libdw/memory-access.h - platform/external/elfutils - Gitiles

 /* Unaligned memory access functionality.
    Copyright (C) 2000, 2001, 2002, 2003, 2004, 2005 Red Hat, Inc.
    Written by Ulrich Drepper <drepper@redhat.com>, 2001.

    This program is Open Source software; you can redistribute it and/or
    modify it under the terms of the Open Software License version 1.0 as
    published by the Open Source Initiative.

    You should have received a copy of the Open Software License along
    with this program; if not, you may obtain a copy of the Open Software
    License version 1.0 from http://www.opensource.org/licenses/osl.php or
    by writing the Open Source Initiative c/o Lawrence Rosen, Esq.,
    3001 King Ranch Road, Ukiah, CA 95482.   */

 #ifndef _MEMORY_ACCESS_H
 #define _MEMORY_ACCESS_H 1

 #include <byteswap.h>
 #include <limits.h>
 #include <stdint.h>


 /* Number decoding macros.  See 7.6 Variable Length Data.  */

 #define get_uleb128_step(var, addr, nth, break)				      \
     __b = *(addr)++;							      \
     var |= (uintmax_t) (__b & 0x7f) << (nth * 7);			      \
     if (likely ((__b & 0x80) == 0))					      \
       break

 #define get_uleb128(var, addr)						      \
   do {									      \
     unsigned char __b;							      \
     var = 0;								      \
     get_uleb128_step (var, addr, 0, break);				      \
     var = __libdw_get_uleb128 (var, 1, &(addr));			      \
   } while (0)

 #define get_uleb128_rest_return(var, i, addrp)				      \
   do {									      \
     for (; i < 10; ++i)							      \
       {									      \
 	get_uleb128_step (var, *addrp, i, return var);			      \
       }									      \
     /* Other implementations set VALUE to UINT_MAX in this		      \
        case.  So we better do this as well.  */				      \
     return UINT64_MAX;							      \
   } while (0)

 /* The signed case is similar, but we sign-extend the result.  */

 #define get_sleb128_step(var, addr, nth, break)				      \
     __b = *(addr)++;							      \
     _v |= (uint64_t) (__b & 0x7f) << (nth * 7);				      \
     if (likely ((__b & 0x80) == 0))					      \
       {									      \
 	var = (_v << (64 - (nth * 7) - 7) >> (64 - (nth * 7) - 7));	      \
         break;					 			      \
       }									      \
     else do {} while (0)

 #define get_sleb128(var, addr)						      \
   do {									      \
     unsigned char __b;							      \
     int64_t _v = 0;							      \
     get_sleb128_step (var, addr, 0, break);				      \
     var = __libdw_get_sleb128 (_v, 1, &(addr));				      \
   } while (0)

 #define get_sleb128_rest_return(var, i, addrp)				      \
   do {									      \
     for (; i < 9; ++i)							      \
       {									      \
 	get_sleb128_step (var, *addrp, i, return var);			      \
       }									      \
     /* Other implementations set VALUE to INT_MAX in this		      \
        case.  So we better do this as well.  */				      \
     return INT64_MAX;							      \
   } while (0)

 #ifdef IS_LIBDW
 extern uint64_t __libdw_get_uleb128 (uint64_t acc, unsigned int i,
 				     const unsigned char **addrp)
      internal_function attribute_hidden;
 extern int64_t __libdw_get_sleb128 (int64_t acc, unsigned int i,
 				    const unsigned char **addrp)
      internal_function attribute_hidden;
 #else
 static uint64_t
 __attribute__ ((unused))
 __libdw_get_uleb128 (uint64_t acc, unsigned int i, const unsigned char **addrp)
 {
   unsigned char __b;
   get_uleb128_rest_return (acc, i, addrp);
 }
 static int64_t
 __attribute__ ((unused))
 __libdw_get_sleb128 (int64_t acc, unsigned int i, const unsigned char **addrp)
 {
   unsigned char __b;
   int64_t _v = acc;
   get_sleb128_rest_return (acc, i, addrp);
 }
 #endif


 /* We use simple memory access functions in case the hardware allows it.
    The caller has to make sure we don't have alias problems.  */
 #if ALLOW_UNALIGNED

 # define read_2ubyte_unaligned(Dbg, Addr) \
   (unlikely ((Dbg)->other_byte_order)					      \
    ? bswap_16 (*((const uint16_t *) (Addr)))				      \
    : *((const uint16_t *) (Addr)))
 # define read_2sbyte_unaligned(Dbg, Addr) \
   (unlikely ((Dbg)->other_byte_order)					      \
    ? (int16_t) bswap_16 (*((const int16_t *) (Addr)))			      \
    : *((const int16_t *) (Addr)))

