#include "internal.h" #include "internal/gc.h" #include "internal/hash.h" #include "internal/proc.h" #include "internal/sanitizers.h" #include "ruby/st.h" /* ===== WeakMap ===== * * WeakMap contains one ST table which contains a pointer to the object as the * key and a pointer to the object as the value. This means that the key and * value of the table are both of the type `VALUE *`. * * The objects are not directly stored as keys and values in the table because * `rb_gc_mark_weak` requires a pointer to the memory location to overwrite * when the object is reclaimed. Using a pointer into the ST table entry is not * safe because the pointer can change when the ST table is resized. * * WeakMap hashes and compares using the pointer address of the object. * * For performance and memory efficiency reasons, the key and value * are allocated at the same time and adjacent to each other. * * During GC and while iterating, reclaimed entries (i.e. either the key or * value points to `Qundef`) are removed from the ST table. */ struct weakmap { st_table *table; }; struct weakmap_entry { VALUE key; VALUE val; }; static bool wmap_live_p(VALUE obj) { return !UNDEF_P(obj); } struct wmap_foreach_data { int (*func)(struct weakmap_entry *, st_data_t); st_data_t arg; struct weakmap_entry *dead_entry; }; static int wmap_foreach_i(st_data_t key, st_data_t val, st_data_t arg) { struct wmap_foreach_data *data = (struct wmap_foreach_data *)arg; if (data->dead_entry != NULL) { ruby_sized_xfree(data->dead_entry, sizeof(struct weakmap_entry)); data->dead_entry = NULL; } struct weakmap_entry *entry = (struct weakmap_entry *)key; RUBY_ASSERT(&entry->val == (VALUE *)val); if (wmap_live_p(entry->key) && wmap_live_p(entry->val)) { VALUE k = entry->key; VALUE v = entry->val; int ret = data->func(entry, data->arg); RB_GC_GUARD(k); RB_GC_GUARD(v); return ret; } else { /* We cannot free the weakmap_entry here because the ST_DELETE could * hash the key which would read the weakmap_entry and would cause a * use-after-free. Instead, we store this entry and free it on the next * iteration. */ data->dead_entry = entry; return ST_DELETE; } } static void wmap_foreach(struct weakmap *w, int (*func)(struct weakmap_entry *, st_data_t), st_data_t arg) { struct wmap_foreach_data foreach_data = { .func = func, .arg = arg, .dead_entry = NULL, }; st_foreach(w->table, wmap_foreach_i, (st_data_t)&foreach_data); ruby_sized_xfree(foreach_data.dead_entry, sizeof(struct weakmap_entry)); } static int wmap_mark_weak_table_i(struct weakmap_entry *entry, st_data_t _) { rb_gc_mark_weak(&entry->key); rb_gc_mark_weak(&entry->val); return ST_CONTINUE; } static void wmap_mark(void *ptr) { struct weakmap *w = ptr; if (w->table) { wmap_foreach(w, wmap_mark_weak_table_i, (st_data_t)0); } } static int wmap_free_table_i(st_data_t key, st_data_t val, st_data_t arg) { struct weakmap_entry *entry = (struct weakmap_entry *)key; RUBY_ASSERT(&entry->val == (VALUE *)val); ruby_sized_xfree(entry, sizeof(struct weakmap_entry)); return ST_CONTINUE; } static void wmap_free(void *ptr) { struct weakmap *w = ptr; st_foreach(w->table, wmap_free_table_i, 0); st_free_table(w->table); } static size_t wmap_memsize(const void *ptr) { const struct weakmap *w = ptr; size_t size = 0; size += st_memsize(w->table); /* The key and value of the table each take sizeof(VALUE) in size. */ size += st_table_size(w->table) * (2 * sizeof(VALUE)); return size; } static int wmap_compact_table_i(struct weakmap_entry *entry, st_data_t data) { st_table *table = (st_table *)data; VALUE new_key = rb_gc_location(entry->key); entry->val = rb_gc_location(entry->val); /* If the key object moves, then we must reinsert because the