xmss-KAT-generator/xmss.c
Joost Rijneveld 5122ac6f73
Reduce code duplication
A large number of functions was repeated in xmss_fast; these are now
shared between the two implementations via the xmss_commons file.
Notably, we ensure compatability by sharing the verification functions.
2017-06-02 14:46:30 +02:00

417 rader
12 KiB
C

/*
xmss.c version 20160722
Andreas Hülsing
Joost Rijneveld
Public domain.
*/
#include "xmss.h"
#include <stdlib.h>
#include <string.h>
#include <stdint.h>
#include <math.h>
#include "randombytes.h"
#include "wots.h"
#include "hash.h"
//#include "prg.h"
#include "xmss_commons.h"
#include "hash_address.h"
#include "params.h"
// For testing
#include "stdio.h"
/**
* Merkle's TreeHash algorithm. The address only needs to initialize the first 78 bits of addr. Everything else will be set by treehash.
* Currently only used for key generation.
*
*/
static void treehash(unsigned char *node, uint16_t height, uint32_t index, const unsigned char *sk_seed, const unsigned char *pub_seed, const uint32_t addr[8])
{
uint32_t idx = index;
// use three different addresses because at this point we use all three formats in parallel
uint32_t ots_addr[8];
uint32_t ltree_addr[8];
uint32_t node_addr[8];
// only copy layer and tree address parts
memcpy(ots_addr, addr, 12);
// type = ots
setType(ots_addr, 0);
memcpy(ltree_addr, addr, 12);
setType(ltree_addr, 1);
memcpy(node_addr, addr, 12);
setType(node_addr, 2);
uint32_t lastnode, i;
unsigned char stack[(height+1)*XMSS_N];
uint16_t stacklevels[height+1];
unsigned int stackoffset=0;
lastnode = idx+(1 << height);
for (; idx < lastnode; idx++) {
setLtreeADRS(ltree_addr, idx);
setOTSADRS(ots_addr, idx);
gen_leaf_wots(stack+stackoffset*XMSS_N, sk_seed, pub_seed, ltree_addr, ots_addr);
stacklevels[stackoffset] = 0;
stackoffset++;
while (stackoffset>1 && stacklevels[stackoffset-1] == stacklevels[stackoffset-2]) {
setTreeHeight(node_addr, stacklevels[stackoffset-1]);
setTreeIndex(node_addr, (idx >> (stacklevels[stackoffset-1]+1)));
hash_h(stack+(stackoffset-2)*XMSS_N, stack+(stackoffset-2)*XMSS_N, pub_seed,
node_addr, XMSS_N);
stacklevels[stackoffset-2]++;
stackoffset--;
}
}
for (i=0; i < XMSS_N; i++)
node[i] = stack[i];
}
/**
* Computes the authpath and the root. This method is using a lot of space as we build the whole tree and then select the authpath nodes.
* For more efficient algorithms see e.g. the chapter on hash-based signatures in Bernstein, Buchmann, Dahmen. "Post-quantum Cryptography", Springer 2009.
* It returns the authpath in "authpath" with the node on level 0 at index 0.
*/
static void compute_authpath_wots(unsigned char *root, unsigned char *authpath, unsigned long leaf_idx, const unsigned char *sk_seed, unsigned char *pub_seed, uint32_t addr[8])
{
uint32_t i, j, level;
unsigned char tree[2*(1<<XMSS_TREEHEIGHT)*XMSS_N];
uint32_t ots_addr[8];
uint32_t ltree_addr[8];
uint32_t node_addr[8];
memcpy(ots_addr, addr, 12);
setType(ots_addr, 0);
memcpy(ltree_addr, addr, 12);
setType(ltree_addr, 1);
memcpy(node_addr, addr, 12);
setType(node_addr, 2);
// Compute all leaves
for (i = 0; i < (1U << XMSS_TREEHEIGHT); i++) {
setLtreeADRS(ltree_addr, i);
setOTSADRS(ots_addr, i);
gen_leaf_wots(tree+((1<<XMSS_TREEHEIGHT)*XMSS_N + i*XMSS_N), sk_seed, pub_seed, ltree_addr, ots_addr);
}
level = 0;
// Compute tree:
// Outer loop: For each inner layer
for (i = (1<<XMSS_TREEHEIGHT); i > 1; i>>=1) {
setTreeHeight(node_addr, level);
// Inner loop: for each pair of sibling nodes
for (j = 0; j < i; j+=2) {
setTreeIndex(node_addr, j>>1);
hash_h(tree + (i>>1)*XMSS_N + (j>>1) * XMSS_N, tree + i*XMSS_N + j*XMSS_N, pub_seed, node_addr, XMSS_N);
}
level++;
}
// copy authpath
for (i=0; i < XMSS_TREEHEIGHT; i++)
memcpy(authpath + i*XMSS_N, tree + ((1<<XMSS_TREEHEIGHT)>>i)*XMSS_N + ((leaf_idx >> i) ^ 1) * XMSS_N, XMSS_N);
// copy root
memcpy(root, tree+XMSS_N, XMSS_N);
}
/*
* Generates a XMSS key pair for a given parameter set.
