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|
/* Definitions of target machine for GNU compiler for IA-32.
Copyright (C) 1988, 1992, 1994, 1995, 1996, 1997, 1998, 1999, 2000,
2001, 2002 Free Software Foundation, Inc.
This file is part of GNU CC.
GNU CC is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 2, or (at your option)
any later version.
GNU CC is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with GNU CC; see the file COPYING. If not, write to
the Free Software Foundation, 59 Temple Place - Suite 330,
Boston, MA 02111-1307, USA. */
/* The purpose of this file is to define the characteristics of the i386,
independent of assembler syntax or operating system.
Three other files build on this one to describe a specific assembler syntax:
bsd386.h, att386.h, and sun386.h.
The actual tm.h file for a particular system should include
this file, and then the file for the appropriate assembler syntax.
Many macros that specify assembler syntax are omitted entirely from
this file because they really belong in the files for particular
assemblers. These include RP, IP, LPREFIX, PUT_OP_SIZE, USE_STAR,
ADDR_BEG, ADDR_END, PRINT_IREG, PRINT_SCALE, PRINT_B_I_S, and many
that start with ASM_ or end in ASM_OP. */
/* Define the specific costs for a given cpu */
struct processor_costs {
const int add; /* cost of an add instruction */
const int lea; /* cost of a lea instruction */
const int shift_var; /* variable shift costs */
const int shift_const; /* constant shift costs */
const int mult_init; /* cost of starting a multiply */
const int mult_bit; /* cost of multiply per each bit set */
const int divide; /* cost of a divide/mod */
int movsx; /* The cost of movsx operation. */
int movzx; /* The cost of movzx operation. */
const int large_insn; /* insns larger than this cost more */
const int move_ratio; /* The threshold of number of scalar
memory-to-memory move insns. */
const int movzbl_load; /* cost of loading using movzbl */
const int int_load[3]; /* cost of loading integer registers
in QImode, HImode and SImode relative
to reg-reg move (2). */
const int int_store[3]; /* cost of storing integer register
in QImode, HImode and SImode */
const int fp_move; /* cost of reg,reg fld/fst */
const int fp_load[3]; /* cost of loading FP register
in SFmode, DFmode and XFmode */
const int fp_store[3]; /* cost of storing FP register
in SFmode, DFmode and XFmode */
const int mmx_move; /* cost of moving MMX register. */
const int mmx_load[2]; /* cost of loading MMX register
in SImode and DImode */
const int mmx_store[2]; /* cost of storing MMX register
in SImode and DImode */
const int sse_move; /* cost of moving SSE register. */
const int sse_load[3]; /* cost of loading SSE register
in SImode, DImode and TImode*/
const int sse_store[3]; /* cost of storing SSE register
in SImode, DImode and TImode*/
const int mmxsse_to_integer; /* cost of moving mmxsse register to
integer and vice versa. */
const int prefetch_block; /* bytes moved to cache for prefetch. */
const int simultaneous_prefetches; /* number of parallel prefetch
operations. */
const int fadd; /* cost of FADD and FSUB instructions. */
const int fmul; /* cost of FMUL instruction. */
const int fdiv; /* cost of FDIV instruction. */
const int fabs; /* cost of FABS instruction. */
const int fchs; /* cost of FCHS instruction. */
const int fsqrt; /* cost of FSQRT instruction. */
};
extern const struct processor_costs *ix86_cost;
/* Run-time compilation parameters selecting different hardware subsets. */
extern int target_flags;
/* Macros used in the machine description to test the flags. */
/* configure can arrange to make this 2, to force a 486. */
#ifndef TARGET_CPU_DEFAULT
#define TARGET_CPU_DEFAULT 0
#endif
/* Masks for the -m switches */
#define MASK_80387 0x00000001 /* Hardware floating point */
#define MASK_RTD 0x00000002 /* Use ret that pops args */
#define MASK_ALIGN_DOUBLE 0x00000004 /* align doubles to 2 word boundary */
#define MASK_SVR3_SHLIB 0x00000008 /* Uninit locals into bss */
#define MASK_IEEE_FP 0x00000010 /* IEEE fp comparisons */
#define MASK_FLOAT_RETURNS 0x00000020 /* Return float in st(0) */
#define MASK_NO_FANCY_MATH_387 0x00000040 /* Disable sin, cos, sqrt */
#define MASK_OMIT_LEAF_FRAME_POINTER 0x080 /* omit leaf frame pointers */
#define MASK_STACK_PROBE 0x00000100 /* Enable stack probing */
#define MASK_NO_ALIGN_STROPS 0x00000200 /* Enable aligning of string ops. */
#define MASK_INLINE_ALL_STROPS 0x00000400 /* Inline stringops in all cases */
#define MASK_NO_PUSH_ARGS 0x00000800 /* Use push instructions */
#define MASK_ACCUMULATE_OUTGOING_ARGS 0x00001000/* Accumulate outgoing args */
#define MASK_MMX 0x00002000 /* Support MMX regs/builtins */
#define MASK_SSE 0x00004000 /* Support SSE regs/builtins */
#define MASK_SSE2 0x00008000 /* Support SSE2 regs/builtins */
#define MASK_3DNOW 0x00010000 /* Support 3Dnow builtins */
#define MASK_3DNOW_A 0x00020000 /* Support Athlon 3Dnow builtins */
#define MASK_128BIT_LONG_DOUBLE 0x00040000 /* long double size is 128bit */
#define MASK_64BIT 0x00080000 /* Produce 64bit code */
/* Unused: 0x03f0000 */
/* ... overlap with subtarget options starts by 0x04000000. */
#define MASK_NO_RED_ZONE 0x04000000 /* Do not use red zone */
/* Use the floating point instructions */
#define TARGET_80387 (target_flags & MASK_80387)
/* Compile using ret insn that pops args.
This will not work unless you use prototypes at least
for all functions that can take varying numbers of args. */
#define TARGET_RTD (target_flags & MASK_RTD)
/* Align doubles to a two word boundary. This breaks compatibility with
the published ABI's for structures containing doubles, but produces
faster code on the pentium. */
#define TARGET_ALIGN_DOUBLE (target_flags & MASK_ALIGN_DOUBLE)
/* Use push instructions to save outgoing args. */
#define TARGET_PUSH_ARGS (!(target_flags & MASK_NO_PUSH_ARGS))
/* Accumulate stack adjustments to prologue/epilogue. */
#define TARGET_ACCUMULATE_OUTGOING_ARGS \
(target_flags & MASK_ACCUMULATE_OUTGOING_ARGS)
/* Put uninitialized locals into bss, not data.
Meaningful only on svr3. */
#define TARGET_SVR3_SHLIB (target_flags & MASK_SVR3_SHLIB)
/* Use IEEE floating point comparisons. These handle correctly the cases
where the result of a comparison is unordered. Normally SIGFPE is
generated in such cases, in which case this isn't needed. */
#define TARGET_IEEE_FP (target_flags & MASK_IEEE_FP)
/* Functions that return a floating point value may return that value
in the 387 FPU or in 386 integer registers. If set, this flag causes
the 387 to be used, which is compatible with most calling conventions. */
#define TARGET_FLOAT_RETURNS_IN_80387 (target_flags & MASK_FLOAT_RETURNS)
/* Long double is 128bit instead of 96bit, even when only 80bits are used.
This mode wastes cache, but avoid misaligned data accesses and simplifies
address calculations. */
#define TARGET_128BIT_LONG_DOUBLE (target_flags & MASK_128BIT_LONG_DOUBLE)
/* Disable generation of FP sin, cos and sqrt operations for 387.
This is because FreeBSD lacks these in the math-emulator-code */
#define TARGET_NO_FANCY_MATH_387 (target_flags & MASK_NO_FANCY_MATH_387)
/* Don't create frame pointers for leaf functions */
#define TARGET_OMIT_LEAF_FRAME_POINTER \
(target_flags & MASK_OMIT_LEAF_FRAME_POINTER)
/* Debug GO_IF_LEGITIMATE_ADDRESS */
#define TARGET_DEBUG_ADDR (ix86_debug_addr_string != 0)
/* Debug FUNCTION_ARG macros */
#define TARGET_DEBUG_ARG (ix86_debug_arg_string != 0)
/* 64bit Sledgehammer mode. For libgcc2 we make sure this is a
compile-time constant. */
#ifdef IN_LIBGCC2
#ifdef __x86_64__
#define TARGET_64BIT 1
#else
#define TARGET_64BIT 0
#endif
#else
#ifdef TARGET_BI_ARCH
#define TARGET_64BIT (target_flags & MASK_64BIT)
#else
#if TARGET_64BIT_DEFAULT
#define TARGET_64BIT 1
#else
#define TARGET_64BIT 0
#endif
#endif
#endif
#define TARGET_386 (ix86_cpu == PROCESSOR_I386)
#define TARGET_486 (ix86_cpu == PROCESSOR_I486)
#define TARGET_PENTIUM (ix86_cpu == PROCESSOR_PENTIUM)
#define TARGET_PENTIUMPRO (ix86_cpu == PROCESSOR_PENTIUMPRO)
#define TARGET_K6 (ix86_cpu == PROCESSOR_K6)
#define TARGET_ATHLON (ix86_cpu == PROCESSOR_ATHLON)
#define TARGET_PENTIUM4 (ix86_cpu == PROCESSOR_PENTIUM4)
#define CPUMASK (1 << ix86_cpu)
extern const int x86_use_leave, x86_push_memory, x86_zero_extend_with_and;
extern const int x86_use_bit_test, x86_cmove, x86_deep_branch;
extern const int x86_branch_hints, x86_unroll_strlen;
extern const int x86_double_with_add, x86_partial_reg_stall, x86_movx;
extern const int x86_use_loop, x86_use_fiop, x86_use_mov0;
extern const int x86_use_cltd, x86_read_modify_write;
extern const int x86_read_modify, x86_split_long_moves;
extern const int x86_promote_QImode, x86_single_stringop, x86_fast_prefix;
extern const int x86_himode_math, x86_qimode_math, x86_promote_qi_regs;
extern const int x86_promote_hi_regs, x86_integer_DFmode_moves;
extern const int x86_add_esp_4, x86_add_esp_8, x86_sub_esp_4, x86_sub_esp_8;
extern const int x86_partial_reg_dependency, x86_memory_mismatch_stall;
extern const int x86_accumulate_outgoing_args, x86_prologue_using_move;
extern const int x86_epilogue_using_move, x86_decompose_lea;
extern const int x86_arch_always_fancy_math_387, x86_shift1;
extern int x86_prefetch_sse;
#define TARGET_USE_LEAVE (x86_use_leave & CPUMASK)
#define TARGET_PUSH_MEMORY (x86_push_memory & CPUMASK)
#define TARGET_ZERO_EXTEND_WITH_AND (x86_zero_extend_with_and & CPUMASK)
#define TARGET_USE_BIT_TEST (x86_use_bit_test & CPUMASK)
#define TARGET_UNROLL_STRLEN (x86_unroll_strlen & CPUMASK)
/* For sane SSE instruction set generation we need fcomi instruction. It is
safe to enable all CMOVE instructions. */
#define TARGET_CMOVE ((x86_cmove & (1 << ix86_arch)) || TARGET_SSE)
#define TARGET_DEEP_BRANCH_PREDICTION (x86_deep_branch & CPUMASK)
#define TARGET_BRANCH_PREDICTION_HINTS (x86_branch_hints & CPUMASK)
#define TARGET_DOUBLE_WITH_ADD (x86_double_with_add & CPUMASK)
#define TARGET_USE_SAHF ((x86_use_sahf & CPUMASK) && !TARGET_64BIT)
#define TARGET_MOVX (x86_movx & CPUMASK)
#define TARGET_PARTIAL_REG_STALL (x86_partial_reg_stall & CPUMASK)
#define TARGET_USE_LOOP (x86_use_loop & CPUMASK)
#define TARGET_USE_FIOP (x86_use_fiop & CPUMASK)
#define TARGET_USE_MOV0 (x86_use_mov0 & CPUMASK)
#define TARGET_USE_CLTD (x86_use_cltd & CPUMASK)
#define TARGET_SPLIT_LONG_MOVES (x86_split_long_moves & CPUMASK)
#define TARGET_READ_MODIFY_WRITE (x86_read_modify_write & CPUMASK)
#define TARGET_READ_MODIFY (x86_read_modify & CPUMASK)
#define TARGET_PROMOTE_QImode (x86_promote_QImode & CPUMASK)
#define TARGET_FAST_PREFIX (x86_fast_prefix & CPUMASK)
#define TARGET_SINGLE_STRINGOP (x86_single_stringop & CPUMASK)
#define TARGET_QIMODE_MATH (x86_qimode_math & CPUMASK)
#define TARGET_HIMODE_MATH (x86_himode_math & CPUMASK)
#define TARGET_PROMOTE_QI_REGS (x86_promote_qi_regs & CPUMASK)
#define TARGET_PROMOTE_HI_REGS (x86_promote_hi_regs & CPUMASK)
#define TARGET_ADD_ESP_4 (x86_add_esp_4 & CPUMASK)
#define TARGET_ADD_ESP_8 (x86_add_esp_8 & CPUMASK)
#define TARGET_SUB_ESP_4 (x86_sub_esp_4 & CPUMASK)
#define TARGET_SUB_ESP_8 (x86_sub_esp_8 & CPUMASK)
#define TARGET_INTEGER_DFMODE_MOVES (x86_integer_DFmode_moves & CPUMASK)
#define TARGET_PARTIAL_REG_DEPENDENCY (x86_partial_reg_dependency & CPUMASK)
#define TARGET_MEMORY_MISMATCH_STALL (x86_memory_mismatch_stall & CPUMASK)
#define TARGET_PROLOGUE_USING_MOVE (x86_prologue_using_move & CPUMASK)
#define TARGET_EPILOGUE_USING_MOVE (x86_epilogue_using_move & CPUMASK)
#define TARGET_DECOMPOSE_LEA (x86_decompose_lea & CPUMASK)
#define TARGET_PREFETCH_SSE (x86_prefetch_sse)
#define TARGET_SHIFT1 (x86_shift1 & CPUMASK)
#define TARGET_STACK_PROBE (target_flags & MASK_STACK_PROBE)
#define TARGET_ALIGN_STRINGOPS (!(target_flags & MASK_NO_ALIGN_STROPS))
#define TARGET_INLINE_ALL_STRINGOPS (target_flags & MASK_INLINE_ALL_STROPS)
#define ASSEMBLER_DIALECT (ix86_asm_dialect)
#define TARGET_SSE ((target_flags & (MASK_SSE | MASK_SSE2)) != 0)
#define TARGET_SSE2 ((target_flags & MASK_SSE2) != 0)
#define TARGET_SSE_MATH ((ix86_fpmath & FPMATH_SSE) != 0)
#define TARGET_MIX_SSE_I387 ((ix86_fpmath & FPMATH_SSE) \
&& (ix86_fpmath & FPMATH_387))
#define TARGET_MMX ((target_flags & MASK_MMX) != 0)
#define TARGET_3DNOW ((target_flags & MASK_3DNOW) != 0)
#define TARGET_3DNOW_A ((target_flags & MASK_3DNOW_A) != 0)
#define TARGET_RED_ZONE (!(target_flags & MASK_NO_RED_ZONE))
#define TARGET_GNU_TLS (ix86_tls_dialect == TLS_DIALECT_GNU)
#define TARGET_SUN_TLS (ix86_tls_dialect == TLS_DIALECT_SUN)
/* WARNING: Do not mark empty strings for translation, as calling
gettext on an empty string does NOT return an empty
string. */
#define TARGET_SWITCHES \
{ { "80387", MASK_80387, N_("Use hardware fp") }, \
{ "no-80387", -MASK_80387, N_("Do not use hardware fp") }, \
{ "hard-float", MASK_80387, N_("Use hardware fp") }, \
{ "soft-float", -MASK_80387, N_("Do not use hardware fp") }, \
{ "no-soft-float", MASK_80387, N_("Use hardware fp") }, \
{ "386", 0, "" /*Deprecated.*/}, \
{ "486", 0, "" /*Deprecated.*/}, \
{ "pentium", 0, "" /*Deprecated.*/}, \
{ "pentiumpro", 0, "" /*Deprecated.*/}, \
{ "intel-syntax", 0, "" /*Deprecated.*/}, \
{ "no-intel-syntax", 0, "" /*Deprecated.*/}, \
{ "rtd", MASK_RTD, \
N_("Alternate calling convention") }, \
{ "no-rtd", -MASK_RTD, \
N_("Use normal calling convention") }, \
{ "align-double", MASK_ALIGN_DOUBLE, \
N_("Align some doubles on dword boundary") }, \
{ "no-align-double", -MASK_ALIGN_DOUBLE, \
N_("Align doubles on word boundary") }, \
{ "svr3-shlib", MASK_SVR3_SHLIB, \
N_("Uninitialized locals in .bss") }, \
{ "no-svr3-shlib", -MASK_SVR3_SHLIB, \
N_("Uninitialized locals in .data") }, \
{ "ieee-fp", MASK_IEEE_FP, \
N_("Use IEEE math for fp comparisons") }, \
{ "no-ieee-fp", -MASK_IEEE_FP, \
N_("Do not use IEEE math for fp comparisons") }, \
{ "fp-ret-in-387", MASK_FLOAT_RETURNS, \
N_("Return values of functions in FPU registers") }, \
{ "no-fp-ret-in-387", -MASK_FLOAT_RETURNS , \
N_("Do not return values of functions in FPU registers")}, \
{ "no-fancy-math-387", MASK_NO_FANCY_MATH_387, \
N_("Do not generate sin, cos, sqrt for FPU") }, \
{ "fancy-math-387", -MASK_NO_FANCY_MATH_387, \
N_("Generate sin, cos, sqrt for FPU")}, \
{ "omit-leaf-frame-pointer", MASK_OMIT_LEAF_FRAME_POINTER, \
N_("Omit the frame pointer in leaf functions") }, \
{ "no-omit-leaf-frame-pointer",-MASK_OMIT_LEAF_FRAME_POINTER, "" }, \
{ "stack-arg-probe", MASK_STACK_PROBE, \
N_("Enable stack probing") }, \
{ "no-stack-arg-probe", -MASK_STACK_PROBE, "" }, \
{ "windows", 0, 0 /* undocumented */ }, \
{ "dll", 0, 0 /* undocumented */ }, \
{ "align-stringops", -MASK_NO_ALIGN_STROPS, \
N_("Align destination of the string operations") }, \
{ "no-align-stringops", MASK_NO_ALIGN_STROPS, \
N_("Do not align destination of the string operations") }, \
{ "inline-all-stringops", MASK_INLINE_ALL_STROPS, \
N_("Inline all known string operations") }, \
{ "no-inline-all-stringops", -MASK_INLINE_ALL_STROPS, \
N_("Do not inline all known string operations") }, \
{ "push-args", -MASK_NO_PUSH_ARGS, \
N_("Use push instructions to save outgoing arguments") }, \
{ "no-push-args", MASK_NO_PUSH_ARGS, \
N_("Do not use push instructions to save outgoing arguments") }, \
{ "accumulate-outgoing-args", MASK_ACCUMULATE_OUTGOING_ARGS, \
N_("Use push instructions to save outgoing arguments") }, \
{ "no-accumulate-outgoing-args",-MASK_ACCUMULATE_OUTGOING_ARGS, \
N_("Do not use push instructions to save outgoing arguments") }, \
{ "mmx", MASK_MMX, \
N_("Support MMX built-in functions") }, \
{ "no-mmx", -MASK_MMX, \
N_("Do not support MMX built-in functions") }, \
{ "3dnow", MASK_3DNOW, \
N_("Support 3DNow! built-in functions") }, \
{ "no-3dnow", -MASK_3DNOW, \
N_("Do not support 3DNow! built-in functions") }, \
{ "sse", MASK_SSE, \
N_("Support MMX and SSE built-in functions and code generation") }, \
{ "no-sse", -MASK_SSE, \
N_("Do not support MMX and SSE built-in functions and code generation") },\
{ "sse2", MASK_SSE2, \
N_("Support MMX, SSE and SSE2 built-in functions and code generation") }, \
{ "no-sse2", -MASK_SSE2, \
N_("Do not support MMX, SSE and SSE2 built-in functions and code generation") }, \
{ "128bit-long-double", MASK_128BIT_LONG_DOUBLE, \
N_("sizeof(long double) is 16") }, \
{ "96bit-long-double", -MASK_128BIT_LONG_DOUBLE, \
N_("sizeof(long double) is 12") }, \
{ "64", MASK_64BIT, \
N_("Generate 64bit x86-64 code") }, \
{ "32", -MASK_64BIT, \
N_("Generate 32bit i386 code") }, \
{ "red-zone", -MASK_NO_RED_ZONE, \
N_("Use red-zone in the x86-64 code") }, \
{ "no-red-zone", MASK_NO_RED_ZONE, \
N_("Do not use red-zone in the x86-64 code") }, \
SUBTARGET_SWITCHES \
{ "", TARGET_DEFAULT | TARGET_64BIT_DEFAULT | TARGET_SUBTARGET_DEFAULT, 0 }}
#ifndef TARGET_64BIT_DEFAULT
#define TARGET_64BIT_DEFAULT 0
#endif
/* Once GDB has been enhanced to deal with functions without frame
pointers, we can change this to allow for elimination of
the frame pointer in leaf functions. */
#define TARGET_DEFAULT 0
/* This is not really a target flag, but is done this way so that
it's analogous to similar code for Mach-O on PowerPC. darwin.h
redefines this to 1. */
#define TARGET_MACHO 0
/* This macro is similar to `TARGET_SWITCHES' but defines names of
command options that have values. Its definition is an
initializer with a subgrouping for each command option.
