--- layout: pattern title: Bridge folder: bridge permalink: /patterns/bridge/ categories: Structural language: en tags: - Gang of Four --- ## Also known as Handle/Body ## Intent Decouple an abstraction from its implementation so that the two can vary independently. ## Explanation Real-world example > Consider you have a weapon with different enchantments, and you are supposed to allow mixing > different weapons with different enchantments. What would you do? Create multiple copies of each > of the weapons for each of the enchantments or would you just create separate enchantment and set > it for the weapon as needed? Bridge pattern allows you to do the second. In Plain Words > Bridge pattern is about preferring composition over inheritance. Implementation details are pushed > from a hierarchy to another object with a separate hierarchy. Wikipedia says > The bridge pattern is a design pattern used in software engineering that is meant to "decouple an abstraction from its implementation so that the two can vary independently" **Programmatic Example** Translating our weapon example from above. Here we have the `Weapon` hierarchy: ```java public interface Weapon { void wield(); void swing(); void unwield(); Enchantment getEnchantment(); } public class Sword implements Weapon { private final Enchantment enchantment; public Sword(Enchantment enchantment) { this.enchantment = enchantment; } @Override public void wield() { LOGGER.info("The sword is wielded."); enchantment.onActivate(); } @Override public void swing() { LOGGER.info("The sword is swinged."); enchantment.apply(); } @Override public void unwield() { LOGGER.info("The sword is unwielded."); enchantment.onDeactivate(); } @Override public Enchantment getEnchantment() { return enchantment; } } public class Hammer implements Weapon { private final Enchantment enchantment; public Hammer(Enchantment enchantment) { this.enchantment = enchantment; } @Override public void wield() { LOGGER.info("The hammer is wielded."); enchantment.onActivate(); } @Override public void swing() { LOGGER.info("The hammer is swinged."); enchantment.apply(); } @Override public void unwield() { LOGGER.info("The hammer is unwielded."); enchantment.onDeactivate(); } @Override public Enchantment getEnchantment() { return enchantment; } } ``` Here's the separate enchantment hierarchy: ```java public interface Enchantment { void onActivate(); void apply(); void onDeactivate(); } public class FlyingEnchantment implements Enchantment { @Override public void onActivate() { LOGGER.info("The item begins to glow faintly."); } @Override public void apply() { LOGGER.info("The item flies and strikes the enemies finally returning to owner's hand."); } @Override public void onDeactivate() { LOGGER.info("The item's glow fades."); } } public class SoulEatingEnchantment implements Enchantment { @Override public void onActivate() { LOGGER.info("The item spreads bloodlust."); } @Override public void apply() { LOGGER.info("The item eats the soul of enemies."); } @Override public void onDeactivate() { LOGGER.info("Bloodlust slowly disappears."); } } ``` Here are both hierarchies in action: ```java LOGGER.info("The knight receives an enchanted sword."); var enchantedSword = new Sword(new SoulEatingEnchantment()); enchantedSword.wield(); enchantedSword.swing(); enchantedSword.unwield(); LOGGER.info("The valkyrie receives an enchanted hammer."); var hammer = new Hammer(new FlyingEnchantment()); hammer.wield(); hammer.swing(); hammer.unwield(); ``` Here's the console output. ``` The knight receives an enchanted sword. The sword is wielded. The item spreads bloodlust. The sword is swung. The item eats the soul of enemies. The sword is unwielded. Bloodlust slowly disappears. The valkyrie receives an enchanted hammer. The hammer is wielded. The item begins to glow faintly. The hammer is swung. The item flies and strikes the enemies finally returning to owner's hand. The hammer is unwielded. The item's glow fades. ``` ## Class diagram ![alt text](./etc/bridge.urm.png "Bridge class diagram") ## Applicability Use the Bridge pattern when * You want to avoid a permanent binding between an abstraction and its implementation. This might be the case, for example, when the implementation must be selected or switched at run-time. * Both the abstractions and their implementations should be extensible by subclassing. In this case, the Bridge pattern lets you combine the different abstractions and implementations and extend them independently. * Changes in the implementation of an abstraction should have no impact on clients; that is, their code should not have to be recompiled. * You have a proliferation of classes. Such a class hierarchy indicates the need for splitting an object into two parts. Rumbaugh uses the term "nested generalizations" to refer to such class hierarchies. * You want to share an implementation among multiple objects (perhaps using reference counting), and this fact should be hidden from the client. A simple example is Coplien's String class, in which multiple objects can share the same string representation. ## Tutorial * [Bridge Pattern Tutorial](https://www.journaldev.com/1491/bridge-design-pattern-java) ## Credits * [Design Patterns: Elements of Reusable Object-Oriented Software](https://www.amazon.com/gp/product/0201633612/ref=as_li_tl?ie=UTF8&camp=1789&creative=9325&creativeASIN=0201633612&linkCode=as2&tag=javadesignpat-20&linkId=675d49790ce11db99d90bde47f1aeb59) * [Head First Design Patterns: A Brain-Friendly Guide](https://www.amazon.com/gp/product/0596007124/ref=as_li_tl?ie=UTF8&camp=1789&creative=9325&creativeASIN=0596007124&linkCode=as2&tag=javadesignpat-20&linkId=6b8b6eea86021af6c8e3cd3fc382cb5b)