hash is * based on the pointer rather than the object itself. */ if (entry->key != new_key) { entry->key = new_key; DURING_GC_COULD_MALLOC_REGION_START(); { st_insert(table, (st_data_t)&entry->key, (st_data_t)&entry->val); } DURING_GC_COULD_MALLOC_REGION_END(); return ST_DELETE; } return ST_CONTINUE; } static void wmap_compact(void *ptr) { struct weakmap *w = ptr; if (w->table) { wmap_foreach(w, wmap_compact_table_i, (st_data_t)w->table); } } static const rb_data_type_t weakmap_type = { "weakmap", { wmap_mark, wmap_free, wmap_memsize, wmap_compact, }, 0, 0, RUBY_TYPED_FREE_IMMEDIATELY | RUBY_TYPED_WB_PROTECTED | RUBY_TYPED_EMBEDDABLE }; static int wmap_cmp(st_data_t x, st_data_t y) { return *(VALUE *)x != *(VALUE *)y; } static st_index_t wmap_hash(st_data_t n) { return st_numhash(*(VALUE *)n); } static const struct st_hash_type wmap_hash_type = { wmap_cmp, wmap_hash, }; static VALUE wmap_allocate(VALUE klass) { struct weakmap *w; VALUE obj = TypedData_Make_Struct(klass, struct weakmap, &weakmap_type, w); w->table = st_init_table(&wmap_hash_type); return obj; } static VALUE wmap_inspect_append(VALUE str, VALUE obj) { if (SPECIAL_CONST_P(obj)) { return rb_str_append(str, rb_inspect(obj)); } else { return rb_str_append(str, rb_any_to_s(obj)); } } static int wmap_inspect_i(struct weakmap_entry *entry, st_data_t data) { VALUE str = (VALUE)data; if (RSTRING_PTR(str)[0] == '#') { rb_str_cat2(str, ", "); } else { rb_str_cat2(str, ": "); RSTRING_PTR(str)[0] = '#'; } wmap_inspect_append(str, entry->key); rb_str_cat2(str, " => "); wmap_inspect_append(str, entry->val); return ST_CONTINUE; } static VALUE wmap_inspect(VALUE self) { VALUE c = rb_class_name(CLASS_OF(self)); struct weakmap *w; TypedData_Get_Struct(self, struct weakmap, &weakmap_type, w); VALUE str = rb_sprintf("-<%"PRIsVALUE":%p", c, (void *)self); wmap_foreach(w, wmap_inspect_i, (st_data_t)str); RSTRING_PTR(str)[0] = '#'; rb_str_cat2(str, ">"); return str; } static int wmap_each_i(struct weakmap_entry *entry, st_data_t _) { rb_yield_values(2, entry->key, entry->val); return ST_CONTINUE; } /* * call-seq: * map.each {|key, val| ... } -> self * * Iterates over keys and values. Note that unlike other collections, * +each+ without block isn't supported. * */ static VALUE wmap_each(VALUE self) { struct weakmap *w; TypedData_Get_Struct(self, struct weakmap, &weakmap_type, w); wmap_foreach(w, wmap_each_i, (st_data_t)0); return self; } static int wmap_each_key_i(struct weakmap_entry *entry, st_data_t _data) { rb_yield(entry->key); return ST_CONTINUE; } /* * call-seq: * map.each_key {|key| ... } -> self * * Iterates over keys. Note that unlike other collections, * +each_key+ without block isn't supported. * */ static VALUE wmap_each_key(VALUE self) { struct weakmap *w; TypedData_Get_Struct(self, struct weakmap, &weakmap_type, w); wmap_foreach(w, wmap_each_key_i, (st_data_t)0); return self; } static int wmap_each_value_i(struct weakmap_entry *entry, st_data_t _data) { rb_yield(entry->val); return ST_CONTINUE; } /* * call-seq: * map.each_value {|val| ... } -> self * * Iterates over values. Note that unlike other collections, * +each_value+ without block isn't supported. * */ static VALUE wmap_each_value(VALUE self) { struct weakmap *w; TypedData_Get_Struct(self, struct weakmap, &weakmap_type, w); wmap_foreach(w, wmap_each_value_i, (st_data_t)0); return self; } static int wmap_keys_i(struct weakmap_entry *entry, st_data_t arg) { VALUE ary = (VALUE)arg; rb_ary_push(ary, entry->key); return ST_CONTINUE; } /* * call-seq: * map.keys -> new_array * * Returns a new Array containing all keys in the map. * */ static VALUE wmap_keys(VALUE self) { struct weakmap *w; TypedData_Get_Struct(self, struct