drivers/tty/tty_buffer.c - linux/kernel/git/viro/vfs - Git at Google

 /*
  * Tty buffer allocation management
  */

 #include <linux/types.h>
 #include <linux/errno.h>
 #include <linux/tty.h>
 #include <linux/tty_driver.h>
 #include <linux/tty_flip.h>
 #include <linux/timer.h>
 #include <linux/string.h>
 #include <linux/slab.h>
 #include <linux/sched.h>
 #include <linux/init.h>
 #include <linux/wait.h>
 #include <linux/bitops.h>
 #include <linux/delay.h>
 #include <linux/module.h>
 #include <linux/ratelimit.h>


 #define MIN_TTYB_SIZE	256
 #define TTYB_ALIGN_MASK	255

 /*
  * Byte threshold to limit memory consumption for flip buffers.
  * The actual memory limit is > 2x this amount.
  */
 #define TTYB_MEM_LIMIT	65536

 /*
  * We default to dicing tty buffer allocations to this many characters
  * in order to avoid multiple page allocations. We know the size of
  * tty_buffer itself but it must also be taken into account that the
  * the buffer is 256 byte aligned. See tty_buffer_find for the allocation
  * logic this must match
  */

 #define TTY_BUFFER_PAGE	(((PAGE_SIZE - sizeof(struct tty_buffer)) / 2) & ~0xFF)


 /**
  *	tty_buffer_lock_exclusive	-	gain exclusive access to buffer
  *	tty_buffer_unlock_exclusive	-	release exclusive access
  *
  *	@port - tty_port owning the flip buffer
  *
  *	Guarantees safe use of the line discipline's receive_buf() method by
  *	excluding the buffer work and any pending flush from using the flip
  *	buffer. Data can continue to be added concurrently to the flip buffer
  *	from the driver side.
  *
  *	On release, the buffer work is restarted if there is data in the
  *	flip buffer
  */

 void tty_buffer_lock_exclusive(struct tty_port *port)
 {
 	struct tty_bufhead *buf = &port->buf;

 	atomic_inc(&buf->priority);
 	mutex_lock(&buf->lock);
 }

 void tty_buffer_unlock_exclusive(struct tty_port *port)
 {
 	struct tty_bufhead *buf = &port->buf;
 	int restart;

 	restart = buf->head->commit != buf->head->read;

 	atomic_dec(&buf->priority);
 	mutex_unlock(&buf->lock);
 	if (restart)
 		queue_work(system_unbound_wq, &buf->work);
 }

 /**
  *	tty_buffer_space_avail	-	return unused buffer space
  *	@port - tty_port owning the flip buffer
  *
  *	Returns the # of bytes which can be written by the driver without
  *	reaching the buffer limit.
  *
  *	Note: this does not guarantee that memory is available to write
  *	the returned # of bytes (use tty_prepare_flip_string_xxx() to
  *	pre-allocate if memory guarantee is required).
  */

 int tty_buffer_space_avail(struct tty_port *port)
 {
 	int space = TTYB_MEM_LIMIT - atomic_read(&port->buf.memory_used);
 	return max(space, 0);
 }

 static void tty_buffer_reset(struct tty_buffer *p, size_t size)
 {
 	p->used = 0;
 	p->size = size;
 	p->next = NULL;
 	p->commit = 0;
 	p->read = 0;
 }

 /**
  *	tty_buffer_free_all		-	free buffers used by a tty
  *	@tty: tty to free from
  *
  *	Remove all the buffers pending on a tty whether queued with data
  *	or in the free ring. Must be called when the tty is no longer in use
  */

 void tty_buffer_free_all(struct tty_port *port)
 {
 	struct tty_bufhead *buf = &port->buf;
 	struct tty_buffer *p, *next;
 	struct llist_node *llist;

 	while ((p = buf->head) != NULL) {
 		buf->head = p->next;
 		if (p->size > 0)
 			kfree(p);
 	}
 	llist = llist_del_all(&buf->free);
 	llist_for_each_entry_safe(p, next, llist, free)
 		kfree(p);

 	tty_buffer_reset(&buf->sentinel, 0);
 	buf->head = &buf->sentinel;
 	buf->tail = &buf->sentinel;

 	atomic_set(&buf->memory_used, 0);
 }

 /**
  *	tty_buffer_alloc	-	allocate a tty buffer
  *	@tty: tty device
  *	@size: desired size (characters)
  *
  *	Allocate a new tty buffer to hold the desired number of characters.
  *	We round our buffers off in 256 character chunks to get better
  *	allocation behaviour.
  *	Return NULL if out of memory or the allocation would exceed the
  *	per device queue
  */

 static struct tty_buffer *tty_buffer_alloc(struct tty_port *port, size_t size)
 {
 	struct llist_node *free;
 	struct tty_buffer *p;

