pqcrypto/crypto_sign/dilithium3/avx2/sign.c

#include <stdint.h>
#include <string.h>

#include "fips202.h"
#include "packing.h"
#include "params.h"
#include "poly.h"
#include "polyvec.h"
#include "randombytes.h"
#include "sign.h"
#include "symmetric.h"

/*************************************************
* Name:        expand_mat
*
* Description: Implementation of ExpandA. Generates matrix A with uniformly
*              random coefficients a_{i,j} by performing rejection
*              sampling on the output stream of SHAKE128(rho|i|j).
*
* Arguments:   - polyvecl mat[K]: output matrix
*              - const uint8_t rho[]: byte array containing seed rho
**************************************************/

void PQCLEAN_DILITHIUM3_AVX2_expand_mat(polyvecl mat[5], const uint8_t rho[SEEDBYTES]) {
    PQCLEAN_DILITHIUM3_AVX2_poly_uniform_4x(&mat[0].vec[0],
                                            &mat[0].vec[1],
                                            &mat[0].vec[2],
                                            &mat[0].vec[3],
                                            rho, 0, 1, 2, 3);
    PQCLEAN_DILITHIUM3_AVX2_poly_uniform_4x(&mat[1].vec[0],
                                            &mat[1].vec[1],
                                            &mat[1].vec[2],
                                            &mat[1].vec[3],
                                            rho, 256, 257, 258, 259);
    PQCLEAN_DILITHIUM3_AVX2_poly_uniform_4x(&mat[2].vec[0],
                                            &mat[2].vec[1],
                                            &mat[2].vec[2],
                                            &mat[2].vec[3],
                                            rho, 512, 513, 514, 515);
    PQCLEAN_DILITHIUM3_AVX2_poly_uniform_4x(&mat[3].vec[0],
                                            &mat[3].vec[1],
                                            &mat[3].vec[2],
                                            &mat[3].vec[3],
                                            rho, 768, 769, 770, 771);
    PQCLEAN_DILITHIUM3_AVX2_poly_uniform_4x(&mat[4].vec[0],
                                            &mat[4].vec[1],
                                            &mat[4].vec[2],
                                            &mat[4].vec[3],
                                            rho, 1024, 1025, 1026, 1027);
}


/*************************************************
* Name:        PQCLEAN_DILITHIUM3_AVX2_challenge
*
* Description: Implementation of H. Samples polynomial with 60 nonzero
*              coefficients in {-1,1} using the output stream of
*              SHAKE256(mu|w1).
*
* Arguments:   - poly *c: pointer to output polynomial
*              - const uint8_t mu[]: byte array containing mu
*              - const polyveck *w1: pointer to vector w1
**************************************************/
void PQCLEAN_DILITHIUM3_AVX2_challenge(poly *c,
                                       const uint8_t mu[CRHBYTES],
                                       const polyveck *w1) {
    unsigned int i, b, pos;
    uint64_t signs;
    uint8_t inbuf[CRHBYTES + K * POLW1_SIZE_PACKED];
    uint8_t outbuf[SHAKE256_RATE];
    shake256ctx state;

    for (i = 0; i < CRHBYTES; ++i) {
        inbuf[i] = mu[i];
    }
    for (i = 0; i < K; ++i) {
        PQCLEAN_DILITHIUM3_AVX2_polyw1_pack(inbuf + CRHBYTES + i * POLW1_SIZE_PACKED, &w1->vec[i]);
    }

    shake256_absorb(&state, inbuf, sizeof(inbuf));
    shake256_squeezeblocks(outbuf, 1, &state);

    signs = 0;
    for (i = 0; i < 8; ++i) {
        signs |= (uint64_t) outbuf[i] << 8 * i;
    }

    pos = 8;

    for (i = 0; i < N; ++i) {
        c->coeffs[i] = 0;
    }

    for (i = 196; i < 256; ++i) {
        do {
            if (pos >= SHAKE256_RATE) {
                shake256_squeezeblocks(outbuf, 1, &state);
                pos = 0;
            }

            b = outbuf[pos++];
        } while (b > i);

        c->coeffs[i] = c->coeffs[b];
        c->coeffs[b] = 1;
        c->coeffs[b] ^= -(signs & 1) & (1 ^ (Q - 1));
        signs >>= 1;
    }
}

/*************************************************
* Name:        PQCLEAN_DILITHIUM3_AVX2_crypto_sign_keypair
*
* Description: Generates public and private key.
*
* Arguments:   - uint8_t *pk: pointer to output public key (allocated
*                                   array of PQCLEAN_DILITHIUM3_AVX2_CRYPTO_PUBLICKEYBYTES bytes)
*              - uint8_t *sk: pointer to output private key (allocated
*                                   array of PQCLEAN_DILITHIUM3_AVX2_CRYPTO_SECRETKEYBYTES bytes)
*
* Returns 0 (success)
**************************************************/
int PQCLEAN_DILITHIUM3_AVX2_crypto_sign_keypair(uint8_t *pk, uint8_t *sk) {
    unsigned int i;
    uint8_t seedbuf[3 * SEEDBYTES];
    uint8_t tr[CRHBYTES];
    const uint8_t *rho, *rhoprime, *key;
    uint16_t nonce = 0;
    polyvecl mat[K];
    polyvecl s1, s1hat;
    polyveck s2, t, t1, t0;

    /* Expand 32 bytes of randomness into rho, rhoprime and key */
    randombytes(seedbuf, 3 * SEEDBYTES);
    rho = seedbuf;
    rhoprime = seedbuf + SEEDBYTES;
    key = seedbuf + 2 * SEEDBYTES;

