tests/ztest/error_hook/src/main.c - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 /*
  * Copyright (c) 2020 Intel Corporation
  *
  * SPDX-License-Identifier: Apache-2.0
  */

 #include <zephyr/irq_offload.h>
 #include <zephyr/syscall_handler.h>

 #include <ztest.h>
 #include <ztest_error_hook.h>

 #define STACK_SIZE (1024 + CONFIG_TEST_EXTRA_STACK_SIZE)
 #define THREAD_TEST_PRIORITY 5

 static K_THREAD_STACK_DEFINE(tstack, STACK_SIZE);
 static struct k_thread tdata;

 static ZTEST_BMEM int case_type;

 /* A semaphore using inside irq_offload */
 extern struct k_sem offload_sem;

 /* test case type */
 enum {
 	ZTEST_CATCH_FATAL_ACCESS,
 	ZTEST_CATCH_FATAL_ILLEAGAL_INSTRUCTION,
 	ZTEST_CATCH_FATAL_DIVIDE_ZERO,
 	ZTEST_CATCH_FATAL_K_PANIC,
 	ZTEST_CATCH_FATAL_K_OOPS,
 	ZTEST_CATCH_FATAL_IN_ISR,
 	ZTEST_CATCH_ASSERT_FAIL,
 	ZTEST_CATCH_ASSERT_IN_ISR,
 	ZTEST_CATCH_USER_FATAL_Z_OOPS,
 	ZTEST_ERROR_MAX
 } error_case_type;


 static void trigger_assert_fail(void *a)
 {
 	/* trigger an assert fail condition */
 	__ASSERT(a != NULL, "parameter a should not be NULL!");
 }

 /*
  * Do not optimize to prevent GCC from generating invalid
  * opcode exception instruction instead of real instruction.
  */
 __no_optimization static void trigger_fault_illegal_instruction(void)
 {
 	void *a = NULL;

 	/* execute an illegal instruction */
 	((void(*)(void))&a)();
 }

 /*
  * Do not optimize to prevent GCC from generating invalid
  * opcode exception instruction instead of real instruction.
  */
 __no_optimization static void trigger_fault_access(void)
 {
 #if defined(CONFIG_SOC_ARC_IOT) || defined(CONFIG_SOC_NSIM) || defined(CONFIG_SOC_EMSK)
 	/* For iotdk, em_starterkit and ARC/nSIM, nSIM simulates full address space of
 	 * memory, iotdk has eflash at 0x0 address, em_starterkit has ICCM at 0x0 address,
 	 * access to 0x0 address doesn't generate any exception. So we access to 0XFFFFFFFF
 	 * address instead to trigger exception. See issue #31419.
 	 */
 	void *a = (void *)0xFFFFFFFF;
 #elif defined(CONFIG_CPU_CORTEX_M) || defined(CONFIG_CPU_AARCH32_CORTEX_R) || \
 	defined(CONFIG_CPU_AARCH64_CORTEX_R)
 	/* As this test case only runs when User Mode is enabled,
 	 * accessing _current always triggers a memory access fault,
 	 * and is guaranteed not to trigger SecureFault exceptions.
 	 */
 	void *a = (void *)_current;
 #else
 	/* For most arch which support userspace, dereferencing NULL
 	 * pointer will be caught by exception.
 	 *
 	 * Note: this is not applicable for ARM Cortex-M:
 	 * In Cortex-M, nPRIV read access to address 0x0 is generally allowed,
 	 * provided that it is "mapped" e.g. when CONFIG_FLASH_BASE_ADDRESS is
 	 * 0x0. So, de-referencing NULL pointer is not guaranteed to trigger an
 	 * exception.
 	 */
 	void *a = (void *)NULL;
 #endif
 	/* access an illegal address */
 	volatile int b = *((int *)a);

 	printk("b is %d\n", b);
 }


 /*
  * Do not optimize the divide instruction. GCC will generate invalid
  * opcode exception instruction instead of real divide instruction.
  */
 __no_optimization static void trigger_fault_divide_zero(void)
 {
 	int a = 1;
 	int b = 0;