Each subgrouping contains a string constant, that defines the
fixed part of the option name, and the address of a variable. The
variable, type `char *', is set to the variable part of the given
option if the fixed part matches. The actual option name is made
by appending `-m' to the specified name. */
#define TARGET_OPTIONS \
{ { "cpu=", &ix86_cpu_string, \
N_("Schedule code for given CPU")}, \
{ "fpmath=", &ix86_fpmath_string, \
N_("Generate floating point mathematics using given instruction set")},\
{ "arch=", &ix86_arch_string, \
N_("Generate code for given CPU")}, \
{ "regparm=", &ix86_regparm_string, \
N_("Number of registers used to pass integer arguments") }, \
{ "align-loops=", &ix86_align_loops_string, \
N_("Loop code aligned to this power of 2") }, \
{ "align-jumps=", &ix86_align_jumps_string, \
N_("Jump targets are aligned to this power of 2") }, \
{ "align-functions=", &ix86_align_funcs_string, \
N_("Function starts are aligned to this power of 2") }, \
{ "preferred-stack-boundary=", \
&ix86_preferred_stack_boundary_string, \
N_("Attempt to keep stack aligned to this power of 2") }, \
{ "branch-cost=", &ix86_branch_cost_string, \
N_("Branches are this expensive (1-5, arbitrary units)") }, \
{ "cmodel=", &ix86_cmodel_string, \
N_("Use given x86-64 code model") }, \
{ "debug-arg", &ix86_debug_arg_string, \
"" /* Undocumented. */ }, \
{ "debug-addr", &ix86_debug_addr_string, \
"" /* Undocumented. */ }, \
{ "asm=", &ix86_asm_string, \
N_("Use given assembler dialect") }, \
{ "tls-dialect=", &ix86_tls_dialect_string, \
N_("Use given thread-local storage dialect") }, \
SUBTARGET_OPTIONS \
}
/* Sometimes certain combinations of command options do not make
sense on a particular target machine. You can define a macro
`OVERRIDE_OPTIONS' to take account of this. This macro, if
defined, is executed once just after all the command options have
been parsed.
Don't use this macro to turn on various extra optimizations for
`-O'. That is what `OPTIMIZATION_OPTIONS' is for. */
#define OVERRIDE_OPTIONS override_options ()
/* These are meant to be redefined in the host dependent files */
#define SUBTARGET_SWITCHES
#define SUBTARGET_OPTIONS
/* Define this to change the optimizations performed by default. */
#define OPTIMIZATION_OPTIONS(LEVEL, SIZE) \
optimization_options ((LEVEL), (SIZE))
/* Specs for the compiler proper */
#ifndef CC1_CPU_SPEC
#define CC1_CPU_SPEC "\
%{!mcpu*: \
%{m386:-mcpu=i386 \
%n`-m386' is deprecated. Use `-march=i386' or `-mcpu=i386' instead.\n} \
%{m486:-mcpu=i486 \
%n`-m486' is deprecated. Use `-march=i486' or `-mcpu=i486' instead.\n} \
%{mpentium:-mcpu=pentium \
%n`-mpentium' is deprecated. Use `-march=pentium' or `-mcpu=pentium' instead.\n} \
%{mpentiumpro:-mcpu=pentiumpro \
%n`-mpentiumpro' is deprecated. Use `-march=pentiumpro' or `-mcpu=pentiumpro' instead.\n}} \
%{mintel-syntax:-masm=intel \
%n`-mintel-syntax' is deprecated. Use `-masm=intel' instead.\n} \
%{mno-intel-syntax:-masm=att \
%n`-mno-intel-syntax' is deprecated. Use `-masm=att' instead.\n}"
#endif
/* Target CPU builtins. */
#define TARGET_CPU_CPP_BUILTINS() \
do \
{ \
size_t arch_len = strlen (ix86_arch_string); \
size_t cpu_len = strlen (ix86_cpu_string); \
int last_arch_char = ix86_arch_string[arch_len - 1]; \
int last_cpu_char = ix86_cpu_string[cpu_len - 1]; \
\
if (TARGET_64BIT) \
{ \
builtin_assert ("cpu=x86_64"); \
builtin_assert ("machine=x86_64"); \
builtin_define ("__x86_64"); \
builtin_define ("__x86_64__"); \
} \
else \
{ \
builtin_assert ("cpu=i386"); \
builtin_assert ("machine=i386"); \
builtin_define_std ("i386"); \
} \
\
/* Built-ins based on -mcpu= (or -march= if no \
CPU given). */ \
if (TARGET_386) \
builtin_define ("__tune_i386__"); \
else if (TARGET_486) \
builtin_define ("__tune_i486__"); \
else if (TARGET_PENTIUM) \
{ \
builtin_define ("__tune_i586__"); \
builtin_define ("__tune_pentium__"); \
if (last_cpu_char == 'x') \
builtin_define ("__tune_pentium_mmx__"); \
} \
else if (TARGET_PENTIUMPRO) \
{ \
builtin_define ("__tune_i686__"); \
builtin_define ("__tune_pentiumpro__"); \
} \
else if (TARGET_K6) \
{ \
builtin_define ("__tune_k6__"); \
if (last_cpu_char == '2') \
builtin_define ("__tune_k6_2__"); \
else if (last_cpu_char == '3') \
builtin_define ("__tune_k6_3__"); \
} \
else if (TARGET_ATHLON) \
{ \
builtin_define ("__tune_athlon__"); \
/* Only plain "athlon" lacks SSE. */ \
if (last_cpu_char != 'n') \
builtin_define ("__tune_athlon_sse__"); \
} \
else if (TARGET_PENTIUM4) \
builtin_define ("__tune_pentium4__"); \
\
if (TARGET_MMX) \
builtin_define ("__MMX__"); \
if (TARGET_3DNOW) \
builtin_define ("__3dNOW__"); \
if (TARGET_3DNOW_A) \
builtin_define ("__3dNOW_A__"); \
if (TARGET_SSE) \
builtin_define ("__SSE__"); \
if (TARGET_SSE2) \
builtin_define ("__SSE2__"); \
if (TARGET_SSE_MATH && TARGET_SSE) \
builtin_define ("__SSE_MATH__"); \
if (TARGET_SSE_MATH && TARGET_SSE2) \
builtin_define ("__SSE2_MATH__"); \
\
/* Built-ins based on -march=. */ \
if (ix86_arch == PROCESSOR_I486) \
{ \
builtin_define ("__i486"); \
builtin_define ("__i486__"); \
} \
else if (ix86_arch == PROCESSOR_PENTIUM) \
{ \
builtin_define ("__i586"); \
builtin_define ("__i586__"); \
builtin_define ("__pentium"); \
builtin_define ("__pentium__"); \
if (last_arch_char == 'x') \
builtin_define ("__pentium_mmx__"); \
} \
else if (ix86_arch == PROCESSOR_PENTIUMPRO) \
{ \
builtin_define ("__i686"); \
builtin_define ("__i686__"); \
builtin_define ("__pentiumpro"); \
builtin_define ("__pentiumpro__"); \
} \
else if (ix86_arch == PROCESSOR_K6) \
{ \
\
builtin_define ("__k6"); \
builtin_define ("__k6__"); \
if (last_arch_char == '2') \
builtin_define ("__k6_2__"); \
else if (last_arch_char == '3') \
builtin_define ("__k6_3__"); \
} \
else if (ix86_arch == PROCESSOR_ATHLON) \
{ \
builtin_define ("__athlon"); \
builtin_define ("__athlon__"); \
/* Only plain "athlon" lacks SSE. */ \
if (last_arch_char != 'n') \
builtin_define ("__athlon_sse__"); \
} \
else if (ix86_arch == PROCESSOR_PENTIUM4) \
{ \
builtin_define ("__pentium4"); \
builtin_define ("__pentium4__"); \
} \
} \
while (0)
#define TARGET_CPU_DEFAULT_i386 0
#define TARGET_CPU_DEFAULT_i486 1
#define TARGET_CPU_DEFAULT_pentium 2
#define TARGET_CPU_DEFAULT_pentium_mmx 3
#define TARGET_CPU_DEFAULT_pentiumpro 4
#define TARGET_CPU_DEFAULT_pentium2 5
#define TARGET_CPU_DEFAULT_pentium3 6
#define TARGET_CPU_DEFAULT_pentium4 7
#define TARGET_CPU_DEFAULT_k6 8
#define TARGET_CPU_DEFAULT_k6_2 9
#define TARGET_CPU_DEFAULT_k6_3 10
#define TARGET_CPU_DEFAULT_athlon 11
#define TARGET_CPU_DEFAULT_athlon_sse 12
#define TARGET_CPU_DEFAULT_NAMES {"i386", "i486", "pentium", "pentium-mmx",\
"pentiumpro", "pentium2", "pentium3", \
"pentium4", "k6", "k6-2", "k6-3",\
"athlon", "athlon-4"}
#ifndef CC1_SPEC
#define CC1_SPEC "%(cc1_cpu) "
#endif
/* This macro defines names of additional specifications to put in the
specs that can be used in various specifications like CC1_SPEC. Its
definition is an initializer with a subgrouping for each command option.
Each subgrouping contains a string constant, that defines the
specification name, and a string constant that used by the GNU CC driver
program.
Do not define this macro if it does not need to do anything. */
#ifndef SUBTARGET_EXTRA_SPECS
#define SUBTARGET_EXTRA_SPECS
#endif
#define EXTRA_SPECS \
{ "cc1_cpu", CC1_CPU_SPEC }, \
SUBTARGET_EXTRA_SPECS
/* target machine storage layout */
/* Define for XFmode or TFmode extended real floating point support.
The XFmode is specified by i386 ABI, while TFmode may be faster
due to alignment and simplifications in the address calculations. */
#define LONG_DOUBLE_TYPE_SIZE (TARGET_128BIT_LONG_DOUBLE ? 128 : 96)
#define MAX_LONG_DOUBLE_TYPE_SIZE 128
#ifdef __x86_64__
#define LIBGCC2_LONG_DOUBLE_TYPE_SIZE 128
#else
#define LIBGCC2_LONG_DOUBLE_TYPE_SIZE 96
#endif
/* Set the value of FLT_EVAL_METHOD in float.h. When using only the
FPU, assume that the fpcw is set to extended precision; when using
only SSE, rounding is correct; when using both SSE and the FPU,
the rounding precision is indeterminate, since either may be chosen
apparently at random. */
#define TARGET_FLT_EVAL_METHOD \
(TARGET_MIX_SSE_I387 ? -1 : TARGET_SSE_MATH ? 1 : 2)
#define SHORT_TYPE_SIZE 16
#define INT_TYPE_SIZE 32
#define FLOAT_TYPE_SIZE 32
#define LONG_TYPE_SIZE BITS_PER_WORD
#define MAX_WCHAR_TYPE_SIZE 32
#define DOUBLE_TYPE_SIZE 64
#define LONG_LONG_TYPE_SIZE 64
#if defined (TARGET_BI_ARCH) || TARGET_64BIT_DEFAULT
#define MAX_BITS_PER_WORD 64
#define MAX_LONG_TYPE_SIZE 64
#else
#define MAX_BITS_PER_WORD 32
#define MAX_LONG_TYPE_SIZE 32
#endif
/* Define this if most significant byte of a word is the lowest numbered. */
/* That is true on the 80386. */
#define BITS_BIG_ENDIAN 0
/* Define this if most significant byte of a word is the lowest numbered. */
/* That is not true on the 80386. */
#define BYTES_BIG_ENDIAN 0
/* Define this if most significant word of a multiword number is the lowest
numbered. */
/* Not true for 80386 */
#define WORDS_BIG_ENDIAN 0
/* Width of a word, in units (bytes). */
#define UNITS_PER_WORD (TARGET_64BIT ? 8 : 4)
#define MIN_UNITS_PER_WORD 4
/* Allocation boundary (in *bits*) for storing arguments in argument list. */
#define PARM_BOUNDARY BITS_PER_WORD
/* Boundary (in *bits*) on which stack pointer should be aligned. */
#define STACK_BOUNDARY BITS_PER_WORD
/* Boundary (in *bits*) on which the stack pointer preferrs to be
aligned; the compiler cannot rely on having this alignment. */
#define PREFERRED_STACK_BOUNDARY ix86_preferred_stack_boundary
/* As of July 2001, many runtimes to not align the stack properly when
entering main. This causes expand_main_function to forcably align
the stack, which results in aligned frames for functions called from
main, though it does nothing for the alignment of main itself. */
#define FORCE_PREFERRED_STACK_BOUNDARY_IN_MAIN \
(ix86_preferred_stack_boundary > STACK_BOUNDARY && !TARGET_64BIT)
/* Minimum allocation boundary for the code of a function. */
#define FUNCTION_BOUNDARY 8
/* C++ stores the virtual bit in the lowest bit of function pointers. */
#define TARGET_PTRMEMFUNC_VBIT_LOCATION ptrmemfunc_vbit_in_pfn
/* Alignment of field after `int : 0' in a structure. */
#define EMPTY_FIELD_BOUNDARY BITS_PER_WORD
/* Minimum size in bits of the largest boundary to which any
and all fundamental data types supported by the hardware
might need to be aligned. No data type wants to be aligned
rounder than this.
Pentium+ preferrs DFmode values to be aligned to 64 bit boundary
and Pentium Pro XFmode values at 128 bit boundaries. */
#define BIGGEST_ALIGNMENT 128
/* Decide whether a variable of mode MODE should be 128 bit aligned. */
#define ALIGN_MODE_128(MODE) \
((MODE) == XFmode || (MODE) == TFmode || SSE_REG_MODE_P (MODE))
/* The published ABIs say that doubles should be aligned on word
boundaries, so lower the aligment for structure fields unless
-malign-double is set. */
/* ??? Blah -- this macro is used directly by libobjc. Since it
supports no vector modes, cut out the complexity and fall back
on BIGGEST_FIELD_ALIGNMENT. */
#ifdef IN_TARGET_LIBS
#ifdef __x86_64__
#define BIGGEST_FIELD_ALIGNMENT 128
#else
#define BIGGEST_FIELD_ALIGNMENT 32
#endif
#else
#define ADJUST_FIELD_ALIGN(FIELD, COMPUTED) \
x86_field_alignment (FIELD, COMPUTED)
#endif
/* If defined, a C expression to compute the alignment given to a
constant that is being placed in memory. EXP is the constant
and ALIGN is the alignment that the object would ordinarily have.
The value of this macro is used instead of that alignment to align
the object.
If this macro is not defined, then ALIGN is used.
The typical use of this macro is to increase alignment for string
constants to be word aligned so that `strcpy' calls that copy
constants can be done inline. */
#define CONSTANT_ALIGNMENT(EXP, ALIGN) ix86_constant_alignment ((EXP), (ALIGN))
/* If defined, a C expression to compute the alignment for a static
variable. TYPE is the data type, and ALIGN is the alignment that
the object would ordinarily have. The value of this macro is used
instead of that alignment to align the object.
If this macro is not defined, then ALIGN is used.
One use of this macro is to increase alignment of medium-size
data to make it all fit in fewer cache lines. Another is to
cause character arrays to be word-aligned so that `strcpy' calls
that copy constants to character arrays can be done inline. */
#define DATA_ALIGNMENT(TYPE, ALIGN) ix86_data_alignment ((TYPE), (ALIGN))
/* If defined, a C expression to compute the alignment for a local
variable. TYPE is the data type, and ALIGN is the alignment that
the object would ordinarily have. The value of this macro is used
instead of that alignment to align the object.
If this macro is not defined, then ALIGN is used.
