xmss-KAT-generator/xmss_fast.c

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/*
2016-09-22 15:31:41 +01:00
xmss_fast.c version 20160722
Andreas Hülsing
Joost Rijneveld
Public domain.
*/
#include "xmss_fast.h"
#include <stdlib.h>
#include <string.h>
#include <stdint.h>
#include "randombytes.h"
#include "wots.h"
#include "hash.h"
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#include "xmss_commons.h"
#include "hash_address.h"
#include "params.h"
/**
* Initialize BDS state struct
* parameter names are the same as used in the description of the BDS traversal
*/
void xmss_set_bds_state(bds_state *state, unsigned char *stack, int stackoffset, unsigned char *stacklevels, unsigned char *auth, unsigned char *keep, treehash_inst *treehash, unsigned char *retain, int next_leaf)
{
state->stack = stack;
state->stackoffset = stackoffset;
state->stacklevels = stacklevels;
state->auth = auth;
state->keep = keep;
state->treehash = treehash;
state->retain = retain;
state->next_leaf = next_leaf;
}
static int treehash_minheight_on_stack(bds_state* state, const treehash_inst *treehash)
{
unsigned int r = XMSS_TREEHEIGHT, i;
for (i = 0; i < treehash->stackusage; i++) {
if (state->stacklevels[state->stackoffset - i - 1] < r) {
r = state->stacklevels[state->stackoffset - i - 1];
}
}
return r;
}
/**
* 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_setup(unsigned char *node, int height, int index, bds_state *state, const unsigned char *sk_seed, const unsigned char *pub_seed, const uint32_t addr[8])
{
unsigned int idx = index;
// use three different addresses because at this point we use all three formats in parallel
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uint32_t ots_addr[8];
uint32_t ltree_addr[8];
uint32_t node_addr[8];
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// 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];
unsigned int stacklevels[height+1];
unsigned int stackoffset=0;
unsigned int nodeh;
lastnode = idx+(1<<height);
for (i = 0; i < XMSS_TREEHEIGHT-XMSS_BDS_K; i++) {
state->treehash[i].h = i;
state->treehash[i].completed = 1;
state->treehash[i].stackusage = 0;
}
i = 0;
for (; idx < lastnode; idx++) {
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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++;
if (XMSS_TREEHEIGHT - XMSS_BDS_K > 0 && i == 3) {
memcpy(state->treehash[0].node, stack+stackoffset*XMSS_N, XMSS_N);
}
while (stackoffset>1 && stacklevels[stackoffset-1] == stacklevels[stackoffset-2])
{
nodeh = stacklevels[stackoffset-1];
if (i >> nodeh == 1) {
memcpy(state->auth + nodeh*XMSS_N, stack+(stackoffset-1)*XMSS_N, XMSS_N);
}
else {
if (nodeh < XMSS_TREEHEIGHT - XMSS_BDS_K && i >> nodeh == 3) {
memcpy(state->treehash[nodeh].node, stack+(stackoffset-1)*XMSS_N, XMSS_N);
}
else if (nodeh >= XMSS_TREEHEIGHT - XMSS_BDS_K) {
memcpy(state->retain + ((1 << (XMSS_TREEHEIGHT - 1 - nodeh)) + nodeh - XMSS_TREEHEIGHT + (((i >> nodeh) - 3) >> 1)) * XMSS_N, stack+(stackoffset-1)*XMSS_N, XMSS_N);
}
}
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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);
stacklevels[stackoffset-2]++;
stackoffset--;
}
i++;
}
for (i = 0; i < XMSS_N; i++)
node[i] = stack[i];
}
static void treehash_update(treehash_inst *treehash, bds_state *state, const unsigned char *sk_seed, const unsigned char *pub_seed, const uint32_t addr[8])
{
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uint32_t ots_addr[8];
uint32_t ltree_addr[8];
uint32_t node_addr[8];
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// 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);
setLtreeADRS(ltree_addr, treehash->next_idx);
setOTSADRS(ots_addr, treehash->next_idx);
unsigned char nodebuffer[2 * XMSS_N];
unsigned int nodeheight = 0;
gen_leaf_wots(nodebuffer, sk_seed, pub_seed, ltree_addr, ots_addr);
while (treehash->stackusage > 0 && state->stacklevels[state->stackoffset-1] == nodeheight) {
memcpy(nodebuffer + XMSS_N, nodebuffer, XMSS_N);
memcpy(nodebuffer, state->stack + (state->stackoffset-1)*XMSS_N, XMSS_N);
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setTreeHeight(node_addr, nodeheight);
setTreeIndex(node_addr, (treehash->next_idx >> (nodeheight+1)));
hash_h(nodebuffer, nodebuffer, pub_seed, node_addr);
nodeheight++;
treehash->stackusage--;
state->stackoffset--;
}
if (nodeheight == treehash->h) { // this also implies stackusage == 0
memcpy(treehash->node, nodebuffer, XMSS_N);
treehash->completed = 1;
}
else {
memcpy(state->stack + state->stackoffset*XMSS_N, nodebuffer, XMSS_N);
treehash->stackusage++;
state->stacklevels[state->stackoffset] = nodeheight;
state->stackoffset++;
treehash->next_idx++;
}
}
/**
* Performs one treehash update on the instance that needs it the most.
