d3/d22/imemo_8h_source.html

#ifndef INTERNAL_IMEMO_H                                 /*-*-C-*-vi:se ft=c:*/

#define INTERNAL_IMEMO_H

#include "ruby/internal/config.h"

#include <stddef.h>             /* for size_t */

#include "id_table.h"

#include "internal/array.h"     /* for rb_ary_hidden_new_fill */

#include "ruby/internal/stdbool.h"     /* for bool */

#include "ruby/ruby.h"          /* for rb_block_call_func_t */


#define IMEMO_MASK   0x0f


/* FL_USER0 to FL_USER3 is for type */

#define IMEMO_FL_USHIFT (FL_USHIFT + 4)

#define IMEMO_FL_USER0 FL_USER4

#define IMEMO_FL_USER1 FL_USER5

#define IMEMO_FL_USER2 FL_USER6

#define IMEMO_FL_USER3 FL_USER7

#define IMEMO_FL_USER4 FL_USER8

#define IMEMO_FL_USER5 FL_USER9

#define IMEMO_FL_USER6 FL_USER10


enum imemo_type {

    imemo_env            =  0,

    imemo_cref           =  1,

    imemo_svar           =  2,

    imemo_throw_data     =  3,

    imemo_ifunc          =  4,

    imemo_memo           =  5,

    imemo_ment           =  6,

    imemo_iseq           =  7,

    imemo_tmpbuf         =  8,

    imemo_cvar_entry     =  9,

    imemo_callinfo       = 10,

    imemo_callcache      = 11,

    imemo_constcache     = 12,

    imemo_fields   = 13,

};


/* CREF (Class REFerence) is defined in method.h */


struct vm_svar {

    VALUE flags;

    const VALUE cref_or_me;

    const VALUE lastline;

    const VALUE backref;

    const VALUE others;

};


struct vm_throw_data {

    VALUE flags;

    VALUE reserved;

    const VALUE throw_obj;

    const struct rb_control_frame_struct *catch_frame;

    int throw_state;

};


#define THROW_DATA_CONSUMED IMEMO_FL_USER0


/* IFUNC (Internal FUNCtion) */


struct vm_ifunc_argc {

#if SIZEOF_INT * 2 > SIZEOF_VALUE

    signed int min: (SIZEOF_VALUE * CHAR_BIT) / 2;

    signed int max: (SIZEOF_VALUE * CHAR_BIT) / 2;

#else

    int min, max;

#endif

};


struct vm_ifunc {

    VALUE flags;

    VALUE *svar_lep;

    rb_block_call_func_t func;

    const void *data;

    struct vm_ifunc_argc argc;

};


#define IFUNC_YIELD_OPTIMIZABLE IMEMO_FL_USER0


struct rb_imemo_tmpbuf_struct {

    VALUE flags;

    VALUE *ptr; /* malloc'ed buffer */

    size_t cnt; /* buffer size in VALUE */

};


struct MEMO {

    VALUE flags;

    VALUE reserved;

    const VALUE v1;

    const VALUE v2;

    union {

        long cnt;

        long state;

        const VALUE value;

        void (*func)(void);

    } u3;

};


#define IMEMO_NEW(T, type, v0) ((T *)rb_imemo_new((type), (v0), sizeof(T), false))

#define SHAREABLE_IMEMO_NEW(T, type, v0) ((T *)rb_imemo_new((type), (v0), sizeof(T), true))


/* ment is in method.h */


#define THROW_DATA_P(err) imemo_throw_data_p((VALUE)err)

#define MEMO_CAST(m) ((struct MEMO *)(m))

#define MEMO_FOR(type, value) ((type *)RARRAY_PTR(value))

#define NEW_MEMO_FOR(type, value) \

  ((value) = rb_ary_hidden_new_fill(type_roomof(type, VALUE)), MEMO_FOR(type, value))

