darling-gdb/sim/common/sim-bits.h
Andrew Cagney b85e4829fa 2002-11-22 Andrew Cagney <ac131313@redhat.com>
* dv-core.c: Update copyright.  sim/common contributed to the FSF.
	* dv-glue.c, dv-pal.c, hw-base.c, hw-base.h, hw-device.c: Ditto.
	* hw-device.h, hw-handles.c, hw-handles.h: Ditto.
	* hw-instances.c, hw-instances.h, hw-properties.c: Ditto.
	* hw-properties.h, hw-tree.c, hw-tree.h, sim-alu.h: Ditto.
	* sim-basics.h, sim-bits.c, sim-bits.h, sim-config.c: Ditto.
	* sim-config.h, sim-core.c, sim-core.h, sim-endian.c: Ditto.
	* sim-endian.h, sim-events.c, sim-events.h, sim-inline.c: Ditto.
	* sim-inline.h, sim-io.c, sim-io.h, sim-n-bits.h: Ditto.
	* sim-n-core.h, sim-n-endian.h, sim-types.h: Ditto.
2002-11-23 01:12:05 +00:00

611 lines
19 KiB
C

/* The common simulator framework for GDB, the GNU Debugger.
Copyright 2002 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 2 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, write to the Free Software
Foundation, Inc., 59 Temple Place - Suite 330,
Boston, MA 02111-1307, USA. */
#ifndef _SIM_BITS_H_
#define _SIM_BITS_H_
/* Bit manipulation routines:
Bit numbering: The bits are numbered according to the target ISA's
convention. That being controlled by WITH_TARGET_WORD_MSB. For
the PowerPC (WITH_TARGET_WORD_MSB == 0) the numbering is 0..31
while for the MIPS (WITH_TARGET_WORD_MSB == 31) it is 31..0.
Size convention: Each macro is in three forms - <MACRO>32 which
operates in 32bit quantity (bits are numbered 0..31); <MACRO>64
which operates using 64bit quantites (and bits are numbered 0..63);
and <MACRO> which operates using the bit size of the target
architecture (bits are still numbered 0..63), with 32bit
architectures ignoring the first 32bits leaving bit 32 as the most
significant.
NB: Use EXTRACTED, MSEXTRACTED and LSEXTRACTED as a guideline for
naming. LSMASK and LSMASKED are wrong.
BIT*(POS): `*' bit constant with just 1 bit set.
LSBIT*(OFFSET): `*' bit constant with just 1 bit set - LS bit is
zero.
MSBIT*(OFFSET): `*' bit constant with just 1 bit set - MS bit is
zero.
MASK*(FIRST, LAST): `*' bit constant with bits [FIRST .. LAST]
set. The <MACRO> (no size) version permits FIRST >= LAST and
generates a wrapped bit mask vis ([0..LAST] | [FIRST..LSB]).
LSMASK*(FIRST, LAST): Like MASK - LS bit is zero.
MSMASK*(FIRST, LAST): Like MASK - LS bit is zero.
MASKED*(VALUE, FIRST, LAST): Masks out all but bits [FIRST
.. LAST].
LSMASKED*(VALUE, FIRST, LAST): Like MASKED - LS bit is zero.
MSMASKED*(VALUE, FIRST, LAST): Like MASKED - MS bit is zero.
EXTRACTED*(VALUE, FIRST, LAST): Masks out bits [FIRST .. LAST] but
also right shifts the masked value so that bit LAST becomes the
least significant (right most).
LSEXTRACTED*(VALUE, FIRST, LAST): Same as extracted - LS bit is
zero.
MSEXTRACTED*(VALUE, FIRST, LAST): Same as extracted - MS bit is
zero.
SHUFFLED**(VALUE, OLD, NEW): Mask then move a single bit from OLD
new NEW.
MOVED**(VALUE, OLD_FIRST, OLD_LAST, NEW_FIRST, NEW_LAST): Moves
things around so that bits OLD_FIRST..OLD_LAST are masked then
moved to NEW_FIRST..NEW_LAST.
