   1355  * IDEA-CBC
   1356  */
   1357 vchar_t *
   1358 eay_idea_encrypt(data, key, iv)
   1359 	vchar_t *data, *key, *iv;
   1360 {
   1361 	vchar_t *res;
   1362 	IDEA_KEY_SCHEDULE ks;
   1363 
   1364 	idea_set_encrypt_key((unsigned char *)key->v, &ks);
   1365 
   1366 	/* allocate buffer for result */
   1367 	if ((res = vmalloc(data->l)) == NULL)
   1368 		return NULL;
   1369 
   1370 	/* decryption data */
   1371 	idea_cbc_encrypt((unsigned char *)data->v, (unsigned char *)res->v, data->l,
   1372 			&ks, (unsigned char *)iv->v, IDEA_ENCRYPT);
   1373 
   1374 	return res;
   1375 }
   1376 
   1377 vchar_t *
   1378 eay_idea_decrypt(data, key, iv)
   1379 	vchar_t *data, *key, *iv;
   1380 {
   1381 	vchar_t *res;
   1382 	IDEA_KEY_SCHEDULE ks, dks;
   1383 
   1384 	idea_set_encrypt_key((unsigned char *)key->v, &ks);
   1385 	idea_set_decrypt_key(&ks, &dks);
   1386 
   1387 	/* allocate buffer for result */
   1388 	if ((res = vmalloc(data->l)) == NULL)
   1389 		return NULL;
   1390 
   1391 	/* decryption data */
   1392 	idea_cbc_encrypt((unsigned char *)data->v, (unsigned char *)res->v, data->l,
   1393 			&dks, (unsigned char *)iv->v, IDEA_DECRYPT);
   1394 
   1395 	return res;
   1396 }
   1397 
   1398 int
   1399 eay_idea_weakkey(key)
   1400 	vchar_t *key;
   1401 {
   1402 	return 0;       /* XXX */
   1403 }
   1404 
   1405 int
   1406 eay_idea_keylen(len)
   1407 	int len;
   1408 {
   1409 	if (len != 0 && len != 128)
   1410 		return -1;
   1411 	return 128;
   1412 }
   1413 #endif
   1414 
   1415 /*
   1416  * BLOWFISH-CBC
   1417  */
   1418 vchar_t *
   1419 eay_bf_encrypt(data, key, iv)
   1420 	vchar_t *data, *key, *iv;
   1421 {
   1422 	return evp_crypt(data, key, iv, EVP_bf_cbc(), 1);
   1423 }
   1424 
   1425 vchar_t *
   1426 eay_bf_decrypt(data, key, iv)
   1427 	vchar_t *data, *key, *iv;
   1428 {
   1429 	return evp_crypt(data, key, iv, EVP_bf_cbc(), 0);
   1430 }
   1431 
   1432 int
   1433 eay_bf_weakkey(key)
   1434 	vchar_t *key;
   1435 {
   1436 	return 0;	/* XXX to be done. refer to RFC 2451 */
   1437 }
   1438 
   1439 int
   1440 eay_bf_keylen(len)
   1441 	int len;
   1442 {
   1443 	if (len == 0)
   1444 		return 448;
   1445 	if (len < 40 || len > 448)
   1446 		return -1;
   1447 	return len;
   1448 }
   1449 
   1450 #ifdef HAVE_OPENSSL_RC5_H
   1451 /*
   1452  * RC5-CBC
   1453  */
   1454 vchar_t *
   1455 eay_rc5_encrypt(data, key, iv)
   1456 	vchar_t *data, *key, *iv;
   1457 {
   1458 	vchar_t *res;
   1459 	RC5_32_KEY ks;
   1460 
   1461 	/* in RFC 2451, there is information about the number of round. */
   1462 	RC5_32_set_key(&ks, key->l, (unsigned char *)key->v, 16);
   1463 
   1464 	/* allocate buffer for result */
   1465 	if ((res = vmalloc(data->l)) == NULL)
   1466 		return NULL;
   1467 
   1468 	/* decryption data */
   1469 	RC5_32_cbc_encrypt((unsigned char *)data->v, (unsigned char *)res->v, data->l,
   1470 		&ks, (unsigned char *)iv->v, RC5_ENCRYPT);
   1471 
   1472 	return res;
   1473 }
   1474 
   1475 vchar_t *
   1476 eay_rc5_decrypt(data, key, iv)
   1477 	vchar_t *data, *key, *iv;
   1478 {
   1479 	vchar_t *res;
   1480 	RC5_32_KEY ks;
   1481 
   1482 	/* in RFC 2451, there is information about the number of round. */
   1483 	RC5_32_set_key(&ks, key->l, (unsigned char *)key->v, 16);
   1484 
   1485 	/* allocate buffer for result */
   1486 	if ((res = vmalloc(data->l)) == NULL)
   1487 		return NULL;
   1488 
   1489 	/* decryption data */
   1490 	RC5_32_cbc_encrypt((unsigned char *)data->v, (unsigned char *)res->v, data->l,
   1491 		&ks, (unsigned char *)iv->v, RC5_DECRYPT);
   1492 
   1493 	return res;
   1494 }
   1495 
   1496 int
   1497 eay_rc5_weakkey(key)
   1498 	vchar_t *key;
   1499 {
   1500 	return 0;       /* No known weak keys when used with 16 rounds. */
   1501 
   1502 }
   1503 
   1504 int
   1505 eay_rc5_keylen(len)
   1506 	int len;
   1507 {
   1508 	if (len == 0)
   1509 		return 128;
   1510 	if (len < 40 || len > 2040)
