UT for occupancy per ioclass utils

Signed-off-by: Michal Mielewczyk <michal.mielewczyk@intel.com>
2020-11-16 04:42:32 -05:00 · 2020-11-16 04:42:32 -05:00 · 418303eee8
commit 418303eee8
parent 05f3c22dad
1 changed files with 516 additions and 0 deletions
--- a/tests/unit/tests/utils/utils_part.c/ocf_part_evict_size.c
+++ b/tests/unit/tests/utils/utils_part.c/ocf_part_evict_size.c
@ -0,0 +1,516 @@
 /*
 * <tested_file_path>src/utils/utils_part.c</tested_file_path>
 * <tested_function>ocf_part_evict_size</tested_function>
 * <functions_to_leave>
 *	INSERT HERE LIST OF FUNCTIONS YOU WANT TO LEAVE
 *	ONE FUNCTION PER LINE
 * </functions_to_leave>
 */
 #undef static
 #undef inline
 #include <stdarg.h>
 #include <stddef.h>
 #include <setjmp.h>
 #include <cmocka.h>
 #include "print_desc.h"
 #include "ocf/ocf.h"
 #include "../ocf_cache_priv.h"
 #include "../ocf_request.h"
 #include "../metadata/metadata.h"
 #include "../engine/cache_engine.h"
 #include "../eviction/ops.h"
 #include "utils_part.h"
 #include "utils/utils_part.c/ocf_part_evict_size_generated_wraps.c"
 uint32_t __wrap_ocf_part_get_max_size(ocf_cache_t cache,
 		struct ocf_user_part *target_part)
 {
 	return mock();
 }
 uint32_t __wrap_ocf_engine_repart_count(struct ocf_request *req)
 {
 	return mock();
 }
 uint32_t __wrap_ocf_engine_unmapped_count(struct ocf_request *req)
 {
 	return mock();
 }
 uint32_t __wrap_ocf_part_get_occupancy(struct ocf_user_part *target_part)
 {
 	return mock();
 }
 ocf_cache_line_t __wrap_ocf_freelist_num_free(ocf_freelist_t freelist)
 {
 	return mock();
 }
 void __wrap_ocf_req_set_part_evict(struct ocf_request *req)
 {
 	function_called();
 }
 void __wrap_ocf_req_clear_part_evict(struct ocf_request *req)
 {
 	function_called();
 }
 static void ocf_part_evict_size_test01(void **state)
 {
 	uint32_t max_part_size = 1024;
 	uint32_t cachelines_to_repart = 0;
 	uint32_t cachelines_to_map = 320;
 	uint32_t part_occupied_cachelines = 512;
 	uint32_t freelist_size = 500;
 	struct ocf_request req;
 	req.cache = test_malloc(sizeof(struct ocf_cache));
 	print_test_description("Enough free space available");
 	will_return(__wrap_ocf_part_get_max_size, max_part_size);
 	will_return(__wrap_ocf_engine_unmapped_count, cachelines_to_map);
 	will_return(__wrap_ocf_engine_repart_count, cachelines_to_repart);
 	will_return(__wrap_ocf_part_get_occupancy, part_occupied_cachelines);
 	// Enough free cachelines to map a whole request
 	will_return(__wrap_ocf_freelist_num_free, freelist_size);
 	will_return(__wrap_ocf_engine_unmapped_count, cachelines_to_map);
 	assert_int_equal(ocf_part_evict_size(&req), 0);
 	test_free(req.cache);
 }
 static void ocf_part_evict_size_test02(void **state)
 {
 	uint32_t max_part_size = 1024;
 	uint32_t cachelines_to_repart = 0;
 	uint32_t cachelines_to_map = 320;
 	uint32_t part_occupied_cachelines = 960;
 	uint32_t freelist_size = 500;
 	struct ocf_request req;
 	req.cache = test_malloc(sizeof(struct ocf_cache));
 	uint32_t available_cachelines = max_part_size - part_occupied_cachelines;
 	uint32_t cachelines_to_evict = cachelines_to_map - available_cachelines;
 	print_test_description("Cache has enough free cachelines,"
 		   " but target partition must be evicted");
 	will_return(__wrap_ocf_part_get_max_size, max_part_size);
