binutils-gdb/gdb/rdi-share/angel_endian.h

/* 
 * Copyright (C) 1995 Advanced RISC Machines Limited. All rights reserved.
 * 
 * This software may be freely used, copied, modified, and distributed
 * provided that the above copyright notice is preserved in all copies of the
 * software.
 */

/* -*-C-*-
 *
 * $Revision$
 *     $Date$
 *
 *
 * angel_endian.h - target endianness independent read/write primitives.
 */

#ifndef angel_endian_h
#define angel_endian_h

/*
 * The endianness of the data being processed needs to be known, but
 * the host endianness is not required (since the data is constructed
 * using bytes).  At the moment these are provided as macros. This
 * gives the compiler freedom in optimising individual calls. However,
 * if space is at a premium then functions should be provided.
 *
 * NOTE: These macros assume that the data has been packed in the same format
 *       as the packing on the build host. If this is not the case then
 *       the wrong addresses could be used when dealing with structures.
 *
 */

/*
 * For all the following routines the target endianness is defined by the
 * following boolean definitions.
 */
#define BE (1 == 1) /* TRUE  : big-endian */
#define LE (1 == 0) /* FALSE : little-endian */

/*
 * The following type definitions are used by the endianness converting
 * macros.
 */
typedef unsigned char U8;
typedef U8 *P_U8;
typedef const U8 *CP_U8;

typedef unsigned short U16;
typedef U16 *P_U16;

typedef unsigned int U32;
typedef U32 *P_U32;

/*
 * If the endianness of the host and target are known (fixed) and the same
 * then the following macro definitions can be used. These just directly copy
 * the data.
 *
 * #define READ(e,a)       (a)
 * #define WRITE(e,a,v)    ((a) = (v))
 * #define PREAD(e,a)      (a)
 * #define PWRITE(e,a,v)   (*(a) = (v))
 */

/*
 * These macros assume that a byte (char) is 8bits in size, and that the
 * endianness is not important when reading or writing bytes.
 */
#define PUT8(a,v)       (*((P_U8)(a)) = (U8)(v))
#define PUT16LE(a,v)    (PUT8(a,((v) & 0xFF)), \
                         PUT8((((P_U8)(a)) + sizeof(char)),((v) >> 8)))
#define PUT16BE(a,v)    (PUT8(a,((v) >> 8)), \
                         PUT8((((P_U8)(a)) + sizeof(char)),((v) & 0xFF)))
#define PUT32LE(a,v)    (PUT16LE(a,v), \
                         PUT16LE((((P_U8)(a)) + sizeof(short)),((v) >> 16)))
#define PUT32BE(a,v)    (PUT16BE(a,((v) >> 16)), \
                         PUT16BE((((P_U8)(a)) + sizeof(short)),v))

#define GET8(a)     (*((CP_U8)(a)))
#define GET16LE(a)  (GET8(a) | (((U16)GET8(((CP_U8)(a)) + sizeof(char))) << 8))
#define GET16BE(a)  ((((U16)GET8(a)) << 8) | GET8(((CP_U8)(a)) + sizeof(char)))
#define GET32LE(a)  (GET16LE(a) | \
                     (((U32)GET16LE(((CP_U8)(a)) + sizeof(short))) << 16))
#define GET32BE(a)  ((((U32)GET16BE(a)) << 16) | \
                     GET16BE(((CP_U8)(a)) + sizeof(short)))

/*
 * These macros simplify the code in respect to reading and writing the
 * correct size data when dealing with endianness. "e" is TRUE if we are
 * dealing with big-endian data, FALSE if we are dealing with little-endian.
 */

/* void WRITE(int endianness, void *address, unsigned value); */

#define WRITE16(e,a,v) ((e) ? PUT16BE(&(a),v) : PUT16LE(&(a),v))
#define WRITE32(e,a,v) ((e) ? PUT32BE(&(a),v) : PUT32LE(&(a),v))
#define WRITE(e,a,v)   ((sizeof(v) == sizeof(char)) ? \
                        PUT8(&(a),v) : ((sizeof(v) == sizeof(short)) ? \
                                        WRITE16(e,a,v) : WRITE32(e,a,v)))

