// Copyright 1995-2016 The OpenSSL Project Authors. All Rights Reserved. // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // https://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. #include #include #include #include #include #include #include #include "internal.h" #include "rsaz_exp.h" #if defined(OPENSSL_BN_ASM_MONT5) // bn_mul_mont_gather5 multiples loads index |power| of |table|, multiplies it // by |ap| modulo |np|, and stores the result in |rp|. The values are |num| // words long and represented in Montgomery form. |n0| is a pointer to the // corresponding field in |BN_MONT_CTX|. |table| must be aligned to at least // 16 bytes. |power| must be less than 32 and is treated as secret. // // WARNING: This function implements Almost Montgomery Multiplication from // https://eprint.iacr.org/2011/239. The inputs do not need to be fully reduced. // However, even if they are fully reduced, the output may not be. static void bn_mul_mont_gather5(BN_ULONG *rp, const BN_ULONG *ap, const BN_ULONG *table, const BN_ULONG *np, const BN_ULONG *n0, int num, int power) { if (bn_mulx4x_mont_gather5_capable(num)) { bn_mulx4x_mont_gather5(rp, ap, table, np, n0, num, power); } else if (bn_mul4x_mont_gather5_capable(num)) { bn_mul4x_mont_gather5(rp, ap, table, np, n0, num, power); } else { bn_mul_mont_gather5_nohw(rp, ap, table, np, n0, num, power); } } // bn_power5 squares |ap| five times and multiplies it by the value stored at // index |power| of |table|, modulo |np|. It stores the result in |rp|. The // values are |num| words long and represented in Montgomery form. |n0| is a // pointer to the corresponding field in |BN_MONT_CTX|. |num| must be divisible // by 8. |power| must be less than 32 and is treated as secret. // // WARNING: This function implements Almost Montgomery Multiplication from // https://eprint.iacr.org/2011/239. The inputs do not need to be fully reduced. // However, even if they are fully reduced, the output may not be. static void bn_power5(BN_ULONG *rp, const BN_ULONG *ap, const BN_ULONG *table, const BN_ULONG *np, const BN_ULONG *n0, int num, int power) { assert(bn_power5_capable(num)); if (bn_powerx5_capable(num)) { bn_powerx5(rp, ap, table, np, n0, num, power); } else { bn_power5_nohw(rp, ap, table, np, n0, num, power); } } #endif // defined(OPENSSL_BN_ASM_MONT5) // BN_window_bits_for_exponent_size returns sliding window size for mod_exp with // a |b| bit exponent. // // For window size 'w' (w >= 2) and a random 'b' bits exponent, the number of // multiplications is a constant plus on average // // 2^(w-1) + (b-w)/(w+1); // // here 2^(w-1) is for precomputing the table (we actually need entries only // for windows that have the lowest bit set), and (b-w)/(w+1) is an // approximation for the expected number of w-bit windows, not counting the // first one. // // Thus we should use // // w >= 6 if b > 671 // w = 5 if 671 > b > 239 // w = 4 if 239 > b > 79 // w = 3 if 79 > b > 23 // w <= 2 if 23 > b // // (with draws in between). Very small exponents are often selected // with low Hamming weight, so we use w = 1 for b <= 23. static int BN_window_bits_for_exponent_size(size_t b) { if (b > 671) { return 6; } if (b > 239) { return 5; } if (b > 79) { return 4; } if (b > 23) { return 3; } return 1; } // TABLE_SIZE is the maximum precomputation table size for *variable* sliding // windows. This must be 2^(max_window - 1), where max_window is the largest // value returned from |BN_window_bits_for_exponent_size|. #define TABLE_SIZE 32 // TABLE_BITS_SMALL is the smallest value returned from // |BN_window_bits_for_exponent_size| when |b| is at most |BN_BITS2| * // |BN_SMALL_MAX_WORDS| words. #define TABLE_BITS_SMALL 5 // TABLE_SIZE_SMALL is the same as |TABLE_SIZE|, but when |b| is at most // |BN_BITS2| * |BN_SMALL_MAX_WORDS|. #define TABLE_SIZE_SMALL (1 << (TABLE_BITS_SMALL - 1)) int BN_mod_exp_mont(BIGNUM *rr, const BIGNUM *a, const BIGNUM *p, const BIGNUM *m, BN_CTX *ctx, const BN_MONT_CTX *mont) { if (!BN_is_odd(m)) { OPENSSL_PUT_ERROR(BN, BN_R_CALLED_WITH_EVEN_MODULUS); return 0; } if (m->neg) { OPENSSL_PUT_ERROR(BN, BN_R_NEGATIVE_NUMBER); return 0; } // |a| is secret, but |a < m| is not. if (a->neg || constant_time_declassify_int(BN_ucmp(a, m)) >= 0) { OPENSSL_PUT_ERROR(BN, BN_R_INPUT_NOT_REDUCED); return 0; } int bits = BN_num_bits(p); if (bits == 0) { // x**0 mod 1 is still zero. if (BN_abs_is_word(m, 1)) { BN_zero(rr); return 1; } return BN_one(rr); } BIGNUM *val[TABLE_SIZE]; bssl::BN_CTXScope scope(ctx); BIGNUM *r = BN_CTX_get(ctx); val[0] = BN_CTX_get(ctx); if (r == NULL || val[0] == NULL) { return 0; } // Allocate a montgomery context if it was not supplied by the caller. bssl::UniquePtr new_mont; if (mont == nullptr) { new_mont.reset(BN_MONT_CTX_new_consttime(m, ctx)); if (new_mont == nullptr) { return 0; } mont = new_mont.get(); } // We exponentiate by looking at sliding windows of the exponent and // precomputing powers of |a|. Windows may be shifted so they always end on a // set bit, so only precompute odd powers. We compute val[i] = a^(2*i + 1) // for i = 0 to 2^(window-1), all in Montgomery form. int window = BN_window_bits_for_exponent_size(bits); if (!BN_to_montgomery(val[0], a, mont, ctx)) { return 0; } if (window > 1) { BIGNUM *d = BN_CTX_get(ctx); if (d == NULL || !BN_mod_mul_montgomery(d, val[0], val[0], mont, ctx)) { return 0; } for (int i = 1; i < 1 << (window - 1); i++) { val[i] = BN_CTX_get(ctx); if (val[i] == NULL || !BN_mod_mul_montgomery(val[i], val[i - 1], d, mont, ctx)) { return 0; } } } // |p| is non-zero, so at least one window is non-zero. To save some // multiplications, defer initializing |r| until then. int r_is_one = 1; int wstart = bits - 1; // The top bit of the window. for (;;) { if (!BN_is_bit_set(p, wstart)) { if (!r_is_one && !BN_mod_mul_montgomery(r, r, r, mont, ctx)) { return 0; } if (wstart == 0) { break; } wstart--; continue; } // We now have wstart on a set bit. Find the largest window we can use. int wvalue = 1; int wsize = 0; for (int i = 1; i < window && i <= wstart; i++) { if (BN_is_bit_set(p, wstart - i)) { wvalue <<= (i - wsize); wvalue |= 1; wsize = i; } } // Shift |r| to the end of the window. if (!r_is_one) { for (int i = 0; i < wsize + 1; i++) { if (!BN_mod_mul_montgomery(r, r, r, mont, ctx)) { return 0; } } } assert(wvalue & 1); assert(wvalue < (1 << window)); if (r_is_one) { if (!BN_copy(r, val[wvalue >> 1])) { return 0; } } else if (!BN_mod_mul_montgomery(r, r, val[wvalue >> 1], mont, ctx)) { return 0; } r_is_one = 0; if (wstart == wsize) { break; } wstart -= wsize + 1; } // |p| is non-zero, so |r_is_one| must be cleared at some point. assert(!r_is_one); return BN_from_montgomery(rr, r, mont, ctx); } void bn_mod_exp_mont_small(BN_ULONG *r, const BN_ULONG *a, size_t num, const BN_ULONG *p, size_t num_p, const BN_MONT_CTX *mont) { if (num != (size_t)mont->N.width || num > BN_SMALL_MAX_WORDS || num_p > SIZE_MAX / BN_BITS2) { abort(); } assert(BN_is_odd(&mont->N)); // Count the number of bits in |p|, skipping leading zeros. Note this function // treats |p| as public. while (num_p != 0 && p[num_p - 1] == 0) { num_p--; } if (num_p == 0) { bn_from_montgomery_small(r, num, mont->RR.d, num, mont); return; } size_t bits = BN_num_bits_word(p[num_p - 1]) + (num_p - 