arch/unicore32/include/asm/cacheflush.h - pub/scm/linux/kernel/git/grover/linux - Git at Google

 /*
  * linux/arch/unicore32/include/asm/cacheflush.h
  *
  * Code specific to PKUnity SoC and UniCore ISA
  *
  * Copyright (C) 2001-2010 GUAN Xue-tao
  *
  * This program is free software; you can redistribute it and/or modify
  * it under the terms of the GNU General Public License version 2 as
  * published by the Free Software Foundation.
  */
 #ifndef __UNICORE_CACHEFLUSH_H__
 #define __UNICORE_CACHEFLUSH_H__

 #include <linux/mm.h>

 #include <asm/shmparam.h>

 #define CACHE_COLOUR(vaddr)	((vaddr & (SHMLBA - 1)) >> PAGE_SHIFT)

 /*
  * This flag is used to indicate that the page pointed to by a pte is clean
  * and does not require cleaning before returning it to the user.
  */
 #define PG_dcache_clean PG_arch_1

 /*
  *	MM Cache Management
  *	===================
  *
  *	The arch/unicore32/mm/cache.S files implement these methods.
  *
  *	Start addresses are inclusive and end addresses are exclusive;
  *	start addresses should be rounded down, end addresses up.
  *
  *	See Documentation/cachetlb.txt for more information.
  *	Please note that the implementation of these, and the required
  *	effects are cache-type (VIVT/VIPT/PIPT) specific.
  *
  *	flush_icache_all()
  *
  *		Unconditionally clean and invalidate the entire icache.
  *		Currently only needed for cache-v6.S and cache-v7.S, see
  *		__flush_icache_all for the generic implementation.
  *
  *	flush_kern_all()
  *
  *		Unconditionally clean and invalidate the entire cache.
  *
  *	flush_user_all()
  *
  *		Clean and invalidate all user space cache entries
  *		before a change of page tables.
  *
  *	flush_user_range(start, end, flags)
  *
  *		Clean and invalidate a range of cache entries in the
  *		specified address space before a change of page tables.
  *		- start - user start address (inclusive, page aligned)
  *		- end   - user end address   (exclusive, page aligned)
  *		- flags - vma->vm_flags field
  *
  *	coherent_kern_range(start, end)
  *
  *		Ensure coherency between the Icache and the Dcache in the
  *		region described by start, end.  If you have non-snooping
  *		Harvard caches, you need to implement this function.
  *		- start  - virtual start address
  *		- end    - virtual end address
  *
  *	coherent_user_range(start, end)
  *
  *		Ensure coherency between the Icache and the Dcache in the
  *		region described by start, end.  If you have non-snooping
  *		Harvard caches, you need to implement this function.
  *		- start  - virtual start address
  *		- end    - virtual end address
  *
  *	flush_kern_dcache_area(kaddr, size)
  *
  *		Ensure that the data held in page is written back.
  *		- kaddr  - page address
  *		- size   - region size
  *
  *	DMA Cache Coherency
  *	===================
  *
  *	dma_flush_range(start, end)
  *
  *		Clean and invalidate the specified virtual address range.
  *		- start  - virtual start address
  *		- end    - virtual end address
  */

 extern void __cpuc_flush_icache_all(void);
 extern void __cpuc_flush_kern_all(void);
 extern void __cpuc_flush_user_all(void);
 extern void __cpuc_flush_user_range(unsigned long, unsigned long, unsigned int);
 extern void __cpuc_coherent_kern_range(unsigned long, unsigned long);
 extern void __cpuc_coherent_user_range(unsigned long, unsigned long);
 extern void __cpuc_flush_dcache_area(void *, size_t);
 extern void __cpuc_flush_kern_dcache_area(void *addr, size_t size);

 /*
  * These are private to the dma-mapping API.  Do not use directly.
  * Their sole purpose is to ensure that data held in the cache
  * is visible to DMA, or data written by DMA to system memory is
  * visible to the CPU.
  */
 extern void __cpuc_dma_clean_range(unsigned long, unsigned long);
 extern void __cpuc_dma_flush_range(unsigned long, unsigned long);

 /*
  * Copy user data from/to a page which is mapped into a different
  * processes address space.  Really, we want to allow our "user
  * space" model to handle this.
  */
 extern void copy_to_user_page(struct vm_area_struct *, struct page *,
 	unsigned long, void *, const void *, unsigned long);
 #define copy_from_user_page(vma, page, vaddr, dst, src, len)	\
 	do {							\
 		memcpy(dst, src, len);				\
 	} while (0)

 /*
  * Convert calls to our calling convention.
  */
 /* Invalidate I-cache */
 static inline void __flush_icache_all(void)
 {
 	asm("movc	p0.c5, %0, #20;\n"
 	    "nop; nop; nop; nop; nop; nop; nop; nop\n"
 	    :
 	    : "r" (0));
 }

 #define flush_cache_all()		__cpuc_flush_kern_all()

 extern void flush_cache_mm(struct mm_struct *mm);
 extern void flush_cache_range(struct vm_area_struct *vma,
 		unsigned long start, unsigned long end);
 extern void flush_cache_page(struct vm_area_struct *vma,
 		unsigned long user_addr, unsigned long pfn);

