github.com/FISCO-BCOS/crypto@v0.0.0-20200202032121-bd8ab0b5d4f1/elliptic/p256.go (about) 1 // Copyright 2013 The Go Authors. All rights reserved. 2 // Use of this source code is governed by a BSD-style 3 // license that can be found in the LICENSE file. 4 5 // +build !amd64,!arm64 6 7 package elliptic 8 9 // This file contains a constant-time, 32-bit implementation of P256. 10 11 import ( 12 "math/big" 13 ) 14 15 type p256Curve struct { 16 *CurveParams 17 } 18 19 var ( 20 p256Params *CurveParams 21 22 // RInverse contains 1/R mod p - the inverse of the Montgomery constant 23 // (2**257). 24 p256RInverse *big.Int 25 ) 26 27 func initP256() { 28 // See FIPS 186-3, section D.2.3 29 p256Params = &CurveParams{Name: "P-256"} 30 p256Params.P, _ = new(big.Int).SetString("115792089210356248762697446949407573530086143415290314195533631308867097853951", 10) 31 p256Params.N, _ = new(big.Int).SetString("115792089210356248762697446949407573529996955224135760342422259061068512044369", 10) 32 p256Params.A, _ = new(big.Int).SetString("ffffffff00000001000000000000000000000000fffffffffffffffffffffffc", 16) 33 p256Params.B, _ = new(big.Int).SetString("5ac635d8aa3a93e7b3ebbd55769886bc651d06b0cc53b0f63bce3c3e27d2604b", 16) 34 p256Params.Gx, _ = new(big.Int).SetString("6b17d1f2e12c4247f8bce6e563a440f277037d812deb33a0f4a13945d898c296", 16) 35 p256Params.Gy, _ = new(big.Int).SetString("4fe342e2fe1a7f9b8ee7eb4a7c0f9e162bce33576b315ececbb6406837bf51f5", 16) 36 p256Params.BitSize = 256 37 38 p256RInverse, _ = new(big.Int).SetString("7fffffff00000001fffffffe8000000100000000ffffffff0000000180000000", 16) 39 40 // Arch-specific initialization, i.e. let a platform dynamically pick a P256 implementation 41 initP256Arch() 42 } 43 44 func (curve p256Curve) Params() *CurveParams { 45 return curve.CurveParams 46 } 47 48 // p256GetScalar endian-swaps the big-endian scalar value from in and writes it 49 // to out. If the scalar is equal or greater than the order of the group, it's 50 // reduced modulo that order. 51 func p256GetScalar(out *[32]byte, in []byte) { 52 n := new(big.Int).SetBytes(in) 53 var scalarBytes []byte 54 55 if n.Cmp(p256Params.N) >= 0 { 56 n.Mod(n, p256Params.N) 57 scalarBytes = n.Bytes() 58 } else { 59 scalarBytes = in 60 } 61 62 for i, v := range scalarBytes { 63 out[len(scalarBytes)-(1+i)] = v 64 } 65 } 66 67 func (p256Curve) ScalarBaseMult(scalar []byte) (x, y *big.Int) { 68 var scalarReversed [32]byte 69 p256GetScalar(&scalarReversed, scalar) 70 71 var x1, y1, z1 [p256Limbs]uint32 72 p256ScalarBaseMult(&x1, &y1, &z1, &scalarReversed) 73 return p256ToAffine(&x1, &y1, &z1) 74 } 75 76 func (p256Curve) ScalarMult(bigX, bigY *big.Int, scalar []byte) (x, y *big.Int) { 77 var scalarReversed [32]byte 78 p256GetScalar(&scalarReversed, scalar) 79 80 var px, py, x1, y1, z1 [p256Limbs]uint32 81 p256FromBig(&px, bigX) 82 p256FromBig(&py, bigY) 83 p256ScalarMult(&x1, &y1, &z1, &px, &py, &scalarReversed) 84 return p256ToAffine(&x1, &y1, &z1) 85 } 86 87 // Field elements are represented as nine, unsigned 32-bit words. 88 // 89 // The value of an field element is: 90 // x[0] + (x[1] * 2**29) + (x[2] * 2**57) + ... + (x[8] * 2**228) 91 // 92 // That is, each limb is alternately 29 or 28-bits wide in little-endian 93 // order. 94 // 95 // This means that a field element hits 2**257, rather than 2**256 as we would 96 // like. A 28, 29, ... pattern would cause us to hit 2**256, but that causes 97 // problems when multiplying as terms end up one bit short of a limb which 98 // would require much bit-shifting to correct. 99 // 100 // Finally, the values stored in a field element are in Montgomery form. So the 101 // value |y| is stored as (y*R) mod p, where p is the P-256 prime and R is 102 // 2**257. 103 104 const ( 105 p256Limbs = 9 106 bottom29Bits = 0x1fffffff 107 ) 108 109 var ( 110 // p256One is the number 1 as a field element. 111 p256One = [p256Limbs]uint32{2, 0, 0, 0xffff800, 0x1fffffff, 0xfffffff, 0x1fbfffff, 0x1ffffff, 0} 112 p256Zero = [p256Limbs]uint32{0, 0, 0, 0, 0, 0, 0, 0, 0} 113 // p256P is the prime modulus as a field element. 114 p256P = [p256Limbs]uint32{0x1fffffff, 0xfffffff, 0x1fffffff, 0x3ff, 0, 0, 0x200000, 0xf000000, 0xfffffff} 115 // p2562P is the twice prime modulus as a field element. 116 p2562P = [p256Limbs]uint32{0x1ffffffe, 0xfffffff, 0x1fffffff, 0x7ff, 0, 0, 0x400000, 0xe000000, 0x1fffffff} 117 ) 118 119 // p256Precomputed contains precomputed values to aid the calculation of scalar 120 // multiples of the base point, G. It's actually two, equal length, tables 121 // concatenated. 122 // 123 // The first table contains (x,y) field element pairs for 16 multiples of the 124 // base point, G. 125 // 126 // Index | Index (binary) | Value 127 // 0 | 0000 | 0G (all zeros, omitted) 128 // 1 | 0001 | G 129 // 2 | 0010 | 2**64G 130 // 3 | 0011 | 2**64G + G 131 // 4 | 0100 | 2**128G 132 // 5 | 0101 | 2**128G + G 133 // 6 | 0110 | 2**128G + 2**64G 134 // 7 | 0111 | 2**128G + 2**64G + G 135 // 8 | 1000 | 2**192G 136 // 9 | 1001 | 2**192G + G 137 // 10 | 1010 | 2**192G + 2**64G 138 // 11 | 1011 | 2**192G + 2**64G + G 139 // 12 | 1100 | 2**192G + 2**128G 140 // 13 | 1101 | 2**192G + 2**128G + G 141 // 14 | 1110 | 2**192G + 2**128G + 2**64G 142 // 15 | 1111 | 2**192G + 2**128G + 2**64G + G 143 // 144 // The second table follows the same style, but the terms are 2**32G, 145 // 2**96G, 2**160G, 2**224G. 146 // 147 // This is ~2KB of data. 