#define NEW_PARTIAL_MEMO_FOR(type, value, member) \

  ((value) = rb_ary_hidden_new_fill(type_roomof(type, VALUE)), \

   rb_ary_set_len((value), offsetof(type, member) / sizeof(VALUE)), \

   MEMO_FOR(type, value))


#ifndef RUBY_RUBYPARSER_H

typedef struct rb_imemo_tmpbuf_struct rb_imemo_tmpbuf_t;

#endif

VALUE rb_imemo_new(enum imemo_type type, VALUE v0, size_t size, bool is_shareable);

VALUE rb_imemo_tmpbuf_new(void);

struct vm_ifunc *rb_vm_ifunc_new(rb_block_call_func_t func, const void *data, int min_argc, int max_argc);

static inline enum imemo_type imemo_type(VALUE imemo);

static inline int imemo_type_p(VALUE imemo, enum imemo_type imemo_type);

static inline bool imemo_throw_data_p(VALUE imemo);

static inline struct vm_ifunc *rb_vm_ifunc_proc_new(rb_block_call_func_t func, const void *data);

static inline void *RB_IMEMO_TMPBUF_PTR(VALUE v);

static inline void *rb_imemo_tmpbuf_set_ptr(VALUE v, void *ptr);

static inline void MEMO_V1_SET(struct MEMO *m, VALUE v);

static inline void MEMO_V2_SET(struct MEMO *m, VALUE v);


size_t rb_imemo_memsize(VALUE obj);

void rb_imemo_mark_and_move(VALUE obj, bool reference_updating);

void rb_imemo_free(VALUE obj);


RUBY_SYMBOL_EXPORT_BEGIN

const char *rb_imemo_name(enum imemo_type type);

RUBY_SYMBOL_EXPORT_END


static inline struct MEMO *

MEMO_NEW(VALUE a, VALUE b, VALUE c)

{

    struct MEMO *memo = IMEMO_NEW(struct MEMO, imemo_memo, 0);

    *((VALUE *)&memo->v1) = a;

    *((VALUE *)&memo->v2) = b;

    *((VALUE *)&memo->u3.value) = c;


    return memo;

}


static inline enum imemo_type

imemo_type(VALUE imemo)

{

    return (RBASIC(imemo)->flags >> FL_USHIFT) & IMEMO_MASK;

}


static inline int

imemo_type_p(VALUE imemo, enum imemo_type imemo_type)

{

    if (LIKELY(!RB_SPECIAL_CONST_P(imemo))) {

        /* fixed at compile time if imemo_type is given. */

        const VALUE mask = (IMEMO_MASK << FL_USHIFT) | RUBY_T_MASK;

        const VALUE expected_type = (imemo_type << FL_USHIFT) | T_IMEMO;

        /* fixed at runtime. */

        return expected_type == (RBASIC(imemo)->flags & mask);

    }

    else {

        return 0;

    }

}


#define IMEMO_TYPE_P(v, t) imemo_type_p((VALUE)(v), t)


static inline bool

imemo_throw_data_p(VALUE imemo)

{

    return RB_TYPE_P(imemo, T_IMEMO);

}


static inline struct vm_ifunc *

rb_vm_ifunc_proc_new(rb_block_call_func_t func, const void *data)

{

    return rb_vm_ifunc_new(func, data, 0, UNLIMITED_ARGUMENTS);

}


static inline void *

RB_IMEMO_TMPBUF_PTR(VALUE v)

{

    const struct rb_imemo_tmpbuf_struct *p = (const void *)v;

    return p->ptr;

}


static inline void *

rb_imemo_tmpbuf_set_ptr(VALUE v, void *ptr)

{

    return ((rb_imemo_tmpbuf_t *)v)->ptr = ptr;

}


static inline VALUE

rb_imemo_tmpbuf_new_from_an_RString(VALUE str)

{

    const void *src;

    VALUE imemo;

    rb_imemo_tmpbuf_t *tmpbuf;

    void *dst;

    size_t len;


