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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.

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package org.bouncycastle.math.ec.custom.sec;

import java.math.BigInteger;

import org.bouncycastle.math.raw.Nat;
import org.bouncycastle.math.raw.Nat128;
import org.bouncycastle.math.raw.Nat256;

public class SecP128R1Field
{
    private static final long M = 0xFFFFFFFFL;

    // 2^128 - 2^97 - 1
    static final int[] P = new int[] { 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFD };
    static final int[] PExt = new int[] { 0x00000001, 0x00000000, 0x00000000, 0x00000004, 0xFFFFFFFE,
        0xFFFFFFFF, 0x00000003, 0xFFFFFFFC };
    private static final int[] PExtInv = new int[]{ 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFB,
        0x00000001, 0x00000000, 0xFFFFFFFC, 0x00000003 };
    private static final int P3s1 = 0xFFFFFFFD >>> 1;
    private static final int PExt7s1 = 0xFFFFFFFC >>> 1;

    public static void add(int[] x, int[] y, int[] z)
    {
        int c = Nat128.add(x, y, z);
        if (c != 0 || ((z[3] >>> 1) >= P3s1 && Nat128.gte(z, P)))
        {
            addPInvTo(z);
        }
    }

    public static void addExt(int[] xx, int[] yy, int[] zz)
    {
        int c = Nat256.add(xx, yy, zz);
        if (c != 0 || ((zz[7] >>> 1) >= PExt7s1 && Nat256.gte(zz, PExt)))
        {
            Nat.addTo(PExtInv.length, PExtInv, zz);
        }
    }

    public static void addOne(int[] x, int[] z)
    {
        int c = Nat.inc(4, x, z);
        if (c != 0 || ((z[3] >>> 1) >= P3s1 && Nat128.gte(z, P)))
        {
            addPInvTo(z);
        }
    }

    public static int[] fromBigInteger(BigInteger x)
    {
        int[] z = Nat128.fromBigInteger(x);
        if ((z[3] >>> 1) >= P3s1 && Nat128.gte(z, P))
        {
            Nat128.subFrom(P, z);
        }
        return z;
    }

    public static void half(int[] x, int[] z)
    {
        if ((x[0] & 1) == 0)
        {
            Nat.shiftDownBit(4, x, 0, z);
        }
        else
        {
            int c = Nat128.add(x, P, z);
            Nat.shiftDownBit(4, z, c);
        }
    }

    public static void multiply(int[] x, int[] y, int[] z)
    {
        int[] tt = Nat128.createExt();
        Nat128.mul(x, y, tt);
        reduce(tt, z);
    }

    public static void multiplyAddToExt(int[] x, int[] y, int[] zz)
    {
        int c = Nat128.mulAddTo(x, y, zz);
        if (c != 0 || ((zz[7] >>> 1) >= PExt7s1 && Nat256.gte(zz, PExt)))
        {
            Nat.addTo(PExtInv.length, PExtInv, zz);
        }
    }

    public static void negate(int[] x, int[] z)
    {
        if (Nat128.isZero(x))
        {
            Nat128.zero(z);
        }
        else
        {
            Nat128.sub(P, x, z);
        }
    }

    public static void reduce(int[] xx, int[] z)
    {
        long x0 = xx[0] & M, x1 = xx[1] & M, x2 = xx[2] & M, x3 = xx[3] & M;
        long x4 = xx[4] & M, x5 = xx[5] & M, x6 = xx[6] & M, x7 = xx[7] & M;

        x3 += x7; x6 += (x7 << 1);
        x2 += x6; x5 += (x6 << 1);
        x1 += x5; x4 += (x5 << 1);
        x0 += x4; x3 += (x4 << 1);

        z[0] = (int)x0; x1 += (x0 >>> 32);
        z[1] = (int)x1; x2 += (x1 >>> 32);
        z[2] = (int)x2; x3 += (x2 >>> 32);
        z[3] = (int)x3;

        reduce32((int)(x3 >>> 32), z);
    }

    public static void reduce32(int x, int[] z)
    {
        while (x != 0)
        {
            long c, x4 = x & M;

            c = (z[0] & M) + x4;
            z[0] = (int)c; c >>= 32;
            if (c != 0)
            {
                c += (z[1] & M);
                z[1] = (int)c; c >>= 32;
                c += (z[2] & M);
                z[2] = (int)c; c >>= 32;
            }
            c += (z[3] & M) + (x4 << 1);
            z[3] = (int)c; c >>= 32;

//            assert c >= 0 && c <= 2;

            x = (int)c;
        }
    }

    public static void square(int[] x, int[] z)
    {
        int[] tt = Nat128.createExt();
        Nat128.square(x, tt);
        reduce(tt, z);
    }

    public static void squareN(int[] x, int n, int[] z)
    {
//        assert n > 0;

        int[] tt = Nat128.createExt();
        Nat128.square(x, tt);
        reduce(tt, z);

        while (--n > 0)
        {
            Nat128.square(z, tt);
            reduce(tt, z);
        }
    }

    public static void subtract(int[] x, int[] y, int[] z)
    {
        int c = Nat128.sub(x, y, z);
        if (c != 0)
        {
            subPInvFrom(z);
        }
    }

    public static void subtractExt(int[] xx, int[] yy, int[] zz)
    {
        int c = Nat.sub(10, xx, yy, zz);
        if (c != 0)
        {
            Nat.subFrom(PExtInv.length, PExtInv, zz);
        }
    }

    public static void twice(int[] x, int[] z)
    {
        int c = Nat.shiftUpBit(4, x, 0, z);
        if (c != 0 || ((z[3] >>> 1) >= P3s1 && Nat128.gte(z, P)))
        {
            addPInvTo(z);
        }
    }

    private static void addPInvTo(int[] z)
    {
        long c = (z[0] & M) + 1;
        z[0] = (int)c; c >>= 32;
        if (c != 0)
        {
            c += (z[1] & M);
            z[1] = (int)c; c >>= 32;
            c += (z[2] & M);
            z[2] = (int)c; c >>= 32;
        }
        c += (z[3] & M) + 2;
        z[3] = (int)c;
    }

    private static void subPInvFrom(int[] z)
    {
        long c = (z[0] & M) - 1;
        z[0] = (int)c; c >>= 32;
        if (c != 0)
        {
            c += (z[1] & M);
            z[1] = (int)c; c >>= 32;
            c += (z[2] & M);
            z[2] = (int)c; c >>= 32;
        }
        c += (z[3] & M) - 2;
        z[3] = (int)c;
    }
}




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