weakmap, &weakmap_type, w); VALUE ary = rb_ary_new(); wmap_foreach(w, wmap_keys_i, (st_data_t)ary); return ary; } static int wmap_values_i(struct weakmap_entry *entry, st_data_t arg) { VALUE ary = (VALUE)arg; rb_ary_push(ary, entry->val); return ST_CONTINUE; } /* * call-seq: * map.values -> new_array * * Returns a new Array containing all values in the map. * */ static VALUE wmap_values(VALUE self) { struct weakmap *w; TypedData_Get_Struct(self, struct weakmap, &weakmap_type, w); VALUE ary = rb_ary_new(); wmap_foreach(w, wmap_values_i, (st_data_t)ary); return ary; } static VALUE nonspecial_obj_id(VALUE obj) { #if SIZEOF_LONG == SIZEOF_VOIDP return (VALUE)((SIGNED_VALUE)(obj)|FIXNUM_FLAG); #elif SIZEOF_LONG_LONG == SIZEOF_VOIDP return LL2NUM((SIGNED_VALUE)(obj) / 2); #else # error not supported #endif } static int wmap_aset_replace(st_data_t *key, st_data_t *val, st_data_t new_key_ptr, int existing) { VALUE new_key = *(VALUE *)new_key_ptr; VALUE new_val = *(((VALUE *)new_key_ptr) + 1); if (existing) { RUBY_ASSERT(*(VALUE *)*key == new_key); } else { struct weakmap_entry *entry = xmalloc(sizeof(struct weakmap_entry)); *key = (st_data_t)&entry->key;; *val = (st_data_t)&entry->val; } *(VALUE *)*key = new_key; *(VALUE *)*val = new_val; return ST_CONTINUE; } /* * call-seq: * map[key] = value -> value * * Associates the given +value+ with the given +key+. * * If the given +key+ exists, replaces its value with the given +value+; * the ordering is not affected. */ static VALUE wmap_aset(VALUE self, VALUE key, VALUE val) { struct weakmap *w; TypedData_Get_Struct(self, struct weakmap, &weakmap_type, w); VALUE pair[2] = { key, val }; st_update(w->table, (st_data_t)pair, wmap_aset_replace, (st_data_t)pair); RB_OBJ_WRITTEN(self, Qundef, key); RB_OBJ_WRITTEN(self, Qundef, val); return nonspecial_obj_id(val); } /* Retrieves a weakly referenced object with the given key */ static VALUE wmap_lookup(VALUE self, VALUE key) { RUBY_ASSERT(wmap_live_p(key)); struct weakmap *w; TypedData_Get_Struct(self, struct weakmap, &weakmap_type, w); st_data_t data; if (!st_lookup(w->table, (st_data_t)&key, &data)) return Qundef; if (!wmap_live_p(*(VALUE *)data)) return Qundef; return *(VALUE *)data; } /* * call-seq: * map[key] -> value * * Returns the value associated with the given +key+ if found. * * If +key+ is not found, returns +nil+. */ static VALUE wmap_aref(VALUE self, VALUE key) { VALUE obj = wmap_lookup(self, key); return !UNDEF_P(obj) ? obj : Qnil; } /* * call-seq: * map.delete(key) -> value or nil * map.delete(key) {|key| ... } -> object * * Deletes the entry for the given +key+ and returns its associated value. * * If no block is given and +key+ is found, deletes the entry and returns the associated value: * m = ObjectSpace::WeakMap.new * key = "foo" * m[key] = 1 * m.delete(key) # => 1 * m[key] # => nil * * If no block is given and +key+ is not found, returns +nil+. * * If a block is given and +key+ is found, ignores the block, * deletes the entry, and returns the associated value: * m = ObjectSpace::WeakMap.new * key = "foo" * m[key] = 2 * m.delete(key) { |key| raise 'Will never happen'} # => 2 * * If a block is given and +key+ is not found, * yields the +key+ to the block and returns the block's return value: * m = ObjectSpace::WeakMap.new * m.delete("nosuch") { |key| "Key #{key} not found" } # => "Key nosuch not found" */ static VALUE wmap_delete(VALUE self, VALUE key) { struct weakmap *w; TypedData_Get_Struct(self, struct weakmap, &weakmap_type, w); VALUE orig_key = key; st_data_t orig_key_data = (st_data_t)&orig_key; st_data_t orig_val_data; if (st_delete(w->table, &orig_key_data, &orig_val_data)) { VALUE orig_val = *(VALUE *)orig_val_data; rb_gc_remove_weak(self, (VALUE *)orig_key_data); rb_gc_remove_weak(self, (VALUE *)orig_val_data); struct weakmap_entry *entry = (struct weakmap_entry *)orig_key_data; ruby_sized_xfree(entry, sizeof(struct weakmap_entry)); if (wmap_live_p(orig_val)) { return orig_val; } } if (rb_block_given_p()) { return rb_yield(key); } else { return Qnil; } } /* * call-seq: * map.key?