 	/* divide by zero */
 	a = a / b;
 	printk("a is %d\n", a);

 /*
  * While no optimization is enabled, some QEMU such as QEMU cortex a53
  * series, QEMU mps2 and mps3 series and QEMU ARC series boards will not
  * trigger an exception for divide zero. They might need to enable the divide
  * zero exception. We only skip the QEMU board here, this means this
  * test will still apply on the physical board.
  * For the Cortex-M0, M0+, M23 (CONFIG_ARMV6_M_ARMV8_M_BASELINE)
  * which does not include a divide instruction, the test is skipped,
  * and there will be no hardware exception for that.
  */
 #if (defined(CONFIG_SOC_SERIES_MPS2) && defined(CONFIG_QEMU_TARGET)) || \
 	(defined(CONFIG_SOC_SERIES_MPS3) && defined(CONFIG_QEMU_TARGET)) || \
 	defined(CONFIG_BOARD_QEMU_CORTEX_A53) || defined(CONFIG_SOC_QEMU_ARC) || \
 	defined(CONFIG_ARMV6_M_ARMV8_M_BASELINE) || \
 	defined(CONFIG_BOARD_QEMU_CORTEX_R5) || \
 	defined(CONFIG_BOARD_FVP_BASER_AEMV8R) || defined(CONFIG_BOARD_FVP_BASE_REVC_2XAEMV8A)
 	ztest_test_skip();
 #endif
 }

 static void trigger_fault_oops(void)
 {
 	k_oops();
 }

 static void trigger_fault_panic(void)
 {
 	k_panic();
 }

 static void release_offload_sem(void)
 {
 	/* Semaphore used inside irq_offload needs to be
 	 * released after an assert or a fault has happened.
 	 */
 	k_sem_give(&offload_sem);
 }

 /* This is the fatal error hook that allows you to do actions after
  * the fatal error has occurred. This is optional; you can choose
  * to define the hook yourself. If not, the program will use the
  * default one.
  */
 void ztest_post_fatal_error_hook(unsigned int reason,
 		const z_arch_esf_t *pEsf)
 {
 	switch (case_type) {
 	case ZTEST_CATCH_FATAL_ACCESS:
 	case ZTEST_CATCH_FATAL_ILLEAGAL_INSTRUCTION:
 	case ZTEST_CATCH_FATAL_DIVIDE_ZERO:
 	case ZTEST_CATCH_FATAL_K_PANIC:
 	case ZTEST_CATCH_FATAL_K_OOPS:
 	case ZTEST_CATCH_USER_FATAL_Z_OOPS:
 		zassert_true(true, NULL);
 		break;

 	/* Unfortunately, the case of trigger a fatal error
 	 * inside ISR context still cannot be dealt with,
 	 * So please don't use it this way.
 	 */
 	case ZTEST_CATCH_FATAL_IN_ISR:
 		zassert_true(false, NULL);
 		break;
 	default:
 		zassert_true(false, NULL);
 		break;
 	}
 }

 /* This is the assert fail post hook that allows you to do actions after
  * the assert fail happened. This is optional, you can choose to define
  * the hook yourself. If not, the program will use the default one.
  */
 void ztest_post_assert_fail_hook(void)
 {
 	switch (case_type) {
 	case ZTEST_CATCH_ASSERT_FAIL:
 		ztest_test_pass();
 		break;
 	case ZTEST_CATCH_ASSERT_IN_ISR:
 		release_offload_sem();
 		ztest_test_pass();
 		break;

 	default:
 		ztest_test_fail();
 		break;
 	}
 }

 static void tThread_entry(void *p1, void *p2, void *p3)
 {
 	int sub_type = *(int *)p1;

 	printk("case type is %d\n", case_type);

 	ztest_set_fault_valid(false);

