[proxmark3-svn] / client / emv / emv_pki_priv.c

/*
 * libopenemv - a library to work with EMV family of smart cards
 * Copyright (C) 2015 Dmitry Eremin-Solenikov
 *
 * This library is free software; you can redistribute it and/or
 * modify it under the terms of the GNU Lesser General Public
 * License as published by the Free Software Foundation; either
 * version 2.1 of the License, or (at your option) any later version.
 *
 * This library is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
 * Lesser General Public License for more details.
 */

#ifdef HAVE_CONFIG_H
#include <config.h>
#endif

#include "emv_pki_priv.h"
#include "crypto.h"

#include <stdlib.h>
#include <string.h>
#include <stdarg.h>

struct emv_pk *emv_pki_make_ca(const struct crypto_pk *cp,
		const unsigned char *rid, unsigned char index,
		unsigned int expire, enum crypto_algo_hash hash_algo)
{
	size_t modlen, explen;
	unsigned char *mod, *exp;

	if (!rid)
		return NULL;

	mod = crypto_pk_get_parameter(cp, 0, &modlen);
	exp = crypto_pk_get_parameter(cp, 1, &explen);

	if (!mod || !modlen || !exp || !explen) {
		free(mod);
		free(exp);

		return NULL;
	}

	struct emv_pk *pk = emv_pk_new(modlen, explen);
	memcpy(pk->rid, rid, 5);
	pk->index = index;
	pk->expire = expire;
	pk->pk_algo = crypto_pk_get_algo(cp);
	pk->hash_algo = hash_algo;
	memcpy(pk->modulus, mod, modlen);
	memcpy(pk->exp, exp, explen);

	free(mod);
	free(exp);

	struct crypto_hash *ch = crypto_hash_open(pk->hash_algo);
	if (!ch) {
		emv_pk_free(pk);
		return false;
	}

	crypto_hash_write(ch, pk->rid, sizeof(pk->rid));
	crypto_hash_write(ch, &pk->index, 1);
	crypto_hash_write(ch, pk->modulus, pk->mlen);
	crypto_hash_write(ch, pk->exp, pk->elen);

	unsigned char *h = crypto_hash_read(ch);
	if (!h) {
		crypto_hash_close(ch);
		emv_pk_free(pk);

		return NULL;
	}

	memcpy(pk->hash, h, crypto_hash_get_size(ch));
	crypto_hash_close(ch);

	return pk;
}

static struct tlvdb *emv_pki_sign_message(const struct crypto_pk *cp,
		tlv_tag_t cert_tag, tlv_tag_t rem_tag,
		const unsigned char *msg, size_t msg_len,
		... /* A list of tlv pointers, end with NULL */
		)
{
	size_t tmp_len = (crypto_pk_get_nbits(cp) + 7) / 8;
	unsigned char *tmp = malloc(tmp_len);
	if (!tmp)
		return NULL;

	// XXX
	struct crypto_hash *ch = crypto_hash_open(HASH_SHA_1);
	if (!ch) {
		free(tmp);

		return NULL;
	}

	tmp[0] = 0x6a;
	tmp[tmp_len - 1] = 0xbc;

	const unsigned char *rem;
	size_t rem_len;
	size_t hash_len = crypto_hash_get_size(ch);
	size_t part_len = tmp_len - 2 - hash_len;
	if (part_len < msg_len) {
		memcpy(tmp + 1, msg, part_len);
		rem = msg + part_len;
		rem_len = msg_len - part_len;
	} else {
		memcpy(tmp + 1, msg, msg_len);
		memset(tmp + 1 + msg_len, 0xbb, part_len - msg_len);
		rem = NULL;
		rem_len = 0;
	}
	crypto_hash_write(ch, tmp + 1, part_len);
	crypto_hash_write(ch, rem, rem_len);

	va_list vl;
	va_start(vl, msg_len);
	while (true) {
		const struct tlv *add_tlv = va_arg(vl, const struct tlv *);
		if (!add_tlv)
			break;

		crypto_hash_write(ch, add_tlv->value, add_tlv->len);
	}
	va_end(vl);

	unsigned char *h = crypto_hash_read(ch);
	if (!h) {
		crypto_hash_close(ch);
		free(tmp);

		return NULL;
	}

	memcpy(tmp + 1 + part_len, h, hash_len);
	crypto_hash_close(ch);

	size_t cert_len;
	unsigned char *cert = crypto_pk_decrypt(cp, tmp, tmp_len, &cert_len);
	free(tmp);

	if (!cert)
		return NULL;

	struct tlvdb *db = tlvdb_fixed(cert_tag, cert_len, cert);
	free(cert);
	if (!db)
		return NULL;

	if (rem) {
		struct tlvdb *rdb = tlvdb_fixed(rem_tag, rem_len, rem);
		if (!rdb) {
			tlvdb_free(db);

