/********************************************************************** variable.c - $Author$ created at: Tue Apr 19 23:55:15 JST 1994 Copyright (C) 1993-2007 Yukihiro Matsumoto Copyright (C) 2000 Network Applied Communication Laboratory, Inc. Copyright (C) 2000 Information-technology Promotion Agency, Japan **********************************************************************/ #include "ruby/internal/config.h" #include #include "ruby/internal/stdbool.h" #include "ccan/list/list.h" #include "constant.h" #include "debug_counter.h" #include "id.h" #include "id_table.h" #include "internal.h" #include "internal/class.h" #include "internal/compilers.h" #include "internal/error.h" #include "internal/eval.h" #include "internal/hash.h" #include "internal/object.h" #include "internal/re.h" #include "internal/symbol.h" #include "internal/thread.h" #include "internal/variable.h" #include "ruby/encoding.h" #include "ruby/st.h" #include "ruby/util.h" #include "transient_heap.h" #include "variable.h" #include "vm_core.h" #include "ractor_core.h" #include "vm_sync.h" RUBY_EXTERN rb_serial_t ruby_vm_global_cvar_state; #define GET_GLOBAL_CVAR_STATE() (ruby_vm_global_cvar_state) typedef void rb_gvar_compact_t(void *var); static struct rb_id_table *rb_global_tbl; static ID autoload, classpath, tmp_classpath; // This hash table maps file paths to loadable features. We use this to track // autoload state until it's no longer needed. // feature (file path) => struct autoload_data static VALUE autoload_features; // This mutex is used to protect autoloading state. We use a global mutex which // is held until a per-feature mutex can be created. This ensures there are no // race conditions relating to autoload state. static VALUE autoload_mutex; static void check_before_mod_set(VALUE, ID, VALUE, const char *); static void setup_const_entry(rb_const_entry_t *, VALUE, VALUE, rb_const_flag_t); static VALUE rb_const_search(VALUE klass, ID id, int exclude, int recurse, int visibility); static st_table *generic_iv_tbl_; struct ivar_update { union { st_table *iv_index_tbl; struct gen_ivtbl *ivtbl; } u; st_data_t index; int iv_extended; }; void Init_var_tables(void) { rb_global_tbl = rb_id_table_create(0); generic_iv_tbl_ = st_init_numtable(); autoload = rb_intern_const("__autoload__"); /* __classpath__: fully qualified class path */ classpath = rb_intern_const("__classpath__"); /* __tmp_classpath__: temporary class path which contains anonymous names */ tmp_classpath = rb_intern_const("__tmp_classpath__"); autoload_mutex = rb_mutex_new(); rb_obj_hide(autoload_mutex); rb_gc_register_mark_object(autoload_mutex); autoload_features = rb_ident_hash_new(); rb_obj_hide(autoload_features); rb_gc_register_mark_object(autoload_features); } static inline bool rb_namespace_p(VALUE obj) { if (RB_SPECIAL_CONST_P(obj)) return false; switch (RB_BUILTIN_TYPE(obj)) { case T_MODULE: case T_CLASS: return true; default: break; } return false; } /** * Returns +classpath+ of _klass_, if it is named, or +nil+ for * anonymous +class+/+module+. A named +classpath+ may contain * an anonymous component, but the last component is guaranteed * to not be anonymous. *permanent is set to 1 * if +classpath+ has no anonymous components. There is no builtin * Ruby level APIs that can change a permanent +classpath+. */ static VALUE classname(VALUE klass, int *permanent) { st_table *ivtbl; st_data_t n; *permanent = 0; if (!RCLASS_EXT(klass)) return Qnil; if (!(ivtbl = RCLASS_IV_TBL(klass))) return Qnil; if (st_lookup(ivtbl, (st_data_t)classpath, &n)) { *permanent = 1; return (VALUE)n; } if (st_lookup(ivtbl, (st_data_t)tmp_classpath, &n)) return (VALUE)n; return Qnil; } /* * call-seq: * mod.name -> string * * Returns the name of the module mod. Returns nil for anonymous modules. */ VALUE rb_mod_name(VALUE mod) { int permanent; return classname(mod, &permanent); } static VALUE make_temporary_path(VALUE obj, VALUE klass) { VALUE path; switch (klass) { case Qnil: path = rb_sprintf("#", (void*)obj); break; case Qfalse: path = rb_sprintf("#", (void*)obj); break; default: path = rb_sprintf("#<%"PRIsVALUE":%p>", klass, (void*)obj); break; } OBJ_FREEZE(path); return path; } typedef VALUE (*fallback_func)(VALUE obj, VALUE name); static VALUE rb_tmp_class_path(VALUE klass, int *permanent, fallback_func fallback) { VALUE path = classname(klass, permanent); if (!NIL_P(path)) { return path; } else { if (RB_TYPE_P(klass, T_MODULE)) { if (rb_obj_class(klass) == rb_cModule) { path = Qfalse; } else { int perm; path = rb_tmp_class_path(RBASIC(klass)->klass, &perm, fallback); } } *permanent = 0; return fallback(klass, path); } } VALUE rb_class_path(VALUE klass) { int permanent; VALUE path = rb_tmp_class_path(klass, &permanent, make_temporary_path); if (!NIL_P(path)) path = rb_str_dup(path); return path; } VALUE rb_class_path_cached(VALUE klass) { return rb_mod_name(klass); } static VALUE no_fallback(VALUE obj, VALUE name) { return name; } VALUE rb_search_class_path(VALUE klass) { int permanent; return rb_tmp_class_path(klass, &permanent, no_fallback); } static VALUE build_const_pathname(VALUE head, VALUE tail) { VALUE path = rb_str_dup(head); rb_str_cat2(path, "::"); rb_str_append(path, tail); return rb_fstring(path); } static VALUE build_const_path(VALUE head, ID tail) { return build_const_pathname(head, rb_id2str(tail)); } void rb_set_class_path_string(VALUE klass, VALUE under, VALUE name) { VALUE str; ID pathid = classpath; if (under == rb_cObject) { str = rb_str_new_frozen(name); } else { int permanent; str = rb_tmp_class_path(under, &permanent, make_temporary_path); str = build_const_pathname(str, name); if (!permanent) { pathid = tmp_classpath; } } rb_ivar_set(klass, pathid, str); } void rb_set_class_path(VALUE klass, VALUE under, const char *name) { VALUE str = rb_str_new2(name); OBJ_FREEZE(str); rb_set_class_path_string(klass, under, str); } VALUE rb_path_to_class(VALUE pathname) { rb_encoding *enc = rb_enc_get(pathname); const char *pbeg, *pend, *p, *path = RSTRING_PTR(pathname); ID id; VALUE c = rb_cObject; if (!rb_enc_asciicompat(enc)) { rb_raise(rb_eArgError, "invalid class path encoding (non ASCII)"); } pbeg = p = path; pend = path + RSTRING_LEN(pathname); if (path == pend || path[0] == '#') { rb_raise(rb_eArgError, "can't retrieve anonymous class %"PRIsVALUE, QUOTE(pathname)); } while (p < pend) { while (p < pend && *p != ':') p++; id = rb_check_id_cstr(pbeg, p-pbeg, enc); if (p < pend && p[0] == ':') { if ((size_t)(pend - p) < 2 || p[1] != ':') goto undefined_class; p += 2; pbeg = p; } if (!id) { goto undefined_class; } c = rb_const_search(c, id, TRUE, FALSE, FALSE); if (c == Qundef) goto undefined_class; if (!rb_namespace_p(c)) { rb_raise(rb_eTypeError, "%"PRIsVALUE" does not refer to class/module", pathname); } } RB_GC_GUARD(pathname); return c; undefined_class: rb_raise(rb_eArgError, "undefined class/module % "PRIsVALUE, rb_str_subseq(pathname, 0, p-path)); UNREACHABLE_RETURN(Qundef); } VALUE rb_path2class(const char *path) { return rb_path_to_class(rb_str_new_cstr(path)); } VALUE rb_class_name(VALUE klass) { return rb_class_path(rb_class_real(klass)); } const char * rb_class2name(VALUE klass) { int permanent; VALUE path = rb_tmp_class_path(rb_class_real(klass), &permanent, make_temporary_path); if (NIL_P(path)) return NULL; return RSTRING_PTR(path); } const char * rb_obj_classname(VALUE obj) { return rb_class2name(CLASS_OF(obj)); } struct trace_var { int removed; void (*func)(VALUE arg, VALUE val); VALUE data; struct trace_var *next; }; struct rb_global_variable { int counter; int block_trace; VALUE *data; rb_gvar_getter_t *getter; rb_gvar_setter_t *setter; rb_gvar_marker_t *marker; rb_gvar_compact_t *compactor; struct trace_var *trace; }; struct rb_global_entry { struct rb_global_variable *var; ID id; bool ractor_local; }; static struct rb_global_entry* rb_find_global_entry(ID id) { struct rb_global_entry *entry; VALUE data; if (!rb_id_table_lookup(rb_global_tbl, id, &data)) { entry = NULL; } else { entry = (struct rb_global_entry *)data; RUBY_ASSERT(entry != NULL); } if (UNLIKELY(!rb_ractor_main_p()) && (!entry || !entry->ractor_local)) { rb_raise(rb_eRactorIsolationError, "can not access global variables %s from non-main Ractors", rb_id2name(id)); } return entry; } void rb_gvar_ractor_local(const char *name) { struct rb_global_entry *entry = rb_find_global_entry(rb_intern(name)); entry->ractor_local = true; } static void rb_gvar_undef_compactor(void *var) { } static struct rb_global_entry* rb_global_entry(ID id) { struct rb_global_entry *entry = rb_find_global_entry(id); if (!entry) { struct rb_global_variable *var; entry = ALLOC(struct rb_global_entry); var = ALLOC(struct rb_global_variable); entry->id = id; entry->var = var; entry->ractor_local = false; var->counter = 1; var->data = 0; var->getter = rb_gvar_undef_getter; var->setter = rb_gvar_undef_setter; var->marker = rb_gvar_undef_marker; var->compactor = rb_gvar_undef_compactor; var->block_trace = 0; var->trace = 0; rb_id_table_insert(rb_global_tbl, id, (VALUE)entry); } return entry; } VALUE rb_gvar_undef_getter(ID id, VALUE *_) { rb_warning("global variable `%"PRIsVALUE"' not initialized", QUOTE_ID(id)); return Qnil; } static void rb_gvar_val_compactor(void *_var) { struct rb_global_variable *var = (struct rb_global_variable *)_var; VALUE obj = (VALUE)var->data; if (obj) { VALUE new = rb_gc_location(obj); if (new != obj) { var->data = (void*)new; } } } void rb_gvar_undef_setter(VALUE val, ID id, VALUE *_) { struct rb_global_variable *var = rb_global_entry(id)->var; var->getter = rb_gvar_val_getter; var->setter = rb_gvar_val_setter; var->marker = rb_gvar_val_marker; var->compactor = rb_gvar_val_compactor; var->data = (void*)val; } void rb_gvar_undef_marker(VALUE *var) { } VALUE rb_gvar_val_getter(ID id, VALUE *data) { return (VALUE)data; } void rb_gvar_val_setter(VALUE val, ID id, VALUE *_) { struct rb_global_variable *var = rb_global_entry(id)->var; var->data = (void*)val; } void rb_gvar_val_marker(VALUE *var) { VALUE data = (VALUE)var; if (data) rb_gc_mark_movable(data); } VALUE rb_gvar_var_getter(ID id, VALUE *var) { if (!var) return Qnil; return *var; } void rb_gvar_var_setter(VALUE val, ID id, VALUE *data) { *data = val; } void rb_gvar_var_marker(VALUE *var) { if (var) rb_gc_mark_maybe(*var); } void rb_gvar_readonly_setter(VALUE v, ID id, VALUE *_) { rb_name_error(id, "%"PRIsVALUE" is a read-only variable", QUOTE_ID(id)); } static enum rb_id_table_iterator_result mark_global_entry(VALUE v, void *ignored) { struct rb_global_entry *entry = (struct rb_global_entry *)v; struct trace_var *trace; struct rb_global_variable *var = entry->var; (*var->marker)(var->data); trace = var->trace; while (trace) { if (trace->data) rb_gc_mark_maybe(trace->data); trace = trace->next; } return ID_TABLE_CONTINUE; } void rb_gc_mark_global_tbl(void) { if (rb_global_tbl) { rb_id_table_foreach_values(rb_global_tbl, mark_global_entry, 0); } } static enum rb_id_table_iterator_result update_global_entry(VALUE v, void *ignored) { struct rb_global_entry *entry = (struct rb_global_entry *)v; struct rb_global_variable *var = entry->var; (*var->compactor)(var); return ID_TABLE_CONTINUE; } void rb_gc_update_global_tbl(void) { if (rb_global_tbl) { rb_id_table_foreach_values(rb_global_tbl, update_global_entry, 0); } } static ID global_id(const char *name) { ID id; if (name[0] == '$') id = rb_intern(name); else { size_t len = strlen(name); VALUE vbuf = 0; char *buf = ALLOCV_N(char, vbuf, len+1); buf[0] = '$'; memcpy(buf+1, name, len); id = rb_intern2(buf, len+1); ALLOCV_END(vbuf); } return id; } static ID find_global_id(const char *name) { ID id; size_t len = strlen(name); if (name[0] == '$') { id = rb_check_id_cstr(name, len, NULL); } else { VALUE vbuf = 0; char *buf = ALLOCV_N(char, vbuf, len+1); buf[0] = '$'; memcpy(buf+1, name, len); id = rb_check_id_cstr(buf, len+1, NULL); ALLOCV_END(vbuf); } return id; } void rb_define_hooked_variable( const char *name, VALUE *var, rb_gvar_getter_t *getter, rb_gvar_setter_t *setter) { volatile VALUE tmp = var ? *var : Qnil; ID id = global_id(name); struct rb_global_variable *gvar = rb_global_entry(id)->var; gvar->data = (void*)var; gvar->getter = getter ? (rb_gvar_getter_t *)getter : rb_gvar_var_getter; gvar->setter = setter ? (rb_gvar_setter_t *)setter : rb_gvar_var_setter; gvar->marker = rb_gvar_var_marker; RB_GC_GUARD(tmp); } void rb_define_variable(const char *name, VALUE *var) { rb_define_hooked_variable(name, var, 0, 0); } void rb_define_readonly_variable(const char *name, const VALUE *var) { rb_define_hooked_variable(name, (VALUE *)var, 0, rb_gvar_readonly_setter); } void rb_define_virtual_variable( const char *name, rb_gvar_getter_t *getter, rb_gvar_setter_t *setter) { if (!getter) getter = rb_gvar_val_getter; if (!setter) setter = rb_gvar_readonly_setter; rb_define_hooked_variable(name, 0, getter, setter); } static void rb_trace_eval(VALUE cmd, VALUE val) { rb_eval_cmd_kw(cmd, rb_ary_new3(1, val), RB_NO_KEYWORDS); } VALUE rb_f_trace_var(int argc, const VALUE *argv) { VALUE var, cmd; struct rb_global_entry *entry; struct trace_var *trace; if (rb_scan_args(argc, argv, "11", &var, &cmd) == 1) { cmd = rb_block_proc(); } if (NIL_P(cmd)) { return rb_f_untrace_var(argc, argv); } entry = rb_global_entry(rb_to_id(var)); trace = ALLOC(struct trace_var); trace->next = entry->var->trace; trace->func = rb_trace_eval; trace->data = cmd; trace->removed = 0; entry->var->trace = trace; return Qnil; } static void remove_trace(struct rb_global_variable *var) { struct trace_var *trace = var->trace; struct trace_var t; struct trace_var *next; t.next = trace; trace = &t; while (trace->next) { next = trace->next; if (next->removed) { trace->next = next->next; xfree(next); } else { trace = next; } } var->trace = t.next; } VALUE rb_f_untrace_var(int argc, const VALUE *argv) { VALUE var, cmd; ID id; struct rb_global_entry *entry; struct trace_var *trace; rb_scan_args(argc, argv, "11", &var, &cmd); id = rb_check_id(&var); if (!id) { rb_name_error_str(var, "undefined global variable %"PRIsVALUE"", QUOTE(var)); } if ((entry = rb_find_global_entry(id)) == NULL) { rb_name_error(id, "undefined global variable %"PRIsVALUE"", QUOTE_ID(id)); } trace = entry->var->trace; if (NIL_P(cmd)) { VALUE ary = rb_ary_new(); while (trace) { struct trace_var *next = trace->next; rb_ary_push(ary, (VALUE)trace->data); trace->removed = 1; trace = next; } if (!entry->var->block_trace) remove_trace(entry->var); return ary; } else { while (trace) { if (trace->data == cmd) { trace->removed = 1; if (!entry->var->block_trace) remove_trace(entry->var); return rb_ary_new3(1, cmd); } trace = trace->next; } } return Qnil; } struct trace_data { struct trace_var *trace; VALUE val; }; static VALUE trace_ev(VALUE v) { struct trace_data *data = (void *)v; struct trace_var *trace = data->trace; while (trace) { (*trace->func)(trace->data, data->val); trace = trace->next; } return Qnil; } static VALUE trace_en(VALUE v) { struct rb_global_variable *var = (void *)v; var->block_trace = 0; remove_trace(var); return Qnil; /* not reached */ } static VALUE rb_gvar_set_entry(struct rb_global_entry *entry, VALUE val) { struct trace_data trace; struct rb_global_variable *var = entry->var; (*var->setter)(val, entry->id, var->data); if (var->trace && !var->block_trace) { var->block_trace = 1; trace.trace = var->trace; trace.val = val; rb_ensure(trace_ev, (VALUE)&trace, trace_en, (VALUE)var); } return val; } VALUE rb_gvar_set(ID id, VALUE val) { struct rb_global_entry *entry; entry = rb_global_entry(id); return rb_gvar_set_entry(entry, val); } VALUE rb_gv_set(const char *name, VALUE val) { return rb_gvar_set(global_id(name), val); } VALUE rb_gvar_get(ID id) { struct rb_global_entry *entry = rb_global_entry(id); struct rb_global_variable *var = entry->var; return (*var->getter)(entry->id, var->data); } VALUE rb_gv_get(const char *name) { ID id = find_global_id(name); if (!id) { rb_warning("global variable `%s' not initialized", name); return Qnil; } return rb_gvar_get(id); } MJIT_FUNC_EXPORTED VALUE rb_gvar_defined(ID id) { struct rb_global_entry *entry = rb_global_entry(id); return RBOOL(entry->var->getter != rb_gvar_undef_getter); } rb_gvar_getter_t * rb_gvar_getter_function_of(ID id) { const struct rb_global_entry *entry = rb_global_entry(id); return entry->var->getter; } rb_gvar_setter_t * rb_gvar_setter_function_of(ID id) { const struct rb_global_entry *entry = rb_global_entry(id); return entry->var->setter; } static enum rb_id_table_iterator_result gvar_i(ID key, VALUE val, void *a) { VALUE ary = (VALUE)a; rb_ary_push(ary, ID2SYM(key)); return ID_TABLE_CONTINUE; } VALUE rb_f_global_variables(void) { VALUE ary = rb_ary_new(); VALUE sym, backref = rb_backref_get(); if (!rb_ractor_main_p()) { rb_raise(rb_eRactorIsolationError, "can not access global variables from non-main Ractors"); } rb_id_table_foreach(rb_global_tbl, gvar_i, (void *)ary); if (!NIL_P(backref)) { char buf[2]; int i, nmatch = rb_match_count(backref); buf[0] = '$'; for (i = 1; i <= nmatch; ++i) { if (!rb_match_nth_defined(i, backref)) continue; if (i < 10) { /* probably reused, make static ID */ buf[1] = (char)(i + '0'); sym = ID2SYM(rb_intern2(buf, 2)); } else { /* dynamic symbol */ sym = rb_str_intern(rb_sprintf("$%d", i)); } rb_ary_push(ary, sym); } } return ary; } void rb_alias_variable(ID name1, ID name2) { struct rb_global_entry *entry1, *entry2; VALUE data1; struct rb_id_table *gtbl = rb_global_tbl; if (!rb_ractor_main_p()) { rb_raise(rb_eRactorIsolationError, "can not access global variables from non-main Ractors"); } entry2 = rb_global_entry(name2); if (!rb_id_table_lookup(gtbl, name1, &data1)) { entry1 = ALLOC(struct rb_global_entry); entry1->id = name1; rb_id_table_insert(gtbl, name1, (VALUE)entry1); } else if ((entry1 = (struct rb_global_entry *)data1)->var != entry2->var) { struct rb_global_variable *var = entry1->var; if (var->block_trace) { rb_raise(rb_eRuntimeError, "can't alias in tracer"); } var->counter--; if (var->counter == 0) { struct trace_var *trace = var->trace; while (trace) { struct trace_var *next = trace->next; xfree(trace); trace = next; } xfree(var); } } else { return; } entry2->var->counter++; entry1->var = entry2->var; } static bool iv_index_tbl_lookup(struct st_table *tbl, ID id, uint32_t *indexp) { st_data_t ent_data; int r; if (tbl == NULL) return false; RB_VM_LOCK_ENTER(); { r = st_lookup(tbl, (st_data_t)id, &ent_data); } RB_VM_LOCK_LEAVE(); if (r) { struct rb_iv_index_tbl_entry *ent = (void *)ent_data; *indexp = ent->index; return true; } else { return false; } } static void IVAR_ACCESSOR_SHOULD_BE_MAIN_RACTOR(ID id) { if (UNLIKELY(!rb_ractor_main_p())) { if (rb_is_instance_id(id)) { // check only normal ivars rb_raise(rb_eRactorIsolationError, "can not set instance variables of classes/modules by non-main Ractors"); } } } #define CVAR_ACCESSOR_SHOULD_BE_MAIN_RACTOR() \ if (UNLIKELY(!rb_ractor_main_p())) { \ rb_raise(rb_eRactorIsolationError, "can not access class variables from non-main Ractors"); \ } static inline struct st_table * generic_ivtbl(VALUE obj, ID id, bool force_check_ractor) { ASSERT_vm_locking(); if ((force_check_ractor || LIKELY(rb_is_instance_id(id)) /* not internal ID */ ) && !RB_OBJ_FROZEN_RAW(obj) && UNLIKELY(!rb_ractor_main_p()) && UNLIKELY(rb_ractor_shareable_p(obj))) { rb_raise(rb_eRactorIsolationError, "can not access instance variables of shareable objects from non-main Ractors"); } return generic_iv_tbl_; } static inline struct st_table * generic_ivtbl_no_ractor_check(VALUE obj) { return generic_ivtbl(obj, 0, false); } static int gen_ivtbl_get(VALUE obj, ID id, struct gen_ivtbl **ivtbl) { st_data_t data; int r = 0; RB_VM_LOCK_ENTER(); { if (st_lookup(generic_ivtbl(obj, id, false), (st_data_t)obj, &data)) { *ivtbl = (struct gen_ivtbl *)data; r = 1; } } RB_VM_LOCK_LEAVE(); return r; } MJIT_FUNC_EXPORTED int rb_ivar_generic_ivtbl_lookup(VALUE obj, struct gen_ivtbl **ivtbl) { return gen_ivtbl_get(obj, 0, ivtbl); } MJIT_FUNC_EXPORTED VALUE rb_ivar_generic_lookup_with_index(VALUE obj, ID id, uint32_t index) { struct gen_ivtbl *ivtbl; if (gen_ivtbl_get(obj, id, &ivtbl)) { if (LIKELY(index < ivtbl->numiv)) { VALUE val = ivtbl->ivptr[index]; return val; } } return Qundef; } static VALUE generic_ivar_delete(VALUE obj, ID id, VALUE undef) { struct gen_ivtbl *ivtbl; if (gen_ivtbl_get(obj, id, &ivtbl)) { st_table *iv_index_tbl = RCLASS_IV_INDEX_TBL(rb_obj_class(obj)); uint32_t index; if (iv_index_tbl && iv_index_tbl_lookup(iv_index_tbl, id, &index)) { if (index < ivtbl->numiv) { VALUE ret = ivtbl->ivptr[index]; ivtbl->ivptr[index] = Qundef; return ret == Qundef ? undef : ret; } } } return undef; } static VALUE generic_ivar_get(VALUE obj, ID id, VALUE undef) { struct gen_ivtbl *ivtbl; if (gen_ivtbl_get(obj, id, &ivtbl)) { st_table *iv_index_tbl = RCLASS_IV_INDEX_TBL(rb_obj_class(obj)); uint32_t index; if (iv_index_tbl && iv_index_tbl_lookup(iv_index_tbl, id, &index)) { if (index < ivtbl->numiv) { VALUE ret = ivtbl->ivptr[index]; return ret == Qundef ? undef : ret; } } } return undef; } static size_t gen_ivtbl_bytes(size_t n) { return offsetof(struct gen_ivtbl, ivptr) + n * sizeof(VALUE); } static struct gen_ivtbl * gen_ivtbl_resize(struct gen_ivtbl *old, uint32_t n) { uint32_t len = old ? old->numiv : 0; struct gen_ivtbl *ivtbl = xrealloc(old, gen_ivtbl_bytes(n)); ivtbl->numiv = n; for (; len < n; len++) { ivtbl->ivptr[len] = Qundef; } return ivtbl; } #if 0 static struct gen_ivtbl * gen_ivtbl_dup(const struct gen_ivtbl *orig) { size_t s = gen_ivtbl_bytes(orig->numiv); struct gen_ivtbl *ivtbl = xmalloc(s); memcpy(ivtbl, orig, s); return ivtbl; } #endif static uint32_t iv_index_tbl_newsize(struct ivar_update *ivup) { if (!ivup->iv_extended) { return (uint32_t)ivup->u.iv_index_tbl->num_entries; } else { uint32_t index = (uint32_t)ivup->index; /* should not overflow */ return (index+1) + (index+1)/4; /* (index+1)*1.25 */ } } static int generic_ivar_update(st_data_t *k, st_data_t *v, st_data_t u, int existing) { ASSERT_vm_locking(); struct ivar_update *ivup = (struct ivar_update *)u; struct gen_ivtbl *ivtbl = 0; if (existing) { ivtbl = (struct gen_ivtbl *)*v; if (ivup->index < ivtbl->numiv) { ivup->u.ivtbl = ivtbl; return ST_STOP; } } FL_SET((VALUE)*k, FL_EXIVAR); uint32_t newsize = iv_index_tbl_newsize(ivup); ivtbl = gen_ivtbl_resize(ivtbl, newsize); *v = (st_data_t)ivtbl; ivup->u.ivtbl = ivtbl; return ST_CONTINUE; } static VALUE generic_ivar_defined(VALUE obj, ID id) { struct gen_ivtbl *ivtbl; st_table *iv_index_tbl = RCLASS_IV_INDEX_TBL(rb_obj_class(obj)); uint32_t index; if (!iv_index_tbl_lookup(iv_index_tbl, id, &index)) return Qfalse; if (!gen_ivtbl_get(obj, id, &ivtbl)) return Qfalse; return RBOOL((index < ivtbl->numiv) && (ivtbl->ivptr[index] != Qundef)); } static int generic_ivar_remove(VALUE obj, ID id, VALUE *valp) { struct gen_ivtbl *ivtbl; uint32_t index; st_table *iv_index_tbl = RCLASS_IV_INDEX_TBL(rb_obj_class(obj)); if (!iv_index_tbl) return 0; if (!iv_index_tbl_lookup(iv_index_tbl, id, &index)) return 0; if (!gen_ivtbl_get(obj, id, &ivtbl)) return 0; if (index < ivtbl->numiv) { if (ivtbl->ivptr[index] != Qundef) { *valp = ivtbl->ivptr[index]; ivtbl->ivptr[index] = Qundef; return 1; } } return 0; } static void gen_ivtbl_mark(const struct gen_ivtbl *ivtbl) { uint32_t i; for (i = 0; i < ivtbl->numiv; i++) { rb_gc_mark(ivtbl->ivptr[i]); } } void rb_mark_generic_ivar(VALUE obj) { struct gen_ivtbl *ivtbl; if (gen_ivtbl_get(obj, 0, &ivtbl)) { gen_ivtbl_mark(ivtbl); } } void rb_mv_generic_ivar(VALUE rsrc, VALUE dst) { st_data_t key = (st_data_t)rsrc; st_data_t ivtbl; if (st_delete(generic_ivtbl_no_ractor_check(rsrc), &key, &ivtbl)) st_insert(generic_ivtbl_no_ractor_check(dst), (st_data_t)dst, ivtbl); } void rb_free_generic_ivar(VALUE obj) { st_data_t key = (st_data_t)obj, ivtbl; if (st_delete(generic_ivtbl_no_ractor_check(obj), &key, &ivtbl)) xfree((struct gen_ivtbl *)ivtbl); } RUBY_FUNC_EXPORTED size_t rb_generic_ivar_memsize(VALUE obj) { struct gen_ivtbl *ivtbl; if (gen_ivtbl_get(obj, 0, &ivtbl)) return gen_ivtbl_bytes(ivtbl->numiv); return 0; } static size_t gen_ivtbl_count(const struct gen_ivtbl *ivtbl) { uint32_t i; size_t n = 0; for (i = 0; i < ivtbl->numiv; i++) { if (ivtbl->ivptr[i] != Qundef) { n++; } } return n; } static int lock_st_lookup(st_table *tab, st_data_t key, st_data_t *value) { int r; RB_VM_LOCK_ENTER(); { r = st_lookup(tab, key, value); } RB_VM_LOCK_LEAVE(); return r; } static int lock_st_delete(st_table *tab, st_data_t *key, st_data_t *value) { int r; RB_VM_LOCK_ENTER(); { r = st_delete(tab, key, value); } RB_VM_LOCK_LEAVE(); return r; } static int lock_st_is_member(st_table *tab, st_data_t key) { int r; RB_VM_LOCK_ENTER(); { r = st_is_member(tab, key); } RB_VM_LOCK_LEAVE(); return r; } static int lock_st_insert(st_table *tab, st_data_t key, st_data_t value) { int r; RB_VM_LOCK_ENTER(); { r = st_insert(tab, key, value); } RB_VM_LOCK_LEAVE(); return r; } VALUE rb_ivar_lookup(VALUE obj, ID id, VALUE undef) { if (SPECIAL_CONST_P(obj)) return undef; switch (BUILTIN_TYPE(obj)) { case T_OBJECT: { uint32_t index; uint32_t len = ROBJECT_NUMIV(obj); VALUE *ptr = ROBJECT_IVPTR(obj); VALUE val; if (iv_index_tbl_lookup(ROBJECT_IV_INDEX_TBL(obj), id, &index) && index < len && (val = ptr[index]) != Qundef) { return val; } else { break; } } case T_CLASS: case T_MODULE: { st_data_t val; if (RCLASS_IV_TBL(obj) && lock_st_lookup(RCLASS_IV_TBL(obj), (st_data_t)id, &val)) { if (rb_is_instance_id(id) && UNLIKELY(!rb_ractor_main_p()) && !rb_ractor_shareable_p(val)) { rb_raise(rb_eRactorIsolationError, "can not get unshareable values from instance variables of classes/modules from non-main Ractors"); } return val; } else { break; } } default: if (FL_TEST(obj, FL_EXIVAR)) return generic_ivar_get(obj, id, undef); break; } return undef; } VALUE rb_ivar_get(VALUE obj, ID id) { VALUE iv = rb_ivar_lookup(obj, id, Qnil); RB_DEBUG_COUNTER_INC(ivar_get_base); return iv; } VALUE rb_attr_get(VALUE obj, ID id) { return rb_ivar_lookup(obj, id, Qnil); } static VALUE rb_ivar_delete(VALUE obj, ID id, VALUE undef) { VALUE *ptr; struct st_table *iv_index_tbl; uint32_t len, index; rb_check_frozen(obj); switch (BUILTIN_TYPE(obj)) { case T_OBJECT: len = ROBJECT_NUMIV(obj); ptr = ROBJECT_IVPTR(obj); iv_index_tbl = ROBJECT_IV_INDEX_TBL(obj); if (iv_index_tbl_lookup(iv_index_tbl, id, &index) && index < len) { VALUE val = ptr[index]; ptr[index] = Qundef; if (val != Qundef) { return val; } } break; case T_CLASS: case T_MODULE: IVAR_ACCESSOR_SHOULD_BE_MAIN_RACTOR(id); if (RCLASS_IV_TBL(obj)) { st_data_t id_data = (st_data_t)id, val; if (lock_st_delete(RCLASS_IV_TBL(obj), &id_data, &val)) { return (VALUE)val; } } break; default: if (FL_TEST(obj, FL_EXIVAR)) return generic_ivar_delete(obj, id, undef); break; } return undef; } VALUE rb_attr_delete(VALUE obj, ID id) { return rb_ivar_delete(obj, id, Qnil); } static st_table * iv_index_tbl_make(VALUE obj, VALUE klass) { st_table *iv_index_tbl; if (UNLIKELY(!klass)) { rb_raise(rb_eTypeError, "hidden object cannot have instance variables"); } if ((iv_index_tbl = RCLASS_IV_INDEX_TBL(klass)) == NULL) { RB_VM_LOCK_ENTER(); if ((iv_index_tbl = RCLASS_IV_INDEX_TBL(klass)) == NULL) { iv_index_tbl = RCLASS_IV_INDEX_TBL(klass) = st_init_numtable(); } RB_VM_LOCK_LEAVE(); } return iv_index_tbl; } static void iv_index_tbl_extend(struct ivar_update *ivup, ID id, VALUE klass) { ASSERT_vm_locking(); st_data_t ent_data; struct rb_iv_index_tbl_entry *ent; if (st_lookup(ivup->u.iv_index_tbl, (st_data_t)id, &ent_data)) { ent = (void *)ent_data; ivup->index = ent->index; return; } if (ivup->u.iv_index_tbl->num_entries >= INT_MAX) { rb_raise(rb_eArgError, "too many instance variables"); } ent = ALLOC(struct rb_iv_index_tbl_entry); ent->index = ivup->index = (uint32_t)ivup->u.iv_index_tbl->num_entries; ent->class_value = klass; ent->class_serial = RCLASS_SERIAL(klass); st_add_direct(ivup->u.iv_index_tbl, (st_data_t)id, (st_data_t)ent); ivup->iv_extended = 1; } static void generic_ivar_set(VALUE obj, ID id, VALUE val) { VALUE klass = rb_obj_class(obj); struct ivar_update ivup; ivup.iv_extended = 0; ivup.u.iv_index_tbl = iv_index_tbl_make(obj, klass); RB_VM_LOCK_ENTER(); { iv_index_tbl_extend(&ivup, id, klass); st_update(generic_ivtbl(obj, id, false), (st_data_t)obj, generic_ivar_update, (st_data_t)&ivup); } RB_VM_LOCK_LEAVE(); ivup.u.ivtbl->ivptr[ivup.index] = val; RB_OBJ_WRITTEN(obj, Qundef, val); } static VALUE * obj_ivar_heap_alloc(VALUE obj, size_t newsize) { VALUE *newptr = rb_transient_heap_alloc(obj, sizeof(VALUE) * newsize); if (newptr != NULL) { ROBJ_TRANSIENT_SET(obj); } else { ROBJ_TRANSIENT_UNSET(obj); newptr = ALLOC_N(VALUE, newsize); } return newptr; } static VALUE * obj_ivar_heap_realloc(VALUE obj, int32_t len, size_t newsize) { VALUE *newptr; int i; if (ROBJ_TRANSIENT_P(obj)) { const VALUE *orig_ptr = ROBJECT(obj)->as.heap.ivptr; newptr = obj_ivar_heap_alloc(obj, newsize); assert(newptr); ROBJECT(obj)->as.heap.ivptr = newptr; for (i=0; i<(int)len; i++) { newptr[i] = orig_ptr[i]; } } else { REALLOC_N(ROBJECT(obj)->as.heap.ivptr, VALUE, newsize); newptr = ROBJECT(obj)->as.heap.ivptr; } return newptr; } #if USE_TRANSIENT_HEAP void rb_obj_transient_heap_evacuate(VALUE obj, int promote) { if (ROBJ_TRANSIENT_P(obj)) { uint32_t len = ROBJECT_NUMIV(obj); const VALUE *old_ptr = ROBJECT_IVPTR(obj); VALUE *new_ptr; if (promote) { new_ptr = ALLOC_N(VALUE, len); ROBJ_TRANSIENT_UNSET(obj); } else { new_ptr = obj_ivar_heap_alloc(obj, len); } MEMCPY(new_ptr, old_ptr, VALUE, len); ROBJECT(obj)->as.heap.ivptr = new_ptr; } } #endif static void init_iv_list(VALUE obj, uint32_t len, uint32_t newsize, st_table *index_tbl) { VALUE *ptr = ROBJECT_IVPTR(obj); VALUE *newptr; if (RBASIC(obj)->flags & ROBJECT_EMBED) { newptr = obj_ivar_heap_alloc(obj, newsize); MEMCPY(newptr, ptr, VALUE, len); RBASIC(obj)->flags &= ~ROBJECT_EMBED; ROBJECT(obj)->as.heap.ivptr = newptr; } else { newptr = obj_ivar_heap_realloc(obj, len, newsize); } for (; len < newsize; len++) { newptr[len] = Qundef; } ROBJECT(obj)->as.heap.numiv = newsize; ROBJECT(obj)->as.heap.iv_index_tbl = index_tbl; } void rb_init_iv_list(VALUE obj) { st_table *index_tbl = ROBJECT_IV_INDEX_TBL(obj); uint32_t newsize = (uint32_t)index_tbl->num_entries; uint32_t len = ROBJECT_NUMIV(obj); init_iv_list(obj, len, newsize, index_tbl); } // Retrieve or create the id-to-index mapping for a given object and an // instance variable name. static struct ivar_update obj_ensure_iv_index_mapping(VALUE obj, ID id) { VALUE klass = rb_obj_class(obj); struct ivar_update ivup; ivup.iv_extended = 0; ivup.u.iv_index_tbl = iv_index_tbl_make(obj, klass); RB_VM_LOCK_ENTER(); { iv_index_tbl_extend(&ivup, id, klass); } RB_VM_LOCK_LEAVE(); return ivup; } // Return the instance variable index for a given name and T_OBJECT object. The // mapping between name and index lives on `rb_obj_class(obj)` and is created // if not already present. // // @note May raise when there are too many instance variables. // @note YJIT uses this function at compile time to simplify the work needed to // access the variable at runtime. uint32_t rb_obj_ensure_iv_index_mapping(VALUE obj, ID id) { RUBY_ASSERT(RB_TYPE_P(obj, T_OBJECT)); // This uint32_t cast shouldn't lose information as it's checked in // iv_index_tbl_extend(). The index is stored as an uint32_t in // struct rb_iv_index_tbl_entry. return (uint32_t)obj_ensure_iv_index_mapping(obj, id).index; } static VALUE obj_ivar_set(VALUE obj, ID id, VALUE val) { uint32_t len; struct ivar_update ivup = obj_ensure_iv_index_mapping(obj, id); len = ROBJECT_NUMIV(obj); if (len <= ivup.index) { uint32_t newsize = iv_index_tbl_newsize(&ivup); init_iv_list(obj, len, newsize, ivup.u.iv_index_tbl); } RB_OBJ_WRITE(obj, &ROBJECT_IVPTR(obj)[ivup.index], val); return val; } static void ivar_set(VALUE obj, ID id, VALUE val) { RB_DEBUG_COUNTER_INC(ivar_set_base); switch (BUILTIN_TYPE(obj)) { case T_OBJECT: obj_ivar_set(obj, id, val); break; case T_CLASS: case T_MODULE: IVAR_ACCESSOR_SHOULD_BE_MAIN_RACTOR(id); rb_class_ivar_set(obj, id, val); break; default: