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ruby--ruby/include/ruby/ruby.h
nobu 247fdeedf8 * include/ruby/ruby.h (rb_funcall_passing_block): add prototype.
a patch by James M. Lawrence at [ruby-core:35501]

git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@31119 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2011-03-17 15:54:22 +00:00

1477 lines
43 KiB
C

/**********************************************************************
ruby/ruby.h -
$Author$
created at: Thu Jun 10 14:26:32 JST 1993
Copyright (C) 1993-2008 Yukihiro Matsumoto
Copyright (C) 2000 Network Applied Communication Laboratory, Inc.
Copyright (C) 2000 Information-technology Promotion Agency, Japan
**********************************************************************/
#ifndef RUBY_RUBY_H
#define RUBY_RUBY_H 1
#if defined(__cplusplus)
extern "C" {
#if 0
} /* satisfy cc-mode */
#endif
#endif
#include "ruby/config.h"
#ifdef RUBY_EXTCONF_H
#include RUBY_EXTCONF_H
#endif
#define NORETURN_STYLE_NEW 1
#ifndef NORETURN
# define NORETURN(x) x
#endif
#ifndef DEPRECATED
# define DEPRECATED(x) x
#endif
#ifndef NOINLINE
# define NOINLINE(x) x
#endif
#ifdef __GNUC__
#define PRINTF_ARGS(decl, string_index, first_to_check) \
decl __attribute__((format(printf, string_index, first_to_check)))
#else
#define PRINTF_ARGS(decl, string_index, first_to_check) decl
#endif
#ifdef HAVE_STRING_H
# include <string.h>
#else
# include <strings.h>
#endif
#ifdef HAVE_INTRINSICS_H
# include <intrinsics.h>
#endif
#ifdef HAVE_STDINT_H
# include <stdint.h>
#endif
#ifdef HAVE_INTTYPES_H
# include <inttypes.h>
#endif
#include <stdarg.h>
#include <stdio.h>
#include "defines.h"
#if defined __GNUC__ && __GNUC__ >= 4
#pragma GCC visibility push(default)
#endif
#if defined(HAVE_ALLOCA_H)
#include <alloca.h>
#else
# ifdef _AIX
#pragma alloca
# endif
#endif
#if defined HAVE_UINTPTR_T && 0
typedef uintptr_t VALUE;
typedef uintptr_t ID;
# define SIGNED_VALUE intptr_t
# define SIZEOF_VALUE SIZEOF_UINTPTR_T
# undef PRI_VALUE_PREFIX
#elif SIZEOF_LONG == SIZEOF_VOIDP
typedef unsigned long VALUE;
typedef unsigned long ID;
# define SIGNED_VALUE long
# define SIZEOF_VALUE SIZEOF_LONG
# define PRI_VALUE_PREFIX "l"
#elif SIZEOF_LONG_LONG == SIZEOF_VOIDP
typedef unsigned LONG_LONG VALUE;
typedef unsigned LONG_LONG ID;
# define SIGNED_VALUE LONG_LONG
# define LONG_LONG_VALUE 1
# define SIZEOF_VALUE SIZEOF_LONG_LONG
# define PRI_VALUE_PREFIX PRI_LL_PREFIX
#else
# error ---->> ruby requires sizeof(void*) == sizeof(long) to be compiled. <<----
#endif
typedef char ruby_check_sizeof_int[SIZEOF_INT == sizeof(int) ? 1 : -1];
typedef char ruby_check_sizeof_long[SIZEOF_LONG == sizeof(long) ? 1 : -1];
#ifdef SIZEOF_LONG_LONG
typedef char ruby_check_sizeof_long_long[SIZEOF_LONG_LONG == sizeof(LONG_LONG) ? 1 : -1];
#endif
typedef char ruby_check_sizeof_voidp[SIZEOF_VOIDP == sizeof(void*) ? 1 : -1];
#ifndef PRI_INT_PREFIX
#define PRI_INT_PREFIX ""
#endif
#ifndef PRI_LONG_PREFIX
#define PRI_LONG_PREFIX "l"
#endif
#if defined PRIdPTR && !defined PRI_VALUE_PREFIX
#define PRIdVALUE PRIdPTR
#define PRIiVALUE PRIiPTR
#define PRIoVALUE PRIoPTR
#define PRIuVALUE PRIuPTR
#define PRIxVALUE PRIxPTR
#define PRIXVALUE PRIXPTR
#else
#define PRIdVALUE PRI_VALUE_PREFIX"d"
#define PRIiVALUE PRI_VALUE_PREFIX"i"
#define PRIoVALUE PRI_VALUE_PREFIX"o"
#define PRIuVALUE PRI_VALUE_PREFIX"u"
#define PRIxVALUE PRI_VALUE_PREFIX"x"
#define PRIXVALUE PRI_VALUE_PREFIX"X"
#endif
#ifndef PRI_VALUE_PREFIX
# define PRI_VALUE_PREFIX ""
#endif
#ifndef PRI_TIMET_PREFIX
# if SIZEOF_TIME_T == SIZEOF_INT
# define PRI_TIMET_PREFIX
# elif SIZEOF_TIME_T == SIZEOF_LONG
# define PRI_TIMET_PREFIX "l"
# elif SIZEOF_TIME_T == SIZEOF_LONG_LONG
# define PRI_TIMET_PREFIX PRI_LL_PREFIX
# endif
#endif
#if defined PRI_PTRDIFF_PREFIX
#elif SIZEOF_PTRDIFF_T == SIZEOF_INT
# define PRI_PTRDIFF_PREFIX ""
#elif SIZEOF_PTRDIFF_T == SIZEOF_LONG
# define PRI_PTRDIFF_PREFIX "l"
#elif SIZEOF_PTRDIFF_T == SIZEOF_LONG_LONG
# define PRI_PTRDIFF_PREFIX PRI_LL_PREFIX
#endif
#define PRIdPTRDIFF PRI_PTRDIFF_PREFIX"d"
#define PRIiPTRDIFF PRI_PTRDIFF_PREFIX"i"
#define PRIoPTRDIFF PRI_PTRDIFF_PREFIX"o"
#define PRIuPTRDIFF PRI_PTRDIFF_PREFIX"u"
#define PRIxPTRDIFF PRI_PTRDIFF_PREFIX"x"
#define PRIXPTRDIFF PRI_PTRDIFF_PREFIX"X"
#if defined PRI_SIZE_PREFIX
#elif SIZEOF_SIZE_T == SIZEOF_INT
# define PRI_SIZE_PREFIX ""
#elif SIZEOF_SIZE_T == SIZEOF_LONG
# define PRI_SIZE_PREFIX "l"
#elif SIZEOF_SIZE_T == SIZEOF_LONG_LONG
# define PRI_SIZE_PREFIX PRI_LL_PREFIX
#endif
#define PRIdSIZE PRI_SIZE_PREFIX"d"
#define PRIiSIZE PRI_SIZE_PREFIX"i"
#define PRIoSIZE PRI_SIZE_PREFIX"o"
#define PRIuSIZE PRI_SIZE_PREFIX"u"
#define PRIxSIZE PRI_SIZE_PREFIX"x"
#define PRIXSIZE PRI_SIZE_PREFIX"X"
#ifdef __STDC__
# include <limits.h>
#else
# ifndef LONG_MAX
# ifdef HAVE_LIMITS_H
# include <limits.h>
# else
/* assuming 32bit(2's compliment) long */
# define LONG_MAX 2147483647
# endif
# endif
# ifndef LONG_MIN
# define LONG_MIN (-LONG_MAX-1)
# endif
# ifndef CHAR_BIT
# define CHAR_BIT 8
# endif
#endif