   1511 		return -1;
   1512 	return len;
   1513 }
   1514 #endif
   1515 
   1516 /*
   1517  * 3DES-CBC
   1518  */
   1519 vchar_t *
   1520 eay_3des_encrypt(data, key, iv)
   1521 	vchar_t *data, *key, *iv;
   1522 {
   1523 	return evp_crypt(data, key, iv, EVP_des_ede3_cbc(), 1);
   1524 }
   1525 
   1526 vchar_t *
   1527 eay_3des_decrypt(data, key, iv)
   1528 	vchar_t *data, *key, *iv;
   1529 {
   1530 	return evp_crypt(data, key, iv, EVP_des_ede3_cbc(), 0);
   1531 }
   1532 
   1533 int
   1534 eay_3des_weakkey(key)
   1535 	vchar_t *key;
   1536 {
   1537 #ifdef USE_NEW_DES_API
   1538 	return (DES_is_weak_key((void *)key->v) ||
   1539 	    DES_is_weak_key((void *)(key->v + 8)) ||
   1540 	    DES_is_weak_key((void *)(key->v + 16)));
   1541 #else
   1542 	if (key->l < 24)
   1543 		return 0;
   1544 
   1545 	return (des_is_weak_key((void *)key->v) ||
   1546 	    des_is_weak_key((void *)(key->v + 8)) ||
   1547 	    des_is_weak_key((void *)(key->v + 16)));
   1548 #endif
   1549 }
   1550 
   1551 int
   1552 eay_3des_keylen(len)
   1553 	int len;
   1554 {
   1555 	if (len != 0 && len != 192)
   1556 		return -1;
   1557 	return 192;
   1558 }
   1559 
   1560 /*
   1561  * CAST-CBC
   1562  */
   1563 vchar_t *
   1564 eay_cast_encrypt(data, key, iv)
   1565 	vchar_t *data, *key, *iv;
   1566 {
   1567 	return evp_crypt(data, key, iv, EVP_cast5_cbc(), 1);
   1568 }
   1569 
   1570 vchar_t *
   1571 eay_cast_decrypt(data, key, iv)
   1572 	vchar_t *data, *key, *iv;
   1573 {
   1574 	return evp_crypt(data, key, iv, EVP_cast5_cbc(), 0);
   1575 }
   1576 
   1577 int
   1578 eay_cast_weakkey(key)
   1579 	vchar_t *key;
   1580 {
   1581 	return 0;	/* No known weak keys. */
   1582 }
   1583 
   1584 int
   1585 eay_cast_keylen(len)
   1586 	int len;
   1587 {
   1588 	if (len == 0)
   1589 		return 128;
   1590 	if (len < 40 || len > 128)
   1591 		return -1;
   1592 	return len;
   1593 }
   1594 
   1595 /*
   1596  * AES(RIJNDAEL)-CBC
   1597  */
   1598 #ifndef HAVE_OPENSSL_AES_H
   1599 vchar_t *
   1600 eay_aes_encrypt(data, key, iv)
   1601 	vchar_t *data, *key, *iv;
   1602 {
   1603 	vchar_t *res;
   1604 	keyInstance k;
   1605 	cipherInstance c;
   1606 
   1607 	memset(&k, 0, sizeof(k));
   1608 	if (rijndael_makeKey(&k, DIR_ENCRYPT, key->l << 3, key->v) < 0)
   1609 		return NULL;
   1610 
   1611 	/* allocate buffer for result */
   1612 	if ((res = vmalloc(data->l)) == NULL)
   1613 		return NULL;
   1614 
   1615 	/* encryption data */
   1616 	memset(&c, 0, sizeof(c));
   1617 	if (rijndael_cipherInit(&c, MODE_CBC, iv->v) < 0){
   1618 		vfree(res);
   1619 		return NULL;
   1620 	}
   1621 	if (rijndael_blockEncrypt(&c, &k, data->v, data->l << 3, res->v) < 0){
   1622 		vfree(res);
   1623 		return NULL;
   1624 	}
   1625 
   1626 	return res;
   1627 }
   1628 
   1629 vchar_t *
   1630 eay_aes_decrypt(data, key, iv)
   1631 	vchar_t *data, *key, *iv;
   1632 {
   1633 	vchar_t *res;
   1634 	keyInstance k;
   1635 	cipherInstance c;
   1636 
   1637 	memset(&k, 0, sizeof(k));
   1638 	if (rijndael_makeKey(&k, DIR_DECRYPT, key->l << 3, key->v) < 0)
   1639 		return NULL;
   1640 
   1641 	/* allocate buffer for result */
   1642 	if ((res = vmalloc(data->l)) == NULL)
   1643 		return NULL;
   1644 
   1645 	/* decryption data */
   1646 	memset(&c, 0, sizeof(c));
   1647 	if (rijndael_cipherInit(&c, MODE_CBC, iv->v) < 0){
   1648 		vfree(res);
   1649 		return NULL;
   1650 	}
   1651 	if (rijndael_blockDecrypt(&c, &k, data->v, data->l << 3, res->v) < 0){
   1652 		vfree(res);
   1653 		return NULL;
   1654 	}
   1655 
   1656 	return res;
   1657 }
   1658 #else
   1659 static inline const EVP_CIPHER *
   1660 aes_evp_by_keylen(int keylen)
   1661 {
   1662 	switch(keylen) {
   1663 		case 16:
   1664 		case 128:
   1665 			return EVP_aes_128_cbc();
   1666 		case 24:
   1667 		case 192:
   1668 			return EVP_aes_192_cbc();
   1669 		case 32:
   1670 		case 256:
   1671 			return EVP_aes_256_cbc();
