sim/common/sim-endian.h - binutils-gdb - Git at Google

 /* The common simulator framework for GDB, the GNU Debugger.

    Copyright 2002-2021 Free Software Foundation, Inc.

    Contributed by Andrew Cagney and Red Hat.

    This file is part of GDB.

    This program is free software; you can redistribute it and/or modify
    it under the terms of the GNU General Public License as published by
    the Free Software Foundation; either version 3 of the License, or
    (at your option) any later version.

    This program is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    GNU General Public License for more details.

    You should have received a copy of the GNU General Public License
    along with this program.  If not, see <http://www.gnu.org/licenses/>.  */


 #ifndef SIM_ENDIAN_H
 #define SIM_ENDIAN_H

 #include "bfd.h"

 /* C byte conversion functions */

 INLINE_SIM_ENDIAN(unsigned_1) endian_h2t_1(unsigned_1 x);
 INLINE_SIM_ENDIAN(unsigned_2) endian_h2t_2(unsigned_2 x);
 INLINE_SIM_ENDIAN(unsigned_4) endian_h2t_4(unsigned_4 x);
 INLINE_SIM_ENDIAN(unsigned_8) endian_h2t_8(unsigned_8 x);
 INLINE_SIM_ENDIAN(unsigned_16) endian_h2t_16(unsigned_16 x);

 INLINE_SIM_ENDIAN(unsigned_1) endian_t2h_1(unsigned_1 x);
 INLINE_SIM_ENDIAN(unsigned_2) endian_t2h_2(unsigned_2 x);
 INLINE_SIM_ENDIAN(unsigned_4) endian_t2h_4(unsigned_4 x);
 INLINE_SIM_ENDIAN(unsigned_8) endian_t2h_8(unsigned_8 x);
 INLINE_SIM_ENDIAN(unsigned_16) endian_t2h_16(unsigned_16 x);

 INLINE_SIM_ENDIAN(unsigned_1) swap_1(unsigned_1 x);
 INLINE_SIM_ENDIAN(unsigned_2) swap_2(unsigned_2 x);
 INLINE_SIM_ENDIAN(unsigned_4) swap_4(unsigned_4 x);
 INLINE_SIM_ENDIAN(unsigned_8) swap_8(unsigned_8 x);
 INLINE_SIM_ENDIAN(unsigned_16) swap_16(unsigned_16 x);

 INLINE_SIM_ENDIAN(unsigned_1) endian_h2be_1(unsigned_1 x);
 INLINE_SIM_ENDIAN(unsigned_2) endian_h2be_2(unsigned_2 x);
 INLINE_SIM_ENDIAN(unsigned_4) endian_h2be_4(unsigned_4 x);
 INLINE_SIM_ENDIAN(unsigned_8) endian_h2be_8(unsigned_8 x);
 INLINE_SIM_ENDIAN(unsigned_16) endian_h2be_16(unsigned_16 x);

 INLINE_SIM_ENDIAN(unsigned_1) endian_be2h_1(unsigned_1 x);
 INLINE_SIM_ENDIAN(unsigned_2) endian_be2h_2(unsigned_2 x);
 INLINE_SIM_ENDIAN(unsigned_4) endian_be2h_4(unsigned_4 x);
 INLINE_SIM_ENDIAN(unsigned_8) endian_be2h_8(unsigned_8 x);
 INLINE_SIM_ENDIAN(unsigned_16) endian_be2h_16(unsigned_16 x);

 INLINE_SIM_ENDIAN(unsigned_1) endian_h2le_1(unsigned_1 x);
 INLINE_SIM_ENDIAN(unsigned_2) endian_h2le_2(unsigned_2 x);
 INLINE_SIM_ENDIAN(unsigned_4) endian_h2le_4(unsigned_4 x);
 INLINE_SIM_ENDIAN(unsigned_8) endian_h2le_8(unsigned_8 x);
 INLINE_SIM_ENDIAN(unsigned_16) endian_h2le_16(unsigned_16 x);

 INLINE_SIM_ENDIAN(unsigned_1) endian_le2h_1(unsigned_1 x);
 INLINE_SIM_ENDIAN(unsigned_2) endian_le2h_2(unsigned_2 x);
 INLINE_SIM_ENDIAN(unsigned_4) endian_le2h_4(unsigned_4 x);
 INLINE_SIM_ENDIAN(unsigned_8) endian_le2h_8(unsigned_8 x);
 INLINE_SIM_ENDIAN(unsigned_16) endian_le2h_16(unsigned_16 x);

 INLINE_SIM_ENDIAN(void*) offset_1(unsigned_1 *x, unsigned ws, unsigned w);
 INLINE_SIM_ENDIAN(void*) offset_2(unsigned_2 *x, unsigned ws, unsigned w);
 INLINE_SIM_ENDIAN(void*) offset_4(unsigned_4 *x, unsigned ws, unsigned w);
 INLINE_SIM_ENDIAN(void*) offset_8(unsigned_8 *x, unsigned ws, unsigned w);
 INLINE_SIM_ENDIAN(void*) offset_16(unsigned_16 *x, unsigned ws, unsigned w);

