ruby/ext/google/protobuf_c/map.c - third_party/protobuf - Git at Google

 // Protocol Buffers - Google's data interchange format
 // Copyright 2014 Google Inc.  All rights reserved.
 //
 // Use of this source code is governed by a BSD-style
 // license that can be found in the LICENSE file or at
 // https://developers.google.com/open-source/licenses/bsd

 #include "convert.h"
 #include "defs.h"
 #include "message.h"
 #include "protobuf.h"

 // -----------------------------------------------------------------------------
 // Basic map operations on top of upb_Map.
 //
 // Note that we roll our own `Map` container here because, as for
 // `RepeatedField`, we want a strongly-typed container. This is so that any user
 // errors due to incorrect map key or value types are raised as close as
 // possible to the error site, rather than at some deferred point (e.g.,
 // serialization).
 // -----------------------------------------------------------------------------

 // -----------------------------------------------------------------------------
 // Map container type.
 // -----------------------------------------------------------------------------

 typedef struct {
   const upb_Map* map;  // Can convert to mutable when non-frozen.
   upb_CType key_type;
   TypeInfo value_type_info;
   VALUE value_type_class;
   VALUE arena;
 } Map;

 static void Map_mark(void* _self) {
   Map* self = _self;
   rb_gc_mark(self->value_type_class);
   rb_gc_mark(self->arena);
 }

 static size_t Map_memsize(const void* _self) { return sizeof(Map); }

 const rb_data_type_t Map_type = {
     "Google::Protobuf::Map",
     {Map_mark, RUBY_DEFAULT_FREE, Map_memsize},
     .flags = RUBY_TYPED_FREE_IMMEDIATELY,
 };

 VALUE cMap;

 static Map* ruby_to_Map(VALUE _self) {
   Map* self;
   TypedData_Get_Struct(_self, Map, &Map_type, self);
   return self;
 }

 static VALUE Map_alloc(VALUE klass) {
   Map* self = ALLOC(Map);
   self->map = NULL;
   self->value_type_class = Qnil;
   self->value_type_info.def.msgdef = NULL;
   self->arena = Qnil;
   return TypedData_Wrap_Struct(klass, &Map_type, self);
 }

 VALUE Map_GetRubyWrapper(const upb_Map* map, upb_CType key_type,
                          TypeInfo value_type, VALUE arena) {
   PBRUBY_ASSERT(map);
   PBRUBY_ASSERT(arena != Qnil);

   VALUE val = ObjectCache_Get(map);

   if (val == Qnil) {
     val = Map_alloc(cMap);
     Map* self;
     TypedData_Get_Struct(val, Map, &Map_type, self);
     self->map = map;
     self->arena = arena;
     self->key_type = key_type;
     self->value_type_info = value_type;
     if (self->value_type_info.type == kUpb_CType_Message) {
       const upb_MessageDef* val_m = self->value_type_info.def.msgdef;
       self->value_type_class = Descriptor_DefToClass(val_m);
     }
     return ObjectCache_TryAdd(map, val);
   }
   return val;
 }

 static VALUE Map_new_this_type(Map* from) {
   VALUE arena_rb = Arena_new();
   upb_Map* map = upb_Map_New(Arena_get(arena_rb), from->key_type,
                              from->value_type_info.type);
   VALUE ret =
       Map_GetRubyWrapper(map, from->key_type, from->value_type_info, arena_rb);
   PBRUBY_ASSERT(ruby_to_Map(ret)->value_type_class == from->value_type_class);
   return ret;
 }

 static TypeInfo Map_keyinfo(Map* self) {
   TypeInfo ret;
   ret.type = self->key_type;
   ret.def.msgdef = NULL;
   return ret;
 }

 static upb_Map* Map_GetMutable(VALUE _self) {
   const upb_Map* map = ruby_to_Map(_self)->map;
   Protobuf_CheckNotFrozen(_self, upb_Map_IsFrozen(map));
   return (upb_Map*)map;
 }

 VALUE Map_CreateHash(const upb_Map* map, upb_CType key_type,
                      TypeInfo val_info) {
   VALUE hash = rb_hash_new();
   TypeInfo key_info = TypeInfo_from_type(key_type);

   if (!map) return hash;

   size_t iter = kUpb_Map_Begin;
   upb_MessageValue key, val;
   while (upb_Map_Next(map, &key, &val, &iter)) {
     VALUE key_val = Convert_UpbToRuby(key, key_info, Qnil);
     VALUE val_val = Scalar_CreateHash(val, val_info);
     rb_hash_aset(hash, key_val, val_val);
   }

   return hash;
 }

 VALUE Map_deep_copy(VALUE obj) {
   Map* self = ruby_to_Map(obj);
   VALUE new_arena_rb = Arena_new();
   upb_Arena* arena = Arena_get(new_arena_rb);
   upb_Map* new_map =
       upb_Map_New(arena, self->key_type, self->value_type_info.type);
   size_t iter = kUpb_Map_Begin;
   upb_MessageValue key, val;
   while (upb_Map_Next(self->map, &key, &val, &iter)) {
     upb_MessageValue val_copy =
         Msgval_DeepCopy(val, self->value_type_info, arena);
     upb_Map_Set(new_map, key, val_copy, arena);
   }

   return Map_GetRubyWrapper(new_map, self->key_type, self->value_type_info,
                             new_arena_rb);
 }

 const upb_Map* Map_GetUpbMap(VALUE val, const upb_FieldDef* field,
                              upb_Arena* arena) {
   const upb_FieldDef* key_field = map_field_key(field);
   const upb_FieldDef* value_field = map_field_value(field);
   TypeInfo value_type_info = TypeInfo_get(value_field);
   Map* self;

   if (!RB_TYPE_P(val, T_DATA) || !RTYPEDDATA_P(val) ||
       RTYPEDDATA_TYPE(val) != &Map_type) {
     rb_raise(cTypeError, "Expected Map instance");
   }

   self = ruby_to_Map(val);
   if (self->key_type != upb_FieldDef_CType(key_field)) {
     rb_raise(cTypeError, "Map key type does not match field's key type");
   }
   if (self->value_type_info.type != value_type_info.type) {
     rb_raise(cTypeError, "Map value type does not match field's value type");
   }
   if (self->value_type_info.def.msgdef != value_type_info.def.msgdef) {
     rb_raise(cTypeError, "Map value type has wrong message/enum class");
   }

