arch/mips/include/asm/mach-powertv/ioremap.h - nest-hello/linux-3.10 - Git at Google

 /*
  *	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.
  *
  * Portions Copyright (C)  Cisco Systems, Inc.
  */
 #ifndef __ASM_MACH_POWERTV_IOREMAP_H
 #define __ASM_MACH_POWERTV_IOREMAP_H

 #include <linux/types.h>
 #include <linux/log2.h>
 #include <linux/compiler.h>

 #include <asm/pgtable-bits.h>
 #include <asm/addrspace.h>

 /* We're going to mess with bits, so get sizes */
 #define IOR_BPC			8			/* Bits per char */
 #define IOR_PHYS_BITS		(IOR_BPC * sizeof(phys_addr_t))
 #define IOR_DMA_BITS		(IOR_BPC * sizeof(dma_addr_t))

 /*
  * Define the granularity of physical/DMA mapping in terms of the number
  * of bits that defines the offset within a grain. These will be the
  * least significant bits of the address. The rest of a physical or DMA
  * address will be used to index into an appropriate table to find the
  * offset to add to the address to yield the corresponding DMA or physical
  * address, respectively.
  */
 #define IOR_LSBITS		22			/* Bits in a grain */

 /*
  * Compute the number of most significant address bits after removing those
  * used for the offset within a grain and then compute the number of table
  * entries for the conversion.
  */
 #define IOR_PHYS_MSBITS		(IOR_PHYS_BITS - IOR_LSBITS)
 #define IOR_NUM_PHYS_TO_DMA	((phys_addr_t) 1 << IOR_PHYS_MSBITS)

 #define IOR_DMA_MSBITS		(IOR_DMA_BITS - IOR_LSBITS)
 #define IOR_NUM_DMA_TO_PHYS	((dma_addr_t) 1 << IOR_DMA_MSBITS)

 /*
  * Define data structures used as elements in the arrays for the conversion
  * between physical and DMA addresses. We do some slightly fancy math to
  * compute the width of the offset element of the conversion tables so
  * that we can have the smallest conversion tables. Next, round up the
  * sizes to the next higher power of two, i.e. the offset element will have
  * 8, 16, 32, 64, etc. bits. This eliminates the need to mask off any
  * bits.  Finally, we compute a shift value that puts the most significant
  * bits of the offset into the most significant bits of the offset element.
  * This makes it more efficient on processors without barrel shifters and
  * easier to see the values if the conversion table is dumped in binary.
  */
 #define _IOR_OFFSET_WIDTH(n)	(1 << order_base_2(n))
 #define IOR_OFFSET_WIDTH(n) \
 	(_IOR_OFFSET_WIDTH(n) < 8 ? 8 : _IOR_OFFSET_WIDTH(n))

 #define IOR_PHYS_OFFSET_BITS	IOR_OFFSET_WIDTH(IOR_PHYS_MSBITS)
 #define IOR_PHYS_SHIFT		(IOR_PHYS_BITS - IOR_PHYS_OFFSET_BITS)

 #define IOR_DMA_OFFSET_BITS	IOR_OFFSET_WIDTH(IOR_DMA_MSBITS)
 #define IOR_DMA_SHIFT		(IOR_DMA_BITS - IOR_DMA_OFFSET_BITS)

 struct ior_phys_to_dma {
 	dma_addr_t offset:IOR_DMA_OFFSET_BITS __packed
 		__aligned((IOR_DMA_OFFSET_BITS / IOR_BPC));
 };

 struct ior_dma_to_phys {
 	dma_addr_t offset:IOR_PHYS_OFFSET_BITS __packed
 		__aligned((IOR_PHYS_OFFSET_BITS / IOR_BPC));
 };

 extern struct ior_phys_to_dma _ior_phys_to_dma[IOR_NUM_PHYS_TO_DMA];
 extern struct ior_dma_to_phys _ior_dma_to_phys[IOR_NUM_DMA_TO_PHYS];

 static inline dma_addr_t _phys_to_dma_offset_raw(phys_addr_t phys)
 {
 	return (dma_addr_t)_ior_phys_to_dma[phys >> IOR_LSBITS].offset;
 }

 static inline dma_addr_t _dma_to_phys_offset_raw(dma_addr_t dma)
 {
 	return (dma_addr_t)_ior_dma_to_phys[dma >> IOR_LSBITS].offset;
 }