One use of this macro is to increase alignment of medium-size
data to make it all fit in fewer cache lines. */
#define LOCAL_ALIGNMENT(TYPE, ALIGN) ix86_local_alignment ((TYPE), (ALIGN))
/* If defined, a C expression that gives the alignment boundary, in
bits, of an argument with the specified mode and type. If it is
not defined, `PARM_BOUNDARY' is used for all arguments. */
#define FUNCTION_ARG_BOUNDARY(MODE, TYPE) \
ix86_function_arg_boundary ((MODE), (TYPE))
/* Set this nonzero if move instructions will actually fail to work
when given unaligned data. */
#define STRICT_ALIGNMENT 0
/* If bit field type is int, don't let it cross an int,
and give entire struct the alignment of an int. */
/* Required on the 386 since it doesn't have bit-field insns. */
#define PCC_BITFIELD_TYPE_MATTERS 1
/* Standard register usage. */
/* This processor has special stack-like registers. See reg-stack.c
for details. */
#define STACK_REGS
#define IS_STACK_MODE(MODE) \
((MODE) == DFmode || (MODE) == SFmode || (MODE) == XFmode \
|| (MODE) == TFmode)
/* Number of actual hardware registers.
The hardware registers are assigned numbers for the compiler
from 0 to just below FIRST_PSEUDO_REGISTER.
All registers that the compiler knows about must be given numbers,
even those that are not normally considered general registers.
In the 80386 we give the 8 general purpose registers the numbers 0-7.
We number the floating point registers 8-15.
Note that registers 0-7 can be accessed as a short or int,
while only 0-3 may be used with byte `mov' instructions.
Reg 16 does not correspond to any hardware register, but instead
appears in the RTL as an argument pointer prior to reload, and is
eliminated during reloading in favor of either the stack or frame
pointer. */
#define FIRST_PSEUDO_REGISTER 53
/* Number of hardware registers that go into the DWARF-2 unwind info.
If not defined, equals FIRST_PSEUDO_REGISTER. */
#define DWARF_FRAME_REGISTERS 17
/* 1 for registers that have pervasive standard uses
and are not available for the register allocator.
On the 80386, the stack pointer is such, as is the arg pointer.
The value is an mask - bit 1 is set for fixed registers
for 32bit target, while 2 is set for fixed registers for 64bit.
Proper value is computed in the CONDITIONAL_REGISTER_USAGE.
*/
#define FIXED_REGISTERS \
/*ax,dx,cx,bx,si,di,bp,sp,st,st1,st2,st3,st4,st5,st6,st7*/ \
{ 0, 0, 0, 0, 0, 0, 0, 3, 0, 0, 0, 0, 0, 0, 0, 0, \
/*arg,flags,fpsr,dir,frame*/ \
3, 3, 3, 3, 3, \
/*xmm0,xmm1,xmm2,xmm3,xmm4,xmm5,xmm6,xmm7*/ \
0, 0, 0, 0, 0, 0, 0, 0, \
/*mmx0,mmx1,mmx2,mmx3,mmx4,mmx5,mmx6,mmx7*/ \
0, 0, 0, 0, 0, 0, 0, 0, \
/* r8, r9, r10, r11, r12, r13, r14, r15*/ \
1, 1, 1, 1, 1, 1, 1, 1, \
/*xmm8,xmm9,xmm10,xmm11,xmm12,xmm13,xmm14,xmm15*/ \
1, 1, 1, 1, 1, 1, 1, 1}
/* 1 for registers not available across function calls.
These must include the FIXED_REGISTERS and also any
registers that can be used without being saved.
The latter must include the registers where values are returned
and the register where structure-value addresses are passed.
Aside from that, you can include as many other registers as you like.
The value is an mask - bit 1 is set for call used
for 32bit target, while 2 is set for call used for 64bit.
Proper value is computed in the CONDITIONAL_REGISTER_USAGE.
*/
#define CALL_USED_REGISTERS \
/*ax,dx,cx,bx,si,di,bp,sp,st,st1,st2,st3,st4,st5,st6,st7*/ \
{ 3, 3, 3, 0, 2, 2, 0, 3, 3, 3, 3, 3, 3, 3, 3, 3, \
/*arg,flags,fpsr,dir,frame*/ \
3, 3, 3, 3, 3, \
/*xmm0,xmm1,xmm2,xmm3,xmm4,xmm5,xmm6,xmm7*/ \
3, 3, 3, 3, 3, 3, 3, 3, \
/*mmx0,mmx1,mmx2,mmx3,mmx4,mmx5,mmx6,mmx7*/ \
3, 3, 3, 3, 3, 3, 3, 3, \
/* r8, r9, r10, r11, r12, r13, r14, r15*/ \
3, 3, 3, 3, 1, 1, 1, 1, \
/*xmm8,xmm9,xmm10,xmm11,xmm12,xmm13,xmm14,xmm15*/ \
3, 3, 3, 3, 3, 3, 3, 3} \
/* Order in which to allocate registers. Each register must be
listed once, even those in FIXED_REGISTERS. List frame pointer
late and fixed registers last. Note that, in general, we prefer
registers listed in CALL_USED_REGISTERS, keeping the others
available for storage of persistent values.
The ORDER_REGS_FOR_LOCAL_ALLOC actually overwrite the order,
so this is just empty initializer for array. */
#define REG_ALLOC_ORDER \
{ 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17,\
18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, \
33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, \
48, 49, 50, 51, 52 }
/* ORDER_REGS_FOR_LOCAL_ALLOC is a macro which permits reg_alloc_order
to be rearranged based on a particular function. When using sse math,
we want to allocase SSE before x87 registers and vice vera. */
#define ORDER_REGS_FOR_LOCAL_ALLOC x86_order_regs_for_local_alloc ()
/* Macro to conditionally modify fixed_regs/call_used_regs. */
#define CONDITIONAL_REGISTER_USAGE \
do { \
int i; \
for (i = 0; i < FIRST_PSEUDO_REGISTER; i++) \
{ \
fixed_regs[i] = (fixed_regs[i] & (TARGET_64BIT ? 2 : 1)) != 0; \
call_used_regs[i] = (call_used_regs[i] \
& (TARGET_64BIT ? 2 : 1)) != 0; \
} \
if (PIC_OFFSET_TABLE_REGNUM != INVALID_REGNUM) \
{ \
fixed_regs[PIC_OFFSET_TABLE_REGNUM] = 1; \
call_used_regs[PIC_OFFSET_TABLE_REGNUM] = 1; \
} \
if (! TARGET_MMX) \
{ \
int i; \
for (i = 0; i < FIRST_PSEUDO_REGISTER; i++) \
if (TEST_HARD_REG_BIT (reg_class_contents[(int)MMX_REGS], i)) \
fixed_regs[i] = call_used_regs[i] = 1; \
} \
if (! TARGET_SSE) \
{ \
int i; \
for (i = 0; i < FIRST_PSEUDO_REGISTER; i++) \
if (TEST_HARD_REG_BIT (reg_class_contents[(int)SSE_REGS], i)) \
fixed_regs[i] = call_used_regs[i] = 1; \
} \
if (! TARGET_80387 && ! TARGET_FLOAT_RETURNS_IN_80387) \
{ \
int i; \
HARD_REG_SET x; \
COPY_HARD_REG_SET (x, reg_class_contents[(int)FLOAT_REGS]); \
for (i = 0; i < FIRST_PSEUDO_REGISTER; i++) \
if (TEST_HARD_REG_BIT (x, i)) \
fixed_regs[i] = call_used_regs[i] = 1; \
} \
} while (0)
/* Return number of consecutive hard regs needed starting at reg REGNO
to hold something of mode MODE.
This is ordinarily the length in words of a value of mode MODE
but can be less for certain modes in special long registers.
Actually there are no two word move instructions for consecutive
registers. And only registers 0-3 may have mov byte instructions
applied to them.
*/
#define HARD_REGNO_NREGS(REGNO, MODE) \
(FP_REGNO_P (REGNO) || SSE_REGNO_P (REGNO) || MMX_REGNO_P (REGNO) \
? (COMPLEX_MODE_P (MODE) ? 2 : 1) \
: ((MODE) == TFmode \
? (TARGET_64BIT ? 2 : 3) \
: (MODE) == TCmode \
? (TARGET_64BIT ? 4 : 6) \
: ((GET_MODE_SIZE (MODE) + UNITS_PER_WORD - 1) / UNITS_PER_WORD)))
#define VALID_SSE2_REG_MODE(MODE) \
((MODE) == V16QImode || (MODE) == V8HImode || (MODE) == V2DFmode \
|| (MODE) == V2DImode)
#define VALID_SSE_REG_MODE(MODE) \
((MODE) == TImode || (MODE) == V4SFmode || (MODE) == V4SImode \
|| (MODE) == SFmode \
/* Always accept SSE2 modes so that xmmintrin.h compiles. */ \
|| VALID_SSE2_REG_MODE (MODE) \
|| (TARGET_SSE2 && ((MODE) == DFmode || VALID_MMX_REG_MODE (MODE))))
#define VALID_MMX_REG_MODE_3DNOW(MODE) \
((MODE) == V2SFmode || (MODE) == SFmode)
#define VALID_MMX_REG_MODE(MODE) \
((MODE) == DImode || (MODE) == V8QImode || (MODE) == V4HImode \
|| (MODE) == V2SImode || (MODE) == SImode)
#define VECTOR_MODE_SUPPORTED_P(MODE) \
(VALID_SSE_REG_MODE (MODE) && TARGET_SSE ? 1 \
: VALID_MMX_REG_MODE (MODE) && TARGET_MMX ? 1 \
: VALID_MMX_REG_MODE_3DNOW (MODE) && TARGET_3DNOW ? 1 : 0)
#define VALID_FP_MODE_P(MODE) \
((MODE) == SFmode || (MODE) == DFmode || (MODE) == TFmode \
|| (!TARGET_64BIT && (MODE) == XFmode) \
|| (MODE) == SCmode || (MODE) == DCmode || (MODE) == TCmode \
|| (!TARGET_64BIT && (MODE) == XCmode))
#define VALID_INT_MODE_P(MODE) \
((MODE) == QImode || (MODE) == HImode || (MODE) == SImode \
|| (MODE) == DImode \
|| (MODE) == CQImode || (MODE) == CHImode || (MODE) == CSImode \
|| (MODE) == CDImode \
|| (TARGET_64BIT && ((MODE) == TImode || (MODE) == CTImode)))
/* Return true for modes passed in SSE registers. */
#define SSE_REG_MODE_P(MODE) \
((MODE) == TImode || (MODE) == V16QImode \
|| (MODE) == V8HImode || (MODE) == V2DFmode || (MODE) == V2DImode \
|| (MODE) == V4SFmode || (MODE) == V4SImode)
/* Return true for modes passed in MMX registers. */
#define MMX_REG_MODE_P(MODE) \
((MODE) == V8QImode || (MODE) == V4HImode || (MODE) == V2SImode \
|| (MODE) == V2SFmode)
/* Value is 1 if hard register REGNO can hold a value of machine-mode MODE. */
#define HARD_REGNO_MODE_OK(REGNO, MODE) \
ix86_hard_regno_mode_ok ((REGNO), (MODE))
/* Value is 1 if it is a good idea to tie two pseudo registers
when one has mode MODE1 and one has mode MODE2.
If HARD_REGNO_MODE_OK could produce different values for MODE1 and MODE2,
for any hard reg, then this must be 0 for correct output. */
#define MODES_TIEABLE_P(MODE1, MODE2) \
((MODE1) == (MODE2) \
|| (((MODE1) == HImode || (MODE1) == SImode \
|| ((MODE1) == QImode \
&& (TARGET_64BIT || !TARGET_PARTIAL_REG_STALL)) \
|| ((MODE1) == DImode && TARGET_64BIT)) \
&& ((MODE2) == HImode || (MODE2) == SImode \
|| ((MODE1) == QImode \
&& (TARGET_64BIT || !TARGET_PARTIAL_REG_STALL)) \
|| ((MODE2) == DImode && TARGET_64BIT))))
/* Specify the modes required to caller save a given hard regno.
We do this on i386 to prevent flags from being saved at all.
Kill any attempts to combine saving of modes. */
#define HARD_REGNO_CALLER_SAVE_MODE(REGNO, NREGS, MODE) \
(CC_REGNO_P (REGNO) ? VOIDmode \
: (MODE) == VOIDmode && (NREGS) != 1 ? VOIDmode \
: (MODE) == VOIDmode ? choose_hard_reg_mode ((REGNO), (NREGS)) \
: (MODE) == HImode && !TARGET_PARTIAL_REG_STALL ? SImode \
: (MODE) == QImode && (REGNO) >= 4 && !TARGET_64BIT ? SImode \
: (MODE))
/* Specify the registers used for certain standard purposes.
The values of these macros are register numbers. */
/* on the 386 the pc register is %eip, and is not usable as a general
register. The ordinary mov instructions won't work */
/* #define PC_REGNUM */
/* Register to use for pushing function arguments. */
#define STACK_POINTER_REGNUM 7
/* Base register for access to local variables of the function. */
#define HARD_FRAME_POINTER_REGNUM 6
/* Base register for access to local variables of the function. */
#define FRAME_POINTER_REGNUM 20
/* First floating point reg */
#define FIRST_FLOAT_REG 8
/* First & last stack-like regs */
#define FIRST_STACK_REG FIRST_FLOAT_REG
#define LAST_STACK_REG (FIRST_FLOAT_REG + 7)
#define FLAGS_REG 17
#define FPSR_REG 18
#define DIRFLAG_REG 19
#define FIRST_SSE_REG (FRAME_POINTER_REGNUM + 1)
#define LAST_SSE_REG (FIRST_SSE_REG + 7)
#define FIRST_MMX_REG (LAST_SSE_REG + 1)
#define LAST_MMX_REG (FIRST_MMX_REG + 7)
#define FIRST_REX_INT_REG (LAST_MMX_REG + 1)
#define LAST_REX_INT_REG (FIRST_REX_INT_REG + 7)
#define FIRST_REX_SSE_REG (LAST_REX_INT_REG + 1)
#define LAST_REX_SSE_REG (FIRST_REX_SSE_REG + 7)
/* Value should be nonzero if functions must have frame pointers.
Zero means the frame pointer need not be set up (and parms
may be accessed via the stack pointer) in functions that seem suitable.
This is computed in `reload', in reload1.c. */
#define FRAME_POINTER_REQUIRED ix86_frame_pointer_required ()
/* Override this in other tm.h files to cope with various OS losage
requiring a frame pointer. */
#ifndef SUBTARGET_FRAME_POINTER_REQUIRED
#define SUBTARGET_FRAME_POINTER_REQUIRED 0
#endif
/* Make sure we can access arbitrary call frames. */
#define SETUP_FRAME_ADDRESSES() ix86_setup_frame_addresses ()
/* Base register for access to arguments of the function. */
#define ARG_POINTER_REGNUM 16
/* Register in which static-chain is passed to a function.
We do use ECX as static chain register for 32 bit ABI. On the
64bit ABI, ECX is an argument register, so we use R10 instead. */
#define STATIC_CHAIN_REGNUM (TARGET_64BIT ? FIRST_REX_INT_REG + 10 - 8 : 2)
/* Register to hold the addressing base for position independent
code access to data items. We don't use PIC pointer for 64bit
mode. Define the regnum to dummy value to prevent gcc from
pessimizing code dealing with EBX.
To avoid clobbering a call-saved register unnecessarily, we renumber
the pic register when possible. The change is visible after the
prologue has been emitted. */
#define REAL_PIC_OFFSET_TABLE_REGNUM 3
#define PIC_OFFSET_TABLE_REGNUM \
(TARGET_64BIT || !flag_pic ? INVALID_REGNUM \
: reload_completed ? REGNO (pic_offset_table_rtx) \
: REAL_PIC_OFFSET_TABLE_REGNUM)
#define GOT_SYMBOL_NAME "_GLOBAL_OFFSET_TABLE_"
/* Register in which address to store a structure value
arrives in the function. On the 386, the prologue
copies this from the stack to register %eax. */
#define STRUCT_VALUE_INCOMING 0
/* Place in which caller passes the structure value address.
0 means push the value on the stack like an argument. */
#define STRUCT_VALUE 0
/* A C expression which can inhibit the returning of certain function
values in registers, based on the type of value. A nonzero value
says to return the function value in memory, just as large
structures are always returned. Here TYPE will be a C expression
of type `tree', representing the data type of the value.
Note that values of mode `BLKmode' must be explicitly handled by
this macro. Also, the option `-fpcc-struct-return' takes effect
regardless of this macro. On most systems, it is possible to
leave the macro undefined; this causes a default definition to be
used, whose value is the constant 1 for `BLKmode' values, and 0
otherwise.
Do not use this macro to indicate that structures and unions
should always be returned in memory. You should instead use
`DEFAULT_PCC_STRUCT_RETURN' to indicate this. */
#define RETURN_IN_MEMORY(TYPE) \
ix86_return_in_memory (TYPE)
/* Define the classes of registers for register constraints in the
machine description. Also define ranges of constants.
One of the classes must always be named ALL_REGS and include all hard regs.
If there is more than one class, another class must be named NO_REGS
and contain no registers.
The name GENERAL_REGS must be the name of a class (or an alias for
another name such as ALL_REGS). This is the class of registers
that is allowed by "g" or "r" in a register constraint.
Also, registers outside this class are allocated only when
instructions express preferences for them.
The classes must be numbered in nondecreasing order; that is,
a larger-numbered class must never be contained completely
in a smaller-numbered class.
For any two classes, it is very desirable that there be another
class that represents their union.
It might seem that class BREG is unnecessary, since no useful 386
opcode needs reg %ebx. But some systems pass args to the OS in ebx,
and the "b" register constraint is useful in asms for syscalls.
The flags and fpsr registers are in no class. */
enum reg_class
{
NO_REGS,
AREG, DREG, CREG, BREG, SIREG, DIREG,
AD_REGS, /* %eax/%edx for DImode */
Q_REGS, /* %eax %ebx %ecx %edx */
NON_Q_REGS, /* %esi %edi %ebp %esp */
INDEX_REGS, /* %eax %ebx %ecx %edx %esi %edi %ebp */
LEGACY_REGS, /* %eax %ebx %ecx %edx %esi %edi %ebp %esp */
GENERAL_REGS, /* %eax %ebx %ecx %edx %esi %edi %ebp %esp %r8 - %r15*/
FP_TOP_REG, FP_SECOND_REG, /* %st(0) %st(1) */
FLOAT_REGS,
SSE_REGS,
MMX_REGS,
FP_TOP_SSE_REGS,
FP_SECOND_SSE_REGS,
FLOAT_SSE_REGS,
FLOAT_INT_REGS,
INT_SSE_REGS,
FLOAT_INT_SSE_REGS,
ALL_REGS, LIM_REG_CLASSES
};
#define N_REG_CLASSES ((int) LIM_REG_CLASSES)
#define INTEGER_CLASS_P(CLASS) \
reg_class_subset_p ((CLASS), GENERAL_REGS)
#define FLOAT_CLASS_P(CLASS) \
reg_class_subset_p ((CLASS), FLOAT_REGS)
#define SSE_CLASS_P(CLASS) \
reg_class_subset_p ((CLASS), SSE_REGS)
#define MMX_CLASS_P(CLASS) \
reg_class_subset_p ((CLASS), MMX_REGS)
#define MAYBE_INTEGER_CLASS_P(CLASS) \
reg_classes_intersect_p ((CLASS), GENERAL_REGS)
#define MAYBE_FLOAT_CLASS_P(CLASS) \
reg_classes_intersect_p ((CLASS), FLOAT_REGS)
#define MAYBE_SSE_CLASS_P(CLASS) \
reg_classes_intersect_p (SSE_REGS, (CLASS))
#define MAYBE_MMX_CLASS_P(CLASS) \
reg_classes_intersect_p (MMX_REGS, (CLASS))
#define Q_CLASS_P(CLASS) \
reg_class_subset_p ((CLASS), Q_REGS)
/* Give names of register classes as strings for dump file. */
#define REG_CLASS_NAMES \
{ "NO_REGS", \
"AREG", "DREG", "CREG", "BREG", \
"SIREG", "DIREG", \
"AD_REGS", \
"Q_REGS", "NON_Q_REGS", \
"INDEX_REGS", \
"LEGACY_REGS", \
"GENERAL_REGS", \
"FP_TOP_REG", "FP_SECOND_REG", \
"FLOAT_REGS", \
"SSE_REGS", \
"MMX_REGS", \
"FP_TOP_SSE_REGS", \
"FP_SECOND_SSE_REGS", \
"FLOAT_SSE_REGS", \
"FLOAT_INT_REGS", \
"INT_SSE_REGS", \
"FLOAT_INT_SSE_REGS", \
"ALL_REGS" }
/* Define which registers fit in which classes.
