kernel/pipes.c - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 /*
  * Copyright (c) 2016 Wind River Systems, Inc.
  *
  * SPDX-License-Identifier: Apache-2.0
  */

 /**
  * @file
  *
  * @brief Pipes
  */

 #include <kernel.h>
 #include <kernel_structs.h>
 #include <debug/object_tracing_common.h>
 #include <toolchain.h>
 #include <linker/sections.h>
 #include <wait_q.h>
 #include <sys/dlist.h>
 #include <init.h>
 #include <syscall_handler.h>
 #include <sys/__assert.h>
 #include <kernel_internal.h>

 struct k_pipe_desc {
 	unsigned char *buffer;           /* Position in src/dest buffer */
 	size_t bytes_to_xfer;            /* # bytes left to transfer */
 #if (CONFIG_NUM_PIPE_ASYNC_MSGS > 0)
 	struct k_mem_block *block;       /* Pointer to memory block */
 	struct k_mem_block  copy_block;  /* For backwards compatibility */
 	struct k_sem *sem;               /* Semaphore to give if async */
 #endif
 };

 struct k_pipe_async {
 	struct _thread_base thread;   /* Dummy thread object */
 	struct k_pipe_desc  desc;     /* Pipe message descriptor */
 };

 #ifdef CONFIG_OBJECT_TRACING
 struct k_pipe *_trace_list_k_pipe;
 #endif	/* CONFIG_OBJECT_TRACING */

 #if (CONFIG_NUM_PIPE_ASYNC_MSGS > 0)

 /* stack of unused asynchronous message descriptors */
 K_STACK_DEFINE(pipe_async_msgs, CONFIG_NUM_PIPE_ASYNC_MSGS);

 /* Allocate an asynchronous message descriptor */
 static void pipe_async_alloc(struct k_pipe_async **async)
 {
 	(void)k_stack_pop(&pipe_async_msgs, (stack_data_t *)async, K_FOREVER);
 }

 /* Free an asynchronous message descriptor */
 static void pipe_async_free(struct k_pipe_async *async)
 {
 	k_stack_push(&pipe_async_msgs, (stack_data_t)async);
 }

 /* Finish an asynchronous operation */
 static void pipe_async_finish(struct k_pipe_async *async_desc)
 {
 	/*
 	 * An asynchronous operation is finished with the scheduler locked
 	 * to prevent the called routines from scheduling a new thread.
 	 */

 	k_mem_pool_free(async_desc->desc.block);

 	if (async_desc->desc.sem != NULL) {
 		k_sem_give(async_desc->desc.sem);
 	}

 	pipe_async_free(async_desc);
 }
 #endif /* CONFIG_NUM_PIPE_ASYNC_MSGS > 0 */

 #if (CONFIG_NUM_PIPE_ASYNC_MSGS > 0) || \
 	defined(CONFIG_OBJECT_TRACING)

 /*
  * Do run-time initialization of pipe object subsystem.
  */
 static int init_pipes_module(struct device *dev)
 {
 	ARG_UNUSED(dev);

 	/* Array of asynchronous message descriptors */
 	static struct k_pipe_async __noinit async_msg[CONFIG_NUM_PIPE_ASYNC_MSGS];

 #if (CONFIG_NUM_PIPE_ASYNC_MSGS > 0)
 	/*
 	 * Create pool of asynchronous pipe message descriptors.
 	 *
 	 * A dummy thread requires minimal initialization, since it never gets
 	 * to execute. The _THREAD_DUMMY flag is sufficient to distinguish a
 	 * dummy thread from a real one. The threads are *not* added to the
 	 * kernel's list of known threads.
 	 *
 	 * Once initialized, the address of each descriptor is added to a stack
 	 * that governs access to them.
 	 */

 	for (int i = 0; i < CONFIG_NUM_PIPE_ASYNC_MSGS; i++) {
 		async_msg[i].thread.thread_state = _THREAD_DUMMY;
 		async_msg[i].thread.swap_data = &async_msg[i].desc;

 		z_init_thread_timeout(&async_msg[i].thread);

 		k_stack_push(&pipe_async_msgs, (stack_data_t)&async_msg[i]);
 	}
 #endif /* CONFIG_NUM_PIPE_ASYNC_MSGS > 0 */

 	/* Complete initialization of statically defined mailboxes. */

 #ifdef CONFIG_OBJECT_TRACING
 	Z_STRUCT_SECTION_FOREACH(k_pipe, pipe) {
 		SYS_TRACING_OBJ_INIT(k_pipe, pipe);
 	}
 #endif /* CONFIG_OBJECT_TRACING */

 	return 0;
 }

 SYS_INIT(init_pipes_module, PRE_KERNEL_1, CONFIG_KERNEL_INIT_PRIORITY_OBJECTS);

 #endif /* CONFIG_NUM_PIPE_ASYNC_MSGS or CONFIG_OBJECT_TRACING */

 void k_pipe_init(struct k_pipe *pipe, unsigned char *buffer, size_t size)
 {
 	pipe->buffer = buffer;
 	pipe->size = size;
 	pipe->bytes_used = 0;
 	pipe->read_index = 0;
 	pipe->write_index = 0;
 	pipe->flags = 0;
 	z_waitq_init(&pipe->wait_q.writers);
 	z_waitq_init(&pipe->wait_q.readers);
 	SYS_TRACING_OBJ_INIT(k_pipe, pipe);
 	z_object_init(pipe);
 }

 int z_impl_k_pipe_alloc_init(struct k_pipe *pipe, size_t size)
 {
 	void *buffer;
 	int ret;

 	if (size != 0) {
 		buffer = z_thread_malloc(size);
 		if (buffer != NULL) {
 			k_pipe_init(pipe, buffer, size);
 			pipe->flags = K_PIPE_FLAG_ALLOC;
 			ret = 0;
 		} else {
 			ret = -ENOMEM;
 		}
 	} else {
 		k_pipe_init(pipe, NULL, 0);
 		ret = 0;
 	}

 	return ret;
 }

 #ifdef CONFIG_USERSPACE
 static inline int z_vrfy_k_pipe_alloc_init(struct k_pipe *pipe, size_t size)
 {
 	Z_OOPS(Z_SYSCALL_OBJ_NEVER_INIT(pipe, K_OBJ_PIPE));

 	return z_impl_k_pipe_alloc_init(pipe, size);
 }
 #include <syscalls/k_pipe_alloc_init_mrsh.c>
 #endif

 void k_pipe_cleanup(struct k_pipe *pipe)
 {
 	__ASSERT_NO_MSG(!z_waitq_head(&pipe->wait_q.readers));
 	__ASSERT_NO_MSG(!z_waitq_head(&pipe->wait_q.writers));

 	if ((pipe->flags & K_PIPE_FLAG_ALLOC) != 0) {
 		k_free(pipe->buffer);
 		pipe->buffer = NULL;
 		pipe->flags &= ~K_PIPE_FLAG_ALLOC;
 	}
 }

