/*

 * Copyright (C) 2010-2012 Free Software Foundation, Inc.

 * Copyright (C) 2013-2017 Nikos Mavrogiannopoulos

 * Copyright (C) 2016-2017 Red Hat, Inc.

 *

 * Author: Nikos Mavrogiannopoulos

 *

 * This file is part of GNUTLS.

 *

 * The GNUTLS library is free software; you can redistribute it and/or

 * modify it under the terms of the GNU Lesser General Public License

 * as published by the Free Software Foundation; either version 2.1 of

 * the License, or (at your option) any later version.

 *

 * This library is distributed in the hope that it will be useful, but

 * WITHOUT ANY WARRANTY; without even the implied warranty of

 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU

 * Lesser General Public License for more details.

 *

 * You should have received a copy of the GNU Lesser General Public License

 * along with this program.  If not, see <https://www.gnu.org/licenses/>

 *

 */

/* This file contains the functions needed for RSA/DSA public key

 * encryption and signatures.

 */

#include "gnutls_int.h"

#include "mpi.h"

#include "pk.h"

#include "errors.h"

#include "datum.h"

#include "global.h"

#include "tls-sig.h"

#include "num.h"

#include "x509/x509_int.h"

#include "x509/common.h"

#include "random.h"

#include "pk.h"

#include <nettle/dsa.h>

#include "dsa-fips.h"

#include "rsa-fips.h"

#include <nettle/rsa.h>

#include <gnutls/crypto.h>

#include <nettle/bignum.h>

#include <nettle/ecc.h>

#include <nettle/ecdsa.h>

#include <nettle/ecc-curve.h>

#include <nettle/curve25519.h>

#include <nettle/curve448.h>

#include <nettle/eddsa.h>

#include <nettle/version.h>

#if ENABLE_GOST

#if NEED_INT_ECC

#include "ecc/gostdsa.h"

#include "ecc-gost-curve.h"

#else

#include <nettle/gostdsa.h>

#define gost_point_mul_g ecc_point_mul_g

#define gost_point_set ecc_point_set

#endif

#include "gost/gostdsa2.h"

#endif

#include "int/ecdsa-compute-k.h"

#include "int/dsa-compute-k.h"

#include "gnettle.h"

#include "fips.h"

#include "dh.h"

#include "audit.h"

#ifdef HAVE_LEANCRYPTO

#include <leancrypto.h>

#endif

#include "attribute.h"

#define MAX_PRIME_CURVE_COORD_SIZE 66

static inline const struct ecc_curve *get_supported_nist_curve(int curve);

static inline const struct ecc_curve *get_supported_gost_curve(int curve);

static inline const char *get_supported_nist_curve_order(int curve);

static inline const char *get_supported_nist_curve_modulus(int curve);

/* When these callbacks are used for a nettle operation, the

 * caller must check the macro HAVE_LIB_ERROR() after the operation

 * is complete. If the macro is true, the operation is to be considered

 * failed (meaning the random generation failed).

 */

static void rnd_key_func(void *_ctx, size_t length, uint8_t *data)

{

  if (gnutls_rnd(GNUTLS_RND_KEY, data, length) < 0) {

    _gnutls_switch_lib_state(LIB_STATE_ERROR);

  }

}

static void rnd_tmpkey_func(void *_ctx, size_t length, uint8_t *data)

{

  if (gnutls_rnd(GNUTLS_RND_RANDOM, data, length) < 0) {

    _gnutls_switch_lib_state(LIB_STATE_ERROR);

  }

}

static void rnd_nonce_func(void *_ctx, size_t length, uint8_t *data)

{

  if (gnutls_rnd(GNUTLS_RND_NONCE, data, length) < 0) {

    _gnutls_switch_lib_state(LIB_STATE_ERROR);

  }

}

static void rnd_datum_func(void *ctx, size_t length, uint8_t *data)

{

  gnutls_datum_t *d = ctx;

  if (length > d->size) {

    memset(data, 0, length - d->size);

    memcpy(data + (length - d->size), d->data, d->size);

  } else {

    memcpy(data, d->data, length);

  }

}

static void rnd_nonce_func_fallback(void *_ctx, size_t length, uint8_t *data)

