In Java 8, what's the difference between Stream.map and Stream.flatMap methods?

  • 40
    The type signature kinda tells the whole story. map :: Stream T -> (T -> R) -> Stream R, flatMap :: Stream T -> (T -> Stream R) -> Stream R. – Chris Martin Oct 31 '14 at 22:56
  • 62
    fwiw, those type signatures don't even look like Java. (I know, I know -- but to say it tells "the whole story" wrt map/flatMap assumes a lot of knowledge about the new & improved "Java++") – michael Jul 17 '17 at 16:33
  • 8
    @michael That type signature looks like Haskell, not Java. But it's not clear whether the actual Java signature is any more readable: <R> Stream<R> flatMap(Function<? super T,? extends Stream<? extends R>> mapper). – Stuart Marks Jul 20 '17 at 1:34
  • 3
    Ha, yeah, I was referring to the "actual Java". Like C++, modern Java is almost unrecognizable to anyone who started using it in the 90s (like I did, both languages). Just replying to the comment, that method signatures hardly tell a "whole story", at least not anymore, not without additional exposition (or in that commenters case, translation). – michael Jul 20 '17 at 13:19
  • Which is to say, a map's mapper lambda returns R, a flatMap's mapper lambda returns a Stream of R (Stream<R>). The streams returned by the flatMap's mapper are effectively concatenated. Otherwise, both map and flatMap return Stream<R>; the difference is what the mapper lambdas return, R vs. Stream<R>. – derekm Mar 7 '18 at 19:20

18 Answers 18


Both map and flatMap can be applied to a Stream<T> and they both return a Stream<R>. The difference is that the map operation produces one output value for each input value, whereas the flatMap operation produces an arbitrary number (zero or more) values for each input value.

This is reflected in the arguments to each operation.

The map operation takes a Function, which is called for each value in the input stream and produces one result value, which is sent to the output stream.

The flatMap operation takes a function that conceptually wants to consume one value and produce an arbitrary number of values. However, in Java, it's cumbersome for a method to return an arbitrary number of values, since methods can return only zero or one value. One could imagine an API where the mapper function for flatMap takes a value and returns an array or a List of values, which are then sent to the output. Given that this is the streams library, a particularly apt way to represent an arbitrary number of return values is for the mapper function itself to return a stream! The values from the stream returned by the mapper are drained from the stream and are passed to the output stream. The "clumps" of values returned by each call to the mapper function are not distinguished at all in the output stream, thus the output is said to have been "flattened."

Typical use is for the mapper function of flatMap to return Stream.empty() if it wants to send zero values, or something like Stream.of(a, b, c) if it wants to return several values. But of course any stream can be returned.

  • 14
    Sounds to me like the flatMap operation is the exact opposite of flat. Yet again, leave it to Computer Scientists to turn a term on it's head. Like a function being "transparent" meaning you can't see anything it does, just the results, while colloquially saying you want a process to be transparent means you want every part of it to be seen. – coladict May 18 '17 at 7:53
  • 28
    @coladict Try viewing it from a different perspective: it's not a transparent case where you can see the inner workings through, but the whole function itself is transparent, i.e. invisible, to you - while still doing their work and letting you see what you're working with. In this case, "flat" refers to the opposite of "nested", flatmap removes one nesting level by flattening. – Zefiro Jun 7 '17 at 16:10
  • 6
    @coladict The "transparent" thing has been eating my head for years. Glad to know at least one other person feels the same way. – Ashok Bijoy Debnath Jul 19 '17 at 19:59
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    Flattening comes from turning 2-level structure into single level structure, see Dici's answer for an example stackoverflow.com/a/26684582/6012102 – andrzej.szmukala Jan 16 '18 at 11:42
  • 10
    This is the best explanation of flatMap. This is what makes it all clicked: The values from the stream returned by the mapper are drained from the stream and are passed to the output stream. The "clumps" of values returned by each call to the mapper function are not distinguished at all in the output stream, thus the output is said to have been "flattened". Thank you! – neevek Mar 7 '18 at 8:20

Stream.flatMap, as it can be guessed by its name, is the combination of a map and a flat operation. That means that you first apply a function to your elements, and then flatten it. Stream.map only applies a function to the stream without flattening the stream.

To understand what flattening a stream consists in, consider a structure like [ [1,2,3],[4,5,6],[7,8,9] ] which has "two levels". Flattening this means transforming it in a "one level" structure : [ 1,2,3,4,5,6,7,8,9 ].


I would like to give 2 examples to get a more practical point of view:
First example making usage of map:

public void convertStringToUpperCaseStreams() {
    List<String> collected = Stream.of("a", "b", "hello") // Stream of String 
            .map(String::toUpperCase) // Returns a stream consisting of the results of applying the given function to the elements of this stream.
    assertEquals(asList("A", "B", "HELLO"), collected);

Nothing special in the first example, a Function is applied to return the String in uppercase.

