mbedtls/tests/suites/test_suite_ccm.function

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/* BEGIN_HEADER */
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#include "mbedtls/ccm.h"
/* Use the multipart interface to process the encrypted data in two parts
* and check that the output matches the expected output.
* The context must have been set up with the key. */
static int check_multipart(mbedtls_ccm_context *ctx,
int mode,
const data_t *iv,
const data_t *add,
const data_t *input,
const data_t *expected_output,
const data_t *tag,
size_t n1,
size_t n1_add)
{
int ok = 0;
uint8_t *output = NULL;
size_t n2 = input->len - n1;
size_t n2_add = add->len - n1_add;
size_t olen;
/* Sanity checks on the test data */
TEST_ASSERT(n1 <= input->len);
TEST_ASSERT(n1_add <= add->len);
TEST_EQUAL(input->len, expected_output->len);
TEST_EQUAL(0, mbedtls_ccm_starts(ctx, mode, iv->x, iv->len));
TEST_EQUAL(0, mbedtls_ccm_set_lengths(ctx, add->len, input->len, tag->len));
TEST_EQUAL(0, mbedtls_ccm_update_ad(ctx, add->x, n1_add));
TEST_EQUAL(0, mbedtls_ccm_update_ad(ctx, add->x + n1_add, n2_add));
/* Allocate a tight buffer for each update call. This way, if the function
* tries to write beyond the advertised required buffer size, this will
* count as an overflow for memory sanitizers and static checkers. */
ASSERT_ALLOC(output, n1);
olen = 0xdeadbeef;
TEST_EQUAL(0, mbedtls_ccm_update(ctx, input->x, n1, output, n1, &olen));
TEST_EQUAL(n1, olen);
ASSERT_COMPARE(output, olen, expected_output->x, n1);
mbedtls_free(output);
output = NULL;
ASSERT_ALLOC(output, n2);
olen = 0xdeadbeef;
TEST_EQUAL(0, mbedtls_ccm_update(ctx, input->x + n1, n2, output, n2, &olen));
TEST_EQUAL(n2, olen);
ASSERT_COMPARE(output, olen, expected_output->x + n1, n2);
mbedtls_free(output);
output = NULL;
ASSERT_ALLOC(output, tag->len);
TEST_EQUAL(0, mbedtls_ccm_finish(ctx, output, tag->len));
ASSERT_COMPARE(output, tag->len, tag->x, tag->len);
mbedtls_free(output);
output = NULL;
ok = 1;
exit:
mbedtls_free(output);
return ok;
}
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/* END_HEADER */
/* BEGIN_DEPENDENCIES
* depends_on:MBEDTLS_CCM_C
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* END_DEPENDENCIES
*/
/* BEGIN_CASE depends_on:MBEDTLS_SELF_TEST:MBEDTLS_AES_C */
void mbedtls_ccm_self_test()
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{
TEST_ASSERT(mbedtls_ccm_self_test(1) == 0);
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}
/* END_CASE */
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/* BEGIN_CASE */
void mbedtls_ccm_setkey(int cipher_id, int key_size, int result)
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{
mbedtls_ccm_context ctx;
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unsigned char key[32];
int ret;
mbedtls_ccm_init(&ctx);
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memset(key, 0x2A, sizeof(key));
TEST_ASSERT((unsigned) key_size <= 8 * sizeof(key));
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ret = mbedtls_ccm_setkey(&ctx, cipher_id, key, key_size);
TEST_ASSERT(ret == result);
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exit:
mbedtls_ccm_free(&ctx);
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}
/* END_CASE */
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/* BEGIN_CASE depends_on:MBEDTLS_AES_C */
void ccm_lengths(int msg_len, int iv_len, int add_len, int tag_len, int res)
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{
mbedtls_ccm_context ctx;
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unsigned char key[16];
unsigned char msg[10];
unsigned char iv[14];
unsigned char *add = NULL;