148 var p256Precomputed = [p256Limbs * 2 * 15 * 2]uint32{ 149 0x11522878, 0xe730d41, 0xdb60179, 0x4afe2ff, 0x12883add, 0xcaddd88, 0x119e7edc, 0xd4a6eab, 0x3120bee, 150 0x1d2aac15, 0xf25357c, 0x19e45cdd, 0x5c721d0, 0x1992c5a5, 0xa237487, 0x154ba21, 0x14b10bb, 0xae3fe3, 151 0xd41a576, 0x922fc51, 0x234994f, 0x60b60d3, 0x164586ae, 0xce95f18, 0x1fe49073, 0x3fa36cc, 0x5ebcd2c, 152 0xb402f2f, 0x15c70bf, 0x1561925c, 0x5a26704, 0xda91e90, 0xcdc1c7f, 0x1ea12446, 0xe1ade1e, 0xec91f22, 153 0x26f7778, 0x566847e, 0xa0bec9e, 0x234f453, 0x1a31f21a, 0xd85e75c, 0x56c7109, 0xa267a00, 0xb57c050, 154 0x98fb57, 0xaa837cc, 0x60c0792, 0xcfa5e19, 0x61bab9e, 0x589e39b, 0xa324c5, 0x7d6dee7, 0x2976e4b, 155 0x1fc4124a, 0xa8c244b, 0x1ce86762, 0xcd61c7e, 0x1831c8e0, 0x75774e1, 0x1d96a5a9, 0x843a649, 0xc3ab0fa, 156 0x6e2e7d5, 0x7673a2a, 0x178b65e8, 0x4003e9b, 0x1a1f11c2, 0x7816ea, 0xf643e11, 0x58c43df, 0xf423fc2, 157 0x19633ffa, 0x891f2b2, 0x123c231c, 0x46add8c, 0x54700dd, 0x59e2b17, 0x172db40f, 0x83e277d, 0xb0dd609, 158 0xfd1da12, 0x35c6e52, 0x19ede20c, 0xd19e0c0, 0x97d0f40, 0xb015b19, 0x449e3f5, 0xe10c9e, 0x33ab581, 159 0x56a67ab, 0x577734d, 0x1dddc062, 0xc57b10d, 0x149b39d, 0x26a9e7b, 0xc35df9f, 0x48764cd, 0x76dbcca, 160 0xca4b366, 0xe9303ab, 0x1a7480e7, 0x57e9e81, 0x1e13eb50, 0xf466cf3, 0x6f16b20, 0x4ba3173, 0xc168c33, 161 0x15cb5439, 0x6a38e11, 0x73658bd, 0xb29564f, 0x3f6dc5b, 0x53b97e, 0x1322c4c0, 0x65dd7ff, 0x3a1e4f6, 162 0x14e614aa, 0x9246317, 0x1bc83aca, 0xad97eed, 0xd38ce4a, 0xf82b006, 0x341f077, 0xa6add89, 0x4894acd, 163 0x9f162d5, 0xf8410ef, 0x1b266a56, 0xd7f223, 0x3e0cb92, 0xe39b672, 0x6a2901a, 0x69a8556, 0x7e7c0, 164 0x9b7d8d3, 0x309a80, 0x1ad05f7f, 0xc2fb5dd, 0xcbfd41d, 0x9ceb638, 0x1051825c, 0xda0cf5b, 0x812e881, 165 0x6f35669, 0x6a56f2c, 0x1df8d184, 0x345820, 0x1477d477, 0x1645db1, 0xbe80c51, 0xc22be3e, 0xe35e65a, 166 0x1aeb7aa0, 0xc375315, 0xf67bc99, 0x7fdd7b9, 0x191fc1be, 0x61235d, 0x2c184e9, 0x1c5a839, 0x47a1e26, 167 0xb7cb456, 0x93e225d, 0x14f3c6ed, 0xccc1ac9, 0x17fe37f3, 0x4988989, 0x1a90c502, 0x2f32042, 0xa17769b, 168 0xafd8c7c, 0x8191c6e, 0x1dcdb237, 0x16200c0, 0x107b32a1, 0x66c08db, 0x10d06a02, 0x3fc93, 0x5620023, 169 0x16722b27, 0x68b5c59, 0x270fcfc, 0xfad0ecc, 0xe5de1c2, 0xeab466b, 0x2fc513c, 0x407f75c, 0xbaab133, 170 0x9705fe9, 0xb88b8e7, 0x734c993, 0x1e1ff8f, 0x19156970, 0xabd0f00, 0x10469ea7, 0x3293ac0, 0xcdc98aa, 171 0x1d843fd, 0xe14bfe8, 0x15be825f, 0x8b5212, 0xeb3fb67, 0x81cbd29, 0xbc62f16, 0x2b6fcc7, 0xf5a4e29, 172 0x13560b66, 0xc0b6ac2, 0x51ae690, 0xd41e271, 0xf3e9bd4, 0x1d70aab, 0x1029f72, 0x73e1c35, 0xee70fbc, 173 0xad81baf, 0x9ecc49a, 0x86c741e, 0xfe6be30, 0x176752e7, 0x23d416, 0x1f83de85, 0x27de188, 0x66f70b8, 174 0x181cd51f, 0x96b6e4c, 0x188f2335, 0xa5df759, 0x17a77eb6, 0xfeb0e73, 0x154ae914, 0x2f3ec51, 0x3826b59, 175 0xb91f17d, 0x1c72949, 0x1362bf0a, 0xe23fddf, 0xa5614b0, 0xf7d8f, 0x79061, 0x823d9d2, 0x8213f39, 176 0x1128ae0b, 0xd095d05, 0xb85c0c2, 0x1ecb2ef, 0x24ddc84, 0xe35e901, 0x18411a4a, 0xf5ddc3d, 0x3786689, 177 0x52260e8, 0x5ae3564, 0x542b10d, 0x8d93a45, 0x19952aa4, 0x996cc41, 0x1051a729, 0x4be3499, 0x52b23aa, 178 0x109f307e, 0x6f5b6bb, 0x1f84e1e7, 0x77a0cfa, 0x10c4df3f, 0x25a02ea, 0xb048035, 0xe31de66, 0xc6ecaa3, 179 0x28ea335, 0x2886024, 0x1372f020, 0xf55d35, 0x15e4684c, 0xf2a9e17, 0x1a4a7529, 0xcb7beb1, 0xb2a78a1, 180 0x1ab21f1f, 0x6361ccf, 0x6c9179d, 0xb135627, 0x1267b974, 0x4408bad, 0x1cbff658, 0xe3d6511, 0xc7d76f, 181 0x1cc7a69, 0xe7ee31b, 0x54fab4f, 0x2b914f, 0x1ad27a30, 0xcd3579e, 0xc50124c, 0x50daa90, 0xb13f72, 182 0xb06aa75, 0x70f5cc6, 0x1649e5aa, 0x84a5312, 0x329043c, 0x41c4011, 0x13d32411, 0xb04a838, 0xd760d2d, 183 0x1713b532, 0xbaa0c03, 0x84022ab, 0x6bcf5c1, 0x2f45379, 0x18ae070, 0x18c9e11e, 0x20bca9a, 0x66f496b, 184 0x3eef294, 0x67500d2, 0xd7f613c, 0x2dbbeb, 0xb741038, 0xe04133f, 0x1582968d, 0xbe985f7, 0x1acbc1a, 185 0x1a6a939f, 0x33e50f6, 0xd665ed4, 0xb4b7bd6, 0x1e5a3799, 0x6b33847, 0x17fa56ff, 0x65ef930, 0x21dc4a, 186 0x2b37659, 0x450fe17, 0xb357b65, 0xdf5efac, 0x15397bef, 0x9d35a7f, 0x112ac15f, 0x624e62e, 0xa90ae2f, 187 0x107eecd2, 0x1f69bbe, 0x77d6bce, 0x5741394, 0x13c684fc, 0x950c910, 0x725522b, 0xdc78583, 0x40eeabb, 188 0x1fde328a, 0xbd61d96, 0xd28c387, 0x9e77d89, 0x12550c40, 0x759cb7d, 0x367ef34, 0xae2a960, 0x91b8bdc, 189 0x93462a9, 0xf469ef, 0xb2e9aef, 0xd2ca771, 0x54e1f42, 0x7aaa49, 0x6316abb, 0x2413c8e, 0x5425bf9, 190 0x1bed3e3a, 0xf272274, 0x1f5e7326, 0x6416517, 0xea27072, 0x9cedea7, 0x6e7633, 0x7c91952, 0xd806dce, 191 0x8e2a7e1, 0xe421e1a, 0x418c9e1, 0x1dbc890, 0x1b395c36, 0xa1dc175, 0x1dc4ef73, 0x8956f34, 0xe4b5cf2, 192 0x1b0d3a18, 0x3194a36, 0x6c2641f, 0xe44124c, 0xa2f4eaa, 0xa8c25ba, 0xf927ed7, 0x627b614, 0x7371cca, 193 0xba16694, 0x417bc03, 0x7c0a7e3, 0x9c35c19, 0x1168a205, 0x8b6b00d, 0x10e3edc9, 0x9c19bf2, 0x5882229, 194 0x1b2b4162, 0xa5cef1a, 0x1543622b, 0x9bd433e, 0x364e04d, 0x7480792, 0x5c9b5b3, 0xe85ff25, 0x408ef57, 195 0x1814cfa4, 0x121b41b, 0xd248a0f, 0x3b05222, 0x39bb16a, 0xc75966d, 0xa038113, 0xa4a1769, 0x11fbc6c, 196 0x917e50e, 0xeec3da8, 0x169d6eac, 0x10c1699, 0xa416153, 0xf724912, 0x15cd60b7, 0x4acbad9, 0x5efc5fa, 197 0xf150ed7, 0x122b51, 0x1104b40a, 0xcb7f442, 0xfbb28ff, 0x6ac53ca, 0x196142cc, 0x7bf0fa9, 0x957651, 198 0x4e0f215, 0xed439f8, 0x3f46bd5, 0x5ace82f, 0x110916b6, 0x6db078, 0xffd7d57, 0xf2ecaac, 0xca86dec, 199 0x15d6b2da, 0x965ecc9, 0x1c92b4c2, 0x1f3811, 0x1cb080f5, 0x2d8b804, 0x19d1c12d, 0xf20bd46, 0x1951fa7, 200 0xa3656c3, 0x523a425, 0xfcd0692, 