This is an initializer for a vector of HARD_REG_SET
of length N_REG_CLASSES. */
#define REG_CLASS_CONTENTS \
{ { 0x00, 0x0 }, \
{ 0x01, 0x0 }, { 0x02, 0x0 }, /* AREG, DREG */ \
{ 0x04, 0x0 }, { 0x08, 0x0 }, /* CREG, BREG */ \
{ 0x10, 0x0 }, { 0x20, 0x0 }, /* SIREG, DIREG */ \
{ 0x03, 0x0 }, /* AD_REGS */ \
{ 0x0f, 0x0 }, /* Q_REGS */ \
{ 0x1100f0, 0x1fe0 }, /* NON_Q_REGS */ \
{ 0x7f, 0x1fe0 }, /* INDEX_REGS */ \
{ 0x1100ff, 0x0 }, /* LEGACY_REGS */ \
{ 0x1100ff, 0x1fe0 }, /* GENERAL_REGS */ \
{ 0x100, 0x0 }, { 0x0200, 0x0 },/* FP_TOP_REG, FP_SECOND_REG */\
{ 0xff00, 0x0 }, /* FLOAT_REGS */ \
{ 0x1fe00000,0x1fe000 }, /* SSE_REGS */ \
{ 0xe0000000, 0x1f }, /* MMX_REGS */ \
{ 0x1fe00100,0x1fe000 }, /* FP_TOP_SSE_REG */ \
{ 0x1fe00200,0x1fe000 }, /* FP_SECOND_SSE_REG */ \
{ 0x1fe0ff00,0x1fe000 }, /* FLOAT_SSE_REGS */ \
{ 0x1ffff, 0x1fe0 }, /* FLOAT_INT_REGS */ \
{ 0x1fe100ff,0x1fffe0 }, /* INT_SSE_REGS */ \
{ 0x1fe1ffff,0x1fffe0 }, /* FLOAT_INT_SSE_REGS */ \
{ 0xffffffff,0x1fffff } \
}
/* The same information, inverted:
Return the class number of the smallest class containing
reg number REGNO. This could be a conditional expression
or could index an array. */
#define REGNO_REG_CLASS(REGNO) (regclass_map[REGNO])
/* When defined, the compiler allows registers explicitly used in the
rtl to be used as spill registers but prevents the compiler from
extending the lifetime of these registers. */
#define SMALL_REGISTER_CLASSES 1
#define QI_REG_P(X) \
(REG_P (X) && REGNO (X) < 4)
#define GENERAL_REGNO_P(N) \
((N) < 8 || REX_INT_REGNO_P (N))
#define GENERAL_REG_P(X) \
(REG_P (X) && GENERAL_REGNO_P (REGNO (X)))
#define ANY_QI_REG_P(X) (TARGET_64BIT ? GENERAL_REG_P(X) : QI_REG_P (X))
#define NON_QI_REG_P(X) \
(REG_P (X) && REGNO (X) >= 4 && REGNO (X) < FIRST_PSEUDO_REGISTER)
#define REX_INT_REGNO_P(N) ((N) >= FIRST_REX_INT_REG && (N) <= LAST_REX_INT_REG)
#define REX_INT_REG_P(X) (REG_P (X) && REX_INT_REGNO_P (REGNO (X)))
#define FP_REG_P(X) (REG_P (X) && FP_REGNO_P (REGNO (X)))
#define FP_REGNO_P(N) ((N) >= FIRST_STACK_REG && (N) <= LAST_STACK_REG)
#define ANY_FP_REG_P(X) (REG_P (X) && ANY_FP_REGNO_P (REGNO (X)))
#define ANY_FP_REGNO_P(N) (FP_REGNO_P (N) || SSE_REGNO_P (N))
#define SSE_REGNO_P(N) \
(((N) >= FIRST_SSE_REG && (N) <= LAST_SSE_REG) \
|| ((N) >= FIRST_REX_SSE_REG && (N) <= LAST_REX_SSE_REG))
#define SSE_REGNO(N) \
((N) < 8 ? FIRST_SSE_REG + (N) : FIRST_REX_SSE_REG + (N) - 8)
#define SSE_REG_P(N) (REG_P (N) && SSE_REGNO_P (REGNO (N)))
#define SSE_FLOAT_MODE_P(MODE) \
((TARGET_SSE && (MODE) == SFmode) || (TARGET_SSE2 && (MODE) == DFmode))
#define MMX_REGNO_P(N) ((N) >= FIRST_MMX_REG && (N) <= LAST_MMX_REG)
#define MMX_REG_P(XOP) (REG_P (XOP) && MMX_REGNO_P (REGNO (XOP)))
#define STACK_REG_P(XOP) \
(REG_P (XOP) && \
REGNO (XOP) >= FIRST_STACK_REG && \
REGNO (XOP) <= LAST_STACK_REG)
#define NON_STACK_REG_P(XOP) (REG_P (XOP) && ! STACK_REG_P (XOP))
#define STACK_TOP_P(XOP) (REG_P (XOP) && REGNO (XOP) == FIRST_STACK_REG)
#define CC_REG_P(X) (REG_P (X) && CC_REGNO_P (REGNO (X)))
#define CC_REGNO_P(X) ((X) == FLAGS_REG || (X) == FPSR_REG)
/* Indicate whether hard register numbered REG_NO should be converted
to SSA form. */
#define CONVERT_HARD_REGISTER_TO_SSA_P(REG_NO) \
((REG_NO) == FLAGS_REG || (REG_NO) == ARG_POINTER_REGNUM)
/* The class value for index registers, and the one for base regs. */
#define INDEX_REG_CLASS INDEX_REGS
#define BASE_REG_CLASS GENERAL_REGS
/* Get reg_class from a letter such as appears in the machine description. */
#define REG_CLASS_FROM_LETTER(C) \
((C) == 'r' ? GENERAL_REGS : \
(C) == 'R' ? LEGACY_REGS : \
(C) == 'q' ? TARGET_64BIT ? GENERAL_REGS : Q_REGS : \
(C) == 'Q' ? Q_REGS : \
(C) == 'f' ? (TARGET_80387 || TARGET_FLOAT_RETURNS_IN_80387 \
? FLOAT_REGS \
: NO_REGS) : \
(C) == 't' ? (TARGET_80387 || TARGET_FLOAT_RETURNS_IN_80387 \
? FP_TOP_REG \
: NO_REGS) : \
(C) == 'u' ? (TARGET_80387 || TARGET_FLOAT_RETURNS_IN_80387 \
? FP_SECOND_REG \
: NO_REGS) : \
(C) == 'a' ? AREG : \
(C) == 'b' ? BREG : \
(C) == 'c' ? CREG : \
(C) == 'd' ? DREG : \
(C) == 'x' ? TARGET_SSE ? SSE_REGS : NO_REGS : \
(C) == 'Y' ? TARGET_SSE2? SSE_REGS : NO_REGS : \
(C) == 'y' ? TARGET_MMX ? MMX_REGS : NO_REGS : \
(C) == 'A' ? AD_REGS : \
(C) == 'D' ? DIREG : \
(C) == 'S' ? SIREG : NO_REGS)
/* The letters I, J, K, L and M in a register constraint string
can be used to stand for particular ranges of immediate operands.
This macro defines what the ranges are.
C is the letter, and VALUE is a constant value.
Return 1 if VALUE is in the range specified by C.
I is for non-DImode shifts.
J is for DImode shifts.
K is for signed imm8 operands.
L is for andsi as zero-extending move.
M is for shifts that can be executed by the "lea" opcode.
N is for immedaite operands for out/in instructions (0-255)
*/
#define CONST_OK_FOR_LETTER_P(VALUE, C) \
((C) == 'I' ? (VALUE) >= 0 && (VALUE) <= 31 \
: (C) == 'J' ? (VALUE) >= 0 && (VALUE) <= 63 \
: (C) == 'K' ? (VALUE) >= -128 && (VALUE) <= 127 \
: (C) == 'L' ? (VALUE) == 0xff || (VALUE) == 0xffff \
: (C) == 'M' ? (VALUE) >= 0 && (VALUE) <= 3 \
: (C) == 'N' ? (VALUE) >= 0 && (VALUE) <= 255 \
: 0)
/* Similar, but for floating constants, and defining letters G and H.
Here VALUE is the CONST_DOUBLE rtx itself. We allow constants even if
TARGET_387 isn't set, because the stack register converter may need to
load 0.0 into the function value register. */
#define CONST_DOUBLE_OK_FOR_LETTER_P(VALUE, C) \
((C) == 'G' ? standard_80387_constant_p (VALUE) \
: ((C) == 'H' ? standard_sse_constant_p (VALUE) : 0))
/* A C expression that defines the optional machine-dependent
constraint letters that can be used to segregate specific types of
operands, usually memory references, for the target machine. Any
letter that is not elsewhere defined and not matched by
`REG_CLASS_FROM_LETTER' may be used. Normally this macro will not
be defined.
If it is required for a particular target machine, it should
return 1 if VALUE corresponds to the operand type represented by
the constraint letter C. If C is not defined as an extra
constraint, the value returned should be 0 regardless of VALUE. */
#define EXTRA_CONSTRAINT(VALUE, C) \
((C) == 'e' ? x86_64_sign_extended_value (VALUE) \
: (C) == 'Z' ? x86_64_zero_extended_value (VALUE) \
: 0)
/* Place additional restrictions on the register class to use when it
is necessary to be able to hold a value of mode MODE in a reload
register for which class CLASS would ordinarily be used. */
#define LIMIT_RELOAD_CLASS(MODE, CLASS) \
((MODE) == QImode && !TARGET_64BIT \
&& ((CLASS) == ALL_REGS || (CLASS) == GENERAL_REGS \
|| (CLASS) == LEGACY_REGS || (CLASS) == INDEX_REGS) \
? Q_REGS : (CLASS))
/* Given an rtx X being reloaded into a reg required to be
in class CLASS, return the class of reg to actually use.
In general this is just CLASS; but on some machines
in some cases it is preferable to use a more restrictive class.
On the 80386 series, we prevent floating constants from being
reloaded into floating registers (since no move-insn can do that)
and we ensure that QImodes aren't reloaded into the esi or edi reg. */
/* Put float CONST_DOUBLE in the constant pool instead of fp regs.
QImode must go into class Q_REGS.
Narrow ALL_REGS to GENERAL_REGS. This supports allowing movsf and
movdf to do mem-to-mem moves through integer regs. */
#define PREFERRED_RELOAD_CLASS(X, CLASS) \
ix86_preferred_reload_class ((X), (CLASS))
/* If we are copying between general and FP registers, we need a memory
location. The same is true for SSE and MMX registers. */
#define SECONDARY_MEMORY_NEEDED(CLASS1, CLASS2, MODE) \
ix86_secondary_memory_needed ((CLASS1), (CLASS2), (MODE), 1)
/* QImode spills from non-QI registers need a scratch. This does not
happen often -- the only example so far requires an uninitialized
pseudo. */
#define SECONDARY_OUTPUT_RELOAD_CLASS(CLASS, MODE, OUT) \
(((CLASS) == GENERAL_REGS || (CLASS) == LEGACY_REGS \
|| (CLASS) == INDEX_REGS) && !TARGET_64BIT && (MODE) == QImode \
? Q_REGS : NO_REGS)
/* Return the maximum number of consecutive registers
needed to represent mode MODE in a register of class CLASS. */
/* On the 80386, this is the size of MODE in words,
except in the FP regs, where a single reg is always enough.
The TFmodes are really just 80bit values, so we use only 3 registers
to hold them, instead of 4, as the size would suggest.
*/
#define CLASS_MAX_NREGS(CLASS, MODE) \
(!MAYBE_INTEGER_CLASS_P (CLASS) \
? (COMPLEX_MODE_P (MODE) ? 2 : 1) \
: ((GET_MODE_SIZE ((MODE) == TFmode ? XFmode : (MODE)) \
+ UNITS_PER_WORD - 1) / UNITS_PER_WORD))
/* A C expression whose value is nonzero if pseudos that have been
assigned to registers of class CLASS would likely be spilled
because registers of CLASS are needed for spill registers.
The default value of this macro returns 1 if CLASS has exactly one
register and zero otherwise. On most machines, this default
should be used. Only define this macro to some other expression
if pseudo allocated by `local-alloc.c' end up in memory because
their hard registers were needed for spill registers. If this
macro returns nonzero for those classes, those pseudos will only
be allocated by `global.c', which knows how to reallocate the
pseudo to another register. If there would not be another
register available for reallocation, you should not change the
definition of this macro since the only effect of such a
definition would be to slow down register allocation. */
#define CLASS_LIKELY_SPILLED_P(CLASS) \
(((CLASS) == AREG) \
|| ((CLASS) == DREG) \
|| ((CLASS) == CREG) \
|| ((CLASS) == BREG) \
|| ((CLASS) == AD_REGS) \
|| ((CLASS) == SIREG) \
|| ((CLASS) == DIREG))
/* A C statement that adds to CLOBBERS any hard regs the port wishes
to automatically clobber for all asms.
We do this in the new i386 backend to maintain source compatibility
with the old cc0-based compiler. */
#define MD_ASM_CLOBBERS(CLOBBERS) \
do { \
(CLOBBERS) = tree_cons (NULL_TREE, build_string (5, "flags"), \
(CLOBBERS)); \
(CLOBBERS) = tree_cons (NULL_TREE, build_string (4, "fpsr"), \
(CLOBBERS)); \
(CLOBBERS) = tree_cons (NULL_TREE, build_string (7, "dirflag"), \
(CLOBBERS)); \
} while (0)
/* Stack layout; function entry, exit and calling. */
/* Define this if pushing a word on the stack
makes the stack pointer a smaller address. */
#define STACK_GROWS_DOWNWARD
/* Define this if the nominal address of the stack frame
is at the high-address end of the local variables;
that is, each additional local variable allocated
goes at a more negative offset in the frame. */
#define FRAME_GROWS_DOWNWARD
/* Offset within stack frame to start allocating local variables at.
If FRAME_GROWS_DOWNWARD, this is the offset to the END of the
first local allocated. Otherwise, it is the offset to the BEGINNING
of the first local allocated. */
#define STARTING_FRAME_OFFSET 0
/* If we generate an insn to push BYTES bytes,
this says how many the stack pointer really advances by.
On 386 pushw decrements by exactly 2 no matter what the position was.
On the 386 there is no pushb; we use pushw instead, and this
has the effect of rounding up to 2.
For 64bit ABI we round up to 8 bytes.
*/
#define PUSH_ROUNDING(BYTES) \
(TARGET_64BIT \
? (((BYTES) + 7) & (-8)) \
: (((BYTES) + 1) & (-2)))
/* If defined, the maximum amount of space required for outgoing arguments will
be computed and placed into the variable
`current_function_outgoing_args_size'. No space will be pushed onto the
stack for each call; instead, the function prologue should increase the stack
frame size by this amount. */
#define ACCUMULATE_OUTGOING_ARGS TARGET_ACCUMULATE_OUTGOING_ARGS
/* If defined, a C expression whose value is nonzero when we want to use PUSH
instructions to pass outgoing arguments. */
#define PUSH_ARGS (TARGET_PUSH_ARGS && !ACCUMULATE_OUTGOING_ARGS)
/* Offset of first parameter from the argument pointer register value. */
#define FIRST_PARM_OFFSET(FNDECL) 0
/* Define this macro if functions should assume that stack space has been
allocated for arguments even when their values are passed in registers.
The value of this macro is the size, in bytes, of the area reserved for
arguments passed in registers for the function represented by FNDECL.
This space can be allocated by the caller, or be a part of the
machine-dependent stack frame: `OUTGOING_REG_PARM_STACK_SPACE' says
which. */
#define REG_PARM_STACK_SPACE(FNDECL) 0
/* Define as a C expression that evaluates to nonzero if we do not know how
to pass TYPE solely in registers. The file expr.h defines a
definition that is usually appropriate, refer to expr.h for additional
documentation. If `REG_PARM_STACK_SPACE' is defined, the argument will be
computed in the stack and then loaded into a register. */
#define MUST_PASS_IN_STACK(MODE, TYPE) \
((TYPE) != 0 \
&& (TREE_CODE (TYPE_SIZE (TYPE)) != INTEGER_CST \
|| TREE_ADDRESSABLE (TYPE) \
|| ((MODE) == TImode) \
|| ((MODE) == BLKmode \
&& ! ((TYPE) != 0 \
&& TREE_CODE (TYPE_SIZE (TYPE)) == INTEGER_CST \
&& 0 == (int_size_in_bytes (TYPE) \
% (PARM_BOUNDARY / BITS_PER_UNIT))) \
&& (FUNCTION_ARG_PADDING (MODE, TYPE) \
== (BYTES_BIG_ENDIAN ? upward : downward)))))
/* Value is the number of bytes of arguments automatically
popped when returning from a subroutine call.
FUNDECL is the declaration node of the function (as a tree),
FUNTYPE is the data type of the function (as a tree),
or for a library call it is an identifier node for the subroutine name.
SIZE is the number of bytes of arguments passed on the stack.
On the 80386, the RTD insn may be used to pop them if the number
of args is fixed, but if the number is variable then the caller
must pop them all. RTD can't be used for library calls now
because the library is compiled with the Unix compiler.
Use of RTD is a selectable option, since it is incompatible with
standard Unix calling sequences. If the option is not selected,
the caller must always pop the args.