 INLINE_SIM_ENDIAN(unsigned_16) sim_endian_join_16 (unsigned_8 h, unsigned_8 l);
 INLINE_SIM_ENDIAN(unsigned_8) sim_endian_split_16 (unsigned_16 word, int w);


 /* SWAP */

 #define SWAP_1 swap_1
 #define SWAP_2 swap_2
 #define SWAP_4 swap_4
 #define SWAP_8 swap_8
 #define SWAP_16 swap_16


 /* HOST to BE */

 #define H2BE_1 endian_h2be_1
 #define H2BE_2 endian_h2be_2
 #define H2BE_4 endian_h2be_4
 #define H2BE_8 endian_h2be_8
 #define H2BE_16 endian_h2be_16
 #define BE2H_1 endian_be2h_1
 #define BE2H_2 endian_be2h_2
 #define BE2H_4 endian_be2h_4
 #define BE2H_8 endian_be2h_8
 #define BE2H_16 endian_be2h_16


 /* HOST to LE */

 #define H2LE_1 endian_h2le_1
 #define H2LE_2 endian_h2le_2
 #define H2LE_4 endian_h2le_4
 #define H2LE_8 endian_h2le_8
 #define H2LE_16 endian_h2le_16
 #define LE2H_1 endian_le2h_1
 #define LE2H_2 endian_le2h_2
 #define LE2H_4 endian_le2h_4
 #define LE2H_8 endian_le2h_8
 #define LE2H_16 endian_le2h_16


 /* HOST to TARGET */

 #define H2T_1 endian_h2t_1
 #define H2T_2 endian_h2t_2
 #define H2T_4 endian_h2t_4
 #define H2T_8 endian_h2t_8
 #define H2T_16 endian_h2t_16
 #define T2H_1 endian_t2h_1
 #define T2H_2 endian_t2h_2
 #define T2H_4 endian_t2h_4
 #define T2H_8 endian_t2h_8
 #define T2H_16 endian_t2h_16


 /* CONVERT IN PLACE

    These macros, given an argument of unknown size, swap its value in
    place if a host/target conversion is required. */

 #define H2T(VARIABLE) \
 do { \
   void *vp = &(VARIABLE); \
   switch (sizeof (VARIABLE)) { \
   case 1: *(unsigned_1*)vp = H2T_1(*(unsigned_1*)vp); break; \
   case 2: *(unsigned_2*)vp = H2T_2(*(unsigned_2*)vp); break; \
   case 4: *(unsigned_4*)vp = H2T_4(*(unsigned_4*)vp); break; \
   case 8: *(unsigned_8*)vp = H2T_8(*(unsigned_8*)vp); break; \
   case 16: *(unsigned_16*)vp = H2T_16(*(unsigned_16*)vp); break; \
   } \
 } while (0)

 #define T2H(VARIABLE) \
 do { \
   switch (sizeof(VARIABLE)) { \
   case 1: VARIABLE = T2H_1(VARIABLE); break; \
   case 2: VARIABLE = T2H_2(VARIABLE); break; \
   case 4: VARIABLE = T2H_4(VARIABLE); break; \
   case 8: VARIABLE = T2H_8(VARIABLE); break; \
   /*case 16: VARIABLE = T2H_16(VARIABLE); break;*/ \
   } \
 } while (0)

 #define SWAP(VARIABLE) \
 do { \
   switch (sizeof(VARIABLE)) { \
   case 1: VARIABLE = SWAP_1(VARIABLE); break; \
   case 2: VARIABLE = SWAP_2(VARIABLE); break; \
   case 4: VARIABLE = SWAP_4(VARIABLE); break; \
   case 8: VARIABLE = SWAP_8(VARIABLE); break; \
   /*case 16: VARIABLE = SWAP_16(VARIABLE); break;*/ \
   } \
 } while (0)

 #define H2BE(VARIABLE) \
 do { \
   switch (sizeof(VARIABLE)) { \
   case 1: VARIABLE = H2BE_1(VARIABLE); break; \
   case 2: VARIABLE = H2BE_2(VARIABLE); break; \
   case 4: VARIABLE = H2BE_4(VARIABLE); break; \
   case 8: VARIABLE = H2BE_8(VARIABLE); break; \
   /*case 16: VARIABLE = H2BE_16(VARIABLE); break;*/ \
   } \
 } while (0)

 #define BE2H(VARIABLE) \
 do { \
   switch (sizeof(VARIABLE)) { \
   case 1: VARIABLE = BE2H_1(VARIABLE); break; \
   case 2: VARIABLE = BE2H_2(VARIABLE); break; \
   case 4: VARIABLE = BE2H_4(VARIABLE); break; \
   case 8: VARIABLE = BE2H_8(VARIABLE); break; \
   /*case 16: VARIABLE = BE2H_16(VARIABLE); break;*/ \
   } \
 } while (0)

 #define H2LE(VARIABLE) \
 do { \
   switch (sizeof(VARIABLE)) { \
   case 1: VARIABLE = H2LE_1(VARIABLE); break; \
   case 2: VARIABLE = H2LE_2(VARIABLE); break; \
   case 4: VARIABLE = H2LE_4(VARIABLE); break; \
   case 8: VARIABLE = H2LE_8(VARIABLE); break; \
   /*case 16: VARIABLE = H2LE_16(VARIABLE); break;*/ \
   } \
 } while (0)

