File Coverage

src/rsa/rsa_i15_priv.c

Criterion	Covered	Total	%
statement	0	61	0.0
branch	0	16	0.0
condition			n/a
subroutine			n/a
pod			n/a
total	0	77	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 U (2 + ((BR_MAX_RSA_FACTOR + 14) / 15))
28			#define TLEN (8 * U)
29
30			/* see bearssl_rsa.h */
31			uint32_t
32	0		br_rsa_i15_private(unsigned char x, const br_rsa_private_key sk)
33			{
34			const unsigned char p, q;
35			size_t plen, qlen;
36			size_t fwlen;
37			uint16_t p0i, q0i;
38			size_t xlen, u;
39			uint16_t tmp[1 + TLEN];
40			long z;
41			uint16_t mp, mq, s1, s2, t1, t2, *t3;
42			uint32_t r;
43
44			/*
45			* Compute the actual lengths of p and q, in bytes.
46			* These lengths are not considered secret (we cannot really hide
47			* them anyway in constant-time code).
48			*/
49	0		p = sk->p;
50	0		plen = sk->plen;
51	0	0	while (plen > 0 && *p == 0) {
		0
52	0		p ++;
53	0		plen --;
54			}
55	0		q = sk->q;
56	0		qlen = sk->qlen;
57	0	0	while (qlen > 0 && *q == 0) {
		0
58	0		q ++;
59	0		qlen --;
60			}
61
62			/*
63			* Compute the maximum factor length, in words.
64			*/
65	0		z = (long)(plen > qlen ? plen : qlen) << 3;
66	0		fwlen = 1;
67	0	0	while (z > 0) {
68	0		z -= 15;
69	0		fwlen ++;
70			}
71			/*
72			* Round up the word length to an even number.
73			*/
74	0		fwlen += (fwlen & 1);
75
76			/*
77			* We need to fit at least 6 values in the stack buffer.
78			*/
79	0	0	if (6 * fwlen > TLEN) {
80	0		return 0;
81			}
82
83			/*
84			* Compute signature length (in bytes).
85			*/
86	0		xlen = (sk->n_bitlen + 7) >> 3;
87
88			/*
89			* Ensure 32-bit alignment for value words.
90			*/
91	0		mq = tmp;
92	0	0	if (((uintptr_t)mq & 2) == 0) {
93	0		mq ++;
94			}
95
96			/*
97			* Decode q.
98			*/
99	0		br_i15_decode(mq, q, qlen);
100
101			/*
102			* Decode p.
103			*/
104	0		t1 = mq + fwlen;
105	0		br_i15_decode(t1, p, plen);
106
107			/*
108			* Compute the modulus (product of the two factors), to compare
109			* it with the source value. We use br_i15_mulacc(), since it's
110			* already used later on.
111			*/
112	0		t2 = mq + 2 * fwlen;
113	0		br_i15_zero(t2, mq[0]);
114	0		br_i15_mulacc(t2, mq, t1);
115
116			/*
117			* We encode the modulus into bytes, to perform the comparison
118			* with bytes. We know that the product length, in bytes, is
119			* exactly xlen.
120			* The comparison actually computes the carry when subtracting
121			* the modulus from the source value; that carry must be 1 for
122			* a value in the correct range. We keep it in r, which is our
123			* accumulator for the error code.
124			*/
125	0		t3 = mq + 4 * fwlen;
126	0		br_i15_encode(t3, xlen, t2);
127	0		u = xlen;
128	0		r = 0;
129	0	0	while (u > 0) {
130			uint32_t wn, wx;
131
132	0		u --;
133	0		wn = ((unsigned char *)t3)[u];
134	0		wx = x[u];
135	0		r = ((wx - (wn + r)) >> 8) & 1;
136			}
137
138			/*
139			* Move the decoded p to another temporary buffer.
140			*/
141	0		mp = mq + 2 * fwlen;
142	0		memmove(mp, t1, fwlen * sizeof *t1);
143
144			/*
145			* Compute s2 = x^dq mod q.
146			*/
147	0		q0i = br_i15_ninv15(mq[1]);
148	0		s2 = mq + fwlen;
149	0		br_i15_decode_reduce(s2, x, xlen, mq);
150	0		r &= br_i15_modpow_opt(s2, sk->dq, sk->dqlen, mq, q0i,
151	0		mq + 3 * fwlen, TLEN - 3 * fwlen);
152
153			/*
154			* Compute s1 = x^dq mod q.
155			*/
156	0		p0i = br_i15_ninv15(mp[1]);
157	0		s1 = mq + 3 * fwlen;
158	0		br_i15_decode_reduce(s1, x, xlen, mp);
159	0		r &= br_i15_modpow_opt(s1, sk->dp, sk->dplen, mp, p0i,
160	0		mq + 4 * fwlen, TLEN - 4 * fwlen);
161
162			/*
163			* Compute:
164			* h = (s1 - s2)*(1/q) mod p
165			* s1 is an integer modulo p, but s2 is modulo q. PKCS#1 is
166			* unclear about whether p may be lower than q (some existing,
167			* widely deployed implementations of RSA don't tolerate p < q),
168			* but we want to support that occurrence, so we need to use the
169			* reduction function.
170			*
171			* Since we use br_i15_decode_reduce() for iq (purportedly, the
172			* inverse of q modulo p), we also tolerate improperly large
173			* values for this parameter.
174			*/
175	0		t1 = mq + 4 * fwlen;
176	0		t2 = mq + 5 * fwlen;
177	0		br_i15_reduce(t2, s2, mp);
178	0		br_i15_add(s1, mp, br_i15_sub(s1, t2, 1));
179	0		br_i15_to_monty(s1, mp);
180	0		br_i15_decode_reduce(t1, sk->iq, sk->iqlen, mp);
181	0		br_i15_montymul(t2, s1, t1, mp, p0i);
182
183			/*
184			* h is now in t2. We compute the final result:
185			* s = s2 + q*h
186			* All these operations are non-modular.
187			*
188			* We need mq, s2 and t2. We use the t3 buffer as destination.
189			* The buffers mp, s1 and t1 are no longer needed, so we can
190			* reuse them for t3. Moreover, the first step of the computation
191			* is to copy s2 into t3, after which s2 is not needed. Right
192			* now, mq is in slot 0, s2 is in slot 1, and t2 in slot 5.
193			* Therefore, we have ample room for t3 by simply using s2.
194			*/
195	0		t3 = s2;
196	0		br_i15_mulacc(t3, mq, t2);
197
198			/*
199			* Encode the result. Since we already checked the value of xlen,
200			* we can just use it right away.
201			*/
202	0		br_i15_encode(x, xlen, t3);
203
204			/*
205			* The only error conditions remaining at that point are invalid
206			* values for p and q (even integers).
207			*/
208	0		return p0i & q0i & r;
209			}