 	will_return(__wrap_ocf_engine_unmapped_count, cachelines_to_map);
 	will_return(__wrap_ocf_engine_repart_count, cachelines_to_repart);
 	will_return(__wrap_ocf_part_get_occupancy, part_occupied_cachelines);
 	will_return(__wrap_ocf_freelist_num_free, freelist_size);
 	will_return(__wrap_ocf_engine_unmapped_count, cachelines_to_map);
 	expect_function_call(__wrap_ocf_req_set_part_evict);
 	assert_int_equal(ocf_part_evict_size(&req), cachelines_to_evict);
 	test_free(req.cache);
 }
 static void ocf_part_evict_size_test03(void **state)
 {
 	uint32_t max_part_size = 1024;
 	uint32_t cachelines_to_repart = 320;
 	uint32_t cachelines_to_map = 0;
 	uint32_t part_occupied_cachelines = 512;
 	uint32_t freelist_size = 0;
 	struct ocf_request req;
 	req.cache = test_malloc(sizeof(struct ocf_cache));
 	uint32_t cachelines_to_evict = 0;
 	print_test_description("Only repart (no mapping). Freelist is empty but "
 			"space in a target part is availabe,");
 	print_test_description("\tso no cachelines should be "
 			" evcited from cache");
 	will_return(__wrap_ocf_part_get_max_size, max_part_size);
 	will_return(__wrap_ocf_engine_unmapped_count, cachelines_to_map);
 	will_return(__wrap_ocf_engine_repart_count, cachelines_to_repart);
 	will_return(__wrap_ocf_part_get_occupancy, part_occupied_cachelines);
 	will_return(__wrap_ocf_freelist_num_free, freelist_size);
 	will_return(__wrap_ocf_engine_unmapped_count, cachelines_to_map);
 	assert_int_equal(ocf_part_evict_size(&req), cachelines_to_evict);
 	test_free(req.cache);
 }
 static void ocf_part_evict_size_test04(void **state)
 {
 	uint32_t max_part_size = 1024;
 	uint32_t cachelines_to_repart = 320;
 	uint32_t cachelines_to_map = 0;
 	uint32_t part_occupied_cachelines = 1100;
 	uint32_t freelist_size = 0;
 	struct ocf_request req;
 	req.cache = test_malloc(sizeof(struct ocf_cache));
 	uint32_t cachelines_debt = part_occupied_cachelines - max_part_size;
 	uint32_t cachelines_to_evict = cachelines_to_repart + cachelines_debt;
 	print_test_description("Only repart (no mapping). Freelist is empty and no"
 			" space in target part is availabe.");
 	print_test_description("\tEvict only from target partition");
 	will_return(__wrap_ocf_part_get_max_size, max_part_size);
 	will_return(__wrap_ocf_engine_unmapped_count, cachelines_to_map);
 	will_return(__wrap_ocf_engine_repart_count, cachelines_to_repart);
 	will_return(__wrap_ocf_part_get_occupancy, part_occupied_cachelines);
 	will_return(__wrap_ocf_freelist_num_free, freelist_size);
 	will_return(__wrap_ocf_engine_unmapped_count, cachelines_to_map);
 	expect_function_call(__wrap_ocf_req_set_part_evict);
 	assert_int_equal(ocf_part_evict_size(&req), cachelines_to_evict);
 	test_free(req.cache);
 }
 static void ocf_part_evict_size_test05(void **state)
 {
 	uint32_t max_part_size = 1024;
 	uint32_t cachelines_to_repart = 0;
 	uint32_t cachelines_to_map = 320;
 	uint32_t part_occupied_cachelines = 960;
 	uint32_t freelist_size = 0;
 	struct ocf_request req;
 	req.cache = test_malloc(sizeof(struct ocf_cache));
 	uint32_t available_cachelines = max_part_size - part_occupied_cachelines;
 	uint32_t cachelines_to_evict = cachelines_to_map - available_cachelines;
 	print_test_description("Freelist is empty and no space in the target part "