 	switch (sub_type) {
 	case ZTEST_CATCH_FATAL_ACCESS:
 		ztest_set_fault_valid(true);
 		trigger_fault_access();
 		break;
 	case ZTEST_CATCH_FATAL_ILLEAGAL_INSTRUCTION:
 		ztest_set_fault_valid(true);
 		trigger_fault_illegal_instruction();
 		break;
 	case ZTEST_CATCH_FATAL_DIVIDE_ZERO:
 		ztest_set_fault_valid(true);
 		trigger_fault_divide_zero();
 		break;
 	case ZTEST_CATCH_FATAL_K_PANIC:
 		ztest_set_fault_valid(true);
 		trigger_fault_panic();
 		break;
 	case ZTEST_CATCH_FATAL_K_OOPS:
 		ztest_set_fault_valid(true);
 		trigger_fault_oops();
 		break;

 	default:
 		break;
 	}

 	/* should not reach here */
 	ztest_test_fail();
 }

 static int run_trigger_thread(int i)
 {
 	int ret;
 	uint32_t perm = K_INHERIT_PERMS;

 	case_type = i;

 	if (k_is_user_context()) {
 		perm = perm | K_USER;
 	}

 	k_tid_t tid = k_thread_create(&tdata, tstack, STACK_SIZE,
 			(k_thread_entry_t)tThread_entry,
 			(void *)&case_type, NULL, NULL,
 			K_PRIO_PREEMPT(THREAD_TEST_PRIORITY),
 			perm, K_NO_WAIT);

 	ret = k_thread_join(tid, K_FOREVER);

 	return ret;
 }

 /**
  * @brief Test if a fatal error can be caught
  *
  * @details Valid a fatal error we triggered in thread context works.
  * If the fatal error happened and the program enter assert_post_handler,
  * that means fatal error triggered as expected.
  */
 ZTEST_USER(error_hook_tests, test_catch_fatal_error)
 {
 #if defined(CONFIG_USERSPACE)
 	run_trigger_thread(ZTEST_CATCH_FATAL_ACCESS);
 	run_trigger_thread(ZTEST_CATCH_FATAL_ILLEAGAL_INSTRUCTION);
 #if !defined(CONFIG_RISCV)
 	/*
 	 * Because RISC-V Arch doesn't trigger exception for division-by-zero,
 	 * this test couldn't support RISC-V.
 	 * (RISC-V ISA Manual v2.2, Ch6.2 Division Operation)
 	 */
 	run_trigger_thread(ZTEST_CATCH_FATAL_DIVIDE_ZERO);
 #endif
 #endif
 	run_trigger_thread(ZTEST_CATCH_FATAL_K_PANIC);
 	run_trigger_thread(ZTEST_CATCH_FATAL_K_OOPS);
 }

 /**
  * @brief Test if catching an assert works
  *
  * @details Valid the assert in thread context works or not. If the assert
  * fail happened and the program enter assert_post_handler, that means
  * assert works as expected.
  */
 ZTEST_USER(error_hook_tests, test_catch_assert_fail)
 {
 	case_type = ZTEST_CATCH_ASSERT_FAIL;

 	printk("1\n");
 	ztest_set_assert_valid(false);

 	printk("2\n");
 	ztest_set_assert_valid(true);

 	printk("3\n");
 	trigger_assert_fail(NULL);

 	printk("4\n");
 	ztest_test_fail();
 }

 /* a handler using by irq_offload  */
 static void tIsr_assert(const void *p)
 {
 	ztest_set_assert_valid(true);
 	trigger_assert_fail(NULL);
 }

 /**
  * @brief Test if an assert fail works in ISR context
  *
  * @details Valid the assert in ISR context works or not. If the assert
  * fail happened and the program enter assert_post_handler, that means
  * assert works as expected.
  */
 ZTEST(error_hook_tests, test_catch_assert_in_isr)
 {
 	case_type = ZTEST_CATCH_ASSERT_IN_ISR;
 	irq_offload(tIsr_assert, NULL);
 }


 #if defined(CONFIG_USERSPACE)
 static void trigger_z_oops(void)
 {
 	/* Set up a dummy syscall frame, pointing to a valid area in memory. */
 	_current->syscall_frame = _image_ram_start;