0xd44ddc8, 0x131f0f5b, 0xaf80e4a, 0xcd9fc74, 0x99bb618, 0x2db944c, 201 0xa673090, 0x1c210e1, 0x178c8d23, 0x1474383, 0x10b8743d, 0x985a55b, 0x2e74779, 0x576138, 0x9587927, 202 0x133130fa, 0xbe05516, 0x9f4d619, 0xbb62570, 0x99ec591, 0xd9468fe, 0x1d07782d, 0xfc72e0b, 0x701b298, 203 0x1863863b, 0x85954b8, 0x121a0c36, 0x9e7fedf, 0xf64b429, 0x9b9d71e, 0x14e2f5d8, 0xf858d3a, 0x942eea8, 204 0xda5b765, 0x6edafff, 0xa9d18cc, 0xc65e4ba, 0x1c747e86, 0xe4ea915, 0x1981d7a1, 0x8395659, 0x52ed4e2, 205 0x87d43b7, 0x37ab11b, 0x19d292ce, 0xf8d4692, 0x18c3053f, 0x8863e13, 0x4c146c0, 0x6bdf55a, 0x4e4457d, 206 0x16152289, 0xac78ec2, 0x1a59c5a2, 0x2028b97, 0x71c2d01, 0x295851f, 0x404747b, 0x878558d, 0x7d29aa4, 207 0x13d8341f, 0x8daefd7, 0x139c972d, 0x6b7ea75, 0xd4a9dde, 0xff163d8, 0x81d55d7, 0xa5bef68, 0xb7b30d8, 208 0xbe73d6f, 0xaa88141, 0xd976c81, 0x7e7a9cc, 0x18beb771, 0xd773cbd, 0x13f51951, 0x9d0c177, 0x1c49a78, 209 } 210 211 // Field element operations: 212 213 // nonZeroToAllOnes returns: 214 // 0xffffffff for 0 < x <= 2**31 215 // 0 for x == 0 or x > 2**31. 216 func nonZeroToAllOnes(x uint32) uint32 { 217 return ((x - 1) >> 31) - 1 218 } 219 220 // p256ReduceCarry adds a multiple of p in order to cancel |carry|, 221 // which is a term at 2**257. 222 // 223 // On entry: carry < 2**3, inout[0,2,...] < 2**29, inout[1,3,...] < 2**28. 224 // On exit: inout[0,2,..] < 2**30, inout[1,3,...] < 2**29. 225 func p256ReduceCarry(inout *[p256Limbs]uint32, carry uint32) { 226 carry_mask := nonZeroToAllOnes(carry) 227 228 inout[0] += carry << 1 229 inout[3] += 0x10000000 & carry_mask 230 // carry < 2**3 thus (carry << 11) < 2**14 and we added 2**28 in the 231 // previous line therefore this doesn't underflow. 232 inout[3] -= carry << 11 233 inout[4] += (0x20000000 - 1) & carry_mask 234 inout[5] += (0x10000000 - 1) & carry_mask 235 inout[6] += (0x20000000 - 1) & carry_mask 236 inout[6] -= carry << 22 237 // This may underflow if carry is non-zero but, if so, we'll fix it in the 238 // next line. 239 inout[7] -= 1 & carry_mask 240 inout[7] += carry << 25 241 } 242 243 // p256Sum sets out = in+in2. 244 // 245 // On entry, in[i]+in2[i] must not overflow a 32-bit word. 246 // On exit: out[0,2,...] < 2**30, out[1,3,...] < 2**29 247 func p256Sum(out, in, in2 *[p256Limbs]uint32) { 248 carry := uint32(0) 249 for i := 0; ; i++ { 250 out[i] = in[i] + in2[i] 251 out[i] += carry 252 carry = out[i] >> 29 253 out[i] &= bottom29Bits 254 255 i++ 256 if i == p256Limbs { 257 break 258 } 259 260 out[i] = in[i] + in2[i] 261 out[i] += carry 262 carry = out[i] >> 28 263 out[i] &= bottom28Bits 264 } 265 266 p256ReduceCarry(out, carry) 267 } 268 269 const ( 270 two30m2 = 1<<30 - 1<<2 271 two30p13m2 = 1<<30 + 1<<13 - 1<<2 272 two31m2 = 1<<31 - 1<<2 273 two31p24m2 = 1<<31 + 1<<24 - 1<<2 274 two30m27m2 = 1<<30 - 1<<27 - 1<<2 275 ) 276 277 // p256Zero31 is 0 mod p. 278 var p256Zero31 = [p256Limbs]uint32{two31m3, two30m2, two31m2, two30p13m2, two31m2, two30m2, two31p24m2, two30m27m2, two31m2} 279 280 // p256Diff sets out = in-in2. 281 // 282 // On entry: in[0,2,...] < 2**30, in[1,3,...] < 2**29 and 283 // in2[0,2,...] < 2**30, in2[1,3,...] < 2**29. 284 // On exit: out[0,2,...] < 2**30, out[1,3,...] < 2**29. 285 func p256Diff(out, in, in2 *[p256Limbs]uint32) { 286 var carry uint32 287 288 for i := 0; ; i++ { 289 out[i] = in[i] - in2[i] 290 out[i] += p256Zero31[i] 291 out[i] += carry 292 carry = out[i] >> 29 293 out[i] &= bottom29Bits 294 295 i++ 296 if i == p256Limbs { 297 break 298 } 299 300 out[i] = in[i] - in2[i] 301 out[i] += p256Zero31[i] 302 out[i] += carry 303 carry = out[i] >> 28 304 out[i] &= bottom28Bits 305 } 306 307 p256ReduceCarry(out, carry) 308 } 309 310 // p256ReduceDegree sets out = tmp/R mod p where tmp contains 64-bit words with 311 // the same 29,28,... bit positions as an field element. 312 // 313 // The values in field elements are in Montgomery form: x*R mod p where R = 314 // 2**257. Since we just multiplied two Montgomery values together, the result 315 // is x*y*R*R mod p. We wish to divide by R in order for the result also to be 316 // in Montgomery form. 317 // 318 // On entry: tmp[i] < 2**64 319 // On exit: out[0,2,...] < 2**30, out[1,3,...] < 2**29 320 func p256ReduceDegree(out *[p256Limbs]uint32, tmp [17]uint64) { 321 // The following table may be helpful when reading this code: 322 // 323 // Limb number: 0 | 1 | 2 | 3 | 4 | 5 | 6 | 7 | 8 | 9 | 10... 324 // Width (bits): 29| 28| 29| 28| 29| 28| 29| 28| 29| 28| 29 325 // Start bit: 0 | 29| 57| 86|114|143|171|200|228|257|285 326 // (odd phase): 0 | 28| 57| 85|114|142|171|199|228|256|285 327 var tmp2 [18]uint32 328 var carry, x, xMask uint32 329 330 // tmp contains 64-bit words with the same 29,28,29-bit positions as an 331 // field element. So the top of an element of tmp might overlap with 332 // another element two positions down. The following loop eliminates 333 // this overlap. 