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348 | #include <stddef.h>
#include <string.h>
#include "api.h"
#include "inner.h"
/* ==================================================================== */
/*
* Falcon degree is N = 2^LOGN, where LOGN=9 (for Falcon-512) or 10
* (for Falcon-1024). We use the advertised public key size to know
* which degree is used.
*/
#if CRYPTO_PUBLICKEYBYTES == 897
#define LOGN 9
#elif CRYPTO_PUBLICKEYBYTES == 1793
#define LOGN 10
#else
#error Unknown Falcon degree (unexpected public key size)
#endif
#define N ((size_t)1 << LOGN)
#define NONCELEN 40
#define SEEDLEN 48
/*
* If the private key length is larger than 10000, then this is the
* variant with precomputed expanded keys.
*/
#if CRYPTO_SECRETKEYBYTES > 10000
#define KG_EXPAND 1
#else
#define KG_EXPAND 0
#endif
/*
* Common buffer, to avoid bulky stack allocation. The buffer sizes are
* all expressed in bytes, but the buffer must be suitably aligned for
* 64-bit integers and floating-point values.
*
* Required size (in bytes):
*
* With expanded key:
* keygen: 48*N + 6*N = 54*N
* sign: 48*N + 2*N = 50*N
* vrfy: 8*N
*
* Without expanded key:
* keygen: 28*N + 5*N = 33*N
* sign: 72*N + 6*N = 78*N
* vrfy: 8*N
*/
static union {
#if KG_EXPAND
uint8_t b[54 * N];
#else
uint8_t b[78 * N];
#endif
uint64_t dummy_u64;
fpr dummy_fp;
} tmp;
int randombytes(unsigned char *dst, size_t len);
int
crypto_sign_keypair(unsigned char *pk, unsigned char *sk)
{
int8_t *f, *g, *F, *G;
uint16_t *h;
inner_shake256_context rng;
unsigned char seed[SEEDLEN];
#if KG_EXPAND
size_t v;
#else
size_t u, v;
#endif
unsigned sav_cw;
#if KG_EXPAND
f = (int8_t *)&tmp.b[48 * N];
g = f + N;
F = g + N;
G = F + N;
h = (uint16_t *)(G + N);
#else
f = (int8_t *)&tmp.b[28 * N];
g = f + N;
F = g + N;
G = NULL;
h = (uint16_t *)(F + N);
#endif
randombytes(seed, SEEDLEN);
inner_shake256_init(&rng);
inner_shake256_inject(&rng, seed, SEEDLEN);
inner_shake256_flip(&rng);
sav_cw = set_fpu_cw(2);
Zf(keygen)(&rng, f, g, F, G, h, LOGN, tmp.b);
#if KG_EXPAND
/*
* Expand private key.
*/
Zf(expand_privkey)((fpr *)sk, f, g, F, G, LOGN, tmp.b);
set_fpu_cw(sav_cw);
#else
set_fpu_cw(sav_cw);
/*
* Encode private key.
*/
sk[0] = 0x50 + LOGN;
u = 1;
v = Zf(trim_i8_encode)(sk + u, CRYPTO_SECRETKEYBYTES - u,
f, LOGN, Zf(max_fg_bits)[LOGN]);
if (v == 0) {
return -1;
}
u += v;
v = Zf(trim_i8_encode)(sk + u, CRYPTO_SECRETKEYBYTES - u,
g, LOGN, Zf(max_fg_bits)[LOGN]);
if (v == 0) {
return -1;
}
u += v;
v = Zf(trim_i8_encode)(sk + u, CRYPTO_SECRETKEYBYTES - u,
F, LOGN, Zf(max_FG_bits)[LOGN]);
if (v == 0) {
return -1;
}
u += v;
if (u != CRYPTO_SECRETKEYBYTES) {
return -1;
}
#endif
/*
* Encode public key.
*/
pk[0] = 0x00 + LOGN;
v = Zf(modq_encode)(pk + 1, CRYPTO_PUBLICKEYBYTES - 1, h, LOGN);
if (v != CRYPTO_PUBLICKEYBYTES - 1) {
return -1;
}
return 0;
}
int
crypto_sign(unsigned char *sm, size_t *smlen,
const unsigned char *m, size_t mlen,
const unsigned char *sk)
{
#if KG_EXPAND
const fpr *expanded_key;
#else
int8_t *f, *g, *F, *G;
size_t u, v;
#endif
int16_t *sig;
uint16_t *hm;
unsigned char seed[SEEDLEN], nonce[NONCELEN];
unsigned char *esig;
inner_shake256_context sc;
size_t sig_len;
unsigned sav_cw;
#if KG_EXPAND
sig = (int16_t *)&tmp.b[48 * N];
#else
f = (int8_t *)&tmp.b[72 * N];
g = f + N;
F = g + N;
G = F + N;
sig = (int16_t *)(G + N);
#endif
hm = (uint16_t *)sig; /* hm[] is shared with sig[] */
esig = (unsigned char *)tmp.b;
#if KG_EXPAND
/*
* Expanded key is provided "as is".
