/****************************************************************************** The MIT License(MIT) Embedded Template Library. https://github.com/ETLCPP/etl https://www.etlcpp.com Copyright(c) 2021 John Wellbelove Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files(the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and / or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions : The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software. THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. ******************************************************************************/ #include "unit_test_framework.h" #include "etl/message_router.h" #include "etl/message_bus.h" #include "etl/message_timer_atomic.h" #include #include #include #include #if defined(ETL_COMPILER_MICROSOFT) #include #endif #define REALTIME_TEST 0 //*************************************************************************** // The set of messages. //*************************************************************************** namespace { uint64_t ticks = 0; enum { MESSAGE1, MESSAGE2, MESSAGE3, }; enum { ROUTER1 = 1, }; struct Message1 : public etl::message { }; struct Message2 : public etl::message { }; struct Message3 : public etl::message { }; Message1 message1; Message2 message2; Message3 message3; //*************************************************************************** // Router that handles messages 1, 2, 3 //*************************************************************************** class Router1 : public etl::message_router { public: Router1() : message_router(ROUTER1) { } void on_receive(const Message1&) { message1.push_back(ticks); } void on_receive(const Message2&) { message2.push_back(ticks); } void on_receive(const Message3&) { message3.push_back(ticks); } void on_receive_unknown(const etl::imessage&) { } void clear() { message1.clear(); message2.clear(); message3.clear(); } std::vector message1; std::vector message2; std::vector message3; }; //*************************************************************************** // Bus that handles messages 1, 2, 3 //*************************************************************************** class Bus1 : public etl::message_bus<1> { }; //*********************************** Router1 router1; Bus1 bus1; SUITE(test_message_timer) { //************************************************************************* TEST(message_timer_too_many_timers) { etl::message_timer_atomic<2, std::atomic_uint32_t> timer_controller; etl::timer::id::type id1 = timer_controller.register_timer(message1, router1, 37, etl::timer::mode::Single_Shot); etl::timer::id::type id2 = timer_controller.register_timer(message2, router1, 23, etl::timer::mode::Single_Shot); etl::timer::id::type id3 = timer_controller.register_timer(message3, router1, 11, etl::timer::mode::Single_Shot); CHECK(id1 != etl::timer::id::NO_TIMER); CHECK(id2 != etl::timer::id::NO_TIMER); CHECK(id3 == etl::timer::id::NO_TIMER); timer_controller.clear(); id3 = timer_controller.register_timer(message3, router1, 11, etl::timer::mode::Single_Shot); CHECK(id3 != etl::timer::id::NO_TIMER); } //************************************************************************* TEST(message_timer_one_shot) { etl::message_timer_atomic<3, std::atomic_uint32_t> timer_controller; etl::timer::id::type id1 = timer_controller.register_timer(message1, router1, 37, etl::timer::mode::Single_Shot); etl::timer::id::type id2 = timer_controller.register_timer(message2, router1, 23, etl::timer::mode::Single_Shot); etl::timer::id::type id3 = timer_controller.register_timer(message3, router1, 11, etl::timer::mode::Single_Shot); router1.clear(); timer_controller.start(id1); timer_controller.start(id3); timer_controller.start(id2); timer_controller.enable(true); ticks = 0; const uint32_t step = 1UL; while (ticks <= 100U) { ticks += step; timer_controller.tick(step); } std::vector compare1 = { 37ULL }; std::vector compare2 = { 23ULL }; std::vector compare3 = { 11ULL }; CHECK_ARRAY_EQUAL(compare1.data(), router1.message1.data(), compare1.size()); CHECK_ARRAY_EQUAL(compare2.data(), router1.message2.data(), compare2.size()); CHECK_ARRAY_EQUAL(compare3.data(), router1.message3.data(), compare3.size()); } //************************************************************************* TEST(message_timer_one_shot_after_timeout) { etl::message_timer_atomic<1, std::atomic_uint32_t> timer_controller; etl::timer::id::type id1 = timer_controller.register_timer(message1, router1, 37, etl::timer::mode::Single_Shot); router1.clear(); timer_controller.start(id1); timer_controller.enable(true); ticks = 0; const uint32_t step = 1U; while (ticks <= 100U) { ticks += step; timer_controller.tick(step); } // Timer should have timed out. CHECK(timer_controller.set_period(id1, 50)); timer_controller.start(id1); router1.clear(); ticks = 0; while (ticks <= 100U) { ticks += step; timer_controller.tick(step); } // Timer should have timed out. CHECK_EQUAL(50U, *router1.message1.data()); CHECK(timer_controller.unregister_timer(id1)); CHECK(!timer_controller.unregister_timer(id1)); CHECK(!timer_controller.start(id1)); CHECK(!timer_controller.stop(id1)); } //************************************************************************* TEST(message_timer_repeating) { etl::message_timer_atomic<3, std::atomic_uint32_t> timer_controller; etl::timer::id::type id1 = timer_controller.register_timer(message1, router1, 37, etl::timer::mode::Repeating); etl::timer::id::type id2 = timer_controller.register_timer(message2, router1, 23, etl::timer::mode::Repeating); etl::timer::id::type id3 = timer_controller.register_timer(message3, router1, 11, etl::timer::mode::Repeating); router1.clear(); timer_controller.start(id1); timer_controller.start(id3); timer_controller.start(id2); timer_controller.enable(true); ticks = 0; const uint32_t step = 1U; while (ticks <= 100U) { ticks += step; timer_controller.tick(step); } std::vector compare1 = { 37ULL, 74ULL }; std::vector compare2 = { 23ULL, 46ULL, 69ULL, 92ULL }; std::vector compare3 = { 11ULL, 22ULL, 33ULL, 44ULL, 55ULL, 66ULL, 77ULL, 88ULL, 99ULL }; CHECK_ARRAY_EQUAL(compare1.data(), router1.message1.data(), compare1.size()); CHECK_ARRAY_EQUAL(compare2.data(), router1.message2.data(), compare2.size()); CHECK_ARRAY_EQUAL(compare3.data(), router1.message3.data(), compare3.size()); } //************************************************************************* TEST(message_timer_repeating_bigger_step) { etl::message_timer_atomic<3, std::atomic_uint32_t> timer_controller; etl::timer::id::type id1 = timer_controller.register_timer(message1, router1, 37, etl::timer::mode::Repeating); etl::timer::id::type id2 = timer_controller.register_timer(message2, router1, 23, etl::timer::mode::Repeating); etl::timer::id::type id3 = timer_controller.register_timer(message3, router1, 11, etl::timer::mode::Repeating); router1.clear(); timer_controller.start(id1); timer_controller.start(id3); timer_controller.start(id2); CHECK(!timer_controller.is_running()); timer_controller.enable(true); CHECK(timer_controller.is_running()); ticks = 0; const uint32_t step = 5UL; while (ticks <= 100U) { ticks += step; timer_controller.tick(step); } std::vector compare1 = { 40ULL, 75ULL }; std::vector compare2 = { 25ULL, 50ULL, 70ULL, 95ULL }; std::vector compare3 = { 15ULL, 25ULL, 35ULL, 45ULL, 55ULL, 70ULL, 80ULL, 90ULL, 100ULL }; CHECK_ARRAY_EQUAL(compare1.data(), router1.message1.data(), compare1.size()); CHECK_ARRAY_EQUAL(compare2.data(), router1.message2.data(), compare2.size()); CHECK_ARRAY_EQUAL(compare3.data(), router1.message3.data(), compare3.size()); } //************************************************************************* TEST(message_timer_repeating_stop_start) { etl::message_timer_atomic<3, std::atomic_uint32_t> timer_controller; etl::timer::id::type id1 = timer_controller.register_timer(message1, router1, 37, etl::timer::mode::Repeating); etl::timer::id::type id2 = timer_controller.register_timer(message2, router1, 23, etl::timer::mode::Repeating); etl::timer::id::type