    /* Expand matrix */
    PQCLEAN_DILITHIUM3_AVX2_expand_mat(mat, rho);

    /* Sample short vectors s1 and s2 */
    PQCLEAN_DILITHIUM3_AVX2_poly_uniform_eta_4x(&s1.vec[0], &s1.vec[1], &s1.vec[2], &s1.vec[3], rhoprime,
            nonce, nonce + 1, nonce + 2, nonce + 3);
    PQCLEAN_DILITHIUM3_AVX2_poly_uniform_eta_4x(&s2.vec[0], &s2.vec[1], &s2.vec[2], &s2.vec[3], rhoprime,
            nonce + 4, nonce + 5, nonce + 6, nonce + 7);
    PQCLEAN_DILITHIUM3_AVX2_poly_uniform_eta(&s2.vec[4], rhoprime, nonce + 8);

    /* Matrix-vector multiplication */
    s1hat = s1;
    PQCLEAN_DILITHIUM3_AVX2_polyvecl_ntt(&s1hat);
    for (i = 0; i < K; ++i) {
        PQCLEAN_DILITHIUM3_AVX2_polyvecl_pointwise_acc_invmontgomery(&t.vec[i], &mat[i], &s1hat);
        //PQCLEAN_DILITHIUM3_AVX2_poly_reduce(&t.vec[i]);
        PQCLEAN_DILITHIUM3_AVX2_poly_invntt_montgomery(&t.vec[i]);
    }

    /* Add error vector s2 */
    PQCLEAN_DILITHIUM3_AVX2_polyveck_add(&t, &t, &s2);

    /* Extract t1 and write public key */
    PQCLEAN_DILITHIUM3_AVX2_polyveck_freeze(&t);
    PQCLEAN_DILITHIUM3_AVX2_polyveck_power2round(&t1, &t0, &t);
    PQCLEAN_DILITHIUM3_AVX2_pack_pk(pk, rho, &t1);

    /* Compute CRH(rho, t1) and write secret key */
    crh(tr, pk, PQCLEAN_DILITHIUM3_AVX2_CRYPTO_PUBLICKEYBYTES);
    PQCLEAN_DILITHIUM3_AVX2_pack_sk(sk, rho, key, tr, &s1, &s2, &t0);

    return 0;
}

/*************************************************
* Name:        PQCLEAN_DILITHIUM3_AVX2_crypto_sign_signature
*
* Description: Compute signed message.
*
* Arguments:   - uint8_t *sig:  pointer to output signature (PQCLEAN_DILITHIUM3_AVX2_CRYPTO_BYTES
*                               of len)
*              - size_t *siglen: pointer to output length of signed message
*                               (should be PQCLEAN_DILITHIUM3_AVX2_CRYPTO_BYTES)
*              - uint8_t *m:    pointer to message to be signed
*              - size_t mlen:   length of message
*              - uint8_t *sk:   pointer to bit-packed secret key
*
* Returns 0 (success)
**************************************************/
int PQCLEAN_DILITHIUM3_AVX2_crypto_sign_signature(
    uint8_t *sig, size_t *siglen,
    const uint8_t *m, size_t mlen,
    const uint8_t *sk) {
    size_t i;
    unsigned int n;
    uint8_t seedbuf[2 * SEEDBYTES + 3 * CRHBYTES];
    uint8_t *rho, *tr, *key, *mu, *rhoprime;
    uint16_t nonce = 0;
    poly c, chat;
    polyvecl mat[K], s1, y, yhat, z;
    polyveck t0, s2, w, w1, w0;
    polyveck h, cs2, ct0;

    rho = seedbuf;
    tr = rho + SEEDBYTES;
    key = tr + CRHBYTES;
    mu = key + SEEDBYTES;
    rhoprime = mu + CRHBYTES;
    PQCLEAN_DILITHIUM3_AVX2_unpack_sk(rho, key, tr, &s1, &s2, &t0, sk);


    // use incremental hash API instead of copying around buffers
    /* Compute CRH(tr, m) */
    shake256incctx state;
    shake256_inc_init(&state);
    shake256_inc_absorb(&state, tr, CRHBYTES);
    shake256_inc_absorb(&state, m, mlen);
    shake256_inc_finalize(&state);
    shake256_inc_squeeze(mu, CRHBYTES, &state);

    crh(rhoprime, key, SEEDBYTES + CRHBYTES);

    /* Expand matrix and transform vectors */
    PQCLEAN_DILITHIUM3_AVX2_expand_mat(mat, rho);
    PQCLEAN_DILITHIUM3_AVX2_polyvecl_ntt(&s1);
    PQCLEAN_DILITHIUM3_AVX2_polyveck_ntt(&s2);
    PQCLEAN_DILITHIUM3_AVX2_polyveck_ntt(&t0);

rej:
    /* Sample intermediate vector y */
    PQCLEAN_DILITHIUM3_AVX2_poly_uniform_gamma1m1_4x(&y.vec[0], &y.vec[1], &y.vec[2], &y.vec[3],
            rhoprime, nonce, nonce + 1, nonce + 2, nonce + 3);
    nonce += 4;

    /* Matrix-vector multiplication */
    yhat = y;
    PQCLEAN_DILITHIUM3_AVX2_polyvecl_ntt(&yhat);
    for (i = 0; i < K; ++i) {
        PQCLEAN_DILITHIUM3_AVX2_polyvecl_pointwise_acc_invmontgomery(&w.vec[i], &mat[i], &yhat);
        PQCLEAN_DILITHIUM3_AVX2_poly_reduce(&w.vec[i]);
        PQCLEAN_DILITHIUM3_AVX2_poly_invntt_montgomery(&w.vec[i]);
    }

