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1b2af6a41e
Nothing checks this define anywhere, so drop all the logic. We don't want this to be a configure option in the first place as all such usage should be automatic & following proper types.
597 lines
17 KiB
C++
597 lines
17 KiB
C++
/* This file is part of the program psim.
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Copyright 1994, 1995, 2002 Andrew Cagney <cagney@highland.com.au>
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This program is free software; you can redistribute it and/or modify
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it under the terms of the GNU General Public License as published by
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the Free Software Foundation; either version 3 of the License, or
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(at your option) any later version.
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This program is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with this program; if not, see <http://www.gnu.org/licenses/>.
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*/
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#ifndef _PSIM_CONFIG_H_
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#define _PSIM_CONFIG_H_
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#include "bfd.h"
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/* endianness of the host/target:
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If the build process is aware (at compile time) of the endianness
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of the host/target it is able to eliminate slower generic endian
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handling code.
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Possible values are BFD_ENDIAN_UNKNOWN, BFD_ENDIAN_LITTLE,
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BFD_ENDIAN_BIG. */
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#ifdef WORDS_BIGENDIAN
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# define HOST_BYTE_ORDER BFD_ENDIAN_BIG
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#else
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# define HOST_BYTE_ORDER BFD_ENDIAN_LITTLE
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#endif
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#ifndef WITH_TARGET_BYTE_ORDER
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#define WITH_TARGET_BYTE_ORDER BFD_ENDIAN_UNKNOWN
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#endif
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extern enum bfd_endian current_target_byte_order;
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#define CURRENT_TARGET_BYTE_ORDER \
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(WITH_TARGET_BYTE_ORDER != BFD_ENDIAN_UNKNOWN \
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? WITH_TARGET_BYTE_ORDER : current_target_byte_order)
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/* PowerPC XOR endian.
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In addition to the above, the simulator can support the PowerPC's
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horrible XOR endian mode. This feature makes it possible to
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control the endian mode of a processor using the MSR. */
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#ifndef WITH_XOR_ENDIAN
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#define WITH_XOR_ENDIAN 8
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#endif
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/* SMP support:
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Sets a limit on the number of processors that can be simulated. If
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WITH_SMP is set to zero (0), the simulator is restricted to
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suporting only on processor (and as a consequence leaves the SMP
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code out of the build process).
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The actual number of processors is taken from the device
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/options/smp@<nr-cpu> */
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#ifndef WITH_SMP
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#define WITH_SMP 5
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#endif
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#if WITH_SMP
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#define MAX_NR_PROCESSORS WITH_SMP
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#else
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#define MAX_NR_PROCESSORS 1
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#endif
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/* Word size of target:
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Set these according to your target requirements. At this
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point in time, I've only compiled (not run) for a 64bit and never
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built for a 64bit host. This will always remain a compile time
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option */
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#ifndef WITH_TARGET_WORD_BITSIZE
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#define WITH_TARGET_WORD_BITSIZE 32 /* compiled only */
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#endif
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/* Program environment:
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Three environments are available - UEA (user), VEA (virtual) and
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OEA (perating). The former two are environment that users would
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expect to see (VEA includes things like coherency and the time
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base) while OEA is what an operating system expects to see. By
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setting these to specific values, the build process is able to
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eliminate non relevent environment code
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CURRENT_ENVIRONMENT specifies which of vea or oea is required for
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the current runtime. */
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#define ALL_ENVIRONMENT 0
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#define USER_ENVIRONMENT 1
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#define VIRTUAL_ENVIRONMENT 2
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#define OPERATING_ENVIRONMENT 3
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extern int current_environment;
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#define CURRENT_ENVIRONMENT (WITH_ENVIRONMENT \
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? WITH_ENVIRONMENT \
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: current_environment)
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/* Optional VEA/OEA code:
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The below, required for the OEA model may also be included in the
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VEA model however, as far as I can tell only make things
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slower... */
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/* Events. Devices modeling real H/W need to be able to efficiently
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schedule things to do at known times in the future. The event
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queue implements this. Unfortunatly this adds the need to check
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for any events once each full instruction cycle. */
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#define WITH_EVENTS (WITH_ENVIRONMENT != USER_ENVIRONMENT)
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/* Time base:
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The PowerPC architecture includes the addition of both a time base
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register and a decrement timer. Like events adds to the overhead
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of of some instruction cycles. */
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#ifndef WITH_TIME_BASE
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#define WITH_TIME_BASE (WITH_ENVIRONMENT != USER_ENVIRONMENT)
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#endif
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/* Callback/Default Memory.