generic_ivar_set(obj, id, val); break; } } VALUE rb_ivar_set(VALUE obj, ID id, VALUE val) { rb_check_frozen(obj); ivar_set(obj, id, val); return val; } void rb_ivar_set_internal(VALUE obj, ID id, VALUE val) { // should be internal instance variable name (no @ prefix) VM_ASSERT(!rb_is_instance_id(id)); ivar_set(obj, id, val); } VALUE rb_ivar_defined(VALUE obj, ID id) { VALUE val; struct st_table *iv_index_tbl; uint32_t index; if (SPECIAL_CONST_P(obj)) return Qfalse; switch (BUILTIN_TYPE(obj)) { case T_OBJECT: iv_index_tbl = ROBJECT_IV_INDEX_TBL(obj); if (iv_index_tbl_lookup(iv_index_tbl, id, &index) && index < ROBJECT_NUMIV(obj) && (val = ROBJECT_IVPTR(obj)[index]) != Qundef) { return Qtrue; } break; case T_CLASS: case T_MODULE: if (RCLASS_IV_TBL(obj) && lock_st_is_member(RCLASS_IV_TBL(obj), (st_data_t)id)) return Qtrue; break; default: if (FL_TEST(obj, FL_EXIVAR)) return generic_ivar_defined(obj, id); break; } return Qfalse; } typedef int rb_ivar_foreach_callback_func(ID key, VALUE val, st_data_t arg); st_data_t rb_st_nth_key(st_table *tab, st_index_t index); static ID iv_index_tbl_nth_id(st_table *iv_index_tbl, uint32_t index) { st_data_t key; RB_VM_LOCK_ENTER(); { key = rb_st_nth_key(iv_index_tbl, index); } RB_VM_LOCK_LEAVE(); return (ID)key; } static inline bool ivar_each_i(st_table *iv_index_tbl, VALUE val, uint32_t i, rb_ivar_foreach_callback_func *func, st_data_t arg) { if (val != Qundef) { ID id = iv_index_tbl_nth_id(iv_index_tbl, i); switch (func(id, val, arg)) { case ST_CHECK: case ST_CONTINUE: break; case ST_STOP: return true; default: rb_bug("unreachable"); } } return false; } static void obj_ivar_each(VALUE obj, rb_ivar_foreach_callback_func *func, st_data_t arg) { st_table *iv_index_tbl = ROBJECT_IV_INDEX_TBL(obj); if (!iv_index_tbl) return; uint32_t i=0; for (i=0; i < ROBJECT_NUMIV(obj); i++) { VALUE val = ROBJECT_IVPTR(obj)[i]; if (ivar_each_i(iv_index_tbl, val, i, func, arg)) { return; } } } static void gen_ivar_each(VALUE obj, rb_ivar_foreach_callback_func *func, st_data_t arg) { struct gen_ivtbl *ivtbl; st_table *iv_index_tbl = RCLASS_IV_INDEX_TBL(rb_obj_class(obj)); if (!iv_index_tbl) return; if (!gen_ivtbl_get(obj, 0, &ivtbl)) return; for (uint32_t i=0; inumiv; i++) { VALUE val = ivtbl->ivptr[i]; if (ivar_each_i(iv_index_tbl, val, i, func, arg)) { return; } } } struct givar_copy { VALUE obj; VALUE klass; st_table *iv_index_tbl; struct gen_ivtbl *ivtbl; }; static int gen_ivar_copy(ID id, VALUE val, st_data_t arg) { struct givar_copy *c = (struct givar_copy *)arg; struct ivar_update ivup; ivup.iv_extended = 0; ivup.u.iv_index_tbl = c->iv_index_tbl; RB_VM_LOCK_ENTER(); { iv_index_tbl_extend(&ivup, id, c->klass); } RB_VM_LOCK_LEAVE(); if (ivup.index >= c->ivtbl->numiv) { uint32_t newsize = iv_index_tbl_newsize(&ivup); c->ivtbl = gen_ivtbl_resize(c->ivtbl, newsize); } c->ivtbl->ivptr[ivup.index] = val; RB_OBJ_WRITTEN(c->obj, Qundef, val); return ST_CONTINUE; } void rb_copy_generic_ivar(VALUE clone, VALUE obj) { struct gen_ivtbl *ivtbl; rb_check_frozen(clone); if (!FL_TEST(obj, FL_EXIVAR)) { goto clear; } if (gen_ivtbl_get(obj, 0, &ivtbl)) { struct givar_copy c; uint32_t i; if (gen_ivtbl_count(ivtbl) == 0) goto clear; if (gen_ivtbl_get(clone, 0, &c.ivtbl)) { for (i = 0; i < c.ivtbl->numiv; i++) c.ivtbl->ivptr[i] = Qundef; } else { c.ivtbl = gen_ivtbl_resize(0, ivtbl->numiv); FL_SET(clone, FL_EXIVAR); } VALUE klass = rb_obj_class(clone); c.iv_index_tbl = iv_index_tbl_make(clone, klass); c.obj = clone; c.klass = klass; gen_ivar_each(obj, gen_ivar_copy, (st_data_t)&c); /* * c.ivtbl may change in gen_ivar_copy due to realloc, * no need to free */ RB_VM_LOCK_ENTER(); { generic_ivtbl_no_ractor_check(clone); st_insert(generic_ivtbl_no_ractor_check(obj), (st_data_t)clone, (st_data_t)c.ivtbl); } RB_VM_LOCK_LEAVE(); } return; clear: if (FL_TEST(clone, FL_EXIVAR)) { rb_free_generic_ivar(clone); FL_UNSET(clone, FL_EXIVAR); } } void rb_replace_generic_ivar(VALUE clone, VALUE obj) { RUBY_ASSERT(FL_TEST(obj, FL_EXIVAR)); RB_VM_LOCK_ENTER(); { st_data_t ivtbl, obj_data = (st_data_t)obj; if (st_lookup(generic_iv_tbl_, (st_data_t)obj, &ivtbl)) { st_insert(generic_iv_tbl_, (st_data_t)clone, ivtbl); st_delete(generic_iv_tbl_, &obj_data, NULL); } else { rb_bug("unreachable"); } } RB_VM_LOCK_LEAVE(); FL_SET(clone, FL_EXIVAR); } void rb_ivar_foreach(VALUE obj, rb_ivar_foreach_callback_func *func, st_data_t arg) { if (SPECIAL_CONST_P(obj)) return; switch (BUILTIN_TYPE(obj)) { case T_OBJECT: obj_ivar_each(obj, func, arg); break; case T_CLASS: case T_MODULE: IVAR_ACCESSOR_SHOULD_BE_MAIN_RACTOR(0); if (RCLASS_IV_TBL(obj)) { RB_VM_LOCK_ENTER(); { st_foreach_safe(RCLASS_IV_TBL(obj), func, arg); } RB_VM_LOCK_LEAVE(); } break; default: if (FL_TEST(obj, FL_EXIVAR)) { gen_ivar_each(obj, func, arg); } break; } } st_index_t rb_ivar_count(VALUE obj) { st_table *tbl; if (SPECIAL_CONST_P(obj)) return 0; switch (BUILTIN_TYPE(obj)) { case T_OBJECT: if (ROBJECT_IV_INDEX_TBL(obj) != 0) { st_index_t i, count, num = ROBJECT_NUMIV(obj); const VALUE *const ivptr = ROBJECT_IVPTR(obj); for (i = count = 0; i < num; ++i) { if (ivptr[i] != Qundef) { count++; } } return count; } break; case T_CLASS: case T_MODULE: if ((tbl = RCLASS_IV_TBL(obj)) != 0) { return tbl->num_entries; } break; default: if (FL_TEST(obj, FL_EXIVAR)) { struct gen_ivtbl *ivtbl; if (gen_ivtbl_get(obj, 0, &ivtbl)) { return gen_ivtbl_count(ivtbl); } } break; } return 0; } static int ivar_i(st_data_t k, st_data_t v, st_data_t a) { ID key = (ID)k; VALUE ary = (VALUE)a; if (rb_is_instance_id(key)) { rb_ary_push(ary, ID2SYM(key)); } return ST_CONTINUE; } /* * call-seq: * obj.instance_variables -> array * * Returns an array of instance variable names for the receiver. Note * that simply defining an accessor does not create the corresponding * instance variable. * * class Fred * attr_accessor :a1 * def initialize * @iv = 3 * end * end * Fred.new.instance_variables #=> [:@iv] */ VALUE rb_obj_instance_variables(VALUE obj) { VALUE ary; ary = rb_ary_new(); rb_ivar_foreach(obj, ivar_i, ary); return ary; } #define rb_is_constant_id rb_is_const_id #define rb_is_constant_name rb_is_const_name #define id_for_var(obj, name, part, type) \ id_for_var_message(obj, name, type, "`%1$s' is not allowed as "#part" "#type" variable name") #define id_for_var_message(obj, name, type, message) \ check_id_type(obj, &(name), rb_is_##type##_id, rb_is_##type##_name, message, strlen(message)) static ID check_id_type(VALUE obj, VALUE *pname, int (*valid_id_p)(ID), int (*valid_name_p)(VALUE), const char *message, size_t message_len) { ID id = rb_check_id(pname); VALUE name = *pname; if (id ? !valid_id_p(id) : !valid_name_p(name)) { rb_name_err_raise_str(rb_fstring_new(message, message_len), obj, name); } return id; } /* * call-seq: * obj.remove_instance_variable(symbol) -> obj * obj.remove_instance_variable(string) -> obj * * Removes the named instance variable from obj, returning that * variable's value. * String arguments are converted to symbols. * * class Dummy * attr_reader :var * def initialize * @var = 99 * end * def remove * remove_instance_variable(:@var) * end * end * d = Dummy.new * d.var #=> 99 * d.remove #=> 99 * d.var #=> nil */ VALUE rb_obj_remove_instance_variable(VALUE obj, VALUE name) { VALUE val = Qnil; const ID id = id_for_var(obj, name, an, instance); st_data_t n, v; struct st_table *iv_index_tbl; uint32_t index; rb_check_frozen(obj); if (!id) { goto not_defined; } switch (BUILTIN_TYPE(obj)) { case T_OBJECT: iv_index_tbl = ROBJECT_IV_INDEX_TBL(obj); if (iv_index_tbl_lookup(iv_index_tbl, id, &index) && index < ROBJECT_NUMIV(obj) && (val = ROBJECT_IVPTR(obj)[index]) != Qundef) { ROBJECT_IVPTR(obj)[index] = Qundef; return val; } break; case T_CLASS: case T_MODULE: IVAR_ACCESSOR_SHOULD_BE_MAIN_RACTOR(id); n = id; if (RCLASS_IV_TBL(obj) && lock_st_delete(RCLASS_IV_TBL(obj), &n, &v)) { return (VALUE)v; } break; default: if (FL_TEST(obj, FL_EXIVAR)) { if (generic_ivar_remove(obj, id, &val)) { return val; } } break; } not_defined: rb_name_err_raise("instance variable %1$s not defined", obj, name); UNREACHABLE_RETURN(Qnil); } NORETURN(static void uninitialized_constant(VALUE, VALUE)); static void uninitialized_constant(VALUE klass, VALUE name) { if (klass && rb_class_real(klass) != rb_cObject) rb_name_err_raise("uninitialized constant %2$s::%1$s", klass, name); else rb_name_err_raise("uninitialized constant %1$s", klass, name); } VALUE rb_const_missing(VALUE klass, VALUE name) { VALUE value = rb_funcallv(klass, idConst_missing, 1, &name); rb_vm_inc_const_missing_count(); return value; } /* * call-seq: * mod.const_missing(sym) -> obj * * Invoked when a reference is made to an undefined constant in * mod. It is passed a symbol for the undefined constant, and * returns a value to be used for that constant. The * following code is an example of the same: * * def Foo.const_missing(name) * name # return the constant name as Symbol * end * * Foo::UNDEFINED_CONST #=> :UNDEFINED_CONST: symbol returned * * In the next example when a reference is made to an undefined constant, * it attempts to load a file whose name is the lowercase version of the * constant (thus class Fred is assumed to be in file * fred.rb). If found, it returns the loaded class. It * therefore implements an autoload feature similar to Kernel#autoload and * Module#autoload. * * def Object.const_missing(name) * @looked_for ||= {} * str_name = name.to_s * raise "Class not found: #{name}" if @looked_for[str_name] * @looked_for[str_name] = 1 * file = str_name.downcase * require file * klass = const_get(name) * return klass if klass * raise "Class not found: #{name}" * end * */ VALUE rb_mod_const_missing(VALUE klass, VALUE name) { VALUE ref = GET_EC()->private_const_reference; rb_vm_pop_cfunc_frame(); if (ref) { rb_name_err_raise("private constant %2$s::%1$s referenced", ref, name); } uninitialized_constant(klass, name); UNREACHABLE_RETURN(Qnil); } static void autoload_table_mark(void *ptr) { rb_mark_tbl_no_pin((st_table *)ptr); } static void autoload_table_free(void *ptr) { st_free_table((st_table *)ptr); } static size_t autoload_table_memsize(const void *ptr) { const st_table *tbl = ptr; return st_memsize(tbl); } static void autoload_table_compact(void *ptr) { rb_gc_update_tbl_refs((st_table *)ptr); } static const rb_data_type_t autoload_table_type = { "autoload_table", {autoload_table_mark, autoload_table_free, autoload_table_memsize, autoload_table_compact,}, 0, 0, RUBY_TYPED_FREE_IMMEDIATELY }; #define check_autoload_table(av) \ (struct st_table *)rb_check_typeddata((av), &autoload_table_type) static VALUE autoload_data(VALUE mod, ID id) { struct st_table *tbl; st_data_t val; // Look up the instance variable table for `autoload`, then index into that table with the given constant name `id`. if (!st_lookup(RCLASS_IV_TBL(mod), autoload, &val) || !