Lambda Expressions and Functional Interfaces: Tips and Best Practices

转载自https://www.baeldung.com/java-8-lambda-expressions-tips

1. Overview

 

Now that Java 8 has reached wide usage, patterns, and best practices have begun to emerge for some of its headlining features. In this tutorial, we will take a closer look to functional interfaces and lambda expressions.

Further reading:

Why Do Local Variables Used in Lambdas Have to Be Final or Effectively Final?

Learn why Java requires local variables to be effectively final when used in a lambda. Read more →

Java 8 – Powerful Comparison with Lambdas

Elegant Sort in Java 8 - Lambda Expressions go right past syntactic sugar and bring powerful functional semantics into Java. Read more →

2. Prefer Standard Functional Interfaces

 

Functional interfaces, which are gathered in the java.util.function package, satisfy most developers' needs in providing target types for lambda expressions and method references. Each of these interfaces is general and abstract, making them easy to adapt to almost any lambda expression. Developers should explore this package before creating new functional interfaces.

 

Consider an interface Foo:

1 2 3 4 @FunctionalInterface public interface Foo {     String method(String string); }

and a method add() in some class UseFoo, which takes this interface as a parameter:

1 2 3 public String add(String string, Foo foo) {     return foo.method(string); }

To execute it, you would write:

1 2 Foo foo = parameter -> parameter + " from lambda"; String result = useFoo.add("Message ", foo);

Look closer and you will see that Foo is nothing more than a function that accepts one argument and produces a result. Java 8 already provides such an interface in Function<T,R> from the java.util.function package.

Now we can remove interface Foo completely and change our code to:

1 2 3 public String add(String string, Function<String, String> fn) {     return fn.apply(string); }

To execute this, we can write:

1 2 3 Function<String, String> fn =   parameter -> parameter + " from lambda"; String result = useFoo.add("Message ", fn);

3. Use the @FunctionalInterface Annotation

 

Annotate your functional interfaces with @FunctionalInterface. At first, this annotation seems to be useless. Even without it, your interface will be treated as functional as long as it has just one abstract method.

But imagine a big project with several interfaces – it's hard to control everything manually. An interface, which was designed to be functional, could accidentally be changed by adding of other abstract method/methods, rendering it unusable as a functional interface.

But using the @FunctionalInterface annotation, the compiler will trigger an error in response to any attempt to break the predefined structure of a functional interface. It is also a very handy tool to make your application architecture easier to understand for other developers.

So, use this:

 
1 2 3 4 @FunctionalInterface public interface Foo {     String method(); }

instead of just:

1 2 3 public interface Foo {     String method(); }

4. Don't Overuse Default Methods in Functional Interfaces

 

You can easily add default methods to the functional interface. This is acceptable to the functional interface contract as long as there is only one abstract method declaration:

1 2 3 4 5 @FunctionalInterface public interface Foo {     String method();     default void defaultMethod() {} }

Functional interfaces can be extended by other functional interfaces if their abstract methods have the same signature. For example:

1 2 3 4 5 6 7 8 9 10 11 12 13 14 @FunctionalInterface public interface FooExtended extends Baz, Bar {}       @FunctionalInterface public interface Baz {      String method();        default void defaultBaz() {}        }       @FunctionalInterface public interface Bar {      String method();        default void defaultBar() {}    }

Just as with regular interfaces, extending different functional interfaces with the same default method can be problematic. For example, assume that interfaces Bar and Baz both have a default method defaultCommon(). In this case, you will get a compile-time error:

1 interface Foo inherits unrelated defaults for defaultCommon() from types Baz and Bar...

To fix this, defaultCommon() method should be overridden in the Foo interface. You can, of course, provide a custom implementation of this method. But if you want to use one of the parent interfaces' implementations (for example, from the Baz interface), add following line of code to the defaultCommon() method's body:

1 Baz.super.defaultCommon();

But be careful. Adding too many default methods to the interface is not a very good architectural decision. It is should be viewed as a compromise, only to be used when required, for upgrading existing interfaces without breaking backward compatibility.

5. Instantiate Functional Interfaces with Lambda Expressions

 

The compiler will allow you to use an inner class to instantiate a functional interface. However, this can lead to very verbose code. You should prefer lambda expressions:

1 Foo foo = parameter -> parameter + " from Foo";

over an inner class:

1 2 3 4 5 6 Foo fooByIC = new Foo() {     @Override     public String method(String string) {         return string + " from Foo";     } };

The lambda expression approach can be used for any suitable interface from old libraries. It is usable for interfaces like RunnableComparator, and so on. However, this doesn't mean that you should review your whole older codebase and change everything.

6. Avoid Overloading Methods with Functional Interfaces as Parameters

 

Use methods with different names to avoid collisions; let's look at an example:

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 public interface Processor {     String process(Callable<String> c) throws Exception;     String process(Supplier<String> s); }   public class ProcessorImpl implements Processor {     @Override     public String process(Callable<String> c) throws Exception {         // implementation details     }       @Override     public String process(Supplier<String> s) {         // implementation details     } }

At first glance, this seems reasonable. But any attempt to execute either of the ProcessorImpl‘s methods:

 
1 String result = processor.process(() -> "abc");

ends with an error with the following message:

1 2 3 4 5 reference to process is ambiguous both method process(java.util.concurrent.Callable<java.lang.String>) in com.baeldung.java8.lambda.tips.ProcessorImpl and method process(java.util.function.Supplier<java.lang.String>) in com.baeldung.java8.lambda.tips.ProcessorImpl match

To solve this problem, we have two options. The first is to use methods with different names:

1 2 3 String processWithCallable(Callable<String> c) throws Exception;   String processWithSupplier(Supplier<String> s);

The second is to perform casting manually. This is not preferred.

