CoCalc -- bign

GitHub Repository: freebsd/freebsd-src
Path: blob/main/crypto/libecc/src/sig/bign_common.c
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/*
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 *  Copyright (C) 2022 - This file is part of libecc project
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 *
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 *  Authors:
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 *      Ryad BENADJILA <[email protected]>
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 *      Arnaud EBALARD <[email protected]>
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 *
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 *  This software is licensed under a dual BSD and GPL v2 license.
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 *  See LICENSE file at the root folder of the project.
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 */
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#include <libecc/lib_ecc_config.h>
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#if defined(WITH_SIG_BIGN) || defined(WITH_SIG_DBIGN)
13

14
#include <libecc/nn/nn_rand.h>
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#include <libecc/nn/nn_mul_public.h>
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#include <libecc/nn/nn_logical.h>
17

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#include <libecc/sig/sig_algs_internal.h>
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#include <libecc/sig/ec_key.h>
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#include <libecc/utils/utils.h>
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#ifdef VERBOSE_INNER_VALUES
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#define EC_SIG_ALG "BIGN"
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#endif
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#include <libecc/utils/dbg_sig.h>
25

26
/*
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 * This is an implementation of the BIGN signature algorithm as
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 * described in the STB 34.101.45 standard
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 * (http://apmi.bsu.by/assets/files/std/bign-spec29.pdf).
30
 *
31
 * The BIGN signature is a variation on the Shnorr signature scheme.
32
 *
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 * An english high-level (less formal) description and rationale can be found
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 * in the IETF archive:
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 *   https://mailarchive.ietf.org/arch/msg/cfrg/pI92HSRjMBg50NVEz32L5RciVBk/
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 *
37
 * BIGN comes in two flavors: deterministic and non-deterministic. The current
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 * file implements the two.
39
 *
40
 * In this implementation, we are *on purpose* more lax than the STB standard regarding
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 * the so called "internal"/"external" hash function sizes and the order size:
42
 *   - We accept order sizes that might be different than twice the internal hash
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 *   function (HASH-BELT truncated) and the size of the external hash function.
44
 *   - We accept security levels that might be different from {128, 192, 256}.
45
 *
46
 * If we strictly conform to STB 34.101.45, only orders of size exactly twice the
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 * internal hash function length are accepted, and only external hash functions of size
48
 * of the order are accepted. Also only security levels of 128, 192 or 256 bits
49
 * are accepted.
50
 *
51
 * Being more lax on these parameters allows to be compatible with more hash
52
 * functions and curves.
53
 *
54
 * Finally, although the IETF archive in english leaves the "internal" hash functions
55
 * as configurable (wrt size constraints), the STB 34.101.45 standard fixes the BELT hash
56
 * function (standardized in STB 34.101.31) as the one to be used. The current file follows
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 * this mandatory requirement and uses BELT as the only possible internal hash function
58
 * while the external one is configurable.
59
 *
60
 */
61

62
/* NOTE: BIGN uses per its standard the BELT-HASH hash function as its "internal"
63
 * hash function, as well as the BELT encryption block cipher during the deterministic
64
 * computation of the nonce for the deterministic version of BIGN.
65
 * Hence the sanity check below.
66
 */
67
#if !defined(WITH_HASH_BELT_HASH)
68
#error "BIGN and DBIGN need BELT-HASH, please activate it!"
69
#endif
70

71

72
/* Reverses the endiannes of a buffer in place */
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ATTRIBUTE_WARN_UNUSED_RET static inline int _reverse_endianness(u8 *buf, u16 buf_size)
74
{
75
	u16 i;
76
	u8 tmp;
77
	int ret;
78

79
	MUST_HAVE((buf != NULL), ret, err);
80

81
	if(buf_size > 1){
82
		for(i = 0; i < (buf_size / 2); i++){
83
			tmp = buf[i];
84
			buf[i] = buf[buf_size - 1 - i];
85
			buf[buf_size - 1 - i] = tmp;
86
		}
87
	}
88

89
	ret = 0;
90
err:
91
	return ret;
92
}
93

94
/* The additional data for bign are specific. We provide
95
 * helpers to extract them from an adata pointer.
96
 */
97
int bign_get_oid_from_adata(const u8 *adata, u16 adata_len, const u8 **oid_ptr, u16 *oid_len)
98
{
99
	int ret;
100
	u16 t_len;
101

102
	MUST_HAVE((adata != NULL) && (oid_ptr != NULL) && (oid_len != NULL), ret, err);
103
	MUST_HAVE((adata_len >= 4), ret, err);
104

105
	(*oid_len) = (u16)(((u16)adata[0] << 8) | adata[1]);
106
	t_len = (u16)(((u16)adata[2] << 8) | adata[3]);
107
	/* Check overflow */
108
	MUST_HAVE(((*oid_len) + t_len) >= (t_len), ret, err);
109
	MUST_HAVE(((*oid_len) + t_len) <= (adata_len - 4), ret, err);
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	(*oid_ptr) = &adata[4];
111

112
	ret = 0;
113
err:
114
	if(ret && (oid_ptr != NULL)){
115
		(*oid_ptr) = NULL;
116
	}
117
	if(ret && (oid_len != NULL)){
118
		(*oid_len) = 0;
119
	}
120
	return ret;
121
}
122

123
int bign_get_t_from_adata(const u8 *adata, u16 adata_len, const u8 **t_ptr, u16 *t_len)
124
{
125
	int ret;
126
	u16 oid_len;
127

128
	MUST_HAVE((adata != NULL) && (t_ptr != NULL) && (t_len != NULL), ret, err);
129
	MUST_HAVE((adata_len >= 4), ret, err);
130

131
	oid_len = (u16)(((u16)adata[0] << 8) | adata[1]);
132
	(*t_len) = (u16)(((u16)adata[2] << 8) | adata[3]);
133
	/* Check overflow */
134
	MUST_HAVE((oid_len + (*t_len)) >= (oid_len), ret, err);
135
	MUST_HAVE((oid_len + (*t_len)) <= (adata_len - 4), ret, err);
136
	(*t_ptr) = &adata[4 + oid_len];
137

138
	ret = 0;
139
err:
140
	if(ret && (t_ptr != NULL)){
141
		(*t_ptr) = NULL;
142
	}
143
	if(ret && (t_len != NULL)){
144
		(*t_len) = 0;
145
	}
146
	return ret;
147
}
148

