Merge "libcrypto_utils: Use accessors to manipulate RSA keys." am: cdfef7fe

../.clang-format-2

 No newline at end of file

    // RSA modulus as a little-endian array.

    uint8_t modulus[ANDROID_PUBKEY_MODULUS_SIZE];

    // Montgomery parameter R^2 as a little-endian array of little-endian words.

    // Montgomery parameter R^2 as a little-endian array.

    uint8_t rr[ANDROID_PUBKEY_MODULUS_SIZE];

    // RSA modulus: 3 or 65537

    uint32_t exponent;

} RSAPublicKey;

// Reverses byte order in |buffer|.

static void reverse_bytes(uint8_t* buffer, size_t size) {

  for (size_t i = 0; i < (size + 1) / 2; ++i) {

    uint8_t tmp = buffer[i];

    buffer[i] = buffer[size - i - 1];

    buffer[size - i - 1] = tmp;

  }

}

bool android_pubkey_decode(const uint8_t* key_buffer, size_t size, RSA** key) {

  const RSAPublicKey* key_struct = (RSAPublicKey*)key_buffer;

  bool ret = false;

  uint8_t modulus_buffer[ANDROID_PUBKEY_MODULUS_SIZE];

  RSA* new_key = RSA_new();

  BIGNUM* n = NULL;

  BIGNUM* e = NULL;

  if (!new_key) {

    goto cleanup;

  }

  }

  // Convert the modulus to big-endian byte order as expected by BN_bin2bn.

  memcpy(modulus_buffer, key_struct->modulus, sizeof(modulus_buffer));

  reverse_bytes(modulus_buffer, sizeof(modulus_buffer));

  new_key->n = BN_bin2bn(modulus_buffer, sizeof(modulus_buffer), NULL);

  if (!new_key->n) {

  n = BN_le2bn(key_struct->modulus, ANDROID_PUBKEY_MODULUS_SIZE, NULL);

  if (!n) {

    goto cleanup;

  }

  // Read the exponent.

  new_key->e = BN_new();

  if (!new_key->e || !BN_set_word(new_key->e, key_struct->exponent)) {

  e = BN_new();

  if (!e || !BN_set_word(e, key_struct->exponent)) {

    goto cleanup;

  }

  if (!RSA_set0_key(new_key, n, e, NULL)) {

    goto cleanup;

  }

  // RSA_set0_key takes ownership of its inputs on success.

  n = NULL;

  e = NULL;

  // Note that we don't extract the montgomery parameters n0inv and rr from

  // the RSAPublicKey structure. They assume a word size of 32 bits, but

  // pre-computed montgomery parameters.

  *key = new_key;

  new_key = NULL;

  ret = true;

cleanup:

  if (!ret && new_key) {

  RSA_free(new_key);

  }

  BN_free(n);

  BN_free(e);

  return ret;

}

static bool android_pubkey_encode_bignum(const BIGNUM* num, uint8_t* buffer) {

  if (!BN_bn2bin_padded(buffer, ANDROID_PUBKEY_MODULUS_SIZE, num)) {

    return false;

  }

  reverse_bytes(buffer, ANDROID_PUBKEY_MODULUS_SIZE);

  return true;

}

bool android_pubkey_encode(const RSA* key, uint8_t* key_buffer, size_t size) {

  RSAPublicKey* key_struct = (RSAPublicKey*)key_buffer;

  bool ret = false;

  key_struct->modulus_size_words = ANDROID_PUBKEY_MODULUS_SIZE_WORDS;

  // Compute and store n0inv = -1 / N[0] mod 2^32.

  if (!ctx || !r32 || !n0inv || !BN_set_bit(r32, 32) ||

      !BN_mod(n0inv, key->n, r32, ctx) ||

  if (!ctx || !r32 || !n0inv || !BN_set_bit(r32, 32) || !BN_mod(n0inv, RSA_get0_n(key), r32, ctx) ||

      !BN_mod_inverse(n0inv, n0inv, r32, ctx) || !BN_sub(n0inv, r32, n0inv)) {

    goto cleanup;

  }

  key_struct->n0inv = (uint32_t)BN_get_word(n0inv);

  // Store the modulus.

  if (!android_pubkey_encode_bignum(key->n, key_struct->modulus)) {

  if (!BN_bn2le_padded(key_struct->modulus, ANDROID_PUBKEY_MODULUS_SIZE, RSA_get0_n(key))) {

    goto cleanup;

  }

  // Compute and store rr = (2^(rsa_size)) ^ 2 mod N.

  if (!ctx || !rr || !BN_set_bit(rr, ANDROID_PUBKEY_MODULUS_SIZE * 8) ||

      !BN_mod_sqr(rr, rr, key->n, ctx) ||

      !android_pubkey_encode_bignum(rr, key_struct->rr)) {

      !BN_mod_sqr(rr, rr, RSA_get0_n(key), ctx) ||

      !BN_bn2le_padded(key_struct->rr, ANDROID_PUBKEY_MODULUS_SIZE, rr)) {

    goto cleanup;

  }

  // Store the exponent.

  key_struct->exponent = (uint32_t)BN_get_word(key->e);

  key_struct->exponent = (uint32_t)BN_get_word(RSA_get0_e(key));

  ret = true;