{

  if (unlikely(_gnutls_get_lib_state() != LIB_STATE_SELFTEST)) {

    _gnutls_switch_lib_state(LIB_STATE_ERROR);

  }

  memset(data, 0xAA, length);

}

static void ecc_scalar_zclear(struct ecc_scalar *s)

{

  zeroize_key(s->p, ecc_size(s->ecc) * sizeof(mp_limb_t));

  ecc_scalar_clear(s);

}

static void ecc_point_zclear(struct ecc_point *p)

{

  zeroize_key(p->p, ecc_size_a(p->ecc) * sizeof(mp_limb_t));

  ecc_point_clear(p);

}

static void _dsa_params_get(const gnutls_pk_params_st *pk_params,

          struct dsa_params *pub)

{

  memcpy(pub->p, pk_params->params[DSA_P], SIZEOF_MPZT);

  if (pk_params->params[DSA_Q])

    memcpy(&pub->q, pk_params->params[DSA_Q], SIZEOF_MPZT);

  memcpy(pub->g, pk_params->params[DSA_G], SIZEOF_MPZT);

}

static void _rsa_params_to_privkey(const gnutls_pk_params_st *pk_params,

           struct rsa_private_key *priv)

{

  memcpy(priv->d, pk_params->params[RSA_PRIV], SIZEOF_MPZT);

  memcpy(priv->p, pk_params->params[RSA_PRIME1], SIZEOF_MPZT);

  memcpy(priv->q, pk_params->params[RSA_PRIME2], SIZEOF_MPZT);

  memcpy(priv->c, pk_params->params[RSA_COEF], SIZEOF_MPZT);

  memcpy(priv->a, pk_params->params[RSA_E1], SIZEOF_MPZT);

  memcpy(priv->b, pk_params->params[RSA_E2], SIZEOF_MPZT);

  /* we do not rsa_private_key_prepare() because it involves a multiplication.

   * we call it once when we import the parameters */

  priv->size = nettle_mpz_sizeinbase_256_u(

    TOMPZ(pk_params->params[RSA_MODULUS]));

}

/* returns a negative value on invalid pubkey */

static int _rsa_params_to_pubkey(const gnutls_pk_params_st *pk_params,

         struct rsa_public_key *pub)

{

  memcpy(pub->n, pk_params->params[RSA_MODULUS], SIZEOF_MPZT);

  memcpy(pub->e, pk_params->params[RSA_PUB], SIZEOF_MPZT);

  if (rsa_public_key_prepare(pub) == 0)

    return gnutls_assert_val(GNUTLS_E_PK_INVALID_PUBKEY);

  return 0;

}

static int _ecc_params_to_privkey(const gnutls_pk_params_st *pk_params,

          struct ecc_scalar *priv,

          const struct ecc_curve *curve)

{

  ecc_scalar_init(priv, curve);

  if (ecc_scalar_set(priv, pk_params->params[ECC_K]) == 0) {

    ecc_scalar_clear(priv);

    return gnutls_assert_val(GNUTLS_E_PK_INVALID_PRIVKEY);

  }

  return 0;

}

static int _ecc_params_to_pubkey(const gnutls_pk_params_st *pk_params,

         struct ecc_point *pub,

         const struct ecc_curve *curve)

{

  ecc_point_init(pub, curve);

  if (ecc_point_set(pub, pk_params->params[ECC_X],

        pk_params->params[ECC_Y]) == 0) {

    ecc_point_clear(pub);

    return gnutls_assert_val(GNUTLS_E_PK_INVALID_PUBKEY);

  }

  return 0;

}

#if ENABLE_GOST

static int _gost_params_to_privkey(const gnutls_pk_params_st *pk_params,

           struct ecc_scalar *priv,

           const struct ecc_curve *curve)

{

  ecc_scalar_init(priv, curve);

  if (ecc_scalar_set(priv, pk_params->params[GOST_K]) == 0) {

    ecc_scalar_clear(priv);

    return gnutls_assert_val(GNUTLS_E_PK_INVALID_PRIVKEY);

  }

  return 0;

}

static int _gost_params_to_pubkey(const gnutls_pk_params_st *pk_params,

          struct ecc_point *pub,

          const struct ecc_curve *curve)