   Arena_fuse(self->arena, arena);
   return self->map;
 }

 void Map_Inspect(StringBuilder* b, const upb_Map* map, upb_CType key_type,
                  TypeInfo val_type) {
   bool first = true;
   TypeInfo key_type_info = {key_type};
   StringBuilder_Printf(b, "{");
   if (map) {
     size_t iter = kUpb_Map_Begin;
     upb_MessageValue key, val;
     while (upb_Map_Next(map, &key, &val, &iter)) {
       if (first) {
         first = false;
       } else {
         StringBuilder_Printf(b, ", ");
       }
       StringBuilder_PrintMsgval(b, key, key_type_info);
       StringBuilder_Printf(b, "=>");
       StringBuilder_PrintMsgval(b, val, val_type);
     }
   }
   StringBuilder_Printf(b, "}");
 }

 static int merge_into_self_callback(VALUE key, VALUE val, VALUE _self) {
   Map* self = ruby_to_Map(_self);
   upb_Arena* arena = Arena_get(self->arena);
   upb_MessageValue key_val =
       Convert_RubyToUpb(key, "", Map_keyinfo(self), arena);
   upb_MessageValue val_val =
       Convert_RubyToUpb(val, "", self->value_type_info, arena);
   upb_Map_Set(Map_GetMutable(_self), key_val, val_val, arena);
   return ST_CONTINUE;
 }

 // Used only internally -- shared by #merge and #initialize.
 static VALUE Map_merge_into_self(VALUE _self, VALUE hashmap) {
   if (TYPE(hashmap) == T_HASH) {
     rb_hash_foreach(hashmap, merge_into_self_callback, _self);
   } else if (RB_TYPE_P(hashmap, T_DATA) && RTYPEDDATA_P(hashmap) &&
              RTYPEDDATA_TYPE(hashmap) == &Map_type) {
     Map* self = ruby_to_Map(_self);
     Map* other = ruby_to_Map(hashmap);
     upb_Arena* arena = Arena_get(self->arena);
     upb_Map* self_map = Map_GetMutable(_self);

     Arena_fuse(other->arena, arena);

     if (self->key_type != other->key_type ||
         self->value_type_info.type != other->value_type_info.type ||
         self->value_type_class != other->value_type_class) {
       rb_raise(rb_eArgError, "Attempt to merge Map with mismatching types");
     }

     size_t iter = kUpb_Map_Begin;
     upb_MessageValue key, val;
     while (upb_Map_Next(other->map, &key, &val, &iter)) {
       upb_Map_Set(self_map, key, val, arena);
     }
   } else {
     rb_raise(rb_eArgError, "Unknown type merging into Map");
   }
   return _self;
 }

 /*
  * call-seq:
  *     Map.new(key_type, value_type, value_typeclass = nil, init_hashmap = {})
  *     => new map
  *
  * Allocates a new Map container. This constructor may be called with 2, 3, or 4
  * arguments. The first two arguments are always present and are symbols (taking
  * on the same values as field-type symbols in message descriptors) that
  * indicate the type of the map key and value fields.
  *
  * The supported key types are: :int32, :int64, :uint32, :uint64, :bool,
  * :string, :bytes.
  *
  * The supported value types are: :int32, :int64, :uint32, :uint64, :bool,
  * :string, :bytes, :enum, :message.
  *
  * The third argument, value_typeclass, must be present if value_type is :enum
  * or :message. As in RepeatedField#new, this argument must be a message class
  * (for :message) or enum module (for :enum).
  *
  * The last argument, if present, provides initial content for map. Note that
  * this may be an ordinary Ruby hashmap or another Map instance with identical
  * key and value types. Also note that this argument may be present whether or
  * not value_typeclass is present (and it is unambiguously separate from
  * value_typeclass because value_typeclass's presence is strictly determined by
  * value_type). The contents of this initial hashmap or Map instance are
  * shallow-copied into the new Map: the original map is unmodified, but
  * references to underlying objects will be shared if the value type is a
  * message type.
  */
 static VALUE Map_init(int argc, VALUE* argv, VALUE _self) {
   Map* self = ruby_to_Map(_self);
   VALUE init_arg;

   // We take either two args (:key_type, :value_type), three args (:key_type,
   // :value_type, "ValueMessageType"), or four args (the above plus an initial
   // hashmap).
   if (argc < 2 || argc > 4) {
     rb_raise(rb_eArgError, "Map constructor expects 2, 3 or 4 arguments.");
   }

   self->key_type = ruby_to_fieldtype(argv[0]);
   self->value_type_info =
       TypeInfo_FromClass(argc, argv, 1, &self->value_type_class, &init_arg);
   self->arena = Arena_new();

   // Check that the key type is an allowed type.
   switch (self->key_type) {
     case kUpb_CType_Int32:
     case kUpb_CType_Int64:
     case kUpb_CType_UInt32:
     case kUpb_CType_UInt64:
     case kUpb_CType_Bool:
     case kUpb_CType_String:
     case kUpb_CType_Bytes:
       // These are OK.
       break;
     default:
       rb_raise(rb_eArgError, "Invalid key type for map.");
   }

   self->map = upb_Map_New(Arena_get(self->arena), self->key_type,
                           self->value_type_info.type);
   VALUE stored = ObjectCache_TryAdd(self->map, _self);
   (void)stored;
   PBRUBY_ASSERT(stored == _self);

   if (init_arg != Qnil) {
     Map_merge_into_self(_self, init_arg);
   }

   return Qnil;
 }

 /*
  * call-seq:
  *     Map.each(&block)
  *
  * Invokes &block on each |key, value| pair in the map, in unspecified order.
  * Note that Map also includes Enumerable; map thus acts like a normal Ruby
  * sequence.
  */
 static VALUE Map_each(VALUE _self) {
   Map* self = ruby_to_Map(_self);
   size_t iter = kUpb_Map_Begin;
   upb_MessageValue key, val;

   while (upb_Map_Next(self->map, &key, &val, &iter)) {
     VALUE key_val = Convert_UpbToRuby(key, Map_keyinfo(self), self->arena);
     VALUE val_val = Convert_UpbToRuby(val, self->value_type_info, self->arena);
     rb_yield_values(2, key_val, val_val);
   }

   return Qnil;
 }

 /*
  * call-seq:
  *     Map.keys => [list_of_keys]
  *
  * Returns the list of keys contained in the map, in unspecified order.
  */
 static VALUE Map_keys(VALUE _self) {
   Map* self = ruby_to_Map(_self);
   size_t iter = kUpb_Map_Begin;
   VALUE ret = rb_ary_new();
   upb_MessageValue key, val;

   while (upb_Map_Next(self->map, &key, &val, &iter)) {
     VALUE key_val = Convert_UpbToRuby(key, Map_keyinfo(self), self->arena);
     rb_ary_push(ret, key_val);
   }

