config/arm/arm.h

1.1  mrg /* Definitions of target machine for GNU compiler, for ARM.
1.1  mrg    Copyright (C) 1991, 1993, 1994, 1995, 1996, 1997, 1998, 1999, 2000,
1.1  mrg    2001, 2002, 2003, 2004, 2005, 2006, 2007, 2008, 2009
1.1  mrg    Free Software Foundation, Inc.
1.1  mrg    Contributed by Pieter `Tiggr' Schoenmakers (rcpieter (at) win.tue.nl)
1.1  mrg    and Martin Simmons (@harleqn.co.uk).
1.1  mrg    More major hacks by Richard Earnshaw (rearnsha (at) arm.com)
1.1  mrg    Minor hacks by Nick Clifton (nickc (at) cygnus.com)
1.1  mrg
1.1  mrg    This file is part of GCC.
1.1  mrg
1.1  mrg    GCC is free software; you can redistribute it and/or modify it
1.1  mrg    under the terms of the GNU General Public License as published
1.1  mrg    by the Free Software Foundation; either version 3, or (at your
1.1  mrg    option) any later version.
1.1  mrg
1.1  mrg    GCC is distributed in the hope that it will be useful, but WITHOUT
1.1  mrg    ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
1.1  mrg    or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public
1.1  mrg    License for more details.
1.1  mrg
1.1  mrg    You should have received a copy of the GNU General Public License
1.1  mrg    along with GCC; see the file COPYING3.  If not see
1.1  mrg    <http://www.gnu.org/licenses/>.  */
1.1  mrg
1.1  mrg #ifndef GCC_ARM_H
1.1  mrg #define GCC_ARM_H
1.1  mrg
1.1  mrg /* We can't use enum machine_mode inside a generator file because it
1.1  mrg    hasn't been created yet; we shouldn't be using any code that
1.1  mrg    needs the real definition though, so this ought to be safe.  */
1.1  mrg #ifdef GENERATOR_FILE
1.1  mrg #define MACHMODE int
1.1  mrg #else
1.1  mrg #include "insn-modes.h"
1.1  mrg #define MACHMODE enum machine_mode
1.1  mrg #endif
1.1  mrg
1.1  mrg #include "config/vxworks-dummy.h"
1.1  mrg
1.1  mrg /* The architecture define.  */
1.1  mrg extern char arm_arch_name[];
1.1  mrg
1.1  mrg /* Target CPU builtins.  */
1.1  mrg #define TARGET_CPU_CPP_BUILTINS()			\
1.1  mrg   do							\
1.1  mrg     {							\
1.1  mrg 	/* Define __arm__ even when in thumb mode, for	\
1.1  mrg 	   consistency with armcc.  */			\
1.1  mrg 	builtin_define ("__arm__");			\
1.1  mrg 	builtin_define ("__APCS_32__");			\
1.1  mrg 	if (TARGET_THUMB)				\
1.1  mrg 	  builtin_define ("__thumb__");			\
1.1  mrg 	if (TARGET_THUMB2)				\
1.1  mrg 	  builtin_define ("__thumb2__");		\
1.1  mrg 							\
1.1  mrg 	if (TARGET_BIG_END)				\
1.1  mrg 	  {						\
1.1  mrg 	    builtin_define ("__ARMEB__");		\
1.1  mrg 	    if (TARGET_THUMB)				\
1.1  mrg 	      builtin_define ("__THUMBEB__");		\
1.1  mrg 	    if (TARGET_LITTLE_WORDS)			\
1.1  mrg 	      builtin_define ("__ARMWEL__");		\
1.1  mrg 	  }						\
1.1  mrg         else						\
1.1  mrg 	  {						\
1.1  mrg 	    builtin_define ("__ARMEL__");		\
1.1  mrg 	    if (TARGET_THUMB)				\
1.1  mrg 	      builtin_define ("__THUMBEL__");		\
1.1  mrg 	  }						\
1.1  mrg 							\
1.1  mrg 	if (TARGET_SOFT_FLOAT)				\
1.1  mrg 	  builtin_define ("__SOFTFP__");		\
1.1  mrg 							\
1.1  mrg 	if (TARGET_VFP)					\
1.1  mrg 	  builtin_define ("__VFP_FP__");		\
1.1  mrg 							\
1.1  mrg 	if (TARGET_NEON)				\
1.1  mrg 	  builtin_define ("__ARM_NEON__");		\
1.1  mrg 							\
1.1  mrg 	/* Add a define for interworking.		\
1.1  mrg 	   Needed when building libgcc.a.  */		\
1.1  mrg 	if (arm_cpp_interwork)				\
1.1  mrg 	  builtin_define ("__THUMB_INTERWORK__");	\
1.1  mrg 							\
1.1  mrg 	builtin_assert ("cpu=arm");			\
1.1  mrg 	builtin_assert ("machine=arm");			\
1.1  mrg 							\
1.1  mrg 	builtin_define (arm_arch_name);			\
1.1  mrg 	if (arm_arch_cirrus)				\
1.1  mrg 	  builtin_define ("__MAVERICK__");		\
1.1  mrg 	if (arm_arch_xscale)				\
1.1  mrg 	  builtin_define ("__XSCALE__");		\
1.1  mrg 	if (arm_arch_iwmmxt)				\
1.1  mrg 	  builtin_define ("__IWMMXT__");		\
1.1  mrg 	if (TARGET_AAPCS_BASED)				\
1.1  mrg 	  {						\
1.1  mrg 	    builtin_define ("__ARM_EABI__");		\
1.1  mrg 	    builtin_define ("__ARM_PCS");		\
1.1  mrg 	    if (TARGET_HARD_FLOAT && TARGET_VFP)	\
1.1  mrg 	      builtin_define ("__ARM_PCS_VFP");		\
1.1  mrg 	  }						\
1.1  mrg 	if (TARGET_IDIV)				\
1.1  mrg 	  builtin_define ("__ARM_ARCH_EXT_IDIV__");	\
1.1  mrg     } while (0)
1.1  mrg
1.1  mrg /* The various ARM cores.  */
1.1  mrg enum processor_type
1.1  mrg {
1.1  mrg #define ARM_CORE(NAME, IDENT, ARCH, FLAGS, COSTS) \
1.1  mrg   IDENT,
1.1  mrg #include "arm-cores.def"
1.1  mrg #undef ARM_CORE
1.1  mrg   /* Used to indicate that no processor has been specified.  */
1.1  mrg   arm_none
1.1  mrg };
1.1  mrg
1.1  mrg enum target_cpus
1.1  mrg {
1.1  mrg #define ARM_CORE(NAME, IDENT, ARCH, FLAGS, COSTS) \
1.1  mrg   TARGET_CPU_##IDENT,
1.1  mrg #include "arm-cores.def"
1.1  mrg #undef ARM_CORE
1.1  mrg   TARGET_CPU_generic
1.1  mrg };
1.1  mrg
1.1  mrg /* The processor for which instructions should be scheduled.  */
1.1  mrg extern enum processor_type arm_tune;
1.1  mrg
1.1  mrg typedef enum arm_cond_code
1.1  mrg {
1.1  mrg   ARM_EQ = 0, ARM_NE, ARM_CS, ARM_CC, ARM_MI, ARM_PL, ARM_VS, ARM_VC,
1.1  mrg   ARM_HI, ARM_LS, ARM_GE, ARM_LT, ARM_GT, ARM_LE, ARM_AL, ARM_NV
1.1  mrg }
1.1  mrg arm_cc;
1.1  mrg
1.1  mrg extern arm_cc arm_current_cc;
1.1  mrg
1.1  mrg #define ARM_INVERSE_CONDITION_CODE(X)  ((arm_cc) (((int)X) ^ 1))
1.1  mrg
1.1  mrg extern int arm_target_label;
1.1  mrg extern int arm_ccfsm_state;
1.1  mrg extern GTY(()) rtx arm_target_insn;
1.1  mrg /* The label of the current constant pool.  */
1.1  mrg extern rtx pool_vector_label;
1.1  mrg /* Set to 1 when a return insn is output, this means that the epilogue
1.1  mrg    is not needed.  */
1.1  mrg extern int return_used_this_function;
1.1  mrg /* Callback to output language specific object attributes.  */
1.1  mrg extern void (*arm_lang_output_object_attributes_hook)(void);
1.1  mrg
1.1  mrg /* Just in case configure has failed to define anything.  */
1.1  mrg #ifndef TARGET_CPU_DEFAULT
1.1  mrg #define TARGET_CPU_DEFAULT TARGET_CPU_generic
1.1  mrg #endif
1.1  mrg
1.1  mrg
1.1  mrg #undef  CPP_SPEC
1.1  mrg #define CPP_SPEC "%(subtarget_cpp_spec)					\
1.1  mrg %{msoft-float:%{mhard-float:						\
1.1  mrg 	%e-msoft-float and -mhard_float may not be used together}}	\
1.1  mrg %{mbig-endian:%{mlittle-endian:						\
1.1  mrg 	%e-mbig-endian and -mlittle-endian may not be used together}}"
1.1  mrg
1.1  mrg #ifndef CC1_SPEC
1.1  mrg #define CC1_SPEC ""
1.1  mrg #endif
1.1  mrg
1.1  mrg /* This macro defines names of additional specifications to put in the specs
1.1  mrg    that can be used in various specifications like CC1_SPEC.  Its definition
1.1  mrg    is an initializer with a subgrouping for each command option.
1.1  mrg
1.1  mrg    Each subgrouping contains a string constant, that defines the
1.1  mrg    specification name, and a string constant that used by the GCC driver
1.1  mrg    program.
1.1  mrg
1.1  mrg    Do not define this macro if it does not need to do anything.  */
1.1  mrg #define EXTRA_SPECS						\
1.1  mrg   { "subtarget_cpp_spec",	SUBTARGET_CPP_SPEC },           \
1.1  mrg   SUBTARGET_EXTRA_SPECS
1.1  mrg
1.1  mrg #ifndef SUBTARGET_EXTRA_SPECS
1.1  mrg #define SUBTARGET_EXTRA_SPECS
1.1  mrg #endif
1.1  mrg
1.1  mrg #ifndef SUBTARGET_CPP_SPEC
1.1  mrg #define SUBTARGET_CPP_SPEC      ""
1.1  mrg #endif
1.1  mrg
1.1  mrg /* Run-time Target Specification.  */
1.1  mrg #ifndef TARGET_VERSION
1.1  mrg #define TARGET_VERSION fputs (" (ARM/generic)", stderr);
1.1  mrg #endif
1.1  mrg
1.1  mrg #define TARGET_SOFT_FLOAT		(arm_float_abi == ARM_FLOAT_ABI_SOFT)
1.1  mrg /* Use hardware floating point instructions. */
1.1  mrg #define TARGET_HARD_FLOAT		(arm_float_abi != ARM_FLOAT_ABI_SOFT)
1.1  mrg /* Use hardware floating point calling convention.  */
1.1  mrg #define TARGET_HARD_FLOAT_ABI		(arm_float_abi == ARM_FLOAT_ABI_HARD)
1.1  mrg #define TARGET_FPA		(arm_fpu_desc->model == ARM_FP_MODEL_FPA)
1.1  mrg #define TARGET_MAVERICK		(arm_fpu_desc->model == ARM_FP_MODEL_MAVERICK)
1.1  mrg #define TARGET_VFP		(arm_fpu_desc->model == ARM_FP_MODEL_VFP)
1.1  mrg #define TARGET_IWMMXT			(arm_arch_iwmmxt)
1.1  mrg #define TARGET_REALLY_IWMMXT		(TARGET_IWMMXT && TARGET_32BIT)
1.1  mrg #define TARGET_IWMMXT_ABI (TARGET_32BIT && arm_abi == ARM_ABI_IWMMXT)
1.1  mrg #define TARGET_ARM                      (! TARGET_THUMB)
1.1  mrg #define TARGET_EITHER			1 /* (TARGET_ARM | TARGET_THUMB) */
1.1  mrg #define TARGET_BACKTRACE	        (leaf_function_p () \
1.1  mrg 				         ? TARGET_TPCS_LEAF_FRAME \
1.1  mrg 				         : TARGET_TPCS_FRAME)
1.1  mrg #define TARGET_LDRD			(arm_arch5e && ARM_DOUBLEWORD_ALIGN)
1.1  mrg #define TARGET_AAPCS_BASED \
1.1  mrg     (arm_abi != ARM_ABI_APCS && arm_abi != ARM_ABI_ATPCS)
1.1  mrg
1.1  mrg #define TARGET_HARD_TP			(target_thread_pointer == TP_CP15)
1.1  mrg #define TARGET_SOFT_TP			(target_thread_pointer == TP_SOFT)
1.1  mrg
1.1  mrg /* Only 16-bit thumb code.  */
1.1  mrg #define TARGET_THUMB1			(TARGET_THUMB && !arm_arch_thumb2)
1.1  mrg /* Arm or Thumb-2 32-bit code.  */
1.1  mrg #define TARGET_32BIT			(TARGET_ARM || arm_arch_thumb2)
1.1  mrg /* 32-bit Thumb-2 code.  */
1.1  mrg #define TARGET_THUMB2			(TARGET_THUMB && arm_arch_thumb2)
1.1  mrg /* Thumb-1 only.  */
1.1  mrg #define TARGET_THUMB1_ONLY		(TARGET_THUMB1 && !arm_arch_notm)
1.1  mrg /* FPA emulator without LFM.  */
1.1  mrg #define TARGET_FPA_EMU2			(TARGET_FPA && arm_fpu_desc->rev == 2)
1.1  mrg
1.1  mrg /* The following two macros concern the ability to execute coprocessor
1.1  mrg    instructions for VFPv3 or NEON.  TARGET_VFP3/TARGET_VFPD32 are currently
1.1  mrg    only ever tested when we know we are generating for VFP hardware; we need
1.1  mrg    to be more careful with TARGET_NEON as noted below.  */
1.1  mrg
1.1  mrg /* FPU is has the full VFPv3/NEON register file of 32 D registers.  */
1.1  mrg #define TARGET_VFPD32 (TARGET_VFP && arm_fpu_desc->regs == VFP_REG_D32)
1.1  mrg
1.1  mrg /* FPU supports VFPv3 instructions.  */
1.1  mrg #define TARGET_VFP3 (TARGET_VFP && arm_fpu_desc->rev >= 3)
1.1  mrg
1.1  mrg /* FPU only supports VFP single-precision instructions.  */
1.1  mrg #define TARGET_VFP_SINGLE (TARGET_VFP && arm_fpu_desc->regs == VFP_REG_SINGLE)
1.1  mrg
1.1  mrg /* FPU supports VFP double-precision instructions.  */
1.1  mrg #define TARGET_VFP_DOUBLE (TARGET_VFP && arm_fpu_desc->regs != VFP_REG_SINGLE)
1.1  mrg
1.1  mrg /* FPU supports half-precision floating-point with NEON element load/store.  */
1.1  mrg #define TARGET_NEON_FP16 \
1.1  mrg   (TARGET_VFP && arm_fpu_desc->neon && arm_fpu_desc->fp16)
1.1  mrg
1.1  mrg /* FPU supports VFP half-precision floating-point.  */
1.1  mrg #define TARGET_FP16 (TARGET_VFP && arm_fpu_desc->fp16)
1.1  mrg
1.1  mrg /* FPU supports Neon instructions.  The setting of this macro gets
1.1  mrg    revealed via __ARM_NEON__ so we add extra guards upon TARGET_32BIT
1.1  mrg    and TARGET_HARD_FLOAT to ensure that NEON instructions are
1.1  mrg    available.  */
1.1  mrg #define TARGET_NEON (TARGET_32BIT && TARGET_HARD_FLOAT \
1.1  mrg 		     && TARGET_VFP && arm_fpu_desc->neon)
1.1  mrg
1.1  mrg /* "DSP" multiply instructions, eg. SMULxy.  */
1.1  mrg #define TARGET_DSP_MULTIPLY \
1.1  mrg   (TARGET_32BIT && arm_arch5e && (arm_arch_notm || arm_arch7em))
1.1  mrg /* Integer SIMD instructions, and extend-accumulate instructions.  */
1.1  mrg #define TARGET_INT_SIMD \
1.1  mrg   (TARGET_32BIT && arm_arch6 && (arm_arch_notm || arm_arch7em))
1.1  mrg
1.1  mrg /* Should MOVW/MOVT be used in preference to a constant pool.  */
1.1  mrg #define TARGET_USE_MOVT (arm_arch_thumb2 && !optimize_size)
1.1  mrg
1.1  mrg /* We could use unified syntax for arm mode, but for now we just use it
1.1  mrg    for Thumb-2.  */
1.1  mrg #define TARGET_UNIFIED_ASM TARGET_THUMB2
1.1  mrg
1.1  mrg /* Nonzero if integer division instructions supported.  */
1.1  mrg #define TARGET_IDIV (arm_arch_hwdiv)
1.1  mrg
1.1  mrg /* True iff the full BPABI is being used.  If TARGET_BPABI is true,
1.1  mrg    then TARGET_AAPCS_BASED must be true -- but the converse does not
1.1  mrg    hold.  TARGET_BPABI implies the use of the BPABI runtime library,
1.1  mrg    etc., in addition to just the AAPCS calling conventions.  */
1.1  mrg #ifndef TARGET_BPABI
1.1  mrg #define TARGET_BPABI false
1.1  mrg #endif
1.1  mrg
1.1  mrg /* Support for a compile-time default CPU, et cetera.  The rules are:
1.1  mrg    --with-arch is ignored if -march or -mcpu are specified.
1.1  mrg    --with-cpu is ignored if -march or -mcpu are specified, and is overridden
1.1  mrg     by --with-arch.
1.1  mrg    --with-tune is ignored if -mtune or -mcpu are specified (but not affected
1.1  mrg      by -march).
1.1  mrg    --with-float is ignored if -mhard-float, -msoft-float or -mfloat-abi are
1.1  mrg    specified.
1.1  mrg    --with-fpu is ignored if -mfpu is specified.
1.1  mrg    --with-abi is ignored is -mabi is specified.  */
1.1  mrg #define OPTION_DEFAULT_SPECS \
1.1  mrg   {"arch", "%{!march=*:%{!mcpu=*:-march=%(VALUE)}}" }, \
1.1  mrg   {"cpu", "%{!march=*:%{!mcpu=*:-mcpu=%(VALUE)}}" }, \
1.1  mrg   {"tune", "%{!mcpu=*:%{!mtune=*:-mtune=%(VALUE)}}" }, \
1.1  mrg   {"float", \
1.1  mrg     "%{!msoft-float:%{!mhard-float:%{!mfloat-abi=*:-mfloat-abi=%(VALUE)}}}" }, \
1.1  mrg   {"fpu", "%{!mfpu=*:-mfpu=%(VALUE)}"}, \
1.1  mrg   {"abi", "%{!mabi=*:-mabi=%(VALUE)}"}, \
1.1  mrg   {"mode", "%{!marm:%{!mthumb:-m%(VALUE)}}"},
1.1  mrg
1.1  mrg /* Which floating point model to use.  */
1.1  mrg enum arm_fp_model
1.1  mrg {
1.1  mrg   ARM_FP_MODEL_UNKNOWN,
1.1  mrg   /* FPA model (Hardware or software).  */
1.1  mrg   ARM_FP_MODEL_FPA,
1.1  mrg   /* Cirrus Maverick floating point model.  */
1.1  mrg   ARM_FP_MODEL_MAVERICK,
1.1  mrg   /* VFP floating point model.  */
1.1  mrg   ARM_FP_MODEL_VFP
1.1  mrg };
1.1  mrg
1.1  mrg enum vfp_reg_type
1.1  mrg {
1.1  mrg   VFP_NONE = 0,
1.1  mrg   VFP_REG_D16,
1.1  mrg   VFP_REG_D32,
1.1  mrg   VFP_REG_SINGLE
1.1  mrg };
1.1  mrg
1.1  mrg extern const struct arm_fpu_desc
1.1  mrg {
1.1  mrg   const char *name;
1.1  mrg   enum arm_fp_model model;
1.1  mrg   int rev;
1.1  mrg   enum vfp_reg_type regs;
1.1  mrg   int neon;
1.1  mrg   int fp16;
1.1  mrg } *arm_fpu_desc;
1.1  mrg
1.1  mrg /* Which floating point hardware to schedule for.  */
1.1  mrg extern int arm_fpu_attr;
1.1  mrg
1.1  mrg enum float_abi_type
1.1  mrg {
1.1  mrg   ARM_FLOAT_ABI_SOFT,
1.1  mrg   ARM_FLOAT_ABI_SOFTFP,
1.1  mrg   ARM_FLOAT_ABI_HARD
1.1  mrg };
1.1  mrg
1.1  mrg extern enum float_abi_type arm_float_abi;
1.1  mrg
1.1  mrg #ifndef TARGET_DEFAULT_FLOAT_ABI
1.1  mrg #define TARGET_DEFAULT_FLOAT_ABI ARM_FLOAT_ABI_SOFT
1.1  mrg #endif
1.1  mrg
1.1  mrg /* Which __fp16 format to use.
1.1  mrg    The enumeration values correspond to the numbering for the
1.1  mrg    Tag_ABI_FP_16bit_format attribute.