 			"is available");
 	will_return(__wrap_ocf_part_get_max_size, max_part_size);
 	will_return(__wrap_ocf_engine_unmapped_count, cachelines_to_map);
 	will_return(__wrap_ocf_engine_repart_count, cachelines_to_repart);
 	will_return(__wrap_ocf_part_get_occupancy, part_occupied_cachelines);
 	will_return(__wrap_ocf_freelist_num_free, freelist_size);
 	will_return(__wrap_ocf_engine_unmapped_count, cachelines_to_map);
 	expect_function_call(__wrap_ocf_req_set_part_evict);
 	assert_int_equal(ocf_part_evict_size(&req), cachelines_to_evict);
 	test_free(req.cache);
 }
 static void ocf_part_evict_size_test06(void **state)
 {
 	uint32_t max_part_size = 1024;
 	uint32_t cachelines_to_repart = 0;
 	uint32_t cachelines_to_map = 320;
 	uint32_t part_occupied_cachelines = 320;
 	uint32_t freelist_size = 0;
 	struct ocf_request req;
 	req.cache = test_malloc(sizeof(struct ocf_cache));
 	uint32_t available_cachelines = max_part_size - part_occupied_cachelines;
 	uint32_t cachelines_to_evict = cachelines_to_map;
 	print_test_description("Freelist is empty but target part has enough space");
 	will_return(__wrap_ocf_part_get_max_size, max_part_size);
 	will_return(__wrap_ocf_engine_unmapped_count, cachelines_to_map);
 	will_return(__wrap_ocf_engine_repart_count, cachelines_to_repart);
 	will_return(__wrap_ocf_part_get_occupancy, part_occupied_cachelines);
 	will_return(__wrap_ocf_freelist_num_free, freelist_size);
 	will_return(__wrap_ocf_engine_unmapped_count, cachelines_to_map);
 	expect_function_call(__wrap_ocf_req_clear_part_evict);
 	assert_int_equal(ocf_part_evict_size(&req), cachelines_to_evict);
 	test_free(req.cache);
 }
 static void ocf_part_evict_size_test07(void **state)
 {
 	uint32_t max_part_size = 1024;
 	uint32_t cachelines_to_repart = 0;
 	uint32_t cachelines_to_map = 320;
 	uint32_t part_occupied_cachelines = 1280;
 	uint32_t freelist_size = 0;
 	struct ocf_request req;
 	req.cache = test_malloc(sizeof(struct ocf_cache));
 	uint32_t debt_cachelines = part_occupied_cachelines - max_part_size;
 	uint32_t cachelines_to_evict = cachelines_to_map + debt_cachelines;
 	print_test_description("Freelist is empty and part occupancy exceeded");
 	will_return(__wrap_ocf_part_get_max_size, max_part_size);
 	will_return(__wrap_ocf_engine_unmapped_count, cachelines_to_map);
 	will_return(__wrap_ocf_engine_repart_count, cachelines_to_repart);
 	will_return(__wrap_ocf_part_get_occupancy, part_occupied_cachelines);
 	will_return(__wrap_ocf_freelist_num_free, freelist_size);
 	will_return(__wrap_ocf_engine_unmapped_count, cachelines_to_map);
 	expect_function_call(__wrap_ocf_req_set_part_evict);
 	assert_int_equal(ocf_part_evict_size(&req),
 			(part_occupied_cachelines - max_part_size) + cachelines_to_map);
 	test_free(req.cache);
 }
 static void ocf_part_evict_size_test08(void **state)
 {
 	uint32_t max_part_size = 1024;
 	uint32_t cachelines_to_repart = 320;
 	uint32_t cachelines_to_map = 0;
 	uint32_t part_occupied_cachelines = 1280;
 	uint32_t freelist_size = 0;
 	struct ocf_request req;
 	req.cache = test_malloc(sizeof(struct ocf_cache));
 	uint32_t debt_cachelines = part_occupied_cachelines - max_part_size;
 	uint32_t cachelines_to_evict = debt_cachelines + cachelines_to_repart;