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unsigned char out[10];
unsigned char tag[18];
int decrypt_ret;
mbedtls_ccm_init(&ctx);
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ASSERT_ALLOC_WEAK(add, add_len);
memset(key, 0, sizeof(key));
memset(msg, 0, sizeof(msg));
memset(iv, 0, sizeof(iv));
memset(out, 0, sizeof(out));
memset(tag, 0, sizeof(tag));
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TEST_ASSERT(mbedtls_ccm_setkey(&ctx, MBEDTLS_CIPHER_ID_AES,
key, 8 * sizeof(key)) == 0);
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TEST_ASSERT(mbedtls_ccm_encrypt_and_tag(&ctx, msg_len, iv, iv_len, add, add_len,
msg, out, tag, tag_len) == res);
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decrypt_ret = mbedtls_ccm_auth_decrypt(&ctx, msg_len, iv, iv_len, add, add_len,
msg, out, tag, tag_len);
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if (res == 0) {
TEST_ASSERT(decrypt_ret == MBEDTLS_ERR_CCM_AUTH_FAILED);
} else {
TEST_ASSERT(decrypt_ret == res);
}
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exit:
mbedtls_free(add);
mbedtls_ccm_free(&ctx);
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}
/* END_CASE */
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/* BEGIN_CASE depends_on:MBEDTLS_AES_C */
void ccm_star_lengths(int msg_len, int iv_len, int add_len, int tag_len,
int res)
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{
mbedtls_ccm_context ctx;
unsigned char key[16];
unsigned char msg[10];
unsigned char iv[14];
unsigned char add[10];
unsigned char out[10];
unsigned char tag[18];
int decrypt_ret;
mbedtls_ccm_init(&ctx);
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memset(key, 0, sizeof(key));
memset(msg, 0, sizeof(msg));
memset(iv, 0, sizeof(iv));
memset(add, 0, sizeof(add));
memset(out, 0, sizeof(out));
memset(tag, 0, sizeof(tag));
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TEST_ASSERT(mbedtls_ccm_setkey(&ctx, MBEDTLS_CIPHER_ID_AES,
key, 8 * sizeof(key)) == 0);
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TEST_ASSERT(mbedtls_ccm_star_encrypt_and_tag(&ctx, msg_len, iv, iv_len,
add, add_len, msg, out, tag, tag_len) == res);
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decrypt_ret = mbedtls_ccm_star_auth_decrypt(&ctx, msg_len, iv, iv_len, add,
add_len, msg, out, tag, tag_len);
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if (res == 0 && tag_len != 0) {
TEST_ASSERT(decrypt_ret == MBEDTLS_ERR_CCM_AUTH_FAILED);
} else {
TEST_ASSERT(decrypt_ret == res);
}
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exit:
mbedtls_ccm_free(&ctx);
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}
/* END_CASE */
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/* BEGIN_CASE */
void mbedtls_ccm_encrypt_and_tag(int cipher_id, data_t *key,
data_t *msg, data_t *iv,
data_t *add, data_t *result)
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{
mbedtls_ccm_context ctx;
size_t n1, n1_add;
uint8_t *io_msg_buf = NULL;
uint8_t *tag_buf = NULL;
const size_t expected_tag_len = result->len - msg->len;
const uint8_t *expected_tag = result->x + msg->len;
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/* Prepare input/output message buffer */
ASSERT_ALLOC(io_msg_buf, msg->len);
if (msg->len != 0) {
memcpy(io_msg_buf, msg->x, msg->len);
}
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/* Prepare tag buffer */
ASSERT_ALLOC(tag_buf, expected_tag_len);
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mbedtls_ccm_init(&ctx);
TEST_EQUAL(mbedtls_ccm_setkey(&ctx, cipher_id, key->x, key->len * 8), 0);
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/* Test with input == output */