1.1  mrg  */
1.1  mrg enum arm_fp16_format_type
1.1  mrg {
1.1  mrg   ARM_FP16_FORMAT_NONE = 0,
1.1  mrg   ARM_FP16_FORMAT_IEEE = 1,
1.1  mrg   ARM_FP16_FORMAT_ALTERNATIVE = 2
1.1  mrg };
1.1  mrg
1.1  mrg extern enum arm_fp16_format_type arm_fp16_format;
1.1  mrg #define LARGEST_EXPONENT_IS_NORMAL(bits) \
1.1  mrg     ((bits) == 16 && arm_fp16_format == ARM_FP16_FORMAT_ALTERNATIVE)
1.1  mrg
1.1  mrg /* Which ABI to use.  */
1.1  mrg enum arm_abi_type
1.1  mrg {
1.1  mrg   ARM_ABI_APCS,
1.1  mrg   ARM_ABI_ATPCS,
1.1  mrg   ARM_ABI_AAPCS,
1.1  mrg   ARM_ABI_IWMMXT,
1.1  mrg   ARM_ABI_AAPCS_LINUX
1.1  mrg };
1.1  mrg
1.1  mrg extern enum arm_abi_type arm_abi;
1.1  mrg
1.1  mrg #ifndef ARM_DEFAULT_ABI
1.1  mrg #define ARM_DEFAULT_ABI ARM_ABI_APCS
1.1  mrg #endif
1.1  mrg
1.1  mrg /* Which thread pointer access sequence to use.  */
1.1  mrg enum arm_tp_type {
1.1  mrg   TP_AUTO,
1.1  mrg   TP_SOFT,
1.1  mrg   TP_CP15
1.1  mrg };
1.1  mrg
1.1  mrg extern enum arm_tp_type target_thread_pointer;
1.1  mrg
1.1  mrg /* Nonzero if this chip supports the ARM Architecture 3M extensions.  */
1.1  mrg extern int arm_arch3m;
1.1  mrg
1.1  mrg /* Nonzero if this chip supports the ARM Architecture 4 extensions.  */
1.1  mrg extern int arm_arch4;
1.1  mrg
1.1  mrg /* Nonzero if this chip supports the ARM Architecture 4T extensions.  */
1.1  mrg extern int arm_arch4t;
1.1  mrg
1.1  mrg /* Nonzero if this chip supports the ARM Architecture 5 extensions.  */
1.1  mrg extern int arm_arch5;
1.1  mrg
1.1  mrg /* Nonzero if this chip supports the ARM Architecture 5E extensions.  */
1.1  mrg extern int arm_arch5e;
1.1  mrg
1.1  mrg /* Nonzero if this chip supports the ARM Architecture 6 extensions.  */
1.1  mrg extern int arm_arch6;
1.1  mrg
1.1  mrg /* Nonzero if instructions not present in the 'M' profile can be used.  */
1.1  mrg extern int arm_arch_notm;
1.1  mrg
1.1  mrg /* Nonzero if instructions present in ARMv7E-M can be used.  */
1.1  mrg extern int arm_arch7em;
1.1  mrg
1.1  mrg /* Nonzero if this chip can benefit from load scheduling.  */
1.1  mrg extern int arm_ld_sched;
1.1  mrg
1.1  mrg /* Nonzero if generating thumb code.  */
1.1  mrg extern int thumb_code;
1.1  mrg
1.1  mrg /* Nonzero if this chip is a StrongARM.  */
1.1  mrg extern int arm_tune_strongarm;
1.1  mrg
1.1  mrg /* Nonzero if this chip is a Cirrus variant.  */
1.1  mrg extern int arm_arch_cirrus;
1.1  mrg
1.1  mrg /* Nonzero if this chip supports Intel XScale with Wireless MMX technology.  */
1.1  mrg extern int arm_arch_iwmmxt;
1.1  mrg
1.1  mrg /* Nonzero if this chip is an XScale.  */
1.1  mrg extern int arm_arch_xscale;
1.1  mrg
1.1  mrg /* Nonzero if tuning for XScale.  */
1.1  mrg extern int arm_tune_xscale;
1.1  mrg
1.1  mrg /* Nonzero if tuning for stores via the write buffer.  */
1.1  mrg extern int arm_tune_wbuf;
1.1  mrg
1.1  mrg /* Nonzero if tuning for Cortex-A9.  */
1.1  mrg extern int arm_tune_cortex_a9;
1.1  mrg
1.1  mrg /* Nonzero if we should define __THUMB_INTERWORK__ in the
1.1  mrg    preprocessor.
1.1  mrg    XXX This is a bit of a hack, it's intended to help work around
1.1  mrg    problems in GLD which doesn't understand that armv5t code is
1.1  mrg    interworking clean.  */
1.1  mrg extern int arm_cpp_interwork;
1.1  mrg
1.1  mrg /* Nonzero if chip supports Thumb 2.  */
1.1  mrg extern int arm_arch_thumb2;
1.1  mrg
1.1  mrg /* Nonzero if chip supports integer division instruction.  */
1.1  mrg extern int arm_arch_hwdiv;
1.1  mrg
1.1  mrg #ifndef TARGET_DEFAULT
1.1  mrg #define TARGET_DEFAULT  (MASK_APCS_FRAME)
1.1  mrg #endif
1.1  mrg
1.1  mrg /* The frame pointer register used in gcc has nothing to do with debugging;
1.1  mrg    that is controlled by the APCS-FRAME option.  */
1.1  mrg #define CAN_DEBUG_WITHOUT_FP
1.1  mrg
1.1  mrg #define OVERRIDE_OPTIONS  arm_override_options ()
1.1  mrg
1.1  mrg #define OPTIMIZATION_OPTIONS(LEVEL,SIZE)		\
1.1  mrg 	arm_optimization_options ((LEVEL), (SIZE))
1.1  mrg
1.1  mrg /* Nonzero if PIC code requires explicit qualifiers to generate
1.1  mrg    PLT and GOT relocs rather than the assembler doing so implicitly.
1.1  mrg    Subtargets can override these if required.  */
1.1  mrg #ifndef NEED_GOT_RELOC
1.1  mrg #define NEED_GOT_RELOC	0
1.1  mrg #endif
1.1  mrg #ifndef NEED_PLT_RELOC
1.1  mrg #define NEED_PLT_RELOC	0
1.1  mrg #endif
1.1  mrg
1.1  mrg /* Nonzero if we need to refer to the GOT with a PC-relative
1.1  mrg    offset.  In other words, generate
1.1  mrg
1.1  mrg    .word	_GLOBAL_OFFSET_TABLE_ - [. - (.Lxx + 8)]
1.1  mrg
1.1  mrg    rather than
1.1  mrg
1.1  mrg    .word	_GLOBAL_OFFSET_TABLE_ - (.Lxx + 8)
1.1  mrg
1.1  mrg    The default is true, which matches NetBSD.  Subtargets can
1.1  mrg    override this if required.  */
1.1  mrg #ifndef GOT_PCREL
1.1  mrg #define GOT_PCREL   1
1.1  mrg #endif
1.1  mrg
1.1  mrg /* Target machine storage Layout.  */
1.1  mrg
1.1  mrg
1.1  mrg /* Define this macro if it is advisable to hold scalars in registers
1.1  mrg    in a wider mode than that declared by the program.  In such cases,
1.1  mrg    the value is constrained to be within the bounds of the declared
1.1  mrg    type, but kept valid in the wider mode.  The signedness of the
1.1  mrg    extension may differ from that of the type.  */
1.1  mrg
1.1  mrg /* It is far faster to zero extend chars than to sign extend them */
1.1  mrg
1.1  mrg #define PROMOTE_MODE(MODE, UNSIGNEDP, TYPE)	\
1.1  mrg   if (GET_MODE_CLASS (MODE) == MODE_INT		\
1.1  mrg       && GET_MODE_SIZE (MODE) < 4)      	\
1.1  mrg     {						\
1.1  mrg       if (MODE == QImode)			\
1.1  mrg 	UNSIGNEDP = 1;				\
1.1  mrg       else if (MODE == HImode)			\
1.1  mrg 	UNSIGNEDP = 1;				\
1.1  mrg       (MODE) = SImode;				\
1.1  mrg     }
1.1  mrg
1.1  mrg /* Define this if most significant bit is lowest numbered
1.1  mrg    in instructions that operate on numbered bit-fields.  */
1.1  mrg #define BITS_BIG_ENDIAN  0
1.1  mrg
1.1  mrg /* Define this if most significant byte of a word is the lowest numbered.
1.1  mrg    Most ARM processors are run in little endian mode, so that is the default.
1.1  mrg    If you want to have it run-time selectable, change the definition in a
1.1  mrg    cover file to be TARGET_BIG_ENDIAN.  */
1.1  mrg #define BYTES_BIG_ENDIAN  (TARGET_BIG_END != 0)
1.1  mrg
1.1  mrg /* Define this if most significant word of a multiword number is the lowest
1.1  mrg    numbered.
1.1  mrg    This is always false, even when in big-endian mode.  */
1.1  mrg #define WORDS_BIG_ENDIAN  (BYTES_BIG_ENDIAN && ! TARGET_LITTLE_WORDS)
1.1  mrg
1.1  mrg /* LIBGCC2_WORDS_BIG_ENDIAN has to be a constant, so we define this based
1.1  mrg    on processor pre-defineds when compiling libgcc2.c.  */
1.1  mrg #if defined(__ARMEB__) && !defined(__ARMWEL__)
1.1  mrg #define LIBGCC2_WORDS_BIG_ENDIAN 1
1.1  mrg #else
1.1  mrg #define LIBGCC2_WORDS_BIG_ENDIAN 0
1.1  mrg #endif
1.1  mrg
1.1  mrg /* Define this if most significant word of doubles is the lowest numbered.
1.1  mrg    The rules are different based on whether or not we use FPA-format,
1.1  mrg    VFP-format or some other floating point co-processor's format doubles.  */
1.1  mrg #define FLOAT_WORDS_BIG_ENDIAN (arm_float_words_big_endian ())
1.1  mrg
1.1  mrg #define UNITS_PER_WORD	4
1.1  mrg
1.1  mrg /* Use the option -mvectorize-with-neon-quad to override the use of doubleword
1.1  mrg    registers when autovectorizing for Neon, at least until multiple vector
1.1  mrg    widths are supported properly by the middle-end.  */
1.1  mrg #define UNITS_PER_SIMD_WORD(MODE) \
1.1  mrg   (TARGET_NEON ? (TARGET_NEON_VECTORIZE_QUAD ? 16 : 8) : UNITS_PER_WORD)
1.1  mrg
1.1  mrg /* True if natural alignment is used for doubleword types.  */
1.1  mrg #define ARM_DOUBLEWORD_ALIGN	TARGET_AAPCS_BASED
1.1  mrg
1.1  mrg #define DOUBLEWORD_ALIGNMENT 64
1.1  mrg
1.1  mrg #define PARM_BOUNDARY  	32
1.1  mrg
1.1  mrg #define STACK_BOUNDARY  (ARM_DOUBLEWORD_ALIGN ? DOUBLEWORD_ALIGNMENT : 32)
1.1  mrg
1.1  mrg #define PREFERRED_STACK_BOUNDARY \
1.1  mrg     (arm_abi == ARM_ABI_ATPCS ? 64 : STACK_BOUNDARY)
1.1  mrg
1.1  mrg #define FUNCTION_BOUNDARY  ((TARGET_THUMB && optimize_size) ? 16 : 32)
1.1  mrg
1.1  mrg /* The lowest bit is used to indicate Thumb-mode functions, so the
1.1  mrg    vbit must go into the delta field of pointers to member
1.1  mrg    functions.  */
1.1  mrg #define TARGET_PTRMEMFUNC_VBIT_LOCATION ptrmemfunc_vbit_in_delta
1.1  mrg
1.1  mrg #define EMPTY_FIELD_BOUNDARY  32
1.1  mrg
1.1  mrg #define BIGGEST_ALIGNMENT (ARM_DOUBLEWORD_ALIGN ? DOUBLEWORD_ALIGNMENT : 32)
1.1  mrg
1.1  mrg /* XXX Blah -- this macro is used directly by libobjc.  Since it
1.1  mrg    supports no vector modes, cut out the complexity and fall back
1.1  mrg    on BIGGEST_FIELD_ALIGNMENT.  */
1.1  mrg #ifdef IN_TARGET_LIBS
1.1  mrg #define BIGGEST_FIELD_ALIGNMENT 64
1.1  mrg #endif
1.1  mrg
1.1  mrg /* Make strings word-aligned so strcpy from constants will be faster.  */
1.1  mrg #define CONSTANT_ALIGNMENT_FACTOR (TARGET_THUMB || ! arm_tune_xscale ? 1 : 2)
1.1  mrg
1.1  mrg #define CONSTANT_ALIGNMENT(EXP, ALIGN)				\
1.1  mrg    ((TREE_CODE (EXP) == STRING_CST				\
1.1  mrg      && !optimize_size						\
1.1  mrg      && (ALIGN) < BITS_PER_WORD * CONSTANT_ALIGNMENT_FACTOR)	\
1.1  mrg     ? BITS_PER_WORD * CONSTANT_ALIGNMENT_FACTOR : (ALIGN))
1.1  mrg
1.1  mrg /* Align definitions of arrays, unions and structures so that
1.1  mrg    initializations and copies can be made more efficient.  This is not
1.1  mrg    ABI-changing, so it only affects places where we can see the
1.1  mrg    definition.  */
1.1  mrg #define DATA_ALIGNMENT(EXP, ALIGN)					\
1.1  mrg   ((((ALIGN) < BITS_PER_WORD)                                           \
1.1  mrg     && (TREE_CODE (EXP) == ARRAY_TYPE					\
1.1  mrg 	|| TREE_CODE (EXP) == UNION_TYPE				\
1.1  mrg 	|| TREE_CODE (EXP) == RECORD_TYPE)) ? BITS_PER_WORD : (ALIGN))
1.1  mrg
1.1  mrg /* Similarly, make sure that objects on the stack are sensibly aligned.  */
1.1  mrg #define LOCAL_ALIGNMENT(EXP, ALIGN) DATA_ALIGNMENT(EXP, ALIGN)
1.1  mrg
1.1  mrg /* Setting STRUCTURE_SIZE_BOUNDARY to 32 produces more efficient code, but the
1.1  mrg    value set in previous versions of this toolchain was 8, which produces more
1.1  mrg    compact structures.  The command line option -mstructure_size_boundary=<n>
1.1  mrg    can be used to change this value.  For compatibility with the ARM SDK
1.1  mrg    however the value should be left at 32.  ARM SDT Reference Manual (ARM DUI
1.1  mrg    0020D) page 2-20 says "Structures are aligned on word boundaries".
1.1  mrg    The AAPCS specifies a value of 8.  */
1.1  mrg #define STRUCTURE_SIZE_BOUNDARY arm_structure_size_boundary
1.1  mrg extern int arm_structure_size_boundary;
1.1  mrg
1.1  mrg /* This is the value used to initialize arm_structure_size_boundary.  If a
1.1  mrg    particular arm target wants to change the default value it should change
1.1  mrg    the definition of this macro, not STRUCTURE_SIZE_BOUNDARY.  See netbsd.h
1.1  mrg    for an example of this.  */
1.1  mrg #ifndef DEFAULT_STRUCTURE_SIZE_BOUNDARY
1.1  mrg #define DEFAULT_STRUCTURE_SIZE_BOUNDARY 32
1.1  mrg #endif
1.1  mrg
1.1  mrg /* Nonzero if move instructions will actually fail to work
1.1  mrg    when given unaligned data.  */
1.1  mrg #define STRICT_ALIGNMENT 1
1.1  mrg
1.1  mrg /* wchar_t is unsigned under the AAPCS.  */
1.1  mrg #ifndef WCHAR_TYPE
1.1  mrg #define WCHAR_TYPE (TARGET_AAPCS_BASED ? "unsigned int" : "int")
1.1  mrg
1.1  mrg #define WCHAR_TYPE_SIZE BITS_PER_WORD
1.1  mrg #endif
1.1  mrg
1.1  mrg #ifndef SIZE_TYPE
1.1  mrg #define SIZE_TYPE (TARGET_AAPCS_BASED ? "unsigned int" : "long unsigned int")
1.1  mrg #endif
1.1  mrg
1.1  mrg #ifndef PTRDIFF_TYPE
1.1  mrg #define PTRDIFF_TYPE (TARGET_AAPCS_BASED ? "int" : "long int")
1.1  mrg #endif
1.1  mrg
1.1  mrg /* AAPCS requires that structure alignment is affected by bitfields.  */
1.1  mrg #ifndef PCC_BITFIELD_TYPE_MATTERS
1.1  mrg #define PCC_BITFIELD_TYPE_MATTERS TARGET_AAPCS_BASED
1.1  mrg #endif
1.1  mrg
1.1  mrg
1.1  mrg /* Standard register usage.  */
1.1  mrg
1.1  mrg /* Register allocation in ARM Procedure Call Standard (as used on RISCiX):
1.1  mrg    (S - saved over call).
1.1  mrg
1.1  mrg 	r0	   *	argument word/integer result
1.1  mrg 	r1-r3		argument word
1.1  mrg
1.1  mrg 	r4-r8	     S	register variable
1.1  mrg 	r9	     S	(rfp) register variable (real frame pointer)
1.1  mrg
1.1  mrg 	r10  	   F S	(sl) stack limit (used by -mapcs-stack-check)
1.1  mrg 	r11 	   F S	(fp) argument pointer
1.1  mrg 	r12		(ip) temp workspace
1.1  mrg 	r13  	   F S	(sp) lower end of current stack frame
1.1  mrg 	r14		(lr) link address/workspace
1.1  mrg 	r15	   F	(pc) program counter
1.1  mrg
1.1  mrg 	f0		floating point result
1.1  mrg 	f1-f3		floating point scratch
1.1  mrg
1.1  mrg 	f4-f7	     S	floating point variable
1.1  mrg
1.1  mrg 	cc		This is NOT a real register, but is used internally
1.1  mrg 	                to represent things that use or set the condition
1.1  mrg 			codes.
1.1  mrg 	sfp             This isn't either.  It is used during rtl generation
1.1  mrg 	                since the offset between the frame pointer and the
1.1  mrg 			auto's isn't known until after register allocation.
1.1  mrg 	afp		Nor this, we only need this because of non-local
1.1  mrg 	                goto.  Without it fp appears to be used and the
1.1  mrg 			elimination code won't get rid of sfp.  It tracks
1.1  mrg 			fp exactly at all times.
1.1  mrg
1.1  mrg    *: See CONDITIONAL_REGISTER_USAGE  */
1.1  mrg
1.1  mrg /*
1.1  mrg   	mvf0		Cirrus floating point result
1.1  mrg 	mvf1-mvf3	Cirrus floating point scratch
1.1  mrg 	mvf4-mvf15   S	Cirrus floating point variable.  */
1.1  mrg
1.1  mrg /*	s0-s15		VFP scratch (aka d0-d7).
1.1  mrg 	s16-s31	      S	VFP variable (aka d8-d15).
1.1  mrg 	vfpcc		Not a real register.  Represents the VFP condition
1.1  mrg 			code flags.  */
1.1  mrg
1.1  mrg /* The stack backtrace structure is as follows:
1.1  mrg   fp points to here:  |  save code pointer  |      [fp]
1.1  mrg                       |  return link value  |      [fp, #-4]
1.1  mrg                       |  return sp value    |      [fp, #-8]
1.1  mrg                       |  return fp value    |      [fp, #-12]
1.1  mrg                      [|  saved r10 value    |]
1.1  mrg                      [|  saved r9 value     |]
1.1  mrg                      [|  saved r8 value     |]
1.1  mrg                      [|  saved r7 value     |]
1.1  mrg                      [|  saved r6 value     |]
1.1  mrg                      [|  saved r5 value     |]
1.1  mrg                      [|  saved r4 value     |]
1.1  mrg                      [|  saved r3 value     |]
1.1  mrg                      [|  saved r2 value     |]
1.1  mrg                      [|  saved r1 value     |]
1.1  mrg                      [|  saved r0 value     |]
1.1  mrg                      [|  saved f7 value     |]     three words
1.1  mrg                      [|  saved f6 value     |]     three words
1.1  mrg                      [|  saved f5 value     |]     three words
1.1  mrg                      [|  saved f4 value     |]     three words
1.1  mrg   r0-r3 are not normally saved in a C function.  */
1.1  mrg
1.1  mrg /* 1 for registers that have pervasive standard uses
1.1  mrg    and are not available for the register allocator.  */
1.1  mrg #define FIXED_REGISTERS \
1.1  mrg {                       \
1.1  mrg   0,0,0,0,0,0,0,0,	\
1.1  mrg   0,0,0,0,0,1,0,1,	\
1.1  mrg   0,0,0,0,0,0,0,0,	\
1.1  mrg   1,1,1,		\
1.1  mrg   1,1,1,1,1,1,1,1,	\
1.1  mrg   1,1,1,1,1,1,1,1,	\
1.1  mrg   1,1,1,1,1,1,1,1,	\
1.1  mrg   1,1,1,1,1,1,1,1,	\
1.1  mrg   1,1,1,1,		\
1.1  mrg   1,1,1,1,1,1,1,1,	\
1.1  mrg   1,1,1,1,1,1,1,1,	\
1.1  mrg   1,1,1,1,1,1,1,1,	\
1.1  mrg   1,1,1,1,1,1,1,1,	\
1.1  mrg   1,1,1,1,1,1,1,1,	\
1.1  mrg   1,1,1,1,1,1,1,1,	\
1.1  mrg   1,1,1,1,1,1,1,1,	\
1.1  mrg   1,1,1,1,1,1,1,1,	\
1.1  mrg   1			\
1.1  mrg }
1.1  mrg
1.1  mrg /* 1 for registers not available across function calls.
1.1  mrg    These must include the FIXED_REGISTERS and also any
1.1  mrg    registers that can be used without being saved.
1.1  mrg    The latter must include the registers where values are returned
1.1  mrg    and the register where structure-value addresses are passed.
1.1  mrg    Aside from that, you can include as many other registers as you like.