#ifdef HAVE_LONG_LONG
# ifndef LLONG_MAX
# ifdef LONG_LONG_MAX
# define LLONG_MAX LONG_LONG_MAX
# else
# ifdef _I64_MAX
# define LLONG_MAX _I64_MAX
# else
/* assuming 64bit(2's complement) long long */
# define LLONG_MAX 9223372036854775807LL
# endif
# endif
# endif
# ifndef LLONG_MIN
# ifdef LONG_LONG_MIN
# define LLONG_MIN LONG_LONG_MIN
# else
# ifdef _I64_MIN
# define LLONG_MIN _I64_MIN
# else
# define LLONG_MIN (-LLONG_MAX-1)
# endif
# endif
# endif
#endif
#define FIXNUM_MAX (LONG_MAX>>1)
#define FIXNUM_MIN RSHIFT((long)LONG_MIN,1)
#define INT2FIX(i) ((VALUE)(((SIGNED_VALUE)(i))<<1 | FIXNUM_FLAG))
#define LONG2FIX(i) INT2FIX(i)
#define rb_fix_new(v) INT2FIX(v)
VALUE rb_int2inum(SIGNED_VALUE);
#define rb_int_new(v) rb_int2inum(v)
VALUE rb_uint2inum(VALUE);
#define rb_uint_new(v) rb_uint2inum(v)
#ifdef HAVE_LONG_LONG
VALUE rb_ll2inum(LONG_LONG);
#define LL2NUM(v) rb_ll2inum(v)
VALUE rb_ull2inum(unsigned LONG_LONG);
#define ULL2NUM(v) rb_ull2inum(v)
#endif
#if SIZEOF_OFF_T > SIZEOF_LONG && defined(HAVE_LONG_LONG)
# define OFFT2NUM(v) LL2NUM(v)
#elif SIZEOF_OFF_T == SIZEOF_LONG
# define OFFT2NUM(v) LONG2NUM(v)
#else
# define OFFT2NUM(v) INT2NUM(v)
#endif
#if SIZEOF_SIZE_T > SIZEOF_LONG && defined(HAVE_LONG_LONG)
# define SIZET2NUM(v) ULL2NUM(v)
# define SSIZET2NUM(v) LL2NUM(v)
#elif SIZEOF_SIZE_T == SIZEOF_LONG
# define SIZET2NUM(v) ULONG2NUM(v)
# define SSIZET2NUM(v) LONG2NUM(v)
#else
# define SIZET2NUM(v) UINT2NUM(v)
# define SSIZET2NUM(v) INT2NUM(v)
#endif
#ifndef SSIZE_MAX
# if SIZEOF_SIZE_T > SIZEOF_LONG && defined(HAVE_LONG_LONG)
# define SSIZE_MAX LLONG_MAX
# define SSIZE_MIN LLONG_MIN
# elif SIZEOF_SIZE_T == SIZEOF_LONG
# define SSIZE_MAX LONG_MAX
# define SSIZE_MIN LONG_MIN
# elif SIZEOF_SIZE_T == SIZEOF_INT
# define SSIZE_MAX INT_MAX
# define SSIZE_MIN INT_MIN
# else
# define SSIZE_MAX SHRT_MAX
# define SSIZE_MIN SHRT_MIN
# endif
#endif
#if SIZEOF_INT < SIZEOF_VALUE
NORETURN(void rb_out_of_int(SIGNED_VALUE num));
#endif
#if SIZEOF_INT < SIZEOF_LONG
#define rb_long2int_internal(n, i) \
int i = (int)(n); \
if ((long)i != (n)) rb_out_of_int(n)
#ifdef __GNUC__
#define rb_long2int(n) __extension__ ({long i2l_n = (n); rb_long2int_internal(i2l_n, i2l_i); i2l_i;})
#else
static inline int
rb_long2int(long n) {rb_long2int_internal(n, i); return i;}
#endif
#else
#define rb_long2int(n) ((int)(n))
#endif
#ifndef PIDT2NUM
#define PIDT2NUM(v) LONG2NUM(v)
#endif
#ifndef NUM2PIDT
#define NUM2PIDT(v) NUM2LONG(v)
#endif
#ifndef UIDT2NUM
#define UIDT2NUM(v) LONG2NUM(v)
#endif
#ifndef NUM2UIDT
#define NUM2UIDT(v) NUM2LONG(v)
#endif
#ifndef GIDT2NUM
#define GIDT2NUM(v) LONG2NUM(v)
#endif
#ifndef NUM2GIDT
#define NUM2GIDT(v) NUM2LONG(v)
#endif
#ifndef NUM2MODET
#define NUM2MODET(v) NUM2INT(v)
#endif
#ifndef MODET2NUM
#define MODET2NUM(v) INT2NUM(v)
#endif
#define FIX2LONG(x) (long)RSHIFT((SIGNED_VALUE)(x),1)
#define FIX2ULONG(x) ((((VALUE)(x))>>1)&LONG_MAX)
#define FIXNUM_P(f) (((SIGNED_VALUE)(f))&FIXNUM_FLAG)
#define POSFIXABLE(f) ((f) < FIXNUM_MAX+1)
#define NEGFIXABLE(f) ((f) >= FIXNUM_MIN)
#define FIXABLE(f) (POSFIXABLE(f) && NEGFIXABLE(f))
#define IMMEDIATE_P(x) ((VALUE)(x) & IMMEDIATE_MASK)
#define SYMBOL_P(x) (((VALUE)(x)&~(~(VALUE)0<<RUBY_SPECIAL_SHIFT))==SYMBOL_FLAG)
#define ID2SYM(x) (((VALUE)(x)<<RUBY_SPECIAL_SHIFT)|SYMBOL_FLAG)
#define SYM2ID(x) RSHIFT((unsigned long)(x),RUBY_SPECIAL_SHIFT)
/* Module#methods, #singleton_methods and so on return Symbols */
#define USE_SYMBOL_AS_METHOD_NAME 1
/* special constants - i.e. non-zero and non-fixnum constants */
enum ruby_special_consts {
RUBY_Qfalse = 0,
RUBY_Qtrue = 2,
RUBY_Qnil = 4,
RUBY_Qundef = 6,
RUBY_IMMEDIATE_MASK = 0x03,
RUBY_FIXNUM_FLAG = 0x01,
RUBY_SYMBOL_FLAG = 0x0e,
RUBY_SPECIAL_SHIFT = 8
};
#define Qfalse ((VALUE)RUBY_Qfalse)
#define Qtrue ((VALUE)RUBY_Qtrue)
#define Qnil ((VALUE)RUBY_Qnil)
#define Qundef ((VALUE)RUBY_Qundef) /* undefined value for placeholder */
#define IMMEDIATE_MASK RUBY_IMMEDIATE_MASK
#define FIXNUM_FLAG RUBY_FIXNUM_FLAG
#define SYMBOL_FLAG RUBY_SYMBOL_FLAG
#define RTEST(v) (((VALUE)(v) & ~Qnil) != 0)
#define NIL_P(v) ((VALUE)(v) == Qnil)
#define CLASS_OF(v) rb_class_of((VALUE)(v))
enum ruby_value_type {
RUBY_T_NONE = 0x00,
RUBY_T_OBJECT = 0x01,
RUBY_T_CLASS = 0x02,
RUBY_T_MODULE = 0x03,
RUBY_T_FLOAT = 0x04,
RUBY_T_STRING = 0x05,
RUBY_T_REGEXP = 0x06,
RUBY_T_ARRAY = 0x07,
RUBY_T_HASH = 0x08,
RUBY_T_STRUCT = 0x09,
RUBY_T_BIGNUM = 0x0a,
RUBY_T_FILE = 0x0b,
RUBY_T_DATA = 0x0c,
RUBY_T_MATCH = 0x0d,
RUBY_T_COMPLEX = 0x0e,
RUBY_T_RATIONAL = 0x0f,
RUBY_T_NIL = 0x11,
RUBY_T_TRUE = 0x12,
RUBY_T_FALSE = 0x13,
RUBY_T_SYMBOL = 0x14,
RUBY_T_FIXNUM = 0x15,
RUBY_T_UNDEF = 0x1b,
RUBY_T_NODE = 0x1c,
RUBY_T_ICLASS = 0x1d,
RUBY_T_ZOMBIE = 0x1e,
RUBY_T_MASK = 0x1f
};
#define T_NONE RUBY_T_NONE
#define T_NIL RUBY_T_NIL
#define T_OBJECT RUBY_T_OBJECT
#define T_CLASS RUBY_T_CLASS
#define T_ICLASS RUBY_T_ICLASS
#define T_MODULE RUBY_T_MODULE
#define T_FLOAT RUBY_T_FLOAT
