dect/linux-2.6
Archived
14
0
Fork 0
Code Releases Activity
This repository has been archived on 2022-02-17. You can view files and clone it, but cannot push or open issues or pull requests.
linux-2.6/include/asm-avr32/io.h
Haavard Skinnemoen 5f97f7f940 [PATCH] avr32 architecture 
This adds support for the Atmel AVR32 architecture as well as the AT32AP7000
CPU and the AT32STK1000 development board.

AVR32 is a new high-performance 32-bit RISC microprocessor core, designed for
cost-sensitive embedded applications, with particular emphasis on low power
consumption and high code density.  The AVR32 architecture is not binary
compatible with earlier 8-bit AVR architectures.

The AVR32 architecture, including the instruction set, is described by the
AVR32 Architecture Manual, available from

http://www.atmel.com/dyn/resources/prod_documents/doc32000.pdf

The Atmel AT32AP7000 is the first CPU implementing the AVR32 architecture.  It
features a 7-stage pipeline, 16KB instruction and data caches and a full
Memory Management Unit.  It also comes with a large set of integrated
peripherals, many of which are shared with the AT91 ARM-based controllers from
Atmel.

Full data sheet is available from

http://www.atmel.com/dyn/resources/prod_documents/doc32003.pdf

while the CPU core implementation including caches and MMU is documented by
the AVR32 AP Technical Reference, available from

http://www.atmel.com/dyn/resources/prod_documents/doc32001.pdf

Information about the AT32STK1000 development board can be found at

http://www.atmel.com/dyn/products/tools_card.asp?tool_id=3918

including a BSP CD image with an earlier version of this patch, development
tools (binaries and source/patches) and a root filesystem image suitable for
booting from SD card.

Alternatively, there's a preliminary "getting started" guide available at
http://avr32linux.org/twiki/bin/view/Main/GettingStarted which provides links
to the sources and patches you will need in order to set up a cross-compiling
environment for avr32-linux.

This patch, as well as the other patches included with the BSP and the
toolchain patches, is actively supported by Atmel Corporation.

[dmccr@us.ibm.com: Fix more pxx_page macro locations]
[bunk@stusta.de: fix `make defconfig']
Signed-off-by: Haavard Skinnemoen <hskinnemoen@atmel.com>
Signed-off-by: Adrian Bunk <bunk@stusta.de>
Signed-off-by: Dave McCracken <dmccr@us.ibm.com>
Signed-off-by: Andrew Morton <akpm@osdl.org>
Signed-off-by: Linus Torvalds <torvalds@osdl.org>
2006-09-26 08:48:54 -07:00

