/* * Copyright (c) 2018 Thomas Pornin * * Permission is hereby granted, free of charge, to any person obtaining * a copy of this software and associated documentation files (the * "Software"), to deal in the Software without restriction, including * without limitation the rights to use, copy, modify, merge, publish, * distribute, sublicense, and/or sell copies of the Software, and to * permit persons to whom the Software is furnished to do so, subject to * the following conditions: * * The above copyright notice and this permission notice shall be * included in all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, * EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND * NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS * BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN * ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN * CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE * SOFTWARE. */ #include "inner.h" #if BR_INT128 || BR_UMUL128 #if BR_UMUL128 #include #endif static const unsigned char GEN[] = { 0x09, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00 }; static const unsigned char ORDER[] = { 0x7F, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF }; static const unsigned char * api_generator(int curve, size_t *len) { (void)curve; *len = 32; return GEN; } static const unsigned char * api_order(int curve, size_t *len) { (void)curve; *len = 32; return ORDER; } static size_t api_xoff(int curve, size_t *len) { (void)curve; *len = 32; return 0; } /* * A field element is encoded as five 64-bit integers, in basis 2^51. * Limbs may be occasionally larger than 2^51, to save on carry * propagation costs. */ #define MASK51 (((uint64_t)1 << 51) - (uint64_t)1) /* * Swap two field elements, conditionally on a flag. */ static inline void f255_cswap(uint64_t *a, uint64_t *b, uint32_t ctl) { uint64_t m, w; m = -(uint64_t)ctl; w = m & (a[0] ^ b[0]); a[0] ^= w; b[0] ^= w; w = m & (a[1] ^ b[1]); a[1] ^= w; b[1] ^= w; w = m & (a[2] ^ b[2]); a[2] ^= w; b[2] ^= w; w = m & (a[3] ^ b[3]); a[3] ^= w; b[3] ^= w; w = m & (a[4] ^ b[4]); a[4] ^= w; b[4] ^= w; } /* * Addition with no carry propagation. Limbs double in size. */ static inline void f255_add(uint64_t *d, const uint64_t *a, const uint64_t *b) { d[0] = a[0] + b[0]; d[1] = a[1] + b[1]; d[2] = a[2] + b[2]; d[3] = a[3] + b[3]; d[4] = a[4] + b[4]; } /* * Subtraction. * On input, limbs must fit on 60 bits each. On output, result is * partially reduced, with max value 2^255+19456; moreover, all * limbs will fit on 51 bits, except the low limb, which may have * value up to 2^51+19455. */ static inline void f255_sub(uint64_t *d, const uint64_t *a, const uint64_t *b) { uint64_t cc, w; /* * We compute d = (2^255-19)*1024 + a - b. Since the limbs * fit on 60 bits, the maximum value of operands are slightly * more than 2^264, but much less than 2^265-19456. This * ensures that the result is positive. */ /* * Initial carry is 19456, since we add 2^265-19456. Each * individual subtraction may yield a carry up to 513. */ w = a[0] - b[0] - 19456; d[0] = w & MASK51; cc = -(w >> 51) & 0x3FF; w = a[1] - b[1] - cc; d[1] = w & MASK51; cc = -(w >> 51) & 0x3FF; w = a[2] - b[2] - cc; d[2] = w & MASK51; cc = -(w >> 51) & 0x3FF; w = a[3] - b[3] - cc; d[3] = w & MASK51; cc = -(w >> 51) & 