* Format sk: [(32bit) idx || SK_SEED || SK_PRF || PUB_SEED || root]
* Format pk: [root || PUB_SEED] omitting algo oid.
*/
int xmss_keypair(unsigned char *pk, unsigned char *sk)
{
// Set idx = 0
sk[0] = 0;
sk[1] = 0;
sk[2] = 0;
sk[3] = 0;
// Init SK_SEED (XMSS_N byte), SK_PRF (XMSS_N byte), and PUB_SEED (XMSS_N byte)
randombytes(sk+4, 3*XMSS_N);
// Copy PUB_SEED to public key
memcpy(pk+XMSS_N, sk+4+2*XMSS_N, XMSS_N);
uint32_t addr[8] = {0, 0, 0, 0, 0, 0, 0, 0};
// Compute root
treehash(pk, XMSS_TREEHEIGHT, 0, sk+4, sk+4+2*XMSS_N, addr);
// copy root to sk
memcpy(sk+4+3*XMSS_N, pk, XMSS_N);
return 0;
}
/**
* Signs a message.
* Returns
* 1. an array containing the signature followed by the message AND
* 2. an updated secret key!
*
*/
int xmss_sign(unsigned char *sk, unsigned char *sig_msg, unsigned long long *sig_msg_len, const unsigned char *msg, unsigned long long msglen)
{
uint16_t i = 0;
// Extract SK
uint32_t idx = ((unsigned long)sk[0] << 24) | ((unsigned long)sk[1] << 16) | ((unsigned long)sk[2] << 8) | sk[3];
unsigned char sk_seed[XMSS_N];
memcpy(sk_seed, sk+4, XMSS_N);
unsigned char sk_prf[XMSS_N];
memcpy(sk_prf, sk+4+XMSS_N, XMSS_N);
unsigned char pub_seed[XMSS_N];
memcpy(pub_seed, sk+4+2*XMSS_N, XMSS_N);
// index as 32 bytes string
unsigned char idx_bytes_32[32];
to_byte(idx_bytes_32, idx, 32);
unsigned char hash_key[3*XMSS_N];
// Update SK
sk[0] = ((idx + 1) >> 24) & 255;
sk[1] = ((idx + 1) >> 16) & 255;
sk[2] = ((idx + 1) >> 8) & 255;
sk[3] = (idx + 1) & 255;
// -- Secret key for this non-forward-secure version is now updated.
// -- A productive implementation should use a file handle instead and write the updated secret key at this point!