   1672 		default:
   1673 			return NULL;
   1674 	}
   1675 }
   1676 
   1677 vchar_t *
   1678 eay_aes_encrypt(data, key, iv)
   1679        vchar_t *data, *key, *iv;
   1680 {
   1681 	return evp_crypt(data, key, iv, aes_evp_by_keylen(key->l), 1);
   1682 }
   1683 
   1684 vchar_t *
   1685 eay_aes_decrypt(data, key, iv)
   1686        vchar_t *data, *key, *iv;
   1687 {
   1688 	return evp_crypt(data, key, iv, aes_evp_by_keylen(key->l), 0);
   1689 }
   1690 #endif
   1691 
   1692 int
   1693 eay_aes_weakkey(key)
   1694 	vchar_t *key;
   1695 {
   1696 	return 0;
   1697 }
   1698 
   1699 int
   1700 eay_aes_keylen(len)
   1701 	int len;
   1702 {
   1703 	if (len == 0)
   1704 		return 128;
   1705 	if (len != 128 && len != 192 && len != 256)
   1706 		return -1;
   1707 	return len;
   1708 }
   1709 
   1710 #if defined(HAVE_OPENSSL_CAMELLIA_H)
   1711 /*
   1712  * CAMELLIA-CBC
   1713  */
   1714 static inline const EVP_CIPHER *
   1715 camellia_evp_by_keylen(int keylen)
   1716 {
   1717 	switch(keylen) {
   1718 		case 16:
   1719 		case 128:
   1720 			return EVP_camellia_128_cbc();
   1721 		case 24:
   1722 		case 192:
   1723 			return EVP_camellia_192_cbc();
   1724 		case 32:
   1725 		case 256:
   1726 			return EVP_camellia_256_cbc();
   1727 		default:
   1728 			return NULL;
   1729 	}
   1730 }
   1731 
   1732 vchar_t *
   1733 eay_camellia_encrypt(data, key, iv)
   1734        vchar_t *data, *key, *iv;
   1735 {
   1736 	return evp_crypt(data, key, iv, camellia_evp_by_keylen(key->l), 1);
   1737 }
   1738 
   1739 vchar_t *
   1740 eay_camellia_decrypt(data, key, iv)
   1741        vchar_t *data, *key, *iv;
   1742 {
   1743 	return evp_crypt(data, key, iv, camellia_evp_by_keylen(key->l), 0);
   1744 }
   1745 
   1746 int
   1747 eay_camellia_weakkey(key)
   1748 	vchar_t *key;
   1749 {
   1750 	return 0;
   1751 }
   1752 
   1753 int
   1754 eay_camellia_keylen(len)
   1755 	int len;
   1756 {
   1757 	if (len == 0)
   1758 		return 128;
   1759 	if (len != 128 && len != 192 && len != 256)
   1760 		return -1;
   1761 	return len;
   1762 }
   1763 
   1764 #endif
   1765 
   1766 /* for ipsec part */
   1767 int
   1768 eay_null_hashlen()
   1769 {
   1770 	return 0;
   1771 }
   1772 
   1773 int
   1774 eay_kpdk_hashlen()
   1775 {
   1776 	return 0;
   1777 }
   1778 
   1779 int
   1780 eay_twofish_keylen(len)
   1781 	int len;
   1782 {
   1783 	if (len < 0 || len > 256)
   1784 		return -1;
   1785 	return len;
   1786 }
   1787 
   1788 int
   1789 eay_null_keylen(len)
   1790 	int len;
   1791 {
   1792 	return 0;
   1793 }
   1794 
   1795 /*
   1796  * HMAC functions
   1797  */
   1798 static caddr_t
   1799 eay_hmac_init(key, md)
   1800 	vchar_t *key;
   1801 	const EVP_MD *md;
   1802 {
   1803 	HMAC_CTX *c = racoon_malloc(sizeof(*c));
   1804 
   1805 	HMAC_Init(c, key->v, key->l, md);
   1806 
   1807 	return (caddr_t)c;
   1808 }
   1809 
   1810 #ifdef WITH_SHA2
   1811 /*
   1812  * HMAC SHA2-512
   1813  */
   1814 vchar_t *
   1815 eay_hmacsha2_512_one(key, data)
   1816 	vchar_t *key, *data;
   1817 {
   1818 	vchar_t *res;
   1819 	caddr_t ctx;
   1820 
   1821 	ctx = eay_hmacsha2_512_init(key);
   1822 	eay_hmacsha2_512_update(ctx, data);
   1823 	res = eay_hmacsha2_512_final(ctx);
   1824 
   1825 	return(res);
   1826 }
   1827 
   1828 caddr_t
   1829 eay_hmacsha2_512_init(key)
   1830 	vchar_t *key;
   1831 {
   1832 	return eay_hmac_init(key, EVP_sha2_512());
   1833 }
   1834 
   1835 void
   1836 eay_hmacsha2_512_update(c, data)
   1837 	caddr_t c;
   1838 	vchar_t *data;
   1839 {
   1840 	HMAC_Update((HMAC_CTX *)c, (unsigned char *) data->v, data->l);
   1841 }
   1842 
   1843 vchar_t *
   1844 eay_hmacsha2_512_final(c)
   1845 	caddr_t c;
   1846 {
   1847 	vchar_t *res;
   1848 	unsigned int l;
   1849 
   1850 	if ((res = vmalloc(SHA512_DIGEST_LENGTH)) == 0)
   1851 		return NULL;
   1852 
   1853 	HMAC_Final((HMAC_CTX *)c, (unsigned char *) res->v, &l);
