/[smecontribs]/rpms/openssl3/contribs10/0102-CVE-2022-4304-RSA-time-oracle.patch
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Contents of /rpms/openssl3/contribs10/0102-CVE-2022-4304-RSA-time-oracle.patch

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Revision 1.1 - (show annotations) (download)
Wed Jan 31 17:24:50 2024 UTC (9 months, 4 weeks ago) by jpp
Branch: MAIN
CVS Tags: openssl3-3_0_7-5_el7_sme_1, HEAD
Initial import

1 From 8e257b86e5812c6e1cfa9e8e5f5660ac7bed899d Mon Sep 17 00:00:00 2001
2 From: Dmitry Belyavskiy <beldmit@gmail.com>
3 Date: Fri, 20 Jan 2023 15:03:40 +0000
4 Subject: [PATCH 03/18] Fix Timing Oracle in RSA decryption
5
6 A timing based side channel exists in the OpenSSL RSA Decryption
7 implementation which could be sufficient to recover a plaintext across
8 a network in a Bleichenbacher style attack. To achieve a successful
9 decryption an attacker would have to be able to send a very large number
10 of trial messages for decryption. The vulnerability affects all RSA
11 padding modes: PKCS#1 v1.5, RSA-OEAP and RSASVE.
12
13 Patch written by Dmitry Belyavsky and Hubert Kario
14
15 CVE-2022-4304
16
17 Reviewed-by: Matt Caswell <matt@openssl.org>
18 Reviewed-by: Tomas Mraz <tomas@openssl.org>
19 ---
20 crypto/bn/bn_blind.c | 14 -
21 crypto/bn/bn_local.h | 14 +
22 crypto/bn/build.info | 2 +-
23 crypto/bn/rsa_sup_mul.c | 604 ++++++++++++++++++++++++++++++++++++++++
24 crypto/rsa/rsa_ossl.c | 19 +-
25 include/crypto/bn.h | 6 +
26 6 files changed, 638 insertions(+), 21 deletions(-)
27 create mode 100644 crypto/bn/rsa_sup_mul.c
28
29 diff --git a/crypto/bn/bn_blind.c b/crypto/bn/bn_blind.c
30 index 72457b34cf..6061ebb4c0 100644
31 --- a/crypto/bn/bn_blind.c
32 +++ b/crypto/bn/bn_blind.c
33 @@ -13,20 +13,6 @@
34
35 #define BN_BLINDING_COUNTER 32
36
37 -struct bn_blinding_st {
38 - BIGNUM *A;
39 - BIGNUM *Ai;
40 - BIGNUM *e;
41 - BIGNUM *mod; /* just a reference */
42 - CRYPTO_THREAD_ID tid;
43 - int counter;
44 - unsigned long flags;
45 - BN_MONT_CTX *m_ctx;
46 - int (*bn_mod_exp) (BIGNUM *r, const BIGNUM *a, const BIGNUM *p,
47 - const BIGNUM *m, BN_CTX *ctx, BN_MONT_CTX *m_ctx);
48 - CRYPTO_RWLOCK *lock;
49 -};
50 -
51 BN_BLINDING *BN_BLINDING_new(const BIGNUM *A, const BIGNUM *Ai, BIGNUM *mod)
52 {
53 BN_BLINDING *ret = NULL;
54 diff --git a/crypto/bn/bn_local.h b/crypto/bn/bn_local.h
55 index c9a7ecf298..8c428f919d 100644
56 --- a/crypto/bn/bn_local.h
57 +++ b/crypto/bn/bn_local.h
58 @@ -290,6 +290,20 @@ struct bn_gencb_st {
59 } cb;
60 };
61
62 +struct bn_blinding_st {
63 + BIGNUM *A;
64 + BIGNUM *Ai;
65 + BIGNUM *e;
66 + BIGNUM *mod; /* just a reference */
67 + CRYPTO_THREAD_ID tid;
68 + int counter;
69 + unsigned long flags;
70 + BN_MONT_CTX *m_ctx;
71 + int (*bn_mod_exp) (BIGNUM *r, const BIGNUM *a, const BIGNUM *p,
72 + const BIGNUM *m, BN_CTX *ctx, BN_MONT_CTX *m_ctx);
73 + CRYPTO_RWLOCK *lock;
74 +};
75 +
76 /*-
77 * BN_window_bits_for_exponent_size -- macro for sliding window mod_exp functions
