tests/kernel/pipe/pipe_api/src/test_pipe_contexts.c - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 /*
  * Copyright (c) 2016 Intel Corporation
  *
  * SPDX-License-Identifier: Apache-2.0
  */

 #include <ztest.h>

 #define STACK_SIZE	(1024 + CONFIG_TEST_EXTRA_STACKSIZE)
 #define PIPE_LEN	16
 #define BYTES_TO_WRITE	4
 #define BYTES_TO_READ BYTES_TO_WRITE
 K_MEM_POOL_DEFINE(mpool, BYTES_TO_WRITE, PIPE_LEN, 1, BYTES_TO_WRITE);

 static ZTEST_DMEM unsigned char __aligned(4) data[] = "abcd1234$%^&PIPE";
 /**TESTPOINT: init via K_PIPE_DEFINE*/
 K_PIPE_DEFINE(kpipe, PIPE_LEN, 4);
 K_PIPE_DEFINE(khalfpipe, (PIPE_LEN / 2), 4);
 K_PIPE_DEFINE(kpipe1, PIPE_LEN, 4);
 K_PIPE_DEFINE(pipe_test_alloc, PIPE_LEN, 4);
 struct k_pipe pipe;

 K_THREAD_STACK_DEFINE(tstack, STACK_SIZE);
 K_THREAD_STACK_DEFINE(tstack1, STACK_SIZE);
 K_THREAD_STACK_DEFINE(tstack2, STACK_SIZE);
 struct k_thread tdata;
 struct k_thread tdata1;
 struct k_thread tdata2;
 K_SEM_DEFINE(end_sema, 0, 1);

 /* By design, only two blocks. We should never need more than that, one
  * to allocate the pipe object, one for its buffer. Both should be auto-
  * released when the thread exits
  */
 K_MEM_POOL_DEFINE(test_pool, 128, 128, 4, 4);

 static void tpipe_put(struct k_pipe *ppipe, int timeout)
 {
 	size_t to_wt, wt_byte = 0;

 	for (int i = 0; i < PIPE_LEN; i += wt_byte) {
 		/**TESTPOINT: pipe put*/
 		to_wt = (PIPE_LEN - i) >= BYTES_TO_WRITE ?
 			BYTES_TO_WRITE : (PIPE_LEN - i);
 		zassert_false(k_pipe_put(ppipe, &data[i], to_wt,
 					 &wt_byte, 1, timeout), NULL);
 		zassert_true(wt_byte == to_wt || wt_byte == 1, NULL);
 	}
 }

 static void tpipe_block_put(struct k_pipe *ppipe, struct k_sem *sema,
 			    int timeout)
 {
 	struct k_mem_block block;

 	for (int i = 0; i < PIPE_LEN; i += BYTES_TO_WRITE) {
 		/**TESTPOINT: pipe block put*/
 		zassert_equal(k_mem_pool_alloc(&mpool, &block, BYTES_TO_WRITE,
 					       timeout), 0, NULL);
 		memcpy(block.data, &data[i], BYTES_TO_WRITE);
 		k_pipe_block_put(ppipe, &block, BYTES_TO_WRITE, sema);
 		if (sema) {
 			k_sem_take(sema, K_FOREVER);
 		}
 		k_mem_pool_free(&block);
 	}
 }

 static void tpipe_get(struct k_pipe *ppipe, int timeout)
 {
 	unsigned char rx_data[PIPE_LEN];
 	size_t to_rd, rd_byte = 0;