   1854 	res->l = l;
   1855 	HMAC_cleanup((HMAC_CTX *)c);
   1856 	(void)racoon_free(c);
   1857 
   1858 	if (SHA512_DIGEST_LENGTH != res->l) {
   1859 		plog(LLV_ERROR, LOCATION, NULL,
   1860 			"hmac sha2_512 length mismatch %zd.\n", res->l);
   1861 		vfree(res);
   1862 		return NULL;
   1863 	}
   1864 
   1865 	return(res);
   1866 }
   1867 
   1868 /*
   1869  * HMAC SHA2-384
   1870  */
   1871 vchar_t *
   1872 eay_hmacsha2_384_one(key, data)
   1873 	vchar_t *key, *data;
   1874 {
   1875 	vchar_t *res;
   1876 	caddr_t ctx;
   1877 
   1878 	ctx = eay_hmacsha2_384_init(key);
   1879 	eay_hmacsha2_384_update(ctx, data);
   1880 	res = eay_hmacsha2_384_final(ctx);
   1881 
   1882 	return(res);
   1883 }
   1884 
   1885 caddr_t
   1886 eay_hmacsha2_384_init(key)
   1887 	vchar_t *key;
   1888 {
   1889 	return eay_hmac_init(key, EVP_sha2_384());
   1890 }
   1891 
   1892 void
   1893 eay_hmacsha2_384_update(c, data)
   1894 	caddr_t c;
   1895 	vchar_t *data;
   1896 {
   1897 	HMAC_Update((HMAC_CTX *)c, (unsigned char *) data->v, data->l);
   1898 }
   1899 
   1900 vchar_t *
   1901 eay_hmacsha2_384_final(c)
   1902 	caddr_t c;
   1903 {
   1904 	vchar_t *res;
   1905 	unsigned int l;
   1906 
   1907 	if ((res = vmalloc(SHA384_DIGEST_LENGTH)) == 0)
   1908 		return NULL;
   1909 
   1910 	HMAC_Final((HMAC_CTX *)c, (unsigned char *) res->v, &l);
   1911 	res->l = l;
   1912 	HMAC_cleanup((HMAC_CTX *)c);
   1913 	(void)racoon_free(c);
   1914 
   1915 	if (SHA384_DIGEST_LENGTH != res->l) {
   1916 		plog(LLV_ERROR, LOCATION, NULL,
   1917 			"hmac sha2_384 length mismatch %zd.\n", res->l);
   1918 		vfree(res);
   1919 		return NULL;
   1920 	}
   1921 
   1922 	return(res);
   1923 }
   1924 
   1925 /*
   1926  * HMAC SHA2-256
   1927  */
   1928 vchar_t *
   1929 eay_hmacsha2_256_one(key, data)
   1930 	vchar_t *key, *data;
   1931 {
   1932 	vchar_t *res;
   1933 	caddr_t ctx;
   1934 
   1935 	ctx = eay_hmacsha2_256_init(key);
   1936 	eay_hmacsha2_256_update(ctx, data);
   1937 	res = eay_hmacsha2_256_final(ctx);
   1938 
   1939 	return(res);
   1940 }
   1941 
   1942 caddr_t
   1943 eay_hmacsha2_256_init(key)
   1944 	vchar_t *key;
   1945 {
   1946 	return eay_hmac_init(key, EVP_sha2_256());
   1947 }
   1948 
   1949 void
   1950 eay_hmacsha2_256_update(c, data)
   1951 	caddr_t c;
   1952 	vchar_t *data;
   1953 {
   1954 	HMAC_Update((HMAC_CTX *)c, (unsigned char *) data->v, data->l);
   1955 }
   1956 
   1957 vchar_t *
   1958 eay_hmacsha2_256_final(c)
   1959 	caddr_t c;
   1960 {
   1961 	vchar_t *res;
   1962 	unsigned int l;
   1963 
   1964 	if ((res = vmalloc(SHA256_DIGEST_LENGTH)) == 0)
   1965 		return NULL;
   1966 
   1967 	HMAC_Final((HMAC_CTX *)c, (unsigned char *) res->v, &l);
   1968 	res->l = l;
   1969 	HMAC_cleanup((HMAC_CTX *)c);
   1970 	(void)racoon_free(c);
   1971 
   1972 	if (SHA256_DIGEST_LENGTH != res->l) {
   1973 		plog(LLV_ERROR, LOCATION, NULL,
   1974 			"hmac sha2_256 length mismatch %zd.\n", res->l);
   1975 		vfree(res);
   1976 		return NULL;
   1977 	}
   1978 
   1979 	return(res);
   1980 }
   1981 #endif	/* WITH_SHA2 */
   1982 
   1983 /*
   1984  * HMAC SHA1
   1985  */
   1986 vchar_t *
   1987 eay_hmacsha1_one(key, data)
   1988 	vchar_t *key, *data;
   1989 {
   1990 	vchar_t *res;
   1991 	caddr_t ctx;
   1992 
   1993 	ctx = eay_hmacsha1_init(key);
   1994 	eay_hmacsha1_update(ctx, data);
   1995 	res = eay_hmacsha1_final(ctx);
   1996 
   1997 	return(res);
   1998 }
   1999 
   2000 caddr_t
   2001 eay_hmacsha1_init(key)
   2002 	vchar_t *key;
   2003 {
   2004 	return eay_hmac_init(key, EVP_sha1());
   2005 }
   2006 
   2007 void
   2008 eay_hmacsha1_update(c, data)
   2009 	caddr_t c;
   2010 	vchar_t *data;
   2011 {
   2012 	HMAC_Update((HMAC_CTX *)c, (unsigned char *) data->v, data->l);
   2013 }
   2014 
   2015 vchar_t *
   2016 eay_hmacsha1_final(c)
   2017 	caddr_t c;
   2018 {
   2019 	vchar_t *res;
   2020 	unsigned int l;
   2021 