   return ret;
 }

 /*
  * call-seq:
  *     Map.values => [list_of_values]
  *
  * Returns the list of values contained in the map, in unspecified order.
  */
 static VALUE Map_values(VALUE _self) {
   Map* self = ruby_to_Map(_self);
   size_t iter = kUpb_Map_Begin;
   VALUE ret = rb_ary_new();
   upb_MessageValue key, val;

   while (upb_Map_Next(self->map, &key, &val, &iter)) {
     VALUE val_val = Convert_UpbToRuby(val, self->value_type_info, self->arena);
     rb_ary_push(ret, val_val);
   }

   return ret;
 }

 /*
  * call-seq:
  *     Map.[](key) => value
  *
  * Accesses the element at the given key. Throws an exception if the key type is
  * incorrect. Returns nil when the key is not present in the map.
  */
 static VALUE Map_index(VALUE _self, VALUE key) {
   Map* self = ruby_to_Map(_self);
   upb_MessageValue key_upb =
       Convert_RubyToUpb(key, "", Map_keyinfo(self), NULL);
   upb_MessageValue val;

   if (upb_Map_Get(self->map, key_upb, &val)) {
     return Convert_UpbToRuby(val, self->value_type_info, self->arena);
   } else {
     return Qnil;
   }
 }

 /*
  * call-seq:
  *     Map.[]=(key, value) => value
  *
  * Inserts or overwrites the value at the given key with the given new value.
  * Throws an exception if the key type is incorrect. Returns the new value that
  * was just inserted.
  */
 static VALUE Map_index_set(VALUE _self, VALUE key, VALUE val) {
   Map* self = ruby_to_Map(_self);
   upb_Arena* arena = Arena_get(self->arena);
   upb_MessageValue key_upb =
       Convert_RubyToUpb(key, "", Map_keyinfo(self), NULL);
   upb_MessageValue val_upb =
       Convert_RubyToUpb(val, "", self->value_type_info, arena);

   upb_Map_Set(Map_GetMutable(_self), key_upb, val_upb, arena);

   return val;
 }

 /*
  * call-seq:
  *     Map.has_key?(key) => bool
  *
  * Returns true if the given key is present in the map. Throws an exception if
  * the key has the wrong type.
  */
 static VALUE Map_has_key(VALUE _self, VALUE key) {
   Map* self = ruby_to_Map(_self);
   upb_MessageValue key_upb =
       Convert_RubyToUpb(key, "", Map_keyinfo(self), NULL);

   if (upb_Map_Get(self->map, key_upb, NULL)) {
     return Qtrue;
   } else {
     return Qfalse;
   }
 }

 /*
  * call-seq:
  *     Map.delete(key) => old_value
  *
  * Deletes the value at the given key, if any, returning either the old value or
  * nil if none was present. Throws an exception if the key is of the wrong type.
  */
 static VALUE Map_delete(VALUE _self, VALUE key) {
   upb_Map* map = Map_GetMutable(_self);
   Map* self = ruby_to_Map(_self);

   upb_MessageValue key_upb =
       Convert_RubyToUpb(key, "", Map_keyinfo(self), NULL);
   upb_MessageValue val_upb;

   if (upb_Map_Delete(map, key_upb, &val_upb)) {
     return Convert_UpbToRuby(val_upb, self->value_type_info, self->arena);
   } else {
     return Qnil;
   }
 }

 /*
  * call-seq:
  *     Map.clear
  *
  * Removes all entries from the map.
  */
 static VALUE Map_clear(VALUE _self) {
   upb_Map_Clear(Map_GetMutable(_self));
   return Qnil;
 }

 /*
  * call-seq:
  *     Map.length
  *
  * Returns the number of entries (key-value pairs) in the map.
  */
 static VALUE Map_length(VALUE _self) {
   Map* self = ruby_to_Map(_self);
   return ULL2NUM(upb_Map_Size(self->map));
 }

 /*
  * call-seq:
  *     Map.dup => new_map
  *
  * Duplicates this map with a shallow copy. References to all non-primitive
  * element objects (e.g., submessages) are shared.
  */
 static VALUE Map_dup(VALUE _self) {
   Map* self = ruby_to_Map(_self);
   VALUE new_map_rb = Map_new_this_type(self);
   Map* new_self = ruby_to_Map(new_map_rb);
   size_t iter = kUpb_Map_Begin;
   upb_Arena* arena = Arena_get(new_self->arena);
   upb_Map* new_map = Map_GetMutable(new_map_rb);

   Arena_fuse(self->arena, arena);

   upb_MessageValue key, val;
   while (upb_Map_Next(self->map, &key, &val, &iter)) {
     upb_Map_Set(new_map, key, val, arena);
   }

   return new_map_rb;
 }

 /*
  * call-seq:
  *     Map.==(other) => boolean
  *
  * Compares this map to another. Maps are equal if they have identical key sets,
  * and for each key, the values in both maps compare equal. Elements are
  * compared as per normal Ruby semantics, by calling their :== methods (or
  * performing a more efficient comparison for primitive types).
  *
  * Maps with dissimilar key types or value types/typeclasses are never equal,
  * even if value comparison (for example, between integers and floats) would
  * have otherwise indicated that every element has equal value.
  */
 VALUE Map_eq(VALUE _self, VALUE _other) {
   Map* self = ruby_to_Map(_self);
   Map* other;

   // Allow comparisons to Ruby hashmaps by converting to a temporary Map
   // instance. Slow, but workable.
   if (TYPE(_other) == T_HASH) {
     VALUE other_map = Map_new_this_type(self);
     Map_merge_into_self(other_map, _other);
     _other = other_map;
   }

   other = ruby_to_Map(_other);

   if (self == other) {
     return Qtrue;
   }
   if (self->key_type != other->key_type ||
       self->value_type_info.type != other->value_type_info.type ||
       self->value_type_class != other->value_type_class) {
     return Qfalse;
   }
   if (upb_Map_Size(self->map) != upb_Map_Size(other->map)) {
     return Qfalse;
   }