 #define flush_cache_dup_mm(mm) flush_cache_mm(mm)

 /*
  * flush_cache_user_range is used when we want to ensure that the
  * Harvard caches are synchronised for the user space address range.
  * This is used for the UniCore private sys_cacheflush system call.
  */
 #define flush_cache_user_range(vma, start, end) \
 	__cpuc_coherent_user_range((start) & PAGE_MASK, PAGE_ALIGN(end))

 /*
  * Perform necessary cache operations to ensure that data previously
  * stored within this range of addresses can be executed by the CPU.
  */
 #define flush_icache_range(s, e)	__cpuc_coherent_kern_range(s, e)

 /*
  * Perform necessary cache operations to ensure that the TLB will
  * see data written in the specified area.
  */
 #define clean_dcache_area(start, size)	cpu_dcache_clean_area(start, size)

 /*
  * flush_dcache_page is used when the kernel has written to the page
  * cache page at virtual address page->virtual.
  *
  * If this page isn't mapped (ie, page_mapping == NULL), or it might
  * have userspace mappings, then we _must_ always clean + invalidate
  * the dcache entries associated with the kernel mapping.
  *
  * Otherwise we can defer the operation, and clean the cache when we are
  * about to change to user space.  This is the same method as used on SPARC64.
  * See update_mmu_cache for the user space part.
  */
 #define ARCH_IMPLEMENTS_FLUSH_DCACHE_PAGE 1
 extern void flush_dcache_page(struct page *);

 #define flush_dcache_mmap_lock(mapping)			\
 	spin_lock_irq(&(mapping)->tree_lock)
 #define flush_dcache_mmap_unlock(mapping)		\
 	spin_unlock_irq(&(mapping)->tree_lock)

 #define flush_icache_user_range(vma, page, addr, len)	\
 	flush_dcache_page(page)

 /*
  * We don't appear to need to do anything here.  In fact, if we did, we'd
  * duplicate cache flushing elsewhere performed by flush_dcache_page().
  */
 #define flush_icache_page(vma, page)	do { } while (0)

 /*
  * flush_cache_vmap() is used when creating mappings (eg, via vmap,
  * vmalloc, ioremap etc) in kernel space for pages.  On non-VIPT
  * caches, since the direct-mappings of these pages may contain cached
  * data, we need to do a full cache flush to ensure that writebacks
  * don't corrupt data placed into these pages via the new mappings.
  */
 static inline void flush_cache_vmap(unsigned long start, unsigned long end)
 {
 }

 static inline void flush_cache_vunmap(unsigned long start, unsigned long end)
 {
 }

 #endif
	/*
	* linux/arch/unicore32/include/asm/cacheflush.h
	*
	* Code specific to PKUnity SoC and UniCore ISA
	*
	* Copyright (C) 2001-2010 GUAN Xue-tao
	*
	* This program is free software; you can redistribute it and/or modify
	* it under the terms of the GNU General Public License version 2 as
	* published by the Free Software Foundation.
	*/
	#ifndef __UNICORE_CACHEFLUSH_H__
	#define __UNICORE_CACHEFLUSH_H__

	#include <linux/mm.h>

	#include <asm/shmparam.h>

	#define CACHE_COLOUR(vaddr) ((vaddr & (SHMLBA - 1)) >> PAGE_SHIFT)

	/*
	* This flag is used to indicate that the page pointed to by a pte is clean
	* and does not require cleaning before returning it to the user.
	*/
	#define PG_dcache_clean PG_arch_1

	/*
	* MM Cache Management
	* ===================
	*
	* The arch/unicore32/mm/cache.S files implement these methods.
	*
	* Start addresses are inclusive and end addresses are exclusive;
	* start addresses should be rounded down, end addresses up.
	*
	* See Documentation/cachetlb.txt for more information.
	* Please note that the implementation of these, and the required
	* effects are cache-type (VIVT/VIPT/PIPT) specific.
	*
	* flush_icache_all()
	*
	* Unconditionally clean and invalidate the entire icache.
	* Currently only needed for cache-v6.S and cache-v7.S, see
	* __flush_icache_all for the generic implementation.
	*
	* flush_kern_all()
	*
	* Unconditionally clean and invalidate the entire cache.
	*
	* flush_user_all()
	*
	* Clean and invalidate all user space cache entries
	* before a change of page tables.
	*
	* flush_user_range(start, end, flags)
	*
	* Clean and invalidate a range of cache entries in the
	* specified address space before a change of page tables.
	* - start - user start address (inclusive, page aligned)
	* - end - user end address (exclusive, page aligned)
	* - flags - vma->vm_flags field
	*
	* coherent_kern_range(start, end)
	*
	* Ensure coherency between the Icache and the Dcache in the
	* region described by start, end. If you have non-snooping
	* Harvard caches, you need to implement this function.
	* - start - virtual start address
	* - end - virtual end address
	*
	* coherent_user_range(start, end)
	*
	* Ensure coherency between the Icache and the Dcache in the
	* region described by start, end. If you have non-snooping
	* Harvard caches, you need to implement this function.
	* - start - virtual start address
	* - end - virtual end address
	*
	* flush_kern_dcache_area(kaddr, size)
	*
	* Ensure that the data held in page is written back.
	* - kaddr - page address
	* - size - region size
	*
	* DMA Cache Coherency
	* ===================
	*
	* dma_flush_range(start, end)
	*
	* Clean and invalidate the specified virtual address range.
	* - start - virtual start address
	* - end - virtual end address
	*/

