xmss-KAT-generator/xmss_commons.c

263 regels
8.6 KiB
C

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#include <stdlib.h>
#include <string.h>
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#include <stdint.h>
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#include "hash.h"
#include "hash_address.h"
#include "params.h"
#include "wots.h"
#include "xmss_commons.h"
/**
* Converts the value of 'in' to 'outlen' bytes in big-endian byte order.
*/
void ull_to_bytes(unsigned char *out, unsigned int outlen,
unsigned long long in)
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{
int i;
/* Iterate over out in decreasing order, for big-endianness. */
for (i = outlen - 1; i >= 0; i--) {
out[i] = in & 0xff;
in = in >> 8;
}
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}
/**
* Converts the inlen bytes in 'in' from big-endian byte order to an integer.
*/
unsigned long long bytes_to_ull(const unsigned char *in, unsigned int inlen)
{
unsigned long long retval = 0;
unsigned int i;
for (i = 0; i < inlen; i++) {
retval |= ((unsigned long long)in[i]) << (8*(inlen - 1 - i));
}
return retval;
}
/**
* Computes the leaf at a given address. First generates the WOTS key pair,
* then computes leaf using l_tree. As this happens position independent, we
* only require that addr encodes the right ltree-address.
*/
void gen_leaf_wots(const xmss_params *params, unsigned char *leaf,
const unsigned char *sk_seed, const unsigned char *pub_seed,
uint32_t ltree_addr[8], uint32_t ots_addr[8])
{
unsigned char seed[params->n];
unsigned char pk[params->wots_sig_bytes];
get_seed(params, seed, sk_seed, ots_addr);
wots_pkgen(params, pk, seed, pub_seed, ots_addr);
l_tree(params, leaf, pk, pub_seed, ltree_addr);
}
/**
* Used for pseudo-random key generation.
* Generates the seed for the WOTS key pair at address 'addr'.
*
* Takes n-byte sk_seed and returns n-byte seed using 32 byte address 'addr'.
*/
void get_seed(const xmss_params *params, unsigned char *seed,
const unsigned char *sk_seed, uint32_t addr[8])
{
unsigned char bytes[32];
/* Make sure that chain addr, hash addr, and key bit are zeroed. */
set_chain_addr(addr, 0);
set_hash_addr(addr, 0);
set_key_and_mask(addr, 0);
/* Generate seed. */
addr_to_bytes(bytes, addr);
prf(params, seed, bytes, sk_seed, params->n);
}
/**
* Computes a leaf node from a WOTS public key using an L-tree.
* Note that this destroys the used WOTS public key.
*/
void l_tree(const xmss_params *params,
unsigned char *leaf, unsigned char *wots_pk,
const unsigned char *pub_seed, uint32_t addr[8])
{
unsigned int l = params->wots_len;
unsigned int parent_nodes;
uint32_t i;
uint32_t height = 0;
set_tree_height(addr, height);
while (l > 1) {
parent_nodes = l >> 1;
for (i = 0; i < parent_nodes; i++) {
set_tree_index(addr, i);
/* Hashes the nodes at (i*2)*params->n and (i*2)*params->n + 1 */
hash_h(params, wots_pk + i*params->n,
wots_pk + (i*2)*params->n, pub_seed, addr);
}
/* If the row contained an odd number of nodes, the last node was not
hashed. Instead, we pull it up to the next layer. */
if (l & 1) {
memcpy(wots_pk + (l >> 1)*params->n,
wots_pk + (l - 1)*params->n, params->n);
l = (l >> 1) + 1;
}
else {
l = l >> 1;
}
height++;
set_tree_height(addr, height);
}
memcpy(leaf, wots_pk, params->n);
}
/**
* Computes a root node given a leaf and an auth path
*/
static void compute_root(const xmss_params *params, unsigned char *root,
const unsigned char *leaf, unsigned long leafidx,
const unsigned char *auth_path,
const unsigned char *pub_seed, uint32_t addr[8])
{
uint32_t i;
unsigned char buffer[2*params->n];
/* If leafidx is odd (last bit = 1), current path element is a right child
and auth_path has to go left. Otherwise it is the other way around. */
if (leafidx & 1) {
memcpy(buffer + params->n, leaf, params->n);
memcpy(buffer, auth_path, params->n);
}
else {
memcpy(buffer, leaf, params->n);
memcpy(buffer + params->n, auth_path, params->n);
}
auth_path += params->n;
for (i = 0; i < params->tree_height - 1; i++) {
set_tree_height(addr, i);
leafidx >>= 1;
set_tree_index(addr, leafidx);
/* Pick the right or left neighbor, depending on parity of the node. */
if (leafidx & 1) {
hash_h(params, buffer + params->n, buffer, pub_seed, addr);
memcpy(buffer, auth_path, params->n);
}
else {
hash_h(params, buffer, buffer, pub_seed, addr);
memcpy(buffer + params->n, auth_path, params->n);
}
auth_path += params->n;
}
/* The last iteration is exceptional; we do not copy an auth)path node. */
set_tree_height(addr, params->tree_height - 1);
leafidx >>= 1;
set_tree_index(addr, leafidx);
hash_h(params, root, buffer, pub_seed, addr);
}
/**
* Verifies a given message signature pair under a given public key.