   2022 	if ((res = vmalloc(SHA_DIGEST_LENGTH)) == 0)
   2023 		return NULL;
   2024 
   2025 	HMAC_Final((HMAC_CTX *)c, (unsigned char *) res->v, &l);
   2026 	res->l = l;
   2027 	HMAC_cleanup((HMAC_CTX *)c);
   2028 	(void)racoon_free(c);
   2029 
   2030 	if (SHA_DIGEST_LENGTH != res->l) {
   2031 		plog(LLV_ERROR, LOCATION, NULL,
   2032 			"hmac sha1 length mismatch %zd.\n", res->l);
   2033 		vfree(res);
   2034 		return NULL;
   2035 	}
   2036 
   2037 	return(res);
   2038 }
   2039 
   2040 /*
   2041  * HMAC MD5
   2042  */
   2043 vchar_t *
   2044 eay_hmacmd5_one(key, data)
   2045 	vchar_t *key, *data;
   2046 {
   2047 	vchar_t *res;
   2048 	caddr_t ctx;
   2049 
   2050 	ctx = eay_hmacmd5_init(key);
   2051 	eay_hmacmd5_update(ctx, data);
   2052 	res = eay_hmacmd5_final(ctx);
   2053 
   2054 	return(res);
   2055 }
   2056 
   2057 caddr_t
   2058 eay_hmacmd5_init(key)
   2059 	vchar_t *key;
   2060 {
   2061 	return eay_hmac_init(key, EVP_md5());
   2062 }
   2063 
   2064 void
   2065 eay_hmacmd5_update(c, data)
   2066 	caddr_t c;
   2067 	vchar_t *data;
   2068 {
   2069 	HMAC_Update((HMAC_CTX *)c, (unsigned char *) data->v, data->l);
   2070 }
   2071 
   2072 vchar_t *
   2073 eay_hmacmd5_final(c)
   2074 	caddr_t c;
   2075 {
   2076 	vchar_t *res;
   2077 	unsigned int l;
   2078 
   2079 	if ((res = vmalloc(MD5_DIGEST_LENGTH)) == 0)
   2080 		return NULL;
   2081 
   2082 	HMAC_Final((HMAC_CTX *)c, (unsigned char *) res->v, &l);
   2083 	res->l = l;
   2084 	HMAC_cleanup((HMAC_CTX *)c);
   2085 	(void)racoon_free(c);
   2086 
   2087 	if (MD5_DIGEST_LENGTH != res->l) {
   2088 		plog(LLV_ERROR, LOCATION, NULL,
   2089 			"hmac md5 length mismatch %zd.\n", res->l);
   2090 		vfree(res);
   2091 		return NULL;
   2092 	}
   2093 
   2094 	return(res);
   2095 }
   2096 
   2097 #ifdef WITH_SHA2
   2098 /*
   2099  * SHA2-512 functions
   2100  */
   2101 caddr_t
   2102 eay_sha2_512_init()
   2103 {
   2104 	SHA512_CTX *c = racoon_malloc(sizeof(*c));
   2105 
   2106 	SHA512_Init(c);
   2107 
   2108 	return((caddr_t)c);
   2109 }
   2110 
   2111 void
   2112 eay_sha2_512_update(c, data)
   2113 	caddr_t c;
   2114 	vchar_t *data;
   2115 {
   2116 	SHA512_Update((SHA512_CTX *)c, (unsigned char *) data->v, data->l);
   2117 
   2118 	return;
   2119 }
   2120 
   2121 vchar_t *
   2122 eay_sha2_512_final(c)
   2123 	caddr_t c;
   2124 {
   2125 	vchar_t *res;
   2126 
   2127 	if ((res = vmalloc(SHA512_DIGEST_LENGTH)) == 0)
   2128 		return(0);
   2129 
   2130 	SHA512_Final((unsigned char *) res->v, (SHA512_CTX *)c);
   2131 	(void)racoon_free(c);
   2132 
   2133 	return(res);
   2134 }
   2135 
   2136 vchar_t *
   2137 eay_sha2_512_one(data)
   2138 	vchar_t *data;
   2139 {
   2140 	caddr_t ctx;
   2141 	vchar_t *res;
   2142 
   2143 	ctx = eay_sha2_512_init();
   2144 	eay_sha2_512_update(ctx, data);
   2145 	res = eay_sha2_512_final(ctx);
   2146 
   2147 	return(res);
   2148 }
   2149 
   2150 int
   2151 eay_sha2_512_hashlen()
   2152 {
   2153 	return SHA512_DIGEST_LENGTH << 3;
   2154 }
   2155 #endif
   2156 
   2157 #ifdef WITH_SHA2
   2158 /*
   2159  * SHA2-384 functions
   2160  */
   2161 caddr_t
   2162 eay_sha2_384_init()
   2163 {
   2164 	SHA384_CTX *c = racoon_malloc(sizeof(*c));
   2165 
   2166 	SHA384_Init(c);
   2167 
   2168 	return((caddr_t)c);
   2169 }
   2170 
   2171 void
   2172 eay_sha2_384_update(c, data)
   2173 	caddr_t c;
   2174 	vchar_t *data;
   2175 {
   2176 	SHA384_Update((SHA384_CTX *)c, (unsigned char *) data->v, data->l);
   2177 
   2178 	return;
   2179 }
   2180 
   2181 vchar_t *
   2182 eay_sha2_384_final(c)
   2183 	caddr_t c;
   2184 {
   2185 	vchar_t *res;
   2186 
   2187 	if ((res = vmalloc(SHA384_DIGEST_LENGTH)) == 0)
   2188 		return(0);
   2189 
   2190 	SHA384_Final((unsigned char *) res->v, (SHA384_CTX *)c);
   2191 	(void)racoon_free(c);
   2192 
   2193 	return(res);
   2194 }
   2195 
   2196 vchar_t *
   2197 eay_sha2_384_one(data)
   2198 	vchar_t *data;
   2199 {