{

  ecc_point_init(pub, curve);

  if (gost_point_set(pub, pk_params->params[GOST_X],

         pk_params->params[GOST_Y]) == 0) {

    ecc_point_clear(pub);

    return gnutls_assert_val(GNUTLS_E_INVALID_REQUEST);

  }

  return 0;

}

#endif

static int ecc_shared_secret(struct ecc_scalar *private_key,

           struct ecc_point *public_key, void *out,

           unsigned size)

{

  struct ecc_point r;

  mpz_t x, y;

  int ret = 0;

  mpz_init(x);

  mpz_init(y);

  ecc_point_init(&r, public_key->ecc);

  ecc_point_mul(&r, private_key, public_key);

  ecc_point_get(&r, x, y);

  /* Check if the point is not an identity element.  Note that this cannot

   * happen in nettle implementation, because it cannot represent an

   * infinity point. */

  if (mpz_cmp_ui(x, 0) == 0 && mpz_cmp_ui(y, 0) == 0) {

    ret = gnutls_assert_val(GNUTLS_E_ILLEGAL_PARAMETER);

    goto cleanup;

  }

  nettle_mpz_get_str_256(size, out, x);

cleanup:

  mpz_clear(x);

  mpz_clear(y);

  ecc_point_clear(&r);

  return ret;

}

#define MAX_DH_BITS DEFAULT_MAX_VERIFY_BITS

/* This is used when we have no idea on the structure

 * of p-1 used by the peer. It is still a conservative

 * choice, but small than what we've been using before.

 */

#define DH_EXPONENT_SIZE(p_size) (2 * _gnutls_pk_bits_to_subgroup_bits(p_size))

static inline int edwards_curve_mul(gnutls_pk_algorithm_t algo, uint8_t *q,

            const uint8_t *n, const uint8_t *p)

{

  switch (algo) {

  case GNUTLS_PK_ECDH_X25519:

    curve25519_mul(q, n, p);

    return 0;

  case GNUTLS_PK_ECDH_X448:

    curve448_mul(q, n, p);

    return 0;

  default:

    return gnutls_assert_val(GNUTLS_E_ECC_UNSUPPORTED_CURVE);

  }

}

/* This is used for DH or ECDH key derivation. In DH for example

 * it is given the peers Y and our x, and calculates Y^x

 */

static int _wrap_nettle_pk_derive(gnutls_pk_algorithm_t algo,

          gnutls_datum_t *out,

          const gnutls_pk_params_st *priv,

          const gnutls_pk_params_st *pub,

          const gnutls_datum_t *nonce,

          unsigned int flags)

{

  int ret;

  bool not_approved = false;

  _gnutls_audit_new_context_with_data("name", CRAU_STRING, "pk::derive",

              "pk::algorithm", CRAU_STRING,

              gnutls_pk_get_name(algo), NULL);

  switch (algo) {

  case GNUTLS_PK_DH: {

    bigint_t f, x, q, prime;

    bigint_t k = NULL, primesub1 = NULL, r = NULL;

    unsigned int bits;

    if (nonce != NULL) {

      ret = gnutls_assert_val(GNUTLS_E_INVALID_REQUEST);

      goto cleanup;

    }

    f = pub->params[DH_Y];

    x = priv->params[DH_X];

    q = priv->params[DH_Q];

    prime = priv->params[DH_P];

    ret = _gnutls_mpi_init_multi(&k, &primesub1, &r, NULL);

    if (ret < 0) {

      gnutls_assert();

      goto cleanup;

    }

    ret = _gnutls_mpi_sub_ui(primesub1, prime, 1);

    if (ret < 0) {

      gnutls_assert();

      goto dh_cleanup;

    }

    /* check if f==0,1, or f >= p-1 */

    if ((_gnutls_mpi_cmp_ui(f, 1) == 0) ||

        (_gnutls_mpi_cmp_ui(f, 0) == 0) ||

        (_gnutls_mpi_cmp(f, primesub1) >= 0)) {

      gnutls_assert();

      ret = GNUTLS_E_RECEIVED_ILLEGAL_PARAMETER;

      goto dh_cleanup;

    }

    /* if we have Q check that y ^ q mod p == 1 */

    if (q != NULL) {

      ret = _gnutls_mpi_powm(r, f, q, prime);

      if (ret < 0) {

        gnutls_assert();

        goto dh_cleanup;