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Core includes a builtin memory type (raw_memory) that is
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implemented using an array. raw_memory does not require any
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additional functions etc.
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Callback memory is where the core calls a core device for the data
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it requires.
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Default memory is an extenstion of this where for addresses that do
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not map into either a callback or core memory range a default map
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can be used.
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The OEA model uses callback memory for devices and default memory
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for buses.
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The VEA model uses callback memory to capture `page faults'.
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While it may be possible to eliminate callback/default memory (and
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hence also eliminate an additional test per memory fetch) it
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probably is not worth the effort.
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BTW, while raw_memory could have been implemented as a callback,
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profiling has shown that there is a biger win (at least for the
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x86) in eliminating a function call for the most common
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(raw_memory) case. */
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#define WITH_CALLBACK_MEMORY 1
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/* Alignment:
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The PowerPC may or may not handle miss aligned transfers. An
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implementation normally handles miss aligned transfers in big
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endian mode but generates an exception in little endian mode.
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This model. Instead allows both little and big endian modes to
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either take exceptions or handle miss aligned transfers.
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If 0 is specified then for big-endian mode miss aligned accesses
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are permitted (NONSTRICT_ALIGNMENT) while in little-endian mode the
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processor will fault on them (STRICT_ALIGNMENT). */
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#define NONSTRICT_ALIGNMENT 1
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#define STRICT_ALIGNMENT 2
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#ifndef WITH_ALIGNMENT
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#define WITH_ALIGNMENT 0
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#endif
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extern int current_alignment;
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#define CURRENT_ALIGNMENT (WITH_ALIGNMENT \
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? WITH_ALIGNMENT \
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: current_alignment)
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/* Floating point suport:
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Still under development. */
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#define SOFT_FLOATING_POINT 1
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#define HARD_FLOATING_POINT 2
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#ifndef WITH_FLOATING_POINT
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#define WITH_FLOATING_POINT HARD_FLOATING_POINT
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#endif
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extern int current_floating_point;
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#define CURRENT_FLOATING_POINT (WITH_FLOATING_POINT \
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? WITH_FLOATING_POINT \
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: current_floating_point)
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/* Debugging:
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Control the inclusion of debugging code. */
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/* include monitoring code */
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#define MONITOR_INSTRUCTION_ISSUE 1
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#define MONITOR_LOAD_STORE_UNIT 2
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#ifndef WITH_MON
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#define WITH_MON (MONITOR_LOAD_STORE_UNIT \
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| MONITOR_INSTRUCTION_ISSUE)
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#endif
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/* Current CPU model (models are in the generated models.h include file) */
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#ifndef WITH_MODEL
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#define WITH_MODEL 0
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#endif
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#define CURRENT_MODEL (WITH_MODEL \
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? WITH_MODEL \
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: current_model)
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#ifndef WITH_DEFAULT_MODEL
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#define WITH_DEFAULT_MODEL DEFAULT_MODEL
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#endif
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#define MODEL_ISSUE_IGNORE (-1)
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#define MODEL_ISSUE_PROCESS 1
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#ifndef WITH_MODEL_ISSUE
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#define WITH_MODEL_ISSUE 0
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#endif
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extern int current_model_issue;
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#define CURRENT_MODEL_ISSUE (WITH_MODEL_ISSUE \
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? WITH_MODEL_ISSUE \
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: current_model_issue)
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/* Whether or not input/output just uses stdio, or uses printf_filtered for
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output, and polling input for input. */
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#define DONT_USE_STDIO 2
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#define DO_USE_STDIO 1
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extern int current_stdio;
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#define CURRENT_STDIO (WITH_STDIO \
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? WITH_STDIO \
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: current_stdio)
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/* INLINE CODE SELECTION:
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GCC -O3 attempts to inline any function or procedure in scope. The
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options below facilitate fine grained control over what is and what
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isn't made inline. For instance it can control things down to a
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specific modules static routines. Doing this allows the compiler
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to both eliminate the overhead of function calls and (as a
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consequence) also eliminate further dead code.
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On a CISC (x86) I've found that I can achieve an order of magnitude
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speed improvement (x3-x5). In the case of RISC (sparc) while the
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performance gain isn't as great it is still significant.
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Each module is controled by the macro <module>_INLINE which can
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have the values described below
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0 Do not inline any thing for the given module
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The following additional values are `bit fields' and can be
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combined.
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REVEAL_MODULE:
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Include the C file for the module into the file being compiled
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but do not make the functions within the module inline.