149
int bign_set_adata(u8 *adata, u16 adata_len, const u8 *oid, u16 oid_len, const u8 *t, u16 t_len)
150
{
151
	int ret;
152

153
	MUST_HAVE((adata != NULL), ret, err);
154

155
	MUST_HAVE((oid != NULL) || (oid_len == 0), ret, err);
156
	MUST_HAVE((t != NULL) || (t_len == 0), ret, err);
157
	MUST_HAVE((adata_len >= 4), ret, err);
158
	/* Check overflow */
159
	MUST_HAVE(((oid_len + t_len) >= oid_len), ret, err);
160
	MUST_HAVE(((adata_len - 4) >= (oid_len + t_len)), ret, err);
161

162
	if(oid != NULL){
163
		adata[0] = (u8)(oid_len >> 8);
164
		adata[1] = (u8)(oid_len & 0xff);
165
		ret = local_memcpy(&adata[4], oid, oid_len); EG(ret, err);
166
	}
167
	else{
168
		adata[0] = adata[1] = 0;
169
	}
170
	if(t != NULL){
171
		adata[2] = (u8)(t_len >> 8);
172
		adata[3] = (u8)(t_len & 0xff);
173
		ret = local_memcpy(&adata[4 + oid_len], t, t_len); EG(ret, err);
174

175
	}
176
	else{
177
		adata[2] = adata[3] = 0;
178
	}
179

180
	ret = 0;
181
err:
182
	return ret;
183
}
184

185
#if defined(WITH_SIG_DBIGN)
186
/*
187
 * Deterministic nonce generation function for deterministic BIGN, as
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 * described in STB 34.101.45 6.3.3.
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 *
190
 * NOTE: Deterministic nonce generation for BIGN is useful against attackers
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 * in contexts where only poor RNG/entropy are available, or when nonce bits
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 * leaking can be possible through side-channel attacks.
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 * However, in contexts where fault attacks are easy to mount, deterministic
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 * BIGN can bring more security risks than regular BIGN.
195
 *
196
 * Depending on the context where you use the library, choose carefully if
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 * you want to use the deterministic version or not.
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 *
199
 */
200
ATTRIBUTE_WARN_UNUSED_RET static int __bign_determinitic_nonce(nn_t k, nn_src_t q, bitcnt_t q_bit_len,
201
							       nn_src_t x, const u8 *adata, u16 adata_len,
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							       const u8 *h, u8 hlen)
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{
204
	int ret, cmp, iszero;
205
	u8 theta[BELT_HASH_DIGEST_SIZE];
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	u8 FE2OS_D[LOCAL_MAX(BYTECEIL(CURVES_MAX_Q_BIT_LEN), 2 * BELT_HASH_DIGEST_SIZE)];
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	u8 r[((MAX_DIGEST_SIZE / BELT_BLOCK_LEN) * BELT_BLOCK_LEN) + (2 * BELT_BLOCK_LEN)];
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	u8 r_bar[((MAX_DIGEST_SIZE / BELT_BLOCK_LEN) * BELT_BLOCK_LEN) + (2 * BELT_BLOCK_LEN)];
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	u8 q_len, l;
210
	unsigned int j, z, n;
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	u32 i;
212
	u16 r_bar_len;
213

214
	belt_hash_context belt_hash_ctx;
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	const u8 *oid_ptr = NULL;
216
	const u8 *t_ptr = NULL;
217
	u16 oid_len = 0, t_len = 0;
218

219
	MUST_HAVE((adata != NULL) && (h != NULL), ret, err);
220
	ret = nn_check_initialized(q); EG(ret, err);
221
	ret = nn_check_initialized(x); EG(ret, err);
222

223
	ret = local_memset(theta, 0, sizeof(theta)); EG(ret, err);
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	ret = local_memset(FE2OS_D, 0, sizeof(FE2OS_D)); EG(ret, err);
225
	ret = local_memset(r_bar, 0, sizeof(r_bar)); EG(ret, err);
226

227
	q_len = (u8)BYTECEIL(q_bit_len);
228

229
	/* Compute l depending on the order */
230
	l = (u8)BIGN_S0_LEN(q_bit_len);
231

232
	/* Extract oid and t from the additional data */
233
	ret = bign_get_oid_from_adata(adata, adata_len, &oid_ptr, &oid_len); EG(ret, err);
234
	ret = bign_get_t_from_adata(adata, adata_len, &t_ptr, &t_len); EG(ret, err);
235

236
	ret = belt_hash_init(&belt_hash_ctx); EG(ret, err);
237
	ret = belt_hash_update(&belt_hash_ctx, oid_ptr, oid_len); EG(ret, err);
238

239
	/* Put the private key in a string <d>2*l */
240
	ret = local_memset(FE2OS_D, 0, sizeof(FE2OS_D)); EG(ret, err);
241
	ret = nn_export_to_buf(&FE2OS_D[0], q_len, x); EG(ret, err);
242
	ret = _reverse_endianness(&FE2OS_D[0], q_len); EG(ret, err);
243
	/* Only hash the 2*l bytes of d */
244
	ret = belt_hash_update(&belt_hash_ctx, &FE2OS_D[0], (u32)(2*l)); EG(ret, err);
245

246
	ret = belt_hash_update(&belt_hash_ctx, t_ptr, t_len); EG(ret, err);
247

248
	ret = belt_hash_final(&belt_hash_ctx, theta); EG(ret, err);
249

250
	dbg_buf_print("theta", theta, BELT_HASH_DIGEST_SIZE);
251

252
	/* n is the number of 128 bits blocks in H */
253
	n = (hlen / BELT_BLOCK_LEN);
254

255
	MUST_HAVE((hlen <= sizeof(r)), ret, err);
256
	ret = local_memset(r, 0, sizeof(r));
257
	ret = local_memcpy(r, h, hlen); EG(ret, err);
258
	/* If we have less than two blocks for the input hash size, we use zero
259
	 * padding to achieve at least two blocks.
260
	 * NOTE: this is not in the standard but allows to be compatible with small
261
	 * size hash functions.
262
	 */
263
	if(n <= 1){
264
		n = 2;
265
	}
266

