blob: 1fb7055a89ef2704a6bc2b59f3f5197e032915e4 [file] [log] [blame]
/**
* @file perf.c
* @author Michal Vasko <mvasko@cesnet.cz>
* @brief performance tests
*
* Copyright (c) 2021 CESNET, z.s.p.o.
*
* This source code is licensed under BSD 3-Clause License (the "License").
* You may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* https://opensource.org/licenses/BSD-3-Clause
*/
#define _GNU_SOURCE
#include <assert.h>
#include <inttypes.h>
#include <stdlib.h>
#include <sys/time.h>
#include <time.h>
#include "libyang.h"
#include "tests_config.h"
#ifdef HAVE_CALLGRIND
# include <valgrind/callgrind.h>
#endif
#define TEMP_FILE "perf_tmp"
/**
* @brief Test state structure.
*/
struct test_state {
const struct lys_module *mod;
uint32_t count;
struct lyd_node *data1;
struct lyd_node *data2;
};
typedef LY_ERR (*setup_cb)(const struct lys_module *mod, uint32_t count, struct test_state *state);
typedef LY_ERR (*test_cb)(struct test_state *state, struct timespec *ts_start, struct timespec *ts_end);
/**
* @brief Single test structure.
*/
struct test {
const char *name;
setup_cb setup;
test_cb test;
};
/**
* @brief Get current time as timespec.
*
* @param[out] ts Timespect to fill.
*/
static void
time_get(struct timespec *ts)
{
#ifdef CLOCK_MONOTONIC_RAW
clock_gettime(CLOCK_MONOTONIC_RAW, ts);
#elif defined (CLOCK_MONOTONIC)
clock_gettime(CLOCK_MONOTONIC, ts);
#elif defined (CLOCK_REALTIME)
/* no monotonic clock available, return realtime */
clock_gettime(CLOCK_REALTIME, ts);
#else
int rc;
struct timeval tv;
gettimeofday(&tv, NULL);
ts->tv_sec = (time_t)tv.tv_sec;
ts->tv_nsec = 1000L * (long)tv.tv_usec;
#endif
}
/**
* @brief Get the difference of 2 timespecs in microseconds.
*
* @param[in] ts1 Smaller (older) timespec.
* @param[in] ts2 Larger (later) timespec.
* @return Difference of timespecs in usec.
*/
static uint64_t
time_diff(const struct timespec *ts1, const struct timespec *ts2)
{
uint64_t usec_diff = 0;
int64_t nsec_diff;
assert(ts1->tv_sec <= ts2->tv_sec);
/* seconds diff */
usec_diff += (ts2->tv_sec - ts1->tv_sec) * 1000000;
/* nanoseconds diff */
nsec_diff = ts2->tv_nsec - ts1->tv_nsec;
usec_diff += nsec_diff ? nsec_diff / 1000 : 0;
return usec_diff;
}
/**
* @brief Create data tree with list instances.
*
* @param[in] mod Module of the top-level node.
* @param[in] offset Starting offset of the identifier number values.
* @param[in] count Number of list instances to create, with increasing identifier numbers.
* @param[out] data Created data.
* @return LY_ERR value.
*/
static LY_ERR
create_list_inst(const struct lys_module *mod, uint32_t offset, uint32_t count, struct lyd_node **data)
{
LY_ERR ret;
uint32_t i;
char k1_val[32], k2_val[32], l_val[32], lfl_val[32];
struct lyd_node *list;
if ((ret = lyd_new_inner(NULL, mod, "cont", 0, data))) {
return ret;
}
for (i = 0; i < count; ++i) {
sprintf(k1_val, "%" PRIu32, i + offset);
sprintf(k2_val, "str%" PRIu32, i + offset);
sprintf(l_val, "l%" PRIu32, i + offset);
if ((ret = lyd_new_list(*data, NULL, "lst", 0, &list, k1_val, k2_val))) {
return ret;
}
if ((ret = lyd_new_term(list, NULL, "l", l_val, 0, NULL))) {
return ret;
}
}
/* Last list contains a "lfl" leaf-list with @p count terms. */
for (i = 0; i < count; ++i) {
sprintf(lfl_val, "%" PRIu32, i + offset);
if ((ret = lyd_new_term(list, NULL, "lfl", lfl_val, 0, NULL))) {
return ret;
}
}
return LY_SUCCESS;
}
/**
* @brief Execute a test.
