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|
/**
* Copyright Amazon.com, Inc. or its affiliates. All Rights Reserved.
* SPDX-License-Identifier: Apache-2.0.
*/
#include <aws/cal/private/symmetric_cipher_priv.h>
#include <openssl/evp.h>
struct openssl_aes_cipher {
struct aws_symmetric_cipher cipher_base;
EVP_CIPHER_CTX *encryptor_ctx;
EVP_CIPHER_CTX *decryptor_ctx;
struct aws_byte_buf working_buffer;
};
static int s_encrypt(struct aws_symmetric_cipher *cipher, struct aws_byte_cursor input, struct aws_byte_buf *out) {
size_t required_buffer_space = input.len + cipher->block_size;
if (aws_symmetric_cipher_try_ensure_sufficient_buffer_space(out, required_buffer_space)) {
return aws_raise_error(AWS_ERROR_SHORT_BUFFER);
}
size_t available_write_space = out->capacity - out->len;
struct openssl_aes_cipher *openssl_cipher = cipher->impl;
int len_written = (int)(available_write_space);
if (!EVP_EncryptUpdate(
openssl_cipher->encryptor_ctx, out->buffer + out->len, &len_written, input.ptr, (int)input.len)) {
cipher->good = false;
return aws_raise_error(AWS_ERROR_INVALID_ARGUMENT);
}
out->len += len_written;
return AWS_OP_SUCCESS;
}
static int s_finalize_encryption(struct aws_symmetric_cipher *cipher, struct aws_byte_buf *out) {
struct openssl_aes_cipher *openssl_cipher = cipher->impl;
size_t required_buffer_space = cipher->block_size;
if (aws_symmetric_cipher_try_ensure_sufficient_buffer_space(out, required_buffer_space)) {
return aws_raise_error(AWS_ERROR_SHORT_BUFFER);
}
int len_written = (int)(out->capacity - out->len);
if (!EVP_EncryptFinal_ex(openssl_cipher->encryptor_ctx, out->buffer + out->len, &len_written)) {
cipher->good = false;
return aws_raise_error(AWS_ERROR_INVALID_ARGUMENT);
}
out->len += len_written;
return AWS_OP_SUCCESS;
}
static int s_decrypt(struct aws_symmetric_cipher *cipher, struct aws_byte_cursor input, struct aws_byte_buf *out) {
struct openssl_aes_cipher *openssl_cipher = cipher->impl;
size_t required_buffer_space = input.len + cipher->block_size;
if (aws_symmetric_cipher_try_ensure_sufficient_buffer_space(out, required_buffer_space)) {
return aws_raise_error(AWS_ERROR_SHORT_BUFFER);
}
size_t available_write_space = out->capacity - out->len;
int len_written = (int)available_write_space;
if (!EVP_DecryptUpdate(
openssl_cipher->decryptor_ctx, out->buffer + out->len, &len_written, input.ptr, (int)input.len)) {
cipher->good = false;
return aws_raise_error(AWS_ERROR_INVALID_ARGUMENT);
}
out->len += len_written;
return AWS_OP_SUCCESS;
}
static int s_finalize_decryption(struct aws_symmetric_cipher *cipher, struct aws_byte_buf *out) {
struct openssl_aes_cipher *openssl_cipher = cipher->impl;
size_t required_buffer_space = cipher->block_size;
if (aws_symmetric_cipher_try_ensure_sufficient_buffer_space(out, required_buffer_space)) {
return aws_raise_error(AWS_ERROR_SHORT_BUFFER);
}
int len_written = (int)out->capacity - out->len;
if (!EVP_DecryptFinal_ex(openssl_cipher->decryptor_ctx, out->buffer + out->len, &len_written)) {
cipher->good = false;