* Returns 1 if such an instance was not found
**/
static char bds_treehash_update(bds_state *state, unsigned int updates, const unsigned char *sk_seed, unsigned char *pub_seed, const uint32_t addr[8]) {
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uint32_t i, j;
unsigned int level, l_min, low;
unsigned int used = 0;
for (j = 0; j < updates; j++) {
l_min = XMSS_TREEHEIGHT;
level = XMSS_TREEHEIGHT - XMSS_BDS_K;
for (i = 0; i < XMSS_TREEHEIGHT - XMSS_BDS_K; i++) {
if (state->treehash[i].completed) {
low = XMSS_TREEHEIGHT;
}
else if (state->treehash[i].stackusage == 0) {
low = i;
}
else {
low = treehash_minheight_on_stack(state, &(state->treehash[i]));
}
if (low < l_min) {
level = i;
l_min = low;
}
}
if (level == XMSS_TREEHEIGHT - XMSS_BDS_K) {
break;
}
treehash_update(&(state->treehash[level]), state, sk_seed, pub_seed, addr);
used++;
}
return updates - used;
}
/**
* Updates the state (typically NEXT_i) by adding a leaf and updating the stack
* Returns 1 if all leaf nodes have already been processed
**/
static char bds_state_update(bds_state *state, const unsigned char *sk_seed, unsigned char *pub_seed, const uint32_t addr[8]) {
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uint32_t ltree_addr[8];
uint32_t node_addr[8];
uint32_t ots_addr[8];
int nodeh;
int idx = state->next_leaf;
if (idx == 1 << XMSS_TREEHEIGHT) {
return 1;
}
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// 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);
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setOTSADRS(ots_addr, idx);
setLtreeADRS(ltree_addr, idx);
gen_leaf_wots(state->stack+state->stackoffset*XMSS_N, sk_seed, pub_seed, ltree_addr, ots_addr);
state->stacklevels[state->stackoffset] = 0;
state->stackoffset++;
if (XMSS_TREEHEIGHT - XMSS_BDS_K > 0 && idx == 3) {
memcpy(state->treehash[0].node, state->stack+state->stackoffset*XMSS_N, XMSS_N);
}
while (state->stackoffset>1 && state->stacklevels[state->stackoffset-1] == state->stacklevels[state->stackoffset-2]) {
nodeh = state->stacklevels[state->stackoffset-1];
if (idx >> nodeh == 1) {
memcpy(state->auth + nodeh*XMSS_N, state->stack+(state->stackoffset-1)*XMSS_N, XMSS_N);
}
else {
if (nodeh < XMSS_TREEHEIGHT - XMSS_BDS_K && idx >> nodeh == 3) {
memcpy(state->treehash[nodeh].node, state->stack+(state->stackoffset-1)*XMSS_N, XMSS_N);
}
else if (nodeh >= XMSS_TREEHEIGHT - XMSS_BDS_K) {
memcpy(state->retain + ((1 << (XMSS_TREEHEIGHT - 1 - nodeh)) + nodeh - XMSS_TREEHEIGHT + (((idx >> nodeh) - 3) >> 1)) * XMSS_N, state->stack+(state->stackoffset-1)*XMSS_N, XMSS_N);
}
}
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setTreeHeight(node_addr, state->stacklevels[state->stackoffset-1]);
setTreeIndex(node_addr, (idx >> (state->stacklevels[state->stackoffset-1]+1)));
hash_h(state->stack+(state->stackoffset-2)*XMSS_N, state->stack+(state->stackoffset-2)*XMSS_N, pub_seed, node_addr);
state->stacklevels[state->stackoffset-2]++;
state->stackoffset--;
}
state->next_leaf++;
return 0;
}
/**
* Returns the auth path for node leaf_idx and computes the auth path for the
* next leaf node, using the algorithm described by Buchmann, Dahmen and Szydlo
* in "Post Quantum Cryptography", Springer 2009.