(key) -> true or false * * Returns +true+ if +key+ is a key in +self+, otherwise +false+. */ static VALUE wmap_has_key(VALUE self, VALUE key) { return RBOOL(!UNDEF_P(wmap_lookup(self, key))); } /* * call-seq: * map.size -> number * * Returns the number of referenced objects */ static VALUE wmap_size(VALUE self) { struct weakmap *w; TypedData_Get_Struct(self, struct weakmap, &weakmap_type, w); st_index_t n = st_table_size(w->table); #if SIZEOF_ST_INDEX_T <= SIZEOF_LONG return ULONG2NUM(n); #else return ULL2NUM(n); #endif } /* ===== WeakKeyMap ===== * * WeakKeyMap contains one ST table which contains a pointer to the object as * the key and the object as the value. This means that the key is of the type * `VALUE *` while the value is of the type `VALUE`. * * The object is not directly stored as keys in the table because * `rb_gc_mark_weak` requires a pointer to the memory location to overwrite * when the object is reclaimed. Using a pointer into the ST table entry is not * safe because the pointer can change when the ST table is resized. * * WeakKeyMap hashes and compares using the `#hash` and `#==` methods of the * object, respectively. * * During GC and while iterating, reclaimed entries (i.e. the key points to * `Qundef`) are removed from the ST table. */ struct weakkeymap { st_table *table; }; static int wkmap_mark_table_i(st_data_t key, st_data_t val_obj, st_data_t data) { VALUE **dead_entry = (VALUE **)data; if (dead_entry != NULL) { ruby_sized_xfree(*dead_entry, sizeof(VALUE)); *dead_entry = NULL; } VALUE *key_ptr = (VALUE *)key; if (wmap_live_p(*key_ptr)) { rb_gc_mark_weak(key_ptr); rb_gc_mark_movable((VALUE)val_obj); return ST_CONTINUE; } else { *dead_entry = key_ptr; return ST_DELETE; } } static void wkmap_mark(void *ptr) { struct weakkeymap *w = ptr; if (w->table) { VALUE *dead_entry = NULL; st_foreach(w->table, wkmap_mark_table_i, (st_data_t)&dead_entry); if (dead_entry != NULL) { ruby_sized_xfree(dead_entry, sizeof(VALUE)); } } } static int wkmap_free_table_i(st_data_t key, st_data_t _val, st_data_t _arg) { ruby_sized_xfree((VALUE *)key, sizeof(VALUE)); return ST_CONTINUE; } static void wkmap_free(void *ptr) { struct weakkeymap *w = ptr; st_foreach(w->table, wkmap_free_table_i, 0); st_free_table(w->table); } static size_t wkmap_memsize(const void *ptr) { const struct weakkeymap *w = ptr; size_t size = 0; size += st_memsize(w->table); /* Each key of the table takes sizeof(VALUE) in size. */ size += st_table_size(w->table) * sizeof(VALUE); return size; } static int wkmap_compact_table_i(st_data_t key, st_data_t val_obj, st_data_t data, int _error) { VALUE **dead_entry = (VALUE **)data; if (dead_entry != NULL) { ruby_sized_xfree(*dead_entry, sizeof(VALUE)); *dead_entry = NULL; } VALUE *key_ptr = (VALUE *)key; if (wmap_live_p(*key_ptr)) { if (*key_ptr != rb_gc_location(*key_ptr) || val_obj != rb_gc_location(val_obj)) { return ST_REPLACE; } return ST_CONTINUE; } else { *dead_entry = key_ptr; return ST_DELETE; } } static int wkmap_compact_table_replace(st_data_t *key_ptr, st_data_t *val_ptr, st_data_t _data, int existing) { RUBY_ASSERT(existing); *(VALUE *)*key_ptr = rb_gc_location(*(VALUE *)*key_ptr); *val_ptr = (st_data_t)rb_gc_location((VALUE)*val_ptr); return ST_CONTINUE; } static void wkmap_compact(void *ptr) { struct weakkeymap *w = ptr; if (w->table) { VALUE *dead_entry = NULL; st_foreach_with_replace(w->table, wkmap_compact_table_i, wkmap_compact_table_replace, (st_data_t)&dead_entry); if (dead_entry != NULL) { ruby_sized_xfree(dead_entry, sizeof(VALUE)); } } } static const rb_data_type_t weakkeymap_type = { "weakkeymap", { wkmap_mark, wkmap_free, wkmap_memsize, wkmap_compact, }, 0, 0, RUBY_TYPED_FREE_IMMEDIATELY | RUBY_TYPED_WB_PROTECTED | RUBY_TYPED_EMBEDDABLE }; static int wkmap_cmp(st_data_t x, st_data_t y) { VALUE x_obj = *(VALUE *)x; VALUE y_obj = *(VALUE *)y; if (wmap_live_p(x_obj) && wmap_live_p(y_obj)) { return rb_any_cmp(x_obj, y_obj); } else { /* If one of the objects is dead, then they cannot be the same. */ return 1; } } static st_index_t wkmap_hash(st_data_t n) { VALUE obj = *(VALUE *)n; RUBY_ASSERT(wmap_live_p(obj)); return rb_any_hash(obj); } static const struct st_hash_type wkmap_hash_type = { wkmap_cmp, wkmap_hash, }; static VALUE wkmap_allocate(VALUE klass) { struct weakkeymap *w; VALUE obj = TypedData_Make_Struct(klass, struct weakkeymap, &weakkeymap_type, w); w->table = st_init_table(&wkmap_hash_type); return obj; } static VALUE wkmap_lookup(VALUE self, VALUE key) { struct weakkeymap *w; TypedData_Get_Struct(self, struct weakkeymap, &weakkeymap_type, w); st_data_t data; if (!st_lookup(w->table, (st_data_t)&key, &data)) return Qundef; return (VALUE)data; } /* * call-seq: * map[key] -> value * * Returns the value associated with the given +key+ if found. * * If +key+ is not found, returns +nil+. */ static VALUE wkmap_aref(VALUE self, VALUE key) { VALUE obj = wkmap_lookup(self, key); return !UNDEF_P(obj) ? obj : Qnil; } struct wkmap_aset_args { VALUE new_key; VALUE new_val; }; static int wkmap_aset_replace(st_data_t *key, st_data_t *val, st_data_t data_args, int existing) { struct wkmap_aset_args *args = (struct wkmap_aset_args *)data_args; if (!existing) { *key = (st_data_t)xmalloc(sizeof(VALUE)); } *(VALUE *)*key = args->new_key; *val = (st_data_t)args->new_val; return ST_CONTINUE; } /* * call-seq: * map[key] = value -> value * * Associates the given +value+ with the given +key+ * * The reference to +key+ is weak, so when there is no other reference * to +key+ it may be garbage collected. * * If the given +key+ exists, replaces its value with the given +value+; * the ordering is not affected */ static VALUE wkmap_aset(VALUE self, VALUE key, VALUE val) { struct weakkeymap *w; TypedData_Get_Struct(self, struct weakkeymap, &weakkeymap_type, w); if (!FL_ABLE(key) || SYMBOL_P(key) || RB_BIGNUM_TYPE_P(key) || RB_TYPE_P(key, T_FLOAT)) { rb_raise(rb_eArgError, "WeakKeyMap must be garbage collectable"); UNREACHABLE_RETURN(Qnil); } struct wkmap_aset_args args = { .new_key = key, .new_val = val, }; st_update(w->table, (st_data_t)&key, wkmap_aset_replace, (st_data_t)&args); RB_OBJ_WRITTEN(self, Qundef, key); RB_OBJ_WRITTEN(self, Qundef, val); return val; } /* * call-seq: * map.delete(key) -> value or nil * map.delete(key) {|key| ... } -> object * * Deletes the entry for the given +key+ and returns its associated value. * * If no block is given and +key+ is found, deletes the entry and returns the associated value: * m = ObjectSpace::WeakKeyMap.new * key = "foo" # to hold reference to the key * m[key] = 1 * m.delete("foo") # => 1 * m["foo"] # => nil * * If no block given and +key+ is not found, returns +nil+. * * If a block is given and +key+ is found, ignores the block, * deletes the entry, and returns the associated value: * m = ObjectSpace::WeakKeyMap.new * key = "foo" # to hold reference to the key * m[key] = 2 * m.delete("foo") { |key| raise 'Will never happen'} # => 2 * * If a block is given and +key+ is not found, * yields