(tbl = check_autoload_table((VALUE)val)) || !st_lookup(tbl, (st_data_t)id, &val)) { return 0; } return (VALUE)val; } // Every autoload constant has exactly one instance of autoload_const, stored in `autoload_features`. Since multiple autoload constants can refer to the same file, every `autoload_const` refers to a de-duplicated `autoload_data`. struct autoload_const { // The linked list node of all constants which are loaded by the related autoload feature. struct ccan_list_node cnode; /* <=> autoload_data.constants */ // The shared "autoload_data" if multiple constants are defined from the same feature. VALUE autoload_data_value; // The module we are loading a constant into. VALUE module; // The name of the constant we are loading. ID name; // The value of the constant (after it's loaded). VALUE value; // The constant entry flags which need to be re-applied after autoloading the feature. rb_const_flag_t flag; // The source file and line number that defined this constant (different from feature path). VALUE file; int line; }; // Each `autoload_data` uniquely represents a specific feature which can be loaded, and a list of constants which it is able to define. We use a mutex to coordinate multiple threads trying to load the same feature. struct autoload_data { // The feature path to require to load this constant. VALUE feature; // The mutex which is protecting autoloading this feature. VALUE mutex; // The process fork serial number since the autoload mutex will become invalid on fork. rb_serial_t fork_gen; // The linked list of all constants that are going to be loaded by this autoload. struct ccan_list_head constants; /* <=> autoload_const.cnode */ }; static void autoload_data_compact(void *ptr) { struct autoload_data *p = ptr; p->feature = rb_gc_location(p->feature); p->mutex = rb_gc_location(p->mutex); } static void autoload_data_mark(void *ptr) { struct autoload_data *p = ptr; rb_gc_mark_movable(p->feature); rb_gc_mark_movable(p->mutex); } static void autoload_data_free(void *ptr) { struct autoload_data *p = ptr; // We may leak some memory at VM shutdown time, no big deal...? if (ccan_list_empty(&p->constants)) { ruby_xfree(p); } } static size_t autoload_data_memsize(const void *ptr) { return sizeof(struct autoload_data); } static const rb_data_type_t autoload_data_type = { "autoload_data", {autoload_data_mark, autoload_data_free, autoload_data_memsize, autoload_data_compact}, 0, 0, RUBY_TYPED_FREE_IMMEDIATELY }; static void autoload_const_compact(void *ptr) { struct autoload_const *ac = ptr; ac->module = rb_gc_location(ac->module); ac->autoload_data_value = rb_gc_location(ac->autoload_data_value); ac->value = rb_gc_location(ac->value); ac->file = rb_gc_location(ac->file); } static void autoload_const_mark(void *ptr) { struct autoload_const *ac = ptr; rb_gc_mark_movable(ac->module); rb_gc_mark_movable(ac->autoload_data_value); rb_gc_mark_movable(ac->value); rb_gc_mark_movable(ac->file); } static size_t autoload_const_memsize(const void *ptr) { return sizeof(struct autoload_const); } static void autoload_const_free(void *ptr) { struct autoload_const *autoload_const = ptr; ccan_list_del(&autoload_const->cnode); ruby_xfree(ptr); } static const rb_data_type_t autoload_const_type = { "autoload_const", {autoload_const_mark, autoload_const_free, autoload_const_memsize, autoload_const_compact,}, 0, 0, RUBY_TYPED_FREE_IMMEDIATELY }; static struct autoload_data * get_autoload_data(VALUE autoload_const_value, struct autoload_const **autoload_const_pointer) { struct autoload_const *autoload_const = rb_check_typeddata(autoload_const_value, &autoload_const_type); struct autoload_data *autoload_data = rb_check_typeddata(autoload_const->autoload_data_value, &autoload_data_type); /* do not reach across stack for ->state after forking: */ if (autoload_data && autoload_data->fork_gen != GET_VM()->fork_gen) { autoload_data->mutex = Qnil; autoload_data->fork_gen = 0; } if (autoload_const_pointer) *autoload_const_pointer = autoload_const; return autoload_data; } RUBY_FUNC_EXPORTED void rb_autoload(VALUE module, ID name, const char *feature) { if (!feature || !*feature) { rb_raise(rb_eArgError, "empty feature name"); } rb_autoload_str(module, name, rb_fstring_cstr(feature)); } static void const_set(VALUE klass, ID id, VALUE val); static void const_added(VALUE klass, ID const_name); struct autoload_arguments { VALUE module; ID name; VALUE feature; }; static VALUE autoload_feature_lookup_or_create(VALUE feature, struct autoload_data **autoload_data_pointer) { RUBY_ASSERT_MUTEX_OWNED(autoload_mutex); RUBY_ASSERT_CRITICAL_SECTION_ENTER(); VALUE autoload_data_value = rb_hash_aref(autoload_features, feature); struct autoload_data *autoload_data; if (NIL_P(autoload_data_value)) { autoload_data_value = TypedData_Make_Struct(0, struct autoload_data, &autoload_data_type, autoload_data); autoload_data->feature = feature; autoload_data->mutex = Qnil; ccan_list_head_init(&autoload_data->constants); if (autoload_data_pointer) *autoload_data_pointer = autoload_data; rb_hash_aset(autoload_features, feature, autoload_data_value); } else if (autoload_data_pointer) { *autoload_data_pointer = rb_check_typeddata(autoload_data_value, &autoload_data_type); } RUBY_ASSERT_CRITICAL_SECTION_LEAVE(); return autoload_data_value; } static struct st_table * autoload_table_lookup_or_create(VALUE module) { // Get or create an autoload table in the class instance variables: struct st_table *table = RCLASS_IV_TBL(module); VALUE autoload_table_value; if (table && st_lookup(table, (st_data_t)autoload, &autoload_table_value)) { return check_autoload_table((VALUE)autoload_table_value); } if (!table) { table = RCLASS_IV_TBL(module) = st_init_numtable(); } autoload_table_value = TypedData_Wrap_Struct(0, &autoload_table_type, 0); st_add_direct(table, (st_data_t)autoload, (st_data_t)autoload_table_value); RB_OBJ_WRITTEN(module, Qnil, autoload_table_value); return (DATA_PTR(autoload_table_value) = st_init_numtable()); } static VALUE autoload_synchronized(VALUE _arguments) { struct autoload_arguments *arguments = (struct autoload_arguments *)_arguments; rb_const_entry_t *constant_entry = rb_const_lookup(arguments->module, arguments->name); if (constant_entry && constant_entry->value != Qundef) { return Qfalse; } // Reset any state associated with any previous constant: const_set(arguments->module, arguments->name, Qundef); struct st_table *autoload_table = autoload_table_lookup_or_create(arguments->module); // Ensure the string is uniqued since we use an identity lookup: VALUE feature = rb_fstring(arguments->feature); struct autoload_data *autoload_data; VALUE autoload_data_value = autoload_feature_lookup_or_create(feature, &autoload_data); { struct autoload_const *autoload_const; VALUE autoload_const_value = TypedData_Make_Struct(0, struct autoload_const, &autoload_const_type, autoload_const); autoload_const->module = arguments->module; autoload_const->name = arguments->name; autoload_const->value = Qundef; autoload_const->flag = CONST_PUBLIC; autoload_const->autoload_data_value = autoload_data_value; ccan_list_add_tail(&autoload_data->constants, &autoload_const->cnode); st_insert(autoload_table, (st_data_t)arguments->name, (st_data_t)autoload_const_value); } return Qtrue; } void rb_autoload_str(VALUE module, ID name, VALUE feature) { if (!rb_is_const_id(name)) { rb_raise(rb_eNameError, "autoload must be constant name: %"PRIsVALUE"", QUOTE_ID(name)); } Check_Type(feature, T_STRING); if (!RSTRING_LEN(feature)) { rb_raise(rb_eArgError, "empty feature name"); } struct autoload_arguments arguments = { .module = module, .name = name, .feature = feature, }; VALUE result = rb_mutex_synchronize(autoload_mutex, autoload_synchronized, (VALUE)&arguments); if (result == Qtrue) { const_added(module, name); } } static void autoload_delete(VALUE module, ID name) { RUBY_ASSERT_CRITICAL_SECTION_ENTER(); st_data_t value, load = 0, key = name; if (st_lookup(RCLASS_IV_TBL(module), (st_data_t)autoload, &value)) { struct st_table *table = check_autoload_table((VALUE)value); st_delete(table, &key, &load); /* Qfalse can indicate already deleted */ if (load != Qfalse) { struct autoload_const *autoload_const; struct autoload_data *autoload_data = get_autoload_data((VALUE)load, &autoload_const); VM_ASSERT(autoload_data); VM_ASSERT(!ccan_list_empty(&autoload_data->constants)); /* * we must delete here to avoid "already initialized" warnings * with parallel autoload. Using list_del_init here so list_del * works in autoload_const_free */ ccan_list_del_init(&autoload_const->cnode); if (ccan_list_empty(&autoload_data->constants)) { rb_hash_delete(autoload_features, autoload_data->feature); } // If the autoload table is empty, we can delete it. if (table->num_entries == 0) { name = autoload; st_delete(RCLASS_IV_TBL(module), &name, &value); } } } RUBY_ASSERT_CRITICAL_SECTION_LEAVE(); } static int autoload_by_someone_else(struct autoload_data *ele) { return ele->mutex != Qnil && !rb_mutex_owned_p(ele->mutex); } static VALUE check_autoload_required(VALUE mod, ID id, const char **loadingpath) { VALUE autoload_const_value = autoload_data(mod, id); struct autoload_data *autoload_data; const char *loading; if (!autoload_const_value || !(autoload_data = get_autoload_data(autoload_const_value, 0))) { return 0; } VALUE feature = autoload_data->feature; /* * if somebody else is autoloading, we MUST wait for them, since * rb_provide_feature can provide a feature before autoload_const_set * completes. We must wait until autoload_const_set finishes in * the other thread. */ if (autoload_by_someone_else(autoload_data)) { return autoload_const_value; } loading = RSTRING_PTR(feature); if (!rb_feature_provided(loading, &loading)) { return autoload_const_value; } if (loadingpath && loading) { *loadingpath = loading; return autoload_const_value; } return 0; } static struct autoload_const *autoloading_const_entry(VALUE mod, ID id); MJIT_FUNC_EXPORTED int rb_autoloading_value(VALUE mod, ID id, VALUE* value, rb_const_flag_t *flag) { struct autoload_const *ac = autoloading_const_entry(mod, id); if (!ac) return FALSE; if (value) { *value = ac->value; } if (flag) { *flag = ac->flag; } return TRUE; } static int autoload_by_current(struct autoload_data *ele) { return ele->mutex != Qnil && rb_mutex_owned_p(ele->mutex); } // If there is an autoloading constant and it has been set by the current // execution context, return it. This allows threads which are loading code to // refer to their own autoloaded constants. struct autoload_const * autoloading_const_entry(VALUE mod, ID id) { VALUE load = autoload_data(mod, id); struct autoload_data *ele; struct autoload_const *ac; // Find the autoloading state: if (!load || !