 /**
  * @brief Copy bytes from @a src to @a dest
  *
  * @return Number of bytes copied
  */
 static size_t pipe_xfer(unsigned char *dest, size_t dest_size,
 			 const unsigned char *src, size_t src_size)
 {
 	size_t num_bytes = MIN(dest_size, src_size);
 	const unsigned char *end = src + num_bytes;

 	while (src != end) {
 		*dest = *src;
 		dest++;
 		src++;
 	}

 	return num_bytes;
 }

 /**
  * @brief Put data from @a src into the pipe's circular buffer
  *
  * Modifies the following fields in @a pipe:
  *        buffer, bytes_used, write_index
  *
  * @return Number of bytes written to the pipe's circular buffer
  */
 static size_t pipe_buffer_put(struct k_pipe *pipe,
 			       const unsigned char *src, size_t src_size)
 {
 	size_t  bytes_copied;
 	size_t  run_length;
 	size_t  num_bytes_written = 0;
 	int     i;


 	for (i = 0; i < 2; i++) {
 		run_length = MIN(pipe->size - pipe->bytes_used,
 				 pipe->size - pipe->write_index);

 		bytes_copied = pipe_xfer(pipe->buffer + pipe->write_index,
 					  run_length,
 					  src + num_bytes_written,
 					  src_size - num_bytes_written);

 		num_bytes_written += bytes_copied;
 		pipe->bytes_used += bytes_copied;
 		pipe->write_index += bytes_copied;
 		if (pipe->write_index == pipe->size) {
 			pipe->write_index = 0;
 		}
 	}

 	return num_bytes_written;
 }

 /**
  * @brief Get data from the pipe's circular buffer
  *
  * Modifies the following fields in @a pipe:
  *        bytes_used, read_index
  *
  * @return Number of bytes read from the pipe's circular buffer
  */
 static size_t pipe_buffer_get(struct k_pipe *pipe,
 			       unsigned char *dest, size_t dest_size)
 {
 	size_t  bytes_copied;
 	size_t  run_length;
 	size_t  num_bytes_read = 0;
 	int     i;

 	for (i = 0; i < 2; i++) {
 		run_length = MIN(pipe->bytes_used,
 				 pipe->size - pipe->read_index);

 		bytes_copied = pipe_xfer(dest + num_bytes_read,
 					  dest_size - num_bytes_read,
 					  pipe->buffer + pipe->read_index,
 					  run_length);

 		num_bytes_read += bytes_copied;
 		pipe->bytes_used -= bytes_copied;
 		pipe->read_index += bytes_copied;
 		if (pipe->read_index == pipe->size) {
 			pipe->read_index = 0;
 		}
 	}

 	return num_bytes_read;
 }

 /**
  * @brief Prepare a working set of readers/writers
  *
  * Prepare a list of "working threads" into/from which the data
  * will be directly copied. This list is useful as it is used to ...
  *
  *  1. avoid double copying
  *  2. minimize interrupt latency as interrupts are unlocked
  *     while copying data
  *  3. ensure a timeout can not make the request impossible to satisfy
  *
  * The list is populated with previously pended threads that will be ready to
  * run after the pipe call is complete.
  *
  * Important things to remember when reading from the pipe ...
  * 1. If there are writers int @a wait_q, then the pipe's buffer is full.
  * 2. Conversely if the pipe's buffer is not full, there are no writers.
  * 3. The amount of available data in the pipe is the sum the bytes used in
  *    the pipe (@a pipe_space) and all the requests from the waiting writers.
  * 4. Since data is read from the pipe's buffer first, the working set must
  *    include writers that will (try to) re-fill the pipe's buffer afterwards.
  *
  * Important things to remember when writing to the pipe ...
  * 1. If there are readers in @a wait_q, then the pipe's buffer is empty.
  * 2. Conversely if the pipe's buffer is not empty, then there are no readers.
  * 3. The amount of space available in the pipe is the sum of the bytes unused
  *    in the pipe (@a pipe_space) and all the requests from the waiting readers.
  *
  * @return false if request is unsatisfiable, otherwise true
  */
 static bool pipe_xfer_prepare(sys_dlist_t      *xfer_list,
 			       struct k_thread **waiter,
 			       _wait_q_t        *wait_q,
 			       size_t            pipe_space,
 			       size_t            bytes_to_xfer,
 			       size_t            min_xfer,
 			       s32_t           timeout)
 {
 	struct k_thread  *thread;
 	struct k_pipe_desc *desc;
 	size_t num_bytes = 0;

 	if (timeout == K_NO_WAIT) {
 		_WAIT_Q_FOR_EACH(wait_q, thread) {
 			desc = (struct k_pipe_desc *)thread->base.swap_data;

 			num_bytes += desc->bytes_to_xfer;

 			if (num_bytes >= bytes_to_xfer) {
 				break;
 			}
 		}

 		if (num_bytes + pipe_space < min_xfer) {
 			return false;
 		}
 	}

 	/*
 	 * Either @a timeout is not K_NO_WAIT (so the thread may pend) or
 	 * the entire request can be satisfied. Generate the working list.
 	 */

 	sys_dlist_init(xfer_list);
 	num_bytes = 0;

 	while ((thread = z_waitq_head(wait_q)) != NULL) {
 		desc = (struct k_pipe_desc *)thread->base.swap_data;
 		num_bytes += desc->bytes_to_xfer;

 		if (num_bytes > bytes_to_xfer) {
 			/*
 			 * This request can not be fully satisfied.
 			 * Do not remove it from the wait_q.
 			 * Do not abort its timeout (if applicable).
 			 * Do not add it to the transfer list
 			 */
 			break;
 		}

 		/*
 		 * This request can be fully satisfied.
 		 * Remove it from the wait_q.
 		 * Abort its timeout.
 		 * Add it to the transfer list.
 		 */
 		z_unpend_thread(thread);
 		sys_dlist_append(xfer_list, &thread->base.qnode_dlist);
 	}