 	/*get pipe data from "pipe_put"*/
 	for (int i = 0; i < PIPE_LEN; i += rd_byte) {
 		/**TESTPOINT: pipe get*/
 		to_rd = (PIPE_LEN - i) >= BYTES_TO_READ ?
 			BYTES_TO_READ : (PIPE_LEN - i);
 		zassert_false(k_pipe_get(ppipe, &rx_data[i], to_rd,
 					 &rd_byte, 1, timeout), NULL);
 		zassert_true(rd_byte == to_rd || rd_byte == 1, NULL);
 	}
 	for (int i = 0; i < PIPE_LEN; i++) {
 		zassert_equal(rx_data[i], data[i], NULL);
 	}
 }

 static void tThread_entry(void *p1, void *p2, void *p3)
 {
 	tpipe_get((struct k_pipe *)p1, K_FOREVER);
 	k_sem_give(&end_sema);

 	tpipe_put((struct k_pipe *)p1, K_NO_WAIT);
 	k_sem_give(&end_sema);
 }

 static void tThread_block_put(void *p1, void *p2, void *p3)
 {
 	tpipe_block_put((struct k_pipe *)p1, (struct k_sem *)p2, K_NO_WAIT);
 	k_sem_give(&end_sema);
 }

 static void tpipe_thread_thread(struct k_pipe *ppipe)
 {
 	/**TESTPOINT: thread-thread data passing via pipe*/
 	k_tid_t tid = k_thread_create(&tdata, tstack, STACK_SIZE,
 				      tThread_entry, ppipe, NULL, NULL,
 				      K_PRIO_PREEMPT(0),
 				      K_INHERIT_PERMS | K_USER, 0);

 	tpipe_put(ppipe, K_NO_WAIT);
 	k_sem_take(&end_sema, K_FOREVER);

 	k_sem_take(&end_sema, K_FOREVER);
 	tpipe_get(ppipe, K_FOREVER);

 	/* clear the spawned thread avoid side effect */
 	k_thread_abort(tid);
 }

 static void tpipe_kthread_to_kthread(struct k_pipe *ppipe)
 {
 	/**TESTPOINT: thread-thread data passing via pipe*/
 	k_tid_t tid = k_thread_create(&tdata, tstack, STACK_SIZE,
 				      tThread_entry, ppipe, NULL, NULL,
 				      K_PRIO_PREEMPT(0), 0, 0);

 	tpipe_put(ppipe, K_NO_WAIT);
 	k_sem_take(&end_sema, K_FOREVER);

 	k_sem_take(&end_sema, K_FOREVER);
 	tpipe_get(ppipe, K_FOREVER);

 	/* clear the spawned thread avoid side effect */
 	k_thread_abort(tid);
 }

 static void tpipe_put_no_wait(struct k_pipe *ppipe)
 {
 	size_t to_wt, wt_byte = 0;

 	for (int i = 0; i < PIPE_LEN; i += wt_byte) {
 	/**TESTPOINT: pipe put*/
 		to_wt = (PIPE_LEN - i) >= BYTES_TO_WRITE ?
 			BYTES_TO_WRITE : (PIPE_LEN - i);
 		zassert_false(k_pipe_put(ppipe, &data[i], to_wt,
 					&wt_byte, 1, K_NO_WAIT), NULL);
 		zassert_true(wt_byte == to_wt || wt_byte == 1, NULL);
 	}
 }

 static void thread_handler(void *p1, void *p2, void *p3)
 {
 	tpipe_put_no_wait((struct k_pipe *)p1);
 	k_sem_give(&end_sema);
 }

 static void thread_for_block_put(void *p1, void *p2, void *p3)
 {
 	tpipe_block_put((struct k_pipe *)p1, (struct k_sem *)p2, K_FOREVER);
 }

 /**
  * @addtogroup kernel_pipe_tests
  * @{
  */

 /**
  * @brief Test pipe data passing between threads
  * @see k_pipe_init(), k_pipe_put(), #K_PIPE_DEFINE(x)
  */
 void test_pipe_thread2thread(void)
 {
 	/**TESTPOINT: test k_pipe_init pipe*/

 	k_pipe_init(&pipe, data, PIPE_LEN);
 	tpipe_thread_thread(&pipe);

