takashi kadono
/
Nucleo_446
Color Oled(SSD1331) connect to STMicroelectronics Nucleo-F466
mbed-os/TESTS/mbed_drivers/timer/main.cpp
- Committer:
- kadonotakashi
- Date:
- 2018-10-11
- Revision:
- 3:f3764f852aa8
- Parent:
- 0:8fdf9a60065b
File content as of revision 3:f3764f852aa8:
/* * Copyright (c) 2017, ARM Limited, All Rights Reserved * SPDX-License-Identifier: Apache-2.0 * * Licensed under the Apache License, Version 2.0 (the "License"); you may * not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, WITHOUT * WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include "mbed.h" #include "greentea-client/test_env.h" #include "unity.h" #include "utest.h" #include "rtos.h" #include "hal/us_ticker_api.h" #if !DEVICE_USTICKER #error [NOT_SUPPORTED] test not supported #endif using namespace utest::v1; extern uint32_t SystemCoreClock; #define US_PER_SEC 1000000 #define US_PER_MSEC 1000 #define MSEC_PER_SEC 1000 /* * Define tolerance as follows: * tolerance = 500 us + 2% of measured time * * e.g. * 1 ms delay: tolerance = 520 us * 10 ms delay: tolerance = 700 us * 100 ms delay: tolerance = 2500 us * 1000 ms delay: tolerance = 20500 us * * */ #ifdef NO_SYSTICK #define TOLERANCE 5 #else #define TOLERANCE 2 #endif #define DELTA_US(delay_ms) (500 + (delay_ms) * US_PER_MSEC * TOLERANCE / 100) #define DELTA_MS(delay_ms) (1 + (delay_ms) * TOLERANCE / 100) #define DELTA_S(delay_ms) (0.000500f + ((float)(delay_ms)) * ((float)(TOLERANCE) / 100.f) / MSEC_PER_SEC) #define TICKER_FREQ_1MHZ 1000000 #define TICKER_BITS 32 static Timer *p_timer = NULL; /* Global variable used to simulate passage of time * in case when timer which uses user ticker is tested. */ static uint32_t curr_ticker_ticks_val; /* Replacement for generic wait functions to avoid invoking OS scheduling stuff. */ void busy_wait_us(int us) { const ticker_data_t *const ticker = get_us_ticker_data(); uint32_t start = ticker_read(ticker); while ((ticker_read(ticker) - start) < (uint32_t)us); } void busy_wait_ms(int ms) { busy_wait_us(ms * US_PER_MSEC); } /* User ticker interface function. */ static void stub_interface_init() { /* do nothing. */ } /* User ticker interface function - only this * ticker interface function is used by Timer API. */ static uint32_t stub_ticker_read(void) { /* Simulate elapsed time. */ return curr_ticker_ticks_val; } /* User ticker interface function. */ static void stub_disable_interrupt(void) { /* do nothing. */ } /* User ticker interface function. */ static void stub_clear_interrupt(void) { /* do nothing. */ } /* User ticker interface function. */ static void stub_set_interrupt(timestamp_t timestamp) { /* do nothing. */ } /* User ticker interface function. */ static void stub_fire_interrupt(void) { /* do nothing. */ } /* User ticker interface function. */ static void stub_free(void) { /* do nothing. */ } ticker_info_t info = { TICKER_FREQ_1MHZ, TICKER_BITS }; const ticker_info_t *stub_get_info(void) { return &info; } /* User ticker event queue. */ static ticker_event_queue_t my_events = { 0 }; /* User ticker interface data. */ static const ticker_interface_t us_interface = { .init = stub_interface_init, .read = stub_ticker_read, /* Only this function is used by the Timer. */ .disable_interrupt = stub_disable_interrupt, .clear_interrupt = stub_clear_interrupt, .set_interrupt = stub_set_interrupt, .fire_interrupt = stub_fire_interrupt, .free = stub_free, .get_info = stub_get_info, }; /* User ticker data structure. */ static const ticker_data_t us_data = { .interface = &us_interface, .queue = &my_events }; /* Function which returns user ticker data. */ const ticker_data_t *get_user_ticker_data(void) { return &us_data; } /* Initialisation of the Timer object which uses * ticker data provided by the user. * * */ utest::v1::status_t timer_user_ticker_setup_handler(const Case *const source, const size_t index_of_case) { p_timer = new Timer(get_user_ticker_data()); /* Check if Timer object has been created. */ TEST_ASSERT_NOT_NULL(p_timer); return greentea_case_setup_handler(source, index_of_case); } /* Initialisation of the Timer object which uses * default os ticker data. * * */ utest::v1::status_t timer_os_ticker_setup_handler(const Case *const source, const size_t index_of_case) { p_timer = new Timer(); /* Check if Timer object has been created. */ TEST_ASSERT_NOT_NULL(p_timer); return greentea_case_setup_handler(source, index_of_case); } /* Test finalisation. * * */ utest::v1::status_t cleanup_handler(const Case *const source, const size_t passed, const size_t failed, const failure_t reason) { delete p_timer; p_timer = NULL; return greentea_case_teardown_handler(source, passed, failed, reason); } /* This test verifies if timer is stopped after * creation. * * Note: this function assumes that Timer uses os ticker. * * Given Timer has been successfully created. * When read of timer elapsed time is requested. * Then result is always 0. */ void test_timer_creation_os_ticker() { /* Check results. */ TEST_ASSERT_EQUAL_FLOAT(0, p_timer->read()); TEST_ASSERT_EQUAL_INT32(0, p_timer->read_ms()); TEST_ASSERT_EQUAL_INT32(0, p_timer->read_us()); TEST_ASSERT_EQUAL_UINT64(0, p_timer->read_high_resolution_us()); /* Wait 10 ms. * After that operation timer read routines should still return 0. */ busy_wait_ms(10); /* Check results. */ TEST_ASSERT_EQUAL_FLOAT(0, p_timer->read()); TEST_ASSERT_EQUAL_INT32(0, p_timer->read_ms()); TEST_ASSERT_EQUAL_INT32(0, p_timer->read_us()); TEST_ASSERT_EQUAL_UINT64(0, p_timer->read_high_resolution_us()); } /* This test verifies if timer is stopped after * creation. * * Note: this function assumes that Timer uses user/fake ticker * which returns time value provided in curr_ticker_ticks_val * global variable. * * Given Timer has been successfully created. * When read of timer elapsed time is requested. * Then result is always 0. */ void test_timer_creation_user_ticker() { /* For timer which is using user ticker simulate timer * creation time (irrelevant in case of os ticker). */ curr_ticker_ticks_val = 10000; /* Check results. */ TEST_ASSERT_EQUAL_FLOAT(0, p_timer->read()); TEST_ASSERT_EQUAL_INT32(0, p_timer->read_ms()); TEST_ASSERT_EQUAL_INT32(0, p_timer->read_us()); TEST_ASSERT_EQUAL_UINT64(0, p_timer->read_high_resolution_us()); /* Simulate that 10 ms has elapsed. * After that operation timer read routines should still return 0. */ curr_ticker_ticks_val += 10000; /* Check results. */ TEST_ASSERT_EQUAL_FLOAT(0, p_timer->read()); TEST_ASSERT_EQUAL_INT32(0, p_timer->read_ms()); TEST_ASSERT_EQUAL_INT32(0, p_timer->read_us()); TEST_ASSERT_EQUAL_UINT64(0, p_timer->read_high_resolution_us()); } /* This test verifies