78 *
79 diff --git a/crypto/bn/build.info b/crypto/bn/build.info
80 index c4ba51b265..f4ff619239 100644
81 --- a/crypto/bn/build.info
82 +++ b/crypto/bn/build.info
83 @@ -105,7 +105,7 @@ $COMMON=bn_add.c bn_div.c bn_exp.c bn_lib.c bn_ctx.c bn_mul.c \
84 bn_mod.c bn_conv.c bn_rand.c bn_shift.c bn_word.c bn_blind.c \
85 bn_kron.c bn_sqrt.c bn_gcd.c bn_prime.c bn_sqr.c \
86 bn_recp.c bn_mont.c bn_mpi.c bn_exp2.c bn_gf2m.c bn_nist.c \
87 - bn_intern.c bn_dh.c bn_rsa_fips186_4.c bn_const.c
88 + bn_intern.c bn_dh.c bn_rsa_fips186_4.c bn_const.c rsa_sup_mul.c
89 SOURCE[../../libcrypto]=$COMMON $BNASM bn_print.c bn_err.c bn_srp.c
90 DEFINE[../../libcrypto]=$BNDEF
91 IF[{- !$disabled{'deprecated-0.9.8'} -}]
92 diff --git a/crypto/bn/rsa_sup_mul.c b/crypto/bn/rsa_sup_mul.c
93 new file mode 100644
94 index 0000000000..0e0d02e194
95 --- /dev/null
96 +++ b/crypto/bn/rsa_sup_mul.c
97 @@ -0,0 +1,604 @@
98 +#include <openssl/e_os2.h>
99 +#include <stddef.h>
100 +#include <sys/types.h>
101 +#include <string.h>
102 +#include <openssl/bn.h>
103 +#include <openssl/err.h>
104 +#include <openssl/rsaerr.h>
105 +#include "internal/endian.h"
106 +#include "internal/numbers.h"
107 +#include "internal/constant_time.h"
108 +#include "bn_local.h"
109 +
110 +# if BN_BYTES == 8
111 +typedef uint64_t limb_t;
112 +# if defined(__SIZEOF_INT128__) && __SIZEOF_INT128__ == 16
113 +typedef uint128_t limb2_t;
114 +# define HAVE_LIMB2_T
115 +# endif
116 +# define LIMB_BIT_SIZE 64
117 +# define LIMB_BYTE_SIZE 8
118 +# elif BN_BYTES == 4
119 +typedef uint32_t limb_t;
120 +typedef uint64_t limb2_t;
121 +# define LIMB_BIT_SIZE 32
122 +# define LIMB_BYTE_SIZE 4
123 +# define HAVE_LIMB2_T
124 +# else
125 +# error "Not supported"
126 +# endif
127 +
128 +/*
129 + * For multiplication we're using schoolbook multiplication,
130 + * so if we have two numbers, each with 6 "digits" (words)
131 + * the multiplication is calculated as follows:
132 + * A B C D E F
133 + * x I J K L M N
134 + * --------------
135 + * N*F
136 + * N*E
137 + * N*D
138 + * N*C
139 + * N*B
140 + * N*A
141 + * M*F
142 + * M*E
143 + * M*D
144 + * M*C
145 + * M*B
146 + * M*A
147 + * L*F
148 + * L*E
149 + * L*D
150 + * L*C
151 + * L*B
152 + * L*A
153 + * K*F
154 + * K*E
155 + * K*D
156 + * K*C
157 + * K*B
158 + * K*A
159 + * J*F
160 + * J*E
161 + * J*D
162 + * J*C
163 + * J*B
164 + * J*A
165 + * I*F
166 + * I*E
167 + * I*D
168 + * I*C
169 + * I*B
170 + * + I*A
171 + * ==========================
172 + * N*B N*D N*F
173 + * + N*A N*C N*E
174 + * + M*B M*D M*F
175 + * + M*A M*C M*E
176 + * + L*B L*D L*F
177 + * + L*A L*C L*E
178 + * + K*B K*D K*F
179 + * + K*A K*C K*E
180 + * + J*B J*D J*F
181 + * + J*A J*C J*E
182 + * + I*B I*D I*F
183 + * + I*A I*C I*E
184 + *
185 + * 1+1 1+3 1+5
186 + * 1+0 1+2 1+4
187 + * 0+1 0+3 0+5
188 + * 0+0 0+2 0+4
189 + *
190 + * 0 1 2 3 4 5 6
191 + * which requires n^2 multiplications and 2n full length additions
192 + * as we can keep every other result of limb multiplication in two separate