			return NULL;
		}
		tlvdb_add(db, rdb);
	}

	return db;
}

static struct tlvdb *emv_pki_sign_key(const struct crypto_pk *cp,
		struct emv_pk *ipk,
		unsigned char msgtype,
		size_t pan_len,
		tlv_tag_t cert_tag,
		tlv_tag_t exp_tag,
		tlv_tag_t rem_tag,
		const struct tlv *add_tlv
		)
{
	unsigned pos = 0;
	unsigned char *msg = malloc(1 + pan_len + 2 + 3 + 1 + 1 + 1 + 1 + ipk->mlen);

	if (!msg)
		return NULL;

	msg[pos++] = msgtype;
	memcpy(msg + pos, ipk->pan, pan_len); pos += pan_len;
	msg[pos++] = (ipk->expire >> 8) & 0xff;
	msg[pos++] = (ipk->expire >> 16) & 0xff;
	memcpy(msg + pos, ipk->serial, 3); pos += 3;
	msg[pos++] = ipk->hash_algo;
	msg[pos++] = ipk->pk_algo;
	msg[pos++] = ipk->mlen;
	msg[pos++] = ipk->elen;
	memcpy(msg + pos, ipk->modulus, ipk->mlen);
	pos += ipk->mlen;

	struct tlvdb *exp_db = tlvdb_fixed(exp_tag, ipk->elen, ipk->exp);
	if (!exp_db) {
		free(msg);

		return NULL;
	}

	struct tlvdb *db = emv_pki_sign_message(cp,
			cert_tag, rem_tag,
			msg, pos,
			tlvdb_get(exp_db, exp_tag, NULL),
			add_tlv,
			NULL);
	free(msg);
	if (!db)
		return NULL;

	tlvdb_add(db, exp_db);

	return db;
}

struct tlvdb *emv_pki_sign_issuer_cert(const struct crypto_pk *cp, struct emv_pk *issuer_pk)
{
	return emv_pki_sign_key(cp, issuer_pk, 2, 4, 0x90, 0x9f32, 0x92, NULL);
}

struct tlvdb *emv_pki_sign_icc_cert(const struct crypto_pk *cp, struct emv_pk *icc_pk, const struct tlv *sda_tlv)
{
	return emv_pki_sign_key(cp, icc_pk, 4, 10, 0x9f46, 0x9f47, 0x9f48, sda_tlv);
}

struct tlvdb *emv_pki_sign_icc_pe_cert(const struct crypto_pk *cp, struct emv_pk *icc_pe_pk)
{
	return emv_pki_sign_key(cp, icc_pe_pk, 4, 10, 0x9f2d, 0x9f2e, 0x9f2f, NULL);
}

struct tlvdb *emv_pki_sign_dac(const struct crypto_pk *cp, const struct tlv *dac_tlv, const struct tlv *sda_tlv)
{
	unsigned pos = 0;
	unsigned char *msg = malloc(1+1+dac_tlv->len);

	if (!msg)
		return NULL;

	msg[pos++] = 3;
	msg[pos++] = HASH_SHA_1;
	memcpy(msg+pos, dac_tlv->value, dac_tlv->len);
	pos += dac_tlv->len;

	struct tlvdb *db = emv_pki_sign_message(cp,
			0x93, 0,
			msg, pos,
			sda_tlv,
			NULL);

	free(msg);

	return db;
}

struct tlvdb *emv_pki_sign_idn(const struct crypto_pk *cp, const struct tlv *idn_tlv, const struct tlv *dyn_tlv)
{
	unsigned pos = 0;
	unsigned char *msg = malloc(1+1+1+1+idn_tlv->len);

	if (!msg)
		return NULL;

	msg[pos++] = 5;
	msg[pos++] = HASH_SHA_1;
	msg[pos++] = idn_tlv->len + 1;
	msg[pos++] = idn_tlv->len;
	memcpy(msg+pos, idn_tlv->value, idn_tlv->len);
	pos += idn_tlv->len;

	struct tlvdb *db = emv_pki_sign_message(cp,
			0x9f4b, 0,
			msg, pos,
			dyn_tlv,
			NULL);

	free(msg);