 	/**TESTPOINT: test K_PIPE_DEFINE pipe*/
 	tpipe_thread_thread(&kpipe);
 }

 #ifdef CONFIG_USERSPACE
 /**
  * @brief Test data passing using pipes between user threads
  * @see k_pipe_init(), k_pipe_put(), #K_PIPE_DEFINE(x)
  */
 void test_pipe_user_thread2thread(void)
 {
 	/**TESTPOINT: test k_pipe_init pipe*/

 	struct k_pipe *p = k_object_alloc(K_OBJ_PIPE);

 	zassert_true(p != NULL, NULL);
 	zassert_false(k_pipe_alloc_init(p, PIPE_LEN), NULL);
 	tpipe_thread_thread(&pipe);

 	/**TESTPOINT: test K_PIPE_DEFINE pipe*/
 	tpipe_thread_thread(&kpipe);
 }
 #endif

 /**
  * @brief Test pipe put of blocks
  * @see k_pipe_block_put()
  */
 void test_pipe_block_put(void)
 {

 	/**TESTPOINT: test k_pipe_block_put without semaphore*/
 	k_tid_t tid = k_thread_create(&tdata, tstack, STACK_SIZE,
 				      tThread_block_put, &kpipe, NULL, NULL,
 				      K_PRIO_PREEMPT(0), 0, 0);

 	k_sleep(10);
 	tpipe_get(&kpipe, K_FOREVER);
 	k_sem_take(&end_sema, K_FOREVER);

 	k_thread_abort(tid);
 }

 /**
  * @brief Test pipe block put with semaphore
  * @see k_pipe_block_put()
  */
 void test_pipe_block_put_sema(void)
 {
 	struct k_sem sync_sema;

 	k_sem_init(&sync_sema, 0, 1);
 	/**TESTPOINT: test k_pipe_block_put with semaphore*/
 	k_tid_t tid = k_thread_create(&tdata, tstack, STACK_SIZE,
 				      tThread_block_put, &pipe, &sync_sema,
 				      NULL, K_PRIO_PREEMPT(0), 0, 0);
 	k_sleep(10);
 	tpipe_get(&pipe, K_FOREVER);
 	k_sem_take(&end_sema, K_FOREVER);

 	k_thread_abort(tid);
 }

 /**
  * @brief Test pipe get and put
  * @see k_pipe_put(), k_pipe_get()
  */
 void test_pipe_get_put(void)
 {
 	/**TESTPOINT: test API sequence: [get, put]*/
 	k_tid_t tid = k_thread_create(&tdata, tstack, STACK_SIZE,
 				      tThread_block_put, &kpipe, NULL, NULL,
 				      K_PRIO_PREEMPT(0), 0, 0);

 	/*get will be executed previous to put*/
 	tpipe_get(&kpipe, K_FOREVER);
 	k_sem_take(&end_sema, K_FOREVER);

 	k_thread_abort(tid);
 }
 /**
  * @brief Test resource pool free
  * @see k_mem_pool_malloc()
  */
 #ifdef CONFIG_USERSPACE
 void test_resource_pool_auto_free(void)
 {
 	/* Pool has 2 blocks, both should succeed if kernel object and pipe
 	 * buffer are auto-freed when the allocating threads exit
 	 */
 	zassert_true(k_mem_pool_malloc(&test_pool, 64) != NULL, NULL);
 	zassert_true(k_mem_pool_malloc(&test_pool, 64) != NULL, NULL);
 }
 #endif

 static void tThread_half_pipe_put(void *p1, void *p2, void *p3)
 {
 	tpipe_put((struct k_pipe *)p1, K_FOREVER);
 }

 static void tThread_half_pipe_block_put(void *p1, void *p2, void *p3)
 {
 	tpipe_block_put((struct k_pipe *)p1, (struct k_sem *)p2, K_FOREVER);
 }