193 + * limbs
194 + */
195 +
196 +#if defined HAVE_LIMB2_T
197 +static ossl_inline void _mul_limb(limb_t *hi, limb_t *lo, limb_t a, limb_t b)
198 +{
199 + limb2_t t;
200 + /*
201 + * this is idiomatic code to tell compiler to use the native mul
202 + * those three lines will actually compile to single instruction
203 + */
204 +
205 + t = (limb2_t)a * b;
206 + *hi = t >> LIMB_BIT_SIZE;
207 + *lo = (limb_t)t;
208 +}
209 +#elif (BN_BYTES == 8) && (defined _MSC_VER)
210 +/* https://learn.microsoft.com/en-us/cpp/intrinsics/umul128?view=msvc-170 */
211 +#pragma intrinsic(_umul128)
212 +static ossl_inline void _mul_limb(limb_t *hi, limb_t *lo, limb_t a, limb_t b)
213 +{
214 + *lo = _umul128(a, b, hi);
215 +}
216 +#else
217 +/*
218 + * if the compiler doesn't have either a 128bit data type nor a "return
219 + * high 64 bits of multiplication"
220 + */
221 +static ossl_inline void _mul_limb(limb_t *hi, limb_t *lo, limb_t a, limb_t b)
222 +{
223 + limb_t a_low = (limb_t)(uint32_t)a;
224 + limb_t a_hi = a >> 32;
225 + limb_t b_low = (limb_t)(uint32_t)b;
226 + limb_t b_hi = b >> 32;
227 +
228 + limb_t p0 = a_low * b_low;
229 + limb_t p1 = a_low * b_hi;
230 + limb_t p2 = a_hi * b_low;
231 + limb_t p3 = a_hi * b_hi;
232 +
233 + uint32_t cy = (uint32_t)(((p0 >> 32) + (uint32_t)p1 + (uint32_t)p2) >> 32);
234 +
235 + *lo = p0 + (p1 << 32) + (p2 << 32);
236 + *hi = p3 + (p1 >> 32) + (p2 >> 32) + cy;
237 +}
238 +#endif
239 +
240 +/* add two limbs with carry in, return carry out */
241 +static ossl_inline limb_t _add_limb(limb_t *ret, limb_t a, limb_t b, limb_t carry)
242 +{
243 + limb_t carry1, carry2, t;
244 + /*
245 + * `c = a + b; if (c < a)` is idiomatic code that makes compilers
246 + * use add with carry on assembly level
247 + */
248 +
249 + *ret = a + carry;
250 + if (*ret < a)
251 + carry1 = 1;
252 + else
253 + carry1 = 0;
254 +
255 + t = *ret;
256 + *ret = t + b;
257 + if (*ret < t)
258 + carry2 = 1;
259 + else
260 + carry2 = 0;
261 +
262 + return carry1 + carry2;
263 +}
264 +
265 +/*
266 + * add two numbers of the same size, return overflow
267 + *
268 + * add a to b, place result in ret; all arrays need to be n limbs long
269 + * return overflow from addition (0 or 1)
270 + */
271 +static ossl_inline limb_t add(limb_t *ret, limb_t *a, limb_t *b, size_t n)
272 +{
273 + limb_t c = 0;
274 + ossl_ssize_t i;
275 +
276 + for(i = n - 1; i > -1; i--)
277 + c = _add_limb(&ret[i], a[i], b[i], c);
278 +
279 + return c;
280 +}
281 +
282 +/*
283 + * return number of limbs necessary for temporary values
284 + * when multiplying numbers n limbs large
285 + */
286 +static ossl_inline size_t mul_limb_numb(size_t n)
287 +{
288 + return 2 * n * 2;
289 +}
290 +
291 +/*
292 + * multiply two numbers of the same size
293 + *
294 + * multiply a by b, place result in ret; a and b need to be n limbs long
295 + * ret needs to be 2*n limbs long, tmp needs to be mul_limb_numb(n) limbs
296 + * long
297 + */