id3 = timer_controller.register_timer(message3, router1, 11, etl::timer::mode::Repeating); router1.clear(); timer_controller.start(id3); timer_controller.start(id2); timer_controller.enable(true); ticks = 0; const uint32_t step = 1UL; while (ticks <= 100U) { if (ticks == 40) { timer_controller.start(id1); timer_controller.stop(id2); } if (ticks == 80) { timer_controller.stop(id1); timer_controller.start(id2); } ticks += step; timer_controller.tick(step); } std::vector compare1 = { 77ULL }; std::vector compare2 = { 23ULL }; std::vector compare3 = { 11ULL, 22ULL, 33ULL, 44ULL, 55ULL, 66ULL, 77ULL, 88ULL, 99ULL }; CHECK_ARRAY_EQUAL(compare1.data(), router1.message1.data(), compare1.size()); CHECK_ARRAY_EQUAL(compare2.data(), router1.message2.data(), compare2.size()); CHECK_ARRAY_EQUAL(compare3.data(), router1.message3.data(), compare3.size()); } //************************************************************************* TEST(message_timer_repeating_register_unregister) { etl::message_timer_atomic<3, std::atomic_uint32_t> timer_controller; etl::timer::id::type id1; etl::timer::id::type id2 = timer_controller.register_timer(message2, router1, 23, etl::timer::mode::Repeating); etl::timer::id::type id3 = timer_controller.register_timer(message3, router1, 11, etl::timer::mode::Repeating); router1.clear(); timer_controller.start(id3); timer_controller.start(id2); timer_controller.enable(true); ticks = 0; const uint32_t step = 1UL; while (ticks <= 100U) { if (ticks == 40) { timer_controller.unregister_timer(id2); id1 = timer_controller.register_timer(message1, router1, 37, etl::timer::mode::Repeating); timer_controller.start(id1); } ticks += step; timer_controller.tick(step); } std::vector compare1 = { 77ULL }; std::vector compare2 = { 23ULL }; std::vector compare3 = { 11ULL, 22ULL, 33ULL, 44ULL, 55ULL, 66ULL, 77ULL, 88ULL, 99ULL }; CHECK_ARRAY_EQUAL(compare1.data(), router1.message1.data(), compare1.size()); CHECK_ARRAY_EQUAL(compare2.data(), router1.message2.data(), compare2.size()); CHECK_ARRAY_EQUAL(compare3.data(), router1.message3.data(), compare3.size()); } //************************************************************************* TEST(message_timer_repeating_clear) { etl::message_timer_atomic<3, std::atomic_uint32_t> timer_controller; etl::timer::id::type id1 = timer_controller.register_timer(message1, router1, 37, etl::timer::mode::Repeating); etl::timer::id::type id2 = timer_controller.register_timer(message2, router1, 23, etl::timer::mode::Repeating); etl::timer::id::type id3 = timer_controller.register_timer(message3, router1, 11, etl::timer::mode::Repeating); router1.clear(); timer_controller.start(id1); timer_controller.start(id3); timer_controller.start(id2); timer_controller.enable(true); ticks = 0; const uint32_t step = 1UL; while (ticks <= 100U) { ticks += step; if (ticks == 40) { timer_controller.clear(); } timer_controller.tick(step); } std::vector compare1 = { 37ULL }; std::vector compare2 = { 23ULL }; std::vector compare3 = { 11ULL, 22ULL, 33ULL }; CHECK_ARRAY_EQUAL(compare1.data(), router1.message1.data(), compare1.size()); CHECK_ARRAY_EQUAL(compare2.data(), router1.message2.data(), compare2.size()); CHECK_ARRAY_EQUAL(compare3.data(), router1.message3.data(), compare3.size()); } //************************************************************************* TEST(message_timer_route_through_bus) { etl::message_timer_atomic<3, std::atomic_uint32_t> timer_controller; etl::timer::id::type id1 = timer_controller.register_timer(message1, bus1, 37, etl::timer::mode::Single_Shot, ROUTER1); etl::timer::id::type id2 = timer_controller.register_timer(message2, bus1, 23, etl::timer::mode::Single_Shot, ROUTER1); etl::timer::id::type id3 = timer_controller.register_timer(message3, bus1, 11, etl::timer::mode::Single_Shot, etl::imessage_router::ALL_MESSAGE_ROUTERS); bus1.subscribe(router1); router1.clear(); timer_controller.start(id1); timer_controller.start(id3); timer_controller.start(id2); timer_controller.enable(true); ticks = 