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1022 1023 1024 1025 1026 1027 1028 1029 1030 1031 1032 1033 1034 1035 1036 1037 1038 1039 1040 1041 1042 1043 1044 1045 1046 1047 1048 1049 1050 1051 1052 1053 1054 1055 1056 1057 1058 1059 1060 1061 1062 1063 1064 1065 1066 1067 1068 1069 1070 1071 1072 1073 1074 1075 1076 1077 1078 1079 1080 1081 1082 1083 1084 1085 1086 1087 1088 1089 1090 1091 1092 1093 1094 1095 1096 1097 1098 1099 1100 1101 1102 1103 1104 1105 1106 1107 1108 1109 1110 1111 1112 | /* * Copyright (c) 2012-2015 Wind River Systems, Inc. * * SPDX-License-Identifier: Apache-2.0 */ /* * @brief test context and thread APIs * * @defgroup kernel_context_tests Context Tests * * @ingroup all_tests * * This module tests the following CPU and thread related routines: * k_thread_create(), k_yield(), k_is_in_isr(), * k_current_get(), k_cpu_idle(), k_cpu_atomic_idle(), * irq_lock(), irq_unlock(), * irq_offload(), irq_enable(), irq_disable(), * @{ * @} */ #include <stdlib.h> #include <zephyr/ztest.h> #include <zephyr/kernel_structs.h> #include <zephyr/arch/cpu.h> #include <zephyr/irq_offload.h> #include <zephyr/sys_clock.h> #if defined(CONFIG_SOC_POSIX) /* TIMER_TICK_IRQ <soc.h> header for certain platforms */ #include <soc.h> #endif #define THREAD_STACKSIZE (512 + CONFIG_TEST_EXTRA_STACK_SIZE) #define THREAD_STACKSIZE2 (384 + CONFIG_TEST_EXTRA_STACK_SIZE) #define THREAD_PRIORITY 4 #define THREAD_SELF_CMD 0 #define EXEC_CTX_TYPE_CMD 1 #define UNKNOWN_COMMAND -1 #define INVALID_BEHAVIOUR -2 /* * Get the timer type dependent IRQ number. If timer type * is not defined in platform, generate an error */ #if defined(CONFIG_APIC_TSC_DEADLINE_TIMER) #define TICK_IRQ z_loapic_irq_base() /* first LVT interrupt */ #elif defined(CONFIG_CPU_CORTEX_M) /* * The Cortex-M use the SYSTICK exception for the system timer, which is * not considered an IRQ by the irq_enable/Disable APIs. */ #elif defined(CONFIG_SPARC) #elif defined(CONFIG_MIPS) #elif defined(CONFIG_ARCH_POSIX) #if defined(CONFIG_BOARD_NATIVE_POSIX) #define TICK_IRQ TIMER_TICK_IRQ #else /* * Other POSIX arch boards will skip the irq_disable() and irq_enable() test * unless TICK_IRQ is defined here for them */ #endif /* defined(CONFIG_ARCH_POSIX) */ #else extern const int32_t z_sys_timer_irq_for_test; #define TICK_IRQ (z_sys_timer_irq_for_test) #endif /* Cortex-M1, Nios II, and RISCV without CONFIG_RISCV_HAS_CPU_IDLE * do have a power saving instruction, so k_cpu_idle() returns immediately */ #if !defined(CONFIG_CPU_CORTEX_M1) && !defined(CONFIG_NIOS2) && \ (!defined(CONFIG_RISCV) || defined(CONFIG_RISCV_HAS_CPU_IDLE)) #define HAS_POWERSAVE_INSTRUCTION #endif typedef struct { int command; /* command to process */ int error; /* error value (if any) */ union { void *data; /* pointer to data to use or return */ int value; /* value to be passed or returned */ }; } ISR_INFO; typedef int (*disable_int_func) (int); typedef void (*enable_int_func) (int); static struct k_sem sem_thread; static struct k_timer timer; static struct k_sem reply_timeout; struct k_fifo timeout_order_fifo; static int thread_evidence; static K_THREAD_STACK_DEFINE(thread_stack1, THREAD_STACKSIZE); static K_THREAD_STACK_DEFINE(thread_stack2, THREAD_STACKSIZE); static K_THREAD_STACK_DEFINE(thread_stack3, THREAD_STACKSIZE); static struct k_thread thread_data1; static struct k_thread thread_data2; static struct k_thread thread_data3; static ISR_INFO isr_info; /** * @brief