INSERTED*(VALUE, FIRST, LAST): Takes VALUE and `inserts' the (LAST
- FIRST + 1) least significant bits into bit positions [ FIRST
.. LAST ]. This is almost the complement to EXTRACTED.
IEA_MASKED(SHOULD_MASK, ADDR): Convert the address to the targets
natural size. If in 32bit mode, discard the high 32bits.
EXTEND*(VALUE): Convert the `*' bit value to the targets natural
word size. Sign extend the value if needed.
ALIGN_*(VALUE): Round the value upwards so that it is aligned to a
`_*' byte boundary.
FLOOR_*(VALUE): Truncate the value so that it is aligned to a `_*'
byte boundary.
ROT*(VALUE, NR_BITS): Return the `*' bit VALUE rotated by NR_BITS
right (positive) or left (negative).
ROTL*(VALUE, NR_BITS): Return the `*' bit value rotated by NR_BITS
left. 0 <= NR_BITS <= `*'.
ROTR*(VALUE, NR_BITS): Return the `*' bit value rotated by NR_BITS
right. 0 <= NR_BITS <= N.
SEXT*(VALUE, SIGN_BIT): Treat SIGN_BIT as VALUEs sign, extend it ti
`*' bits.
Note: Only the BIT* and MASK* macros return a constant that can be
used in variable declarations.
*/
/* compute the number of bits between START and STOP */
#if (WITH_TARGET_WORD_MSB == 0)
#define _MAKE_WIDTH(START, STOP) (STOP - START + 1)
#else
#define _MAKE_WIDTH(START, STOP) (START - STOP + 1)
#endif
/* compute the number shifts required to move a bit between LSB (MSB)
and POS */
#if (WITH_TARGET_WORD_MSB == 0)
#define _LSB_SHIFT(WIDTH, POS) (WIDTH - 1 - POS)
#else
#define _LSB_SHIFT(WIDTH, POS) (POS)
#endif
#if (WITH_TARGET_WORD_MSB == 0)
#define _MSB_SHIFT(WIDTH, POS) (POS)
#else
#define _MSB_SHIFT(WIDTH, POS) (WIDTH - 1 - POS)
#endif
/* compute the absolute bit position given the OFFSET from the MSB(LSB)
NB: _MAKE_xxx_POS (WIDTH, _MAKE_xxx_SHIFT (WIDTH, POS)) == POS */
#if (WITH_TARGET_WORD_MSB == 0)
#define _MSB_POS(WIDTH, SHIFT) (SHIFT)
#else
#define _MSB_POS(WIDTH, SHIFT) (WIDTH - 1 - SHIFT)
#endif
#if (WITH_TARGET_WORD_MSB == 0)
#define _LSB_POS(WIDTH, SHIFT) (WIDTH - 1 - SHIFT)
#else
#define _LSB_POS(WIDTH, SHIFT) (SHIFT)
#endif
/* convert a 64 bit position into a corresponding 32bit position. MSB
pos handles the posibility that the bit lies beyond the 32bit
boundary */
#if (WITH_TARGET_WORD_MSB == 0)
#define _MSB_32(START, STOP) (START <= STOP \
? (START < 32 ? 0 : START - 32) \
: (STOP < 32 ? 0 : STOP - 32))
#define _MSB_16(START, STOP) (START <= STOP \
? (START < 48 ? 0 : START - 48) \
: (STOP < 48 ? 0 : STOP - 48))
#else
#define _MSB_32(START, STOP) (START >= STOP \
? (START >= 32 ? 31 : START) \
: (STOP >= 32 ? 31 : STOP))
#define _MSB_16(START, STOP) (START >= STOP \