0; const uint32_t step = 1UL; while (ticks <= 100U) { ticks += step; timer_controller.tick(step); } std::vector compare1 = { 37ULL }; std::vector compare2 = { 23ULL }; std::vector compare3 = { 11ULL }; CHECK_ARRAY_EQUAL(compare1.data(), router1.message1.data(), compare1.size()); CHECK_ARRAY_EQUAL(compare2.data(), router1.message2.data(), compare2.size()); CHECK_ARRAY_EQUAL(compare3.data(), router1.message3.data(), compare3.size()); } //************************************************************************* TEST(message_timer_immediate_delayed) { etl::message_timer_atomic<3, std::atomic_uint32_t> timer_controller; etl::timer::id::type id1 = timer_controller.register_timer(message1, router1, 37, etl::timer::mode::Repeating); etl::timer::id::type id2 = timer_controller.register_timer(message2, router1, 23, etl::timer::mode::Repeating); etl::timer::id::type id3 = timer_controller.register_timer(message3, router1, 11, etl::timer::mode::Repeating); router1.clear(); timer_controller.start(id1); timer_controller.start(id3); timer_controller.start(id2); timer_controller.enable(true); ticks = 5; timer_controller.tick(uint32_t(ticks)); timer_controller.start(id1, etl::timer::start::Immediate); timer_controller.start(id2, etl::timer::start::Immediate); timer_controller.start(id3, etl::timer::start::Delayed); const uint32_t step = 1UL; while (ticks <= 100U) { ticks += step; timer_controller.tick(step); } std::vector compare1 = { 6ULL, 42ULL, 79ULL }; std::vector compare2 = { 6ULL, 28ULL, 51ULL, 74ULL, 97ULL }; std::vector compare3 = { 16ULL, 27ULL, 38ULL, 49ULL, 60ULL, 71ULL, 82ULL, 93ULL }; CHECK_ARRAY_EQUAL(compare1.data(), router1.message1.data(), compare1.size()); CHECK_ARRAY_EQUAL(compare2.data(), router1.message2.data(), compare2.size()); CHECK_ARRAY_EQUAL(compare3.data(), router1.message3.data(), compare3.size()); } //************************************************************************* TEST(message_timer_one_shot_big_step_short_delay_insert) { etl::message_timer_atomic<3, std::atomic_uint32_t> timer_controller; etl::timer::id::type id1 = timer_controller.register_timer(message1, router1, 15, etl::timer::mode::Single_Shot); etl::timer::id::type id2 = timer_controller.register_timer(message2, router1, 5, etl::timer::mode::Repeating); router1.clear(); timer_controller.start(id1); timer_controller.start(id2); timer_controller.enable(true); ticks = 0; const uint32_t step = 11UL; ticks += step; timer_controller.tick(step); ticks += step; timer_controller.tick(step); std::vector compare1 = { 22 }; std::vector compare2 = { 11, 11, 22, 22 }; CHECK_ARRAY_EQUAL(compare1.data(), router1.message1.data(), compare1.size()); CHECK_ARRAY_EQUAL(compare2.data(), router1.message2.data(), compare2.size()); } //************************************************************************* TEST(callback_timer_one_shot_empty_list_huge_tick_before_insert) { etl::message_timer_atomic<3, std::atomic_uint32_t> timer_controller; etl::timer::id::type id1 = timer_controller.register_timer(message1, router1, 5, etl::timer::mode::Single_Shot); router1.clear(); timer_controller.start(id1); timer_controller.enable(true); ticks = 0; const uint32_t step = 5ULL; for (uint32_t i = 0UL; i < step; ++i) { ++ticks; timer_controller.tick(1); } // Huge tick count. timer_controller.tick(UINT32_MAX - step + 1); timer_controller.start(id1); for (uint32_t i = 0UL; i < step; ++i) { ++ticks; timer_controller.tick(1); } std::vector compare1 = { 5, 10 }; CHECK_ARRAY_EQUAL(compare1.data(), router1.message1.data(), compare1.size()); } //************************************************************************* TEST(message_timer_time_to_next) { etl::message_timer_atomic<3, std::atomic_uint32_t> timer_controller; etl::timer::id::type id1 = timer_controller.register_timer(message1, router1, 37, etl::timer::mode::Repeating); etl::timer::id::type id2 = timer_controller.register_timer(message2, router1, 23, etl::timer::mode::Repeating); etl::timer::id::type id3 = timer_controller.register_timer(message3, router1, 