(ele = get_autoload_data(load, &ac))) { // Couldn't be found: return 0; } // Check if it's being loaded by the current thread/fiber: if (autoload_by_current(ele)) { if (ac->value != Qundef) { return ac; } } return 0; } static int autoload_defined_p(VALUE mod, ID id) { rb_const_entry_t *ce = rb_const_lookup(mod, id); // If there is no constant or the constant is not undefined (special marker for autoloading): if (!ce || ce->value != Qundef) { // We are not autoloading: return 0; } // Otherwise check if there is an autoload in flight right now: return !rb_autoloading_value(mod, id, NULL, NULL); } static void const_tbl_update(struct autoload_const *, int); struct autoload_load_arguments { VALUE module; ID name; int flag; VALUE result; VALUE mutex; // The specific constant which triggered the autoload code to fire: struct autoload_const *autoload_const; // The parent autoload data which is shared between multiple constants: struct autoload_data *autoload_data; }; static VALUE autoload_const_set(struct autoload_const *ac) { check_before_mod_set(ac->module, ac->name, ac->value, "constant"); RB_VM_LOCK_ENTER(); { const_tbl_update(ac, true); } RB_VM_LOCK_LEAVE(); return 0; /* ignored */ } static VALUE autoload_load_needed(VALUE _arguments) { struct autoload_load_arguments *arguments = (struct autoload_load_arguments*)_arguments; const char *loading = 0, *src; if (!autoload_defined_p(arguments->module, arguments->name)) { return Qfalse; } VALUE autoload_const_value = check_autoload_required(arguments->module, arguments->name, &loading); if (!autoload_const_value) { return Qfalse; } src = rb_sourcefile(); if (src && loading && strcmp(src, loading) == 0) { return Qfalse; } struct autoload_const *autoload_const; struct autoload_data *autoload_data; if (!(autoload_data = get_autoload_data(autoload_const_value, &autoload_const))) { return Qfalse; } if (autoload_data->mutex == Qnil) { autoload_data->mutex = rb_mutex_new(); autoload_data->fork_gen = GET_VM()->fork_gen; } else if (rb_mutex_owned_p(autoload_data->mutex)) { return Qfalse; } arguments->mutex = autoload_data->mutex; arguments->autoload_const = autoload_const; return autoload_const_value; } static VALUE autoload_feature_require(VALUE _arguments) { struct autoload_load_arguments *arguments = (struct autoload_load_arguments*)_arguments; struct autoload_const *autoload_const = arguments->autoload_const; // We save this for later use in autoload_apply_constants: arguments->autoload_data = rb_check_typeddata(autoload_const->autoload_data_value, &autoload_data_type); arguments->result = rb_funcall(rb_vm_top_self(), rb_intern("require"), 1, arguments->autoload_data->feature); return arguments->result; } static VALUE autoload_apply_constants(VALUE _arguments) { RUBY_ASSERT_CRITICAL_SECTION_ENTER(); struct autoload_load_arguments *arguments = (struct autoload_load_arguments*)_arguments; if (arguments->result == Qtrue) { struct autoload_const *autoload_const; struct autoload_const *next; // We use safe iteration here because `autoload_const_set` will eventually invoke // `autoload_delete` which will remove the constant from the linked list. In theory, once // the `autoload_data->constants` linked list is empty, we can remove it. // Iterate over all constants and assign them: ccan_list_for_each_safe(&arguments->autoload_data->constants, autoload_const, next, cnode) { if (autoload_const->value != Qundef) { autoload_const_set(autoload_const); } } } RUBY_ASSERT_CRITICAL_SECTION_LEAVE(); return Qtrue; } static VALUE autoload_feature_require_ensure(VALUE _arguments) { return rb_mutex_synchronize(autoload_mutex, autoload_apply_constants, _arguments); } static VALUE autoload_try_load(VALUE _arguments) { struct autoload_load_arguments *arguments = (struct autoload_load_arguments*)_arguments; // Try to require the autoload feature: rb_ensure(autoload_feature_require, _arguments, autoload_feature_require_ensure, _arguments); // After we loaded the feature, if the constant is not defined, we remove it completely: rb_const_entry_t *ce = rb_const_lookup(arguments->module, arguments->name); if (!ce || ce->value == Qundef) { // Absolutely ensure that any other threads will bail out, returning false: arguments->result = Qfalse; rb_const_remove(arguments->module, arguments->name); } else { // Otherwise, it was loaded, copy the flags from the autoload constant: ce->flag |= arguments->flag; } return arguments->result; } VALUE rb_autoload_load(VALUE module, ID name) { rb_const_entry_t *ce = rb_const_lookup(module, name); // We bail out as early as possible without any synchronisation: if (!ce || ce->value != Qundef) { return Qfalse; } // At this point, we assume there might be autoloading, so fail if it's ractor: if (UNLIKELY(!rb_ractor_main_p())) { rb_raise(rb_eRactorUnsafeError, "require by autoload on non-main Ractor is not supported (%s)", rb_id2name(name)); } // This state is stored on thes stack and is used during the autoload process. struct autoload_load_arguments arguments = {.module = module, .name = name, .mutex = Qnil, .result = Qnil}; // Figure out whether we can autoload the named constant: VALUE autoload_const_value = rb_mutex_synchronize(autoload_mutex, autoload_load_needed, (VALUE)&arguments); // This confirms whether autoloading is required or not: if (autoload_const_value == Qfalse) return autoload_const_value; arguments.flag = ce->flag & (CONST_DEPRECATED | CONST_VISIBILITY_MASK); // Only one thread will enter here at a time: VALUE result = rb_mutex_synchronize(arguments.mutex, autoload_try_load, (VALUE)&arguments); // If you don't guard this value, it's possible for the autoload constant to // be freed by another thread which loads multiple constants, one of which // resolves to the constant this thread is trying to load, so proteect this // so that it is not freed until we are done with it in `autoload_try_load`: RB_GC_GUARD(autoload_const_value); return result; } VALUE rb_autoload_p(VALUE mod, ID id) { return rb_autoload_at_p(mod, id, TRUE); } VALUE rb_autoload_at_p(VALUE mod, ID id, int recur) { VALUE load; struct autoload_data *ele; while (!autoload_defined_p(mod, id)) { if (!recur) return Qnil; mod = RCLASS_SUPER(mod); if (!mod) return Qnil; } load = check_autoload_required(mod, id, 0); if (!load) return Qnil; return (ele = get_autoload_data(load, 0)) ? ele->feature : Qnil; } MJIT_FUNC_EXPORTED void rb_const_warn_if_deprecated(const rb_const_entry_t *ce, VALUE klass, ID id) { if (RB_CONST_DEPRECATED_P(ce) && rb_warning_category_enabled_p(RB_WARN_CATEGORY_DEPRECATED)) { if (klass == rb_cObject) { rb_category_warn(RB_WARN_CATEGORY_DEPRECATED, "constant ::%"PRIsVALUE" is deprecated", QUOTE_ID(id)); } else { rb_category_warn(RB_WARN_CATEGORY_DEPRECATED, "constant %"PRIsVALUE"::%"PRIsVALUE" is deprecated", rb_class_name(klass), QUOTE_ID(id)); } } } static VALUE rb_const_get_0(VALUE klass, ID id, int exclude, int recurse, int visibility) { VALUE c = rb_const_search(klass, id, exclude, recurse, visibility); if (c != Qundef) { if (UNLIKELY(!rb_ractor_main_p())) { if (!rb_ractor_shareable_p(c)) { rb_raise(rb_eRactorIsolationError, "can not access non-shareable objects in constant %"PRIsVALUE"::%s by non-main Ractor.", rb_class_path(klass), rb_id2name(id)); } } return c; } return rb_const_missing(klass, ID2SYM(id)); } static VALUE rb_const_search_from(VALUE klass, ID id, int exclude, int recurse, int visibility) { VALUE value, current; bool first_iteration = true; for (current = klass; RTEST(current); current = RCLASS_SUPER(current), first_iteration = false) { VALUE tmp; VALUE am = 0; rb_const_entry_t *ce; if (!first_iteration && RCLASS_ORIGIN(current) != current) { // This item in the super chain has an origin iclass // that comes later in the chain. Skip this item so // prepended modules take precedence. continue; } // Do lookup in original class or module in case we are at an origin // iclass in the chain. tmp = current; if (BUILTIN_TYPE(tmp) == T_ICLASS) tmp = RBASIC(tmp)->klass; // Do the lookup. Loop in case of autoload. while ((ce = rb_const_lookup(tmp, id))) { if (visibility && RB_CONST_PRIVATE_P(ce)) { GET_EC()->private_const_reference = tmp; return Qundef; } rb_const_warn_if_deprecated(ce, tmp, id); value = ce->value; if (value == Qundef) { struct autoload_const *ac; if (am == tmp) break; am = tmp; ac = autoloading_const_entry(tmp, id); if (ac) return ac->value; rb_autoload_load(tmp, id); continue; } if (exclude && tmp == rb_cObject) { goto not_found; } return value; } if (!recurse) break; } not_found: GET_EC()->private_const_reference = 0; return Qundef; } static VALUE rb_const_search(VALUE klass, ID id, int exclude, int recurse, int visibility) { VALUE value; if (klass == rb_cObject) exclude = FALSE; value = rb_const_search_from(klass, id, exclude, recurse, visibility); if (value != Qundef) return value; if (exclude) return value; if (BUILTIN_TYPE(klass) != T_MODULE) return value; /* search global const too, if klass is a module */ return rb_const_search_from(rb_cObject, id, FALSE, recurse, visibility); } VALUE rb_const_get_from(VALUE klass, ID id) { return rb_const_get_0(klass, id, TRUE, TRUE, FALSE); } VALUE rb_const_get(VALUE klass, ID id) { return rb_const_get_0(klass, id, FALSE, TRUE, FALSE); } VALUE rb_const_get_at(VALUE klass, ID id) { return rb_const_get_0(klass, id, TRUE, FALSE, FALSE); } MJIT_FUNC_EXPORTED VALUE rb_public_const_get_from(VALUE klass, ID id) { return rb_const_get_0(klass, id, TRUE, TRUE, TRUE); } MJIT_FUNC_EXPORTED VALUE rb_public_const_get_at(VALUE klass, ID id) { return rb_const_get_0(klass, id, TRUE, FALSE, TRUE); } NORETURN(static void undefined_constant(VALUE mod, VALUE name)); static void undefined_constant(VALUE mod, VALUE name) { rb_name_err_raise("constant %2$s::%1$s not defined", mod, name); } static VALUE rb_const_location_from(VALUE klass, ID id, int exclude, int recurse, int visibility) { while (RTEST(klass)) { rb_const_entry_t *ce; while ((ce = rb_const_lookup(klass, id))) { if (visibility && RB_CONST_PRIVATE_P(ce)) { return Qnil; } if (exclude && klass == rb_cObject) { goto not_found; } if (NIL_P(ce->file)) return rb_ary_new(); return rb_assoc_new(ce->file, INT2NUM(ce->line)); } if (!recurse) break; klass = RCLASS_SUPER(klass); } not_found: return Qnil; } static VALUE rb_const_location(VALUE klass, ID id, int exclude, int recurse, int visibility) { VALUE loc; if (klass == rb_cObject) exclude = FALSE; loc = rb_const_location_from(klass, id, exclude, recurse, visibility); if (!NIL_P(loc)) return loc; if (exclude) return