Handler to perform various actions from within an ISR context * * This routine is the ISR handler for isr_handler_trigger(). It performs * the command requested in <isr_info.command>. */ static void isr_handler(const void *data) { ARG_UNUSED(data); if (k_can_yield()) { isr_info.error = INVALID_BEHAVIOUR; } switch (isr_info.command) { case THREAD_SELF_CMD: isr_info.data = (void *)k_current_get(); break; case EXEC_CTX_TYPE_CMD: if (k_is_in_isr()) { isr_info.value = K_ISR; break; } if (_current->base.prio < 0) { isr_info.value = K_COOP_THREAD; break; } isr_info.value = K_PREEMPT_THREAD; break; default: isr_info.error = UNKNOWN_COMMAND; break; } } static void isr_handler_trigger(void) { irq_offload(isr_handler, NULL); } /** * * @brief Initialize kernel objects * * This routine initializes the kernel objects used in this module's tests. * */ static void kernel_init_objects(void) { k_sem_init(&reply_timeout, 0, UINT_MAX); k_timer_init(&timer, NULL, NULL); k_fifo_init(&timeout_order_fifo); } /** * @brief A wrapper for irq_lock() * * @return irq_lock() return value */ int irq_lock_wrapper(int unused) { ARG_UNUSED(unused); return irq_lock(); } /** * @brief A wrapper for irq_unlock() */ void irq_unlock_wrapper(int imask) { irq_unlock(imask); } /** * @brief A wrapper for irq_disable() * * @return @a irq */ int irq_disable_wrapper(int irq) { irq_disable(irq); return irq; } /** * @brief A wrapper for irq_enable() */ void irq_enable_wrapper(int irq) { irq_enable(irq); } #if defined(HAS_POWERSAVE_INSTRUCTION) #if defined(CONFIG_TICKLESS_KERNEL) static struct k_timer idle_timer; static void idle_timer_expiry_function(struct k_timer *timer_id) { k_timer_stop(&idle_timer); } static void _test_kernel_cpu_idle(int atomic) { uint64_t t0, dt; unsigned int i, key; uint32_t dur = k_ms_to_ticks_ceil32(10); uint32_t slop = 1 + k_ms_to_ticks_ceil32(1); /* Set up a time to trigger events to exit idle mode */ k_timer_init(&idle_timer, idle_timer_expiry_function, NULL); for (i = 0; i < 5; i++) { k_usleep(1); t0 = k_uptime_ticks(); k_timer_start(&idle_timer, K_TICKS(dur), K_NO_WAIT); key = irq_lock(); if (atomic) { k_cpu_atomic_idle(key); } else { k_cpu_idle(); } dt = k_uptime_ticks() - t0; zassert_true(abs((int32_t) (dt - dur)) <= slop, "Inaccurate wakeup, idled for %d ticks, expected %d", dt, dur); } } #else /* CONFIG_TICKLESS_KERNEL */ static void _test_kernel_cpu_idle(int atomic) { int tms, tms2; int i; /* Align to a "ms boundary". */ tms = k_uptime_get_32(); while (tms == k_uptime_get_32()) { Z_SPIN_DELAY(50); } tms = k_uptime_get_32(); for (i = 0; i < 5; i++) { /* Repeat the test five times */ if (atomic) { unsigned int key = irq_lock(); k_cpu_atomic_idle(key); } else { k_cpu_idle(); } /* calculating milliseconds per tick*/ tms += k_ticks_to_ms_floor64(1); tms2 = k_uptime_get_32(); zassert_false(tms2 < tms, "Bad ms per tick value computed," "got %d which is less than %d\n", tms2, tms); } } #endif /* CONFIG_TICKLESS_KERNEL */ /** * @brief Test cpu idle function * * @details * Test Objective: * - The kernel architecture provide an idle function to be run when the system * has no work for the current CPU * - This routine tests the k_cpu_atomic_idle() routine * * Testing techniques * - Functional and black box testing * - Interface testing * * Prerequisite Condition: * - HAS_POWERSAVE_INSTRUCTION is set * * Input Specifications: * - N/A * * Test Procedure: * -# Record system time before cpu enters idle state * -# Enter cpu idle state by k_cpu_atomic_idle() * -# Record system time after cpu idle state is interrupted * -# Compare the two system time values. * * Expected Test Result: * - cpu enters idle state for a given time * * Pass/Fail criteria: * - Success if the cpu enters idle state, failure otherwise. * * Assumptions and Constraints * - N/A * * @see k_cpu_atomic_idle() * @ingroup kernel_context_tests */ ZTEST(context_cpu_idle, test_cpu_idle_atomic) { #if defined(CONFIG_ARM) || defined(CONFIG_ARM64) ztest_test_skip(); #else _test_kernel_cpu_idle(1); #endif } /** * @brief Test cpu idle function * * @details * Test Objective: * - The kernel architecture provide an idle function to be run when the system * has no work for the current CPU * - This routine tests the k_cpu_idle() routine * * Testing techniques * - Functional and black box testing * - Interface testing * * Prerequisite Condition: * - HAS_POWERSAVE_INSTRUCTION is set * * Input Specifications: * - N/A * * Test Procedure: * -# Record system time before cpu enters idle state * -# Enter cpu idle state by k_cpu_idle() * -# Record system time after cpu idle state is interrupted * -# Compare the two system time values. * * Expected Test Result: * - cpu enters idle state for a given time * * Pass/Fail criteria: * - Success if the cpu enters idle state, failure otherwise. * * Assumptions and Constraints * - N/A * * @see k_cpu_idle() * @ingroup kernel_context_tests */ ZTEST(context_cpu_idle, test_cpu_idle) { /* * Fixme: remove the skip code when sleep instruction in * nsim_hs_smp is fixed. */ #if defined(CONFIG_SOC_NSIM) && defined(CONFIG_SMP) ztest_test_skip(); #endif _test_kernel_cpu_idle(0); } #else /* HAS_POWERSAVE_INSTRUCTION */ ZTEST(context_cpu_idle, test_cpu_idle) { ztest_test_skip(); } ZTEST(context_cpu_idle, test_cpu_idle_atomic) { ztest_test_skip(); } #endif static void _test_kernel_interrupts(disable_int_func disable_int, enable_int_func enable_int, int irq) { unsigned long long count = 0; unsigned long long i = 0; int tick; int tick2; int imask; /* Align to a "tick boundary" */ tick = sys_clock_tick_get_32(); while (sys_clock_tick_get_32() == tick) { Z_SPIN_DELAY(1000); } tick++; while (sys_clock_tick_get_32() == tick) { Z_SPIN_DELAY(1000); count++; } /* * Inflate <count> so that when we loop later, many ticks should have * elapsed during the loop. This later loop will not exactly match the * previous loop, but it should be close enough in structure that when * combined with the inflated count, many ticks will have passed. */ count <<= 4; imask = disable_int(irq); tick = sys_clock_tick_get_32(); for (i = 0; i < count; i++) { sys_clock_tick_get_32(); Z_SPIN_DELAY(1000); } tick2 = sys_clock_tick_get_32(); /* * Re-enable interrupts before returning (for both success and failure * cases). */ enable_int(imask); /* In TICKLESS, current time is retrieved from a hardware * counter and ticks DO advance with interrupts locked! */ if (!IS_ENABLED(CONFIG_TICKLESS_KERNEL)) { zassert_equal(tick2, tick, "tick advanced with interrupts locked"); } /* Now repeat with interrupts unlocked. */ for (i = 0; i < count; i++) { sys_clock_tick_get_32(); Z_SPIN_DELAY(1000); } tick2 = sys_clock_tick_get_32(); zassert_not_equal(tick, tick2, "tick didn't advance as expected"); } /** * @brief Test routines for disabling and enabling interrupts * * @ingroup kernel_context_tests * * @details * Test Objective: * - To verify kernel architecture layer shall