// Init working params
unsigned char R[XMSS_N];
unsigned char msg_h[XMSS_N];
unsigned char root[XMSS_N];
unsigned char ots_seed[XMSS_N];
uint32_t ots_addr[8] = {0, 0, 0, 0, 0, 0, 0, 0};
// ---------------------------------
// Message Hashing
// ---------------------------------
// Message Hash:
// First compute pseudorandom value
prf(R, idx_bytes_32, sk_prf, XMSS_N);
// Generate hash key (R || root || idx)
memcpy(hash_key, R, XMSS_N);
memcpy(hash_key+XMSS_N, sk+4+3*XMSS_N, XMSS_N);
to_byte(hash_key+2*XMSS_N, idx, XMSS_N);
// Then use it for message digest
h_msg(msg_h, msg, msglen, hash_key, 3*XMSS_N, XMSS_N);
// Start collecting signature
*sig_msg_len = 0;
// Copy index to signature
sig_msg[0] = (idx >> 24) & 255;
sig_msg[1] = (idx >> 16) & 255;
sig_msg[2] = (idx >> 8) & 255;
sig_msg[3] = idx & 255;
sig_msg += 4;
*sig_msg_len += 4;
// Copy R to signature
for (i = 0; i < XMSS_N; i++)
sig_msg[i] = R[i];
sig_msg += XMSS_N;
*sig_msg_len += XMSS_N;
// ----------------------------------
// Now we start to "really sign"
// ----------------------------------
// Prepare Address
setType(ots_addr, 0);
setOTSADRS(ots_addr, idx);
// Compute seed for OTS key pair
get_seed(ots_seed, sk_seed, ots_addr);
// Compute WOTS signature
wots_sign(sig_msg, msg_h, ots_seed, pub_seed, ots_addr);
sig_msg += XMSS_WOTS_KEYSIZE;
*sig_msg_len += XMSS_WOTS_KEYSIZE;
compute_authpath_wots(root, sig_msg, idx, sk_seed, pub_seed, ots_addr);
sig_msg += XMSS_TREEHEIGHT*XMSS_N;
*sig_msg_len += XMSS_TREEHEIGHT*XMSS_N;
//Whipe secret elements?
//zerobytes(tsk, CRYPTO_SECRETKEYBYTES);
memcpy(sig_msg, msg, msglen);
*sig_msg_len += msglen;
return 0;
}
/*
* Generates a XMSSMT key pair for a given parameter set.
* Format sk: [(ceil(h/8) bit) idx || SK_SEED || SK_PRF || PUB_SEED]
* Format pk: [root || PUB_SEED] omitting algo oid.
*/
int xmssmt_keypair(unsigned char *pk, unsigned char *sk)
{
uint16_t i;
// Set idx = 0
for (i = 0; i < XMSS_INDEX_LEN; i++) {
sk[i] = 0;
}
// Init SK_SEED (XMSS_N byte), SK_PRF (XMSS_N byte), and PUB_SEED (XMSS_N byte)
randombytes(sk+XMSS_INDEX_LEN, 3*XMSS_N);
// Copy PUB_SEED to public key
memcpy(pk+XMSS_N, sk+XMSS_INDEX_LEN+2*XMSS_N, XMSS_N);
// Set address to point on the single tree on layer d-1
uint32_t addr[8] = {0, 0, 0, 0, 0, 0, 0, 0};
setLayerADRS(addr, (XMSS_D-1));
// Compute root
treehash(pk, XMSS_TREEHEIGHT, 0, sk+XMSS_INDEX_LEN, pk+XMSS_N, addr);
memcpy(sk+XMSS_INDEX_LEN+3*XMSS_N, pk, XMSS_N);
return 0;
}
/**
* Signs a message.
* Returns
* 1. an array containing the signature followed by the message AND
* 2. an updated secret key!
*
*/
int xmssmt_sign(unsigned char *sk, unsigned char *sig_msg, unsigned long long *sig_msg_len, const unsigned char *msg, unsigned long long msglen)
{
uint64_t idx_tree;
uint32_t idx_leaf;
uint64_t i;
unsigned char sk_seed[XMSS_N];
unsigned char sk_prf[XMSS_N];
unsigned char pub_seed[XMSS_N];
// Init working params
unsigned char R[XMSS_N];
unsigned char hash_key[3*XMSS_N];
unsigned char msg_h[XMSS_N];
unsigned char root[XMSS_N];
unsigned char ots_seed[XMSS_N];
uint32_t ots_addr[8] = {0, 0, 0, 0, 0, 0, 0, 0};
unsigned char idx_bytes_32[32];
// Extract SK
unsigned long long idx = 0;
for (i = 0; i < XMSS_INDEX_LEN; i++) {
idx |= ((unsigned long long)sk[i]) << 8*(XMSS_INDEX_LEN - 1 - i);
}
memcpy(sk_seed, sk+XMSS_INDEX_LEN, XMSS_N);
memcpy(sk_prf, sk+XMSS_INDEX_LEN+XMSS_N, XMSS_N);
memcpy(pub_seed, sk+XMSS_INDEX_LEN+2*XMSS_N, XMSS_N);
// Update SK
for (i = 0; i < XMSS_INDEX_LEN; i++) {
sk[i] = ((idx + 1) >> 8*(XMSS_INDEX_LEN - 1 - i)) & 255;
}
// -- Secret key for this non-forward-secure version is now updated.