 	/* Round the buffer size out */
 	size = __ALIGN_MASK(size, TTYB_ALIGN_MASK);

 	if (size <= MIN_TTYB_SIZE) {
 		free = llist_del_first(&port->buf.free);
 		if (free) {
 			p = llist_entry(free, struct tty_buffer, free);
 			goto found;
 		}
 	}

 	/* Should possibly check if this fails for the largest buffer we
 	   have queued and recycle that ? */
 	if (atomic_read(&port->buf.memory_used) > TTYB_MEM_LIMIT)
 		return NULL;
 	p = kmalloc(sizeof(struct tty_buffer) + 2 * size, GFP_ATOMIC);
 	if (p == NULL)
 		return NULL;

 found:
 	tty_buffer_reset(p, size);
 	atomic_add(size, &port->buf.memory_used);
 	return p;
 }

 /**
  *	tty_buffer_free		-	free a tty buffer
  *	@tty: tty owning the buffer
  *	@b: the buffer to free
  *
  *	Free a tty buffer, or add it to the free list according to our
  *	internal strategy
  */

 static void tty_buffer_free(struct tty_port *port, struct tty_buffer *b)
 {
 	struct tty_bufhead *buf = &port->buf;

 	/* Dumb strategy for now - should keep some stats */
 	WARN_ON(atomic_sub_return(b->size, &buf->memory_used) < 0);

 	if (b->size > MIN_TTYB_SIZE)
 		kfree(b);
 	else if (b->size > 0)
 		llist_add(&b->free, &buf->free);
 }

 /**
  *	tty_buffer_flush		-	flush full tty buffers
  *	@tty: tty to flush
  *
  *	flush all the buffers containing receive data. If the buffer is
  *	being processed by flush_to_ldisc then we defer the processing
  *	to that function
  *
  *	Locking: takes buffer lock to ensure single-threaded flip buffer
  *		 'consumer'
  */

 void tty_buffer_flush(struct tty_struct *tty)
 {
 	struct tty_port *port = tty->port;
 	struct tty_bufhead *buf = &port->buf;
 	struct tty_buffer *next;

 	atomic_inc(&buf->priority);

 	mutex_lock(&buf->lock);
 	while ((next = buf->head->next) != NULL) {
 		tty_buffer_free(port, buf->head);
 		buf->head = next;
 	}
 	buf->head->read = buf->head->commit;
 	atomic_dec(&buf->priority);
 	mutex_unlock(&buf->lock);
 }

 /**
  *	tty_buffer_request_room		-	grow tty buffer if needed
  *	@tty: tty structure
  *	@size: size desired
  *
  *	Make at least size bytes of linear space available for the tty
  *	buffer. If we fail return the size we managed to find.
  */
 int tty_buffer_request_room(struct tty_port *port, size_t size)
 {
 	struct tty_bufhead *buf = &port->buf;
 	struct tty_buffer *b, *n;
 	int left;

 	b = buf->tail;
 	left = b->size - b->used;

 	if (left < size) {
 		/* This is the slow path - looking for new buffers to use */
 		if ((n = tty_buffer_alloc(port, size)) != NULL) {
 			buf->tail = n;
 			b->commit = b->used;
 			smp_mb();
 			b->next = n;
 		} else
 			size = left;
 	}
 	return size;
 }
 EXPORT_SYMBOL_GPL(tty_buffer_request_room);

