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|
/**
* Copyright Amazon.com, Inc. or its affiliates. All Rights Reserved.
* SPDX-License-Identifier: Apache-2.0.
*/
#include <aws/cal/private/ecc.h>
#include <aws/cal/cal.h>
#include <aws/cal/private/der.h>
#define OPENSSL_SUPPRESS_DEPRECATED
#include <openssl/bn.h>
#include <openssl/ec.h>
#include <openssl/ecdsa.h>
#include <openssl/obj_mac.h>
struct libcrypto_ecc_key {
struct aws_ecc_key_pair key_pair;
EC_KEY *ec_key;
};
static int s_curve_name_to_nid(enum aws_ecc_curve_name curve_name) {
switch (curve_name) {
case AWS_CAL_ECDSA_P256:
return NID_X9_62_prime256v1;
case AWS_CAL_ECDSA_P384:
return NID_secp384r1;
}
AWS_FATAL_ASSERT(!"Unsupported elliptic curve name");
return -1;
}
static void s_key_pair_destroy(struct aws_ecc_key_pair *key_pair) {
if (key_pair) {
aws_byte_buf_clean_up(&key_pair->pub_x);
aws_byte_buf_clean_up(&key_pair->pub_y);
aws_byte_buf_clean_up_secure(&key_pair->priv_d);
struct libcrypto_ecc_key *key_impl = key_pair->impl;
if (key_impl->ec_key) {
EC_KEY_free(key_impl->ec_key);
}
aws_mem_release(key_pair->allocator, key_pair);
}
}
static int s_sign_payload(
const struct aws_ecc_key_pair *key_pair,
const struct aws_byte_cursor *hash,
struct aws_byte_buf *signature_output) {
struct libcrypto_ecc_key *libcrypto_key_pair = key_pair->impl;
unsigned int signature_size = signature_output->capacity - signature_output->len;
int ret_val = ECDSA_sign(
0,
hash->ptr,
hash->len,
signature_output->buffer + signature_output->len,
&signature_size,
libcrypto_key_pair->ec_key);
signature_output->len += signature_size;
return ret_val == 1 ? AWS_OP_SUCCESS : aws_raise_error(AWS_ERROR_INVALID_ARGUMENT);
}
static int s_verify_payload(
const struct aws_ecc_key_pair *key_pair,
const struct aws_byte_cursor *hash,
const struct aws_byte_cursor *signature) {
struct libcrypto_ecc_key *libcrypto_key_pair = key_pair->impl;
return ECDSA_verify(0, hash->ptr, hash->len, signature->ptr, signature->len, libcrypto_key_pair->ec_key) == 1
? AWS_OP_SUCCESS
: aws_raise_error(AWS_ERROR_CAL_SIGNATURE_VALIDATION_FAILED);
}
static size_t s_signature_length(const struct aws_ecc_key_pair *key_pair) {
struct libcrypto_ecc_key *libcrypto_key_pair = key_pair->impl;
return ECDSA_size(libcrypto_key_pair->ec_key);
}
static int s_fill_in_public_key_info(
struct libcrypto_ecc_key *libcrypto_key_pair,
const EC_GROUP *group,
const EC_POINT *pub_key_point) {
BIGNUM *big_num_x = BN_new();
BIGNUM *big_num_y = BN_new();
int ret_val = AWS_OP_ERR;
if (EC_POINT_get_affine_coordinates_GFp(group, pub_key_point, big_num_x, big_num_y, NULL) != 1) {
aws_raise_error(AWS_ERROR_INVALID_STATE);
goto clean_up;
}
size_t x_coor_size = BN_num_bytes(big_num_x);
size_t y_coor_size = BN_num_bytes(big_num_y);
if (aws_byte_buf_init(&libcrypto_key_pair->key_pair.pub_x, libcrypto_key_pair->key_pair.allocator, x_coor_size)) {
goto clean_up;
}
if (aws_byte_buf_init(&libcrypto_key_pair->key_pair.pub_y, libcrypto_key_pair->key_pair.allocator, y_coor_size)) {
goto clean_up;
}
BN_bn2bin(big_num_x, libcrypto_key_pair->key_pair.pub_x.buffer);
BN_bn2bin(big_num_y, libcrypto_key_pair->key_pair.pub_y.buffer);
libcrypto_key_pair->key_pair.pub_x.len = x_coor_size;
libcrypto_key_pair->key_pair.pub_y.len = y_coor_size;
ret_val = AWS_OP_SUCCESS;
clean_up:
BN_free(big_num_x);
BN_free(big_num_y);
return ret_val;
}
static int s_derive_public_key(struct aws_ecc_key_pair *key_pair) {
struct libcrypto_ecc_key *libcrypto_key_pair = key_pair->impl;
if (!libcrypto_key_pair->key_pair.priv_d.buffer) {
return aws_raise_error(AWS_ERROR_INVALID_STATE);
}