 #define LE2H(VARIABLE) \
 do { \
   switch (sizeof(VARIABLE)) { \
   case 1: VARIABLE = LE2H_1(VARIABLE); break; \
   case 2: VARIABLE = LE2H_2(VARIABLE); break; \
   case 4: VARIABLE = LE2H_4(VARIABLE); break; \
   case 8: VARIABLE = LE2H_8(VARIABLE); break; \
   /*case 16: VARIABLE = LE2H_16(VARIABLE); break;*/ \
   } \
 } while (0)


 /* TARGET WORD:

    Byte swap a quantity the size of the targets word */

 #if (WITH_TARGET_WORD_BITSIZE == 64)
 #define H2T_word H2T_8
 #define T2H_word T2H_8
 #define H2BE_word H2BE_8
 #define BE2H_word BE2H_8
 #define H2LE_word H2LE_8
 #define LE2H_word LE2H_8
 #define SWAP_word SWAP_8
 #endif
 #if (WITH_TARGET_WORD_BITSIZE == 32)
 #define H2T_word H2T_4
 #define T2H_word T2H_4
 #define H2BE_word H2BE_4
 #define BE2H_word BE2H_4
 #define H2LE_word H2LE_4
 #define LE2H_word LE2H_4
 #define SWAP_word SWAP_4
 #endif


 /* TARGET CELL:

    Byte swap a quantity the size of the targets IEEE 1275 memory cell */

 #define H2T_cell H2T_4
 #define T2H_cell T2H_4
 #define H2BE_cell H2BE_4
 #define BE2H_cell BE2H_4
 #define H2LE_cell H2LE_4
 #define LE2H_cell LE2H_4
 #define SWAP_cell SWAP_4


 /* HOST Offsets:

    Address of high/low sub-word within a host word quantity.

    Address of sub-word N within a host word quantity.  NOTE: Numbering
    is BIG endian always. */

 #define AH1_2(X) (unsigned_1*)offset_2((X), 1, 0)
 #define AL1_2(X) (unsigned_1*)offset_2((X), 1, 1)

 #define AH2_4(X) (unsigned_2*)offset_4((X), 2, 0)
 #define AL2_4(X) (unsigned_2*)offset_4((X), 2, 1)

 #define AH4_8(X) (unsigned_4*)offset_8((X), 4, 0)
 #define AL4_8(X) (unsigned_4*)offset_8((X), 4, 1)

 #define AH8_16(X) (unsigned_8*)offset_16((X), 8, 0)
 #define AL8_16(X) (unsigned_8*)offset_16((X), 8, 1)

 #if (WITH_TARGET_WORD_BITSIZE == 64)
 #define AH_word(X) AH4_8(X)
 #define AL_word(X) AL4_8(X)
 #endif
 #if (WITH_TARGET_WORD_BITSIZE == 32)
 #define AH_word(X) AH2_4(X)
 #define AL_word(X) AL2_4(X)
 #endif


 #define A1_2(X,N) (unsigned_1*)offset_2((X), 1, (N))

 #define A1_4(X,N) (unsigned_1*)offset_4((X), 1, (N))
 #define A2_4(X,N) (unsigned_2*)offset_4((X), 2, (N))

 #define A1_8(X,N) (unsigned_1*)offset_8((X), 1, (N))
 #define A2_8(X,N) (unsigned_2*)offset_8((X), 2, (N))
 #define A4_8(X,N) (unsigned_4*)offset_8((X), 4, (N))

 #define A1_16(X,N) (unsigned_1*)offset_16((X), 1, (N))
 #define A2_16(X,N) (unsigned_2*)offset_16((X), 2, (N))
 #define A4_16(X,N) (unsigned_4*)offset_16((X), 4, (N))
 #define A8_16(X,N) (unsigned_8*)offset_16((X), 8, (N))


 /* HOST Components:

    Value of sub-word within a host word quantity */

 #define VH1_2(X) ((unsigned_1)((unsigned_2)(X) >> 8))
 #define VL1_2(X) (unsigned_1)(X)

 #define VH2_4(X) ((unsigned_2)((unsigned_4)(X) >> 16))
 #define VL2_4(X) ((unsigned_2)(X))

 #define VH4_8(X) ((unsigned_4)((unsigned_8)(X) >> 32))
 #define VL4_8(X) ((unsigned_4)(X))

 #define VH8_16(X) (sim_endian_split_16 ((X), 0))
 #define VL8_16(X) (sim_endian_split_16 ((X), 1))

 #if (WITH_TARGET_WORD_BITSIZE == 64)
 #define VH_word(X) VH4_8(X)
 #define VL_word(X) VL4_8(X)
 #endif
 #if (WITH_TARGET_WORD_BITSIZE == 32)
 #define VH_word(X) VH2_4(X)
 #define VL_word(X) VL2_4(X)
 #endif


 #define V1_2(X,N) ((unsigned_1)((unsigned_2)(X) >> ( 8 * (1 - (N)))))

 #define V1_4(X,N) ((unsigned_1)((unsigned_4)(X) >> ( 8 * (3 - (N)))))
 #define V2_4(X,N) ((unsigned_2)((unsigned_4)(X) >> (16 * (1 - (N)))))