? (START >= 16 ? 15 : START) \
: (STOP >= 16 ? 15 : STOP))
#endif
#if (WITH_TARGET_WORD_MSB == 0)
#define _LSB_32(START, STOP) (START <= STOP \
? (STOP < 32 ? 0 : STOP - 32) \
: (START < 32 ? 0 : START - 32))
#define _LSB_16(START, STOP) (START <= STOP \
? (STOP < 48 ? 0 : STOP - 48) \
: (START < 48 ? 0 : START - 48))
#else
#define _LSB_32(START, STOP) (START >= STOP \
? (STOP >= 32 ? 31 : STOP) \
: (START >= 32 ? 31 : START))
#define _LSB_16(START, STOP) (START >= STOP \
? (STOP >= 16 ? 15 : STOP) \
: (START >= 16 ? 15 : START))
#endif
#if (WITH_TARGET_WORD_MSB == 0)
#define _MSB(START, STOP) (START <= STOP ? START : STOP)
#else
#define _MSB(START, STOP) (START >= STOP ? START : STOP)
#endif
#if (WITH_TARGET_WORD_MSB == 0)
#define _LSB(START, STOP) (START <= STOP ? STOP : START)
#else
#define _LSB(START, STOP) (START >= STOP ? STOP : START)
#endif
/* LS/MS Bit operations */
#define LSBIT8(POS) ((unsigned8) 1 << (POS))
#define LSBIT16(POS) ((unsigned16)1 << (POS))
#define LSBIT32(POS) ((unsigned32)1 << (POS))
#define LSBIT64(POS) ((unsigned64)1 << (POS))
#if (WITH_TARGET_WORD_BITSIZE == 64)
#define LSBIT(POS) LSBIT64 (POS)
#endif
#if (WITH_TARGET_WORD_BITSIZE == 32)
#define LSBIT(POS) ((unsigned32)((POS) >= 32 \
? 0 \
: (1 << ((POS) >= 32 ? 0 : (POS)))))
#endif
#if (WITH_TARGET_WORD_BITSIZE == 16)
#define LSBIT(POS) ((unsigned16)((POS) >= 16 \
? 0 \
: (1 << ((POS) >= 16 ? 0 : (POS)))))
#endif
#define MSBIT8(POS) ((unsigned8) 1 << ( 8 - 1 - (POS)))
#define MSBIT16(POS) ((unsigned16)1 << (16 - 1 - (POS)))
#define MSBIT32(POS) ((unsigned32)1 << (32 - 1 - (POS)))
#define MSBIT64(POS) ((unsigned64)1 << (64 - 1 - (POS)))
#if (WITH_TARGET_WORD_BITSIZE == 64)
#define MSBIT(POS) MSBIT64 (POS)
#endif
#if (WITH_TARGET_WORD_BITSIZE == 32)
#define MSBIT(POS) ((unsigned32)((POS) < 32 \
? 0 \
: (1 << ((POS) < 32 ? 0 : (64 - 1) - (POS)))))
#endif
#if (WITH_TARGET_WORD_BITSIZE == 16)
#define MSBIT(POS) ((unsigned16)((POS) < 48 \
? 0 \
: (1 << ((POS) < 48 ? 0 : (64 - 1) - (POS)))))
#endif
/* Bit operations */
#define BIT4(POS) (1 << _LSB_SHIFT (4, (POS)))
#define BIT5(POS) (1 << _LSB_SHIFT (5, (POS)))
#define BIT10(POS) (1 << _LSB_SHIFT (10, (POS)))
#if (WITH_TARGET_WORD_MSB == 0)
#define BIT8 MSBIT8
#define BIT16 MSBIT16
#define BIT32 MSBIT32
#define BIT64 MSBIT64
#define BIT MSBIT
#else
#define BIT8 LSBIT8
#define BIT16 LSBIT16
#define BIT32 LSBIT32
#define BIT64 LSBIT64
#define BIT LSBIT
#endif
/* multi bit mask */
/* 111111 -> mmll11 -> mm11ll */
#define _MASKn(WIDTH, START, STOP) (((unsigned##WIDTH)(-1) \
>> (_MSB_SHIFT (WIDTH, START) \