1.1  mrg    The CC is not preserved over function calls on the ARM 6, so it is
1.1  mrg    easier to assume this for all.  SFP is preserved, since FP is.  */
1.1  mrg #define CALL_USED_REGISTERS  \
1.1  mrg {                            \
1.1  mrg   1,1,1,1,0,0,0,0,	     \
1.1  mrg   0,0,0,0,1,1,1,1,	     \
1.1  mrg   1,1,1,1,0,0,0,0,	     \
1.1  mrg   1,1,1,		     \
1.1  mrg   1,1,1,1,1,1,1,1,	     \
1.1  mrg   1,1,1,1,1,1,1,1,	     \
1.1  mrg   1,1,1,1,1,1,1,1,	     \
1.1  mrg   1,1,1,1,1,1,1,1,	     \
1.1  mrg   1,1,1,1,		     \
1.1  mrg   1,1,1,1,1,1,1,1,	     \
1.1  mrg   1,1,1,1,1,1,1,1,	     \
1.1  mrg   1,1,1,1,1,1,1,1,	     \
1.1  mrg   1,1,1,1,1,1,1,1,	     \
1.1  mrg   1,1,1,1,1,1,1,1,	     \
1.1  mrg   1,1,1,1,1,1,1,1,	     \
1.1  mrg   1,1,1,1,1,1,1,1,	     \
1.1  mrg   1,1,1,1,1,1,1,1,	     \
1.1  mrg   1			     \
1.1  mrg }
1.1  mrg
1.1  mrg #ifndef SUBTARGET_CONDITIONAL_REGISTER_USAGE
1.1  mrg #define SUBTARGET_CONDITIONAL_REGISTER_USAGE
1.1  mrg #endif
1.1  mrg
1.1  mrg #define CONDITIONAL_REGISTER_USAGE				\
1.1  mrg {								\
1.1  mrg   int regno;							\
1.1  mrg 								\
1.1  mrg   if (TARGET_SOFT_FLOAT || TARGET_THUMB1 || !TARGET_FPA)	\
1.1  mrg     {								\
1.1  mrg       for (regno = FIRST_FPA_REGNUM;				\
1.1  mrg 	   regno <= LAST_FPA_REGNUM; ++regno)			\
1.1  mrg 	fixed_regs[regno] = call_used_regs[regno] = 1;		\
1.1  mrg     }								\
1.1  mrg 								\
1.1  mrg   if (TARGET_THUMB && optimize_size)				\
1.1  mrg     {								\
1.1  mrg       /* When optimizing for size, it's better not to use	\
1.1  mrg 	 the HI regs, because of the overhead of stacking 	\
1.1  mrg 	 them.  */						\
1.1  mrg       /* ??? Is this still true for thumb2?  */			\
1.1  mrg       for (regno = FIRST_HI_REGNUM;				\
1.1  mrg 	   regno <= LAST_HI_REGNUM; ++regno)			\
1.1  mrg 	fixed_regs[regno] = call_used_regs[regno] = 1;		\
1.1  mrg     }								\
1.1  mrg 								\
1.1  mrg   /* The link register can be clobbered by any branch insn,	\
1.1  mrg      but we have no way to track that at present, so mark	\
1.1  mrg      it as unavailable.  */					\
1.1  mrg   if (TARGET_THUMB1)						\
1.1  mrg     fixed_regs[LR_REGNUM] = call_used_regs[LR_REGNUM] = 1;	\
1.1  mrg 								\
1.1  mrg   if (TARGET_32BIT && TARGET_HARD_FLOAT)			\
1.1  mrg     {								\
1.1  mrg       if (TARGET_MAVERICK)					\
1.1  mrg 	{							\
1.1  mrg 	  for (regno = FIRST_FPA_REGNUM;			\
1.1  mrg 	       regno <= LAST_FPA_REGNUM; ++ regno)		\
1.1  mrg 	    fixed_regs[regno] = call_used_regs[regno] = 1;	\
1.1  mrg 	  for (regno = FIRST_CIRRUS_FP_REGNUM;			\
1.1  mrg 	       regno <= LAST_CIRRUS_FP_REGNUM; ++ regno)	\
1.1  mrg 	    {							\
1.1  mrg 	      fixed_regs[regno] = 0;				\
1.1  mrg 	      call_used_regs[regno] = regno < FIRST_CIRRUS_FP_REGNUM + 4; \
1.1  mrg 	    }							\
1.1  mrg 	}							\
1.1  mrg       if (TARGET_VFP)						\
1.1  mrg 	{							\
1.1  mrg 	  /* VFPv3 registers are disabled when earlier VFP	\
1.1  mrg 	     versions are selected due to the definition of	\
1.1  mrg 	     LAST_VFP_REGNUM.  */				\
1.1  mrg 	  for (regno = FIRST_VFP_REGNUM;			\
1.1  mrg 	       regno <= LAST_VFP_REGNUM; ++ regno)		\
1.1  mrg 	    {							\
1.1  mrg 	      fixed_regs[regno] = 0;				\
1.1  mrg 	      call_used_regs[regno] = regno < FIRST_VFP_REGNUM + 16 \
1.1  mrg 	      	|| regno >= FIRST_VFP_REGNUM + 32;		\
1.1  mrg 	    }							\
1.1  mrg 	}							\
1.1  mrg     }								\
1.1  mrg 								\
1.1  mrg   if (TARGET_REALLY_IWMMXT)					\
1.1  mrg     {								\
1.1  mrg       regno = FIRST_IWMMXT_GR_REGNUM;				\
1.1  mrg       /* The 2002/10/09 revision of the XScale ABI has wCG0     \
1.1  mrg          and wCG1 as call-preserved registers.  The 2002/11/21  \
1.1  mrg          revision changed this so that all wCG registers are    \
1.1  mrg          scratch registers.  */					\
1.1  mrg       for (regno = FIRST_IWMMXT_GR_REGNUM;			\
1.1  mrg 	   regno <= LAST_IWMMXT_GR_REGNUM; ++ regno)		\
1.1  mrg 	fixed_regs[regno] = 0;					\
1.1  mrg       /* The XScale ABI has wR0 - wR9 as scratch registers,     \
1.1  mrg 	 the rest as call-preserved registers.  */		\
1.1  mrg       for (regno = FIRST_IWMMXT_REGNUM;				\
1.1  mrg 	   regno <= LAST_IWMMXT_REGNUM; ++ regno)		\
1.1  mrg 	{							\
1.1  mrg 	  fixed_regs[regno] = 0;				\
1.1  mrg 	  call_used_regs[regno] = regno < FIRST_IWMMXT_REGNUM + 10; \
1.1  mrg 	}							\
1.1  mrg     }								\
1.1  mrg 								\
1.1  mrg   if ((unsigned) PIC_OFFSET_TABLE_REGNUM != INVALID_REGNUM)	\
1.1  mrg     {								\
1.1  mrg       fixed_regs[PIC_OFFSET_TABLE_REGNUM] = 1;			\
1.1  mrg       call_used_regs[PIC_OFFSET_TABLE_REGNUM] = 1;		\
1.1  mrg     }								\
1.1  mrg   else if (TARGET_APCS_STACK)					\
1.1  mrg     {								\
1.1  mrg       fixed_regs[10]     = 1;					\
1.1  mrg       call_used_regs[10] = 1;					\
1.1  mrg     }								\
1.1  mrg   /* -mcaller-super-interworking reserves r11 for calls to	\
1.1  mrg      _interwork_r11_call_via_rN().  Making the register global	\
1.1  mrg      is an easy way of ensuring that it remains valid for all	\
1.1  mrg      calls.  */							\
1.1  mrg   if (TARGET_APCS_FRAME || TARGET_CALLER_INTERWORKING		\
1.1  mrg       || TARGET_TPCS_FRAME || TARGET_TPCS_LEAF_FRAME)		\
1.1  mrg     {								\
1.1  mrg       fixed_regs[ARM_HARD_FRAME_POINTER_REGNUM] = 1;		\
1.1  mrg       call_used_regs[ARM_HARD_FRAME_POINTER_REGNUM] = 1;	\
1.1  mrg       if (TARGET_CALLER_INTERWORKING)				\
1.1  mrg 	global_regs[ARM_HARD_FRAME_POINTER_REGNUM] = 1;		\
1.1  mrg     }								\
1.1  mrg   SUBTARGET_CONDITIONAL_REGISTER_USAGE				\
1.1  mrg }
1.1  mrg
1.1  mrg /* These are a couple of extensions to the formats accepted
1.1  mrg    by asm_fprintf:
1.1  mrg      %@ prints out ASM_COMMENT_START
1.1  mrg      %r prints out REGISTER_PREFIX reg_names[arg]  */
1.1  mrg #define ASM_FPRINTF_EXTENSIONS(FILE, ARGS, P)		\
1.1  mrg   case '@':						\
1.1  mrg     fputs (ASM_COMMENT_START, FILE);			\
1.1  mrg     break;						\
1.1  mrg 							\
1.1  mrg   case 'r':						\
1.1  mrg     fputs (REGISTER_PREFIX, FILE);			\
1.1  mrg     fputs (reg_names [va_arg (ARGS, int)], FILE);	\
1.1  mrg     break;
1.1  mrg
1.1  mrg /* Round X up to the nearest word.  */
1.1  mrg #define ROUND_UP_WORD(X) (((X) + 3) & ~3)
1.1  mrg
1.1  mrg /* Convert fron bytes to ints.  */
1.1  mrg #define ARM_NUM_INTS(X) (((X) + UNITS_PER_WORD - 1) / UNITS_PER_WORD)
1.1  mrg
1.1  mrg /* The number of (integer) registers required to hold a quantity of type MODE.
1.1  mrg    Also used for VFP registers.  */
1.1  mrg #define ARM_NUM_REGS(MODE)				\
1.1  mrg   ARM_NUM_INTS (GET_MODE_SIZE (MODE))
1.1  mrg
1.1  mrg /* The number of (integer) registers required to hold a quantity of TYPE MODE.  */
1.1  mrg #define ARM_NUM_REGS2(MODE, TYPE)                   \
1.1  mrg   ARM_NUM_INTS ((MODE) == BLKmode ? 		\
1.1  mrg   int_size_in_bytes (TYPE) : GET_MODE_SIZE (MODE))
1.1  mrg
1.1  mrg /* The number of (integer) argument register available.  */
1.1  mrg #define NUM_ARG_REGS		4
1.1  mrg
1.1  mrg /* And similarly for the VFP.  */
1.1  mrg #define NUM_VFP_ARG_REGS	16
1.1  mrg
1.1  mrg /* Return the register number of the N'th (integer) argument.  */
1.1  mrg #define ARG_REGISTER(N) 	(N - 1)
1.1  mrg
1.1  mrg /* Specify the registers used for certain standard purposes.
1.1  mrg    The values of these macros are register numbers.  */
1.1  mrg
1.1  mrg /* The number of the last argument register.  */
1.1  mrg #define LAST_ARG_REGNUM 	ARG_REGISTER (NUM_ARG_REGS)
1.1  mrg
1.1  mrg /* The numbers of the Thumb register ranges.  */
1.1  mrg #define FIRST_LO_REGNUM  	0
1.1  mrg #define LAST_LO_REGNUM  	7
1.1  mrg #define FIRST_HI_REGNUM		8
1.1  mrg #define LAST_HI_REGNUM		11
1.1  mrg
1.1  mrg #ifndef TARGET_UNWIND_INFO
1.1  mrg /* We use sjlj exceptions for backwards compatibility.  */
1.1  mrg #define MUST_USE_SJLJ_EXCEPTIONS 1
1.1  mrg #endif
1.1  mrg
1.1  mrg /* We can generate DWARF2 Unwind info, even though we don't use it.  */
1.1  mrg #define DWARF2_UNWIND_INFO 1
1.1  mrg
1.1  mrg /* Use r0 and r1 to pass exception handling information.  */
1.1  mrg #define EH_RETURN_DATA_REGNO(N) (((N) < 2) ? N : INVALID_REGNUM)
1.1  mrg
1.1  mrg /* The register that holds the return address in exception handlers.  */
1.1  mrg #define ARM_EH_STACKADJ_REGNUM	2
1.1  mrg #define EH_RETURN_STACKADJ_RTX	gen_rtx_REG (SImode, ARM_EH_STACKADJ_REGNUM)
1.1  mrg
1.1  mrg /* The native (Norcroft) Pascal compiler for the ARM passes the static chain
1.1  mrg    as an invisible last argument (possible since varargs don't exist in
1.1  mrg    Pascal), so the following is not true.  */
1.1  mrg #define STATIC_CHAIN_REGNUM	12
1.1  mrg
1.1  mrg /* Define this to be where the real frame pointer is if it is not possible to
1.1  mrg    work out the offset between the frame pointer and the automatic variables
1.1  mrg    until after register allocation has taken place.  FRAME_POINTER_REGNUM
1.1  mrg    should point to a special register that we will make sure is eliminated.
1.1  mrg
1.1  mrg    For the Thumb we have another problem.  The TPCS defines the frame pointer
1.1  mrg    as r11, and GCC believes that it is always possible to use the frame pointer
1.1  mrg    as base register for addressing purposes.  (See comments in
1.1  mrg    find_reloads_address()).  But - the Thumb does not allow high registers,
1.1  mrg    including r11, to be used as base address registers.  Hence our problem.
1.1  mrg
1.1  mrg    The solution used here, and in the old thumb port is to use r7 instead of
1.1  mrg    r11 as the hard frame pointer and to have special code to generate
1.1  mrg    backtrace structures on the stack (if required to do so via a command line
1.1  mrg    option) using r11.  This is the only 'user visible' use of r11 as a frame
1.1  mrg    pointer.  */
1.1  mrg #define ARM_HARD_FRAME_POINTER_REGNUM	11
1.1  mrg #define THUMB_HARD_FRAME_POINTER_REGNUM	 7
1.1  mrg
1.1  mrg #define HARD_FRAME_POINTER_REGNUM		\
1.1  mrg   (TARGET_ARM					\
1.1  mrg    ? ARM_HARD_FRAME_POINTER_REGNUM		\
1.1  mrg    : THUMB_HARD_FRAME_POINTER_REGNUM)
1.1  mrg
1.1  mrg #define FP_REGNUM	                HARD_FRAME_POINTER_REGNUM
1.1  mrg
1.1  mrg /* Register to use for pushing function arguments.  */
1.1  mrg #define STACK_POINTER_REGNUM	SP_REGNUM
1.1  mrg
1.1  mrg /* ARM floating pointer registers.  */
1.1  mrg #define FIRST_FPA_REGNUM 	16
1.1  mrg #define LAST_FPA_REGNUM  	23
1.1  mrg #define IS_FPA_REGNUM(REGNUM) \
1.1  mrg   (((REGNUM) >= FIRST_FPA_REGNUM) && ((REGNUM) <= LAST_FPA_REGNUM))
1.1  mrg
1.1  mrg #define FIRST_IWMMXT_GR_REGNUM	43
1.1  mrg #define LAST_IWMMXT_GR_REGNUM	46
1.1  mrg #define FIRST_IWMMXT_REGNUM	47
1.1  mrg #define LAST_IWMMXT_REGNUM	62
1.1  mrg #define IS_IWMMXT_REGNUM(REGNUM) \
1.1  mrg   (((REGNUM) >= FIRST_IWMMXT_REGNUM) && ((REGNUM) <= LAST_IWMMXT_REGNUM))
1.1  mrg #define IS_IWMMXT_GR_REGNUM(REGNUM) \
1.1  mrg   (((REGNUM) >= FIRST_IWMMXT_GR_REGNUM) && ((REGNUM) <= LAST_IWMMXT_GR_REGNUM))
1.1  mrg
1.1  mrg /* Base register for access to local variables of the function.  */
1.1  mrg #define FRAME_POINTER_REGNUM	25
1.1  mrg
1.1  mrg /* Base register for access to arguments of the function.  */
1.1  mrg #define ARG_POINTER_REGNUM	26
1.1  mrg
1.1  mrg #define FIRST_CIRRUS_FP_REGNUM	27
1.1  mrg #define LAST_CIRRUS_FP_REGNUM	42
1.1  mrg #define IS_CIRRUS_REGNUM(REGNUM) \
1.1  mrg   (((REGNUM) >= FIRST_CIRRUS_FP_REGNUM) && ((REGNUM) <= LAST_CIRRUS_FP_REGNUM))
1.1  mrg
1.1  mrg #define FIRST_VFP_REGNUM	63
1.1  mrg #define D7_VFP_REGNUM		78  /* Registers 77 and 78 == VFP reg D7.  */
1.1  mrg #define LAST_VFP_REGNUM	\
1.1  mrg   (TARGET_VFPD32 ? LAST_HI_VFP_REGNUM : LAST_LO_VFP_REGNUM)
1.1  mrg
1.1  mrg #define IS_VFP_REGNUM(REGNUM) \
1.1  mrg   (((REGNUM) >= FIRST_VFP_REGNUM) && ((REGNUM) <= LAST_VFP_REGNUM))
1.1  mrg
1.1  mrg /* VFP registers are split into two types: those defined by VFP versions < 3
1.1  mrg    have D registers overlaid on consecutive pairs of S registers. VFP version 3
1.1  mrg    defines 16 new D registers (d16-d31) which, for simplicity and correctness
1.1  mrg    in various parts of the backend, we implement as "fake" single-precision
1.1  mrg    registers (which would be S32-S63, but cannot be used in that way).  The
1.1  mrg    following macros define these ranges of registers.  */
1.1  mrg #define LAST_LO_VFP_REGNUM	94
1.1  mrg #define FIRST_HI_VFP_REGNUM	95
1.1  mrg #define LAST_HI_VFP_REGNUM	126
1.1  mrg
1.1  mrg #define VFP_REGNO_OK_FOR_SINGLE(REGNUM) \
1.1  mrg   ((REGNUM) <= LAST_LO_VFP_REGNUM)
1.1  mrg
1.1  mrg /* DFmode values are only valid in even register pairs.  */
1.1  mrg #define VFP_REGNO_OK_FOR_DOUBLE(REGNUM) \
1.1  mrg   ((((REGNUM) - FIRST_VFP_REGNUM) & 1) == 0)
1.1  mrg
1.1  mrg /* Neon Quad values must start at a multiple of four registers.  */
1.1  mrg #define NEON_REGNO_OK_FOR_QUAD(REGNUM) \
1.1  mrg   ((((REGNUM) - FIRST_VFP_REGNUM) & 3) == 0)
1.1  mrg
1.1  mrg /* Neon structures of vectors must be in even register pairs and there
1.1  mrg    must be enough registers available.  Because of various patterns
1.1  mrg    requiring quad registers, we require them to start at a multiple of
1.1  mrg    four.  */
1.1  mrg #define NEON_REGNO_OK_FOR_NREGS(REGNUM, N) \
1.1  mrg   ((((REGNUM) - FIRST_VFP_REGNUM) & 3) == 0 \
1.1  mrg    && (LAST_VFP_REGNUM - (REGNUM) >= 2 * (N) - 1))
1.1  mrg
1.1  mrg /* The number of hard registers is 16 ARM + 8 FPA + 1 CC + 1 SFP + 1 AFP.  */
1.1  mrg /* + 16 Cirrus registers take us up to 43.  */
1.1  mrg /* Intel Wireless MMX Technology registers add 16 + 4 more.  */
1.1  mrg /* VFP (VFP3) adds 32 (64) + 1 more.  */
1.1  mrg #define FIRST_PSEUDO_REGISTER   128
1.1  mrg
1.1  mrg #define DBX_REGISTER_NUMBER(REGNO) arm_dbx_register_number (REGNO)
1.1  mrg
1.1  mrg /* Value should be nonzero if functions must have frame pointers.
1.1  mrg    Zero means the frame pointer need not be set up (and parms may be accessed
1.1  mrg    via the stack pointer) in functions that seem suitable.
1.1  mrg    If we have to have a frame pointer we might as well make use of it.
1.1  mrg    APCS says that the frame pointer does not need to be pushed in leaf
1.1  mrg    functions, or simple tail call functions.  */
1.1  mrg
1.1  mrg #ifndef SUBTARGET_FRAME_POINTER_REQUIRED
1.1  mrg #define SUBTARGET_FRAME_POINTER_REQUIRED 0
1.1  mrg #endif
1.1  mrg
1.1  mrg /* Return number of consecutive hard regs needed starting at reg REGNO
1.1  mrg    to hold something of mode MODE.
1.1  mrg    This is ordinarily the length in words of a value of mode MODE
1.1  mrg    but can be less for certain modes in special long registers.
1.1  mrg
1.1  mrg    On the ARM regs are UNITS_PER_WORD bits wide; FPA regs can hold any FP
1.1  mrg    mode.  */
1.1  mrg #define HARD_REGNO_NREGS(REGNO, MODE)  	\
1.1  mrg   ((TARGET_32BIT			\
1.1  mrg     && REGNO >= FIRST_FPA_REGNUM	\
1.1  mrg     && REGNO != FRAME_POINTER_REGNUM	\
1.1  mrg     && REGNO != ARG_POINTER_REGNUM)	\
1.1  mrg     && !IS_VFP_REGNUM (REGNO)		\
1.1  mrg    ? 1 : ARM_NUM_REGS (MODE))
1.1  mrg
1.1  mrg /* Return true if REGNO is suitable for holding a quantity of type MODE.  */
1.1  mrg #define HARD_REGNO_MODE_OK(REGNO, MODE)					\
1.1  mrg   arm_hard_regno_mode_ok ((REGNO), (MODE))
1.1  mrg
1.1  mrg /* Value is 1 if it is a good idea to tie two pseudo registers
1.1  mrg    when one has mode MODE1 and one has mode MODE2.
1.1  mrg    If HARD_REGNO_MODE_OK could produce different values for MODE1 and MODE2,
1.1  mrg    for any hard reg, then this must be 0 for correct output.  */
1.1  mrg #define MODES_TIEABLE_P(MODE1, MODE2)  \
1.1  mrg   (GET_MODE_CLASS (MODE1) == GET_MODE_CLASS (MODE2))
1.1  mrg
1.1  mrg #define VALID_IWMMXT_REG_MODE(MODE) \
1.1  mrg  (arm_vector_mode_supported_p (MODE) || (MODE) == DImode)
1.1  mrg
1.1  mrg /* Modes valid for Neon D registers.  */
1.1  mrg #define VALID_NEON_DREG_MODE(MODE) \
1.1  mrg   ((MODE) == V2SImode || (MODE) == V4HImode || (MODE) == V8QImode \
1.1  mrg    || (MODE) == V2SFmode || (MODE) == DImode)
1.1  mrg
1.1  mrg /* Modes valid for Neon Q registers.  */
1.1  mrg #define VALID_NEON_QREG_MODE(MODE) \
1.1  mrg   ((MODE) == V4SImode || (MODE) == V8HImode || (MODE) == V16QImode \
1.1  mrg    || (MODE) == V4SFmode || (MODE) == V2DImode)
1.1  mrg
1.1  mrg /* Structure modes valid for Neon registers.  */
1.1  mrg #define VALID_NEON_STRUCT_MODE(MODE) \
1.1  mrg   ((MODE) == TImode || (MODE) == EImode || (MODE) == OImode \
1.1  mrg    || (MODE) == CImode || (MODE) == XImode)
1.1  mrg
1.1  mrg /* The order in which register should be allocated.  It is good to use ip
1.1  mrg    since no saving is required (though calls clobber it) and it never contains
1.1  mrg    function parameters.  It is quite good to use lr since other calls may
1.1  mrg    clobber it anyway.  Allocate r0 through r3 in reverse order since r3 is
1.1  mrg    least likely to contain a function parameter; in addition results are
1.1  mrg    returned in r0.