   // For each member of self, check that an equal member exists at the same key
   // in other.
   size_t iter = kUpb_Map_Begin;
   upb_MessageValue key, val;
   while (upb_Map_Next(self->map, &key, &val, &iter)) {
     upb_MessageValue other_val;
     if (!upb_Map_Get(other->map, key, &other_val)) {
       // Not present in other map.
       return Qfalse;
     }
     if (!Msgval_IsEqual(val, other_val, self->value_type_info)) {
       // Present but different value.
       return Qfalse;
     }
   }

   return Qtrue;
 }

 /*
  * call-seq:
  *     Map.frozen? => bool
  *
  * Returns true if the map is frozen in either Ruby or the underlying
  * representation. Freezes the Ruby map object if it is not already frozen in
  * Ruby but it is frozen in the underlying representation.
  */
 VALUE Map_frozen(VALUE _self) {
   Map* self = ruby_to_Map(_self);
   if (!upb_Map_IsFrozen(self->map)) {
     PBRUBY_ASSERT(!RB_OBJ_FROZEN(_self));
     return Qfalse;
   }

   // Lazily freeze the Ruby wrapper.
   if (!RB_OBJ_FROZEN(_self)) RB_OBJ_FREEZE(_self);
   return Qtrue;
 }

 /*
  * call-seq:
  *     Map.freeze => self
  *
  * Freezes the map object. We have to intercept this so we can freeze the
  * underlying representation, not just the Ruby wrapper.
  */
 VALUE Map_freeze(VALUE _self) {
   Map* self = ruby_to_Map(_self);
   if (RB_OBJ_FROZEN(_self)) {
     PBRUBY_ASSERT(upb_Map_IsFrozen(self->map));
     return _self;
   }

   if (!upb_Map_IsFrozen(self->map)) {
     if (self->value_type_info.type == kUpb_CType_Message) {
       upb_Map_Freeze(
           Map_GetMutable(_self),
           upb_MessageDef_MiniTable(self->value_type_info.def.msgdef));
     } else {
       upb_Map_Freeze(Map_GetMutable(_self), NULL);
     }
   }

   RB_OBJ_FREEZE(_self);

   return _self;
 }

 VALUE Map_EmptyFrozen(const upb_FieldDef* f) {
   PBRUBY_ASSERT(upb_FieldDef_IsMap(f));
   VALUE val = ObjectCache_Get(f);

   if (val == Qnil) {
     const upb_FieldDef* key_f = map_field_key(f);
     const upb_FieldDef* val_f = map_field_value(f);
     upb_CType key_type = upb_FieldDef_CType(key_f);
     TypeInfo value_type_info = TypeInfo_get(val_f);
     val = Map_alloc(cMap);
     Map* self;
     TypedData_Get_Struct(val, Map, &Map_type, self);
     self->arena = Arena_new();
     self->map =
         upb_Map_New(Arena_get(self->arena), key_type, value_type_info.type);
     self->key_type = key_type;
     self->value_type_info = value_type_info;
     if (self->value_type_info.type == kUpb_CType_Message) {
       const upb_MessageDef* val_m = value_type_info.def.msgdef;
       self->value_type_class = Descriptor_DefToClass(val_m);
     }
     return ObjectCache_TryAdd(f, Map_freeze(val));
   }
   PBRUBY_ASSERT(RB_OBJ_FROZEN(val));
   PBRUBY_ASSERT(upb_Map_IsFrozen(ruby_to_Map(val)->map));
   return val;
 }

 /*
  * call-seq:
  *     Map.hash => hash_value
  *
  * Returns a hash value based on this map's contents.
  */
 VALUE Map_hash(VALUE _self) {
   Map* self = ruby_to_Map(_self);
   uint64_t hash = 0;

   size_t iter = kUpb_Map_Begin;
   TypeInfo key_info = {self->key_type};
   upb_MessageValue key, val;
   while (upb_Map_Next(self->map, &key, &val, &iter)) {
     hash = Msgval_GetHash(key, key_info, hash);
     hash = Msgval_GetHash(val, self->value_type_info, hash);
   }

   return LL2NUM(hash);
 }

 /*
  * call-seq:
  *     Map.to_h => {}
  *
  * Returns a Ruby Hash object containing all the values within the map
  */
 VALUE Map_to_h(VALUE _self) {
   Map* self = ruby_to_Map(_self);
   return Map_CreateHash(self->map, self->key_type, self->value_type_info);
 }

 /*
  * call-seq:
  *     Map.inspect => string
  *
  * Returns a string representing this map's elements. It will be formatted as
  * "{key => value, key => value, ...}", with each key and value string
  * representation computed by its own #inspect method.
  */
 VALUE Map_inspect(VALUE _self) {
   Map* self = ruby_to_Map(_self);

   StringBuilder* builder = StringBuilder_New();
   Map_Inspect(builder, self->map, self->key_type, self->value_type_info);
   VALUE ret = StringBuilder_ToRubyString(builder);
   StringBuilder_Free(builder);
   return ret;
 }

 /*
  * call-seq:
  *     Map.merge(other_map) => map
  *
  * Copies key/value pairs from other_map into a copy of this map. If a key is
  * set in other_map and this map, the value from other_map overwrites the value
  * in the new copy of this map. Returns the new copy of this map with merged
  * contents.
  */
 static VALUE Map_merge(VALUE _self, VALUE hashmap) {
   VALUE dupped = Map_dup(_self);
   return Map_merge_into_self(dupped, hashmap);
 }

 void Map_register(VALUE module) {
   VALUE klass = rb_define_class_under(module, "Map", rb_cObject);
   rb_define_alloc_func(klass, Map_alloc);
   rb_gc_register_address(&cMap);
   cMap = klass;

   rb_define_method(klass, "initialize", Map_init, -1);
   rb_define_method(klass, "each", Map_each, 0);
   rb_define_method(klass, "keys", Map_keys, 0);
   rb_define_method(klass, "values", Map_values, 0);
   rb_define_method(klass, "[]", Map_index, 1);
   rb_define_method(klass, "[]=", Map_index_set, 2);
   rb_define_method(klass, "has_key?", Map_has_key, 1);
   rb_define_method(klass, "delete", Map_delete, 1);
   rb_define_method(klass, "clear", Map_clear, 0);
   rb_define_method(klass, "length", Map_length, 0);
   rb_define_method(klass, "size", Map_length, 0);
   rb_define_method(klass, "dup", Map_dup, 0);
   // Also define #clone so that we don't inherit Object#clone.
   rb_define_method(klass, "clone", Map_dup, 0);
   rb_define_method(klass, "==", Map_eq, 1);
   rb_define_method(klass, "freeze", Map_freeze, 0);
   rb_define_method(klass, "frozen?", Map_frozen, 0);
   rb_define_method(klass, "hash", Map_hash, 0);
   rb_define_method(klass, "to_h", Map_to_h, 0);
   rb_define_method(klass, "inspect", Map_inspect, 0);
   rb_define_method(klass, "merge", Map_merge, 1);
   rb_include_module(klass, rb_mEnumerable);
 }
	// Protocol Buffers - Google's data interchange format
	// Copyright 2014 Google Inc. All rights reserved.
	//
	// Use of this source code is governed by a BSD-style
	// license that can be found in the LICENSE file or at
	// https://developers.google.com/open-source/licenses/bsd