provide a mechanism to * selectively disable and enable specific numeric interrupts. * - This routine tests the routines for disabling and enabling interrupts. * These include irq_lock() and irq_unlock(). * * Testing techniques: * - Interface testing, function and black box testing, * dynamic analysis and testing * * Prerequisite Conditions: * - CONFIG_TICKLESS_KERNEL is not set. * * Input Specifications: * - N/A * * Test Procedure: * -# Do action to align to a tick boundary. * -# Left shift 4 bits for the value of counts. * -# Call irq_lock() and restore its return value to imask. * -# Call sys_clock_tick_get_32() and store its return value to tick. * -# Repeat counts of calling sys_clock_tick_get_32(). * -# Call sys_clock_tick_get_32() and store its return value to tick2. * -# Call irq_unlock() with parameter imask. * -# Check if tick is equal to tick2. * -# Repeat counts of calling sys_clock_tick_get_32(). * -# Call sys_clock_tick_get_32() and store its return value to tick2. * -# Check if tick is NOT equal to tick2. * * Expected Test Result: * - The ticks shall not increase while interrupt locked. * * Pass/Fail Criteria: * - Successful if check points in test procedure are all passed, otherwise * failure. * * Assumptions and Constraints: * - N/A * * @see irq_lock(), irq_unlock() */ ZTEST(context, test_interrupts) { /* IRQ locks don't prevent ticks from advancing in tickless mode */ if (IS_ENABLED(CONFIG_TICKLESS_KERNEL)) { ztest_test_skip(); } _test_kernel_interrupts(irq_lock_wrapper, irq_unlock_wrapper, -1); } /** * @brief Test routines for disabling and enabling interrupts (disable timer) * * @ingroup kernel_context_tests * * @details * Test Objective: * - To verify the kernel architecture layer shall provide a mechanism to * simultaneously mask all local CPU interrupts and return the previous mask * state for restoration. * - This routine tests the routines for disabling and enabling interrupts. * These include irq_disable() and irq_enable(). * * Testing techniques: * - Interface testing, function and black box testing, * dynamic analysis and testing * * Prerequisite Conditions: * - TICK_IRQ is defined. * * Input Specifications: * - N/A * * Test Procedure: * -# Do action to align to a tick boundary. * -# Left shift 4 bit for the value of counts. * -# Call irq_disable() and restore its return value to imask. * -# Call sys_clock_tick_get_32() and store its return value to tick. * -# Repeat counts of calling sys_clock_tick_get_32(). * -# Call sys_clock_tick_get_32() and store its return value to tick2. * -# Call irq_enable() with parameter imask. * -# Check if tick is equal to tick2. * -# Repeat counts of calling sys_clock_tick_get_32(). * -# Call sys_clock_tick_get_32() and store its return value to tick2. * -# Check if tick is NOT equal to tick2. * * Expected Test Result: * - The ticks shall not increase while interrupt locked. * * Pass/Fail Criteria: * - Successful if check points in test procedure are all passed, otherwise * failure. * * Assumptions and Constraints: * - Note that this test works by disabling the timer interrupt * directly, without any interaction with the timer driver or * timeout subsystem. NOT ALL ARCHITECTURES will latch and deliver * a timer interrupt that arrives while the interrupt is disabled, * which means that the timeout list will become corrupted (because * it contains items that should have expired in the past). Any use * of kernel timeouts after