1.1  mrg    For VFP/VFPv3, allocate D16-D31 first, then caller-saved registers (D0-D7),
1.1  mrg    then D8-D15.  The reason for doing this is to attempt to reduce register
1.1  mrg    pressure when both single- and double-precision registers are used in a
1.1  mrg    function.  */
1.1  mrg
1.1  mrg #define REG_ALLOC_ORDER				\
1.1  mrg {						\
1.1  mrg      3,  2,  1,  0, 12, 14,  4,  5,		\
1.1  mrg      6,  7,  8, 10,  9, 11, 13, 15,		\
1.1  mrg     16, 17, 18, 19, 20, 21, 22, 23,		\
1.1  mrg     27, 28, 29, 30, 31, 32, 33, 34,		\
1.1  mrg     35, 36, 37, 38, 39, 40, 41, 42,		\
1.1  mrg     43, 44, 45, 46, 47, 48, 49, 50,		\
1.1  mrg     51, 52, 53, 54, 55, 56, 57, 58,		\
1.1  mrg     59, 60, 61, 62,				\
1.1  mrg     24, 25, 26,					\
1.1  mrg     95,  96,  97,  98,  99, 100, 101, 102,	\
1.1  mrg    103, 104, 105, 106, 107, 108, 109, 110,	\
1.1  mrg    111, 112, 113, 114, 115, 116, 117, 118,	\
1.1  mrg    119, 120, 121, 122, 123, 124, 125, 126,	\
1.1  mrg     78,  77,  76,  75,  74,  73,  72,  71,	\
1.1  mrg     70,  69,  68,  67,  66,  65,  64,  63,	\
1.1  mrg     79,  80,  81,  82,  83,  84,  85,  86,	\
1.1  mrg     87,  88,  89,  90,  91,  92,  93,  94,	\
1.1  mrg    127						\
1.1  mrg }
1.1  mrg
1.1  mrg /* Use different register alloc ordering for Thumb.  */
1.1  mrg #define ORDER_REGS_FOR_LOCAL_ALLOC arm_order_regs_for_local_alloc ()
1.1  mrg
1.1  mrg /* Interrupt functions can only use registers that have already been
1.1  mrg    saved by the prologue, even if they would normally be
1.1  mrg    call-clobbered.  */
1.1  mrg #define HARD_REGNO_RENAME_OK(SRC, DST)					\
1.1  mrg 	(! IS_INTERRUPT (cfun->machine->func_type) ||			\
1.1  mrg 	 df_regs_ever_live_p (DST))
1.1  mrg
1.1  mrg /* Register and constant classes.  */
1.1  mrg
1.1  mrg /* Register classes: used to be simple, just all ARM regs or all FPA regs
1.1  mrg    Now that the Thumb is involved it has become more complicated.  */
1.1  mrg enum reg_class
1.1  mrg {
1.1  mrg   NO_REGS,
1.1  mrg   FPA_REGS,
1.1  mrg   CIRRUS_REGS,
1.1  mrg   VFP_D0_D7_REGS,
1.1  mrg   VFP_LO_REGS,
1.1  mrg   VFP_HI_REGS,
1.1  mrg   VFP_REGS,
1.1  mrg   IWMMXT_GR_REGS,
1.1  mrg   IWMMXT_REGS,
1.1  mrg   LO_REGS,
1.1  mrg   STACK_REG,
1.1  mrg   BASE_REGS,
1.1  mrg   HI_REGS,
1.1  mrg   CC_REG,
1.1  mrg   VFPCC_REG,
1.1  mrg   GENERAL_REGS,
1.1  mrg   CORE_REGS,
1.1  mrg   ALL_REGS,
1.1  mrg   LIM_REG_CLASSES
1.1  mrg };
1.1  mrg
1.1  mrg #define N_REG_CLASSES  (int) LIM_REG_CLASSES
1.1  mrg
1.1  mrg /* Give names of register classes as strings for dump file.  */
1.1  mrg #define REG_CLASS_NAMES  \
1.1  mrg {			\
1.1  mrg   "NO_REGS",		\
1.1  mrg   "FPA_REGS",		\
1.1  mrg   "CIRRUS_REGS",	\
1.1  mrg   "VFP_D0_D7_REGS",	\
1.1  mrg   "VFP_LO_REGS",	\
1.1  mrg   "VFP_HI_REGS",	\
1.1  mrg   "VFP_REGS",		\
1.1  mrg   "IWMMXT_GR_REGS",	\
1.1  mrg   "IWMMXT_REGS",	\
1.1  mrg   "LO_REGS",		\
1.1  mrg   "STACK_REG",		\
1.1  mrg   "BASE_REGS",		\
1.1  mrg   "HI_REGS",		\
1.1  mrg   "CC_REG",		\
1.1  mrg   "VFPCC_REG",		\
1.1  mrg   "GENERAL_REGS",	\
1.1  mrg   "CORE_REGS",		\
1.1  mrg   "ALL_REGS",		\
1.1  mrg }
1.1  mrg
1.1  mrg /* Define which registers fit in which classes.
1.1  mrg    This is an initializer for a vector of HARD_REG_SET
1.1  mrg    of length N_REG_CLASSES.  */
1.1  mrg #define REG_CLASS_CONTENTS						\
1.1  mrg {									\
1.1  mrg   { 0x00000000, 0x00000000, 0x00000000, 0x00000000 }, /* NO_REGS  */	\
1.1  mrg   { 0x00FF0000, 0x00000000, 0x00000000, 0x00000000 }, /* FPA_REGS */	\
1.1  mrg   { 0xF8000000, 0x000007FF, 0x00000000, 0x00000000 }, /* CIRRUS_REGS */	\
1.1  mrg   { 0x00000000, 0x80000000, 0x00007FFF, 0x00000000 }, /* VFP_D0_D7_REGS  */ \
1.1  mrg   { 0x00000000, 0x80000000, 0x7FFFFFFF, 0x00000000 }, /* VFP_LO_REGS  */ \
1.1  mrg   { 0x00000000, 0x00000000, 0x80000000, 0x7FFFFFFF }, /* VFP_HI_REGS  */ \
1.1  mrg   { 0x00000000, 0x80000000, 0xFFFFFFFF, 0x7FFFFFFF }, /* VFP_REGS  */	\
1.1  mrg   { 0x00000000, 0x00007800, 0x00000000, 0x00000000 }, /* IWMMXT_GR_REGS */ \
1.1  mrg   { 0x00000000, 0x7FFF8000, 0x00000000, 0x00000000 }, /* IWMMXT_REGS */	\
1.1  mrg   { 0x000000FF, 0x00000000, 0x00000000, 0x00000000 }, /* LO_REGS */	\
1.1  mrg   { 0x00002000, 0x00000000, 0x00000000, 0x00000000 }, /* STACK_REG */	\
1.1  mrg   { 0x000020FF, 0x00000000, 0x00000000, 0x00000000 }, /* BASE_REGS */	\
1.1  mrg   { 0x0000DF00, 0x00000000, 0x00000000, 0x00000000 }, /* HI_REGS */	\
1.1  mrg   { 0x01000000, 0x00000000, 0x00000000, 0x00000000 }, /* CC_REG */	\
1.1  mrg   { 0x00000000, 0x00000000, 0x00000000, 0x80000000 }, /* VFPCC_REG */	\
1.1  mrg   { 0x0200DFFF, 0x00000000, 0x00000000, 0x00000000 }, /* GENERAL_REGS */ \
1.1  mrg   { 0x0200FFFF, 0x00000000, 0x00000000, 0x00000000 }, /* CORE_REGS */	\
1.1  mrg   { 0xFAFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0x7FFFFFFF }  /* ALL_REGS */	\
1.1  mrg }
1.1  mrg
1.1  mrg /* Any of the VFP register classes.  */
1.1  mrg #define IS_VFP_CLASS(X) \
1.1  mrg   ((X) == VFP_D0_D7_REGS || (X) == VFP_LO_REGS \
1.1  mrg    || (X) == VFP_HI_REGS || (X) == VFP_REGS)
1.1  mrg
1.1  mrg /* The same information, inverted:
1.1  mrg    Return the class number of the smallest class containing
1.1  mrg    reg number REGNO.  This could be a conditional expression
1.1  mrg    or could index an array.  */
1.1  mrg #define REGNO_REG_CLASS(REGNO)  arm_regno_class (REGNO)
1.1  mrg
1.1  mrg /* The following macro defines cover classes for Integrated Register
1.1  mrg    Allocator.  Cover classes is a set of non-intersected register
1.1  mrg    classes covering all hard registers used for register allocation
1.1  mrg    purpose.  Any move between two registers of a cover class should be
1.1  mrg    cheaper than load or store of the registers.  The macro value is
1.1  mrg    array of register classes with LIM_REG_CLASSES used as the end
1.1  mrg    marker.  */
1.1  mrg
1.1  mrg #define IRA_COVER_CLASSES						     \
1.1  mrg {									     \
1.1  mrg   GENERAL_REGS, FPA_REGS, CIRRUS_REGS, VFP_REGS, IWMMXT_GR_REGS, IWMMXT_REGS,\
1.1  mrg   LIM_REG_CLASSES							     \
1.1  mrg }
1.1  mrg
1.1  mrg /* FPA registers can't do subreg as all values are reformatted to internal
1.1  mrg    precision.  VFP registers may only be accessed in the mode they
1.1  mrg    were set.  */
1.1  mrg #define CANNOT_CHANGE_MODE_CLASS(FROM, TO, CLASS)	\
1.1  mrg   (GET_MODE_SIZE (FROM) != GET_MODE_SIZE (TO)		\
1.1  mrg    ? reg_classes_intersect_p (FPA_REGS, (CLASS))	\
1.1  mrg      || reg_classes_intersect_p (VFP_REGS, (CLASS))	\
1.1  mrg    : 0)
1.1  mrg
1.1  mrg /* We need to define this for LO_REGS on thumb.  Otherwise we can end up
1.1  mrg    using r0-r4 for function arguments, r7 for the stack frame and don't
1.1  mrg    have enough left over to do doubleword arithmetic.  */
1.1  mrg #define CLASS_LIKELY_SPILLED_P(CLASS)	\
1.1  mrg     ((TARGET_THUMB && (CLASS) == LO_REGS)	\
1.1  mrg      || (CLASS) == CC_REG)
1.1  mrg
1.1  mrg /* The class value for index registers, and the one for base regs.  */
1.1  mrg #define INDEX_REG_CLASS  (TARGET_THUMB1 ? LO_REGS : GENERAL_REGS)
1.1  mrg #define BASE_REG_CLASS   (TARGET_THUMB1 ? LO_REGS : CORE_REGS)
1.1  mrg
1.1  mrg /* For the Thumb the high registers cannot be used as base registers
1.1  mrg    when addressing quantities in QI or HI mode; if we don't know the
1.1  mrg    mode, then we must be conservative.  */
1.1  mrg #define MODE_BASE_REG_CLASS(MODE)					\
1.1  mrg     (TARGET_32BIT ? CORE_REGS :					\
1.1  mrg      (((MODE) == SImode) ? BASE_REGS : LO_REGS))
1.1  mrg
1.1  mrg /* For Thumb we can not support SP+reg addressing, so we return LO_REGS
1.1  mrg    instead of BASE_REGS.  */
1.1  mrg #define MODE_BASE_REG_REG_CLASS(MODE) BASE_REG_CLASS
1.1  mrg
1.1  mrg /* When SMALL_REGISTER_CLASSES is nonzero, the compiler allows
1.1  mrg    registers explicitly used in the rtl to be used as spill registers
1.1  mrg    but prevents the compiler from extending the lifetime of these
1.1  mrg    registers.  */
1.1  mrg #define SMALL_REGISTER_CLASSES   TARGET_THUMB1
1.1  mrg
1.1  mrg /* Given an rtx X being reloaded into a reg required to be
1.1  mrg    in class CLASS, return the class of reg to actually use.
1.1  mrg    In general this is just CLASS, but for the Thumb core registers and
1.1  mrg    immediate constants we prefer a LO_REGS class or a subset.  */
1.1  mrg #define PREFERRED_RELOAD_CLASS(X, CLASS)		\
1.1  mrg   (TARGET_32BIT ? (CLASS) :				\
1.1  mrg    ((CLASS) == GENERAL_REGS || (CLASS) == HI_REGS	\
1.1  mrg     || (CLASS) == NO_REGS || (CLASS) == STACK_REG	\
1.1  mrg    ? LO_REGS : (CLASS)))
1.1  mrg
1.1  mrg /* Must leave BASE_REGS reloads alone */
1.1  mrg #define THUMB_SECONDARY_INPUT_RELOAD_CLASS(CLASS, MODE, X)		\
1.1  mrg   ((CLASS) != LO_REGS && (CLASS) != BASE_REGS				\
1.1  mrg    ? ((true_regnum (X) == -1 ? LO_REGS					\
1.1  mrg        : (true_regnum (X) + HARD_REGNO_NREGS (0, MODE) > 8) ? LO_REGS	\
1.1  mrg        : NO_REGS)) 							\
1.1  mrg    : NO_REGS)
1.1  mrg
1.1  mrg #define THUMB_SECONDARY_OUTPUT_RELOAD_CLASS(CLASS, MODE, X)		\
1.1  mrg   ((CLASS) != LO_REGS && (CLASS) != BASE_REGS				\
1.1  mrg    ? ((true_regnum (X) == -1 ? LO_REGS					\
1.1  mrg        : (true_regnum (X) + HARD_REGNO_NREGS (0, MODE) > 8) ? LO_REGS	\
1.1  mrg        : NO_REGS)) 							\
1.1  mrg    : NO_REGS)
1.1  mrg
1.1  mrg /* Return the register class of a scratch register needed to copy IN into
1.1  mrg    or out of a register in CLASS in MODE.  If it can be done directly,
1.1  mrg    NO_REGS is returned.  */
1.1  mrg #define SECONDARY_OUTPUT_RELOAD_CLASS(CLASS, MODE, X)		\
1.1  mrg   /* Restrict which direct reloads are allowed for VFP/iWMMXt regs.  */ \
1.1  mrg   ((TARGET_VFP && TARGET_HARD_FLOAT				\
1.1  mrg     && IS_VFP_CLASS (CLASS))					\
1.1  mrg    ? coproc_secondary_reload_class (MODE, X, FALSE)		\
1.1  mrg    : (TARGET_IWMMXT && (CLASS) == IWMMXT_REGS)			\
1.1  mrg    ? coproc_secondary_reload_class (MODE, X, TRUE)		\
1.1  mrg    : TARGET_32BIT						\
1.1  mrg    ? (((MODE) == HImode && ! arm_arch4 && true_regnum (X) == -1) \
1.1  mrg     ? GENERAL_REGS : NO_REGS)					\
1.1  mrg    : THUMB_SECONDARY_OUTPUT_RELOAD_CLASS (CLASS, MODE, X))
1.1  mrg
1.1  mrg /* If we need to load shorts byte-at-a-time, then we need a scratch.  */
1.1  mrg #define SECONDARY_INPUT_RELOAD_CLASS(CLASS, MODE, X)		\
1.1  mrg   /* Restrict which direct reloads are allowed for VFP/iWMMXt regs.  */ \
1.1  mrg   ((TARGET_VFP && TARGET_HARD_FLOAT				\
1.1  mrg     && IS_VFP_CLASS (CLASS))					\
1.1  mrg     ? coproc_secondary_reload_class (MODE, X, FALSE) :		\
1.1  mrg     (TARGET_IWMMXT && (CLASS) == IWMMXT_REGS) ?			\
1.1  mrg     coproc_secondary_reload_class (MODE, X, TRUE) :		\
1.1  mrg   /* Cannot load constants into Cirrus registers.  */		\
1.1  mrg    (TARGET_MAVERICK && TARGET_HARD_FLOAT			\
1.1  mrg      && (CLASS) == CIRRUS_REGS					\
1.1  mrg      && (CONSTANT_P (X) || GET_CODE (X) == SYMBOL_REF))		\
1.1  mrg     ? GENERAL_REGS :						\
1.1  mrg   (TARGET_32BIT ?						\
1.1  mrg    (((CLASS) == IWMMXT_REGS || (CLASS) == IWMMXT_GR_REGS)	\
1.1  mrg       && CONSTANT_P (X))					\
1.1  mrg    ? GENERAL_REGS :						\
1.1  mrg    (((MODE) == HImode && ! arm_arch4				\
1.1  mrg      && (GET_CODE (X) == MEM					\
1.1  mrg 	 || ((GET_CODE (X) == REG || GET_CODE (X) == SUBREG)	\
1.1  mrg 	     && true_regnum (X) == -1)))			\
1.1  mrg     ? GENERAL_REGS : NO_REGS)					\
1.1  mrg    : THUMB_SECONDARY_INPUT_RELOAD_CLASS (CLASS, MODE, X)))
1.1  mrg
1.1  mrg /* Try a machine-dependent way of reloading an illegitimate address
1.1  mrg    operand.  If we find one, push the reload and jump to WIN.  This
1.1  mrg    macro is used in only one place: `find_reloads_address' in reload.c.
1.1  mrg
1.1  mrg    For the ARM, we wish to handle large displacements off a base
1.1  mrg    register by splitting the addend across a MOV and the mem insn.
1.1  mrg    This can cut the number of reloads needed.  */
1.1  mrg #define ARM_LEGITIMIZE_RELOAD_ADDRESS(X, MODE, OPNUM, TYPE, IND, WIN)	   \
1.1  mrg   do									   \
1.1  mrg     {									   \
1.1  mrg       if (GET_CODE (X) == PLUS						   \
1.1  mrg 	  && GET_CODE (XEXP (X, 0)) == REG				   \
1.1  mrg 	  && REGNO (XEXP (X, 0)) < FIRST_PSEUDO_REGISTER		   \
1.1  mrg 	  && REG_MODE_OK_FOR_BASE_P (XEXP (X, 0), MODE)			   \
1.1  mrg 	  && GET_CODE (XEXP (X, 1)) == CONST_INT)			   \
1.1  mrg 	{								   \
1.1  mrg 	  HOST_WIDE_INT val = INTVAL (XEXP (X, 1));			   \
1.1  mrg 	  HOST_WIDE_INT low, high;					   \
1.1  mrg 									   \
1.1  mrg 	  if (MODE == DImode || (MODE == DFmode && TARGET_SOFT_FLOAT))	   \
1.1  mrg 	    low = ((val & 0xf) ^ 0x8) - 0x8;				   \
1.1  mrg 	  else if (TARGET_MAVERICK && TARGET_HARD_FLOAT)		   \
1.1  mrg 	    /* Need to be careful, -256 is not a valid offset.  */	   \
1.1  mrg 	    low = val >= 0 ? (val & 0xff) : -((-val) & 0xff);		   \
1.1  mrg 	  else if (MODE == SImode					   \
1.1  mrg 		   || (MODE == SFmode && TARGET_SOFT_FLOAT)		   \
1.1  mrg 		   || ((MODE == HImode || MODE == QImode) && ! arm_arch4)) \
1.1  mrg 	    /* Need to be careful, -4096 is not a valid offset.  */	   \
1.1  mrg 	    low = val >= 0 ? (val & 0xfff) : -((-val) & 0xfff);		   \
1.1  mrg 	  else if ((MODE == HImode || MODE == QImode) && arm_arch4)	   \
1.1  mrg 	    /* Need to be careful, -256 is not a valid offset.  */	   \
1.1  mrg 	    low = val >= 0 ? (val & 0xff) : -((-val) & 0xff);		   \
1.1  mrg 	  else if (GET_MODE_CLASS (MODE) == MODE_FLOAT			   \
1.1  mrg 		   && TARGET_HARD_FLOAT && TARGET_FPA)			   \
1.1  mrg 	    /* Need to be careful, -1024 is not a valid offset.  */	   \
1.1  mrg 	    low = val >= 0 ? (val & 0x3ff) : -((-val) & 0x3ff);		   \
1.1  mrg 	  else								   \
1.1  mrg 	    break;							   \
1.1  mrg 									   \
1.1  mrg 	  high = ((((val - low) & (unsigned HOST_WIDE_INT) 0xffffffff)	   \
1.1  mrg 		   ^ (unsigned HOST_WIDE_INT) 0x80000000)		   \
1.1  mrg 		  - (unsigned HOST_WIDE_INT) 0x80000000);		   \
1.1  mrg 	  /* Check for overflow or zero */				   \
1.1  mrg 	  if (low == 0 || high == 0 || (high + low != val))		   \
1.1  mrg 	    break;							   \
1.1  mrg 									   \
1.1  mrg 	  /* Reload the high part into a base reg; leave the low part	   \
1.1  mrg 	     in the mem.  */						   \
1.1  mrg 	  X = gen_rtx_PLUS (GET_MODE (X),				   \
1.1  mrg 			    gen_rtx_PLUS (GET_MODE (X), XEXP (X, 0),	   \
1.1  mrg 					  GEN_INT (high)),		   \
1.1  mrg 			    GEN_INT (low));				   \
1.1  mrg 	  push_reload (XEXP (X, 0), NULL_RTX, &XEXP (X, 0), NULL,	   \
1.1  mrg 		       MODE_BASE_REG_CLASS (MODE), GET_MODE (X), 	   \
1.1  mrg 		       VOIDmode, 0, 0, OPNUM, TYPE);			   \
1.1  mrg 	  goto WIN;							   \
1.1  mrg 	}								   \
1.1  mrg     }									   \
1.1  mrg   while (0)
1.1  mrg
1.1  mrg /* XXX If an HImode FP+large_offset address is converted to an HImode
1.1  mrg    SP+large_offset address, then reload won't know how to fix it.  It sees
1.1  mrg    only that SP isn't valid for HImode, and so reloads the SP into an index
1.1  mrg    register, but the resulting address is still invalid because the offset
1.1  mrg    is too big.  We fix it here instead by reloading the entire address.  */
1.1  mrg /* We could probably achieve better results by defining PROMOTE_MODE to help
1.1  mrg    cope with the variances between the Thumb's signed and unsigned byte and
1.1  mrg    halfword load instructions.  */
1.1  mrg /* ??? This should be safe for thumb2, but we may be able to do better.  */
1.1  mrg #define THUMB_LEGITIMIZE_RELOAD_ADDRESS(X, MODE, OPNUM, TYPE, IND_L, WIN)     \
1.1  mrg do {									      \
1.1  mrg   rtx new_x = thumb_legitimize_reload_address (&X, MODE, OPNUM, TYPE, IND_L); \
1.1  mrg   if (new_x)								      \
1.1  mrg     {									      \
1.1  mrg       X = new_x;							      \
1.1  mrg       goto WIN;								      \
1.1  mrg     }									      \
1.1  mrg } while (0)
1.1  mrg
1.1  mrg #define LEGITIMIZE_RELOAD_ADDRESS(X, MODE, OPNUM, TYPE, IND_LEVELS, WIN)   \
1.1  mrg   if (TARGET_ARM)							   \
1.1  mrg     ARM_LEGITIMIZE_RELOAD_ADDRESS (X, MODE, OPNUM, TYPE, IND_LEVELS, WIN); \
1.1  mrg   else									   \
1.1  mrg     THUMB_LEGITIMIZE_RELOAD_ADDRESS (X, MODE, OPNUM, TYPE, IND_LEVELS, WIN)
1.1  mrg
1.1  mrg /* Return the maximum number of consecutive registers
1.1  mrg    needed to represent mode MODE in a register of class CLASS.