267
	/* Now iterate until the nonce is computed in [1, q-1]
268
	 * NOTE: we are ensured here that n >= 2, which allows us to
269
	 * index (n-1) and (n-2) blocks in r.
270
	 */
271
	i = (u32)1;
272

273
	while(1){
274
		u8 s[BELT_BLOCK_LEN];
275
		u8 i_block[BELT_BLOCK_LEN];
276
		ret = local_memset(s, 0, sizeof(s)); EG(ret, err);
277

278
		/* Put the xor of all n-1 elements in s */
279
		for(j = 0; j < (n - 1); j++){
280
			for(z = 0; z < BELT_BLOCK_LEN; z++){
281
				s[z] ^= r[(BELT_BLOCK_LEN * j) + z];
282
			}
283
		}
284
		/* Move elements left for the first n-2 elements */
285
		ret = local_memcpy(&r[0], &r[BELT_BLOCK_LEN], (n - 2) * BELT_BLOCK_LEN); EG(ret, err);
286

287
		/* r_n-1 = belt-block(s, theta) ^ r_n ^ <i>128 */
288
		ret = local_memset(i_block, 0, sizeof(i_block)); EG(ret, err);
289
		PUT_UINT32_LE(i, i_block, 0);
290
		belt_encrypt(s, &r[(n - 2) * BELT_BLOCK_LEN], theta);
291
		for(z = 0; z < BELT_BLOCK_LEN; z++){
292
			r[((n - 2) * BELT_BLOCK_LEN) + z] ^= (r[((n - 1) * BELT_BLOCK_LEN) + z] ^ i_block[z]);
293
		}
294

295
		/* r_n = s */
296
		ret = local_memcpy(&r[(n - 1) * BELT_BLOCK_LEN], s, BELT_BLOCK_LEN); EG(ret, err);
297

298
		/* Import r_bar as a big number in little endian
299
		 * (truncate our import to the bitlength size of q)
300
		 */
301
		if(q_len < (n * BELT_BLOCK_LEN)){
302
			r_bar_len = q_len;
303
			ret = local_memcpy(&r_bar[0], &r[0], r_bar_len); EG(ret, err);
304
			/* Handle the useless bits between q_bit_len and (8 * q_len) */
305
			if((q_bit_len % 8) != 0){
306
				r_bar[r_bar_len - 1] &= (u8)((0x1 << (q_bit_len % 8)) - 1);
307
			}
308
		}
309
		else{
310
			/* In this case, q_len is bigger than the size of r, we need to adapt:
311
			 * we truncate to the size of r.
312
			 * NOTE: we of course lose security, but this is the explicit choice
313
			 * of the user using a "small" hash function with a "big" order.
314
			 */
315
			MUST_HAVE((n * BELT_BLOCK_LEN) <= 0xffff, ret, err);
316
			r_bar_len = (u16)(n * BELT_BLOCK_LEN);
317
			ret = local_memcpy(&r_bar[0], &r[0], r_bar_len); EG(ret, err);
318
		}
319
		ret = _reverse_endianness(&r_bar[0], r_bar_len); EG(ret, err);
320
		ret = nn_init_from_buf(k, &r_bar[0], r_bar_len); EG(ret, err);
321

322
		/* Compare it to q */
323
		ret = nn_cmp(k, q, &cmp); EG(ret, err);
324
		/* Compare it to 0 */
325
		ret = nn_iszero(k, &iszero); EG(ret, err);
326

327
		if((i >= (2 * n)) && (cmp < 0) && (!iszero)){
328
			break;
329
		}
330
		i += (u32)1;
331
		/* If we have wrapped (meaning i > 2^32), we exit with failure */
332
		MUST_HAVE((i != 0), ret, err);
333
	}
334

335
	ret = 0;
336
err:
337
	/* Destroy local variables potentially containing sensitive data */
338
	IGNORE_RET_VAL(local_memset(theta, 0, sizeof(theta)));
339
	IGNORE_RET_VAL(local_memset(FE2OS_D, 0, sizeof(FE2OS_D)));
340

341
	return ret;
342
}
343
#endif
344

345
int __bign_init_pub_key(ec_pub_key *out_pub, const ec_priv_key *in_priv,
346
			 ec_alg_type key_type)
347
{
348
	prj_pt_src_t G;
349
	int ret, cmp;
350
	nn_src_t q;
351

352
	MUST_HAVE((out_pub != NULL), ret, err);
353

354
	/* Zero init public key to be generated */
355
	ret = local_memset(out_pub, 0, sizeof(ec_pub_key)); EG(ret, err);
356

357
	ret = priv_key_check_initialized_and_type(in_priv, key_type); EG(ret, err);
358
	q = &(in_priv->params->ec_gen_order);
359

360
	/* Sanity check on key compliance */
361
	MUST_HAVE((!nn_cmp(&(in_priv->x), q, &cmp)) && (cmp < 0), ret, err);
362

363
	/* Y = xG */
364
	G = &(in_priv->params->ec_gen);
365
	/* Use blinding when computing point scalar multiplication */
366
	ret = prj_pt_mul_blind(&(out_pub->y), &(in_priv->x), G); EG(ret, err);
367

368
	out_pub->key_type = key_type;
369
	out_pub->params = in_priv->params;
370
	out_pub->magic = PUB_KEY_MAGIC;
371

372
err:
373
	return ret;
374
}
375

376
int __bign_siglen(u16 p_bit_len, u16 q_bit_len, u8 hsize, u8 blocksize, u8 *siglen)
377
{
378
	int ret;
379

380
	MUST_HAVE(siglen != NULL, ret, err);
381
	MUST_HAVE((p_bit_len <= CURVES_MAX_P_BIT_LEN) &&
382
		  (q_bit_len <= CURVES_MAX_Q_BIT_LEN) &&
383
		  (hsize <= MAX_DIGEST_SIZE) && (blocksize <= MAX_BLOCK_SIZE), ret, err);
384
	(*siglen) = (u8)BIGN_SIGLEN(q_bit_len);
385
	ret = 0;
386

387
err:
388
	return ret;
389
}
390

391
/*
392
 * Generic *internal* BIGN signature functions (init, update and finalize).
393
 * Their purpose is to allow passing a specific hash function (along with
394
 * its output size) and the random ephemeral key k, so that compliance
395
 * tests against test vectors can be made without ugly hack in the code
396
 * itself.
397
 *
398
 * Implementation notes:
399
 *
400
 * a) The BIGN algorithm makes use of the OID of the external hash function.
401
 *    We let the upper layer provide us with this in the "adata" field of the
402
 *    context.
403
 *
404
 */
405

