I am confused by the following code

class LambdaTest {
    public static void main(String[] args) {
        Consumer<String>         lambda1 = s -> {};
        Function<String, String> lambda2 = s -> s;

        Consumer<String>         lambda3 = LambdaTest::consume; // but s -> s doesn't work!
        Function<String, String> lambda4 = LambdaTest::consume;

    static String consume(String s) { return s;}

I would have expected the assignment of lambda3 to fail as my consume method does not match the accept method in the Consumer Interface - the return types are different, String vs. void.

Moreover, I always thought that there is a one-to-one relationship between Lambda expressions and method references but this is clearly not the case as my example shows.

Could somebody explain to me what is happening here?


consume(String) method matches Consumer<String> interface, because it consumes a String - the fact that it returns a value is irrelevant, as - in this case - it is simply ignored. (Because the Consumer interface does not expect any return value at all).

It must have been a design choice and basically a utility: imagine how many methods would have to be refactored or duplicated to match needs of functional interfaces like Consumer or even the very common Runnable. (Note that you can pass any method that consumes no parameters as a Runnable to an Executor, for example.)

Even methods like java.util.List#add(Object) return a value: boolean. Being unable to pass such method references just because that they return something (that is mostly irrelevant in many cases) would be rather annoying.

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    About the s -> s - my guess is that if you explicitly define a new lambda without referencing an existing method, you have to follow its exact method signature. In this case, Consumer<String> does not return anything, so you cannot just end the lambda with a line that basically stands for return s;. s -> s.toString() (which would pretty have the same result) should work, as the method would be simply invoked and its result (s) would be ignored. – JustACluelessNewbie May 18 '16 at 20:56
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    s -> s is an equivalent of s -> { return s; }, which fails to compile, as Consumer method cannot return a value. s -> s.toString() might seem to "do" the same thing, but it actually is an equivalent of s -> { s.toString(); }, which simply invokes a method, but does not return anything. So - in the first example, you're trying to return a value. In the second, you're actually invoking a method and ignoring its result. – JustACluelessNewbie May 18 '16 at 21:14
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    Yes, that's it. Is there anything you'd like me to add to the original answer or can it be accepted as it is? – JustACluelessNewbie May 18 '16 at 21:31
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    Here's the basis for this design decision: Java allows you to call a method and ignore the return value (a method invocation expression as a statement). Since we allow this at the invocation, we also allow this when adapting a method to a functional interface whose arguments are compatible but the functional interface is void-returning. – Brian Goetz May 18 '16 at 23:20
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    Note also that we'll do other adaptations (boxing, unboxing) to make the shape of the lambda match up with the expected shape of the functional interface. Ignoring a return value is just one of those adaptations. – Brian Goetz May 18 '16 at 23:21

As Brian Goetz pointed out in a comment, the basis for the design decision was to allow adapting a method to a functional interface the same way you can call the method, i.e. you can call every value returning method and ignore the returned value.

When it comes to lambda expressions, things get a bit more complicated. There are two forms of lambda expressions, (args) -> expression and (args) -> { statements* }.

Whether the second form is void compatible, depends on the question whether no code path attempts to return a value, e.g. () -> { return ""; } is not void compatible, but expression compatible, whereas () -> {} or () -> { return; } are void compatible. Note that () -> { for(;;); } and () -> { throw new RuntimeException(); } are both, void compatible and value compatible, as they don’t complete normally and there’s no return statement.

The form (arg) -> expression is value compatible if the expression evaluates to a value. But there are also expressions, which are statements at the same time. These expressions may have a side effect and therefore can be written as stand-alone statement for producing the side effect only, ignoring the produced result. Similarly, the form (arg) -> expression can be void compatible, if the expression is also a statement.

An expression of the form s -> s can’t be void compatible as s is not a statement, i.e. you can’t write s -> { s; } either. On the other hand s -> s.toString() can be void compatible, because method invocations are statements. Similarly, s -> i++ can be void compatible as increments can be used as a statement, so s -> { i++; } is valid too. Of course, i has to be a field for this to work, not a local variable.

The Java Language Specification §14.8. Expression Statements lists all expressions which may be used as statements. Besides the already mentioned method invocations and increment/ decrement operators, it names assignments and class instance creation expressions, so s -> foo=s and s -> new WhatEver(s) are void compatible too.

As a side note, the form (arg) -> methodReturningVoid(arg) is the only expression form that is not value compatible.

  • Thanks for this enlightening discussion of the design rationales especially with regard to the notions of void and value compatibility. I wasn't aware that void plays such a special role in type compatibility questions. I first stumbled onto this when I saw somewhere StringBuilder::append being used both as a BiFunction and a BiConsumer in Stream.reduce() and Stream.collect(), respectively. I understand now why this is possible but I am still wondering whether this constitutes fair use or abuse ... – Ulrich Schmidt May 19 '16 at 14:31
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    As said, you can always call a method for its side-effect and ignore the returned result and so you can do with a method reference/lambda expression. That’s a fair use. It would be bad code if you invoke a method that way that is known to have no side effect, e.g. s -> s.toString() is suspicious. Similarly, an expression of the form i -> i++ which modifies the parameter, which has no persisting effect, is strongly discouraged. – Holger May 19 '16 at 14:50
  • "complete normally" is used incorrectly here. According to docs.oracle.com/javase/specs/jls/se8/html/jls-14.html#jls-14.1, a return statement is abrupt completion, not normal completion. – Kylos Apr 23 '19 at 14:26
  • "value-compatible" is defined in (§15.27.2) as "A block lambda body is value-compatible if it cannot complete normally (§14.21) and every return statement in the block has the form return Expression;." – Kylos Apr 23 '19 at 14:33
  • The statement in the answer "whether all code paths that complete normally won’t attempt to return a value" implies that returning a value is considered completing normally. This should be corrected. – Kylos Apr 23 '19 at 14:35

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