 	*waiter = (num_bytes > bytes_to_xfer) ? thread : NULL;

 	return true;
 }

 /**
  * @brief Determine the correct return code
  *
  * Bytes Xferred   No Wait   Wait
  *   >= Minimum       0       0
  *    < Minimum      -EIO*   -EAGAIN
  *
  * * The "-EIO No Wait" case was already checked when the "working set"
  *   was created in  _pipe_xfer_prepare().
  *
  * @return See table above
  */
 static int pipe_return_code(size_t min_xfer, size_t bytes_remaining,
 			     size_t bytes_requested)
 {
 	if (bytes_requested - bytes_remaining >= min_xfer) {
 		/*
 		 * At least the minimum number of requested
 		 * bytes have been transferred.
 		 */
 		return 0;
 	}

 	return -EAGAIN;
 }

 /**
  * @brief Ready a pipe thread
  *
  * If the pipe thread is a real thread, then add it to the ready queue.
  * If it is a dummy thread, then finish the asynchronous work.
  *
  * @return N/A
  */
 static void pipe_thread_ready(struct k_thread *thread)
 {
 #if (CONFIG_NUM_PIPE_ASYNC_MSGS > 0)
 	if ((thread->base.thread_state & _THREAD_DUMMY) != 0U) {
 		pipe_async_finish((struct k_pipe_async *)thread);
 		return;
 	}
 #endif

 	z_ready_thread(thread);
 }

 /**
  * @brief Internal API used to send data to a pipe
  */
 int z_pipe_put_internal(struct k_pipe *pipe, struct k_pipe_async *async_desc,
 			 unsigned char *data, size_t bytes_to_write,
 			 size_t *bytes_written, size_t min_xfer,
 			 s32_t timeout)
 {
 	struct k_thread    *reader;
 	struct k_pipe_desc *desc;
 	sys_dlist_t    xfer_list;
 	size_t         num_bytes_written = 0;
 	size_t         bytes_copied;

 #if (CONFIG_NUM_PIPE_ASYNC_MSGS == 0)
 	ARG_UNUSED(async_desc);
 #endif

 	k_spinlock_key_t key = k_spin_lock(&pipe->lock);

 	/*
 	 * Create a list of "working readers" into which the data will be
 	 * directly copied.
 	 */

 	if (!pipe_xfer_prepare(&xfer_list, &reader, &pipe->wait_q.readers,
 				pipe->size - pipe->bytes_used, bytes_to_write,
 				min_xfer, timeout)) {
 		k_spin_unlock(&pipe->lock, key);
 		*bytes_written = 0;
 		return -EIO;
 	}

 	z_sched_lock();
 	k_spin_unlock(&pipe->lock, key);

 	/*
 	 * 1. 'xfer_list' currently contains a list of reader threads that can
 	 * have their read requests fulfilled by the current call.
 	 * 2. 'reader' if not NULL points to a thread on the reader wait_q
 	 * that can get some of its requested data.
 	 * 3. Interrupts are unlocked but the scheduler is locked to allow
 	 * ticks to be delivered but no scheduling to occur
 	 * 4. If 'reader' times out while we are copying data, not only do we
 	 * still have a pointer to it, but it can not execute until this call
 	 * is complete so it is still safe to copy data to it.
 	 */

 	struct k_thread *thread = (struct k_thread *)
 				  sys_dlist_get(&xfer_list);
 	while (thread != NULL) {
 		desc = (struct k_pipe_desc *)thread->base.swap_data;
 		bytes_copied = pipe_xfer(desc->buffer, desc->bytes_to_xfer,
 					  data + num_bytes_written,
 					  bytes_to_write - num_bytes_written);

 		num_bytes_written   += bytes_copied;
 		desc->buffer        += bytes_copied;
 		desc->bytes_to_xfer -= bytes_copied;

 		/* The thread's read request has been satisfied. Ready it. */
 		z_ready_thread(thread);

 		thread = (struct k_thread *)sys_dlist_get(&xfer_list);
 	}

 	/*
 	 * Copy any data to the reader that we left on the wait_q.
 	 * It is possible no data will be copied.
 	 */
 	if (reader != NULL) {
 		desc = (struct k_pipe_desc *)reader->base.swap_data;
 		bytes_copied = pipe_xfer(desc->buffer, desc->bytes_to_xfer,
 					  data + num_bytes_written,
 					  bytes_to_write - num_bytes_written);

 		num_bytes_written   += bytes_copied;
 		desc->buffer        += bytes_copied;
 		desc->bytes_to_xfer -= bytes_copied;
 	}

 	/*
 	 * As much data as possible has been directly copied to any waiting
 	 * readers. Add as much as possible to the pipe's circular buffer.
 	 */

 	num_bytes_written +=
 		pipe_buffer_put(pipe, data + num_bytes_written,
 				 bytes_to_write - num_bytes_written);

 	if (num_bytes_written == bytes_to_write) {
 		*bytes_written = num_bytes_written;
 #if (CONFIG_NUM_PIPE_ASYNC_MSGS > 0)
 		if (async_desc != NULL) {
 			pipe_async_finish(async_desc);
 		}
 #endif
 		k_sched_unlock();
 		return 0;
 	}

 	/* Not all data was copied. */

 #if (CONFIG_NUM_PIPE_ASYNC_MSGS > 0)
 	if (async_desc != NULL) {
 		/*
 		 * Lock interrupts and unlock the scheduler before
 		 * manipulating the writers wait_q.
 		 */
 		k_spinlock_key_t key = k_spin_lock(&pipe->lock);
 		z_sched_unlock_no_reschedule();

 		async_desc->desc.buffer = data + num_bytes_written;
 		async_desc->desc.bytes_to_xfer =
 			bytes_to_write - num_bytes_written;

 		z_pend_thread((struct k_thread *) &async_desc->thread,
 			     &pipe->wait_q.writers, K_FOREVER);
 		z_reschedule(&pipe->lock, key);
 		return 0;
 	}
 #endif

 	struct k_pipe_desc  pipe_desc;

 	pipe_desc.buffer         = data + num_bytes_written;
 	pipe_desc.bytes_to_xfer  = bytes_to_write - num_bytes_written;

 	if (timeout != K_NO_WAIT) {
 		_current->base.swap_data = &pipe_desc;
 		/*
 		 * Lock interrupts and unlock the scheduler before
 		 * manipulating the writers wait_q.
 		 */
 		k_spinlock_key_t key = k_spin_lock(&pipe->lock);
 		z_sched_unlock_no_reschedule();
 		(void)z_pend_curr(&pipe->lock, key,
 				 &pipe->wait_q.writers, timeout);
 	} else {
 		k_sched_unlock();
 	}

 	*bytes_written = bytes_to_write - pipe_desc.bytes_to_xfer;

 	return pipe_return_code(min_xfer, pipe_desc.bytes_to_xfer,
 				 bytes_to_write);
 }

 int z_impl_k_pipe_get(struct k_pipe *pipe, void *data, size_t bytes_to_read,
 		     size_t *bytes_read, size_t min_xfer, s32_t timeout)
 {
 	struct k_thread    *writer;
 	struct k_pipe_desc *desc;
 	sys_dlist_t    xfer_list;
 	size_t         num_bytes_read = 0;
 	size_t         bytes_copied;

 	__ASSERT(min_xfer <= bytes_to_read, "");
 	__ASSERT(bytes_read != NULL, "");

 	k_spinlock_key_t key = k_spin_lock(&pipe->lock);

 	/*
 	 * Create a list of "working readers" into which the data will be
 	 * directly copied.
 	 */

 	if (!pipe_xfer_prepare(&xfer_list, &writer, &pipe->wait_q.writers,
 				pipe->bytes_used, bytes_to_read,
 				min_xfer, timeout)) {
 		k_spin_unlock(&pipe->lock, key);
 		*bytes_read = 0;
 		return -EIO;
 	}

 	z_sched_lock();
 	k_spin_unlock(&pipe->lock, key);

 	num_bytes_read = pipe_buffer_get(pipe, data, bytes_to_read);