TEST_EQUAL(mbedtls_ccm_encrypt_and_tag(&ctx, msg->len, iv->x, iv->len, add->x, add->len,
io_msg_buf, io_msg_buf, tag_buf, expected_tag_len), 0);
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ASSERT_COMPARE(io_msg_buf, msg->len, result->x, msg->len);
ASSERT_COMPARE(tag_buf, expected_tag_len, expected_tag, expected_tag_len);
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/* Prepare data_t structures for multipart testing */
const data_t encrypted_expected = { .x = result->x,
.len = msg->len };
const data_t tag_expected = { .x = (uint8_t *) expected_tag, /* cast to conform with data_t x type */
.len = expected_tag_len };
for (n1 = 0; n1 <= msg->len; n1 += 1) {
for (n1_add = 0; n1_add <= add->len; n1_add += 1) {
mbedtls_test_set_step(n1 * 10000 + n1_add);
if (!check_multipart(&ctx, MBEDTLS_CCM_ENCRYPT,
iv, add, msg,
&encrypted_expected,
&tag_expected,
n1, n1_add)) {
goto exit;
}
}
}
exit:
mbedtls_ccm_free(&ctx);
mbedtls_free(io_msg_buf);
mbedtls_free(tag_buf);
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}
/* END_CASE */
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/* BEGIN_CASE */
void mbedtls_ccm_star_no_tag(int cipher_id, int mode, data_t *key,
data_t *msg, data_t *iv, data_t *result)
{
mbedtls_ccm_context ctx;
uint8_t *output = NULL;
size_t olen;
mbedtls_ccm_init(&ctx);
TEST_EQUAL(mbedtls_ccm_setkey(&ctx, cipher_id, key->x, key->len * 8), 0);
TEST_EQUAL(0, mbedtls_ccm_starts(&ctx, mode, iv->x, iv->len));
TEST_EQUAL(0, mbedtls_ccm_set_lengths(&ctx, 0, msg->len, 0));
ASSERT_ALLOC(output, msg->len);
TEST_EQUAL(0, mbedtls_ccm_update(&ctx, msg->x, msg->len, output, msg->len, &olen));
TEST_EQUAL(result->len, olen);
ASSERT_COMPARE(output, olen, result->x, result->len);
TEST_EQUAL(0, mbedtls_ccm_finish(&ctx, NULL, 0));
exit:
mbedtls_free(output);
mbedtls_ccm_free(&ctx);
}
/* END_CASE */
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/* BEGIN_CASE */
void mbedtls_ccm_auth_decrypt(int cipher_id, data_t *key,
data_t *msg, data_t *iv,
data_t *add, int expected_tag_len, int result,
data_t *expected_msg)
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{
mbedtls_ccm_context ctx;
size_t n1, n1_add;
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const size_t expected_msg_len = msg->len - expected_tag_len;
const uint8_t *expected_tag = msg->x + expected_msg_len;
/* Prepare input/output message buffer */
uint8_t *io_msg_buf = NULL;
ASSERT_ALLOC(io_msg_buf, expected_msg_len);
if (expected_msg_len) {
memcpy(io_msg_buf, msg->x, expected_msg_len);
}
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mbedtls_ccm_init(&ctx);
TEST_EQUAL(mbedtls_ccm_setkey(&ctx, cipher_id, key->x, key->len * 8), 0);
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/* Test with input == output */
TEST_EQUAL(mbedtls_ccm_auth_decrypt(&ctx, expected_msg_len, iv->x, iv->len, add->x, add->len,
io_msg_buf, io_msg_buf, expected_tag, expected_tag_len),
result);
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if (result == 0) {
ASSERT_COMPARE(io_msg_buf, expected_msg_len, expected_msg->x, expected_msg_len);
/* Prepare data_t structures for multipart testing */
const data_t encrypted = { .x = msg->x,
.len = expected_msg_len };
const data_t tag_expected = { .x = (uint8_t *) expected_tag,
.len = expected_tag_len };
for (n1 = 0; n1 <= expected_msg_len; n1 += 1) {
for (n1_add = 0; n1_add <= add->len; n1_add += 1) {
mbedtls_test_set_step(n1 * 10000 + n1_add);
if (!check_multipart(&ctx, MBEDTLS_CCM_DECRYPT,
iv, add, &encrypted,
expected_msg,
&tag_expected,
n1, n1_add)) {
goto exit;
}
}
}
} else {
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size_t i;
for (i = 0; i < expected_msg_len; i++) {