*
* @param[in] setup Setup callback to call once.
* @param[in] test Test callback.
* @param[in] name Name of the test.
* @param[in] mod Module of testing data.
* @param[in] count Count of list instances, size of the testing data set.
* @param[in] tries Number of (re)tries of the test to get more accurate measurements.
* @return LY_ERR value.
*/
static LY_ERR
exec_test(setup_cb setup, test_cb test, const char *name, const struct lys_module *mod, uint32_t count, uint32_t tries)
{
LY_ERR ret;
struct timespec ts_start, ts_end;
struct test_state state = {0};
const uint32_t name_fixed_len = 38;
char str[name_fixed_len + 1];
uint32_t i, printed;
uint64_t time_usec = 0;
/* print test start */
printed = sprintf(str, "| %s ", name);
while (printed + 2 < name_fixed_len) {
printed += sprintf(str + printed, ".");
}
if (printed + 1 < name_fixed_len) {
printed += sprintf(str + printed, " ");
}
sprintf(str + printed, "|");
fputs(str, stdout);
fflush(stdout);
/* setup */
if ((ret = setup(mod, count, &state))) {
return ret;
}
/* test */
for (i = 0; i < tries; ++i) {
if ((ret = test(&state, &ts_start, &ts_end))) {
return ret;
}
time_usec += time_diff(&ts_start, &ts_end);
}
time_usec /= tries;
/* teardown */
lyd_free_siblings(state.data1);
lyd_free_siblings(state.data2);
/* print time */
printf(" %" PRIu64 ".%06" PRIu64 " s |\n", time_usec / 1000000, time_usec % 1000000);
return LY_SUCCESS;
}
static void
TEST_START(struct timespec *ts)
{
time_get(ts);
#ifdef HAVE_CALLGRIND
CALLGRIND_START_INSTRUMENTATION;
#endif
}
static void
TEST_END(struct timespec *ts)
{
time_get(ts);
#ifdef HAVE_CALLGRIND
CALLGRIND_STOP_INSTRUMENTATION;
#endif
}
/* TEST SETUP */
static LY_ERR
setup_basic(const struct lys_module *mod, uint32_t count, struct test_state *state)
{
state->mod = mod;
state->count = count;
return LY_SUCCESS;
}
static LY_ERR
setup_data_single_tree(const struct lys_module *mod, uint32_t count, struct test_state *state)
{
state->mod = mod;
state->count = count;
return create_list_inst(mod, 0, count, &state->data1);
}
static LY_ERR
setup_data_same_trees(const struct lys_module *mod, uint32_t count, struct test_state *state)
{
LY_ERR ret;
state->mod = mod;
state->count = count;
if ((ret = create_list_inst(mod, 0, count, &state->data1))) {
return ret;
}
if ((ret = create_list_inst(mod, 0, count, &state->data2))) {
return ret;
}
return LY_SUCCESS;
}
static LY_ERR
setup_data_no_same_trees(const struct lys_module *mod, uint32_t count, struct test_state *state)
{
LY_ERR ret;
state->mod = mod;
state->count = count;
if ((ret = create_list_inst(mod, 0, count, &state->data1))) {
return ret;
}
if ((ret = create_list_inst(mod, count, count, &state->data2))) {
return ret;
}
return LY_SUCCESS;
}
static LY_ERR
setup_data_empty_and_full_trees(const struct lys_module *mod, uint32_t count, struct test_state *state)
{
LY_ERR ret;
state->mod = mod;
state->count = count;
if ((ret = create_list_inst(mod, 0, 0, &state->data1))) {
return ret;
}
if ((ret = create_list_inst(mod, 0, count, &state->data2))) {
return ret;
}
return LY_SUCCESS;
}
static LY_ERR
setup_data_offset_tree(const struct lys_module *mod, uint32_t count, struct test_state *state)
{
LY_ERR ret;
state->mod = mod;