 /**
  * @brief Test get/put with smaller pipe buffer
  * @see k_pipe_put(), k_pipe_get()
  */
 void test_half_pipe_get_put(void)
 {
 	/**TESTPOINT: thread-thread data passing via pipe*/
 	k_tid_t tid = k_thread_create(&tdata, tstack, STACK_SIZE,
 				      tThread_half_pipe_put, &khalfpipe,
 				      NULL, NULL, K_PRIO_PREEMPT(0),
 				      K_INHERIT_PERMS | K_USER, 0);

 	tpipe_get(&khalfpipe, K_FOREVER);

 	/* clear the spawned thread avoid side effect */
 	k_thread_abort(tid);
 }

 /**
  * @brief Test pipe block put with semaphore and smaller pipe buffer
  * @see k_pipe_block_put()
  */
 void test_half_pipe_block_put_sema(void)
 {
 	struct k_sem sync_sema;

 	k_sem_init(&sync_sema, 0, 1);

 	/**TESTPOINT: test k_pipe_block_put with semaphore*/
 	k_tid_t tid = k_thread_create(&tdata, tstack, STACK_SIZE,
 				      tThread_half_pipe_block_put,
 				      &khalfpipe, &sync_sema, NULL,
 				      K_PRIO_PREEMPT(0), 0, 0);

 	k_sleep(10);
 	tpipe_get(&khalfpipe, K_FOREVER);

 	k_thread_abort(tid);
 }

 /**
  * @brief Test Initialization and buffer allocation of pipe,
  * with various parameters
  * @see k_pipe_alloc_init(), k_pipe_cleanup()
  */
 void test_pipe_alloc(void)
 {
 	int ret;

 	zassert_false(k_pipe_alloc_init(&pipe_test_alloc, PIPE_LEN), NULL);

 	tpipe_kthread_to_kthread(&pipe_test_alloc);
 	k_pipe_cleanup(&pipe_test_alloc);

 	zassert_false(k_pipe_alloc_init(&pipe_test_alloc, 0), NULL);
 	k_pipe_cleanup(&pipe_test_alloc);

 	ret = k_pipe_alloc_init(&pipe_test_alloc, PIPE_LEN * 8);
 	zassert_true(ret == -ENOMEM,
 		"resource pool is smaller then requested buffer");
 }

 /**
  * @brief Test pending reader in pipe
  * @see k_pipe_put(), k_pipe_get()
  */
 void test_pipe_reader_wait(void)
 {
 	/**TESTPOINT: test k_pipe_block_put with semaphore*/
 	k_tid_t tid = k_thread_create(&tdata, tstack, STACK_SIZE,
 					thread_handler, &kpipe1, NULL, NULL,
 					K_PRIO_PREEMPT(0), 0, 0);

 	tpipe_get(&kpipe1, K_FOREVER);
 	k_sem_take(&end_sema, K_FOREVER);
 	k_thread_abort(tid);
 }

 /**
  * @brief Test pending writer in pipe
  * @see k_pipe_block_put(), k_pipe_get()
  */
 void test_pipe_block_writer_wait(void)
 {
 	struct k_sem s_sema;
 	struct k_sem s_sema1;

 	const int main_low_prio = 10;

 	k_sem_init(&s_sema, 0, 1);
 	k_sem_init(&s_sema1, 0, 1);

 	int old_prio = k_thread_priority_get(k_current_get());

 	k_thread_priority_set(k_current_get(), main_low_prio);
 	/**TESTPOINT: test k_pipe_block_put with semaphore*/

 	k_tid_t tid = k_thread_create(&tdata, tstack, STACK_SIZE,
 					thread_for_block_put, &kpipe1, &s_sema,
 					NULL, K_PRIO_PREEMPT(main_low_prio - 1),
 					0, 0);

 	k_tid_t tid1 = k_thread_create(&tdata1, tstack1, STACK_SIZE,
 					thread_for_block_put, &kpipe1, &s_sema1,
 					NULL, K_PRIO_PREEMPT(main_low_prio - 1),
 					0, 0);

 	tpipe_get(&kpipe1, K_FOREVER);
 	k_thread_priority_set(k_current_get(), old_prio);
 	k_thread_abort(tid);
 	k_thread_abort(tid1);
 }