#define T_STRING RUBY_T_STRING
#define T_REGEXP RUBY_T_REGEXP
#define T_ARRAY RUBY_T_ARRAY
#define T_HASH RUBY_T_HASH
#define T_STRUCT RUBY_T_STRUCT
#define T_BIGNUM RUBY_T_BIGNUM
#define T_FILE RUBY_T_FILE
#define T_FIXNUM RUBY_T_FIXNUM
#define T_TRUE RUBY_T_TRUE
#define T_FALSE RUBY_T_FALSE
#define T_DATA RUBY_T_DATA
#define T_MATCH RUBY_T_MATCH
#define T_SYMBOL RUBY_T_SYMBOL
#define T_RATIONAL RUBY_T_RATIONAL
#define T_COMPLEX RUBY_T_COMPLEX
#define T_UNDEF RUBY_T_UNDEF
#define T_NODE RUBY_T_NODE
#define T_ZOMBIE RUBY_T_ZOMBIE
#define T_MASK RUBY_T_MASK
#define BUILTIN_TYPE(x) (int)(((struct RBasic*)(x))->flags & T_MASK)
static inline int rb_type(VALUE obj);
#define TYPE(x) rb_type((VALUE)(x))
#ifdef __GNUC__
#define RB_GC_GUARD_PTR(ptr) \
__extension__ ({volatile VALUE *rb_gc_guarded_ptr = (ptr); rb_gc_guarded_ptr;})
#else
#ifdef _MSC_VER
#pragma optimize("", off)
#endif
static inline volatile VALUE *rb_gc_guarded_ptr(volatile VALUE *ptr) {return ptr;}
#ifdef _MSC_VER
#pragma optimize("", on)
#endif
#define RB_GC_GUARD_PTR(ptr) rb_gc_guarded_ptr(ptr)
#endif
#define RB_GC_GUARD(v) (*RB_GC_GUARD_PTR(&(v)))
void rb_check_type(VALUE,int);
#define Check_Type(v,t) rb_check_type((VALUE)(v),t)
VALUE rb_str_to_str(VALUE);
VALUE rb_string_value(volatile VALUE*);
char *rb_string_value_ptr(volatile VALUE*);
char *rb_string_value_cstr(volatile VALUE*);
#define StringValue(v) rb_string_value(&(v))
#define StringValuePtr(v) rb_string_value_ptr(&(v))
#define StringValueCStr(v) rb_string_value_cstr(&(v))
void rb_check_safe_obj(VALUE);
DEPRECATED(void rb_check_safe_str(VALUE));
#define SafeStringValue(v) do {\
StringValue(v);\
rb_check_safe_obj(v);\
} while (0)
/* obsolete macro - use SafeStringValue(v) */
#define Check_SafeStr(v) rb_check_safe_str((VALUE)(v))
VALUE rb_str_export(VALUE);
#define ExportStringValue(v) do {\
SafeStringValue(v);\
(v) = rb_str_export(v);\
} while (0)
VALUE rb_str_export_locale(VALUE);
VALUE rb_get_path(VALUE);
#define FilePathValue(v) (RB_GC_GUARD(v) = rb_get_path(v))
VALUE rb_get_path_no_checksafe(VALUE);
#define FilePathStringValue(v) ((v) = rb_get_path_no_checksafe(v))
void rb_secure(int);
int rb_safe_level(void);
void rb_set_safe_level(int);
void rb_set_safe_level_force(int);
void rb_secure_update(VALUE);
NORETURN(void rb_insecure_operation(void));
VALUE rb_errinfo(void);
void rb_set_errinfo(VALUE);
SIGNED_VALUE rb_num2long(VALUE);
VALUE rb_num2ulong(VALUE);
#define NUM2LONG_internal(x) ((long)(FIXNUM_P(x) ? FIX2LONG(x) : rb_num2long(x)))
#ifdef __GNUC__
#define NUM2LONG(x) \
__extension__ ({VALUE num2long_x = (x); NUM2LONG_internal(num2long_x);})
#else
static inline long
NUM2LONG(VALUE x)
{
return NUM2LONG_internal(x);
}
#endif
#define NUM2ULONG(x) rb_num2ulong((VALUE)x)
#if SIZEOF_INT < SIZEOF_LONG
long rb_num2int(VALUE);
long rb_fix2int(VALUE);
#define FIX2INT(x) ((int)rb_fix2int((VALUE)x))
#define NUM2INT_internal(x) (FIXNUM_P(x) ? FIX2INT(x) : (int)rb_num2int(x))
#ifdef __GNUC__
#define NUM2INT(x) \
__extension__ ({VALUE num2int_x = (x); NUM2INT_internal(num2int_x);})
#else
static inline int
NUM2INT(VALUE x)
{
return NUM2INT_internal(x);
}
#endif
unsigned long rb_num2uint(VALUE);
#define NUM2UINT(x) ((unsigned int)rb_num2uint(x))
unsigned long rb_fix2uint(VALUE);
#define FIX2UINT(x) ((unsigned int)rb_fix2uint(x))
#else
#define NUM2INT(x) ((int)NUM2LONG(x))
#define NUM2UINT(x) ((unsigned int)NUM2ULONG(x))
#define FIX2INT(x) ((int)FIX2LONG(x))
#define FIX2UINT(x) ((unsigned int)FIX2ULONG(x))
#endif
#ifdef HAVE_LONG_LONG
LONG_LONG rb_num2ll(VALUE);
unsigned LONG_LONG rb_num2ull(VALUE);
# define NUM2LL_internal(x) (FIXNUM_P(x) ? FIX2LONG(x) : rb_num2ll(x))
# ifdef __GNUC__
# define NUM2LL(x) \
__extension__ ({VALUE num2ll_x = (x); NUM2LL_internal(num2ll_x);})
# else
static inline LONG_LONG
NUM2LL(VALUE x)
{
return NUM2LL_internal(x);
}
# endif
# define NUM2ULL(x) rb_num2ull((VALUE)x)
#endif
#if defined(HAVE_LONG_LONG) && SIZEOF_OFF_T > SIZEOF_LONG
# define NUM2OFFT(x) ((off_t)NUM2LL(x))
#else
# define NUM2OFFT(x) NUM2LONG(x)
#endif
#if defined(HAVE_LONG_LONG) && SIZEOF_SIZE_T > SIZEOF_LONG
# define NUM2SIZET(x) ((size_t)NUM2ULL(x))
# define NUM2SSIZET(x) ((size_t)NUM2LL(x))
#else
# define NUM2SIZET(x) NUM2ULONG(x)
# define NUM2SSIZET(x) NUM2LONG(x)
#endif
double rb_num2dbl(VALUE);
#define NUM2DBL(x) rb_num2dbl((VALUE)(x))
VALUE rb_uint2big(VALUE);
VALUE rb_int2big(SIGNED_VALUE);
VALUE rb_newobj(void);
#define NEWOBJ(obj,type) type *obj = (type*)rb_newobj()
#define OBJSETUP(obj,c,t) do {\
RBASIC(obj)->flags = (t);\
RBASIC(obj)->klass = (c);\
if (rb_safe_level() >= 3) FL_SET(obj, FL_TAINT | FL_UNTRUSTED);\
} while (0)
#define CLONESETUP(clone,obj) do {\
OBJSETUP(clone,rb_singleton_class_clone((VALUE)obj),RBASIC(obj)->flags);\
rb_singleton_class_attached(RBASIC(clone)->klass, (VALUE)clone);\
if (FL_TEST(obj, FL_EXIVAR)) rb_copy_generic_ivar((VALUE)clone,(VALUE)obj);\
} while (0)
#define DUPSETUP(dup,obj) do {\