 	Z_OOPS(true);
 }

 /**
  * @brief Test if a z_oops can be catched
  *
  * @details Valid a z_oops we triggered in thread context works.
  * If the z_oops happened and the program enter our handler,
  * that means z_oops triggered as expected. This test only for
  * userspace.
  */
 ZTEST(error_hook_tests, test_catch_z_oops)
 {
 	case_type = ZTEST_CATCH_USER_FATAL_Z_OOPS;

 	ztest_set_fault_valid(true);
 	trigger_z_oops();
 }
 #endif


 static void *error_hook_tests_setup(void)
 {
 #if defined(CONFIG_USERSPACE)
 	k_thread_access_grant(k_current_get(), &tdata, &tstack);
 #endif
 	return NULL;
 }
 ZTEST_SUITE(error_hook_tests, NULL, error_hook_tests_setup, NULL, NULL, NULL);

 static void *fail_assume_in_setup_setup(void)
 {
 	/* Fail the assume, will skip all the tests */
 	zassume_true(false, NULL);
 	return NULL;
 }

 ZTEST_SUITE(fail_assume_in_setup, NULL, fail_assume_in_setup_setup, NULL, NULL, NULL);

 ZTEST(fail_assume_in_setup, test_to_skip0)
 {
 	/* This test should never be run */
 	ztest_test_fail();
 }

 ZTEST(fail_assume_in_setup, test_to_skip1)
 {
 	/* This test should never be run */
 	ztest_test_fail();
 }

 static void fail_assume_in_before_before(void *unused)
 {
 	ARG_UNUSED(unused);
 	zassume_true(false, NULL);
 }

 ZTEST_SUITE(fail_assume_in_before, NULL, NULL, fail_assume_in_before_before, NULL, NULL);

 ZTEST(fail_assume_in_before, test_to_skip0)
 {
 	/* This test should never be run */
 	ztest_test_fail();
 }

 ZTEST(fail_assume_in_before, test_to_skip1)
 {
 	/* This test should never be run */
 	ztest_test_fail();
 }

 ZTEST_SUITE(fail_assume_in_test, NULL, NULL, NULL, NULL, NULL);

 ZTEST(fail_assume_in_test, test_to_skip)
 {
 	zassume_true(false, NULL);
 	ztest_test_fail();
 }

 void test_main(void)
 {
 	ztest_run_test_suites(NULL);
 	/* Can't run ztest_verify_all_test_suites_ran() since some tests are
 	 * skipped by design.
 	 */
 }
	/*
	* Copyright (c) 2020 Intel Corporation
	*
	* SPDX-License-Identifier: Apache-2.0
	*/

	#include <zephyr/irq_offload.h>
	#include <zephyr/syscall_handler.h>

	#include <ztest.h>
	#include <ztest_error_hook.h>

	#define STACK_SIZE (1024 + CONFIG_TEST_EXTRA_STACK_SIZE)
	#define THREAD_TEST_PRIORITY 5

	static K_THREAD_STACK_DEFINE(tstack, STACK_SIZE);
	static struct k_thread tdata;

	static ZTEST_BMEM int case_type;

	/* A semaphore using inside irq_offload */
	extern struct k_sem offload_sem;

	/* test case type */
	enum {
	ZTEST_CATCH_FATAL_ACCESS,
	ZTEST_CATCH_FATAL_ILLEAGAL_INSTRUCTION,
	ZTEST_CATCH_FATAL_DIVIDE_ZERO,
	ZTEST_CATCH_FATAL_K_PANIC,
	ZTEST_CATCH_FATAL_K_OOPS,
	ZTEST_CATCH_FATAL_IN_ISR,
	ZTEST_CATCH_ASSERT_FAIL,
	ZTEST_CATCH_ASSERT_IN_ISR,
	ZTEST_CATCH_USER_FATAL_Z_OOPS,
	ZTEST_ERROR_MAX
	} error_case_type;


	static void trigger_assert_fail(void *a)
	{
	/* trigger an assert fail condition */
	__ASSERT(a != NULL, "parameter a should not be NULL!");
	}

	/*
	* Do not optimize to prevent GCC from generating invalid
	* opcode exception instruction instead of real instruction.
	*/
	__no_optimization static void trigger_fault_illegal_instruction(void)
	{
	void *a = NULL;