334 tmp2[0] = uint32(tmp[0]) & bottom29Bits 335 336 tmp2[1] = uint32(tmp[0]) >> 29 337 tmp2[1] |= (uint32(tmp[0]>>32) << 3) & bottom28Bits 338 tmp2[1] += uint32(tmp[1]) & bottom28Bits 339 carry = tmp2[1] >> 28 340 tmp2[1] &= bottom28Bits 341 342 for i := 2; i < 17; i++ { 343 tmp2[i] = (uint32(tmp[i-2] >> 32)) >> 25 344 tmp2[i] += (uint32(tmp[i-1])) >> 28 345 tmp2[i] += (uint32(tmp[i-1]>>32) << 4) & bottom29Bits 346 tmp2[i] += uint32(tmp[i]) & bottom29Bits 347 tmp2[i] += carry 348 carry = tmp2[i] >> 29 349 tmp2[i] &= bottom29Bits 350 351 i++ 352 if i == 17 { 353 break 354 } 355 tmp2[i] = uint32(tmp[i-2]>>32) >> 25 356 tmp2[i] += uint32(tmp[i-1]) >> 29 357 tmp2[i] += ((uint32(tmp[i-1] >> 32)) << 3) & bottom28Bits 358 tmp2[i] += uint32(tmp[i]) & bottom28Bits 359 tmp2[i] += carry 360 carry = tmp2[i] >> 28 361 tmp2[i] &= bottom28Bits 362 } 363 364 tmp2[17] = uint32(tmp[15]>>32) >> 25 365 tmp2[17] += uint32(tmp[16]) >> 29 366 tmp2[17] += uint32(tmp[16]>>32) << 3 367 tmp2[17] += carry 368 369 // Montgomery elimination of terms: 370 // 371 // Since R is 2**257, we can divide by R with a bitwise shift if we can 372 // ensure that the right-most 257 bits are all zero. We can make that true 373 // by adding multiplies of p without affecting the value. 374 // 375 // So we eliminate limbs from right to left. Since the bottom 29 bits of p 376 // are all ones, then by adding tmp2[0]*p to tmp2 we'll make tmp2[0] == 0. 377 // We can do that for 8 further limbs and then right shift to eliminate the 378 // extra factor of R. 379 for i := 0; ; i += 2 { 380 tmp2[i+1] += tmp2[i] >> 29 381 x = tmp2[i] & bottom29Bits 382 xMask = nonZeroToAllOnes(x) 383 tmp2[i] = 0 384 385 // The bounds calculations for this loop are tricky. Each iteration of 386 // the loop eliminates two words by adding values to words to their 387 // right. 388 // 389 // The following table contains the amounts added to each word (as an 390 // offset from the value of i at the top of the loop). The amounts are 391 // accounted for from the first and second half of the loop separately 392 // and are written as, for example, 28 to mean a value <2**28. 393 // 394 // Word: 3 4 5 6 7 8 9 10 395 // Added in top half: 28 11 29 21 29 28 396 // 28 29 397 // 29 398 // Added in bottom half: 29 10 28 21 28 28 399 // 29 400 // 401 // The value that is currently offset 7 will be offset 5 for the next 402 // iteration and then offset 3 for the iteration after that. Therefore 403 // the total value added will be the values added at 7, 5 and 3. 404 // 405 // The following table accumulates these values. The sums at the bottom 406 // are written as, for example, 29+28, to mean a value < 2**29+2**28. 407 // 408 // Word: 3 4 5 6 7 8 9 10 11 12 13 409 // 28 11 10 29 21 29 28 28 28 28 28 410 // 29 28 11 28 29 28 29 28 29 28 411 // 29 28 21 21 29 21 29 21 412 // 10 29 28 21 28 21 28 413 // 28 29 28 29 28 29 28 414 // 11 10 29 10 29 10 415 // 29 28 11 28 11 416 // 29 29 417 // -------------------------------------------- 418 // 30+ 31+ 30+ 31+ 30+ 419 // 28+ 29+ 28+ 29+ 21+ 420 // 21+ 28+ 21+ 28+ 10 421 // 10 21+ 10 21+ 422 // 11 11 423 // 424 // So the greatest amount is added to tmp2[10] and tmp2[12]. If 425 // tmp2[10/12] has an initial value of <2**29, then the maximum value 426 // will be < 2**31 + 2**30 + 2**28 + 2**21 + 2**11, which is < 2**32, 427 // as required. 428 tmp2[i+3] += (x << 10) & bottom28Bits 429 tmp2[i+4] += (x >> 18) 430 431 tmp2[i+6] += (x << 21) & bottom29Bits 432 tmp2[i+7] += x >> 8 433 434 // At position 200, which is the starting bit position for word 7, we 435 // have a factor of 0xf000000 = 2**28 - 2**24. 436 tmp2[i+7] += 0x10000000 & xMask 437 tmp2[i+8] += (x - 1) & xMask 438 tmp2[i+7] -= (x << 24) & bottom28Bits 439 tmp2[i+8] -= x >> 4 440 441 tmp2[i+8] += 0x20000000 & xMask 442 tmp2[i+8] -= x 443 tmp2[i+8] += (x << 28) & bottom29Bits 444 tmp2[i+9] += ((x >> 1) - 1) & xMask 445 446 if i+1 == p256Limbs { 447 break 448 } 449 tmp2[i+2] += tmp2[i+1] >> 28 450 x = tmp2[i+1] & bottom28Bits 451 xMask = nonZeroToAllOnes(x) 452 tmp2[i+1] = 0 453 454 tmp2[i+4] += (x << 11) & bottom29Bits 455 tmp2[i+5] += (x >> 18) 456 457 tmp2[i+7] += (x << 21) & bottom28Bits 458 tmp2[i+8] += x >> 7 459 460 // At position 199, which is the starting bit of the 8th word when 461 // dealing with a context starting on an odd word, we have a factor of 462 // 0x1e000000 = 2**29 - 2**25. Since we have not updated i, the 8th 463 // word from i+1 is i+8. 464 tmp2[i+8] += 0x20000000 & xMask 465 tmp2[i+9] += (x - 1) & xMask 466 tmp2[i+8] -= (x << 25) & bottom29Bits 467 tmp2[i+9] -= x >> 4 468 469 tmp2[i+9] += 0x10000000 & xMask 470 tmp2[i+9] -= x 471 tmp2[i+10] += (x - 1) & xMask 472 } 473 474 // We merge the right shift with a carry chain. The words above 2**257 have 475 // widths of 28,29,... which we need to correct when copying them down. 476 carry = 0 477 for i := 0; i < 8; i++ { 478 // The maximum value of tmp2[i + 9] occurs on the first iteration and 479 // is < 2**30+2**29+2**28. Adding 2**29 (from tmp2[i + 10]) is 480 // therefore safe. 481 out[i] = tmp2[i+9] 482 out[i] += carry 483 out[i] += (tmp2[i+10] << 28) & bottom29Bits 484 carry = out[i] >> 29 485 out[i] &= bottom29Bits 486 487 i++ 488 out[i] = tmp2[i+9] >> 1 489 out[i] += carry 490 carry = out[i] >> 28 491 out[i] &= bottom28Bits 492 } 493 494 out[8] = tmp2[17] 495 out[8] += carry 496 carry = out[8] >> 29 497 out[8] &= bottom29Bits 498 499 p256ReduceCarry(out, carry) 500 } 501 502 // p256Square sets out=in*in. 503 // 504 // On entry: in[0,2,...] < 2**30, in[1,3,...] < 2**29. 505 // On exit: out[0,2,...] < 2**30, out[1,3,...] < 2**29. 