0x3FF; d[4] = ((uint64_t)1 << 61) + a[4] - b[4] - cc; /* * Partial reduction. The intermediate result may be up to * slightly above 2^265, but less than 2^265+2^255. When we * truncate to 255 bits, the upper bits will be at most 1024. */ d[0] += 19 * (d[4] >> 51); d[4] &= MASK51; } /* * UMUL51(hi, lo, x, y) computes: * * hi = floor((x * y) / (2^51)) * lo = x * y mod 2^51 * * Note that lo < 2^51, but "hi" may be larger, if the input operands are * larger. */ #if BR_INT128 #define UMUL51(hi, lo, x, y) do { \ unsigned __int128 umul_tmp; \ umul_tmp = (unsigned __int128)(x) * (unsigned __int128)(y); \ (hi) = (uint64_t)(umul_tmp >> 51); \ (lo) = (uint64_t)umul_tmp & MASK51; \ } while (0) #elif BR_UMUL128 #define UMUL51(hi, lo, x, y) do { \ uint64_t umul_hi, umul_lo; \ umul_lo = _umul128((x), (y), &umul_hi); \ (hi) = (umul_hi << 13) | (umul_lo >> 51); \ (lo) = umul_lo & MASK51; \ } while (0) #endif /* * Multiplication. * On input, limbs must fit on 54 bits each. * On output, limb 0 is at most 2^51 + 155647, and other limbs fit * on 51 bits each. */ static inline void f255_mul(uint64_t *d, uint64_t *a, uint64_t *b) { uint64_t t[10], hi, lo, w, cc; /* * Perform cross products, accumulating values without carry * propagation. * * Since input limbs fit on 54 bits each, each individual * UMUL51 will produce a "hi" of less than 2^57. The maximum * sum will be at most 5*(2^57-1) + 4*(2^51-1) (for t[5]), * i.e. less than 324*2^51. */ UMUL51(t[1], t[0], a[0], b[0]); UMUL51(t[2], lo, a[1], b[0]); t[1] += lo; UMUL51(hi, lo, a[0], b[1]); t[1] += lo; t[2] += hi; UMUL51(t[3], lo, a[2], b[0]); t[2] += lo; UMUL51(hi, lo, a[1], b[1]); t[2] += lo; t[3] += hi; UMUL51(hi, lo, a[0], b[2]); t[2] += lo; t[3] += hi; UMUL51(t[4], lo, a[3], b[0]); t[3] += lo; UMUL51(hi, lo, a[2], b[1]); t[3] += lo; t[4] += hi; UMUL51(hi, lo, a[1], b[2]); t[3] += lo; t[4] += hi; UMUL51(hi, lo, a[0], b[3]); t[3] += lo; t[4] += hi; UMUL51(t[5], lo, a[4], b[0]); t[4] += lo; UMUL51(hi, lo, a[3], b[1]); t[4] += lo; t[5] += hi; UMUL51(hi, lo, a[2], b[2]); t[4] += lo; t[5] += hi; UMUL51(hi, lo, a[1], b[3]); t[4] += lo; t[5] += hi; UMUL51(hi, lo, a[0], b[4]); t[4] += lo; t[5] += hi; UMUL51(t[6], lo, a[4], b[1]); t[5] += lo; UMUL51(hi, lo, a[3], b[2]); t[5] += lo; t[6] += hi; UMUL51(hi, lo, a[2], b[3]); t[5] += lo; t[6] += hi; UMUL51(hi, lo, a[1], b[4]); t[5] += lo; t[6] += hi; UMUL51(t[7], lo, a[4], b[2]); t[6] += lo; UMUL51(hi, lo, a[3], b[3]); t[6] += lo; t[7] += hi; UMUL51(hi, lo, a[2], b[4]); t[6] += lo; t[7] += hi; UMUL51(t[8], lo, a[4], b[3]); t[7] += lo; UMUL51(hi, lo, a[3], b[4]); t[7] += lo; t[8] += hi; UMUL51(t[9], lo, a[4], b[4]); t[8] += lo; /* * The upper words t[5]..t[9] are folded back into the lower * words, using the rule that 2^255 = 19 in the field. * * Since each t[i] is less than 324*2^51, the additions below * will yield less than 6480*2^51 in each limb; this fits in * 64 bits (6480*2^51 < 8192*2^51 = 2^64), hence there is * no overflow. */ t[0] += 19 * t[5]; t[1] += 19 * t[6]; t[2] += 19 * t[7]; t[3] += 19 * t[8]; t[4] += 19 * t[9]; /* * Propagate carries. */ w = t[0]; d[0] = w & MASK51; cc = w >> 51; w = t[1] + cc; d[1] = w & MASK51; cc = w >> 51; w = t[2] + cc; d[2] = w & MASK51; cc = w >> 51; w = t[3] + cc; d[3] = w & MASK51; cc = w >> 51; w = t[4] + cc; d[4] = w & MASK51; cc = w >> 