    /* Decompose w and call the random oracle */
    PQCLEAN_DILITHIUM3_AVX2_polyveck_csubq(&w);
    PQCLEAN_DILITHIUM3_AVX2_polyveck_decompose(&w1, &w0, &w);
    PQCLEAN_DILITHIUM3_AVX2_challenge(&c, mu, &w1);
    chat = c;
    PQCLEAN_DILITHIUM3_AVX2_poly_ntt(&chat);

    /* Check that subtracting cs2 does not change high bits of w and low bits
     * do not reveal secret information */
    for (i = 0; i < K; ++i) {
        PQCLEAN_DILITHIUM3_AVX2_poly_pointwise_invmontgomery(&cs2.vec[i], &chat, &s2.vec[i]);
        PQCLEAN_DILITHIUM3_AVX2_poly_invntt_montgomery(&cs2.vec[i]);
    }
    PQCLEAN_DILITHIUM3_AVX2_polyveck_sub(&w0, &w0, &cs2);
    PQCLEAN_DILITHIUM3_AVX2_polyveck_freeze(&w0);
    if (PQCLEAN_DILITHIUM3_AVX2_polyveck_chknorm(&w0, GAMMA2 - BETA)) {
        goto rej;
    }

    /* Compute z, reject if it reveals secret */
    for (i = 0; i < L; ++i) {
        PQCLEAN_DILITHIUM3_AVX2_poly_pointwise_invmontgomery(&z.vec[i], &chat, &s1.vec[i]);
        PQCLEAN_DILITHIUM3_AVX2_poly_invntt_montgomery(&z.vec[i]);
    }
    PQCLEAN_DILITHIUM3_AVX2_polyvecl_add(&z, &z, &y);
    PQCLEAN_DILITHIUM3_AVX2_polyvecl_freeze(&z);
    if (PQCLEAN_DILITHIUM3_AVX2_polyvecl_chknorm(&z, GAMMA1 - BETA)) {
        goto rej;
    }

    /* Compute hints for w1 */
    for (i = 0; i < K; ++i) {
        PQCLEAN_DILITHIUM3_AVX2_poly_pointwise_invmontgomery(&ct0.vec[i], &chat, &t0.vec[i]);
        PQCLEAN_DILITHIUM3_AVX2_poly_invntt_montgomery(&ct0.vec[i]);
    }

    PQCLEAN_DILITHIUM3_AVX2_polyveck_csubq(&ct0);
    if (PQCLEAN_DILITHIUM3_AVX2_polyveck_chknorm(&ct0, GAMMA2)) {
        goto rej;
    }

    PQCLEAN_DILITHIUM3_AVX2_polyveck_add(&w0, &w0, &ct0);
    PQCLEAN_DILITHIUM3_AVX2_polyveck_csubq(&w0);
    n = PQCLEAN_DILITHIUM3_AVX2_polyveck_make_hint(&h, &w0, &w1);
    if (n > OMEGA) {
        goto rej;
    }

    /* Write signature */
    PQCLEAN_DILITHIUM3_AVX2_pack_sig(sig, &z, &h, &c);
    *siglen = PQCLEAN_DILITHIUM3_AVX2_CRYPTO_BYTES;
    return 0;
}

/*************************************************
* Name:        PQCLEAN_DILITHIUM3_AVX2_crypto_sign
*
* Description: Compute signed message.
*
* Arguments:   - uint8_t *sm: pointer to output signed message (allocated
*                             array with PQCLEAN_DILITHIUM3_AVX2_CRYPTO_BYTES + mlen bytes),
*                             can be equal to m
*              - unsigned long long *smlen: pointer to output length of signed
*                                           message
*              - const uint8_t *m: pointer to message to be signed
*              - unsigned long long mlen: length of message
*              - const uint8_t *sk: pointer to bit-packed secret key
*
* Returns 0 (success)
**************************************************/
int PQCLEAN_DILITHIUM3_AVX2_crypto_sign(
    uint8_t *sm, size_t *smlen,
    const uint8_t *m, size_t mlen,
    const uint8_t *sk) {
    int rc;
    memmove(sm + PQCLEAN_DILITHIUM3_AVX2_CRYPTO_BYTES, m, mlen);
    rc = PQCLEAN_DILITHIUM3_AVX2_crypto_sign_signature(sm, smlen, m, mlen, sk);
    *smlen += mlen;
    return rc;
}

/*************************************************
* Name:        PQCLEAN_DILITHIUM3_AVX2_crypto_sign_verify
*
* Description: Verify signed message.
*
* Arguments:   - uint8_t *sig:  signature
*              - size_t siglen: length of signature (PQCLEAN_DILITHIUM3_AVX2_CRYPTO_BYTES)
*              - uint8_t *m:    pointer to message
*              - size_t *mlen:  pointer to output length of message
*              - uint8_t *pk:   pointer to bit-packed public key
*
* Returns 0 if signed message could be verified correctly and -1 otherwise
**************************************************/
int PQCLEAN_DILITHIUM3_AVX2_crypto_sign_verify(
    const uint8_t *sig, size_t siglen,
    const uint8_t *m, size_t mlen,
    const uint8_t *pk) {
    size_t i;
    uint8_t rho[SEEDBYTES];
    uint8_t mu[CRHBYTES];
    poly c, chat, cp;
    polyvecl mat[K], z;
    polyveck t1, w1, h, tmp1, tmp2;

    if (siglen < PQCLEAN_DILITHIUM3_AVX2_CRYPTO_BYTES) {
        return -1;
    }

    PQCLEAN_DILITHIUM3_AVX2_unpack_pk(rho, &t1, pk);
    if (PQCLEAN_DILITHIUM3_AVX2_unpack_sig(&z, &h, &c, sig)) {
        return -1;
    }
    if (PQCLEAN_DILITHIUM3_AVX2_polyvecl_chknorm(&z, GAMMA1 - BETA)) {
        return -1;
    }