406
#define BIGN_SIGN_MAGIC ((word_t)(0x63439a2b38921340ULL))
407
#define BIGN_SIGN_CHECK_INITIALIZED(A, ret, err) \
408
	MUST_HAVE((((void *)(A)) != NULL) && ((A)->magic == BIGN_SIGN_MAGIC), ret, err)
409

410
int __bign_sign_init(struct ec_sign_context *ctx, ec_alg_type key_type)
411
{
412
	int ret;
413

414
	/* First, verify context has been initialized */
415
	ret = sig_sign_check_initialized(ctx); EG(ret, err);
416

417
	/* Additional sanity checks on input params from context */
418
	ret = key_pair_check_initialized_and_type(ctx->key_pair, key_type); EG(ret, err);
419

420
	MUST_HAVE((ctx->h != NULL) && (ctx->h->digest_size <= MAX_DIGEST_SIZE) &&
421
		  (ctx->h->block_size <= MAX_BLOCK_SIZE), ret, err);
422

423
	/* We check that our additional data is not NULL as it must contain
424
	 * the mandatory external hash OID.
425
	 */
426
	MUST_HAVE((ctx->adata != NULL) && (ctx->adata_len != 0), ret, err);
427

428
	/*
429
	 * Initialize hash context stored in our private part of context
430
	 * and record data init has been done
431
	 */
432
	/* Since we call a callback, sanity check our mapping */
433
	ret = hash_mapping_callbacks_sanity_check(ctx->h); EG(ret, err);
434
	ret = ctx->h->hfunc_init(&(ctx->sign_data.bign.h_ctx)); EG(ret, err);
435

436
	ctx->sign_data.bign.magic = BIGN_SIGN_MAGIC;
437

438
err:
439
	return ret;
440
}
441

442
int __bign_sign_update(struct ec_sign_context *ctx,
443
		       const u8 *chunk, u32 chunklen, ec_alg_type key_type)
444
{
445
	int ret;
446

447
	/*
448
	 * First, verify context has been initialized and private
449
	 * part too. This guarantees the context is an BIGN
450
	 * signature one and we do not update() or finalize()
451
	 * before init().
452
	 */
453
	ret = sig_sign_check_initialized(ctx); EG(ret, err);
454
	BIGN_SIGN_CHECK_INITIALIZED(&(ctx->sign_data.bign), ret, err);
455

456
	/* Additional sanity checks on input params from context */
457
	ret = key_pair_check_initialized_and_type(ctx->key_pair, key_type); EG(ret, err);
458

459
	/* 1. Compute h = H(m) */
460
	/* Since we call a callback, sanity check our mapping */
461
	ret = hash_mapping_callbacks_sanity_check(ctx->h); EG(ret, err);
462
	ret = ctx->h->hfunc_update(&(ctx->sign_data.bign.h_ctx), chunk, chunklen);
463

464
err:
465
	return ret;
466
}
467

468
int __bign_sign_finalize(struct ec_sign_context *ctx, u8 *sig, u8 siglen,
469
			  ec_alg_type key_type)
470
{
471
	int ret, cmp;
472
	const ec_priv_key *priv_key;
473
	prj_pt_src_t G;
474
	u8 hash[MAX_DIGEST_SIZE];
475
	u8 hash_belt[BELT_HASH_DIGEST_SIZE];
476
	u8 FE2OS_W[LOCAL_MAX(2 * BYTECEIL(CURVES_MAX_P_BIT_LEN), 2 * BIGN_S0_LEN(CURVES_MAX_Q_BIT_LEN))];
477
	bitcnt_t q_bit_len, p_bit_len;
478
	prj_pt kG;
479
	nn_src_t q, x;
480
	u8 hsize, p_len, l;
481
	nn k, h, tmp, s1;
482
	belt_hash_context belt_hash_ctx;
483
	const u8 *oid_ptr = NULL;
484
	u16 oid_len = 0;
485
#ifdef USE_SIG_BLINDING
486
	/* b is the blinding mask */
487
	nn b, binv;
488
	b.magic = binv.magic = WORD(0);
489
#endif
490

491
	k.magic = h.magic = WORD(0);
492
	tmp.magic = s1.magic = WORD(0);
493
	kG.magic = WORD(0);
494

495
	/*
496
	 * First, verify context has been initialized and private
497
	 * part too. This guarantees the context is an BIGN
498
	 * signature one and we do not finalize() before init().
499
	 */
500
	ret = sig_sign_check_initialized(ctx); EG(ret, err);
501
	BIGN_SIGN_CHECK_INITIALIZED(&(ctx->sign_data.bign), ret, err);
502
	MUST_HAVE((sig != NULL), ret, err);
503

504
	/* Additional sanity checks on input params from context */
505
	ret = key_pair_check_initialized_and_type(ctx->key_pair, key_type); EG(ret, err);
506

507
	/* Zero init out point */
508
	ret = local_memset(&kG, 0, sizeof(prj_pt)); EG(ret, err);
509

510
	/* Make things more readable */
511
	priv_key = &(ctx->key_pair->priv_key);
512
	q = &(priv_key->params->ec_gen_order);
513
	q_bit_len = priv_key->params->ec_gen_order_bitlen;
514
	p_bit_len = priv_key->params->ec_fp.p_bitlen;
515
	G = &(priv_key->params->ec_gen);
516
	p_len = (u8)BYTECEIL(p_bit_len);
517
	x = &(priv_key->x);
518
	hsize = ctx->h->digest_size;
519

520
	MUST_HAVE((priv_key->key_type == key_type), ret, err);
521

522
	/* Compute l depending on the order */
523
	l = (u8)BIGN_S0_LEN(q_bit_len);
524

525
	/* Sanity check */
526
	ret = nn_cmp(x, q, &cmp); EG(ret, err);
527
	/* This should not happen and means that our
528
	 * private key is not compliant!
529
	 */
530
	MUST_HAVE((cmp < 0), ret, err);
531