 #define V1_8(X,N) ((unsigned_1)((unsigned_8)(X) >> ( 8 * (7 - (N)))))
 #define V2_8(X,N) ((unsigned_2)((unsigned_8)(X) >> (16 * (3 - (N)))))
 #define V4_8(X,N) ((unsigned_4)((unsigned_8)(X) >> (32 * (1 - (N)))))

 #define V1_16(X,N) (*A1_16 (&(X),N))
 #define V2_16(X,N) (*A2_16 (&(X),N))
 #define V4_16(X,N) (*A4_16 (&(X),N))
 #define V8_16(X,N) (*A8_16 (&(X),N))


 /* Reverse - insert sub-word into word quantity */

 #define V2_H1(X) ((unsigned_2)(unsigned_1)(X) <<  8)
 #define V2_L1(X) ((unsigned_2)(unsigned_1)(X))

 #define V4_H2(X) ((unsigned_4)(unsigned_2)(X) << 16)
 #define V4_L2(X) ((unsigned_4)(unsigned_2)(X))

 #define V8_H4(X) ((unsigned_8)(unsigned_4)(X) << 32)
 #define V8_L4(X) ((unsigned_8)(unsigned_4)(X))

 #define V16_H8(X) ((unsigned_16)(unsigned_8)(X) << 64)
 #define V16_L8(X) ((unsigned_16)(unsigned_8)(X))


 #define V2_1(X,N) ((unsigned_2)(unsigned_1)(X) << ( 8 * (1 - (N))))

 #define V4_1(X,N) ((unsigned_4)(unsigned_1)(X) << ( 8 * (3 - (N))))
 #define V4_2(X,N) ((unsigned_4)(unsigned_2)(X) << (16 * (1 - (N))))

 #define V8_1(X,N) ((unsigned_8)(unsigned_1)(X) << ( 8 * (7 - (N))))
 #define V8_2(X,N) ((unsigned_8)(unsigned_2)(X) << (16 * (3 - (N))))
 #define V8_4(X,N) ((unsigned_8)(unsigned_4)(X) << (32 * (1 - (N))))

 #define V16_1(X,N) ((unsigned_16)(unsigned_1)(X) << ( 8 * (15 - (N))))
 #define V16_2(X,N) ((unsigned_16)(unsigned_2)(X) << (16 * (7 - (N))))
 #define V16_4(X,N) ((unsigned_16)(unsigned_4)(X) << (32 * (3 - (N))))
 #define V16_8(X,N) ((unsigned_16)(unsigned_8)(X) << (64 * (1 - (N))))


 /* Reverse - insert N sub-words into single word quantity */

 #define U2_1(I0,I1) (V2_1(I0,0) | V2_1(I1,1))
 #define U4_1(I0,I1,I2,I3) (V4_1(I0,0) | V4_1(I1,1) | V4_1(I2,2) | V4_1(I3,3))
 #define U8_1(I0,I1,I2,I3,I4,I5,I6,I7) \
 (V8_1(I0,0) | V8_1(I1,1) | V8_1(I2,2) | V8_1(I3,3) \
  | V8_1(I4,4) | V8_1(I5,5) | V8_1(I6,6) | V8_1(I7,7))
 #define U16_1(I0,I1,I2,I3,I4,I5,I6,I7,I8,I9,I10,I11,I12,I13,I14,I15) \
 (V16_1(I0,0) | V16_1(I1,1) | V16_1(I2,2) | V16_1(I3,3) \
  | V16_1(I4,4) | V16_1(I5,5) | V16_1(I6,6) | V16_1(I7,7) \
  | V16_1(I8,8) | V16_1(I9,9) | V16_1(I10,10) | V16_1(I11,11) \
  | V16_1(I12,12) | V16_1(I13,13) | V16_1(I14,14) | V16_1(I15,15))

 #define U4_2(I0,I1) (V4_2(I0,0) | V4_2(I1,1))
 #define U8_2(I0,I1,I2,I3) (V8_2(I0,0) | V8_2(I1,1) | V8_2(I2,2) | V8_2(I3,3))
 #define U16_2(I0,I1,I2,I3,I4,I5,I6,I7) \
 (V16_2(I0,0) | V16_2(I1,1) | V16_2(I2,2) | V16_2(I3,3) \
  | V16_2(I4,4) | V16_2(I5,5) | V16_2(I6,6) | V16_2(I7,7) )

 #define U8_4(I0,I1) (V8_4(I0,0) | V8_4(I1,1))
 #define U16_4(I0,I1,I2,I3) (V16_4(I0,0) | V16_4(I1,1) | V16_4(I2,2) | V16_4(I3,3))

 #define U16_8(I0,I1) (sim_endian_join_16 (I0, I1))


 #if (WITH_TARGET_WORD_BITSIZE == 64)
 #define Vword_H(X) V8_H4(X)
 #define Vword_L(X) V8_L4(X)
 #endif
 #if (WITH_TARGET_WORD_BITSIZE == 32)
 #define Vword_H(X) V4_H2(X)
 #define Vword_L(X) V4_L2(X)
 #endif


 #if H_REVEALS_MODULE_P (SIM_ENDIAN_INLINE)
 #include "sim-endian.c"
 #endif

 #endif /* SIM_ENDIAN_H */
	/* The common simulator framework for GDB, the GNU Debugger.