+ _LSB_SHIFT (WIDTH, STOP))) \
<< _LSB_SHIFT (WIDTH, STOP))
#if (WITH_TARGET_WORD_MSB == 0)
#define _POS_LE(START, STOP) (START <= STOP)
#else
#define _POS_LE(START, STOP) (STOP <= START)
#endif
#if (WITH_TARGET_WORD_BITSIZE == 64)
#define MASK(START, STOP) \
(_POS_LE ((START), (STOP)) \
? _MASKn(64, \
_MSB ((START), (STOP)), \
_LSB ((START), (STOP)) ) \
: (_MASKn(64, _MSB_POS (64, 0), (STOP)) \
| _MASKn(64, (START), _LSB_POS (64, 0))))
#endif
#if (WITH_TARGET_WORD_BITSIZE == 32)
#define MASK(START, STOP) \
(_POS_LE ((START), (STOP)) \
? (_POS_LE ((STOP), _MSB_POS (64, 31)) \
? 0 \
: _MASKn (32, \
_MSB_32 ((START), (STOP)), \
_LSB_32 ((START), (STOP)))) \
: (_MASKn (32, \
_LSB_32 ((START), (STOP)), \
_LSB_POS (32, 0)) \
| (_POS_LE ((STOP), _MSB_POS (64, 31)) \
? 0 \
: _MASKn (32, \
_MSB_POS (32, 0), \
_MSB_32 ((START), (STOP))))))
#endif
#if (WITH_TARGET_WORD_BITSIZE == 16)
#define MASK(START, STOP) \
(_POS_LE ((START), (STOP)) \
? (_POS_LE ((STOP), _MSB_POS (64, 15)) \
? 0 \
: _MASKn (16, \
_MSB_16 ((START), (STOP)), \
_LSB_16 ((START), (STOP)))) \
: (_MASKn (16, \
_LSB_16 ((START), (STOP)), \
_LSB_POS (16, 0)) \
| (_POS_LE ((STOP), _MSB_POS (64, 15)) \
? 0 \
: _MASKn (16, \
_MSB_POS (16, 0), \
_MSB_16 ((START), (STOP))))))
#endif
#if !defined (MASK)
#error "MASK never undefined"
#endif
/* Multi-bit mask on least significant bits */
#define _LSMASKn(WIDTH, FIRST, LAST) _MASKn (WIDTH, \
_LSB_POS (WIDTH, FIRST), \
_LSB_POS (WIDTH, LAST))
#define LSMASK8(FIRST, LAST) _LSMASKn ( 8, (FIRST), (LAST))
#define LSMASK16(FIRST, LAST) _LSMASKn (16, (FIRST), (LAST))
#define LSMASK32(FIRST, LAST) _LSMASKn (32, (FIRST), (LAST))
#define LSMASK64(FIRST, LAST) _LSMASKn (64, (FIRST), (LAST))
#define LSMASK(FIRST, LAST) (MASK (_LSB_POS (64, FIRST), _LSB_POS (64, LAST)))
/* Multi-bit mask on most significant bits */
#define _MSMASKn(WIDTH, FIRST, LAST) _MASKn (WIDTH, \
_MSB_POS (WIDTH, FIRST), \
_MSB_POS (WIDTH, LAST))
#define MSMASK8(FIRST, LAST) _MSMASKn ( 8, (FIRST), (LAST))
#define MSMASK16(FIRST, LAST) _MSMASKn (16, (FIRST), (LAST))
#define MSMASK32(FIRST, LAST) _MSMASKn (32, (FIRST), (LAST))
#define MSMASK64(FIRST, LAST) _MSMASKn (64, (FIRST), (LAST))
#define MSMASK(FIRST, LAST) (MASK (_MSB_POS (64, FIRST), _MSB_POS (64, LAST)))
#if (WITH_TARGET_WORD_MSB == 0)
#define MASK8 MSMASK8
#define MASK16 MSMASK16
#define MASK32 MSMASK32
#define MASK64 MSMASK64
#else
#define MASK8 LSMASK8
#define MASK16 LSMASK16
#define MASK32 LSMASK32
#define MASK64 LSMASK64
#endif
/* mask the required bits, leaving them in place */
INLINE_SIM_BITS(unsigned8) LSMASKED8 (unsigned8 word, int first, int last);