	/* execute an illegal instruction */
	((void(*)(void))&a)();
	}

	/*
	* Do not optimize to prevent GCC from generating invalid
	* opcode exception instruction instead of real instruction.
	*/
	__no_optimization static void trigger_fault_access(void)
	{
	#if defined(CONFIG_SOC_ARC_IOT) \|\| defined(CONFIG_SOC_NSIM) \|\| defined(CONFIG_SOC_EMSK)
	/* For iotdk, em_starterkit and ARC/nSIM, nSIM simulates full address space of
	* memory, iotdk has eflash at 0x0 address, em_starterkit has ICCM at 0x0 address,
	* access to 0x0 address doesn't generate any exception. So we access to 0XFFFFFFFF
	* address instead to trigger exception. See issue #31419.
	*/
	void a = (void )0xFFFFFFFF;
	#elif defined(CONFIG_CPU_CORTEX_M) \|\| defined(CONFIG_CPU_AARCH32_CORTEX_R) \|\| \
	defined(CONFIG_CPU_AARCH64_CORTEX_R)
	/* As this test case only runs when User Mode is enabled,
	* accessing _current always triggers a memory access fault,
	* and is guaranteed not to trigger SecureFault exceptions.
	*/
	void a = (void )_current;
	#else
	/* For most arch which support userspace, dereferencing NULL
	* pointer will be caught by exception.
	*
	* Note: this is not applicable for ARM Cortex-M:
	* In Cortex-M, nPRIV read access to address 0x0 is generally allowed,
	* provided that it is "mapped" e.g. when CONFIG_FLASH_BASE_ADDRESS is
	* 0x0. So, de-referencing NULL pointer is not guaranteed to trigger an
	* exception.
	*/
	void a = (void )NULL;
	#endif
	/* access an illegal address */
	volatile int b = ((int )a);

	printk("b is %d\n", b);
	}


	/*
	* Do not optimize the divide instruction. GCC will generate invalid
	* opcode exception instruction instead of real divide instruction.
	*/
	__no_optimization static void trigger_fault_divide_zero(void)
	{
	int a = 1;
	int b = 0;

	/* divide by zero */
	a = a / b;
	printk("a is %d\n", a);

	/*
	* While no optimization is enabled, some QEMU such as QEMU cortex a53
	* series, QEMU mps2 and mps3 series and QEMU ARC series boards will not
	* trigger an exception for divide zero. They might need to enable the divide
	* zero exception. We only skip the QEMU board here, this means this
	* test will still apply on the physical board.
	* For the Cortex-M0, M0+, M23 (CONFIG_ARMV6_M_ARMV8_M_BASELINE)
	* which does not include a divide instruction, the test is skipped,
	* and there will be no hardware exception for that.
	*/
	#if (defined(CONFIG_SOC_SERIES_MPS2) && defined(CONFIG_QEMU_TARGET)) \|\| \
	(defined(CONFIG_SOC_SERIES_MPS3) && defined(CONFIG_QEMU_TARGET)) \|\| \
	defined(CONFIG_BOARD_QEMU_CORTEX_A53) \|\| defined(CONFIG_SOC_QEMU_ARC) \|\| \
	defined(CONFIG_ARMV6_M_ARMV8_M_BASELINE) \|\| \
	defined(CONFIG_BOARD_QEMU_CORTEX_R5) \|\| \
	defined(CONFIG_BOARD_FVP_BASER_AEMV8R) \|\| defined(CONFIG_BOARD_FVP_BASE_REVC_2XAEMV8A)
	ztest_test_skip();
	#endif
	}

	static void trigger_fault_oops(void)
	{
	k_oops();
	}

	static void trigger_fault_panic(void)
	{
	k_panic();
	}

	static void release_offload_sem(void)
	{
	/* Semaphore used inside irq_offload needs to be
	* released after an assert or a fault has happened.
	*/
	k_sem_give(&offload_sem);
	}