*/
static void bds_round(bds_state *state, const unsigned long leaf_idx, const unsigned char *sk_seed, unsigned char *pub_seed, uint32_t addr[8])
{
unsigned int i;
unsigned int tau = XMSS_TREEHEIGHT;
unsigned int startidx;
unsigned int offset, rowidx;
unsigned char buf[2 * XMSS_N];
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uint32_t ots_addr[8];
uint32_t ltree_addr[8];
uint32_t node_addr[8];
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// 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);
for (i = 0; i < XMSS_TREEHEIGHT; i++) {
if (! ((leaf_idx >> i) & 1)) {
tau = i;
break;
}
}
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if (tau > 0) {
memcpy(buf, state->auth + (tau-1) * XMSS_N, XMSS_N);
// we need to do this before refreshing state->keep to prevent overwriting
memcpy(buf + XMSS_N, state->keep + ((tau-1) >> 1) * XMSS_N, XMSS_N);
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}
if (!((leaf_idx >> (tau + 1)) & 1) && (tau < XMSS_TREEHEIGHT - 1)) {
memcpy(state->keep + (tau >> 1)*XMSS_N, state->auth + tau*XMSS_N, XMSS_N);
}
if (tau == 0) {
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setLtreeADRS(ltree_addr, leaf_idx);
setOTSADRS(ots_addr, leaf_idx);
gen_leaf_wots(state->auth, sk_seed, pub_seed, ltree_addr, ots_addr);
}
else {
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setTreeHeight(node_addr, (tau-1));
setTreeIndex(node_addr, leaf_idx >> tau);
hash_h(state->auth + tau * XMSS_N, buf, pub_seed, node_addr);
for (i = 0; i < tau; i++) {
if (i < XMSS_TREEHEIGHT - XMSS_BDS_K) {
memcpy(state->auth + i * XMSS_N, state->treehash[i].node, XMSS_N);
}
else {
offset = (1 << (XMSS_TREEHEIGHT - 1 - i)) + i - XMSS_TREEHEIGHT;
rowidx = ((leaf_idx >> i) - 1) >> 1;
memcpy(state->auth + i * XMSS_N, state->retain + (offset + rowidx) * XMSS_N, XMSS_N);
}
}
for (i = 0; i < ((tau < XMSS_TREEHEIGHT - XMSS_BDS_K) ? tau : (XMSS_TREEHEIGHT - XMSS_BDS_K)); i++) {
startidx = leaf_idx + 1 + 3 * (1 << i);
if (startidx < 1U << XMSS_TREEHEIGHT) {
state->treehash[i].h = i;
state->treehash[i].next_idx = startidx;
state->treehash[i].completed = 0;
state->treehash[i].stackusage = 0;
}
}
}
}
/*
* Generates a XMSS key pair for a given parameter set.