1.1  mrg    ARM regs are UNITS_PER_WORD bits while FPA regs can hold any FP mode */
1.1  mrg #define CLASS_MAX_NREGS(CLASS, MODE)  \
1.1  mrg   (((CLASS) == FPA_REGS || (CLASS) == CIRRUS_REGS) ? 1 : ARM_NUM_REGS (MODE))
1.1  mrg
1.1  mrg /* If defined, gives a class of registers that cannot be used as the
1.1  mrg    operand of a SUBREG that changes the mode of the object illegally.  */
1.1  mrg
1.1  mrg /* Moves between FPA_REGS and GENERAL_REGS are two memory insns.
1.1  mrg    Moves between VFP_REGS and GENERAL_REGS are a single insn, but
1.1  mrg    it is typically more expensive than a single memory access.  We set
1.1  mrg    the cost to less than two memory accesses so that floating
1.1  mrg    point to integer conversion does not go through memory.  */
1.1  mrg #define REGISTER_MOVE_COST(MODE, FROM, TO)		\
1.1  mrg   (TARGET_32BIT ?						\
1.1  mrg    ((FROM) == FPA_REGS && (TO) != FPA_REGS ? 20 :	\
1.1  mrg     (FROM) != FPA_REGS && (TO) == FPA_REGS ? 20 :	\
1.1  mrg     IS_VFP_CLASS (FROM) && !IS_VFP_CLASS (TO) ? 15 :	\
1.1  mrg     !IS_VFP_CLASS (FROM) && IS_VFP_CLASS (TO) ? 15 :	\
1.1  mrg     (FROM) == IWMMXT_REGS && (TO) != IWMMXT_REGS ? 4 :  \
1.1  mrg     (FROM) != IWMMXT_REGS && (TO) == IWMMXT_REGS ? 4 :  \
1.1  mrg     (FROM) == IWMMXT_GR_REGS || (TO) == IWMMXT_GR_REGS ? 20 :  \
1.1  mrg     (FROM) == CIRRUS_REGS && (TO) != CIRRUS_REGS ? 20 :	\
1.1  mrg     (FROM) != CIRRUS_REGS && (TO) == CIRRUS_REGS ? 20 :	\
1.1  mrg    2)							\
1.1  mrg    :							\
1.1  mrg    ((FROM) == HI_REGS || (TO) == HI_REGS) ? 4 : 2)
1.1  mrg
1.1  mrg /* Stack layout; function entry, exit and calling.  */
1.1  mrg
1.1  mrg /* Define this if pushing a word on the stack
1.1  mrg    makes the stack pointer a smaller address.  */
1.1  mrg #define STACK_GROWS_DOWNWARD  1
1.1  mrg
1.1  mrg /* Define this to nonzero if the nominal address of the stack frame
1.1  mrg    is at the high-address end of the local variables;
1.1  mrg    that is, each additional local variable allocated
1.1  mrg    goes at a more negative offset in the frame.  */
1.1  mrg #define FRAME_GROWS_DOWNWARD 1
1.1  mrg
1.1  mrg /* The amount of scratch space needed by _interwork_{r7,r11}_call_via_rN().
1.1  mrg    When present, it is one word in size, and sits at the top of the frame,
1.1  mrg    between the soft frame pointer and either r7 or r11.
1.1  mrg
1.1  mrg    We only need _interwork_rM_call_via_rN() for -mcaller-super-interworking,
1.1  mrg    and only then if some outgoing arguments are passed on the stack.  It would
1.1  mrg    be tempting to also check whether the stack arguments are passed by indirect
1.1  mrg    calls, but there seems to be no reason in principle why a post-reload pass
1.1  mrg    couldn't convert a direct call into an indirect one.  */
1.1  mrg #define CALLER_INTERWORKING_SLOT_SIZE			\
1.1  mrg   (TARGET_CALLER_INTERWORKING				\
1.1  mrg    && crtl->outgoing_args_size != 0		\
1.1  mrg    ? UNITS_PER_WORD : 0)
1.1  mrg
1.1  mrg /* Offset within stack frame to start allocating local variables at.
1.1  mrg    If FRAME_GROWS_DOWNWARD, this is the offset to the END of the
1.1  mrg    first local allocated.  Otherwise, it is the offset to the BEGINNING
1.1  mrg    of the first local allocated.  */
1.1  mrg #define STARTING_FRAME_OFFSET  0
1.1  mrg
1.1  mrg /* If we generate an insn to push BYTES bytes,
1.1  mrg    this says how many the stack pointer really advances by.  */
1.1  mrg /* The push insns do not do this rounding implicitly.
1.1  mrg    So don't define this.  */
1.1  mrg /* #define PUSH_ROUNDING(NPUSHED)  ROUND_UP_WORD (NPUSHED) */
1.1  mrg
1.1  mrg /* Define this if the maximum size of all the outgoing args is to be
1.1  mrg    accumulated and pushed during the prologue.  The amount can be
1.1  mrg    found in the variable crtl->outgoing_args_size.  */
1.1  mrg #define ACCUMULATE_OUTGOING_ARGS 1
1.1  mrg
1.1  mrg /* Offset of first parameter from the argument pointer register value.  */
1.1  mrg #define FIRST_PARM_OFFSET(FNDECL)  (TARGET_ARM ? 4 : 0)
1.1  mrg
1.1  mrg /* Value is the number of byte of arguments automatically
1.1  mrg    popped when returning from a subroutine call.
1.1  mrg    FUNDECL is the declaration node of the function (as a tree),
1.1  mrg    FUNTYPE is the data type of the function (as a tree),
1.1  mrg    or for a library call it is an identifier node for the subroutine name.
1.1  mrg    SIZE is the number of bytes of arguments passed on the stack.
1.1  mrg
1.1  mrg    On the ARM, the caller does not pop any of its arguments that were passed
1.1  mrg    on the stack.  */
1.1  mrg #define RETURN_POPS_ARGS(FUNDECL, FUNTYPE, SIZE)  0
1.1  mrg
1.1  mrg /* Define how to find the value returned by a library function
1.1  mrg    assuming the value has mode MODE.  */
1.1  mrg #define LIBCALL_VALUE(MODE)  						\
1.1  mrg   (TARGET_AAPCS_BASED ? aapcs_libcall_value (MODE)			\
1.1  mrg    : (TARGET_32BIT && TARGET_HARD_FLOAT_ABI && TARGET_FPA		\
1.1  mrg       && GET_MODE_CLASS (MODE) == MODE_FLOAT)				\
1.1  mrg    ? gen_rtx_REG (MODE, FIRST_FPA_REGNUM)				\
1.1  mrg    : TARGET_32BIT && TARGET_HARD_FLOAT_ABI && TARGET_MAVERICK		\
1.1  mrg      && GET_MODE_CLASS (MODE) == MODE_FLOAT				\
1.1  mrg    ? gen_rtx_REG (MODE, FIRST_CIRRUS_FP_REGNUM) 			\
1.1  mrg    : TARGET_IWMMXT_ABI && arm_vector_mode_supported_p (MODE)    	\
1.1  mrg    ? gen_rtx_REG (MODE, FIRST_IWMMXT_REGNUM) 				\
1.1  mrg    : gen_rtx_REG (MODE, ARG_REGISTER (1)))
1.1  mrg
1.1  mrg /* 1 if REGNO is a possible register number for a function value.  */
1.1  mrg #define FUNCTION_VALUE_REGNO_P(REGNO)				\
1.1  mrg   ((REGNO) == ARG_REGISTER (1)					\
1.1  mrg    || (TARGET_AAPCS_BASED && TARGET_32BIT 			\
1.1  mrg        && TARGET_VFP && TARGET_HARD_FLOAT			\
1.1  mrg        && (REGNO) == FIRST_VFP_REGNUM)				\
1.1  mrg    || (TARGET_32BIT && ((REGNO) == FIRST_CIRRUS_FP_REGNUM)	\
1.1  mrg        && TARGET_HARD_FLOAT_ABI && TARGET_MAVERICK)		\
1.1  mrg    || ((REGNO) == FIRST_IWMMXT_REGNUM && TARGET_IWMMXT_ABI)	\
1.1  mrg    || (TARGET_32BIT && ((REGNO) == FIRST_FPA_REGNUM)		\
1.1  mrg        && TARGET_HARD_FLOAT_ABI && TARGET_FPA))
1.1  mrg
1.1  mrg /* Amount of memory needed for an untyped call to save all possible return
1.1  mrg    registers.  */
1.1  mrg #define APPLY_RESULT_SIZE arm_apply_result_size()
1.1  mrg
1.1  mrg /* Define DEFAULT_PCC_STRUCT_RETURN to 1 if all structure and union return
1.1  mrg    values must be in memory.  On the ARM, they need only do so if larger
1.1  mrg    than a word, or if they contain elements offset from zero in the struct.  */
1.1  mrg #define DEFAULT_PCC_STRUCT_RETURN 0
1.1  mrg
1.1  mrg /* These bits describe the different types of function supported
1.1  mrg    by the ARM backend.  They are exclusive.  i.e. a function cannot be both a
1.1  mrg    normal function and an interworked function, for example.  Knowing the
1.1  mrg    type of a function is important for determining its prologue and
1.1  mrg    epilogue sequences.
1.1  mrg    Note value 7 is currently unassigned.  Also note that the interrupt
1.1  mrg    function types all have bit 2 set, so that they can be tested for easily.
1.1  mrg    Note that 0 is deliberately chosen for ARM_FT_UNKNOWN so that when the
1.1  mrg    machine_function structure is initialized (to zero) func_type will
1.1  mrg    default to unknown.  This will force the first use of arm_current_func_type
1.1  mrg    to call arm_compute_func_type.  */
1.1  mrg #define ARM_FT_UNKNOWN		 0 /* Type has not yet been determined.  */
1.1  mrg #define ARM_FT_NORMAL		 1 /* Your normal, straightforward function.  */
1.1  mrg #define ARM_FT_INTERWORKED	 2 /* A function that supports interworking.  */
1.1  mrg #define ARM_FT_ISR		 4 /* An interrupt service routine.  */
1.1  mrg #define ARM_FT_FIQ		 5 /* A fast interrupt service routine.  */
1.1  mrg #define ARM_FT_EXCEPTION	 6 /* An ARM exception handler (subcase of ISR).  */
1.1  mrg
1.1  mrg #define ARM_FT_TYPE_MASK	((1 << 3) - 1)
1.1  mrg
1.1  mrg /* In addition functions can have several type modifiers,
1.1  mrg    outlined by these bit masks:  */
1.1  mrg #define ARM_FT_INTERRUPT	(1 << 2) /* Note overlap with FT_ISR and above.  */
1.1  mrg #define ARM_FT_NAKED		(1 << 3) /* No prologue or epilogue.  */
1.1  mrg #define ARM_FT_VOLATILE		(1 << 4) /* Does not return.  */
1.1  mrg #define ARM_FT_NESTED		(1 << 5) /* Embedded inside another func.  */
1.1  mrg #define ARM_FT_STACKALIGN	(1 << 6) /* Called with misaligned stack.  */
1.1  mrg
1.1  mrg /* Some macros to test these flags.  */
1.1  mrg #define ARM_FUNC_TYPE(t)	(t & ARM_FT_TYPE_MASK)
1.1  mrg #define IS_INTERRUPT(t)		(t & ARM_FT_INTERRUPT)
1.1  mrg #define IS_VOLATILE(t)     	(t & ARM_FT_VOLATILE)
1.1  mrg #define IS_NAKED(t)        	(t & ARM_FT_NAKED)
1.1  mrg #define IS_NESTED(t)       	(t & ARM_FT_NESTED)
1.1  mrg #define IS_STACKALIGN(t)       	(t & ARM_FT_STACKALIGN)
1.1  mrg
1.1  mrg
1.1  mrg /* Structure used to hold the function stack frame layout.  Offsets are
1.1  mrg    relative to the stack pointer on function entry.  Positive offsets are
1.1  mrg    in the direction of stack growth.
1.1  mrg    Only soft_frame is used in thumb mode.  */
1.1  mrg
1.1  mrg typedef struct GTY(()) arm_stack_offsets
1.1  mrg {
1.1  mrg   int saved_args;	/* ARG_POINTER_REGNUM.  */
1.1  mrg   int frame;		/* ARM_HARD_FRAME_POINTER_REGNUM.  */
1.1  mrg   int saved_regs;
1.1  mrg   int soft_frame;	/* FRAME_POINTER_REGNUM.  */
1.1  mrg   int locals_base;	/* THUMB_HARD_FRAME_POINTER_REGNUM.  */
1.1  mrg   int outgoing_args;	/* STACK_POINTER_REGNUM.  */
1.1  mrg   unsigned int saved_regs_mask;
1.1  mrg }
1.1  mrg arm_stack_offsets;
1.1  mrg
1.1  mrg /* A C structure for machine-specific, per-function data.
1.1  mrg    This is added to the cfun structure.  */
1.1  mrg typedef struct GTY(()) machine_function
1.1  mrg {
1.1  mrg   /* Additional stack adjustment in __builtin_eh_throw.  */
1.1  mrg   rtx eh_epilogue_sp_ofs;
1.1  mrg   /* Records if LR has to be saved for far jumps.  */
1.1  mrg   int far_jump_used;
1.1  mrg   /* Records if ARG_POINTER was ever live.  */
1.1  mrg   int arg_pointer_live;
1.1  mrg   /* Records if the save of LR has been eliminated.  */
1.1  mrg   int lr_save_eliminated;
1.1  mrg   /* The size of the stack frame.  Only valid after reload.  */
1.1  mrg   arm_stack_offsets stack_offsets;
1.1  mrg   /* Records the type of the current function.  */
1.1  mrg   unsigned long func_type;
1.1  mrg   /* Record if the function has a variable argument list.  */
1.1  mrg   int uses_anonymous_args;
1.1  mrg   /* Records if sibcalls are blocked because an argument
1.1  mrg      register is needed to preserve stack alignment.  */
1.1  mrg   int sibcall_blocked;
1.1  mrg   /* The PIC register for this function.  This might be a pseudo.  */
1.1  mrg   rtx pic_reg;
1.1  mrg   /* Labels for per-function Thumb call-via stubs.  One per potential calling
1.1  mrg      register.  We can never call via LR or PC.  We can call via SP if a
1.1  mrg      trampoline happens to be on the top of the stack.  */
1.1  mrg   rtx call_via[14];
1.1  mrg   /* Set to 1 when a return insn is output, this means that the epilogue
1.1  mrg      is not needed.  */
1.1  mrg   int return_used_this_function;
1.1  mrg }
1.1  mrg machine_function;
1.1  mrg
1.1  mrg /* As in the machine_function, a global set of call-via labels, for code
1.1  mrg    that is in text_section.  */
1.1  mrg extern GTY(()) rtx thumb_call_via_label[14];
1.1  mrg
1.1  mrg /* The number of potential ways of assigning to a co-processor.  */
1.1  mrg #define ARM_NUM_COPROC_SLOTS 1
1.1  mrg
1.1  mrg /* Enumeration of procedure calling standard variants.  We don't really
1.1  mrg    support all of these yet.  */
1.1  mrg enum arm_pcs
1.1  mrg {
1.1  mrg   ARM_PCS_AAPCS,	/* Base standard AAPCS.  */
1.1  mrg   ARM_PCS_AAPCS_VFP,	/* Use VFP registers for floating point values.  */
1.1  mrg   ARM_PCS_AAPCS_IWMMXT, /* Use iWMMXT registers for vectors.  */
1.1  mrg   /* This must be the last AAPCS variant.  */
1.1  mrg   ARM_PCS_AAPCS_LOCAL,	/* Private call within this compilation unit.  */
1.1  mrg   ARM_PCS_ATPCS,	/* ATPCS.  */
1.1  mrg   ARM_PCS_APCS,		/* APCS (legacy Linux etc).  */
1.1  mrg   ARM_PCS_UNKNOWN
1.1  mrg };
1.1  mrg
1.1  mrg /* A C type for declaring a variable that is used as the first argument of
1.1  mrg    `FUNCTION_ARG' and other related values.  */
1.1  mrg typedef struct
1.1  mrg {
1.1  mrg   /* This is the number of registers of arguments scanned so far.  */
1.1  mrg   int nregs;
1.1  mrg   /* This is the number of iWMMXt register arguments scanned so far.  */
1.1  mrg   int iwmmxt_nregs;
1.1  mrg   int named_count;
1.1  mrg   int nargs;
1.1  mrg   /* Which procedure call variant to use for this call.  */
1.1  mrg   enum arm_pcs pcs_variant;
1.1  mrg
1.1  mrg   /* AAPCS related state tracking.  */
1.1  mrg   int aapcs_arg_processed;  /* No need to lay out this argument again.  */
1.1  mrg   int aapcs_cprc_slot;      /* Index of co-processor rules to handle
1.1  mrg 			       this argument, or -1 if using core
1.1  mrg 			       registers.  */
1.1  mrg   int aapcs_ncrn;
1.1  mrg   int aapcs_next_ncrn;
1.1  mrg   rtx aapcs_reg;	    /* Register assigned to this argument.  */
1.1  mrg   int aapcs_partial;	    /* How many bytes are passed in regs (if
1.1  mrg 			       split between core regs and stack.
1.1  mrg 			       Zero otherwise.  */
1.1  mrg   int aapcs_cprc_failed[ARM_NUM_COPROC_SLOTS];
1.1  mrg   int can_split;	    /* Argument can be split between core regs
1.1  mrg 			       and the stack.  */
1.1  mrg   /* Private data for tracking VFP register allocation */
1.1  mrg   unsigned aapcs_vfp_regs_free;
1.1  mrg   unsigned aapcs_vfp_reg_alloc;
1.1  mrg   int aapcs_vfp_rcount;
1.1  mrg   MACHMODE aapcs_vfp_rmode;
1.1  mrg } CUMULATIVE_ARGS;
1.1  mrg
1.1  mrg /* Define where to put the arguments to a function.
1.1  mrg    Value is zero to push the argument on the stack,
1.1  mrg    or a hard register in which to store the argument.
1.1  mrg
1.1  mrg    MODE is the argument's machine mode.
1.1  mrg    TYPE is the data type of the argument (as a tree).
1.1  mrg     This is null for libcalls where that information may
1.1  mrg     not be available.
1.1  mrg    CUM is a variable of type CUMULATIVE_ARGS which gives info about
1.1  mrg     the preceding args and about the function being called.
1.1  mrg    NAMED is nonzero if this argument is a named parameter
1.1  mrg     (otherwise it is an extra parameter matching an ellipsis).
1.1  mrg
1.1  mrg    On the ARM, normally the first 16 bytes are passed in registers r0-r3; all
1.1  mrg    other arguments are passed on the stack.  If (NAMED == 0) (which happens
1.1  mrg    only in assign_parms, since TARGET_SETUP_INCOMING_VARARGS is
1.1  mrg    defined), say it is passed in the stack (function_prologue will
1.1  mrg    indeed make it pass in the stack if necessary).  */
1.1  mrg #define FUNCTION_ARG(CUM, MODE, TYPE, NAMED) \
1.1  mrg   arm_function_arg (&(CUM), (MODE), (TYPE), (NAMED))
1.1  mrg
1.1  mrg #define FUNCTION_ARG_PADDING(MODE, TYPE) \
1.1  mrg   (arm_pad_arg_upward (MODE, TYPE) ? upward : downward)
1.1  mrg
1.1  mrg #define BLOCK_REG_PADDING(MODE, TYPE, FIRST) \
1.1  mrg   (arm_pad_reg_upward (MODE, TYPE, FIRST) ? upward : downward)
1.1  mrg
1.1  mrg /* For AAPCS, padding should never be below the argument. For other ABIs,
1.1  mrg  * mimic the default.  */
1.1  mrg #define PAD_VARARGS_DOWN \
1.1  mrg   ((TARGET_AAPCS_BASED) ? 0 : BYTES_BIG_ENDIAN)
1.1  mrg
1.1  mrg /* Initialize a variable CUM of type CUMULATIVE_ARGS
1.1  mrg    for a call to a function whose data type is FNTYPE.
1.1  mrg    For a library call, FNTYPE is 0.
1.1  mrg    On the ARM, the offset starts at 0.  */
1.1  mrg #define INIT_CUMULATIVE_ARGS(CUM, FNTYPE, LIBNAME, FNDECL, N_NAMED_ARGS) \
1.1  mrg   arm_init_cumulative_args (&(CUM), (FNTYPE), (LIBNAME), (FNDECL))
1.1  mrg
1.1  mrg /* Update the data in CUM to advance over an argument
1.1  mrg    of mode MODE and data type TYPE.