 	/*
 	 * 1. 'xfer_list' currently contains a list of writer threads that can
 	 *     have their write requests fulfilled by the current call.
 	 * 2. 'writer' if not NULL points to a thread on the writer wait_q
 	 *    that can post some of its requested data.
 	 * 3. Data will be copied from each writer's buffer to either the
 	 *    reader's buffer and/or to the pipe's circular buffer.
 	 * 4. Interrupts are unlocked but the scheduler is locked to allow
 	 *    ticks to be delivered but no scheduling to occur
 	 * 5. If 'writer' times out while we are copying data, not only do we
 	 *    still have a pointer to it, but it can not execute until this
 	 *    call is complete so it is still safe to copy data from it.
 	 */

 	struct k_thread *thread = (struct k_thread *)
 				  sys_dlist_get(&xfer_list);
 	while ((thread != NULL) && (num_bytes_read < bytes_to_read)) {
 		desc = (struct k_pipe_desc *)thread->base.swap_data;
 		bytes_copied = pipe_xfer((u8_t *)data + num_bytes_read,
 					  bytes_to_read - num_bytes_read,
 					  desc->buffer, desc->bytes_to_xfer);

 		num_bytes_read       += bytes_copied;
 		desc->buffer         += bytes_copied;
 		desc->bytes_to_xfer  -= bytes_copied;

 		/*
 		 * It is expected that the write request will be satisfied.
 		 * However, if the read request was satisfied before the
 		 * write request was satisfied, then the write request must
 		 * finish later when writing to the pipe's circular buffer.
 		 */
 		if (num_bytes_read == bytes_to_read) {
 			break;
 		}
 		pipe_thread_ready(thread);

 		thread = (struct k_thread *)sys_dlist_get(&xfer_list);
 	}

 	if ((writer != NULL) && (num_bytes_read < bytes_to_read)) {
 		desc = (struct k_pipe_desc *)writer->base.swap_data;
 		bytes_copied = pipe_xfer((u8_t *)data + num_bytes_read,
 					  bytes_to_read - num_bytes_read,
 					  desc->buffer, desc->bytes_to_xfer);

 		num_bytes_read       += bytes_copied;
 		desc->buffer         += bytes_copied;
 		desc->bytes_to_xfer  -= bytes_copied;
 	}

 	/*
 	 * Copy as much data as possible from the writers (if any)
 	 * into the pipe's circular buffer.
 	 */

 	while (thread != NULL) {
 		desc = (struct k_pipe_desc *)thread->base.swap_data;
 		bytes_copied = pipe_buffer_put(pipe, desc->buffer,
 						desc->bytes_to_xfer);

 		desc->buffer         += bytes_copied;
 		desc->bytes_to_xfer  -= bytes_copied;

 		/* Write request has been satisfied */
 		pipe_thread_ready(thread);

 		thread = (struct k_thread *)sys_dlist_get(&xfer_list);
 	}

 	if (writer != NULL) {
 		desc = (struct k_pipe_desc *)writer->base.swap_data;
 		bytes_copied = pipe_buffer_put(pipe, desc->buffer,
 						desc->bytes_to_xfer);

 		desc->buffer         += bytes_copied;
 		desc->bytes_to_xfer  -= bytes_copied;
 	}

 	if (num_bytes_read == bytes_to_read) {
 		k_sched_unlock();

 		*bytes_read = num_bytes_read;

 		return 0;
 	}

 	/* Not all data was read. */

 	struct k_pipe_desc  pipe_desc;

 	pipe_desc.buffer        = (u8_t *)data + num_bytes_read;
 	pipe_desc.bytes_to_xfer = bytes_to_read - num_bytes_read;

 	if (timeout != K_NO_WAIT) {
 		_current->base.swap_data = &pipe_desc;
 		k_spinlock_key_t key = k_spin_lock(&pipe->lock);

 		z_sched_unlock_no_reschedule();
 		(void)z_pend_curr(&pipe->lock, key,
 				 &pipe->wait_q.readers, timeout);
 	} else {
 		k_sched_unlock();
 	}

 	*bytes_read = bytes_to_read - pipe_desc.bytes_to_xfer;

 	return pipe_return_code(min_xfer, pipe_desc.bytes_to_xfer,
 				 bytes_to_read);
 }

 #ifdef CONFIG_USERSPACE
 int z_vrfy_k_pipe_get(struct k_pipe *pipe, void *data, size_t bytes_to_read,
 		      size_t *bytes_read, size_t min_xfer, s32_t timeout)
 {
 	Z_OOPS(Z_SYSCALL_OBJ(pipe, K_OBJ_PIPE));
 	Z_OOPS(Z_SYSCALL_MEMORY_WRITE(bytes_read, sizeof(*bytes_read)));
 	Z_OOPS(Z_SYSCALL_MEMORY_WRITE((void *)data, bytes_to_read));
 	Z_OOPS(Z_SYSCALL_VERIFY(min_xfer <= bytes_to_read));

 	return z_impl_k_pipe_get((struct k_pipe *)pipe, (void *)data,
 				bytes_to_read, bytes_read, min_xfer,
 				timeout);
 }
 #include <syscalls/k_pipe_get_mrsh.c>
 #endif

 int z_impl_k_pipe_put(struct k_pipe *pipe, void *data, size_t bytes_to_write,
 		     size_t *bytes_written, size_t min_xfer, s32_t timeout)
 {
 	__ASSERT(min_xfer <= bytes_to_write, "");
 	__ASSERT(bytes_written != NULL, "");

 	return z_pipe_put_internal(pipe, NULL, data,
 				    bytes_to_write, bytes_written,
 				    min_xfer, timeout);
 }

 #ifdef CONFIG_USERSPACE
 int z_vrfy_k_pipe_put(struct k_pipe *pipe, void *data, size_t bytes_to_write,
 		     size_t *bytes_written, size_t min_xfer, s32_t timeout)
 {
 	Z_OOPS(Z_SYSCALL_OBJ(pipe, K_OBJ_PIPE));
 	Z_OOPS(Z_SYSCALL_MEMORY_WRITE(bytes_written, sizeof(*bytes_written)));
 	Z_OOPS(Z_SYSCALL_MEMORY_READ((void *)data, bytes_to_write));
 	Z_OOPS(Z_SYSCALL_VERIFY(min_xfer <= bytes_to_write));

 	return z_impl_k_pipe_put((struct k_pipe *)pipe, (void *)data,
 				bytes_to_write, bytes_written, min_xfer,
 				timeout);
 }
 #include <syscalls/k_pipe_put_mrsh.c>
 #endif