loc; if (BUILTIN_TYPE(klass) != T_MODULE) return loc; /* search global const too, if klass is a module */ return rb_const_location_from(rb_cObject, id, FALSE, recurse, visibility); } VALUE rb_const_source_location(VALUE klass, ID id) { return rb_const_location(klass, id, FALSE, TRUE, FALSE); } MJIT_FUNC_EXPORTED VALUE rb_const_source_location_at(VALUE klass, ID id) { return rb_const_location(klass, id, TRUE, FALSE, FALSE); } /* * call-seq: * remove_const(sym) -> obj * * Removes the definition of the given constant, returning that * constant's previous value. If that constant referred to * a module, this will not change that module's name and can lead * to confusion. */ VALUE rb_mod_remove_const(VALUE mod, VALUE name) { const ID id = id_for_var(mod, name, a, constant); if (!id) { undefined_constant(mod, name); } return rb_const_remove(mod, id); } VALUE rb_const_remove(VALUE mod, ID id) { VALUE val; rb_const_entry_t *ce; rb_check_frozen(mod); ce = rb_const_lookup(mod, id); if (!ce || !rb_id_table_delete(RCLASS_CONST_TBL(mod), id)) { if (rb_const_defined_at(mod, id)) { rb_name_err_raise("cannot remove %2$s::%1$s", mod, ID2SYM(id)); } undefined_constant(mod, ID2SYM(id)); } rb_clear_constant_cache_for_id(id); val = ce->value; if (val == Qundef) { autoload_delete(mod, id); val = Qnil; } ruby_xfree(ce); return val; } static int cv_i_update(st_data_t *k, st_data_t *v, st_data_t a, int existing) { if (existing) return ST_STOP; *v = a; return ST_CONTINUE; } static enum rb_id_table_iterator_result sv_i(ID key, VALUE v, void *a) { rb_const_entry_t *ce = (rb_const_entry_t *)v; st_table *tbl = a; if (rb_is_const_id(key)) { st_update(tbl, (st_data_t)key, cv_i_update, (st_data_t)ce); } return ID_TABLE_CONTINUE; } static enum rb_id_table_iterator_result rb_local_constants_i(ID const_name, VALUE const_value, void *ary) { if (rb_is_const_id(const_name) && !RB_CONST_PRIVATE_P((rb_const_entry_t *)const_value)) { rb_ary_push((VALUE)ary, ID2SYM(const_name)); } return ID_TABLE_CONTINUE; } static VALUE rb_local_constants(VALUE mod) { struct rb_id_table *tbl = RCLASS_CONST_TBL(mod); VALUE ary; if (!tbl) return rb_ary_new2(0); RB_VM_LOCK_ENTER(); { ary = rb_ary_new2(rb_id_table_size(tbl)); rb_id_table_foreach(tbl, rb_local_constants_i, (void *)ary); } RB_VM_LOCK_LEAVE(); return ary; } void* rb_mod_const_at(VALUE mod, void *data) { st_table *tbl = data; if (!tbl) { tbl = st_init_numtable(); } if (RCLASS_CONST_TBL(mod)) { RB_VM_LOCK_ENTER(); { rb_id_table_foreach(RCLASS_CONST_TBL(mod), sv_i, tbl); } RB_VM_LOCK_LEAVE(); } return tbl; } void* rb_mod_const_of(VALUE mod, void *data) { VALUE tmp = mod; for (;;) { data = rb_mod_const_at(tmp, data); tmp = RCLASS_SUPER(tmp); if (!tmp) break; if (tmp == rb_cObject && mod != rb_cObject) break; } return data; } static int list_i(st_data_t key, st_data_t value, VALUE ary) { ID sym = (ID)key; rb_const_entry_t *ce = (rb_const_entry_t *)value; if (RB_CONST_PUBLIC_P(ce)) rb_ary_push(ary, ID2SYM(sym)); return ST_CONTINUE; } VALUE rb_const_list(void *data) { st_table *tbl = data; VALUE ary; if (!tbl) return rb_ary_new2(0); ary = rb_ary_new2(tbl->num_entries); st_foreach_safe(tbl, list_i, ary); st_free_table(tbl); return ary; } /* * call-seq: * mod.constants(inherit=true) -> array * * Returns an array of the names of the constants accessible in * mod. This includes the names of constants in any included * modules (example at start of section), unless the inherit * parameter is set to false. * * The implementation makes no guarantees about the order in which the * constants are yielded. * * IO.constants.include?(:SYNC) #=> true * IO.constants(false).include?(:SYNC) #=> false * * Also see Module#const_defined?. */ VALUE rb_mod_constants(int argc, const VALUE *argv, VALUE mod) { bool inherit = true; if (rb_check_arity(argc, 0, 1)) inherit = RTEST(argv[0]); if (inherit) { return rb_const_list(rb_mod_const_of(mod, 0)); } else { return rb_local_constants(mod); } } static int rb_const_defined_0(VALUE klass, ID id, int exclude, int recurse, int visibility) { VALUE tmp; int mod_retry = 0; rb_const_entry_t *ce; tmp = klass; retry: while (tmp) { if ((ce = rb_const_lookup(tmp, id))) { if (visibility && RB_CONST_PRIVATE_P(ce)) { return (int)Qfalse; } if (ce->value == Qundef && !check_autoload_required(tmp, id, 0) && !rb_autoloading_value(tmp, id, NULL, NULL)) return (int)Qfalse; if (exclude && tmp == rb_cObject && klass != rb_cObject) { return (int)Qfalse; } return (int)Qtrue; } if (!recurse) break; tmp = RCLASS_SUPER(tmp); } if (!exclude && !mod_retry && BUILTIN_TYPE(klass) == T_MODULE) { mod_retry = 1; tmp = rb_cObject; goto retry; } return (int)Qfalse; } int rb_const_defined_from(VALUE klass, ID id) { return rb_const_defined_0(klass, id, TRUE, TRUE, FALSE); } int rb_const_defined(VALUE klass, ID id) { return rb_const_defined_0(klass, id, FALSE, TRUE, FALSE); } int rb_const_defined_at(VALUE klass, ID id) { return rb_const_defined_0(klass, id, TRUE, FALSE, FALSE); } MJIT_FUNC_EXPORTED int rb_public_const_defined_from(VALUE klass, ID id) { return rb_const_defined_0(klass, id, TRUE, TRUE, TRUE); } static void check_before_mod_set(VALUE klass, ID id, VALUE val, const char *dest) { rb_check_frozen(klass); } static void set_namespace_path(VALUE named_namespace, VALUE name); static enum rb_id_table_iterator_result set_namespace_path_i(ID id, VALUE v, void *payload) { rb_const_entry_t *ce = (rb_const_entry_t *)v; VALUE value = ce->value; int has_permanent_classpath; VALUE parental_path = *((VALUE *) payload); if (!rb_is_const_id(id) || !rb_namespace_p(value)) { return ID_TABLE_CONTINUE; } classname(value, &has_permanent_classpath); if (has_permanent_classpath) { return ID_TABLE_CONTINUE; } set_namespace_path(value, build_const_path(parental_path, id)); if (RCLASS_IV_TBL(value)) { st_data_t tmp = tmp_classpath; st_delete(RCLASS_IV_TBL(value), &tmp, 0); } return ID_TABLE_CONTINUE; } /* * Assign permanent classpaths to all namespaces that are directly or indirectly * nested under +named_namespace+. +named_namespace+ must have a permanent * classpath. */ static void set_namespace_path(VALUE named_namespace, VALUE namespace_path) { struct rb_id_table *const_table = RCLASS_CONST_TBL(named_namespace); RB_VM_LOCK_ENTER(); { rb_class_ivar_set(named_namespace, classpath, namespace_path); if (const_table) { rb_id_table_foreach(const_table, set_namespace_path_i, &namespace_path); } } RB_VM_LOCK_LEAVE(); } static void const_added(VALUE klass, ID const_name) { if (GET_VM()->running) { VALUE name = ID2SYM(const_name); rb_funcallv(klass, idConst_added, 1, &name); } } static void const_set(VALUE klass, ID id, VALUE val) { rb_const_entry_t *ce; if (NIL_P(klass)) { rb_raise(rb_eTypeError, "no class/module to define constant %"PRIsVALUE"", QUOTE_ID(id)); } if (!rb_ractor_main_p() && !rb_ractor_shareable_p(val)) { rb_raise(rb_eRactorIsolationError, "can not set constants with non-shareable objects by non-main Ractors"); } check_before_mod_set(klass, id, val, "constant"); RB_VM_LOCK_ENTER(); { struct rb_id_table *tbl = RCLASS_CONST_TBL(klass); if (!tbl) { RCLASS_CONST_TBL(klass) = tbl = rb_id_table_create(0); rb_clear_constant_cache_for_id(id); ce = ZALLOC(rb_const_entry_t); rb_id_table_insert(tbl, id, (VALUE)ce); setup_const_entry(ce, klass, val, CONST_PUBLIC); } else { struct autoload_const ac = { .module = klass, .name = id, .value = val, .flag = CONST_PUBLIC, /* fill the rest with 0 */ }; const_tbl_update(&ac, false); } } RB_VM_LOCK_LEAVE(); /* * Resolve and cache class name immediately to resolve ambiguity * and avoid order-dependency on const_tbl */ if (rb_cObject && rb_namespace_p(val)) { int val_path_permanent; VALUE val_path = classname(val, &val_path_permanent); if (NIL_P(val_path) || !val_path_permanent) { if (klass == rb_cObject) { set_namespace_path(val, rb_id2str(id)); } else { int parental_path_permanent; VALUE parental_path = classname(klass, &parental_path_permanent); if (NIL_P(parental_path)) { int throwaway; parental_path = rb_tmp_class_path(klass, &throwaway, make_temporary_path); } if (parental_path_permanent && !val_path_permanent) { set_namespace_path(val, build_const_path(parental_path, id)); } else if (!parental_path_permanent && NIL_P(val_path)) { ivar_set(val, tmp_classpath, build_const_path(parental_path, id)); } } } } } void rb_const_set(VALUE klass, ID id, VALUE val) { const_set(klass, id, val); const_added(klass, id); } static struct autoload_data * autoload_data_for_named_constant(VALUE module, ID name, struct autoload_const **autoload_const_pointer) { VALUE autoload_data_value = autoload_data(module, name); if (!autoload_data_value) return 0; struct autoload_data *autoload_data = get_autoload_data(autoload_data_value, autoload_const_pointer); if (!autoload_data) return 0; /* for autoloading thread, keep the defined value to autoloading storage */ if (autoload_by_current(autoload_data)) { return autoload_data; } return 0; } static void const_tbl_update(struct autoload_const *ac, int autoload_force) { VALUE value; VALUE klass = ac->module; VALUE val = ac->value; ID id = ac->name; struct rb_id_table *tbl = RCLASS_CONST_TBL(klass); rb_const_flag_t visibility = ac->flag; rb_const_entry_t *ce; if (rb_id_table_lookup(tbl, id, &value)) { ce = (rb_const_entry_t *)value; if (ce->value == Qundef) { RUBY_ASSERT_CRITICAL_SECTION_ENTER(); struct autoload_data *ele = autoload_data_for_named_constant(klass, id, &ac); if (!autoload_force && ele) { rb_clear_constant_cache_for_id(id); ac->value = val; /* autoload_data is non-WB-protected */ ac->file = rb_source_location(&ac->line); } else { /* otherwise autoloaded constant, allow to override */ autoload_delete(klass, id); ce->flag = visibility; RB_OBJ_WRITE(klass, &ce->value, val); RB_OBJ_WRITE(klass, &ce->file, ac->file); ce->line = ac->line; } RUBY_ASSERT_CRITICAL_SECTION_LEAVE(); return; } else { VALUE name = QUOTE_ID(id); visibility = ce->flag; if (klass == rb_cObject) rb_warn("already initialized constant %"PRIsVALUE"", name); else rb_warn("already initialized constant %"PRIsVALUE"::%"PRIsVALUE"", rb_class_name(klass), name); if (!NIL_P(ce->file) && ce->line) { rb_compile_warn(RSTRING_PTR(ce->file), ce->line, "previous definition of %"PRIsVALUE" was here", name); } } rb_clear_constant_cache_for_id(id); setup_const_entry(ce, klass, val, visibility); } else { rb_clear_constant_cache_for_id(id); ce = ZALLOC(rb_const_entry_t); rb_id_table_insert(tbl, id, (VALUE)ce); setup_const_entry(ce, klass, val, visibility); } } static void setup_const_entry(rb_const_entry_t *ce, VALUE klass, VALUE val, rb_const_flag_t visibility) { ce->flag = visibility; RB_OBJ_WRITE(klass, &ce->value, val); RB_OBJ_WRITE(klass, &ce->file, rb_source_location(&ce->line)); } void rb_define_const(VALUE klass, const char *name, VALUE val) { ID id = rb_intern(name); if (!rb_is_const_id(id)) { rb_warn("rb_define_const: invalid name `%s' for constant", name); } rb_gc_register_mark_object(val); rb_const_set(klass, id, val); } void rb_define_global_const(const char *name, VALUE val) { rb_define_const(rb_cObject, name, val); } static void set_const_visibility(VALUE mod, int argc, const VALUE *argv, rb_const_flag_t flag, rb_const_flag_t mask) { int i; rb_const_entry_t *ce; ID id; rb_class_modify_check(mod); if (argc == 0) { rb_warning("%"PRIsVALUE" with no argument is just ignored", QUOTE_ID(rb_frame_callee())); return; } for (i = 0; i < argc; i++) { struct autoload_const *ac; VALUE val = argv[i]; id = rb_check_id(&val); if (!id) { undefined_constant(mod, val); } if ((ce = rb_const_lookup(mod, id))) { ce->flag &= ~mask; ce->flag |= flag; if (ce->value == Qundef) { struct autoload_data *ele; ele = autoload_data_for_named_constant(mod, id, &ac); if (ele) { ac->flag &= ~mask; ac->flag |= flag; } } rb_clear_constant_cache_for_id(id); } else { undefined_constant(mod, ID2SYM(id)); } } } void rb_deprecate_constant(VALUE mod, const char *name) { rb_const_entry_t *ce; ID id; long len = strlen(name); rb_class_modify_check(mod); if (!