1.1  mrg    (TYPE is null for libcalls where that information may not be available.)  */
1.1  mrg #define FUNCTION_ARG_ADVANCE(CUM, MODE, TYPE, NAMED)	\
1.1  mrg   arm_function_arg_advance (&(CUM), (MODE), (TYPE), (NAMED))
1.1  mrg
1.1  mrg /* If defined, a C expression that gives the alignment boundary, in bits, of an
1.1  mrg    argument with the specified mode and type.  If it is not defined,
1.1  mrg    `PARM_BOUNDARY' is used for all arguments.  */
1.1  mrg #define FUNCTION_ARG_BOUNDARY(MODE,TYPE) \
1.1  mrg    ((ARM_DOUBLEWORD_ALIGN && arm_needs_doubleword_align (MODE, TYPE)) \
1.1  mrg    ? DOUBLEWORD_ALIGNMENT \
1.1  mrg    : PARM_BOUNDARY )
1.1  mrg
1.1  mrg /* 1 if N is a possible register number for function argument passing.
1.1  mrg    On the ARM, r0-r3 are used to pass args.  */
1.1  mrg #define FUNCTION_ARG_REGNO_P(REGNO)					\
1.1  mrg    (IN_RANGE ((REGNO), 0, 3)						\
1.1  mrg     || (TARGET_AAPCS_BASED && TARGET_VFP && TARGET_HARD_FLOAT		\
1.1  mrg 	&& IN_RANGE ((REGNO), FIRST_VFP_REGNUM, FIRST_VFP_REGNUM + 15))	\
1.1  mrg     || (TARGET_IWMMXT_ABI						\
1.1  mrg 	&& IN_RANGE ((REGNO), FIRST_IWMMXT_REGNUM, FIRST_IWMMXT_REGNUM + 9)))
1.1  mrg
1.1  mrg
1.1  mrg /* If your target environment doesn't prefix user functions with an
1.1  mrg    underscore, you may wish to re-define this to prevent any conflicts.  */
1.1  mrg #ifndef ARM_MCOUNT_NAME
1.1  mrg #define ARM_MCOUNT_NAME "*mcount"
1.1  mrg #endif
1.1  mrg
1.1  mrg /* Call the function profiler with a given profile label.  The Acorn
1.1  mrg    compiler puts this BEFORE the prolog but gcc puts it afterwards.
1.1  mrg    On the ARM the full profile code will look like:
1.1  mrg 	.data
1.1  mrg 	LP1
1.1  mrg 		.word	0
1.1  mrg 	.text
1.1  mrg 		mov	ip, lr
1.1  mrg 		bl	mcount
1.1  mrg 		.word	LP1
1.1  mrg
1.1  mrg    profile_function() in final.c outputs the .data section, FUNCTION_PROFILER
1.1  mrg    will output the .text section.
1.1  mrg
1.1  mrg    The ``mov ip,lr'' seems like a good idea to stick with cc convention.
1.1  mrg    ``prof'' doesn't seem to mind about this!
1.1  mrg
1.1  mrg    Note - this version of the code is designed to work in both ARM and
1.1  mrg    Thumb modes.  */
1.1  mrg #ifndef ARM_FUNCTION_PROFILER
1.1  mrg #define ARM_FUNCTION_PROFILER(STREAM, LABELNO)  	\
1.1  mrg {							\
1.1  mrg   char temp[20];					\
1.1  mrg   rtx sym;						\
1.1  mrg 							\
1.1  mrg   asm_fprintf (STREAM, "\tmov\t%r, %r\n\tbl\t",		\
1.1  mrg 	   IP_REGNUM, LR_REGNUM);			\
1.1  mrg   assemble_name (STREAM, ARM_MCOUNT_NAME);		\
1.1  mrg   fputc ('\n', STREAM);					\
1.1  mrg   ASM_GENERATE_INTERNAL_LABEL (temp, "LP", LABELNO);	\
1.1  mrg   sym = gen_rtx_SYMBOL_REF (Pmode, temp);		\
1.1  mrg   assemble_aligned_integer (UNITS_PER_WORD, sym);	\
1.1  mrg }
1.1  mrg #endif
1.1  mrg
1.1  mrg #ifdef THUMB_FUNCTION_PROFILER
1.1  mrg #define FUNCTION_PROFILER(STREAM, LABELNO)		\
1.1  mrg   if (TARGET_ARM)					\
1.1  mrg     ARM_FUNCTION_PROFILER (STREAM, LABELNO)		\
1.1  mrg   else							\
1.1  mrg     THUMB_FUNCTION_PROFILER (STREAM, LABELNO)
1.1  mrg #else
1.1  mrg #define FUNCTION_PROFILER(STREAM, LABELNO)		\
1.1  mrg     ARM_FUNCTION_PROFILER (STREAM, LABELNO)
1.1  mrg #endif
1.1  mrg
1.1  mrg /* EXIT_IGNORE_STACK should be nonzero if, when returning from a function,
1.1  mrg    the stack pointer does not matter.  The value is tested only in
1.1  mrg    functions that have frame pointers.
1.1  mrg    No definition is equivalent to always zero.
1.1  mrg
1.1  mrg    On the ARM, the function epilogue recovers the stack pointer from the
1.1  mrg    frame.  */
1.1  mrg #define EXIT_IGNORE_STACK 1
1.1  mrg
1.1  mrg #define EPILOGUE_USES(REGNO) ((REGNO) == LR_REGNUM)
1.1  mrg
1.1  mrg /* Determine if the epilogue should be output as RTL.
1.1  mrg    You should override this if you define FUNCTION_EXTRA_EPILOGUE.  */
1.1  mrg /* This is disabled for Thumb-2 because it will confuse the
1.1  mrg    conditional insn counter.  */
1.1  mrg #define USE_RETURN_INSN(ISCOND)				\
1.1  mrg   (TARGET_ARM ? use_return_insn (ISCOND, NULL) : 0)
1.1  mrg
1.1  mrg /* Definitions for register eliminations.
1.1  mrg
1.1  mrg    This is an array of structures.  Each structure initializes one pair
1.1  mrg    of eliminable registers.  The "from" register number is given first,
1.1  mrg    followed by "to".  Eliminations of the same "from" register are listed
1.1  mrg    in order of preference.
1.1  mrg
1.1  mrg    We have two registers that can be eliminated on the ARM.  First, the
1.1  mrg    arg pointer register can often be eliminated in favor of the stack
1.1  mrg    pointer register.  Secondly, the pseudo frame pointer register can always
1.1  mrg    be eliminated; it is replaced with either the stack or the real frame
1.1  mrg    pointer.  Note we have to use {ARM|THUMB}_HARD_FRAME_POINTER_REGNUM
1.1  mrg    because the definition of HARD_FRAME_POINTER_REGNUM is not a constant.  */
1.1  mrg
1.1  mrg #define ELIMINABLE_REGS						\
1.1  mrg {{ ARG_POINTER_REGNUM,        STACK_POINTER_REGNUM            },\
1.1  mrg  { ARG_POINTER_REGNUM,        FRAME_POINTER_REGNUM            },\
1.1  mrg  { ARG_POINTER_REGNUM,        ARM_HARD_FRAME_POINTER_REGNUM   },\
1.1  mrg  { ARG_POINTER_REGNUM,        THUMB_HARD_FRAME_POINTER_REGNUM },\
1.1  mrg  { FRAME_POINTER_REGNUM,      STACK_POINTER_REGNUM            },\
1.1  mrg  { FRAME_POINTER_REGNUM,      ARM_HARD_FRAME_POINTER_REGNUM   },\
1.1  mrg  { FRAME_POINTER_REGNUM,      THUMB_HARD_FRAME_POINTER_REGNUM }}
1.1  mrg
1.1  mrg /* Define the offset between two registers, one to be eliminated, and the
1.1  mrg    other its replacement, at the start of a routine.  */
1.1  mrg #define INITIAL_ELIMINATION_OFFSET(FROM, TO, OFFSET)			\
1.1  mrg   if (TARGET_ARM)							\
1.1  mrg     (OFFSET) = arm_compute_initial_elimination_offset (FROM, TO);	\
1.1  mrg   else									\
1.1  mrg     (OFFSET) = thumb_compute_initial_elimination_offset (FROM, TO)
1.1  mrg
1.1  mrg /* Special case handling of the location of arguments passed on the stack.  */
1.1  mrg #define DEBUGGER_ARG_OFFSET(value, addr) value ? value : arm_debugger_arg_offset (value, addr)
1.1  mrg
1.1  mrg /* Initialize data used by insn expanders.  This is called from insn_emit,
1.1  mrg    once for every function before code is generated.  */
1.1  mrg #define INIT_EXPANDERS  arm_init_expanders ()
1.1  mrg
1.1  mrg /* Length in units of the trampoline for entering a nested function.  */
1.1  mrg #define TRAMPOLINE_SIZE  (TARGET_32BIT ? 16 : 20)
1.1  mrg
1.1  mrg /* Alignment required for a trampoline in bits.  */
1.1  mrg #define TRAMPOLINE_ALIGNMENT  32
1.1  mrg
1.1  mrg /* Addressing modes, and classification of registers for them.  */
1.1  mrg #define HAVE_POST_INCREMENT   1
1.1  mrg #define HAVE_PRE_INCREMENT    TARGET_32BIT
1.1  mrg #define HAVE_POST_DECREMENT   TARGET_32BIT
1.1  mrg #define HAVE_PRE_DECREMENT    TARGET_32BIT
1.1  mrg #define HAVE_PRE_MODIFY_DISP  TARGET_32BIT
1.1  mrg #define HAVE_POST_MODIFY_DISP TARGET_32BIT
1.1  mrg #define HAVE_PRE_MODIFY_REG   TARGET_32BIT
1.1  mrg #define HAVE_POST_MODIFY_REG  TARGET_32BIT
1.1  mrg
1.1  mrg /* Macros to check register numbers against specific register classes.  */
1.1  mrg
1.1  mrg /* These assume that REGNO is a hard or pseudo reg number.
1.1  mrg    They give nonzero only if REGNO is a hard reg of the suitable class
1.1  mrg    or a pseudo reg currently allocated to a suitable hard reg.
1.1  mrg    Since they use reg_renumber, they are safe only once reg_renumber
1.1  mrg    has been allocated, which happens in local-alloc.c.  */
1.1  mrg #define TEST_REGNO(R, TEST, VALUE) \
1.1  mrg   ((R TEST VALUE) || ((unsigned) reg_renumber[R] TEST VALUE))
1.1  mrg
1.1  mrg /* Don't allow the pc to be used.  */
1.1  mrg #define ARM_REGNO_OK_FOR_BASE_P(REGNO)			\
1.1  mrg   (TEST_REGNO (REGNO, <, PC_REGNUM)			\
1.1  mrg    || TEST_REGNO (REGNO, ==, FRAME_POINTER_REGNUM)	\
1.1  mrg    || TEST_REGNO (REGNO, ==, ARG_POINTER_REGNUM))
1.1  mrg
1.1  mrg #define THUMB1_REGNO_MODE_OK_FOR_BASE_P(REGNO, MODE)		\
1.1  mrg   (TEST_REGNO (REGNO, <=, LAST_LO_REGNUM)			\
1.1  mrg    || (GET_MODE_SIZE (MODE) >= 4				\
1.1  mrg        && TEST_REGNO (REGNO, ==, STACK_POINTER_REGNUM)))
1.1  mrg
1.1  mrg #define REGNO_MODE_OK_FOR_BASE_P(REGNO, MODE)		\
1.1  mrg   (TARGET_THUMB1					\
1.1  mrg    ? THUMB1_REGNO_MODE_OK_FOR_BASE_P (REGNO, MODE)	\
1.1  mrg    : ARM_REGNO_OK_FOR_BASE_P (REGNO))
1.1  mrg
1.1  mrg /* Nonzero if X can be the base register in a reg+reg addressing mode.
1.1  mrg    For Thumb, we can not use SP + reg, so reject SP.  */
1.1  mrg #define REGNO_MODE_OK_FOR_REG_BASE_P(X, MODE)	\
1.1  mrg   REGNO_MODE_OK_FOR_BASE_P (X, QImode)
1.1  mrg
1.1  mrg /* For ARM code, we don't care about the mode, but for Thumb, the index
1.1  mrg    must be suitable for use in a QImode load.  */
1.1  mrg #define REGNO_OK_FOR_INDEX_P(REGNO)	\
1.1  mrg   (REGNO_MODE_OK_FOR_BASE_P (REGNO, QImode) \
1.1  mrg    && !TEST_REGNO (REGNO, ==, STACK_POINTER_REGNUM))
1.1  mrg
1.1  mrg /* Maximum number of registers that can appear in a valid memory address.
1.1  mrg    Shifts in addresses can't be by a register.  */
1.1  mrg #define MAX_REGS_PER_ADDRESS 2
1.1  mrg
1.1  mrg /* Recognize any constant value that is a valid address.  */
1.1  mrg /* XXX We can address any constant, eventually...  */
1.1  mrg /* ??? Should the TARGET_ARM here also apply to thumb2?  */
1.1  mrg #define CONSTANT_ADDRESS_P(X)  			\
1.1  mrg   (GET_CODE (X) == SYMBOL_REF 			\
1.1  mrg    && (CONSTANT_POOL_ADDRESS_P (X)		\
1.1  mrg        || (TARGET_ARM && optimize > 0 && SYMBOL_REF_FLAG (X))))
1.1  mrg
1.1  mrg /* True if SYMBOL + OFFSET constants must refer to something within
1.1  mrg    SYMBOL's section.  */
1.1  mrg #define ARM_OFFSETS_MUST_BE_WITHIN_SECTIONS_P 0
1.1  mrg
1.1  mrg /* Nonzero if all target requires all absolute relocations be R_ARM_ABS32.  */
1.1  mrg #ifndef TARGET_DEFAULT_WORD_RELOCATIONS
1.1  mrg #define TARGET_DEFAULT_WORD_RELOCATIONS 0
1.1  mrg #endif
1.1  mrg
1.1  mrg /* Nonzero if the constant value X is a legitimate general operand.
1.1  mrg    It is given that X satisfies CONSTANT_P or is a CONST_DOUBLE.
1.1  mrg
1.1  mrg    On the ARM, allow any integer (invalid ones are removed later by insn
1.1  mrg    patterns), nice doubles and symbol_refs which refer to the function's
1.1  mrg    constant pool XXX.
1.1  mrg
1.1  mrg    When generating pic allow anything.  */
1.1  mrg #define ARM_LEGITIMATE_CONSTANT_P(X)	(flag_pic || ! label_mentioned_p (X))
1.1  mrg
1.1  mrg #define THUMB_LEGITIMATE_CONSTANT_P(X)	\
1.1  mrg  (   GET_CODE (X) == CONST_INT		\
1.1  mrg   || GET_CODE (X) == CONST_DOUBLE	\
1.1  mrg   || CONSTANT_ADDRESS_P (X)		\
1.1  mrg   || flag_pic)
1.1  mrg
1.1  mrg #define LEGITIMATE_CONSTANT_P(X)			\
1.1  mrg   (!arm_cannot_force_const_mem (X)			\
1.1  mrg    && (TARGET_32BIT ? ARM_LEGITIMATE_CONSTANT_P (X)	\
1.1  mrg 		    : THUMB_LEGITIMATE_CONSTANT_P (X)))
1.1  mrg
1.1  mrg #ifndef SUBTARGET_NAME_ENCODING_LENGTHS
1.1  mrg #define SUBTARGET_NAME_ENCODING_LENGTHS
1.1  mrg #endif
1.1  mrg
1.1  mrg /* This is a C fragment for the inside of a switch statement.
1.1  mrg    Each case label should return the number of characters to
1.1  mrg    be stripped from the start of a function's name, if that
1.1  mrg    name starts with the indicated character.  */
1.1  mrg #define ARM_NAME_ENCODING_LENGTHS		\
1.1  mrg   case '*':  return 1;				\
1.1  mrg   SUBTARGET_NAME_ENCODING_LENGTHS
1.1  mrg
1.1  mrg /* This is how to output a reference to a user-level label named NAME.
1.1  mrg    `assemble_name' uses this.  */
1.1  mrg #undef  ASM_OUTPUT_LABELREF
1.1  mrg #define ASM_OUTPUT_LABELREF(FILE, NAME)		\
1.1  mrg    arm_asm_output_labelref (FILE, NAME)
1.1  mrg
1.1  mrg /* Output IT instructions for conditionally executed Thumb-2 instructions.  */
1.1  mrg #define ASM_OUTPUT_OPCODE(STREAM, PTR)	\
1.1  mrg   if (TARGET_THUMB2)			\
1.1  mrg     thumb2_asm_output_opcode (STREAM);
1.1  mrg
1.1  mrg /* The EABI specifies that constructors should go in .init_array.
1.1  mrg    Other targets use .ctors for compatibility.  */
1.1  mrg #ifndef ARM_EABI_CTORS_SECTION_OP
1.1  mrg #define ARM_EABI_CTORS_SECTION_OP \
1.1  mrg   "\t.section\t.init_array,\"aw\",%init_array"
1.1  mrg #endif
1.1  mrg #ifndef ARM_EABI_DTORS_SECTION_OP
1.1  mrg #define ARM_EABI_DTORS_SECTION_OP \
1.1  mrg   "\t.section\t.fini_array,\"aw\",%fini_array"
1.1  mrg #endif
1.1  mrg #define ARM_CTORS_SECTION_OP \
1.1  mrg   "\t.section\t.ctors,\"aw\",%progbits"
1.1  mrg #define ARM_DTORS_SECTION_OP \
1.1  mrg   "\t.section\t.dtors,\"aw\",%progbits"
1.1  mrg
1.1  mrg /* Define CTORS_SECTION_ASM_OP.  */
1.1  mrg #undef CTORS_SECTION_ASM_OP
1.1  mrg #undef DTORS_SECTION_ASM_OP
1.1  mrg #ifndef IN_LIBGCC2
1.1  mrg # define CTORS_SECTION_ASM_OP \
1.1  mrg    (TARGET_AAPCS_BASED ? ARM_EABI_CTORS_SECTION_OP : ARM_CTORS_SECTION_OP)
1.1  mrg # define DTORS_SECTION_ASM_OP \
1.1  mrg    (TARGET_AAPCS_BASED ? ARM_EABI_DTORS_SECTION_OP : ARM_DTORS_SECTION_OP)
1.1  mrg #else /* !defined (IN_LIBGCC2) */
1.1  mrg /* In libgcc, CTORS_SECTION_ASM_OP must be a compile-time constant,
1.1  mrg    so we cannot use the definition above.  */
1.1  mrg # ifdef __ARM_EABI__
1.1  mrg /* The .ctors section is not part of the EABI, so we do not define
1.1  mrg    CTORS_SECTION_ASM_OP when in libgcc; that prevents crtstuff
1.1  mrg    from trying to use it.  We do define it when doing normal
1.1  mrg    compilation, as .init_array can be used instead of .ctors.  */
1.1  mrg /* There is no need to emit begin or end markers when using
1.1  mrg    init_array; the dynamic linker will compute the size of the
1.1  mrg    array itself based on special symbols created by the static
1.1  mrg    linker.  However, we do need to arrange to set up
1.1  mrg    exception-handling here.  */
1.1  mrg #   define CTOR_LIST_BEGIN asm (ARM_EABI_CTORS_SECTION_OP)
1.1  mrg #   define CTOR_LIST_END /* empty */
1.1  mrg #   define DTOR_LIST_BEGIN asm (ARM_EABI_DTORS_SECTION_OP)
1.1  mrg #   define DTOR_LIST_END /* empty */
1.1  mrg # else /* !defined (__ARM_EABI__) */
1.1  mrg #   define CTORS_SECTION_ASM_OP ARM_CTORS_SECTION_OP
1.1  mrg #   define DTORS_SECTION_ASM_OP ARM_DTORS_SECTION_OP
1.1  mrg # endif /* !defined (__ARM_EABI__) */
1.1  mrg #endif /* !defined (IN_LIBCC2) */
1.1  mrg
1.1  mrg /* True if the operating system can merge entities with vague linkage
1.1  mrg    (e.g., symbols in COMDAT group) during dynamic linking.  */
1.1  mrg #ifndef TARGET_ARM_DYNAMIC_VAGUE_LINKAGE_P
1.1  mrg #define TARGET_ARM_DYNAMIC_VAGUE_LINKAGE_P true
1.1  mrg #endif
1.1  mrg
1.1  mrg #define ARM_OUTPUT_FN_UNWIND(F, PROLOGUE) arm_output_fn_unwind (F, PROLOGUE)
1.1  mrg
1.1  mrg #ifdef TARGET_UNWIND_INFO
1.1  mrg #define ARM_EABI_UNWIND_TABLES \
1.1  mrg   ((!USING_SJLJ_EXCEPTIONS && flag_exceptions) || flag_unwind_tables)
1.1  mrg #else
1.1  mrg #define ARM_EABI_UNWIND_TABLES 0
1.1  mrg #endif
1.1  mrg
1.1  mrg /* The macros REG_OK_FOR..._P assume that the arg is a REG rtx
1.1  mrg    and check its validity for a certain class.
1.1  mrg    We have two alternate definitions for each of them.
1.1  mrg    The usual definition accepts all pseudo regs; the other rejects
1.1  mrg    them unless they have been allocated suitable hard regs.
1.1  mrg    The symbol REG_OK_STRICT causes the latter definition to be used.