/* we already have a public key. */
if (libcrypto_key_pair->key_pair.pub_x.len) {
return AWS_OP_SUCCESS;
}
BIGNUM *priv_key_num =
BN_bin2bn(libcrypto_key_pair->key_pair.priv_d.buffer, libcrypto_key_pair->key_pair.priv_d.len, NULL);
const EC_GROUP *group = EC_KEY_get0_group(libcrypto_key_pair->ec_key);
EC_POINT *point = EC_POINT_new(group);
EC_POINT_mul(group, point, priv_key_num, NULL, NULL, NULL);
BN_free(priv_key_num);
EC_KEY_set_public_key(libcrypto_key_pair->ec_key, point);
int ret_val = s_fill_in_public_key_info(libcrypto_key_pair, group, point);
EC_POINT_free(point);
return ret_val;
}
static struct aws_ecc_key_pair_vtable vtable = {
.sign_message = s_sign_payload,
.verify_signature = s_verify_payload,
.derive_pub_key = s_derive_public_key,
.signature_length = s_signature_length,
.destroy = s_key_pair_destroy,
};
struct aws_ecc_key_pair *aws_ecc_key_pair_new_from_private_key_impl(
struct aws_allocator *allocator,
enum aws_ecc_curve_name curve_name,
const struct aws_byte_cursor *priv_key) {
size_t key_length = aws_ecc_key_coordinate_byte_size_from_curve_name(curve_name);
if (priv_key->len != key_length) {
AWS_LOGF_ERROR(AWS_LS_CAL_ECC, "Private key length does not match curve's expected length");
aws_raise_error(AWS_ERROR_CAL_INVALID_KEY_LENGTH_FOR_ALGORITHM);
return NULL;
}
struct libcrypto_ecc_key *key_impl = aws_mem_calloc(allocator, 1, sizeof(struct libcrypto_ecc_key));
key_impl->ec_key = EC_KEY_new_by_curve_name(s_curve_name_to_nid(curve_name));
key_impl->key_pair.curve_name = curve_name;
key_impl->key_pair.allocator = allocator;
key_impl->key_pair.vtable = &vtable;
key_impl->key_pair.impl = key_impl;
aws_atomic_init_int(&key_impl->key_pair.ref_count, 1);
aws_byte_buf_init_copy_from_cursor(&key_impl->key_pair.priv_d, allocator, *priv_key);
BIGNUM *priv_key_num = BN_bin2bn(key_impl->key_pair.priv_d.buffer, key_impl->key_pair.priv_d.len, NULL);
if (!EC_KEY_set_private_key(key_impl->ec_key, priv_key_num)) {
AWS_LOGF_ERROR(AWS_LS_CAL_ECC, "Failed to set openssl private key");
aws_raise_error(AWS_ERROR_INVALID_ARGUMENT);
BN_free(priv_key_num);
s_key_pair_destroy(&key_impl->key_pair);
return NULL;
}
BN_free(priv_key_num);
return &key_impl->key_pair;
}
struct aws_ecc_key_pair *aws_ecc_key_pair_new_generate_random(
struct aws_allocator *allocator,
enum aws_ecc_curve_name curve_name) {
struct libcrypto_ecc_key *key_impl = aws_mem_calloc(allocator, 1, sizeof(struct libcrypto_ecc_key));
key_impl->ec_key = EC_KEY_new_by_curve_name(s_curve_name_to_nid(curve_name));
key_impl->key_pair.curve_name = curve_name;
key_impl->key_pair.allocator = allocator;
key_impl->key_pair.vtable = &vtable;
key_impl->key_pair.impl = key_impl;
aws_atomic_init_int(&key_impl->key_pair.ref_count, 1);
if (EC_KEY_generate_key(key_impl->ec_key) != 1) {
goto error;
}
const EC_POINT *pub_key_point = EC_KEY_get0_public_key(key_impl->ec_key);
const EC_GROUP *group = EC_KEY_get0_group(key_impl->ec_key);
const BIGNUM *private_key_num = EC_KEY_get0_private_key(key_impl->ec_key);
size_t priv_key_size = BN_num_bytes(private_key_num);
if (aws_byte_buf_init(&key_impl->key_pair.priv_d, allocator, priv_key_size)) {
goto error;
}
BN_bn2bin(private_key_num, key_impl->key_pair.priv_d.buffer);
key_impl->key_pair.priv_d.len = priv_key_size;
if (!s_fill_in_public_key_info(key_impl, group, pub_key_point)) {
return &key_impl->key_pair;
}
error:
s_key_pair_destroy(&key_impl->key_pair);
return NULL;
}
struct aws_ecc_key_pair *aws_ecc_key_pair_new_from_public_key_impl(
struct aws_allocator *allocator,
enum aws_ecc_curve_name curve_name,
const struct aws_byte_cursor *public_key_x,