1) * BN_BITS2; assert(bits != 0); // We exponentiate by looking at sliding windows of the exponent and // precomputing powers of |a|. Windows may be shifted so they always end on a // set bit, so only precompute odd powers. We compute val[i] = a^(2*i + 1) for // i = 0 to 2^(window-1), all in Montgomery form. unsigned window = BN_window_bits_for_exponent_size(bits); if (window > TABLE_BITS_SMALL) { window = TABLE_BITS_SMALL; // Tolerate excessively large |p|. } BN_ULONG val[TABLE_SIZE_SMALL][BN_SMALL_MAX_WORDS]; OPENSSL_memcpy(val[0], a, num * sizeof(BN_ULONG)); if (window > 1) { BN_ULONG d[BN_SMALL_MAX_WORDS]; bn_mod_mul_montgomery_small(d, val[0], val[0], num, mont); for (unsigned i = 1; i < 1u << (window - 1); i++) { bn_mod_mul_montgomery_small(val[i], val[i - 1], d, num, mont); } } // |p| is non-zero, so at least one window is non-zero. To save some // multiplications, defer initializing |r| until then. int r_is_one = 1; size_t wstart = bits - 1; // The top bit of the window. for (;;) { if (!bn_is_bit_set_words(p, num_p, wstart)) { if (!r_is_one) { bn_mod_mul_montgomery_small(r, r, r, num, mont); } if (wstart == 0) { break; } wstart--; continue; } // We now have wstart on a set bit. Find the largest window we can use. unsigned wvalue = 1; unsigned wsize = 0; for (unsigned i = 1; i < window && i <= wstart; i++) { if (bn_is_bit_set_words(p, num_p, wstart - i)) { wvalue <<= (i - wsize); wvalue |= 1; wsize = i; } } // Shift |r| to the end of the window. if (!r_is_one) { for (unsigned i = 0; i < wsize + 1; i++) { bn_mod_mul_montgomery_small(r, r, r, num, mont); } } assert(wvalue & 1); assert(wvalue < (1u << window)); if (r_is_one) { OPENSSL_memcpy(r, val[wvalue >> 1], num * sizeof(BN_ULONG)); } else { bn_mod_mul_montgomery_small(r, r, val[wvalue >> 1], num, mont); } r_is_one = 0; if (wstart == wsize) { break; } wstart -= wsize + 1; } // |p| is non-zero, so |r_is_one| must be cleared at some point. assert(!r_is_one); OPENSSL_cleanse(val, sizeof(val)); } void bn_mod_inverse0_prime_mont_small(BN_ULONG *r, const BN_ULONG *a, size_t num, const BN_MONT_CTX *mont) { if (num != (size_t)mont->N.width || num > BN_SMALL_MAX_WORDS) { abort(); } // Per Fermat's Little Theorem, a^-1 = a^(p-2) (mod p) for p prime. BN_ULONG p_minus_two[BN_SMALL_MAX_WORDS]; const BN_ULONG *p = mont->N.d; OPENSSL_memcpy(p_minus_two, p, num * sizeof(BN_ULONG)); if (p_minus_two[0] >= 2) { p_minus_two[0] -= 2; } else { p_minus_two[0] -= 2; for (size_t i = 1; i < num; i++) { if (p_minus_two[i]-- != 0) { break; } } } bn_mod_exp_mont_small(r, a, num, p_minus_two, num, mont); } static void copy_to_prebuf(const BIGNUM *b, int top, BN_ULONG *table, int idx, int window) { int ret = bn_copy_words(table + idx * top, top, b); assert(ret); // |b| is guaranteed to fit. (void)ret; } static int copy_from_prebuf(BIGNUM *b, int top, const BN_ULONG *table, int idx, int window) { if (!bn_wexpand(b, top)) { return 0; } OPENSSL_memset(b->d, 0, sizeof(BN_ULONG) * top); const int width = 1 << window; for (int i = 0; i < width; i++, table += top) { // Use a value barrier to prevent Clang from adding a branch when |i != idx| // and making this copy not constant time. Clang is still allowed to learn // that |mask| is constant across the inner loop, so this won't inhibit any // vectorization it might do. BN_ULONG mask = value_barrier_w(constant_time_eq_int(i, idx)); for (int j = 0; j < top; j++) { b->d[j] |= table[j] & mask; } } b->width = top; return 1; } // Window sizes optimized for fixed window size modular exponentiation // algorithm (BN_mod_exp_mont_consttime). // // TODO(davidben): These window sizes were originally set for 64-byte cache // lines with a cache-line-dependent constant-time mitigation. They can probably // be revised now that our implementation is no longer cache-time-dependent. #define BN_window_bits_for_ctime_exponent_size(b) \ ((b) > 937 ? 