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While of no apparent benefit, this makes it possible for the
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included module, when compiled to inline its calls to what
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would otherwize be external functions.
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INLINE_MODULE:
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Make external functions within the module `inline'. Thus if
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the module is included into a file being compiled, calls to
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its funtions can be eliminated. 2 implies 1.
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INLINE_LOCALS:
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Make internal (static) functions within the module `inline'.
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The following abreviations are available:
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INCLUDE_MODULE == (REVEAL_MODULE | INLINE_MODULE)
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ALL_C_INLINE == (REVEAL_MODULE | INLINE_MODULE | INLINE_LOCALS)
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In addition to this, modules have been put into two categories.
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Simple modules - eg sim-endian.h bits.h
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Because these modules are small and simple and do not have
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any complex interpendencies they are configured, if
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<module>_INLINE is so enabled, to inline themselves in all
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modules that include those files.
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For the default build, this is a real win as all byte
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conversion and bit manipulation functions are inlined.
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Complex modules - the rest
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These are all handled using the files inline.h and inline.c.
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psim.c includes the above which in turn include any remaining
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code.
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IMPLEMENTATION:
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The inline ability is enabled by prefixing every data / function
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declaration and definition with one of the following:
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INLINE_<module>
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Prefix to any global function that is a candidate for being
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inline.
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values - `', `static', `static INLINE'
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EXTERN_<module>
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Prefix to any global data structures for the module. Global
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functions that are not to be inlined shall also be prefixed
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with this.
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values - `', `static', `static'
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STATIC_INLINE_<module>
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Prefix to any local (static) function that is a candidate for
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being made inline.
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values - `static', `static INLINE'
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static
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Prefix all local data structures. Local functions that are not
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to be inlined shall also be prefixed with this.
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values - `static', `static'
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nb: will not work for modules that are being inlined for every
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use (white lie).
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extern
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#ifndef _INLINE_C_
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#endif
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Prefix to any declaration of a global object (function or
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variable) that should not be inlined and should have only one
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definition. The #ifndef wrapper goes around the definition
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propper to ensure that only one copy is generated.
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nb: this will not work when a module is being inlined for every
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use.
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STATIC_<module>
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Replaced by either `static' or `EXTERN_MODULE'.
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REALITY CHECK:
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This is not for the faint hearted. I've seen GCC get up to 500mb
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trying to compile what this can create.
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Some of the modules do not yet implement the WITH_INLINE_STATIC
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option. Instead they use the macro STATIC_INLINE to control their
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local function.
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Because of the way that GCC parses __attribute__(), the macro's
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need to be adjacent to the function name rather than at the start
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of the line vis:
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int STATIC_INLINE_MODULE f(void);
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void INLINE_MODULE *g(void);
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*/
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#include "../common/sim-inline.h"
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#define REVEAL_MODULE H_REVEALS_MODULE
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#define INLINE_MODULE C_REVEALS_MODULE
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#define INCLUDE_MODULE (INLINE_MODULE | REVEAL_MODULE)
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/* Your compilers inline reserved word */
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#ifndef INLINE
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#if defined(__GNUC__) && defined(__OPTIMIZE__)
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#define INLINE __inline__
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#else
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#define INLINE /*inline*/
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#endif
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#endif
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/* Default prefix for static functions */
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#ifndef STATIC_INLINE
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#define STATIC_INLINE static INLINE
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#endif
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/* Default macro to simplify control several of key the inlines */
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#ifndef DEFAULT_INLINE
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#define DEFAULT_INLINE INLINE_LOCALS
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#endif
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/* Code that converts between hosts and target byte order. Used on
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every memory access (instruction and data). See sim-endian.h for
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additional byte swapping configuration information. This module
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can inline for all callers */
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#ifndef SIM_ENDIAN_INLINE
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#define SIM_ENDIAN_INLINE (DEFAULT_INLINE ? ALL_C_INLINE : 0)
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#endif
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/* Low level bit manipulation routines. This module can inline for all
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callers */
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#ifndef BITS_INLINE
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#define BITS_INLINE (DEFAULT_INLINE ? ALL_C_INLINE : 0)
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#endif
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/* Code that gives access to various CPU internals such as registers.
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Used every time an instruction is executed */
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#ifndef CPU_INLINE
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#define CPU_INLINE (DEFAULT_INLINE ? ALL_C_INLINE : 0)
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#endif
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/* Code that translates between an effective and real address. Used
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by every load or store. */
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#ifndef VM_INLINE
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#define VM_INLINE DEFAULT_INLINE
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#endif
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/* Code that loads/stores data to/from the memory data structure.