506 func p256Square(out, in *[p256Limbs]uint32) { 507 var tmp [17]uint64 508 509 tmp[0] = uint64(in[0]) * uint64(in[0]) 510 tmp[1] = uint64(in[0]) * (uint64(in[1]) << 1) 511 tmp[2] = uint64(in[0])*(uint64(in[2])<<1) + 512 uint64(in[1])*(uint64(in[1])<<1) 513 tmp[3] = uint64(in[0])*(uint64(in[3])<<1) + 514 uint64(in[1])*(uint64(in[2])<<1) 515 tmp[4] = uint64(in[0])*(uint64(in[4])<<1) + 516 uint64(in[1])*(uint64(in[3])<<2) + 517 uint64(in[2])*uint64(in[2]) 518 tmp[5] = uint64(in[0])*(uint64(in[5])<<1) + 519 uint64(in[1])*(uint64(in[4])<<1) + 520 uint64(in[2])*(uint64(in[3])<<1) 521 tmp[6] = uint64(in[0])*(uint64(in[6])<<1) + 522 uint64(in[1])*(uint64(in[5])<<2) + 523 uint64(in[2])*(uint64(in[4])<<1) + 524 uint64(in[3])*(uint64(in[3])<<1) 525 tmp[7] = uint64(in[0])*(uint64(in[7])<<1) + 526 uint64(in[1])*(uint64(in[6])<<1) + 527 uint64(in[2])*(uint64(in[5])<<1) + 528 uint64(in[3])*(uint64(in[4])<<1) 529 // tmp[8] has the greatest value of 2**61 + 2**60 + 2**61 + 2**60 + 2**60, 530 // which is < 2**64 as required. 531 tmp[8] = uint64(in[0])*(uint64(in[8])<<1) + 532 uint64(in[1])*(uint64(in[7])<<2) + 533 uint64(in[2])*(uint64(in[6])<<1) + 534 uint64(in[3])*(uint64(in[5])<<2) + 535 uint64(in[4])*uint64(in[4]) 536 tmp[9] = uint64(in[1])*(uint64(in[8])<<1) + 537 uint64(in[2])*(uint64(in[7])<<1) + 538 uint64(in[3])*(uint64(in[6])<<1) + 539 uint64(in[4])*(uint64(in[5])<<1) 540 tmp[10] = uint64(in[2])*(uint64(in[8])<<1) + 541 uint64(in[3])*(uint64(in[7])<<2) + 542 uint64(in[4])*(uint64(in[6])<<1) + 543 uint64(in[5])*(uint64(in[5])<<1) 544 tmp[11] = uint64(in[3])*(uint64(in[8])<<1) + 545 uint64(in[4])*(uint64(in[7])<<1) + 546 uint64(in[5])*(uint64(in[6])<<1) 547 tmp[12] = uint64(in[4])*(uint64(in[8])<<1) + 548 uint64(in[5])*(uint64(in[7])<<2) + 549 uint64(in[6])*uint64(in[6]) 550 tmp[13] = uint64(in[5])*(uint64(in[8])<<1) + 551 uint64(in[6])*(uint64(in[7])<<1) 552 tmp[14] = uint64(in[6])*(uint64(in[8])<<1) + 553 uint64(in[7])*(uint64(in[7])<<1) 554 tmp[15] = uint64(in[7]) * (uint64(in[8]) << 1) 555 tmp[16] = uint64(in[8]) * uint64(in[8]) 556 557 p256ReduceDegree(out, tmp) 558 } 559 560 // p256Mul sets out=in*in2. 561 // 562 // On entry: in[0,2,...] < 2**30, in[1,3,...] < 2**29 and 563 // in2[0,2,...] < 2**30, in2[1,3,...] < 2**29. 564 // On exit: out[0,2,...] < 2**30, out[1,3,...] < 2**29. 565 func p256Mul(out, in, in2 *[p256Limbs]uint32) { 566 var tmp [17]uint64 567 568 tmp[0] = uint64(in[0]) * uint64(in2[0]) 569 tmp[1] = uint64(in[0])*(uint64(in2[1])<<0) + 570 uint64(in[1])*(uint64(in2[0])<<0) 571 tmp[2] = uint64(in[0])*(uint64(in2[2])<<0) + 572 uint64(in[1])*(uint64(in2[1])<<1) + 573 uint64(in[2])*(uint64(in2[0])<<0) 574 tmp[3] = uint64(in[0])*(uint64(in2[3])<<0) + 575 uint64(in[1])*(uint64(in2[2])<<0) + 576 uint64(in[2])*(uint64(in2[1])<<0) + 577 uint64(in[3])*(uint64(in2[0])<<0) 578 tmp[4] = uint64(in[0])*(uint64(in2[4])<<0) + 579 uint64(in[1])*(uint64(in2[3])<<1) + 580 uint64(in[2])*(uint64(in2[2])<<0) + 581 uint64(in[3])*(uint64(in2[1])<<1) + 582 uint64(in[4])*(uint64(in2[0])<<0) 583 tmp[5] = uint64(in[0])*(uint64(in2[5])<<0) + 584 uint64(in[1])*(uint64(in2[4])<<0) + 585 uint64(in[2])*(uint64(in2[3])<<0) + 586 uint64(in[3])*(uint64(in2[2])<<0) + 587 uint64(in[4])*(uint64(in2[1])<<0) + 588 uint64(in[5])*(uint64(in2[0])<<0) 589 tmp[6] = uint64(in[0])*(uint64(in2[6])<<0) + 590 uint64(in[1])*(uint64(in2[5])<<1) + 591 uint64(in[2])*(uint64(in2[4])<<0) + 592 uint64(in[3])*(uint64(in2[3])<<1) + 593 uint64(in[4])*(uint64(in2[2])<<0) + 594 uint64(in[5])*(uint64(in2[1])<<1) + 595 uint64(in[6])*(uint64(in2[0])<<0) 596 tmp[7] = uint64(in[0])*(uint64(in2[7])<<0) + 597 uint64(in[1])*(uint64(in2[6])<<0) + 598 uint64(in[2])*(uint64(in2[5])<<0) + 599 uint64(in[3])*(uint64(in2[4])<<0) + 600 uint64(in[4])*(uint64(in2[3])<<0) + 601 uint64(in[5])*(uint64(in2[2])<<0) + 602 uint64(in[6])*(uint64(in2[1])<<0) + 603 uint64(in[7])*(uint64(in2[0])<<0) 604 // tmp[8] has the greatest value but doesn't overflow. See logic in 605 // p256Square. 606 tmp[8] = uint64(in[0])*(uint64(in2[8])<<0) + 607 uint64(in[1])*(uint64(in2[7])<<1) + 608 uint64(in[2])*(uint64(in2[6])<<0) + 609 uint64(in[3])*(uint64(in2[5])<<1) + 610 uint64(in[4])*(uint64(in2[4])<<0) + 611 uint64(in[5])*(uint64(in2[3])<<1) + 612 uint64(in[6])*(uint64(in2[2])<<0) + 613 uint64(in[7])*(uint64(in2[1])<<1) + 614 uint64(in[8])*(uint64(in2[0])<<0) 615 tmp[9] = uint64(in[1])*(uint64(in2[8])<<0) + 616 uint64(in[2])*(uint64(in2[7])<<0) + 617 uint64(in[3])*(uint64(in2[6])<<0) + 618 uint64(in[4])*(uint64(in2[5])<<0) + 619 uint64(in[5])*(uint64(in2[4])<<0) + 620 uint64(in[6])*(uint64(in2[3])<<0) + 621 uint64(in[7])*(uint64(in2[2])<<0) + 622 uint64(in[8])*(uint64(in2[1])<<0) 623 tmp[10] = uint64(in[2])*(uint64(in2[8])<<0) + 624 uint64(in[3])*(uint64(in2[7])<<1) + 625 uint64(in[4])*(uint64(in2[6])<<0) + 626 uint64(in[5])*(uint64(in2[5])<<1) + 627 uint64(in[6])*(uint64(in2[4])<<0) + 628 uint64(in[7])*(uint64(in2[3])<<1) + 629 uint64(in[8])*(uint64(in2[2])<<0) 630 tmp[11] = uint64(in[3])*(uint64(in2[8])<<0) + 631 uint64(in[4])*(uint64(in2[7])<<0) + 632 uint64(in[5])*(uint64(in2[6])<<0) + 633 uint64(in[6])*(uint64(in2[5])<<0) + 634 uint64(in[7])*(uint64(in2[4])<<0) + 635 uint64(in[8])*(uint64(in2[3])<<0) 636 tmp[12] = uint64(in[4])*(uint64(in2[8])<<0) + 637 uint64(in[5])*(uint64(in2[7])<<1) + 638 uint64(in[6])*(uint64(in2[6])<<0) + 639 uint64(in[7])*(uint64(in2[5])<<1) + 640 uint64(in[8])*(uint64(in2[4])<<0) 641 tmp[13] = uint64(in[5])*(uint64(in2[8])<<0) + 642 uint64(in[6])*(uint64(in2[7])<<0) + 643 uint64(in[7])*(uint64(in2[6])<<0) + 644 uint64(in[8])*(uint64(in2[5])<<0) 645 tmp[14] = uint64(in[6])*(uint64(in2[8])<<0) + 646 uint64(in[7])*(uint64(in2[7])<<1) + 647 uint64(in[8])*(uint64(in2[6])<<0) 648 