   2200 	caddr_t ctx;
   2201 	vchar_t *res;
   2202 
   2203 	ctx = eay_sha2_384_init();
   2204 	eay_sha2_384_update(ctx, data);
   2205 	res = eay_sha2_384_final(ctx);
   2206 
   2207 	return(res);
   2208 }
   2209 
   2210 int
   2211 eay_sha2_384_hashlen()
   2212 {
   2213 	return SHA384_DIGEST_LENGTH << 3;
   2214 }
   2215 #endif
   2216 
   2217 #ifdef WITH_SHA2
   2218 /*
   2219  * SHA2-256 functions
   2220  */
   2221 caddr_t
   2222 eay_sha2_256_init()
   2223 {
   2224 	SHA256_CTX *c = racoon_malloc(sizeof(*c));
   2225 
   2226 	SHA256_Init(c);
   2227 
   2228 	return((caddr_t)c);
   2229 }
   2230 
   2231 void
   2232 eay_sha2_256_update(c, data)
   2233 	caddr_t c;
   2234 	vchar_t *data;
   2235 {
   2236 	SHA256_Update((SHA256_CTX *)c, (unsigned char *) data->v, data->l);
   2237 
   2238 	return;
   2239 }
   2240 
   2241 vchar_t *
   2242 eay_sha2_256_final(c)
   2243 	caddr_t c;
   2244 {
   2245 	vchar_t *res;
   2246 
   2247 	if ((res = vmalloc(SHA256_DIGEST_LENGTH)) == 0)
   2248 		return(0);
   2249 
   2250 	SHA256_Final((unsigned char *) res->v, (SHA256_CTX *)c);
   2251 	(void)racoon_free(c);
   2252 
   2253 	return(res);
   2254 }
   2255 
   2256 vchar_t *
   2257 eay_sha2_256_one(data)
   2258 	vchar_t *data;
   2259 {
   2260 	caddr_t ctx;
   2261 	vchar_t *res;
   2262 
   2263 	ctx = eay_sha2_256_init();
   2264 	eay_sha2_256_update(ctx, data);
   2265 	res = eay_sha2_256_final(ctx);
   2266 
   2267 	return(res);
   2268 }
   2269 
   2270 int
   2271 eay_sha2_256_hashlen()
   2272 {
   2273 	return SHA256_DIGEST_LENGTH << 3;
   2274 }
   2275 #endif
   2276 
   2277 /*
   2278  * SHA functions
   2279  */
   2280 caddr_t
   2281 eay_sha1_init()
   2282 {
   2283 	SHA_CTX *c = racoon_malloc(sizeof(*c));
   2284 
   2285 	SHA1_Init(c);
   2286 
   2287 	return((caddr_t)c);
   2288 }
   2289 
   2290 void
   2291 eay_sha1_update(c, data)
   2292 	caddr_t c;
   2293 	vchar_t *data;
   2294 {
   2295 	SHA1_Update((SHA_CTX *)c, data->v, data->l);
   2296 
   2297 	return;
   2298 }
   2299 
   2300 vchar_t *
   2301 eay_sha1_final(c)
   2302 	caddr_t c;
   2303 {
   2304 	vchar_t *res;
   2305 
   2306 	if ((res = vmalloc(SHA_DIGEST_LENGTH)) == 0)
   2307 		return(0);
   2308 
   2309 	SHA1_Final((unsigned char *) res->v, (SHA_CTX *)c);
   2310 	(void)racoon_free(c);
   2311 
   2312 	return(res);
   2313 }
   2314 
   2315 vchar_t *
   2316 eay_sha1_one(data)
   2317 	vchar_t *data;
   2318 {
   2319 	caddr_t ctx;
   2320 	vchar_t *res;
   2321 
   2322 	ctx = eay_sha1_init();
   2323 	eay_sha1_update(ctx, data);
   2324 	res = eay_sha1_final(ctx);
   2325 
   2326 	return(res);
   2327 }
   2328 
   2329 int
   2330 eay_sha1_hashlen()
   2331 {
   2332 	return SHA_DIGEST_LENGTH << 3;
   2333 }
   2334 
   2335 /*
   2336  * MD5 functions
   2337  */
   2338 caddr_t
   2339 eay_md5_init()
   2340 {
   2341 	MD5_CTX *c = racoon_malloc(sizeof(*c));
   2342 
   2343 	MD5_Init(c);
   2344 
   2345 	return((caddr_t)c);
   2346 }
   2347 
   2348 void
   2349 eay_md5_update(c, data)
   2350 	caddr_t c;
   2351 	vchar_t *data;
   2352 {
   2353 	MD5_Update((MD5_CTX *)c, data->v, data->l);
   2354 
   2355 	return;
   2356 }
   2357 
   2358 vchar_t *
   2359 eay_md5_final(c)
   2360 	caddr_t c;
   2361 {
   2362 	vchar_t *res;
   2363 
   2364 	if ((res = vmalloc(MD5_DIGEST_LENGTH)) == 0)
   2365 		return(0);
   2366 
   2367 	MD5_Final((unsigned char *) res->v, (MD5_CTX *)c);
   2368 	(void)racoon_free(c);
   2369 
   2370 	return(res);
   2371 }
   2372 
   2373 vchar_t *
   2374 eay_md5_one(data)
   2375 	vchar_t *data;
   2376 {
   2377 	caddr_t ctx;
   2378 	vchar_t *res;
   2379 
   2380 	ctx = eay_md5_init();
   2381 	eay_md5_update(ctx, data);
   2382 	res = eay_md5_final(ctx);
   2383 
   2384 	return(res);
   2385 }
   2386 
   2387 int
   2388 eay_md5_hashlen()
   2389 {
   2390 	return MD5_DIGEST_LENGTH << 3;
   2391 }
   2392 
   2393 /*
   2394  * eay_set_random
   2395  *   size: number of bytes.