298 +static void limb_mul(limb_t *ret, limb_t *a, limb_t *b, size_t n, limb_t *tmp)
299 +{
300 + limb_t *r_odd, *r_even;
301 + size_t i, j, k;
302 +
303 + r_odd = tmp;
304 + r_even = &tmp[2 * n];
305 +
306 + memset(ret, 0, 2 * n * sizeof(limb_t));
307 +
308 + for (i = 0; i < n; i++) {
309 + for (k = 0; k < i + n + 1; k++) {
310 + r_even[k] = 0;
311 + r_odd[k] = 0;
312 + }
313 + for (j = 0; j < n; j++) {
314 + /*
315 + * place results from even and odd limbs in separate arrays so that
316 + * we don't have to calculate overflow every time we get individual
317 + * limb multiplication result
318 + */
319 + if (j % 2 == 0)
320 + _mul_limb(&r_even[i + j], &r_even[i + j + 1], a[i], b[j]);
321 + else
322 + _mul_limb(&r_odd[i + j], &r_odd[i + j + 1], a[i], b[j]);
323 + }
324 + /*
325 + * skip the least significant limbs when adding multiples of
326 + * more significant limbs (they're zero anyway)
327 + */
328 + add(ret, ret, r_even, n + i + 1);
329 + add(ret, ret, r_odd, n + i + 1);
330 + }
331 +}
332 +
333 +/* modifies the value in place by performing a right shift by one bit */
334 +static ossl_inline void rshift1(limb_t *val, size_t n)
335 +{
336 + limb_t shift_in = 0, shift_out = 0;
337 + size_t i;
338 +
339 + for (i = 0; i < n; i++) {
340 + shift_out = val[i] & 1;
341 + val[i] = shift_in << (LIMB_BIT_SIZE - 1) | (val[i] >> 1);
342 + shift_in = shift_out;
343 + }
344 +}
345 +
346 +/* extend the LSB of flag to all bits of limb */
347 +static ossl_inline limb_t mk_mask(limb_t flag)
348 +{
349 + flag |= flag << 1;
350 + flag |= flag << 2;
351 + flag |= flag << 4;
352 + flag |= flag << 8;
353 + flag |= flag << 16;
354 +#if (LIMB_BYTE_SIZE == 8)
355 + flag |= flag << 32;
356 +#endif
357 + return flag;
358 +}
359 +
360 +/*
361 + * copy from either a or b to ret based on flag
362 + * when flag == 0, then copies from b
363 + * when flag == 1, then copies from a
364 + */
365 +static ossl_inline void cselect(limb_t flag, limb_t *ret, limb_t *a, limb_t *b, size_t n)
366 +{
367 + /*
368 + * would be more efficient with non volatile mask, but then gcc
369 + * generates code with jumps
370 + */
371 + volatile limb_t mask;
372 + size_t i;
373 +
374 + mask = mk_mask(flag);
375 + for (i = 0; i < n; i++) {
376 +#if (LIMB_BYTE_SIZE == 8)
377 + ret[i] = constant_time_select_64(mask, a[i], b[i]);
378 +#else
379 + ret[i] = constant_time_select_32(mask, a[i], b[i]);
380 +#endif
381 + }
382 +}
383 +
384 +static limb_t _sub_limb(limb_t *ret, limb_t a, limb_t b, limb_t borrow)
385 +{
386 + limb_t borrow1, borrow2, t;
387 + /*
388 + * while it doesn't look constant-time, this is idiomatic code
389 + * to tell compilers to use the carry bit from subtraction
390 + */
391 +
392 + *ret = a - borrow;
393 + if (*ret > a)
394 + borrow1 = 1;
395 + else
396 + borrow1 = 0;
397 +
398 + t = *ret;
399 + *ret = t - b;
400 + if (*ret > t)
401 + borrow2 = 1;
402 + else
403 + borrow2 = 0;
404 +
405 + return borrow1 + borrow2;
406 +}
407 +
408 +/*
409 + * place the result of a - b into ret, return the borrow bit.