    /* Compute CRH(CRH(rho, t1), msg) */
    crh(mu, pk, PQCLEAN_DILITHIUM3_AVX2_CRYPTO_PUBLICKEYBYTES);

    shake256incctx state;
    shake256_inc_init(&state);
    shake256_inc_absorb(&state, mu, CRHBYTES);
    shake256_inc_absorb(&state, m, mlen);
    shake256_inc_finalize(&state);
    shake256_inc_squeeze(mu, CRHBYTES, &state);

    /* Matrix-vector multiplication; compute Az - c2^dt1 */
    PQCLEAN_DILITHIUM3_AVX2_expand_mat(mat, rho);
    PQCLEAN_DILITHIUM3_AVX2_polyvecl_ntt(&z);
    for (i = 0; i < K; ++i) {
        PQCLEAN_DILITHIUM3_AVX2_polyvecl_pointwise_acc_invmontgomery(&tmp1.vec[i], &mat[i], &z);
    }

    chat = c;
    PQCLEAN_DILITHIUM3_AVX2_poly_ntt(&chat);
    PQCLEAN_DILITHIUM3_AVX2_polyveck_shiftl(&t1);
    PQCLEAN_DILITHIUM3_AVX2_polyveck_ntt(&t1);
    for (i = 0; i < K; ++i) {
        PQCLEAN_DILITHIUM3_AVX2_poly_pointwise_invmontgomery(&tmp2.vec[i], &chat, &t1.vec[i]);
    }

    PQCLEAN_DILITHIUM3_AVX2_polyveck_sub(&tmp1, &tmp1, &tmp2);
    PQCLEAN_DILITHIUM3_AVX2_polyveck_reduce(&tmp1);
    PQCLEAN_DILITHIUM3_AVX2_polyveck_invntt_montgomery(&tmp1);

    /* Reconstruct w1 */
    PQCLEAN_DILITHIUM3_AVX2_polyveck_csubq(&tmp1);
    PQCLEAN_DILITHIUM3_AVX2_polyveck_use_hint(&w1, &tmp1, &h);

    /* Call random oracle and verify challenge */
    PQCLEAN_DILITHIUM3_AVX2_challenge(&cp, mu, &w1);
    for (i = 0; i < N; ++i) {
        if (c.coeffs[i] != cp.coeffs[i]) {
            return -1;
        }
    }

    return 0;
}

/*************************************************
* Name:        PQCLEAN_DILITHIUM3_AVX2_crypto_sign_open
*
* Description: Verify signed message.
*
* Arguments:   - unsigned char *m: pointer to output message (allocated
*                                  array with smlen bytes), can be equal to sm
*              - unsigned long long *mlen: pointer to output length of message
*              - const unsigned char *sm: pointer to signed message
*              - unsigned long long smlen: length of signed message
*              - const unsigned char *pk: pointer to bit-packed public key
*
* Returns 0 if signed message could be verified correctly and -1 otherwise
**************************************************/
int PQCLEAN_DILITHIUM3_AVX2_crypto_sign_open(
    uint8_t *m, size_t *mlen,
    const uint8_t *sm, size_t smlen,
    const uint8_t *pk) {
    size_t i;
    if (smlen < PQCLEAN_DILITHIUM3_AVX2_CRYPTO_BYTES) {
        goto badsig;
    }
    *mlen = smlen - PQCLEAN_DILITHIUM3_AVX2_CRYPTO_BYTES;

    if (PQCLEAN_DILITHIUM3_AVX2_crypto_sign_verify(sm, PQCLEAN_DILITHIUM3_AVX2_CRYPTO_BYTES,
            sm + PQCLEAN_DILITHIUM3_AVX2_CRYPTO_BYTES, *mlen, pk)) {
        goto badsig;
    } else {
        /* All good, copy msg, return 0 */
        for (i = 0; i < *mlen; ++i) {
            m[i] = sm[PQCLEAN_DILITHIUM3_AVX2_CRYPTO_BYTES + i];
        }
        return 0;
    }

    /* Signature verification failed */
badsig:
    *mlen = (size_t) -1;
    for (i = 0; i < smlen; ++i) {
        m[i] = 0;
    }

    return -1;
}
Add Dilithium's AVX2 implementations 2019-12-06 15:16:41 +00:00			`#include <stdint.h>`
			`#include <string.h>`

			`#include "fips202.h"`
			`#include "packing.h"`
			`#include "params.h"`
			`#include "poly.h"`
			`#include "polyvec.h"`
			`#include "randombytes.h"`
			`#include "sign.h"`
			`#include "symmetric.h"`

			`/*************************************************`
			`* Name: expand_mat`
			`*`
			`* Description: Implementation of ExpandA. Generates matrix A with uniformly`
			`* random coefficients a_{i,j} by performing rejection`
			`* sampling on the output stream of SHAKE128(rho\|i\|j).`
			`*`
			`* Arguments: - polyvecl mat[K]: output matrix`
			`* - const uint8_t rho[]: byte array containing seed rho`
			`**************************************************/`