* Note that this assumes a pk without an OID, i.e. [root || PUB_SEED]
*/
int xmss_core_sign_open(const xmss_params *params,
unsigned char *m, unsigned long long *mlen,
const unsigned char *sm, unsigned long long smlen,
const unsigned char *pk)
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{
/* XMSS signatures are fundamentally an instance of XMSSMT signatures.
For d=1, as is the case with XMSS, some of the calls in the XMSSMT
routine become vacuous (i.e. the loop only iterates once, and address
management can be simplified a bit).*/
return xmssmt_core_sign_open(params, m, mlen, sm, smlen, pk);
}
/**
* Verifies a given message signature pair under a given public key.
* Note that this assumes a pk without an OID, i.e. [root || PUB_SEED]
*/
int xmssmt_core_sign_open(const xmss_params *params,
unsigned char *m, unsigned long long *mlen,
const unsigned char *sm, unsigned long long smlen,
const unsigned char *pk)
{
const unsigned char *pub_seed = pk + params->n;
unsigned char wots_pk[params->wots_sig_bytes];
unsigned char leaf[params->n];
unsigned char root[params->n];
unsigned char *mhash = root;
unsigned long long idx = 0;
unsigned int i;
uint32_t idx_leaf;
uint32_t ots_addr[8] = {0};
uint32_t ltree_addr[8] = {0};
uint32_t node_addr[8] = {0};
set_type(ots_addr, XMSS_ADDR_TYPE_OTS);
set_type(ltree_addr, XMSS_ADDR_TYPE_LTREE);
set_type(node_addr, XMSS_ADDR_TYPE_HASHTREE);
*mlen = smlen - params->sig_bytes;
/* Convert the index bytes from the signature to an integer. */
idx = bytes_to_ull(sm, params->index_bytes);
/* Put the message all the way at the end of the m buffer, so that we can
* prepend the required other inputs for the hash function. */
memcpy(m + params->sig_bytes, sm + params->sig_bytes, *mlen);
/* Compute the message hash. */
hash_message(params, mhash, sm + params->index_bytes, pk, idx,
m + params->sig_bytes - 4*params->n, *mlen);
sm += params->index_bytes + params->n;
/* For each subtree.. */
for (i = 0; i < params->d; i++) {
idx_leaf = (idx & ((1 << params->tree_height)-1));
idx = idx >> params->tree_height;
set_layer_addr(ots_addr, i);
set_layer_addr(ltree_addr, i);
set_layer_addr(node_addr, i);
set_tree_addr(ltree_addr, idx);
set_tree_addr(ots_addr, idx);
set_tree_addr(node_addr, idx);
/* The WOTS public key is only correct if the signature was correct. */
set_ots_addr(ots_addr, idx_leaf);
/* Initially, root = mhash, but on subsequent iterations it is the root
of the subtree below the currently processed subtree. */
wots_pk_from_sig(params, wots_pk, sm, root, pub_seed, ots_addr);
sm += params->wots_sig_bytes;
/* Compute the leaf node using the WOTS public key. */
set_ltree_addr(ltree_addr, idx_leaf);
l_tree(params, leaf, wots_pk, pub_seed, ltree_addr);
/* Compute the root node of this subtree. */
compute_root(params, root, leaf, idx_leaf, sm, pub_seed, node_addr);
sm += params->tree_height*params->n;
}
/* Check if the root node equals the root node in the public key. */
if (memcmp(root, pk, params->n)) {
/* If not, zero the message */
memset(m, 0, *mlen);
*mlen = 0;
return -1;
}
/* If verification was successful, copy the message from the signature. */
memcpy(m, sm, *mlen);
return 0;
}