OBJSETUP(dup,rb_obj_class(obj), (RBASIC(obj)->flags)&(T_MASK|FL_EXIVAR|FL_TAINT|FL_UNTRUSTED)); \
if (FL_TEST(obj, FL_EXIVAR)) rb_copy_generic_ivar((VALUE)dup,(VALUE)obj);\
} while (0)
struct RBasic {
VALUE flags;
VALUE klass;
};
#define ROBJECT_EMBED_LEN_MAX 3
struct RObject {
struct RBasic basic;
union {
struct {
long numiv;
VALUE *ivptr;
struct st_table *iv_index_tbl; /* shortcut for RCLASS_IV_INDEX_TBL(rb_obj_class(obj)) */
} heap;
VALUE ary[ROBJECT_EMBED_LEN_MAX];
} as;
};
#define ROBJECT_EMBED FL_USER1
#define ROBJECT_NUMIV(o) \
((RBASIC(o)->flags & ROBJECT_EMBED) ? \
ROBJECT_EMBED_LEN_MAX : \
ROBJECT(o)->as.heap.numiv)
#define ROBJECT_IVPTR(o) \
((RBASIC(o)->flags & ROBJECT_EMBED) ? \
ROBJECT(o)->as.ary : \
ROBJECT(o)->as.heap.ivptr)
#define ROBJECT_IV_INDEX_TBL(o) \
((RBASIC(o)->flags & ROBJECT_EMBED) ? \
RCLASS_IV_INDEX_TBL(rb_obj_class(o)) : \
ROBJECT(o)->as.heap.iv_index_tbl)
/** @internal */
typedef struct {
VALUE super;
struct st_table *iv_tbl;
struct st_table *const_tbl;
} rb_classext_t;
struct RClass {
struct RBasic basic;
rb_classext_t *ptr;
struct st_table *m_tbl;
struct st_table *iv_index_tbl;
};
#define RCLASS_IV_TBL(c) (RCLASS(c)->ptr->iv_tbl)
#define RCLASS_CONST_TBL(c) (RCLASS(c)->ptr->const_tbl)
#define RCLASS_M_TBL(c) (RCLASS(c)->m_tbl)
#define RCLASS_SUPER(c) (RCLASS(c)->ptr->super)
#define RCLASS_IV_INDEX_TBL(c) (RCLASS(c)->iv_index_tbl)
#define RMODULE_IV_TBL(m) RCLASS_IV_TBL(m)
#define RMODULE_CONST_TBL(m) RCLASS_CONST_TBL(m)
#define RMODULE_M_TBL(m) RCLASS_M_TBL(m)
#define RMODULE_SUPER(m) RCLASS_SUPER(m)
struct RFloat {
struct RBasic basic;
double float_value;
};
#define RFLOAT_VALUE(v) (RFLOAT(v)->float_value)
#define DBL2NUM(dbl) rb_float_new(dbl)
#define ELTS_SHARED FL_USER2
#define RSTRING_EMBED_LEN_MAX ((int)((sizeof(VALUE)*3)/sizeof(char)-1))
struct RString {
struct RBasic basic;
union {
struct {
long len;
char *ptr;
union {
long capa;
VALUE shared;
} aux;
} heap;
char ary[RSTRING_EMBED_LEN_MAX + 1];
} as;
};
#define RSTRING_NOEMBED FL_USER1
#define RSTRING_EMBED_LEN_MASK (FL_USER2|FL_USER3|FL_USER4|FL_USER5|FL_USER6)
#define RSTRING_EMBED_LEN_SHIFT (FL_USHIFT+2)
#define RSTRING_EMBED_LEN(str) \
(long)((RBASIC(str)->flags >> RSTRING_EMBED_LEN_SHIFT) & \
(RSTRING_EMBED_LEN_MASK >> RSTRING_EMBED_LEN_SHIFT))
#define RSTRING_LEN(str) \
(!(RBASIC(str)->flags & RSTRING_NOEMBED) ? \
RSTRING_EMBED_LEN(str) : \
RSTRING(str)->as.heap.len)
#define RSTRING_PTR(str) \
(!(RBASIC(str)->flags & RSTRING_NOEMBED) ? \
RSTRING(str)->as.ary : \
RSTRING(str)->as.heap.ptr)
#define RSTRING_END(str) \
(!(RBASIC(str)->flags & RSTRING_NOEMBED) ? \
(RSTRING(str)->as.ary + RSTRING_EMBED_LEN(str)) : \
(RSTRING(str)->as.heap.ptr + RSTRING(str)->as.heap.len))
#define RSTRING_LENINT(str) rb_long2int(RSTRING_LEN(str))
#define RSTRING_GETMEM(str, ptrvar, lenvar) \
(!(RBASIC(str)->flags & RSTRING_NOEMBED) ? \
((ptrvar) = RSTRING(str)->as.ary, (lenvar) = RSTRING_EMBED_LEN(str)) : \
((ptrvar) = RSTRING(str)->as.heap.ptr, (lenvar) = RSTRING(str)->as.heap.len))
#define RARRAY_EMBED_LEN_MAX 3
struct RArray {
struct RBasic basic;
union {
struct {
long len;
union {
long capa;
VALUE shared;
} aux;
VALUE *ptr;
} heap;
VALUE ary[RARRAY_EMBED_LEN_MAX];
} as;
};
#define RARRAY_EMBED_FLAG FL_USER1
/* FL_USER2 is for ELTS_SHARED */
#define RARRAY_EMBED_LEN_MASK (FL_USER4|FL_USER3)
#define RARRAY_EMBED_LEN_SHIFT (FL_USHIFT+3)
#define RARRAY_LEN(a) \
((RBASIC(a)->flags & RARRAY_EMBED_FLAG) ? \
(long)((RBASIC(a)->flags >> RARRAY_EMBED_LEN_SHIFT) & \
(RARRAY_EMBED_LEN_MASK >> RARRAY_EMBED_LEN_SHIFT)) : \
RARRAY(a)->as.heap.len)
#define RARRAY_PTR(a) \
((RBASIC(a)->flags & RARRAY_EMBED_FLAG) ? \
RARRAY(a)->as.ary : \
RARRAY(a)->as.heap.ptr)
#define RARRAY_LENINT(ary) rb_long2int(RARRAY_LEN(ary))
struct RRegexp {
struct RBasic basic;
struct re_pattern_buffer *ptr;
VALUE src;
unsigned long usecnt;
};
#define RREGEXP_SRC(r) RREGEXP(r)->src
#define RREGEXP_SRC_PTR(r) RSTRING_PTR(RREGEXP(r)->src)
#define RREGEXP_SRC_LEN(r) RSTRING_LEN(RREGEXP(r)->src)
#define RREGEXP_SRC_END(r) RSTRING_END(RREGEXP(r)->src)
struct RHash {
struct RBasic basic;
struct st_table *ntbl; /* possibly 0 */
int iter_lev;
VALUE ifnone;
};
/* RHASH_TBL allocates st_table if not available. */
#define RHASH_TBL(h) rb_hash_tbl(h)
#define RHASH_ITER_LEV(h) (RHASH(h)->iter_lev)
#define RHASH_IFNONE(h) (RHASH(h)->ifnone)
#define RHASH_SIZE(h) (RHASH(h)->ntbl ? RHASH(h)->ntbl->num_entries : 0)
#define RHASH_EMPTY_P(h) (RHASH_SIZE(h) == 0)
struct RFile {
struct RBasic basic;
struct rb_io_t *fptr;
};
struct RRational {
struct RBasic basic;
VALUE num;
VALUE den;
};
struct RComplex {
struct RBasic basic;
VALUE real;
VALUE imag;
};
struct RData {
struct RBasic basic;
void (*dmark)(void*);
void (*dfree)(void*);
void *data;
};
typedef struct rb_data_type_struct rb_data_type_t;
struct rb_data_type_struct {
const char *wrap_struct_name;
struct {
void (*dmark)(void*);
void (*dfree)(void*);
size_t (*dsize)(const void *);
void *reserved[2]; /* For future extension.