      }

      ret = _gnutls_mpi_cmp_ui(r, 1);

      if (ret != 0) {

        gnutls_assert();

        ret = GNUTLS_E_RECEIVED_ILLEGAL_PARAMETER;

        goto dh_cleanup;

      }

    } else if ((flags & PK_DERIVE_TLS13) &&

         _gnutls_fips_mode_enabled()) {

      /* Mandatory in FIPS mode for TLS 1.3 */

      ret = gnutls_assert_val(

        GNUTLS_E_RECEIVED_ILLEGAL_PARAMETER);

      goto dh_cleanup;

    }

    /* prevent denial of service */

    bits = _gnutls_mpi_get_nbits(prime);

    if (bits == 0 || bits > MAX_DH_BITS) {

      gnutls_assert();

      ret = GNUTLS_E_RECEIVED_ILLEGAL_PARAMETER;

      goto dh_cleanup;

    }

    _gnutls_audit_data("pk::bits", CRAU_WORD, bits, NULL);

    if (bits < 2048) {

      not_approved = true;

    }

    ret = _gnutls_mpi_powm(k, f, x, prime);

    if (ret < 0) {

      gnutls_assert();

      goto dh_cleanup;

    }

    /* check if k==0,1, or k = p-1 */

    if ((_gnutls_mpi_cmp_ui(k, 1) == 0) ||

        (_gnutls_mpi_cmp_ui(k, 0) == 0) ||

        (_gnutls_mpi_cmp(k, primesub1) == 0)) {

      ret = gnutls_assert_val(

        GNUTLS_E_RECEIVED_ILLEGAL_PARAMETER);

      goto dh_cleanup;

    }

    if (flags & PK_DERIVE_TLS13) {

      ret = _gnutls_mpi_dprint_size(k, out, (bits + 7) / 8);

    } else {

      ret = _gnutls_mpi_dprint(k, out);

    }

    if (ret < 0) {

      gnutls_assert();

      goto dh_cleanup;

    }

    ret = 0;

  dh_cleanup:

    _gnutls_mpi_release(&r);

    _gnutls_mpi_release(&primesub1);

    zrelease_mpi_key(&k);

    if (ret < 0)

      goto cleanup;

    break;

  }

  case GNUTLS_PK_EC: {

    struct ecc_scalar ecc_priv;

    struct ecc_point ecc_pub;

    const struct ecc_curve *curve;

    struct ecc_scalar n;

    struct ecc_scalar m;

    struct ecc_point r;

    mpz_t x, y, xx, yy, nn, mm;

    out->data = NULL;

    if (nonce != NULL) {

      ret = gnutls_assert_val(GNUTLS_E_INVALID_REQUEST);

      goto cleanup;

    }

    curve = get_supported_nist_curve(priv->curve);

    if (curve == NULL) {

      ret = gnutls_assert_val(GNUTLS_E_ECC_UNSUPPORTED_CURVE);

      goto cleanup;

    }

    _gnutls_audit_data("pk::curve", CRAU_STRING,

           gnutls_ecc_curve_get_name(priv->curve),

           NULL);

    /* P-192 is not supported in FIPS 140-3 */

    if (priv->curve == GNUTLS_ECC_CURVE_SECP192R1) {

      not_approved = true;

    }

    mpz_init(x);

    mpz_init(y);

    mpz_init(xx);

    mpz_init(yy);

    mpz_init(nn);

    mpz_init(mm);

    ecc_scalar_init(&n, curve);

    ecc_scalar_init(&m, curve);

    ecc_point_init(&r, curve);

    ret = _ecc_params_to_pubkey(pub, &ecc_pub, curve);

    if (ret < 0) {

      gnutls_assert();

      goto ecc_fail_cleanup;

    }

    ret = _ecc_params_to_privkey(priv, &ecc_priv, curve);

    if (ret < 0) {

      ecc_point_clear(&ecc_pub);

      gnutls_assert();

      goto ecc_fail_cleanup;

    }

    out->size = gnutls_ecc_curve_get_size(priv->curve);

    /*ecc_size(curve)*sizeof(mp_limb_t); */

    out->data = gnutls_malloc(out->size);

    if (out->data == NULL) {

      ret = gnutls_assert_val(GNUTLS_E_MEMORY_ERROR);

      goto ecc_cleanup;

    }

    /* Perform ECC Full Public-Key Validation Routine

       * according to SP800-56A (revision 3), 5.6.2.3.3.