 /* These are not portable and should not be used in drivers. Drivers should
  * be using ioremap() and friends to map physical addresses to virtual
  * addresses and dma_map*() and friends to map virtual addresses into DMA
  * addresses and back.
  */
 static inline dma_addr_t phys_to_dma(phys_addr_t phys)
 {
 	return phys + (_phys_to_dma_offset_raw(phys) << IOR_PHYS_SHIFT);
 }

 static inline phys_addr_t dma_to_phys(dma_addr_t dma)
 {
 	return dma + (_dma_to_phys_offset_raw(dma) << IOR_DMA_SHIFT);
 }

 extern void ioremap_add_map(dma_addr_t phys, phys_addr_t alias,
 	dma_addr_t size);

 /*
  * Allow physical addresses to be fixed up to help peripherals located
  * outside the low 32-bit range -- generic pass-through version.
  */
 static inline phys_t fixup_bigphys_addr(phys_t phys_addr, phys_t size)
 {
 	return phys_addr;
 }

 /*
  * Handle the special case of addresses the area aliased into the first
  * 512 MiB of the processor's physical address space. These turn into either
  * kseg0 or kseg1 addresses, depending on flags.
  */
 static inline void __iomem *plat_ioremap(phys_t start, unsigned long size,
 	unsigned long flags)
 {
 	phys_addr_t start_offset;
 	void __iomem *result = NULL;

 	/* Start by checking to see whether this is an aliased address */
 	start_offset = _dma_to_phys_offset_raw(start);

 	/*
 	 * If:
 	 * o	the memory is aliased into the first 512 MiB, and
 	 * o	the start and end are in the same RAM bank, and
 	 * o	we don't have a zero size or wrap around, and
 	 * o	we are supposed to create an uncached mapping,
 	 *	handle this is a kseg0 or kseg1 address
 	 */
 	if (start_offset != 0) {
 		phys_addr_t last;
 		dma_addr_t dma_to_phys_offset;

 		last = start + size - 1;
 		dma_to_phys_offset =
 			_dma_to_phys_offset_raw(last) << IOR_DMA_SHIFT;

 		if (dma_to_phys_offset == start_offset &&
 			size != 0 && start <= last) {
 			phys_t adjusted_start;
 			adjusted_start = start + start_offset;
 			if (flags == _CACHE_UNCACHED)
 				result = (void __iomem *) (unsigned long)
 					CKSEG1ADDR(adjusted_start);
 			else
 				result = (void __iomem *) (unsigned long)
 					CKSEG0ADDR(adjusted_start);
 		}
 	}

 	return result;
 }

 static inline int plat_iounmap(const volatile void __iomem *addr)
 {
 	return 0;
 }
 #endif /* __ASM_MACH_POWERTV_IOREMAP_H */
	/*
	* 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.
	*
	* Portions Copyright (C) Cisco Systems, Inc.
	*/
	#ifndef __ASM_MACH_POWERTV_IOREMAP_H
	#define __ASM_MACH_POWERTV_IOREMAP_H

	#include <linux/types.h>
	#include <linux/log2.h>
	#include <linux/compiler.h>

	#include <asm/pgtable-bits.h>
	#include <asm/addrspace.h>

	/* We're going to mess with bits, so get sizes */
	#define IOR_BPC 8 /* Bits per char */
	#define IOR_PHYS_BITS (IOR_BPC * sizeof(phys_addr_t))
	#define IOR_DMA_BITS (IOR_BPC * sizeof(dma_addr_t))

	/*
	* Define the granularity of physical/DMA mapping in terms of the number
	* of bits that defines the offset within a grain. These will be the
	* least significant bits of the address. The rest of a physical or DMA
	* address will be used to index into an appropriate table to find the
	* offset to add to the address to yield the corresponding DMA or physical
	* address, respectively.
	*/
	#define IOR_LSBITS 22 /* Bits in a grain */

	/*
	* Compute the number of most significant address bits after removing those
	* used for the offset within a grain and then compute the number of table
	* entries for the conversion.
	*/
	#define IOR_PHYS_MSBITS (IOR_PHYS_BITS - IOR_LSBITS)
	#define IOR_NUM_PHYS_TO_DMA ((phys_addr_t) 1 << IOR_PHYS_MSBITS)

	#define IOR_DMA_MSBITS (IOR_DMA_BITS - IOR_LSBITS)
	#define IOR_NUM_DMA_TO_PHYS ((dma_addr_t) 1 << IOR_DMA_MSBITS)

	/*
	* Define data structures used as elements in the arrays for the conversion
	* between physical and DMA addresses. We do some slightly fancy math to
	* compute the width of the offset element of the conversion tables so
	* that we can have the smallest conversion tables. Next, round up the
	* sizes to the next higher power of two, i.e. the offset element will have
	* 8, 16, 32, 64, etc. bits. This eliminates the need to mask off any
	* bits. Finally, we compute a shift value that puts the most significant
	* bits of the offset into the most significant bits of the offset element.
	* This makes it more efficient on processors without barrel shifters and
	* easier to see the values if the conversion table is dumped in binary.
	*/
	#define _IOR_OFFSET_WIDTH(n) (1 << order_base_2(n))
	#define IOR_OFFSET_WIDTH(n) \
	(_IOR_OFFSET_WIDTH(n) < 8 ? 8 : _IOR_OFFSET_WIDTH(n))