6 : (b) > 306 ? 5 : (b) > 89 ? 4 : (b) > 22 ? 3 : 1) #define BN_MAX_MOD_EXP_CTIME_WINDOW (6) // This variant of |BN_mod_exp_mont| uses fixed windows and fixed memory access // patterns to protect secret exponents (cf. the hyper-threading timing attacks // pointed out by Colin Percival, // http://www.daemonology.net/hyperthreading-considered-harmful/) int BN_mod_exp_mont_consttime(BIGNUM *rr, const BIGNUM *a, const BIGNUM *p, const BIGNUM *m, BN_CTX *ctx, const BN_MONT_CTX *mont) { int i, ret = 0, wvalue; BN_MONT_CTX *new_mont = NULL; void *powerbuf_free = NULL; size_t powerbuf_len = 0; BN_ULONG *powerbuf = NULL; if (!BN_is_odd(m)) { OPENSSL_PUT_ERROR(BN, BN_R_CALLED_WITH_EVEN_MODULUS); return 0; } if (m->neg) { OPENSSL_PUT_ERROR(BN, BN_R_NEGATIVE_NUMBER); return 0; } // |a| is secret, but it is required to be in range, so these comparisons may // be leaked. if (a->neg || constant_time_declassify_int(BN_ucmp(a, m) >= 0)) { OPENSSL_PUT_ERROR(BN, BN_R_INPUT_NOT_REDUCED); return 0; } // Use all bits stored in |p|, rather than |BN_num_bits|, so we do not leak // whether the top bits are zero. int max_bits = p->width * BN_BITS2; int bits = max_bits; if (bits == 0) { // x**0 mod 1 is still zero. if (BN_abs_is_word(m, 1)) { BN_zero(rr); return 1; } return BN_one(rr); } // Allocate a montgomery context if it was not supplied by the caller. int top, num_powers, window; if (mont == NULL) { new_mont = BN_MONT_CTX_new_consttime(m, ctx); if (new_mont == NULL) { goto err; } mont = new_mont; } // Use the width in |mont->N|, rather than the copy in |m|. The assembly // implementation assumes it can use |top| to size R. top = mont->N.width; #if defined(OPENSSL_BN_ASM_MONT5) || defined(RSAZ_ENABLED) // Share one large stack-allocated buffer between the RSAZ and non-RSAZ code // paths. If we were to use separate static buffers for each then there is // some chance that both large buffers would be allocated on the stack, // causing the stack space requirement to be truly huge (~10KB). alignas(MOD_EXP_CTIME_ALIGN) BN_ULONG storage[MOD_EXP_CTIME_STORAGE_LEN]; #endif #if defined(RSAZ_ENABLED) // If the size of the operands allow it, perform the optimized RSAZ // exponentiation. For further information see crypto/fipsmodule/bn/rsaz_exp.c // and accompanying assembly modules. if (a->width == 16 && p->width == 16 && BN_num_bits(m) == 1024 && rsaz_avx2_preferred()) { if (!bn_wexpand(rr, 16)) { goto err; } RSAZ_1024_mod_exp_avx2(rr->d, a->d, p->d, m->d, mont->RR.d, mont->n0[0], storage); rr->width = 16; rr->neg = 0; ret = 1; goto err; } #endif // Get the window size to use with size of p. window = BN_window_bits_for_ctime_exponent_size(bits); assert(window <= BN_MAX_MOD_EXP_CTIME_WINDOW); // Calculating |powerbuf_len| below cannot overflow because of the bound on // Montgomery reduction. assert((size_t)top <= BN_MONTGOMERY_MAX_WORDS); static_assert( BN_MONTGOMERY_MAX_WORDS <= INT_MAX / sizeof(BN_ULONG) / ((1 << BN_MAX_MOD_EXP_CTIME_WINDOW) + 3), "powerbuf_len may overflow"); #if defined(OPENSSL_BN_ASM_MONT5) if (window >= 5) { window = 5; // ~5% improvement for RSA2048 sign, and even for RSA4096 // Reserve space for the |mont->N| copy. powerbuf_len += top * sizeof(mont->N.d[0]); } #endif // Allocate a buffer large enough to hold all of the pre-computed // powers of |am|, |am| itself, and |tmp|. num_powers = 1 << window; powerbuf_len += sizeof(m->d[0]) * top * (num_powers + 2); #if