	Copyright 2002-2021 Free Software Foundation, Inc.

	Contributed by Andrew Cagney and Red Hat.

	This file is part of GDB.

	This program is free software; you can redistribute it and/or modify
	it under the terms of the GNU General Public License as published by
	the Free Software Foundation; either version 3 of the License, or
	(at your option) any later version.

	This program is distributed in the hope that it will be useful,
	but WITHOUT ANY WARRANTY; without even the implied warranty of
	MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	GNU General Public License for more details.

	You should have received a copy of the GNU General Public License
	along with this program. If not, see <http://www.gnu.org/licenses/>. */


	#ifndef SIM_ENDIAN_H
	#define SIM_ENDIAN_H

	#include "bfd.h"

	/* C byte conversion functions */

	INLINE_SIM_ENDIAN(unsigned_1) endian_h2t_1(unsigned_1 x);
	INLINE_SIM_ENDIAN(unsigned_2) endian_h2t_2(unsigned_2 x);
	INLINE_SIM_ENDIAN(unsigned_4) endian_h2t_4(unsigned_4 x);
	INLINE_SIM_ENDIAN(unsigned_8) endian_h2t_8(unsigned_8 x);
	INLINE_SIM_ENDIAN(unsigned_16) endian_h2t_16(unsigned_16 x);

	INLINE_SIM_ENDIAN(unsigned_1) endian_t2h_1(unsigned_1 x);
	INLINE_SIM_ENDIAN(unsigned_2) endian_t2h_2(unsigned_2 x);
	INLINE_SIM_ENDIAN(unsigned_4) endian_t2h_4(unsigned_4 x);
	INLINE_SIM_ENDIAN(unsigned_8) endian_t2h_8(unsigned_8 x);
	INLINE_SIM_ENDIAN(unsigned_16) endian_t2h_16(unsigned_16 x);

	INLINE_SIM_ENDIAN(unsigned_1) swap_1(unsigned_1 x);
	INLINE_SIM_ENDIAN(unsigned_2) swap_2(unsigned_2 x);
	INLINE_SIM_ENDIAN(unsigned_4) swap_4(unsigned_4 x);
	INLINE_SIM_ENDIAN(unsigned_8) swap_8(unsigned_8 x);
	INLINE_SIM_ENDIAN(unsigned_16) swap_16(unsigned_16 x);

	INLINE_SIM_ENDIAN(unsigned_1) endian_h2be_1(unsigned_1 x);
	INLINE_SIM_ENDIAN(unsigned_2) endian_h2be_2(unsigned_2 x);
	INLINE_SIM_ENDIAN(unsigned_4) endian_h2be_4(unsigned_4 x);
	INLINE_SIM_ENDIAN(unsigned_8) endian_h2be_8(unsigned_8 x);
	INLINE_SIM_ENDIAN(unsigned_16) endian_h2be_16(unsigned_16 x);

	INLINE_SIM_ENDIAN(unsigned_1) endian_be2h_1(unsigned_1 x);
	INLINE_SIM_ENDIAN(unsigned_2) endian_be2h_2(unsigned_2 x);
	INLINE_SIM_ENDIAN(unsigned_4) endian_be2h_4(unsigned_4 x);
	INLINE_SIM_ENDIAN(unsigned_8) endian_be2h_8(unsigned_8 x);
	INLINE_SIM_ENDIAN(unsigned_16) endian_be2h_16(unsigned_16 x);

	INLINE_SIM_ENDIAN(unsigned_1) endian_h2le_1(unsigned_1 x);
	INLINE_SIM_ENDIAN(unsigned_2) endian_h2le_2(unsigned_2 x);
	INLINE_SIM_ENDIAN(unsigned_4) endian_h2le_4(unsigned_4 x);
	INLINE_SIM_ENDIAN(unsigned_8) endian_h2le_8(unsigned_8 x);
	INLINE_SIM_ENDIAN(unsigned_16) endian_h2le_16(unsigned_16 x);

	INLINE_SIM_ENDIAN(unsigned_1) endian_le2h_1(unsigned_1 x);
	INLINE_SIM_ENDIAN(unsigned_2) endian_le2h_2(unsigned_2 x);
	INLINE_SIM_ENDIAN(unsigned_4) endian_le2h_4(unsigned_4 x);
	INLINE_SIM_ENDIAN(unsigned_8) endian_le2h_8(unsigned_8 x);
	INLINE_SIM_ENDIAN(unsigned_16) endian_le2h_16(unsigned_16 x);

	INLINE_SIM_ENDIAN(void) offset_1(unsigned_1 x, unsigned ws, unsigned w);
	INLINE_SIM_ENDIAN(void) offset_2(unsigned_2 x, unsigned ws, unsigned w);
	INLINE_SIM_ENDIAN(void) offset_4(unsigned_4 x, unsigned ws, unsigned w);
	INLINE_SIM_ENDIAN(void) offset_8(unsigned_8 x, unsigned ws, unsigned w);
	INLINE_SIM_ENDIAN(void) offset_16(unsigned_16 x, unsigned ws, unsigned w);