state->count = count;
if ((ret = create_list_inst(mod, count, count, &state->data2))) {
return ret;
}
return LY_SUCCESS;
}
/* TEST CB */
static LY_ERR
test_create_new_text(struct test_state *state, struct timespec *ts_start, struct timespec *ts_end)
{
LY_ERR r;
struct lyd_node *data = NULL;
TEST_START(ts_start);
if ((r = create_list_inst(state->mod, 0, state->count, &data))) {
return r;
}
TEST_END(ts_end);
lyd_free_siblings(data);
return LY_SUCCESS;
}
static LY_ERR
test_create_new_bin(struct test_state *state, struct timespec *ts_start, struct timespec *ts_end)
{
LY_ERR r;
struct lyd_node *data = NULL;
uint32_t i, k2_len, l_len;
char k2_val[32], l_val[32];
struct lyd_node *list;
TEST_START(ts_start);
if ((r = lyd_new_inner(NULL, state->mod, "cont", 0, &data))) {
return r;
}
for (i = 0; i < state->count; ++i) {
k2_len = sprintf(k2_val, "str%" PRIu32, i);
l_len = sprintf(l_val, "l%" PRIu32, i);
if ((r = lyd_new_list_bin(data, NULL, "lst", 0, &list, &i, sizeof i, k2_val, k2_len))) {
return r;
}
if ((r = lyd_new_term_bin(list, NULL, "l", l_val, l_len, 0, NULL))) {
return r;
}
}
TEST_END(ts_end);
lyd_free_siblings(data);
return LY_SUCCESS;
}
static LY_ERR
test_create_path(struct test_state *state, struct timespec *ts_start, struct timespec *ts_end)
{
LY_ERR r;
struct lyd_node *data = NULL;
uint32_t i;
char path[64], l_val[32];
TEST_START(ts_start);
if ((r = lyd_new_inner(NULL, state->mod, "cont", 0, &data))) {
return r;
}
for (i = 0; i < state->count; ++i) {
sprintf(path, "/perf:cont/lst[k1='%" PRIu32 "'][k2='str%" PRIu32 "']/l", i, i);
sprintf(l_val, "l%" PRIu32, i);
if ((r = lyd_new_path(data, NULL, path, l_val, 0, NULL))) {
return r;
}
}
TEST_END(ts_end);
lyd_free_siblings(data);
return LY_SUCCESS;
}
static LY_ERR
test_validate(struct test_state *state, struct timespec *ts_start, struct timespec *ts_end)
{
LY_ERR r;
TEST_START(ts_start);
if ((r = lyd_validate_all(&state->data1, NULL, LYD_VALIDATE_PRESENT, NULL))) {
return r;
}
TEST_END(ts_end);
return LY_SUCCESS;
}
static LY_ERR
_test_parse(struct test_state *state, LYD_FORMAT format, ly_bool use_file, uint32_t print_options, uint32_t parse_options,
uint32_t validate_options, struct timespec *ts_start, struct timespec *ts_end)
{
LY_ERR ret = LY_SUCCESS;
struct lyd_node *data = NULL;
char *buf = NULL;
struct ly_in *in = NULL;
if (use_file) {
if ((ret = lyd_print_path(TEMP_FILE, state->data1, format, print_options))) {
goto cleanup;
}
if ((ret = ly_in_new_filepath(TEMP_FILE, 0, &in))) {
goto cleanup;
}
} else {
if ((ret = lyd_print_mem(&buf, state->data1, format, print_options))) {
goto cleanup;
}
if ((ret = ly_in_new_memory(buf, &in))) {
goto cleanup;
}
}
TEST_START(ts_start);
if ((ret = lyd_parse_data(state->mod->ctx, NULL, in, format, parse_options, validate_options, &data))) {
goto cleanup;
}
TEST_END(ts_end);
cleanup:
free(buf);
ly_in_free(in, 0);
lyd_free_siblings(data);
return ret;
}
static LY_ERR
test_parse_xml_mem_validate(struct test_state *state, struct timespec *ts_start, struct timespec *ts_end)
{
return _test_parse(state, LYD_XML, 0, LYD_PRINT_SHRINK, LYD_PARSE_STRICT, LYD_VALIDATE_PRESENT, ts_start, ts_end);
}
static LY_ERR
