tests/kernel/interrupt/src/regular_isr.c - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 /*
  * Copyright (c) 2021 Intel Corporation
  *
  * SPDX-License-Identifier: Apache-2.0
  */

 #include <zephyr/ztest.h>
 #include <zephyr/interrupt_util.h>
 #include <zephyr/irq.h>

 /*
  * Other arch has already been tested in testcase of gen_isr_table,
  * so we only test x86 series here.
  */

 #define TEST_IRQ_LINE_1	27
 #define TEST_IRQ_LINE_2	28

 #define TEST_IRQ_PRIO	2


 volatile uint32_t reg_int_executed[2];

 void isr_comm(const void *param)
 {
 	int choice = POINTER_TO_INT(param);

 	switch (choice) {
 	case TEST_IRQ_LINE_1:
 		reg_int_executed[0]++;
 	break;
 	case TEST_IRQ_LINE_2:
 		reg_int_executed[1]++;
 	break;

 	default:
 	break;
 	}
 }

 /**
  * @brief Test regular interrupt
  *
  * @details Validate regular interrupt works as expected.
  * - Register two regular interrupt at build time.
  * - Trigger interrupt and check if isr handler has executed or not.
  * - Also check irq_enable and irq_disable works.
  *
  * @ingroup kernel_interrupt_tests
  *
  * @see IRQ_CONNECT(), irq_enable(), irq_disable(),
  * irq_unlock(),
  */
 ZTEST(interrupt_feature, test_isr_regular)
 {
 	int trig_vec1, trig_vec2;

 	IRQ_CONNECT(TEST_IRQ_LINE_1, TEST_IRQ_PRIO, isr_comm, (void *)TEST_IRQ_LINE_1, 0);
 	IRQ_CONNECT(TEST_IRQ_LINE_2, TEST_IRQ_PRIO, isr_comm, (void *)TEST_IRQ_LINE_2, 0);

 	trig_vec1 = Z_IRQ_TO_INTERRUPT_VECTOR(TEST_IRQ_LINE_1);
 	trig_vec2 = Z_IRQ_TO_INTERRUPT_VECTOR(TEST_IRQ_LINE_2);

 	TC_PRINT("irq(%d)=vector(%d)\n", TEST_IRQ_LINE_1, trig_vec1);
 	TC_PRINT("irq(%d)=vector(%d)\n", TEST_IRQ_LINE_2, trig_vec2);

 	irq_enable(TEST_IRQ_LINE_1);
 	irq_enable(TEST_IRQ_LINE_2);

 	trigger_irq(trig_vec1);

 	zassert_true(reg_int_executed[0] == 1 &&
 			reg_int_executed[1] == 0,
 			"ISR1 should execute");

 	trigger_irq(trig_vec2);

 	zassert_true(reg_int_executed[0] == 1 &&
 			reg_int_executed[1] == 1,
 			"Both ISR should execute");

 	unsigned int key = irq_lock();

 	/* trigger under irq locked */
 	trigger_irq(trig_vec1);
 	trigger_irq(trig_vec2);

 	zassert_true(reg_int_executed[0] == 1 &&
 			reg_int_executed[1] == 1,
 			"Both ISR should not execute again(%d)(%d)",
 			reg_int_executed[0], reg_int_executed[1]);

 	irq_unlock(key);

 	/* interrupt serve after irq unlocked */
 	zassert_true(reg_int_executed[0] == 2 &&
 			reg_int_executed[1] == 2,
 			"Both ISR should execute again(%d)(%d)",
 			reg_int_executed[0], reg_int_executed[1]);

 	/* trigger after irq unlocked */
 	trigger_irq(trig_vec1);
 	trigger_irq(trig_vec2);

 	zassert_true(reg_int_executed[0] == 3 &&
 			reg_int_executed[1] == 3,
 			"Both ISR should execute again(%d)(%d)",
 			reg_int_executed[0], reg_int_executed[1]);
 }
	/*
	* Copyright (c) 2021 Intel Corporation
	*
	* SPDX-License-Identifier: Apache-2.0
	*/

	#include <zephyr/ztest.h>
	#include <zephyr/interrupt_util.h>
	#include <zephyr/irq.h>

	/*
	* Other arch has already been tested in testcase of gen_isr_table,
	* so we only test x86 series here.
	*/

	#define TEST_IRQ_LINE_1 27
	#define TEST_IRQ_LINE_2 28

	#define TEST_IRQ_PRIO 2


	volatile uint32_t reg_int_executed[2];

	void isr_comm(const void *param)
	{
	int choice = POINTER_TO_INT(param);

	switch (choice) {
	case TEST_IRQ_LINE_1:
	reg_int_executed[0]++;
	break;
	case TEST_IRQ_LINE_2:
	reg_int_executed[1]++;
	break;

	default:
	break;
	}
	}

	/**
	* @brief Test regular interrupt
	*
	* @details Validate regular interrupt works as expected.
	* - Register two regular interrupt at build time.
	* - Trigger interrupt and check if isr handler has executed or not.
	* - Also check irq_enable and irq_disable works.
	*
	* @ingroup kernel_interrupt_tests
	*
	* @see IRQ_CONNECT(), irq_enable(), irq_disable(),
	* irq_unlock(),
	*/
	ZTEST(interrupt_feature, test_isr_regular)
	{
	int trig_vec1, trig_vec2;

	IRQ_CONNECT(TEST_IRQ_LINE_1, TEST_IRQ_PRIO, isr_comm, (void *)TEST_IRQ_LINE_1, 0);
	IRQ_CONNECT(TEST_IRQ_LINE_2, TEST_IRQ_PRIO, isr_comm, (void *)TEST_IRQ_LINE_2, 0);

	trig_vec1 = Z_IRQ_TO_INTERRUPT_VECTOR(TEST_IRQ_LINE_1);
	trig_vec2 = Z_IRQ_TO_INTERRUPT_VECTOR(TEST_IRQ_LINE_2);

	TC_PRINT("irq(%d)=vector(%d)\n", TEST_IRQ_LINE_1, trig_vec1);
	TC_PRINT("irq(%d)=vector(%d)\n", TEST_IRQ_LINE_2, trig_vec2);

	irq_enable(TEST_IRQ_LINE_1);
	irq_enable(TEST_IRQ_LINE_2);

	trigger_irq(trig_vec1);

	zassert_true(reg_int_executed[0] == 1 &&
	reg_int_executed[1] == 0,
	"ISR1 should execute");

	trigger_irq(trig_vec2);

	zassert_true(reg_int_executed[0] == 1 &&
	reg_int_executed[1] == 1,
	"Both ISR should execute");

	unsigned int key = irq_lock();

	/* trigger under irq locked */
	trigger_irq(trig_vec1);
	trigger_irq(trig_vec2);

	zassert_true(reg_int_executed[0] == 1 &&
	reg_int_executed[1] == 1,
	"Both ISR should not execute again(%d)(%d)",
	reg_int_executed[0], reg_int_executed[1]);

	irq_unlock(key);

	/* interrupt serve after irq unlocked */
	zassert_true(reg_int_executed[0] == 2 &&
	reg_int_executed[1] == 2,
	"Both ISR should execute again(%d)(%d)",
	reg_int_executed[0], reg_int_executed[1]);

	/* trigger after irq unlocked */
	trigger_irq(trig_vec1);
	trigger_irq(trig_vec2);

	zassert_true(reg_int_executed[0] == 3 &&
	reg_int_executed[1] == 3,
	"Both ISR should execute again(%d)(%d)",
	reg_int_executed[0], reg_int_executed[1]);
	}