	INLINE_SIM_ENDIAN(unsigned_16) sim_endian_join_16 (unsigned_8 h, unsigned_8 l);
	INLINE_SIM_ENDIAN(unsigned_8) sim_endian_split_16 (unsigned_16 word, int w);


	/* SWAP */

	#define SWAP_1 swap_1
	#define SWAP_2 swap_2
	#define SWAP_4 swap_4
	#define SWAP_8 swap_8
	#define SWAP_16 swap_16


	/* HOST to BE */

	#define H2BE_1 endian_h2be_1
	#define H2BE_2 endian_h2be_2
	#define H2BE_4 endian_h2be_4
	#define H2BE_8 endian_h2be_8
	#define H2BE_16 endian_h2be_16
	#define BE2H_1 endian_be2h_1
	#define BE2H_2 endian_be2h_2
	#define BE2H_4 endian_be2h_4
	#define BE2H_8 endian_be2h_8
	#define BE2H_16 endian_be2h_16


	/* HOST to LE */

	#define H2LE_1 endian_h2le_1
	#define H2LE_2 endian_h2le_2
	#define H2LE_4 endian_h2le_4
	#define H2LE_8 endian_h2le_8
	#define H2LE_16 endian_h2le_16
	#define LE2H_1 endian_le2h_1
	#define LE2H_2 endian_le2h_2
	#define LE2H_4 endian_le2h_4
	#define LE2H_8 endian_le2h_8
	#define LE2H_16 endian_le2h_16


	/* HOST to TARGET */

	#define H2T_1 endian_h2t_1
	#define H2T_2 endian_h2t_2
	#define H2T_4 endian_h2t_4
	#define H2T_8 endian_h2t_8
	#define H2T_16 endian_h2t_16
	#define T2H_1 endian_t2h_1
	#define T2H_2 endian_t2h_2
	#define T2H_4 endian_t2h_4
	#define T2H_8 endian_t2h_8
	#define T2H_16 endian_t2h_16


	/* CONVERT IN PLACE

	These macros, given an argument of unknown size, swap its value in
	place if a host/target conversion is required. */

	#define H2T(VARIABLE) \
	do { \
	void *vp = &(VARIABLE); \
	switch (sizeof (VARIABLE)) { \
	case 1: (unsigned_1)vp = H2T_1((unsigned_1)vp); break; \
	case 2: (unsigned_2)vp = H2T_2((unsigned_2)vp); break; \
	case 4: (unsigned_4)vp = H2T_4((unsigned_4)vp); break; \
	case 8: (unsigned_8)vp = H2T_8((unsigned_8)vp); break; \
	case 16: (unsigned_16)vp = H2T_16((unsigned_16)vp); break; \
	} \
	} while (0)

	#define T2H(VARIABLE) \
	do { \
	switch (sizeof(VARIABLE)) { \
	case 1: VARIABLE = T2H_1(VARIABLE); break; \
	case 2: VARIABLE = T2H_2(VARIABLE); break; \
	case 4: VARIABLE = T2H_4(VARIABLE); break; \
	case 8: VARIABLE = T2H_8(VARIABLE); break; \
	/case 16: VARIABLE = T2H_16(VARIABLE); break;/ \
	} \
	} while (0)

	#define SWAP(VARIABLE) \
	do { \
	switch (sizeof(VARIABLE)) { \
	case 1: VARIABLE = SWAP_1(VARIABLE); break; \
	case 2: VARIABLE = SWAP_2(VARIABLE); break; \
	case 4: VARIABLE = SWAP_4(VARIABLE); break; \
	case 8: VARIABLE = SWAP_8(VARIABLE); break; \
	/case 16: VARIABLE = SWAP_16(VARIABLE); break;/ \
	} \
	} while (0)

	#define H2BE(VARIABLE) \
	do { \
	switch (sizeof(VARIABLE)) { \
	case 1: VARIABLE = H2BE_1(VARIABLE); break; \
	case 2: VARIABLE = H2BE_2(VARIABLE); break; \
	case 4: VARIABLE = H2BE_4(VARIABLE); break; \
	case 8: VARIABLE = H2BE_8(VARIABLE); break; \
	/case 16: VARIABLE = H2BE_16(VARIABLE); break;/ \
	} \
	} while (0)

	#define BE2H(VARIABLE) \
	do { \
	switch (sizeof(VARIABLE)) { \
	case 1: VARIABLE = BE2H_1(VARIABLE); break; \
	case 2: VARIABLE = BE2H_2(VARIABLE); break; \
	case 4: VARIABLE = BE2H_4(VARIABLE); break; \
	case 8: VARIABLE = BE2H_8(VARIABLE); break; \
	/case 16: VARIABLE = BE2H_16(VARIABLE); break;/ \
	} \
	} while (0)

	#define H2LE(VARIABLE) \
	do { \
	switch (sizeof(VARIABLE)) { \
	case 1: VARIABLE = H2LE_1(VARIABLE); break; \
	case 2: VARIABLE = H2LE_2(VARIABLE); break; \
	case 4: VARIABLE = H2LE_4(VARIABLE); break; \
	case 8: VARIABLE = H2LE_8(VARIABLE); break; \
	/case 16: VARIABLE = H2LE_16(VARIABLE); break;/ \
	} \
	} while (0)