       */

    /* Step 1: verify that Q is not an identity

       * element (an infinity point). Note that this

       * cannot happen in the nettle implementation,

       * because it cannot represent an infinity point

       * on curves. */

    ret = ecc_shared_secret(&ecc_priv, &ecc_pub, out->data,

          out->size);

    if (ret < 0) {

      gnutls_free(out->data);

      goto ecc_cleanup;

    }

#ifdef ENABLE_FIPS140

    if (_gnutls_fips_mode_enabled()) {

      const char *order, *modulus;

      ecc_point_mul(&r, &ecc_priv, &ecc_pub);

      ecc_point_get(&r, x, y);

      /* Step 2: verify that both coordinates of Q are

         * in the range [0, p - 1].

         *

         * Step 3: verify that Q lie on the curve

         *

         * Both checks are performed in nettle.  */

      if (!ecc_point_set(&r, x, y)) {

        ret = gnutls_assert_val(

          GNUTLS_E_ILLEGAL_PARAMETER);

        goto ecc_cleanup;

      }

      /* Step 4: verify that n * Q, where n is the

         * curve order, result in an identity element

         *

         * Since nettle internally cannot represent an

         * identity element on curves, we validate this

         * instead:

         *

         *   (n - 1) * Q = -Q

         *

         * That effectively means: n * Q = -Q + Q = O

         */

      order = get_supported_nist_curve_order(priv->curve);

      if (unlikely(order == NULL)) {

        ret = gnutls_assert_val(

          GNUTLS_E_INTERNAL_ERROR);

        goto ecc_cleanup;

      }

      ret = mpz_set_str(nn, order, 16);

      if (unlikely(ret < 0)) {

        ret = gnutls_assert_val(

          GNUTLS_E_MPI_SCAN_FAILED);

        goto ecc_cleanup;

      }

      modulus = get_supported_nist_curve_modulus(priv->curve);

      if (unlikely(modulus == NULL)) {

        ret = gnutls_assert_val(

          GNUTLS_E_INTERNAL_ERROR);

        goto ecc_cleanup;

      }

      ret = mpz_set_str(mm, modulus, 16);

      if (unlikely(ret < 0)) {

        ret = gnutls_assert_val(

          GNUTLS_E_MPI_SCAN_FAILED);

        goto ecc_cleanup;

      }

      /* (n - 1) * Q = -Q */

      mpz_sub_ui(nn, nn, 1);

      ecc_scalar_set(&n, nn);

      ecc_point_mul(&r, &n, &r);

      ecc_point_get(&r, xx, yy);

      mpz_sub(mm, mm, y);

      if (mpz_cmp(xx, x) != 0 || mpz_cmp(yy, mm) != 0) {

        ret = gnutls_assert_val(

          GNUTLS_E_ILLEGAL_PARAMETER);

        goto ecc_cleanup;

      }

    } else {

      not_approved = true;

    }

#endif

  ecc_cleanup:

    ecc_point_clear(&ecc_pub);

    ecc_scalar_zclear(&ecc_priv);

  ecc_fail_cleanup:

    mpz_clear(x);

    mpz_clear(y);

    mpz_clear(xx);

    mpz_clear(yy);

    mpz_clear(nn);

    mpz_clear(mm);

    ecc_point_clear(&r);

    ecc_scalar_clear(&n);

    ecc_scalar_clear(&m);

    if (ret < 0)

      goto cleanup;

    break;

  }

  case GNUTLS_PK_ECDH_X25519:

  case GNUTLS_PK_ECDH_X448: {

    unsigned size = gnutls_ecc_curve_get_size(priv->curve);

    /* Edwards curves are not approved */

    not_approved = true;

    if (nonce != NULL) {

      ret = gnutls_assert_val(GNUTLS_E_INVALID_REQUEST);

      goto cleanup;

    }

    /* The point is in pub, while the private part (scalar) in priv. */

    if (size == 0 || priv->raw_priv.size != size) {

      ret = gnutls_assert_val(GNUTLS_E_INVALID_REQUEST);

      goto cleanup;

