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The Bouncy Castle Crypto package is a Java implementation of cryptographic algorithms. This jar contains JCE provider and lightweight API for the Bouncy Castle Cryptography APIs for JDK 1.5 to JDK 1.8 with debug enabled.
package org.bouncycastle.math.ec.custom.sec;
import java.math.BigInteger;
import org.bouncycastle.math.raw.Interleave;
import org.bouncycastle.math.raw.Nat256;
public class SecT193Field
{
private static final long M01 = 1L;
private static final long M49 = -1L >>> 15;
public static void add(long[] x, long[] y, long[] z)
{
z[0] = x[0] ^ y[0];
z[1] = x[1] ^ y[1];
z[2] = x[2] ^ y[2];
z[3] = x[3] ^ y[3];
}
public static void addExt(long[] xx, long[] yy, long[] zz)
{
zz[0] = xx[0] ^ yy[0];
zz[1] = xx[1] ^ yy[1];
zz[2] = xx[2] ^ yy[2];
zz[3] = xx[3] ^ yy[3];
zz[4] = xx[4] ^ yy[4];
zz[5] = xx[5] ^ yy[5];
zz[6] = xx[6] ^ yy[6];
}
public static void addOne(long[] x, long[] z)
{
z[0] = x[0] ^ 1L;
z[1] = x[1];
z[2] = x[2];
z[3] = x[3];
}
public static long[] fromBigInteger(BigInteger x)
{
long[] z = Nat256.fromBigInteger64(x);
reduce63(z, 0);
return z;
}
public static void invert(long[] x, long[] z)
{
if (Nat256.isZero64(x))
{
throw new IllegalStateException();
}
// Itoh-Tsujii inversion with bases { 2, 3 }
long[] t0 = Nat256.create64();
long[] t1 = Nat256.create64();
square(x, t0);
// 3 | 192
squareN(t0, 1, t1);
multiply(t0, t1, t0);
squareN(t1, 1, t1);
multiply(t0, t1, t0);
// 2 | 64
squareN(t0, 3, t1);
multiply(t0, t1, t0);
// 2 | 32
squareN(t0, 6, t1);
multiply(t0, t1, t0);
// 2 | 16
squareN(t0, 12, t1);
multiply(t0, t1, t0);
// 2 | 8
squareN(t0, 24, t1);
multiply(t0, t1, t0);
// 2 | 4
squareN(t0, 48, t1);
multiply(t0, t1, t0);
// 2 | 2
squareN(t0, 96, t1);
multiply(t0, t1, z);
}
public static void multiply(long[] x, long[] y, long[] z)
{
long[] tt = Nat256.createExt64();
implMultiply(x, y, tt);
reduce(tt, z);
}
public static void multiplyAddToExt(long[] x, long[] y, long[] zz)
{
long[] tt = Nat256.createExt64();
implMultiply(x, y, tt);
addExt(zz, tt, zz);
}
public static void reduce(long[] xx, long[] z)
{
long x0 = xx[0], x1 = xx[1], x2 = xx[2], x3 = xx[3], x4 = xx[4], x5 = xx[5], x6 = xx[6];
x2 ^= (x6 << 63);
x3 ^= (x6 >>> 1) ^ (x6 << 14);
x4 ^= (x6 >>> 50);
x1 ^= (x5 << 63);
x2 ^= (x5 >>> 1) ^ (x5 << 14);
x3 ^= (x5 >>> 50);
x0 ^= (x4 << 63);
x1 ^= (x4 >>> 1) ^ (x4 << 14);
x2 ^= (x4 >>> 50);
long t = x3 >>> 1;
z[0] = x0 ^ t ^ (t << 15);
z[1] = x1 ^ (t >>> 49);
z[2] = x2;
z[3] = x3 & M01;
}
public static void reduce63(long[] z, int zOff)
{
long z3 = z[zOff + 3], t = z3 >>> 1;
z[zOff ] ^= t ^ (t << 15);
z[zOff + 1] ^= (t >>> 49);
z[zOff + 3] = z3 & M01;
}
public static void sqrt(long[] x, long[] z)
{
long u0, u1;
u0 = Interleave.unshuffle(x[0]); u1 = Interleave.unshuffle(x[1]);
long e0 = (u0 & 0x00000000FFFFFFFFL) | (u1 << 32);
long c0 = (u0 >>> 32) | (u1 & 0xFFFFFFFF00000000L);
u0 = Interleave.unshuffle(x[2]);
long e1 = (u0 & 0x00000000FFFFFFFFL) ^ (x[3] << 32);
long c1 = (u0 >>> 32);
z[0] = e0 ^ (c0 << 8);
z[1] = e1 ^ (c1 << 8) ^ (c0 >>> 56) ^ (c0 << 33);