	#include "convert.h"
	#include "defs.h"
	#include "message.h"
	#include "protobuf.h"

	// -----------------------------------------------------------------------------
	// Basic map operations on top of upb_Map.
	//
	// Note that we roll our own `Map` container here because, as for
	// `RepeatedField`, we want a strongly-typed container. This is so that any user
	// errors due to incorrect map key or value types are raised as close as
	// possible to the error site, rather than at some deferred point (e.g.,
	// serialization).
	// -----------------------------------------------------------------------------

	// -----------------------------------------------------------------------------
	// Map container type.
	// -----------------------------------------------------------------------------

	typedef struct {
	const upb_Map* map; // Can convert to mutable when non-frozen.
	upb_CType key_type;
	TypeInfo value_type_info;
	VALUE value_type_class;
	VALUE arena;
	} Map;

	static void Map_mark(void* _self) {
	Map* self = _self;
	rb_gc_mark(self->value_type_class);
	rb_gc_mark(self->arena);
	}

	static size_t Map_memsize(const void* _self) { return sizeof(Map); }

	const rb_data_type_t Map_type = {
	"Google::Protobuf::Map",
	{Map_mark, RUBY_DEFAULT_FREE, Map_memsize},
	.flags = RUBY_TYPED_FREE_IMMEDIATELY,
	};

	VALUE cMap;

	static Map* ruby_to_Map(VALUE _self) {
	Map* self;
	TypedData_Get_Struct(_self, Map, &Map_type, self);
	return self;
	}

	static VALUE Map_alloc(VALUE klass) {
	Map* self = ALLOC(Map);
	self->map = NULL;
	self->value_type_class = Qnil;
	self->value_type_info.def.msgdef = NULL;
	self->arena = Qnil;
	return TypedData_Wrap_Struct(klass, &Map_type, self);
	}

	VALUE Map_GetRubyWrapper(const upb_Map* map, upb_CType key_type,
	TypeInfo value_type, VALUE arena) {
	PBRUBY_ASSERT(map);
	PBRUBY_ASSERT(arena != Qnil);

	VALUE val = ObjectCache_Get(map);

	if (val == Qnil) {
	val = Map_alloc(cMap);
	Map* self;
	TypedData_Get_Struct(val, Map, &Map_type, self);
	self->map = map;
	self->arena = arena;
	self->key_type = key_type;
	self->value_type_info = value_type;
	if (self->value_type_info.type == kUpb_CType_Message) {
	const upb_MessageDef* val_m = self->value_type_info.def.msgdef;
	self->value_type_class = Descriptor_DefToClass(val_m);
	}
	return ObjectCache_TryAdd(map, val);
	}
	return val;
	}

	static VALUE Map_new_this_type(Map* from) {
	VALUE arena_rb = Arena_new();
	upb_Map* map = upb_Map_New(Arena_get(arena_rb), from->key_type,
	from->value_type_info.type);
	VALUE ret =
	Map_GetRubyWrapper(map, from->key_type, from->value_type_info, arena_rb);
	PBRUBY_ASSERT(ruby_to_Map(ret)->value_type_class == from->value_type_class);
	return ret;
	}

	static TypeInfo Map_keyinfo(Map* self) {
	TypeInfo ret;
	ret.type = self->key_type;
	ret.def.msgdef = NULL;
	return ret;
	}

	static upb_Map* Map_GetMutable(VALUE _self) {
	const upb_Map* map = ruby_to_Map(_self)->map;
	Protobuf_CheckNotFrozen(_self, upb_Map_IsFrozen(map));
	return (upb_Map*)map;
	}

	VALUE Map_CreateHash(const upb_Map* map, upb_CType key_type,
	TypeInfo val_info) {
	VALUE hash = rb_hash_new();
	TypeInfo key_info = TypeInfo_from_type(key_type);

	if (!map) return hash;

	size_t iter = kUpb_Map_Begin;
	upb_MessageValue key, val;
	while (upb_Map_Next(map, &key, &val, &iter)) {
	VALUE key_val = Convert_UpbToRuby(key, key_info, Qnil);
	VALUE val_val = Scalar_CreateHash(val, val_info);
	rb_hash_aset(hash, key_val, val_val);
	}

	return hash;
	}

	VALUE Map_deep_copy(VALUE obj) {
	Map* self = ruby_to_Map(obj);
	VALUE new_arena_rb = Arena_new();
	upb_Arena* arena = Arena_get(new_arena_rb);
	upb_Map* new_map =
	upb_Map_New(arena, self->key_type, self->value_type_info.type);
	size_t iter = kUpb_Map_Begin;
	upb_MessageValue key, val;
	while (upb_Map_Next(self->map, &key, &val, &iter)) {
	upb_MessageValue val_copy =
	Msgval_DeepCopy(val, self->value_type_info, arena);
	upb_Map_Set(new_map, key, val_copy, arena);
	}

	return Map_GetRubyWrapper(new_map, self->key_type, self->value_type_info,
	new_arena_rb);
	}

	const upb_Map* Map_GetUpbMap(VALUE val, const upb_FieldDef* field,
	upb_Arena* arena) {
	const upb_FieldDef* key_field = map_field_key(field);
	const upb_FieldDef* value_field = map_field_value(field);
	TypeInfo value_type_info = TypeInfo_get(value_field);
	Map* self;

	if (!RB_TYPE_P(val, T_DATA) \|\| !RTYPEDDATA_P(val) \|\|
	RTYPEDDATA_TYPE(val) != &Map_type) {
	rb_raise(cTypeError, "Expected Map instance");
	}

	self = ruby_to_Map(val);
	if (self->key_type != upb_FieldDef_CType(key_field)) {
	rb_raise(cTypeError, "Map key type does not match field's key type");
	}
	if (self->value_type_info.type != value_type_info.type) {
	rb_raise(cTypeError, "Map value type does not match field's value type");
	}
	if (self->value_type_info.def.msgdef != value_type_info.def.msgdef) {
	rb_raise(cTypeError, "Map value type has wrong message/enum class");
	}