    }

    out->data = gnutls_malloc(size);

    if (out->data == NULL) {

      ret = gnutls_assert_val(GNUTLS_E_MEMORY_ERROR);

      goto cleanup;

    }

    out->size = size;

    ret = edwards_curve_mul(algo, out->data, priv->raw_priv.data,

          pub->raw_pub.data);

    if (ret < 0)

      goto cleanup;

    if (_gnutls_mem_is_zero(out->data, out->size)) {

      gnutls_free(out->data);

      gnutls_assert();

      ret = GNUTLS_E_RECEIVED_ILLEGAL_PARAMETER;

      goto cleanup;

    }

    break;

  }

#if ENABLE_GOST

  case GNUTLS_PK_GOST_01:

  case GNUTLS_PK_GOST_12_256:

  case GNUTLS_PK_GOST_12_512: {

    struct ecc_scalar ecc_priv;

    struct ecc_point ecc_pub;

    const struct ecc_curve *curve;

    /* GOST curves are not approved */

    not_approved = true;

    out->data = NULL;

    curve = get_supported_gost_curve(priv->curve);

    if (curve == NULL) {

      gnutls_assert();

      ret = GNUTLS_E_ECC_UNSUPPORTED_CURVE;

      goto cleanup;

    }

    _gnutls_audit_data("pk::curve", CRAU_STRING,

           gnutls_ecc_curve_get_name(priv->curve),

           NULL);

    if (nonce == NULL) {

      gnutls_assert();

      ret = GNUTLS_E_INVALID_REQUEST;

      goto cleanup;

    }

    ret = _gost_params_to_pubkey(pub, &ecc_pub, curve);

    if (ret < 0) {

      gnutls_assert();

      goto cleanup;

    }

    ret = _gost_params_to_privkey(priv, &ecc_priv, curve);

    if (ret < 0) {

      ecc_point_clear(&ecc_pub);

      gnutls_assert();

      goto cleanup;

    }

    out->size = 2 * gnutls_ecc_curve_get_size(priv->curve);

    out->data = gnutls_malloc(out->size);

    if (out->data == NULL) {

      ret = gnutls_assert_val(GNUTLS_E_MEMORY_ERROR);

      goto gost_cleanup;

    }

    gostdsa_vko(&ecc_priv, &ecc_pub, nonce->size, nonce->data,

          out->data);

  gost_cleanup:

    ecc_point_clear(&ecc_pub);

    ecc_scalar_zclear(&ecc_priv);

    if (ret < 0)

      goto cleanup;

    break;

  }

#endif

  default:

    gnutls_assert();

    ret = GNUTLS_E_INTERNAL_ERROR;

    goto cleanup;

  }

  ret = 0;

cleanup:

  if (ret < 0) {

    _gnutls_switch_fips_state(GNUTLS_FIPS140_OP_ERROR);

  } else if (not_approved) {

    _gnutls_switch_fips_state(GNUTLS_FIPS140_OP_NOT_APPROVED);

  } else {

    _gnutls_switch_fips_state(GNUTLS_FIPS140_OP_APPROVED);

  }

  gnutls_audit_pop_context();

  return ret;

}

#ifdef HAVE_LEANCRYPTO

static enum lc_kyber_type ml_kem_pk_to_lc_kyber_type(gnutls_pk_algorithm_t algo)

{

  switch (algo) {

#ifdef LC_KYBER_768_ENABLED

  case GNUTLS_PK_MLKEM768:

    return LC_KYBER_768;

#endif

#ifdef LC_KYBER_1024_ENABLED

  case GNUTLS_PK_MLKEM1024:

    return LC_KYBER_1024;

#endif

  default:

    return gnutls_assert_val(LC_KYBER_UNKNOWN);

  }

}

static int ml_kem_exists(gnutls_pk_algorithm_t algo)

{

  return ml_kem_pk_to_lc_kyber_type(algo) != LC_KYBER_UNKNOWN;

}

static int ml_kem_encaps(gnutls_pk_algorithm_t algo, gnutls_datum_t *ciphertext,

       gnutls_datum_t *shared_secret,

       const gnutls_datum_t *pub)