return aws_raise_error(AWS_ERROR_INVALID_ARGUMENT);
}
out->len += len_written;
return AWS_OP_SUCCESS;
}
static void s_destroy(struct aws_symmetric_cipher *cipher) {
struct openssl_aes_cipher *openssl_cipher = cipher->impl;
if (openssl_cipher->encryptor_ctx) {
EVP_CIPHER_CTX_free(openssl_cipher->encryptor_ctx);
}
if (openssl_cipher->decryptor_ctx) {
EVP_CIPHER_CTX_free(openssl_cipher->decryptor_ctx);
}
aws_byte_buf_clean_up_secure(&cipher->key);
aws_byte_buf_clean_up_secure(&cipher->iv);
if (cipher->tag.buffer) {
aws_byte_buf_clean_up_secure(&cipher->tag);
}
if (cipher->aad.buffer) {
aws_byte_buf_clean_up_secure(&cipher->aad);
}
aws_byte_buf_clean_up_secure(&openssl_cipher->working_buffer);
aws_mem_release(cipher->allocator, openssl_cipher);
}
static int s_clear_reusable_state(struct aws_symmetric_cipher *cipher) {
struct openssl_aes_cipher *openssl_cipher = cipher->impl;
EVP_CIPHER_CTX_cleanup(openssl_cipher->encryptor_ctx);
EVP_CIPHER_CTX_cleanup(openssl_cipher->decryptor_ctx);
aws_byte_buf_secure_zero(&openssl_cipher->working_buffer);
cipher->good = true;
return AWS_OP_SUCCESS;
}
static int s_init_cbc_cipher_materials(struct aws_symmetric_cipher *cipher) {
struct openssl_aes_cipher *openssl_cipher = cipher->impl;
if (!EVP_EncryptInit_ex(
openssl_cipher->encryptor_ctx,
EVP_aes_256_cbc(),
NULL,
openssl_cipher->cipher_base.key.buffer,
openssl_cipher->cipher_base.iv.buffer) ||
!EVP_DecryptInit_ex(
openssl_cipher->decryptor_ctx,
EVP_aes_256_cbc(),
NULL,
openssl_cipher->cipher_base.key.buffer,
openssl_cipher->cipher_base.iv.buffer)) {
return aws_raise_error(AWS_ERROR_INVALID_ARGUMENT);
}
return AWS_OP_SUCCESS;
}
static int s_reset_cbc_cipher_materials(struct aws_symmetric_cipher *cipher) {
int ret_val = s_clear_reusable_state(cipher);
if (ret_val == AWS_OP_SUCCESS) {
return s_init_cbc_cipher_materials(cipher);
}
return ret_val;
}
static struct aws_symmetric_cipher_vtable s_cbc_vtable = {
.alg_name = "AES-CBC 256",
.provider = "OpenSSL Compatible LibCrypto",
.destroy = s_destroy,
.reset = s_reset_cbc_cipher_materials,
.decrypt = s_decrypt,
.encrypt = s_encrypt,
.finalize_decryption = s_finalize_decryption,
.finalize_encryption = s_finalize_encryption,
};
struct aws_symmetric_cipher *aws_aes_cbc_256_new_impl(
struct aws_allocator *allocator,
const struct aws_byte_cursor *key,
const struct aws_byte_cursor *iv) {
struct openssl_aes_cipher *cipher = aws_mem_calloc(allocator, 1, sizeof(struct openssl_aes_cipher));
cipher->cipher_base.allocator = allocator;
cipher->cipher_base.block_size = AWS_AES_256_CIPHER_BLOCK_SIZE;
cipher->cipher_base.key_length_bits = AWS_AES_256_KEY_BIT_LEN;
cipher->cipher_base.vtable = &s_cbc_vtable;
cipher->cipher_base.impl = cipher;
if (key) {
aws_byte_buf_init_copy_from_cursor(&cipher->cipher_base.key, allocator, *key);
} else {
aws_byte_buf_init(&cipher->cipher_base.key, allocator, AWS_AES_256_KEY_BYTE_LEN);
aws_symmetric_cipher_generate_key(AWS_AES_256_KEY_BYTE_LEN, &cipher->cipher_base.key);
}
if (iv) {