Second example making usage of flatMap:

public void testflatMap() throws Exception {
    List<Integer> together = Stream.of(asList(1, 2), asList(3, 4)) // Stream of List<Integer>
            .map(integer -> integer + 1)
    assertEquals(asList(2, 3, 4, 5), together);

In the second example, a Stream of List is passed. It is NOT a Stream of Integer!
If a transformation Function has to be used (through map), then first the Stream has to be flattened to something else (a Stream of Integer).
If flatMap is removed then the following error is returned: The operator + is undefined for the argument type(s) List, int.
It is NOT possible to apply + 1 on a List of Integers!

  • 3
    Here .flatMap(List::stream) , can we use map instead of flatmap ??? – Prashanth Debbadwar May 15 '17 at 13:00
  • 2
    @PrashanthDebbadwar you could, but that would return Stream<Stream<Integer>>, not what you might need... how about this simple explanation ? – Eugene Sep 9 '18 at 21:09

Please go through the post fully to get a clear idea, map vs flatMap: To return a length of each word from a list, we would do something like below..

For example:-
Consider a list [“STACK”, ”OOOVVVER”] and we are trying to return a list like [“STACKOVER”](returning only unique letters from that list) Initially, we would do something like below to return a list [“STACKOVER”] from [“STACK”, ”OOOVVVER”]

public class WordMap {
  public static void main(String[] args) {
    List<String> lst = Arrays.asList("STACK","OOOVER");

Here the issue is, Lambda passed to the map method returns a String array for each word, So the stream returned by the map method is actually of type Stream, But what we need is Stream to represent a stream of characters, below image illustrates the problem.

Figure A:

enter image description here

You might think that, We can resolve this problem using flatmap,
OK, let us see how to solve this by using map and Arrays.stream First of all you gonna need a stream of characters instead of a stream of arrays. There is a method called Arrays.stream() that would take an array and produces a stream, for example:

String[] arrayOfWords = {"STACK", "OOOVVVER"};
Stream<String> streamOfWords = Arrays.stream(arrayOfWords);
streamOfWords.map(s->s.split("")) //Converting word in to array of letters
    .map(Arrays::stream).distinct() //Make array in to separate stream

The above still does not work, because we now end up with a list of streams (more precisely, Stream>), Instead, we must first convert each word into an array of individual letters and then make each array into a separate stream

By using flatMap we should be able to fix this problem as below:

String[] arrayOfWords = {"STACK", "OOOVVVER"};
Stream<String> streamOfWords = Arrays.stream(arrayOfWords);
streamOfWords.map(s->s.split("")) //Converting word in to array of letters
    .flatMap(Arrays::stream).distinct() //flattens each generated stream in to a single stream

flatMap would perform mapping each array not with stream but with the contents of that stream. All of the individual streams that would get generated while using map(Arrays::stream) get merged into a single stream. Figure B illustrates the effect of using the flatMap method. Compare it with what map does in figure A. Figure B enter image description here

The flatMap method lets you replace each value of a stream with another stream and then joins all the generated streams into a single stream.

  • 1
    Nice diagrammatic explanation. – Hitesh Feb 17 at 8:32

One line answer: flatMap helps to flatten a Collection<Collection<T>> into a Collection<T>. In the same way, it will also flatten an Optional<Optional<T>> into Optional<T>.

enter image description here

As you can see, with map() only:

  • The intermediate type is Stream<List<Item>>
  • The return type is List<List<Item>>

and with flatMap():

  • The intermediate type is Stream<Item>
  • The return type is List<Item>

This is the test result from the code used right below:

-------- Without flatMap() -------------------------------
     collect returns: [[Laptop, Phone], [Mouse, Keyboard]]

-------- With flatMap() ----------------------------------
     collect returns: [Laptop, Phone, Mouse, Keyboard]

Code used:

import java.util.Arrays;
import java.util.Collection;
import java.util.List;
import java.util.stream.Collectors;

public class Parcel {
  String name;
  List<String> items;

  public Parcel(String name, String... items) {
    this.name = name;
    this.items = Arrays.asList(items);

  public List<String> getItems() {
    return items;

  public static void main(String[] args) {
    Parcel amazon = new Parcel("amazon", "Laptop", "Phone");
    Parcel ebay = new Parcel("ebay", "Mouse", "Keyboard");
    List<Parcel> parcels = Arrays.asList(amazon, ebay);

    System.out.println("-------- Without flatMap() ---------------------------");
    List<List<String>> mapReturn = parcels.stream()
    System.out.println("\t collect return: " + mapReturn);

    System.out.println("\n-------- With flatMap() ------------------------------");
    List<String> flatMapReturn = parcels.stream()
    System.out.println("\t collect return: " + flatMapReturn);

The function you pass to stream.map has to return one object. That means each object in the input stream results in exactly one object in the output stream.