 #if (CONFIG_NUM_PIPE_ASYNC_MSGS > 0)
 void k_pipe_block_put(struct k_pipe *pipe, struct k_mem_block *block,
 		      size_t bytes_to_write, struct k_sem *sem)
 {
 	struct k_pipe_async  *async_desc;
 	size_t                dummy_bytes_written;

 	/* For simplicity, always allocate an asynchronous descriptor */
 	pipe_async_alloc(&async_desc);

 	async_desc->desc.block = &async_desc->desc.copy_block;
 	async_desc->desc.copy_block = *block;
 	async_desc->desc.sem = sem;
 	async_desc->thread.prio = k_thread_priority_get(_current);
 #ifdef CONFIG_SMP
 	async_desc->thread.is_idle = 0;
 #endif

 	(void) z_pipe_put_internal(pipe, async_desc, block->data,
 				    bytes_to_write, &dummy_bytes_written,
 				    bytes_to_write, K_FOREVER);
 }
 #endif
	/*
	* Copyright (c) 2016 Wind River Systems, Inc.
	*
	* SPDX-License-Identifier: Apache-2.0
	*/

	/**
	* @file
	*
	* @brief Pipes
	*/

	#include <kernel.h>
	#include <kernel_structs.h>
	#include <debug/object_tracing_common.h>
	#include <toolchain.h>
	#include <linker/sections.h>
	#include <wait_q.h>
	#include <sys/dlist.h>
	#include <init.h>
	#include <syscall_handler.h>
	#include <sys/__assert.h>
	#include <kernel_internal.h>

	struct k_pipe_desc {
	unsigned char buffer; / Position in src/dest buffer */
	size_t bytes_to_xfer; /* # bytes left to transfer */
	#if (CONFIG_NUM_PIPE_ASYNC_MSGS > 0)
	struct k_mem_block block; / Pointer to memory block */
	struct k_mem_block copy_block; /* For backwards compatibility */
	struct k_sem sem; / Semaphore to give if async */
	#endif
	};

	struct k_pipe_async {
	struct _thread_base thread; /* Dummy thread object */
	struct k_pipe_desc desc; /* Pipe message descriptor */
	};

	#ifdef CONFIG_OBJECT_TRACING
	struct k_pipe *_trace_list_k_pipe;
	#endif /* CONFIG_OBJECT_TRACING */

	#if (CONFIG_NUM_PIPE_ASYNC_MSGS > 0)

	/* stack of unused asynchronous message descriptors */
	K_STACK_DEFINE(pipe_async_msgs, CONFIG_NUM_PIPE_ASYNC_MSGS);

	/* Allocate an asynchronous message descriptor */
	static void pipe_async_alloc(struct k_pipe_async **async)
	{
	(void)k_stack_pop(&pipe_async_msgs, (stack_data_t *)async, K_FOREVER);
	}

	/* Free an asynchronous message descriptor */
	static void pipe_async_free(struct k_pipe_async *async)
	{
	k_stack_push(&pipe_async_msgs, (stack_data_t)async);
	}

	/* Finish an asynchronous operation */
	static void pipe_async_finish(struct k_pipe_async *async_desc)
	{
	/*
	* An asynchronous operation is finished with the scheduler locked
	* to prevent the called routines from scheduling a new thread.
	*/

	k_mem_pool_free(async_desc->desc.block);

	if (async_desc->desc.sem != NULL) {
	k_sem_give(async_desc->desc.sem);
	}

	pipe_async_free(async_desc);
	}
	#endif /* CONFIG_NUM_PIPE_ASYNC_MSGS > 0 */

	#if (CONFIG_NUM_PIPE_ASYNC_MSGS > 0) \|\| \
	defined(CONFIG_OBJECT_TRACING)

	/*
	* Do run-time initialization of pipe object subsystem.
	*/
	static int init_pipes_module(struct device *dev)
	{
	ARG_UNUSED(dev);

	/* Array of asynchronous message descriptors */
	static struct k_pipe_async __noinit async_msg[CONFIG_NUM_PIPE_ASYNC_MSGS];

	#if (CONFIG_NUM_PIPE_ASYNC_MSGS > 0)
	/*
	* Create pool of asynchronous pipe message descriptors.
	*
	* A dummy thread requires minimal initialization, since it never gets
	* to execute. The _THREAD_DUMMY flag is sufficient to distinguish a
	* dummy thread from a real one. The threads are not added to the
	* kernel's list of known threads.
	*
	* Once initialized, the address of each descriptor is added to a stack
	* that governs access to them.
	*/

	for (int i = 0; i < CONFIG_NUM_PIPE_ASYNC_MSGS; i++) {
	async_msg[i].thread.thread_state = _THREAD_DUMMY;
	async_msg[i].thread.swap_data = &async_msg[i].desc;

	z_init_thread_timeout(&async_msg[i].thread);

	k_stack_push(&pipe_async_msgs, (stack_data_t)&async_msg[i]);
	}
	#endif /* CONFIG_NUM_PIPE_ASYNC_MSGS > 0 */

	/* Complete initialization of statically defined mailboxes. */

	#ifdef CONFIG_OBJECT_TRACING
	Z_STRUCT_SECTION_FOREACH(k_pipe, pipe) {
	SYS_TRACING_OBJ_INIT(k_pipe, pipe);
	}
	#endif /* CONFIG_OBJECT_TRACING */

	return 0;
	}

	SYS_INIT(init_pipes_module, PRE_KERNEL_1, CONFIG_KERNEL_INIT_PRIORITY_OBJECTS);

	#endif /* CONFIG_NUM_PIPE_ASYNC_MSGS or CONFIG_OBJECT_TRACING */

	void k_pipe_init(struct k_pipe pipe, unsigned char buffer, size_t size)
	{
	pipe->buffer = buffer;
	pipe->size = size;
	pipe->bytes_used = 0;
	pipe->read_index = 0;
	pipe->write_index = 0;
	pipe->flags = 0;
	z_waitq_init(&pipe->wait_q.writers);
	z_waitq_init(&pipe->wait_q.readers);
	SYS_TRACING_OBJ_INIT(k_pipe, pipe);
	z_object_init(pipe);
	}

	int z_impl_k_pipe_alloc_init(struct k_pipe *pipe, size_t size)
	{
	void *buffer;
	int ret;

	if (size != 0) {
	buffer = z_thread_malloc(size);
	if (buffer != NULL) {
	k_pipe_init(pipe, buffer, size);
	pipe->flags = K_PIPE_FLAG_ALLOC;
	ret = 0;
	} else {
	ret = -ENOMEM;
	}
	} else {
	k_pipe_init(pipe, NULL, 0);
	ret = 0;
	}

	return ret;
	}

	#ifdef CONFIG_USERSPACE
	static inline int z_vrfy_k_pipe_alloc_init(struct k_pipe *pipe, size_t size)
	{
	Z_OOPS(Z_SYSCALL_OBJ_NEVER_INIT(pipe, K_OBJ_PIPE));

	return z_impl_k_pipe_alloc_init(pipe, size);
	}
	#include <syscalls/k_pipe_alloc_init_mrsh.c>
	#endif

	void k_pipe_cleanup(struct k_pipe *pipe)
	{
	__ASSERT_NO_MSG(!z_waitq_head(&pipe->wait_q.readers));
	__ASSERT_NO_MSG(!z_waitq_head(&pipe->wait_q.writers));

	if ((pipe->flags & K_PIPE_FLAG_ALLOC) != 0) {
	k_free(pipe->buffer);
	pipe->buffer = NULL;
	pipe->flags &= ~K_PIPE_FLAG_ALLOC;
	}
	}