{

  enum lc_kyber_type type;

  struct lc_kyber_ct ct;

  struct lc_kyber_ss ss;

  struct lc_kyber_pk pk;

  gnutls_datum_t tmp_ciphertext = { NULL, 0 };

  gnutls_datum_t tmp_shared_secret = { NULL, 0 };

  uint8_t *ptr;

  size_t len;

  int ret;

  type = ml_kem_pk_to_lc_kyber_type(algo);

  if (type == LC_KYBER_UNKNOWN)

    return gnutls_assert_val(GNUTLS_E_UNKNOWN_PK_ALGORITHM);

  ret = lc_kyber_pk_load(&pk, pub->data, pub->size);

  if (ret < 0 || lc_kyber_pk_type(&pk) != type) {

    ret = gnutls_assert_val(GNUTLS_E_INVALID_REQUEST);

    goto cleanup;

  }

  ret = lc_kyber_enc(&ct, &ss, &pk);

  if (ret < 0) {

    ret = gnutls_assert_val(GNUTLS_E_PK_ENCRYPTION_FAILED);

    goto cleanup;

  }

  ret = lc_kyber_ct_ptr(&ptr, &len, &ct);

  if (ret < 0) {

    ret = gnutls_assert_val(GNUTLS_E_INTERNAL_ERROR);

    goto cleanup;

  }

  ret = _gnutls_set_datum(&tmp_ciphertext, ptr, len);

  if (ret < 0) {

    gnutls_assert();

    goto cleanup;

  }

  ret = lc_kyber_ss_ptr(&ptr, &len, &ss);

  if (ret < 0) {

    ret = gnutls_assert_val(GNUTLS_E_INTERNAL_ERROR);

    goto cleanup;

  }

  ret = _gnutls_set_datum(&tmp_shared_secret, ptr, len);

  if (ret < 0) {

    ret = gnutls_assert_val(GNUTLS_E_INTERNAL_ERROR);

    goto cleanup;

  }

  *ciphertext = _gnutls_take_datum(&tmp_ciphertext);

  *shared_secret = _gnutls_take_datum(&tmp_shared_secret);

  ret = 0;

cleanup:

  _gnutls_free_datum(&tmp_ciphertext);

  _gnutls_free_key_datum(&tmp_shared_secret);

  zeroize_key(&pk, sizeof(pk));

  return ret;

}

static int ml_kem_decaps(gnutls_pk_algorithm_t algo,

       gnutls_datum_t *shared_secret,

       const gnutls_datum_t *ciphertext,

       const gnutls_datum_t *priv)

{

  int ret;

  enum lc_kyber_type type;

  struct lc_kyber_ss ss;

  struct lc_kyber_ct ct;

  struct lc_kyber_sk sk;

  gnutls_datum_t tmp_shared_secret = { NULL, 0 };

  uint8_t *ptr;

  size_t len;

  type = ml_kem_pk_to_lc_kyber_type(algo);

  if (type == LC_KYBER_UNKNOWN)

    return gnutls_assert_val(GNUTLS_E_UNKNOWN_PK_ALGORITHM);

  ret = lc_kyber_sk_load(&sk, priv->data, priv->size);

  if (ret < 0 || lc_kyber_sk_type(&sk) != type) {

    ret = gnutls_assert_val(GNUTLS_E_INVALID_REQUEST);

    goto cleanup;

  }

  ret = lc_kyber_ct_load(&ct, ciphertext->data, ciphertext->size);

  if (ret < 0 || lc_kyber_ct_type(&ct) != type) {

    ret = gnutls_assert_val(GNUTLS_E_INVALID_REQUEST);

    goto cleanup;

  }

  ret = lc_kyber_dec(&ss, &ct, &sk);

  if (ret < 0) {

    ret = gnutls_assert_val(GNUTLS_E_PK_DECRYPTION_FAILED);

    goto cleanup;

  }

  ret = lc_kyber_ss_ptr(&ptr, &len, &ss);

  if (ret < 0) {

    ret = gnutls_assert_val(GNUTLS_E_INTERNAL_ERROR);

    goto cleanup;

  }

  ret = _gnutls_set_datum(&tmp_shared_secret, ptr, len);

  if (ret < 0) {

    ret = gnutls_assert_val(GNUTLS_E_INTERNAL_ERROR);

    goto cleanup;