INLINE_SIM_BITS(unsigned16) LSMASKED16 (unsigned16 word, int first, int last);
INLINE_SIM_BITS(unsigned32) LSMASKED32 (unsigned32 word, int first, int last);
INLINE_SIM_BITS(unsigned64) LSMASKED64 (unsigned64 word, int first, int last);
INLINE_SIM_BITS(unsigned_word) LSMASKED (unsigned_word word, int first, int last);
INLINE_SIM_BITS(unsigned8) MSMASKED8 (unsigned8 word, int first, int last);
INLINE_SIM_BITS(unsigned16) MSMASKED16 (unsigned16 word, int first, int last);
INLINE_SIM_BITS(unsigned32) MSMASKED32 (unsigned32 word, int first, int last);
INLINE_SIM_BITS(unsigned64) MSMASKED64 (unsigned64 word, int first, int last);
INLINE_SIM_BITS(unsigned_word) MSMASKED (unsigned_word word, int first, int last);
#if (WITH_TARGET_WORD_MSB == 0)
#define MASKED8 MSMASKED8
#define MASKED16 MSMASKED16
#define MASKED32 MSMASKED32
#define MASKED64 MSMASKED64
#define MASKED MSMASKED
#else
#define MASKED8 LSMASKED8
#define MASKED16 LSMASKED16
#define MASKED32 LSMASKED32
#define MASKED64 LSMASKED64
#define MASKED LSMASKED
#endif
/* extract the required bits aligning them with the lsb */
INLINE_SIM_BITS(unsigned8) LSEXTRACTED8 (unsigned8 val, int start, int stop);
INLINE_SIM_BITS(unsigned16) LSEXTRACTED16 (unsigned16 val, int start, int stop);
INLINE_SIM_BITS(unsigned32) LSEXTRACTED32 (unsigned32 val, int start, int stop);
INLINE_SIM_BITS(unsigned64) LSEXTRACTED64 (unsigned64 val, int start, int stop);
INLINE_SIM_BITS(unsigned_word) LSEXTRACTED (unsigned_word val, int start, int stop);
INLINE_SIM_BITS(unsigned8) MSEXTRACTED8 (unsigned8 val, int start, int stop);
INLINE_SIM_BITS(unsigned16) MSEXTRACTED16 (unsigned16 val, int start, int stop);
INLINE_SIM_BITS(unsigned32) MSEXTRACTED32 (unsigned32 val, int start, int stop);
INLINE_SIM_BITS(unsigned64) MSEXTRACTED64 (unsigned64 val, int start, int stop);
INLINE_SIM_BITS(unsigned_word) MSEXTRACTED (unsigned_word val, int start, int stop);
#if (WITH_TARGET_WORD_MSB == 0)
#define EXTRACTED8 MSEXTRACTED8
#define EXTRACTED16 MSEXTRACTED16
#define EXTRACTED32 MSEXTRACTED32
#define EXTRACTED64 MSEXTRACTED64
#define EXTRACTED MSEXTRACTED
#else
#define EXTRACTED8 LSEXTRACTED8
#define EXTRACTED16 LSEXTRACTED16
#define EXTRACTED32 LSEXTRACTED32
#define EXTRACTED64 LSEXTRACTED64
#define EXTRACTED LSEXTRACTED
#endif
/* move a single bit around */
/* NB: the wierdness (N>O?N-O:0) is to stop a warning from GCC */
#define _SHUFFLEDn(N, WORD, OLD, NEW) \
((OLD) < (NEW) \
? (((unsigned##N)(WORD) \
>> (((NEW) > (OLD)) ? ((NEW) - (OLD)) : 0)) \
& MASK32((NEW), (NEW))) \
: (((unsigned##N)(WORD) \