 /**
  *	tty_insert_flip_string_fixed_flag - Add characters to the tty buffer
  *	@port: tty port
  *	@chars: characters
  *	@flag: flag value for each character
  *	@size: size
  *
  *	Queue a series of bytes to the tty buffering. All the characters
  *	passed are marked with the supplied flag. Returns the number added.
  */

 int tty_insert_flip_string_fixed_flag(struct tty_port *port,
 		const unsigned char *chars, char flag, size_t size)
 {
 	int copied = 0;
 	do {
 		int goal = min_t(size_t, size - copied, TTY_BUFFER_PAGE);
 		int space = tty_buffer_request_room(port, goal);
 		struct tty_buffer *tb = port->buf.tail;
 		if (unlikely(space == 0))
 			break;
 		memcpy(char_buf_ptr(tb, tb->used), chars, space);
 		memset(flag_buf_ptr(tb, tb->used), flag, space);
 		tb->used += space;
 		copied += space;
 		chars += space;
 		/* There is a small chance that we need to split the data over
 		   several buffers. If this is the case we must loop */
 	} while (unlikely(size > copied));
 	return copied;
 }
 EXPORT_SYMBOL(tty_insert_flip_string_fixed_flag);

 /**
  *	tty_insert_flip_string_flags	-	Add characters to the tty buffer
  *	@port: tty port
  *	@chars: characters
  *	@flags: flag bytes
  *	@size: size
  *
  *	Queue a series of bytes to the tty buffering. For each character
  *	the flags array indicates the status of the character. Returns the
  *	number added.
  */

 int tty_insert_flip_string_flags(struct tty_port *port,
 		const unsigned char *chars, const char *flags, size_t size)
 {
 	int copied = 0;
 	do {
 		int goal = min_t(size_t, size - copied, TTY_BUFFER_PAGE);
 		int space = tty_buffer_request_room(port, goal);
 		struct tty_buffer *tb = port->buf.tail;
 		if (unlikely(space == 0))
 			break;
 		memcpy(char_buf_ptr(tb, tb->used), chars, space);
 		memcpy(flag_buf_ptr(tb, tb->used), flags, space);
 		tb->used += space;
 		copied += space;
 		chars += space;
 		flags += space;
 		/* There is a small chance that we need to split the data over
 		   several buffers. If this is the case we must loop */
 	} while (unlikely(size > copied));
 	return copied;
 }
 EXPORT_SYMBOL(tty_insert_flip_string_flags);

 /**
  *	tty_schedule_flip	-	push characters to ldisc
  *	@port: tty port to push from
  *
  *	Takes any pending buffers and transfers their ownership to the
  *	ldisc side of the queue. It then schedules those characters for
  *	processing by the line discipline.
  *	Note that this function can only be used when the low_latency flag
  *	is unset. Otherwise the workqueue won't be flushed.
  */

 void tty_schedule_flip(struct tty_port *port)
 {
 	struct tty_bufhead *buf = &port->buf;
 	WARN_ON(port->low_latency);

 	buf->tail->commit = buf->tail->used;
 	schedule_work(&buf->work);
 }
 EXPORT_SYMBOL(tty_schedule_flip);

 /**
  *	tty_prepare_flip_string		-	make room for characters
  *	@port: tty port
  *	@chars: return pointer for character write area
  *	@size: desired size
  *
  *	Prepare a block of space in the buffer for data. Returns the length
  *	available and buffer pointer to the space which is now allocated and
  *	accounted for as ready for normal characters. This is used for drivers
  *	that need their own block copy routines into the buffer. There is no
  *	guarantee the buffer is a DMA target!
  */

 int tty_prepare_flip_string(struct tty_port *port, unsigned char **chars,
 		size_t size)
 {
 	int space = tty_buffer_request_room(port, size);
 	if (likely(space)) {
 		struct tty_buffer *tb = port->buf.tail;
 		*chars = char_buf_ptr(tb, tb->used);
 		memset(flag_buf_ptr(tb, tb->used), TTY_NORMAL, space);
 		tb->used += space;
 	}
 	return space;
 }
 EXPORT_SYMBOL_GPL(tty_prepare_flip_string);