1.1  mrg    Thumb-2 has the same restrictions as arm.  */
1.1  mrg #ifndef REG_OK_STRICT
1.1  mrg
1.1  mrg #define ARM_REG_OK_FOR_BASE_P(X)		\
1.1  mrg   (REGNO (X) <= LAST_ARM_REGNUM			\
1.1  mrg    || REGNO (X) >= FIRST_PSEUDO_REGISTER	\
1.1  mrg    || REGNO (X) == FRAME_POINTER_REGNUM		\
1.1  mrg    || REGNO (X) == ARG_POINTER_REGNUM)
1.1  mrg
1.1  mrg #define ARM_REG_OK_FOR_INDEX_P(X)		\
1.1  mrg   ((REGNO (X) <= LAST_ARM_REGNUM		\
1.1  mrg     && REGNO (X) != STACK_POINTER_REGNUM)	\
1.1  mrg    || REGNO (X) >= FIRST_PSEUDO_REGISTER	\
1.1  mrg    || REGNO (X) == FRAME_POINTER_REGNUM		\
1.1  mrg    || REGNO (X) == ARG_POINTER_REGNUM)
1.1  mrg
1.1  mrg #define THUMB1_REG_MODE_OK_FOR_BASE_P(X, MODE)	\
1.1  mrg   (REGNO (X) <= LAST_LO_REGNUM			\
1.1  mrg    || REGNO (X) >= FIRST_PSEUDO_REGISTER	\
1.1  mrg    || (GET_MODE_SIZE (MODE) >= 4		\
1.1  mrg        && (REGNO (X) == STACK_POINTER_REGNUM	\
1.1  mrg 	   || (X) == hard_frame_pointer_rtx	\
1.1  mrg 	   || (X) == arg_pointer_rtx)))
1.1  mrg
1.1  mrg #define REG_STRICT_P 0
1.1  mrg
1.1  mrg #else /* REG_OK_STRICT */
1.1  mrg
1.1  mrg #define ARM_REG_OK_FOR_BASE_P(X) 		\
1.1  mrg   ARM_REGNO_OK_FOR_BASE_P (REGNO (X))
1.1  mrg
1.1  mrg #define ARM_REG_OK_FOR_INDEX_P(X) 		\
1.1  mrg   ARM_REGNO_OK_FOR_INDEX_P (REGNO (X))
1.1  mrg
1.1  mrg #define THUMB1_REG_MODE_OK_FOR_BASE_P(X, MODE)	\
1.1  mrg   THUMB1_REGNO_MODE_OK_FOR_BASE_P (REGNO (X), MODE)
1.1  mrg
1.1  mrg #define REG_STRICT_P 1
1.1  mrg
1.1  mrg #endif /* REG_OK_STRICT */
1.1  mrg
1.1  mrg /* Now define some helpers in terms of the above.  */
1.1  mrg
1.1  mrg #define REG_MODE_OK_FOR_BASE_P(X, MODE)		\
1.1  mrg   (TARGET_THUMB1				\
1.1  mrg    ? THUMB1_REG_MODE_OK_FOR_BASE_P (X, MODE)	\
1.1  mrg    : ARM_REG_OK_FOR_BASE_P (X))
1.1  mrg
1.1  mrg /* For 16-bit Thumb, a valid index register is anything that can be used in
1.1  mrg    a byte load instruction.  */
1.1  mrg #define THUMB1_REG_OK_FOR_INDEX_P(X) \
1.1  mrg   THUMB1_REG_MODE_OK_FOR_BASE_P (X, QImode)
1.1  mrg
1.1  mrg /* Nonzero if X is a hard reg that can be used as an index
1.1  mrg    or if it is a pseudo reg.  On the Thumb, the stack pointer
1.1  mrg    is not suitable.  */
1.1  mrg #define REG_OK_FOR_INDEX_P(X)			\
1.1  mrg   (TARGET_THUMB1				\
1.1  mrg    ? THUMB1_REG_OK_FOR_INDEX_P (X)		\
1.1  mrg    : ARM_REG_OK_FOR_INDEX_P (X))
1.1  mrg
1.1  mrg /* Nonzero if X can be the base register in a reg+reg addressing mode.
1.1  mrg    For Thumb, we can not use SP + reg, so reject SP.  */
1.1  mrg #define REG_MODE_OK_FOR_REG_BASE_P(X, MODE)	\
1.1  mrg   REG_OK_FOR_INDEX_P (X)
1.1  mrg
1.1  mrg #define ARM_BASE_REGISTER_RTX_P(X)  \
1.1  mrg   (GET_CODE (X) == REG && ARM_REG_OK_FOR_BASE_P (X))
1.1  mrg
1.1  mrg #define ARM_INDEX_REGISTER_RTX_P(X)  \
1.1  mrg   (GET_CODE (X) == REG && ARM_REG_OK_FOR_INDEX_P (X))
1.1  mrg
1.1  mrg /* Define this for compatibility reasons. */
1.1  mrg #define HANDLE_PRAGMA_PACK_PUSH_POP 1
1.1  mrg
1.1  mrg /* Specify the machine mode that this machine uses
1.1  mrg    for the index in the tablejump instruction.  */
1.1  mrg #define CASE_VECTOR_MODE Pmode
1.1  mrg
1.1  mrg #define CASE_VECTOR_PC_RELATIVE (TARGET_THUMB2				\
1.1  mrg 				 || (TARGET_THUMB1			\
1.1  mrg 				     && (optimize_size || flag_pic)))
1.1  mrg
1.1  mrg #define CASE_VECTOR_SHORTEN_MODE(min, max, body)			\
1.1  mrg   (TARGET_THUMB1							\
1.1  mrg    ? (min >= 0 && max < 512						\
1.1  mrg       ? (ADDR_DIFF_VEC_FLAGS (body).offset_unsigned = 1, QImode)	\
1.1  mrg       : min >= -256 && max < 256					\
1.1  mrg       ? (ADDR_DIFF_VEC_FLAGS (body).offset_unsigned = 0, QImode)	\
1.1  mrg       : min >= 0 && max < 8192						\
1.1  mrg       ? (ADDR_DIFF_VEC_FLAGS (body).offset_unsigned = 1, HImode)	\
1.1  mrg       : min >= -4096 && max < 4096					\
1.1  mrg       ? (ADDR_DIFF_VEC_FLAGS (body).offset_unsigned = 0, HImode)	\
1.1  mrg       : SImode)								\
1.1  mrg    : ((min < 0 || max >= 0x2000 || !TARGET_THUMB2) ? SImode		\
1.1  mrg       : (max >= 0x200) ? HImode						\
1.1  mrg       : QImode))
1.1  mrg
1.1  mrg /* signed 'char' is most compatible, but RISC OS wants it unsigned.
1.1  mrg    unsigned is probably best, but may break some code.  */
1.1  mrg #ifndef DEFAULT_SIGNED_CHAR
1.1  mrg #define DEFAULT_SIGNED_CHAR  0
1.1  mrg #endif
1.1  mrg
1.1  mrg /* Max number of bytes we can move from memory to memory
1.1  mrg    in one reasonably fast instruction.  */
1.1  mrg #define MOVE_MAX 4
1.1  mrg
1.1  mrg #undef  MOVE_RATIO
1.1  mrg #define MOVE_RATIO(speed) (arm_tune_xscale ? 4 : 2)
1.1  mrg
1.1  mrg /* Define if operations between registers always perform the operation
1.1  mrg    on the full register even if a narrower mode is specified.  */
1.1  mrg #define WORD_REGISTER_OPERATIONS
1.1  mrg
1.1  mrg /* Define if loading in MODE, an integral mode narrower than BITS_PER_WORD
1.1  mrg    will either zero-extend or sign-extend.  The value of this macro should
1.1  mrg    be the code that says which one of the two operations is implicitly
1.1  mrg    done, UNKNOWN if none.  */
1.1  mrg #define LOAD_EXTEND_OP(MODE)						\
1.1  mrg   (TARGET_THUMB ? ZERO_EXTEND :						\
1.1  mrg    ((arm_arch4 || (MODE) == QImode) ? ZERO_EXTEND			\
1.1  mrg     : ((BYTES_BIG_ENDIAN && (MODE) == HImode) ? SIGN_EXTEND : UNKNOWN)))
1.1  mrg
1.1  mrg /* Nonzero if access to memory by bytes is slow and undesirable.  */
1.1  mrg #define SLOW_BYTE_ACCESS 0
1.1  mrg
1.1  mrg #define SLOW_UNALIGNED_ACCESS(MODE, ALIGN) 1
1.1  mrg
1.1  mrg /* Immediate shift counts are truncated by the output routines (or was it
1.1  mrg    the assembler?).  Shift counts in a register are truncated by ARM.  Note
1.1  mrg    that the native compiler puts too large (> 32) immediate shift counts
1.1  mrg    into a register and shifts by the register, letting the ARM decide what
1.1  mrg    to do instead of doing that itself.  */
1.1  mrg /* This is all wrong.  Defining SHIFT_COUNT_TRUNCATED tells combine that
1.1  mrg    code like (X << (Y % 32)) for register X, Y is equivalent to (X << Y).
1.1  mrg    On the arm, Y in a register is used modulo 256 for the shift. Only for
1.1  mrg    rotates is modulo 32 used.  */
1.1  mrg /* #define SHIFT_COUNT_TRUNCATED 1 */
1.1  mrg
1.1  mrg /* All integers have the same format so truncation is easy.  */
1.1  mrg #define TRULY_NOOP_TRUNCATION(OUTPREC, INPREC)  1
1.1  mrg
1.1  mrg /* Calling from registers is a massive pain.  */
1.1  mrg #define NO_FUNCTION_CSE 1
1.1  mrg
1.1  mrg /* The machine modes of pointers and functions */
1.1  mrg #define Pmode  SImode
1.1  mrg #define FUNCTION_MODE  Pmode
1.1  mrg
1.1  mrg #define ARM_FRAME_RTX(X)					\
1.1  mrg   (   (X) == frame_pointer_rtx || (X) == stack_pointer_rtx	\
1.1  mrg    || (X) == arg_pointer_rtx)
1.1  mrg
1.1  mrg /* Moves to and from memory are quite expensive */
1.1  mrg #define MEMORY_MOVE_COST(M, CLASS, IN)			\
1.1  mrg   (TARGET_32BIT ? 10 :					\
1.1  mrg    ((GET_MODE_SIZE (M) < 4 ? 8 : 2 * GET_MODE_SIZE (M))	\
1.1  mrg     * (CLASS == LO_REGS ? 1 : 2)))
1.1  mrg
1.1  mrg /* Try to generate sequences that don't involve branches, we can then use
1.1  mrg    conditional instructions */
1.1  mrg #define BRANCH_COST(speed_p, predictable_p) \
1.1  mrg   (TARGET_32BIT ? 4 : (optimize > 0 ? 2 : 0))
1.1  mrg
1.1  mrg /* Position Independent Code.  */
1.1  mrg /* We decide which register to use based on the compilation options and
1.1  mrg    the assembler in use; this is more general than the APCS restriction of
1.1  mrg    using sb (r9) all the time.  */
1.1  mrg extern unsigned arm_pic_register;
1.1  mrg
1.1  mrg /* The register number of the register used to address a table of static
1.1  mrg    data addresses in memory.  */
1.1  mrg #define PIC_OFFSET_TABLE_REGNUM arm_pic_register
1.1  mrg
1.1  mrg /* We can't directly access anything that contains a symbol,
1.1  mrg    nor can we indirect via the constant pool.  One exception is
1.1  mrg    UNSPEC_TLS, which is always PIC.  */
1.1  mrg #define LEGITIMATE_PIC_OPERAND_P(X)					\
1.1  mrg 	(!(symbol_mentioned_p (X)					\
1.1  mrg 	   || label_mentioned_p (X)					\
1.1  mrg 	   || (GET_CODE (X) == SYMBOL_REF				\
1.1  mrg 	       && CONSTANT_POOL_ADDRESS_P (X)				\
1.1  mrg 	       && (symbol_mentioned_p (get_pool_constant (X))		\
1.1  mrg 		   || label_mentioned_p (get_pool_constant (X)))))	\
1.1  mrg 	 || tls_mentioned_p (X))
1.1  mrg
1.1  mrg /* We need to know when we are making a constant pool; this determines
1.1  mrg    whether data needs to be in the GOT or can be referenced via a GOT
1.1  mrg    offset.  */
1.1  mrg extern int making_const_table;
1.1  mrg
1.1  mrg /* Handle pragmas for compatibility with Intel's compilers.  */
1.1  mrg /* Also abuse this to register additional C specific EABI attributes.  */
1.1  mrg #define REGISTER_TARGET_PRAGMAS() do {					\
1.1  mrg   c_register_pragma (0, "long_calls", arm_pr_long_calls);		\
1.1  mrg   c_register_pragma (0, "no_long_calls", arm_pr_no_long_calls);		\
1.1  mrg   c_register_pragma (0, "long_calls_off", arm_pr_long_calls_off);	\
1.1  mrg   arm_lang_object_attributes_init(); \
1.1  mrg } while (0)
1.1  mrg
1.1  mrg /* Condition code information.  */
1.1  mrg /* Given a comparison code (EQ, NE, etc.) and the first operand of a COMPARE,
1.1  mrg    return the mode to be used for the comparison.  */
1.1  mrg
1.1  mrg #define SELECT_CC_MODE(OP, X, Y)  arm_select_cc_mode (OP, X, Y)
1.1  mrg
1.1  mrg #define REVERSIBLE_CC_MODE(MODE) 1
1.1  mrg
1.1  mrg #define REVERSE_CONDITION(CODE,MODE) \
1.1  mrg   (((MODE) == CCFPmode || (MODE) == CCFPEmode) \
1.1  mrg    ? reverse_condition_maybe_unordered (code) \
1.1  mrg    : reverse_condition (code))
1.1  mrg
1.1  mrg #define CANONICALIZE_COMPARISON(CODE, OP0, OP1)				\
1.1  mrg   do									\
1.1  mrg     {									\
1.1  mrg       if (GET_CODE (OP1) == CONST_INT					\
1.1  mrg           && ! (const_ok_for_arm (INTVAL (OP1))				\
1.1  mrg 	        || (const_ok_for_arm (- INTVAL (OP1)))))		\
1.1  mrg         {								\
1.1  mrg           rtx const_op = OP1;						\
1.1  mrg           CODE = arm_canonicalize_comparison ((CODE), GET_MODE (OP0),	\
1.1  mrg 					      &const_op);		\
1.1  mrg           OP1 = const_op;						\
1.1  mrg         }								\
1.1  mrg     }									\
1.1  mrg   while (0)
1.1  mrg
1.1  mrg /* The arm5 clz instruction returns 32.  */
1.1  mrg #define CLZ_DEFINED_VALUE_AT_ZERO(MODE, VALUE)  ((VALUE) = 32, 1)
1.1  mrg #define CTZ_DEFINED_VALUE_AT_ZERO(MODE, VALUE)  ((VALUE) = 32, 1)
1.1  mrg
1.1  mrg #undef  ASM_APP_OFF
1.1  mrg #define ASM_APP_OFF (TARGET_THUMB1 ? "\t.code\t16\n" : \
1.1  mrg 		     TARGET_THUMB2 ? "\t.thumb\n" : "")
1.1  mrg
1.1  mrg /* Output a push or a pop instruction (only used when profiling).
1.1  mrg    We can't push STATIC_CHAIN_REGNUM (r12) directly with Thumb-1.  We know
1.1  mrg    that ASM_OUTPUT_REG_PUSH will be matched with ASM_OUTPUT_REG_POP, and
1.1  mrg    that r7 isn't used by the function profiler, so we can use it as a
1.1  mrg    scratch reg.  WARNING: This isn't safe in the general case!  It may be
1.1  mrg    sensitive to future changes in final.c:profile_function.  */
1.1  mrg #define ASM_OUTPUT_REG_PUSH(STREAM, REGNO)		\
1.1  mrg   do							\
1.1  mrg     {							\
1.1  mrg       if (TARGET_ARM)					\
1.1  mrg 	asm_fprintf (STREAM,"\tstmfd\t%r!,{%r}\n",	\
1.1  mrg 		     STACK_POINTER_REGNUM, REGNO);	\
1.1  mrg       else if (TARGET_THUMB1				\
1.1  mrg 	       && (REGNO) == STATIC_CHAIN_REGNUM)	\
1.1  mrg 	{						\
1.1  mrg 	  asm_fprintf (STREAM, "\tpush\t{r7}\n");	\
1.1  mrg 	  asm_fprintf (STREAM, "\tmov\tr7, %r\n", REGNO);\
1.1  mrg 	  asm_fprintf (STREAM, "\tpush\t{r7}\n");	\
1.1  mrg 	}						\
1.1  mrg       else						\
1.1  mrg 	asm_fprintf (STREAM, "\tpush {%r}\n", REGNO);	\
1.1  mrg     } while (0)
1.1  mrg
1.1  mrg
1.1  mrg /* See comment for ASM_OUTPUT_REG_PUSH concerning Thumb-1 issue.  */
1.1  mrg #define ASM_OUTPUT_REG_POP(STREAM, REGNO)		\
1.1  mrg   do							\
1.1  mrg     {							\
1.1  mrg       if (TARGET_ARM)					\
1.1  mrg 	asm_fprintf (STREAM, "\tldmfd\t%r!,{%r}\n",	\
1.1  mrg 		     STACK_POINTER_REGNUM, REGNO);	\
1.1  mrg       else if (TARGET_THUMB1				\
1.1  mrg 	       && (REGNO) == STATIC_CHAIN_REGNUM)	\
1.1  mrg 	{						\
1.1  mrg 	  asm_fprintf (STREAM, "\tpop\t{r7}\n");	\
1.1  mrg 	  asm_fprintf (STREAM, "\tmov\t%r, r7\n", REGNO);\
1.1  mrg 	  asm_fprintf (STREAM, "\tpop\t{r7}\n");	\
1.1  mrg 	}						\
1.1  mrg       else						\
1.1  mrg 	asm_fprintf (STREAM, "\tpop {%r}\n", REGNO);	\
1.1  mrg     } while (0)
1.1  mrg
1.1  mrg /* Jump table alignment is explicit in ASM_OUTPUT_CASE_LABEL.  */
1.1  mrg #define ADDR_VEC_ALIGN(JUMPTABLE) 0
1.1  mrg
1.1  mrg /* This is how to output a label which precedes a jumptable.  Since
1.1  mrg    Thumb instructions are 2 bytes, we may need explicit alignment here.  */
1.1  mrg #undef  ASM_OUTPUT_CASE_LABEL
1.1  mrg #define ASM_OUTPUT_CASE_LABEL(FILE, PREFIX, NUM, JUMPTABLE)		\
1.1  mrg   do									\
1.1  mrg     {									\
1.1  mrg       if (TARGET_THUMB && GET_MODE (PATTERN (JUMPTABLE)) == SImode)	\
1.1  mrg         ASM_OUTPUT_ALIGN (FILE, 2);					\
1.1  mrg       (*targetm.asm_out.internal_label) (FILE, PREFIX, NUM);		\
1.1  mrg     }									\
1.1  mrg   while (0)
1.1  mrg
1.1  mrg /* Make sure subsequent insns are aligned after a TBB.  */
1.1  mrg #define ASM_OUTPUT_CASE_END(FILE, NUM, JUMPTABLE)	\
1.1  mrg   do							\
1.1  mrg     {							\
1.1  mrg       if (GET_MODE (PATTERN (JUMPTABLE)) == QImode)	\
1.1  mrg 	ASM_OUTPUT_ALIGN (FILE, 1);			\
1.1  mrg     }							\
1.1  mrg   while (0)
1.1  mrg
1.1  mrg #define ARM_DECLARE_FUNCTION_NAME(STREAM, NAME, DECL) 	\
1.1  mrg   do							\
1.1  mrg     {							\
1.1  mrg       if (TARGET_THUMB) 				\
1.1  mrg         {						\
1.1  mrg           if (is_called_in_ARM_mode (DECL)		\
1.1  mrg 	      || (TARGET_THUMB1 && !TARGET_THUMB1_ONLY	\
1.1  mrg 		  && cfun->is_thunk))	\
1.1  mrg             fprintf (STREAM, "\t.code 32\n") ;		\
1.1  mrg           else if (TARGET_THUMB1)			\
1.1  mrg            fprintf (STREAM, "\t.code\t16\n\t.thumb_func\n") ;	\
1.1  mrg           else						\
1.1  mrg            fprintf (STREAM, "\t.thumb\n\t.thumb_func\n") ;	\
1.1  mrg         }						\
1.1  mrg       if (TARGET_POKE_FUNCTION_NAME)			\
1.1  mrg         arm_poke_function_name (STREAM, (const char *) NAME);	\
1.1  mrg     }							\
1.1  mrg   while (0)
1.1  mrg
1.1  mrg /* For aliases of functions we use .thumb_set instead.  */
1.1  mrg #define ASM_OUTPUT_DEF_FROM_DECLS(FILE, DECL1, DECL2)		\
1.1  mrg   do						   		\
1.1  mrg     {								\
1.1  mrg       const char *const LABEL1 = XSTR (XEXP (DECL_RTL (decl), 0), 0); \
1.1  mrg       const char *const LABEL2 = IDENTIFIER_POINTER (DECL2);	\
1.1  mrg 								\
1.1  mrg       if (TARGET_THUMB && TREE_CODE (DECL1) == FUNCTION_DECL)	\
1.1  mrg 	{							\
