}
static int
-test_perf_AES_GCM(void)
+test_perf_AES_GCM(int continual_buf_len, int continual_size)
{
- uint16_t i, j;
+ uint16_t i, j, k, loops = 1;
uint16_t buf_lengths[] = { 64, 128, 256, 512, 1024, 1536, 2048 };
&AES_GCM_128_12IV_0AAD
};
+ if (continual_buf_len)
+ loops = continual_size;
+
int TEST_CASES_GCM = RTE_DIM(gcm_tests);
const unsigned burst_size = 32;
params_set[i].chain = CIPHER_HASH;
params_set[i].session_attrs = &session_attrs[i];
params_set[i].symmetric_op = &ops_set[i];
- params_set[i].total_operations = 1000000;
+ if (continual_buf_len)
+ params_set[i].total_operations = 0xFFFFFF;
+ else
+ params_set[i].total_operations = 1000000;
+
params_set[i].burst_size = burst_size;
}
+ if (continual_buf_len)
+ printf("\nCipher algo: %s Cipher hash: %s cipher key size: %ub"
+ " burst size: %u", "AES_GCM", "AES_GCM",
+ gcm_test->key.len << 3, burst_size);
+
for (i = 0; i < RTE_DIM(gcm_tests); i++) {
- printf("\nCipher algo: %s Cipher hash: %s cipher key size: %ub"
+ if (!continual_buf_len) {
+ printf("\nCipher algo: %s Cipher hash: %s cipher key size: %ub"
" burst size: %u", "AES_GCM", "AES_GCM",
- gcm_test->key.len << 3, burst_size
- );
- printf("\nBuffer Size(B)\tOPS(M)\tThroughput(Gbps)\t"
- " Retries\tEmptyPolls");
+ gcm_test->key.len << 3, burst_size);
+ printf("\nBuffer Size(B)\tOPS(M)\tThroughput(Gbps)\t"
+ " Retries\tEmptyPolls");
+ }
- for (j = 0; j < RTE_DIM(buf_lengths); ++j) {
+ uint16_t len = RTE_DIM(buf_lengths);
+ uint16_t p = 0;
+
+ if (continual_buf_len) {
+ for (k = 0; k < RTE_DIM(buf_lengths); k++)
+ if (buf_lengths[k] == continual_buf_len) {
+ len = k + 1;
+ p = k;
+ break;
+ }
+ }
+ for (j = p; j < len; ++j) {
params_set[i].symmetric_op->c_len = buf_lengths[j];
params_set[i].symmetric_op->p_len = buf_lengths[j];
¶ms_set[i], 1))
return TEST_FAILED;
- if (perf_AES_GCM(testsuite_params.dev_id, 0,
- ¶ms_set[i], 0))
- return TEST_FAILED;
+ for (k = 0; k < loops; k++) {
+ if (continual_buf_len)
+ printf("\n\nBuffer Size(B)\tOPS(M)\t"
+ "Throughput(Gbps)\t"
+ "Retries\tEmptyPolls");
+ if (perf_AES_GCM(testsuite_params.dev_id, 0,
+ ¶ms_set[i], 0))
+ return TEST_FAILED;
+ if (continual_buf_len)
+ printf("\n\nCompleted loop %i of %i ...",
+ k+1, loops);
+ }
}
}
return 0;
}
+static int test_cryptodev_perf_AES_GCM(void)
+{
+ return test_perf_AES_GCM(0, 0);
+}
+/*
+ * This function calls AES GCM performance tests providing
+ * size of packet as an argument. If size of packet is not
+ * in the buf_lengths array, all sizes will be used
+ */
+static int test_continual_perf_AES_GCM(void)
+{
+ return test_perf_AES_GCM(1024, 10);
+}
+
+static int
+test_perf_continual_performance_test(void)
+{
+ unsigned int total_operations = 0xFFFFFF;
+ unsigned int total_loops = 10;
+ unsigned int burst_size = 32;
+ uint8_t i;
+
+ struct perf_test_params params_set = {
+ .total_operations = total_operations,
+ .burst_size = burst_size,
+ .buf_size = 1024,
+
+ .chain = CIPHER_HASH,
+
+ .cipher_algo = RTE_CRYPTO_CIPHER_AES_CBC,
+ .cipher_key_length = 16,
+ .auth_algo = RTE_CRYPTO_AUTH_SHA1_HMAC
+ };
+
+ for (i = 1; i <= total_loops; ++i) {
+ printf("\n%s. cipher algo: %s auth algo: %s cipher key size=%u."