 /**
  *	tty_prepare_flip_string_flags	-	make room for characters
  *	@port: tty port
  *	@chars: return pointer for character write area
  *	@flags: return pointer for status flag write area
  *	@size: desired size
  *
  *	Prepare a block of space in the buffer for data. Returns the length
  *	available and buffer pointer to the space which is now allocated and
  *	accounted for as ready for characters. This is used for drivers
  *	that need their own block copy routines into the buffer. There is no
  *	guarantee the buffer is a DMA target!
  */

 int tty_prepare_flip_string_flags(struct tty_port *port,
 			unsigned char **chars, char **flags, size_t size)
 {
 	int space = tty_buffer_request_room(port, size);
 	if (likely(space)) {
 		struct tty_buffer *tb = port->buf.tail;
 		*chars = char_buf_ptr(tb, tb->used);
 		*flags = flag_buf_ptr(tb, tb->used);
 		tb->used += space;
 	}
 	return space;
 }
 EXPORT_SYMBOL_GPL(tty_prepare_flip_string_flags);


 static int
 receive_buf(struct tty_struct *tty, struct tty_buffer *head, int count)
 {
 	struct tty_ldisc *disc = tty->ldisc;
 	unsigned char *p = char_buf_ptr(head, head->read);
 	char	      *f = flag_buf_ptr(head, head->read);

 	if (disc->ops->receive_buf2)
 		count = disc->ops->receive_buf2(tty, p, f, count);
 	else {
 		count = min_t(int, count, tty->receive_room);
 		if (count)
 			disc->ops->receive_buf(tty, p, f, count);
 	}
 	head->read += count;
 	return count;
 }

 /**
  *	flush_to_ldisc
  *	@work: tty structure passed from work queue.
  *
  *	This routine is called out of the software interrupt to flush data
  *	from the buffer chain to the line discipline.
  *
  *	The receive_buf method is single threaded for each tty instance.
  *
  *	Locking: takes buffer lock to ensure single-threaded flip buffer
  *		 'consumer'
  */

 static void flush_to_ldisc(struct work_struct *work)
 {
 	struct tty_port *port = container_of(work, struct tty_port, buf.work);
 	struct tty_bufhead *buf = &port->buf;
 	struct tty_struct *tty;
 	struct tty_ldisc *disc;

 	tty = port->itty;
 	if (tty == NULL)
 		return;

 	disc = tty_ldisc_ref(tty);
 	if (disc == NULL)
 		return;

 	mutex_lock(&buf->lock);

 	while (1) {
 		struct tty_buffer *head = buf->head;
 		int count;

 		/* Ldisc or user is trying to gain exclusive access */
 		if (atomic_read(&buf->priority))
 			break;

 		count = head->commit - head->read;
 		if (!count) {
 			if (head->next == NULL)
 				break;
 			buf->head = head->next;
 			tty_buffer_free(port, head);
 			continue;
 		}

 		count = receive_buf(tty, head, count);
 		if (!count)
 			break;
 	}

 	mutex_unlock(&buf->lock);

 	tty_ldisc_deref(disc);
 }

 /**
  *	tty_flush_to_ldisc
  *	@tty: tty to push
  *
  *	Push the terminal flip buffers to the line discipline.
  *
  *	Must not be called from IRQ context.
  */
 void tty_flush_to_ldisc(struct tty_struct *tty)
 {
 	if (!tty->port->low_latency)
 		flush_work(&tty->port->buf.work);
 }

 /**
  *	tty_flip_buffer_push	-	terminal
  *	@port: tty port to push
  *
  *	Queue a push of the terminal flip buffers to the line discipline. This
  *	function must not be called from IRQ context if port->low_latency is
  *	set.
  *
  *	In the event of the queue being busy for flipping the work will be
  *	held off and retried later.
  */

 void tty_flip_buffer_push(struct tty_port *port)
 {
 	struct tty_bufhead *buf = &port->buf;

 	buf->tail->commit = buf->tail->used;

 	if (port->low_latency)
 		flush_to_ldisc(&buf->work);
 	else
 		schedule_work(&buf->work);
 }
 EXPORT_SYMBOL(tty_flip_buffer_push);