/* unsigned READ(int endianness, void *address) */
#define READ16(e,a) ((e) ? GET16BE(&(a)) : GET16LE(&(a)))
#define READ32(e,a) ((e) ? GET32BE(&(a)) : GET32LE(&(a)))
#define READ(e,a) ((sizeof(a) == sizeof(char)) ? \
                   GET8((CP_U8)&(a)) : ((sizeof(a) == sizeof(short)) ? \
                                       READ16(e,a) : READ32(e,a)))

/* void PWRITE(int endianness, void *address, unsigned value); */
#define PWRITE16(e,a,v) ((e) ? PUT16BE(a,v) : PUT16LE(a,v))
#define PWRITE32(e,a,v) ((e) ? PUT32BE(a,v) : PUT32LE(a,v))
#define PWRITE(e,a,v)   ((sizeof(v) == sizeof(char)) ? \
                         PUT8(a,v) : ((sizeof(v) == sizeof(short)) ? \
                                      PWRITE16(e,a,v) : PWRITE32(e,a,v)))

/* unsigned PREAD(int endianness, void *address) */
#define PREAD16(e,a) ((e) ? GET16BE(a) : GET16LE(a))
#define PREAD32(e,a) ((e) ? GET32BE(a) : GET32LE(a))
#define PREAD(e,a) ((sizeof(*(a)) == sizeof(char)) ? \
                    GET8((CP_U8)a) : ((sizeof(*(a)) == sizeof(short)) ? \
                                     PREAD16(e,a) : PREAD32(e,a)))

#endif /* !defined(angel_endian_h) */

/* EOF angel_endian.h */
import gdb-1999-11-01 snapshot 1999-11-02 05:44:47 +01:00			`/*`
			`* Copyright (C) 1995 Advanced RISC Machines Limited. All rights reserved.`
			`*`
			`* This software may be freely used, copied, modified, and distributed`
			`* provided that the above copyright notice is preserved in all copies of the`
			`* software.`
			`*/`

			`/* --C--`
			`*`
			`* $Revision$`
			`* $Date$`
			`*`
			`*`
			`* angel_endian.h - target endianness independent read/write primitives.`
			`*/`

			`#ifndef angel_endian_h`
			`#define angel_endian_h`

			`/*`
			`* The endianness of the data being processed needs to be known, but`
			`* the host endianness is not required (since the data is constructed`
			`* using bytes). At the moment these are provided as macros. This`
			`* gives the compiler freedom in optimising individual calls. However,`
			`* if space is at a premium then functions should be provided.`
			`*`
			`* NOTE: These macros assume that the data has been packed in the same format`
			`* as the packing on the build host. If this is not the case then`
			`* the wrong addresses could be used when dealing with structures.`
			`*`
			`*/`

			`/*`
			`* For all the following routines the target endianness is defined by the`
			`* following boolean definitions.`
			`*/`
			`#define BE (1 == 1) /* TRUE : big-endian */`
			`#define LE (1 == 0) /* FALSE : little-endian */`

			`/*`
			`* The following type definitions are used by the endianness converting`
			`* macros.`
			`*/`
			`typedef unsigned char U8;`
			`typedef U8 *P_U8;`
			`typedef const U8 *CP_U8;`

			`typedef unsigned short U16;`
			`typedef U16 *P_U16;`

			`typedef unsigned int U32;`
			`typedef U32 *P_U32;`

			`/*`
			`* If the endianness of the host and target are known (fixed) and the same`
			`* then the following macro definitions can be used. These just directly copy`
			`* the data.`
			`*`
			`* #define READ(e,a) (a)`
			`* #define WRITE(e,a,v) ((a) = (v))`
			`* #define PREAD(e,a) (a)`
			`* #define PWRITE(e,a,v) (*(a) = (v))`
			`*/`