532
	dbg_nn_print("p", &(priv_key->params->ec_fp.p));
533
	dbg_nn_print("q", &(priv_key->params->ec_gen_order));
534
	dbg_priv_key_print("x", priv_key);
535
	dbg_ec_point_print("G", &(priv_key->params->ec_gen));
536
	dbg_pub_key_print("Y", &(ctx->key_pair->pub_key));
537

538
	/* Check given signature buffer length has the expected size */
539
	MUST_HAVE((siglen == BIGN_SIGLEN(q_bit_len)), ret, err);
540

541
	/* We check that our additional data is not NULL as it must contain
542
	 * the mandatory external hash OID.
543
	 */
544
	MUST_HAVE((ctx->adata != NULL) && (ctx->adata_len != 0), ret, err);
545

546
	/* 1. Compute h = H(m) */
547
	ret = local_memset(hash, 0, hsize); EG(ret, err);
548
	/* Since we call a callback, sanity check our mapping */
549
	ret = hash_mapping_callbacks_sanity_check(ctx->h); EG(ret, err);
550
	ret = ctx->h->hfunc_finalize(&(ctx->sign_data.bign.h_ctx), hash); EG(ret, err);
551
	dbg_buf_print("h", hash, hsize);
552

553

554
	/* 2. get a random value k in ]0,q[ */
555
#ifdef NO_KNOWN_VECTORS
556
	/* NOTE: when we do not need self tests for known vectors,
557
	 * we can be strict about random function handler!
558
	 * This allows us to avoid the corruption of such a pointer.
559
	 */
560
	/* Sanity check on the handler before calling it */
561
	if(ctx->rand != nn_get_random_mod){
562
#ifdef WITH_SIG_DBIGN
563
		/* In deterministic BIGN, nevermind! */
564
		if(key_type != DBIGN)
565
#endif
566
		{
567
			ret = -1;
568
			goto err;
569
		}
570
	}
571
#endif
572
	if(ctx->rand != NULL){
573
		/* Non-deterministic generation, or deterministic with
574
		 * test vectors.
575
		 */
576
		ret = ctx->rand(&k, q);
577
	}
578
	else
579
#if defined(WITH_SIG_DBIGN)
580
	{
581
		/* Only applies for DETERMINISTIC BIGN */
582
		if(key_type != DBIGN){
583
			ret = -1;
584
			goto err;
585
		}
586
		/* Deterministically generate k as STB 34.101.45 mandates */
587
		ret = __bign_determinitic_nonce(&k, q, q_bit_len, &(priv_key->x), ctx->adata, ctx->adata_len,  hash, hsize);
588
	}
589
#else
590
	{
591
		/* NULL rand function is not accepted for regular BIGN */
592
		ret = -1;
593
		goto err;
594
	}
595
#endif
596
	if (ret) {
597
		ret = -1;
598
		goto err;
599
	}
600
	dbg_nn_print("k", &k);
601

602
#ifdef USE_SIG_BLINDING
603
	/* Note: if we use blinding, r and e are multiplied by
604
	 * a random value b in ]0,q[ */
605
	ret = nn_get_random_mod(&b, q); EG(ret, err);
606
	/* NOTE: we use Fermat's little theorem inversion for
607
	 * constant time here. This is possible since q is prime.
608
	 */
609
	ret = nn_modinv_fermat(&binv, &b, q); EG(ret, err);
610

611
	dbg_nn_print("b", &b);
612
#endif /* USE_SIG_BLINDING */
613

614

615
	/* 3. Compute W = (W_x,W_y) = kG */
616
#ifdef USE_SIG_BLINDING
617
	ret = prj_pt_mul_blind(&kG, &k, G); EG(ret, err);
618
#else
619
	ret = prj_pt_mul(&kG, &k, G); EG(ret, err);
620
#endif /* USE_SIG_BLINDING */
621
	ret = prj_pt_unique(&kG, &kG); EG(ret, err);
622

623
	dbg_nn_print("W_x", &(kG.X.fp_val));
624
	dbg_nn_print("W_y", &(kG.Y.fp_val));
625

626
	/* 4. Compute s0 = <BELT-HASH(OID(H) || <<FE2OS(W_x)> || <FE2OS(W_y)>>2*l || H(X))>l */
627
	ret = belt_hash_init(&belt_hash_ctx); EG(ret, err);
628
	ret = bign_get_oid_from_adata(ctx->adata, ctx->adata_len, &oid_ptr, &oid_len); EG(ret, err);
629
	ret = belt_hash_update(&belt_hash_ctx, oid_ptr, oid_len); EG(ret, err);
630
	/**/
631
	ret = local_memset(FE2OS_W, 0, sizeof(FE2OS_W)); EG(ret, err);
632
	ret = fp_export_to_buf(&FE2OS_W[0],  p_len, &(kG.X)); EG(ret, err);
633
	ret = _reverse_endianness(&FE2OS_W[0],  p_len); EG(ret, err);
634
	ret = fp_export_to_buf(&FE2OS_W[p_len], p_len, &(kG.Y)); EG(ret, err);
635
	ret = _reverse_endianness(&FE2OS_W[p_len], p_len); EG(ret, err);
636
	/* Only hash the 2*l bytes of FE2OS(W_x) || FE2OS(W_y) */
637
	ret = belt_hash_update(&belt_hash_ctx, &FE2OS_W[0], (u32)(2*l)); EG(ret, err);
638
	/**/
639
	ret = belt_hash_update(&belt_hash_ctx, hash, hsize); EG(ret, err);
640
	/* Store our s0 */
641
	ret = local_memset(hash_belt, 0, sizeof(hash_belt)); EG(ret, err);
642
	ret = belt_hash_final(&belt_hash_ctx, hash_belt); EG(ret, err);
643
	ret = local_memset(&sig[0], 0, l); EG(ret, err);
644
	ret = local_memcpy(&sig[0], &hash_belt[0], LOCAL_MIN(l, BELT_HASH_DIGEST_SIZE)); EG(ret, err);
645
	dbg_buf_print("s0", &sig[0], LOCAL_MIN(l, BELT_HASH_DIGEST_SIZE));
646