verifies if read(), read_us(), read_ms(), * read_high_resolution_us() functions returns valid values. * * Note: this function assumes that Timer uses user/fake ticker * which returns time value provided in curr_ticker_ticks_val * global variable. * * Given Timer has been successfully created and * few times started and stopped after a specified period of time. * When timer read request is performed. * Then read functions return accumulated time elapsed between starts * and stops. */ void test_timer_time_accumulation_user_ticker() { /* Simulate that current time is equal to 0 us. */ curr_ticker_ticks_val = 0; /* Start the timer. */ p_timer->start(); /* -- Simulate that current time is equal to 1 us -- */ curr_ticker_ticks_val = 1; /* Stop the timer. */ p_timer->stop(); /* Check results - 1 us has elapsed. */ TEST_ASSERT_EQUAL_FLOAT(0.000001f, p_timer->read()); TEST_ASSERT_EQUAL_INT32(0, p_timer->read_ms()); TEST_ASSERT_EQUAL_INT32(1, p_timer->read_us()); TEST_ASSERT_EQUAL_UINT64(1, p_timer->read_high_resolution_us()); /* Simulate that 100 us has elapsed between stop and start. */ curr_ticker_ticks_val = 101; /* Start the timer. */ p_timer->start(); /* -- Simulate that current time is equal to 225 us -- */ curr_ticker_ticks_val = 225; /* Stop the timer. */ p_timer->stop(); /* Check results - 125 us have elapsed. */ TEST_ASSERT_EQUAL_FLOAT(0.000125f, p_timer->read()); TEST_ASSERT_EQUAL_INT32(0, p_timer->read_ms()); TEST_ASSERT_EQUAL_INT32(125, p_timer->read_us()); TEST_ASSERT_EQUAL_UINT64(125, p_timer->read_high_resolution_us()); /* Simulate that 100 us has elapsed between stop and start. */ curr_ticker_ticks_val = 325; /* Start the timer. */ p_timer->start(); /* -- Simulate that current time is equal to 1200 us -- */ curr_ticker_ticks_val = 1200; /* Stop the timer. */ p_timer->stop(); /* Check results - 1 ms has elapsed. */ TEST_ASSERT_EQUAL_FLOAT(0.001000f, p_timer->read()); TEST_ASSERT_EQUAL_INT32(1, p_timer->read_ms()); TEST_ASSERT_EQUAL_INT32(1000, p_timer->read_us()); TEST_ASSERT_EQUAL_UINT64(1000, p_timer->read_high_resolution_us()); /* Simulate that 100 us has elapsed between stop and start. */ curr_ticker_ticks_val = 1300; /* Start the timer. */ p_timer->start(); /* -- Simulate that current time is equal to 125300 us -- */ curr_ticker_ticks_val = 125300; /* Stop the timer. */ p_timer->stop(); /* Check results - 125 ms have elapsed. */ TEST_ASSERT_EQUAL_FLOAT(0.125000f, p_timer->read()); TEST_ASSERT_EQUAL_INT32(125, p_timer->read_ms()); TEST_ASSERT_EQUAL_INT32(125000, p_timer->read_us()); TEST_ASSERT_EQUAL_UINT64(125000, p_timer->read_high_resolution_us()); /* Simulate that 100 us has elapsed between stop and start. */ curr_ticker_ticks_val = 125400; /* Start the timer. */ p_timer->start(); /* -- Simulate that current time is equal to 1000400 us -- */ curr_ticker_ticks_val = 1000400; /* Stop the timer. */ p_timer->stop(); /* Check results - 1 s has elapsed. */ TEST_ASSERT_EQUAL_FLOAT(1.000000f, p_timer->read()); TEST_ASSERT_EQUAL_INT32(1000, p_timer->read_ms()); TEST_ASSERT_EQUAL_INT32(1000000, p_timer->read_us()); TEST_ASSERT_EQUAL_UINT64(1000000, p_timer->read_high_resolution_us()); /* Simulate that 100 us has elapsed between stop and start. */ curr_ticker_ticks_val = 1000500; /* Start the timer. */ p_timer->start(); /* -- Simulate that current