254 lines
6.9 KiB
C
Raw Blame History

#ifndef __ASM_AVR32_IO_H
#define __ASM_AVR32_IO_H
#include <linux/string.h>
#ifdef __KERNEL__
#include <asm/addrspace.h>
#include <asm/byteorder.h>
/* virt_to_phys will only work when address is in P1 or P2 */
static __inline__ unsigned long virt_to_phys(volatile void *address)
{
return PHYSADDR(address);
}
static __inline__ void * phys_to_virt(unsigned long address)
{
return (void *)P1SEGADDR(address);
}
#define cached_to_phys(addr) ((unsigned long)PHYSADDR(addr))
#define uncached_to_phys(addr) ((unsigned long)PHYSADDR(addr))
#define phys_to_cached(addr) ((void *)P1SEGADDR(addr))
#define phys_to_uncached(addr) ((void *)P2SEGADDR(addr))
/*
* Generic IO read/write. These perform native-endian accesses. Note
* that some architectures will want to re-define __raw_{read,write}w.
*/
extern void __raw_writesb(unsigned int addr, const void *data, int bytelen);
extern void __raw_writesw(unsigned int addr, const void *data, int wordlen);
extern void __raw_writesl(unsigned int addr, const void *data, int longlen);
extern void __raw_readsb(unsigned int addr, void *data, int bytelen);
extern void __raw_readsw(unsigned int addr, void *data, int wordlen);
extern void __raw_readsl(unsigned int addr, void *data, int longlen);
static inline void writeb(unsigned char b, volatile void __iomem *addr)
{
*(volatile unsigned char __force *)addr = b;
}
static inline void writew(unsigned short b, volatile void __iomem *addr)
{
*(volatile unsigned short __force *)addr = b;
}
static inline void writel(unsigned int b, volatile void __iomem *addr)
{
*(volatile unsigned int __force *)addr = b;
}
#define __raw_writeb writeb
#define __raw_writew writew
#define __raw_writel writel
static inline unsigned char readb(const volatile void __iomem *addr)
{
return *(const volatile unsigned char __force *)addr;
}
static inline unsigned short readw(const volatile void __iomem *addr)
{
return *(const volatile unsigned short __force *)addr;
}
static inline unsigned int readl(const volatile void __iomem *addr)
{
return *(const volatile unsigned int __force *)addr;
}
#define __raw_readb readb
#define __raw_readw readw
#define __raw_readl readl
#define writesb(p, d, l) __raw_writesb((unsigned int)p, d, l)
#define writesw(p, d, l) __raw_writesw((unsigned int)p, d, l)
#define writesl(p, d, l) __raw_writesl((unsigned int)p, d, l)
#define readsb(p, d, l) __raw_readsb((unsigned int)p, d, l)
#define readsw(p, d, l) __raw_readsw((unsigned int)p, d, l)
#define readsl(p, d, l) __raw_readsl((unsigned int)p, d, l)
/*
* These two are only here because ALSA _thinks_ it needs them...
*/
static inline void memcpy_fromio(void * to, const volatile void __iomem *from,
unsigned long count)
{
char *p = to;
while (count) {
count--;
*p = readb(from);
p++;
from++;
}
}
static inline void memcpy_toio(volatile void __iomem *to, const void * from,
unsigned long count)
{
const char *p = from;
while (count) {
count--;
writeb(*p, to);
p++;
to++;
}
}
static inline void memset_io(volatile void __iomem *addr, unsigned char val,
unsigned long count)
{
memset((void __force *)addr, val, count);
}
/*
* Bad read/write accesses...
*/
extern void __readwrite_bug(const char *fn);
#define IO_SPACE_LIMIT 0xffffffff
/* Convert I/O port address to virtual address */
#define __io(p) ((void __iomem *)phys_to_uncached(p))
/*
* IO port access primitives
* -------------------------
*
* The AVR32 doesn't have special IO access instructions; all IO is memory
* mapped. Note that these are defined to perform little endian accesses
* only. Their primary purpose is to access PCI and ISA peripherals.
*
* Note that for a big endian machine, this implies that the following
* big endian mode connectivity is in place.
*
* The machine specific io.h include defines __io to translate an "IO"
* address to a memory address.
*
* Note that we prevent GCC re-ordering or caching values in expressions
* by introducing sequence points into the in*() definitions. Note that
* __raw_* do not guarantee this behaviour.
*
* The {in,out}[bwl] macros are for emulating x86-style PCI/ISA IO space.
*/
#define outb(v, p) __raw_writeb(v, __io(p))
#define outw(v, p) __raw_writew(cpu_to_le16(v), __io(p))
#define outl(v, p) __raw_writel(cpu_to_le32(v), __io(p))
#define inb(p) __raw_readb(__io(p))
#define inw(p) le16_to_cpu(__raw_readw(__io(p)))
#define inl(p) le32_to_cpu(__raw_readl(__io(p)))
static inline void __outsb(unsigned long port, void *addr, unsigned int count)
{
while (count--) {
outb(*(u8 *)addr, port);
addr++;
}
}
static inline void __insb(unsigned long port, void *addr, unsigned int count)
{
while (count--) {
*(u8 *)addr = inb(port);
addr++;
}
}
static inline void __outsw(unsigned long port, void *addr, unsigned int count)
{
while (count--) {
outw(*(u16 *)addr, port);
addr += 2;
}
}
static inline void __insw(unsigned long port, void *addr, unsigned int count)
{
while (count--) {
*(u16 *)addr = inw(port);
addr += 2;
}
}
static inline void __outsl(unsigned long port, void *addr, unsigned int count)
{
while (count--) {
outl(*(u32 *)addr, port);
addr += 4;
}
}
static inline void __insl(unsigned long port, void *addr, unsigned int count)
{
while (count--) {
*(u32 *)addr = inl(port);
addr += 4;
}
}
#define outsb(port, addr, count) __outsb(port, addr, count)
#define insb(port, addr, count) __insb(port, addr, count)
#define outsw(port, addr, count) __outsw(port, addr, count)
#define insw(port, addr, count) __insw(port, addr, count)
#define outsl(port, addr, count) __outsl(port, addr, count)
#define insl(port, addr, count) __insl(port, addr, count)
extern void __iomem *__ioremap(unsigned long offset, size_t size,
unsigned long flags);
extern void __iounmap(void __iomem *addr);
/*
* ioremap - map bus memory into CPU space
* @offset bus address of the memory
* @size size of the resource to map
*
* ioremap performs a platform specific sequence of operations to make
* bus memory CPU accessible via the readb/.../writel functions and
* the other mmio helpers. The returned address is not guaranteed to
* be usable directly as a virtual address.
*/
#define ioremap(offset, size) \
__ioremap((offset), (size), 0)
#define iounmap(addr) \
__iounmap(addr)
#define cached(addr) P1SEGADDR(addr)
#define uncached(addr) P2SEGADDR(addr)
#define virt_to_bus virt_to_phys
#define bus_to_virt phys_to_virt
#define page_to_bus page_to_phys
#define bus_to_page phys_to_page
#define dma_cache_wback_inv(_start, _size) \
flush_dcache_region(_start, _size)
#define dma_cache_inv(_start, _size) \
invalidate_dcache_region(_start, _size)
#define dma_cache_wback(_start, _size) \
clean_dcache_region(_start, _size)
/*
* Convert a physical pointer to a virtual kernel pointer for /dev/mem
* access
*/
#define xlate_dev_mem_ptr(p) __va(p)
/*
* Convert a virtual cached pointer to an uncached pointer
*/
#define xlate_dev_kmem_ptr(p) p
#endif /* __KERNEL__ */
#endif /* __ASM_AVR32_IO_H */
View git blame Copy permalink