	/**
	* @brief Copy bytes from @a src to @a dest
	*
	* @return Number of bytes copied
	*/
	static size_t pipe_xfer(unsigned char *dest, size_t dest_size,
	const unsigned char *src, size_t src_size)
	{
	size_t num_bytes = MIN(dest_size, src_size);
	const unsigned char *end = src + num_bytes;

	while (src != end) {
	dest = src;
	dest++;
	src++;
	}

	return num_bytes;
	}

	/**
	* @brief Put data from @a src into the pipe's circular buffer
	*
	* Modifies the following fields in @a pipe:
	* buffer, bytes_used, write_index
	*
	* @return Number of bytes written to the pipe's circular buffer
	*/
	static size_t pipe_buffer_put(struct k_pipe *pipe,
	const unsigned char *src, size_t src_size)
	{
	size_t bytes_copied;
	size_t run_length;
	size_t num_bytes_written = 0;
	int i;


	for (i = 0; i < 2; i++) {
	run_length = MIN(pipe->size - pipe->bytes_used,
	pipe->size - pipe->write_index);

	bytes_copied = pipe_xfer(pipe->buffer + pipe->write_index,
	run_length,
	src + num_bytes_written,
	src_size - num_bytes_written);

	num_bytes_written += bytes_copied;
	pipe->bytes_used += bytes_copied;
	pipe->write_index += bytes_copied;
	if (pipe->write_index == pipe->size) {
	pipe->write_index = 0;
	}
	}

	return num_bytes_written;
	}

	/**
	* @brief Get data from the pipe's circular buffer
	*
	* Modifies the following fields in @a pipe:
	* bytes_used, read_index
	*
	* @return Number of bytes read from the pipe's circular buffer
	*/
	static size_t pipe_buffer_get(struct k_pipe *pipe,
	unsigned char *dest, size_t dest_size)
	{
	size_t bytes_copied;
	size_t run_length;
	size_t num_bytes_read = 0;
	int i;

	for (i = 0; i < 2; i++) {
	run_length = MIN(pipe->bytes_used,
	pipe->size - pipe->read_index);

	bytes_copied = pipe_xfer(dest + num_bytes_read,
	dest_size - num_bytes_read,
	pipe->buffer + pipe->read_index,
	run_length);

	num_bytes_read += bytes_copied;
	pipe->bytes_used -= bytes_copied;
	pipe->read_index += bytes_copied;
	if (pipe->read_index == pipe->size) {
	pipe->read_index = 0;
	}
	}

	return num_bytes_read;
	}

	/**
	* @brief Prepare a working set of readers/writers
	*
	* Prepare a list of "working threads" into/from which the data
	* will be directly copied. This list is useful as it is used to ...
	*
	* 1. avoid double copying
	* 2. minimize interrupt latency as interrupts are unlocked
	* while copying data
	* 3. ensure a timeout can not make the request impossible to satisfy
	*
	* The list is populated with previously pended threads that will be ready to
	* run after the pipe call is complete.
	*
	* Important things to remember when reading from the pipe ...
	* 1. If there are writers int @a wait_q, then the pipe's buffer is full.
	* 2. Conversely if the pipe's buffer is not full, there are no writers.
	* 3. The amount of available data in the pipe is the sum the bytes used in
	* the pipe (@a pipe_space) and all the requests from the waiting writers.
	* 4. Since data is read from the pipe's buffer first, the working set must
	* include writers that will (try to) re-fill the pipe's buffer afterwards.
	*
	* Important things to remember when writing to the pipe ...
	* 1. If there are readers in @a wait_q, then the pipe's buffer is empty.
	* 2. Conversely if the pipe's buffer is not empty, then there are no readers.
	* 3. The amount of space available in the pipe is the sum of the bytes unused
	* in the pipe (@a pipe_space) and all the requests from the waiting readers.
	*
	* @return false if request is unsatisfiable, otherwise true
	*/
	static bool pipe_xfer_prepare(sys_dlist_t *xfer_list,
	struct k_thread **waiter,
	_wait_q_t *wait_q,
	size_t pipe_space,
	size_t bytes_to_xfer,
	size_t min_xfer,
	s32_t timeout)
	{
	struct k_thread *thread;
	struct k_pipe_desc *desc;
	size_t num_bytes = 0;

	if (timeout == K_NO_WAIT) {
	_WAIT_Q_FOR_EACH(wait_q, thread) {
	desc = (struct k_pipe_desc *)thread->base.swap_data;

	num_bytes += desc->bytes_to_xfer;

	if (num_bytes >= bytes_to_xfer) {
	break;
	}
	}

	if (num_bytes + pipe_space < min_xfer) {
	return false;
	}
	}

	/*
	* Either @a timeout is not K_NO_WAIT (so the thread may pend) or
	* the entire request can be satisfied. Generate the working list.
	*/

	sys_dlist_init(xfer_list);
	num_bytes = 0;

	while ((thread = z_waitq_head(wait_q)) != NULL) {
	desc = (struct k_pipe_desc *)thread->base.swap_data;
	num_bytes += desc->bytes_to_xfer;

	if (num_bytes > bytes_to_xfer) {
	/*
	* This request can not be fully satisfied.
	* Do not remove it from the wait_q.
	* Do not abort its timeout (if applicable).
	* Do not add it to the transfer list
	*/
	break;
	}

	/*
	* This request can be fully satisfied.
	* Remove it from the wait_q.
	* Abort its timeout.
	* Add it to the transfer list.
	*/
	z_unpend_thread(thread);
	sys_dlist_append(xfer_list, &thread->base.qnode_dlist);
	}