*/
expanded_key = (const fpr *)sk;
#else
/*
* Decode the private key.
*/
if (sk[0] != 0x50 + LOGN) {
return -1;
}
u = 1;
v = Zf(trim_i8_decode)(f, LOGN, Zf(max_fg_bits)[LOGN],
sk + u, CRYPTO_SECRETKEYBYTES - u);
if (v == 0) {
return -1;
}
u += v;
v = Zf(trim_i8_decode)(g, LOGN, Zf(max_fg_bits)[LOGN],
sk + u, CRYPTO_SECRETKEYBYTES - u);
if (v == 0) {
return -1;
}
u += v;
v = Zf(trim_i8_decode)(F, LOGN, Zf(max_FG_bits)[LOGN],
sk + u, CRYPTO_SECRETKEYBYTES - u);
if (v == 0) {
return -1;
}
u += v;
if (u != CRYPTO_SECRETKEYBYTES) {
return -1;
}
if (!Zf(complete_private)(G, f, g, F, LOGN, tmp.b)) {
return -1;
}
#endif
/*
* Create a random nonce (40 bytes).
*/
randombytes(nonce, NONCELEN);
/*
* Hash message nonce + message into a vector.
*/
inner_shake256_init(&sc);
inner_shake256_inject(&sc, nonce, NONCELEN);
inner_shake256_inject(&sc, m, mlen);
inner_shake256_flip(&sc);
Zf(hash_to_point_vartime)(&sc, hm, LOGN);
/*
* Initialize a RNG.
*/
randombytes(seed, SEEDLEN);
inner_shake256_init(&sc);
inner_shake256_inject(&sc, seed, SEEDLEN);
inner_shake256_flip(&sc);
/*
* Compute the signature.
*/
sav_cw = set_fpu_cw(2);
#if KG_EXPAND
Zf(sign_tree)(sig, &sc, expanded_key, hm, LOGN, tmp.b);
#else
Zf(sign_dyn)(sig, &sc, f, g, F, G, hm, LOGN, tmp.b);
#endif
set_fpu_cw(sav_cw);
/*
* Encode the signature and bundle it with the message. Format is:
* signature length 2 bytes, big-endian
* nonce 40 bytes
* message mlen bytes
* signature slen bytes
*/
esig[0] = 0x20 + LOGN;
sig_len = Zf(comp_encode)(esig + 1, CRYPTO_BYTES - 1, sig, LOGN);
if (sig_len == 0) {
return -1;
}
sig_len ++;
memmove(sm + 2 + NONCELEN, m, mlen);
sm[0] = (unsigned char)(sig_len >> 8);
sm[1] = (unsigned char)sig_len;
memcpy(sm + 2, nonce, NONCELEN);
memcpy(sm + 2 + NONCELEN + mlen, esig, sig_len);
*smlen = 2 + NONCELEN + mlen + sig_len;
return 0;
}
int
crypto_sign_open(unsigned char *m, size_t *mlen,
const unsigned char *sm, size_t smlen,
const unsigned char *pk)
{
uint16_t *h, *hm;
int16_t *sig;
const unsigned char *esig;
inner_shake256_context sc;
size_t sig_len, msg_len;
h = (uint16_t *)&tmp.b[2 * N];
hm = h + N;
sig = (int16_t *)(hm + N);
/*
* Decode public key.
*/
if (pk[0] != 0x00 + LOGN) {
return -1;
}
if (Zf(modq_decode)(h, LOGN, pk + 1, CRYPTO_PUBLICKEYBYTES - 1)
!= CRYPTO_PUBLICKEYBYTES - 1)
{
return -1;
}
Zf(to_ntt_monty)(h, LOGN);
/*
* Find nonce, signature, message length.
*/
if (smlen < 2 + NONCELEN) {
return -1;
}
sig_len = ((size_t)sm[0] << 8) | (size_t)sm[1];
if (sig_len > (smlen - 2 - NONCELEN)) {
return -1;
}
msg_len = smlen - 2 - NONCELEN - sig_len;
/*
* Decode signature.
*/
esig = sm + 2 + NONCELEN + msg_len;
if (sig_len < 1 || esig[0] != 0x20 + LOGN) {
return -1;
}
if (Zf(comp_decode)(sig, LOGN,
esig + 1, sig_len - 1) != sig_len - 1)
{
return -1;
}
/*
* Hash nonce + message into a vector.
*/
inner_shake256_init(&sc);
inner_shake256_inject(&sc, sm + 2, NONCELEN + msg_len);
inner_shake256_flip(&sc);
Zf(hash_to_point_vartime)(&sc, hm, LOGN);
/*
* Verify signature.
*/
if (!Zf(verify_raw)(hm, sig, h, LOGN, tmp.b)) {
return -1;
}
/*
* Return plaintext.
*/
memmove(m, sm + 2 + NONCELEN, msg_len);
*mlen = msg_len;
return 0;
}
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