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pqcrypto/crypto_sign/sphincs-sha256-256f-simple/clean/hash_sha256.c

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#include <stdint.h>
#include <string.h>
#include "address.h"
#include "hash.h"
#include "params.h"
#include "utils.h"
#include "sha2.h"
#include "sha256.h"
/* For SHA256, there is no immediate reason to initialize at the start,
so this function is an empty operation. */
void PQCLEAN_SPHINCSSHA256256FSIMPLE_CLEAN_initialize_hash_function(
const unsigned char *pub_seed, const unsigned char *sk_seed) {
PQCLEAN_SPHINCSSHA256256FSIMPLE_CLEAN_seed_state(pub_seed);
(void)sk_seed; /* Suppress an 'unused parameter' warning. */
}
/*
* Computes PRF(key, addr), given a secret key of SPX_N bytes and an address
*/
void PQCLEAN_SPHINCSSHA256256FSIMPLE_CLEAN_prf_addr(
unsigned char *out, const unsigned char *key, const uint32_t addr[8]) {
unsigned char buf[SPX_N + SPX_SHA256_ADDR_BYTES];
unsigned char outbuf[SPX_SHA256_OUTPUT_BYTES];
memcpy(buf, key, SPX_N);
PQCLEAN_SPHINCSSHA256256FSIMPLE_CLEAN_compress_address(buf + SPX_N, addr);
sha256(outbuf, buf, SPX_N + SPX_SHA256_ADDR_BYTES);
memcpy(out, outbuf, SPX_N);
}
/**
* Computes the message-dependent randomness R, using a secret seed as a key
* for HMAC, and an optional randomization value prefixed to the message.
* This requires m to have at least SPX_SHA256_BLOCK_BYTES + SPX_N space
* available in front of the pointer, i.e. before the message to use for the
* prefix. This is necessary to prevent having to move the message around (and
* allocate memory for it).
*/
void PQCLEAN_SPHINCSSHA256256FSIMPLE_CLEAN_gen_message_random(
unsigned char *R,
const unsigned char *sk_prf, const unsigned char *optrand,
const unsigned char *m, size_t mlen) {
unsigned char buf[SPX_SHA256_BLOCK_BYTES + SPX_SHA256_OUTPUT_BYTES];
uint8_t state[40];
int i;
/* This implements HMAC-SHA256 */
for (i = 0; i < SPX_N; i++) {
buf[i] = 0x36 ^ sk_prf[i];
}
memset(buf + SPX_N, 0x36, SPX_SHA256_BLOCK_BYTES - SPX_N);
sha256_inc_init(state);
sha256_inc_blocks(state, buf, 1);
memcpy(buf, optrand, SPX_N);
/* If optrand + message cannot fill up an entire block */
if (SPX_N + mlen < SPX_SHA256_BLOCK_BYTES) {
memcpy(buf + SPX_N, m, mlen);
sha256_inc_finalize(buf + SPX_SHA256_BLOCK_BYTES, state,
buf, mlen + SPX_N);
}
/* Otherwise first fill a block, so that finalize only uses the message */
else {
memcpy(buf + SPX_N, m, SPX_SHA256_BLOCK_BYTES - SPX_N);
sha256_inc_blocks(state, buf, 1);
m += SPX_SHA256_BLOCK_BYTES - SPX_N;
mlen -= SPX_SHA256_BLOCK_BYTES - SPX_N;
sha256_inc_finalize(buf + SPX_SHA256_BLOCK_BYTES, state, m, mlen);
}
for (i = 0; i < SPX_N; i++) {
buf[i] = 0x5c ^ sk_prf[i];
}
memset(buf + SPX_N, 0x5c, SPX_SHA256_BLOCK_BYTES - SPX_N);
sha256(buf, buf, SPX_SHA256_BLOCK_BYTES + SPX_SHA256_OUTPUT_BYTES);
memcpy(R, buf, SPX_N);
}
/**
* Computes the message hash using R, the public key, and the message.