	*waiter = (num_bytes > bytes_to_xfer) ? thread : NULL;

	return true;
	}

	/**
	* @brief Determine the correct return code
	*
	* Bytes Xferred No Wait Wait
	* >= Minimum 0 0
	* < Minimum -EIO* -EAGAIN
	*
	* * The "-EIO No Wait" case was already checked when the "working set"
	* was created in _pipe_xfer_prepare().
	*
	* @return See table above
	*/
	static int pipe_return_code(size_t min_xfer, size_t bytes_remaining,
	size_t bytes_requested)
	{
	if (bytes_requested - bytes_remaining >= min_xfer) {
	/*
	* At least the minimum number of requested
	* bytes have been transferred.
	*/
	return 0;
	}

	return -EAGAIN;
	}

	/**
	* @brief Ready a pipe thread
	*
	* If the pipe thread is a real thread, then add it to the ready queue.
	* If it is a dummy thread, then finish the asynchronous work.
	*
	* @return N/A
	*/
	static void pipe_thread_ready(struct k_thread *thread)
	{
	#if (CONFIG_NUM_PIPE_ASYNC_MSGS > 0)
	if ((thread->base.thread_state & _THREAD_DUMMY) != 0U) {
	pipe_async_finish((struct k_pipe_async *)thread);
	return;
	}
	#endif

	z_ready_thread(thread);
	}

	/**
	* @brief Internal API used to send data to a pipe
	*/
	int z_pipe_put_internal(struct k_pipe pipe, struct k_pipe_async async_desc,
	unsigned char *data, size_t bytes_to_write,
	size_t *bytes_written, size_t min_xfer,
	s32_t timeout)
	{
	struct k_thread *reader;
	struct k_pipe_desc *desc;
	sys_dlist_t xfer_list;
	size_t num_bytes_written = 0;
	size_t bytes_copied;

	#if (CONFIG_NUM_PIPE_ASYNC_MSGS == 0)
	ARG_UNUSED(async_desc);
	#endif

	k_spinlock_key_t key = k_spin_lock(&pipe->lock);

	/*
	* Create a list of "working readers" into which the data will be
	* directly copied.
	*/

	if (!pipe_xfer_prepare(&xfer_list, &reader, &pipe->wait_q.readers,
	pipe->size - pipe->bytes_used, bytes_to_write,
	min_xfer, timeout)) {
	k_spin_unlock(&pipe->lock, key);
	*bytes_written = 0;
	return -EIO;
	}

	z_sched_lock();
	k_spin_unlock(&pipe->lock, key);

	/*
	* 1. 'xfer_list' currently contains a list of reader threads that can
	* have their read requests fulfilled by the current call.
	* 2. 'reader' if not NULL points to a thread on the reader wait_q
	* that can get some of its requested data.
	* 3. Interrupts are unlocked but the scheduler is locked to allow
	* ticks to be delivered but no scheduling to occur
	* 4. If 'reader' times out while we are copying data, not only do we
	* still have a pointer to it, but it can not execute until this call
	* is complete so it is still safe to copy data to it.
	*/

	struct k_thread thread = (struct k_thread )
	sys_dlist_get(&xfer_list);
	while (thread != NULL) {
	desc = (struct k_pipe_desc *)thread->base.swap_data;
	bytes_copied = pipe_xfer(desc->buffer, desc->bytes_to_xfer,
	data + num_bytes_written,
	bytes_to_write - num_bytes_written);

	num_bytes_written += bytes_copied;
	desc->buffer += bytes_copied;
	desc->bytes_to_xfer -= bytes_copied;

	/* The thread's read request has been satisfied. Ready it. */
	z_ready_thread(thread);

	thread = (struct k_thread *)sys_dlist_get(&xfer_list);
	}

	/*
	* Copy any data to the reader that we left on the wait_q.
	* It is possible no data will be copied.
	*/
	if (reader != NULL) {
	desc = (struct k_pipe_desc *)reader->base.swap_data;
	bytes_copied = pipe_xfer(desc->buffer, desc->bytes_to_xfer,
	data + num_bytes_written,
	bytes_to_write - num_bytes_written);

	num_bytes_written += bytes_copied;
	desc->buffer += bytes_copied;
	desc->bytes_to_xfer -= bytes_copied;
	}

	/*
	* As much data as possible has been directly copied to any waiting
	* readers. Add as much as possible to the pipe's circular buffer.
	*/

	num_bytes_written +=
	pipe_buffer_put(pipe, data + num_bytes_written,
	bytes_to_write - num_bytes_written);

	if (num_bytes_written == bytes_to_write) {
	*bytes_written = num_bytes_written;
	#if (CONFIG_NUM_PIPE_ASYNC_MSGS > 0)
	if (async_desc != NULL) {
	pipe_async_finish(async_desc);
	}
	#endif
	k_sched_unlock();
	return 0;
	}

	/* Not all data was copied. */

	#if (CONFIG_NUM_PIPE_ASYNC_MSGS > 0)
	if (async_desc != NULL) {
	/*
	* Lock interrupts and unlock the scheduler before
	* manipulating the writers wait_q.
	*/
	k_spinlock_key_t key = k_spin_lock(&pipe->lock);
	z_sched_unlock_no_reschedule();

	async_desc->desc.buffer = data + num_bytes_written;
	async_desc->desc.bytes_to_xfer =
	bytes_to_write - num_bytes_written;

	z_pend_thread((struct k_thread *) &async_desc->thread,
	&pipe->wait_q.writers, K_FOREVER);
	z_reschedule(&pipe->lock, key);
	return 0;
	}
	#endif

	struct k_pipe_desc pipe_desc;

	pipe_desc.buffer = data + num_bytes_written;
	pipe_desc.bytes_to_xfer = bytes_to_write - num_bytes_written;

	if (timeout != K_NO_WAIT) {
	_current->base.swap_data = &pipe_desc;
	/*
	* Lock interrupts and unlock the scheduler before
	* manipulating the writers wait_q.
	*/
	k_spinlock_key_t key = k_spin_lock(&pipe->lock);
	z_sched_unlock_no_reschedule();
	(void)z_pend_curr(&pipe->lock, key,
	&pipe->wait_q.writers, timeout);
	} else {
	k_sched_unlock();
	}

	*bytes_written = bytes_to_write - pipe_desc.bytes_to_xfer;

	return pipe_return_code(min_xfer, pipe_desc.bytes_to_xfer,
	bytes_to_write);
	}

	int z_impl_k_pipe_get(struct k_pipe pipe, void data, size_t bytes_to_read,
	size_t *bytes_read, size_t min_xfer, s32_t timeout)
	{
	struct k_thread *writer;
	struct k_pipe_desc *desc;
	sys_dlist_t xfer_list;
	size_t num_bytes_read = 0;
	size_t bytes_copied;

	__ASSERT(min_xfer <= bytes_to_read, "");
	__ASSERT(bytes_read != NULL, "");

	k_spinlock_key_t key = k_spin_lock(&pipe->lock);

	/*
	* Create a list of "working readers" into which the data will be
	* directly copied.
	*/

	if (!pipe_xfer_prepare(&xfer_list, &writer, &pipe->wait_q.writers,
	pipe->bytes_used, bytes_to_read,
	min_xfer, timeout)) {
	k_spin_unlock(&pipe->lock, key);
	*bytes_read = 0;
	return -EIO;
	}

	z_sched_lock();
	k_spin_unlock(&pipe->lock, key);

	num_bytes_read = pipe_buffer_get(pipe, data, bytes_to_read);