time is equal to 125000500 us -- */ curr_ticker_ticks_val = 125000500; /* Stop the timer. */ p_timer->stop(); /* Check results - 125 s have elapsed. */ TEST_ASSERT_EQUAL_FLOAT(125.000000f, p_timer->read()); TEST_ASSERT_EQUAL_INT32(125000, p_timer->read_ms()); TEST_ASSERT_EQUAL_INT32(125000000, p_timer->read_us()); TEST_ASSERT_EQUAL_UINT64(125000000, p_timer->read_high_resolution_us()); /* Simulate that 100 us has elapsed between stop and start. */ curr_ticker_ticks_val = 125000600; /* Start the timer. */ p_timer->start(); /* -- Simulate that current time is equal to MAX_INT_32 us + 600 us (delays * between stops and starts) -- */ /* Note that ticker is based on unsigned 32-bit int microsecond counters * while timers are based on 32-bit signed int microsecond counters, * so timers can only count up to a maximum of 2^31-1 microseconds i.e. * 2147483647 us (about 35 minutes). */ curr_ticker_ticks_val = 2147484247; /* Stop the timer. */ p_timer->stop(); /* Check results - 2147483647 (MAX_INT_32) us have elapsed. */ TEST_ASSERT_EQUAL_FLOAT(2147.483647f, p_timer->read()); TEST_ASSERT_EQUAL_INT32(2147483, p_timer->read_ms()); TEST_ASSERT_EQUAL_INT32(2147483647, p_timer->read_us()); TEST_ASSERT_EQUAL_UINT64(2147483647, p_timer->read_high_resolution_us()); } /* This test verifies if read(), read_us(), read_ms(), * read_high_resolution_us() * functions return time accumulated between * timer starts and stops. * * Note this function assumes that Timer uses os ticker. * * Given Timer has been successfully created and * few times started and stopped after a specified period of time. * When timer read request is performed. * Then read functions return accumulated time elapsed between starts * and stops. */ void test_timer_time_accumulation_os_ticker() { /* Start the timer. */ p_timer->start(); /* Wait 10 ms. */ busy_wait_ms(10); /* Stop the timer. */ p_timer->stop(); /* Check results - totally 10 ms have elapsed. */ TEST_ASSERT_FLOAT_WITHIN(DELTA_S(10), 0.010f, p_timer->read()); TEST_ASSERT_INT32_WITHIN(DELTA_MS(10), 10, p_timer->read_ms()); TEST_ASSERT_INT32_WITHIN(DELTA_US(10), 10000, p_timer->read_us()); TEST_ASSERT_UINT64_WITHIN(DELTA_US(10), 10000, p_timer->read_high_resolution_us()); /* Wait 50 ms - this is done to show that time elapsed when * the timer is stopped does not have influence on the * timer counted time. */ busy_wait_ms(50); /* ------ */ /* Start the timer. */ p_timer->start(); /* Wait 20 ms. */ busy_wait_ms(20); /* Stop the timer. */ p_timer->stop(); /* Check results - totally 30 ms have elapsed. */ TEST_ASSERT_FLOAT_WITHIN(DELTA_S(30), 0.030f, p_timer->read()); TEST_ASSERT_INT32_WITHIN(DELTA_MS(30), 30, p_timer->read_ms()); TEST_ASSERT_INT32_WITHIN(DELTA_US(30), 30000, p_timer->read_us()); TEST_ASSERT_UINT64_WITHIN(DELTA_US(30), 30000, p_timer->read_high_resolution_us()); /* Wait 50 ms - this is done to show that time elapsed when * the timer is stopped does not have influence on the * timer counted time. */ /* ------ */ /* Start the timer. */ p_timer->start(); /* Wait 30 ms. */ busy_wait_ms(30); /* Stop the timer. */ p_timer->stop(); /* Check results - totally 60 ms have elapsed. */ TEST_ASSERT_FLOAT_WITHIN(DELTA_S(60), 0.060f, p_timer->read()); TEST_ASSERT_INT32_WITHIN(DELTA_MS(60), 60, p_timer->read_ms()); TEST_ASSERT_INT32_WITHIN(DELTA_US(60), 