defined(OPENSSL_BN_ASM_MONT5) if (powerbuf_len <= sizeof(storage)) { powerbuf = storage; } // |storage| is more than large enough to handle 1024-bit inputs. assert(powerbuf != NULL || top * BN_BITS2 > 1024); #endif if (powerbuf == NULL) { powerbuf_free = OPENSSL_malloc(powerbuf_len + MOD_EXP_CTIME_ALIGN); if (powerbuf_free == NULL) { goto err; } powerbuf = reinterpret_cast( align_pointer(powerbuf_free, MOD_EXP_CTIME_ALIGN)); } OPENSSL_memset(powerbuf, 0, powerbuf_len); // Place |tmp| and |am| right after powers table. BIGNUM tmp, am; tmp.d = powerbuf + top * num_powers; am.d = tmp.d + top; tmp.width = am.width = 0; tmp.dmax = am.dmax = top; tmp.neg = am.neg = 0; tmp.flags = am.flags = BN_FLG_STATIC_DATA; if (!bn_one_to_montgomery(&tmp, mont, ctx) || !bn_resize_words(&tmp, top)) { goto err; } // Prepare a^1 in the Montgomery domain. assert(!a->neg); declassify_assert(BN_ucmp(a, m) < 0); if (!BN_to_montgomery(&am, a, mont, ctx) || !bn_resize_words(&am, top)) { goto err; } #if defined(OPENSSL_BN_ASM_MONT5) // This optimization uses ideas from https://eprint.iacr.org/2011/239, // specifically optimization of cache-timing attack countermeasures, // pre-computation optimization, and Almost Montgomery Multiplication. // // The paper discusses a 4-bit window to optimize 512-bit modular // exponentiation, used in RSA-1024 with CRT, but RSA-1024 is no longer // important. // // |bn_mul_mont_gather5| and |bn_power5| implement the "almost" reduction // variant, so the values here may not be fully reduced. They are bounded by R // (i.e. they fit in |top| words), not |m|. Additionally, we pass these // "almost" reduced inputs into |bn_mul_mont|, which implements the normal // reduction variant. Given those inputs, |bn_mul_mont| may not give reduced // output, but it will still produce "almost" reduced output. // // TODO(davidben): Using "almost" reduction complicates analysis of this code, // and its interaction with other parts of the project. Determine whether this // is actually necessary for performance. if (window == 5 && top > 1) { // Copy |mont->N| to improve cache locality. BN_ULONG *np = am.d + top; for (i = 0; i < top; i++) { np[i] = mont->N.d[i]; } // Fill |powerbuf| with the first 32 powers of |am|. const BN_ULONG *n0 = mont->n0; bn_scatter5(tmp.d, top, powerbuf, 0); bn_scatter5(am.d, am.width, powerbuf, 1); bn_mul_mont(tmp.d, am.d, am.d, np, n0, top); bn_scatter5(tmp.d, top, powerbuf, 2); // Square to compute powers of two. for (i = 4; i < 32; i *= 2) { bn_mul_mont(tmp.d, tmp.d, tmp.d, np, n0, top); bn_scatter5(tmp.d, top, powerbuf, i); } // Compute odd powers |i| based on |i - 1|, then all powers |i * 2^j|. for (i = 3; i < 32; i += 2) { bn_mul_mont_gather5(tmp.d, am.d, powerbuf, np, n0, top, i - 1); bn_scatter5(tmp.d, top, powerbuf, i); for (int j = 2 * i; j < 32; j *= 2) { bn_mul_mont(tmp.d, tmp.d, tmp.d, np, n0, top); bn_scatter5(tmp.d, top, powerbuf, j); } } bits--; for (wvalue = 0, i = bits % 5; i >= 0; i--, bits--) { wvalue = (wvalue << 1) + BN_is_bit_set(p, bits); } bn_gather5(tmp.d, top, powerbuf, wvalue); // At this point |bits| is 4 mod 5 and at least -1. (|bits| is the first bit // that has not been read yet.) assert(bits >= -1 && (bits == -1 || bits % 5 == 4)); // Scan the exponent one window at a time starting from the most // significant bits. if (!bn_power5_capable(top)) { while (bits >= 0) { for (wvalue = 0, i = 0; i < 5; i++, bits--) { wvalue = (wvalue << 1) + BN_is_bit_set(p, bits); } bn_mul_mont(tmp.d, tmp.d, tmp.d, np, n0, top); bn_mul_mont(tmp.d, tmp.d, tmp.d, np, n0, top); bn_mul_mont(tmp.d, tmp.d, tmp.d, np, n0, top); bn_mul_mont(tmp.d, tmp.d, tmp.d, np, n0, top); bn_mul_mont(tmp.d, tmp.d, tmp.d, np, n0, top); bn_mul_mont_gather5(tmp.d, tmp.d, powerbuf, np, n0, top, wvalue); } } else { const uint8_t *p_bytes = (const uint8_t *)p->d; assert(bits < max_bits); // |p = 0| has been handled as a special case, so |max_bits| is at least // one word. assert(max_bits >= 64); // If the first bit to be read lands in the last byte, unroll the first // iteration to avoid reading past the bounds of |p->d|. (After the first // iteration, we are guaranteed to be past the last byte.) Note |bits| // here is the top bit, inclusive. if (bits - 4 >= max_bits - 8) { // Read five bits from |bits-4| through |bits|, inclusive. wvalue = p_bytes[p->width * BN_BYTES - 1]; wvalue >>= (bits - 4) & 7; wvalue &= 0x1f; bits -= 5; bn_power5(tmp.d, tmp.d, powerbuf, np, n0, top, wvalue); } while (bits >= 0) { // Read five bits from |bits-4| through |bits|, inclusive. int first_bit = bits - 4; uint16_t val; OPENSSL_memcpy(&val, p_bytes + (first_bit >> 3), sizeof(val)); val >>= first_bit & 7; val &= 0x1f; bits -= 5; bn_power5(tmp.d, tmp.d, powerbuf, np, n0, top, val); } } // The result is now in |tmp| in Montgomery form, but it may not be fully // reduced. This is within bounds for |BN_from_montgomery| (tmp < R <= m*R) // so it will, when converting from Montgomery form, produce a fully reduced // result. // // This differs from Figure 2 of the paper, which uses AMM(h, 1) to convert // from Montgomery form with unreduced output, followed by an extra // reduction step. In the paper's terminology, we replace steps 9 and 10 // with MM(h, 1). } else #endif { copy_to_prebuf(&tmp, top, powerbuf, 0, window); copy_to_prebuf(&am, top, powerbuf, 1, window); // If the window size is greater than 1, then calculate // val[i=2..2^winsize-1]. Powers are computed as a*a^(i-1) // (even powers could instead be computed as (a^(i/2))^2 // to use the slight performance advantage of sqr over mul). if (window > 1) { if (!BN_mod_mul_montgomery(&tmp, &am, &am, mont, ctx)) { goto err; } copy_to_prebuf(&tmp, top, powerbuf, 2, window); for (i = 3; i < num_powers; i++) { // Calculate a^i = a^(i-1) * a if (!BN_mod_mul_montgomery(&tmp, &am, &tmp, mont, ctx)) { goto err; } copy_to_prebuf(&tmp, top, powerbuf, i, window); } } bits--; for (wvalue = 0, i = bits % window; i >= 0; i--, bits--) { wvalue = (wvalue << 1) + BN_is_bit_set(p, bits); } if (!copy_from_prebuf(&tmp, top, powerbuf, wvalue, window)) { goto err; } // Scan the exponent one window at a time starting from the most // significant bits. while (bits >= 0) { wvalue = 0; // The 'value' of the window // Scan the window, squaring the result as we go for (i = 0; i < window; i++, bits--) { if (!BN_mod_mul_montgomery(&tmp, &tmp, &tmp, mont, ctx)) { goto err; } wvalue = (wvalue << 1) + BN_is_bit_set(p, bits); } // Fetch the appropriate pre-computed value from the pre-buf if (!copy_from_prebuf(&am, top, powerbuf, wvalue, window)) { goto err; } // Multiply the result into the intermediate result if (!BN_mod_mul_montgomery(&tmp, &tmp, &am, mont, ctx)) { goto err; } } } // Convert the final result from Montgomery to standard format. If we used the // |OPENSSL_BN_ASM_MONT5| codepath, |tmp| may not be fully reduced. It is only // bounded by R rather than |m|. However, that is still within bounds for // |BN_from_montgomery|, which implements full Montgomery reduction, not // "almost" Montgomery reduction. if (!BN_from_montgomery(rr, &tmp, mont, ctx)) { goto err; } ret = 1; err: BN_MONT_CTX_free(new_mont); if (powerbuf != NULL && powerbuf_free == NULL) { OPENSSL_cleanse(powerbuf, powerbuf_len); } OPENSSL_free(powerbuf_free); return ret; }