410 + * All arrays need to be n limbs long
411 + */
412 +static limb_t sub(limb_t *ret, limb_t *a, limb_t *b, size_t n)
413 +{
414 + limb_t borrow = 0;
415 + ossl_ssize_t i;
416 +
417 + for (i = n - 1; i > -1; i--)
418 + borrow = _sub_limb(&ret[i], a[i], b[i], borrow);
419 +
420 + return borrow;
421 +}
422 +
423 +/* return the number of limbs necessary to allocate for the mod() tmp operand */
424 +static ossl_inline size_t mod_limb_numb(size_t anum, size_t modnum)
425 +{
426 + return (anum + modnum) * 3;
427 +}
428 +
429 +/*
430 + * calculate a % mod, place the result in ret
431 + * size of a is defined by anum, size of ret and mod is modnum,
432 + * size of tmp is returned by mod_limb_numb()
433 + */
434 +static void mod(limb_t *ret, limb_t *a, size_t anum, limb_t *mod,
435 + size_t modnum, limb_t *tmp)
436 +{
437 + limb_t *atmp, *modtmp, *rettmp;
438 + limb_t res;
439 + size_t i;
440 +
441 + memset(tmp, 0, mod_limb_numb(anum, modnum) * LIMB_BYTE_SIZE);
442 +
443 + atmp = tmp;
444 + modtmp = &tmp[anum + modnum];
445 + rettmp = &tmp[(anum + modnum) * 2];
446 +
447 + for (i = modnum; i <modnum + anum; i++)
448 + atmp[i] = a[i-modnum];
449 +
450 + for (i = 0; i < modnum; i++)
451 + modtmp[i] = mod[i];
452 +
453 + for (i = 0; i < anum * LIMB_BIT_SIZE; i++) {
454 + rshift1(modtmp, anum + modnum);
455 + res = sub(rettmp, atmp, modtmp, anum+modnum);
456 + cselect(res, atmp, atmp, rettmp, anum+modnum);
457 + }
458 +
459 + memcpy(ret, &atmp[anum], sizeof(limb_t) * modnum);
460 +}
461 +
462 +/* necessary size of tmp for a _mul_add_limb() call with provided anum */
463 +static ossl_inline size_t _mul_add_limb_numb(size_t anum)
464 +{
465 + return 2 * (anum + 1);
466 +}
467 +
468 +/* multiply a by m, add to ret, return carry */
469 +static limb_t _mul_add_limb(limb_t *ret, limb_t *a, size_t anum,
470 + limb_t m, limb_t *tmp)
471 +{
472 + limb_t carry = 0;
473 + limb_t *r_odd, *r_even;
474 + size_t i;
475 +
476 + memset(tmp, 0, sizeof(limb_t) * (anum + 1) * 2);
477 +
478 + r_odd = tmp;
479 + r_even = &tmp[anum + 1];
480 +
481 + for (i = 0; i < anum; i++) {
482 + /*
483 + * place the results from even and odd limbs in separate arrays
484 + * so that we have to worry about carry just once
485 + */
486 + if (i % 2 == 0)
487 + _mul_limb(&r_even[i], &r_even[i + 1], a[i], m);
488 + else
489 + _mul_limb(&r_odd[i], &r_odd[i + 1], a[i], m);
490 + }
491 + /* assert: add() carry here will be equal zero */
492 + add(r_even, r_even, r_odd, anum + 1);
493 + /*
494 + * while here it will not overflow as the max value from multiplication
495 + * is -2 while max overflow from addition is 1, so the max value of
496 + * carry is -1 (i.e. max int)
497 + */
498 + carry = add(ret, ret, &r_even[1], anum) + r_even[0];
499 +
500 + return carry;
501 +}
502 +
503 +static ossl_inline size_t mod_montgomery_limb_numb(size_t modnum)
504 +{
505 + return modnum * 2 + _mul_add_limb_numb(modnum);
506 +}
507 +
508 +/*
509 + * calculate a % mod, place result in ret
510 + * assumes that a is in Montgomery form with the R (Montgomery modulus) being
511 + * smallest power of two big enough to fit mod and that's also a power
512 + * of the count of number of bits in limb_t (B).