tmp[15] = uint64(in[7])*(uint64(in2[8])<<0) + 649 uint64(in[8])*(uint64(in2[7])<<0) 650 tmp[16] = uint64(in[8]) * (uint64(in2[8]) << 0) 651 652 p256ReduceDegree(out, tmp) 653 } 654 655 func p256Assign(out, in *[p256Limbs]uint32) { 656 *out = *in 657 } 658 659 // p256Invert calculates |out| = |in|^{-1} 660 // 661 // Based on Fermat's Little Theorem: 662 // a^p = a (mod p) 663 // a^{p-1} = 1 (mod p) 664 // a^{p-2} = a^{-1} (mod p) 665 func p256Invert(out, in *[p256Limbs]uint32) { 666 var ftmp, ftmp2 [p256Limbs]uint32 667 668 // each e_I will hold |in|^{2^I - 1} 669 var e2, e4, e8, e16, e32, e64 [p256Limbs]uint32 670 671 p256Square(&ftmp, in) // 2^1 672 p256Mul(&ftmp, in, &ftmp) // 2^2 - 2^0 673 p256Assign(&e2, &ftmp) 674 p256Square(&ftmp, &ftmp) // 2^3 - 2^1 675 p256Square(&ftmp, &ftmp) // 2^4 - 2^2 676 p256Mul(&ftmp, &ftmp, &e2) // 2^4 - 2^0 677 p256Assign(&e4, &ftmp) 678 p256Square(&ftmp, &ftmp) // 2^5 - 2^1 679 p256Square(&ftmp, &ftmp) // 2^6 - 2^2 680 p256Square(&ftmp, &ftmp) // 2^7 - 2^3 681 p256Square(&ftmp, &ftmp) // 2^8 - 2^4 682 p256Mul(&ftmp, &ftmp, &e4) // 2^8 - 2^0 683 p256Assign(&e8, &ftmp) 684 for i := 0; i < 8; i++ { 685 p256Square(&ftmp, &ftmp) 686 } // 2^16 - 2^8 687 p256Mul(&ftmp, &ftmp, &e8) // 2^16 - 2^0 688 p256Assign(&e16, &ftmp) 689 for i := 0; i < 16; i++ { 690 p256Square(&ftmp, &ftmp) 691 } // 2^32 - 2^16 692 p256Mul(&ftmp, &ftmp, &e16) // 2^32 - 2^0 693 p256Assign(&e32, &ftmp) 694 for i := 0; i < 32; i++ { 695 p256Square(&ftmp, &ftmp) 696 } // 2^64 - 2^32 697 p256Assign(&e64, &ftmp) 698 p256Mul(&ftmp, &ftmp, in) // 2^64 - 2^32 + 2^0 699 for i := 0; i < 192; i++ { 700 p256Square(&ftmp, &ftmp) 701 } // 2^256 - 2^224 + 2^192 702 703 p256Mul(&ftmp2, &e64, &e32) // 2^64 - 2^0 704 for i := 0; i < 16; i++ { 705 p256Square(&ftmp2, &ftmp2) 706 } // 2^80 - 2^16 707 p256Mul(&ftmp2, &ftmp2, &e16) // 2^80 - 2^0 708 for i := 0; i < 8; i++ { 709 p256Square(&ftmp2, &ftmp2) 710 } // 2^88 - 2^8 711 p256Mul(&ftmp2, &ftmp2, &e8) // 2^88 - 2^0 712 for i := 0; i < 4; i++ { 713 p256Square(&ftmp2, &ftmp2) 714 } // 2^92 - 2^4 715 p256Mul(&ftmp2, &ftmp2, &e4) // 2^92 - 2^0 716 p256Square(&ftmp2, &ftmp2) // 2^93 - 2^1 717 p256Square(&ftmp2, &ftmp2) // 2^94 - 2^2 718 p256Mul(&ftmp2, &ftmp2, &e2) // 2^94 - 2^0 719 p256Square(&ftmp2, &ftmp2) // 2^95 - 2^1 720 p256Square(&ftmp2, &ftmp2) // 2^96 - 2^2 721 p256Mul(&ftmp2, &ftmp2, in) // 2^96 - 3 722 723 p256Mul(out, &ftmp2, &ftmp) // 2^256 - 2^224 + 2^192 + 2^96 - 3 724 } 725 726 // p256Scalar3 sets out=3*out. 727 // 728 // On entry: out[0,2,...] < 2**30, out[1,3,...] < 2**29. 729 // On exit: out[0,2,...] < 2**30, out[1,3,...] < 2**29. 730 func p256Scalar3(out *[p256Limbs]uint32) { 731 var carry uint32 732 733 for i := 0; ; i++ { 734 out[i] *= 3 735 out[i] += carry 736 carry = out[i] >> 29 737 out[i] &= bottom29Bits 738 739 i++ 740 if i == p256Limbs { 741 break 742 } 743 744 out[i] *= 3 745 out[i] += carry 746 carry = out[i] >> 28 747 out[i] &= bottom28Bits 748 } 749 750 p256ReduceCarry(out, carry) 751 } 752 753 // p256Scalar4 sets out=4*out. 754 // 755 // On entry: out[0,2,...] < 2**30, out[1,3,...] < 2**29. 756 // On exit: out[0,2,...] < 2**30, out[1,3,...] < 2**29. 757 func p256Scalar4(out *[p256Limbs]uint32) { 758 var carry, nextCarry uint32 759 760 for i := 0; ; i++ { 761 nextCarry = out[i] >> 27 762 out[i] <<= 2 763 out[i] &= bottom29Bits 764 out[i] += carry 765 carry = nextCarry + (out[i] >> 29) 766 out[i] &= bottom29Bits 767 768 i++ 769 if i == p256Limbs { 770 break 771 } 772 nextCarry = out[i] >> 26 773 out[i] <<= 2 774 out[i] &= bottom28Bits 775 out[i] += carry 776 carry = nextCarry + (out[i] >> 28) 777 out[i] &= bottom28Bits 778 } 779 780 p256ReduceCarry(out, carry) 781 } 782 783 // p256Scalar8 sets out=8*out. 784 // 785 // On entry: out[0,2,...] < 2**30, out[1,3,...] < 2**29. 786 // On exit: out[0,2,...] < 2**30, out[1,3,...] < 2**29. 787 func p256Scalar8(out *[p256Limbs]uint32) { 788 var carry, nextCarry uint32 789 790 for i := 0; ; i++ { 791 nextCarry = out[i] >> 26 792 out[i] <<= 3 793 out[i] &= bottom29Bits 794 out[i] += carry 795 carry = nextCarry + (out[i] >> 29) 796 out[i] &= bottom29Bits 797 798 i++ 799 if i == p256Limbs { 800 break 801 } 802 nextCarry = out[i] >> 25 803 out[i] <<= 3 804 out[i] &= bottom28Bits 805 out[i] += carry 806 carry = nextCarry + (out[i] >> 28) 807 out[i] &= bottom28Bits 808 } 809 810 p256ReduceCarry(out, carry) 811 } 812 813 // Group operations: 814 // 815 // Elements of the elliptic curve group are represented in Jacobian 816 // coordinates: (x, y, z). An affine point (x', y') is x'=x/z**2, y'=y/z**3 in 817 // Jacobian form. 818 819 // p256PointDouble sets {xOut,yOut,zOut} = 2*{x,y,z}. 820 // 821 // See https://www.hyperelliptic.org/EFD/g1p/auto-shortw-jacobian-0.html#doubling-dbl-2009-l 822 func p256PointDouble(xOut, yOut, zOut, x, y, z *[p256Limbs]uint32) { 823 var delta, gamma, alpha, beta, tmp, tmp2 [p256Limbs]uint32 824 825 p256Square(&delta, z) 826 p256Square(&gamma, y) 827 p256Mul(&beta, x, &gamma) 828 829 p256Sum(&tmp, x, &delta) 830 p256Diff(&tmp2, x, &delta) 831 p256Mul(&alpha, &tmp, &tmp2) 832 p256Scalar3(&alpha) 833 834 p256Sum(&tmp, y, z) 835 p256Square(&tmp, &tmp) 836 p256Diff(&tmp, &tmp, &gamma) 837 p256Diff(zOut, &tmp, &delta) 838 839 p256Scalar4(&beta) 840 p256Square(xOut, &alpha) 841 p256Diff(xOut, xOut, &beta) 842 p256Diff(xOut, xOut, &beta) 843 844 p256Diff(&tmp, &beta, xOut) 845 p256Mul(&tmp, &alpha, &tmp) 846 p256Square(&tmp2, &gamma) 847 p256Scalar8(&tmp2) 848 p256Diff(yOut, &tmp, &tmp2) 849 } 850 851 // p256PointAddMixed sets {xOut,yOut,zOut} = {x1,y1,z1} + {x2,y2,1}. 