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* 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, bds_state *state)
{
// Set idx = 0
sk[0] = 0;
sk[1] = 0;
sk[2] = 0;
sk[3] = 0;
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// Init SK_SEED (n byte), SK_PRF (n byte), and PUB_SEED (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);
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uint32_t addr[8] = {0, 0, 0, 0, 0, 0, 0, 0};
// Compute root
treehash_setup(pk, XMSS_TREEHEIGHT, 0, state, sk+4, sk+4+2*XMSS_N, addr);
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// 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, bds_state *state, unsigned char *sm, unsigned long long *smlen, const unsigned char *m, unsigned long long mlen)
{
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uint16_t i = 0;
// Extract SK
unsigned long 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);
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// 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 ots_seed[XMSS_N];
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uint32_t ots_addr[8] = {0, 0, 0, 0, 0, 0, 0, 0};
// ---------------------------------
// Message Hashing
// ---------------------------------
// Message Hash:
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// First compute pseudorandom value
prf(R, idx_bytes_32, sk_prf, XMSS_N);
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// 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, m, mlen, hash_key, 3*XMSS_N);
// Start collecting signature
*smlen = 0;
// Copy index to signature
sm[0] = (idx >> 24) & 255;
sm[1] = (idx >> 16) & 255;
sm[2] = (idx >> 8) & 255;
sm[3] = idx & 255;
sm += 4;
*smlen += 4;
// Copy R to signature
for (i = 0; i < XMSS_N; i++)
sm[i] = R[i];
sm += XMSS_N;
*smlen += XMSS_N;
// ----------------------------------
// Now we start to "really sign"
// ----------------------------------
// Prepare Address
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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(sm, msg_h, ots_seed, pub_seed, ots_addr);
sm += XMSS_WOTS_KEYSIZE;
*smlen += XMSS_WOTS_KEYSIZE;
// the auth path was already computed during the previous round
memcpy(sm, state->auth, XMSS_TREEHEIGHT*XMSS_N);
if (idx < (1U << XMSS_TREEHEIGHT) - 1) {
bds_round(state, idx, sk_seed, pub_seed, ots_addr);
bds_treehash_update(state, (XMSS_TREEHEIGHT - XMSS_BDS_K) >> 1, sk_seed, pub_seed, ots_addr);
}
sm += XMSS_TREEHEIGHT*XMSS_N;
*smlen += XMSS_TREEHEIGHT*XMSS_N;
memcpy(sm, m, mlen);
*smlen += mlen;
return 0;
}
/*
* Generates a XMSSMT key pair for a given parameter set.
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* Format sk: [(ceil(h/8) bit) idx || SK_SEED || SK_PRF || PUB_SEED || root]
* Format pk: [root || PUB_SEED] omitting algo oid.
*/
int xmssmt_keypair(unsigned char *pk, unsigned char *sk, bds_state *states, unsigned char *wots_sigs)
{
unsigned char ots_seed[XMSS_N];
int 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);
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uint32_t addr[8] = {0, 0, 0, 0, 0, 0, 0, 0};
// Start with the bottom-most layer
setLayerADRS(addr, 0);
// Set up state and compute wots signatures for all but topmost tree root
for (i = 0; i < XMSS_D - 1; i++) {
// Compute seed for OTS key pair
treehash_setup(pk, XMSS_TREEHEIGHT, 0, states + i, sk+XMSS_INDEX_LEN, pk+XMSS_N, addr);
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setLayerADRS(addr, (i+1));
get_seed(ots_seed, sk+XMSS_INDEX_LEN, addr);
wots_sign(wots_sigs + i*XMSS_WOTS_KEYSIZE, pk, ots_seed, pk+XMSS_N, addr);
}
// Address now points to the single tree on layer d-1
treehash_setup(pk, XMSS_TREEHEIGHT, 0, states + i, 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, bds_state *states, unsigned char *wots_sigs, unsigned char *sm, unsigned long long *smlen, const unsigned char *m, unsigned long long mlen)
{
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uint64_t idx_tree;
uint32_t idx_leaf;
uint64_t i, j;
int needswap_upto = -1;
unsigned int updates;
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 msg_h[XMSS_N];
unsigned char hash_key[3*XMSS_N];
unsigned char ots_seed[XMSS_N];
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uint32_t addr[8] = {0, 0, 0, 0, 0, 0, 0, 0};
uint32_t ots_addr[8] = {0, 0, 0, 0, 0, 0, 0, 0};
unsigned char idx_bytes_32[32];
bds_state tmp;
// 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:
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// First compute pseudorandom value
to_byte(idx_bytes_32, idx, 32);
prf(R, idx_bytes_32, sk_prf, XMSS_N);
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// 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, m, mlen, hash_key, 3*XMSS_N);
// Start collecting signature
*smlen = 0;
// Copy index to signature
for (i = 0; i < XMSS_INDEX_LEN; i++) {
sm[i] = (idx >> 8*(XMSS_INDEX_LEN - 1 - i)) & 255;
}
sm += XMSS_INDEX_LEN;
*smlen += XMSS_INDEX_LEN;
// Copy R to signature
for (i = 0; i < XMSS_N; i++)
sm[i] = R[i];
sm += XMSS_N;
*smlen += XMSS_N;
// ----------------------------------
// Now we start to "really sign"
// ----------------------------------
// Handle lowest layer separately as it is slightly different...