	Arena_fuse(self->arena, arena);
	return self->map;
	}

	void Map_Inspect(StringBuilder* b, const upb_Map* map, upb_CType key_type,
	TypeInfo val_type) {
	bool first = true;
	TypeInfo key_type_info = {key_type};
	StringBuilder_Printf(b, "{");
	if (map) {
	size_t iter = kUpb_Map_Begin;
	upb_MessageValue key, val;
	while (upb_Map_Next(map, &key, &val, &iter)) {
	if (first) {
	first = false;
	} else {
	StringBuilder_Printf(b, ", ");
	}
	StringBuilder_PrintMsgval(b, key, key_type_info);
	StringBuilder_Printf(b, "=>");
	StringBuilder_PrintMsgval(b, val, val_type);
	}
	}
	StringBuilder_Printf(b, "}");
	}

	static int merge_into_self_callback(VALUE key, VALUE val, VALUE _self) {
	Map* self = ruby_to_Map(_self);
	upb_Arena* arena = Arena_get(self->arena);
	upb_MessageValue key_val =
	Convert_RubyToUpb(key, "", Map_keyinfo(self), arena);
	upb_MessageValue val_val =
	Convert_RubyToUpb(val, "", self->value_type_info, arena);
	upb_Map_Set(Map_GetMutable(_self), key_val, val_val, arena);
	return ST_CONTINUE;
	}

	// Used only internally -- shared by #merge and #initialize.
	static VALUE Map_merge_into_self(VALUE _self, VALUE hashmap) {
	if (TYPE(hashmap) == T_HASH) {
	rb_hash_foreach(hashmap, merge_into_self_callback, _self);
	} else if (RB_TYPE_P(hashmap, T_DATA) && RTYPEDDATA_P(hashmap) &&
	RTYPEDDATA_TYPE(hashmap) == &Map_type) {
	Map* self = ruby_to_Map(_self);
	Map* other = ruby_to_Map(hashmap);
	upb_Arena* arena = Arena_get(self->arena);
	upb_Map* self_map = Map_GetMutable(_self);

	Arena_fuse(other->arena, arena);

	if (self->key_type != other->key_type \|\|
	self->value_type_info.type != other->value_type_info.type \|\|
	self->value_type_class != other->value_type_class) {
	rb_raise(rb_eArgError, "Attempt to merge Map with mismatching types");
	}

	size_t iter = kUpb_Map_Begin;
	upb_MessageValue key, val;
	while (upb_Map_Next(other->map, &key, &val, &iter)) {
	upb_Map_Set(self_map, key, val, arena);
	}
	} else {
	rb_raise(rb_eArgError, "Unknown type merging into Map");
	}
	return _self;
	}

	/*
	* call-seq:
	* Map.new(key_type, value_type, value_typeclass = nil, init_hashmap = {})
	* => new map
	*
	* Allocates a new Map container. This constructor may be called with 2, 3, or 4
	* arguments. The first two arguments are always present and are symbols (taking
	* on the same values as field-type symbols in message descriptors) that
	* indicate the type of the map key and value fields.
	*
	* The supported key types are: :int32, :int64, :uint32, :uint64, :bool,
	* :string, :bytes.
	*
	* The supported value types are: :int32, :int64, :uint32, :uint64, :bool,
	* :string, :bytes, :enum, :message.
	*
	* The third argument, value_typeclass, must be present if value_type is :enum
	* or :message. As in RepeatedField#new, this argument must be a message class
	* (for :message) or enum module (for :enum).
	*
	* The last argument, if present, provides initial content for map. Note that
	* this may be an ordinary Ruby hashmap or another Map instance with identical
	* key and value types. Also note that this argument may be present whether or
	* not value_typeclass is present (and it is unambiguously separate from
	* value_typeclass because value_typeclass's presence is strictly determined by
	* value_type). The contents of this initial hashmap or Map instance are
	* shallow-copied into the new Map: the original map is unmodified, but
	* references to underlying objects will be shared if the value type is a
	* message type.
	*/
	static VALUE Map_init(int argc, VALUE* argv, VALUE _self) {
	Map* self = ruby_to_Map(_self);
	VALUE init_arg;

	// We take either two args (:key_type, :value_type), three args (:key_type,
	// :value_type, "ValueMessageType"), or four args (the above plus an initial
	// hashmap).
	if (argc < 2 \|\| argc > 4) {
	rb_raise(rb_eArgError, "Map constructor expects 2, 3 or 4 arguments.");
	}

	self->key_type = ruby_to_fieldtype(argv[0]);
	self->value_type_info =
	TypeInfo_FromClass(argc, argv, 1, &self->value_type_class, &init_arg);
	self->arena = Arena_new();

	// Check that the key type is an allowed type.
	switch (self->key_type) {
	case kUpb_CType_Int32:
	case kUpb_CType_Int64:
	case kUpb_CType_UInt32:
	case kUpb_CType_UInt64:
	case kUpb_CType_Bool:
	case kUpb_CType_String:
	case kUpb_CType_Bytes:
	// These are OK.
	break;
	default:
	rb_raise(rb_eArgError, "Invalid key type for map.");
	}

	self->map = upb_Map_New(Arena_get(self->arena), self->key_type,
	self->value_type_info.type);
	VALUE stored = ObjectCache_TryAdd(self->map, _self);
	(void)stored;
	PBRUBY_ASSERT(stored == _self);

	if (init_arg != Qnil) {
	Map_merge_into_self(_self, init_arg);
	}

	return Qnil;
	}

	/*
	* call-seq:
	* Map.each(&block)
	*
	* Invokes &block on each \|key, value\| pair in the map, in unspecified order.
	* Note that Map also includes Enumerable; map thus acts like a normal Ruby
	* sequence.
	*/
	static VALUE Map_each(VALUE _self) {
	Map* self = ruby_to_Map(_self);
	size_t iter = kUpb_Map_Begin;
	upb_MessageValue key, val;

	while (upb_Map_Next(self->map, &key, &val, &iter)) {
	VALUE key_val = Convert_UpbToRuby(key, Map_keyinfo(self), self->arena);
	VALUE val_val = Convert_UpbToRuby(val, self->value_type_info, self->arena);
	rb_yield_values(2, key_val, val_val);
	}

	return Qnil;
	}

	/*
	* call-seq:
	* Map.keys => [list_of_keys]
	*
	* Returns the list of keys contained in the map, in unspecified order.
	*/
	static VALUE Map_keys(VALUE _self) {
	Map* self = ruby_to_Map(_self);
	size_t iter = kUpb_Map_Begin;
	VALUE ret = rb_ary_new();
	upb_MessageValue key, val;

	while (upb_Map_Next(self->map, &key, &val, &iter)) {
	VALUE key_val = Convert_UpbToRuby(key, Map_keyinfo(self), self->arena);
	rb_ary_push(ret, key_val);
	}

