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XECOperations
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params: XECParameters
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field: IntegerFieldModuloP
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zero: ImmutableIntegerModuloP
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one: ImmutableIntegerModuloP
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a24: SmallValue
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basePoint: ImmutableIntegerModuloP
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XECOperations(XECParameters): void
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getParameters(): XECParameters
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generatePrivate(SecureRandom): byte[]
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computePublic(byte[]): BigInteger
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encodedPointMultiply(byte[], BigInteger): byte[]
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encodedPointMultiply(byte[], byte[]): byte[]
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decodeU(byte[], int): ImmutableIntegerModuloP
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maskHighOrder(byte[], int): byte
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pruneK(byte[], int, int): void
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pruneK(byte[]): void
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decodeU(byte[]): ImmutableIntegerModuloP
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cswap(int, MutableIntegerModuloP, MutableIntegerModuloP): void
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getIntegerFieldModulo(BigInteger): IntegerFieldModuloP
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bitAt(byte[], int): int
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pointMultiply(byte[], ImmutableIntegerModuloP): IntegerModuloP
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/*
* Copyright (c) 2018, Oracle and/or its affiliates. All rights reserved.
* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
*
* This code is free software; you can redistribute it and/or modify it
* under the terms of the GNU General Public License version 2 only, as
* published by the Free Software Foundation. Oracle designates this
* particular file as subject to the "Classpath" exception as provided
* by Oracle in the LICENSE file that accompanied this code.
*
* This code is distributed in the hope that it will be useful, but WITHOUT
* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
* version 2 for more details (a copy is included in the LICENSE file that
* accompanied this code).
*
* You should have received a copy of the GNU General Public License version
* 2 along with this work; if not, write to the Free Software Foundation,
* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
*
* Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
* or visit www.oracle.com if you need additional information or have any
* questions.
*/
package sun.security.ec;
import sun.security.util.math.IntegerFieldModuloP;
import sun.security.util.math.ImmutableIntegerModuloP;
import sun.security.util.math.IntegerModuloP;
import sun.security.util.math.MutableIntegerModuloP;
import sun.security.util.math.SmallValue;
import sun.security.util.math.intpoly.IntegerPolynomial25519;
import sun.security.util.math.intpoly.IntegerPolynomial448;
import java.math.BigInteger;
import java.security.ProviderException;
import java.security.SecureRandom;
public class XECOperations {
private final XECParameters params;
private final IntegerFieldModuloP field;
private final ImmutableIntegerModuloP zero;
private final ImmutableIntegerModuloP one;
private final SmallValue a24;
private final ImmutableIntegerModuloP basePoint;
public XECOperations(XECParameters c) {
this.params = c;
BigInteger p = params.getP();
this.field = getIntegerFieldModulo(p);
this.zero = field.getElement(BigInteger.ZERO).fixed();
this.one = field.get1().fixed();
this.a24 = field.getSmallValue(params.getA24());
this.basePoint = field.getElement(
BigInteger.valueOf(c.getBasePoint()));
}
public XECParameters getParameters() {
return params;
}
public byte[] generatePrivate(SecureRandom random) {
byte[] result = new byte[this.params.getBytes()];
random.nextBytes(result);
return result;
}
Compute a public key from an encoded private key. This method will
modify the supplied array in order to prune it.
/**
* Compute a public key from an encoded private key. This method will
* modify the supplied array in order to prune it.
*/
public BigInteger computePublic(byte[] k) {
pruneK(k);
return pointMultiply(k, this.basePoint).asBigInteger();
}
Multiply an encoded scalar with a point as a BigInteger and return an
encoded point. The array k holding the scalar will be pruned by
modifying it in place.
Params: - k – an encoded scalar
- u – the u-coordinate of a point as a BigInteger
Returns: the encoded product
/**
*
* Multiply an encoded scalar with a point as a BigInteger and return an
* encoded point. The array k holding the scalar will be pruned by
* modifying it in place.
*
* @param k an encoded scalar
* @param u the u-coordinate of a point as a BigInteger
* @return the encoded product
*/
public byte[] encodedPointMultiply(byte[] k, BigInteger u) {
pruneK(k);
ImmutableIntegerModuloP elemU = field.getElement(u);
return pointMultiply(k, elemU).asByteArray(params.getBytes());
}
Multiply an encoded scalar with an encoded point and return an encoded
point. The array k holding the scalar will be pruned by
modifying it in place.
Params: - k – an encoded scalar
- u – an encoded point
Returns: the encoded product
/**
*
* Multiply an encoded scalar with an encoded point and return an encoded
* point. The array k holding the scalar will be pruned by
* modifying it in place.
*
* @param k an encoded scalar
* @param u an encoded point
* @return the encoded product
*/
public byte[] encodedPointMultiply(byte[] k, byte[] u) {
pruneK(k);
ImmutableIntegerModuloP elemU = decodeU(u);
return pointMultiply(k, elemU).asByteArray(params.getBytes());
}
Return the field element corresponding to an encoded u-coordinate.
This method prunes u by modifying it in place.
Params: - u –
- bits –
Returns:
/**
* Return the field element corresponding to an encoded u-coordinate.
* This method prunes u by modifying it in place.
*
* @param u
* @param bits
* @return
*/
private ImmutableIntegerModuloP decodeU(byte[] u, int bits) {
maskHighOrder(u, bits);
return field.getElement(u);
}
Mask off the high order bits of an encoded integer in an array. The
array is modified in place.