 	print_test_description("Target part occupancy limit is exceeded during "
 			"repart");
 	will_return(__wrap_ocf_part_get_max_size, max_part_size);
 	will_return(__wrap_ocf_engine_unmapped_count, cachelines_to_map);
 	will_return(__wrap_ocf_engine_repart_count, cachelines_to_repart);
 	will_return(__wrap_ocf_part_get_occupancy, part_occupied_cachelines);
 	will_return(__wrap_ocf_freelist_num_free, freelist_size);
 	will_return(__wrap_ocf_engine_unmapped_count, cachelines_to_map);
 	expect_function_call(__wrap_ocf_req_set_part_evict);
 	assert_int_equal(ocf_part_evict_size(&req),
 			(part_occupied_cachelines - max_part_size) + cachelines_to_repart);
 	test_free(req.cache);
 }
 static void ocf_part_evict_size_test09(void **state)
 {
 	uint32_t max_part_size = 1024;
 	uint32_t cachelines_to_repart = 320;
 	uint32_t cachelines_to_map = 0;
 	uint32_t part_occupied_cachelines = 320;
 	uint32_t freelist_size = 0;
 	struct ocf_request req;
 	req.cache = test_malloc(sizeof(struct ocf_cache));
 	uint32_t cachelines_to_evict = 0;
 	print_test_description("Repart while target part has enough of available "
 		   "space");
 	will_return(__wrap_ocf_part_get_max_size, max_part_size);
 	will_return(__wrap_ocf_engine_unmapped_count, cachelines_to_map);
 	will_return(__wrap_ocf_engine_repart_count, cachelines_to_repart);
 	will_return(__wrap_ocf_part_get_occupancy, part_occupied_cachelines);
 	will_return(__wrap_ocf_freelist_num_free, freelist_size);
 	will_return(__wrap_ocf_engine_unmapped_count, cachelines_to_map);
 	assert_int_equal(ocf_part_evict_size(&req), cachelines_to_evict);
 	test_free(req.cache);
 }
 static void ocf_part_evict_size_test10(void **state)
 {
 	uint32_t max_part_size = 1024;
 	uint32_t cachelines_to_repart = 0;
 	uint32_t cachelines_to_map = 320;
 	uint32_t part_occupied_cachelines = 320;
 	uint32_t freelist_size = 320;
 	struct ocf_request req;
 	req.cache = test_malloc(sizeof(struct ocf_cache));
 	uint32_t cachelines_to_evict = 0;
 	print_test_description("Enough of available cachelines in target part, "
 			"freelist has exactly required number of free cachelines");
 	will_return(__wrap_ocf_part_get_max_size, max_part_size);
 	will_return(__wrap_ocf_engine_unmapped_count, cachelines_to_map);
 	will_return(__wrap_ocf_engine_repart_count, cachelines_to_repart);
 	will_return(__wrap_ocf_part_get_occupancy, part_occupied_cachelines);
 	will_return(__wrap_ocf_freelist_num_free, freelist_size);
 	will_return(__wrap_ocf_engine_unmapped_count, cachelines_to_map);
 	assert_int_equal(ocf_part_evict_size(&req), cachelines_to_evict);
 	test_free(req.cache);
 }
 static void ocf_part_evict_size_test11(void **state)
 {
 	uint32_t max_part_size = 1024;
 	uint32_t cachelines_to_repart = 320;
 	uint32_t cachelines_to_map = 0;
 	uint32_t part_occupied_cachelines = 384;
 	uint32_t freelist_size = 0;
 	struct ocf_request req;
 	req.cache = test_malloc(sizeof(struct ocf_cache));
 	uint32_t cachelines_to_evict = 0;
 	print_test_description("Number of cachelines to repart is equal to number "
 			"of cachelines available in the target partition");
 	will_return(__wrap_ocf_part_get_max_size, max_part_size);
 	will_return(__wrap_ocf_engine_unmapped_count, cachelines_to_map);
 	will_return(__wrap_ocf_engine_repart_count, cachelines_to_repart);