 /**
  * @}
  */
	/*
	* Copyright (c) 2016 Intel Corporation
	*
	* SPDX-License-Identifier: Apache-2.0
	*/

	#include <ztest.h>

	#define STACK_SIZE (1024 + CONFIG_TEST_EXTRA_STACKSIZE)
	#define PIPE_LEN 16
	#define BYTES_TO_WRITE 4
	#define BYTES_TO_READ BYTES_TO_WRITE
	K_MEM_POOL_DEFINE(mpool, BYTES_TO_WRITE, PIPE_LEN, 1, BYTES_TO_WRITE);

	static ZTEST_DMEM unsigned char __aligned(4) data[] = "abcd1234$%^&PIPE";
	/*TESTPOINT: init via K_PIPE_DEFINE/
	K_PIPE_DEFINE(kpipe, PIPE_LEN, 4);
	K_PIPE_DEFINE(khalfpipe, (PIPE_LEN / 2), 4);
	K_PIPE_DEFINE(kpipe1, PIPE_LEN, 4);
	K_PIPE_DEFINE(pipe_test_alloc, PIPE_LEN, 4);
	struct k_pipe pipe;

	K_THREAD_STACK_DEFINE(tstack, STACK_SIZE);
	K_THREAD_STACK_DEFINE(tstack1, STACK_SIZE);
	K_THREAD_STACK_DEFINE(tstack2, STACK_SIZE);
	struct k_thread tdata;
	struct k_thread tdata1;
	struct k_thread tdata2;
	K_SEM_DEFINE(end_sema, 0, 1);

	/* By design, only two blocks. We should never need more than that, one
	* to allocate the pipe object, one for its buffer. Both should be auto-
	* released when the thread exits
	*/
	K_MEM_POOL_DEFINE(test_pool, 128, 128, 4, 4);

	static void tpipe_put(struct k_pipe *ppipe, int timeout)
	{
	size_t to_wt, wt_byte = 0;

	for (int i = 0; i < PIPE_LEN; i += wt_byte) {
	/*TESTPOINT: pipe put/
	to_wt = (PIPE_LEN - i) >= BYTES_TO_WRITE ?
	BYTES_TO_WRITE : (PIPE_LEN - i);
	zassert_false(k_pipe_put(ppipe, &data[i], to_wt,
	&wt_byte, 1, timeout), NULL);
	zassert_true(wt_byte == to_wt \|\| wt_byte == 1, NULL);
	}
	}

	static void tpipe_block_put(struct k_pipe ppipe, struct k_sem sema,
	int timeout)
	{
	struct k_mem_block block;

	for (int i = 0; i < PIPE_LEN; i += BYTES_TO_WRITE) {
	/*TESTPOINT: pipe block put/
	zassert_equal(k_mem_pool_alloc(&mpool, &block, BYTES_TO_WRITE,
	timeout), 0, NULL);
	memcpy(block.data, &data[i], BYTES_TO_WRITE);
	k_pipe_block_put(ppipe, &block, BYTES_TO_WRITE, sema);
	if (sema) {
	k_sem_take(sema, K_FOREVER);
	}
	k_mem_pool_free(&block);
	}
	}

	static void tpipe_get(struct k_pipe *ppipe, int timeout)
	{
	unsigned char rx_data[PIPE_LEN];
	size_t to_rd, rd_byte = 0;