aws_byte_buf_init_copy_from_cursor(&cipher->cipher_base.iv, allocator, *iv);
} else {
aws_byte_buf_init(&cipher->cipher_base.iv, allocator, AWS_AES_256_CIPHER_BLOCK_SIZE);
aws_symmetric_cipher_generate_initialization_vector(
AWS_AES_256_CIPHER_BLOCK_SIZE, false, &cipher->cipher_base.iv);
}
/* EVP_CIPHER_CTX_init() will be called inside EVP_CIPHER_CTX_new(). */
cipher->encryptor_ctx = EVP_CIPHER_CTX_new();
AWS_FATAL_ASSERT(cipher->encryptor_ctx && "Cipher initialization failed!");
/* EVP_CIPHER_CTX_init() will be called inside EVP_CIPHER_CTX_new(). */
cipher->decryptor_ctx = EVP_CIPHER_CTX_new();
AWS_FATAL_ASSERT(cipher->decryptor_ctx && "Cipher initialization failed!");
if (s_init_cbc_cipher_materials(&cipher->cipher_base) != AWS_OP_SUCCESS) {
goto error;
}
cipher->cipher_base.good = true;
return &cipher->cipher_base;
error:
s_destroy(&cipher->cipher_base);
return NULL;
}
static int s_init_ctr_cipher_materials(struct aws_symmetric_cipher *cipher) {
struct openssl_aes_cipher *openssl_cipher = cipher->impl;
if (!(EVP_EncryptInit_ex(
openssl_cipher->encryptor_ctx,
EVP_aes_256_ctr(),
NULL,
openssl_cipher->cipher_base.key.buffer,
openssl_cipher->cipher_base.iv.buffer) &&
EVP_CIPHER_CTX_set_padding(openssl_cipher->encryptor_ctx, 0)) ||
!(EVP_DecryptInit_ex(
openssl_cipher->decryptor_ctx,
EVP_aes_256_ctr(),
NULL,
openssl_cipher->cipher_base.key.buffer,
openssl_cipher->cipher_base.iv.buffer) &&
EVP_CIPHER_CTX_set_padding(openssl_cipher->decryptor_ctx, 0))) {
return aws_raise_error(AWS_ERROR_INVALID_ARGUMENT);
}
return AWS_OP_SUCCESS;
}
static int s_reset_ctr_cipher_materials(struct aws_symmetric_cipher *cipher) {
int ret_val = s_clear_reusable_state(cipher);
if (ret_val == AWS_OP_SUCCESS) {
return s_init_ctr_cipher_materials(cipher);
}
return ret_val;
}
static struct aws_symmetric_cipher_vtable s_ctr_vtable = {
.alg_name = "AES-CTR 256",
.provider = "OpenSSL Compatible LibCrypto",
.destroy = s_destroy,
.reset = s_reset_ctr_cipher_materials,
.decrypt = s_decrypt,
.encrypt = s_encrypt,
.finalize_decryption = s_finalize_decryption,
.finalize_encryption = s_finalize_encryption,
};
struct aws_symmetric_cipher *aws_aes_ctr_256_new_impl(
struct aws_allocator *allocator,
const struct aws_byte_cursor *key,
const struct aws_byte_cursor *iv) {
struct openssl_aes_cipher *cipher = aws_mem_calloc(allocator, 1, sizeof(struct openssl_aes_cipher));
cipher->cipher_base.allocator = allocator;
cipher->cipher_base.block_size = AWS_AES_256_CIPHER_BLOCK_SIZE;
cipher->cipher_base.key_length_bits = AWS_AES_256_KEY_BIT_LEN;
cipher->cipher_base.vtable = &s_ctr_vtable;
cipher->cipher_base.impl = cipher;
if (key) {
aws_byte_buf_init_copy_from_cursor(&cipher->cipher_base.key, allocator, *key);
} else {
aws_byte_buf_init(&cipher->cipher_base.key, allocator, AWS_AES_256_KEY_BYTE_LEN);
aws_symmetric_cipher_generate_key(AWS_AES_256_KEY_BYTE_LEN, &cipher->cipher_base.key);
}
if (iv) {
aws_byte_buf_init_copy_from_cursor(&cipher->cipher_base.iv, allocator, *iv);
} else {
aws_byte_buf_init(&cipher->cipher_base.iv, allocator, AWS_AES_256_CIPHER_BLOCK_SIZE);