	/*
	* 1. 'xfer_list' currently contains a list of writer threads that can
	* have their write requests fulfilled by the current call.
	* 2. 'writer' if not NULL points to a thread on the writer wait_q
	* that can post some of its requested data.
	* 3. Data will be copied from each writer's buffer to either the
	* reader's buffer and/or to the pipe's circular buffer.
	* 4. Interrupts are unlocked but the scheduler is locked to allow
	* ticks to be delivered but no scheduling to occur
	* 5. If 'writer' times out while we are copying data, not only do we
	* still have a pointer to it, but it can not execute until this
	* call is complete so it is still safe to copy data from it.
	*/

	struct k_thread thread = (struct k_thread )
	sys_dlist_get(&xfer_list);
	while ((thread != NULL) && (num_bytes_read < bytes_to_read)) {
	desc = (struct k_pipe_desc *)thread->base.swap_data;
	bytes_copied = pipe_xfer((u8_t *)data + num_bytes_read,
	bytes_to_read - num_bytes_read,
	desc->buffer, desc->bytes_to_xfer);

	num_bytes_read += bytes_copied;
	desc->buffer += bytes_copied;
	desc->bytes_to_xfer -= bytes_copied;

	/*
	* It is expected that the write request will be satisfied.
	* However, if the read request was satisfied before the
	* write request was satisfied, then the write request must
	* finish later when writing to the pipe's circular buffer.
	*/
	if (num_bytes_read == bytes_to_read) {
	break;
	}
	pipe_thread_ready(thread);

	thread = (struct k_thread *)sys_dlist_get(&xfer_list);
	}

	if ((writer != NULL) && (num_bytes_read < bytes_to_read)) {
	desc = (struct k_pipe_desc *)writer->base.swap_data;
	bytes_copied = pipe_xfer((u8_t *)data + num_bytes_read,
	bytes_to_read - num_bytes_read,
	desc->buffer, desc->bytes_to_xfer);

	num_bytes_read += bytes_copied;
	desc->buffer += bytes_copied;
	desc->bytes_to_xfer -= bytes_copied;
	}

	/*
	* Copy as much data as possible from the writers (if any)
	* into the pipe's circular buffer.
	*/

	while (thread != NULL) {
	desc = (struct k_pipe_desc *)thread->base.swap_data;
	bytes_copied = pipe_buffer_put(pipe, desc->buffer,
	desc->bytes_to_xfer);

	desc->buffer += bytes_copied;
	desc->bytes_to_xfer -= bytes_copied;

	/* Write request has been satisfied */
	pipe_thread_ready(thread);

	thread = (struct k_thread *)sys_dlist_get(&xfer_list);
	}

	if (writer != NULL) {
	desc = (struct k_pipe_desc *)writer->base.swap_data;
	bytes_copied = pipe_buffer_put(pipe, desc->buffer,
	desc->bytes_to_xfer);

	desc->buffer += bytes_copied;
	desc->bytes_to_xfer -= bytes_copied;
	}

	if (num_bytes_read == bytes_to_read) {
	k_sched_unlock();

	*bytes_read = num_bytes_read;

	return 0;
	}

	/* Not all data was read. */

	struct k_pipe_desc pipe_desc;

	pipe_desc.buffer = (u8_t *)data + num_bytes_read;
	pipe_desc.bytes_to_xfer = bytes_to_read - num_bytes_read;

	if (timeout != K_NO_WAIT) {
	_current->base.swap_data = &pipe_desc;
	k_spinlock_key_t key = k_spin_lock(&pipe->lock);

	z_sched_unlock_no_reschedule();
	(void)z_pend_curr(&pipe->lock, key,
	&pipe->wait_q.readers, timeout);
	} else {
	k_sched_unlock();
	}

	*bytes_read = bytes_to_read - pipe_desc.bytes_to_xfer;

	return pipe_return_code(min_xfer, pipe_desc.bytes_to_xfer,
	bytes_to_read);
	}

	#ifdef CONFIG_USERSPACE
	int z_vrfy_k_pipe_get(struct k_pipe pipe, void data, size_t bytes_to_read,
	size_t *bytes_read, size_t min_xfer, s32_t timeout)
	{
	Z_OOPS(Z_SYSCALL_OBJ(pipe, K_OBJ_PIPE));
	Z_OOPS(Z_SYSCALL_MEMORY_WRITE(bytes_read, sizeof(*bytes_read)));
	Z_OOPS(Z_SYSCALL_MEMORY_WRITE((void *)data, bytes_to_read));
	Z_OOPS(Z_SYSCALL_VERIFY(min_xfer <= bytes_to_read));

	return z_impl_k_pipe_get((struct k_pipe )pipe, (void )data,
	bytes_to_read, bytes_read, min_xfer,
	timeout);
	}
	#include <syscalls/k_pipe_get_mrsh.c>
	#endif

	int z_impl_k_pipe_put(struct k_pipe pipe, void data, size_t bytes_to_write,
	size_t *bytes_written, size_t min_xfer, s32_t timeout)
	{
	__ASSERT(min_xfer <= bytes_to_write, "");
	__ASSERT(bytes_written != NULL, "");

	return z_pipe_put_internal(pipe, NULL, data,
	bytes_to_write, bytes_written,
	min_xfer, timeout);
	}

	#ifdef CONFIG_USERSPACE
	int z_vrfy_k_pipe_put(struct k_pipe pipe, void data, size_t bytes_to_write,
	size_t *bytes_written, size_t min_xfer, s32_t timeout)
	{
	Z_OOPS(Z_SYSCALL_OBJ(pipe, K_OBJ_PIPE));
	Z_OOPS(Z_SYSCALL_MEMORY_WRITE(bytes_written, sizeof(*bytes_written)));
	Z_OOPS(Z_SYSCALL_MEMORY_READ((void *)data, bytes_to_write));
	Z_OOPS(Z_SYSCALL_VERIFY(min_xfer <= bytes_to_write));

	return z_impl_k_pipe_put((struct k_pipe )pipe, (void )data,
	bytes_to_write, bytes_written, min_xfer,
	timeout);
	}
	#include <syscalls/k_pipe_put_mrsh.c>
	#endif

	#if (CONFIG_NUM_PIPE_ASYNC_MSGS > 0)
	void k_pipe_block_put(struct k_pipe pipe, struct k_mem_block block,
	size_t bytes_to_write, struct k_sem *sem)
	{
	struct k_pipe_async *async_desc;
	size_t dummy_bytes_written;

	/* For simplicity, always allocate an asynchronous descriptor */
	pipe_async_alloc(&async_desc);

	async_desc->desc.block = &async_desc->desc.copy_block;
	async_desc->desc.copy_block = *block;
	async_desc->desc.sem = sem;
	async_desc->thread.prio = k_thread_priority_get(_current);
	#ifdef CONFIG_SMP
	async_desc->thread.is_idle = 0;
	#endif

	(void) z_pipe_put_internal(pipe, async_desc, block->data,
	bytes_to_write, &dummy_bytes_written,
	bytes_to_write, K_FOREVER);
	}
	#endif