test_parse_xml_mem_no_validate(struct test_state *state, struct timespec *ts_start, struct timespec *ts_end)
{
return _test_parse(state, LYD_XML, 0, LYD_PRINT_SHRINK, LYD_PARSE_STRICT | LYD_PARSE_ONLY | LYD_PARSE_ORDERED, 0,
ts_start, ts_end);
}
static LY_ERR
test_parse_xml_file_no_validate_format(struct test_state *state, struct timespec *ts_start, struct timespec *ts_end)
{
return _test_parse(state, LYD_XML, 1, 0, LYD_PARSE_STRICT | LYD_PARSE_ONLY | LYD_PARSE_ORDERED, 0, ts_start, ts_end);
}
static LY_ERR
test_parse_json_mem_validate(struct test_state *state, struct timespec *ts_start, struct timespec *ts_end)
{
return _test_parse(state, LYD_JSON, 0, LYD_PRINT_SHRINK, LYD_PARSE_STRICT, LYD_VALIDATE_PRESENT, ts_start, ts_end);
}
static LY_ERR
test_parse_json_mem_no_validate(struct test_state *state, struct timespec *ts_start, struct timespec *ts_end)
{
return _test_parse(state, LYD_JSON, 0, LYD_PRINT_SHRINK, LYD_PARSE_STRICT | LYD_PARSE_ONLY | LYD_PARSE_ORDERED, 0,
ts_start, ts_end);
}
static LY_ERR
test_parse_json_file_no_validate_format(struct test_state *state, struct timespec *ts_start, struct timespec *ts_end)
{
return _test_parse(state, LYD_JSON, 1, 0, LYD_PARSE_STRICT | LYD_PARSE_ONLY | LYD_PARSE_ORDERED, 0, ts_start, ts_end);
}
static LY_ERR
test_parse_lyb_mem_validate(struct test_state *state, struct timespec *ts_start, struct timespec *ts_end)
{
return _test_parse(state, LYD_LYB, 0, LYD_PRINT_SHRINK, LYD_PARSE_STRICT, LYD_VALIDATE_PRESENT, ts_start, ts_end);
}
static LY_ERR
test_parse_lyb_mem_no_validate(struct test_state *state, struct timespec *ts_start, struct timespec *ts_end)
{
return _test_parse(state, LYD_LYB, 0, LYD_PRINT_SHRINK, LYD_PARSE_STRICT | LYD_PARSE_ONLY | LYD_PARSE_ORDERED, 0,
ts_start, ts_end);
}
static LY_ERR
test_parse_lyb_file_no_validate(struct test_state *state, struct timespec *ts_start, struct timespec *ts_end)
{
return _test_parse(state, LYD_LYB, 1, 0, LYD_PARSE_STRICT | LYD_PARSE_ONLY | LYD_PARSE_ORDERED, 0, ts_start, ts_end);
}
static LY_ERR
_test_print(struct test_state *state, LYD_FORMAT format, uint32_t print_options, struct timespec *ts_start,
struct timespec *ts_end)
{
LY_ERR ret = LY_SUCCESS;
char *buf = NULL;
TEST_START(ts_start);
if ((ret = lyd_print_mem(&buf, state->data1, format, print_options))) {
goto cleanup;
}
TEST_END(ts_end);
cleanup:
free(buf);
return ret;
}
static LY_ERR
test_print_xml(struct test_state *state, struct timespec *ts_start, struct timespec *ts_end)
{
return _test_print(state, LYD_XML, LYD_PRINT_SHRINK, ts_start, ts_end);
}
static LY_ERR
test_print_json(struct test_state *state, struct timespec *ts_start, struct timespec *ts_end)
{
return _test_print(state, LYD_JSON, LYD_PRINT_SHRINK, ts_start, ts_end);
}
static LY_ERR
test_print_lyb(struct test_state *state, struct timespec *ts_start, struct timespec *ts_end)
{
return _test_print(state, LYD_LYB, LYD_PRINT_SHRINK, ts_start, ts_end);
}
static LY_ERR
test_dup(struct test_state *state, struct timespec *ts_start, struct timespec *ts_end)
{
LY_ERR r;
struct lyd_node *data;
TEST_START(ts_start);
if ((r = lyd_dup_siblings(state->data1, NULL, LYD_DUP_RECURSIVE, &data))) {
return r;
}
TEST_END(ts_end);
lyd_free_siblings(data);
return LY_SUCCESS;
}
static LY_ERR