aws_symmetric_cipher_generate_initialization_vector(
AWS_AES_256_CIPHER_BLOCK_SIZE, true, &cipher->cipher_base.iv);
}
/* EVP_CIPHER_CTX_init() will be called inside EVP_CIPHER_CTX_new(). */
cipher->encryptor_ctx = EVP_CIPHER_CTX_new();
AWS_FATAL_ASSERT(cipher->encryptor_ctx && "Cipher initialization failed!");
/* EVP_CIPHER_CTX_init() will be called inside EVP_CIPHER_CTX_new(). */
cipher->decryptor_ctx = EVP_CIPHER_CTX_new();
AWS_FATAL_ASSERT(cipher->decryptor_ctx && "Cipher initialization failed!");
if (s_init_ctr_cipher_materials(&cipher->cipher_base) != AWS_OP_SUCCESS) {
goto error;
}
cipher->cipher_base.good = true;
return &cipher->cipher_base;
error:
s_destroy(&cipher->cipher_base);
return NULL;
}
static int s_finalize_gcm_encryption(struct aws_symmetric_cipher *cipher, struct aws_byte_buf *out) {
struct openssl_aes_cipher *openssl_cipher = cipher->impl;
int ret_val = s_finalize_encryption(cipher, out);
if (ret_val == AWS_OP_SUCCESS) {
if (!cipher->tag.len) {
if (!EVP_CIPHER_CTX_ctrl(
openssl_cipher->encryptor_ctx,
EVP_CTRL_GCM_GET_TAG,
(int)cipher->tag.capacity,
cipher->tag.buffer)) {
cipher->good = false;
return aws_raise_error(AWS_ERROR_INVALID_ARGUMENT);
}
cipher->tag.len = AWS_AES_256_CIPHER_BLOCK_SIZE;
}
}
return ret_val;
}
static int s_init_gcm_cipher_materials(struct aws_symmetric_cipher *cipher) {
struct openssl_aes_cipher *openssl_cipher = cipher->impl;
if (!(EVP_EncryptInit_ex(openssl_cipher->encryptor_ctx, EVP_aes_256_gcm(), NULL, NULL, NULL) &&
EVP_EncryptInit_ex(
openssl_cipher->encryptor_ctx,
NULL,
NULL,
openssl_cipher->cipher_base.key.buffer,
openssl_cipher->cipher_base.iv.buffer) &&
EVP_CIPHER_CTX_set_padding(openssl_cipher->encryptor_ctx, 0)) ||
!(EVP_DecryptInit_ex(openssl_cipher->decryptor_ctx, EVP_aes_256_gcm(), NULL, NULL, NULL) &&
EVP_DecryptInit_ex(
openssl_cipher->decryptor_ctx,
NULL,
NULL,
openssl_cipher->cipher_base.key.buffer,
openssl_cipher->cipher_base.iv.buffer) &&
EVP_CIPHER_CTX_set_padding(openssl_cipher->decryptor_ctx, 0))) {
return aws_raise_error(AWS_ERROR_INVALID_ARGUMENT);
}
if (openssl_cipher->cipher_base.aad.len) {
int outLen = 0;
if (!EVP_EncryptUpdate(
openssl_cipher->encryptor_ctx,
NULL,
&outLen,
openssl_cipher->cipher_base.aad.buffer,
(int)openssl_cipher->cipher_base.aad.len) ||
!EVP_DecryptUpdate(
openssl_cipher->decryptor_ctx,
NULL,
&outLen,
openssl_cipher->cipher_base.aad.buffer,
(int)openssl_cipher->cipher_base.aad.len)) {
return aws_raise_error(AWS_ERROR_INVALID_ARGUMENT);
}
}
if (openssl_cipher->cipher_base.tag.len) {
if (!EVP_CIPHER_CTX_ctrl(
openssl_cipher->decryptor_ctx,
EVP_CTRL_GCM_SET_TAG,
(int)openssl_cipher->cipher_base.tag.len,
openssl_cipher->cipher_base.tag.buffer)) {
return aws_raise_error(AWS_ERROR_INVALID_ARGUMENT);
}
}
return AWS_OP_SUCCESS;
}
static int s_reset_gcm_cipher_materials(struct aws_symmetric_cipher *cipher) {
int ret_val = s_clear_reusable_state(cipher);
if (ret_val == AWS_OP_SUCCESS) {
return s_init_gcm_cipher_materials(cipher);
}
return ret_val;
}