513 + * For calculation, we also need n', such that mod * n' == -1 mod B.
514 + * anum must be <= 2 * modnum
515 + * ret needs to be modnum words long
516 + * tmp needs to be mod_montgomery_limb_numb(modnum) limbs long
517 + */
518 +static void mod_montgomery(limb_t *ret, limb_t *a, size_t anum, limb_t *mod,
519 + size_t modnum, limb_t ni0, limb_t *tmp)
520 +{
521 + limb_t carry, v;
522 + limb_t *res, *rp, *tmp2;
523 + ossl_ssize_t i;
524 +
525 + res = tmp;
526 + /*
527 + * for intermediate result we need an integer twice as long as modulus
528 + * but keep the input in the least significant limbs
529 + */
530 + memset(res, 0, sizeof(limb_t) * (modnum * 2));
531 + memcpy(&res[modnum * 2 - anum], a, sizeof(limb_t) * anum);
532 + rp = &res[modnum];
533 + tmp2 = &res[modnum * 2];
534 +
535 + carry = 0;
536 +
537 + /* add multiples of the modulus to the value until R divides it cleanly */
538 + for (i = modnum; i > 0; i--, rp--) {
539 + v = _mul_add_limb(rp, mod, modnum, rp[modnum-1] * ni0, tmp2);
540 + v = v + carry + rp[-1];
541 + carry |= (v != rp[-1]);
542 + carry &= (v <= rp[-1]);
543 + rp[-1] = v;
544 + }
545 +
546 + /* perform the final reduction by mod... */
547 + carry -= sub(ret, rp, mod, modnum);
548 +
549 + /* ...conditionally */
550 + cselect(carry, ret, rp, ret, modnum);
551 +}
552 +
553 +/* allocated buffer should be freed afterwards */
554 +static void BN_to_limb(const BIGNUM *bn, limb_t *buf, size_t limbs)
555 +{
556 + int i;
557 + int real_limbs = (BN_num_bytes(bn) + LIMB_BYTE_SIZE - 1) / LIMB_BYTE_SIZE;
558 + limb_t *ptr = buf + (limbs - real_limbs);
559 +
560 + for (i = 0; i < real_limbs; i++)
561 + ptr[i] = bn->d[real_limbs - i - 1];
562 +}
563 +
564 +#if LIMB_BYTE_SIZE == 8
565 +static ossl_inline uint64_t be64(uint64_t host)
566 +{
567 + uint64_t big = 0;
568 + DECLARE_IS_ENDIAN;
569 +
570 + if (!IS_LITTLE_ENDIAN)
571 + return host;
572 +
573 + big |= (host & 0xff00000000000000) >> 56;
574 + big |= (host & 0x00ff000000000000) >> 40;
575 + big |= (host & 0x0000ff0000000000) >> 24;
576 + big |= (host & 0x000000ff00000000) >> 8;
577 + big |= (host & 0x00000000ff000000) << 8;
578 + big |= (host & 0x0000000000ff0000) << 24;
579 + big |= (host & 0x000000000000ff00) << 40;
580 + big |= (host & 0x00000000000000ff) << 56;
581 + return big;
582 +}
583 +
584 +#else
585 +/* Not all platforms have htobe32(). */
586 +static ossl_inline uint32_t be32(uint32_t host)
587 +{
588 + uint32_t big = 0;
589 + DECLARE_IS_ENDIAN;
590 +
591 + if (!IS_LITTLE_ENDIAN)
592 + return host;
593 +
594 + big |= (host & 0xff000000) >> 24;
595 + big |= (host & 0x00ff0000) >> 8;
596 + big |= (host & 0x0000ff00) << 8;
597 + big |= (host & 0x000000ff) << 24;
598 + return big;
599 +}
600 +#endif
601 +
602 +/*
603 + * We assume that intermediate, possible_arg2, blinding, and ctx are used
604 + * similar to BN_BLINDING_invert_ex() arguments.
