Builder pattern
The builder pattern is an object creation software design pattern. Unlike the abstract factory pattern and the factory method pattern whose intention is to enable polymorphism, the intention of the builder pattern is to find a solution to the telescoping constructor anti-pattern[citation needed]. The telescoping constructor anti-pattern occurs when the increase of object constructor parameter combination leads to an exponential list of constructors. Instead of using numerous constructors, the builder pattern uses another object, a builder, that receives each initialization parameter step by step and then returns the resulting constructed object at once.
The builder pattern has another benefit. It can be used for objects that contain flat data (html code, SQL query, X.509 certificate...), that is to say, data that can't be easily edited. This type of data cannot be edited step by step and must be edited at once. The best way to construct such an object is to use a builder class.[citation needed]
Builder often builds a Composite. 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. Sometimes creational patterns are complementary: Builder can use one of the other patterns to implement which components are built. Builders are good candidates for a fluent interface.[1]
Contents
Definition
The intent of the Builder design pattern is to separate the construction of a complex object from its representation. By doing so the same construction process can create different representations. [2]
Structure
- Builder
- Abstract interface for creating objects (product).
- Concrete Builder
- Provides implementation for Builder. It is an object able to construct other objects. Constructs and assembles parts to build the objects.
Pseudocode
We have a Car
class. The problem is that a car has many options. The combination of each option would lead to a huge list of constructors for this class. So we will create a builder class, CarBuilder
. We will send to the CarBuilder
each car option step by step and then construct the final car with the right options:
class Car is Can have GPS, trip computer and various numbers of seats. Can be a city car, a sports car, or a cabriolet. class CarBuilder is method getResult() is output: a Car with the right options Construct and return the car. method setSeats(number) is input: the number of seats the car may have. Tell the builder the number of seats. method setCityCar() is Make the builder remember that the car is a city car. method setCabriolet() is Make the builder remember that the car is a cabriolet. method setSportsCar() is Make the builder remember that the car is a sports car. method setTripComputer() is Make the builder remember that the car has a trip computer. method unsetTripComputer() is Make the builder remember that the car does not have a trip computer. method setGPS() is Make the builder remember that the car has a global positioning system. method unsetGPS() is Make the builder remember that the car does not have a global positioning system. Construct a CarBuilder called carBuilder carBuilder.setSeats(2) carBuilder.setSportsCar() carBuilder.setTripComputer() carBuilder.unsetGPS() car := carBuilder.getResult()
Of course one could dispense with Builder and just do this:
car = new Car(); car.seats = 2; car.type = CarType.SportsCar; car.setTripComputer(); car.unsetGPS(); car.isValid();
So this indicates that the Builder pattern is more than just a means to limit constructor proliferation. It removes what could be a complex building process from being the responsibility of the user of the object that is built. It also allows for inserting new implementations of how an object is built without disturbing the client code.
C# Example
//Represents a product created by the builder
public class Car
{
public Car()
{
}
public int Wheels { get; set; }
public string Colour { get; set; }
}
//The builder abstraction
public interface ICarBuilder
{
// Adding NotNull attribute to prevent null input argument
void SetColour([NotNull]string colour);
// Adding NotNull attribute to prevent null input argument
void SetWheels([NotNull]int count);
Car GetResult();
}
//Concrete builder implementation
public class CarBuilder : ICarBuilder
{
private Car _car;
public CarBuilder()
{
this._car = new Car();
}
public void SetColour(string colour)
{
this._car.Colour = colour;
}
public void SetWheels(int count)
{
this._car.Wheels = count;
}
public Car GetResult()
{
return this._car;
}
}
//The director
public class CarBuildDirector
{
public Car Construct()
{
CarBuilder builder = new CarBuilder();
builder.SetColour("Red");
builder.SetWheels(4);
return builder.GetResult();
}
}
The Director assembles a car instance in the example above, delegating the construction to a separate builder object.
