File Coverage

src/ec/ecdsa_i15_vrfy_raw.c

Criterion	Covered	Total	%
statement	0	50	0.0
branch	0	12	0.0
condition			n/a
subroutine			n/a
pod			n/a
total	0	62	0.0

line	stmt	bran	code
1			/*
2			* Copyright (c) 2017 Thomas Pornin
3			*
4			* Permission is hereby granted, free of charge, to any person obtaining
5			* a copy of this software and associated documentation files (the
6			* "Software"), to deal in the Software without restriction, including
7			* without limitation the rights to use, copy, modify, merge, publish,
8			* distribute, sublicense, and/or sell copies of the Software, and to
9			* permit persons to whom the Software is furnished to do so, subject to
10			* the following conditions:
11			*
12			* The above copyright notice and this permission notice shall be
13			* included in all copies or substantial portions of the Software.
14			*
15			* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
16			* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
17			* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND
18			* NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS
19			* BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN
20			* ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN
21			* CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
22			* SOFTWARE.
23			*/
24
25			#include "inner.h"
26
27			#define I15_LEN ((BR_MAX_EC_SIZE + 29) / 15)
28			#define POINT_LEN (1 + (((BR_MAX_EC_SIZE + 7) >> 3) << 1))
29
30			/* see bearssl_ec.h */
31			uint32_t
32	0		br_ecdsa_i15_vrfy_raw(const br_ec_impl *impl,
33			const void *hash, size_t hash_len,
34			const br_ec_public_key *pk,
35			const void *sig, size_t sig_len)
36			{
37			/*
38			* IMPORTANT: this code is fit only for curves with a prime
39			* order. This is needed so that modular reduction of the X
40			* coordinate of a point can be done with a simple subtraction.
41			*/
42			const br_ec_curve_def *cd;
43			uint16_t n[I15_LEN], r[I15_LEN], s[I15_LEN], t1[I15_LEN], t2[I15_LEN];
44			unsigned char tx[(BR_MAX_EC_SIZE + 7) >> 3];
45			unsigned char ty[(BR_MAX_EC_SIZE + 7) >> 3];
46			unsigned char eU[POINT_LEN];
47			size_t nlen, rlen, ulen;
48			uint16_t n0i;
49			uint32_t res;
50
51			/*
52			* If the curve is not supported, then report an error.
53			*/
54	0	0	if (((impl->supported_curves >> pk->curve) & 1) == 0) {
55	0		return 0;
56			}
57
58			/*
59			* Get the curve parameters (generator and order).
60			*/
61	0		switch (pk->curve) {
62	0		case BR_EC_secp256r1:
63	0		cd = &br_secp256r1;
64	0		break;
65	0		case BR_EC_secp384r1:
66	0		cd = &br_secp384r1;
67	0		break;
68	0		case BR_EC_secp521r1:
69	0		cd = &br_secp521r1;
70	0		break;
71	0		default:
72	0		return 0;
73			}
74
75			/*
76			* Signature length must be even.
77			*/
78	0	0	if (sig_len & 1) {
79	0		return 0;
80			}
81	0		rlen = sig_len >> 1;
82
83			/*
84			* Public key point must have the proper size for this curve.
85			*/
86	0	0	if (pk->qlen != cd->generator_len) {
87	0		return 0;
88			}
89
90			/*
91			* Get modulus; then decode the r and s values. They must be
92			* lower than the modulus, and s must not be null.
93			*/
94	0		nlen = cd->order_len;
95	0		br_i15_decode(n, cd->order, nlen);
96	0		n0i = br_i15_ninv15(n[1]);
97	0	0	if (!br_i15_decode_mod(r, sig, rlen, n)) {
98	0		return 0;
99			}
100	0	0	if (!br_i15_decode_mod(s, (const unsigned char *)sig + rlen, rlen, n)) {
101	0		return 0;
102			}
103	0	0	if (br_i15_iszero(s)) {
104	0		return 0;
105			}
106
107			/*
108			* Invert s. We do that with a modular exponentiation; we use
109			* the fact that for all the curves we support, the least
110			* significant byte is not 0 or 1, so we can subtract 2 without
111			* any carry to process.
112			* We also want 1/s in Montgomery representation, which can be
113			* done by converting _from_ Montgomery representation before
114			* the inversion (because (1/s)*R = 1/(s/R)).
115			*/
116	0		br_i15_from_monty(s, n, n0i);
117	0		memcpy(tx, cd->order, nlen);
118	0		tx[nlen - 1] -= 2;
119	0		br_i15_modpow(s, tx, nlen, n, n0i, t1, t2);
120
121			/*
122			* Truncate the hash to the modulus length (in bits) and reduce
123			* it modulo the curve order. The modular reduction can be done
124			* with a subtraction since the truncation already reduced the
125			* value to the modulus bit length.
126			*/
127	0		br_ecdsa_i15_bits2int(t1, hash, hash_len, n[0]);
128	0		br_i15_sub(t1, n, br_i15_sub(t1, n, 0) ^ 1);
129
130			/*
131			* Multiply the (truncated, reduced) hash value with 1/s, result in
132			* t2, encoded in ty.
133			*/
134	0		br_i15_montymul(t2, t1, s, n, n0i);
135	0		br_i15_encode(ty, nlen, t2);
136
137			/*
138			* Multiply r with 1/s, result in t1, encoded in tx.
139			*/
140	0		br_i15_montymul(t1, r, s, n, n0i);
141	0		br_i15_encode(tx, nlen, t1);
142
143			/*
144			* Compute the point xQ + yG.
145			*/
146	0		ulen = cd->generator_len;
147	0		memcpy(eU, pk->q, ulen);
148	0		res = impl->muladd(eU, NULL, ulen,
149	0		tx, nlen, ty, nlen, cd->curve);
150
151			/*
152			* Get the X coordinate, reduce modulo the curve order, and
153			* compare with the 'r' value.
154			*
155			* The modular reduction can be done with subtractions because
156			* we work with curves of prime order, so the curve order is
157			* close to the field order (Hasse's theorem).
158			*/
159	0		br_i15_zero(t1, n[0]);
160	0		br_i15_decode(t1, &eU[1], ulen >> 1);
161	0		t1[0] = n[0];
162	0		br_i15_sub(t1, n, br_i15_sub(t1, n, 0) ^ 1);
163	0		res &= ~br_i15_sub(t1, r, 1);
164	0		res &= br_i15_iszero(t1);
165	0		return res;
166			}