I have a question regarding the usage of the Function.identity() method.

Imagine the following code:

Arrays.asList("a", "b", "c")
          .map(Function.identity()) // <- This,
          .map(str -> str)          // <- is the same as this.
                       Function.identity(), // <-- And this,
                       str -> str));        // <-- is the same as this.

Is there any reason why you should use Function.identity() instead of str->str (or vice versa). I think that the second option is more readable (a matter of taste of course). But, is there any "real" reason why one should be preferred?

  • 6
    Ultimately, no, this won't make a difference. – fge Jan 19 '15 at 20:17
  • 48
    Either is fine. Go with whichever you think is more readable. (Don't worry, be happy.) – Brian Goetz Jan 19 '15 at 22:29
  • 3
    I would prefer t -> t simply because it's more succinct. – David Conrad Jan 20 '15 at 16:33
  • 3
    Slightly unrelated question, but does anyone know why the language designers make identity() return an instance of Function instead of having a parameter of type T and returning it so the method can be used with method references? – Kirill Rakhman Jan 22 '15 at 19:47
  • I would argue there's a use to being conversant with the word "identity," since it has an important meaning in other areas of functional programming. – orbfish Jun 14 '15 at 1:14

As of the current JRE implementation, Function.identity() will always return the same instance while each occurrence of identifier -> identifier will not only create its own instance but even have a distinct implementation class. For more details, see here.

The reason is that the compiler generates a synthetic method holding the trivial body of that lambda expression (in the case of x->x, equivalent to return identifier;) and tell the runtime to create an implementation of the functional interface calling this method. So the runtime sees only different target methods and the current implementation does not analyze the methods to find out whether certain methods are equivalent.

So using Function.identity() instead of x -> x might save some memory but that shouldn’t drive your decision if you really think that x -> x is more readable than Function.identity().

You may also consider that when compiling with debug information enabled, the synthetic method will have a line debug attribute pointing to the source code line(s) holding the lambda expression, therefore you have a chance of finding the source of a particular Function instance while debugging. In contrast, when encountering the instance returned by Function.identity() during debugging an operation, you won’t know who has called that method and passed the instance to the operation.

  • 5
    Nice answer. I have some doubts about debugging. How it can be useful? It's very unlikely to get the exception stack trace involving x -> x frame. Do you suggest to set the breakpoint to this lambda? Usually it's not so easy to put the breakpoint into the single-expression lambda (at least in Eclipse)... – Tagir Valeev Aug 19 '15 at 1:57
  • 14
    @Tagir Valeev: you may debug code which receives an arbitrary function and step into the apply method of that function. Then you may end up at the source code of a lambda expression. In the case of an explicit lambda expression you’ll know where the function comes from and have a chance to recognize at which place the decision to pass though an identity function was made. When using Function.identity() that information is lost. Then, the call chain may help in simple cases but think of, e.g. multi-threaded evaluation where the original initiator is not in the stack trace… – Holger Aug 19 '15 at 8:35
  • 2
    Interesting in this context: blog.codefx.org/java/instances-non-capturing-lambdas – Wim Deblauwe Oct 26 '15 at 13:38
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    @Wim Deblauwe: Interesting, but I would always see it the other way round: if a factory method doesn’t explicitly state in its documentation that it will return a new instance on every invocation, you can’t assume that it will. So it shouldn’t be surprising if it doesn’t. After all, that’s one big reason for using factory methods instead of new. new Foo(…) guaranties to create a new instance of the exact type Foo, whereas, Foo.getInstance(…) may return an existing instance of (a subtype of) Foo – Holger Oct 26 '15 at 14:15

In your example there is no big difference between str -> str and Function.identity() since internally it is simply t->t.

But sometimes we can't use Function.identity because we can't use a Function. Take a look here:

List<Integer> list = new ArrayList<>();

this will compile fine

int[] arrayOK = list.stream().mapToInt(i -> i).toArray();

but if you try to compile

int[] arrayProblem = list.stream().mapToInt(Function.identity()).toArray();

you will get compilation error since mapToInt expects ToIntFunction, which is not related to Function. Also ToIntFunction doesn't have identity() method.

  • 3
    See stackoverflow.com/q/38034982/14731 for another example where replacing i -> i with Function.identity() will result in a compiler error. – Gili Jun 26 '16 at 3:35
  • 16
    I prefer mapToInt(Integer::intValue). – shmosel May 1 '17 at 4:52
  • 4
    @shmosel that is OK but it is worth mentioning that both solutions will work similarly since mapToInt(i -> i) is simplification of mapToInt( (Integer i) -> i.intValue()). Use whichever version you think is clearer, for me mapToInt(i -> i) better shows intentions of this code. – Pshemo May 1 '17 at 16:38
  • 1
    I think there can be performance benefits in using method references, but it's mostly just a personal preference. I find it more descriptive, because i -> i looks like an identity function, which it isn't in this case. – shmosel May 1 '17 at 18:57
  • @shmosel I can't say much about performance difference so you may be right. But if performance is not an issue I will stay with i -> i since my goal is to map Integer to int (which mapToInt suggests quite nicely) not to explicitly call intValue() method. How this mapping will be achieved is not really that important. So lets just agree to disagree but thanks for pointing out possible performance difference, I will need to take a closer look at that someday. – Pshemo May 1 '17 at 21:45

From the JDK source:

static <T> Function<T, T> identity() {
    return t -> t;

So, no, as long as it is syntactically correct.

  • 7
    I wonder if this invalidates the answer above relating to a lambda creating an object - or if this is a particular implementation. – orbfish Jun 14 '15 at 1:12
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    @orbfish: that’s perfectly in line. Every occurrence of t->t in source code may create one object and the implementation of Function.identity() is one occurrence. So all call sites invoking identity() will share that one object while all sites explicitly using the lambda expression t->t will create their own object. The method Function.identity() is not special in any way, whenever you create a factory method encapsulating a commonly used lambda expression and call that method instead of repeating the lambda expression, you may save some memory, given the current implementation. – Holger Jun 15 '15 at 8:09
  • I'm guessing that this is because the compiler optimizes away the creation of a new t->t object each time the method is called and recycles the same one whenever the method is called? – Daniel Gray Aug 8 '17 at 10:37
  • 1
    @DanielGray the decision is made at runtime. The compiler inserts an invokedynamic instruction which gets linked on its first execution by executing a so-called bootstrap method, which in the case of lambda expressions is located in the LambdaMetafactory. This implementation decides to return a handle to a constructor, a factory method, or code always returning the same object. It may also decide to return a link to an already existing handle (which currently doesn’t happen). – Holger Aug 30 '19 at 8:16
  • @Holger Are you sure this call to identity wouldn't be inlined then potentially be monomorphized (and inlined again) ? – JasonN Sep 1 '19 at 18:56

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