			`void PQCLEAN_DILITHIUM3_AVX2_expand_mat(polyvecl mat[5], const uint8_t rho[SEEDBYTES]) {`
			`PQCLEAN_DILITHIUM3_AVX2_poly_uniform_4x(&mat[0].vec[0],`
			`&mat[0].vec[1],`
			`&mat[0].vec[2],`
			`&mat[0].vec[3],`
			`rho, 0, 1, 2, 3);`
			`PQCLEAN_DILITHIUM3_AVX2_poly_uniform_4x(&mat[1].vec[0],`
			`&mat[1].vec[1],`
			`&mat[1].vec[2],`
			`&mat[1].vec[3],`
			`rho, 256, 257, 258, 259);`
			`PQCLEAN_DILITHIUM3_AVX2_poly_uniform_4x(&mat[2].vec[0],`
			`&mat[2].vec[1],`
			`&mat[2].vec[2],`
			`&mat[2].vec[3],`
			`rho, 512, 513, 514, 515);`
			`PQCLEAN_DILITHIUM3_AVX2_poly_uniform_4x(&mat[3].vec[0],`
			`&mat[3].vec[1],`
			`&mat[3].vec[2],`
			`&mat[3].vec[3],`
			`rho, 768, 769, 770, 771);`
			`PQCLEAN_DILITHIUM3_AVX2_poly_uniform_4x(&mat[4].vec[0],`
			`&mat[4].vec[1],`
			`&mat[4].vec[2],`
			`&mat[4].vec[3],`
			`rho, 1024, 1025, 1026, 1027);`
			`}`


			`/*************************************************`
			`* Name: PQCLEAN_DILITHIUM3_AVX2_challenge`
			`*`
			`* Description: Implementation of H. Samples polynomial with 60 nonzero`
			`* coefficients in {-1,1} using the output stream of`
			`* SHAKE256(mu\|w1).`
			`*`
			`* Arguments: - poly *c: pointer to output polynomial`
			`* - const uint8_t mu[]: byte array containing mu`
			`* - const polyveck *w1: pointer to vector w1`
			`**************************************************/`
			`void PQCLEAN_DILITHIUM3_AVX2_challenge(poly *c,`
			`const uint8_t mu[CRHBYTES],`
			`const polyveck *w1) {`
			`unsigned int i, b, pos;`
			`uint64_t signs;`
			`uint8_t inbuf[CRHBYTES + K * POLW1_SIZE_PACKED];`
			`uint8_t outbuf[SHAKE256_RATE];`
			`shake256ctx state;`

			`for (i = 0; i < CRHBYTES; ++i) {`
			`inbuf[i] = mu[i];`
			`}`
			`for (i = 0; i < K; ++i) {`
			`PQCLEAN_DILITHIUM3_AVX2_polyw1_pack(inbuf + CRHBYTES + i * POLW1_SIZE_PACKED, &w1->vec[i]);`
			`}`

			`shake256_absorb(&state, inbuf, sizeof(inbuf));`
			`shake256_squeezeblocks(outbuf, 1, &state);`

			`signs = 0;`
			`for (i = 0; i < 8; ++i) {`
			`signs \|= (uint64_t) outbuf[i] << 8 * i;`
			`}`

			`pos = 8;`

			`for (i = 0; i < N; ++i) {`
			`c->coeffs[i] = 0;`
			`}`

			`for (i = 196; i < 256; ++i) {`
			`do {`
			`if (pos >= SHAKE256_RATE) {`
			`shake256_squeezeblocks(outbuf, 1, &state);`
			`pos = 0;`
			`}`

			`b = outbuf[pos++];`
			`} while (b > i);`

			`c->coeffs[i] = c->coeffs[b];`
			`c->coeffs[b] = 1;`
			`c->coeffs[b] ^= -(signs & 1) & (1 ^ (Q - 1));`
			`signs >>= 1;`
			`}`
			`}`

			`/*************************************************`
			`* Name: PQCLEAN_DILITHIUM3_AVX2_crypto_sign_keypair`
			`*`
			`* Description: Generates public and private key.`
			`*`
			`* Arguments: - uint8_t *pk: pointer to output public key (allocated`
			`* array of PQCLEAN_DILITHIUM3_AVX2_CRYPTO_PUBLICKEYBYTES bytes)`
			`* - uint8_t *sk: pointer to output private key (allocated`
			`* array of PQCLEAN_DILITHIUM3_AVX2_CRYPTO_SECRETKEYBYTES bytes)`
			`*`
			`* Returns 0 (success)`
			`**************************************************/`
			`int PQCLEAN_DILITHIUM3_AVX2_crypto_sign_keypair(uint8_t pk, uint8_t sk) {`
			`unsigned int i;`
			`uint8_t seedbuf[3 * SEEDBYTES];`
			`uint8_t tr[CRHBYTES];`
			`const uint8_t rho, rhoprime, *key;`
			`uint16_t nonce = 0;`
			`polyvecl mat[K];`
			`polyvecl s1, s1hat;`
			`polyveck s2, t, t1, t0;`

			`/* Expand 32 bytes of randomness into rho, rhoprime and key */`
			`randombytes(seedbuf, 3 * SEEDBYTES);`
			`rho = seedbuf;`
			`rhoprime = seedbuf + SEEDBYTES;`
			`key = seedbuf + 2 * SEEDBYTES;`