the +key+ to the block and returns the block's return value: * m = ObjectSpace::WeakKeyMap.new * m.delete("nosuch") { |key| "Key #{key} not found" } # => "Key nosuch not found" */ static VALUE wkmap_delete(VALUE self, VALUE key) { struct weakkeymap *w; TypedData_Get_Struct(self, struct weakkeymap, &weakkeymap_type, w); VALUE orig_key = key; st_data_t orig_key_data = (st_data_t)&orig_key; st_data_t orig_val_data; if (st_delete(w->table, &orig_key_data, &orig_val_data)) { VALUE orig_val = (VALUE)orig_val_data; rb_gc_remove_weak(self, (VALUE *)orig_key_data); ruby_sized_xfree((VALUE *)orig_key_data, sizeof(VALUE)); return orig_val; } if (rb_block_given_p()) { return rb_yield(key); } else { return Qnil; } } /* * call-seq: * map.getkey(key) -> existing_key or nil * * Returns the existing equal key if it exists, otherwise returns +nil+. * * This might be useful for implementing caches, so that only one copy of * some object would be used everywhere in the program: * * value = {amount: 1, currency: 'USD'} * * # Now if we put this object in a cache: * cache = ObjectSpace::WeakKeyMap.new * cache[value] = true * * # ...we can always extract from there and use the same object: * copy = cache.getkey({amount: 1, currency: 'USD'}) * copy.object_id == value.object_id #=> true */ static VALUE wkmap_getkey(VALUE self, VALUE key) { struct weakkeymap *w; TypedData_Get_Struct(self, struct weakkeymap, &weakkeymap_type, w); st_data_t orig_key; if (!st_get_key(w->table, (st_data_t)&key, &orig_key)) return Qnil; return *(VALUE *)orig_key; } /* * call-seq: * map.key?(key) -> true or false * * Returns +true+ if +key+ is a key in +self+, otherwise +false+. */ static VALUE wkmap_has_key(VALUE self, VALUE key) { return RBOOL(!UNDEF_P(wkmap_lookup(self, key))); } static int wkmap_clear_i(st_data_t key, st_data_t val, st_data_t data) { VALUE self = (VALUE)data; /* This WeakKeyMap may have already been marked, so we need to remove the * keys to prevent a use-after-free. */ rb_gc_remove_weak(self, (VALUE *)key); return wkmap_free_table_i(key, val, 0); } /* * call-seq: * map.clear -> self * * Removes all map entries; returns +self+. */ static VALUE wkmap_clear(VALUE self) { struct weakkeymap *w; TypedData_Get_Struct(self, struct weakkeymap, &weakkeymap_type, w); st_foreach(w->table, wkmap_clear_i, (st_data_t)self); st_clear(w->table); return self; } /* * call-seq: * map.inspect -> new_string * * Returns a new String containing informations about the map: * * m = ObjectSpace::WeakKeyMap.new * m[key] = value * m.inspect # => "#" * */ static VALUE wkmap_inspect(VALUE self) { struct weakkeymap *w; TypedData_Get_Struct(self, struct weakkeymap, &weakkeymap_type, w); st_index_t n = st_table_size(w->table); #if SIZEOF_ST_INDEX_T <= SIZEOF_LONG const char * format = "#<%"PRIsVALUE":%p size=%lu>"; #else const char * format = "#<%"PRIsVALUE":%p size=%llu>"; #endif VALUE str = rb_sprintf(format, rb_class_name(CLASS_OF(self)), (void *)self, n); return str; } /* * Document-class: ObjectSpace::WeakMap * * An ObjectSpace::WeakMap is a key-value map that holds weak references * to its keys and values, so they can be garbage-collected when there are * no more references left. * * Keys in the map are compared by identity. * * m = ObjectSpace::WeakMap.new * key1 = "foo" * val1 = Object.new * m[key1] = val1 * * key2 = "bar" * val2 = Object.new * m[key2] = val2 * * m[key1] #=> # * m[key2] #=> # * * val1 = nil # remove the other reference to value * GC.start * * m[key1] #=> nil * m.keys #=> ["bar"] * * key2 = nil # remove the other reference to key * GC.start * * m[key2] #=> nil * m.keys #=> [] * * (Note that GC.start is used here only for demonstrational purposes and