// Prepare Address
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setType(ots_addr, 0);
idx_tree = idx >> XMSS_TREEHEIGHT;
idx_leaf = (idx & ((1 << XMSS_TREEHEIGHT)-1));
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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(sm, msg_h, ots_seed, pub_seed, ots_addr);
sm += XMSS_WOTS_KEYSIZE;
*smlen += XMSS_WOTS_KEYSIZE;
memcpy(sm, states[0].auth, XMSS_TREEHEIGHT*XMSS_N);
sm += XMSS_TREEHEIGHT*XMSS_N;
*smlen += XMSS_TREEHEIGHT*XMSS_N;
// prepare signature of remaining layers
for (i = 1; i < XMSS_D; i++) {
// put WOTS signature in place
memcpy(sm, wots_sigs + (i-1)*XMSS_WOTS_KEYSIZE, XMSS_WOTS_KEYSIZE);
sm += XMSS_WOTS_KEYSIZE;
*smlen += XMSS_WOTS_KEYSIZE;
// put AUTH nodes in place
memcpy(sm, states[i].auth, XMSS_TREEHEIGHT*XMSS_N);
sm += XMSS_TREEHEIGHT*XMSS_N;
*smlen += XMSS_TREEHEIGHT*XMSS_N;
}
updates = (XMSS_TREEHEIGHT - XMSS_BDS_K) >> 1;
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setTreeADRS(addr, (idx_tree + 1));
// mandatory update for NEXT_0 (does not count towards h-k/2) if NEXT_0 exists
if ((1 + idx_tree) * (1 << XMSS_TREEHEIGHT) + idx_leaf < (1ULL << XMSS_FULLHEIGHT)) {
bds_state_update(&states[XMSS_D], sk_seed, pub_seed, addr);
}
for (i = 0; i < XMSS_D; i++) {
// check if we're not at the end of a tree
if (! (((idx + 1) & ((1ULL << ((i+1)*XMSS_TREEHEIGHT)) - 1)) == 0)) {
idx_leaf = (idx >> (XMSS_TREEHEIGHT * i)) & ((1 << XMSS_TREEHEIGHT)-1);
idx_tree = (idx >> (XMSS_TREEHEIGHT * (i+1)));
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setLayerADRS(addr, i);
setTreeADRS(addr, idx_tree);
if (i == (unsigned int) (needswap_upto + 1)) {
bds_round(&states[i], idx_leaf, sk_seed, pub_seed, addr);
}
updates = bds_treehash_update(&states[i], updates, sk_seed, pub_seed, addr);
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setTreeADRS(addr, (idx_tree + 1));
// if a NEXT-tree exists for this level;
if ((1 + idx_tree) * (1 << XMSS_TREEHEIGHT) + idx_leaf < (1ULL << (XMSS_FULLHEIGHT - XMSS_TREEHEIGHT * i))) {
if (i > 0 && updates > 0 && states[XMSS_D + i].next_leaf < (1ULL << XMSS_FULLHEIGHT)) {
bds_state_update(&states[XMSS_D + i], sk_seed, pub_seed, addr);
updates--;
}
}
}
else if (idx < (1ULL << XMSS_FULLHEIGHT) - 1) {
memcpy(&tmp, states+XMSS_D + i, sizeof(bds_state));
memcpy(states+XMSS_D + i, states + i, sizeof(bds_state));
memcpy(states + i, &tmp, sizeof(bds_state));
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setLayerADRS(ots_addr, (i+1));
setTreeADRS(ots_addr, ((idx + 1) >> ((i+2) * XMSS_TREEHEIGHT)));
setOTSADRS(ots_addr, (((idx >> ((i+1) * XMSS_TREEHEIGHT)) + 1) & ((1 << XMSS_TREEHEIGHT)-1)));
get_seed(ots_seed, sk+XMSS_INDEX_LEN, ots_addr);
wots_sign(wots_sigs + i*XMSS_WOTS_KEYSIZE, states[i].stack, ots_seed, pub_seed, ots_addr);
states[XMSS_D + i].stackoffset = 0;
states[XMSS_D + i].next_leaf = 0;
updates--; // WOTS-signing counts as one update
needswap_upto = i;
for (j = 0; j < XMSS_TREEHEIGHT-XMSS_BDS_K; j++) {
states[i].treehash[j].completed = 1;
}
}
}
memcpy(sm, m, mlen);
*smlen += mlen;
return 0;
}