 /**
  *	tty_buffer_init		-	prepare a tty buffer structure
  *	@tty: tty to initialise
  *
  *	Set up the initial state of the buffer management for a tty device.
  *	Must be called before the other tty buffer functions are used.
  */

 void tty_buffer_init(struct tty_port *port)
 {
 	struct tty_bufhead *buf = &port->buf;

 	mutex_init(&buf->lock);
 	tty_buffer_reset(&buf->sentinel, 0);
 	buf->head = &buf->sentinel;
 	buf->tail = &buf->sentinel;
 	init_llist_head(&buf->free);
 	atomic_set(&buf->memory_used, 0);
 	atomic_set(&buf->priority, 0);
 	INIT_WORK(&buf->work, flush_to_ldisc);
 }
	/*
	* Tty buffer allocation management
	*/

	#include <linux/types.h>
	#include <linux/errno.h>
	#include <linux/tty.h>
	#include <linux/tty_driver.h>
	#include <linux/tty_flip.h>
	#include <linux/timer.h>
	#include <linux/string.h>
	#include <linux/slab.h>
	#include <linux/sched.h>
	#include <linux/init.h>
	#include <linux/wait.h>
	#include <linux/bitops.h>
	#include <linux/delay.h>
	#include <linux/module.h>
	#include <linux/ratelimit.h>


	#define MIN_TTYB_SIZE 256
	#define TTYB_ALIGN_MASK 255

	/*
	* Byte threshold to limit memory consumption for flip buffers.
	* The actual memory limit is > 2x this amount.
	*/
	#define TTYB_MEM_LIMIT 65536

	/*
	* We default to dicing tty buffer allocations to this many characters
	* in order to avoid multiple page allocations. We know the size of
	* tty_buffer itself but it must also be taken into account that the
	* the buffer is 256 byte aligned. See tty_buffer_find for the allocation
	* logic this must match
	*/

	#define TTY_BUFFER_PAGE (((PAGE_SIZE - sizeof(struct tty_buffer)) / 2) & ~0xFF)


	/**
	* tty_buffer_lock_exclusive - gain exclusive access to buffer
	* tty_buffer_unlock_exclusive - release exclusive access
	*
	* @port - tty_port owning the flip buffer
	*
	* Guarantees safe use of the line discipline's receive_buf() method by
	* excluding the buffer work and any pending flush from using the flip
	* buffer. Data can continue to be added concurrently to the flip buffer
	* from the driver side.
	*
	* On release, the buffer work is restarted if there is data in the
	* flip buffer
	*/

	void tty_buffer_lock_exclusive(struct tty_port *port)
	{
	struct tty_bufhead *buf = &port->buf;

	atomic_inc(&buf->priority);
	mutex_lock(&buf->lock);
	}

	void tty_buffer_unlock_exclusive(struct tty_port *port)
	{
	struct tty_bufhead *buf = &port->buf;
	int restart;

	restart = buf->head->commit != buf->head->read;

	atomic_dec(&buf->priority);
	mutex_unlock(&buf->lock);
	if (restart)
	queue_work(system_unbound_wq, &buf->work);
	}

	/**
	* tty_buffer_space_avail - return unused buffer space
	* @port - tty_port owning the flip buffer
	*
	* Returns the # of bytes which can be written by the driver without
	* reaching the buffer limit.
	*
	* Note: this does not guarantee that memory is available to write
	* the returned # of bytes (use tty_prepare_flip_string_xxx() to
	* pre-allocate if memory guarantee is required).
	*/

	int tty_buffer_space_avail(struct tty_port *port)
	{
	int space = TTYB_MEM_LIMIT - atomic_read(&port->buf.memory_used);
	return max(space, 0);
	}

	static void tty_buffer_reset(struct tty_buffer *p, size_t size)
	{
	p->used = 0;
	p->size = size;
	p->next = NULL;
	p->commit = 0;
	p->read = 0;
	}

