drivers/staging/fwserial/dma_fifo.h - arm/linux - Git at Google

 /*
  * DMA-able FIFO interface
  *
  * Copyright (C) 2012 Peter Hurley <peter@hurleysoftware.com>
  *
  * This program is free software; you can redistribute it and/or modify
  * it under the terms of the GNU General Public License as published by
  * the Free Software Foundation; either version 2 of the License, or
  * (at your option) any later version.
  *
  * This program is distributed in the hope that it will be useful,
  * but WITHOUT ANY WARRANTY; without even the implied warranty of
  * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
  * GNU General Public License for more details.
  */

 #ifndef _DMA_FIFO_H_
 #define _DMA_FIFO_H_

 /**
  * The design basis for the DMA FIFO is to provide an output side that
  * complies with the streaming DMA API design that can be DMA'd from directly
  * (without additional copying), coupled with an input side that maintains a
  * logically consistent 'apparent' size (ie, bytes in + bytes avail is static
  * for the lifetime of the FIFO).
  *
  * DMA output transactions originate on a cache line boundary and can be
  * variably-sized. DMA output transactions can be retired out-of-order but
  * the FIFO will only advance the output in the original input sequence.
  * This means the FIFO will eventually stall if a transaction is never retired.
  *
  * Chunking the output side into cache line multiples means that some FIFO
  * memory is unused. For example, if all the avail input has been pended out,
  * then the in and out markers are re-aligned to the next cache line.
  * The maximum possible waste is
  *     (cache line alignment - 1) * (max outstanding dma transactions)
  * This potential waste requires additional hidden capacity within the FIFO
  * to be able to accept input while the 'apparent' size has not been reached.
  *
  * Additional cache lines (ie, guard area) are used to minimize DMA
  * fragmentation when wrapping at the end of the FIFO. Input is allowed into the
  * guard area, but the in and out FIFO markers are wrapped when DMA is pended.
  */

 #define DMA_FIFO_GUARD 3   /* # of cache lines to reserve for the guard area */

 struct dma_fifo {
 	unsigned int	 in;
 	unsigned int	 out;		/* updated when dma is pended         */
 	unsigned int	 done;		/* updated upon dma completion        */
 	struct {
 		unsigned corrupt:1;
 	};
 	int		 size;		/* 'apparent' size of fifo	      */
 	int		 guard;		/* ofs of guard area		      */
 	int		 capacity;	/* size + reserved                    */
 	int		 avail;		/* # of unused bytes in fifo          */
 	unsigned int	 align;		/* must be power of 2                 */
 	int		 tx_limit;	/* max # of bytes per dma transaction */
 	int		 open_limit;	/* max # of outstanding allowed       */
 	int		 open;		/* # of outstanding dma transactions  */
 	struct list_head pending;	/* fifo markers for outstanding dma   */
 	void		 *data;
 };

 struct dma_pending {
 	struct list_head link;
 	void		 *data;
 	unsigned int	 len;
 	unsigned int	 next;
 	unsigned int	 out;
 };

 static inline void dp_mark_completed(struct dma_pending *dp)
 {
 	dp->data += 1;
 }

 static inline bool dp_is_completed(struct dma_pending *dp)
 {
 	return (unsigned long)dp->data & 1UL;
 }

 void dma_fifo_init(struct dma_fifo *fifo);
 int dma_fifo_alloc(struct dma_fifo *fifo, int size, unsigned int align,
 		   int tx_limit, int open_limit, gfp_t gfp_mask);
 void dma_fifo_free(struct dma_fifo *fifo);
 void dma_fifo_reset(struct dma_fifo *fifo);
 int dma_fifo_in(struct dma_fifo *fifo, const void *src, int n);
 int dma_fifo_out_pend(struct dma_fifo *fifo, struct dma_pending *pended);
 int dma_fifo_out_complete(struct dma_fifo *fifo,
 			  struct dma_pending *complete);

 /* returns the # of used bytes in the fifo */
 static inline int dma_fifo_level(struct dma_fifo *fifo)
 {
 	return fifo->size - fifo->avail;
 }

 /* returns the # of bytes ready for output in the fifo */
 static inline int dma_fifo_out_level(struct dma_fifo *fifo)
 {
 	return fifo->in - fifo->out;
 }

 /* returns the # of unused bytes in the fifo */
 static inline int dma_fifo_avail(struct dma_fifo *fifo)
 {
 	return fifo->avail;
 }

 /* returns true if fifo has max # of outstanding dmas */
 static inline bool dma_fifo_busy(struct dma_fifo *fifo)
 {
 	return fifo->open == fifo->open_limit;
 }

 /* changes the max size of dma returned from dma_fifo_out_pend() */
 static inline int dma_fifo_change_tx_limit(struct dma_fifo *fifo, int tx_limit)
 {
 	tx_limit = round_down(tx_limit, fifo->align);
 	fifo->tx_limit = max_t(int, tx_limit, fifo->align);
 	return 0;
 }