completion of this test is disallowed. * RUN THIS TEST LAST IN THE SUITE. * * @see irq_disable(), irq_enable() */ ZTEST(context_one_cpu, test_timer_interrupts) { #if (defined(TICK_IRQ) && defined(CONFIG_TICKLESS_KERNEL)) /* Disable interrupts coming from the timer. */ _test_kernel_interrupts(irq_disable_wrapper, irq_enable_wrapper, TICK_IRQ); #else ztest_test_skip(); #endif } /** * @brief Test some context routines * * @details * Test Objective: * - Thread context handles derived from context switches must be able to be * restored upon interrupt exit * * Testing techniques * - Functional and black box testing * - Interface testing * * Prerequisite Condition: * - N/A * * Input Specifications: * - N/A * * Test Procedure: * -# Set priority of current thread to 0 as a preemptible thread * -# Trap to interrupt context, get thread id of the interrupted thread and * pass back to that thread. * -# Return to thread context and make sure this context is interrupted by * comparing its thread ID and the thread ID passed by isr. * -# Pass command to isr to check whether the isr is executed in interrupt * context * -# When return to thread context, check the return value of command. * * Expected Test Result: * - Thread context restored upon interrupt exit * * Pass/Fail criteria: * - Success if context of thread restored correctly, failure otherwise. * * Assumptions and Constraints * - N/A * * @ingroup kernel_context_tests * @see k_current_get(), k_is_in_isr() */ ZTEST(context, test_ctx_thread) { k_tid_t self_thread_id; k_thread_priority_set(k_current_get(), 0); TC_PRINT("Testing k_current_get() from an ISR and thread\n"); self_thread_id = k_current_get(); isr_info.command = THREAD_SELF_CMD; isr_info.error = 0; /* isr_info is modified by the isr_handler routine */ isr_handler_trigger(); zassert_false(isr_info.error, "ISR detected an error"); zassert_equal(isr_info.data, (void *)self_thread_id, "ISR context ID mismatch"); TC_PRINT("Testing k_is_in_isr() from an ISR\n"); isr_info.command = EXEC_CTX_TYPE_CMD; isr_info.error = 0; isr_handler_trigger(); zassert_false(isr_info.error, "ISR detected an error"); zassert_equal(isr_info.value, K_ISR, "isr_info.value was not K_ISR"); TC_PRINT("Testing k_is_in_isr() from a preemptible thread\n"); zassert_false(k_is_in_isr(), "Should not be in ISR context"); zassert_false(_current->base.prio < 0, "Current thread should have preemptible priority: %d", _current->base.prio); } /** * @brief Test the various context/thread routines from a cooperative thread * * This routines tests the k_current_get() and k_is_in_isr() routines from both * a thread and an ISR (that interrupted a cooperative thread). Checking those * routines with preemptible threads are done elsewhere. * * @see k_current_get(), k_is_in_isr() */ static void _test_kernel_thread(k_tid_t _thread_id) { k_tid_t self_thread_id; self_thread_id = k_current_get(); zassert_true((self_thread_id != _thread_id), "thread id matches parent thread"); isr_info.command = THREAD_SELF_CMD; isr_info.error = 0; isr_handler_trigger(); /* * Either the ISR detected an error, or the ISR context ID * does not match the interrupted thread's ID. */ zassert_false((isr_info.error || (isr_info.data != (void *)self_thread_id)), "Thread ID taken during ISR != calling thread"); isr_info.command = EXEC_CTX_TYPE_CMD; isr_info.error = 0; isr_handler_trigger(); zassert_false((isr_info.error || (isr_info.value != K_ISR)), "k_is_in_isr() when