The attribute stdcall is equivalent to RTD on a per module basis. */
#define RETURN_POPS_ARGS(FUNDECL, FUNTYPE, SIZE) \
ix86_return_pops_args ((FUNDECL), (FUNTYPE), (SIZE))
/* Define how to find the value returned by a function.
VALTYPE is the data type of the value (as a tree).
If the precise function being called is known, FUNC is its FUNCTION_DECL;
otherwise, FUNC is 0. */
#define FUNCTION_VALUE(VALTYPE, FUNC) \
ix86_function_value (VALTYPE)
#define FUNCTION_VALUE_REGNO_P(N) \
ix86_function_value_regno_p (N)
/* Define how to find the value returned by a library function
assuming the value has mode MODE. */
#define LIBCALL_VALUE(MODE) \
ix86_libcall_value (MODE)
/* Define the size of the result block used for communication between
untyped_call and untyped_return. The block contains a DImode value
followed by the block used by fnsave and frstor. */
#define APPLY_RESULT_SIZE (8+108)
/* 1 if N is a possible register number for function argument passing. */
#define FUNCTION_ARG_REGNO_P(N) ix86_function_arg_regno_p (N)
/* Define a data type for recording info about an argument list
during the scan of that argument list. This data type should
hold all necessary information about the function itself
and about the args processed so far, enough to enable macros
such as FUNCTION_ARG to determine where the next arg should go. */
typedef struct ix86_args {
int words; /* # words passed so far */
int nregs; /* # registers available for passing */
int regno; /* next available register number */
int sse_words; /* # sse words passed so far */
int sse_nregs; /* # sse registers available for passing */
int sse_regno; /* next available sse register number */
int maybe_vaarg; /* true for calls to possibly vardic fncts. */
} CUMULATIVE_ARGS;
/* Initialize a variable CUM of type CUMULATIVE_ARGS
for a call to a function whose data type is FNTYPE.
For a library call, FNTYPE is 0. */
#define INIT_CUMULATIVE_ARGS(CUM, FNTYPE, LIBNAME, INDIRECT) \
init_cumulative_args (&(CUM), (FNTYPE), (LIBNAME))
/* Update the data in CUM to advance over an argument
of mode MODE and data type TYPE.
(TYPE is null for libcalls where that information may not be available.) */
#define FUNCTION_ARG_ADVANCE(CUM, MODE, TYPE, NAMED) \
function_arg_advance (&(CUM), (MODE), (TYPE), (NAMED))
/* Define where to put the arguments to a function.
Value is zero to push the argument on the stack,
or a hard register in which to store the argument.
MODE is the argument's machine mode.
TYPE is the data type of the argument (as a tree).
This is null for libcalls where that information may
not be available.
CUM is a variable of type CUMULATIVE_ARGS which gives info about
the preceding args and about the function being called.
NAMED is nonzero if this argument is a named parameter
(otherwise it is an extra parameter matching an ellipsis). */
#define FUNCTION_ARG(CUM, MODE, TYPE, NAMED) \
function_arg (&(CUM), (MODE), (TYPE), (NAMED))
/* For an arg passed partly in registers and partly in memory,
this is the number of registers used.
For args passed entirely in registers or entirely in memory, zero. */
#define FUNCTION_ARG_PARTIAL_NREGS(CUM, MODE, TYPE, NAMED) 0
/* If PIC, we cannot make sibling calls to global functions
because the PLT requires %ebx live.
If we are returning floats on the register stack, we cannot make
sibling calls to functions that return floats. (The stack adjust
instruction will wind up after the sibcall jump, and not be executed.) */
#define FUNCTION_OK_FOR_SIBCALL(DECL) \
((DECL) \
&& (! flag_pic || ! TREE_PUBLIC (DECL)) \
&& (! TARGET_FLOAT_RETURNS_IN_80387 \
|| ! FLOAT_MODE_P (TYPE_MODE (TREE_TYPE (TREE_TYPE (DECL)))) \
|| FLOAT_MODE_P (TYPE_MODE (TREE_TYPE (TREE_TYPE (cfun->decl))))))
/* Perform any needed actions needed for a function that is receiving a
variable number of arguments.
CUM is as above.
MODE and TYPE are the mode and type of the current parameter.
PRETEND_SIZE is a variable that should be set to the amount of stack
that must be pushed by the prolog to pretend that our caller pushed
it.
Normally, this macro will push all remaining incoming registers on the
stack and set PRETEND_SIZE to the length of the registers pushed. */
#define SETUP_INCOMING_VARARGS(CUM, MODE, TYPE, PRETEND_SIZE, NO_RTL) \
ix86_setup_incoming_varargs (&(CUM), (MODE), (TYPE), &(PRETEND_SIZE), \
(NO_RTL))
/* Define the `__builtin_va_list' type for the ABI. */
#define BUILD_VA_LIST_TYPE(VALIST) \
((VALIST) = ix86_build_va_list ())
/* Implement `va_start' for varargs and stdarg. */
#define EXPAND_BUILTIN_VA_START(VALIST, NEXTARG) \
ix86_va_start (VALIST, NEXTARG)
/* Implement `va_arg'. */
#define EXPAND_BUILTIN_VA_ARG(VALIST, TYPE) \
ix86_va_arg ((VALIST), (TYPE))
/* This macro is invoked at the end of compilation. It is used here to
output code for -fpic that will load the return address into %ebx. */
#undef ASM_FILE_END
#define ASM_FILE_END(FILE) ix86_asm_file_end (FILE)
/* Output assembler code to FILE to increment profiler label # LABELNO
for profiling a function entry. */
#define FUNCTION_PROFILER(FILE, LABELNO) \
do { \
if (flag_pic) \
{ \
fprintf ((FILE), "\tleal\t%sP%d@GOTOFF(%%ebx),%%edx\n", \
LPREFIX, (LABELNO)); \
fprintf ((FILE), "\tcall\t*_mcount@GOT(%%ebx)\n"); \
} \
else \
{ \
fprintf ((FILE), "\tmovl\t$%sP%d,%%edx\n", LPREFIX, (LABELNO)); \
fprintf ((FILE), "\tcall\t_mcount\n"); \
} \
} while (0)
/* EXIT_IGNORE_STACK should be nonzero if, when returning from a function,
the stack pointer does not matter. The value is tested only in
functions that have frame pointers.
No definition is equivalent to always zero. */
/* Note on the 386 it might be more efficient not to define this since
we have to restore it ourselves from the frame pointer, in order to
use pop */
#define EXIT_IGNORE_STACK 1
/* Output assembler code for a block containing the constant parts
of a trampoline, leaving space for the variable parts. */
/* On the 386, the trampoline contains two instructions:
mov #STATIC,ecx
jmp FUNCTION
The trampoline is generated entirely at runtime. The operand of JMP
is the address of FUNCTION relative to the instruction following the
JMP (which is 5 bytes long). */
/* Length in units of the trampoline for entering a nested function. */
#define TRAMPOLINE_SIZE (TARGET_64BIT ? 23 : 10)
/* Emit RTL insns to initialize the variable parts of a trampoline.
FNADDR is an RTX for the address of the function's pure code.
CXT is an RTX for the static chain value for the function. */
#define INITIALIZE_TRAMPOLINE(TRAMP, FNADDR, CXT) \
x86_initialize_trampoline ((TRAMP), (FNADDR), (CXT))
/* Definitions for register eliminations.
This is an array of structures. Each structure initializes one pair
of eliminable registers. The "from" register number is given first,
followed by "to". Eliminations of the same "from" register are listed
in order of preference.
There are two registers that can always be eliminated on the i386.
The frame pointer and the arg pointer can be replaced by either the
hard frame pointer or to the stack pointer, depending upon the
circumstances. The hard frame pointer is not used before reload and
so it is not eligible for elimination. */
#define ELIMINABLE_REGS \
{{ ARG_POINTER_REGNUM, STACK_POINTER_REGNUM}, \
{ ARG_POINTER_REGNUM, HARD_FRAME_POINTER_REGNUM}, \
{ FRAME_POINTER_REGNUM, STACK_POINTER_REGNUM}, \
{ FRAME_POINTER_REGNUM, HARD_FRAME_POINTER_REGNUM}} \
/* Given FROM and TO register numbers, say whether this elimination is
allowed. Frame pointer elimination is automatically handled.
All other eliminations are valid. */
#define CAN_ELIMINATE(FROM, TO) \
((TO) == STACK_POINTER_REGNUM ? ! frame_pointer_needed : 1)
/* Define the offset between two registers, one to be eliminated, and the other
its replacement, at the start of a routine. */
#define INITIAL_ELIMINATION_OFFSET(FROM, TO, OFFSET) \
((OFFSET) = ix86_initial_elimination_offset ((FROM), (TO)))
/* Addressing modes, and classification of registers for them. */
/* #define HAVE_POST_INCREMENT 0 */
/* #define HAVE_POST_DECREMENT 0 */
/* #define HAVE_PRE_DECREMENT 0 */
/* #define HAVE_PRE_INCREMENT 0 */
/* Macros to check register numbers against specific register classes. */
/* These assume that REGNO is a hard or pseudo reg number.
They give nonzero only if REGNO is a hard reg of the suitable class
or a pseudo reg currently allocated to a suitable hard reg.
Since they use reg_renumber, they are safe only once reg_renumber
has been allocated, which happens in local-alloc.c. */
#define REGNO_OK_FOR_INDEX_P(REGNO) \
((REGNO) < STACK_POINTER_REGNUM \
|| (REGNO >= FIRST_REX_INT_REG \
&& (REGNO) <= LAST_REX_INT_REG) \
|| ((unsigned) reg_renumber[(REGNO)] >= FIRST_REX_INT_REG \
&& (unsigned) reg_renumber[(REGNO)] <= LAST_REX_INT_REG) \
|| (unsigned) reg_renumber[(REGNO)] < STACK_POINTER_REGNUM)
#define REGNO_OK_FOR_BASE_P(REGNO) \
((REGNO) <= STACK_POINTER_REGNUM \
|| (REGNO) == ARG_POINTER_REGNUM \
|| (REGNO) == FRAME_POINTER_REGNUM \
|| (REGNO >= FIRST_REX_INT_REG \
&& (REGNO) <= LAST_REX_INT_REG) \
|| ((unsigned) reg_renumber[(REGNO)] >= FIRST_REX_INT_REG \
&& (unsigned) reg_renumber[(REGNO)] <= LAST_REX_INT_REG) \
|| (unsigned) reg_renumber[(REGNO)] <= STACK_POINTER_REGNUM)
#define REGNO_OK_FOR_SIREG_P(REGNO) \
((REGNO) == 4 || reg_renumber[(REGNO)] == 4)
#define REGNO_OK_FOR_DIREG_P(REGNO) \
((REGNO) == 5 || reg_renumber[(REGNO)] == 5)
/* The macros REG_OK_FOR..._P assume that the arg is a REG rtx
and check its validity for a certain class.
We have two alternate definitions for each of them.
The usual definition accepts all pseudo regs; the other rejects
them unless they have been allocated suitable hard regs.
The symbol REG_OK_STRICT causes the latter definition to be used.
Most source files want to accept pseudo regs in the hope that
they will get allocated to the class that the insn wants them to be in.
Source files for reload pass need to be strict.
After reload, it makes no difference, since pseudo regs have
been eliminated by then. */
/* Non strict versions, pseudos are ok */
#define REG_OK_FOR_INDEX_NONSTRICT_P(X) \
(REGNO (X) < STACK_POINTER_REGNUM \
|| (REGNO (X) >= FIRST_REX_INT_REG \
&& REGNO (X) <= LAST_REX_INT_REG) \
|| REGNO (X) >= FIRST_PSEUDO_REGISTER)
#define REG_OK_FOR_BASE_NONSTRICT_P(X) \
(REGNO (X) <= STACK_POINTER_REGNUM \
|| REGNO (X) == ARG_POINTER_REGNUM \
|| REGNO (X) == FRAME_POINTER_REGNUM \
|| (REGNO (X) >= FIRST_REX_INT_REG \
&& REGNO (X) <= LAST_REX_INT_REG) \
|| REGNO (X) >= FIRST_PSEUDO_REGISTER)
/* Strict versions, hard registers only */
#define REG_OK_FOR_INDEX_STRICT_P(X) REGNO_OK_FOR_INDEX_P (REGNO (X))
#define REG_OK_FOR_BASE_STRICT_P(X) REGNO_OK_FOR_BASE_P (REGNO (X))
#ifndef REG_OK_STRICT
#define REG_OK_FOR_INDEX_P(X) REG_OK_FOR_INDEX_NONSTRICT_P (X)
#define REG_OK_FOR_BASE_P(X) REG_OK_FOR_BASE_NONSTRICT_P (X)
#else
#define REG_OK_FOR_INDEX_P(X) REG_OK_FOR_INDEX_STRICT_P (X)
#define REG_OK_FOR_BASE_P(X) REG_OK_FOR_BASE_STRICT_P (X)
#endif
/* GO_IF_LEGITIMATE_ADDRESS recognizes an RTL expression
that is a valid memory address for an instruction.
The MODE argument is the machine mode for the MEM expression
that wants to use this address.
The other macros defined here are used only in GO_IF_LEGITIMATE_ADDRESS,
except for CONSTANT_ADDRESS_P which is usually machine-independent.
See legitimize_pic_address in i386.c for details as to what
constitutes a legitimate address when -fpic is used. */
#define MAX_REGS_PER_ADDRESS 2
#define CONSTANT_ADDRESS_P(X) constant_address_p (X)
/* Nonzero if the constant value X is a legitimate general operand.
It is given that X satisfies CONSTANT_P or is a CONST_DOUBLE. */
#define LEGITIMATE_CONSTANT_P(X) legitimate_constant_p (X)
#ifdef REG_OK_STRICT
#define GO_IF_LEGITIMATE_ADDRESS(MODE, X, ADDR) \
do { \
if (legitimate_address_p ((MODE), (X), 1)) \
goto ADDR; \
} while (0)
#else
#define GO_IF_LEGITIMATE_ADDRESS(MODE, X, ADDR) \
do { \
if (legitimate_address_p ((MODE), (X), 0)) \
goto ADDR; \
} while (0)
#endif
/* If defined, a C expression to determine the base term of address X.
This macro is used in only one place: `find_base_term' in alias.c.
It is always safe for this macro to not be defined. It exists so
that alias analysis can understand machine-dependent addresses.
The typical use of this macro is to handle addresses containing
a label_ref or symbol_ref within an UNSPEC. */
#define FIND_BASE_TERM(X) ix86_find_base_term (X)
/* Try machine-dependent ways of modifying an illegitimate address
to be legitimate. If we find one, return the new, valid address.
This macro is used in only one place: `memory_address' in explow.c.
OLDX is the address as it was before break_out_memory_refs was called.
In some cases it is useful to look at this to decide what needs to be done.
MODE and WIN are passed so that this macro can use
GO_IF_LEGITIMATE_ADDRESS.
It is always safe for this macro to do nothing. It exists to recognize
opportunities to optimize the output.
For the 80386, we handle X+REG by loading X into a register R and
using R+REG. R will go in a general reg and indexing will be used.
However, if REG is a broken-out memory address or multiplication,
nothing needs to be done because REG can certainly go in a general reg.
When -fpic is used, special handling is needed for symbolic references.
See comments by legitimize_pic_address in i386.c for details. */
#define LEGITIMIZE_ADDRESS(X, OLDX, MODE, WIN) \
do { \
(X) = legitimize_address ((X), (OLDX), (MODE)); \
if (memory_address_p ((MODE), (X))) \
goto WIN; \
} while (0)
#define REWRITE_ADDRESS(X) rewrite_address (X)
/* Nonzero if the constant value X is a legitimate general operand
when generating PIC code. It is given that flag_pic is on and
that X satisfies CONSTANT_P or is a CONST_DOUBLE. */
#define LEGITIMATE_PIC_OPERAND_P(X) legitimate_pic_operand_p (X)
#define SYMBOLIC_CONST(X) \
(GET_CODE (X) == SYMBOL_REF \
|| GET_CODE (X) == LABEL_REF \
|| (GET_CODE (X) == CONST && symbolic_reference_mentioned_p (X)))
/* Go to LABEL if ADDR (a legitimate address expression)
has an effect that depends on the machine mode it is used for.