  }

  *shared_secret = _gnutls_take_datum(&tmp_shared_secret);

  ret = 0;

cleanup:

  _gnutls_free_key_datum(&tmp_shared_secret);

  zeroize_key(&ss, sizeof(ss));

  zeroize_key(&sk, sizeof(sk));

  return ret;

}

static int ml_kem_generate_keypair(gnutls_pk_algorithm_t algo,

           gnutls_datum_t *raw_priv,

           gnutls_datum_t *raw_pub)

{

  int ret;

  enum lc_kyber_type type;

  struct lc_kyber_sk sk;

  struct lc_kyber_pk pk;

  gnutls_datum_t tmp_raw_priv = { NULL, 0 };

  gnutls_datum_t tmp_raw_pub = { NULL, 0 };

  uint8_t *ptr;

  size_t len;

  type = ml_kem_pk_to_lc_kyber_type(algo);

  if (type == LC_KYBER_UNKNOWN)

    return gnutls_assert_val(GNUTLS_E_UNKNOWN_PK_ALGORITHM);

  ret = lc_kyber_keypair(&pk, &sk, lc_seeded_rng, type);

  if (ret < 0) {

    ret = gnutls_assert_val(GNUTLS_E_PK_GENERATION_ERROR);

    goto cleanup;

  }

  ret = lc_kyber_sk_ptr(&ptr, &len, &sk);

  if (ret < 0) {

    ret = gnutls_assert_val(GNUTLS_E_INTERNAL_ERROR);

    goto cleanup;

  }

  ret = _gnutls_set_datum(&tmp_raw_priv, ptr, len);

  if (ret < 0) {

    gnutls_assert();

    goto cleanup;

  }

  ret = lc_kyber_pk_ptr(&ptr, &len, &pk);

  if (ret < 0) {

    ret = gnutls_assert_val(GNUTLS_E_INTERNAL_ERROR);

    goto cleanup;

  }

  ret = _gnutls_set_datum(&tmp_raw_pub, ptr, len);

  if (ret < 0) {

    ret = gnutls_assert_val(GNUTLS_E_INTERNAL_ERROR);

    goto cleanup;

  }

  *raw_priv = _gnutls_take_datum(&tmp_raw_priv);

  *raw_pub = _gnutls_take_datum(&tmp_raw_pub);

  ret = 0;

cleanup:

  _gnutls_free_key_datum(&tmp_raw_priv);

  _gnutls_free_key_datum(&tmp_raw_pub);

  zeroize_key(&pk, sizeof(pk));

  zeroize_key(&sk, sizeof(sk));

  return ret;

}

#else

static int ml_kem_exists(gnutls_pk_algorithm_t algo MAYBE_UNUSED)

{

  return 0;

}

static int ml_kem_encaps(gnutls_pk_algorithm_t algo MAYBE_UNUSED,

       gnutls_datum_t *ciphertext MAYBE_UNUSED,

       gnutls_datum_t *shared_secret MAYBE_UNUSED,

       const gnutls_datum_t *pub MAYBE_UNUSED)

{

  return gnutls_assert_val(GNUTLS_E_UNKNOWN_ALGORITHM);

}

static int ml_kem_decaps(gnutls_pk_algorithm_t algo MAYBE_UNUSED,

       gnutls_datum_t *shared_secret MAYBE_UNUSED,

       const gnutls_datum_t *ciphertext MAYBE_UNUSED,

       const gnutls_datum_t *priv MAYBE_UNUSED)

{

  return gnutls_assert_val(GNUTLS_E_UNKNOWN_ALGORITHM);

}

static int ml_kem_generate_keypair(gnutls_pk_algorithm_t algo MAYBE_UNUSED,

           gnutls_datum_t *raw_priv MAYBE_UNUSED,

           gnutls_datum_t *raw_pub MAYBE_UNUSED)

{

  return gnutls_assert_val(GNUTLS_E_UNKNOWN_ALGORITHM);

}

#endif

static int _wrap_nettle_pk_encaps(gnutls_pk_algorithm_t algo,

          gnutls_datum_t *ciphertext,

          gnutls_datum_t *shared_secret,