852 // (i.e. the second point is affine.) 853 // 854 // See https://www.hyperelliptic.org/EFD/g1p/auto-shortw-jacobian-0.html#addition-add-2007-bl 855 // 856 // Note that this function does not handle P+P, infinity+P nor P+infinity 857 // correctly. 858 func p256PointAddMixed(xOut, yOut, zOut, x1, y1, z1, x2, y2 *[p256Limbs]uint32) { 859 var z1z1, z1z1z1, s2, u2, h, i, j, r, rr, v, tmp [p256Limbs]uint32 860 861 p256Square(&z1z1, z1) 862 p256Sum(&tmp, z1, z1) 863 864 p256Mul(&u2, x2, &z1z1) 865 p256Mul(&z1z1z1, z1, &z1z1) 866 p256Mul(&s2, y2, &z1z1z1) 867 p256Diff(&h, &u2, x1) 868 p256Sum(&i, &h, &h) 869 p256Square(&i, &i) 870 p256Mul(&j, &h, &i) 871 p256Diff(&r, &s2, y1) 872 p256Sum(&r, &r, &r) 873 p256Mul(&v, x1, &i) 874 875 p256Mul(zOut, &tmp, &h) 876 p256Square(&rr, &r) 877 p256Diff(xOut, &rr, &j) 878 p256Diff(xOut, xOut, &v) 879 p256Diff(xOut, xOut, &v) 880 881 p256Diff(&tmp, &v, xOut) 882 p256Mul(yOut, &tmp, &r) 883 p256Mul(&tmp, y1, &j) 884 p256Diff(yOut, yOut, &tmp) 885 p256Diff(yOut, yOut, &tmp) 886 } 887 888 // p256PointAdd sets {xOut,yOut,zOut} = {x1,y1,z1} + {x2,y2,z2}. 889 // 890 // See https://www.hyperelliptic.org/EFD/g1p/auto-shortw-jacobian-0.html#addition-add-2007-bl 891 // 892 // Note that this function does not handle P+P, infinity+P nor P+infinity 893 // correctly. 894 func p256PointAdd(xOut, yOut, zOut, x1, y1, z1, x2, y2, z2 *[p256Limbs]uint32) { 895 var z1z1, z1z1z1, z2z2, z2z2z2, s1, s2, u1, u2, h, i, j, r, rr, v, tmp [p256Limbs]uint32 896 897 p256Square(&z1z1, z1) 898 p256Square(&z2z2, z2) 899 p256Mul(&u1, x1, &z2z2) 900 901 p256Sum(&tmp, z1, z2) 902 p256Square(&tmp, &tmp) 903 p256Diff(&tmp, &tmp, &z1z1) 904 p256Diff(&tmp, &tmp, &z2z2) 905 906 p256Mul(&z2z2z2, z2, &z2z2) 907 p256Mul(&s1, y1, &z2z2z2) 908 909 p256Mul(&u2, x2, &z1z1) 910 p256Mul(&z1z1z1, z1, &z1z1) 911 p256Mul(&s2, y2, &z1z1z1) 912 p256Diff(&h, &u2, &u1) 913 p256Sum(&i, &h, &h) 914 p256Square(&i, &i) 915 p256Mul(&j, &h, &i) 916 p256Diff(&r, &s2, &s1) 917 p256Sum(&r, &r, &r) 918 p256Mul(&v, &u1, &i) 919 920 p256Mul(zOut, &tmp, &h) 921 p256Square(&rr, &r) 922 p256Diff(xOut, &rr, &j) 923 p256Diff(xOut, xOut, &v) 924 p256Diff(xOut, xOut, &v) 925 926 p256Diff(&tmp, &v, xOut) 927 p256Mul(yOut, &tmp, &r) 928 p256Mul(&tmp, &s1, &j) 929 p256Diff(yOut, yOut, &tmp) 930 p256Diff(yOut, yOut, &tmp) 931 } 932 933 // p256CopyConditional sets out=in if mask = 0xffffffff in constant time. 934 // 935 // On entry: mask is either 0 or 0xffffffff. 936 func p256CopyConditional(out, in *[p256Limbs]uint32, mask uint32) { 937 for i := 0; i < p256Limbs; i++ { 938 tmp := mask & (in[i] ^ out[i]) 939 out[i] ^= tmp 940 } 941 } 942 943 // p256SelectAffinePoint sets {out_x,out_y} to the index'th entry of table. 944 // On entry: index < 16, table[0] must be zero. 945 func p256SelectAffinePoint(xOut, yOut *[p256Limbs]uint32, table []uint32, index uint32) { 946 for i := range xOut { 947 xOut[i] = 0 948 } 949 for i := range yOut { 950 yOut[i] = 0 951 } 952 953 for i := uint32(1); i < 16; i++ { 954 mask := i ^ index 955 mask |= mask >> 2 956 mask |= mask >> 1 957 mask &= 1 958 mask-- 959 for j := range xOut { 960 xOut[j] |= table[0] & mask 961 table = table[1:] 962 } 963 for j := range yOut { 964 yOut[j] |= table[0] & mask 965 table = table[1:] 966 } 967 } 968 } 969 970 // p256SelectJacobianPoint sets {out_x,out_y,out_z} to the index'th entry of 971 // table. 972 // On entry: index < 16, table[0] must be zero. 973 func p256SelectJacobianPoint(xOut, yOut, zOut *[p256Limbs]uint32, table *[16][3][p256Limbs]uint32, index uint32) { 974 for i := range xOut { 975 xOut[i] = 0 976 } 977 for i := range yOut { 978 yOut[i] = 0 979 } 980 for i := range zOut { 981 zOut[i] = 0 982 } 983 984 // The implicit value at index 0 is all zero. We don't need to perform that 985 // iteration of the loop because we already set out_* to zero. 986 for i := uint32(1); i < 16; i++ { 987 mask := i ^ index 988 mask |= mask >> 2 989 mask |= mask >> 1 990 mask &= 1 991 mask-- 992 for j := range xOut { 993 xOut[j] |= table[i][0][j] & mask 994 } 995 for j := range yOut { 996 yOut[j] |= table[i][1][j] & mask 997 } 998 for j := range zOut { 999 zOut[j] |= table[i][2][j] & mask 1000 } 1001 } 1002 } 1003 1004 // p256GetBit returns the bit'th bit of scalar. 1005 func p256GetBit(scalar *[32]uint8, bit uint) uint32 { 1006 return uint32(((scalar[bit>>3]) >> (bit & 7)) & 1) 1007 } 1008 1009 // p256ScalarBaseMult sets {xOut,yOut,zOut} = scalar*G where scalar is a 1010 // little-endian number. Note that the value of scalar must be less than the 1011 // order of the group. 1012 func p256ScalarBaseMult(xOut, yOut, zOut *[p256Limbs]uint32, scalar *[32]uint8) { 1013 nIsInfinityMask := ^uint32(0) 1014 var pIsNoninfiniteMask, mask, tableOffset uint32 1015 var px, py, tx, ty, tz [p256Limbs]uint32 1016 1017 for i := range xOut { 1018 xOut[i] = 0 1019 } 1020 for i := range yOut { 1021 yOut[i] = 0 1022 } 1023 for i := range zOut { 1024 zOut[i] = 0 1025 } 1026 1027 // The loop adds bits at positions 0, 64, 128 and 192, followed by 1028 // positions 32,96,160 and 224 and does this 32 times. 