On the 80386, only postdecrement and postincrement address depend thus
(the amount of decrement or increment being the length of the operand). */
#define GO_IF_MODE_DEPENDENT_ADDRESS(ADDR, LABEL) \
do { \
if (GET_CODE (ADDR) == POST_INC \
|| GET_CODE (ADDR) == POST_DEC) \
goto LABEL; \
} while (0)
/* Codes for all the SSE/MMX builtins. */
enum ix86_builtins
{
IX86_BUILTIN_ADDPS,
IX86_BUILTIN_ADDSS,
IX86_BUILTIN_DIVPS,
IX86_BUILTIN_DIVSS,
IX86_BUILTIN_MULPS,
IX86_BUILTIN_MULSS,
IX86_BUILTIN_SUBPS,
IX86_BUILTIN_SUBSS,
IX86_BUILTIN_CMPEQPS,
IX86_BUILTIN_CMPLTPS,
IX86_BUILTIN_CMPLEPS,
IX86_BUILTIN_CMPGTPS,
IX86_BUILTIN_CMPGEPS,
IX86_BUILTIN_CMPNEQPS,
IX86_BUILTIN_CMPNLTPS,
IX86_BUILTIN_CMPNLEPS,
IX86_BUILTIN_CMPNGTPS,
IX86_BUILTIN_CMPNGEPS,
IX86_BUILTIN_CMPORDPS,
IX86_BUILTIN_CMPUNORDPS,
IX86_BUILTIN_CMPNEPS,
IX86_BUILTIN_CMPEQSS,
IX86_BUILTIN_CMPLTSS,
IX86_BUILTIN_CMPLESS,
IX86_BUILTIN_CMPNEQSS,
IX86_BUILTIN_CMPNLTSS,
IX86_BUILTIN_CMPNLESS,
IX86_BUILTIN_CMPORDSS,
IX86_BUILTIN_CMPUNORDSS,
IX86_BUILTIN_CMPNESS,
IX86_BUILTIN_COMIEQSS,
IX86_BUILTIN_COMILTSS,
IX86_BUILTIN_COMILESS,
IX86_BUILTIN_COMIGTSS,
IX86_BUILTIN_COMIGESS,
IX86_BUILTIN_COMINEQSS,
IX86_BUILTIN_UCOMIEQSS,
IX86_BUILTIN_UCOMILTSS,
IX86_BUILTIN_UCOMILESS,
IX86_BUILTIN_UCOMIGTSS,
IX86_BUILTIN_UCOMIGESS,
IX86_BUILTIN_UCOMINEQSS,
IX86_BUILTIN_CVTPI2PS,
IX86_BUILTIN_CVTPS2PI,
IX86_BUILTIN_CVTSI2SS,
IX86_BUILTIN_CVTSS2SI,
IX86_BUILTIN_CVTTPS2PI,
IX86_BUILTIN_CVTTSS2SI,
IX86_BUILTIN_MAXPS,
IX86_BUILTIN_MAXSS,
IX86_BUILTIN_MINPS,
IX86_BUILTIN_MINSS,
IX86_BUILTIN_LOADAPS,
IX86_BUILTIN_LOADUPS,
IX86_BUILTIN_STOREAPS,
IX86_BUILTIN_STOREUPS,
IX86_BUILTIN_LOADSS,
IX86_BUILTIN_STORESS,
IX86_BUILTIN_MOVSS,
IX86_BUILTIN_MOVHLPS,
IX86_BUILTIN_MOVLHPS,
IX86_BUILTIN_LOADHPS,
IX86_BUILTIN_LOADLPS,
IX86_BUILTIN_STOREHPS,
IX86_BUILTIN_STORELPS,
IX86_BUILTIN_MASKMOVQ,
IX86_BUILTIN_MOVMSKPS,
IX86_BUILTIN_PMOVMSKB,
IX86_BUILTIN_MOVNTPS,
IX86_BUILTIN_MOVNTQ,
IX86_BUILTIN_PACKSSWB,
IX86_BUILTIN_PACKSSDW,
IX86_BUILTIN_PACKUSWB,
IX86_BUILTIN_PADDB,
IX86_BUILTIN_PADDW,
IX86_BUILTIN_PADDD,
IX86_BUILTIN_PADDSB,
IX86_BUILTIN_PADDSW,
IX86_BUILTIN_PADDUSB,
IX86_BUILTIN_PADDUSW,
IX86_BUILTIN_PSUBB,
IX86_BUILTIN_PSUBW,
IX86_BUILTIN_PSUBD,
IX86_BUILTIN_PSUBSB,
IX86_BUILTIN_PSUBSW,
IX86_BUILTIN_PSUBUSB,
IX86_BUILTIN_PSUBUSW,
IX86_BUILTIN_PAND,
IX86_BUILTIN_PANDN,
IX86_BUILTIN_POR,
IX86_BUILTIN_PXOR,
IX86_BUILTIN_PAVGB,
IX86_BUILTIN_PAVGW,
IX86_BUILTIN_PCMPEQB,
IX86_BUILTIN_PCMPEQW,
IX86_BUILTIN_PCMPEQD,
IX86_BUILTIN_PCMPGTB,
IX86_BUILTIN_PCMPGTW,
IX86_BUILTIN_PCMPGTD,
IX86_BUILTIN_PEXTRW,
IX86_BUILTIN_PINSRW,
IX86_BUILTIN_PMADDWD,
IX86_BUILTIN_PMAXSW,
IX86_BUILTIN_PMAXUB,
IX86_BUILTIN_PMINSW,
IX86_BUILTIN_PMINUB,
IX86_BUILTIN_PMULHUW,
IX86_BUILTIN_PMULHW,
IX86_BUILTIN_PMULLW,
IX86_BUILTIN_PSADBW,
IX86_BUILTIN_PSHUFW,
IX86_BUILTIN_PSLLW,
IX86_BUILTIN_PSLLD,
IX86_BUILTIN_PSLLQ,
IX86_BUILTIN_PSRAW,
IX86_BUILTIN_PSRAD,
IX86_BUILTIN_PSRLW,
IX86_BUILTIN_PSRLD,
IX86_BUILTIN_PSRLQ,
IX86_BUILTIN_PSLLWI,
IX86_BUILTIN_PSLLDI,
IX86_BUILTIN_PSLLQI,
IX86_BUILTIN_PSRAWI,
IX86_BUILTIN_PSRADI,
IX86_BUILTIN_PSRLWI,
IX86_BUILTIN_PSRLDI,
IX86_BUILTIN_PSRLQI,
IX86_BUILTIN_PUNPCKHBW,
IX86_BUILTIN_PUNPCKHWD,
IX86_BUILTIN_PUNPCKHDQ,
IX86_BUILTIN_PUNPCKLBW,
IX86_BUILTIN_PUNPCKLWD,
IX86_BUILTIN_PUNPCKLDQ,
IX86_BUILTIN_SHUFPS,
IX86_BUILTIN_RCPPS,
IX86_BUILTIN_RCPSS,
IX86_BUILTIN_RSQRTPS,
IX86_BUILTIN_RSQRTSS,
IX86_BUILTIN_SQRTPS,
IX86_BUILTIN_SQRTSS,
IX86_BUILTIN_UNPCKHPS,
IX86_BUILTIN_UNPCKLPS,
IX86_BUILTIN_ANDPS,
IX86_BUILTIN_ANDNPS,
IX86_BUILTIN_ORPS,
IX86_BUILTIN_XORPS,
IX86_BUILTIN_EMMS,
IX86_BUILTIN_LDMXCSR,
IX86_BUILTIN_STMXCSR,
IX86_BUILTIN_SFENCE,
/* 3DNow! Original */
IX86_BUILTIN_FEMMS,
IX86_BUILTIN_PAVGUSB,
IX86_BUILTIN_PF2ID,
IX86_BUILTIN_PFACC,
IX86_BUILTIN_PFADD,
IX86_BUILTIN_PFCMPEQ,
IX86_BUILTIN_PFCMPGE,
IX86_BUILTIN_PFCMPGT,
IX86_BUILTIN_PFMAX,
IX86_BUILTIN_PFMIN,
IX86_BUILTIN_PFMUL,
IX86_BUILTIN_PFRCP,
IX86_BUILTIN_PFRCPIT1,
IX86_BUILTIN_PFRCPIT2,
IX86_BUILTIN_PFRSQIT1,
IX86_BUILTIN_PFRSQRT,
IX86_BUILTIN_PFSUB,
IX86_BUILTIN_PFSUBR,
IX86_BUILTIN_PI2FD,
IX86_BUILTIN_PMULHRW,
/* 3DNow! Athlon Extensions */
IX86_BUILTIN_PF2IW,
IX86_BUILTIN_PFNACC,
IX86_BUILTIN_PFPNACC,
IX86_BUILTIN_PI2FW,
IX86_BUILTIN_PSWAPDSI,
IX86_BUILTIN_PSWAPDSF,
IX86_BUILTIN_SSE_ZERO,
IX86_BUILTIN_MMX_ZERO,
/* SSE2 */
IX86_BUILTIN_ADDPD,
IX86_BUILTIN_ADDSD,
IX86_BUILTIN_DIVPD,
IX86_BUILTIN_DIVSD,
IX86_BUILTIN_MULPD,
IX86_BUILTIN_MULSD,
IX86_BUILTIN_SUBPD,
IX86_BUILTIN_SUBSD,
IX86_BUILTIN_CMPEQPD,
IX86_BUILTIN_CMPLTPD,
IX86_BUILTIN_CMPLEPD,
IX86_BUILTIN_CMPGTPD,
IX86_BUILTIN_CMPGEPD,
IX86_BUILTIN_CMPNEQPD,
IX86_BUILTIN_CMPNLTPD,
IX86_BUILTIN_CMPNLEPD,
IX86_BUILTIN_CMPNGTPD,
IX86_BUILTIN_CMPNGEPD,
IX86_BUILTIN_CMPORDPD,
IX86_BUILTIN_CMPUNORDPD,
IX86_BUILTIN_CMPNEPD,
IX86_BUILTIN_CMPEQSD,
IX86_BUILTIN_CMPLTSD,
IX86_BUILTIN_CMPLESD,
IX86_BUILTIN_CMPNEQSD,
IX86_BUILTIN_CMPNLTSD,
IX86_BUILTIN_CMPNLESD,
IX86_BUILTIN_CMPORDSD,
IX86_BUILTIN_CMPUNORDSD,
IX86_BUILTIN_CMPNESD,
IX86_BUILTIN_COMIEQSD,
IX86_BUILTIN_COMILTSD,
IX86_BUILTIN_COMILESD,
IX86_BUILTIN_COMIGTSD,
IX86_BUILTIN_COMIGESD,
IX86_BUILTIN_COMINEQSD,
IX86_BUILTIN_UCOMIEQSD,
IX86_BUILTIN_UCOMILTSD,
IX86_BUILTIN_UCOMILESD,
IX86_BUILTIN_UCOMIGTSD,
IX86_BUILTIN_UCOMIGESD,
IX86_BUILTIN_UCOMINEQSD,
IX86_BUILTIN_MAXPD,
IX86_BUILTIN_MAXSD,
IX86_BUILTIN_MINPD,
IX86_BUILTIN_MINSD,
IX86_BUILTIN_ANDPD,
IX86_BUILTIN_ANDNPD,
IX86_BUILTIN_ORPD,
IX86_BUILTIN_XORPD,
IX86_BUILTIN_SQRTPD,
IX86_BUILTIN_SQRTSD,
IX86_BUILTIN_UNPCKHPD,
IX86_BUILTIN_UNPCKLPD,
IX86_BUILTIN_SHUFPD,
IX86_BUILTIN_LOADAPD,
IX86_BUILTIN_LOADUPD,
IX86_BUILTIN_STOREAPD,
IX86_BUILTIN_STOREUPD,
IX86_BUILTIN_LOADSD,
IX86_BUILTIN_STORESD,
IX86_BUILTIN_MOVSD,
IX86_BUILTIN_LOADHPD,
IX86_BUILTIN_LOADLPD,
IX86_BUILTIN_STOREHPD,
IX86_BUILTIN_STORELPD,
IX86_BUILTIN_CVTDQ2PD,
IX86_BUILTIN_CVTDQ2PS,
IX86_BUILTIN_CVTPD2DQ,
IX86_BUILTIN_CVTPD2PI,
IX86_BUILTIN_CVTPD2PS,
IX86_BUILTIN_CVTTPD2DQ,
IX86_BUILTIN_CVTTPD2PI,
IX86_BUILTIN_CVTPI2PD,
IX86_BUILTIN_CVTSI2SD,
IX86_BUILTIN_CVTSD2SI,
IX86_BUILTIN_CVTSD2SS,
IX86_BUILTIN_CVTSS2SD,
IX86_BUILTIN_CVTTSD2SI,
IX86_BUILTIN_CVTPS2DQ,
IX86_BUILTIN_CVTPS2PD,
IX86_BUILTIN_CVTTPS2DQ,
IX86_BUILTIN_MOVNTI,
IX86_BUILTIN_MOVNTPD,
IX86_BUILTIN_MOVNTDQ,
IX86_BUILTIN_SETPD1,
IX86_BUILTIN_SETPD,
IX86_BUILTIN_CLRPD,
IX86_BUILTIN_SETRPD,
IX86_BUILTIN_LOADPD1,
IX86_BUILTIN_LOADRPD,
IX86_BUILTIN_STOREPD1,
IX86_BUILTIN_STORERPD,
/* SSE2 MMX */
IX86_BUILTIN_MASKMOVDQU,
IX86_BUILTIN_MOVMSKPD,
IX86_BUILTIN_PMOVMSKB128,
IX86_BUILTIN_MOVQ2DQ,
IX86_BUILTIN_PACKSSWB128,
IX86_BUILTIN_PACKSSDW128,
IX86_BUILTIN_PACKUSWB128,
IX86_BUILTIN_PADDB128,
IX86_BUILTIN_PADDW128,
IX86_BUILTIN_PADDD128,
IX86_BUILTIN_PADDQ128,
IX86_BUILTIN_PADDSB128,
IX86_BUILTIN_PADDSW128,
IX86_BUILTIN_PADDUSB128,
IX86_BUILTIN_PADDUSW128,
IX86_BUILTIN_PSUBB128,
IX86_BUILTIN_PSUBW128,
IX86_BUILTIN_PSUBD128,
IX86_BUILTIN_PSUBQ128,
IX86_BUILTIN_PSUBSB128,
IX86_BUILTIN_PSUBSW128,
IX86_BUILTIN_PSUBUSB128,
IX86_BUILTIN_PSUBUSW128,
IX86_BUILTIN_PAND128,
IX86_BUILTIN_PANDN128,
IX86_BUILTIN_POR128,
IX86_BUILTIN_PXOR128,
IX86_BUILTIN_PAVGB128,
IX86_BUILTIN_PAVGW128,
IX86_BUILTIN_PCMPEQB128,
IX86_BUILTIN_PCMPEQW128,
IX86_BUILTIN_PCMPEQD128,
IX86_BUILTIN_PCMPGTB128,
IX86_BUILTIN_PCMPGTW128,
IX86_BUILTIN_PCMPGTD128,
IX86_BUILTIN_PEXTRW128,
IX86_BUILTIN_PINSRW128,
IX86_BUILTIN_PMADDWD128,
IX86_BUILTIN_PMAXSW128,
IX86_BUILTIN_PMAXUB128,
IX86_BUILTIN_PMINSW128,
IX86_BUILTIN_PMINUB128,
IX86_BUILTIN_PMULUDQ,
IX86_BUILTIN_PMULUDQ128,
IX86_BUILTIN_PMULHUW128,
IX86_BUILTIN_PMULHW128,
IX86_BUILTIN_PMULLW128,
IX86_BUILTIN_PSADBW128,
IX86_BUILTIN_PSHUFHW,
IX86_BUILTIN_PSHUFLW,
IX86_BUILTIN_PSHUFD,
IX86_BUILTIN_PSLLW128,
IX86_BUILTIN_PSLLD128,
IX86_BUILTIN_PSLLQ128,
IX86_BUILTIN_PSRAW128,
IX86_BUILTIN_PSRAD128,
IX86_BUILTIN_PSRLW128,
IX86_BUILTIN_PSRLD128,
IX86_BUILTIN_PSRLQ128,
IX86_BUILTIN_PSLLWI128,
IX86_BUILTIN_PSLLDI128,
IX86_BUILTIN_PSLLQI128,
IX86_BUILTIN_PSRAWI128,
IX86_BUILTIN_PSRADI128,
IX86_BUILTIN_PSRLWI128,
IX86_BUILTIN_PSRLDI128,
IX86_BUILTIN_PSRLQI128,
IX86_BUILTIN_PUNPCKHBW128,
IX86_BUILTIN_PUNPCKHWD128,
IX86_BUILTIN_PUNPCKHDQ128,
IX86_BUILTIN_PUNPCKLBW128,
IX86_BUILTIN_PUNPCKLWD128,
IX86_BUILTIN_PUNPCKLDQ128,
IX86_BUILTIN_CLFLUSH,
IX86_BUILTIN_MFENCE,
IX86_BUILTIN_LFENCE,
IX86_BUILTIN_MAX
};
#define TARGET_ENCODE_SECTION_INFO ix86_encode_section_info
#define TARGET_STRIP_NAME_ENCODING ix86_strip_name_encoding
#define ASM_OUTPUT_LABELREF(FILE,NAME) \
do { \
const char *xname = (NAME); \
if (xname[0] == '%') \
xname += 2; \
if (xname[0] == '*') \
xname += 1; \
else \
fputs (user_label_prefix, FILE); \
fputs (xname, FILE); \
} while (0)
/* Max number of args passed in registers. If this is more than 3, we will
have problems with ebx (register #4), since it is a caller save register and
is also used as the pic register in ELF. So for now, don't allow more than
3 registers to be passed in registers. */
#define REGPARM_MAX (TARGET_64BIT ? 6 : 3)
#define SSE_REGPARM_MAX (TARGET_64BIT ? 8 : 0)
/* Specify the machine mode that this machine uses
for the index in the tablejump instruction. */
#define CASE_VECTOR_MODE (!TARGET_64BIT || flag_pic ? SImode : DImode)
/* Define as C expression which evaluates to nonzero if the tablejump
instruction expects the table to contain offsets from the address of the
table.
Do not define this if the table should contain absolute addresses. */
/* #define CASE_VECTOR_PC_RELATIVE 1 */
/* Define this as 1 if `char' should by default be signed; else as 0. */
#define DEFAULT_SIGNED_CHAR 1
/* Number of bytes moved into a data cache for a single prefetch operation. */
#define PREFETCH_BLOCK ix86_cost->prefetch_block
/* Number of prefetch operations that can be done in parallel. */
#define SIMULTANEOUS_PREFETCHES ix86_cost->simultaneous_prefetches
/* Max number of bytes we can move from memory to memory
in one reasonably fast instruction. */
#define MOVE_MAX 16
/* MOVE_MAX_PIECES is the number of bytes at a time which we can
move efficiently, as opposed to MOVE_MAX which is the maximum
number of bytes we can move with a single instruction. */
#define MOVE_MAX_PIECES (TARGET_64BIT ? 8 : 4)
/* If a memory-to-memory move would take MOVE_RATIO or more simple
move-instruction pairs, we will do a movstr or libcall instead.
Increasing the value will always make code faster, but eventually
incurs high cost in increased code size.
If you don't define this, a reasonable default is used. */
#define MOVE_RATIO (optimize_size ? 3 : ix86_cost->move_ratio)
/* Define if shifts truncate the shift count
which implies one can omit a sign-extension or zero-extension
of a shift count. */
/* On i386, shifts do truncate the count. But bit opcodes don't. */
/* #define SHIFT_COUNT_TRUNCATED */
/* Value is 1 if truncating an integer of INPREC bits to OUTPREC bits
is done just by pretending it is already truncated. */
#define TRULY_NOOP_TRUNCATION(OUTPREC, INPREC) 1
/* We assume that the store-condition-codes instructions store 0 for false
and some other value for true. This is the value stored for true. */
#define STORE_FLAG_VALUE 1
/* When a prototype says `char' or `short', really pass an `int'.
(The 386 can't easily push less than an int.) */
#define PROMOTE_PROTOTYPES 1
/* A macro to update M and UNSIGNEDP when an object whose type is
TYPE and which has the specified mode and signedness is to be
stored in a register. This macro is only called when TYPE is a
scalar type.
On i386 it is sometimes useful to promote HImode and QImode
quantities to SImode. The choice depends on target type. */
#define PROMOTE_MODE(MODE, UNSIGNEDP, TYPE) \
do { \
if (((MODE) == HImode && TARGET_PROMOTE_HI_REGS) \
|| ((MODE) == QImode && TARGET_PROMOTE_QI_REGS)) \
(MODE) = SImode; \
} while (0)
/* Specify the machine mode that pointers have.
After generation of rtl, the compiler makes no further distinction
between pointers and any other objects of this machine mode. */
#define Pmode (TARGET_64BIT ? DImode : SImode)
/* A function address in a call instruction
is a byte address (for indexing purposes)
so give the MEM rtx a byte's mode. */
#define FUNCTION_MODE QImode
/* A part of a C `switch' statement that describes the relative costs
of constant RTL expressions. It must contain `case' labels for
expression codes `const_int', `const', `symbol_ref', `label_ref'
and `const_double'. Each case must ultimately reach a `return'
statement to return the relative cost of the use of that kind of
constant value in an expression. The cost may depend on the
precise value of the constant, which is available for examination
in X, and the rtx code of the expression in which it is contained,
found in OUTER_CODE.
