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/* Core.h - Basic core logic functions and definitions */
/* Copyright Galileo Technology. */
/*
DESCRIPTION
This header file contains simple read/write macros for addressing
the SDRAM, devices, GT`s internal registers and PCI (using the PCI`s address
space). The macros take care of Big/Little endian conversions.
*/
#ifndef __INCcoreh
#define __INCcoreh
#include "mv_gen_reg.h"
extern unsigned int INTERNAL_REG_BASE_ADDR;
/****************************************/
/* GENERAL Definitions */
/****************************************/
#define NO_BIT 0x00000000
#define BIT0 0x00000001
#define BIT1 0x00000002
#define BIT2 0x00000004
#define BIT3 0x00000008
#define BIT4 0x00000010
#define BIT5 0x00000020
#define BIT6 0x00000040
#define BIT7 0x00000080
#define BIT8 0x00000100
#define BIT9 0x00000200
#define BIT10 0x00000400
#define BIT11 0x00000800
#define BIT12 0x00001000
#define BIT13 0x00002000
#define BIT14 0x00004000
#define BIT15 0x00008000
#define BIT16 0x00010000
#define BIT17 0x00020000
#define BIT18 0x00040000
#define BIT19 0x00080000
#define BIT20 0x00100000
#define BIT21 0x00200000
#define BIT22 0x00400000
#define BIT23 0x00800000
#define BIT24 0x01000000
#define BIT25 0x02000000
#define BIT26 0x04000000
#define BIT27 0x08000000
#define BIT28 0x10000000
#define BIT29 0x20000000
#define BIT30 0x40000000
#define BIT31 0x80000000
#define _1K 0x00000400
#define _2K 0x00000800
#define _4K 0x00001000
#define _8K 0x00002000
#define _16K 0x00004000
#define _32K 0x00008000
#define _64K 0x00010000
#define _128K 0x00020000
#define _256K 0x00040000
#define _512K 0x00080000
#define _1M 0x00100000
#define _2M 0x00200000
#define _3M 0x00300000
#define _4M 0x00400000
#define _5M 0x00500000
#define _6M 0x00600000
#define _7M 0x00700000
#define _8M 0x00800000
#define _9M 0x00900000
#define _10M 0x00a00000
#define _11M 0x00b00000
#define _12M 0x00c00000
#define _13M 0x00d00000
#define _14M 0x00e00000
#define _15M 0x00f00000
#define _16M 0x01000000
#define _32M 0x02000000
#define _64M 0x04000000
#define _128M 0x08000000
#define _256M 0x10000000
#define _512M 0x20000000
#define _1G 0x40000000
#define _2G 0x80000000
/* Little to Big endian conversion macros */
#ifdef LE /* Little Endian */
#define SHORT_SWAP(X) (X)
#define WORD_SWAP(X) (X)
#define LONG_SWAP(X) ((l64)(X))
#else /* Big Endian */
#define SHORT_SWAP(X) ((X <<8 ) | (X >> 8))
#define WORD_SWAP(X) (((X)&0xff)<<24)+ \
(((X)&0xff00)<<8)+ \
(((X)&0xff0000)>>8)+ \
(((X)&0xff000000)>>24)
#define LONG_SWAP(X) ( (l64) (((X)&0xffULL)<<56)+ \
(((X)&0xff00ULL)<<40)+ \
(((X)&0xff0000ULL)<<24)+ \
(((X)&0xff000000ULL)<<8)+ \
(((X)&0xff00000000ULL)>>8)+ \
(((X)&0xff0000000000ULL)>>24)+ \
(((X)&0xff000000000000ULL)>>40)+ \
(((X)&0xff00000000000000ULL)>>56))
#endif
#ifndef NULL
#define NULL 0
#endif
/* Those two definitions were defined to be compatible with MIPS */
#define NONE_CACHEABLE 0x00000000
#define CACHEABLE 0x00000000
/* 750 cache line */
#define CACHE_LINE_SIZE 32
#define CACHELINE_MASK_BITS (CACHE_LINE_SIZE - 1)
#define CACHELINE_ROUNDUP(A) (((A)+CACHELINE_MASK_BITS) & ~CACHELINE_MASK_BITS)
/* Read/Write to/from GT`s internal registers */
#define GT_REG_READ(offset, pData) \
*pData = ( *((volatile unsigned int *)(NONE_CACHEABLE | \
INTERNAL_REG_BASE_ADDR | (offset))) ) ; \
*pData = WORD_SWAP(*pData)
#define GTREGREAD(offset) \
(WORD_SWAP( *((volatile unsigned int *)(NONE_CACHEABLE | \
INTERNAL_REG_BASE_ADDR | (offset))) ))
#define GT_REG_WRITE(offset, data) \
*((unsigned int *)( INTERNAL_REG_BASE_ADDR | (offset))) = \
WORD_SWAP(data)
/* Write 32/16/8 bit */
#define WRITE_CHAR(address, data) \
*((unsigned char *)(address)) = data
#define WRITE_SHORT(address, data) \
*((unsigned short *)(address)) = data
#define WRITE_WORD(address, data) \
*((unsigned int *)(address)) = data
#define GT_WRITE_CHAR(address, data) WRITE_CHAR(address, data)
/* Write 32/16/8 bit NonCacheable */
/*
#define GT_WRITE_CHAR(address, data) \