	#define LE2H(VARIABLE) \
	do { \
	switch (sizeof(VARIABLE)) { \
	case 1: VARIABLE = LE2H_1(VARIABLE); break; \
	case 2: VARIABLE = LE2H_2(VARIABLE); break; \
	case 4: VARIABLE = LE2H_4(VARIABLE); break; \
	case 8: VARIABLE = LE2H_8(VARIABLE); break; \
	/case 16: VARIABLE = LE2H_16(VARIABLE); break;/ \
	} \
	} while (0)



	/* TARGET WORD:

	Byte swap a quantity the size of the targets word */

	#if (WITH_TARGET_WORD_BITSIZE == 64)
	#define H2T_word H2T_8
	#define T2H_word T2H_8
	#define H2BE_word H2BE_8
	#define BE2H_word BE2H_8
	#define H2LE_word H2LE_8
	#define LE2H_word LE2H_8
	#define SWAP_word SWAP_8
	#endif
	#if (WITH_TARGET_WORD_BITSIZE == 32)
	#define H2T_word H2T_4
	#define T2H_word T2H_4
	#define H2BE_word H2BE_4
	#define BE2H_word BE2H_4
	#define H2LE_word H2LE_4
	#define LE2H_word LE2H_4
	#define SWAP_word SWAP_4
	#endif



	/* TARGET CELL:

	Byte swap a quantity the size of the targets IEEE 1275 memory cell */

	#define H2T_cell H2T_4
	#define T2H_cell T2H_4
	#define H2BE_cell H2BE_4
	#define BE2H_cell BE2H_4
	#define H2LE_cell H2LE_4
	#define LE2H_cell LE2H_4
	#define SWAP_cell SWAP_4



	/* HOST Offsets:

	Address of high/low sub-word within a host word quantity.

	Address of sub-word N within a host word quantity. NOTE: Numbering
	is BIG endian always. */

	#define AH1_2(X) (unsigned_1*)offset_2((X), 1, 0)
	#define AL1_2(X) (unsigned_1*)offset_2((X), 1, 1)

	#define AH2_4(X) (unsigned_2*)offset_4((X), 2, 0)
	#define AL2_4(X) (unsigned_2*)offset_4((X), 2, 1)

	#define AH4_8(X) (unsigned_4*)offset_8((X), 4, 0)
	#define AL4_8(X) (unsigned_4*)offset_8((X), 4, 1)

	#define AH8_16(X) (unsigned_8*)offset_16((X), 8, 0)
	#define AL8_16(X) (unsigned_8*)offset_16((X), 8, 1)

	#if (WITH_TARGET_WORD_BITSIZE == 64)
	#define AH_word(X) AH4_8(X)
	#define AL_word(X) AL4_8(X)
	#endif
	#if (WITH_TARGET_WORD_BITSIZE == 32)
	#define AH_word(X) AH2_4(X)
	#define AL_word(X) AL2_4(X)
	#endif


	#define A1_2(X,N) (unsigned_1*)offset_2((X), 1, (N))

	#define A1_4(X,N) (unsigned_1*)offset_4((X), 1, (N))
	#define A2_4(X,N) (unsigned_2*)offset_4((X), 2, (N))

	#define A1_8(X,N) (unsigned_1*)offset_8((X), 1, (N))
	#define A2_8(X,N) (unsigned_2*)offset_8((X), 2, (N))
	#define A4_8(X,N) (unsigned_4*)offset_8((X), 4, (N))

	#define A1_16(X,N) (unsigned_1*)offset_16((X), 1, (N))
	#define A2_16(X,N) (unsigned_2*)offset_16((X), 2, (N))
	#define A4_16(X,N) (unsigned_4*)offset_16((X), 4, (N))
	#define A8_16(X,N) (unsigned_8*)offset_16((X), 8, (N))




	/* HOST Components:

	Value of sub-word within a host word quantity */

	#define VH1_2(X) ((unsigned_1)((unsigned_2)(X) >> 8))
	#define VL1_2(X) (unsigned_1)(X)

	#define VH2_4(X) ((unsigned_2)((unsigned_4)(X) >> 16))
	#define VL2_4(X) ((unsigned_2)(X))

	#define VH4_8(X) ((unsigned_4)((unsigned_8)(X) >> 32))
	#define VL4_8(X) ((unsigned_4)(X))

	#define VH8_16(X) (sim_endian_split_16 ((X), 0))
	#define VL8_16(X) (sim_endian_split_16 ((X), 1))

	#if (WITH_TARGET_WORD_BITSIZE == 64)
	#define VH_word(X) VH4_8(X)
	#define VL_word(X) VL4_8(X)
	#endif
	#if (WITH_TARGET_WORD_BITSIZE == 32)
	#define VH_word(X) VH2_4(X)
	#define VL_word(X) VL2_4(X)
	#endif


	#define V1_2(X,N) ((unsigned_1)((unsigned_2)(X) >> ( 8 * (1 - (N)))))

	#define V1_4(X,N) ((unsigned_1)((unsigned_4)(X) >> ( 8 * (3 - (N)))))
	#define V2_4(X,N) ((unsigned_2)((unsigned_4)(X) >> (16 * (1 - (N)))))