<< (((OLD) > (NEW)) ? ((OLD) - (NEW)) : 0)) \
& MASK32((NEW), (NEW))))
#define SHUFFLED32(WORD, OLD, NEW) _SHUFFLEDn (32, WORD, OLD, NEW)
#define SHUFFLED64(WORD, OLD, NEW) _SHUFFLEDn (64, WORD, OLD, NEW)
#define SHUFFLED(WORD, OLD, NEW) _SHUFFLEDn (_word, WORD, OLD, NEW)
/* Insert a group of bits into a bit position */
INLINE_SIM_BITS(unsigned8) LSINSERTED8 (unsigned8 val, int start, int stop);
INLINE_SIM_BITS(unsigned16) LSINSERTED16 (unsigned16 val, int start, int stop);
INLINE_SIM_BITS(unsigned32) LSINSERTED32 (unsigned32 val, int start, int stop);
INLINE_SIM_BITS(unsigned64) LSINSERTED64 (unsigned64 val, int start, int stop);
INLINE_SIM_BITS(unsigned_word) LSINSERTED (unsigned_word val, int start, int stop);
INLINE_SIM_BITS(unsigned8) MSINSERTED8 (unsigned8 val, int start, int stop);
INLINE_SIM_BITS(unsigned16) MSINSERTED16 (unsigned16 val, int start, int stop);
INLINE_SIM_BITS(unsigned32) MSINSERTED32 (unsigned32 val, int start, int stop);
INLINE_SIM_BITS(unsigned64) MSINSERTED64 (unsigned64 val, int start, int stop);
INLINE_SIM_BITS(unsigned_word) MSINSERTED (unsigned_word val, int start, int stop);
#if (WITH_TARGET_WORD_MSB == 0)
#define INSERTED8 MSINSERTED8
#define INSERTED16 MSINSERTED16
#define INSERTED32 MSINSERTED32
#define INSERTED64 MSINSERTED64
#define INSERTED MSINSERTED
#else
#define INSERTED8 LSINSERTED8
#define INSERTED16 LSINSERTED16
#define INSERTED32 LSINSERTED32
#define INSERTED64 LSINSERTED64
#define INSERTED LSINSERTED
#endif
/* MOVE bits from one loc to another (combination of extract/insert) */
#define MOVED8(VAL,OH,OL,NH,NL) INSERTED8 (EXTRACTED8 ((VAL), OH, OL), NH, NL)
#define MOVED16(VAL,OH,OL,NH,NL) INSERTED16(EXTRACTED16((VAL), OH, OL), NH, NL)
#define MOVED32(VAL,OH,OL,NH,NL) INSERTED32(EXTRACTED32((VAL), OH, OL), NH, NL)
#define MOVED64(VAL,OH,OL,NH,NL) INSERTED64(EXTRACTED64((VAL), OH, OL), NH, NL)
#define MOVED(VAL,OH,OL,NH,NL) INSERTED (EXTRACTED ((VAL), OH, OL), NH, NL)
/* Sign extend the quantity to the targets natural word size */
#define EXTEND4(X) (LSSEXT ((X), 3))
#define EXTEND5(X) (LSSEXT ((X), 4))
#define EXTEND8(X) ((signed_word)(signed8)(X))
#define EXTEND11(X) (LSSEXT ((X), 10))
#define EXTEND15(X) (LSSEXT ((X), 14))
#define EXTEND16(X) ((signed_word)(signed16)(X))
#define EXTEND24(X) (LSSEXT ((X), 23))
#define EXTEND32(X) ((signed_word)(signed32)(X))
#define EXTEND64(X) ((signed_word)(signed64)(X))
/* depending on MODE return a 64bit or 32bit (sign extended) value */
#if (WITH_TARGET_WORD_BITSIZE == 64)
#define EXTENDED(X) ((signed64)(signed32)(X))
#endif
