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/*
 * Copyright (c) 2018 Intel Corporation
 *
 * SPDX-License-Identifier: Apache-2.0
 */

/*
 * @file
 * @brief Use stack API's in different scenarios
 *
 * This module tests following three basic scenarios:
 *
 * Scenario #1
 * Test thread enters items into a stack, starts the Child thread and
 * waits for a semaphore. Child thread extracts all items from the stack
 * and enters some items back into the stack. Child thread gives the
 * semaphore for Test thread to continue. Once the control is returned
 * back to Test thread, it extracts all items from the stack.
 *
 * Scenario #2
 * Test thread enters an item into stack2, starts a Child thread and
 * extract an item from stack1 once the item is there. The child thread
 * will extract an item from stack2 once the item is there and and enter
 * an item to stack1. The flow of control goes from Test thread to Child
 * thread and so forth.
 *
 * Scenario #3
 * Tests the ISR interfaces. Test thread pushes items into stack2 and gives
 * control to the Child thread. Child thread pops items from stack2 and then
 * pushes items into stack1. Child thread gives back control to the Test thread
 * and Test thread pops the items from stack1.
 * All the Push and Pop operations happen in ISR Context.
 */

#include <ztest.h>
#include <irq_offload.h>

#define TSTACK_SIZE     (512 + CONFIG_TEST_EXTRA_STACKSIZE)
#define STACK_LEN       4

/* stack objects used in this test */
K_STACK_DEFINE(stack1, STACK_LEN);
K_STACK_DEFINE(stack2, STACK_LEN);

/* thread info * */
K_THREAD_STACK_DEFINE(threadstack, TSTACK_SIZE);
struct k_thread thread_data;

/* Data pushed to stack */
static ZTEST_DMEM u32_t data1[STACK_LEN] = { 0xAAAA, 0xBBBB, 0xCCCC, 0xDDDD };
static ZTEST_DMEM u32_t data2[STACK_LEN] = { 0x1111, 0x2222, 0x3333, 0x4444 };
static ZTEST_DMEM u32_t data_isr[STACK_LEN] = { 0xABCD, 0xABCD, 0xABCD,
						0xABCD };

/* semaphore to sync threads */
static struct k_sem end_sema;

/* entry of contexts */
static void tIsr_entry_push(void *p)
{
	u32_t i;

	/* Push items to stack */
	for (i = 0U; i < STACK_LEN; i++) {
		k_stack_push((struct k_stack *)p, data_isr[i]);
	}
}

static void tIsr_entry_pop(void *p)
{
	u32_t i;

	/* Pop items from stack */
	for (i = 0U; i < STACK_LEN; i++) {
		if (p == &stack1) {
			k_stack_pop((struct k_stack *)p, &data1[i], K_NO_WAIT);
		} else {
			k_stack_pop((struct k_stack *)p, &data2[i], K_NO_WAIT);
		}
	}
}

static void thread_entry_fn_single(void *p1, void *p2, void *p3)
{
	u32_t tmp[STACK_LEN];
	u32_t i;

	/* Pop items from stack */
	for (i = STACK_LEN; i; i--) {
		k_stack_pop((struct k_stack *)p1, &tmp[i - 1], K_NO_WAIT);
	}
	zassert_false(memcmp(tmp, data1, STACK_LEN),
		      "Push & Pop items does not match");

	/* Push items from stack */
	for (i = 0U; i < STACK_LEN; i++) {
		k_stack_push((struct k_stack *)p1, data2[i]);
	}

	/* Give control back to Test thread */
	k_sem_give(&end_sema);
}

static void thread_entry_fn_dual(void *p1, void *p2, void *p3)
{
	u32_t tmp[STACK_LEN];
	u32_t i;

	for (i = 0U; i < STACK_LEN; i++) {
		/* Pop items from stack2 */
		k_stack_pop(p2, &tmp[i], K_FOREVER);

		/* Push items to stack1 */
		k_stack_push(p1, data1[i]);

	}
	zassert_false(memcmp(tmp, data2, STACK_LEN),
		      "Push & Pop items does not match");
}

static void thread_entry_fn_isr(void *p1, void *p2, void *p3)
{
	/* Pop items from stack2 */
	irq_offload(tIsr_entry_pop, p2);
	zassert_false(memcmp(data_isr, data2, STACK_LEN),
		      "Push & Pop items does not match");