1029 for i := uint(0); i < 32; i++ { 1030 if i != 0 { 1031 p256PointDouble(xOut, yOut, zOut, xOut, yOut, zOut) 1032 } 1033 tableOffset = 0 1034 for j := uint(0); j <= 32; j += 32 { 1035 bit0 := p256GetBit(scalar, 31-i+j) 1036 bit1 := p256GetBit(scalar, 95-i+j) 1037 bit2 := p256GetBit(scalar, 159-i+j) 1038 bit3 := p256GetBit(scalar, 223-i+j) 1039 index := bit0 | (bit1 << 1) | (bit2 << 2) | (bit3 << 3) 1040 1041 p256SelectAffinePoint(&px, &py, p256Precomputed[tableOffset:], index) 1042 tableOffset += 30 * p256Limbs 1043 1044 // Since scalar is less than the order of the group, we know that 1045 // {xOut,yOut,zOut} != {px,py,1}, unless both are zero, which we handle 1046 // below. 1047 p256PointAddMixed(&tx, &ty, &tz, xOut, yOut, zOut, &px, &py) 1048 // The result of pointAddMixed is incorrect if {xOut,yOut,zOut} is zero 1049 // (a.k.a. the point at infinity). We handle that situation by 1050 // copying the point from the table. 1051 p256CopyConditional(xOut, &px, nIsInfinityMask) 1052 p256CopyConditional(yOut, &py, nIsInfinityMask) 1053 p256CopyConditional(zOut, &p256One, nIsInfinityMask) 1054 1055 // Equally, the result is also wrong if the point from the table is 1056 // zero, which happens when the index is zero. We handle that by 1057 // only copying from {tx,ty,tz} to {xOut,yOut,zOut} if index != 0. 1058 pIsNoninfiniteMask = nonZeroToAllOnes(index) 1059 mask = pIsNoninfiniteMask & ^nIsInfinityMask 1060 p256CopyConditional(xOut, &tx, mask) 1061 p256CopyConditional(yOut, &ty, mask) 1062 p256CopyConditional(zOut, &tz, mask) 1063 // If p was not zero, then n is now non-zero. 1064 nIsInfinityMask &^= pIsNoninfiniteMask 1065 } 1066 } 1067 } 1068 1069 // p256PointToAffine converts a Jacobian point to an affine point. If the input 1070 // is the point at infinity then it returns (0, 0) in constant time. 1071 func p256PointToAffine(xOut, yOut, x, y, z *[p256Limbs]uint32) { 1072 var zInv, zInvSq [p256Limbs]uint32 1073 1074 p256Invert(&zInv, z) 1075 p256Square(&zInvSq, &zInv) 1076 p256Mul(xOut, x, &zInvSq) 1077 p256Mul(&zInv, &zInv, &zInvSq) 1078 p256Mul(yOut, y, &zInv) 1079 } 1080 1081 // p256ToAffine returns a pair of *big.Int containing the affine representation 1082 // of {x,y,z}. 1083 func p256ToAffine(x, y, z *[p256Limbs]uint32) (xOut, yOut *big.Int) { 1084 var xx, yy [p256Limbs]uint32 1085 p256PointToAffine(&xx, &yy, x, y, z) 1086 return p256ToBig(&xx), p256ToBig(&yy) 1087 } 1088 1089 // p256ScalarMult sets {xOut,yOut,zOut} = scalar*{x,y}. 1090 func p256ScalarMult(xOut, yOut, zOut, x, y *[p256Limbs]uint32, scalar *[32]uint8) { 1091 var px, py, pz, tx, ty, tz [p256Limbs]uint32 1092 var precomp [16][3][p256Limbs]uint32 1093 var nIsInfinityMask, index, pIsNoninfiniteMask, mask uint32 1094 1095 // We precompute 0,1,2,... times {x,y}. 1096 precomp[1][0] = *x 1097 precomp[1][1] = *y 1098 precomp[1][2] = p256One 1099 1100 for i := 2; i < 16; i += 2 { 1101 p256PointDouble(&precomp[i][0], &precomp[i][1], &precomp[i][2], &precomp[i/2][0], &precomp[i/2][1], &precomp[i/2][2]) 1102 p256PointAddMixed(&precomp[i+1][0], &precomp[i+1][1], &precomp[i+1][2], &precomp[i][0], &precomp[i][1], &precomp[i][2], x, y) 1103 } 1104 1105 for i := range xOut { 1106 xOut[i] = 0 1107 } 1108 for i := range yOut { 1109 yOut[i] = 0 1110 } 1111 for i := range zOut { 1112 zOut[i] = 0 1113 } 1114 nIsInfinityMask = ^uint32(0) 1115 1116 // We add in a window of four bits each iteration and do this 64 times. 1117 for i := 0; i < 64; i++ { 1118 if i != 0 { 1119 p256PointDouble(xOut, yOut, zOut, xOut, yOut, zOut) 1120 p256PointDouble(xOut, yOut, zOut, xOut, yOut, zOut) 1121 p256PointDouble(xOut, yOut, zOut, xOut, yOut, zOut) 1122 p256PointDouble(xOut, yOut, zOut, xOut, yOut, zOut) 1123 } 1124 1125 index = uint32(scalar[31-i/2]) 1126 if (i & 1) == 1 { 1127 index &= 15 1128 } else { 1129 index >>= 4 1130 } 1131 1132 // See the comments in scalarBaseMult about handling infinities. 1133 p256SelectJacobianPoint(&px, &py, &pz, &precomp, index) 1134 p256PointAdd(&tx, &ty, &tz, xOut, yOut, zOut, &px, &py, &pz) 1135 p256CopyConditional(xOut, &px, nIsInfinityMask) 1136 p256CopyConditional(yOut, &py, nIsInfinityMask) 1137 p256CopyConditional(zOut, &pz, nIsInfinityMask) 1138 1139 pIsNoninfiniteMask = nonZeroToAllOnes(index) 1140 mask = pIsNoninfiniteMask & ^nIsInfinityMask 1141 p256CopyConditional(xOut, &tx, mask) 1142 p256CopyConditional(yOut, &ty, mask) 1143 p256CopyConditional(zOut, &tz, mask) 1144 nIsInfinityMask &^= pIsNoninfiniteMask 1145 } 1146 } 1147 1148 // p256FromBig sets out = R*in. 1149 func p256FromBig(out *[p256Limbs]uint32, in *big.Int) { 1150 tmp := new(big.Int).Lsh(in, 257) 1151 tmp.Mod(tmp, p256Params.P) 1152 1153 for i := 0; i < p256Limbs; i++ { 1154 if bits := tmp.Bits(); len(bits) > 0 { 1155 out[i] = uint32(bits[0]) & bottom29Bits 1156 } else { 1157 out[i] = 0 1158 } 1159 tmp.Rsh(tmp, 29) 1160 1161 i++ 1162 if i == p256Limbs { 1163 break 1164 } 1165 1166 if bits := tmp.Bits(); len(bits) > 0 { 1167 out[i] = uint32(bits[0]) & bottom28Bits 1168 } else { 1169 out[i] = 0 1170 } 1171 tmp.Rsh(tmp, 28) 1172 } 1173 } 1174 1175 // p256ToBig returns a *big.Int containing the value of in. 1176 func p256ToBig(in *[p256Limbs]uint32) *big.Int { 1177 result, tmp := new(big.Int), new(big.Int) 1178 1179 result.SetInt64(int64(in[p256Limbs-1])) 1180 for i := p256Limbs - 2; i >= 0; i-- { 1181 if (i & 1) == 0 { 1182 result.Lsh(result, 29) 1183 } else { 1184 result.Lsh(result, 28) 1185 } 1186 tmp.SetInt64(int64(in[i])) 1187 result.Add(result, tmp) 1188 } 1189 1190 result.Mul(result, p256RInverse) 1191 result.Mod(result, p256Params.P) 1192 return result 1193 }