* Outputs the message digest and the index of the leaf. The index is split in
* the tree index and the leaf index, for convenient copying to an address.
*/
void PQCLEAN_SPHINCSSHA256256FSIMPLE_CLEAN_hash_message(
unsigned char *digest, uint64_t *tree, uint32_t *leaf_idx,
const unsigned char *R, const unsigned char *pk,
const unsigned char *m, size_t mlen) {
#define SPX_TREE_BITS (SPX_TREE_HEIGHT * (SPX_D - 1))
#define SPX_TREE_BYTES ((SPX_TREE_BITS + 7) / 8)
#define SPX_LEAF_BITS SPX_TREE_HEIGHT
#define SPX_LEAF_BYTES ((SPX_LEAF_BITS + 7) / 8)
#define SPX_DGST_BYTES (SPX_FORS_MSG_BYTES + SPX_TREE_BYTES + SPX_LEAF_BYTES)
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unsigned char seed[SPX_SHA256_OUTPUT_BYTES + 4];
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/* Round to nearest multiple of SPX_SHA256_BLOCK_BYTES */
#define SPX_INBLOCKS (((SPX_N + SPX_PK_BYTES + SPX_SHA256_BLOCK_BYTES - 1) & \
-SPX_SHA256_BLOCK_BYTES) / SPX_SHA256_BLOCK_BYTES)
unsigned char inbuf[SPX_INBLOCKS * SPX_SHA256_BLOCK_BYTES];
unsigned char buf[SPX_DGST_BYTES];
unsigned char *bufp = buf;
uint8_t state[40];
sha256_inc_init(state);
memcpy(inbuf, R, SPX_N);
memcpy(inbuf + SPX_N, pk, SPX_PK_BYTES);
/* If R + pk + message cannot fill up an entire block */
if (SPX_N + SPX_PK_BYTES + mlen < SPX_INBLOCKS * SPX_SHA256_BLOCK_BYTES) {
memcpy(inbuf + SPX_N + SPX_PK_BYTES, m, mlen);
sha256_inc_finalize(seed, state, inbuf, SPX_N + SPX_PK_BYTES + mlen);
}
/* Otherwise first fill a block, so that finalize only uses the message */
else {
memcpy(inbuf + SPX_N + SPX_PK_BYTES, m,
SPX_INBLOCKS * SPX_SHA256_BLOCK_BYTES - SPX_N - SPX_PK_BYTES);
sha256_inc_blocks(state, inbuf, SPX_INBLOCKS);
m += SPX_INBLOCKS * SPX_SHA256_BLOCK_BYTES - SPX_N - SPX_PK_BYTES;
mlen -= SPX_INBLOCKS * SPX_SHA256_BLOCK_BYTES - SPX_N - SPX_PK_BYTES;
sha256_inc_finalize(seed, state, m, mlen);
}
/* By doing this in two steps, we prevent hashing the message twice;
otherwise each iteration in MGF1 would hash the message again. */
PQCLEAN_SPHINCSSHA256256FSIMPLE_CLEAN_mgf1(bufp, SPX_DGST_BYTES, seed, SPX_SHA256_OUTPUT_BYTES);
memcpy(digest, bufp, SPX_FORS_MSG_BYTES);
bufp += SPX_FORS_MSG_BYTES;
*tree = PQCLEAN_SPHINCSSHA256256FSIMPLE_CLEAN_bytes_to_ull(bufp, SPX_TREE_BYTES);
*tree &= (~(uint64_t)0) >> (64 - SPX_TREE_BITS);
bufp += SPX_TREE_BYTES;
*leaf_idx = (uint32_t)PQCLEAN_SPHINCSSHA256256FSIMPLE_CLEAN_bytes_to_ull(
bufp, SPX_LEAF_BYTES);
*leaf_idx &= (~(uint32_t)0) >> (32 - SPX_LEAF_BITS);
}