 #endif /* _DMA_FIFO_H_ */
	/*
	* DMA-able FIFO interface
	*
	* Copyright (C) 2012 Peter Hurley <peter@hurleysoftware.com>
	*
	* This program is free software; you can redistribute it and/or modify
	* it under the terms of the GNU General Public License as published by
	* the Free Software Foundation; either version 2 of the License, or
	* (at your option) any later version.
	*
	* This program is distributed in the hope that it will be useful,
	* but WITHOUT ANY WARRANTY; without even the implied warranty of
	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	* GNU General Public License for more details.
	*/

	#ifndef _DMA_FIFO_H_
	#define _DMA_FIFO_H_

	/**
	* The design basis for the DMA FIFO is to provide an output side that
	* complies with the streaming DMA API design that can be DMA'd from directly
	* (without additional copying), coupled with an input side that maintains a
	* logically consistent 'apparent' size (ie, bytes in + bytes avail is static
	* for the lifetime of the FIFO).
	*
	* DMA output transactions originate on a cache line boundary and can be
	* variably-sized. DMA output transactions can be retired out-of-order but
	* the FIFO will only advance the output in the original input sequence.
	* This means the FIFO will eventually stall if a transaction is never retired.
	*
	* Chunking the output side into cache line multiples means that some FIFO
	* memory is unused. For example, if all the avail input has been pended out,
	* then the in and out markers are re-aligned to the next cache line.
	* The maximum possible waste is
	* (cache line alignment - 1) * (max outstanding dma transactions)
	* This potential waste requires additional hidden capacity within the FIFO
	* to be able to accept input while the 'apparent' size has not been reached.
	*
	* Additional cache lines (ie, guard area) are used to minimize DMA
	* fragmentation when wrapping at the end of the FIFO. Input is allowed into the
	* guard area, but the in and out FIFO markers are wrapped when DMA is pended.
	*/

	#define DMA_FIFO_GUARD 3 /* # of cache lines to reserve for the guard area */

	struct dma_fifo {
	unsigned int in;
	unsigned int out; /* updated when dma is pended */
	unsigned int done; /* updated upon dma completion */
	struct {
	unsigned corrupt:1;
	};
	int size; /* 'apparent' size of fifo */
	int guard; /* ofs of guard area */
	int capacity; /* size + reserved */
	int avail; /* # of unused bytes in fifo */
	unsigned int align; /* must be power of 2 */
	int tx_limit; /* max # of bytes per dma transaction */
	int open_limit; /* max # of outstanding allowed */
	int open; /* # of outstanding dma transactions */
	struct list_head pending; /* fifo markers for outstanding dma */
	void *data;
	};

	struct dma_pending {
	struct list_head link;
	void *data;
	unsigned int len;
	unsigned int next;
	unsigned int out;
	};

	static inline void dp_mark_completed(struct dma_pending *dp)
	{
	dp->data += 1;
	}

	static inline bool dp_is_completed(struct dma_pending *dp)
	{
	return (unsigned long)dp->data & 1UL;
	}

	void dma_fifo_init(struct dma_fifo *fifo);
	int dma_fifo_alloc(struct dma_fifo *fifo, int size, unsigned int align,
	int tx_limit, int open_limit, gfp_t gfp_mask);
	void dma_fifo_free(struct dma_fifo *fifo);
	void dma_fifo_reset(struct dma_fifo *fifo);
	int dma_fifo_in(struct dma_fifo fifo, const void src, int n);
	int dma_fifo_out_pend(struct dma_fifo fifo, struct dma_pending pended);
	int dma_fifo_out_complete(struct dma_fifo *fifo,
	struct dma_pending *complete);

	/* returns the # of used bytes in the fifo */
	static inline int dma_fifo_level(struct dma_fifo *fifo)
	{
	return fifo->size - fifo->avail;
	}

	/* returns the # of bytes ready for output in the fifo */
	static inline int dma_fifo_out_level(struct dma_fifo *fifo)
	{
	return fifo->in - fifo->out;
	}

	/* returns the # of unused bytes in the fifo */
	static inline int dma_fifo_avail(struct dma_fifo *fifo)
	{
	return fifo->avail;
	}

	/* returns true if fifo has max # of outstanding dmas */
	static inline bool dma_fifo_busy(struct dma_fifo *fifo)
	{
	return fifo->open == fifo->open_limit;
	}

	/* changes the max size of dma returned from dma_fifo_out_pend() */
	static inline int dma_fifo_change_tx_limit(struct dma_fifo *fifo, int tx_limit)
	{
	tx_limit = round_down(tx_limit, fifo->align);
	fifo->tx_limit = max_t(int, tx_limit, fifo->align);
	return 0;
	}

	#endif /* _DMA_FIFO_H_ */