called from an ISR is false"); zassert_false(k_is_in_isr(), "k_is_in_isr() when called from a thread is true"); zassert_false((_current->base.prio >= 0), "thread is not a cooperative thread"); } /** * * @brief Entry point to the thread's helper * * This routine is the entry point to the thread's helper thread. It is used to * help test the behavior of the k_yield() routine. * * @param arg1 unused * @param arg2 unused * @param arg3 unused * */ static void thread_helper(void *arg1, void *arg2, void *arg3) { k_tid_t self_thread_id; ARG_UNUSED(arg1); ARG_UNUSED(arg2); ARG_UNUSED(arg3); /* * This thread starts off at a higher priority than thread_entry(). * Thus, it should execute immediately. */ thread_evidence++; /* Test that helper will yield to a thread of equal priority */ self_thread_id = k_current_get(); /* Lower priority to that of thread_entry() */ k_thread_priority_set(self_thread_id, self_thread_id->base.prio + 1); k_yield(); /* Yield to thread of equal priority */ thread_evidence++; /* thread_evidence should now be 2 */ } /** * @brief Entry point to thread started by another thread * * This routine is the entry point to the thread started by the thread. */ static void k_yield_entry(void *arg0, void *arg1, void *arg2) { k_tid_t self_thread_id; ARG_UNUSED(arg0); ARG_UNUSED(arg1); ARG_UNUSED(arg2); thread_evidence++; /* Prove that the thread has run */ k_sem_take(&sem_thread, K_FOREVER); /* * Start a thread of higher priority. Note that since the new thread is * being started from a thread, it will not automatically switch to the * thread as it would if done from another thread. */ self_thread_id = k_current_get(); thread_evidence = 0; k_thread_create(&thread_data2, thread_stack2, THREAD_STACKSIZE, thread_helper, NULL, NULL, NULL, K_PRIO_COOP(THREAD_PRIORITY - 1), 0, K_NO_WAIT); zassert_equal(thread_evidence, 0, "Helper created at higher priority ran prematurely."); /* * Validate the thread is allowed to yield */ zassert_true(k_can_yield(), "Thread incorrectly detected it could not yield"); /* * Test that the thread will yield to the higher priority helper. * thread_evidence is still 0. */ k_yield(); zassert_not_equal(thread_evidence, 0, "k_yield() did not yield to a higher priority thread: %d", thread_evidence); zassert_false((thread_evidence > 1), "k_yield() did not yield to an equal priority thread: %d", thread_evidence); /* * Raise the priority of thread_entry(). Calling k_yield() should * not result in switching to the helper. */ k_thread_priority_set(self_thread_id, self_thread_id->base.prio - 1); k_yield(); zassert_equal(thread_evidence, 1, "k_yield() yielded to a lower priority thread"); /* * Block on sem_thread. This will allow the helper thread to * complete. The main thread will wake this thread. */ k_sem_take(&sem_thread, K_FOREVER); } static void kernel_thread_entry(void *_thread_id, void *arg1, void *arg2) { ARG_UNUSED(arg1); ARG_UNUSED(arg2); thread_evidence++; /* Prove that the thread has run */ k_sem_take(&sem_thread, K_FOREVER); _test_kernel_thread((k_tid_t) _thread_id); } /* * @brief Timeout tests * * Test the k_sleep() API, as well as the k_thread_create() ones. */ struct timeout_order { void *link_in_fifo; int32_t timeout; int timeout_order; int q_order; }; struct timeout_order timeouts[] = { { 0, 1000, 2, 0 }, { 0, 1500, 4, 1 }, { 0, 500, 0, 2 }, { 0, 750, 1, 3 }, { 0, 1750, 5, 4 }, { 0, 2000, 6, 5 }, { 0, 1250, 3, 6 }, }; #define NUM_TIMEOUT_THREADS