#if (WITH_TARGET_WORD_BITSIZE == 32)
#define EXTENDED(X) (X)
#endif
#if (WITH_TARGET_WORD_BITSIZE == 16)
#define EXTENDED(X) (X)
#endif
/* memory alignment macro's */
#define _ALIGNa(A,X) (((X) + ((A) - 1)) & ~((A) - 1))
#define _FLOORa(A,X) ((X) & ~((A) - 1))
#define ALIGN_8(X) _ALIGNa (8, X)
#define ALIGN_16(X) _ALIGNa (16, X)
#define ALIGN_PAGE(X) _ALIGNa (0x1000, X)
#define FLOOR_PAGE(X) ((X) & ~(0x1000 - 1))
/* bit bliting macro's */
#define BLIT32(V, POS, BIT) \
do { \
if (BIT) \
V |= BIT32 (POS); \
else \
V &= ~BIT32 (POS); \
} while (0)
#define MBLIT32(V, LO, HI, VAL) \
do { \
(V) = (((V) & ~MASK32 ((LO), (HI))) \
| INSERTED32 (VAL, LO, HI)); \
} while (0)
/* some rotate functions. The generic macro's ROT, ROTL, ROTR are
intentionally omited. */
INLINE_SIM_BITS(unsigned8) ROT8 (unsigned8 val, int shift);
INLINE_SIM_BITS(unsigned16) ROT16 (unsigned16 val, int shift);
INLINE_SIM_BITS(unsigned32) ROT32 (unsigned32 val, int shift);
INLINE_SIM_BITS(unsigned64) ROT64 (unsigned64 val, int shift);
INLINE_SIM_BITS(unsigned8) ROTL8 (unsigned8 val, int shift);
INLINE_SIM_BITS(unsigned16) ROTL16 (unsigned16 val, int shift);
INLINE_SIM_BITS(unsigned32) ROTL32 (unsigned32 val, int shift);
INLINE_SIM_BITS(unsigned64) ROTL64 (unsigned64 val, int shift);
INLINE_SIM_BITS(unsigned8) ROTR8 (unsigned8 val, int shift);
INLINE_SIM_BITS(unsigned16) ROTR16 (unsigned16 val, int shift);
INLINE_SIM_BITS(unsigned32) ROTR32 (unsigned32 val, int shift);
INLINE_SIM_BITS(unsigned64) ROTR64 (unsigned64 val, int shift);
/* Sign extension operations */
INLINE_SIM_BITS(unsigned8) LSSEXT8 (signed8 val, int sign_bit);
INLINE_SIM_BITS(unsigned16) LSSEXT16 (signed16 val, int sign_bit);
INLINE_SIM_BITS(unsigned32) LSSEXT32 (signed32 val, int sign_bit);
INLINE_SIM_BITS(unsigned64) LSSEXT64 (signed64 val, int sign_bit);
INLINE_SIM_BITS(unsigned_word) LSSEXT (signed_word val, int sign_bit);
INLINE_SIM_BITS(unsigned8) MSSEXT8 (signed8 val, int sign_bit);
INLINE_SIM_BITS(unsigned16) MSSEXT16 (signed16 val, int sign_bit);
INLINE_SIM_BITS(unsigned32) MSSEXT32 (signed32 val, int sign_bit);
INLINE_SIM_BITS(unsigned64) MSSEXT64 (signed64 val, int sign_bit);
INLINE_SIM_BITS(unsigned_word) MSSEXT (signed_word val, int sign_bit);
#if (WITH_TARGET_WORD_MSB == 0)
#define SEXT8 MSSEXT8
#define SEXT16 MSSEXT16
#define SEXT32 MSSEXT32
#define SEXT64 MSSEXT64
#define SEXT MSSEXT
#else
#define SEXT8 LSSEXT8
#define SEXT16 LSSEXT16
#define SEXT32 LSSEXT32
#define SEXT64 LSSEXT64
#define SEXT LSSEXT
#endif
#if H_REVEALS_MODULE_P (SIM_BITS_INLINE)
#include "sim-bits.c"
#endif
#endif /* _SIM_BITS_H_ */