static struct aws_symmetric_cipher_vtable s_gcm_vtable = {
.alg_name = "AES-GCM 256",
.provider = "OpenSSL Compatible LibCrypto",
.destroy = s_destroy,
.reset = s_reset_gcm_cipher_materials,
.decrypt = s_decrypt,
.encrypt = s_encrypt,
.finalize_decryption = s_finalize_decryption,
.finalize_encryption = s_finalize_gcm_encryption,
};
struct aws_symmetric_cipher *aws_aes_gcm_256_new_impl(
struct aws_allocator *allocator,
const struct aws_byte_cursor *key,
const struct aws_byte_cursor *iv,
const struct aws_byte_cursor *aad,
const struct aws_byte_cursor *decryption_tag) {
struct openssl_aes_cipher *cipher = aws_mem_calloc(allocator, 1, sizeof(struct openssl_aes_cipher));
cipher->cipher_base.allocator = allocator;
cipher->cipher_base.block_size = AWS_AES_256_CIPHER_BLOCK_SIZE;
cipher->cipher_base.key_length_bits = AWS_AES_256_KEY_BIT_LEN;
cipher->cipher_base.vtable = &s_gcm_vtable;
cipher->cipher_base.impl = cipher;
/* Copy key into the cipher context. */
if (key) {
aws_byte_buf_init_copy_from_cursor(&cipher->cipher_base.key, allocator, *key);
} else {
aws_byte_buf_init(&cipher->cipher_base.key, allocator, AWS_AES_256_KEY_BYTE_LEN);
aws_symmetric_cipher_generate_key(AWS_AES_256_KEY_BYTE_LEN, &cipher->cipher_base.key);
}
/* Copy initialization vector into the cipher context. */
if (iv) {
aws_byte_buf_init_copy_from_cursor(&cipher->cipher_base.iv, allocator, *iv);
} else {
aws_byte_buf_init(&cipher->cipher_base.iv, allocator, AWS_AES_256_CIPHER_BLOCK_SIZE - 4);
aws_symmetric_cipher_generate_initialization_vector(
AWS_AES_256_CIPHER_BLOCK_SIZE - 4, false, &cipher->cipher_base.iv);
}
/* Initialize the cipher contexts. */
cipher->encryptor_ctx = EVP_CIPHER_CTX_new();
AWS_FATAL_ASSERT(cipher->encryptor_ctx && "Encryptor cipher initialization failed!");
cipher->decryptor_ctx = EVP_CIPHER_CTX_new();
AWS_FATAL_ASSERT(cipher->decryptor_ctx && "Decryptor cipher initialization failed!");
/* Set AAD if provided */
if (aad) {
aws_byte_buf_init_copy_from_cursor(&cipher->cipher_base.aad, allocator, *aad);
}
/* Set tag for the decryptor to use.*/
if (decryption_tag) {
aws_byte_buf_init_copy_from_cursor(&cipher->cipher_base.tag, allocator, *decryption_tag);
} else {
/* we'll need this later when we grab the tag during encryption time. */
aws_byte_buf_init(&cipher->cipher_base.tag, allocator, AWS_AES_256_CIPHER_BLOCK_SIZE);
}
/* Initialize the cipher contexts with the specified key and IV. */
if (s_init_gcm_cipher_materials(&cipher->cipher_base)) {
goto error;
}
cipher->cipher_base.good = true;
return &cipher->cipher_base;
error:
s_destroy(&cipher->cipher_base);
return NULL;
}
static int s_key_wrap_encrypt_decrypt(
struct aws_symmetric_cipher *cipher,
struct aws_byte_cursor input,
struct aws_byte_buf *out) {
(void)out;
struct openssl_aes_cipher *openssl_cipher = cipher->impl;
return aws_byte_buf_append_dynamic(&openssl_cipher->working_buffer, &input);
}
static const size_t MIN_CEK_LENGTH_BYTES = 128 / 8;
static const unsigned char INTEGRITY_VALUE = 0xA6;
#define KEYWRAP_BLOCK_SIZE 8u