51; /* * Since the limbs were 64-bit values, the top carry is at * most 8192 (in practice, that cannot be reached). We simply * performed a partial reduction. */ d[0] += 19 * cc; } /* * Multiplication by A24 = 121665. * Input must have limbs of 60 bits at most. */ static inline void f255_mul_a24(uint64_t *d, const uint64_t *a) { uint64_t t[5], cc, w; /* * 121665 = 15 * 8111. We first multiply by 15, with carry * propagation and partial reduction. */ w = a[0] * 15; t[0] = w & MASK51; cc = w >> 51; w = a[1] * 15 + cc; t[1] = w & MASK51; cc = w >> 51; w = a[2] * 15 + cc; t[2] = w & MASK51; cc = w >> 51; w = a[3] * 15 + cc; t[3] = w & MASK51; cc = w >> 51; w = a[4] * 15 + cc; t[4] = w & MASK51; t[0] += 19 * (w >> 51); /* * Then multiplication by 8111. At that point, we known that * t[0] is less than 2^51 + 19*8192, and other limbs are less * than 2^51; thus, there will be no overflow. */ w = t[0] * 8111; d[0] = w & MASK51; cc = w >> 51; w = t[1] * 8111 + cc; d[1] = w & MASK51; cc = w >> 51; w = t[2] * 8111 + cc; d[2] = w & MASK51; cc = w >> 51; w = t[3] * 8111 + cc; d[3] = w & MASK51; cc = w >> 51; w = t[4] * 8111 + cc; d[4] = w & MASK51; d[0] += 19 * (w >> 51); } /* * Finalize reduction. * On input, limbs must fit on 51 bits, except possibly the low limb, * which may be slightly above 2^51. */ static inline void f255_final_reduce(uint64_t *a) { uint64_t t[5], cc, w; /* * We add 19. If the result (in t[]) is below 2^255, then a[] * is already less than 2^255-19, thus already reduced. * Otherwise, we subtract 2^255 from t[], in which case we * have t = a - (2^255-19), and that's our result. */ w = a[0] + 19; t[0] = w & MASK51; cc = w >> 51; w = a[1] + cc; t[1] = w & MASK51; cc = w >> 51; w = a[2] + cc; t[2] = w & MASK51; cc = w >> 51; w = a[3] + cc; t[3] = w & MASK51; cc = w >> 51; w = a[4] + cc; t[4] = w & MASK51; cc = w >> 51; /* * The bit 255 of t is in cc. If that bit is 0, when a[] must * be unchanged; otherwise, it must be replaced with t[]. */ cc = -cc; a[0] ^= cc & (a[0] ^ t[0]); a[1] ^= cc & (a[1] ^ t[1]); a[2] ^= cc & (a[2] ^ t[2]); a[3] ^= cc & (a[3] ^ t[3]); a[4] ^= cc & (a[4] ^ t[4]); } static uint32_t api_mul(unsigned char *G, size_t Glen, const unsigned char *kb, size_t kblen, int curve) { unsigned char k[32]; uint64_t x1[5], x2[5], z2[5], x3[5], z3[5]; uint32_t swap; int i; (void)curve; /* * Points are encoded over exactly 32 bytes. Multipliers must fit * in 32 bytes as well. */ if (Glen != 32 || kblen > 32) { return 0; } /* * RFC 7748 mandates that the high bit of the last point byte must * be ignored/cleared; the "& MASK51" in the initialization for * x1[4] clears that bit. */ x1[0] = br_dec64le(&G[0]) & MASK51; x1[1] = (br_dec64le(&G[6]) >> 3) & MASK51; x1[2] = (br_dec64le(&G[12]) >> 6) & MASK51; x1[3] = (br_dec64le(&G[19]) >> 1) & MASK51; x1[4] = (br_dec64le(&G[24]) >> 12) & MASK51; /* * We can use memset() to clear values, because exact-width types * like uint64_t are guaranteed to have no padding bits or * trap representations. */ memset(x2, 0, sizeof x2); x2[0] = 1; memset(z2, 0, sizeof z2); memcpy(x3, x1, sizeof x1); memcpy(z3, x2, sizeof x2); /* * The multiplier is provided in big-endian notation, and * possibly shorter than 32 bytes. */ memset(k, 0, (sizeof k) - kblen); memcpy(k + (sizeof k) - kblen, kb, kblen); k[31] &= 