605 + * to_mod is RSA modulus.
606 + * buf and num is the serialization buffer and its length.
607 + *
608 + * Here we use classic/Montgomery multiplication and modulo. After the calculation finished
609 + * we serialize the new structure instead of BIGNUMs taking endianness into account.
610 + */
611 +int ossl_bn_rsa_do_unblind(const BIGNUM *intermediate,
612 + const BN_BLINDING *blinding,
613 + const BIGNUM *possible_arg2,
614 + const BIGNUM *to_mod, BN_CTX *ctx,
615 + unsigned char *buf, int num)
616 +{
617 + limb_t *l_im = NULL, *l_mul = NULL, *l_mod = NULL;
618 + limb_t *l_ret = NULL, *l_tmp = NULL, l_buf;
619 + size_t l_im_count = 0, l_mul_count = 0, l_size = 0, l_mod_count = 0;
620 + size_t l_tmp_count = 0;
621 + int ret = 0;
622 + size_t i;
623 + unsigned char *tmp;
624 + const BIGNUM *arg1 = intermediate;
625 + const BIGNUM *arg2 = (possible_arg2 == NULL) ? blinding->Ai : possible_arg2;
626 +
627 + l_im_count = (BN_num_bytes(arg1) + LIMB_BYTE_SIZE - 1) / LIMB_BYTE_SIZE;
628 + l_mul_count = (BN_num_bytes(arg2) + LIMB_BYTE_SIZE - 1) / LIMB_BYTE_SIZE;
629 + l_mod_count = (BN_num_bytes(to_mod) + LIMB_BYTE_SIZE - 1) / LIMB_BYTE_SIZE;
630 +
631 + l_size = l_im_count > l_mul_count ? l_im_count : l_mul_count;
632 + l_im = OPENSSL_zalloc(l_size * LIMB_BYTE_SIZE);
633 + l_mul = OPENSSL_zalloc(l_size * LIMB_BYTE_SIZE);
634 + l_mod = OPENSSL_zalloc(l_mod_count * LIMB_BYTE_SIZE);
635 +
636 + if ((l_im == NULL) || (l_mul == NULL) || (l_mod == NULL))
637 + goto err;
638 +
639 + BN_to_limb(arg1, l_im, l_size);
640 + BN_to_limb(arg2, l_mul, l_size);
641 + BN_to_limb(to_mod, l_mod, l_mod_count);
642 +
643 + l_ret = OPENSSL_malloc(2 * l_size * LIMB_BYTE_SIZE);
644 +
645 + if (blinding->m_ctx != NULL) {
646 + l_tmp_count = mul_limb_numb(l_size) > mod_montgomery_limb_numb(l_mod_count) ?
647 + mul_limb_numb(l_size) : mod_montgomery_limb_numb(l_mod_count);
648 + l_tmp = OPENSSL_malloc(l_tmp_count * LIMB_BYTE_SIZE);
649 + } else {
650 + l_tmp_count = mul_limb_numb(l_size) > mod_limb_numb(2 * l_size, l_mod_count) ?