	/* This is the fatal error hook that allows you to do actions after
	* the fatal error has occurred. This is optional; you can choose
	* to define the hook yourself. If not, the program will use the
	* default one.
	*/
	void ztest_post_fatal_error_hook(unsigned int reason,
	const z_arch_esf_t *pEsf)
	{
	switch (case_type) {
	case ZTEST_CATCH_FATAL_ACCESS:
	case ZTEST_CATCH_FATAL_ILLEAGAL_INSTRUCTION:
	case ZTEST_CATCH_FATAL_DIVIDE_ZERO:
	case ZTEST_CATCH_FATAL_K_PANIC:
	case ZTEST_CATCH_FATAL_K_OOPS:
	case ZTEST_CATCH_USER_FATAL_Z_OOPS:
	zassert_true(true, NULL);
	break;

	/* Unfortunately, the case of trigger a fatal error
	* inside ISR context still cannot be dealt with,
	* So please don't use it this way.
	*/
	case ZTEST_CATCH_FATAL_IN_ISR:
	zassert_true(false, NULL);
	break;
	default:
	zassert_true(false, NULL);
	break;
	}
	}

	/* This is the assert fail post hook that allows you to do actions after
	* the assert fail happened. This is optional, you can choose to define
	* the hook yourself. If not, the program will use the default one.
	*/
	void ztest_post_assert_fail_hook(void)
	{
	switch (case_type) {
	case ZTEST_CATCH_ASSERT_FAIL:
	ztest_test_pass();
	break;
	case ZTEST_CATCH_ASSERT_IN_ISR:
	release_offload_sem();
	ztest_test_pass();
	break;

	default:
	ztest_test_fail();
	break;
	}
	}

	static void tThread_entry(void p1, void p2, void *p3)
	{
	int sub_type = (int )p1;

	printk("case type is %d\n", case_type);

	ztest_set_fault_valid(false);

	switch (sub_type) {
	case ZTEST_CATCH_FATAL_ACCESS:
	ztest_set_fault_valid(true);
	trigger_fault_access();
	break;
	case ZTEST_CATCH_FATAL_ILLEAGAL_INSTRUCTION:
	ztest_set_fault_valid(true);
	trigger_fault_illegal_instruction();
	break;
	case ZTEST_CATCH_FATAL_DIVIDE_ZERO:
	ztest_set_fault_valid(true);
	trigger_fault_divide_zero();
	break;
	case ZTEST_CATCH_FATAL_K_PANIC:
	ztest_set_fault_valid(true);
	trigger_fault_panic();
	break;
	case ZTEST_CATCH_FATAL_K_OOPS:
	ztest_set_fault_valid(true);
	trigger_fault_oops();
	break;

	default:
	break;
	}

	/* should not reach here */
	ztest_test_fail();
	}

	static int run_trigger_thread(int i)
	{
	int ret;
	uint32_t perm = K_INHERIT_PERMS;

	case_type = i;

	if (k_is_user_context()) {
	perm = perm \| K_USER;
	}

	k_tid_t tid = k_thread_create(&tdata, tstack, STACK_SIZE,
	(k_thread_entry_t)tThread_entry,
	(void *)&case_type, NULL, NULL,
	K_PRIO_PREEMPT(THREAD_TEST_PRIORITY),
	perm, K_NO_WAIT);

	ret = k_thread_join(tid, K_FOREVER);

	return ret;
	}

	/**
	* @brief Test if a fatal error can be caught
	*
	* @details Valid a fatal error we triggered in thread context works.
	* If the fatal error happened and the program enter assert_post_handler,
	* that means fatal error triggered as expected.
	*/
	ZTEST_USER(error_hook_tests, test_catch_fatal_error)
	{
	#if defined(CONFIG_USERSPACE)
	run_trigger_thread(ZTEST_CATCH_FATAL_ACCESS);
	run_trigger_thread(ZTEST_CATCH_FATAL_ILLEAGAL_INSTRUCTION);
	#if !defined(CONFIG_RISCV)
	/*
	* Because RISC-V Arch doesn't trigger exception for division-by-zero,
	* this test couldn't support RISC-V.
	* (RISC-V ISA Manual v2.2, Ch6.2 Division Operation)
	*/
	run_trigger_thread(ZTEST_CATCH_FATAL_DIVIDE_ZERO);
	#endif
	#endif
	run_trigger_thread(ZTEST_CATCH_FATAL_K_PANIC);
	run_trigger_thread(ZTEST_CATCH_FATAL_K_OOPS);
	}

