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pqcrypto/crypto_sign/sphincs-haraka-256s-simple/aesni/fors.c
Thom Wiggers facb527c7c SPHINCS+ optimized implementations (#253)
* Add state destroy to SHA2 API

* Include optimized SPHINCS+ implementations

I've generated new implementations from the sphincsplus repository.

* Don't destroy sha256ctx after finalize

* Attempt to shut up MSVC

* Make sure to drop errors in rmtree
2021-03-24 21:02:45 +00:00

207 lines
11 KiB
C

#include <stdint.h>
#include <stdlib.h>
#include <string.h>
#include "address.h"
#include "fors.h"
#include "hash.h"
#include "hashx4.h"
#include "thash.h"
#include "thashx4.h"
#include "utils.h"
#include "utilsx4.h"
static void fors_gen_skx4(unsigned char *sk0,
unsigned char *sk1,
unsigned char *sk2,
unsigned char *sk3, const unsigned char *sk_seed,
uint32_t fors_leaf_addrx4[4 * 8],
const hash_state *state_seeded) {
PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_prf_addrx4(sk0, sk1, sk2, sk3, sk_seed, fors_leaf_addrx4, state_seeded);
}
static void fors_sk_to_leaf(unsigned char *leaf, const unsigned char *sk,
const unsigned char *pub_seed,
uint32_t fors_leaf_addr[8], const hash_state *state_seeded) {
PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_thash_1(leaf, sk, pub_seed, fors_leaf_addr, state_seeded);
}
static void fors_sk_to_leafx4(unsigned char *leaf0,
unsigned char *leaf1,
unsigned char *leaf2,
unsigned char *leaf3,
const unsigned char *sk0,
const unsigned char *sk1,
const unsigned char *sk2,
const unsigned char *sk3,
const unsigned char *pub_seed,
uint32_t fors_leaf_addrx4[4 * 8],
const hash_state *state_seeded) {
PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_thashx4_1(leaf0, leaf1, leaf2, leaf3,
sk0, sk1, sk2, sk3, pub_seed, fors_leaf_addrx4, state_seeded);
}
static void fors_gen_leafx4(unsigned char *leaf0,
unsigned char *leaf1,
unsigned char *leaf2,
unsigned char *leaf3,
const unsigned char *sk_seed,
const unsigned char *pub_seed,
uint32_t addr_idx0,
uint32_t addr_idx1,
uint32_t addr_idx2,
uint32_t addr_idx3,
const uint32_t fors_tree_addr[8],
const hash_state *state_seeded) {
uint32_t fors_leaf_addrx4[4 * 8] = {0};
unsigned int j;
/* Only copy the parts that must be kept in fors_leaf_addrx4. */
for (j = 0; j < 4; j++) {
PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_copy_keypair_addr(fors_leaf_addrx4 + j * 8, fors_tree_addr);
PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_set_type(fors_leaf_addrx4 + j * 8, PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_ADDR_TYPE_FORSTREE);
}
PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_set_tree_index(fors_leaf_addrx4 + 0 * 8, addr_idx0);
PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_set_tree_index(fors_leaf_addrx4 + 1 * 8, addr_idx1);
PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_set_tree_index(fors_leaf_addrx4 + 2 * 8, addr_idx2);
PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_set_tree_index(fors_leaf_addrx4 + 3 * 8, addr_idx3);
fors_gen_skx4(leaf0, leaf1, leaf2, leaf3, sk_seed, fors_leaf_addrx4, state_seeded);
fors_sk_to_leafx4(leaf0, leaf1, leaf2, leaf3,
leaf0, leaf1, leaf2, leaf3, pub_seed, fors_leaf_addrx4, state_seeded);
}
/**
* Interprets m as PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_FORS_HEIGHT-bit unsigned integers.
* Assumes m contains at least PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_FORS_HEIGHT * PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_FORS_TREES bits.
* Assumes indices has space for PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_FORS_TREES integers.
*/
static void message_to_indices(uint32_t *indices, const unsigned char *m) {
unsigned int i, j;
unsigned int offset = 0;
for (i = 0; i < PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_FORS_TREES; i++) {
indices[i] = 0;
for (j = 0; j < PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_FORS_HEIGHT; j++) {
indices[i] ^= (((uint32_t)m[offset >> 3] >> (offset & 0x7)) & 0x1) << j;
offset++;
}
}
}
/**
* Signs a message m, deriving the secret key from sk_seed and the FTS address.
* Assumes m contains at least PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_FORS_HEIGHT * PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_FORS_TREES bits.
*/
void PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_fors_sign(unsigned char *sig, unsigned char *pk,
const unsigned char *m,
const unsigned char *sk_seed, const unsigned char *pub_seed,
const uint32_t fors_addr[8], const hash_state *state_seeded) {
/* Round up to multiple of 4 to prevent out-of-bounds for x4 parallelism */
uint32_t indices[(PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_FORS_TREES + 3) & ~3] = {0};
unsigned char roots[((PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_FORS_TREES + 3) & ~3) * PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_N];
/* Sign to a buffer, since we may not have a nice multiple of 4 and would
otherwise overrun the signature. */
unsigned char sigbufx4[4 * PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_N * (1 + PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_FORS_HEIGHT)];
uint32_t fors_tree_addrx4[4 * 8] = {0};
uint32_t fors_pk_addr[8] = {0};
uint32_t idx_offset[4] = {0};
unsigned int i, j;
for (j = 0; j < 4; j++) {
PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_copy_keypair_addr(fors_tree_addrx4 + j * 8, fors_addr);
PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_set_type(fors_tree_addrx4 + j * 8, PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_ADDR_TYPE_FORSTREE);