static int s_key_wrap_finalize_encryption(struct aws_symmetric_cipher *cipher, struct aws_byte_buf *out) {
struct openssl_aes_cipher *openssl_cipher = cipher->impl;
if (openssl_cipher->working_buffer.len < MIN_CEK_LENGTH_BYTES) {
cipher->good = false;
return aws_raise_error(AWS_ERROR_INVALID_STATE);
}
/* the following is an in place implementation of
RFC 3394 using the alternate in-place implementation.
we use one in-place buffer instead of the copy at the end.
the one letter variable names are meant to directly reflect the variables in the RFC */
size_t required_buffer_space = openssl_cipher->working_buffer.len + cipher->block_size;
size_t starting_len_offset = out->len;
if (aws_symmetric_cipher_try_ensure_sufficient_buffer_space(out, required_buffer_space)) {
return aws_raise_error(AWS_ERROR_SHORT_BUFFER);
}
/* put the integrity check register in the first 8 bytes of the final buffer. */
aws_byte_buf_write_u8_n(out, INTEGRITY_VALUE, KEYWRAP_BLOCK_SIZE);
uint8_t *a = out->buffer + starting_len_offset;
struct aws_byte_cursor working_buf_cur = aws_byte_cursor_from_buf(&openssl_cipher->working_buffer);
aws_byte_buf_write_from_whole_cursor(out, working_buf_cur);
/* put the register buffer after the integrity check register */
uint8_t *r = out->buffer + starting_len_offset + KEYWRAP_BLOCK_SIZE;
int n = (int)(openssl_cipher->working_buffer.len / KEYWRAP_BLOCK_SIZE);
uint8_t b_buf[KEYWRAP_BLOCK_SIZE * 2] = {0};
struct aws_byte_buf b = aws_byte_buf_from_empty_array(b_buf, sizeof(b_buf));
int b_out_len = b.capacity;
uint8_t temp_buf[KEYWRAP_BLOCK_SIZE * 2] = {0};
struct aws_byte_buf temp_input = aws_byte_buf_from_empty_array(temp_buf, sizeof(temp_buf));
for (int j = 0; j <= 5; ++j) {
for (int i = 1; i <= n; ++i) {
/* concat A and R[i], A should be most significant and then R[i] should be least significant. */
memcpy(temp_input.buffer, a, KEYWRAP_BLOCK_SIZE);
memcpy(temp_input.buffer + KEYWRAP_BLOCK_SIZE, r, KEYWRAP_BLOCK_SIZE);
/* encrypt the concatenated A and R[I] and store it in B */
if (!EVP_EncryptUpdate(
openssl_cipher->encryptor_ctx, b.buffer, &b_out_len, temp_input.buffer, (int)temp_input.capacity)) {
cipher->good = false;
return aws_raise_error(AWS_ERROR_INVALID_ARGUMENT);
}
unsigned char t = (unsigned char)((n * j) + i);
/* put the 64 MSB ^ T into A */
memcpy(a, b.buffer, KEYWRAP_BLOCK_SIZE);
a[7] ^= t;
/* put the 64 LSB into R[i] */
memcpy(r, b.buffer + KEYWRAP_BLOCK_SIZE, KEYWRAP_BLOCK_SIZE);
/* increment i -> R[i] */
r += KEYWRAP_BLOCK_SIZE;
}
/* reset R */
r = out->buffer + starting_len_offset + KEYWRAP_BLOCK_SIZE;
}
return AWS_OP_SUCCESS;
}
static int s_key_wrap_finalize_decryption(struct aws_symmetric_cipher *cipher, struct aws_byte_buf *out) {
struct openssl_aes_cipher *openssl_cipher = cipher->impl;
if (openssl_cipher->working_buffer.len < MIN_CEK_LENGTH_BYTES + KEYWRAP_BLOCK_SIZE) {
cipher->good = false;
return aws_raise_error(AWS_ERROR_INVALID_STATE);
}
/* the following is an in place implementation of
RFC 3394 using the alternate in-place implementation.