	return db;
}
Commit	Line	Data
d03fb293 OM	1	/*
	2	* libopenemv - a library to work with EMV family of smart cards
	3	* Copyright (C) 2015 Dmitry Eremin-Solenikov
	4	*
	5	* This library is free software; you can redistribute it and/or
	6	* modify it under the terms of the GNU Lesser General Public
	7	* License as published by the Free Software Foundation; either
	8	* version 2.1 of the License, or (at your option) any later version.
	9	*
	10	* This library is distributed in the hope that it will be useful,
	11	* but WITHOUT ANY WARRANTY; without even the implied warranty of
	12	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
	13	* Lesser General Public License for more details.
	14	*/
	15
	16	#ifdef HAVE_CONFIG_H
	17	#include <config.h>
	18	#endif
	19
	20	#include "emv_pki_priv.h"
	21	#include "crypto.h"
	22
	23	#include <stdlib.h>
	24	#include <string.h>
	25	#include <stdarg.h>
	26
	27	struct emv_pk emv_pki_make_ca(const struct crypto_pk cp,
	28	const unsigned char *rid, unsigned char index,
	29	unsigned int expire, enum crypto_algo_hash hash_algo)
	30	{
	31	size_t modlen, explen;
	32	unsigned char mod, exp;
	33
	34	if (!rid)
	35	return NULL;
	36
	37	mod = crypto_pk_get_parameter(cp, 0, &modlen);
	38	exp = crypto_pk_get_parameter(cp, 1, &explen);
	39
	40	if (!mod \|\| !modlen \|\| !exp \|\| !explen) {
	41	free(mod);
	42	free(exp);
	43
	44	return NULL;
	45	}
	46
	47	struct emv_pk *pk = emv_pk_new(modlen, explen);
	48	memcpy(pk->rid, rid, 5);
	49	pk->index = index;
	50	pk->expire = expire;
	51	pk->pk_algo = crypto_pk_get_algo(cp);
	52	pk->hash_algo = hash_algo;
	53	memcpy(pk->modulus, mod, modlen);
	54	memcpy(pk->exp, exp, explen);
	55
	56	free(mod);
	57	free(exp);
	58
	59	struct crypto_hash *ch = crypto_hash_open(pk->hash_algo);
	60	if (!ch) {
	61	emv_pk_free(pk);
	62	return false;
	63	}
	64
65	crypto_hash_write(ch, pk->rid, sizeof(pk->rid));
66	crypto_hash_write(ch, &pk->index, 1);
67	crypto_hash_write(ch, pk->modulus, pk->mlen);
68	crypto_hash_write(ch, pk->exp, pk->elen);
69
70	unsigned char *h = crypto_hash_read(ch);
71	if (!h) {
72	crypto_hash_close(ch);
73	emv_pk_free(pk);
74
75	return NULL;
76	}
77
78	memcpy(pk->hash, h, crypto_hash_get_size(ch));
79	crypto_hash_close(ch);
80
81	return pk;
82	}
83
84	static struct tlvdb emv_pki_sign_message(const struct crypto_pk cp,
85	tlv_tag_t cert_tag, tlv_tag_t rem_tag,
86	const unsigned char *msg, size_t msg_len,
87	... /* A list of tlv pointers, end with NULL */
88	)
89	{
90	size_t tmp_len = (crypto_pk_get_nbits(cp) + 7) / 8;
91	unsigned char *tmp = malloc(tmp_len);
92	if (!tmp)
93	return NULL;
94
95	// XXX
96	struct crypto_hash *ch = crypto_hash_open(HASH_SHA_1);
97	if (!ch) {
98	free(tmp);
99
100	return NULL;
101	}
102
103	tmp[0] = 0x6a;
104	tmp[tmp_len - 1] = 0xbc;
105
106	const unsigned char *rem;
107	size_t rem_len;
108	size_t hash_len = crypto_hash_get_size(ch);
109	size_t part_len = tmp_len - 2 - hash_len;
110	if (part_len < msg_len) {
111	memcpy(tmp + 1, msg, part_len);
112	rem = msg + part_len;
113	rem_len = msg_len - part_len;
114	} else {
115	memcpy(tmp + 1, msg, msg_len);
116	memset(tmp + 1 + msg_len, 0xbb, part_len - msg_len);
117	rem = NULL;
118	rem_len = 0;
119	}
120	crypto_hash_write(ch, tmp + 1, part_len);
121	crypto_hash_write(ch, rem, rem_len);
122
123	va_list vl;
124	va_start(vl, msg_len);
125	while (true) {
126	const struct tlv add_tlv = va_arg(vl, const struct tlv );
127	if (!add_tlv)
128	break;
129
130	crypto_hash_write(ch, add_tlv->value, add_tlv->len);
131	}
132	va_end(vl);
133