 # define read_4ubyte_unaligned_noncvt(Addr) \
    *((const uint32_t *) (Addr))
 # define read_4ubyte_unaligned(Dbg, Addr) \
   (unlikely ((Dbg)->other_byte_order)					      \
    ? bswap_32 (*((const uint32_t *) (Addr)))				      \
    : *((const uint32_t *) (Addr)))
 # define read_4sbyte_unaligned(Dbg, Addr) \
   (unlikely ((Dbg)->other_byte_order)					      \
    ? (int32_t) bswap_32 (*((const int32_t *) (Addr)))			      \
    : *((const int32_t *) (Addr)))

 # define read_8ubyte_unaligned(Dbg, Addr) \
   (unlikely ((Dbg)->other_byte_order)					      \
    ? bswap_64 (*((const uint64_t *) (Addr)))				      \
    : *((const uint64_t *) (Addr)))
 # define read_8sbyte_unaligned(Dbg, Addr) \
   (unlikely ((Dbg)->other_byte_order)					      \
    ? (int64_t) bswap_64 (*((const int64_t *) (Addr)))			      \
    : *((const int64_t *) (Addr)))

 #else

 union unaligned
   {
     void *p;
     uint16_t u2;
     uint32_t u4;
     uint64_t u8;
     int16_t s2;
     int32_t s4;
     int64_t s8;
   } __attribute__ ((packed));

 static inline uint16_t
 read_2ubyte_unaligned (Dwarf *dbg, const void *p)
 {
   const union unaligned *up = p;
   if (dbg->other_byte_order)
     return bswap_16 (up->u2);
   return up->u2;
 }
 static inline int16_t
 read_2sbyte_unaligned (Dwarf *dbg, const void *p)
 {
   const union unaligned *up = p;
   if (dbg->other_byte_order)
     return (int16_t) bswap_16 (up->u2);
   return up->s2;
 }

 static inline uint32_t
 read_4ubyte_unaligned_noncvt (const void *p)
 {
   const union unaligned *up = p;
   return up->u4;
 }
 static inline uint32_t
 read_4ubyte_unaligned (Dwarf *dbg, const void *p)
 {
   const union unaligned *up = p;
   if (dbg->other_byte_order)
     return bswap_32 (up->u4);
   return up->u4;
 }
 static inline int32_t
 read_4sbyte_unaligned (Dwarf *dbg, const void *p)
 {
   const union unaligned *up = p;
   if (dbg->other_byte_order)
     return (int32_t) bswap_32 (up->u4);
   return up->s4;
 }

 static inline uint64_t
 read_8ubyte_unaligned (Dwarf *dbg, const void *p)
 {
   const union unaligned *up = p;
   if (dbg->other_byte_order)
     return bswap_64 (up->u8);
   return up->u8;
 }
 static inline int64_t
 read_8sbyte_unaligned (Dwarf *dbg, const void *p)
 {
   const union unaligned *up = p;
   if (dbg->other_byte_order)
     return (int64_t) bswap_64 (up->u8);
   return up->s8;
 }

 #endif	/* allow unaligned */


 #define read_2ubyte_unaligned_inc(Dbg, Addr) \
   ({ uint16_t t_ = read_2ubyte_unaligned (Dbg, Addr);			      \
      Addr = (__typeof (Addr)) (((uintptr_t) (Addr)) + 2);		      \
      t_; })
 #define read_2sbyte_unaligned_inc(Dbg, Addr) \
   ({ int16_t t_ = read_2sbyte_unaligned (Dbg, Addr);			      \
      Addr = (__typeof (Addr)) (((uintptr_t) (Addr)) + 2);		      \
      t_; })

 #define read_4ubyte_unaligned_inc(Dbg, Addr) \
   ({ uint32_t t_ = read_4ubyte_unaligned (Dbg, Addr);			      \
      Addr = (__typeof (Addr)) (((uintptr_t) (Addr)) + 4);		      \
      t_; })
 #define read_4sbyte_unaligned_inc(Dbg, Addr) \
   ({ int32_t t_ = read_4sbyte_unaligned (Dbg, Addr);			      \
      Addr = (__typeof (Addr)) (((uintptr_t) (Addr)) + 4);		      \
      t_; })

 #define read_8ubyte_unaligned_inc(Dbg, Addr) \
   ({ uint64_t t_ = read_8ubyte_unaligned (Dbg, Addr);			      \
      Addr = (__typeof (Addr)) (((uintptr_t) (Addr)) + 8);		      \
      t_; })
 #define read_8sbyte_unaligned_inc(Dbg, Addr) \
   ({ int64_t t_ = read_8sbyte_unaligned (Dbg, Addr);			      \
      Addr = (__typeof (Addr)) (((uintptr_t) (Addr)) + 8);		      \
      t_; })

 #endif	/* memory-access.h */
	/* Unaligned memory access functionality.
	Copyright (C) 2000, 2001, 2002, 2003, 2004, 2005 Red Hat, Inc.
	Written by Ulrich Drepper <drepper@redhat.com>, 2001.