    StringValue(str);

    /* create tmpbuf to keep the pointer before xmalloc */

    imemo = rb_imemo_tmpbuf_new();

    tmpbuf = (rb_imemo_tmpbuf_t *)imemo;

    len = RSTRING_LEN(str);

    src = RSTRING_PTR(str);

    dst = ruby_xmalloc(len);

    memcpy(dst, src, len);

    tmpbuf->ptr = dst;

    return imemo;

}


static inline void

MEMO_V1_SET(struct MEMO *m, VALUE v)

{

    RB_OBJ_WRITE(m, &m->v1, v);

}


static inline void

MEMO_V2_SET(struct MEMO *m, VALUE v)

{

    RB_OBJ_WRITE(m, &m->v2, v);

}


struct rb_fields {

    struct RBasic basic;

    union {

        struct {

            VALUE fields[1];

        } embed;

        struct {

            VALUE *ptr;

        } external;

        struct {

            // Note: the st_table could be embedded, but complex T_CLASS should be rare to

            // non-existent, so not really worth the trouble.

            st_table *table;

        } complex;

    } as;

};


// IMEMO/fields and T_OBJECT have exactly the same layout.

// This is useful for JIT and common codepaths.

#define OBJ_FIELD_HEAP ROBJECT_HEAP

STATIC_ASSERT(imemo_fields_flags, OBJ_FIELD_HEAP == IMEMO_FL_USER0);

STATIC_ASSERT(imemo_fields_embed_offset, offsetof(struct RObject, as.ary) == offsetof(struct rb_fields, as.embed.fields));

STATIC_ASSERT(imemo_fields_embed_offset, offsetof(struct RObject, as.heap.fields) == offsetof(struct rb_fields, as.external.ptr));

STATIC_ASSERT(imemo_fields_embed_offset, offsetof(struct RObject, as.heap.fields) == offsetof(struct rb_fields, as.complex.table));


#define IMEMO_OBJ_FIELDS(fields) ((struct rb_fields *)fields)


VALUE rb_imemo_fields_new(VALUE owner, size_t capa, bool shareable);

VALUE rb_imemo_fields_new_complex(VALUE owner, size_t capa, bool shareable);

VALUE rb_imemo_fields_new_complex_tbl(VALUE owner, st_table *tbl, bool shareable);

VALUE rb_imemo_fields_clone(VALUE fields_obj);

void rb_imemo_fields_clear(VALUE fields_obj);


static inline VALUE

rb_imemo_fields_owner(VALUE fields_obj)

{

    RUBY_ASSERT(IMEMO_TYPE_P(fields_obj, imemo_fields));


    return CLASS_OF(fields_obj);

}


static inline VALUE *

rb_imemo_fields_ptr(VALUE fields_obj)

{

    if (!fields_obj) {

        return NULL;

    }


    RUBY_ASSERT(IMEMO_TYPE_P(fields_obj, imemo_fields) || RB_TYPE_P(fields_obj, T_OBJECT));


    if (UNLIKELY(FL_TEST_RAW(fields_obj, OBJ_FIELD_HEAP))) {

        return IMEMO_OBJ_FIELDS(fields_obj)->as.external.ptr;

    }

    else {

        return IMEMO_OBJ_FIELDS(fields_obj)->as.embed.fields;

    }

}


static inline st_table *

rb_imemo_fields_complex_tbl(VALUE fields_obj)

{

    if (!fields_obj) {

        return NULL;

    }


    RUBY_ASSERT(IMEMO_TYPE_P(fields_obj, imemo_fields) || RB_TYPE_P(fields_obj, T_OBJECT));

    RUBY_ASSERT(FL_TEST_RAW(fields_obj, OBJ_FIELD_HEAP));


    // Some codepaths unconditionally access the fields_ptr, and assume it can be used as st_table if the

    // shape is too_complex.