	#define V1_8(X,N) ((unsigned_1)((unsigned_8)(X) >> ( 8 * (7 - (N)))))
	#define V2_8(X,N) ((unsigned_2)((unsigned_8)(X) >> (16 * (3 - (N)))))
	#define V4_8(X,N) ((unsigned_4)((unsigned_8)(X) >> (32 * (1 - (N)))))

	#define V1_16(X,N) (*A1_16 (&(X),N))
	#define V2_16(X,N) (*A2_16 (&(X),N))
	#define V4_16(X,N) (*A4_16 (&(X),N))
	#define V8_16(X,N) (*A8_16 (&(X),N))


	/* Reverse - insert sub-word into word quantity */

	#define V2_H1(X) ((unsigned_2)(unsigned_1)(X) << 8)
	#define V2_L1(X) ((unsigned_2)(unsigned_1)(X))

	#define V4_H2(X) ((unsigned_4)(unsigned_2)(X) << 16)
	#define V4_L2(X) ((unsigned_4)(unsigned_2)(X))

	#define V8_H4(X) ((unsigned_8)(unsigned_4)(X) << 32)
	#define V8_L4(X) ((unsigned_8)(unsigned_4)(X))

	#define V16_H8(X) ((unsigned_16)(unsigned_8)(X) << 64)
	#define V16_L8(X) ((unsigned_16)(unsigned_8)(X))


	#define V2_1(X,N) ((unsigned_2)(unsigned_1)(X) << ( 8 * (1 - (N))))

	#define V4_1(X,N) ((unsigned_4)(unsigned_1)(X) << ( 8 * (3 - (N))))
	#define V4_2(X,N) ((unsigned_4)(unsigned_2)(X) << (16 * (1 - (N))))

	#define V8_1(X,N) ((unsigned_8)(unsigned_1)(X) << ( 8 * (7 - (N))))
	#define V8_2(X,N) ((unsigned_8)(unsigned_2)(X) << (16 * (3 - (N))))
	#define V8_4(X,N) ((unsigned_8)(unsigned_4)(X) << (32 * (1 - (N))))

	#define V16_1(X,N) ((unsigned_16)(unsigned_1)(X) << ( 8 * (15 - (N))))
	#define V16_2(X,N) ((unsigned_16)(unsigned_2)(X) << (16 * (7 - (N))))
	#define V16_4(X,N) ((unsigned_16)(unsigned_4)(X) << (32 * (3 - (N))))
	#define V16_8(X,N) ((unsigned_16)(unsigned_8)(X) << (64 * (1 - (N))))


	/* Reverse - insert N sub-words into single word quantity */

	#define U2_1(I0,I1) (V2_1(I0,0) \| V2_1(I1,1))
	#define U4_1(I0,I1,I2,I3) (V4_1(I0,0) \| V4_1(I1,1) \| V4_1(I2,2) \| V4_1(I3,3))
	#define U8_1(I0,I1,I2,I3,I4,I5,I6,I7) \
	(V8_1(I0,0) \| V8_1(I1,1) \| V8_1(I2,2) \| V8_1(I3,3) \
	\| V8_1(I4,4) \| V8_1(I5,5) \| V8_1(I6,6) \| V8_1(I7,7))
	#define U16_1(I0,I1,I2,I3,I4,I5,I6,I7,I8,I9,I10,I11,I12,I13,I14,I15) \
	(V16_1(I0,0) \| V16_1(I1,1) \| V16_1(I2,2) \| V16_1(I3,3) \
	\| V16_1(I4,4) \| V16_1(I5,5) \| V16_1(I6,6) \| V16_1(I7,7) \
	\| V16_1(I8,8) \| V16_1(I9,9) \| V16_1(I10,10) \| V16_1(I11,11) \
	\| V16_1(I12,12) \| V16_1(I13,13) \| V16_1(I14,14) \| V16_1(I15,15))

	#define U4_2(I0,I1) (V4_2(I0,0) \| V4_2(I1,1))
	#define U8_2(I0,I1,I2,I3) (V8_2(I0,0) \| V8_2(I1,1) \| V8_2(I2,2) \| V8_2(I3,3))
	#define U16_2(I0,I1,I2,I3,I4,I5,I6,I7) \
	(V16_2(I0,0) \| V16_2(I1,1) \| V16_2(I2,2) \| V16_2(I3,3) \
	\| V16_2(I4,4) \| V16_2(I5,5) \| V16_2(I6,6) \| V16_2(I7,7) )

	#define U8_4(I0,I1) (V8_4(I0,0) \| V8_4(I1,1))
	#define U16_4(I0,I1,I2,I3) (V16_4(I0,0) \| V16_4(I1,1) \| V16_4(I2,2) \| V16_4(I3,3))

	#define U16_8(I0,I1) (sim_endian_join_16 (I0, I1))


	#if (WITH_TARGET_WORD_BITSIZE == 64)
	#define Vword_H(X) V8_H4(X)
	#define Vword_L(X) V8_L4(X)
	#endif
	#if (WITH_TARGET_WORD_BITSIZE == 32)
	#define Vword_H(X) V4_H2(X)
	#define Vword_L(X) V4_L2(X)
	#endif




	#if H_REVEALS_MODULE_P (SIM_ENDIAN_INLINE)
	#include "sim-endian.c"
	#endif

	#endif /* SIM_ENDIAN_H */