	return ret;
	}

	/*
	* call-seq:
	* Map.values => [list_of_values]
	*
	* Returns the list of values contained in the map, in unspecified order.
	*/
	static VALUE Map_values(VALUE _self) {
	Map* self = ruby_to_Map(_self);
	size_t iter = kUpb_Map_Begin;
	VALUE ret = rb_ary_new();
	upb_MessageValue key, val;

	while (upb_Map_Next(self->map, &key, &val, &iter)) {
	VALUE val_val = Convert_UpbToRuby(val, self->value_type_info, self->arena);
	rb_ary_push(ret, val_val);
	}

	return ret;
	}

	/*
	* call-seq:
	* Map.[](key) => value
	*
	* Accesses the element at the given key. Throws an exception if the key type is
	* incorrect. Returns nil when the key is not present in the map.
	*/
	static VALUE Map_index(VALUE _self, VALUE key) {
	Map* self = ruby_to_Map(_self);
	upb_MessageValue key_upb =
	Convert_RubyToUpb(key, "", Map_keyinfo(self), NULL);
	upb_MessageValue val;

	if (upb_Map_Get(self->map, key_upb, &val)) {
	return Convert_UpbToRuby(val, self->value_type_info, self->arena);
	} else {
	return Qnil;
	}
	}

	/*
	* call-seq:
	* Map.[]=(key, value) => value
	*
	* Inserts or overwrites the value at the given key with the given new value.
	* Throws an exception if the key type is incorrect. Returns the new value that
	* was just inserted.
	*/
	static VALUE Map_index_set(VALUE _self, VALUE key, VALUE val) {
	Map* self = ruby_to_Map(_self);
	upb_Arena* arena = Arena_get(self->arena);
	upb_MessageValue key_upb =
	Convert_RubyToUpb(key, "", Map_keyinfo(self), NULL);
	upb_MessageValue val_upb =
	Convert_RubyToUpb(val, "", self->value_type_info, arena);

	upb_Map_Set(Map_GetMutable(_self), key_upb, val_upb, arena);

	return val;
	}

	/*
	* call-seq:
	* Map.has_key?(key) => bool
	*
	* Returns true if the given key is present in the map. Throws an exception if
	* the key has the wrong type.
	*/
	static VALUE Map_has_key(VALUE _self, VALUE key) {
	Map* self = ruby_to_Map(_self);
	upb_MessageValue key_upb =
	Convert_RubyToUpb(key, "", Map_keyinfo(self), NULL);

	if (upb_Map_Get(self->map, key_upb, NULL)) {
	return Qtrue;
	} else {
	return Qfalse;
	}
	}

	/*
	* call-seq:
	* Map.delete(key) => old_value
	*
	* Deletes the value at the given key, if any, returning either the old value or
	* nil if none was present. Throws an exception if the key is of the wrong type.
	*/
	static VALUE Map_delete(VALUE _self, VALUE key) {
	upb_Map* map = Map_GetMutable(_self);
	Map* self = ruby_to_Map(_self);

	upb_MessageValue key_upb =
	Convert_RubyToUpb(key, "", Map_keyinfo(self), NULL);
	upb_MessageValue val_upb;

	if (upb_Map_Delete(map, key_upb, &val_upb)) {
	return Convert_UpbToRuby(val_upb, self->value_type_info, self->arena);
	} else {
	return Qnil;
	}
	}

	/*
	* call-seq:
	* Map.clear
	*
	* Removes all entries from the map.
	*/
	static VALUE Map_clear(VALUE _self) {
	upb_Map_Clear(Map_GetMutable(_self));
	return Qnil;
	}

	/*
	* call-seq:
	* Map.length
	*
	* Returns the number of entries (key-value pairs) in the map.
	*/
	static VALUE Map_length(VALUE _self) {
	Map* self = ruby_to_Map(_self);
	return ULL2NUM(upb_Map_Size(self->map));
	}

	/*
	* call-seq:
	* Map.dup => new_map
	*
	* Duplicates this map with a shallow copy. References to all non-primitive
	* element objects (e.g., submessages) are shared.
	*/
	static VALUE Map_dup(VALUE _self) {
	Map* self = ruby_to_Map(_self);
	VALUE new_map_rb = Map_new_this_type(self);
	Map* new_self = ruby_to_Map(new_map_rb);
	size_t iter = kUpb_Map_Begin;
	upb_Arena* arena = Arena_get(new_self->arena);
	upb_Map* new_map = Map_GetMutable(new_map_rb);

	Arena_fuse(self->arena, arena);

	upb_MessageValue key, val;
	while (upb_Map_Next(self->map, &key, &val, &iter)) {
	upb_Map_Set(new_map, key, val, arena);
	}

	return new_map_rb;
	}

	/*
	* call-seq:
	* Map.==(other) => boolean
	*
	* Compares this map to another. Maps are equal if they have identical key sets,
	* and for each key, the values in both maps compare equal. Elements are
	* compared as per normal Ruby semantics, by calling their :== methods (or
	* performing a more efficient comparison for primitive types).
	*
	* Maps with dissimilar key types or value types/typeclasses are never equal,
	* even if value comparison (for example, between integers and floats) would
	* have otherwise indicated that every element has equal value.
	*/
	VALUE Map_eq(VALUE _self, VALUE _other) {
	Map* self = ruby_to_Map(_self);
	Map* other;

	// Allow comparisons to Ruby hashmaps by converting to a temporary Map
	// instance. Slow, but workable.
	if (TYPE(_other) == T_HASH) {
	VALUE other_map = Map_new_this_type(self);
	Map_merge_into_self(other_map, _other);
	_other = other_map;
	}

	other = ruby_to_Map(_other);

	if (self == other) {
	return Qtrue;
	}
	if (self->key_type != other->key_type \|\|
	self->value_type_info.type != other->value_type_info.type \|\|
	self->value_type_class != other->value_type_class) {
	return Qfalse;
	}
	if (upb_Map_Size(self->map) != upb_Map_Size(other->map)) {
	return Qfalse;
	}