	/get pipe data from "pipe_put"/
	for (int i = 0; i < PIPE_LEN; i += rd_byte) {
	/*TESTPOINT: pipe get/
	to_rd = (PIPE_LEN - i) >= BYTES_TO_READ ?
	BYTES_TO_READ : (PIPE_LEN - i);
	zassert_false(k_pipe_get(ppipe, &rx_data[i], to_rd,
	&rd_byte, 1, timeout), NULL);
	zassert_true(rd_byte == to_rd \|\| rd_byte == 1, NULL);
	}
	for (int i = 0; i < PIPE_LEN; i++) {
	zassert_equal(rx_data[i], data[i], NULL);
	}
	}

	static void tThread_entry(void p1, void p2, void *p3)
	{
	tpipe_get((struct k_pipe *)p1, K_FOREVER);
	k_sem_give(&end_sema);

	tpipe_put((struct k_pipe *)p1, K_NO_WAIT);
	k_sem_give(&end_sema);
	}

	static void tThread_block_put(void p1, void p2, void *p3)
	{
	tpipe_block_put((struct k_pipe )p1, (struct k_sem )p2, K_NO_WAIT);
	k_sem_give(&end_sema);
	}

	static void tpipe_thread_thread(struct k_pipe *ppipe)
	{
	/*TESTPOINT: thread-thread data passing via pipe/
	k_tid_t tid = k_thread_create(&tdata, tstack, STACK_SIZE,
	tThread_entry, ppipe, NULL, NULL,
	K_PRIO_PREEMPT(0),
	K_INHERIT_PERMS \| K_USER, 0);

	tpipe_put(ppipe, K_NO_WAIT);
	k_sem_take(&end_sema, K_FOREVER);

	k_sem_take(&end_sema, K_FOREVER);
	tpipe_get(ppipe, K_FOREVER);

	/* clear the spawned thread avoid side effect */
	k_thread_abort(tid);
	}

	static void tpipe_kthread_to_kthread(struct k_pipe *ppipe)
	{
	/*TESTPOINT: thread-thread data passing via pipe/
	k_tid_t tid = k_thread_create(&tdata, tstack, STACK_SIZE,
	tThread_entry, ppipe, NULL, NULL,
	K_PRIO_PREEMPT(0), 0, 0);

	tpipe_put(ppipe, K_NO_WAIT);
	k_sem_take(&end_sema, K_FOREVER);

	k_sem_take(&end_sema, K_FOREVER);
	tpipe_get(ppipe, K_FOREVER);

	/* clear the spawned thread avoid side effect */
	k_thread_abort(tid);
	}

	static void tpipe_put_no_wait(struct k_pipe *ppipe)
	{
	size_t to_wt, wt_byte = 0;

	for (int i = 0; i < PIPE_LEN; i += wt_byte) {
	/*TESTPOINT: pipe put/
	to_wt = (PIPE_LEN - i) >= BYTES_TO_WRITE ?
	BYTES_TO_WRITE : (PIPE_LEN - i);
	zassert_false(k_pipe_put(ppipe, &data[i], to_wt,
	&wt_byte, 1, K_NO_WAIT), NULL);
	zassert_true(wt_byte == to_wt \|\| wt_byte == 1, NULL);
	}
	}

	static void thread_handler(void p1, void p2, void *p3)
	{
	tpipe_put_no_wait((struct k_pipe *)p1);
	k_sem_give(&end_sema);
	}

	static void thread_for_block_put(void p1, void p2, void *p3)
	{
	tpipe_block_put((struct k_pipe )p1, (struct k_sem )p2, K_FOREVER);
	}

	/**
	* @addtogroup kernel_pipe_tests
	* @{
	*/

	/**
	* @brief Test pipe data passing between threads
	* @see k_pipe_init(), k_pipe_put(), #K_PIPE_DEFINE(x)
	*/
	void test_pipe_thread2thread(void)
	{
	/*TESTPOINT: test k_pipe_init pipe/

	k_pipe_init(&pipe, data, PIPE_LEN);
	tpipe_thread_thread(&pipe);