60000, p_timer->read_us()); TEST_ASSERT_UINT64_WITHIN(DELTA_US(60), 60000, p_timer->read_high_resolution_us()); /* Wait 50 ms - this is done to show that time elapsed when * the timer is stopped does not have influence on the * timer time. */ busy_wait_ms(50); /* ------ */ /* Start the timer. */ p_timer->start(); /* Wait 1 sec. */ busy_wait_ms(1000); /* Stop the timer. */ p_timer->stop(); /* Check results - totally 1060 ms have elapsed. */ TEST_ASSERT_FLOAT_WITHIN(DELTA_S(1060), 1.060f, p_timer->read()); TEST_ASSERT_INT32_WITHIN(DELTA_MS(1060), 1060, p_timer->read_ms()); TEST_ASSERT_INT32_WITHIN(DELTA_US(1060), 1060000, p_timer->read_us()); TEST_ASSERT_UINT64_WITHIN(DELTA_US(1060), 1060000, p_timer->read_high_resolution_us()); } /* This test verifies if reset() function resets the timer * counted time. * * Note this function assumes that Timer uses os ticker. * * Given timer has been started and stopped once, then reset * operation was performed. * When timer is started and stopped next time. * Then timer read functions returns only the the second * measured time. */ void test_timer_reset_os_ticker() { /* First measure 10 ms delay. */ p_timer->start(); /* Wait 10 ms. */ busy_wait_ms(10); /* Stop the timer. */ p_timer->stop(); /* Check results - totally 10 ms elapsed. */ TEST_ASSERT_FLOAT_WITHIN(DELTA_S(10), 0.010f, p_timer->read()); TEST_ASSERT_INT32_WITHIN(DELTA_MS(10), 10, p_timer->read_ms()); TEST_ASSERT_INT32_WITHIN(DELTA_US(10), 10000, p_timer->read_us()); TEST_ASSERT_UINT64_WITHIN(DELTA_US(10), 10000, p_timer->read_high_resolution_us()); /* Reset the timer - previous measured time should be lost now. */ p_timer->reset(); /* Now measure 20 ms delay. */ p_timer->start(); /* Wait 20 ms. */ busy_wait_ms(20); /* Stop the timer. */ p_timer->stop(); /* Check results - 20 ms elapsed since the reset. */ TEST_ASSERT_FLOAT_WITHIN(DELTA_S(20), 0.020f, p_timer->read()); TEST_ASSERT_INT32_WITHIN(DELTA_MS(20), 20, p_timer->read_ms()); TEST_ASSERT_INT32_WITHIN(DELTA_US(20), 20000, p_timer->read_us()); TEST_ASSERT_UINT64_WITHIN(DELTA_US(20), 20000, p_timer->read_high_resolution_us()); } /* This test verifies if reset() function resets the timer * counted time. * * Note this function assumes that Timer uses user ticker. * * Given timer has been started and stopped once, then reset * operation was performed. * When timer is started and stopped next time. * Then timer read functions returns only the the second * measured time. */ void test_timer_reset_user_ticker() { /* For timer which is using user ticker simulate set current * time (irrelevant in case of os ticker). */ curr_ticker_ticks_val = 0; /* First measure 10 ms delay. */ p_timer->start(); /* Simulate that 10 ms have elapsed. */ curr_ticker_ticks_val = 10000; /* Stop the timer. */ p_timer->stop(); /* Check results - totally 10 ms elapsed. */ TEST_ASSERT_EQUAL_FLOAT(0.010f, p_timer->read()); TEST_ASSERT_EQUAL_INT32(10, p_timer->read_ms()); TEST_ASSERT_EQUAL_INT32(10000, p_timer->read_us()); TEST_ASSERT_EQUAL_UINT64(10000, p_timer->read_high_resolution_us()); /* Reset the timer - previous measured time should be lost now. */ p_timer->reset(); /* Now measure 20 ms delay. */ p_timer->start(); /* Simulate that 20 ms have elapsed. */ curr_ticker_ticks_val = 30000; /* Stop the timer. */ p_timer->stop(); /* Check