Params: - arr – an array containing an encoded integer
- bits – the number of bits to keep
Returns: the number, in range [1,8], of bits kept in the highest byte
/**
* Mask off the high order bits of an encoded integer in an array. The
* array is modified in place.
*
* @param arr an array containing an encoded integer
* @param bits the number of bits to keep
* @return the number, in range [1,8], of bits kept in the highest byte
*/
private static byte maskHighOrder(byte[] arr, int bits) {
int lastByteIndex = arr.length - 1;
byte bitsMod8 = (byte) (bits % 8);
byte highBits = bitsMod8 == 0 ? 8 : bitsMod8;
byte msbMaskOff = (byte) ((1 << highBits) - 1);
arr[lastByteIndex] &= msbMaskOff;
return highBits;
}
Prune an encoded scalar value by modifying it in place. The extra
high-order bits are masked off, the highest valid bit it set, and the
number is rounded down to a multiple of the cofactor.
Params: - k – an encoded scalar value
- bits – the number of bits in the scalar
- logCofactor – the base-2 logarithm of the cofactor
/**
* Prune an encoded scalar value by modifying it in place. The extra
* high-order bits are masked off, the highest valid bit it set, and the
* number is rounded down to a multiple of the cofactor.
*
* @param k an encoded scalar value
* @param bits the number of bits in the scalar
* @param logCofactor the base-2 logarithm of the cofactor
*/
private static void pruneK(byte[] k, int bits, int logCofactor) {
int lastByteIndex = k.length - 1;
// mask off unused high-order bits
byte highBits = maskHighOrder(k, bits);
// set the highest bit
byte msbMaskOn = (byte) (1 << (highBits - 1));
k[lastByteIndex] |= msbMaskOn;
// round down to a multiple of the cofactor
byte lsbMaskOff = (byte) (0xFF << logCofactor);
k[0] &= lsbMaskOff;
}
private void pruneK(byte[] k) {
pruneK(k, params.getBits(), params.getLogCofactor());
}
private ImmutableIntegerModuloP decodeU(byte [] u) {
return decodeU(u, params.getBits());
}
// Constant-time conditional swap
private static void cswap(int swap, MutableIntegerModuloP x1,
MutableIntegerModuloP x2) {
x1.conditionalSwapWith(x2, swap);
}
private static IntegerFieldModuloP getIntegerFieldModulo(BigInteger p) {
if (p.equals(IntegerPolynomial25519.MODULUS)) {
return new IntegerPolynomial25519();
}
else if (p.equals(IntegerPolynomial448.MODULUS)) {
return new IntegerPolynomial448();
}
throw new ProviderException("Unsupported prime: " + p.toString());
}
private int bitAt(byte[] arr, int index) {
int byteIndex = index / 8;
int bitIndex = index % 8;
return (arr[byteIndex] & (1 << bitIndex)) >> bitIndex;
}
/*
* Constant-time Montgomery ladder that computes k*u and returns the
* result as a field element.
*/
private IntegerModuloP pointMultiply(byte[] k,
ImmutableIntegerModuloP u) {
ImmutableIntegerModuloP x_1 = u;
MutableIntegerModuloP x_2 = this.one.mutable();
MutableIntegerModuloP z_2 = this.zero.mutable();
MutableIntegerModuloP x_3 = u.mutable();
MutableIntegerModuloP z_3 = this.one.mutable();
int swap = 0;
// Variables below are reused to avoid unnecessary allocation
// They will be assigned in the loop, so initial value doesn't matter
MutableIntegerModuloP m1 = this.zero.mutable();
MutableIntegerModuloP DA = this.zero.mutable();
MutableIntegerModuloP E = this.zero.mutable();
MutableIntegerModuloP a24_times_E = this.zero.mutable();
// Comments describe the equivalent operations from RFC 7748
// In comments, A(m1) means the variable m1 holds the value A
for (int t = params.getBits() - 1; t >= 0; t--) {
int k_t = bitAt(k, t);
swap = swap ^ k_t;
cswap(swap, x_2, x_3);
cswap(swap, z_2, z_3);
swap = k_t;
// A(m1) = x_2 + z_2
m1.setValue(x_2).setSum(z_2);
// D = x_3 - z_3
// DA = D * A(m1)
DA.setValue(x_3).setDifference(z_3).setProduct(m1);
// AA(m1) = A(m1)^2
m1.setSquare();
// B(x_2) = x_2 - z_2
x_2.setDifference(z_2);
// C = x_3 + z_3
// CB(x_3) = C * B(x_2)
x_3.setSum(z_3).setProduct(x_2);
// BB(x_2) = B^2
x_2.setSquare();
// E = AA(m1) - BB(x_2)
E.setValue(m1).setDifference(x_2);
// compute a24 * E using SmallValue
a24_times_E.setValue(E);
a24_times_E.setProduct(this.a24);
// assign results to x_3, z_3, x_2, z_2
// x_2 = AA(m1) * BB
x_2.setProduct(m1);
// z_2 = E * (AA(m1) + a24 * E)
z_2.setValue(m1).setSum(a24_times_E).setProduct(E);
// z_3 = x_1*(DA - CB(x_3))^2
z_3.setValue(DA).setDifference(x_3).setSquare().setProduct(x_1);
// x_3 = (CB(x_3) + DA)^2
x_3.setSum(DA).setSquare();
}
cswap(swap, x_2, x_3);
cswap(swap, z_2, z_3);
// return (x_2 * z_2^(p - 2))
return x_2.setProduct(z_2.multiplicativeInverse());
}
}