z[2] = (c1 >>> 56) ^ (c1 << 33) ^ (c0 >>> 31);
z[3] = (c1 >>> 31);
}
public static void square(long[] x, long[] z)
{
long[] tt = Nat256.createExt64();
implSquare(x, tt);
reduce(tt, z);
}
public static void squareAddToExt(long[] x, long[] zz)
{
long[] tt = Nat256.createExt64();
implSquare(x, tt);
addExt(zz, tt, zz);
}
public static void squareN(long[] x, int n, long[] z)
{
// assert n > 0;
long[] tt = Nat256.createExt64();
implSquare(x, tt);
reduce(tt, z);
while (--n > 0)
{
implSquare(z, tt);
reduce(tt, z);
}
}
public static int trace(long[] x)
{
// Non-zero-trace bits: 0
return (int)(x[0]) & 1;
}
protected static void implCompactExt(long[] zz)
{
long z0 = zz[0], z1 = zz[1], z2 = zz[2], z3 = zz[3], z4 = zz[4], z5 = zz[5], z6 = zz[6], z7 = zz[7];
zz[0] = z0 ^ (z1 << 49);
zz[1] = (z1 >>> 15) ^ (z2 << 34);
zz[2] = (z2 >>> 30) ^ (z3 << 19);
zz[3] = (z3 >>> 45) ^ (z4 << 4)
^ (z5 << 53);
zz[4] = (z4 >>> 60) ^ (z6 << 38)
^ (z5 >>> 11);
zz[5] = (z6 >>> 26) ^ (z7 << 23);
zz[6] = (z7 >>> 41);
zz[7] = 0;
}
protected static void implExpand(long[] x, long[] z)
{
long x0 = x[0], x1 = x[1], x2 = x[2], x3 = x[3];
z[0] = x0 & M49;
z[1] = ((x0 >>> 49) ^ (x1 << 15)) & M49;
z[2] = ((x1 >>> 34) ^ (x2 << 30)) & M49;
z[3] = ((x2 >>> 19) ^ (x3 << 45));
}
protected static void implMultiply(long[] x, long[] y, long[] zz)
{
/*
* "Two-level seven-way recursion" as described in "Batch binary Edwards", Daniel J. Bernstein.
*/
long[] f = new long[4], g = new long[4];
implExpand(x, f);
implExpand(y, g);
implMulwAcc(f[0], g[0], zz, 0);
implMulwAcc(f[1], g[1], zz, 1);
implMulwAcc(f[2], g[2], zz, 2);
implMulwAcc(f[3], g[3], zz, 3);
// U *= (1 - t^n)
for (int i = 5; i > 0; --i)
{
zz[i] ^= zz[i - 1];
}
implMulwAcc(f[0] ^ f[1], g[0] ^ g[1], zz, 1);
implMulwAcc(f[2] ^ f[3], g[2] ^ g[3], zz, 3);
// V *= (1 - t^2n)
for (int i = 7; i > 1; --i)
{
zz[i] ^= zz[i - 2];
}
// Double-length recursion
{
long c0 = f[0] ^ f[2], c1 = f[1] ^ f[3];
long d0 = g[0] ^ g[2], d1 = g[1] ^ g[3];
implMulwAcc(c0 ^ c1, d0 ^ d1, zz, 3);
long[] t = new long[3];
implMulwAcc(c0, d0, t, 0);
implMulwAcc(c1, d1, t, 1);
long t0 = t[0], t1 = t[1], t2 = t[2];
zz[2] ^= t0;
zz[3] ^= t0 ^ t1;
zz[4] ^= t2 ^ t1;
zz[5] ^= t2;
}
implCompactExt(zz);
}
protected static void implMulwAcc(long x, long y, long[] z, int zOff)
{
// assert x >>> 49 == 0;
// assert y >>> 49 == 0;
long[] u = new long[8];
// u[0] = 0;
u[1] = y;
u[2] = u[1] << 1;
u[3] = u[2] ^ y;
u[4] = u[2] << 1;
u[5] = u[4] ^ y;
u[6] = u[3] << 1;
u[7] = u[6] ^ y;
int j = (int)x;
long g, h = 0, l = u[j & 7]
^ (u[(j >>> 3) & 7] << 3);
int k = 36;
do
{
j = (int)(x >>> k);
g = u[j & 7]
^ u[(j >>> 3) & 7] << 3
^ u[(j >>> 6) & 7] << 6
^ u[(j >>> 9) & 7] << 9
^ u[(j >>> 12) & 7] << 12;
l ^= (g << k);
h ^= (g >>> -k);
}
while ((k -= 15) > 0);
// assert h >>> 33 == 0;
z[zOff ] ^= l & M49;
z[zOff + 1] ^= (l >>> 49) ^ (h << 15);
}
protected static void implSquare(long[] x, long[] zz)
{
Interleave.expand64To128(x[0], zz, 0);
Interleave.expand64To128(x[1], zz, 2);
Interleave.expand64To128(x[2], zz, 4);
zz[6] = (x[3] & M01);
}
}
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