651 + mul_limb_numb(l_size) : mod_limb_numb(2 * l_size, l_mod_count);
652 + l_tmp = OPENSSL_malloc(l_tmp_count * LIMB_BYTE_SIZE);
653 + }
654 +
655 + if ((l_ret == NULL) || (l_tmp == NULL))
656 + goto err;
657 +
658 + if (blinding->m_ctx != NULL) {
659 + limb_mul(l_ret, l_im, l_mul, l_size, l_tmp);
660 + mod_montgomery(l_ret, l_ret, 2 * l_size, l_mod, l_mod_count,
661 + blinding->m_ctx->n0[0], l_tmp);
662 + } else {
663 + limb_mul(l_ret, l_im, l_mul, l_size, l_tmp);
664 + mod(l_ret, l_ret, 2 * l_size, l_mod, l_mod_count, l_tmp);
665 + }
666 +
667 + /* modulus size in bytes can be equal to num but after limbs conversion it becomes bigger */
668 + if (num < BN_num_bytes(to_mod)) {
669 + ERR_raise(ERR_LIB_BN, ERR_R_PASSED_INVALID_ARGUMENT);
670 + goto err;
671 + }
672 +
673 + memset(buf, 0, num);
674 + tmp = buf + num - BN_num_bytes(to_mod);
675 + for (i = 0; i < l_mod_count; i++) {
676 +#if LIMB_BYTE_SIZE == 8
677 + l_buf = be64(l_ret[i]);
678 +#else
679 + l_buf = be32(l_ret[i]);
680 +#endif
681 + if (i == 0) {
682 + int delta = LIMB_BYTE_SIZE - ((l_mod_count * LIMB_BYTE_SIZE) - num);
683 +
684 + memcpy(tmp, ((char *)&l_buf) + LIMB_BYTE_SIZE - delta, delta);
685 + tmp += delta;
686 + } else {
687 + memcpy(tmp, &l_buf, LIMB_BYTE_SIZE);
688 + tmp += LIMB_BYTE_SIZE;
689 + }
690 + }
691 + ret = num;
692 +
693 + err:
694 + OPENSSL_free(l_im);
695 + OPENSSL_free(l_mul);
696 + OPENSSL_free(l_mod);
697 + OPENSSL_free(l_tmp);
698 + OPENSSL_free(l_ret);
699 +
700 + return ret;
701 +}
702 diff --git a/crypto/rsa/rsa_ossl.c b/crypto/rsa/rsa_ossl.c
703 index 381c659352..7e8b791fba 100644
704 --- a/crypto/rsa/rsa_ossl.c
705 +++ b/crypto/rsa/rsa_ossl.c
706 @@ -469,13 +469,20 @@ static int rsa_ossl_private_decrypt(int flen, const unsigned char *from,
707 BN_free(d);
708 }
709
710 - if (blinding)
711 - if (!rsa_blinding_invert(blinding, ret, unblind, ctx))
712 + if (blinding) {
713 + /*
714 + * ossl_bn_rsa_do_unblind() combines blinding inversion and
715 + * 0-padded BN BE serialization
716 + */
717 + j = ossl_bn_rsa_do_unblind(ret, blinding, unblind, rsa->n, ctx,
718 + buf, num);
719 + if (j == 0)
720 goto err;
721 -
722 - j = BN_bn2binpad(ret, buf, num);
723 - if (j < 0)
724 - goto err;
725 + } else {
726 + j = BN_bn2binpad(ret, buf, num);
727 + if (j < 0)
728 + goto err;
729 + }
730
731 switch (padding) {
732 case RSA_PKCS1_PADDING:
733 diff --git a/include/crypto/bn.h b/include/crypto/bn.h
734 index cf69bea848..cd45654210 100644
735 --- a/include/crypto/bn.h
736 +++ b/include/crypto/bn.h
737 @@ -114,4 +114,10 @@ OSSL_LIB_CTX *ossl_bn_get_libctx(BN_CTX *ctx);
738
739 extern const BIGNUM ossl_bn_inv_sqrt_2;
740
741 +int ossl_bn_rsa_do_unblind(const BIGNUM *intermediate,
742 + const BN_BLINDING *blinding,
743 + const BIGNUM *possible_arg2,
744 + const BIGNUM *to_mod, BN_CTX *ctx,
745 + unsigned char *buf, int num);
746 +
747 #endif
748 --
749 2.39.1
750

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