647
	/* 5. Now compute s1 = (k - H_bar - (s0_bar + 2**l) * d) mod q */
648
	/* First import H and s0 as numbers modulo q */
649
	/* Import H */
650
	ret = _reverse_endianness(hash, hsize); EG(ret, err);
651
	ret = nn_init_from_buf(&h, hash, hsize); EG(ret, err);
652
	ret = nn_mod(&h, &h, q); EG(ret, err);
653
	/* Import s0_bar */
654
	ret = local_memcpy(FE2OS_W, &sig[0], l); EG(ret, err);
655
	ret = _reverse_endianness(FE2OS_W, l); EG(ret, err);
656
	ret = nn_init_from_buf(&s1, FE2OS_W, l); EG(ret, err);
657
	ret = nn_mod(&s1, &s1, q); EG(ret, err);
658
	/* Compute (s0_bar + 2**l) * d */
659
	ret = nn_init(&tmp, 0); EG(ret, err);
660
	ret = nn_one(&tmp); EG(ret, err);
661
	ret = nn_lshift(&tmp, &tmp, (bitcnt_t)(8*l)); EG(ret, err);
662
	ret = nn_mod(&tmp, &tmp, q); EG(ret, err);
663
	ret = nn_mod_add(&s1, &s1, &tmp, q); EG(ret, err);
664
#ifdef USE_SIG_BLINDING
665
	/* Blind s1 with b */
666
	ret = nn_mod_mul(&s1, &s1, &b, q); EG(ret, err);
667

668
	/* Blind the message hash */
669
	ret = nn_mod_mul(&h, &h, &b, q); EG(ret, err);
670

671
	/* Blind the nonce */
672
	ret = nn_mod_mul(&k, &k, &b, q); EG(ret, err);
673
#endif /* USE_SIG_BLINDING */
674

675
	ret = nn_mod_mul(&s1, &s1, &(priv_key->x), q); EG(ret, err);
676
	ret = nn_mod_sub(&s1, &k, &s1, q); EG(ret, err);
677
	ret = nn_mod_sub(&s1, &s1, &h, q); EG(ret, err);
678

679
#ifdef USE_SIG_BLINDING
680
	/* Unblind s1 */
681
	ret = nn_mod_mul(&s1, &s1, &binv, q); EG(ret, err);
682
#endif
683
	dbg_nn_print("s1", &s1);
684

685
	/* Clean hash buffer as we do not need it anymore */
686
	ret = local_memset(hash, 0, hsize); EG(ret, err);
687

688
	/* Now export s1 and reverse its endianness */
689
	ret = nn_export_to_buf(&sig[l], (u16)BIGN_S1_LEN(q_bit_len), &s1); EG(ret, err);
690
	ret = _reverse_endianness(&sig[l], (u16)BIGN_S1_LEN(q_bit_len));
691

692
err:
693
	nn_uninit(&k);
694
	nn_uninit(&h);
695
	nn_uninit(&tmp);
696
	nn_uninit(&s1);
697
	prj_pt_uninit(&kG);
698
#ifdef USE_SIG_BLINDING
699
	nn_uninit(&b);
700
	nn_uninit(&binv);
701
#endif
702

703
	/*
704
	 * We can now clear data part of the context. This will clear
705
	 * magic and avoid further reuse of the whole context.
706
	 */
707
	if(ctx != NULL){
708
		IGNORE_RET_VAL(local_memset(&(ctx->sign_data.bign), 0, sizeof(bign_sign_data)));
709
	}
710

711
	/* Clean what remains on the stack */
712
	PTR_NULLIFY(priv_key);
713
	PTR_NULLIFY(G);
714
	PTR_NULLIFY(q);
715
	PTR_NULLIFY(x);
716
	PTR_NULLIFY(oid_ptr);
717
	VAR_ZEROIFY(q_bit_len);
718
	VAR_ZEROIFY(hsize);
719
	VAR_ZEROIFY(oid_len);
720

721
	return ret;
722
}
723

724
/*
725
 * Generic *internal* BIGN verification functions (init, update and finalize).
726
 * Their purpose is to allow passing a specific hash function (along with
727
 * its output size) and the random ephemeral key k, so that compliance
728
 * tests against test vectors can be made without ugly hack in the code
729
 * itself.
730
 *
731
 * Implementation notes:
732
 *
733
 * a) The BIGN algorithm makes use of the OID of the external hash function.
734
 *    We let the upper layer provide us with this in the "adata" field of the
735
 *    context.
736
 */
737

738
#define BIGN_VERIFY_MAGIC ((word_t)(0xceff8344927346abULL))
739
#define BIGN_VERIFY_CHECK_INITIALIZED(A, ret, err) \
740
	MUST_HAVE((((void *)(A)) != NULL) && ((A)->magic == BIGN_VERIFY_MAGIC), ret, err)
741

742
int __bign_verify_init(struct ec_verify_context *ctx, const u8 *sig, u8 siglen,
743
			ec_alg_type key_type)
744
{
745
	bitcnt_t q_bit_len;
746
	nn_src_t q;
747
	nn *s0, *s1;
748
	u8 *s0_sig;
749
	u8 TMP[BYTECEIL(CURVES_MAX_Q_BIT_LEN)];
750
	u8 l;
751
	int ret, cmp;
752

753
	/* First, verify context has been initialized */
754
	ret = sig_verify_check_initialized(ctx); EG(ret, err);
755

756
	ret = local_memset(TMP, 0, sizeof(TMP)); EG(ret, err);
757

758
	/* Do some sanity checks on input params */
759
	ret = pub_key_check_initialized_and_type(ctx->pub_key, key_type); EG(ret, err);
760
	MUST_HAVE((ctx->h != NULL) && (ctx->h->digest_size <= MAX_DIGEST_SIZE) &&
761
		(ctx->h->block_size <= MAX_BLOCK_SIZE), ret, err);
762
	MUST_HAVE((sig != NULL), ret, err);
763

764
	/* We check that our additional data is not NULL as it must contain
765
	 * the mandatory external hash OID.
766
	 */
767
	MUST_HAVE((ctx->adata != NULL) && (ctx->adata_len != 0), ret, err);
768

769
	/* Make things more readable */
770
	q = &(ctx->pub_key->params->ec_gen_order);
771
	q_bit_len = ctx->pub_key->params->ec_gen_order_bitlen;
772
	s0 = &(ctx->verify_data.bign.s0);
773
	s1 = &(ctx->verify_data.bign.s1);
774
	s0_sig = (u8*)(&(ctx->verify_data.bign.s0_sig));
775