(*((unsigned char *)NONE_CACHEABLE(address))) = data
#define GT_WRITE_SHORT(address, data) \
(*((unsigned short *)NONE_CACHEABLE(address))) = data
#define GT_WRITE_WORD(address, data) \
(*((unsigned int *)NONE_CACHEABLE(address))) = data
*/
/*#define GT_WRITE_CHAR(address, data) ((*((volatile unsigned char *)NONE_CACHEABLE((address)))) = ((unsigned char)(data)))1 */
/*#define GT_WRITE_SHORT(address, data) ((*((volatile unsigned short *)NONE_CACHEABLE((address)))) = ((unsigned short)(data)))1 */
/*#define GT_WRITE_WORD(address, data) ((*((volatile unsigned int *)NONE_CACHEABLE((address)))) = ((unsigned int)(data)))1 */
/* Read 32/16/8 bits - returns data in variable. */
#define READ_CHAR(address, pData) \
*pData = *((volatile unsigned char *)(address))
#define READ_SHORT(address, pData) \
*pData = *((volatile unsigned short *)(address))
#define READ_WORD(address, pData) \
*pData = *((volatile unsigned int *)(address))
/* Read 32/16/8 bit - returns data direct. */
#define READCHAR(address) \
*((volatile unsigned char *)((address) | NONE_CACHEABLE))
#define READSHORT(address) \
*((volatile unsigned short *)((address) | NONE_CACHEABLE))
#define READWORD(address) \
*((volatile unsigned int *)((address) | NONE_CACHEABLE))
/* Those two Macros were defined to be compatible with MIPS */
#define VIRTUAL_TO_PHY(x) (((unsigned int)x) & 0xffffffff)
#define PHY_TO_VIRTUAL(x) (((unsigned int)x) | NONE_CACHEABLE)
/* SET_REG_BITS(regOffset,bits) -
gets register offset and bits: a 32bit value. It set to logic '1' in the
internal register the bits which given as an input example:
SET_REG_BITS(0x840,BIT3 | BIT24 | BIT30) - set bits: 3,24 and 30 to logic
'1' in register 0x840 while the other bits stays as is. */
#define SET_REG_BITS(regOffset,bits) \
*(unsigned int*)(NONE_CACHEABLE | INTERNAL_REG_BASE_ADDR | \
regOffset) |= (unsigned int)WORD_SWAP(bits)
/* RESET_REG_BITS(regOffset,bits) -
gets register offset and bits: a 32bit value. It set to logic '0' in the
internal register the bits which given as an input example:
RESET_REG_BITS(0x840,BIT3 | BIT24 | BIT30) - set bits: 3,24 and 30 to logic
'0' in register 0x840 while the other bits stays as is. */
#define RESET_REG_BITS(regOffset,bits) \
*(unsigned int*)(NONE_CACHEABLE | INTERNAL_REG_BASE_ADDR \
| regOffset) &= ~( (unsigned int)WORD_SWAP(bits) )
/* gets register offset and bits: a 32bit value. It set to logic '1' in the
internal register the bits which given as an input example:
GT_SET_REG_BITS(0x840,BIT3 | BIT24 | BIT30) - set bits: 3,24 and 30 to logic
'1' in register 0x840 while the other bits stays as is. */
/*#define GT_SET_REG_BITS(regOffset,bits) ((*((volatile unsigned int*)(NONE_CACHEABLE(INTERNAL_REG_BASE_ADDR) | (regOffset)))) |= ((unsigned int)WORD_SWAP(bits)))1 */
/*#define GT_SET_REG_BITS(regOffset,bits) RESET_REG_BITS(regOffset,bits)1 */
#define GT_SET_REG_BITS(regOffset,bits) SET_REG_BITS(regOffset,bits)
/* gets register offset and bits: a 32bit value. It set to logic '0' in the
internal register the bits which given as an input example:
GT_RESET_REG_BITS(0x840,BIT3 | BIT24 | BIT30) - set bits: 3,24 and 30 to
logic '0' in register 0x840 while the other bits stays as is. */
/*#define GT_RESET_REG_BITS(regOffset,bits) ((*((volatile unsigned int*)(NONE_CACHEABLE(INTERNAL_REG_BASE_ADDR) | (regOffset)))) &= ~((unsigned int)WORD_SWAP(bits)))1 */
#define GT_RESET_REG_BITS(regOffset,bits) RESET_REG_BITS(regOffset,bits)
#define DEBUG_LED0_ON() WRITE_CHAR(memoryGetDeviceBaseAddress(DEVICE1) | 0x8000,0)
#define DEBUG_LED1_ON() WRITE_CHAR(memoryGetDeviceBaseAddress(DEVICE1) | 0xc000,0)
#define DEBUG_LED2_ON() WRITE_CHAR(memoryGetDeviceBaseAddress(DEVICE1) | 0x10000,0)
#define DEBUG_LED0_OFF() WRITE_CHAR(memoryGetDeviceBaseAddress(DEVICE1) | 0x14000,0)
#define DEBUG_LED1_OFF() WRITE_CHAR(memoryGetDeviceBaseAddress(DEVICE1) | 0x18000,0)
#define DEBUG_LED2_OFF() WRITE_CHAR(memoryGetDeviceBaseAddress(DEVICE1) | 0x1c000,0)
#endif /* __INCcoreh */
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