	This program is Open Source software; you can redistribute it and/or
	modify it under the terms of the Open Software License version 1.0 as
	published by the Open Source Initiative.

	You should have received a copy of the Open Software License along
	with this program; if not, you may obtain a copy of the Open Software
	License version 1.0 from http://www.opensource.org/licenses/osl.php or
	by writing the Open Source Initiative c/o Lawrence Rosen, Esq.,
	3001 King Ranch Road, Ukiah, CA 95482. */

	#ifndef _MEMORY_ACCESS_H
	#define _MEMORY_ACCESS_H 1

	#include <byteswap.h>
	#include <limits.h>
	#include <stdint.h>


	/* Number decoding macros. See 7.6 Variable Length Data. */

	#define get_uleb128_step(var, addr, nth, break) \
	__b = *(addr)++; \
	var \|= (uintmax_t) (__b & 0x7f) << (nth * 7); \
	if (likely ((__b & 0x80) == 0)) \
	break

	#define get_uleb128(var, addr) \
	do { \
	unsigned char __b; \
	var = 0; \
	get_uleb128_step (var, addr, 0, break); \
	var = __libdw_get_uleb128 (var, 1, &(addr)); \
	} while (0)

	#define get_uleb128_rest_return(var, i, addrp) \
	do { \
	for (; i < 10; ++i) \
	{ \
	get_uleb128_step (var, *addrp, i, return var); \
	} \
	/* Other implementations set VALUE to UINT_MAX in this \
	case. So we better do this as well. */ \
	return UINT64_MAX; \
	} while (0)

	/* The signed case is similar, but we sign-extend the result. */

	#define get_sleb128_step(var, addr, nth, break) \
	__b = *(addr)++; \
	_v \|= (uint64_t) (__b & 0x7f) << (nth * 7); \
	if (likely ((__b & 0x80) == 0)) \
	{ \
	var = (_v << (64 - (nth * 7) - 7) >> (64 - (nth * 7) - 7)); \
	break; \
	} \
	else do {} while (0)

	#define get_sleb128(var, addr) \
	do { \
	unsigned char __b; \
	int64_t _v = 0; \
	get_sleb128_step (var, addr, 0, break); \
	var = __libdw_get_sleb128 (_v, 1, &(addr)); \
	} while (0)

	#define get_sleb128_rest_return(var, i, addrp) \
	do { \
	for (; i < 9; ++i) \
	{ \
	get_sleb128_step (var, *addrp, i, return var); \
	} \
	/* Other implementations set VALUE to INT_MAX in this \
	case. So we better do this as well. */ \
	return INT64_MAX; \
	} while (0)

	#ifdef IS_LIBDW
	extern uint64_t __libdw_get_uleb128 (uint64_t acc, unsigned int i,
	const unsigned char **addrp)
	internal_function attribute_hidden;
	extern int64_t __libdw_get_sleb128 (int64_t acc, unsigned int i,
	const unsigned char **addrp)
	internal_function attribute_hidden;
	#else
	static uint64_t
	__attribute__ ((unused))
	__libdw_get_uleb128 (uint64_t acc, unsigned int i, const unsigned char **addrp)
	{
	unsigned char __b;
	get_uleb128_rest_return (acc, i, addrp);
	}
	static int64_t
	__attribute__ ((unused))
	__libdw_get_sleb128 (int64_t acc, unsigned int i, const unsigned char **addrp)
	{
	unsigned char __b;
	int64_t _v = acc;
	get_sleb128_rest_return (acc, i, addrp);
	}
	#endif


	/* We use simple memory access functions in case the hardware allows it.
	The caller has to make sure we don't have alias problems. */
	#if ALLOW_UNALIGNED

	# define read_2ubyte_unaligned(Dbg, Addr) \
	(unlikely ((Dbg)->other_byte_order) \
	? bswap_16 (((const uint16_t ) (Addr))) \
	: ((const uint16_t ) (Addr)))
	# define read_2sbyte_unaligned(Dbg, Addr) \
	(unlikely ((Dbg)->other_byte_order) \
	? (int16_t) bswap_16 (((const int16_t ) (Addr))) \
	: ((const int16_t ) (Addr)))

