Prototype pattern

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The prototype pattern is a creational design pattern in software development. It is used when the types of objects to create is determined by a prototypical instance, which is cloned to produce new objects. This pattern is used to avoid subclasses of an object creator in the client application, like the factory method pattern does, and to avoid the inherent cost of creating a new object in the standard way (e.g., using the 'new' keyword) when it is prohibitively expensive for a given application.

To implement the pattern, the client declares an abstract base class that specifies a pure virtual clone() method. Any class that needs a "polymorphic constructor" capability derives itself from the abstract base class, and implements the clone() operation.

The client, instead of writing code that invokes the "new" operator on a hard-coded class name, calls the clone() method on the prototype, calls a factory method with a parameter designating the particular concrete derived class desired, or invokes the clone() method through some mechanism provided by another design pattern.

The mitotic division of a cell — resulting in two identical cells — is an example of a prototype that plays an active role in copying itself and thus, demonstrates the Prototype pattern. When a cell splits, two cells of identical genotype result. In other words, the cell clones itself.[1]

Overview

The prototype design pattern is one of the 23 Gang of Four design patterns that describe how to solve recurring design problems to design flexible and reusable object-oriented software, that is, objects that are easier to implement, change, test, and reuse.[2]:117

The prototype design pattern solves problems like:[3]

  • How can objects be created so that which objects to create can be specified at run-time?
  • How can dynamically loaded classes be instantiated?

Creating objects directly within the class that requires (uses) the objects is inflexible because it commits the class to particular objects at compile-time and makes it impossible to specify which objects to create at run-time.

The prototype design pattern describes how to solve such problems:

  • Define a Prototype object that returns a copy of itself.
  • Create new objects by copying a Prototype object.

This enables configuration of a class with different Prototype objects, which are copied to create new objects, and even more, Prototype objects can be added and removed at run-time.
See also the UML class and sequence diagram below.

Structure

UML class and sequence diagram

A sample UML class and sequence diagram for the Prototype design pattern.

In the above UML class diagram, the Client class refers to the Prototype interface for cloning a Product. The Product1 class implements the Prototype interface by creating a copy of itself.
The UML sequence diagram shows the run-time interactions: The Client object calls clone() on a prototype:Product1 object, which creates and returns a copy of itself (a product:Product1 object).

UML class diagram

UML class diagram describing the prototype design pattern

Rules of thumb

Sometimes creational patterns overlap—there are cases when either prototype or abstract factory would be appropriate. At other times, they complement each other: abstract factory might store a set of prototypes from which to clone and return product objects.[2]:126 Abstract factory, builder, and prototype can use singleton in their implementations.[2]:81,134 Abstract factory classes are often implemented with factory methods (creation through inheritance), but they can be implemented using prototype (creation through delegation).[2]:95

Often, designs start out using Factory Method (less complicated, more customizable, subclasses proliferate) and evolve toward abstract factory, prototype, or builder (more flexible, more complex) as the designer discovers where more flexibility is needed.[2]:136

Prototype does not require subclassing, but it does require an "initialize" operation. Factory method requires subclassing, but does not require initialization.[2]:116

Designs that make heavy use of the composite and decorator patterns often can benefit from Prototype as well.[2]:126

The rule of thumb could be that you would need to clone() an Object when you want to create another Object at runtime that is a true copy of the Object you are cloning. True copy means all the attributes of the newly created Object should be the same as the Object you are cloning. If you could have instantiated the class by using new instead, you would get an Object with all attributes as their initial values. For example, if you are designing a system for performing bank account transactions, then you would want to make a copy of the Object that holds your account information, perform transactions on it, and then replace the original Object with the modified one. In such cases, you would want to use clone() instead of new.

Example

This C++11 implementation is based on the pre C++98 implementation in the book.