			`/* Expand matrix */`
			`PQCLEAN_DILITHIUM3_AVX2_expand_mat(mat, rho);`

			`/* Sample short vectors s1 and s2 */`
			`PQCLEAN_DILITHIUM3_AVX2_poly_uniform_eta_4x(&s1.vec[0], &s1.vec[1], &s1.vec[2], &s1.vec[3], rhoprime,`
			`nonce, nonce + 1, nonce + 2, nonce + 3);`
			`PQCLEAN_DILITHIUM3_AVX2_poly_uniform_eta_4x(&s2.vec[0], &s2.vec[1], &s2.vec[2], &s2.vec[3], rhoprime,`
			`nonce + 4, nonce + 5, nonce + 6, nonce + 7);`
			`PQCLEAN_DILITHIUM3_AVX2_poly_uniform_eta(&s2.vec[4], rhoprime, nonce + 8);`

			`/* Matrix-vector multiplication */`
			`s1hat = s1;`
			`PQCLEAN_DILITHIUM3_AVX2_polyvecl_ntt(&s1hat);`
			`for (i = 0; i < K; ++i) {`
			`PQCLEAN_DILITHIUM3_AVX2_polyvecl_pointwise_acc_invmontgomery(&t.vec[i], &mat[i], &s1hat);`
			`//PQCLEAN_DILITHIUM3_AVX2_poly_reduce(&t.vec[i]);`
			`PQCLEAN_DILITHIUM3_AVX2_poly_invntt_montgomery(&t.vec[i]);`
			`}`

			`/* Add error vector s2 */`
			`PQCLEAN_DILITHIUM3_AVX2_polyveck_add(&t, &t, &s2);`

			`/* Extract t1 and write public key */`
			`PQCLEAN_DILITHIUM3_AVX2_polyveck_freeze(&t);`
			`PQCLEAN_DILITHIUM3_AVX2_polyveck_power2round(&t1, &t0, &t);`
			`PQCLEAN_DILITHIUM3_AVX2_pack_pk(pk, rho, &t1);`

			`/* Compute CRH(rho, t1) and write secret key */`
			`crh(tr, pk, PQCLEAN_DILITHIUM3_AVX2_CRYPTO_PUBLICKEYBYTES);`
			`PQCLEAN_DILITHIUM3_AVX2_pack_sk(sk, rho, key, tr, &s1, &s2, &t0);`

			`return 0;`
			`}`

			`/*************************************************`
			`* Name: PQCLEAN_DILITHIUM3_AVX2_crypto_sign_signature`
			`*`
			`* Description: Compute signed message.`
			`*`
			`* Arguments: - uint8_t *sig: pointer to output signature (PQCLEAN_DILITHIUM3_AVX2_CRYPTO_BYTES`
			`* of len)`
			`* - size_t *siglen: pointer to output length of signed message`
			`* (should be PQCLEAN_DILITHIUM3_AVX2_CRYPTO_BYTES)`
			`* - uint8_t *m: pointer to message to be signed`
			`* - size_t mlen: length of message`
			`* - uint8_t *sk: pointer to bit-packed secret key`
			`*`
			`* Returns 0 (success)`
			`**************************************************/`
			`int PQCLEAN_DILITHIUM3_AVX2_crypto_sign_signature(`
			`uint8_t sig, size_t siglen,`
			`const uint8_t *m, size_t mlen,`
			`const uint8_t *sk) {`
			`size_t i;`
			`unsigned int n;`
			`uint8_t seedbuf[2 * SEEDBYTES + 3 * CRHBYTES];`
			`uint8_t rho, tr, key, mu, *rhoprime;`
			`uint16_t nonce = 0;`
			`poly c, chat;`
			`polyvecl mat[K], s1, y, yhat, z;`
			`polyveck t0, s2, w, w1, w0;`
			`polyveck h, cs2, ct0;`

			`rho = seedbuf;`
			`tr = rho + SEEDBYTES;`
			`key = tr + CRHBYTES;`
			`mu = key + SEEDBYTES;`
			`rhoprime = mu + CRHBYTES;`
			`PQCLEAN_DILITHIUM3_AVX2_unpack_sk(rho, key, tr, &s1, &s2, &t0, sk);`


			`// use incremental hash API instead of copying around buffers`
			`/* Compute CRH(tr, m) */`
			`shake256incctx state;`
			`shake256_inc_init(&state);`
			`shake256_inc_absorb(&state, tr, CRHBYTES);`
			`shake256_inc_absorb(&state, m, mlen);`
			`shake256_inc_finalize(&state);`
			`shake256_inc_squeeze(mu, CRHBYTES, &state);`

			`crh(rhoprime, key, SEEDBYTES + CRHBYTES);`

			`/* Expand matrix and transform vectors */`
			`PQCLEAN_DILITHIUM3_AVX2_expand_mat(mat, rho);`
			`PQCLEAN_DILITHIUM3_AVX2_polyvecl_ntt(&s1);`
			`PQCLEAN_DILITHIUM3_AVX2_polyveck_ntt(&s2);`
			`PQCLEAN_DILITHIUM3_AVX2_polyveck_ntt(&t0);`

			`rej:`
			`/* Sample intermediate vector y */`
			`PQCLEAN_DILITHIUM3_AVX2_poly_uniform_gamma1m1_4x(&y.vec[0], &y.vec[1], &y.vec[2], &y.vec[3],`
			`rhoprime, nonce, nonce + 1, nonce + 2, nonce + 3);`
			`nonce += 4;`

			`/* Matrix-vector multiplication */`
			`yhat = y;`
			`PQCLEAN_DILITHIUM3_AVX2_polyvecl_ntt(&yhat);`
			`for (i = 0; i < K; ++i) {`
			`PQCLEAN_DILITHIUM3_AVX2_polyvecl_pointwise_acc_invmontgomery(&w.vec[i], &mat[i], &yhat);`
			`PQCLEAN_DILITHIUM3_AVX2_poly_reduce(&w.vec[i]);`
			`PQCLEAN_DILITHIUM3_AVX2_poly_invntt_montgomery(&w.vec[i]);`
			`}`