	# define read_4ubyte_unaligned_noncvt(Addr) \
	((const uint32_t ) (Addr))
	# define read_4ubyte_unaligned(Dbg, Addr) \
	(unlikely ((Dbg)->other_byte_order) \
	? bswap_32 (((const uint32_t ) (Addr))) \
	: ((const uint32_t ) (Addr)))
	# define read_4sbyte_unaligned(Dbg, Addr) \
	(unlikely ((Dbg)->other_byte_order) \
	? (int32_t) bswap_32 (((const int32_t ) (Addr))) \
	: ((const int32_t ) (Addr)))

	# define read_8ubyte_unaligned(Dbg, Addr) \
	(unlikely ((Dbg)->other_byte_order) \
	? bswap_64 (((const uint64_t ) (Addr))) \
	: ((const uint64_t ) (Addr)))
	# define read_8sbyte_unaligned(Dbg, Addr) \
	(unlikely ((Dbg)->other_byte_order) \
	? (int64_t) bswap_64 (((const int64_t ) (Addr))) \
	: ((const int64_t ) (Addr)))

	#else

	union unaligned
	{
	void *p;
	uint16_t u2;
	uint32_t u4;
	uint64_t u8;
	int16_t s2;
	int32_t s4;
	int64_t s8;
	} __attribute__ ((packed));

	static inline uint16_t
	read_2ubyte_unaligned (Dwarf dbg, const void p)
	{
	const union unaligned *up = p;
	if (dbg->other_byte_order)
	return bswap_16 (up->u2);
	return up->u2;
	}
	static inline int16_t
	read_2sbyte_unaligned (Dwarf dbg, const void p)
	{
	const union unaligned *up = p;
	if (dbg->other_byte_order)
	return (int16_t) bswap_16 (up->u2);
	return up->s2;
	}

	static inline uint32_t
	read_4ubyte_unaligned_noncvt (const void *p)
	{
	const union unaligned *up = p;
	return up->u4;
	}
	static inline uint32_t
	read_4ubyte_unaligned (Dwarf dbg, const void p)
	{
	const union unaligned *up = p;
	if (dbg->other_byte_order)
	return bswap_32 (up->u4);
	return up->u4;
	}
	static inline int32_t
	read_4sbyte_unaligned (Dwarf dbg, const void p)
	{
	const union unaligned *up = p;
	if (dbg->other_byte_order)
	return (int32_t) bswap_32 (up->u4);
	return up->s4;
	}

	static inline uint64_t
	read_8ubyte_unaligned (Dwarf dbg, const void p)
	{
	const union unaligned *up = p;
	if (dbg->other_byte_order)
	return bswap_64 (up->u8);
	return up->u8;
	}
	static inline int64_t
	read_8sbyte_unaligned (Dwarf dbg, const void p)
	{
	const union unaligned *up = p;
	if (dbg->other_byte_order)
	return (int64_t) bswap_64 (up->u8);
	return up->s8;
	}

	#endif /* allow unaligned */


	#define read_2ubyte_unaligned_inc(Dbg, Addr) \
	({ uint16_t t_ = read_2ubyte_unaligned (Dbg, Addr); \
	Addr = (__typeof (Addr)) (((uintptr_t) (Addr)) + 2); \
	t_; })
	#define read_2sbyte_unaligned_inc(Dbg, Addr) \
	({ int16_t t_ = read_2sbyte_unaligned (Dbg, Addr); \
	Addr = (__typeof (Addr)) (((uintptr_t) (Addr)) + 2); \
	t_; })

	#define read_4ubyte_unaligned_inc(Dbg, Addr) \
	({ uint32_t t_ = read_4ubyte_unaligned (Dbg, Addr); \
	Addr = (__typeof (Addr)) (((uintptr_t) (Addr)) + 4); \
	t_; })
	#define read_4sbyte_unaligned_inc(Dbg, Addr) \
	({ int32_t t_ = read_4sbyte_unaligned (Dbg, Addr); \
	Addr = (__typeof (Addr)) (((uintptr_t) (Addr)) + 4); \
	t_; })

	#define read_8ubyte_unaligned_inc(Dbg, Addr) \
	({ uint64_t t_ = read_8ubyte_unaligned (Dbg, Addr); \
	Addr = (__typeof (Addr)) (((uintptr_t) (Addr)) + 8); \
	t_; })
	#define read_8sbyte_unaligned_inc(Dbg, Addr) \
	({ int64_t t_ = read_8sbyte_unaligned (Dbg, Addr); \
	Addr = (__typeof (Addr)) (((uintptr_t) (Addr)) + 8); \
	t_; })

	#endif /* memory-access.h */