TEST_EQUAL(io_msg_buf[i], 0);
}
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}
exit:
mbedtls_free(io_msg_buf);
mbedtls_ccm_free(&ctx);
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}
/* END_CASE */
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/* BEGIN_CASE */
void mbedtls_ccm_star_encrypt_and_tag(int cipher_id,
data_t *key, data_t *msg,
data_t *source_address, data_t *frame_counter,
int sec_level, data_t *add,
data_t *expected_result, int output_ret)
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{
unsigned char iv[13];
mbedtls_ccm_context ctx;
size_t iv_len, expected_tag_len;
size_t n1, n1_add;
uint8_t *io_msg_buf = NULL;
uint8_t *tag_buf = NULL;
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const uint8_t *expected_tag = expected_result->x + msg->len;
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/* Calculate tag length */
if (sec_level % 4 == 0) {
expected_tag_len = 0;
} else {
expected_tag_len = 1 << (sec_level % 4 + 1);
}
/* Prepare input/output message buffer */
ASSERT_ALLOC(io_msg_buf, msg->len);
if (msg->len) {
memcpy(io_msg_buf, msg->x, msg->len);
}
/* Prepare tag buffer */
if (expected_tag_len == 0) {
ASSERT_ALLOC(tag_buf, 16);
} else {
ASSERT_ALLOC(tag_buf, expected_tag_len);
}
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/* Calculate iv */
TEST_ASSERT(source_address->len == 8);
TEST_ASSERT(frame_counter->len == 4);
memcpy(iv, source_address->x, source_address->len);
memcpy(iv + source_address->len, frame_counter->x, frame_counter->len);
iv[source_address->len + frame_counter->len] = sec_level;
iv_len = sizeof(iv);
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mbedtls_ccm_init(&ctx);
TEST_EQUAL(mbedtls_ccm_setkey(&ctx, cipher_id,
key->x, key->len * 8), 0);
/* Test with input == output */
TEST_EQUAL(mbedtls_ccm_star_encrypt_and_tag(&ctx, msg->len, iv, iv_len,
add->x, add->len, io_msg_buf,
io_msg_buf, tag_buf, expected_tag_len), output_ret);
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ASSERT_COMPARE(io_msg_buf, msg->len, expected_result->x, msg->len);
ASSERT_COMPARE(tag_buf, expected_tag_len, expected_tag, expected_tag_len);
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if (output_ret == 0) {
const data_t iv_data = { .x = iv,
.len = iv_len };
const data_t encrypted_expected = { .x = expected_result->x,
.len = msg->len };
const data_t tag_expected = { .x = (uint8_t *) expected_tag,
.len = expected_tag_len };
for (n1 = 0; n1 <= msg->len; n1 += 1) {
for (n1_add = 0; n1_add <= add->len; n1_add += 1) {
mbedtls_test_set_step(n1 * 10000 + n1_add);
if (!check_multipart(&ctx, MBEDTLS_CCM_STAR_ENCRYPT,
&iv_data, add, msg,
&encrypted_expected,
&tag_expected,
n1, n1_add)) {
goto exit;
}
}
}
}
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exit:
mbedtls_ccm_free(&ctx);
mbedtls_free(io_msg_buf);
mbedtls_free(tag_buf);
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}
/* END_CASE */
/* BEGIN_CASE */
void mbedtls_ccm_star_auth_decrypt(int cipher_id,
data_t *key, data_t *msg,
data_t *source_address, data_t *frame_counter,
int sec_level, data_t *add,
data_t *expected_result, int output_ret)
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{
unsigned char iv[13];
mbedtls_ccm_context ctx;
size_t iv_len, expected_tag_len;
size_t n1, n1_add;
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/* Calculate tag length */
if (sec_level % 4 == 0) {
expected_tag_len = 0;
} else {
expected_tag_len = 1 << (sec_level % 4 + 1);
}
const size_t expected_msg_len = msg->len - expected_tag_len;
const uint8_t *expected_tag = msg->x + expected_msg_len;
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/* Prepare input/output message buffer */