test_dup_siblings_to_empty(struct test_state *state, struct timespec *ts_start, struct timespec *ts_end)
{
LY_ERR r;
TEST_START(ts_start);
if ((r = lyd_dup_siblings(lyd_child(state->data2), (struct lyd_node_inner *)state->data1, 0, NULL))) {
return r;
}
TEST_END(ts_end);
return LY_SUCCESS;
}
static LY_ERR
test_free(struct test_state *state, struct timespec *ts_start, struct timespec *ts_end)
{
LY_ERR r;
struct lyd_node *data;
if ((r = create_list_inst(state->mod, 0, state->count, &data))) {
return r;
}
TEST_START(ts_start);
lyd_free_siblings(data);
TEST_END(ts_end);
return LY_SUCCESS;
}
static LY_ERR
test_xpath_find(struct test_state *state, struct timespec *ts_start, struct timespec *ts_end)
{
LY_ERR r;
struct ly_set *set;
char path[64];
sprintf(path, "/perf:cont/lst[k1=%" PRIu32 " and k2='str%" PRIu32 "']", state->count / 2, state->count / 2);
TEST_START(ts_start);
if ((r = lyd_find_xpath(state->data1, path, &set))) {
return r;
}
TEST_END(ts_end);
ly_set_free(set, NULL);
return LY_SUCCESS;
}
static LY_ERR
test_xpath_find_hash(struct test_state *state, struct timespec *ts_start, struct timespec *ts_end)
{
LY_ERR r;
struct ly_set *set;
char path[64];
sprintf(path, "/perf:cont/lst[k1=%" PRIu32 "][k2='str%" PRIu32 "']", state->count / 2, state->count / 2);
TEST_START(ts_start);
if ((r = lyd_find_xpath(state->data1, path, &set))) {
return r;
}
TEST_END(ts_end);
ly_set_free(set, NULL);
return LY_SUCCESS;
}
static LY_ERR
test_compare_same(struct test_state *state, struct timespec *ts_start, struct timespec *ts_end)
{
LY_ERR r;
TEST_START(ts_start);
if ((r = lyd_compare_siblings(state->data1, state->data2, LYD_COMPARE_FULL_RECURSION))) {
return r;
}
TEST_END(ts_end);
return LY_SUCCESS;
}
static LY_ERR
test_diff_same(struct test_state *state, struct timespec *ts_start, struct timespec *ts_end)
{
LY_ERR r;
struct lyd_node *diff;
TEST_START(ts_start);
if ((r = lyd_diff_siblings(state->data1, state->data2, 0, &diff))) {
return r;
}
TEST_END(ts_end);
lyd_free_siblings(diff);
return LY_SUCCESS;
}
static LY_ERR
test_diff_no_same(struct test_state *state, struct timespec *ts_start, struct timespec *ts_end)
{
LY_ERR r;
struct lyd_node *diff;
TEST_START(ts_start);
if ((r = lyd_diff_siblings(state->data1, state->data2, 0, &diff))) {
return r;
}
TEST_END(ts_end);
lyd_free_siblings(diff);
return LY_SUCCESS;
}
static LY_ERR
test_merge_same(struct test_state *state, struct timespec *ts_start, struct timespec *ts_end)
{
LY_ERR r;
TEST_START(ts_start);
if ((r = lyd_merge_siblings(&state->data1, state->data2, 0))) {
return r;
}
TEST_END(ts_end);
return LY_SUCCESS;
}
static LY_ERR
test_merge_no_same(struct test_state *state, struct timespec *ts_start, struct timespec *ts_end)
{
LY_ERR r;
struct lyd_node *data1;
if ((r = create_list_inst(state->mod, 0, state->count, &data1))) {
return r;
}
TEST_START(ts_start);
if ((r = lyd_merge_siblings(&data1, state->data2, 0))) {
return r;
}
TEST_END(ts_end);
lyd_free_siblings(data1);
return LY_SUCCESS;
}
static LY_ERR
test_merge_no_same_destruct(struct test_state *state, struct timespec *ts_start, struct timespec *ts_end)
{
LY_ERR r;
struct lyd_node *data1, *data2;
if ((r = create_list_inst(state->mod, 0, state->count, &data1))) {