CODE is the expression code--redundant, since it can be obtained
with `GET_CODE (X)'. */
#define CONST_COSTS(RTX, CODE, OUTER_CODE) \
case CONST_INT: \
case CONST: \
case LABEL_REF: \
case SYMBOL_REF: \
if (TARGET_64BIT && !x86_64_sign_extended_value (RTX)) \
return 3; \
if (TARGET_64BIT && !x86_64_zero_extended_value (RTX)) \
return 2; \
return flag_pic && SYMBOLIC_CONST (RTX) ? 1 : 0; \
\
case CONST_DOUBLE: \
if (GET_MODE (RTX) == VOIDmode) \
return 0; \
switch (standard_80387_constant_p (RTX)) \
{ \
case 1: /* 0.0 */ \
return 1; \
case 2: /* 1.0 */ \
return 2; \
default: \
/* Start with (MEM (SYMBOL_REF)), since that's where \
it'll probably end up. Add a penalty for size. */ \
return (COSTS_N_INSNS (1) + (flag_pic != 0) \
+ (GET_MODE (RTX) == SFmode ? 0 \
: GET_MODE (RTX) == DFmode ? 1 : 2)); \
}
/* Delete the definition here when TOPLEVEL_COSTS_N_INSNS gets added to cse.c */
#define TOPLEVEL_COSTS_N_INSNS(N) \
do { total = COSTS_N_INSNS (N); goto egress_rtx_costs; } while (0)
/* Like `CONST_COSTS' but applies to nonconstant RTL expressions.
This can be used, for example, to indicate how costly a multiply
instruction is. In writing this macro, you can use the construct
`COSTS_N_INSNS (N)' to specify a cost equal to N fast
instructions. OUTER_CODE is the code of the expression in which X
is contained.
This macro is optional; do not define it if the default cost
assumptions are adequate for the target machine. */
#define RTX_COSTS(X, CODE, OUTER_CODE) \
case ZERO_EXTEND: \
/* The zero extensions is often completely free on x86_64, so make \
it as cheap as possible. */ \
if (TARGET_64BIT && GET_MODE (X) == DImode \
&& GET_MODE (XEXP (X, 0)) == SImode) \
{ \
total = 1; goto egress_rtx_costs; \
} \
else \
TOPLEVEL_COSTS_N_INSNS (TARGET_ZERO_EXTEND_WITH_AND ? \
ix86_cost->add : ix86_cost->movzx); \
break; \
case SIGN_EXTEND: \
TOPLEVEL_COSTS_N_INSNS (ix86_cost->movsx); \
break; \
case ASHIFT: \
if (GET_CODE (XEXP (X, 1)) == CONST_INT \
&& (GET_MODE (XEXP (X, 0)) != DImode || TARGET_64BIT)) \
{ \
HOST_WIDE_INT value = INTVAL (XEXP (X, 1)); \
if (value == 1) \
TOPLEVEL_COSTS_N_INSNS (ix86_cost->add); \
if ((value == 2 || value == 3) \
&& !TARGET_DECOMPOSE_LEA \
&& ix86_cost->lea <= ix86_cost->shift_const) \
TOPLEVEL_COSTS_N_INSNS (ix86_cost->lea); \
} \
/* fall through */ \
\
case ROTATE: \
case ASHIFTRT: \
case LSHIFTRT: \
case ROTATERT: \
if (!TARGET_64BIT && GET_MODE (XEXP (X, 0)) == DImode) \
{ \
if (GET_CODE (XEXP (X, 1)) == CONST_INT) \
{ \
if (INTVAL (XEXP (X, 1)) > 32) \
TOPLEVEL_COSTS_N_INSNS(ix86_cost->shift_const + 2); \
else \
TOPLEVEL_COSTS_N_INSNS(ix86_cost->shift_const * 2); \
} \
else \
{ \
if (GET_CODE (XEXP (X, 1)) == AND) \
TOPLEVEL_COSTS_N_INSNS(ix86_cost->shift_var * 2); \
else \
TOPLEVEL_COSTS_N_INSNS(ix86_cost->shift_var * 6 + 2); \
} \
} \
else \
{ \
if (GET_CODE (XEXP (X, 1)) == CONST_INT) \
TOPLEVEL_COSTS_N_INSNS (ix86_cost->shift_const); \
else \
TOPLEVEL_COSTS_N_INSNS (ix86_cost->shift_var); \
} \
break; \
\
case MULT: \
if (FLOAT_MODE_P (GET_MODE (X))) \
TOPLEVEL_COSTS_N_INSNS (ix86_cost->fmul); \
else if (GET_CODE (XEXP (X, 1)) == CONST_INT) \
{ \
unsigned HOST_WIDE_INT value = INTVAL (XEXP (X, 1)); \
int nbits = 0; \
\
while (value != 0) \
{ \
nbits++; \
value >>= 1; \
} \
\
TOPLEVEL_COSTS_N_INSNS (ix86_cost->mult_init \
+ nbits * ix86_cost->mult_bit); \
} \
else /* This is arbitrary */ \
TOPLEVEL_COSTS_N_INSNS (ix86_cost->mult_init \
+ 7 * ix86_cost->mult_bit); \
\
case DIV: \
case UDIV: \
case MOD: \
case UMOD: \
if (FLOAT_MODE_P (GET_MODE (X))) \
TOPLEVEL_COSTS_N_INSNS (ix86_cost->fdiv); \
else \
TOPLEVEL_COSTS_N_INSNS (ix86_cost->divide); \
break; \
\
case PLUS: \
if (FLOAT_MODE_P (GET_MODE (X))) \
TOPLEVEL_COSTS_N_INSNS (ix86_cost->fadd); \
else if (!TARGET_DECOMPOSE_LEA \
&& INTEGRAL_MODE_P (GET_MODE (X)) \
&& GET_MODE_BITSIZE (GET_MODE (X)) <= GET_MODE_BITSIZE (Pmode)) \
{ \
if (GET_CODE (XEXP (X, 0)) == PLUS \
&& GET_CODE (XEXP (XEXP (X, 0), 0)) == MULT \
&& GET_CODE (XEXP (XEXP (XEXP (X, 0), 0), 1)) == CONST_INT \
&& CONSTANT_P (XEXP (X, 1))) \
{ \
HOST_WIDE_INT val = INTVAL (XEXP (XEXP (XEXP (X, 0), 0), 1));\
if (val == 2 || val == 4 || val == 8) \
{ \
return (COSTS_N_INSNS (ix86_cost->lea) \
+ rtx_cost (XEXP (XEXP (X, 0), 1), \
(OUTER_CODE)) \
+ rtx_cost (XEXP (XEXP (XEXP (X, 0), 0), 0), \
(OUTER_CODE)) \
+ rtx_cost (XEXP (X, 1), (OUTER_CODE))); \
} \
} \
else if (GET_CODE (XEXP (X, 0)) == MULT \
&& GET_CODE (XEXP (XEXP (X, 0), 1)) == CONST_INT) \
{ \
HOST_WIDE_INT val = INTVAL (XEXP (XEXP (X, 0), 1)); \
if (val == 2 || val == 4 || val == 8) \
{ \
return (COSTS_N_INSNS (ix86_cost->lea) \
+ rtx_cost (XEXP (XEXP (X, 0), 0), \
(OUTER_CODE)) \
+ rtx_cost (XEXP (X, 1), (OUTER_CODE))); \
} \
} \
else if (GET_CODE (XEXP (X, 0)) == PLUS) \
{ \
return (COSTS_N_INSNS (ix86_cost->lea) \
+ rtx_cost (XEXP (XEXP (X, 0), 0), (OUTER_CODE)) \
+ rtx_cost (XEXP (XEXP (X, 0), 1), (OUTER_CODE)) \
+ rtx_cost (XEXP (X, 1), (OUTER_CODE))); \
} \
} \
/* fall through */ \
\
case MINUS: \
if (FLOAT_MODE_P (GET_MODE (X))) \
TOPLEVEL_COSTS_N_INSNS (ix86_cost->fadd); \
/* fall through */ \
\
case AND: \
case IOR: \
case XOR: \
if (!TARGET_64BIT && GET_MODE (X) == DImode) \
return (COSTS_N_INSNS (ix86_cost->add) * 2 \
+ (rtx_cost (XEXP (X, 0), (OUTER_CODE)) \
<< (GET_MODE (XEXP (X, 0)) != DImode)) \
+ (rtx_cost (XEXP (X, 1), (OUTER_CODE)) \
<< (GET_MODE (XEXP (X, 1)) != DImode))); \
/* fall through */ \
\
case NEG: \
if (FLOAT_MODE_P (GET_MODE (X))) \
TOPLEVEL_COSTS_N_INSNS (ix86_cost->fchs); \
/* fall through */ \
\
case NOT: \
if (!TARGET_64BIT && GET_MODE (X) == DImode) \
TOPLEVEL_COSTS_N_INSNS (ix86_cost->add * 2); \
TOPLEVEL_COSTS_N_INSNS (ix86_cost->add); \
\
case FLOAT_EXTEND: \
if (!TARGET_SSE_MATH \
|| !VALID_SSE_REG_MODE (GET_MODE (X))) \
TOPLEVEL_COSTS_N_INSNS (0); \
break; \
\
case ABS: \
if (FLOAT_MODE_P (GET_MODE (X))) \
TOPLEVEL_COSTS_N_INSNS (ix86_cost->fabs); \
break; \
\
case SQRT: \
if (FLOAT_MODE_P (GET_MODE (X))) \
TOPLEVEL_COSTS_N_INSNS (ix86_cost->fsqrt); \
break; \
\
egress_rtx_costs: \
break;
/* An expression giving the cost of an addressing mode that contains
ADDRESS. If not defined, the cost is computed from the ADDRESS
expression and the `CONST_COSTS' values.
For most CISC machines, the default cost is a good approximation
of the true cost of the addressing mode. However, on RISC
machines, all instructions normally have the same length and
execution time. Hence all addresses will have equal costs.
In cases where more than one form of an address is known, the form
with the lowest cost will be used. If multiple forms have the
same, lowest, cost, the one that is the most complex will be used.
For example, suppose an address that is equal to the sum of a
register and a constant is used twice in the same basic block.
When this macro is not defined, the address will be computed in a
register and memory references will be indirect through that
register. On machines where the cost of the addressing mode
containing the sum is no higher than that of a simple indirect
reference, this will produce an additional instruction and
possibly require an additional register. Proper specification of
this macro eliminates this overhead for such machines.
Similar use of this macro is made in strength reduction of loops.
ADDRESS need not be valid as an address. In such a case, the cost
is not relevant and can be any value; invalid addresses need not be
assigned a different cost.
On machines where an address involving more than one register is as
cheap as an address computation involving only one register,
defining `ADDRESS_COST' to reflect this can cause two registers to
be live over a region of code where only one would have been if
`ADDRESS_COST' were not defined in that manner. This effect should
be considered in the definition of this macro. Equivalent costs
should probably only be given to addresses with different numbers
of registers on machines with lots of registers.
This macro will normally either not be defined or be defined as a
constant.
For i386, it is better to use a complex address than let gcc copy
the address into a reg and make a new pseudo. But not if the address
requires to two regs - that would mean more pseudos with longer
lifetimes. */
#define ADDRESS_COST(RTX) \
ix86_address_cost (RTX)
/* A C expression for the cost of moving data from a register in class FROM to
one in class TO. The classes are expressed using the enumeration values
such as `GENERAL_REGS'. A value of 2 is the default; other values are
interpreted relative to that.
It is not required that the cost always equal 2 when FROM is the same as TO;
on some machines it is expensive to move between registers if they are not
general registers. */
#define REGISTER_MOVE_COST(MODE, CLASS1, CLASS2) \
ix86_register_move_cost ((MODE), (CLASS1), (CLASS2))
/* A C expression for the cost of moving data of mode M between a
register and memory. A value of 2 is the default; this cost is
relative to those in `REGISTER_MOVE_COST'.
If moving between registers and memory is more expensive than
between two registers, you should define this macro to express the
relative cost. */
#define MEMORY_MOVE_COST(MODE, CLASS, IN) \
ix86_memory_move_cost ((MODE), (CLASS), (IN))
/* A C expression for the cost of a branch instruction. A value of 1
is the default; other values are interpreted relative to that. */
#define BRANCH_COST ix86_branch_cost
/* Define this macro as a C expression which is nonzero if accessing
less than a word of memory (i.e. a `char' or a `short') is no
faster than accessing a word of memory, i.e., if such access
require more than one instruction or if there is no difference in
cost between byte and (aligned) word loads.
When this macro is not defined, the compiler will access a field by
finding the smallest containing object; when it is defined, a
fullword load will be used if alignment permits. Unless bytes
accesses are faster than word accesses, using word accesses is
preferable since it may eliminate subsequent memory access if
subsequent accesses occur to other fields in the same word of the
structure, but to different bytes. */
#define SLOW_BYTE_ACCESS 0
/* Nonzero if access to memory by shorts is slow and undesirable. */
#define SLOW_SHORT_ACCESS 0
/* Define this macro to be the value 1 if unaligned accesses have a
cost many times greater than aligned accesses, for example if they
are emulated in a trap handler.
When this macro is nonzero, the compiler will act as if
`STRICT_ALIGNMENT' were nonzero when generating code for block
moves. This can cause significantly more instructions to be
produced. Therefore, do not set this macro nonzero if unaligned
accesses only add a cycle or two to the time for a memory access.
If the value of this macro is always zero, it need not be defined. */
/* #define SLOW_UNALIGNED_ACCESS(MODE, ALIGN) 0 */
/* Define this macro to inhibit strength reduction of memory
addresses. (On some machines, such strength reduction seems to do
harm rather than good.) */
/* #define DONT_REDUCE_ADDR */
/* Define this macro if it is as good or better to call a constant
function address than to call an address kept in a register.
Desirable on the 386 because a CALL with a constant address is
faster than one with a register address. */
#define NO_FUNCTION_CSE
/* Define this macro if it is as good or better for a function to call
itself with an explicit address than to call an address kept in a
register. */
#define NO_RECURSIVE_FUNCTION_CSE
/* Given a comparison code (EQ, NE, etc.) and the first operand of a COMPARE,
return the mode to be used for the comparison.
For floating-point equality comparisons, CCFPEQmode should be used.
VOIDmode should be used in all other cases.
For integer comparisons against zero, reduce to CCNOmode or CCZmode if
possible, to allow for more combinations. */
#define SELECT_CC_MODE(OP, X, Y) ix86_cc_mode ((OP), (X), (Y))
/* Return nonzero if MODE implies a floating point inequality can be
reversed. */
#define REVERSIBLE_CC_MODE(MODE) 1
/* A C expression whose value is reversed condition code of the CODE for
comparison done in CC_MODE mode. */
#define REVERSE_CONDITION(CODE, MODE) \
((MODE) != CCFPmode && (MODE) != CCFPUmode ? reverse_condition (CODE) \
: reverse_condition_maybe_unordered (CODE))
/* Control the assembler format that we output, to the extent
this does not vary between assemblers. */
/* How to refer to registers in assembler output.
This sequence is indexed by compiler's hard-register-number (see above). */
/* In order to refer to the first 8 regs as 32 bit regs prefix an "e"
For non floating point regs, the following are the HImode names.
For float regs, the stack top is sometimes referred to as "%st(0)"
instead of just "%st". PRINT_REG handles this with the "y" code. */
#undef HI_REGISTER_NAMES
#define HI_REGISTER_NAMES \
{"ax","dx","cx","bx","si","di","bp","sp", \
"st","st(1)","st(2)","st(3)","st(4)","st(5)","st(6)","st(7)","", \
"flags","fpsr", "dirflag", "frame", \
"xmm0","xmm1","xmm2","xmm3","xmm4","xmm5","xmm6","xmm7", \
"mm0", "mm1", "mm2", "mm3", "mm4", "mm5", "mm6", "mm7" , \
"r8", "r9", "r10", "r11", "r12", "r13", "r14", "r15", \
"xmm8", "xmm9", "xmm10", "xmm11", "xmm12", "xmm13", "xmm14", "xmm15"}
#define REGISTER_NAMES HI_REGISTER_NAMES
/* Table of additional register names to use in user input. */
#define ADDITIONAL_REGISTER_NAMES \
{ { "eax", 0 }, { "edx", 1 }, { "ecx", 2 }, { "ebx", 3 }, \
{ "esi", 4 }, { "edi", 5 }, { "ebp", 6 }, { "esp", 7 }, \
{ "rax", 0 }, { "rdx", 1 }, { "rcx", 2 }, { "rbx", 3 }, \
{ "rsi", 4 }, { "rdi", 5 }, { "rbp", 6 }, { "rsp", 7 }, \
{ "al", 0 }, { "dl", 1 }, { "cl", 2 }, { "bl", 3 }, \
{ "ah", 0 }, { "dh", 1 }, { "ch", 2 }, { "bh", 3 }, \
{ "mm0", 8}, { "mm1", 9}, { "mm2", 10}, { "mm3", 11}, \
{ "mm4", 12}, { "mm5", 13}, { "mm6", 14}, { "mm7", 15} }
/* Note we are omitting these since currently I don't know how
to get gcc to use these, since they want the same but different
number as al, and ax.
*/
#define QI_REGISTER_NAMES \
{"al", "dl", "cl", "bl", "sil", "dil", "bpl", "spl",}
/* These parallel the array above, and can be used to access bits 8:15
of regs 0 through 3. */
#define QI_HIGH_REGISTER_NAMES \
{"ah", "dh", "ch", "bh", }
/* How to renumber registers for dbx and gdb. */
#define DBX_REGISTER_NUMBER(N) \
(TARGET_64BIT ? dbx64_register_map[(N)] : dbx_register_map[(N)])
extern int const dbx_register_map[FIRST_PSEUDO_REGISTER];
extern int const dbx64_register_map[FIRST_PSEUDO_REGISTER];
extern int const svr4_dbx_register_map[FIRST_PSEUDO_REGISTER];
/* Before the prologue, RA is at 0(%esp). */
#define INCOMING_RETURN_ADDR_RTX \
gen_rtx_MEM (VOIDmode, gen_rtx_REG (VOIDmode, STACK_POINTER_REGNUM))
/* After the prologue, RA is at -4(AP) in the current frame. */
#define RETURN_ADDR_RTX(COUNT, FRAME) \
((COUNT) == 0 \
? gen_rtx_MEM (Pmode, plus_constant (arg_pointer_rtx, -UNITS_PER_WORD)) \
: gen_rtx_MEM (Pmode, plus_constant (FRAME, UNITS_PER_WORD)))
/* PC is dbx register 8; let's use that column for RA. */
#define DWARF_FRAME_RETURN_COLUMN (TARGET_64BIT ? 16 : 8)
/* Before the prologue, the top of the frame is at 4(%esp). */
#define INCOMING_FRAME_SP_OFFSET UNITS_PER_WORD
/* Describe how we implement __builtin_eh_return. */
#define EH_RETURN_DATA_REGNO(N) ((N) < 2 ? (N) : INVALID_REGNUM)
#define EH_RETURN_STACKADJ_RTX gen_rtx_REG (Pmode, 2)
/* Select a format to encode pointers in exception handling data. CODE
is 0 for data, 1 for code labels, 2 for function pointers. GLOBAL is
true if the symbol may be affected by dynamic relocations.