			`/* Decompose w and call the random oracle */`
			`PQCLEAN_DILITHIUM3_AVX2_polyveck_csubq(&w);`
			`PQCLEAN_DILITHIUM3_AVX2_polyveck_decompose(&w1, &w0, &w);`
			`PQCLEAN_DILITHIUM3_AVX2_challenge(&c, mu, &w1);`
			`chat = c;`
			`PQCLEAN_DILITHIUM3_AVX2_poly_ntt(&chat);`

			`/* Check that subtracting cs2 does not change high bits of w and low bits`
			`* do not reveal secret information */`
			`for (i = 0; i < K; ++i) {`
			`PQCLEAN_DILITHIUM3_AVX2_poly_pointwise_invmontgomery(&cs2.vec[i], &chat, &s2.vec[i]);`
			`PQCLEAN_DILITHIUM3_AVX2_poly_invntt_montgomery(&cs2.vec[i]);`
			`}`
			`PQCLEAN_DILITHIUM3_AVX2_polyveck_sub(&w0, &w0, &cs2);`
			`PQCLEAN_DILITHIUM3_AVX2_polyveck_freeze(&w0);`
			`if (PQCLEAN_DILITHIUM3_AVX2_polyveck_chknorm(&w0, GAMMA2 - BETA)) {`
			`goto rej;`
			`}`

			`/* Compute z, reject if it reveals secret */`
			`for (i = 0; i < L; ++i) {`
			`PQCLEAN_DILITHIUM3_AVX2_poly_pointwise_invmontgomery(&z.vec[i], &chat, &s1.vec[i]);`
			`PQCLEAN_DILITHIUM3_AVX2_poly_invntt_montgomery(&z.vec[i]);`
			`}`
			`PQCLEAN_DILITHIUM3_AVX2_polyvecl_add(&z, &z, &y);`
			`PQCLEAN_DILITHIUM3_AVX2_polyvecl_freeze(&z);`
			`if (PQCLEAN_DILITHIUM3_AVX2_polyvecl_chknorm(&z, GAMMA1 - BETA)) {`
			`goto rej;`
			`}`

			`/* Compute hints for w1 */`
			`for (i = 0; i < K; ++i) {`
			`PQCLEAN_DILITHIUM3_AVX2_poly_pointwise_invmontgomery(&ct0.vec[i], &chat, &t0.vec[i]);`
			`PQCLEAN_DILITHIUM3_AVX2_poly_invntt_montgomery(&ct0.vec[i]);`
			`}`

			`PQCLEAN_DILITHIUM3_AVX2_polyveck_csubq(&ct0);`
			`if (PQCLEAN_DILITHIUM3_AVX2_polyveck_chknorm(&ct0, GAMMA2)) {`
			`goto rej;`
			`}`

			`PQCLEAN_DILITHIUM3_AVX2_polyveck_add(&w0, &w0, &ct0);`
			`PQCLEAN_DILITHIUM3_AVX2_polyveck_csubq(&w0);`
			`n = PQCLEAN_DILITHIUM3_AVX2_polyveck_make_hint(&h, &w0, &w1);`
			`if (n > OMEGA) {`
			`goto rej;`
			`}`

			`/* Write signature */`
			`PQCLEAN_DILITHIUM3_AVX2_pack_sig(sig, &z, &h, &c);`
			`*siglen = PQCLEAN_DILITHIUM3_AVX2_CRYPTO_BYTES;`
			`return 0;`
			`}`

			`/*************************************************`
			`* Name: PQCLEAN_DILITHIUM3_AVX2_crypto_sign`
			`*`
			`* Description: Compute signed message.`
			`*`
			`* Arguments: - uint8_t *sm: pointer to output signed message (allocated`
			`* array with PQCLEAN_DILITHIUM3_AVX2_CRYPTO_BYTES + mlen bytes),`
			`* can be equal to m`
			`* - unsigned long long *smlen: pointer to output length of signed`
			`* message`
			`* - const uint8_t *m: pointer to message to be signed`
			`* - unsigned long long mlen: length of message`
			`* - const uint8_t *sk: pointer to bit-packed secret key`
			`*`
			`* Returns 0 (success)`
			`**************************************************/`
			`int PQCLEAN_DILITHIUM3_AVX2_crypto_sign(`
			`uint8_t sm, size_t smlen,`
			`const uint8_t *m, size_t mlen,`
			`const uint8_t *sk) {`
			`int rc;`
			`memmove(sm + PQCLEAN_DILITHIUM3_AVX2_CRYPTO_BYTES, m, mlen);`
			`rc = PQCLEAN_DILITHIUM3_AVX2_crypto_sign_signature(sm, smlen, m, mlen, sk);`
			`*smlen += mlen;`
			`return rc;`
			`}`

			`/*************************************************`
			`* Name: PQCLEAN_DILITHIUM3_AVX2_crypto_sign_verify`
			`*`
			`* Description: Verify signed message.`
			`*`
			`* Arguments: - uint8_t *sig: signature`
			`* - size_t siglen: length of signature (PQCLEAN_DILITHIUM3_AVX2_CRYPTO_BYTES)`
			`* - uint8_t *m: pointer to message`
			`* - size_t *mlen: pointer to output length of message`
			`* - uint8_t *pk: pointer to bit-packed public key`
			`*`
			`* Returns 0 if signed message could be verified correctly and -1 otherwise`
			`**************************************************/`
			`int PQCLEAN_DILITHIUM3_AVX2_crypto_sign_verify(`
			`const uint8_t *sig, size_t siglen,`
			`const uint8_t *m, size_t mlen,`
			`const uint8_t *pk) {`
			`size_t i;`
			`uint8_t rho[SEEDBYTES];`
			`uint8_t mu[CRHBYTES];`
			`poly c, chat, cp;`
			`polyvecl mat[K], z;`
			`polyveck t1, w1, h, tmp1, tmp2;`