This array *must* be filled with ZERO. */
} function;
const rb_data_type_t *parent;
void *data; /* This area can be used for any purpose
by a programmer who define the type. */
};
#define HAVE_TYPE_RB_DATA_TYPE_T 1
#define HAVE_RB_DATA_TYPE_T_FUNCTION 1
#define HAVE_RB_DATA_TYPE_T_PARENT 1
struct RTypedData {
struct RBasic basic;
const rb_data_type_t *type;
VALUE typed_flag; /* 1 or not */
void *data;
};
#define DATA_PTR(dta) (RDATA(dta)->data)
#define RTYPEDDATA_P(v) (RTYPEDDATA(v)->typed_flag == 1)
#define RTYPEDDATA_TYPE(v) (RTYPEDDATA(v)->type)
#define RTYPEDDATA_DATA(v) (RTYPEDDATA(v)->data)
/*
#define RUBY_DATA_FUNC(func) ((void (*)(void*))func)
*/
typedef void (*RUBY_DATA_FUNC)(void*);
VALUE rb_data_object_alloc(VALUE,void*,RUBY_DATA_FUNC,RUBY_DATA_FUNC);
VALUE rb_data_typed_object_alloc(VALUE klass, void *datap, const rb_data_type_t *);
int rb_typeddata_inherited_p(const rb_data_type_t *child, const rb_data_type_t *parent);
int rb_typeddata_is_kind_of(VALUE, const rb_data_type_t *);
void *rb_check_typeddata(VALUE, const rb_data_type_t *);
#define Check_TypedStruct(v,t) rb_check_typeddata((VALUE)(v),t)
#define RUBY_DEFAULT_FREE ((RUBY_DATA_FUNC)-1)
#define RUBY_NEVER_FREE ((RUBY_DATA_FUNC)0)
#define RUBY_TYPED_DEFAULT_FREE RUBY_DEFAULT_FREE
#define RUBY_TYPED_NEVER_FREE RUBY_NEVER_FREE
#define Data_Wrap_Struct(klass,mark,free,sval)\
rb_data_object_alloc(klass,sval,(RUBY_DATA_FUNC)mark,(RUBY_DATA_FUNC)free)
#define Data_Make_Struct(klass,type,mark,free,sval) (\
sval = ALLOC(type),\
memset(sval, 0, sizeof(type)),\
Data_Wrap_Struct(klass,mark,free,sval)\
)
#define TypedData_Wrap_Struct(klass,data_type,sval)\
rb_data_typed_object_alloc(klass,sval,data_type)
#define TypedData_Make_Struct(klass, type, data_type, sval) (\
sval = ALLOC(type),\
memset(sval, 0, sizeof(type)),\
TypedData_Wrap_Struct(klass,data_type,sval)\
)
#define Data_Get_Struct(obj,type,sval) do {\
Check_Type(obj, T_DATA); \
sval = (type*)DATA_PTR(obj);\
} while (0)
#define TypedData_Get_Struct(obj,type,data_type,sval) do {\
sval = (type*)rb_check_typeddata(obj, data_type); \
} while (0)
#define RSTRUCT_EMBED_LEN_MAX 3
struct RStruct {
struct RBasic basic;
union {
struct {
long len;
VALUE *ptr;
} heap;
VALUE ary[RSTRUCT_EMBED_LEN_MAX];
} as;
};
#define RSTRUCT_EMBED_LEN_MASK (FL_USER2|FL_USER1)
#define RSTRUCT_EMBED_LEN_SHIFT (FL_USHIFT+1)
#define RSTRUCT_LEN(st) \
((RBASIC(st)->flags & RSTRUCT_EMBED_LEN_MASK) ? \
(long)((RBASIC(st)->flags >> RSTRUCT_EMBED_LEN_SHIFT) & \
(RSTRUCT_EMBED_LEN_MASK >> RSTRUCT_EMBED_LEN_SHIFT)) : \
RSTRUCT(st)->as.heap.len)
#define RSTRUCT_PTR(st) \
((RBASIC(st)->flags & RSTRUCT_EMBED_LEN_MASK) ? \
RSTRUCT(st)->as.ary : \
RSTRUCT(st)->as.heap.ptr)
#define RSTRUCT_LENINT(st) rb_long2int(RSTRUCT_LEN(st))
#define RBIGNUM_EMBED_LEN_MAX ((int)((sizeof(VALUE)*3)/sizeof(BDIGIT)))
struct RBignum {
struct RBasic basic;
union {
struct {
long len;
BDIGIT *digits;
} heap;
BDIGIT ary[RBIGNUM_EMBED_LEN_MAX];
} as;
};
#define RBIGNUM_SIGN_BIT FL_USER1
/* sign: positive:1, negative:0 */
#define RBIGNUM_SIGN(b) ((RBASIC(b)->flags & RBIGNUM_SIGN_BIT) != 0)
#define RBIGNUM_SET_SIGN(b,sign) \
((sign) ? (RBASIC(b)->flags |= RBIGNUM_SIGN_BIT) \
: (RBASIC(b)->flags &= ~RBIGNUM_SIGN_BIT))
#define RBIGNUM_POSITIVE_P(b) RBIGNUM_SIGN(b)
#define RBIGNUM_NEGATIVE_P(b) (!RBIGNUM_SIGN(b))
#define RBIGNUM_EMBED_FLAG FL_USER2
#define RBIGNUM_EMBED_LEN_MASK (FL_USER5|FL_USER4|FL_USER3)
#define RBIGNUM_EMBED_LEN_SHIFT (FL_USHIFT+3)
#define RBIGNUM_LEN(b) \
((RBASIC(b)->flags & RBIGNUM_EMBED_FLAG) ? \
(long)((RBASIC(b)->flags >> RBIGNUM_EMBED_LEN_SHIFT) & \
(RBIGNUM_EMBED_LEN_MASK >> RBIGNUM_EMBED_LEN_SHIFT)) : \
RBIGNUM(b)->as.heap.len)
/* LSB:RBIGNUM_DIGITS(b)[0], MSB:RBIGNUM_DIGITS(b)[RBIGNUM_LEN(b)-1] */
#define RBIGNUM_DIGITS(b) \
((RBASIC(b)->flags & RBIGNUM_EMBED_FLAG) ? \
RBIGNUM(b)->as.ary : \
RBIGNUM(b)->as.heap.digits)
#define RBIGNUM_LENINT(b) rb_long2int(RBIGNUM_LEN(b))
#define R_CAST(st) (struct st*)
#define RBASIC(obj) (R_CAST(RBasic)(obj))
#define ROBJECT(obj) (R_CAST(RObject)(obj))
#define RCLASS(obj) (R_CAST(RClass)(obj))
#define RMODULE(obj) RCLASS(obj)
#define RFLOAT(obj) (R_CAST(RFloat)(obj))
#define RSTRING(obj) (R_CAST(RString)(obj))
#define RREGEXP(obj) (R_CAST(RRegexp)(obj))
#define RARRAY(obj) (R_CAST(RArray)(obj))
#define RHASH(obj) (R_CAST(RHash)(obj))
#define RDATA(obj) (R_CAST(RData)(obj))
#define RTYPEDDATA(obj) (R_CAST(RTypedData)(obj))
#define RSTRUCT(obj) (R_CAST(RStruct)(obj))
#define RBIGNUM(obj) (R_CAST(RBignum)(obj))
#define RFILE(obj) (R_CAST(RFile)(obj))
#define RRATIONAL(obj) (R_CAST(RRational)(obj))
#define RCOMPLEX(obj) (R_CAST(RComplex)(obj))
#define FL_SINGLETON FL_USER0
#define FL_MARK (((VALUE)1)<<5)
#define FL_RESERVED (((VALUE)1)<<6) /* will be used in the future GC */
#define FL_FINALIZE (((VALUE)1)<<7)
#define FL_TAINT (((VALUE)1)<<8)
#define FL_UNTRUSTED (((VALUE)1)<<9)
#define FL_EXIVAR (((VALUE)1)<<10)
#define FL_FREEZE (((VALUE)1)<<11)
#define FL_USHIFT 12
#define FL_USER0 (((VALUE)1)<<(FL_USHIFT+0))
#define FL_USER1 (((VALUE)1)<<(FL_USHIFT+1))
#define FL_USER2 (((VALUE)1)<<(FL_USHIFT+2))
#define FL_USER3 (((VALUE)1)<<(FL_USHIFT+3))
#define FL_USER4 (((VALUE)1)<<(FL_USHIFT+4))
#define FL_USER5 (((VALUE)1)<<(FL_USHIFT+5))
#define FL_USER6 (((VALUE)1)<<(FL_USHIFT+6))
#define FL_USER7 (((VALUE)1)<<(FL_USHIFT+7))
#define FL_USER8 (((VALUE)1)<<(FL_USHIFT+8))
#define FL_USER9 (((VALUE)1)<<(FL_USHIFT+9))
#define FL_USER10 (((VALUE)1)<<(FL_USHIFT+10))
#define FL_USER11 (((VALUE)1)<<(FL_USHIFT+11))
#define FL_USER12 (((VALUE)1)<<(FL_USHIFT+12))
#define FL_USER13 (((VALUE)1)<<(FL_USHIFT+13))
#define FL_USER14 (((VALUE)1)<<(FL_USHIFT+14))
#define FL_USER15 (((VALUE)1)<<(FL_USHIFT+15))
#define FL_USER16 (((VALUE)1)<<(FL_USHIFT+16))
#define FL_USER17 (((VALUE)1)<<(FL_USHIFT+17))