??? All x86 object file formats are capable of representing this.
After all, the relocation needed is the same as for the call insn.
Whether or not a particular assembler allows us to enter such, I
guess we'll have to see. */
#define ASM_PREFERRED_EH_DATA_FORMAT(CODE, GLOBAL) \
(flag_pic \
? ((GLOBAL) ? DW_EH_PE_indirect : 0) | DW_EH_PE_pcrel | DW_EH_PE_sdata4\
: DW_EH_PE_absptr)
/* Store in OUTPUT a string (made with alloca) containing
an assembler-name for a local static variable named NAME.
LABELNO is an integer which is different for each call. */
#define ASM_FORMAT_PRIVATE_NAME(OUTPUT, NAME, LABELNO) \
( (OUTPUT) = (char *) alloca (strlen ((NAME)) + 10), \
sprintf ((OUTPUT), "%s.%d", (NAME), (LABELNO)))
/* This is how to output an insn to push a register on the stack.
It need not be very fast code. */
#define ASM_OUTPUT_REG_PUSH(FILE, REGNO) \
do { \
if (TARGET_64BIT) \
asm_fprintf ((FILE), "\tpush{q}\t%%r%s\n", \
reg_names[(REGNO)] + (REX_INT_REGNO_P (REGNO) != 0)); \
else \
asm_fprintf ((FILE), "\tpush{l}\t%%e%s\n", reg_names[(REGNO)]); \
} while (0)
/* This is how to output an insn to pop a register from the stack.
It need not be very fast code. */
#define ASM_OUTPUT_REG_POP(FILE, REGNO) \
do { \
if (TARGET_64BIT) \
asm_fprintf ((FILE), "\tpop{q}\t%%r%s\n", \
reg_names[(REGNO)] + (REX_INT_REGNO_P (REGNO) != 0)); \
else \
asm_fprintf ((FILE), "\tpop{l}\t%%e%s\n", reg_names[(REGNO)]); \
} while (0)
/* This is how to output an element of a case-vector that is absolute. */
#define ASM_OUTPUT_ADDR_VEC_ELT(FILE, VALUE) \
ix86_output_addr_vec_elt ((FILE), (VALUE))
/* This is how to output an element of a case-vector that is relative. */
#define ASM_OUTPUT_ADDR_DIFF_ELT(FILE, BODY, VALUE, REL) \
ix86_output_addr_diff_elt ((FILE), (VALUE), (REL))
/* Under some conditions we need jump tables in the text section, because
the assembler cannot handle label differences between sections. */
#define JUMP_TABLES_IN_TEXT_SECTION \
(!TARGET_64BIT && flag_pic && !HAVE_AS_GOTOFF_IN_DATA)
/* A C statement that outputs an address constant appropriate to
for DWARF debugging. */
#define ASM_OUTPUT_DWARF_ADDR_CONST(FILE, X) \
i386_dwarf_output_addr_const ((FILE), (X))
/* Either simplify a location expression, or return the original. */
#define ASM_SIMPLIFY_DWARF_ADDR(X) \
i386_simplify_dwarf_addr (X)
/* Emit a dtp-relative reference to a TLS variable. */
#ifdef HAVE_AS_TLS
#define ASM_OUTPUT_DWARF_DTPREL(FILE, SIZE, X) \
i386_output_dwarf_dtprel (FILE, SIZE, X)
#endif
/* Switch to init or fini section via SECTION_OP, emit a call to FUNC,
and switch back. For x86 we do this only to save a few bytes that
would otherwise be unused in the text section. */
#define CRT_CALL_STATIC_FUNCTION(SECTION_OP, FUNC) \
asm (SECTION_OP "\n\t" \
"call " USER_LABEL_PREFIX #FUNC "\n" \
TEXT_SECTION_ASM_OP);
/* Print operand X (an rtx) in assembler syntax to file FILE.
CODE is a letter or dot (`z' in `%z0') or 0 if no letter was specified.
Effect of various CODE letters is described in i386.c near
print_operand function. */
#define PRINT_OPERAND_PUNCT_VALID_P(CODE) \
((CODE) == '*' || (CODE) == '+' || (CODE) == '&')
/* Print the name of a register based on its machine mode and number.
If CODE is 'w', pretend the mode is HImode.
If CODE is 'b', pretend the mode is QImode.
If CODE is 'k', pretend the mode is SImode.
If CODE is 'q', pretend the mode is DImode.
If CODE is 'h', pretend the reg is the `high' byte register.
If CODE is 'y', print "st(0)" instead of "st", if the reg is stack op. */
#define PRINT_REG(X, CODE, FILE) \
print_reg ((X), (CODE), (FILE))
#define PRINT_OPERAND(FILE, X, CODE) \
print_operand ((FILE), (X), (CODE))
#define PRINT_OPERAND_ADDRESS(FILE, ADDR) \
print_operand_address ((FILE), (ADDR))
#define OUTPUT_ADDR_CONST_EXTRA(FILE, X, FAIL) \
do { \
if (! output_addr_const_extra (FILE, (X))) \
goto FAIL; \
} while (0);
/* Print the name of a register for based on its machine mode and number.
This macro is used to print debugging output.
This macro is different from PRINT_REG in that it may be used in
programs that are not linked with aux-output.o. */
#define DEBUG_PRINT_REG(X, CODE, FILE) \
do { static const char * const hi_name[] = HI_REGISTER_NAMES; \
static const char * const qi_name[] = QI_REGISTER_NAMES; \
fprintf ((FILE), "%d ", REGNO (X)); \
if (REGNO (X) == FLAGS_REG) \
{ fputs ("flags", (FILE)); break; } \
if (REGNO (X) == DIRFLAG_REG) \
{ fputs ("dirflag", (FILE)); break; } \
if (REGNO (X) == FPSR_REG) \
{ fputs ("fpsr", (FILE)); break; } \
if (REGNO (X) == ARG_POINTER_REGNUM) \
{ fputs ("argp", (FILE)); break; } \
if (REGNO (X) == FRAME_POINTER_REGNUM) \
{ fputs ("frame", (FILE)); break; } \
if (STACK_TOP_P (X)) \
{ fputs ("st(0)", (FILE)); break; } \
if (FP_REG_P (X)) \
{ fputs (hi_name[REGNO(X)], (FILE)); break; } \
if (REX_INT_REG_P (X)) \
{ \
switch (GET_MODE_SIZE (GET_MODE (X))) \
{ \
default: \
case 8: \
fprintf ((FILE), "r%i", REGNO (X) \
- FIRST_REX_INT_REG + 8); \
break; \
case 4: \
fprintf ((FILE), "r%id", REGNO (X) \
- FIRST_REX_INT_REG + 8); \
break; \
case 2: \
fprintf ((FILE), "r%iw", REGNO (X) \
- FIRST_REX_INT_REG + 8); \
break; \
case 1: \
fprintf ((FILE), "r%ib", REGNO (X) \
- FIRST_REX_INT_REG + 8); \
break; \
} \
break; \
} \
switch (GET_MODE_SIZE (GET_MODE (X))) \
{ \
case 8: \
fputs ("r", (FILE)); \
fputs (hi_name[REGNO (X)], (FILE)); \
break; \
default: \
fputs ("e", (FILE)); \
case 2: \
fputs (hi_name[REGNO (X)], (FILE)); \
break; \
case 1: \
fputs (qi_name[REGNO (X)], (FILE)); \
break; \
} \
} while (0)
/* a letter which is not needed by the normal asm syntax, which
we can use for operand syntax in the extended asm */
#define ASM_OPERAND_LETTER '#'
#define RET return ""
#define AT_SP(MODE) (gen_rtx_MEM ((MODE), stack_pointer_rtx))
/* Define the codes that are matched by predicates in i386.c. */
#define PREDICATE_CODES \
{"x86_64_immediate_operand", {CONST_INT, SUBREG, REG, \
SYMBOL_REF, LABEL_REF, CONST}}, \
{"x86_64_nonmemory_operand", {CONST_INT, SUBREG, REG, \
SYMBOL_REF, LABEL_REF, CONST}}, \
{"x86_64_movabs_operand", {CONST_INT, SUBREG, REG, \
SYMBOL_REF, LABEL_REF, CONST}}, \
{"x86_64_szext_nonmemory_operand", {CONST_INT, SUBREG, REG, \
SYMBOL_REF, LABEL_REF, CONST}}, \
{"x86_64_general_operand", {CONST_INT, SUBREG, REG, MEM, \
SYMBOL_REF, LABEL_REF, CONST}}, \
{"x86_64_szext_general_operand", {CONST_INT, SUBREG, REG, MEM, \
SYMBOL_REF, LABEL_REF, CONST}}, \
{"x86_64_zext_immediate_operand", {CONST_INT, CONST_DOUBLE, CONST, \
SYMBOL_REF, LABEL_REF}}, \
{"shiftdi_operand", {SUBREG, REG, MEM}}, \
{"const_int_1_operand", {CONST_INT}}, \
{"const_int_1_31_operand", {CONST_INT}}, \
{"symbolic_operand", {SYMBOL_REF, LABEL_REF, CONST}}, \
{"aligned_operand", {CONST_INT, CONST_DOUBLE, CONST, SYMBOL_REF, \
LABEL_REF, SUBREG, REG, MEM}}, \
{"pic_symbolic_operand", {CONST}}, \
{"call_insn_operand", {REG, SUBREG, MEM, SYMBOL_REF}}, \
{"constant_call_address_operand", {SYMBOL_REF, CONST}}, \
{"const0_operand", {CONST_INT, CONST_DOUBLE}}, \
{"const1_operand", {CONST_INT}}, \
{"const248_operand", {CONST_INT}}, \
{"incdec_operand", {CONST_INT}}, \
{"mmx_reg_operand", {REG}}, \
{"reg_no_sp_operand", {SUBREG, REG}}, \
{"general_no_elim_operand", {CONST_INT, CONST_DOUBLE, CONST, \
SYMBOL_REF, LABEL_REF, SUBREG, REG, MEM}}, \
{"nonmemory_no_elim_operand", {CONST_INT, REG, SUBREG}}, \
{"index_register_operand", {SUBREG, REG}}, \
{"q_regs_operand", {SUBREG, REG}}, \
{"non_q_regs_operand", {SUBREG, REG}}, \
{"fcmov_comparison_operator", {EQ, NE, LTU, GTU, LEU, GEU, UNORDERED, \
ORDERED, LT, UNLT, GT, UNGT, LE, UNLE, \
GE, UNGE, LTGT, UNEQ}}, \
{"sse_comparison_operator", {EQ, LT, LE, UNORDERED, NE, UNGE, UNGT, \
ORDERED, UNEQ, UNLT, UNLE, LTGT, GE, GT \
}}, \
{"ix86_comparison_operator", {EQ, NE, LE, LT, GE, GT, LEU, LTU, GEU, \
GTU, UNORDERED, ORDERED, UNLE, UNLT, \
UNGE, UNGT, LTGT, UNEQ }}, \
{"cmp_fp_expander_operand", {CONST_DOUBLE, SUBREG, REG, MEM}}, \
{"ext_register_operand", {SUBREG, REG}}, \
{"binary_fp_operator", {PLUS, MINUS, MULT, DIV}}, \
{"mult_operator", {MULT}}, \
{"div_operator", {DIV}}, \
{"arith_or_logical_operator", {PLUS, MULT, AND, IOR, XOR, SMIN, SMAX, \
UMIN, UMAX, COMPARE, MINUS, DIV, MOD, \
UDIV, UMOD, ASHIFT, ROTATE, ASHIFTRT, \
LSHIFTRT, ROTATERT}}, \
{"promotable_binary_operator", {PLUS, MULT, AND, IOR, XOR, ASHIFT}}, \
{"memory_displacement_operand", {MEM}}, \
{"cmpsi_operand", {CONST_INT, CONST_DOUBLE, CONST, SYMBOL_REF, \
LABEL_REF, SUBREG, REG, MEM, AND}}, \
{"long_memory_operand", {MEM}}, \
{"tls_symbolic_operand", {SYMBOL_REF}}, \
{"global_dynamic_symbolic_operand", {SYMBOL_REF}}, \
{"local_dynamic_symbolic_operand", {SYMBOL_REF}}, \
{"initial_exec_symbolic_operand", {SYMBOL_REF}}, \
{"local_exec_symbolic_operand", {SYMBOL_REF}}, \
{"any_fp_register_operand", {REG}}, \
{"register_and_not_any_fp_reg_operand", {REG}}, \
{"fp_register_operand", {REG}}, \
{"register_and_not_fp_reg_operand", {REG}}, \
/* A list of predicates that do special things with modes, and so
should not elicit warnings for VOIDmode match_operand. */
#define SPECIAL_MODE_PREDICATES \
"ext_register_operand",
/* Which processor to schedule for. The cpu attribute defines a list that
mirrors this list, so changes to i386.md must be made at the same time. */
enum processor_type
{
PROCESSOR_I386, /* 80386 */
PROCESSOR_I486, /* 80486DX, 80486SX, 80486DX[24] */
PROCESSOR_PENTIUM,
PROCESSOR_PENTIUMPRO,
PROCESSOR_K6,
PROCESSOR_ATHLON,
PROCESSOR_PENTIUM4,
PROCESSOR_max
};
extern enum processor_type ix86_cpu;
extern const char *ix86_cpu_string;
extern enum processor_type ix86_arch;
extern const char *ix86_arch_string;
enum fpmath_unit
{
FPMATH_387 = 1,
FPMATH_SSE = 2
};
extern enum fpmath_unit ix86_fpmath;
extern const char *ix86_fpmath_string;
enum tls_dialect
{
TLS_DIALECT_GNU,
TLS_DIALECT_SUN
};
extern enum tls_dialect ix86_tls_dialect;
extern const char *ix86_tls_dialect_string;
enum cmodel {
CM_32, /* The traditional 32-bit ABI. */
CM_SMALL, /* Assumes all code and data fits in the low 31 bits. */
CM_KERNEL, /* Assumes all code and data fits in the high 31 bits. */
CM_MEDIUM, /* Assumes code fits in the low 31 bits; data unlimited. */
CM_LARGE, /* No assumptions. */
CM_SMALL_PIC /* Assumes code+data+got/plt fits in a 31 bit region. */
};
extern enum cmodel ix86_cmodel;
extern const char *ix86_cmodel_string;
/* Size of the RED_ZONE area. */
#define RED_ZONE_SIZE 128
/* Reserved area of the red zone for temporaries. */
#define RED_ZONE_RESERVE 8
enum asm_dialect {
ASM_ATT,
ASM_INTEL
};
extern const char *ix86_asm_string;
extern enum asm_dialect ix86_asm_dialect;
extern int ix86_regparm;
extern const char *ix86_regparm_string;
extern int ix86_preferred_stack_boundary;
extern const char *ix86_preferred_stack_boundary_string;
extern int ix86_branch_cost;
extern const char *ix86_branch_cost_string;
extern const char *ix86_debug_arg_string;
extern const char *ix86_debug_addr_string;
/* Obsoleted by -f options. Remove before 3.2 ships. */
extern const char *ix86_align_loops_string;
extern const char *ix86_align_jumps_string;
extern const char *ix86_align_funcs_string;
/* Smallest class containing REGNO. */
extern enum reg_class const regclass_map[FIRST_PSEUDO_REGISTER];
extern rtx ix86_compare_op0; /* operand 0 for comparisons */
extern rtx ix86_compare_op1; /* operand 1 for comparisons */
/* To properly truncate FP values into integers, we need to set i387 control
word. We can't emit proper mode switching code before reload, as spills
generated by reload may truncate values incorrectly, but we still can avoid
redundant computation of new control word by the mode switching pass.
The fldcw instructions are still emitted redundantly, but this is probably
not going to be noticeable problem, as most CPUs do have fast path for
the sequence.
The machinery is to emit simple truncation instructions and split them
before reload to instructions having USEs of two memory locations that
are filled by this code to old and new control word.
Post-reload pass may be later used to eliminate the redundant fildcw if
needed. */
enum fp_cw_mode {FP_CW_STORED, FP_CW_UNINITIALIZED, FP_CW_ANY};
/* Define this macro if the port needs extra instructions inserted
for mode switching in an optimizing compilation. */
#define OPTIMIZE_MODE_SWITCHING(ENTITY) 1
/* If you define `OPTIMIZE_MODE_SWITCHING', you have to define this as
initializer for an array of integers. Each initializer element N
refers to an entity that needs mode switching, and specifies the
number of different modes that might need to be set for this
entity. The position of the initializer in the initializer -
starting counting at zero - determines the integer that is used to
refer to the mode-switched entity in question. */
#define NUM_MODES_FOR_MODE_SWITCHING { FP_CW_ANY }
/* ENTITY is an integer specifying a mode-switched entity. If
`OPTIMIZE_MODE_SWITCHING' is defined, you must define this macro to
return an integer value not larger than the corresponding element
in `NUM_MODES_FOR_MODE_SWITCHING', to denote the mode that ENTITY
must be switched into prior to the execution of INSN. */
#define MODE_NEEDED(ENTITY, I) \
(GET_CODE (I) == CALL_INSN \
|| (GET_CODE (I) == INSN && (asm_noperands (PATTERN (I)) >= 0 \
|| GET_CODE (PATTERN (I)) == ASM_INPUT))\
? FP_CW_UNINITIALIZED \
: recog_memoized (I) < 0 || get_attr_type (I) != TYPE_FISTP \
? FP_CW_ANY \
: FP_CW_STORED)
/* This macro specifies the order in which modes for ENTITY are
processed. 0 is the highest priority. */
#define MODE_PRIORITY_TO_MODE(ENTITY, N) (N)
/* Generate one or more insns to set ENTITY to MODE. HARD_REG_LIVE
is the set of hard registers live at the point where the insn(s)
are to be inserted. */
#define EMIT_MODE_SET(ENTITY, MODE, HARD_REGS_LIVE) \
((MODE) == FP_CW_STORED \
? emit_i387_cw_initialization (assign_386_stack_local (HImode, 1), \
assign_386_stack_local (HImode, 2)), 0\
: 0)
/* Avoid renaming of stack registers, as doing so in combination with
scheduling just increases amount of live registers at time and in
the turn amount of fxch instructions needed.
??? Maybe Pentium chips benefits from renaming, someone can try... */
#define HARD_REGNO_RENAME_OK(SRC, TARGET) \
((SRC) < FIRST_STACK_REG || (SRC) > LAST_STACK_REG)
#define MACHINE_DEPENDENT_REORG(X) x86_machine_dependent_reorg(X)
/*
Local variables:
version-control: t
End:
*/
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