776
	/* Compute l depending on the order */
777
	l = (u8)BIGN_S0_LEN(q_bit_len);
778

779
	/* Check given signature length is the expected one */
780
	MUST_HAVE((siglen == BIGN_SIGLEN(q_bit_len)), ret, err);
781

782
	/* Copy s0 to be checked later */
783
	ret = local_memcpy(s0_sig, sig, l); EG(ret, err);
784

785
	/* Import s0 and s1 values from signature buffer */
786
	ret = local_memcpy(&TMP[0], sig, l); EG(ret, err);
787
	ret = _reverse_endianness(&TMP[0], l); EG(ret, err);
788
	ret = nn_init_from_buf(s0, &TMP[0], l); EG(ret, err);
789
	/**/
790
	ret = local_memcpy(&TMP[0], &sig[l], (u32)BIGN_S1_LEN(q_bit_len)); EG(ret, err);
791
	ret = _reverse_endianness(&TMP[0], (u16)BIGN_S1_LEN(q_bit_len)); EG(ret, err);
792
	ret = nn_init_from_buf(s1, &TMP[0], (u8)BIGN_S1_LEN(q_bit_len)); EG(ret, err);
793
	dbg_nn_print("s0", s0);
794
	dbg_nn_print("s1", s1);
795

796
	/* 1. Reject the signature if s1 >= q */
797
	ret = nn_cmp(s1, q, &cmp); EG(ret, err);
798
	MUST_HAVE((cmp < 0), ret, err);
799

800
	/* Initialize the remaining of verify context. */
801
	/* Since we call a callback, sanity check our mapping */
802
	ret = hash_mapping_callbacks_sanity_check(ctx->h); EG(ret, err);
803
	ret = ctx->h->hfunc_init(&(ctx->verify_data.bign.h_ctx)); EG(ret, err);
804

805
	ctx->verify_data.bign.magic = BIGN_VERIFY_MAGIC;
806

807
 err:
808
	VAR_ZEROIFY(q_bit_len);
809
	PTR_NULLIFY(q);
810
	PTR_NULLIFY(s0);
811
	PTR_NULLIFY(s1);
812
	PTR_NULLIFY(s0_sig);
813

814
	return ret;
815
}
816

817
int __bign_verify_update(struct ec_verify_context *ctx,
818
			 const u8 *chunk, u32 chunklen, ec_alg_type key_type)
819
{
820
	int ret;
821

822
	/*
823
	 * First, verify context has been initialized and public
824
	 * part too. This guarantees the context is an BIGN
825
	 * verification one and we do not update() or finalize()
826
	 * before init().
827
	 */
828
	ret = sig_verify_check_initialized(ctx); EG(ret, err);
829
	BIGN_VERIFY_CHECK_INITIALIZED(&(ctx->verify_data.bign), ret, err);
830
	/* Do some sanity checks on input params */
831
	ret = pub_key_check_initialized_and_type(ctx->pub_key, key_type); EG(ret, err);
832

833
	/* 2. Compute h = H(m) */
834
	/* Since we call a callback, sanity check our mapping */
835
	ret = hash_mapping_callbacks_sanity_check(ctx->h); EG(ret, err);
836
	ret = ctx->h->hfunc_update(&(ctx->verify_data.bign.h_ctx), chunk, chunklen);
837

838
err:
839
	return ret;
840
}
841

842
int __bign_verify_finalize(struct ec_verify_context *ctx,
843
			    ec_alg_type key_type)
844
{
845
	prj_pt uG, vY;
846
	prj_pt_src_t G, Y;
847
	prj_pt_t W;
848
	u8 hash[MAX_DIGEST_SIZE];
849
	u8 hash_belt[BELT_HASH_DIGEST_SIZE];
850
	u8 t[BIGN_S0_LEN(CURVES_MAX_Q_BIT_LEN)];
851
	u8 FE2OS_W[LOCAL_MAX(2 * BYTECEIL(CURVES_MAX_P_BIT_LEN), 2 * BIGN_S0_LEN(CURVES_MAX_Q_BIT_LEN))];
852
	bitcnt_t p_bit_len, q_bit_len;
853
	nn_src_t q;
854
	nn h, tmp;
855
	nn *s0, *s1;
856
	u8 *s0_sig;
857
	u8 hsize, p_len, l;
858
	belt_hash_context belt_hash_ctx;
859
	int ret, iszero, cmp;
860
	const u8 *oid_ptr = NULL;
861
	u16 oid_len = 0;
862

863
	h.magic = tmp.magic = WORD(0);
864
	uG.magic = vY.magic = WORD(0);
865

866
	/* NOTE: we reuse uG for W to optimize local variables */
867
	W = &uG;
868

869
	/*
870
	 * First, verify context has been initialized and public
871
	 * part too. This guarantees the context is an BIGN
872
	 * verification one and we do not finalize() before init().
873
	 */
874
	ret = sig_verify_check_initialized(ctx); EG(ret, err);
875
	BIGN_VERIFY_CHECK_INITIALIZED(&(ctx->verify_data.bign), ret, err);
876
	/* Do some sanity checks on input params */
877
	ret = pub_key_check_initialized_and_type(ctx->pub_key, key_type); EG(ret, err);
878

879
	/* We check that our additional data is not NULL as it must contain
880
	 * the mandatory external hash OID.
881
	 */
882
	MUST_HAVE((ctx->adata != NULL) && (ctx->adata_len != 0), ret, err);
883

884
	/* Zero init points */
885
	ret = local_memset(&uG, 0, sizeof(prj_pt)); EG(ret, err);
886
	ret = local_memset(&vY, 0, sizeof(prj_pt)); EG(ret, err);
887

888
	/* Make things more readable */
889
	G = &(ctx->pub_key->params->ec_gen);
890
	Y = &(ctx->pub_key->y);
891
	q = &(ctx->pub_key->params->ec_gen_order);
892
	p_bit_len = ctx->pub_key->params->ec_fp.p_bitlen;
893
	q_bit_len = ctx->pub_key->params->ec_gen_order_bitlen;
894
	p_len = (u8)BYTECEIL(p_bit_len);
895
	hsize = ctx->h->digest_size;
896
	s0 = &(ctx->verify_data.bign.s0);
897
	s1 = &(ctx->verify_data.bign.s1);
898
	s0_sig = (u8*)(&(ctx->verify_data.bign.s0_sig));
899