uint8_t *io_msg_buf = NULL;
ASSERT_ALLOC(io_msg_buf, expected_msg_len);
if (expected_msg_len) {
memcpy(io_msg_buf, msg->x, expected_msg_len);
}
/* Calculate iv */
memset(iv, 0x00, sizeof(iv));
TEST_ASSERT(source_address->len == 8);
TEST_ASSERT(frame_counter->len == 4);
memcpy(iv, source_address->x, source_address->len);
memcpy(iv + source_address->len, frame_counter->x, frame_counter->len);
iv[source_address->len + frame_counter->len] = sec_level;
iv_len = sizeof(iv);
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mbedtls_ccm_init(&ctx);
TEST_ASSERT(mbedtls_ccm_setkey(&ctx, cipher_id, key->x, key->len * 8) == 0);
/* Test with input == output */
TEST_EQUAL(mbedtls_ccm_star_auth_decrypt(&ctx, expected_msg_len, iv, iv_len,
add->x, add->len, io_msg_buf, io_msg_buf,
expected_tag, expected_tag_len), output_ret);
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ASSERT_COMPARE(io_msg_buf, expected_msg_len, expected_result->x, expected_msg_len);
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if (output_ret == 0) {
const data_t iv_data = { .x = iv,
.len = iv_len };
const data_t encrypted = { .x = msg->x,
.len = expected_msg_len };
const data_t tag_expected = { .x = (uint8_t *) expected_tag,
.len = expected_tag_len };
for (n1 = 0; n1 <= expected_msg_len; n1 += 1) {
for (n1_add = 0; n1_add <= add->len; n1_add += 1) {
mbedtls_test_set_step(n1 * 10000 + n1_add);
if (!check_multipart(&ctx, MBEDTLS_CCM_STAR_DECRYPT,
&iv_data, add, &encrypted,
expected_result,
&tag_expected,
n1, n1_add)) {
goto exit;
}
}
}
}
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exit:
mbedtls_ccm_free(&ctx);
mbedtls_free(io_msg_buf);
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}
/* END_CASE */
/* Skip auth data, provide full text */
/* BEGIN_CASE */
void mbedtls_ccm_skip_ad(int cipher_id, int mode,
data_t *key, data_t *msg, data_t *iv,
data_t *result, data_t *tag)
{
mbedtls_ccm_context ctx;
uint8_t *output = NULL;
size_t olen;
/* Sanity checks on the test data */
TEST_EQUAL(msg->len, result->len);
mbedtls_ccm_init(&ctx);
TEST_EQUAL(mbedtls_ccm_setkey(&ctx, cipher_id, key->x, key->len * 8), 0);
TEST_EQUAL(0, mbedtls_ccm_starts(&ctx, mode, iv->x, iv->len));
TEST_EQUAL(0, mbedtls_ccm_set_lengths(&ctx, 0, msg->len, tag->len));
ASSERT_ALLOC(output, result->len);
olen = 0xdeadbeef;
TEST_EQUAL(0, mbedtls_ccm_update(&ctx, msg->x, msg->len, output, result->len, &olen));
TEST_EQUAL(result->len, olen);
ASSERT_COMPARE(output, olen, result->x, result->len);
mbedtls_free(output);
output = NULL;
ASSERT_ALLOC(output, tag->len);
TEST_EQUAL(0, mbedtls_ccm_finish(&ctx, output, tag->len));
ASSERT_COMPARE(output, tag->len, tag->x, tag->len);
mbedtls_free(output);
output = NULL;
exit:
mbedtls_free(output);
mbedtls_ccm_free(&ctx);
}
/* END_CASE */
/* Provide auth data, skip full text */
/* BEGIN_CASE */
void mbedtls_ccm_skip_update(int cipher_id, int mode,
data_t *key, data_t *iv, data_t *add,
data_t *tag)
{
mbedtls_ccm_context ctx;
uint8_t *output = NULL;
mbedtls_ccm_init(&ctx);
TEST_EQUAL(mbedtls_ccm_setkey(&ctx, cipher_id, key->x, key->len * 8), 0);
TEST_EQUAL(0, mbedtls_ccm_starts(&ctx, mode, iv->x, iv->len));
TEST_EQUAL(0, mbedtls_ccm_set_lengths(&ctx, add->len, 0, tag->len));
TEST_EQUAL(0, mbedtls_ccm_update_ad(&ctx, add->x, add->len));
ASSERT_ALLOC(output, tag->len);
TEST_EQUAL(0, mbedtls_ccm_finish(&ctx, output, tag->len));
ASSERT_COMPARE(output, tag->len, tag->x, tag->len);
mbedtls_free(output);
output = NULL;
exit:
mbedtls_free(output);
mbedtls_ccm_free(&ctx);
}
/* END_CASE */
/* Provide too much auth data */
/* BEGIN_CASE */
void mbedtls_ccm_overflow_ad(int cipher_id, int mode,