C++ Example
////// Product declarations and inline impl. (possibly Product.h) //////
class Product{
public:
// use this class to construct Product
class Builder;
private:
// variables in need of initialization to make valid object
int i;
float f;
char c;
// Only one simple constructor - rest is handled by Builder
Product( const int i, const float f, const char c ) : i(i), f(f), c(c){}
public:
// Product specific functionality
void print();
void doSomething();
void doSomethingElse();
};
class Product::Builder{
private:
// variables needed for construction of object of Product class
int i;
float f;
char c;
public:
// default values for variables
static const int defaultI = 1;
static const float defaultF = 3.1415f;
static const char defaultC = 'a';
// create Builder with default values assigned
// (in C++11 they can be simply assigned above on declaration instead)
Builder() : i( defaultI ), f( defaultF ), c( defaultC ){}
// sets custom values for Product creation
// returns Builder for shorthand inline usage (same way as cout <<)
Builder& setI( const int i ){ this->i = i; return *this; }
Builder& setF( const float f ){ this->f = f; return *this; }
Builder& setC( const char c ){ this->c = c; return *this; }
// prepare specific frequently desired Product
// returns Builder for shorthand inline usage (same way as cout <<)
Builder& setProductP(){
this->i = 42;
this->f = -1.0f/12.0f;
this->c = '@';
return *this;
}
// produce desired Product
Product build(){
// here optionaly check variable consistency
// and also if Product is buildable from given information
return Product( this->i, this->f, this->c );
}
};
///// Product implementation (possibly Product.cpp) /////
#include <iostream>
void Product::print(){
using namespace std;
cout << "Product internals dump:" << endl;
cout << "i: " << this->i << endl;
cout << "f: " << this->f << endl;
cout << "c: " << this->c << endl;
}
void Product::doSomething(){}
void Product::doSomethingElse(){}
//////////////////// Usage of Builder (replaces Director from diagram)
int main(){
// simple usage
Product p1 = Product::Builder().setI(2).setF(0.5f).setC('x').build();
p1.print(); // test p1
// advanced usage
Product::Builder b;
b.setProductP();
Product p2 = b.build(); // get Product P object
b.setC('!'); // customize Product P
Product p3 = b.build();
p2.print(); // test p2
p3.print(); // test p3
}
Java Example
public class StreetMap {
private final Point origin;
private final Point destination;
private final Color waterColor;
private final Color landColor;
private final Color highTrafficColor;
private final Color mediumTrafficColor;
private final Color lowTrafficColor;
public static class Builder {
// Required parameters
private final Point origin;
private final Point destination;
// Optional parameters - initialize with default values
private Color waterColor = Color.BLUE;
private Color landColor = new Color(30, 30, 30);
private Color highTrafficColor = Color.RED;
private Color mediumTrafficColor = Color.YELLOW;
private Color lowTrafficColor = Color.GREEN;
public Builder(Point origin, Point destination) {
this.origin = origin;
this.destination = destination;
}
public Builder waterColor(Color color) {
waterColor = color;
return this;
}
public Builder landColor(Color color) {
landColor = color;
return this;
}
public Builder highTrafficColor(Color color) {
highTrafficColor = color;
return this;
}
public Builder mediumTrafficColor(Color color) {
mediumTrafficColor = color;
return this;
}
public Builder lowTrafficColor(Color color) {
lowTrafficColor = color;
return this;
}
public StreetMap build() {
return new StreetMap(this);
}
}
private StreetMap(Builder builder) {
// Required parameters
origin = builder.origin;
destination = builder.destination;
// Optional parameters
waterColor = builder.waterColor;
landColor = builder.landColor;
highTrafficColor = builder.highTrafficColor;
mediumTrafficColor = builder.mediumTrafficColor;
lowTrafficColor = builder.lowTrafficColor;
}
public static void main(String args[]) {
StreetMap map = new StreetMap.Builder(new Point(50, 50), new Point(100,
100)).landColor(Color.GRAY).waterColor(Color.BLUE.brighter())
.build();
}
}
See also
References
- ↑ Lua error in package.lua at line 80: module 'strict' not found.
- ↑ Gang Of Four
External links
The Wikibook Computer Science Design Patterns has a page on the topic of: Builder implementations in various languages |
- The JavaWorld article Build user interfaces without getters and setters (Allen Holub) shows the complete Java source code for a Builder.
- Item 2: Consider a builder by Joshua Bloch
- Builder C++ implementation example