(id = rb_check_id_cstr(name, len, NULL))) { undefined_constant(mod, rb_fstring_new(name, len)); } if (!(ce = rb_const_lookup(mod, id))) { undefined_constant(mod, ID2SYM(id)); } ce->flag |= CONST_DEPRECATED; } /* * call-seq: * mod.private_constant(symbol, ...) => mod * * Makes a list of existing constants private. */ VALUE rb_mod_private_constant(int argc, const VALUE *argv, VALUE obj) { set_const_visibility(obj, argc, argv, CONST_PRIVATE, CONST_VISIBILITY_MASK); return obj; } /* * call-seq: * mod.public_constant(symbol, ...) => mod * * Makes a list of existing constants public. */ VALUE rb_mod_public_constant(int argc, const VALUE *argv, VALUE obj) { set_const_visibility(obj, argc, argv, CONST_PUBLIC, CONST_VISIBILITY_MASK); return obj; } /* * call-seq: * mod.deprecate_constant(symbol, ...) => mod * * Makes a list of existing constants deprecated. Attempt * to refer to them will produce a warning. * * module HTTP * NotFound = Exception.new * NOT_FOUND = NotFound # previous version of the library used this name * * deprecate_constant :NOT_FOUND * end * * HTTP::NOT_FOUND * # warning: constant HTTP::NOT_FOUND is deprecated * */ VALUE rb_mod_deprecate_constant(int argc, const VALUE *argv, VALUE obj) { set_const_visibility(obj, argc, argv, CONST_DEPRECATED, CONST_DEPRECATED); return obj; } static VALUE original_module(VALUE c) { if (RB_TYPE_P(c, T_ICLASS)) return RBASIC(c)->klass; return c; } static int cvar_lookup_at(VALUE klass, ID id, st_data_t *v) { if (!RCLASS_IV_TBL(klass)) return 0; return st_lookup(RCLASS_IV_TBL(klass), (st_data_t)id, v); } static VALUE cvar_front_klass(VALUE klass) { if (FL_TEST(klass, FL_SINGLETON)) { VALUE obj = rb_ivar_get(klass, id__attached__); if (rb_namespace_p(obj)) { return obj; } } return RCLASS_SUPER(klass); } static void cvar_overtaken(VALUE front, VALUE target, ID id) { if (front && target != front) { st_data_t did = (st_data_t)id; if (original_module(front) != original_module(target)) { rb_raise(rb_eRuntimeError, "class variable % "PRIsVALUE" of %"PRIsVALUE" is overtaken by %"PRIsVALUE"", ID2SYM(id), rb_class_name(original_module(front)), rb_class_name(original_module(target))); } if (BUILTIN_TYPE(front) == T_CLASS) { st_delete(RCLASS_IV_TBL(front), &did, 0); } } } static VALUE find_cvar(VALUE klass, VALUE * front, VALUE * target, ID id) { VALUE v = Qundef; CVAR_ACCESSOR_SHOULD_BE_MAIN_RACTOR(); if (cvar_lookup_at(klass, id, (&v))) { if (!*front) { *front = klass; } *target = klass; } for (klass = cvar_front_klass(klass); klass; klass = RCLASS_SUPER(klass)) { if (cvar_lookup_at(klass, id, (&v))) { if (!*front) { *front = klass; } *target = klass; } } return v; } #define CVAR_FOREACH_ANCESTORS(klass, v, r) \ for (klass = cvar_front_klass(klass); klass; klass = RCLASS_SUPER(klass)) { \ if (cvar_lookup_at(klass, id, (v))) { \ r; \ } \ } #define CVAR_LOOKUP(v,r) do {\ CVAR_ACCESSOR_SHOULD_BE_MAIN_RACTOR(); \ if (cvar_lookup_at(klass, id, (v))) {r;}\ CVAR_FOREACH_ANCESTORS(klass, v, r);\ } while(0) static void check_for_cvar_table(VALUE subclass, VALUE key) { st_table *tbl = RCLASS_IV_TBL(subclass); if (tbl && st_lookup(tbl, key, NULL)) { RB_DEBUG_COUNTER_INC(cvar_class_invalidate); ruby_vm_global_cvar_state++; return; } rb_class_foreach_subclass(subclass, check_for_cvar_table, key); } void rb_cvar_set(VALUE klass, ID id, VALUE val) { VALUE tmp, front = 0, target = 0; tmp = klass; CVAR_LOOKUP(0, {if (!front) front = klass; target = klass;}); if (target) { cvar_overtaken(front, target, id); } else { target = tmp; } if (RB_TYPE_P(target, T_ICLASS)) { target = RBASIC(target)->klass; } check_before_mod_set(target, id, val, "class variable"); int result = rb_class_ivar_set(target, id, val); struct rb_id_table *rb_cvc_tbl = RCLASS_CVC_TBL(target); if (!rb_cvc_tbl) { rb_cvc_tbl = RCLASS_CVC_TBL(target) = rb_id_table_create(2); } struct rb_cvar_class_tbl_entry *ent; VALUE ent_data; if (!rb_id_table_lookup(rb_cvc_tbl, id, &ent_data)) { ent = ALLOC(struct rb_cvar_class_tbl_entry); ent->class_value = target; ent->global_cvar_state = GET_GLOBAL_CVAR_STATE(); rb_id_table_insert(rb_cvc_tbl, id, (VALUE)ent); RB_DEBUG_COUNTER_INC(cvar_inline_miss); } else { ent = (void *)ent_data; ent->global_cvar_state = GET_GLOBAL_CVAR_STATE(); } // Break the cvar cache if this is a new class variable // and target is a module or a subclass with the same // cvar in this lookup. if (result == 0) { if (RB_TYPE_P(target, T_CLASS)) { if (RCLASS_SUBCLASSES(target)) { rb_class_foreach_subclass(target, check_for_cvar_table, id); } } } } VALUE rb_cvar_find(VALUE klass, ID id, VALUE *front) { VALUE target = 0; VALUE value; value = find_cvar(klass, front, &target, id); if (!target) { rb_name_err_raise("uninitialized class variable %1$s in %2$s", klass, ID2SYM(id)); } cvar_overtaken(*front, target, id); return (VALUE)value; } VALUE rb_cvar_get(VALUE klass, ID id) { VALUE front = 0; return rb_cvar_find(klass, id, &front); } VALUE rb_cvar_defined(VALUE klass, ID id) { if (!klass) return Qfalse; CVAR_LOOKUP(0,return Qtrue); return Qfalse; } static ID cv_intern(VALUE klass, const char *name) { ID id = rb_intern(name); if (!rb_is_class_id(id)) { rb_name_err_raise("wrong class variable name %1$s", klass, rb_str_new_cstr(name)); } return id; } void rb_cv_set(VALUE klass, const char *name, VALUE val) { ID id = cv_intern(klass, name); rb_cvar_set(klass, id, val); } VALUE rb_cv_get(VALUE klass, const char *name) { ID id = cv_intern(klass, name); return rb_cvar_get(klass, id); } void rb_define_class_variable(VALUE klass, const char *name, VALUE val) { rb_cv_set(klass, name, val); } static int cv_i(st_data_t k, st_data_t v, st_data_t a) { ID key = (ID)k; st_table *tbl = (st_table *)a; if (rb_is_class_id(key)) { st_update(tbl, (st_data_t)key, cv_i_update, 0); } return ST_CONTINUE; } static void* mod_cvar_at(VALUE mod, void *data) { st_table *tbl = data; if (!tbl) { tbl = st_init_numtable(); } if (RCLASS_IV_TBL(mod)) { st_foreach_safe(RCLASS_IV_TBL(mod), cv_i, (st_data_t)tbl); } return tbl; } static void* mod_cvar_of(VALUE mod, void *data) { VALUE tmp = mod; if (FL_TEST(mod, FL_SINGLETON)) { if (rb_namespace_p(rb_ivar_get(mod, id__attached__))) { data = mod_cvar_at(tmp, data); tmp = cvar_front_klass(tmp); } } for (;;) { data = mod_cvar_at(tmp, data); tmp = RCLASS_SUPER(tmp); if (!tmp) break; } return data; } static int cv_list_i(st_data_t key, st_data_t value, VALUE ary) { ID sym = (ID)key; rb_ary_push(ary, ID2SYM(sym)); return ST_CONTINUE; } static VALUE cvar_list(void *data) { st_table *tbl = data; VALUE ary; if (!tbl) return rb_ary_new2(0); ary = rb_ary_new2(tbl->num_entries); st_foreach_safe(tbl, cv_list_i, ary); st_free_table(tbl); return ary; } /* * call-seq: * mod.class_variables(inherit=true) -> array * * Returns an array of the names of class variables in mod. * This includes the names of class variables in any included * modules, unless the inherit parameter is set to * false. * * class One * @@var1 = 1 * end * class Two < One * @@var2 = 2 * end * One.class_variables #=> [:@@var1] * Two.class_variables #=> [:@@var2, :@@var1] * Two.class_variables(false) #=> [:@@var2] */ VALUE rb_mod_class_variables(int argc, const VALUE *argv, VALUE mod) { bool inherit = true; st_table *tbl; if (rb_check_arity(argc, 0, 1)) inherit = RTEST(argv[0]); if (inherit) { tbl = mod_cvar_of(mod, 0); } else { tbl = mod_cvar_at(mod, 0); } return cvar_list(tbl); } /* * call-seq: * remove_class_variable(sym) -> obj * * Removes the named class variable from the receiver, returning that * variable's value. * * class Example * @@var = 99 * puts remove_class_variable(:@@var) * p(defined? @@var) * end * * produces: * * 99 * nil */ VALUE rb_mod_remove_cvar(VALUE mod, VALUE name) { const ID id = id_for_var_message(mod, name, class, "wrong class variable name %1$s"); st_data_t val, n = id; if (!id) { goto not_defined; } rb_check_frozen(mod); if (RCLASS_IV_TBL(mod) && st_delete(RCLASS_IV_TBL(mod), &n, &val)) { return (VALUE)val; } if (rb_cvar_defined(mod, id)) { rb_name_err_raise("cannot remove %1$s for %2$s", mod, ID2SYM(id)); } not_defined: rb_name_err_raise("class variable %1$s not defined for %2$s", mod, name); UNREACHABLE_RETURN(Qundef); } VALUE rb_iv_get(VALUE obj, const char *name) { ID id = rb_check_id_cstr(name, strlen(name), rb_usascii_encoding()); if (!id) { return Qnil; } return rb_ivar_get(obj, id); } VALUE rb_iv_set(VALUE obj, const char *name, VALUE val) { ID id = rb_intern(name); return rb_ivar_set(obj, id, val); } /* tbl = xx(obj); tbl[key] = value; */ int rb_class_ivar_set(VALUE obj, ID key, VALUE value) { if (!RCLASS_IV_TBL(obj)) { RCLASS_IV_TBL(obj) = st_init_numtable(); } st_table *tbl = RCLASS_IV_TBL(obj); int result = lock_st_insert(tbl, (st_data_t)key, (st_data_t)value); RB_OBJ_WRITTEN(obj, Qundef, value); return result; } static int tbl_copy_i(st_data_t key, st_data_t value, st_data_t data) { RB_OBJ_WRITTEN((VALUE)data, Qundef, (VALUE)value); return ST_CONTINUE; } void rb_iv_tbl_copy(VALUE dst, VALUE src) { st_table *orig_tbl = RCLASS_IV_TBL(src); st_table *new_tbl = st_copy(orig_tbl); st_foreach(new_tbl, tbl_copy_i, (st_data_t)dst); RCLASS_IV_TBL(dst) = new_tbl; } MJIT_FUNC_EXPORTED rb_const_entry_t * rb_const_lookup(VALUE klass, ID id) { struct rb_id_table *tbl = RCLASS_CONST_TBL(klass); if (tbl) { VALUE val; bool r; RB_VM_LOCK_ENTER(); { r = rb_id_table_lookup(tbl, id, &val); } RB_VM_LOCK_LEAVE(); if (r) return (rb_const_entry_t *)val; } return NULL; }