const struct aws_byte_cursor *public_key_y) {
struct libcrypto_ecc_key *key_impl = aws_mem_calloc(allocator, 1, sizeof(struct libcrypto_ecc_key));
BIGNUM *pub_x_num = NULL;
BIGNUM *pub_y_num = NULL;
EC_POINT *point = NULL;
if (!key_impl) {
return NULL;
}
key_impl->ec_key = EC_KEY_new_by_curve_name(s_curve_name_to_nid(curve_name));
key_impl->key_pair.curve_name = curve_name;
key_impl->key_pair.allocator = allocator;
key_impl->key_pair.vtable = &vtable;
key_impl->key_pair.impl = key_impl;
aws_atomic_init_int(&key_impl->key_pair.ref_count, 1);
if (aws_byte_buf_init_copy_from_cursor(&key_impl->key_pair.pub_x, allocator, *public_key_x)) {
s_key_pair_destroy(&key_impl->key_pair);
return NULL;
}
if (aws_byte_buf_init_copy_from_cursor(&key_impl->key_pair.pub_y, allocator, *public_key_y)) {
s_key_pair_destroy(&key_impl->key_pair);
return NULL;
}
pub_x_num = BN_bin2bn(public_key_x->ptr, public_key_x->len, NULL);
pub_y_num = BN_bin2bn(public_key_y->ptr, public_key_y->len, NULL);
const EC_GROUP *group = EC_KEY_get0_group(key_impl->ec_key);
point = EC_POINT_new(group);
if (EC_POINT_set_affine_coordinates_GFp(group, point, pub_x_num, pub_y_num, NULL) != 1) {
goto error;
}
if (EC_KEY_set_public_key(key_impl->ec_key, point) != 1) {
goto error;
}
EC_POINT_free(point);
BN_free(pub_x_num);
BN_free(pub_y_num);
return &key_impl->key_pair;
error:
if (point) {
EC_POINT_free(point);
}
if (pub_x_num) {
BN_free(pub_x_num);
}
if (pub_y_num) {
BN_free(pub_y_num);
}
s_key_pair_destroy(&key_impl->key_pair);
return NULL;
}
struct aws_ecc_key_pair *aws_ecc_key_pair_new_from_asn1(
struct aws_allocator *allocator,
const struct aws_byte_cursor *encoded_keys) {
struct aws_ecc_key_pair *key = NULL;
struct aws_der_decoder *decoder = aws_der_decoder_new(allocator, *encoded_keys);
if (!decoder) {
return NULL;
}
struct aws_byte_cursor pub_x;
struct aws_byte_cursor pub_y;
struct aws_byte_cursor priv_d;
enum aws_ecc_curve_name curve_name;
if (aws_der_decoder_load_ecc_key_pair(decoder, &pub_x, &pub_y, &priv_d, &curve_name)) {
goto error;
}
if (priv_d.ptr) {
struct libcrypto_ecc_key *key_impl = aws_mem_calloc(allocator, 1, sizeof(struct libcrypto_ecc_key));
key_impl->key_pair.curve_name = curve_name;
/* as awkward as it seems, there's not a great way to manually set the public key, so let openssl just parse
* the der document manually now that we know what parts are what. */
if (!d2i_ECPrivateKey(&key_impl->ec_key, (const unsigned char **)&encoded_keys->ptr, encoded_keys->len)) {
aws_mem_release(allocator, key_impl);
aws_raise_error(AWS_ERROR_CAL_MISSING_REQUIRED_KEY_COMPONENT);
goto error;
}
key_impl->key_pair.allocator = allocator;
key_impl->key_pair.vtable = &vtable;
key_impl->key_pair.impl = key_impl;
aws_atomic_init_int(&key_impl->key_pair.ref_count, 1);
key = &key_impl->key_pair;
struct aws_byte_buf temp_buf;
AWS_ZERO_STRUCT(temp_buf);
if (pub_x.ptr) {
temp_buf = aws_byte_buf_from_array(pub_x.ptr, pub_x.len);
if (aws_byte_buf_init_copy(&key->pub_x, allocator, &temp_buf)) {
goto error;
}
}
if (pub_y.ptr) {
temp_buf = aws_byte_buf_from_array(pub_y.ptr, pub_y.len);
if (aws_byte_buf_init_copy(&key->pub_y, allocator, &temp_buf)) {
goto error;
}
}
if (priv_d.ptr) {
temp_buf = aws_byte_buf_from_array(priv_d.ptr, priv_d.len);
if (aws_byte_buf_init_copy(&key->priv_d, allocator, &temp_buf)) {
goto error;
}
}
} else {
key = aws_ecc_key_pair_new_from_public_key(allocator, curve_name, &pub_x, &pub_y);
if (!key) {
goto error;
}
}
aws_der_decoder_destroy(decoder);
return key;
error:
aws_der_decoder_destroy(decoder);
s_key_pair_destroy(key);
return NULL;
}
|