return r;
}
if ((r = create_list_inst(state->mod, state->count, state->count, &data2))) {
return r;
}
TEST_START(ts_start);
if ((r = lyd_merge_siblings(&data1, data2, LYD_MERGE_DESTRUCT))) {
return r;
}
TEST_END(ts_end);
lyd_free_siblings(data1);
return LY_SUCCESS;
}
struct test tests[] = {
{"create new text", setup_basic, test_create_new_text},
{"create new bin", setup_basic, test_create_new_bin},
{"create path", setup_basic, test_create_path},
{"validate", setup_data_single_tree, test_validate},
{"parse xml mem validate", setup_data_single_tree, test_parse_xml_mem_validate},
{"parse xml mem no validate", setup_data_single_tree, test_parse_xml_mem_no_validate},
{"parse xml file no validate format", setup_data_single_tree, test_parse_xml_file_no_validate_format},
{"parse json mem validate", setup_data_single_tree, test_parse_json_mem_validate},
{"parse json mem no validate", setup_data_single_tree, test_parse_json_mem_no_validate},
{"parse json file no validate format", setup_data_single_tree, test_parse_json_file_no_validate_format},
{"parse lyb mem validate", setup_data_single_tree, test_parse_lyb_mem_validate},
{"parse lyb mem no validate", setup_data_single_tree, test_parse_lyb_mem_no_validate},
{"parse lyb file no validate", setup_data_single_tree, test_parse_lyb_file_no_validate},
{"print xml", setup_data_single_tree, test_print_xml},
{"print json", setup_data_single_tree, test_print_json},
{"print lyb", setup_data_single_tree, test_print_lyb},
{"dup", setup_data_single_tree, test_dup},
{"dup_siblings_to_empty", setup_data_empty_and_full_trees, test_dup_siblings_to_empty},
{"free", setup_basic, test_free},
{"xpath find", setup_data_single_tree, test_xpath_find},
{"xpath find hash", setup_data_single_tree, test_xpath_find_hash},
{"compare same", setup_data_same_trees, test_compare_same},
{"diff same", setup_data_same_trees, test_diff_same},
{"diff no same", setup_data_no_same_trees, test_diff_no_same},
{"merge same", setup_data_same_trees, test_merge_same},
{"merge no same", setup_data_offset_tree, test_merge_no_same},
{"merge no same destruct", setup_basic, test_merge_no_same_destruct},
};
int
main(int argc, char **argv)
{
LY_ERR ret = LY_SUCCESS;
struct ly_ctx *ctx = NULL;
const struct lys_module *mod;
uint32_t i, count, tries;
if (argc < 3) {
fprintf(stderr, "Usage:\n%s list-instance-count test-tries\n\n", argv[0]);
return LY_EINVAL;
}
count = atoi(argv[1]);
if (!count) {
fprintf(stderr, "Invalid count \"%s\".\n", argv[1]);
return LY_EINVAL;
}
tries = atoi(argv[2]);
if (!tries) {
fprintf(stderr, "Invalid tries \"%s\".\n", argv[2]);
return LY_EINVAL;
}
printf("\nly_perf:\n\tdata set size: %" PRIu32 "\n\teach test executed: %" PRIu32 " %s\n\n", count, tries,
(tries > 1) ? "times" : "time");
/* create context */
if ((ret = ly_ctx_new(TESTS_SRC "/perf", 0, &ctx))) {
goto cleanup;
}
/* load modules */
if (!(mod = ly_ctx_load_module(ctx, "perf", NULL, NULL))) {
ret = LY_ENOTFOUND;
goto cleanup;
}
/* tests */
for (i = 0; i < (sizeof tests / sizeof(struct test)); ++i) {
if ((ret = exec_test(tests[i].setup, tests[i].test, tests[i].name, mod, count, tries))) {
goto cleanup;
}
}
printf("\n");
cleanup:
ly_ctx_destroy(ctx);
return ret;
}