0xF8; k[0] &= 0x7F; k[0] |= 0x40; swap = 0; for (i = 254; i >= 0; i --) { uint64_t a[5], aa[5], b[5], bb[5], e[5]; uint64_t c[5], d[5], da[5], cb[5]; uint32_t kt; kt = (k[31 - (i >> 3)] >> (i & 7)) & 1; swap ^= kt; f255_cswap(x2, x3, swap); f255_cswap(z2, z3, swap); swap = kt; /* * At that point, limbs of x_2 and z_2 are assumed to fit * on at most 52 bits each. * * Each f255_add() adds one bit to the maximum range of * the values, but f255_sub() and f255_mul() bring back * the limbs into 52 bits. All f255_add() outputs are * used only as inputs for f255_mul(), which ensures * that limbs remain in the proper range. */ /* A = x_2 + z_2 -- limbs fit on 53 bits each */ f255_add(a, x2, z2); /* AA = A^2 */ f255_mul(aa, a, a); /* B = x_2 - z_2 */ f255_sub(b, x2, z2); /* BB = B^2 */ f255_mul(bb, b, b); /* E = AA - BB */ f255_sub(e, aa, bb); /* C = x_3 + z_3 -- limbs fit on 53 bits each */ f255_add(c, x3, z3); /* D = x_3 - z_3 */ f255_sub(d, x3, z3); /* DA = D * A */ f255_mul(da, d, a); /* CB = C * B */ f255_mul(cb, c, b); /* x_3 = (DA + CB)^2 */ f255_add(x3, da, cb); f255_mul(x3, x3, x3); /* z_3 = x_1 * (DA - CB)^2 */ f255_sub(z3, da, cb); f255_mul(z3, z3, z3); f255_mul(z3, x1, z3); /* x_2 = AA * BB */ f255_mul(x2, aa, bb); /* z_2 = E * (AA + a24 * E) */ f255_mul_a24(z2, e); f255_add(z2, aa, z2); f255_mul(z2, e, z2); } f255_cswap(x2, x3, swap); f255_cswap(z2, z3, swap); /* * Compute 1/z2 = z2^(p-2). Since p = 2^255-19, we can mutualize * most non-squarings. We use x1 and x3, now useless, as temporaries. */ memcpy(x1, z2, sizeof z2); for (i = 0; i < 15; i ++) { f255_mul(x1, x1, x1); f255_mul(x1, x1, z2); } memcpy(x3, x1, sizeof x1); for (i = 0; i < 14; i ++) { int j; for (j = 0; j < 16; j ++) { f255_mul(x3, x3, x3); } f255_mul(x3, x3, x1); } for (i = 14; i >= 0; i --) { f255_mul(x3, x3, x3); if ((0xFFEB >> i) & 1) { f255_mul(x3, z2, x3); } } /* * Compute x2/z2. We have 1/z2 in x3. */ f255_mul(x2, x2, x3); f255_final_reduce(x2); /* * Encode the final x2 value in little-endian. We first assemble * the limbs into 64-bit values. */ x2[0] |= x2[1] << 51; x2[1] = (x2[1] >> 13) | (x2[2] << 38); x2[2] = (x2[2] >> 26) | (x2[3] << 25); x2[3] = (x2[3] >> 39) | (x2[4] << 12); br_enc64le(G, x2[0]); br_enc64le(G + 8, x2[1]); br_enc64le(G + 16, x2[2]); br_enc64le(G + 24, x2[3]); return 1; } static size_t api_mulgen(unsigned char *R, const unsigned char *x, size_t xlen, int curve) { const unsigned char *G; size_t Glen; G = api_generator(curve, &Glen); memcpy(R, G, Glen); api_mul(R, Glen, x, xlen, curve); return Glen; } static uint32_t api_muladd(unsigned char *A, const unsigned char *B, size_t len, const unsigned char *x, size_t xlen, const unsigned char *y, size_t ylen, int curve) { /* * We don't implement this method, since it is used for ECDSA * only, and there is no ECDSA over Curve25519 (which instead * uses EdDSA). */ (void)A; (void)B; (void)len; (void)x; (void)xlen; (void)y; (void)ylen; (void)curve; return 0; } /* see bearssl_ec.h */ const br_ec_impl br_ec_c25519_m62 = { (uint32_t)0x20000000, &api_generator, &api_order, &api_xoff, &api_mul, &api_mulgen, &api_muladd }; /* see bearssl_ec.h */ const br_ec_impl * br_ec_c25519_m62_get(void) { return &br_ec_c25519_m62; } #else /* see bearssl_ec.h */ const br_ec_impl * br_ec_c25519_m62_get(void) { return 0; } #endif