#include <iostream>

enum Direction {North, South, East, West};

class MapSite {
public:
  virtual void enter() = 0;
  virtual MapSite* clone() const = 0;
  virtual ~MapSite() = default;
};

class Room : public MapSite {
public:
  Room() :roomNumber(0) {}
  Room(int n) :roomNumber(n) {}
  void setSide(Direction d, MapSite* ms) {
    std::cout << "Room::setSide " << d << ' ' << ms << '\n';
  }
  virtual void enter() {}
  virtual Room* clone() const { // implements an operation for cloning itself.
    return new Room(*this);
  }
  Room& operator=(const Room&) = delete;
private:
  int roomNumber;
};

class Wall : public MapSite {
public:
  Wall() {}
  virtual void enter() {}
  virtual Wall* clone() const {
    return new Wall(*this);
  }
};

class Door : public MapSite {
public:
  Door(Room* r1 = nullptr, Room* r2 = nullptr)
    :room1(r1), room2(r2) {}
  Door(const Door& other)
    :room1(other.room1), room2(other.room2) {}
  virtual void enter() {}
  virtual Door* clone() const {
    return new Door(*this);
  }
  virtual void initialize(Room* r1, Room* r2) {
    room1 = r1;
    room2 = r2;
  }
  Door& operator=(const Door&) = delete;
private:
  Room* room1;
  Room* room2;
};

class Maze {
public:
  void addRoom(Room* r) {
    std::cout << "Maze::addRoom " << r << '\n';
  }
  Room* roomNo(int) const {
    return nullptr;
  }
  virtual Maze* clone() const {
    return new Maze(*this);
  }
  virtual ~Maze() = default;
};

class MazeFactory {
public:
  MazeFactory() = default;
  virtual ~MazeFactory() = default;

  virtual Maze* makeMaze() const {
    return new Maze;
  }
  virtual Wall* makeWall() const {
    return new Wall;
  }
  virtual Room* makeRoom(int n) const {
    return new Room(n);
  }
  virtual Door* makeDoor(Room* r1, Room* r2) const {
    return new Door(r1, r2);
  }
};

class MazePrototypeFactory : public MazeFactory {
public:
  MazePrototypeFactory(Maze* m, Wall* w, Room* r, Door* d)
    :prototypeMaze(m), prototypeRoom(r),
     prototypeWall(w), prototypeDoor(d) {}
  virtual Maze* makeMaze() const {
    // creates a new object by asking a prototype to clone itself.
    return prototypeMaze->clone();
  }
  virtual Room* makeRoom(int) const {
    return prototypeRoom->clone();
  }
  virtual Wall* makeWall() const {
    return prototypeWall->clone();
  }
  virtual Door* makeDoor(Room* r1, Room* r2) const {
    Door* door = prototypeDoor->clone();
    door->initialize(r1, r2);
    return door;
  }
  MazePrototypeFactory(const MazePrototypeFactory&) = delete;
  MazePrototypeFactory& operator=(const MazePrototypeFactory&) = delete;
private:
  Maze* prototypeMaze;
  Room* prototypeRoom;
  Wall* prototypeWall;
  Door* prototypeDoor;
};

// If createMaze is parameterized by various prototypical room, door, and wall objects, which it then copies and adds to the maze, then you can change the maze's composition by replacing these prototypical objects with different ones. This is an example of the Prototype (133) pattern.

class MazeGame {
public:
  Maze* createMaze(MazePrototypeFactory& m) {
    Maze* aMaze = m.makeMaze();
    Room* r1 = m.makeRoom(1);
    Room* r2 = m.makeRoom(2);
    Door* theDoor = m.makeDoor(r1, r2);
    aMaze->addRoom(r1);
    aMaze->addRoom(r2);
    r1->setSide(North, m.makeWall());
    r1->setSide(East, theDoor);
    r1->setSide(South, m.makeWall());
    r1->setSide(West, m.makeWall());
    r2->setSide(North, m.makeWall());
    r2->setSide(East, m.makeWall());
    r2->setSide(South, m.makeWall());
    r2->setSide(West, theDoor);
    return aMaze;
  }
};

int main() {
  MazeGame game;
  MazePrototypeFactory simpleMazeFactory(new Maze, new Wall, new Room, new Door);
  game.createMaze(simpleMazeFactory);
}

The program output is:

Maze::addRoom 0x1160f50
Maze::addRoom 0x1160f70
Room::setSide 0 0x11613c0
Room::setSide 2 0x1160f90
Room::setSide 1 0x11613e0
Room::setSide 3 0x1161400
Room::setSide 0 0x1161420
Room::setSide 2 0x1161440
Room::setSide 1 0x1161460
Room::setSide 3 0x1160f90

C++ example

Discussion of the design pattern along with a complete illustrative example implementation using polymorphic class design are provided in the C++ Annotations.

See also

References