ARRAY_SIZE(timeouts) static K_THREAD_STACK_ARRAY_DEFINE(timeout_stacks, NUM_TIMEOUT_THREADS, THREAD_STACKSIZE2); static struct k_thread timeout_threads[NUM_TIMEOUT_THREADS]; /* a thread busy waits */ static void busy_wait_thread(void *mseconds, void *arg2, void *arg3) { uint32_t usecs; ARG_UNUSED(arg2); ARG_UNUSED(arg3); usecs = POINTER_TO_INT(mseconds) * 1000; k_busy_wait(usecs); /* FIXME: Broken on Nios II, see #22956 */ #ifndef CONFIG_NIOS2 int key = arch_irq_lock(); k_busy_wait(usecs); arch_irq_unlock(key); #endif /* * Ideally the test should verify that the correct number of ticks * have elapsed. However, when running under QEMU, the tick interrupt * may be processed on a very irregular basis, meaning that far * fewer than the expected number of ticks may occur for a given * number of clock cycles vs. what would ordinarily be expected. * * Consequently, the best we can do for now to test busy waiting is * to invoke the API and verify that it returns. (If it takes way * too long, or never returns, the main test thread may be able to * time out and report an error.) */ k_sem_give(&reply_timeout); } /* a thread sleeps and times out, then reports through a fifo */ static void thread_sleep(void *delta, void *arg2, void *arg3) { int64_t timestamp; int timeout = POINTER_TO_INT(delta); ARG_UNUSED(arg2); ARG_UNUSED(arg3); timestamp = k_uptime_get(); k_msleep(timeout); timestamp = k_uptime_get() - timestamp; int slop = MAX(k_ticks_to_ms_floor64(2), 1); if (timestamp < timeout || timestamp > timeout + slop) { TC_ERROR("timestamp out of range, got %d\n", (int)timestamp); return; } k_sem_give(&reply_timeout); } /* a thread is started with a delay, then it reports that it ran via a fifo */ static void delayed_thread(void *num, void *arg2, void *arg3) { struct timeout_order *timeout = &timeouts[POINTER_TO_INT(num)]; ARG_UNUSED(arg2); ARG_UNUSED(arg3); TC_PRINT(" thread (q order: %d, t/o: %d) is running\n", timeout->q_order, timeout->timeout); k_fifo_put(&timeout_order_fifo, timeout); } /** * @brief Test timeouts * * @ingroup kernel_context_tests * * @see k_busy_wait(), k_sleep() */ ZTEST(context_one_cpu, test_busy_wait) { int32_t timeout; int rv; timeout = 20; /* in ms */ k_thread_create(&timeout_threads[0], timeout_stacks[0], THREAD_STACKSIZE2, busy_wait_thread, INT_TO_POINTER(timeout), NULL, NULL, K_PRIO_COOP(THREAD_PRIORITY), 0, K_NO_WAIT); rv = k_sem_take(&reply_timeout, K_MSEC(timeout * 2 * 2)); zassert_false(rv, " *** thread timed out waiting for " "k_busy_wait()"); } /** * @brief Test timeouts * * @ingroup kernel_context_tests * * @see k_sleep() */ ZTEST(context_one_cpu, test_k_sleep) { struct timeout_order *data; int32_t timeout; int rv; int i; timeout = 50; k_thread_create(&timeout_threads[0], timeout_stacks[0], THREAD_STACKSIZE2, thread_sleep, INT_TO_POINTER(timeout), NULL, NULL, K_PRIO_COOP(THREAD_PRIORITY), 0, K_NO_WAIT); rv = k_sem_take(&reply_timeout, K_MSEC(timeout * 2)); zassert_equal(rv, 0, " *** thread timed out waiting for thread on " "k_sleep()."); /* test k_thread_create() without cancellation */ TC_PRINT("Testing k_thread_create() without cancellation\n"); for (i = 0; i < NUM_TIMEOUT_THREADS; i++) { k_thread_create(&timeout_threads[i], timeout_stacks[i], THREAD_STACKSIZE2, delayed_thread, INT_TO_POINTER(i), NULL, NULL, K_PRIO_COOP(5), 0, K_MSEC(timeouts[i].timeout)); } for (i = 0; i < NUM_TIMEOUT_THREADS; i++) { data = k_fifo_get(&timeout_order_fifo, K_MSEC(750)); zassert_not_null(data, " *** timeout