	/* Push items to stack1 */
	irq_offload(tIsr_entry_push, p1);

	/* Give control back to Test thread */
	k_sem_give(&end_sema);
}

/**
 * @addtogroup kernel_stack_tests
 * @{
 */

/**
 * @brief Verify data passing between threads using single stack
 * @see k_stack_push(), #K_STACK_DEFINE(x), k_stack_pop()
 */
static void test_single_stack_play(void)
{
	u32_t tmp[STACK_LEN];
	u32_t i;

	/* Init kernel objects */
	k_sem_init(&end_sema, 0, 1);

	/* Push items to stack */
	for (i = 0U; i < STACK_LEN; i++) {
		k_stack_push(&stack1, data1[i]);
	}

	k_tid_t tid = k_thread_create(&thread_data, threadstack, TSTACK_SIZE,
				      thread_entry_fn_single, &stack1, NULL,
				      NULL, K_PRIO_PREEMPT(0), K_USER |
				      K_INHERIT_PERMS, 0);

	/* Let the child thread run */
	k_sem_take(&end_sema, K_FOREVER);

	/* Pop items from stack */
	for (i = STACK_LEN; i; i--) {
		k_stack_pop(&stack1, &tmp[i - 1], K_NO_WAIT);
	}

	zassert_false(memcmp(tmp, data2, STACK_LEN),
		      "Push & Pop items does not match");

	/* Clear the spawn thread to avoid side effect */
	k_thread_abort(tid);
}

/**
 * @brief Verify data passing between threads using dual stack
 * @see k_stack_push(), #K_STACK_DEFINE(x), k_stack_pop()
 */
static void test_dual_stack_play(void)
{
	u32_t tmp[STACK_LEN];
	u32_t i;

	k_tid_t tid = k_thread_create(&thread_data, threadstack, TSTACK_SIZE,
				      thread_entry_fn_dual, &stack1, &stack2,
				      NULL, K_PRIO_PREEMPT(0), K_USER |
				      K_INHERIT_PERMS, 0);

	for (i = 0U; i < STACK_LEN; i++) {
		/* Push items to stack2 */
		k_stack_push(&stack2, data2[i]);

		/* Pop items from stack1 */
		k_stack_pop(&stack1, &tmp[i], K_FOREVER);
	}

	zassert_false(memcmp(tmp, data1, STACK_LEN),
		      "Push & Pop items does not match");

	/* Clear the spawn thread to avoid side effect */
	k_thread_abort(tid);
}

/**
 * @brief Verify data passing between thread and ISR
 * @see k_stack_push(), #K_STACK_DEFINE(x), k_stack_pop()
 */
static void test_isr_stack_play(void)
{
	/* Init kernel objects */
	k_sem_init(&end_sema, 0, 1);

	k_tid_t tid = k_thread_create(&thread_data, threadstack, TSTACK_SIZE,
				      thread_entry_fn_isr, &stack1, &stack2,
				      NULL, K_PRIO_PREEMPT(0),
				      K_INHERIT_PERMS, 0);


	/* Push items to stack2 */
	irq_offload(tIsr_entry_push, &stack2);

	/* Let the child thread run */
	k_sem_take(&end_sema, K_FOREVER);

	/* Pop items from stack1 */
	irq_offload(tIsr_entry_pop, &stack1);

	zassert_false(memcmp(data_isr, data1, STACK_LEN),
		      "Push & Pop items does not match");

	/* Clear the spawn thread to avoid side effect */
	k_thread_abort(tid);
}

/**
 * @}
 */

/*test case main entry*/
void test_main(void)
{
	k_thread_access_grant(k_current_get(), &stack1, &stack2, &thread_data,
			      &end_sema, &threadstack);

	ztest_test_suite(test_stack_usage,
			 ztest_user_unit_test(test_single_stack_play),
			 ztest_user_unit_test(test_dual_stack_play),
			 ztest_unit_test(test_isr_stack_play));
	ztest_run_test_suite(test_stack_usage);
}