#define FL_USER18 (((VALUE)1)<<(FL_USHIFT+18))
#define FL_USER19 (((VALUE)1)<<(FL_USHIFT+19))
#define SPECIAL_CONST_P(x) (IMMEDIATE_P(x) || !RTEST(x))
#define FL_ABLE(x) (!SPECIAL_CONST_P(x) && BUILTIN_TYPE(x) != T_NODE)
#define FL_TEST(x,f) (FL_ABLE(x)?(RBASIC(x)->flags&(f)):0)
#define FL_ANY(x,f) FL_TEST(x,f)
#define FL_ALL(x,f) (FL_TEST(x,f) == (f))
#define FL_SET(x,f) do {if (FL_ABLE(x)) RBASIC(x)->flags |= (f);} while (0)
#define FL_UNSET(x,f) do {if (FL_ABLE(x)) RBASIC(x)->flags &= ~(f);} while (0)
#define FL_REVERSE(x,f) do {if (FL_ABLE(x)) RBASIC(x)->flags ^= (f);} while (0)
#define OBJ_TAINTED(x) (!!FL_TEST((x), FL_TAINT))
#define OBJ_TAINT(x) FL_SET((x), FL_TAINT)
#define OBJ_UNTRUSTED(x) (!!FL_TEST((x), FL_UNTRUSTED))
#define OBJ_UNTRUST(x) FL_SET((x), FL_UNTRUSTED)
#define OBJ_INFECT(x,s) do {if (FL_ABLE(x) && FL_ABLE(s)) RBASIC(x)->flags |= RBASIC(s)->flags & (FL_TAINT | FL_UNTRUSTED);} while (0)
#define OBJ_FROZEN(x) (!!FL_TEST((x), FL_FREEZE))
#define OBJ_FREEZE(x) FL_SET((x), FL_FREEZE)
#if SIZEOF_INT < SIZEOF_LONG
# define INT2NUM(v) INT2FIX((int)(v))
# define UINT2NUM(v) LONG2FIX((unsigned int)(v))
#else
# define INT2NUM_internal(v) (FIXABLE(v) ? INT2FIX(v) : rb_int2big(v))
# ifdef __GNUC__
# define INT2NUM(v) __extension__ ({int int2num_v = (v); INT2NUM_internal(int2num_v);})
# else
static inline VALUE
INT2NUM(int v)
{
return INT2NUM_internal(v);
}
# endif
# define UINT2NUM_internal(v) (POSFIXABLE(v) ? LONG2FIX(v) : rb_uint2big(v))
# ifdef __GNUC__
# define UINT2NUM(v) __extension__ ({unsigned int uint2num_v = (v); UINT2NUM_internal(uint2num_v);})
# else
static inline VALUE
UINT2NUM(unsigned int v)
{
return UINT2NUM_internal(v);
}
# endif
#endif
#define LONG2NUM_internal(v) (FIXABLE(v) ? LONG2FIX(v) : rb_int2big(v))
#ifdef __GNUC__
# define LONG2NUM(v) __extension__ ({long long2num_v = (v); LONG2NUM_internal(long2num_v);})
#else
static inline VALUE
LONG2NUM(long v)
{
return LONG2NUM_internal(v);
}
#endif
#define ULONG2NUM_internal(v) (POSFIXABLE(v) ? LONG2FIX(v) : rb_uint2big(v))
#ifdef __GNUC__
# define ULONG2NUM(v) __extension__ ({unsigned long ulong2num_v = (v); ULONG2NUM_internal(ulong2num_v);})
#else
static inline VALUE
ULONG2NUM(unsigned long v)
{
return ULONG2NUM_internal(v);
}
#endif
#define NUM2CHR_internal(x) (((TYPE(x) == T_STRING)&&(RSTRING_LEN(x)>=1))?\
RSTRING_PTR(x)[0]:(char)(NUM2INT(x)&0xff))
#ifdef __GNUC__
# define NUM2CHR(x) __extension__ ({VALUE num2chr_x = (x); NUM2CHR_internal(num2chr_x);})
#else
static inline char
NUM2CHR(VALUE x)
{
return NUM2CHR_internal(x);
}
#endif
#define CHR2FIX(x) INT2FIX((long)((x)&0xff))
#define ALLOC_N(type,n) (type*)xmalloc2((n),sizeof(type))
#define ALLOC(type) (type*)xmalloc(sizeof(type))
#define REALLOC_N(var,type,n) (var)=(type*)xrealloc2((char*)(var),(n),sizeof(type))
#define ALLOCA_N(type,n) (type*)alloca(sizeof(type)*(n))
void *rb_alloc_tmp_buffer(volatile VALUE *store, long len);
void rb_free_tmp_buffer(volatile VALUE *store);
/* allocates _n_ bytes temporary buffer and stores VALUE including it
* in _v_. _n_ may be evaluated twice. */
#ifdef C_ALLOCA
# define ALLOCV(v, n) rb_alloc_tmp_buffer(&(v), (n))
#else
# define ALLOCV(v, n) ((n) < 1024 ? (RB_GC_GUARD(v) = 0, alloca(n)) : rb_alloc_tmp_buffer(&(v), (n)))
#endif
#define ALLOCV_N(type, v, n) (type*)ALLOCV((v), sizeof(type)*(n))
#define ALLOCV_END(v) rb_free_tmp_buffer(&(v))
#define MEMZERO(p,type,n) memset((p), 0, sizeof(type)*(n))
#define MEMCPY(p1,p2,type,n) memcpy((p1), (p2), sizeof(type)*(n))
#define MEMMOVE(p1,p2,type,n) memmove((p1), (p2), sizeof(type)*(n))
#define MEMCMP(p1,p2,type,n) memcmp((p1), (p2), sizeof(type)*(n))
void rb_obj_infect(VALUE,VALUE);
typedef int ruby_glob_func(const char*,VALUE, void*);
void rb_glob(const char*,void(*)(const char*,VALUE,void*),VALUE);
int ruby_glob(const char*,int,ruby_glob_func*,VALUE);
int ruby_brace_glob(const char*,int,ruby_glob_func*,VALUE);
VALUE rb_define_class(const char*,VALUE);
VALUE rb_define_module(const char*);
VALUE rb_define_class_under(VALUE, const char*, VALUE);
VALUE rb_define_module_under(VALUE, const char*);
void rb_include_module(VALUE,VALUE);
void rb_extend_object(VALUE,VALUE);
struct rb_global_variable;
typedef VALUE rb_gvar_getter_t(ID id, void *data, struct rb_global_variable *gvar);
typedef void rb_gvar_setter_t(VALUE val, ID id, void *data, struct rb_global_variable *gvar);
typedef void rb_gvar_marker_t(VALUE *var);
VALUE rb_gvar_undef_getter(ID id, void *data, struct rb_global_variable *gvar);
void rb_gvar_undef_setter(VALUE val, ID id, void *data, struct rb_global_variable *gvar);
void rb_gvar_undef_marker(VALUE *var);
VALUE rb_gvar_val_getter(ID id, void *data, struct rb_global_variable *gvar);
void rb_gvar_val_setter(VALUE val, ID id, void *data, struct rb_global_variable *gvar);
void rb_gvar_val_marker(VALUE *var);
VALUE rb_gvar_var_getter(ID id, void *data, struct rb_global_variable *gvar);
void rb_gvar_var_setter(VALUE val, ID id, void *data, struct rb_global_variable *gvar);
void rb_gvar_var_marker(VALUE *var);
void rb_gvar_readonly_setter(VALUE val, ID id, void *data, struct rb_global_variable *gvar);
void rb_define_variable(const char*,VALUE*);
void rb_define_virtual_variable(const char*,VALUE(*)(ANYARGS),void(*)(ANYARGS));
void rb_define_hooked_variable(const char*,VALUE*,VALUE(*)(ANYARGS),void(*)(ANYARGS));
void rb_define_readonly_variable(const char*,VALUE*);
void rb_define_const(VALUE,const char*,VALUE);
void rb_define_global_const(const char*,VALUE);
#define RUBY_METHOD_FUNC(func) ((VALUE (*)(ANYARGS))func)
void rb_define_method(VALUE,const char*,VALUE(*)(ANYARGS),int);
void rb_define_module_function(VALUE,const char*,VALUE(*)(ANYARGS),int);
void rb_define_global_function(const char*,VALUE(*)(ANYARGS),int);
void rb_undef_method(VALUE,const char*);