900
	/* Sanity check */
901
	MUST_HAVE((sizeof(t) == sizeof(ctx->verify_data.bign.s0_sig)), ret, err);
902

903
	/* Compute our l that is inherited from q size */
904
	l = (u8)BIGN_S0_LEN(q_bit_len);
905

906
	/* 2. Compute h = H(m) */
907
	/* Since we call a callback, sanity check our mapping */
908
	ret = hash_mapping_callbacks_sanity_check(ctx->h); EG(ret, err);
909
	ret = ctx->h->hfunc_finalize(&(ctx->verify_data.bign.h_ctx), hash); EG(ret, err);
910
	dbg_buf_print("h = H(m)", hash, hsize);
911

912
	/* Import H */
913
	ret = _reverse_endianness(hash, hsize); EG(ret, err);
914
	ret = nn_init_from_buf(&h, hash, hsize); EG(ret, err);
915
	ret = nn_mod(&h, &h, q); EG(ret, err);
916
	/* NOTE: we reverse endianness again of the hash since we will
917
	 * have to use the original value.
918
	 */
919
	ret = _reverse_endianness(hash, hsize); EG(ret, err);
920

921
	/* Compute ((s1_bar + h_bar) mod q) */
922
	ret = nn_mod_add(&h, &h, s1, q); EG(ret, err);
923
	/* Compute (s0_bar + 2**l) mod q */
924
	ret = nn_init(&tmp, 0); EG(ret, err);
925
	ret = nn_one(&tmp); EG(ret, err);
926
	ret = nn_lshift(&tmp, &tmp, (bitcnt_t)(8*l)); EG(ret, err);
927
	ret = nn_mod(&tmp, &tmp, q); EG(ret, err);
928
	ret = nn_mod_add(&tmp, &tmp, s0, q); EG(ret, err);
929

930
	/* 3. Compute ((s1_bar + h_bar) mod q) * G + ((s0_bar + 2**l) mod q) * Y. */
931
	ret = prj_pt_mul(&uG, &h, G); EG(ret, err);
932
	ret = prj_pt_mul(&vY, &tmp, Y); EG(ret, err);
933
	ret = prj_pt_add(W, &uG, &vY); EG(ret, err);
934
	/* 5. If the result is point at infinity, return false. */
935
	ret = prj_pt_iszero(W, &iszero); EG(ret, err);
936
	MUST_HAVE((!iszero), ret, err);
937
	ret = prj_pt_unique(W, W); EG(ret, err);
938

939
	/* 6. Compute t = <BELT-HASH(OID(H) || <<FE2OS(W_x)> || <FE2OS(W_y)>>2*l || H(X))>l */
940
	ret = belt_hash_init(&belt_hash_ctx); EG(ret, err);
941
	ret = bign_get_oid_from_adata(ctx->adata, ctx->adata_len, &oid_ptr, &oid_len); EG(ret, err);
942
	ret = belt_hash_update(&belt_hash_ctx, oid_ptr, oid_len); EG(ret, err);
943
	/**/
944
	ret = local_memset(FE2OS_W, 0, sizeof(FE2OS_W)); EG(ret, err);
945
	ret = fp_export_to_buf(&FE2OS_W[0], p_len, &(W->X)); EG(ret, err);
946
	ret = _reverse_endianness(&FE2OS_W[0], p_len); EG(ret, err);
947
	ret = fp_export_to_buf(&FE2OS_W[p_len], p_len, &(W->Y)); EG(ret, err);
948
	ret = _reverse_endianness(&FE2OS_W[p_len], p_len); EG(ret, err);
949
	/* Only hash the 2*l bytes of FE2OS(W_x) || FE2OS(W_y) */
950
	ret = belt_hash_update(&belt_hash_ctx, &FE2OS_W[0], (u32)(2*l)); EG(ret, err);
951
	/**/
952
	ret = belt_hash_update(&belt_hash_ctx, hash, hsize); EG(ret, err);
953
	/* Store our t */
954
	ret = local_memset(hash_belt, 0, sizeof(hash_belt)); EG(ret, err);
955
	ret = belt_hash_final(&belt_hash_ctx, hash_belt); EG(ret, err);
956
	ret = local_memset(&t[0], 0, l); EG(ret, err);
957
	ret = local_memcpy(&t[0], &hash_belt[0], LOCAL_MIN(l, BELT_HASH_DIGEST_SIZE)); EG(ret, err);
958

959
	/* 10. Accept the signature if and only if t equals s0_sig' */
960
	ret = are_equal(t, s0_sig, l, &cmp); EG(ret, err);
961
	ret = (cmp == 0) ? -1 : 0;
962

963
 err:
964
	prj_pt_uninit(&uG);
965
	prj_pt_uninit(&vY);
966
	nn_uninit(&h);
967
	nn_uninit(&tmp);
968

969
	/*
970
	 * We can now clear data part of the context. This will clear
971
	 * magic and avoid further reuse of the whole context.
972
	 */
973
	if(ctx != NULL){
974
		IGNORE_RET_VAL(local_memset(&(ctx->verify_data.bign), 0, sizeof(bign_verify_data)));
975
	}
976

977
	/* Clean what remains on the stack */
978
	PTR_NULLIFY(G);
979
	PTR_NULLIFY(Y);
980
	PTR_NULLIFY(W);
981
	VAR_ZEROIFY(p_bit_len);
982
	VAR_ZEROIFY(q_bit_len);
983
	VAR_ZEROIFY(p_len);
984
	PTR_NULLIFY(q);
985
	PTR_NULLIFY(s0);
986
	PTR_NULLIFY(s1);
987
	PTR_NULLIFY(s0_sig);
988
	PTR_NULLIFY(oid_ptr);
989
	VAR_ZEROIFY(hsize);
990
	VAR_ZEROIFY(oid_len);
991

992
	return ret;
993
}
994

995
#else /* defined(WITH_SIG_BIGN) || defined(WITH_SIG_DBIGN) */
996

997
/*
998
 * Dummy definition to avoid the empty translation unit ISO C warning
999
 */
1000
typedef int dummy;
1001
#endif /* WITH_SIG_BIGN */
1002

1003
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