	// For each member of self, check that an equal member exists at the same key
	// in other.
	size_t iter = kUpb_Map_Begin;
	upb_MessageValue key, val;
	while (upb_Map_Next(self->map, &key, &val, &iter)) {
	upb_MessageValue other_val;
	if (!upb_Map_Get(other->map, key, &other_val)) {
	// Not present in other map.
	return Qfalse;
	}
	if (!Msgval_IsEqual(val, other_val, self->value_type_info)) {
	// Present but different value.
	return Qfalse;
	}
	}

	return Qtrue;
	}

	/*
	* call-seq:
	* Map.frozen? => bool
	*
	* Returns true if the map is frozen in either Ruby or the underlying
	* representation. Freezes the Ruby map object if it is not already frozen in
	* Ruby but it is frozen in the underlying representation.
	*/
	VALUE Map_frozen(VALUE _self) {
	Map* self = ruby_to_Map(_self);
	if (!upb_Map_IsFrozen(self->map)) {
	PBRUBY_ASSERT(!RB_OBJ_FROZEN(_self));
	return Qfalse;
	}

	// Lazily freeze the Ruby wrapper.
	if (!RB_OBJ_FROZEN(_self)) RB_OBJ_FREEZE(_self);
	return Qtrue;
	}

	/*
	* call-seq:
	* Map.freeze => self
	*
	* Freezes the map object. We have to intercept this so we can freeze the
	* underlying representation, not just the Ruby wrapper.
	*/
	VALUE Map_freeze(VALUE _self) {
	Map* self = ruby_to_Map(_self);
	if (RB_OBJ_FROZEN(_self)) {
	PBRUBY_ASSERT(upb_Map_IsFrozen(self->map));
	return _self;
	}

	if (!upb_Map_IsFrozen(self->map)) {
	if (self->value_type_info.type == kUpb_CType_Message) {
	upb_Map_Freeze(
	Map_GetMutable(_self),
	upb_MessageDef_MiniTable(self->value_type_info.def.msgdef));
	} else {
	upb_Map_Freeze(Map_GetMutable(_self), NULL);
	}
	}

	RB_OBJ_FREEZE(_self);

	return _self;
	}

	VALUE Map_EmptyFrozen(const upb_FieldDef* f) {
	PBRUBY_ASSERT(upb_FieldDef_IsMap(f));
	VALUE val = ObjectCache_Get(f);

	if (val == Qnil) {
	const upb_FieldDef* key_f = map_field_key(f);
	const upb_FieldDef* val_f = map_field_value(f);
	upb_CType key_type = upb_FieldDef_CType(key_f);
	TypeInfo value_type_info = TypeInfo_get(val_f);
	val = Map_alloc(cMap);
	Map* self;
	TypedData_Get_Struct(val, Map, &Map_type, self);
	self->arena = Arena_new();
	self->map =
	upb_Map_New(Arena_get(self->arena), key_type, value_type_info.type);
	self->key_type = key_type;
	self->value_type_info = value_type_info;
	if (self->value_type_info.type == kUpb_CType_Message) {
	const upb_MessageDef* val_m = value_type_info.def.msgdef;
	self->value_type_class = Descriptor_DefToClass(val_m);
	}
	return ObjectCache_TryAdd(f, Map_freeze(val));
	}
	PBRUBY_ASSERT(RB_OBJ_FROZEN(val));
	PBRUBY_ASSERT(upb_Map_IsFrozen(ruby_to_Map(val)->map));
	return val;
	}

	/*
	* call-seq:
	* Map.hash => hash_value
	*
	* Returns a hash value based on this map's contents.
	*/
	VALUE Map_hash(VALUE _self) {
	Map* self = ruby_to_Map(_self);
	uint64_t hash = 0;

	size_t iter = kUpb_Map_Begin;
	TypeInfo key_info = {self->key_type};
	upb_MessageValue key, val;
	while (upb_Map_Next(self->map, &key, &val, &iter)) {
	hash = Msgval_GetHash(key, key_info, hash);
	hash = Msgval_GetHash(val, self->value_type_info, hash);
	}

	return LL2NUM(hash);
	}

	/*
	* call-seq:
	* Map.to_h => {}
	*
	* Returns a Ruby Hash object containing all the values within the map
	*/
	VALUE Map_to_h(VALUE _self) {
	Map* self = ruby_to_Map(_self);
	return Map_CreateHash(self->map, self->key_type, self->value_type_info);
	}

	/*
	* call-seq:
	* Map.inspect => string
	*
	* Returns a string representing this map's elements. It will be formatted as
	* "{key => value, key => value, ...}", with each key and value string
	* representation computed by its own #inspect method.
	*/
	VALUE Map_inspect(VALUE _self) {
	Map* self = ruby_to_Map(_self);

	StringBuilder* builder = StringBuilder_New();
	Map_Inspect(builder, self->map, self->key_type, self->value_type_info);
	VALUE ret = StringBuilder_ToRubyString(builder);
	StringBuilder_Free(builder);
	return ret;
	}

	/*
	* call-seq:
	* Map.merge(other_map) => map
	*
	* Copies key/value pairs from other_map into a copy of this map. If a key is
	* set in other_map and this map, the value from other_map overwrites the value
	* in the new copy of this map. Returns the new copy of this map with merged
	* contents.
	*/
	static VALUE Map_merge(VALUE _self, VALUE hashmap) {
	VALUE dupped = Map_dup(_self);
	return Map_merge_into_self(dupped, hashmap);
	}

	void Map_register(VALUE module) {
	VALUE klass = rb_define_class_under(module, "Map", rb_cObject);
	rb_define_alloc_func(klass, Map_alloc);
	rb_gc_register_address(&cMap);
	cMap = klass;

	rb_define_method(klass, "initialize", Map_init, -1);
	rb_define_method(klass, "each", Map_each, 0);
	rb_define_method(klass, "keys", Map_keys, 0);
	rb_define_method(klass, "values", Map_values, 0);
	rb_define_method(klass, "[]", Map_index, 1);
	rb_define_method(klass, "[]=", Map_index_set, 2);
	rb_define_method(klass, "has_key?", Map_has_key, 1);
	rb_define_method(klass, "delete", Map_delete, 1);
	rb_define_method(klass, "clear", Map_clear, 0);
	rb_define_method(klass, "length", Map_length, 0);
	rb_define_method(klass, "size", Map_length, 0);
	rb_define_method(klass, "dup", Map_dup, 0);
	// Also define #clone so that we don't inherit Object#clone.
	rb_define_method(klass, "clone", Map_dup, 0);
	rb_define_method(klass, "==", Map_eq, 1);
	rb_define_method(klass, "freeze", Map_freeze, 0);
	rb_define_method(klass, "frozen?", Map_frozen, 0);
	rb_define_method(klass, "hash", Map_hash, 0);
	rb_define_method(klass, "to_h", Map_to_h, 0);
	rb_define_method(klass, "inspect", Map_inspect, 0);
	rb_define_method(klass, "merge", Map_merge, 1);
	rb_include_module(klass, rb_mEnumerable);
	}