we use one in-place buffer instead of the copy at the end.
the one letter variable names are meant to directly reflect the variables in the RFC */
size_t required_buffer_space = openssl_cipher->working_buffer.len - KEYWRAP_BLOCK_SIZE;
size_t starting_len_offset = out->len;
if (aws_symmetric_cipher_try_ensure_sufficient_buffer_space(out, required_buffer_space)) {
return aws_raise_error(AWS_ERROR_SHORT_BUFFER);
}
memcpy(
out->buffer + starting_len_offset,
openssl_cipher->working_buffer.buffer + KEYWRAP_BLOCK_SIZE,
required_buffer_space);
/* integrity register should be the first 8 bytes of the final buffer. */
uint8_t *a = openssl_cipher->working_buffer.buffer;
/* in-place register is the plaintext. For decryption, start at the last array position (8 bytes before the end); */
uint8_t *r = out->buffer + starting_len_offset + required_buffer_space - KEYWRAP_BLOCK_SIZE;
int n = (int)(required_buffer_space / KEYWRAP_BLOCK_SIZE);
uint8_t b_buf[KEYWRAP_BLOCK_SIZE * 10] = {0};
struct aws_byte_buf b = aws_byte_buf_from_empty_array(b_buf, sizeof(b_buf));
int b_out_len = b.capacity;
uint8_t temp_buf[KEYWRAP_BLOCK_SIZE * 2] = {0};
struct aws_byte_buf temp_input = aws_byte_buf_from_empty_array(temp_buf, sizeof(temp_buf));
for (int j = 5; j >= 0; --j) {
for (int i = n; i >= 1; --i) {
/* concat A and T */
memcpy(temp_input.buffer, a, KEYWRAP_BLOCK_SIZE);
unsigned char t = (unsigned char)((n * j) + i);
temp_input.buffer[7] ^= t;
/* R[i] */
memcpy(temp_input.buffer + KEYWRAP_BLOCK_SIZE, r, KEYWRAP_BLOCK_SIZE);
/* Decrypt the concatenated buffer */
if (!EVP_DecryptUpdate(
openssl_cipher->decryptor_ctx, b.buffer, &b_out_len, temp_input.buffer, (int)temp_input.capacity)) {
cipher->good = false;
return aws_raise_error(AWS_ERROR_INVALID_ARGUMENT);
}
/* set A to 64 MSB of decrypted result */
memcpy(a, b.buffer, KEYWRAP_BLOCK_SIZE);
/* set the R[i] to the 64 LSB of decrypted result */
memcpy(r, b.buffer + KEYWRAP_BLOCK_SIZE, KEYWRAP_BLOCK_SIZE);
/* decrement i -> R[i] */
r -= KEYWRAP_BLOCK_SIZE;
}
/* reset R */
r = out->buffer + starting_len_offset + required_buffer_space - KEYWRAP_BLOCK_SIZE;
}
/* here we perform the integrity check to make sure A == 0xA6A6A6A6A6A6A6A6 */
for (size_t i = 0; i < KEYWRAP_BLOCK_SIZE; ++i) {
if (a[i] != INTEGRITY_VALUE) {
cipher->good = false;
return aws_raise_error(AWS_ERROR_CAL_SIGNATURE_VALIDATION_FAILED);
}
}
out->len += required_buffer_space;
return AWS_OP_SUCCESS;
}
static int s_init_keywrap_cipher_materials(struct aws_symmetric_cipher *cipher) {
struct openssl_aes_cipher *openssl_cipher = cipher->impl;