void rb_define_alias(VALUE,const char*,const char*);
void rb_define_attr(VALUE,const char*,int,int);
void rb_global_variable(VALUE*);
void rb_gc_register_mark_object(VALUE);
void rb_gc_register_address(VALUE*);
void rb_gc_unregister_address(VALUE*);
ID rb_intern(const char*);
ID rb_intern2(const char*, long);
ID rb_intern_str(VALUE str);
const char *rb_id2name(ID);
ID rb_to_id(VALUE);
VALUE rb_id2str(ID);
#define CONST_ID_CACHE(result, str) \
{ \
static ID rb_intern_id_cache; \
if (!rb_intern_id_cache) \
rb_intern_id_cache = rb_intern2(str, (long)strlen(str)); \
result rb_intern_id_cache; \
}
#define CONST_ID(var, str) \
do CONST_ID_CACHE(var =, str) while (0)
#ifdef __GNUC__
/* __builtin_constant_p and statement expression is available
* since gcc-2.7.2.3 at least. */
#define rb_intern(str) \
(__builtin_constant_p(str) ? \
__extension__ (CONST_ID_CACHE((ID), str)) : \
rb_intern(str))
#define rb_intern_const(str) \
(__builtin_constant_p(str) ? \
__extension__ (rb_intern2(str, (long)strlen(str))) : \
(rb_intern)(str))
#else
#define rb_intern_const(str) rb_intern2(str, (long)strlen(str))
#endif
const char *rb_class2name(VALUE);
const char *rb_obj_classname(VALUE);
void rb_p(VALUE);
VALUE rb_eval_string(const char*);
VALUE rb_eval_string_protect(const char*, int*);
VALUE rb_eval_string_wrap(const char*, int*);
VALUE rb_funcall(VALUE, ID, int, ...);
VALUE rb_funcall2(VALUE, ID, int, const VALUE*);
VALUE rb_funcall3(VALUE, ID, int, const VALUE*);
VALUE rb_funcall_passing_block(VALUE, ID, int, const VALUE*);
int rb_scan_args(int, const VALUE*, const char*, ...);
VALUE rb_call_super(int, const VALUE*);
VALUE rb_gv_set(const char*, VALUE);
VALUE rb_gv_get(const char*);
VALUE rb_iv_get(VALUE, const char*);
VALUE rb_iv_set(VALUE, const char*, VALUE);
VALUE rb_equal(VALUE,VALUE);
VALUE *rb_ruby_verbose_ptr(void);
VALUE *rb_ruby_debug_ptr(void);
#define ruby_verbose (*rb_ruby_verbose_ptr())
#define ruby_debug (*rb_ruby_debug_ptr())
PRINTF_ARGS(NORETURN(void rb_raise(VALUE, const char*, ...)), 2, 3);
PRINTF_ARGS(NORETURN(void rb_fatal(const char*, ...)), 1, 2);
PRINTF_ARGS(NORETURN(void rb_bug(const char*, ...)), 1, 2);
NORETURN(void rb_bug_errno(const char*, int));
NORETURN(void rb_sys_fail(const char*));
NORETURN(void rb_mod_sys_fail(VALUE, const char*));
NORETURN(void rb_iter_break(void));
NORETURN(void rb_exit(int));
NORETURN(void rb_notimplement(void));
VALUE rb_syserr_new(int, const char *);
NORETURN(void rb_syserr_fail(int, const char*));
NORETURN(void rb_mod_syserr_fail(VALUE, int, const char*));
/* reports if `-W' specified */
PRINTF_ARGS(void rb_warning(const char*, ...), 1, 2);
PRINTF_ARGS(void rb_compile_warning(const char *, int, const char*, ...), 3, 4);
PRINTF_ARGS(void rb_sys_warning(const char*, ...), 1, 2);
/* reports always */
PRINTF_ARGS(void rb_warn(const char*, ...), 1, 2);
PRINTF_ARGS(void rb_compile_warn(const char *, int, const char*, ...), 3, 4);
typedef VALUE rb_block_call_func(VALUE, VALUE, int, VALUE*);
VALUE rb_each(VALUE);
VALUE rb_yield(VALUE);
VALUE rb_yield_values(int n, ...);
VALUE rb_yield_values2(int n, const VALUE *argv);
VALUE rb_yield_splat(VALUE);
int rb_block_given_p(void);
void rb_need_block(void);
VALUE rb_iterate(VALUE(*)(VALUE),VALUE,VALUE(*)(ANYARGS),VALUE);
VALUE rb_block_call(VALUE,ID,int,VALUE*,VALUE(*)(ANYARGS),VALUE);
VALUE rb_rescue(VALUE(*)(ANYARGS),VALUE,VALUE(*)(ANYARGS),VALUE);
VALUE rb_rescue2(VALUE(*)(ANYARGS),VALUE,VALUE(*)(ANYARGS),VALUE,...);
VALUE rb_ensure(VALUE(*)(ANYARGS),VALUE,VALUE(*)(ANYARGS),VALUE);
VALUE rb_catch(const char*,VALUE(*)(ANYARGS),VALUE);
VALUE rb_catch_obj(VALUE,VALUE(*)(ANYARGS),VALUE);
NORETURN(void rb_throw(const char*,VALUE));
NORETURN(void rb_throw_obj(VALUE,VALUE));
VALUE rb_require(const char*);
#ifdef __ia64
void ruby_init_stack(volatile VALUE*, void*);
#define ruby_init_stack(addr) ruby_init_stack(addr, rb_ia64_bsp())
#else
void ruby_init_stack(volatile VALUE*);
#endif
#define RUBY_INIT_STACK \
VALUE variable_in_this_stack_frame; \
ruby_init_stack(&variable_in_this_stack_frame);
void ruby_init(void);
void *ruby_options(int, char**);
int ruby_run_node(void *);
int ruby_exec_node(void *);
int ruby_executable_node(void *n, int *status);
RUBY_EXTERN VALUE rb_mKernel;
RUBY_EXTERN VALUE rb_mComparable;
RUBY_EXTERN VALUE rb_mEnumerable;
RUBY_EXTERN VALUE rb_mErrno;
RUBY_EXTERN VALUE rb_mFileTest;
RUBY_EXTERN VALUE rb_mGC;
RUBY_EXTERN VALUE rb_mMath;
RUBY_EXTERN VALUE rb_mProcess;
RUBY_EXTERN VALUE rb_mWaitReadable;
RUBY_EXTERN VALUE rb_mWaitWritable;
RUBY_EXTERN VALUE rb_cBasicObject;
RUBY_EXTERN VALUE rb_cObject;
RUBY_EXTERN VALUE rb_cArray;
RUBY_EXTERN VALUE rb_cBignum;
RUBY_EXTERN VALUE rb_cBinding;
RUBY_EXTERN VALUE rb_cClass;
RUBY_EXTERN VALUE rb_cCont;
RUBY_EXTERN VALUE rb_cDir;
RUBY_EXTERN VALUE rb_cData;
RUBY_EXTERN VALUE rb_cFalseClass;
RUBY_EXTERN VALUE rb_cEncoding;
RUBY_EXTERN VALUE rb_cEnumerator;
RUBY_EXTERN VALUE rb_cFile;
RUBY_EXTERN VALUE rb_cFixnum;
RUBY_EXTERN VALUE rb_cFloat;
RUBY_EXTERN VALUE rb_cHash;
RUBY_EXTERN VALUE rb_cInteger;
RUBY_EXTERN VALUE rb_cIO;
RUBY_EXTERN VALUE rb_cMatch;
RUBY_EXTERN VALUE rb_cMethod;
RUBY_EXTERN VALUE rb_cModule;
RUBY_EXTERN VALUE rb_cNameErrorMesg;
RUBY_EXTERN VALUE rb_cNilClass;
RUBY_EXTERN VALUE rb_cNumeric;
RUBY_EXTERN VALUE rb_cProc;
RUBY_EXTERN VALUE rb_cRandom;
RUBY_EXTERN VALUE rb_cRange;
RUBY_EXTERN VALUE rb_cRational;
RUBY_EXTERN VALUE rb_cComplex;
RUBY_EXTERN VALUE rb_cRegexp;
RUBY_EXTERN VALUE rb_cStat;
RUBY_EXTERN VALUE rb_cString;
RUBY_EXTERN VALUE rb_cStruct;
RUBY_EXTERN VALUE rb_cSymbol;
RUBY_EXTERN VALUE rb_cThread;
RUBY_EXTERN VALUE rb_cTime;
RUBY_EXTERN VALUE rb_cTrueClass;
RUBY_EXTERN VALUE rb_cUnboundMethod;
RUBY_EXTERN VALUE rb_eException;
RUBY_EXTERN VALUE rb_eStandardError;
RUBY_EXTERN VALUE rb_eSystemExit;