			`if (siglen < PQCLEAN_DILITHIUM3_AVX2_CRYPTO_BYTES) {`
			`return -1;`
			`}`

			`PQCLEAN_DILITHIUM3_AVX2_unpack_pk(rho, &t1, pk);`
			`if (PQCLEAN_DILITHIUM3_AVX2_unpack_sig(&z, &h, &c, sig)) {`
			`return -1;`
			`}`
			`if (PQCLEAN_DILITHIUM3_AVX2_polyvecl_chknorm(&z, GAMMA1 - BETA)) {`
			`return -1;`
			`}`

			`/* Compute CRH(CRH(rho, t1), msg) */`
			`crh(mu, pk, PQCLEAN_DILITHIUM3_AVX2_CRYPTO_PUBLICKEYBYTES);`

			`shake256incctx state;`
			`shake256_inc_init(&state);`
			`shake256_inc_absorb(&state, mu, CRHBYTES);`
			`shake256_inc_absorb(&state, m, mlen);`
			`shake256_inc_finalize(&state);`
			`shake256_inc_squeeze(mu, CRHBYTES, &state);`

			`/* Matrix-vector multiplication; compute Az - c2^dt1 */`
			`PQCLEAN_DILITHIUM3_AVX2_expand_mat(mat, rho);`
			`PQCLEAN_DILITHIUM3_AVX2_polyvecl_ntt(&z);`
			`for (i = 0; i < K; ++i) {`
			`PQCLEAN_DILITHIUM3_AVX2_polyvecl_pointwise_acc_invmontgomery(&tmp1.vec[i], &mat[i], &z);`
			`}`

			`chat = c;`
			`PQCLEAN_DILITHIUM3_AVX2_poly_ntt(&chat);`
			`PQCLEAN_DILITHIUM3_AVX2_polyveck_shiftl(&t1);`
			`PQCLEAN_DILITHIUM3_AVX2_polyveck_ntt(&t1);`
			`for (i = 0; i < K; ++i) {`
			`PQCLEAN_DILITHIUM3_AVX2_poly_pointwise_invmontgomery(&tmp2.vec[i], &chat, &t1.vec[i]);`
			`}`

			`PQCLEAN_DILITHIUM3_AVX2_polyveck_sub(&tmp1, &tmp1, &tmp2);`
			`PQCLEAN_DILITHIUM3_AVX2_polyveck_reduce(&tmp1);`
			`PQCLEAN_DILITHIUM3_AVX2_polyveck_invntt_montgomery(&tmp1);`

			`/* Reconstruct w1 */`
			`PQCLEAN_DILITHIUM3_AVX2_polyveck_csubq(&tmp1);`
			`PQCLEAN_DILITHIUM3_AVX2_polyveck_use_hint(&w1, &tmp1, &h);`

			`/* Call random oracle and verify challenge */`
			`PQCLEAN_DILITHIUM3_AVX2_challenge(&cp, mu, &w1);`
			`for (i = 0; i < N; ++i) {`
			`if (c.coeffs[i] != cp.coeffs[i]) {`
			`return -1;`
			`}`
			`}`

			`return 0;`
			`}`

			`/*************************************************`
			`* Name: PQCLEAN_DILITHIUM3_AVX2_crypto_sign_open`
			`*`
			`* Description: Verify signed message.`
			`*`
			`* Arguments: - unsigned char *m: pointer to output message (allocated`
			`* array with smlen bytes), can be equal to sm`
			`* - unsigned long long *mlen: pointer to output length of message`
			`* - const unsigned char *sm: pointer to signed message`
			`* - unsigned long long smlen: length of signed message`
			`* - const unsigned char *pk: pointer to bit-packed public key`
			`*`
			`* Returns 0 if signed message could be verified correctly and -1 otherwise`
			`**************************************************/`
			`int PQCLEAN_DILITHIUM3_AVX2_crypto_sign_open(`
			`uint8_t m, size_t mlen,`
			`const uint8_t *sm, size_t smlen,`
			`const uint8_t *pk) {`
			`size_t i;`
			`if (smlen < PQCLEAN_DILITHIUM3_AVX2_CRYPTO_BYTES) {`
			`goto badsig;`
			`}`
			`*mlen = smlen - PQCLEAN_DILITHIUM3_AVX2_CRYPTO_BYTES;`

			`if (PQCLEAN_DILITHIUM3_AVX2_crypto_sign_verify(sm, PQCLEAN_DILITHIUM3_AVX2_CRYPTO_BYTES,`
			`sm + PQCLEAN_DILITHIUM3_AVX2_CRYPTO_BYTES, *mlen, pk)) {`
			`goto badsig;`
			`} else {`
			`/* All good, copy msg, return 0 */`
			`for (i = 0; i < *mlen; ++i) {`
			`m[i] = sm[PQCLEAN_DILITHIUM3_AVX2_CRYPTO_BYTES + i];`
			`}`
			`return 0;`
			`}`

			`/* Signature verification failed */`
			`badsig:`
			`*mlen = (size_t) -1;`
			`for (i = 0; i < smlen; ++i) {`
			`m[i] = 0;`
			`}`

			`return -1;`
			`}`