if (!(EVP_EncryptInit_ex(openssl_cipher->encryptor_ctx, EVP_aes_256_ecb(), NULL, cipher->key.buffer, NULL) &&
EVP_CIPHER_CTX_set_padding(openssl_cipher->encryptor_ctx, 0)) ||
!(EVP_DecryptInit_ex(openssl_cipher->decryptor_ctx, EVP_aes_256_ecb(), NULL, cipher->key.buffer, NULL) &&
EVP_CIPHER_CTX_set_padding(openssl_cipher->decryptor_ctx, 0))) {
cipher->good = false;
return aws_raise_error(AWS_ERROR_INVALID_ARGUMENT);
}
return AWS_OP_SUCCESS;
}
static int s_reset_keywrap_cipher_materials(struct aws_symmetric_cipher *cipher) {
int ret_val = s_clear_reusable_state(cipher);
if (ret_val == AWS_OP_SUCCESS) {
return s_init_keywrap_cipher_materials(cipher);
}
return ret_val;
}
static struct aws_symmetric_cipher_vtable s_keywrap_vtable = {
.alg_name = "AES-KEYWRAP 256",
.provider = "OpenSSL Compatible LibCrypto",
.destroy = s_destroy,
.reset = s_reset_keywrap_cipher_materials,
.decrypt = s_key_wrap_encrypt_decrypt,
.encrypt = s_key_wrap_encrypt_decrypt,
.finalize_decryption = s_key_wrap_finalize_decryption,
.finalize_encryption = s_key_wrap_finalize_encryption,
};
struct aws_symmetric_cipher *aws_aes_keywrap_256_new_impl(
struct aws_allocator *allocator,
const struct aws_byte_cursor *key) {
struct openssl_aes_cipher *cipher = aws_mem_calloc(allocator, 1, sizeof(struct openssl_aes_cipher));
cipher->cipher_base.allocator = allocator;
cipher->cipher_base.block_size = KEYWRAP_BLOCK_SIZE;
cipher->cipher_base.key_length_bits = AWS_AES_256_KEY_BIT_LEN;
cipher->cipher_base.vtable = &s_keywrap_vtable;
cipher->cipher_base.impl = cipher;
/* Copy key into the cipher context. */
if (key) {
aws_byte_buf_init_copy_from_cursor(&cipher->cipher_base.key, allocator, *key);
} else {
aws_byte_buf_init(&cipher->cipher_base.key, allocator, AWS_AES_256_KEY_BYTE_LEN);
aws_symmetric_cipher_generate_key(AWS_AES_256_KEY_BYTE_LEN, &cipher->cipher_base.key);
}
aws_byte_buf_init(&cipher->working_buffer, allocator, KEYWRAP_BLOCK_SIZE);
/* Initialize the cipher contexts. */
cipher->encryptor_ctx = EVP_CIPHER_CTX_new();
AWS_FATAL_ASSERT(cipher->encryptor_ctx && "Encryptor cipher initialization failed!");
cipher->decryptor_ctx = EVP_CIPHER_CTX_new();
AWS_FATAL_ASSERT(cipher->decryptor_ctx && "Decryptor cipher initialization failed!");
/* Initialize the cipher contexts with the specified key and IV. */
if (s_init_keywrap_cipher_materials(&cipher->cipher_base)) {
goto error;
}
cipher->cipher_base.good = true;
return &cipher->cipher_base;
error:
s_destroy(&cipher->cipher_base);
return NULL;
}
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