	/*TESTPOINT: test K_PIPE_DEFINE pipe/
	tpipe_thread_thread(&kpipe);
	}

	#ifdef CONFIG_USERSPACE
	/**
	* @brief Test data passing using pipes between user threads
	* @see k_pipe_init(), k_pipe_put(), #K_PIPE_DEFINE(x)
	*/
	void test_pipe_user_thread2thread(void)
	{
	/*TESTPOINT: test k_pipe_init pipe/

	struct k_pipe *p = k_object_alloc(K_OBJ_PIPE);

	zassert_true(p != NULL, NULL);
	zassert_false(k_pipe_alloc_init(p, PIPE_LEN), NULL);
	tpipe_thread_thread(&pipe);

	/*TESTPOINT: test K_PIPE_DEFINE pipe/
	tpipe_thread_thread(&kpipe);
	}
	#endif

	/**
	* @brief Test pipe put of blocks
	* @see k_pipe_block_put()
	*/
	void test_pipe_block_put(void)
	{

	/*TESTPOINT: test k_pipe_block_put without semaphore/
	k_tid_t tid = k_thread_create(&tdata, tstack, STACK_SIZE,
	tThread_block_put, &kpipe, NULL, NULL,
	K_PRIO_PREEMPT(0), 0, 0);

	k_sleep(10);
	tpipe_get(&kpipe, K_FOREVER);
	k_sem_take(&end_sema, K_FOREVER);

	k_thread_abort(tid);
	}

	/**
	* @brief Test pipe block put with semaphore
	* @see k_pipe_block_put()
	*/
	void test_pipe_block_put_sema(void)
	{
	struct k_sem sync_sema;

	k_sem_init(&sync_sema, 0, 1);
	/*TESTPOINT: test k_pipe_block_put with semaphore/
	k_tid_t tid = k_thread_create(&tdata, tstack, STACK_SIZE,
	tThread_block_put, &pipe, &sync_sema,
	NULL, K_PRIO_PREEMPT(0), 0, 0);
	k_sleep(10);
	tpipe_get(&pipe, K_FOREVER);
	k_sem_take(&end_sema, K_FOREVER);

	k_thread_abort(tid);
	}

	/**
	* @brief Test pipe get and put
	* @see k_pipe_put(), k_pipe_get()
	*/
	void test_pipe_get_put(void)
	{
	/*TESTPOINT: test API sequence: [get, put]/
	k_tid_t tid = k_thread_create(&tdata, tstack, STACK_SIZE,
	tThread_block_put, &kpipe, NULL, NULL,
	K_PRIO_PREEMPT(0), 0, 0);

	/get will be executed previous to put/
	tpipe_get(&kpipe, K_FOREVER);
	k_sem_take(&end_sema, K_FOREVER);

	k_thread_abort(tid);
	}
	/**
	* @brief Test resource pool free
	* @see k_mem_pool_malloc()
	*/
	#ifdef CONFIG_USERSPACE
	void test_resource_pool_auto_free(void)
	{
	/* Pool has 2 blocks, both should succeed if kernel object and pipe
	* buffer are auto-freed when the allocating threads exit
	*/
	zassert_true(k_mem_pool_malloc(&test_pool, 64) != NULL, NULL);
	zassert_true(k_mem_pool_malloc(&test_pool, 64) != NULL, NULL);
	}
	#endif

	static void tThread_half_pipe_put(void p1, void p2, void *p3)
	{
	tpipe_put((struct k_pipe *)p1, K_FOREVER);
	}

	static void tThread_half_pipe_block_put(void p1, void p2, void *p3)
	{
	tpipe_block_put((struct k_pipe )p1, (struct k_sem )p2, K_FOREVER);
	}