1 String result = processor.process((Supplier<String>) () -> "abc");

7. Don’t Treat Lambda Expressions as Inner Classes

 

Despite our previous example, where we essentially substituted inner class by a lambda expression, the two concepts are different in an important way: scope.

When you use an inner class, it creates a new scope. You can hide local variables from the enclosing scope by instantiating new local variables with the same names. You can also use the keyword this inside your inner class as a reference to its instance.

However, lambda expressions work with enclosing scope. You can’t hide variables from the enclosing scope inside the lambda’s body. In this case, the keyword this is a reference to an enclosing instance.

For example, in the class UseFoo you have an instance variable value:

1 private String value = "Enclosing scope value";

Then in some method of this class place the following code and execute this method.

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 public String scopeExperiment() {     Foo fooIC = new Foo() {         String value = "Inner class value";           @Override         public String method(String string) {             return this.value;         }     };     String resultIC = fooIC.method("");       Foo fooLambda = parameter -> {         String value = "Lambda value";         return this.value;     };     String resultLambda = fooLambda.method("");       return "Results: resultIC = " + resultIC +       ", resultLambda = " + resultLambda; }

If you execute the scopeExperiment() method, you will get the following result: Results: resultIC = Inner class value, resultLambda = Enclosing scope value

As you can see, by calling this.value in IC, you can access a local variable from its instance. But in the case of the lambda, this.value call gives you access to the variable value which is defined in the UseFoo class, but not to the variable value defined inside the lambda's body.

8. Keep Lambda Expressions Short And Self-explanatory

 

If possible, use one line constructions instead of a large block of code. Remember lambdas should be an expression, not a narrative. Despite its concise syntax, lambdas should precisely express the functionality they provide.

 

This is mainly stylistic advice, as performance will not change drastically. In general, however, it is much easier to understand and to work with such code.

This can be achieved in many ways – let's have a closer look.

8.1. Avoid Blocks of Code in Lambda's Body

 

In an ideal situation, lambdas should be written in one line of code. With this approach, the lambda is a self-explanatory construction, which declares what action should be executed with what data (in the case of lambdas with parameters).

If you have a large block of code, the lambda's functionality is not immediately clear.

With this in mind, do the following:

1 Foo foo = parameter -> buildString(parameter);
1 2 3 4 5 private String buildString(String parameter) {     String result = "Something " + parameter;     //many lines of code     return result; }

instead of:

1 2 3 4 Foo foo = parameter -> { String result = "Something " + parameter;     //many lines of code     return result; };

However, please don't use this “one-line lambda” rule as dogma. If you have two or three lines in lambda's definition, it may not be valuable to extract that code into another method.

8.2. Avoid Specifying Parameter Types

 

A compiler in most cases is able to resolve the type of lambda parameters with the help of type inference. Therefore, adding a type to the parameters is optional and can be omitted.

Do this:

1 (a, b) -> a.toLowerCase() + b.toLowerCase();

instead of this:

1 (String a, String b) -> a.toLowerCase() + b.toLowerCase();

8.3. Avoid Parentheses Around a Single Parameter

 

Lambda syntax requires parentheses only around more than one parameter or when there is no parameter at all. That is why it is safe to make your code a little bit shorter and to exclude parentheses when there is only one parameter.

 

So, do this:

1 a -> a.toLowerCase();

instead of this:

1 (a) -> a.toLowerCase();

8.4. Avoid Return Statement and Braces

 

Braces and return statements are optional in one-line lambda bodies. This means, that they can be omitted for clarity and conciseness.

Do this:

1 a -> a.toLowerCase();

instead of this:

1 a -> {return a.toLowerCase()};

8.5. Use Method References

 

Very often, even in our previous examples, lambda expressions just call methods which are already implemented elsewhere. In this situation, it is very useful to use another Java 8 feature: method references.

So, the lambda expression:

1 a -> a.toLowerCase();

could be substituted by:

1 String::toLowerCase;

This is not always shorter, but it makes the code more readable.

9. Use “Effectively Final” Variables

 

Accessing a non-final variable inside lambda expressions will cause the compile-time error. But it doesn’t mean that you should mark every target variable as final.

According to the “effectively final” concept, a compiler treats every variable as final, as long as it is assigned only once.

 

It is safe to use such variables inside lambdas because the compiler will control their state and trigger a compile-time error immediately after any attempt to change them.

For example, the following code will not compile:

1 2 3 4 5 6 7 public void method() {     String localVariable = "Local";     Foo foo = parameter -> {         String localVariable = parameter;         return localVariable;     }; }

The compiler will inform you that:

1 Variable 'localVariable' is already defined in the scope.

This approach should simplify the process of making lambda execution thread-safe.

10. Protect Object Variables from Mutation

 

One of the main purposes of lambdas is use in parallel computing – which means that they're really helpful when it comes to thread-safety.

The “effectively final” paradigm helps a lot here, but not in every case. Lambdas can't change a value of an object from enclosing scope. But in the case of mutable object variables, a state could be changed inside lambda expressions.

Consider the following code:

1 2 3 int[] total = new int[1]; Runnable r = () -> total[0]++; r.run();

This code is legal, as total variable remains “effectively final”. But will the object it references to have the same state after execution of the lambda? No!

Keep this example as a reminder to avoid code that can cause unexpected mutations.

11. Conclusion

 

In this tutorial, we saw some best practices and pitfalls in Java 8's lambda expressions and functional interfaces. Despite the utility and power of these new features, they are just tools. Every developer should pay attention while using them.

The complete source code for the example is available in this GitHub project – this is a Maven and Eclipse project, so it can be imported and used as-is.

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