1.1  mrg 	  fprintf (FILE, "\t.thumb_set ");			\
1.1  mrg 	  assemble_name (FILE, LABEL1);			   	\
1.1  mrg 	  fprintf (FILE, ",");			   		\
1.1  mrg 	  assemble_name (FILE, LABEL2);		   		\
1.1  mrg 	  fprintf (FILE, "\n");					\
1.1  mrg 	}							\
1.1  mrg       else							\
1.1  mrg 	ASM_OUTPUT_DEF (FILE, LABEL1, LABEL2);			\
1.1  mrg     }								\
1.1  mrg   while (0)
1.1  mrg
1.1  mrg #ifdef HAVE_GAS_MAX_SKIP_P2ALIGN
1.1  mrg /* To support -falign-* switches we need to use .p2align so
1.1  mrg    that alignment directives in code sections will be padded
1.1  mrg    with no-op instructions, rather than zeroes.  */
1.1  mrg #define ASM_OUTPUT_MAX_SKIP_ALIGN(FILE, LOG, MAX_SKIP)		\
1.1  mrg   if ((LOG) != 0)						\
1.1  mrg     {								\
1.1  mrg       if ((MAX_SKIP) == 0)					\
1.1  mrg         fprintf ((FILE), "\t.p2align %d\n", (int) (LOG));	\
1.1  mrg       else							\
1.1  mrg         fprintf ((FILE), "\t.p2align %d,,%d\n",			\
1.1  mrg                  (int) (LOG), (int) (MAX_SKIP));		\
1.1  mrg     }
1.1  mrg #endif
1.1  mrg
1.1  mrg /* Add two bytes to the length of conditionally executed Thumb-2
1.1  mrg    instructions for the IT instruction.  */
1.1  mrg #define ADJUST_INSN_LENGTH(insn, length) \
1.1  mrg   if (TARGET_THUMB2 && GET_CODE (PATTERN (insn)) == COND_EXEC) \
1.1  mrg     length += 2;
1.1  mrg
1.1  mrg /* Only perform branch elimination (by making instructions conditional) if
1.1  mrg    we're optimizing.  For Thumb-2 check if any IT instructions need
1.1  mrg    outputting.  */
1.1  mrg #define FINAL_PRESCAN_INSN(INSN, OPVEC, NOPERANDS)	\
1.1  mrg   if (TARGET_ARM && optimize)				\
1.1  mrg     arm_final_prescan_insn (INSN);			\
1.1  mrg   else if (TARGET_THUMB2)				\
1.1  mrg     thumb2_final_prescan_insn (INSN);			\
1.1  mrg   else if (TARGET_THUMB1)				\
1.1  mrg     thumb1_final_prescan_insn (INSN)
1.1  mrg
1.1  mrg #define PRINT_OPERAND_PUNCT_VALID_P(CODE)	\
1.1  mrg   (CODE == '@' || CODE == '|' || CODE == '.'	\
1.1  mrg    || CODE == '(' || CODE == ')' || CODE == '#'	\
1.1  mrg    || (TARGET_32BIT && (CODE == '?'))		\
1.1  mrg    || (TARGET_THUMB2 && (CODE == '!'))		\
1.1  mrg    || (TARGET_THUMB && (CODE == '_')))
1.1  mrg
1.1  mrg /* Output an operand of an instruction.  */
1.1  mrg #define PRINT_OPERAND(STREAM, X, CODE)  \
1.1  mrg   arm_print_operand (STREAM, X, CODE)
1.1  mrg
1.1  mrg #define ARM_SIGN_EXTEND(x)  ((HOST_WIDE_INT)			\
1.1  mrg   (HOST_BITS_PER_WIDE_INT <= 32 ? (unsigned HOST_WIDE_INT) (x)	\
1.1  mrg    : ((((unsigned HOST_WIDE_INT)(x)) & (unsigned HOST_WIDE_INT) 0xffffffff) |\
1.1  mrg       ((((unsigned HOST_WIDE_INT)(x)) & (unsigned HOST_WIDE_INT) 0x80000000) \
1.1  mrg        ? ((~ (unsigned HOST_WIDE_INT) 0)			\
1.1  mrg 	  & ~ (unsigned HOST_WIDE_INT) 0xffffffff)		\
1.1  mrg        : 0))))
1.1  mrg
1.1  mrg /* Output the address of an operand.  */
1.1  mrg #define ARM_PRINT_OPERAND_ADDRESS(STREAM, X)				\
1.1  mrg {									\
1.1  mrg     int is_minus = GET_CODE (X) == MINUS;				\
1.1  mrg 									\
1.1  mrg     if (GET_CODE (X) == REG)						\
1.1  mrg       asm_fprintf (STREAM, "[%r, #0]", REGNO (X));			\
1.1  mrg     else if (GET_CODE (X) == PLUS || is_minus)				\
1.1  mrg       {									\
1.1  mrg 	rtx base = XEXP (X, 0);						\
1.1  mrg 	rtx index = XEXP (X, 1);					\
1.1  mrg 	HOST_WIDE_INT offset = 0;					\
1.1  mrg 	if (GET_CODE (base) != REG					\
1.1  mrg 	    || (GET_CODE (index) == REG && REGNO (index) == SP_REGNUM))	\
1.1  mrg 	  {								\
1.1  mrg 	    /* Ensure that BASE is a register.  */			\
1.1  mrg             /* (one of them must be).  */				\
1.1  mrg 	    /* Also ensure the SP is not used as in index register.  */ \
1.1  mrg 	    rtx temp = base;						\
1.1  mrg 	    base = index;						\
1.1  mrg 	    index = temp;						\
1.1  mrg 	  }								\
1.1  mrg 	switch (GET_CODE (index))					\
1.1  mrg 	  {								\
1.1  mrg 	  case CONST_INT:						\
1.1  mrg 	    offset = INTVAL (index);					\
1.1  mrg 	    if (is_minus)						\
1.1  mrg 	      offset = -offset;						\
1.1  mrg 	    asm_fprintf (STREAM, "[%r, #%wd]",				\
1.1  mrg 		         REGNO (base), offset);				\
1.1  mrg 	    break;							\
1.1  mrg 									\
1.1  mrg 	  case REG:							\
1.1  mrg 	    asm_fprintf (STREAM, "[%r, %s%r]",				\
1.1  mrg 		     REGNO (base), is_minus ? "-" : "",			\
1.1  mrg 		     REGNO (index));					\
1.1  mrg 	    break;							\
1.1  mrg 									\
1.1  mrg 	  case MULT:							\
1.1  mrg 	  case ASHIFTRT:						\
1.1  mrg 	  case LSHIFTRT:						\
1.1  mrg 	  case ASHIFT:							\
1.1  mrg 	  case ROTATERT:						\
1.1  mrg 	  {								\
1.1  mrg 	    asm_fprintf (STREAM, "[%r, %s%r",				\
1.1  mrg 		         REGNO (base), is_minus ? "-" : "",		\
1.1  mrg                          REGNO (XEXP (index, 0)));			\
1.1  mrg 	    arm_print_operand (STREAM, index, 'S');			\
1.1  mrg 	    fputs ("]", STREAM);					\
1.1  mrg 	    break;							\
1.1  mrg 	  }								\
1.1  mrg 									\
1.1  mrg 	  default:							\
1.1  mrg 	    gcc_unreachable ();						\
1.1  mrg 	}								\
1.1  mrg     }									\
1.1  mrg   else if (GET_CODE (X) == PRE_INC || GET_CODE (X) == POST_INC		\
1.1  mrg 	   || GET_CODE (X) == PRE_DEC || GET_CODE (X) == POST_DEC)	\
1.1  mrg     {									\
1.1  mrg       extern enum machine_mode output_memory_reference_mode;		\
1.1  mrg 									\
1.1  mrg       gcc_assert (GET_CODE (XEXP (X, 0)) == REG);			\
1.1  mrg 									\
1.1  mrg       if (GET_CODE (X) == PRE_DEC || GET_CODE (X) == PRE_INC)		\
1.1  mrg 	asm_fprintf (STREAM, "[%r, #%s%d]!",				\
1.1  mrg 		     REGNO (XEXP (X, 0)),				\
1.1  mrg 		     GET_CODE (X) == PRE_DEC ? "-" : "",		\
1.1  mrg 		     GET_MODE_SIZE (output_memory_reference_mode));	\
1.1  mrg       else								\
1.1  mrg 	asm_fprintf (STREAM, "[%r], #%s%d",				\
1.1  mrg 		     REGNO (XEXP (X, 0)),				\
1.1  mrg 		     GET_CODE (X) == POST_DEC ? "-" : "",		\
1.1  mrg 		     GET_MODE_SIZE (output_memory_reference_mode));	\
1.1  mrg     }									\
1.1  mrg   else if (GET_CODE (X) == PRE_MODIFY)					\
1.1  mrg     {									\
1.1  mrg       asm_fprintf (STREAM, "[%r, ", REGNO (XEXP (X, 0)));		\
1.1  mrg       if (GET_CODE (XEXP (XEXP (X, 1), 1)) == CONST_INT)		\
1.1  mrg 	asm_fprintf (STREAM, "#%wd]!", 					\
1.1  mrg 		     INTVAL (XEXP (XEXP (X, 1), 1)));			\
1.1  mrg       else								\
1.1  mrg 	asm_fprintf (STREAM, "%r]!", 					\
1.1  mrg 		     REGNO (XEXP (XEXP (X, 1), 1)));			\
1.1  mrg     }									\
1.1  mrg   else if (GET_CODE (X) == POST_MODIFY)					\
1.1  mrg     {									\
1.1  mrg       asm_fprintf (STREAM, "[%r], ", REGNO (XEXP (X, 0)));		\
1.1  mrg       if (GET_CODE (XEXP (XEXP (X, 1), 1)) == CONST_INT)		\
1.1  mrg 	asm_fprintf (STREAM, "#%wd", 					\
1.1  mrg 		     INTVAL (XEXP (XEXP (X, 1), 1)));			\
1.1  mrg       else								\
1.1  mrg 	asm_fprintf (STREAM, "%r", 					\
1.1  mrg 		     REGNO (XEXP (XEXP (X, 1), 1)));			\
1.1  mrg     }									\
1.1  mrg   else output_addr_const (STREAM, X);					\
1.1  mrg }
1.1  mrg
1.1  mrg #define THUMB_PRINT_OPERAND_ADDRESS(STREAM, X)		\
1.1  mrg {							\
1.1  mrg   if (GET_CODE (X) == REG)				\
1.1  mrg     asm_fprintf (STREAM, "[%r]", REGNO (X));		\
1.1  mrg   else if (GET_CODE (X) == POST_INC)			\
1.1  mrg     asm_fprintf (STREAM, "%r!", REGNO (XEXP (X, 0)));	\
1.1  mrg   else if (GET_CODE (X) == PLUS)			\
1.1  mrg     {							\
1.1  mrg       gcc_assert (GET_CODE (XEXP (X, 0)) == REG);	\
1.1  mrg       if (GET_CODE (XEXP (X, 1)) == CONST_INT)		\
1.1  mrg 	asm_fprintf (STREAM, "[%r, #%wd]", 		\
1.1  mrg 		     REGNO (XEXP (X, 0)),		\
1.1  mrg 		     INTVAL (XEXP (X, 1)));		\
1.1  mrg       else						\
1.1  mrg 	asm_fprintf (STREAM, "[%r, %r]",		\
1.1  mrg 		     REGNO (XEXP (X, 0)),		\
1.1  mrg 		     REGNO (XEXP (X, 1)));		\
1.1  mrg     }							\
1.1  mrg   else							\
1.1  mrg     output_addr_const (STREAM, X);			\
1.1  mrg }
1.1  mrg
1.1  mrg #define PRINT_OPERAND_ADDRESS(STREAM, X)	\
1.1  mrg   if (TARGET_32BIT)				\
1.1  mrg     ARM_PRINT_OPERAND_ADDRESS (STREAM, X)	\
1.1  mrg   else						\
1.1  mrg     THUMB_PRINT_OPERAND_ADDRESS (STREAM, X)
1.1  mrg
1.1  mrg #define OUTPUT_ADDR_CONST_EXTRA(file, x, fail)		\
1.1  mrg   if (arm_output_addr_const_extra (file, x) == FALSE)	\
1.1  mrg     goto fail
1.1  mrg
1.1  mrg /* A C expression whose value is RTL representing the value of the return
1.1  mrg    address for the frame COUNT steps up from the current frame.  */
1.1  mrg
1.1  mrg #define RETURN_ADDR_RTX(COUNT, FRAME) \
1.1  mrg   arm_return_addr (COUNT, FRAME)
1.1  mrg
1.1  mrg /* Mask of the bits in the PC that contain the real return address
1.1  mrg    when running in 26-bit mode.  */
1.1  mrg #define RETURN_ADDR_MASK26 (0x03fffffc)
1.1  mrg
1.1  mrg /* Pick up the return address upon entry to a procedure. Used for
1.1  mrg    dwarf2 unwind information.  This also enables the table driven
1.1  mrg    mechanism.  */
1.1  mrg #define INCOMING_RETURN_ADDR_RTX	gen_rtx_REG (Pmode, LR_REGNUM)
1.1  mrg #define DWARF_FRAME_RETURN_COLUMN	DWARF_FRAME_REGNUM (LR_REGNUM)
1.1  mrg
1.1  mrg /* Used to mask out junk bits from the return address, such as
1.1  mrg    processor state, interrupt status, condition codes and the like.  */
1.1  mrg #define MASK_RETURN_ADDR \
1.1  mrg   /* If we are generating code for an ARM2/ARM3 machine or for an ARM6	\
1.1  mrg      in 26 bit mode, the condition codes must be masked out of the	\
1.1  mrg      return address.  This does not apply to ARM6 and later processors	\
1.1  mrg      when running in 32 bit mode.  */					\
1.1  mrg   ((arm_arch4 || TARGET_THUMB)						\
1.1  mrg    ? (gen_int_mode ((unsigned long)0xffffffff, Pmode))			\
1.1  mrg    : arm_gen_return_addr_mask ())
1.1  mrg
1.1  mrg
1.1  mrg /* Neon defines builtins from ARM_BUILTIN_MAX upwards, though they don't have
1.1  mrg    symbolic names defined here (which would require too much duplication).
1.1  mrg    FIXME?  */
1.1  mrg enum arm_builtins
1.1  mrg {
1.1  mrg   ARM_BUILTIN_GETWCX,
1.1  mrg   ARM_BUILTIN_SETWCX,
1.1  mrg
1.1  mrg   ARM_BUILTIN_WZERO,
1.1  mrg
1.1  mrg   ARM_BUILTIN_WAVG2BR,
1.1  mrg   ARM_BUILTIN_WAVG2HR,
1.1  mrg   ARM_BUILTIN_WAVG2B,
1.1  mrg   ARM_BUILTIN_WAVG2H,
1.1  mrg
1.1  mrg   ARM_BUILTIN_WACCB,
1.1  mrg   ARM_BUILTIN_WACCH,
1.1  mrg   ARM_BUILTIN_WACCW,
1.1  mrg
1.1  mrg   ARM_BUILTIN_WMACS,
1.1  mrg   ARM_BUILTIN_WMACSZ,
1.1  mrg   ARM_BUILTIN_WMACU,
1.1  mrg   ARM_BUILTIN_WMACUZ,
1.1  mrg
1.1  mrg   ARM_BUILTIN_WSADB,
1.1  mrg   ARM_BUILTIN_WSADBZ,
1.1  mrg   ARM_BUILTIN_WSADH,
1.1  mrg   ARM_BUILTIN_WSADHZ,
1.1  mrg
1.1  mrg   ARM_BUILTIN_WALIGN,
1.1  mrg
1.1  mrg   ARM_BUILTIN_TMIA,
1.1  mrg   ARM_BUILTIN_TMIAPH,
1.1  mrg   ARM_BUILTIN_TMIABB,
1.1  mrg   ARM_BUILTIN_TMIABT,
1.1  mrg   ARM_BUILTIN_TMIATB,
1.1  mrg   ARM_BUILTIN_TMIATT,
1.1  mrg
1.1  mrg   ARM_BUILTIN_TMOVMSKB,
1.1  mrg   ARM_BUILTIN_TMOVMSKH,
1.1  mrg   ARM_BUILTIN_TMOVMSKW,
1.1  mrg
1.1  mrg   ARM_BUILTIN_TBCSTB,
1.1  mrg   ARM_BUILTIN_TBCSTH,
1.1  mrg   ARM_BUILTIN_TBCSTW,
1.1  mrg
1.1  mrg   ARM_BUILTIN_WMADDS,
1.1  mrg   ARM_BUILTIN_WMADDU,
1.1  mrg
1.1  mrg   ARM_BUILTIN_WPACKHSS,
1.1  mrg   ARM_BUILTIN_WPACKWSS,
1.1  mrg   ARM_BUILTIN_WPACKDSS,
1.1  mrg   ARM_BUILTIN_WPACKHUS,
1.1  mrg   ARM_BUILTIN_WPACKWUS,
1.1  mrg   ARM_BUILTIN_WPACKDUS,
1.1  mrg
1.1  mrg   ARM_BUILTIN_WADDB,
1.1  mrg   ARM_BUILTIN_WADDH,
1.1  mrg   ARM_BUILTIN_WADDW,
1.1  mrg   ARM_BUILTIN_WADDSSB,
1.1  mrg   ARM_BUILTIN_WADDSSH,
1.1  mrg   ARM_BUILTIN_WADDSSW,
1.1  mrg   ARM_BUILTIN_WADDUSB,
1.1  mrg   ARM_BUILTIN_WADDUSH,
1.1  mrg   ARM_BUILTIN_WADDUSW,
1.1  mrg   ARM_BUILTIN_WSUBB,
1.1  mrg   ARM_BUILTIN_WSUBH,
1.1  mrg   ARM_BUILTIN_WSUBW,
1.1  mrg   ARM_BUILTIN_WSUBSSB,
1.1  mrg   ARM_BUILTIN_WSUBSSH,
1.1  mrg   ARM_BUILTIN_WSUBSSW,
1.1  mrg   ARM_BUILTIN_WSUBUSB,
1.1  mrg   ARM_BUILTIN_WSUBUSH,
1.1  mrg   ARM_BUILTIN_WSUBUSW,
1.1  mrg
1.1  mrg   ARM_BUILTIN_WAND,
1.1  mrg   ARM_BUILTIN_WANDN,
1.1  mrg   ARM_BUILTIN_WOR,
1.1  mrg   ARM_BUILTIN_WXOR,
1.1  mrg
1.1  mrg   ARM_BUILTIN_WCMPEQB,
1.1  mrg   ARM_BUILTIN_WCMPEQH,
1.1  mrg   ARM_BUILTIN_WCMPEQW,
1.1  mrg   ARM_BUILTIN_WCMPGTUB,
1.1  mrg   ARM_BUILTIN_WCMPGTUH,
1.1  mrg   ARM_BUILTIN_WCMPGTUW,
1.1  mrg   ARM_BUILTIN_WCMPGTSB,
1.1  mrg   ARM_BUILTIN_WCMPGTSH,
1.1  mrg   ARM_BUILTIN_WCMPGTSW,
1.1  mrg
1.1  mrg   ARM_BUILTIN_TEXTRMSB,
1.1  mrg   ARM_BUILTIN_TEXTRMSH,
1.1  mrg   ARM_BUILTIN_TEXTRMSW,
1.1  mrg   ARM_BUILTIN_TEXTRMUB,
1.1  mrg   ARM_BUILTIN_TEXTRMUH,
1.1  mrg   ARM_BUILTIN_TEXTRMUW,
1.1  mrg   ARM_BUILTIN_TINSRB,
1.1  mrg   ARM_BUILTIN_TINSRH,
1.1  mrg   ARM_BUILTIN_TINSRW,
1.1  mrg
1.1  mrg   ARM_BUILTIN_WMAXSW,
1.1  mrg   ARM_BUILTIN_WMAXSH,
1.1  mrg   ARM_BUILTIN_WMAXSB,
1.1  mrg   ARM_BUILTIN_WMAXUW,
1.1  mrg   ARM_BUILTIN_WMAXUH,
1.1  mrg   ARM_BUILTIN_WMAXUB,
1.1  mrg   ARM_BUILTIN_WMINSW,
1.1  mrg   ARM_BUILTIN_WMINSH,
1.1  mrg   ARM_BUILTIN_WMINSB,
1.1  mrg   ARM_BUILTIN_WMINUW,
1.1  mrg   ARM_BUILTIN_WMINUH,
1.1  mrg   ARM_BUILTIN_WMINUB,
1.1  mrg
1.1  mrg   ARM_BUILTIN_WMULUM,
1.1  mrg   ARM_BUILTIN_WMULSM,
1.1  mrg   ARM_BUILTIN_WMULUL,
1.1  mrg
1.1  mrg   ARM_BUILTIN_PSADBH,
1.1  mrg   ARM_BUILTIN_WSHUFH,
1.1  mrg
1.1  mrg   ARM_BUILTIN_WSLLH,
1.1  mrg   ARM_BUILTIN_WSLLW,
1.1  mrg   ARM_BUILTIN_WSLLD,
1.1  mrg   ARM_BUILTIN_WSRAH,
1.1  mrg   ARM_BUILTIN_WSRAW,
1.1  mrg   ARM_BUILTIN_WSRAD,
1.1  mrg   ARM_BUILTIN_WSRLH,
1.1  mrg   ARM_BUILTIN_WSRLW,
1.1  mrg   ARM_BUILTIN_WSRLD,
1.1  mrg   ARM_BUILTIN_WRORH,
1.1  mrg   ARM_BUILTIN_WRORW,
1.1  mrg   ARM_BUILTIN_WRORD,
1.1  mrg   ARM_BUILTIN_WSLLHI,
1.1  mrg   ARM_BUILTIN_WSLLWI,
1.1  mrg   ARM_BUILTIN_WSLLDI,
1.1  mrg   ARM_BUILTIN_WSRAHI,
1.1  mrg   ARM_BUILTIN_WSRAWI,
1.1  mrg   ARM_BUILTIN_WSRADI,
1.1  mrg   ARM_BUILTIN_WSRLHI,
1.1  mrg   ARM_BUILTIN_WSRLWI,
1.1  mrg   ARM_BUILTIN_WSRLDI,
1.1  mrg   ARM_BUILTIN_WRORHI,
1.1  mrg   ARM_BUILTIN_WRORWI,
1.1  mrg   ARM_BUILTIN_WRORDI,
1.1  mrg
1.1  mrg   ARM_BUILTIN_WUNPCKIHB,
1.1  mrg   ARM_BUILTIN_WUNPCKIHH,
1.1  mrg   ARM_BUILTIN_WUNPCKIHW,
1.1  mrg   ARM_BUILTIN_WUNPCKILB,
1.1  mrg   ARM_BUILTIN_WUNPCKILH,
1.1  mrg   ARM_BUILTIN_WUNPCKILW,
1.1  mrg
1.1  mrg   ARM_BUILTIN_WUNPCKEHSB,
1.1  mrg   ARM_BUILTIN_WUNPCKEHSH,
1.1  mrg   ARM_BUILTIN_WUNPCKEHSW,
1.1  mrg   ARM_BUILTIN_WUNPCKEHUB,
1.1  mrg   ARM_BUILTIN_WUNPCKEHUH,
1.1  mrg   ARM_BUILTIN_WUNPCKEHUW,
1.1  mrg   ARM_BUILTIN_WUNPCKELSB,
1.1  mrg   ARM_BUILTIN_WUNPCKELSH,
1.1  mrg   ARM_BUILTIN_WUNPCKELSW,
1.1  mrg   ARM_BUILTIN_WUNPCKELUB,
1.1  mrg   ARM_BUILTIN_WUNPCKELUH,
           ARM_BUILTIN_WUNPCKELUW,

           ARM_BUILTIN_THREAD_POINTER,

           ARM_BUILTIN_NEON_BASE,

           ARM_BUILTIN_MAX = ARM_BUILTIN_NEON_BASE  /* FIXME: Wrong!  */
         };

         /* Do not emit .note.GNU-stack by default.  */
         #ifndef NEED_INDICATE_EXEC_STACK
         #define NEED_INDICATE_EXEC_STACK	0
         #endif

         #endif /* ! GCC_ARM_H */