data_t *key, data_t *iv,
data_t *add)
{
mbedtls_ccm_context ctx;
mbedtls_ccm_init(&ctx);
TEST_EQUAL(mbedtls_ccm_setkey(&ctx, cipher_id, key->x, key->len * 8), 0);
TEST_EQUAL(0, mbedtls_ccm_starts(&ctx, mode, iv->x, iv->len));
// use hardcoded values for msg length and tag length. They are not a part of this test
// subtract 1 from configured auth data length to provoke an overflow
TEST_EQUAL(0, mbedtls_ccm_set_lengths(&ctx, add->len - 1, 16, 16));
TEST_EQUAL(MBEDTLS_ERR_CCM_BAD_INPUT, mbedtls_ccm_update_ad(&ctx, add->x, add->len));
exit:
mbedtls_ccm_free(&ctx);
}
/* END_CASE */
/* Provide unexpected auth data */
/* BEGIN_CASE */
void mbedtls_ccm_unexpected_ad(int cipher_id, int mode,
data_t *key, data_t *iv,
data_t *add)
{
mbedtls_ccm_context ctx;
mbedtls_ccm_init(&ctx);
TEST_EQUAL(mbedtls_ccm_setkey(&ctx, cipher_id, key->x, key->len * 8), 0);
TEST_EQUAL(0, mbedtls_ccm_starts(&ctx, mode, iv->x, iv->len));
// use hardcoded values for msg length and tag length. They are not a part of this test
TEST_EQUAL(0, mbedtls_ccm_set_lengths(&ctx, 0, 16, 16));
TEST_EQUAL(MBEDTLS_ERR_CCM_BAD_INPUT, mbedtls_ccm_update_ad(&ctx, add->x, add->len));
exit:
mbedtls_ccm_free(&ctx);
}
/* END_CASE */
/* Provide unexpected plaintext/ciphertext data */
/* BEGIN_CASE */
void mbedtls_ccm_unexpected_text(int cipher_id, int mode,
data_t *key, data_t *msg, data_t *iv,
data_t *add)
{
mbedtls_ccm_context ctx;
uint8_t *output = NULL;
size_t olen;
mbedtls_ccm_init(&ctx);
TEST_EQUAL(mbedtls_ccm_setkey(&ctx, cipher_id, key->x, key->len * 8), 0);
TEST_EQUAL(0, mbedtls_ccm_starts(&ctx, mode, iv->x, iv->len));
// use hardcoded value for tag length. It is not a part of this test
TEST_EQUAL(0, mbedtls_ccm_set_lengths(&ctx, add->len, 0, 16));
TEST_EQUAL(0, mbedtls_ccm_update_ad(&ctx, add->x, add->len));
ASSERT_ALLOC(output, msg->len);
olen = 0xdeadbeef;
TEST_EQUAL(MBEDTLS_ERR_CCM_BAD_INPUT,
mbedtls_ccm_update(&ctx, msg->x, msg->len, output, msg->len, &olen));
exit:
mbedtls_free(output);
mbedtls_ccm_free(&ctx);
}
/* END_CASE */
/* Provide incomplete auth data and finish */
/* BEGIN_CASE */
void mbedtls_ccm_incomplete_ad(int cipher_id, int mode,
data_t *key, data_t *iv, data_t *add)
{
mbedtls_ccm_context ctx;
uint8_t *output = NULL;
mbedtls_ccm_init(&ctx);
TEST_EQUAL(mbedtls_ccm_setkey(&ctx, cipher_id, key->x, key->len * 8), 0);
TEST_EQUAL(0, mbedtls_ccm_starts(&ctx, mode, iv->x, iv->len));
// use hardcoded values for msg length and tag length. They are not a part of this test
TEST_EQUAL(0, mbedtls_ccm_set_lengths(&ctx, add->len, 0, 16));
TEST_EQUAL(0, mbedtls_ccm_update_ad(&ctx, add->x, add->len - 1));
ASSERT_ALLOC(output, 16);
TEST_EQUAL(MBEDTLS_ERR_CCM_BAD_INPUT, mbedtls_ccm_finish(&ctx, output, 16));
exit:
mbedtls_free(output);
mbedtls_ccm_free(&ctx);
}
/* END_CASE */
/* Provide complete auth data on first update_ad.
* Provide unexpected auth data on second update_ad */
/* BEGIN_CASE */
void mbedtls_ccm_full_ad_and_overflow(int cipher_id, int mode,
data_t *key, data_t *iv,
data_t *add)
{
mbedtls_ccm_context ctx;
mbedtls_ccm_init(&ctx);
TEST_EQUAL(mbedtls_ccm_setkey(&ctx, cipher_id, key->x, key->len * 8), 0);
TEST_EQUAL(0, mbedtls_ccm_starts(&ctx, mode, iv->x, iv->len));
// use hardcoded values for msg length and tag length. They are not a part of this test
TEST_EQUAL(0, mbedtls_ccm_set_lengths(&ctx, add->len, 16, 16));
// pass full auth data
TEST_EQUAL(0, mbedtls_ccm_update_ad(&ctx, add->x, add->len));
// pass 1 extra byte
TEST_EQUAL(MBEDTLS_ERR_CCM_BAD_INPUT, mbedtls_ccm_update_ad(&ctx, add->x, 1));
exit:
mbedtls_ccm_free(&ctx);
}
/* END_CASE */
/* Provide incomplete auth data on first update_ad.