	/**
	* @brief Test if catching an assert works
	*
	* @details Valid the assert in thread context works or not. If the assert
	* fail happened and the program enter assert_post_handler, that means
	* assert works as expected.
	*/
	ZTEST_USER(error_hook_tests, test_catch_assert_fail)
	{
	case_type = ZTEST_CATCH_ASSERT_FAIL;

	printk("1\n");
	ztest_set_assert_valid(false);

	printk("2\n");
	ztest_set_assert_valid(true);

	printk("3\n");
	trigger_assert_fail(NULL);

	printk("4\n");
	ztest_test_fail();
	}

	/* a handler using by irq_offload */
	static void tIsr_assert(const void *p)
	{
	ztest_set_assert_valid(true);
	trigger_assert_fail(NULL);
	}

	/**
	* @brief Test if an assert fail works in ISR context
	*
	* @details Valid the assert in ISR context works or not. If the assert
	* fail happened and the program enter assert_post_handler, that means
	* assert works as expected.
	*/
	ZTEST(error_hook_tests, test_catch_assert_in_isr)
	{
	case_type = ZTEST_CATCH_ASSERT_IN_ISR;
	irq_offload(tIsr_assert, NULL);
	}


	#if defined(CONFIG_USERSPACE)
	static void trigger_z_oops(void)
	{
	/* Set up a dummy syscall frame, pointing to a valid area in memory. */
	_current->syscall_frame = _image_ram_start;

	Z_OOPS(true);
	}

	/**
	* @brief Test if a z_oops can be catched
	*
	* @details Valid a z_oops we triggered in thread context works.
	* If the z_oops happened and the program enter our handler,
	* that means z_oops triggered as expected. This test only for
	* userspace.
	*/
	ZTEST(error_hook_tests, test_catch_z_oops)
	{
	case_type = ZTEST_CATCH_USER_FATAL_Z_OOPS;

	ztest_set_fault_valid(true);
	trigger_z_oops();
	}
	#endif


	static void *error_hook_tests_setup(void)
	{
	#if defined(CONFIG_USERSPACE)
	k_thread_access_grant(k_current_get(), &tdata, &tstack);
	#endif
	return NULL;
	}
	ZTEST_SUITE(error_hook_tests, NULL, error_hook_tests_setup, NULL, NULL, NULL);

	static void *fail_assume_in_setup_setup(void)
	{
	/* Fail the assume, will skip all the tests */
	zassume_true(false, NULL);
	return NULL;
	}

	ZTEST_SUITE(fail_assume_in_setup, NULL, fail_assume_in_setup_setup, NULL, NULL, NULL);

	ZTEST(fail_assume_in_setup, test_to_skip0)
	{
	/* This test should never be run */
	ztest_test_fail();
	}

	ZTEST(fail_assume_in_setup, test_to_skip1)
	{
	/* This test should never be run */
	ztest_test_fail();
	}

	static void fail_assume_in_before_before(void *unused)
	{
	ARG_UNUSED(unused);
	zassume_true(false, NULL);
	}

	ZTEST_SUITE(fail_assume_in_before, NULL, NULL, fail_assume_in_before_before, NULL, NULL);

	ZTEST(fail_assume_in_before, test_to_skip0)
	{
	/* This test should never be run */
	ztest_test_fail();
	}

	ZTEST(fail_assume_in_before, test_to_skip1)
	{
	/* This test should never be run */
	ztest_test_fail();
	}

	ZTEST_SUITE(fail_assume_in_test, NULL, NULL, NULL, NULL, NULL);

	ZTEST(fail_assume_in_test, test_to_skip)
	{
	zassume_true(false, NULL);
	ztest_test_fail();
	}

	void test_main(void)
	{
	ztest_run_test_suites(NULL);
	/* Can't run ztest_verify_all_test_suites_ran() since some tests are
	* skipped by design.
	*/
	}