+ " burst_size: %d ops\n",
+ chain_mode_name(params_set.chain),
+ cipher_algo_name(params_set.cipher_algo),
+ auth_algo_name(params_set.auth_algo),
+ params_set.cipher_key_length,
+ burst_size);
+ printf("\nBuffer Size(B)\tOPS(M)\tThroughput(Gbps)\t"
+ "Retries\tEmptyPolls\n");
+ test_perf_aes_sha(testsuite_params.dev_id, 0,
+ ¶ms_set);
+ printf("\nCompleted loop %i of %i ...", i, total_loops);
+ }
+ return 0;
+}
+
+static struct unit_test_suite cryptodev_qat_continual_testsuite = {
+ .suite_name = "Crypto Device Continual Performance Test",
+ .setup = testsuite_setup,
+ .teardown = testsuite_teardown,
+ .unit_test_cases = {
+ TEST_CASE_ST(ut_setup, ut_teardown,
+ test_perf_continual_performance_test),
+ TEST_CASE_ST(ut_setup, ut_teardown,
+ test_continual_perf_AES_GCM),
+ TEST_CASES_END() /**< NULL terminate unit test array */
+ }
+};
+
static struct unit_test_suite cryptodev_testsuite = {
.suite_name = "Crypto Device Unit Test Suite",
.setup = testsuite_setup,
TEST_CASE_ST(ut_setup, ut_teardown,
test_perf_aes_cbc_encrypt_digest_vary_pkt_size),
TEST_CASE_ST(ut_setup, ut_teardown,
- test_perf_AES_GCM),
+ test_cryptodev_perf_AES_GCM),
TEST_CASE_ST(ut_setup, ut_teardown,
test_perf_aes_cbc_vary_burst_size),
TEST_CASES_END() /**< NULL terminate unit test array */
.teardown = testsuite_teardown,
.unit_test_cases = {
TEST_CASE_ST(ut_setup, ut_teardown,
- test_perf_AES_GCM),
+ test_cryptodev_perf_AES_GCM),
TEST_CASES_END() /**< NULL terminate unit test array */
}
};
return unit_test_suite_runner(&cryptodev_libcrypto_testsuite);
}
+static int
+perftest_qat_continual_cryptodev(void)
+{
+ gbl_cryptodev_perftest_devtype = RTE_CRYPTODEV_QAT_SYM_PMD;
+
+ return unit_test_suite_runner(&cryptodev_qat_continual_testsuite);
+}
+
REGISTER_TEST_COMMAND(cryptodev_aesni_mb_perftest, perftest_aesni_mb_cryptodev);
REGISTER_TEST_COMMAND(cryptodev_qat_perftest, perftest_qat_cryptodev);
REGISTER_TEST_COMMAND(cryptodev_sw_snow3g_perftest, perftest_sw_snow3g_cryptodev);
REGISTER_TEST_COMMAND(cryptodev_aesni_gcm_perftest, perftest_aesni_gcm_cryptodev);
REGISTER_TEST_COMMAND(cryptodev_libcrypto_perftest,
perftest_libcrypto_cryptodev);
+REGISTER_TEST_COMMAND(cryptodev_qat_continual_perftest,
+ perftest_qat_continual_cryptodev);
git.droids-corp.org / dpdk.git / commitdiff