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Used by every load or store */
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#ifndef CORE_INLINE
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#define CORE_INLINE DEFAULT_INLINE
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#endif
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/* Code to check for and process any events scheduled in the future.
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Called once per instruction cycle */
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#ifndef EVENTS_INLINE
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#define EVENTS_INLINE (DEFAULT_INLINE ? ALL_C_INLINE : 0)
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#endif
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/* Code monotoring the processors performance. It counts events on
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every instruction cycle */
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#ifndef MON_INLINE
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#define MON_INLINE (DEFAULT_INLINE ? ALL_C_INLINE : 0)
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#endif
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/* Code called on the rare occasions that an interrupt occures. */
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#ifndef INTERRUPTS_INLINE
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#define INTERRUPTS_INLINE DEFAULT_INLINE
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#endif
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/* Code called on the rare occasion that either gdb or the device tree
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need to manipulate a register within a processor */
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#ifndef REGISTERS_INLINE
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#define REGISTERS_INLINE DEFAULT_INLINE
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#endif
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/* Code called on the rare occasion that a processor is manipulating
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real hardware instead of RAM.
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Also, most of the functions in devices.c are always called through
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a jump table. */
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#ifndef DEVICE_INLINE
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#define DEVICE_INLINE (DEFAULT_INLINE ? INLINE_LOCALS : 0)
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#endif
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/* Code called used while the device tree is being built.
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Inlining this is of no benefit */
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#ifndef TREE_INLINE
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#define TREE_INLINE (DEFAULT_INLINE ? INLINE_LOCALS : 0)
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#endif
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/* Code called whenever information on a Special Purpose Register is
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required. Called by the mflr/mtlr pseudo instructions */
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#ifndef SPREG_INLINE
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#define SPREG_INLINE DEFAULT_INLINE
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#endif
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/* Functions modeling the semantics of each instruction. Two cases to
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consider, firstly of idecode is implemented with a switch then this
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allows the idecode function to inline each semantic function
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(avoiding a call). The second case is when idecode is using a
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table, even then while the semantic functions can't be inlined,
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setting it to one still enables each semantic function to inline
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anything they call (if that code is marked for being inlined).
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WARNING: you need lots (like 200mb of swap) of swap. Setting this
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to 1 is useful when using a table as it enables the sematic code to
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inline all of their called functions */
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#ifndef SEMANTICS_INLINE
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#define SEMANTICS_INLINE (DEFAULT_INLINE & ~INLINE_MODULE)
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#endif
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/* When using the instruction cache, code to decode an instruction and
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install it into the cache. Normally called when ever there is a
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miss in the instruction cache. */
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#ifndef ICACHE_INLINE
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#define ICACHE_INLINE (DEFAULT_INLINE & ~INLINE_MODULE)
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#endif
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/* General functions called by semantics functions but part of the
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instruction table. Although called by the semantic functions the
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frequency of calls is low. Consequently the need to inline this
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code is reduced. */
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#ifndef SUPPORT_INLINE
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#define SUPPORT_INLINE INLINE_LOCALS
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#endif
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/* Model specific code used in simulating functional units. Note, it actaully
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pays NOT to inline the PowerPC model functions (at least on the x86). This
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is because if it is inlined, each PowerPC instruction gets a separate copy
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of the code, which is not friendly to the cache. */
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#ifndef MODEL_INLINE
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#define MODEL_INLINE (DEFAULT_INLINE & ~INLINE_MODULE)
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#endif
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/* Code to print out what options we were compiled with. Because this
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is called at process startup, it doesn't have to be inlined, but
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if it isn't brought in and the model routines are inline, the model
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routines will be pulled in twice. */
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#ifndef OPTIONS_INLINE
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#define OPTIONS_INLINE MODEL_INLINE
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#endif
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/* idecode acts as the hub of the system, everything else is imported
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into this file */
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#ifndef IDECOCE_INLINE
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#define IDECODE_INLINE INLINE_LOCALS
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#endif
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/* psim, isn't actually inlined */
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#ifndef PSIM_INLINE
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#define PSIM_INLINE INLINE_LOCALS
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#endif
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/* Code to emulate os or rom compatibility. This code is called via a
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table and hence there is little benefit in making it inline */
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#ifndef OS_EMUL_INLINE
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#define OS_EMUL_INLINE 0
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#endif
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#endif /* _PSIM_CONFIG_H */
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