results - 20 ms elapsed since the reset. */ TEST_ASSERT_EQUAL_FLOAT(0.020f, p_timer->read()); TEST_ASSERT_EQUAL_INT32(20, p_timer->read_ms()); TEST_ASSERT_EQUAL_INT32(20000, p_timer->read_us()); TEST_ASSERT_EQUAL_UINT64(20000, p_timer->read_high_resolution_us()); } /* This test verifies if calling start() for already * started timer does nothing. * * Note this function assumes that Timer uses os ticker. * * Given timer is already started. * When timer is started again. * Then second start operation is ignored. */ void test_timer_start_started_timer_os_ticker() { /* Start the timer. */ p_timer->start(); /* Wait 10 ms. */ busy_wait_ms(10); /* Now start timer again. */ p_timer->start(); /* Wait 20 ms. */ busy_wait_ms(20); /* Stop the timer. */ p_timer->stop(); /* Check results - 30 ms have elapsed since the first start. */ TEST_ASSERT_FLOAT_WITHIN(DELTA_S(30), 0.030f, p_timer->read()); TEST_ASSERT_INT32_WITHIN(DELTA_MS(30), 30, p_timer->read_ms()); TEST_ASSERT_INT32_WITHIN(DELTA_US(30), 30000, p_timer->read_us()); TEST_ASSERT_UINT64_WITHIN(DELTA_US(30), 30000, p_timer->read_high_resolution_us()); } /* This test verifies if calling start() for already * started timer does nothing. * * Note this function assumes that Timer uses user ticker. * * Given timer is already started. * When timer is started again. * Then second start operation is ignored. */ void test_timer_start_started_timer_user_ticker() { /* For timer which is using user ticker set current * time (irrelevant in case of os ticker). */ curr_ticker_ticks_val = 0; /* Start the timer. */ p_timer->start(); /* Simulate that 10 ms have elapsed. */ curr_ticker_ticks_val = 10000; /* Now start timer again. */ p_timer->start(); /* Simulate that 20 ms have elapsed. */ curr_ticker_ticks_val = 30000; /* Stop the timer. */ p_timer->stop(); /* Check results - 30 ms have elapsed since the first start. */ TEST_ASSERT_FLOAT_WITHIN(DELTA_S(30), 0.030f, p_timer->read()); TEST_ASSERT_INT32_WITHIN(DELTA_MS(30), 30, p_timer->read_ms()); TEST_ASSERT_INT32_WITHIN(DELTA_US(30), 30000, p_timer->read_us()); TEST_ASSERT_UINT64_WITHIN(DELTA_US(30), 30000, p_timer->read_high_resolution_us()); } /* This test verifies Timer float operator. * * Note this function assumes that Timer uses os ticker. * * Given timer is created and a time period time is counted. * When timer object is casted on float type. * Then counted type in seconds is returned by means of * read() function. */ void test_timer_float_operator_os_ticker() { /* Start the timer. */ p_timer->start(); /* Wait 10 ms. */ busy_wait_ms(10); /* Stop the timer. */ p_timer->stop(); /* Check result - 10 ms elapsed. */ TEST_ASSERT_FLOAT_WITHIN(DELTA_S(10), 0.010f, (float)(*p_timer)); } /* This test verifies Timer float operator. * * Note this function assumes that Timer uses user ticker. * * Given timer is created and a time period time is counted. * When timer object is casted on float type. * Then counted type in seconds is returned by means of * read() function. */ void test_timer_float_operator_user_ticker() { /* For timer which is using user ticker set current * time (irrelevant in case of os ticker). */ curr_ticker_ticks_val = 0; /* Start the timer. */ p_timer->start(); /* Simulate that 10 ms have elapsed. */ curr_ticker_ticks_val = 10000; /* Stop the timer. */ p_timer->stop(); /* Check result - 10 ms elapsed. */ TEST_ASSERT_EQUAL_FLOAT(0.010f, (float)(*p_timer)); } /* This test verifies if time counted by the timer is * valid. * * For this test Timer which uses os ticker * must be used. * * Given timer is created. * When timer is used to measure 1ms/10ms/100ms/1s * delays. * Then the results are valid (within acceptable range). */ template<int wait_val_us> void test_timer_time_measurement() { /* Start the timer. */ p_timer->start(); /* Wait <wait_val_us> us. */ busy_wait_us(wait_val_us); /* Stop the timer. */ p_timer->stop(); /* Check results. */ TEST_ASSERT_FLOAT_WITHIN(DELTA_S(wait_val_us / US_PER_MSEC), (float)wait_val_us / US_PER_SEC, p_timer->read()); TEST_ASSERT_INT32_WITHIN(DELTA_MS(wait_val_us / US_PER_MSEC), wait_val_us / US_PER_MSEC, p_timer->read_ms()); TEST_ASSERT_INT32_WITHIN(DELTA_US(wait_val_us / US_PER_MSEC), wait_val_us, p_timer->read_us()); TEST_ASSERT_UINT64_WITHIN(DELTA_US(wait_val_us / US_PER_MSEC), wait_val_us, p_timer->read_high_resolution_us()); } utest::v1::status_t test_setup(const size_t number_of_cases) { GREENTEA_SETUP(15, "default_auto"); return verbose_test_setup_handler(number_of_cases); } Case cases[] = { Case("Test: Timer (based on os ticker) is stopped after creation.", timer_os_ticker_setup_handler, test_timer_creation_os_ticker, cleanup_handler), Case("Test: Timer (based on user ticker) is stopped after creation.", timer_user_ticker_setup_handler, test_timer_creation_user_ticker, cleanup_handler), Case("Test: Timer (based on os ticker) - measured time accumulation.", timer_os_ticker_setup_handler, test_timer_time_accumulation_os_ticker, cleanup_handler), Case("Test: Timer (based on user ticker) measured time accumulation.", timer_user_ticker_setup_handler, test_timer_time_accumulation_user_ticker, cleanup_handler), Case("Test: Timer (based on os ticker) - reset.", timer_os_ticker_setup_handler, test_timer_reset_os_ticker, cleanup_handler), Case("Test: Timer (based on user ticker) - reset.", timer_user_ticker_setup_handler, test_timer_reset_user_ticker, cleanup_handler), Case("Test: Timer (based on os ticker) - start started timer.", timer_os_ticker_setup_handler, test_timer_start_started_timer_os_ticker, cleanup_handler), Case("Test: Timer (based on user ticker) - start started timer.", timer_user_ticker_setup_handler, test_timer_start_started_timer_user_ticker, cleanup_handler), Case("Test: Timer (based on os ticker) - float operator.", timer_os_ticker_setup_handler, test_timer_float_operator_os_ticker, cleanup_handler), Case("Test: Timer (based on user ticker) - float operator.", timer_user_ticker_setup_handler, test_timer_float_operator_user_ticker, cleanup_handler), Case("Test: Timer - time measurement 1 ms.", timer_os_ticker_setup_handler, test_timer_time_measurement<1000>, cleanup_handler), Case("Test: Timer - time measurement 10 ms.", timer_os_ticker_setup_handler, test_timer_time_measurement<10000>, cleanup_handler), Case("Test: Timer - time measurement 100 ms.", timer_os_ticker_setup_handler, test_timer_time_measurement<100000>, cleanup_handler), Case("Test: Timer - time measurement 1 s.", timer_os_ticker_setup_handler, test_timer_time_measurement<1000000>, cleanup_handler), }; Specification specification(test_setup, cases); int main() { return !Harness::run(specification); }