* Provide too much auth data on second update_ad */
/* BEGIN_CASE */
void mbedtls_ccm_incomplete_ad_and_overflow(int cipher_id, int mode,
data_t *key, data_t *iv,
data_t *add)
{
mbedtls_ccm_context ctx;
uint8_t add_second_buffer[2];
add_second_buffer[0] = add->x[add->len - 1];
add_second_buffer[1] = 0xAB; // some magic value
mbedtls_ccm_init(&ctx);
TEST_EQUAL(mbedtls_ccm_setkey(&ctx, cipher_id, key->x, key->len * 8), 0);
TEST_EQUAL(0, mbedtls_ccm_starts(&ctx, mode, iv->x, iv->len));
// use hardcoded values for msg length and tag length. They are not a part of this test
TEST_EQUAL(0, mbedtls_ccm_set_lengths(&ctx, add->len, 16, 16));
// pass incomplete auth data
TEST_EQUAL(0, mbedtls_ccm_update_ad(&ctx, add->x, add->len - 1));
// pass 2 extra bytes (1 missing byte from previous incomplete pass, and 1 unexpected byte)
TEST_EQUAL(MBEDTLS_ERR_CCM_BAD_INPUT, mbedtls_ccm_update_ad(&ctx, add_second_buffer, 2));
exit:
mbedtls_ccm_free(&ctx);
}
/* END_CASE */
/* Provide too much plaintext/ciphertext */
/* BEGIN_CASE */
void mbedtls_ccm_overflow_update(int cipher_id, int mode,
data_t *key, data_t *msg, data_t *iv,
data_t *add)
{
mbedtls_ccm_context ctx;
uint8_t *output = NULL;
size_t olen;
mbedtls_ccm_init(&ctx);
TEST_EQUAL(mbedtls_ccm_setkey(&ctx, cipher_id, key->x, key->len * 8), 0);
TEST_EQUAL(0, mbedtls_ccm_starts(&ctx, mode, iv->x, iv->len));
// use hardcoded value for tag length. It is a not a part of this test
// subtract 1 from configured msg length to provoke an overflow
TEST_EQUAL(0, mbedtls_ccm_set_lengths(&ctx, add->len, msg->len - 1, 16));
TEST_EQUAL(0, mbedtls_ccm_update_ad(&ctx, add->x, add->len));
ASSERT_ALLOC(output, msg->len);
TEST_EQUAL(MBEDTLS_ERR_CCM_BAD_INPUT, \
mbedtls_ccm_update(&ctx, msg->x, msg->len, output, msg->len, &olen));
exit:
mbedtls_free(output);
mbedtls_ccm_free(&ctx);
}
/* END_CASE */
/* Provide incomplete plaintext/ciphertext and finish */
/* BEGIN_CASE */
void mbedtls_ccm_incomplete_update(int cipher_id, int mode,
data_t *key, data_t *msg, data_t *iv,
data_t *add)
{
mbedtls_ccm_context ctx;
uint8_t *output = NULL;
size_t olen;
mbedtls_ccm_init(&ctx);
TEST_EQUAL(mbedtls_ccm_setkey(&ctx, cipher_id, key->x, key->len * 8), 0);
TEST_EQUAL(0, mbedtls_ccm_starts(&ctx, mode, iv->x, iv->len));
// use hardcoded value for tag length. It is not a part of this test
TEST_EQUAL(0, mbedtls_ccm_set_lengths(&ctx, add->len, msg->len, 16));
TEST_EQUAL(0, mbedtls_ccm_update_ad(&ctx, add->x, add->len));
ASSERT_ALLOC(output, msg->len);
olen = 0xdeadbeef;
TEST_EQUAL(0, mbedtls_ccm_update(&ctx, msg->x, msg->len - 1, output, msg->len, &olen));
mbedtls_free(output);
output = NULL;
ASSERT_ALLOC(output, 16);
TEST_EQUAL(MBEDTLS_ERR_CCM_BAD_INPUT, mbedtls_ccm_finish(&ctx, output, 16));
exit:
mbedtls_free(output);
mbedtls_ccm_free(&ctx);
}
/* END_CASE */
/* Provide full plaintext/ciphertext of first update