	/**
	* @brief Test get/put with smaller pipe buffer
	* @see k_pipe_put(), k_pipe_get()
	*/
	void test_half_pipe_get_put(void)
	{
	/*TESTPOINT: thread-thread data passing via pipe/
	k_tid_t tid = k_thread_create(&tdata, tstack, STACK_SIZE,
	tThread_half_pipe_put, &khalfpipe,
	NULL, NULL, K_PRIO_PREEMPT(0),
	K_INHERIT_PERMS \| K_USER, 0);

	tpipe_get(&khalfpipe, K_FOREVER);

	/* clear the spawned thread avoid side effect */
	k_thread_abort(tid);
	}

	/**
	* @brief Test pipe block put with semaphore and smaller pipe buffer
	* @see k_pipe_block_put()
	*/
	void test_half_pipe_block_put_sema(void)
	{
	struct k_sem sync_sema;

	k_sem_init(&sync_sema, 0, 1);

	/*TESTPOINT: test k_pipe_block_put with semaphore/
	k_tid_t tid = k_thread_create(&tdata, tstack, STACK_SIZE,
	tThread_half_pipe_block_put,
	&khalfpipe, &sync_sema, NULL,
	K_PRIO_PREEMPT(0), 0, 0);

	k_sleep(10);
	tpipe_get(&khalfpipe, K_FOREVER);

	k_thread_abort(tid);
	}

	/**
	* @brief Test Initialization and buffer allocation of pipe,
	* with various parameters
	* @see k_pipe_alloc_init(), k_pipe_cleanup()
	*/
	void test_pipe_alloc(void)
	{
	int ret;

	zassert_false(k_pipe_alloc_init(&pipe_test_alloc, PIPE_LEN), NULL);

	tpipe_kthread_to_kthread(&pipe_test_alloc);
	k_pipe_cleanup(&pipe_test_alloc);

	zassert_false(k_pipe_alloc_init(&pipe_test_alloc, 0), NULL);
	k_pipe_cleanup(&pipe_test_alloc);

	ret = k_pipe_alloc_init(&pipe_test_alloc, PIPE_LEN * 8);
	zassert_true(ret == -ENOMEM,
	"resource pool is smaller then requested buffer");
	}

	/**
	* @brief Test pending reader in pipe
	* @see k_pipe_put(), k_pipe_get()
	*/
	void test_pipe_reader_wait(void)
	{
	/*TESTPOINT: test k_pipe_block_put with semaphore/
	k_tid_t tid = k_thread_create(&tdata, tstack, STACK_SIZE,
	thread_handler, &kpipe1, NULL, NULL,
	K_PRIO_PREEMPT(0), 0, 0);

	tpipe_get(&kpipe1, K_FOREVER);
	k_sem_take(&end_sema, K_FOREVER);
	k_thread_abort(tid);
	}

	/**
	* @brief Test pending writer in pipe
	* @see k_pipe_block_put(), k_pipe_get()
	*/
	void test_pipe_block_writer_wait(void)
	{
	struct k_sem s_sema;
	struct k_sem s_sema1;

	const int main_low_prio = 10;

	k_sem_init(&s_sema, 0, 1);
	k_sem_init(&s_sema1, 0, 1);

	int old_prio = k_thread_priority_get(k_current_get());

	k_thread_priority_set(k_current_get(), main_low_prio);
	/*TESTPOINT: test k_pipe_block_put with semaphore/

	k_tid_t tid = k_thread_create(&tdata, tstack, STACK_SIZE,
	thread_for_block_put, &kpipe1, &s_sema,
	NULL, K_PRIO_PREEMPT(main_low_prio - 1),
	0, 0);

	k_tid_t tid1 = k_thread_create(&tdata1, tstack1, STACK_SIZE,
	thread_for_block_put, &kpipe1, &s_sema1,
	NULL, K_PRIO_PREEMPT(main_low_prio - 1),
	0, 0);

	tpipe_get(&kpipe1, K_FOREVER);
	k_thread_priority_set(k_current_get(), old_prio);
	k_thread_abort(tid);
	k_thread_abort(tid1);
	}

	/**
	* @}
	*/