might * not always lead to demonstrated results.) * * * See also ObjectSpace::WeakKeyMap map class, which compares keys by value, * and holds weak references only to the keys. */ /* * Document-class: ObjectSpace::WeakKeyMap * * An ObjectSpace::WeakKeyMap is a key-value map that holds weak references * to its keys, so they can be garbage collected when there is no more references. * * Unlike ObjectSpace::WeakMap: * * * references to values are _strong_, so they aren't garbage collected while * they are in the map; * * keys are compared by value (using Object#eql?), not by identity; * * only garbage-collectable objects can be used as keys. * * map = ObjectSpace::WeakKeyMap.new * val = Time.new(2023, 12, 7) * key = "name" * map[key] = val * * # Value is fetched by equality: the instance of string "name" is * # different here, but it is equal to the key * map["name"] #=> 2023-12-07 00:00:00 +0200 * * val = nil * GC.start * # There are no more references to `val`, yet the pair isn't * # garbage-collected. * map["name"] #=> 2023-12-07 00:00:00 +0200 * * key = nil * GC.start * # There are no more references to `key`, key and value are * # garbage-collected. * map["name"] #=> nil * * (Note that GC.start is used here only for demonstrational purposes and might * not always lead to demonstrated results.) * * The collection is especially useful for implementing caches of lightweight value * objects, so that only one copy of each value representation would be stored in * memory, but the copies that aren't used would be garbage-collected. * * CACHE = ObjectSpace::WeakKeyMap * * def make_value(**) * val = ValueObject.new(**) * if (existing = @cache.getkey(val)) * # if the object with this value exists, we return it * existing * else * # otherwise, put it in the cache * @cache[val] = true * val * end * end * * This will result in +make_value+ returning the same object for same set of attributes * always, but the values that aren't needed anymore wouldn't be sitting in the cache forever. */ void Init_WeakMap(void) { VALUE rb_mObjectSpace = rb_define_module("ObjectSpace"); VALUE rb_cWeakMap = rb_define_class_under(rb_mObjectSpace, "WeakMap", rb_cObject); rb_define_alloc_func(rb_cWeakMap, wmap_allocate); rb_define_method(rb_cWeakMap, "[]=", wmap_aset, 2); rb_define_method(rb_cWeakMap, "[]", wmap_aref, 1); rb_define_method(rb_cWeakMap, "delete", wmap_delete, 1); rb_define_method(rb_cWeakMap, "include?", wmap_has_key, 1); rb_define_method(rb_cWeakMap, "member?", wmap_has_key, 1); rb_define_method(rb_cWeakMap, "key?", wmap_has_key, 1); rb_define_method(rb_cWeakMap, "inspect", wmap_inspect, 0); rb_define_method(rb_cWeakMap, "each", wmap_each, 0); rb_define_method(rb_cWeakMap, "each_pair", wmap_each, 0); rb_define_method(rb_cWeakMap, "each_key", wmap_each_key, 0); rb_define_method(rb_cWeakMap, "each_value", wmap_each_value, 0); rb_define_method(rb_cWeakMap, "keys", wmap_keys, 0); rb_define_method(rb_cWeakMap, "values", wmap_values, 0); rb_define_method(rb_cWeakMap, "size", wmap_size, 0); rb_define_method(rb_cWeakMap, "length", wmap_size, 0); rb_include_module(rb_cWeakMap, rb_mEnumerable); VALUE rb_cWeakKeyMap = rb_define_class_under(rb_mObjectSpace, "WeakKeyMap", rb_cObject); rb_define_alloc_func(rb_cWeakKeyMap, wkmap_allocate); rb_define_method(rb_cWeakKeyMap, "[]=", wkmap_aset, 2); rb_define_method(rb_cWeakKeyMap, "[]", wkmap_aref, 1); rb_define_method(rb_cWeakKeyMap, "delete", wkmap_delete, 1); rb_define_method(rb_cWeakKeyMap, "getkey", wkmap_getkey, 1); rb_define_method(rb_cWeakKeyMap, "key?", wkmap_has_key, 1); rb_define_method(rb_cWeakKeyMap, "clear", wkmap_clear, 0); rb_define_method(rb_cWeakKeyMap, "inspect", wkmap_inspect, 0); }