   2396  */
   2397 vchar_t *
   2398 eay_set_random(size)
   2399 	u_int32_t size;
   2400 {
   2401 	BIGNUM *r = NULL;
   2402 	vchar_t *res = 0;
   2403 
   2404 	if ((r = BN_new()) == NULL)
   2405 		goto end;
   2406 	BN_rand(r, size * 8, 0, 0);
   2407 	eay_bn2v(&res, r);
   2408 
   2409 end:
   2410 	if (r)
   2411 		BN_free(r);
   2412 	return(res);
   2413 }
   2414 
   2415 /* DH */
   2416 int
   2417 eay_dh_generate(prime, g, publen, pub, priv)
   2418 	vchar_t *prime, **pub, **priv;
   2419 	u_int publen;
   2420 	u_int32_t g;
   2421 {
   2422 	BIGNUM *p = NULL;
   2423 	DH *dh = NULL;
   2424 	int error = -1;
   2425 
   2426 	/* initialize */
   2427 	/* pre-process to generate number */
   2428 	if (eay_v2bn(&p, prime) < 0)
   2429 		goto end;
   2430 
   2431 	if ((dh = DH_new()) == NULL)
   2432 		goto end;
   2433 	dh->p = p;
   2434 	p = NULL;	/* p is now part of dh structure */
   2435 	dh->g = NULL;
   2436 	if ((dh->g = BN_new()) == NULL)
   2437 		goto end;
   2438 	if (!BN_set_word(dh->g, g))
   2439 		goto end;
   2440 
   2441 	if (publen != 0)
   2442 		dh->length = publen;
   2443 
   2444 	/* generate public and private number */
   2445 	if (!DH_generate_key(dh))
   2446 		goto end;
   2447 
   2448 	/* copy results to buffers */
   2449 	if (eay_bn2v(pub, dh->pub_key) < 0)
   2450 		goto end;
   2451 	if (eay_bn2v(priv, dh->priv_key) < 0) {
   2452 		vfree(*pub);
   2453 		goto end;
   2454 	}
   2455 
   2456 	error = 0;
   2457 
   2458 end:
   2459 	if (dh != NULL)
   2460 		DH_free(dh);
   2461 	if (p != 0)
   2462 		BN_free(p);
   2463 	return(error);
   2464 }
   2465 
   2466 int
   2467 eay_dh_compute(prime, g, pub, priv, pub2, key)
   2468 	vchar_t *prime, *pub, *priv, *pub2, **key;
   2469 	u_int32_t g;
   2470 {
   2471 	BIGNUM *dh_pub = NULL;
   2472 	DH *dh = NULL;
   2473 	int l;
   2474 	unsigned char *v = NULL;
   2475 	int error = -1;
   2476 
   2477 	/* make public number to compute */
   2478 	if (eay_v2bn(&dh_pub, pub2) < 0)
   2479 		goto end;
   2480 
   2481 	/* make DH structure */
   2482 	if ((dh = DH_new()) == NULL)
   2483 		goto end;
   2484 	if (eay_v2bn(&dh->p, prime) < 0)
   2485 		goto end;
   2486 	if (eay_v2bn(&dh->pub_key, pub) < 0)
   2487 		goto end;
   2488 	if (eay_v2bn(&dh->priv_key, priv) < 0)
   2489 		goto end;
   2490 	dh->length = pub2->l * 8;
   2491 
   2492 	dh->g = NULL;
   2493 	if ((dh->g = BN_new()) == NULL)
   2494 		goto end;
   2495 	if (!BN_set_word(dh->g, g))
   2496 		goto end;
   2497 
   2498 	if ((v = racoon_calloc(prime->l, sizeof(u_char))) == NULL)
   2499 		goto end;
   2500 	if ((l = DH_compute_key(v, dh_pub, dh)) == -1)
   2501 		goto end;
   2502 	memcpy((*key)->v + (prime->l - l), v, l);
   2503 
   2504 	error = 0;
   2505 
   2506 end:
   2507 	if (dh_pub != NULL)
   2508 		BN_free(dh_pub);
   2509 	if (dh != NULL)
   2510 		DH_free(dh);
   2511 	if (v != NULL)
   2512 		racoon_free(v);
   2513 	return(error);
   2514 }
   2515 
   2516 /*
   2517  * convert vchar_t <-> BIGNUM.
   2518  *
   2519  * vchar_t: unit is u_char, network endian, most significant byte first.
   2520  * BIGNUM: unit is BN_ULONG, each of BN_ULONG is in host endian,
   2521  *	least significant BN_ULONG must come first.
   2522  *
   2523  * hex value of "0x3ffe050104" is represented as follows:
   2524  *	vchar_t: 3f fe 05 01 04
   2525  *	BIGNUM (BN_ULONG = u_int8_t): 04 01 05 fe 3f
   2526  *	BIGNUM (BN_ULONG = u_int16_t): 0x0104 0xfe05 0x003f
   2527  *	BIGNUM (BN_ULONG = u_int32_t_t): 0xfe050104 0x0000003f
   2528  */
   2529 int
   2530 eay_v2bn(bn, var)
   2531 	BIGNUM **bn;
   2532 	vchar_t *var;
   2533 {
   2534 	if ((*bn = BN_bin2bn((unsigned char *) var->v, var->l, NULL)) == NULL)
   2535 		return -1;
   2536 
   2537 	return 0;
   2538 }
   2539 
   2540 int
   2541 eay_bn2v(var, bn)
   2542 	vchar_t **var;
   2543 	BIGNUM *bn;
   2544 {
   2545 	*var = vmalloc(bn->top * BN_BYTES);
   2546 	if (*var == NULL)
   2547 		return(-1);
   2548 
   2549 	(*var)->l = BN_bn2bin(bn, (unsigned char *) (*var)->v);
   2550 
   2551 	return 0;
   2552 }
   2553 
   2554 void
   2555 eay_init()
   2556 {
   2557 	OpenSSL_add_all_algorithms();
   2558 	ERR_load_crypto_strings();
   2559 #ifdef HAVE_OPENSSL_ENGINE_H
   2560 	ENGINE_load_builtin_engines();
   2561 	ENGINE_register_all_complete();
   2562 #endif
   2563 }
   2564 
   2565 vchar_t *
   2566 base64_decode(char *in, long inlen)
   2567 {
   2568 	BIO *bio=NULL, *b64=NULL;