	#define IOR_PHYS_OFFSET_BITS IOR_OFFSET_WIDTH(IOR_PHYS_MSBITS)
	#define IOR_PHYS_SHIFT (IOR_PHYS_BITS - IOR_PHYS_OFFSET_BITS)

	#define IOR_DMA_OFFSET_BITS IOR_OFFSET_WIDTH(IOR_DMA_MSBITS)
	#define IOR_DMA_SHIFT (IOR_DMA_BITS - IOR_DMA_OFFSET_BITS)

	struct ior_phys_to_dma {
	dma_addr_t offset:IOR_DMA_OFFSET_BITS __packed
	__aligned((IOR_DMA_OFFSET_BITS / IOR_BPC));
	};

	struct ior_dma_to_phys {
	dma_addr_t offset:IOR_PHYS_OFFSET_BITS __packed
	__aligned((IOR_PHYS_OFFSET_BITS / IOR_BPC));
	};

	extern struct ior_phys_to_dma _ior_phys_to_dma[IOR_NUM_PHYS_TO_DMA];
	extern struct ior_dma_to_phys _ior_dma_to_phys[IOR_NUM_DMA_TO_PHYS];

	static inline dma_addr_t _phys_to_dma_offset_raw(phys_addr_t phys)
	{
	return (dma_addr_t)_ior_phys_to_dma[phys >> IOR_LSBITS].offset;
	}

	static inline dma_addr_t _dma_to_phys_offset_raw(dma_addr_t dma)
	{
	return (dma_addr_t)_ior_dma_to_phys[dma >> IOR_LSBITS].offset;
	}

	/* These are not portable and should not be used in drivers. Drivers should
	* be using ioremap() and friends to map physical addresses to virtual
	* addresses and dma_map*() and friends to map virtual addresses into DMA
	* addresses and back.
	*/
	static inline dma_addr_t phys_to_dma(phys_addr_t phys)
	{
	return phys + (_phys_to_dma_offset_raw(phys) << IOR_PHYS_SHIFT);
	}

	static inline phys_addr_t dma_to_phys(dma_addr_t dma)
	{
	return dma + (_dma_to_phys_offset_raw(dma) << IOR_DMA_SHIFT);
	}

	extern void ioremap_add_map(dma_addr_t phys, phys_addr_t alias,
	dma_addr_t size);

	/*
	* Allow physical addresses to be fixed up to help peripherals located
	* outside the low 32-bit range -- generic pass-through version.
	*/
	static inline phys_t fixup_bigphys_addr(phys_t phys_addr, phys_t size)
	{
	return phys_addr;
	}

	/*
	* Handle the special case of addresses the area aliased into the first
	* 512 MiB of the processor's physical address space. These turn into either
	* kseg0 or kseg1 addresses, depending on flags.
	*/
	static inline void __iomem *plat_ioremap(phys_t start, unsigned long size,
	unsigned long flags)
	{
	phys_addr_t start_offset;
	void __iomem *result = NULL;

	/* Start by checking to see whether this is an aliased address */
	start_offset = _dma_to_phys_offset_raw(start);

	/*
	* If:
	* o the memory is aliased into the first 512 MiB, and
	* o the start and end are in the same RAM bank, and
	* o we don't have a zero size or wrap around, and
	* o we are supposed to create an uncached mapping,
	* handle this is a kseg0 or kseg1 address
	*/
	if (start_offset != 0) {
	phys_addr_t last;
	dma_addr_t dma_to_phys_offset;

	last = start + size - 1;
	dma_to_phys_offset =
	_dma_to_phys_offset_raw(last) << IOR_DMA_SHIFT;

	if (dma_to_phys_offset == start_offset &&
	size != 0 && start <= last) {
	phys_t adjusted_start;
	adjusted_start = start + start_offset;
	if (flags == _CACHE_UNCACHED)
	result = (void __iomem *) (unsigned long)
	CKSEG1ADDR(adjusted_start);
	else
	result = (void __iomem *) (unsigned long)
	CKSEG0ADDR(adjusted_start);
	}
	}

	return result;
	}

	static inline int plat_iounmap(const volatile void __iomem *addr)
	{
	return 0;
	}
	#endif /* __ASM_MACH_POWERTV_IOREMAP_H */