// -- A productive implementation should use a file handle instead and write the updated secret key at this point!
// ---------------------------------
// Message Hashing
// ---------------------------------
// Message Hash:
// First compute pseudorandom value
to_byte(idx_bytes_32, idx, 32);
prf(R, idx_bytes_32, sk_prf, XMSS_N);
// Generate hash key (R || root || idx)
memcpy(hash_key, R, XMSS_N);
memcpy(hash_key+XMSS_N, sk+XMSS_INDEX_LEN+3*XMSS_N, XMSS_N);
to_byte(hash_key+2*XMSS_N, idx, XMSS_N);
// Then use it for message digest
h_msg(msg_h, msg, msglen, hash_key, 3*XMSS_N, XMSS_N);
// Start collecting signature
*sig_msg_len = 0;
// Copy index to signature
for (i = 0; i < XMSS_INDEX_LEN; i++) {
sig_msg[i] = (idx >> 8*(XMSS_INDEX_LEN - 1 - i)) & 255;
}
sig_msg += XMSS_INDEX_LEN;
*sig_msg_len += XMSS_INDEX_LEN;
// Copy R to signature
for (i=0; i < XMSS_N; i++)
sig_msg[i] = R[i];
sig_msg += XMSS_N;
*sig_msg_len += XMSS_N;
// ----------------------------------
// Now we start to "really sign"
// ----------------------------------
// Handle lowest layer separately as it is slightly different...
// Prepare Address
setType(ots_addr, 0);
idx_tree = idx >> XMSS_TREEHEIGHT;
idx_leaf = (idx & ((1 << XMSS_TREEHEIGHT)-1));
setLayerADRS(ots_addr, 0);
setTreeADRS(ots_addr, idx_tree);
setOTSADRS(ots_addr, idx_leaf);
// Compute seed for OTS key pair
get_seed(ots_seed, sk_seed, ots_addr);
// Compute WOTS signature
wots_sign(sig_msg, msg_h, ots_seed, pub_seed, ots_addr);
sig_msg += XMSS_WOTS_KEYSIZE;
*sig_msg_len += XMSS_WOTS_KEYSIZE;
compute_authpath_wots(root, sig_msg, idx_leaf, sk_seed, pub_seed, ots_addr);
sig_msg += XMSS_TREEHEIGHT*XMSS_N;
*sig_msg_len += XMSS_TREEHEIGHT*XMSS_N;
// Now loop over remaining layers...
unsigned int j;
for (j = 1; j < XMSS_D; j++) {
// Prepare Address
idx_leaf = (idx_tree & ((1 << XMSS_TREEHEIGHT)-1));
idx_tree = idx_tree >> XMSS_TREEHEIGHT;
setLayerADRS(ots_addr, j);
setTreeADRS(ots_addr, idx_tree);
setOTSADRS(ots_addr, idx_leaf);
// Compute seed for OTS key pair
get_seed(ots_seed, sk_seed, ots_addr);
// Compute WOTS signature
wots_sign(sig_msg, root, ots_seed, pub_seed, ots_addr);
sig_msg += XMSS_WOTS_KEYSIZE;
*sig_msg_len += XMSS_WOTS_KEYSIZE;
compute_authpath_wots(root, sig_msg, idx_leaf, sk_seed, pub_seed, ots_addr);
sig_msg += XMSS_TREEHEIGHT*XMSS_N;
*sig_msg_len += XMSS_TREEHEIGHT*XMSS_N;
}
//Whipe secret elements?
//zerobytes(tsk, CRYPTO_SECRETKEYBYTES);
memcpy(sig_msg, msg, msglen);
*sig_msg_len += msglen;
return 0;
}