}
PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_copy_keypair_addr(fors_pk_addr, fors_addr);
PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_set_type(fors_pk_addr, PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_ADDR_TYPE_FORSPK);
message_to_indices(indices, m);
for (i = 0; i < ((PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_FORS_TREES + 3) & ~0x3); i += 4) {
for (j = 0; j < 4; j++) {
if (i + j < PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_FORS_TREES) {
idx_offset[j] = (i + j) * (1 << PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_FORS_HEIGHT);
PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_set_tree_height(fors_tree_addrx4 + j * 8, 0);
PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_set_tree_index(fors_tree_addrx4 + j * 8,
indices[i + j] + idx_offset[j]);
}
}
/* Include the secret key part that produces the selected leaf nodes. */
fors_gen_skx4(sigbufx4 + 0 * PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_N,
sigbufx4 + 1 * PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_N,
sigbufx4 + 2 * PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_N,
sigbufx4 + 3 * PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_N,
sk_seed, fors_tree_addrx4, state_seeded);
PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_treehashx4_FORS_HEIGHT(roots + i * PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_N, sigbufx4 + 4 * PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_N, sk_seed, pub_seed,
&indices[i], idx_offset, fors_gen_leafx4, fors_tree_addrx4,
state_seeded);
for (j = 0; j < 4; j++) {
if (i + j < PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_FORS_TREES) {
memcpy(sig, sigbufx4 + j * PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_N, PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_N);
memcpy(sig + PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_N,
sigbufx4 + 4 * PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_N + j * PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_N * PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_FORS_HEIGHT,
PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_N * PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_FORS_HEIGHT);
sig += PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_N * (1 + PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_FORS_HEIGHT);
}
}
}
/* Hash horizontally across all tree roots to derive the public key. */
PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_thash_FORS_TREES(pk, roots, pub_seed, fors_pk_addr, state_seeded);
}
/**
* Derives the FORS public key from a signature.
* This can be used for verification by comparing to a known public key, or to
* subsequently verify a signature on the derived public key. The latter is the
* typical use-case when used as an FTS below an OTS in a hypertree.
* Assumes m contains at least PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_FORS_HEIGHT * PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_FORS_TREES bits.
*/
void PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_fors_pk_from_sig(unsigned char *pk,
const unsigned char *sig, const unsigned char *m,
const unsigned char *pub_seed,
const uint32_t fors_addr[8],
const hash_state *state_seeded) {
uint32_t indices[PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_FORS_TREES];
unsigned char roots[PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_FORS_TREES * PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_N];
unsigned char leaf[PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_N];
uint32_t fors_tree_addr[8] = {0};
uint32_t fors_pk_addr[8] = {0};
uint32_t idx_offset;
unsigned int i;
PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_copy_keypair_addr(fors_tree_addr, fors_addr);
PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_copy_keypair_addr(fors_pk_addr, fors_addr);
PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_set_type(fors_tree_addr, PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_ADDR_TYPE_FORSTREE);
PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_set_type(fors_pk_addr, PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_ADDR_TYPE_FORSPK);
message_to_indices(indices, m);
for (i = 0; i < PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_FORS_TREES; i++) {
idx_offset = i * (1 << PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_FORS_HEIGHT);
PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_set_tree_height(fors_tree_addr, 0);
PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_set_tree_index(fors_tree_addr, indices[i] + idx_offset);
/* Derive the leaf from the included secret key part. */
fors_sk_to_leaf(leaf, sig, pub_seed, fors_tree_addr, state_seeded);
sig += PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_N;
/* Derive the corresponding root node of this tree. */
PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_compute_root(roots + i * PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_N, leaf, indices[i], idx_offset,
sig, PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_FORS_HEIGHT, pub_seed, fors_tree_addr,
state_seeded);
sig += PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_N * PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_FORS_HEIGHT;
}
/* Hash horizontally across all tree roots to derive the public key. */
PQCLEAN_SPHINCSHARAKA256SSIMPLE_AESNI_thash_FORS_TREES(pk, roots, pub_seed, fors_pk_addr, state_seeded);
}