 	will_return(__wrap_ocf_part_get_occupancy, part_occupied_cachelines);
 	will_return(__wrap_ocf_freelist_num_free, freelist_size);
 	will_return(__wrap_ocf_engine_unmapped_count, cachelines_to_map);
 	assert_int_equal(ocf_part_evict_size(&req), cachelines_to_evict);
 	test_free(req.cache);
 }
 static void ocf_part_evict_size_test12(void **state)
 {
 	uint32_t max_part_size = 0;
 	uint32_t cachelines_to_repart = 0;
 	uint32_t cachelines_to_map = 320;
 	uint32_t part_occupied_cachelines = 384;
 	uint32_t freelist_size = 0;
 	struct ocf_request req;
 	req.cache = test_malloc(sizeof(struct ocf_cache));
 	uint32_t cachelines_to_evict =
 		part_occupied_cachelines + cachelines_to_map;
 	print_test_description("Freelist IS empty. Max occupancy set to 0, but "
 			"some cachelines are still assigned to traget part - evict them");
 	will_return(__wrap_ocf_part_get_max_size, max_part_size);
 	will_return(__wrap_ocf_engine_unmapped_count, cachelines_to_map);
 	will_return(__wrap_ocf_engine_repart_count, cachelines_to_repart);
 	will_return(__wrap_ocf_part_get_occupancy, part_occupied_cachelines);
 	will_return(__wrap_ocf_freelist_num_free, freelist_size);
 	will_return(__wrap_ocf_engine_unmapped_count, cachelines_to_map);
 	expect_function_call(__wrap_ocf_req_set_part_evict);
 	assert_true(ocf_part_evict_size(&req) >= part_occupied_cachelines);
 	test_free(req.cache);
 }
 static void ocf_part_evict_size_test13(void **state)
 {
 	uint32_t max_part_size = 0;
 	uint32_t cachelines_to_repart = 0;
 	uint32_t cachelines_to_map = 320;
 	uint32_t part_occupied_cachelines = 384;
 	uint32_t freelist_size = 1024;
 	struct ocf_request req;
 	req.cache = test_malloc(sizeof(struct ocf_cache));
 	uint32_t cachelines_to_evict =
 		part_occupied_cachelines + cachelines_to_map;
 	print_test_description("Freelist IS NOT empty. Max occupancy set to 0, but"
 			" some cachelines are still assigned to traget part - evict them");
 	will_return(__wrap_ocf_part_get_max_size, max_part_size);
 	will_return(__wrap_ocf_engine_unmapped_count, cachelines_to_map);
 	will_return(__wrap_ocf_engine_repart_count, cachelines_to_repart);
 	will_return(__wrap_ocf_part_get_occupancy, part_occupied_cachelines);
 	will_return(__wrap_ocf_freelist_num_free, freelist_size);
 	will_return(__wrap_ocf_engine_unmapped_count, cachelines_to_map);
 	expect_function_call(__wrap_ocf_req_set_part_evict);
 	assert_true(ocf_part_evict_size(&req) >= part_occupied_cachelines);
 	test_free(req.cache);
 }
 int main(void)
 {
 	const struct CMUnitTest tests[] = {
 		cmocka_unit_test(ocf_part_evict_size_test01),
 		cmocka_unit_test(ocf_part_evict_size_test02),
 		cmocka_unit_test(ocf_part_evict_size_test03),
 		cmocka_unit_test(ocf_part_evict_size_test04),
 		cmocka_unit_test(ocf_part_evict_size_test05),
 		cmocka_unit_test(ocf_part_evict_size_test06),
 		cmocka_unit_test(ocf_part_evict_size_test07),
 		cmocka_unit_test(ocf_part_evict_size_test08),
 		cmocka_unit_test(ocf_part_evict_size_test09),
 		cmocka_unit_test(ocf_part_evict_size_test10),
 		cmocka_unit_test(ocf_part_evict_size_test11),
 		cmocka_unit_test(ocf_part_evict_size_test12),
 		cmocka_unit_test(ocf_part_evict_size_test13)
 	};
 	print_message("Unit test for ocf_part_evict_size\n");
 	return cmocka_run_group_tests(tests, NULL, NULL);
 }