	/**
	* tty_buffer_free_all - free buffers used by a tty
	* @tty: tty to free from
	*
	* Remove all the buffers pending on a tty whether queued with data
	* or in the free ring. Must be called when the tty is no longer in use
	*/

	void tty_buffer_free_all(struct tty_port *port)
	{
	struct tty_bufhead *buf = &port->buf;
	struct tty_buffer p, next;
	struct llist_node *llist;

	while ((p = buf->head) != NULL) {
	buf->head = p->next;
	if (p->size > 0)
	kfree(p);
	}
	llist = llist_del_all(&buf->free);
	llist_for_each_entry_safe(p, next, llist, free)
	kfree(p);

	tty_buffer_reset(&buf->sentinel, 0);
	buf->head = &buf->sentinel;
	buf->tail = &buf->sentinel;

	atomic_set(&buf->memory_used, 0);
	}

	/**
	* tty_buffer_alloc - allocate a tty buffer
	* @tty: tty device
	* @size: desired size (characters)
	*
	* Allocate a new tty buffer to hold the desired number of characters.
	* We round our buffers off in 256 character chunks to get better
	* allocation behaviour.
	* Return NULL if out of memory or the allocation would exceed the
	* per device queue
	*/

	static struct tty_buffer tty_buffer_alloc(struct tty_port port, size_t size)
	{
	struct llist_node *free;
	struct tty_buffer *p;

	/* Round the buffer size out */
	size = __ALIGN_MASK(size, TTYB_ALIGN_MASK);

	if (size <= MIN_TTYB_SIZE) {
	free = llist_del_first(&port->buf.free);
	if (free) {
	p = llist_entry(free, struct tty_buffer, free);
	goto found;
	}
	}

	/* Should possibly check if this fails for the largest buffer we
	have queued and recycle that ? */
	if (atomic_read(&port->buf.memory_used) > TTYB_MEM_LIMIT)
	return NULL;
	p = kmalloc(sizeof(struct tty_buffer) + 2 * size, GFP_ATOMIC);
	if (p == NULL)
	return NULL;

	found:
	tty_buffer_reset(p, size);
	atomic_add(size, &port->buf.memory_used);
	return p;
	}

	/**
	* tty_buffer_free - free a tty buffer
	* @tty: tty owning the buffer
	* @b: the buffer to free
	*
	* Free a tty buffer, or add it to the free list according to our
	* internal strategy
	*/

	static void tty_buffer_free(struct tty_port port, struct tty_buffer b)
	{
	struct tty_bufhead *buf = &port->buf;

	/* Dumb strategy for now - should keep some stats */
	WARN_ON(atomic_sub_return(b->size, &buf->memory_used) < 0);

	if (b->size > MIN_TTYB_SIZE)
	kfree(b);
	else if (b->size > 0)
	llist_add(&b->free, &buf->free);
	}

	/**
	* tty_buffer_flush - flush full tty buffers
	* @tty: tty to flush
	*
	* flush all the buffers containing receive data. If the buffer is
	* being processed by flush_to_ldisc then we defer the processing
	* to that function
	*
	* Locking: takes buffer lock to ensure single-threaded flip buffer
	* 'consumer'
	*/

	void tty_buffer_flush(struct tty_struct *tty)
	{
	struct tty_port *port = tty->port;
	struct tty_bufhead *buf = &port->buf;
	struct tty_buffer *next;

	atomic_inc(&buf->priority);

	mutex_lock(&buf->lock);
	while ((next = buf->head->next) != NULL) {
	tty_buffer_free(port, buf->head);
	buf->head = next;
	}
	buf->head->read = buf->head->commit;
	atomic_dec(&buf->priority);
	mutex_unlock(&buf->lock);
	}

	/**
	* tty_buffer_request_room - grow tty buffer if needed
	* @tty: tty structure
	* @size: size desired
	*
	* Make at least size bytes of linear space available for the tty
	* buffer. If we fail return the size we managed to find.
	*/
	int tty_buffer_request_room(struct tty_port *port, size_t size)
	{
	struct tty_bufhead *buf = &port->buf;
	struct tty_buffer b, n;
	int left;

	b = buf->tail;
	left = b->size - b->used;

	if (left < size) {
	/* This is the slow path - looking for new buffers to use */
	if ((n = tty_buffer_alloc(port, size)) != NULL) {
	buf->tail = n;
	b->commit = b->used;
	smp_mb();
	b->next = n;
	} else
	size = left;
	}
	return size;
	}
	EXPORT_SYMBOL_GPL(tty_buffer_request_room);

