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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 1.4.
package org.bouncycastle.pqc.crypto.sphincsplus;
import java.util.LinkedList;
import org.bouncycastle.util.Arrays;
class Fors
{
SPHINCSPlusEngine engine;
public Fors(SPHINCSPlusEngine engine)
{
this.engine = engine;
}
// Input: Secret seed SK.seed, start index s, target node height z, public seed PK.seed, address ADRS
// Output: n-byte root node - top node on Stack
byte[] treehash(byte[] skSeed, int s, int z, byte[] pkSeed, ADRS adrsParam)
{
LinkedList stack = new LinkedList ();
if (s % (1 << z) != 0)
{
return null;
}
ADRS adrs = new ADRS(adrsParam);
for (int idx = 0; idx < (1 << z); idx++)
{
adrs.setType(ADRS.FORS_PRF);
adrs.setKeyPairAddress(adrsParam.getKeyPairAddress());
adrs.setTreeHeight(0);
adrs.setTreeIndex(s + idx);
byte[] sk = engine.PRF(pkSeed, skSeed, adrs);
adrs.changeType(ADRS.FORS_TREE);
byte[] node = engine.F(pkSeed, adrs, sk);
adrs.setTreeHeight(1);
// while ( Top node on Stack has same height as node )
while (!stack.isEmpty()
&& ((NodeEntry)stack.get(0)).nodeHeight == adrs.getTreeHeight())
{
adrs.setTreeIndex((adrs.getTreeIndex() - 1) / 2);
NodeEntry current = ((NodeEntry)stack.remove(0));
node = engine.H(pkSeed, adrs, current.nodeValue, node);
//topmost node is now one layer higher
adrs.setTreeHeight(adrs.getTreeHeight() + 1);
}
stack.add(0, new NodeEntry(node, adrs.getTreeHeight()));
}
return ((NodeEntry)stack.get(0)).nodeValue;
}
public SIG_FORS[] sign(byte[] md, byte[] skSeed, byte[] pkSeed, ADRS paramAdrs)
{
ADRS adrs = new ADRS(paramAdrs);
int[] idxs = message_to_idxs(md, engine.K, engine.A);
SIG_FORS[] sig_fors = new SIG_FORS[engine.K];
// compute signature elements
int t = engine.T;
for (int i = 0; i < engine.K; i++)
{
// get next index
int idx = idxs[i];
// pick private key element
adrs.setType(ADRS.FORS_PRF);
adrs.setKeyPairAddress(paramAdrs.getKeyPairAddress());
adrs.setTreeHeight(0);
adrs.setTreeIndex(i * t + idx);
byte[] sk = engine.PRF(pkSeed, skSeed, adrs);
adrs.changeType(ADRS.FORS_TREE);
byte[][] authPath = new byte[engine.A][];
// compute auth path
for (int j = 0; j < engine.A; j++)
{
int s = (idx / (1 << j)) ^ 1;
authPath[j] = treehash(skSeed, i * t + s * (1 << j), j, pkSeed, adrs);
}
sig_fors[i] = new SIG_FORS(sk, authPath);
}
return sig_fors;
}
public byte[] pkFromSig(SIG_FORS[] sig_fors, byte[] message, byte[] pkSeed, ADRS adrs)
{
byte[][] node = new byte[2][];
byte[][] root = new byte[engine.K][];
int t = engine.T;
int[] idxs = message_to_idxs(message, engine.K, engine.A);
// compute roots
for (int i = 0; i < engine.K; i++)
{
// get next index
int idx = idxs[i];
// compute leaf
byte[] sk = sig_fors[i].getSK();
adrs.setTreeHeight(0);
adrs.setTreeIndex(i * t + idx);
node[0] = engine.F(pkSeed, adrs, sk);
// compute root from leaf and AUTH
byte[][] authPath = sig_fors[i].getAuthPath();
adrs.setTreeIndex(i * t + idx);
for (int j = 0; j < engine.A; j++)
{
adrs.setTreeHeight(j + 1);
if (((idx / (1 << j)) % 2) == 0)
{
adrs.setTreeIndex(adrs.getTreeIndex() / 2);
node[1] = engine.H(pkSeed, adrs, node[0], authPath[j]);
}
else
{
adrs.setTreeIndex((adrs.getTreeIndex() - 1) / 2);
node[1] = engine.H(pkSeed, adrs, authPath[j], node[0]);
}
node[0] = node[1];
}
root[i] = node[0];
}
ADRS forspkADRS = new ADRS(adrs); // copy address to create FTS public key address
forspkADRS.setType(ADRS.FORS_PK);
forspkADRS.setKeyPairAddress(adrs.getKeyPairAddress());
return engine.T_l(pkSeed, forspkADRS, Arrays.concatenate(root));
}
/**
* Interprets m as SPX_FORS_HEIGHT-bit unsigned integers.
* Assumes m contains at least SPX_FORS_HEIGHT * SPX_FORS_TREES bits.
* Assumes indices has space for SPX_FORS_TREES integers.
*/
static int[] message_to_idxs(byte[] msg, int fors_trees, int fors_height)
{
int offset = 0;
int[] idxs = new int[fors_trees];
for (int i = 0; i < fors_trees; i++)
{
idxs[i] = 0;
for (int j = 0; j < fors_height; j++)
{
idxs[i] ^= ((msg[offset >> 3] >> (offset & 0x7)) & 0x1) << j;
offset++;
}
}
return idxs;
}
}
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