11, etl::timer::mode::Repeating); router1.clear(); timer_controller.start(id1); timer_controller.start(id3); timer_controller.start(id2); timer_controller.enable(true); CHECK_EQUAL(11, timer_controller.time_to_next()); timer_controller.tick(7); CHECK_EQUAL(4, timer_controller.time_to_next()); timer_controller.tick(7); CHECK_EQUAL(8, timer_controller.time_to_next()); timer_controller.tick(7); CHECK_EQUAL(1, timer_controller.time_to_next()); timer_controller.tick(7); CHECK_EQUAL(5, timer_controller.time_to_next()); timer_controller.tick(7); CHECK_EQUAL(2, timer_controller.time_to_next()); timer_controller.tick(7); CHECK_EQUAL(2, timer_controller.time_to_next()); timer_controller.tick(7); CHECK_EQUAL(6, timer_controller.time_to_next()); timer_controller.tick(7); CHECK_EQUAL(10, timer_controller.time_to_next()); timer_controller.tick(7); CHECK_EQUAL(3, timer_controller.time_to_next()); timer_controller.tick(7); CHECK_EQUAL(4, timer_controller.time_to_next()); } //************************************************************************* TEST(message_timer_time_to_next_with_has_active_timer) { etl::message_timer_atomic<3, std::atomic_uint32_t> timer_controller; etl::timer::id::type id1 = timer_controller.register_timer(message1, router1, 37, etl::timer::mode::Single_Shot); etl::timer::id::type id2 = timer_controller.register_timer(message2, router1, 23, etl::timer::mode::Single_Shot); etl::timer::id::type id3 = timer_controller.register_timer(message3, router1, 11, etl::timer::mode::Single_Shot); router1.clear(); timer_controller.start(id1); timer_controller.start(id3); timer_controller.start(id2); timer_controller.enable(true); timer_controller.tick(11); CHECK_EQUAL(12, timer_controller.time_to_next()); CHECK_TRUE(timer_controller.has_active_timer()); timer_controller.tick(23); CHECK_EQUAL(3, timer_controller.time_to_next()); CHECK_TRUE(timer_controller.has_active_timer()); timer_controller.tick(2); CHECK_EQUAL(1, timer_controller.time_to_next()); CHECK_TRUE(timer_controller.has_active_timer()); timer_controller.tick(1); CHECK_EQUAL(static_cast(etl::timer::interval::No_Active_Interval), timer_controller.time_to_next()); CHECK_FALSE(timer_controller.has_active_timer()); } //************************************************************************* #if REALTIME_TEST #if defined(ETL_TARGET_OS_WINDOWS) // Only Windows priority is currently supported #define RAISE_THREAD_PRIORITY SetThreadPriority(GetCurrentThread(), THREAD_PRIORITY_HIGHEST) #define FIX_PROCESSOR_AFFINITY SetThreadAffinityMask(GetCurrentThread(), 1); #else #define RAISE_THREAD_PRIORITY #define FIX_PROCESSOR_AFFINITY #endif etl::message_timer_atomic<3, std::atomic_uint32_t> controller; void timer_event() { const uint32_t TICK = 1UL; uint32_t tick = TICK; ticks = 1; RAISE_THREAD_PRIORITY; FIX_PROCESSOR_AFFINITY; while (ticks <= 1000) { std::this_thread::sleep_for(std::chrono::milliseconds(1)); if (controller.tick(tick)) { tick = TICK; } else { tick += TICK; } ++ticks; } } TEST(message_timer_threads) { FIX_PROCESSOR_AFFINITY; etl::timer::id::type id1 = controller.register_timer(message1, router1, 400, etl::timer::mode::Single_Shot); etl::timer::id::type id2 = controller.register_timer(message2, router1, 100, etl::timer::mode::Repeating); etl::timer::id::type id3 = controller.register_timer(message3, router1, 10, etl::timer::mode::Repeating); router1.clear(); controller.start(id1); controller.start(id2); controller.start(id3); controller.enable(true); std::thread t1(timer_event); bool restart_1 = true; while (ticks < 1000U) { if ((ticks > 200U) && (ticks < 500U)) { controller.stop(id3); } if ((ticks > 600U) && (ticks < 800U)) { controller.start(id3); } if ((ticks > 500U) && restart_1) { controller.start(id1); restart_1 = false; } std::this_thread::sleep_for(std::chrono::milliseconds(1)); } //Join the thread with the main thread t1.join(); CHECK_EQUAL(2U, router1.message1.size()); CHECK_EQUAL(10U, router1.message2.size()); CHECK(router1.message2.size() < 65U); } #endif }; }