File Coverage

src/rsa/rsa_i15_pubexp.c

Criterion	Covered	Total	%
statement	0	38	0.0
branch	0	30	0.0
condition			n/a
subroutine			n/a
pod			n/a
total	0	68	0.0

line	stmt	bran	code
1			/*
2			* Copyright (c) 2018 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			/*
28			* Recompute public exponent, based on factor p and reduced private
29			* exponent dp.
30			*/
31			static uint32_t
32	0		get_pubexp(const unsigned char *pbuf, size_t plen,
33			const unsigned char *dpbuf, size_t dplen)
34			{
35			/*
36			* dp is the inverse of e modulo p-1. If p = 3 mod 4, then
37			* p-1 = 2*((p-1)/2). Taken modulo 2, e is odd and has inverse 1;
38			* thus, dp must be odd.
39			*
40			* We compute the inverse of dp modulo (p-1)/2. This requires
41			* first reducing dp modulo (p-1)/2 (this can be done with a
42			* conditional subtract, no need to use the generic modular
43			* reduction function); then, we use moddiv.
44			*/
45
46			uint16_t tmp[6 * ((BR_MAX_RSA_FACTOR + 29) / 15)];
47			uint16_t p, dp, *x;
48			size_t len;
49			uint32_t e;
50
51			/*
52			* Compute actual factor length (in bytes) and check that it fits
53			* under our size constraints.
54			*/
55	0	0	while (plen > 0 && *pbuf == 0) {
		0
56	0		pbuf ++;
57	0		plen --;
58			}
59	0	0	if (plen == 0 \|\| plen < 5 \|\| plen > (BR_MAX_RSA_FACTOR / 8)) {
		0
		0
60	0		return 0;
61			}
62
63			/*
64			* Compute actual reduced exponent length (in bytes) and check that
65			* it is not longer than p.
66			*/
67	0	0	while (dplen > 0 && *dpbuf == 0) {
		0
68	0		dpbuf ++;
69	0		dplen --;
70			}
71	0	0	if (dplen > plen \|\| dplen == 0
		0
72	0	0	\|\| (dplen == plen && dpbuf[0] > pbuf[0]))
		0
73			{
74	0		return 0;
75			}
76
77			/*
78			* Verify that p = 3 mod 4 and that dp is odd.
79			*/
80	0	0	if ((pbuf[plen - 1] & 3) != 3 \|\| (dpbuf[dplen - 1] & 1) != 1) {
		0
81	0		return 0;
82			}
83
84			/*
85			* Decode p and compute (p-1)/2.
86			*/
87	0		p = tmp;
88	0		br_i15_decode(p, pbuf, plen);
89	0		len = (p[0] + 31) >> 4;
90	0		br_i15_rshift(p, 1);
91
92			/*
93			* Decode dp and make sure its announced bit length matches that of
94			* p (we already know that the size of dp, in bits, does not exceed
95			* the size of p, so we just have to copy the header word).
96			*/
97	0		dp = p + len;
98	0		memset(dp, 0, len * sizeof *dp);
99	0		br_i15_decode(dp, dpbuf, dplen);
100	0		dp[0] = p[0];
101
102			/*
103			* Subtract (p-1)/2 from dp if necessary.
104			*/
105	0		br_i15_sub(dp, p, NOT(br_i15_sub(dp, p, 0)));
106
107			/*
108			* If another subtraction is needed, then this means that the
109			* value was invalid. We don't care to leak information about
110			* invalid keys.
111			*/
112	0	0	if (br_i15_sub(dp, p, 0) == 0) {
113	0		return 0;
114			}
115
116			/*
117			* Invert dp modulo (p-1)/2. If the inversion fails, then the
118			* key value was invalid.
119			*/
120	0		x = dp + len;
121	0		br_i15_zero(x, p[0]);
122	0		x[1] = 1;
123	0	0	if (br_i15_moddiv(x, dp, p, br_i15_ninv15(p[1]), x + len) == 0) {
124	0		return 0;
125			}
126
127			/*
128			* We now have an inverse. We must set it to zero (error) if its
129			* length is greater than 32 bits and/or if it is an even integer.
130			* Take care that the bit_length function returns an encoded
131			* bit length.
132			*/
133	0		e = (uint32_t)x[1] \| ((uint32_t)x[2] << 15) \| ((uint32_t)x[3] << 30);
134	0		e &= -LT(br_i15_bit_length(x + 1, len - 1), 35);
135	0		e &= -(e & 1);
136	0		return e;
137			}
138
139			/* see bearssl_rsa.h */
140			uint32_t
141	0		br_rsa_i15_compute_pubexp(const br_rsa_private_key *sk)
142			{
143			/*
144			* Get the public exponent from both p and q. This is the right
145			* exponent if we get twice the same value.
146			*/
147			uint32_t ep, eq;
148
149	0		ep = get_pubexp(sk->p, sk->plen, sk->dp, sk->dplen);
150	0		eq = get_pubexp(sk->q, sk->qlen, sk->dq, sk->dqlen);
151	0		return ep & -EQ(ep, eq);
152			}