	/**
	* tty_insert_flip_string_fixed_flag - Add characters to the tty buffer
	* @port: tty port
	* @chars: characters
	* @flag: flag value for each character
	* @size: size
	*
	* Queue a series of bytes to the tty buffering. All the characters
	* passed are marked with the supplied flag. Returns the number added.
	*/

	int tty_insert_flip_string_fixed_flag(struct tty_port *port,
	const unsigned char *chars, char flag, size_t size)
	{
	int copied = 0;
	do {
	int goal = min_t(size_t, size - copied, TTY_BUFFER_PAGE);
	int space = tty_buffer_request_room(port, goal);
	struct tty_buffer *tb = port->buf.tail;
	if (unlikely(space == 0))
	break;
	memcpy(char_buf_ptr(tb, tb->used), chars, space);
	memset(flag_buf_ptr(tb, tb->used), flag, space);
	tb->used += space;
	copied += space;
	chars += space;
	/* There is a small chance that we need to split the data over
	several buffers. If this is the case we must loop */
	} while (unlikely(size > copied));
	return copied;
	}
	EXPORT_SYMBOL(tty_insert_flip_string_fixed_flag);

	/**
	* tty_insert_flip_string_flags - Add characters to the tty buffer
	* @port: tty port
	* @chars: characters
	* @flags: flag bytes
	* @size: size
	*
	* Queue a series of bytes to the tty buffering. For each character
	* the flags array indicates the status of the character. Returns the
	* number added.
	*/

	int tty_insert_flip_string_flags(struct tty_port *port,
	const unsigned char chars, const char flags, size_t size)
	{
	int copied = 0;
	do {
	int goal = min_t(size_t, size - copied, TTY_BUFFER_PAGE);
	int space = tty_buffer_request_room(port, goal);
	struct tty_buffer *tb = port->buf.tail;
	if (unlikely(space == 0))
	break;
	memcpy(char_buf_ptr(tb, tb->used), chars, space);
	memcpy(flag_buf_ptr(tb, tb->used), flags, space);
	tb->used += space;
	copied += space;
	chars += space;
	flags += space;
	/* There is a small chance that we need to split the data over
	several buffers. If this is the case we must loop */
	} while (unlikely(size > copied));
	return copied;
	}
	EXPORT_SYMBOL(tty_insert_flip_string_flags);

	/**
	* tty_schedule_flip - push characters to ldisc
	* @port: tty port to push from
	*
	* Takes any pending buffers and transfers their ownership to the
	* ldisc side of the queue. It then schedules those characters for
	* processing by the line discipline.
	* Note that this function can only be used when the low_latency flag
	* is unset. Otherwise the workqueue won't be flushed.
	*/

	void tty_schedule_flip(struct tty_port *port)
	{
	struct tty_bufhead *buf = &port->buf;
	WARN_ON(port->low_latency);

	buf->tail->commit = buf->tail->used;
	schedule_work(&buf->work);
	}
	EXPORT_SYMBOL(tty_schedule_flip);

	/**
	* tty_prepare_flip_string - make room for characters
	* @port: tty port
	* @chars: return pointer for character write area
	* @size: desired size
	*
	* Prepare a block of space in the buffer for data. Returns the length
	* available and buffer pointer to the space which is now allocated and
	* accounted for as ready for normal characters. This is used for drivers
	* that need their own block copy routines into the buffer. There is no
	* guarantee the buffer is a DMA target!
	*/

	int tty_prepare_flip_string(struct tty_port port, unsigned char *chars,
	size_t size)
	{
	int space = tty_buffer_request_room(port, size);
	if (likely(space)) {
	struct tty_buffer *tb = port->buf.tail;
	*chars = char_buf_ptr(tb, tb->used);
	memset(flag_buf_ptr(tb, tb->used), TTY_NORMAL, space);
	tb->used += space;
	}
	return space;
	}
	EXPORT_SYMBOL_GPL(tty_prepare_flip_string);

