package org.bouncycastle.math.ec;
import java.math.BigInteger;
Class implementing the WNAF (Window Non-Adjacent Form) multiplication
algorithm.
/**
* Class implementing the WNAF (Window Non-Adjacent Form) multiplication
* algorithm.
*/
class WNafMultiplier implements ECMultiplier
{
Computes the Window NAF (non-adjacent Form) of an integer.
Params: - width – The width
w
of the Window NAF. The width is
defined as the minimal number w
, such that for any
w
consecutive digits in the resulting representation, at
most one is non-zero. - k – The integer of which the Window NAF is computed.
Returns: The Window NAF of the given width, such that the following holds:
k = ∑i=0l-1 ki2i
, where the ki
denote the elements of the
returned byte[]
.
/**
* Computes the Window NAF (non-adjacent Form) of an integer.
* @param width The width <code>w</code> of the Window NAF. The width is
* defined as the minimal number <code>w</code>, such that for any
* <code>w</code> consecutive digits in the resulting representation, at
* most one is non-zero.
* @param k The integer of which the Window NAF is computed.
* @return The Window NAF of the given width, such that the following holds:
* <code>k = ∑<sub>i=0</sub><sup>l-1</sup> k<sub>i</sub>2<sup>i</sup>
* </code>, where the <code>k<sub>i</sub></code> denote the elements of the
* returned <code>byte[]</code>.
*/
public byte[] windowNaf(byte width, BigInteger k)
{
// The window NAF is at most 1 element longer than the binary
// representation of the integer k. byte can be used instead of short or
// int unless the window width is larger than 8. For larger width use
// short or int. However, a width of more than 8 is not efficient for
// m = log2(q) smaller than 2305 Bits. Note: Values for m larger than
// 1000 Bits are currently not used in practice.
byte[] wnaf = new byte[k.bitLength() + 1];
// 2^width as short and BigInteger
short pow2wB = (short)(1 << width);
BigInteger pow2wBI = BigInteger.valueOf(pow2wB);
int i = 0;
// The actual length of the WNAF
int length = 0;
// while k >= 1
while (k.signum() > 0)
{
// if k is odd
if (k.testBit(0))
{
// k mod 2^width
BigInteger remainder = k.mod(pow2wBI);
// if remainder > 2^(width - 1) - 1
if (remainder.testBit(width - 1))
{
wnaf[i] = (byte)(remainder.intValue() - pow2wB);
}
else
{
wnaf[i] = (byte)remainder.intValue();
}
// wnaf[i] is now in [-2^(width-1), 2^(width-1)-1]
k = k.subtract(BigInteger.valueOf(wnaf[i]));
length = i;
}
else
{
wnaf[i] = 0;
}
// k = k/2
k = k.shiftRight(1);
i++;
}
length++;
// Reduce the WNAF array to its actual length
byte[] wnafShort = new byte[length];
System.arraycopy(wnaf, 0, wnafShort, 0, length);
return wnafShort;
}
Multiplies this
by an integer k
using the
Window NAF method.
Params: - k – The integer by which
this
is multiplied.
Returns: A new ECPoint
which equals this
multiplied by k
.
/**
* Multiplies <code>this</code> by an integer <code>k</code> using the
* Window NAF method.
* @param k The integer by which <code>this</code> is multiplied.
* @return A new <code>ECPoint</code> which equals <code>this</code>
* multiplied by <code>k</code>.
*/
public ECPoint multiply(ECPoint p, BigInteger k, PreCompInfo preCompInfo)
{
WNafPreCompInfo wnafPreCompInfo;
if ((preCompInfo != null) && (preCompInfo instanceof WNafPreCompInfo))
{
wnafPreCompInfo = (WNafPreCompInfo)preCompInfo;
}
else
{
// Ignore empty PreCompInfo or PreCompInfo of incorrect type
wnafPreCompInfo = new WNafPreCompInfo();
}
// floor(log2(k))
int m = k.bitLength();
// width of the Window NAF
byte width;
// Required length of precomputation array
int reqPreCompLen;
// Determine optimal width and corresponding length of precomputation
// array based on literature values
if (m < 13)
{
width = 2;
reqPreCompLen = 1;
}
else
{
if (m < 41)
{
width = 3;
reqPreCompLen = 2;
}
else
{
if (m < 121)
{
width = 4;
reqPreCompLen = 4;
}
else
{
if (m < 337)
{
width = 5;
reqPreCompLen = 8;
}
else
{
if (m < 897)
{
width = 6;
reqPreCompLen = 16;
}
else
{
if (m < 2305)
{
width = 7;
reqPreCompLen = 32;
}
else
{
width = 8;
reqPreCompLen = 127;
}
}
}
}
}
}
// The length of the precomputation array
int preCompLen = 1;
ECPoint[] preComp = wnafPreCompInfo.getPreComp();
ECPoint twiceP = wnafPreCompInfo.getTwiceP();
// Check if the precomputed ECPoints already exist
if (preComp == null)
{
// Precomputation must be performed from scratch, create an empty
// precomputation array of desired length
preComp = new ECPoint[]{ p };
}
else
{
// Take the already precomputed ECPoints to start with
preCompLen = preComp.length;
}
if (twiceP == null)
{
// Compute twice(p)
twiceP = p.twice();
}
if (preCompLen < reqPreCompLen)
{
// Precomputation array must be made bigger, copy existing preComp
// array into the larger new preComp array
ECPoint[] oldPreComp = preComp;
preComp = new ECPoint[reqPreCompLen];
System.arraycopy(oldPreComp, 0, preComp, 0, preCompLen);
for (int i = preCompLen; i < reqPreCompLen; i++)
{
// Compute the new ECPoints for the precomputation array.
// The values 1, 3, 5, ..., 2^(width-1)-1 times p are
// computed
preComp[i] = twiceP.add(preComp[i - 1]);
}
}
// Compute the Window NAF of the desired width
byte[] wnaf = windowNaf(width, k);
int l = wnaf.length;
// Apply the Window NAF to p using the precomputed ECPoint values.
ECPoint q = p.getCurve().getInfinity();
for (int i = l - 1; i >= 0; i--)
{
q = q.twice();
if (wnaf[i] != 0)
{
if (wnaf[i] > 0)
{
q = q.add(preComp[(wnaf[i] - 1)/2]);
}
else
{
// wnaf[i] < 0
q = q.subtract(preComp[(-wnaf[i] - 1)/2]);
}
}
}
// Set PreCompInfo in ECPoint, such that it is available for next
// multiplication.
wnafPreCompInfo.setPreComp(preComp);
wnafPreCompInfo.setTwiceP(twiceP);
p.setPreCompInfo(wnafPreCompInfo);
return q;
}
}