* Provide unexpected plaintext/ciphertext on second update */
/* BEGIN_CASE */
void mbedtls_ccm_full_update_and_overflow(int cipher_id, int mode,
data_t *key, data_t *msg, data_t *iv,
data_t *add)
{
mbedtls_ccm_context ctx;
uint8_t *output = NULL;
size_t olen;
mbedtls_ccm_init(&ctx);
TEST_EQUAL(mbedtls_ccm_setkey(&ctx, cipher_id, key->x, key->len * 8), 0);
TEST_EQUAL(0, mbedtls_ccm_starts(&ctx, mode, iv->x, iv->len));
// use hardcoded value for tag length. It is a not a part of this test
TEST_EQUAL(0, mbedtls_ccm_set_lengths(&ctx, add->len, msg->len, 16));
TEST_EQUAL(0, mbedtls_ccm_update_ad(&ctx, add->x, add->len));
ASSERT_ALLOC(output, msg->len);
// pass full text
TEST_EQUAL(0, mbedtls_ccm_update(&ctx, msg->x, msg->len, output, msg->len, &olen));
// pass 1 extra byte
TEST_EQUAL(MBEDTLS_ERR_CCM_BAD_INPUT, \
mbedtls_ccm_update(&ctx, msg->x, 1, output, 1, &olen));
exit:
mbedtls_free(output);
mbedtls_ccm_free(&ctx);
}
/* END_CASE */
/* Provide incomplete plaintext/ciphertext of first update
* Provide too much plaintext/ciphertext on second update */
/* BEGIN_CASE */
void mbedtls_ccm_incomplete_update_overflow(int cipher_id, int mode,
data_t *key, data_t *msg, data_t *iv,
data_t *add)
{
mbedtls_ccm_context ctx;
uint8_t *output = NULL;
size_t olen;
uint8_t msg_second_buffer[2];
msg_second_buffer[0] = msg->x[msg->len - 1];
msg_second_buffer[1] = 0xAB; // some magic value
mbedtls_ccm_init(&ctx);
TEST_EQUAL(mbedtls_ccm_setkey(&ctx, cipher_id, key->x, key->len * 8), 0);
TEST_EQUAL(0, mbedtls_ccm_starts(&ctx, mode, iv->x, iv->len));
// use hardcoded value for tag length. It is a not a part of this test
TEST_EQUAL(0, mbedtls_ccm_set_lengths(&ctx, add->len, msg->len, 16));
TEST_EQUAL(0, mbedtls_ccm_update_ad(&ctx, add->x, add->len));
ASSERT_ALLOC(output, msg->len + 1);
// pass incomplete text
TEST_EQUAL(0, mbedtls_ccm_update(&ctx, msg->x, msg->len - 1, output, msg->len + 1, &olen));
// pass 2 extra bytes (1 missing byte from previous incomplete pass, and 1 unexpected byte)
TEST_EQUAL(MBEDTLS_ERR_CCM_BAD_INPUT, \
mbedtls_ccm_update(&ctx, msg_second_buffer, 2, output + msg->len - 1, 2, &olen));
exit:
mbedtls_free(output);
mbedtls_ccm_free(&ctx);
}
/* END_CASE */
/* Finish without passing any auth data or plaintext/ciphertext input */
/* BEGIN_CASE */
void mbedtls_ccm_instant_finish(int cipher_id, int mode,
data_t *key, data_t *iv)
{
mbedtls_ccm_context ctx;
uint8_t *output = NULL;
mbedtls_ccm_init(&ctx);
TEST_EQUAL(mbedtls_ccm_setkey(&ctx, cipher_id, key->x, key->len * 8), 0);
TEST_EQUAL(0, mbedtls_ccm_starts(&ctx, mode, iv->x, iv->len));
// use hardcoded values for add length, msg length and tag length.
// They are not a part of this test
TEST_EQUAL(0, mbedtls_ccm_set_lengths(&ctx, 16, 16, 16));
ASSERT_ALLOC(output, 16);
TEST_EQUAL(MBEDTLS_ERR_CCM_BAD_INPUT, mbedtls_ccm_finish(&ctx, output, 16));
exit:
mbedtls_free(output);
mbedtls_ccm_free(&ctx);
}
/* END_CASE */