while waiting for" " delayed thread"); zassert_equal(data->timeout_order, i, " *** wrong delayed thread ran (got %d, " "expected %d)\n", data->timeout_order, i); TC_PRINT(" got thread (q order: %d, t/o: %d) as expected\n", data->q_order, data->timeout); } /* ensure no more thread fire */ data = k_fifo_get(&timeout_order_fifo, K_MSEC(750)); zassert_false(data, " *** got something unexpected in the fifo"); /* test k_thread_create() with cancellation */ TC_PRINT("Testing k_thread_create() with cancellations\n"); int cancellations[] = { 0, 3, 4, 6 }; int num_cancellations = ARRAY_SIZE(cancellations); int next_cancellation = 0; k_tid_t delayed_threads[NUM_TIMEOUT_THREADS]; for (i = 0; i < NUM_TIMEOUT_THREADS; i++) { k_tid_t id; id = k_thread_create(&timeout_threads[i], timeout_stacks[i], THREAD_STACKSIZE2, delayed_thread, INT_TO_POINTER(i), NULL, NULL, K_PRIO_COOP(5), 0, K_MSEC(timeouts[i].timeout)); delayed_threads[i] = id; } for (i = 0; i < NUM_TIMEOUT_THREADS; i++) { int j; if (i == cancellations[next_cancellation]) { TC_PRINT(" cancelling " "[q order: %d, t/o: %d, t/o order: %d]\n", timeouts[i].q_order, timeouts[i].timeout, i); for (j = 0; j < NUM_TIMEOUT_THREADS; j++) { if (timeouts[j].timeout_order == i) { break; } } if (j < NUM_TIMEOUT_THREADS) { k_thread_abort(delayed_threads[j]); ++next_cancellation; continue; } } data = k_fifo_get(&timeout_order_fifo, K_MSEC(2750)); zassert_not_null(data, " *** timeout while waiting for" " delayed thread"); zassert_equal(data->timeout_order, i, " *** wrong delayed thread ran (got %d, " "expected %d)\n", data->timeout_order, i); TC_PRINT(" got (q order: %d, t/o: %d, t/o order %d) " "as expected\n", data->q_order, data->timeout, data->timeout_order); } zassert_equal(num_cancellations, next_cancellation, " *** wrong number of cancellations (expected %d, " "got %d\n", num_cancellations, next_cancellation); /* ensure no more thread fire */ data = k_fifo_get(&timeout_order_fifo, K_MSEC(750)); zassert_false(data, " *** got something unexpected in the fifo"); } /** * * @brief Test the k_yield() routine * * @ingroup kernel_context_tests * * Tests the k_yield() routine. It starts another thread * (thus also testing k_thread_create()) and checks that behavior of * k_yield() against the a higher priority thread, * a lower priority thread, and another thread of equal priority. * * @see k_yield() */ ZTEST(context_one_cpu, test_k_yield) { thread_evidence = 0; k_thread_priority_set(k_current_get(), 0); k_sem_init(&sem_thread, 0, UINT_MAX); k_thread_create(&thread_data1, thread_stack1, THREAD_STACKSIZE, k_yield_entry, NULL, NULL, NULL, K_PRIO_COOP(THREAD_PRIORITY), 0, K_NO_WAIT); zassert_equal(thread_evidence, 1, "Thread did not execute as expected!: %d", thread_evidence); k_sem_give(&sem_thread); k_sem_give(&sem_thread); k_sem_give(&sem_thread); } /** * @brief Test kernel thread creation * * @ingroup kernel_context_tests * * @see k_thread_create */ ZTEST(context_one_cpu, test_thread) { k_thread_create(&thread_data3, thread_stack3, THREAD_STACKSIZE, kernel_thread_entry, NULL, NULL, NULL, K_PRIO_COOP(THREAD_PRIORITY), 0, K_NO_WAIT); } static void *context_setup(void) { kernel_init_objects(); return NULL; } ZTEST_SUITE(context_cpu_idle, NULL, context_setup, NULL, NULL, NULL); ZTEST_SUITE(context, NULL, context_setup, NULL, NULL, NULL); ZTEST_SUITE(context_one_cpu, NULL, context_setup, ztest_simple_1cpu_before, ztest_simple_1cpu_after, NULL); |