RUBY_EXTERN VALUE rb_eInterrupt;
RUBY_EXTERN VALUE rb_eSignal;
RUBY_EXTERN VALUE rb_eFatal;
RUBY_EXTERN VALUE rb_eArgError;
RUBY_EXTERN VALUE rb_eEOFError;
RUBY_EXTERN VALUE rb_eIndexError;
RUBY_EXTERN VALUE rb_eStopIteration;
RUBY_EXTERN VALUE rb_eKeyError;
RUBY_EXTERN VALUE rb_eRangeError;
RUBY_EXTERN VALUE rb_eIOError;
RUBY_EXTERN VALUE rb_eRuntimeError;
RUBY_EXTERN VALUE rb_eSecurityError;
RUBY_EXTERN VALUE rb_eSystemCallError;
RUBY_EXTERN VALUE rb_eThreadError;
RUBY_EXTERN VALUE rb_eTypeError;
RUBY_EXTERN VALUE rb_eZeroDivError;
RUBY_EXTERN VALUE rb_eNotImpError;
RUBY_EXTERN VALUE rb_eNoMemError;
RUBY_EXTERN VALUE rb_eNoMethodError;
RUBY_EXTERN VALUE rb_eFloatDomainError;
RUBY_EXTERN VALUE rb_eLocalJumpError;
RUBY_EXTERN VALUE rb_eSysStackError;
RUBY_EXTERN VALUE rb_eRegexpError;
RUBY_EXTERN VALUE rb_eEncodingError;
RUBY_EXTERN VALUE rb_eEncCompatError;
RUBY_EXTERN VALUE rb_eScriptError;
RUBY_EXTERN VALUE rb_eNameError;
RUBY_EXTERN VALUE rb_eSyntaxError;
RUBY_EXTERN VALUE rb_eLoadError;
RUBY_EXTERN VALUE rb_eMathDomainError;
RUBY_EXTERN VALUE rb_stdin, rb_stdout, rb_stderr;
static inline VALUE
rb_class_of(VALUE obj)
{
if (IMMEDIATE_P(obj)) {
if (FIXNUM_P(obj)) return rb_cFixnum;
if (obj == Qtrue) return rb_cTrueClass;
if (SYMBOL_P(obj)) return rb_cSymbol;
}
else if (!RTEST(obj)) {
if (obj == Qnil) return rb_cNilClass;
if (obj == Qfalse) return rb_cFalseClass;
}
return RBASIC(obj)->klass;
}
static inline int
rb_type(VALUE obj)
{
if (IMMEDIATE_P(obj)) {
if (FIXNUM_P(obj)) return T_FIXNUM;
if (obj == Qtrue) return T_TRUE;
if (SYMBOL_P(obj)) return T_SYMBOL;
if (obj == Qundef) return T_UNDEF;
}
else if (!RTEST(obj)) {
if (obj == Qnil) return T_NIL;
if (obj == Qfalse) return T_FALSE;
}
return BUILTIN_TYPE(obj);
}
#define RB_TYPE_P(obj, type) ( \
((type) == T_FIXNUM) ? FIXNUM_P(obj) : \
((type) == T_TRUE) ? ((obj) == Qtrue) : \
((type) == T_FALSE) ? ((obj) == Qfalse) : \
((type) == T_NIL) ? ((obj) == Qnil) : \
((type) == T_UNDEF) ? ((obj) == Qundef) : \
((type) == T_SYMBOL) ? SYMBOL_P(obj) : \
(!SPECIAL_CONST_P(obj) && BUILTIN_TYPE(obj) == (type)))
#ifdef __GNUC__
#define rb_type_p(obj, type) \
__extension__ (__builtin_constant_p(type) ? RB_TYPE_P(obj, type) : \
rb_type(obj) == (type))
#else
#define rb_type_p(obj, type) (rb_type(obj) == (type))
#endif
#ifdef __GNUC__
#define rb_special_const_p(obj) \
__extension__ ({VALUE special_const_obj = (obj); (int)(SPECIAL_CONST_P(special_const_obj) ? Qtrue : Qfalse);})
#else
static inline int
rb_special_const_p(VALUE obj)
{
if (SPECIAL_CONST_P(obj)) return (int)Qtrue;
return (int)Qfalse;
}
#endif
#include "ruby/missing.h"
#include "ruby/intern.h"
#if defined(EXTLIB) && defined(USE_DLN_A_OUT)
/* hook for external modules */
static char *dln_libs_to_be_linked[] = { EXTLIB, 0 };
#endif
#if (defined(__APPLE__) || defined(__NeXT__)) && defined(__MACH__)
#define RUBY_GLOBAL_SETUP /* use linker option to link startup code with ObjC support */
#else
#define RUBY_GLOBAL_SETUP
#endif
void ruby_sysinit(int *, char ***);
#define RUBY_VM 1 /* YARV */
#define HAVE_NATIVETHREAD
int ruby_native_thread_p(void);
#define RUBY_EVENT_NONE 0x0000
#define RUBY_EVENT_LINE 0x0001
#define RUBY_EVENT_CLASS 0x0002
#define RUBY_EVENT_END 0x0004
#define RUBY_EVENT_CALL 0x0008
#define RUBY_EVENT_RETURN 0x0010
#define RUBY_EVENT_C_CALL 0x0020
#define RUBY_EVENT_C_RETURN 0x0040
#define RUBY_EVENT_RAISE 0x0080
#define RUBY_EVENT_ALL 0xffff
#define RUBY_EVENT_VM 0x10000
#define RUBY_EVENT_SWITCH 0x20000
#define RUBY_EVENT_COVERAGE 0x40000
typedef unsigned int rb_event_flag_t;
typedef void (*rb_event_hook_func_t)(rb_event_flag_t, VALUE data, VALUE, ID, VALUE klass);
typedef struct rb_event_hook_struct {
rb_event_flag_t flag;
rb_event_hook_func_t func;
VALUE data;
struct rb_event_hook_struct *next;
} rb_event_hook_t;
#define RB_EVENT_HOOKS_HAVE_CALLBACK_DATA 1
void rb_add_event_hook(rb_event_hook_func_t func, rb_event_flag_t events,
VALUE data);
int rb_remove_event_hook(rb_event_hook_func_t func);
/* locale insensitive functions */
#define rb_isascii(c) ((unsigned long)(c) < 128)
int rb_isalnum(int c);
int rb_isalpha(int c);
int rb_isblank(int c);
int rb_iscntrl(int c);
int rb_isdigit(int c);
int rb_isgraph(int c);
int rb_islower(int c);
int rb_isprint(int c);
int rb_ispunct(int c);
int rb_isspace(int c);
int rb_isupper(int c);
int rb_isxdigit(int c);
int rb_tolower(int c);
int rb_toupper(int c);
#ifndef ISPRINT
#define ISASCII(c) rb_isascii((unsigned char)(c))
#undef ISPRINT
#define ISPRINT(c) rb_isprint((unsigned char)(c))
#define ISSPACE(c) rb_isspace((unsigned char)(c))
#define ISUPPER(c) rb_isupper((unsigned char)(c))
#define ISLOWER(c) rb_islower((unsigned char)(c))
#define ISALNUM(c) rb_isalnum((unsigned char)(c))
#define ISALPHA(c) rb_isalpha((unsigned char)(c))
#define ISDIGIT(c) rb_isdigit((unsigned char)(c))
#define ISXDIGIT(c) rb_isxdigit((unsigned char)(c))
#endif
#define TOUPPER(c) rb_toupper((unsigned char)(c))
#define TOLOWER(c) rb_tolower((unsigned char)(c))
int st_strcasecmp(const char *s1, const char *s2);
int st_strncasecmp(const char *s1, const char *s2, size_t n);
#define STRCASECMP(s1, s2) (st_strcasecmp(s1, s2))
#define STRNCASECMP(s1, s2, n) (st_strncasecmp(s1, s2, n))
unsigned long ruby_strtoul(const char *str, char **endptr, int base);
#define STRTOUL(str, endptr, base) (ruby_strtoul(str, endptr, base))
#define InitVM(ext) {void InitVM_##ext(void);InitVM_##ext();}
PRINTF_ARGS(int ruby_snprintf(char *str, size_t n, char const *fmt, ...), 3, 4);
int ruby_vsnprintf(char *str, size_t n, char const *fmt, va_list ap);
#if defined __GNUC__ && __GNUC__ >= 4
#pragma GCC visibility pop
#endif
#ifndef RUBY_DONT_SUBST
#include "ruby/subst.h"
#endif
#if defined(__cplusplus)
#if 0
{ /* satisfy cc-mode */
#endif
} /* extern "C" { */
#endif
#endif /* RUBY_RUBY_H */