   2569 	vchar_t *res = NULL;
   2570 	char *outb;
   2571 	long outlen;
   2572 
   2573 	outb = malloc(inlen * 2);
   2574 	if (outb == NULL)
   2575 		goto out;
   2576 	bio = BIO_new_mem_buf(in, inlen);
   2577 	b64 = BIO_new(BIO_f_base64());
   2578 	BIO_set_flags(b64, BIO_FLAGS_BASE64_NO_NL);
   2579 	bio = BIO_push(b64, bio);
   2580 
   2581 	outlen = BIO_read(bio, outb, inlen * 2);
   2582 	if (outlen <= 0) {
   2583 		plog(LLV_ERROR, LOCATION, NULL, "%s\n", eay_strerror());
   2584 		goto out;
   2585 	}
   2586 
   2587 	res = vmalloc(outlen);
   2588 	if (!res)
   2589 		goto out;
   2590 
   2591 	memcpy(res->v, outb, outlen);
   2592 
   2593 out:
   2594 	if (outb)
   2595 		free(outb);
   2596 	if (bio)
   2597 		BIO_free_all(bio);
   2598 
   2599 	return res;
   2600 }
   2601 
   2602 vchar_t *
   2603 base64_encode(char *in, long inlen)
   2604 {
   2605 	BIO *bio=NULL, *b64=NULL;
   2606 	char *ptr;
   2607 	long plen = -1;
   2608 	vchar_t *res = NULL;
   2609 
   2610 	bio = BIO_new(BIO_s_mem());
   2611 	b64 = BIO_new(BIO_f_base64());
   2612 	BIO_set_flags(b64, BIO_FLAGS_BASE64_NO_NL);
   2613 	bio = BIO_push(b64, bio);
   2614 
   2615 	BIO_write(bio, in, inlen);
   2616 	BIO_flush(bio);
   2617 
   2618 	plen = BIO_get_mem_data(bio, &ptr);
   2619 	res = vmalloc(plen+1);
   2620 	if (!res)
   2621 		goto out;
   2622 
   2623 	memcpy (res->v, ptr, plen);
   2624 	res->v[plen] = '\0';
   2625 
   2626 out:
   2627 	if (bio)
   2628 		BIO_free_all(bio);
   2629 
   2630 	return res;
   2631 }
   2632 
   2633 static RSA *
   2634 binbuf_pubkey2rsa(vchar_t *binbuf)
   2635 {
   2636 	BIGNUM *exp, *mod;
   2637 	RSA *rsa_pub = NULL;
   2638 
   2639 	if (binbuf->v[0] > binbuf->l - 1) {
   2640 		plog(LLV_ERROR, LOCATION, NULL, "Plain RSA pubkey format error: decoded string doesn't make sense.\n");
   2641 		goto out;
   2642 	}
   2643 
   2644 	exp = BN_bin2bn((unsigned char *) (binbuf->v + 1), binbuf->v[0], NULL);
   2645 	mod = BN_bin2bn((unsigned char *) (binbuf->v + binbuf->v[0] + 1),
   2646 			binbuf->l - binbuf->v[0] - 1, NULL);
   2647 	rsa_pub = RSA_new();
   2648 
   2649 	if (!exp || !mod || !rsa_pub) {
   2650 		plog(LLV_ERROR, LOCATION, NULL, "Plain RSA pubkey parsing error: %s\n", eay_strerror());
   2651 		if (exp)
   2652 			BN_free(exp);
   2653 		if (mod)
   2654 			BN_free(exp);
   2655 		if (rsa_pub)
   2656 			RSA_free(rsa_pub);
   2657 		rsa_pub = NULL;
   2658 		goto out;
   2659 	}
   2660 
   2661 	rsa_pub->n = mod;
   2662 	rsa_pub->e = exp;
   2663 
   2664 out:
   2665 	return rsa_pub;
   2666 }
   2667 
   2668 RSA *
   2669 base64_pubkey2rsa(char *in)
   2670 {
   2671 	BIGNUM *exp, *mod;
   2672 	RSA *rsa_pub = NULL;
   2673 	vchar_t *binbuf;
   2674 
   2675 	if (strncmp(in, "0s", 2) != 0) {
   2676 		plog(LLV_ERROR, LOCATION, NULL, "Plain RSA pubkey format error: doesn't start with '0s'\n");
   2677 		return NULL;
   2678 	}
   2679 
   2680 	binbuf = base64_decode(in + 2, strlen(in + 2));
   2681 	if (!binbuf) {
   2682 		plog(LLV_ERROR, LOCATION, NULL, "Plain RSA pubkey format error: Base64 decoding failed.\n");
   2683 		return NULL;
   2684 	}
   2685 
   2686 	if (binbuf->v[0] > binbuf->l - 1) {
   2687 		plog(LLV_ERROR, LOCATION, NULL, "Plain RSA pubkey format error: decoded string doesn't make sense.\n");
   2688 		goto out;
   2689 	}
   2690 
   2691 	rsa_pub = binbuf_pubkey2rsa(binbuf);
   2692 
   2693 out:
   2694 	if (binbuf)
   2695 		vfree(binbuf);
   2696 
   2697 	return rsa_pub;
   2698 }
   2699 
   2700 RSA *
   2701 bignum_pubkey2rsa(BIGNUM *in)
   2702 {
   2703 	RSA *rsa_pub = NULL;
   2704 	vchar_t *binbuf;
   2705 
   2706 	binbuf = vmalloc(BN_num_bytes(in));
   2707 	if (!binbuf) {
   2708 		plog(LLV_ERROR, LOCATION, NULL, "Plain RSA pubkey conversion: memory allocation failed..\n");
   2709 		return NULL;
   2710 	}
   2711 
   2712 	BN_bn2bin(in, (unsigned char *) binbuf->v);
   2713 
   2714 	rsa_pub = binbuf_pubkey2rsa(binbuf);
   2715 
   2716 out:
   2717 	if (binbuf)
   2718 		vfree(binbuf);
   2719 
   2720 	return rsa_pub;
   2721 }
   2722 
   2723 u_int32_t
   2724 eay_random()
   2725 {
   2726 	u_int32_t result;
   2727 	vchar_t *vrand;
   2728 
   2729 	vrand = eay_set_random(sizeof(result));
   2730 	memcpy(&result, vrand->v, sizeof(result));
   2731 	vfree(vrand);
   2732 
   2733 	return result;
   2734 }
   2735 
   2736 const char *
   2737 eay_version()
   2738 {
   2739 	return SSLeay_version(SSLEAY_VERSION);
   2740 }
   2741