			`/*`
			`* These macros assume that a byte (char) is 8bits in size, and that the`
			`* endianness is not important when reading or writing bytes.`
			`*/`
			`#define PUT8(a,v) (*((P_U8)(a)) = (U8)(v))`
			`#define PUT16LE(a,v) (PUT8(a,((v) & 0xFF)), \`
			`PUT8((((P_U8)(a)) + sizeof(char)),((v) >> 8)))`
			`#define PUT16BE(a,v) (PUT8(a,((v) >> 8)), \`
			`PUT8((((P_U8)(a)) + sizeof(char)),((v) & 0xFF)))`
			`#define PUT32LE(a,v) (PUT16LE(a,v), \`
			`PUT16LE((((P_U8)(a)) + sizeof(short)),((v) >> 16)))`
			`#define PUT32BE(a,v) (PUT16BE(a,((v) >> 16)), \`
			`PUT16BE((((P_U8)(a)) + sizeof(short)),v))`

			`#define GET8(a) (*((CP_U8)(a)))`
			`#define GET16LE(a) (GET8(a) \| (((U16)GET8(((CP_U8)(a)) + sizeof(char))) << 8))`
			`#define GET16BE(a) ((((U16)GET8(a)) << 8) \| GET8(((CP_U8)(a)) + sizeof(char)))`
			`#define GET32LE(a) (GET16LE(a) \| \`
			`(((U32)GET16LE(((CP_U8)(a)) + sizeof(short))) << 16))`
			`#define GET32BE(a) ((((U32)GET16BE(a)) << 16) \| \`
			`GET16BE(((CP_U8)(a)) + sizeof(short)))`

			`/*`
			`* These macros simplify the code in respect to reading and writing the`
			`* correct size data when dealing with endianness. "e" is TRUE if we are`
			`* dealing with big-endian data, FALSE if we are dealing with little-endian.`
			`*/`

			`/* void WRITE(int endianness, void address, unsigned value); /`

			`#define WRITE16(e,a,v) ((e) ? PUT16BE(&(a),v) : PUT16LE(&(a),v))`
			`#define WRITE32(e,a,v) ((e) ? PUT32BE(&(a),v) : PUT32LE(&(a),v))`
			`#define WRITE(e,a,v) ((sizeof(v) == sizeof(char)) ? \`
			`PUT8(&(a),v) : ((sizeof(v) == sizeof(short)) ? \`
			`WRITE16(e,a,v) : WRITE32(e,a,v)))`

			`/* unsigned READ(int endianness, void address) /`
			`#define READ16(e,a) ((e) ? GET16BE(&(a)) : GET16LE(&(a)))`
			`#define READ32(e,a) ((e) ? GET32BE(&(a)) : GET32LE(&(a)))`
			`#define READ(e,a) ((sizeof(a) == sizeof(char)) ? \`
			`GET8((CP_U8)&(a)) : ((sizeof(a) == sizeof(short)) ? \`
			`READ16(e,a) : READ32(e,a)))`

			`/* void PWRITE(int endianness, void address, unsigned value); /`
			`#define PWRITE16(e,a,v) ((e) ? PUT16BE(a,v) : PUT16LE(a,v))`
			`#define PWRITE32(e,a,v) ((e) ? PUT32BE(a,v) : PUT32LE(a,v))`
			`#define PWRITE(e,a,v) ((sizeof(v) == sizeof(char)) ? \`
			`PUT8(a,v) : ((sizeof(v) == sizeof(short)) ? \`
			`PWRITE16(e,a,v) : PWRITE32(e,a,v)))`

			`/* unsigned PREAD(int endianness, void address) /`
			`#define PREAD16(e,a) ((e) ? GET16BE(a) : GET16LE(a))`
			`#define PREAD32(e,a) ((e) ? GET32BE(a) : GET32LE(a))`
			`#define PREAD(e,a) ((sizeof(*(a)) == sizeof(char)) ? \`
			`GET8((CP_U8)a) : ((sizeof(*(a)) == sizeof(short)) ? \`
			`PREAD16(e,a) : PREAD32(e,a)))`

			`#endif /* !defined(angel_endian_h) */`

			`/* EOF angel_endian.h */`