	extern void __cpuc_flush_icache_all(void);
	extern void __cpuc_flush_kern_all(void);
	extern void __cpuc_flush_user_all(void);
	extern void __cpuc_flush_user_range(unsigned long, unsigned long, unsigned int);
	extern void __cpuc_coherent_kern_range(unsigned long, unsigned long);
	extern void __cpuc_coherent_user_range(unsigned long, unsigned long);
	extern void __cpuc_flush_dcache_area(void *, size_t);
	extern void __cpuc_flush_kern_dcache_area(void *addr, size_t size);

	/*
	* These are private to the dma-mapping API. Do not use directly.
	* Their sole purpose is to ensure that data held in the cache
	* is visible to DMA, or data written by DMA to system memory is
	* visible to the CPU.
	*/
	extern void __cpuc_dma_clean_range(unsigned long, unsigned long);
	extern void __cpuc_dma_flush_range(unsigned long, unsigned long);

	/*
	* Copy user data from/to a page which is mapped into a different
	* processes address space. Really, we want to allow our "user
	* space" model to handle this.
	*/
	extern void copy_to_user_page(struct vm_area_struct , struct page ,
	unsigned long, void , const void , unsigned long);
	#define copy_from_user_page(vma, page, vaddr, dst, src, len) \
	do { \
	memcpy(dst, src, len); \
	} while (0)

	/*
	* Convert calls to our calling convention.
	*/
	/* Invalidate I-cache */
	static inline void __flush_icache_all(void)
	{
	asm("movc p0.c5, %0, #20;\n"
	"nop; nop; nop; nop; nop; nop; nop; nop\n"
	:
	: "r" (0));
	}

	#define flush_cache_all() __cpuc_flush_kern_all()

	extern void flush_cache_mm(struct mm_struct *mm);
	extern void flush_cache_range(struct vm_area_struct *vma,
	unsigned long start, unsigned long end);
	extern void flush_cache_page(struct vm_area_struct *vma,
	unsigned long user_addr, unsigned long pfn);

	#define flush_cache_dup_mm(mm) flush_cache_mm(mm)

	/*
	* flush_cache_user_range is used when we want to ensure that the
	* Harvard caches are synchronised for the user space address range.
	* This is used for the UniCore private sys_cacheflush system call.
	*/
	#define flush_cache_user_range(vma, start, end) \
	__cpuc_coherent_user_range((start) & PAGE_MASK, PAGE_ALIGN(end))

	/*
	* Perform necessary cache operations to ensure that data previously
	* stored within this range of addresses can be executed by the CPU.
	*/
	#define flush_icache_range(s, e) __cpuc_coherent_kern_range(s, e)

	/*
	* Perform necessary cache operations to ensure that the TLB will
	* see data written in the specified area.
	*/
	#define clean_dcache_area(start, size) cpu_dcache_clean_area(start, size)

	/*
	* flush_dcache_page is used when the kernel has written to the page
	* cache page at virtual address page->virtual.
	*
	* If this page isn't mapped (ie, page_mapping == NULL), or it might
	* have userspace mappings, then we _must_ always clean + invalidate
	* the dcache entries associated with the kernel mapping.
	*
	* Otherwise we can defer the operation, and clean the cache when we are
	* about to change to user space. This is the same method as used on SPARC64.
	* See update_mmu_cache for the user space part.
	*/
	#define ARCH_IMPLEMENTS_FLUSH_DCACHE_PAGE 1
	extern void flush_dcache_page(struct page *);

	#define flush_dcache_mmap_lock(mapping) \
	spin_lock_irq(&(mapping)->tree_lock)
	#define flush_dcache_mmap_unlock(mapping) \
	spin_unlock_irq(&(mapping)->tree_lock)

	#define flush_icache_user_range(vma, page, addr, len) \
	flush_dcache_page(page)

	/*
	* We don't appear to need to do anything here. In fact, if we did, we'd
	* duplicate cache flushing elsewhere performed by flush_dcache_page().
	*/
	#define flush_icache_page(vma, page) do { } while (0)

	/*
	* flush_cache_vmap() is used when creating mappings (eg, via vmap,
	* vmalloc, ioremap etc) in kernel space for pages. On non-VIPT
	* caches, since the direct-mappings of these pages may contain cached
	* data, we need to do a full cache flush to ensure that writebacks
	* don't corrupt data placed into these pages via the new mappings.
	*/
	static inline void flush_cache_vmap(unsigned long start, unsigned long end)
	{
	}

	static inline void flush_cache_vunmap(unsigned long start, unsigned long end)
	{
	}

	#endif