134	unsigned char *h = crypto_hash_read(ch);
135	if (!h) {
136	crypto_hash_close(ch);
137	free(tmp);
138
139	return NULL;
140	}
141
142	memcpy(tmp + 1 + part_len, h, hash_len);
143	crypto_hash_close(ch);
144
145	size_t cert_len;
146	unsigned char *cert = crypto_pk_decrypt(cp, tmp, tmp_len, &cert_len);
147	free(tmp);
148
149	if (!cert)
150	return NULL;
151
152	struct tlvdb *db = tlvdb_fixed(cert_tag, cert_len, cert);
153	free(cert);
154	if (!db)
155	return NULL;
156
157	if (rem) {
158	struct tlvdb *rdb = tlvdb_fixed(rem_tag, rem_len, rem);
159	if (!rdb) {
160	tlvdb_free(db);
161
162	return NULL;
163	}
164	tlvdb_add(db, rdb);
165	}
166
167	return db;
168	}
169
170	static struct tlvdb emv_pki_sign_key(const struct crypto_pk cp,
171	struct emv_pk *ipk,
172	unsigned char msgtype,
173	size_t pan_len,
174	tlv_tag_t cert_tag,
175	tlv_tag_t exp_tag,
176	tlv_tag_t rem_tag,
177	const struct tlv *add_tlv
178	)
179	{
180	unsigned pos = 0;
181	unsigned char *msg = malloc(1 + pan_len + 2 + 3 + 1 + 1 + 1 + 1 + ipk->mlen);
182
183	if (!msg)
184	return NULL;
185
186	msg[pos++] = msgtype;
187	memcpy(msg + pos, ipk->pan, pan_len); pos += pan_len;
188	msg[pos++] = (ipk->expire >> 8) & 0xff;
189	msg[pos++] = (ipk->expire >> 16) & 0xff;
190	memcpy(msg + pos, ipk->serial, 3); pos += 3;
191	msg[pos++] = ipk->hash_algo;
192	msg[pos++] = ipk->pk_algo;
193	msg[pos++] = ipk->mlen;
194	msg[pos++] = ipk->elen;
195	memcpy(msg + pos, ipk->modulus, ipk->mlen);
196	pos += ipk->mlen;
197
198	struct tlvdb *exp_db = tlvdb_fixed(exp_tag, ipk->elen, ipk->exp);
199	if (!exp_db) {
200	free(msg);
201
202	return NULL;
203	}
204
205	struct tlvdb *db = emv_pki_sign_message(cp,
206	cert_tag, rem_tag,
207	msg, pos,
208	tlvdb_get(exp_db, exp_tag, NULL),
209	add_tlv,
210	NULL);
211	free(msg);
212	if (!db)
213	return NULL;
214
215	tlvdb_add(db, exp_db);
216
217	return db;
218	}
219
220	struct tlvdb emv_pki_sign_issuer_cert(const struct crypto_pk cp, struct emv_pk *issuer_pk)
221	{
222	return emv_pki_sign_key(cp, issuer_pk, 2, 4, 0x90, 0x9f32, 0x92, NULL);
223	}
224
225	struct tlvdb emv_pki_sign_icc_cert(const struct crypto_pk cp, struct emv_pk icc_pk, const struct tlv sda_tlv)
226	{
227	return emv_pki_sign_key(cp, icc_pk, 4, 10, 0x9f46, 0x9f47, 0x9f48, sda_tlv);
228	}
229
230	struct tlvdb emv_pki_sign_icc_pe_cert(const struct crypto_pk cp, struct emv_pk *icc_pe_pk)
231	{
232	return emv_pki_sign_key(cp, icc_pe_pk, 4, 10, 0x9f2d, 0x9f2e, 0x9f2f, NULL);
233	}
234
235	struct tlvdb emv_pki_sign_dac(const struct crypto_pk cp, const struct tlv dac_tlv, const struct tlv sda_tlv)
236	{
237	unsigned pos = 0;
238	unsigned char *msg = malloc(1+1+dac_tlv->len);
239
240	if (!msg)
241	return NULL;
242
243	msg[pos++] = 3;
244	msg[pos++] = HASH_SHA_1;
245	memcpy(msg+pos, dac_tlv->value, dac_tlv->len);
246	pos += dac_tlv->len;
247
248	struct tlvdb *db = emv_pki_sign_message(cp,
249	0x93, 0,
250	msg, pos,
251	sda_tlv,
252	NULL);
253
254	free(msg);
255
256	return db;
257	}
258
259	struct tlvdb emv_pki_sign_idn(const struct crypto_pk cp, const struct tlv idn_tlv, const struct tlv dyn_tlv)
260	{
261	unsigned pos = 0;
262	unsigned char *msg = malloc(1+1+1+1+idn_tlv->len);
263
264	if (!msg)
265	return NULL;
266
267	msg[pos++] = 5;
268	msg[pos++] = HASH_SHA_1;
269	msg[pos++] = idn_tlv->len + 1;
270	msg[pos++] = idn_tlv->len;
271	memcpy(msg+pos, idn_tlv->value, idn_tlv->len);
272	pos += idn_tlv->len;
273
274	struct tlvdb *db = emv_pki_sign_message(cp,
275	0x9f4b, 0,
276	msg, pos,
277	dyn_tlv,
278	NULL);
279
280	free(msg);
281
282	return db;
283	}