	/**
	* tty_prepare_flip_string_flags - make room for characters
	* @port: tty port
	* @chars: return pointer for character write area
	* @flags: return pointer for status flag write area
	* @size: desired size
	*
	* Prepare a block of space in the buffer for data. Returns the length
	* available and buffer pointer to the space which is now allocated and
	* accounted for as ready for characters. This is used for drivers
	* that need their own block copy routines into the buffer. There is no
	* guarantee the buffer is a DMA target!
	*/

	int tty_prepare_flip_string_flags(struct tty_port *port,
	unsigned char chars, char flags, size_t size)
	{
	int space = tty_buffer_request_room(port, size);
	if (likely(space)) {
	struct tty_buffer *tb = port->buf.tail;
	*chars = char_buf_ptr(tb, tb->used);
	*flags = flag_buf_ptr(tb, tb->used);
	tb->used += space;
	}
	return space;
	}
	EXPORT_SYMBOL_GPL(tty_prepare_flip_string_flags);


	static int
	receive_buf(struct tty_struct tty, struct tty_buffer head, int count)
	{
	struct tty_ldisc *disc = tty->ldisc;
	unsigned char *p = char_buf_ptr(head, head->read);
	char *f = flag_buf_ptr(head, head->read);

	if (disc->ops->receive_buf2)
	count = disc->ops->receive_buf2(tty, p, f, count);
	else {
	count = min_t(int, count, tty->receive_room);
	if (count)
	disc->ops->receive_buf(tty, p, f, count);
	}
	head->read += count;
	return count;
	}

	/**
	* flush_to_ldisc
	* @work: tty structure passed from work queue.
	*
	* This routine is called out of the software interrupt to flush data
	* from the buffer chain to the line discipline.
	*
	* The receive_buf method is single threaded for each tty instance.
	*
	* Locking: takes buffer lock to ensure single-threaded flip buffer
	* 'consumer'
	*/

	static void flush_to_ldisc(struct work_struct *work)
	{
	struct tty_port *port = container_of(work, struct tty_port, buf.work);
	struct tty_bufhead *buf = &port->buf;
	struct tty_struct *tty;
	struct tty_ldisc *disc;

	tty = port->itty;
	if (tty == NULL)
	return;

	disc = tty_ldisc_ref(tty);
	if (disc == NULL)
	return;

	mutex_lock(&buf->lock);

	while (1) {
	struct tty_buffer *head = buf->head;
	int count;

	/* Ldisc or user is trying to gain exclusive access */
	if (atomic_read(&buf->priority))
	break;

	count = head->commit - head->read;
	if (!count) {
	if (head->next == NULL)
	break;
	buf->head = head->next;
	tty_buffer_free(port, head);
	continue;
	}

	count = receive_buf(tty, head, count);
	if (!count)
	break;
	}

	mutex_unlock(&buf->lock);

	tty_ldisc_deref(disc);
	}

	/**
	* tty_flush_to_ldisc
	* @tty: tty to push
	*
	* Push the terminal flip buffers to the line discipline.
	*
	* Must not be called from IRQ context.
	*/
	void tty_flush_to_ldisc(struct tty_struct *tty)
	{
	if (!tty->port->low_latency)
	flush_work(&tty->port->buf.work);
	}

	/**
	* tty_flip_buffer_push - terminal
	* @port: tty port to push
	*
	* Queue a push of the terminal flip buffers to the line discipline. This
	* function must not be called from IRQ context if port->low_latency is
	* set.
	*
	* In the event of the queue being busy for flipping the work will be
	* held off and retried later.
	*/

	void tty_flip_buffer_push(struct tty_port *port)
	{
	struct tty_bufhead *buf = &port->buf;

	buf->tail->commit = buf->tail->used;

	if (port->low_latency)
	flush_to_ldisc(&buf->work);
	else
	schedule_work(&buf->work);
	}
	EXPORT_SYMBOL(tty_flip_buffer_push);

	/**
	* tty_buffer_init - prepare a tty buffer structure
	* @tty: tty to initialise
	*
	* Set up the initial state of the buffer management for a tty device.
	* Must be called before the other tty buffer functions are used.
	*/

	void tty_buffer_init(struct tty_port *port)
	{
	struct tty_bufhead *buf = &port->buf;

	mutex_init(&buf->lock);
	tty_buffer_reset(&buf->sentinel, 0);
	buf->head = &buf->sentinel;
	buf->tail = &buf->sentinel;
	init_llist_head(&buf->free);
	atomic_set(&buf->memory_used, 0);
	atomic_set(&buf->priority, 0);
	INIT_WORK(&buf->work, flush_to_ldisc);
	}