    RUBY_ASSERT((st_table *)rb_imemo_fields_ptr(fields_obj) == IMEMO_OBJ_FIELDS(fields_obj)->as.complex.table);


    return IMEMO_OBJ_FIELDS(fields_obj)->as.complex.table;

}


#endif /* INTERNAL_IMEMO_H */

RUBY_ASSERT
#define RUBY_ASSERT(...)
Asserts that the given expression is truthy if and only if RUBY_DEBUG is truthy.
Definition assert.h:219

T_IMEMO
#define T_IMEMO
Old name of RUBY_T_IMEMO.
Definition value_type.h:67

CLASS_OF
#define CLASS_OF
Old name of rb_class_of.
Definition globals.h:205

FL_TEST_RAW
#define FL_TEST_RAW
Old name of RB_FL_TEST_RAW.
Definition fl_type.h:131

T_OBJECT
#define T_OBJECT
Old name of RUBY_T_OBJECT.
Definition value_type.h:75

FL_USHIFT
#define FL_USHIFT
Old name of RUBY_FL_USHIFT.
Definition fl_type.h:68

RB_OBJ_WRITE
#define RB_OBJ_WRITE(old, slot, young)
Declaration of a "back" pointer.
Definition gc.h:603

UNLIMITED_ARGUMENTS
#define UNLIMITED_ARGUMENTS
This macro is used in conjunction with rb_check_arity().
Definition error.h:35

capa
int capa
Designed capacity of the buffer.
Definition io.h:11

len
int len
Length of the buffer.
Definition io.h:8

rb_block_call_func_t
rb_block_call_func * rb_block_call_func_t
Shorthand type that represents an iterator-written-in-C function pointer.
Definition iterator.h:88

ruby::backward::cxxanyargs::type
VALUE type(ANYARGS)
ANYARGS-ed function type.
Definition cxxanyargs.hpp:56

RBASIC
#define RBASIC(obj)
Convenient casting macro.
Definition rbasic.h:40

StringValue
#define StringValue(v)
Ensures that the parameter object is a String.
Definition rstring.h:66

ruby.h

RB_SPECIAL_CONST_P
static bool RB_SPECIAL_CONST_P(VALUE obj)
Checks if the given object is of enum ruby_special_consts.
Definition special_consts.h:327

stdbool.h
C99 shim for <stdbool.h>.

MEMO
MEMO.
Definition imemo.h:105

RBasic
Ruby object's base components.
Definition rbasic.h:69

RObject
Ruby's ordinal objects.
Definition robject.h:85

RObject::fields
VALUE * fields
Pointer to a C array that holds instance variables.
Definition robject.h:99

RObject::heap
struct RObject::@210145204263252121304200074116325373231002256127::@364327012272247144206277021107154033016101046306 heap
Object that use separated memory region for instance variables use this pattern.

rb_control_frame_struct
Definition vm_core.h:911

rb_fields
Definition imemo.h:248

rb_imemo_tmpbuf_struct
Definition imemo.h:95

st_table
Definition st.h:79

vm_ifunc_argc
Definition imemo.h:71

vm_ifunc
IFUNC (Internal FUNCtion).
Definition imemo.h:86

vm_svar
SVAR (Special VARiable).
Definition imemo.h:50

vm_svar::cref_or_me
const VALUE cref_or_me
class reference or rb_method_entry_t
Definition imemo.h:52

vm_throw_data
THROW_DATA.
Definition imemo.h:59

SIZEOF_VALUE
#define SIZEOF_VALUE
Identical to sizeof(VALUE), except it is a macro that can also be used inside of preprocessor directi...
Definition value.h:69

VALUE
uintptr_t VALUE
Type that represents a Ruby object.
Definition value.h:40

RB_TYPE_P
static bool RB_TYPE_P(VALUE obj, enum ruby_value_type t)
Queries if the given object is of given type.
Definition value_type.h:376

RUBY_T_MASK
@ RUBY_T_MASK
Bitmask of ruby_value_type.
Definition value_type.h:145