The function you pass to stream.flatMap returns a stream for each object. That means the function can return any number of objects for each input object (including none). The resulting streams are then concatenated to one output stream.

  • Why would you want to "return any number of objects for each input object (including none)"? – Derek Mahar Dec 12 '18 at 15:50
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    @DerekMahar There would be plenty of use-cases for this. For example, let's say you have a stream of Departments in your organization. Each department has between 0 and n Employees. What you need is a stream of all employees. So what do you do? You write a flatMap method which takes a department and returns a stream of its employees. – Philipp Dec 12 '18 at 16:11
  • Philipp, does your example illustrate the main reason to use flatMap? I suspect that it may be incidental and doesn't illustrate the key use case or reason why flatMap exists. (Continued below...) – Derek Mahar Dec 12 '18 at 17:17
  • After reading dzone.com/articles/understanding-flatmap, I think the main motivation behind flatMap is to accommodate errors that would be present when using map. How do you handle cases where one or more items in the original set cannot be mapped to an output item? By introducing an intermediate set (say an Optional or Stream) for each input object, flatMap allows you to exclude the "invalid" input objects (or the so called "bad apples" in the spirit of stackoverflow.com/a/52248643/107158) from the final set. – Derek Mahar Dec 12 '18 at 17:17
  • @DerekMahar Yes, stuations where each input-object might or might not return an output-object is another good use-case for flat-map. – Philipp Dec 12 '18 at 17:21

for a Map we have a list of elements and a (function,action) f so :

[a,b,c] f(x) => [f(a),f(b),f(c)]

and for the flat map we have a list of elements list and we have a (function,action) f and we want the result to be flattened :

[[a,b],[c,d,e]] f(x) =>[f(a),f(b),f(c),f(d),f(e)]

I have a feeling that most answers here overcomplicate the simple problem. If you already understand how the map works that should be fairly easy to grasp.

There are cases where we can end up with unwanted nested structures when using map(), the flatMap() method is designed to overcome this by avoiding wrapping.



List<List<Integer>> result = Stream.of(Arrays.asList(1), Arrays.asList(2, 3))

We can avoid having nested lists by using flatMap:

List<Integer> result = Stream.of(Arrays.asList(1), Arrays.asList(2, 3))
  .flatMap(i -> i.stream())


Optional<Optional<String>> result = Optional.of(42)
      .map(id -> findById(id));

Optional<String> result = Optional.of(42)
      .flatMap(id -> findById(id));


private Optional<String> findById(Integer id)
  • sorry but the 2nd snippet from point 1 is not compiling instead of List<Integer> result = Stream.of(Arrays.asList(1), Arrays.asList(2, 3)) .flatMap(i -> i) .collect(Collectors.toList()); . It is should be Stream.of(Arrays.asList(1), Arrays.asList(2, 3)) .flatMap(List::stream) .collect(Collectors.toList()); – arthur Mar 13 '18 at 18:16
  • @arthur I think I used Vavr's Stream and List here - but I agree that it might be confusing a bit - I will change that to standard Java – Grzegorz Piwowarek Mar 14 '18 at 7:07
  • @GrzegorzPiwowarek how about this simple explanation ? – Eugene Sep 9 '18 at 21:06

Oracle's article on Optional highlights this difference between map and flatmap:

String version = computer.map(Computer::getSoundcard)

Unfortunately, this code doesn't compile. Why? The variable computer is of type Optional<Computer>, so it is perfectly correct to call the map method. However, getSoundcard() returns an object of type Optional. This means the result of the map operation is an object of type Optional<Optional<Soundcard>>. As a result, the call to getUSB() is invalid because the outermost Optional contains as its value another Optional, which of course doesn't support the getUSB() method.

With streams, the flatMap method takes a function as an argument, which returns another stream. This function is applied to each element of a stream, which would result in a stream of streams. However, flatMap has the effect of replacing each generated stream by the contents of that stream. In other words, all the separate streams that are generated by the function get amalgamated or "flattened" into one single stream. What we want here is something similar, but we want to "flatten" a two-level Optional into one.

Optional also supports a flatMap method. Its purpose is to apply the transformation function on the value of an Optional (just like the map operation does) and then flatten the resulting two-level Optional into a single one.

So, to make our code correct, we need to rewrite it as follows using flatMap:

String version = computer.flatMap(Computer::getSoundcard)

The first flatMap ensures that an Optional<Soundcard> is returned instead of an Optional<Optional<Soundcard>>, and the second flatMap achieves the same purpose to return an Optional<USB>. Note that the third call just needs to be a map() because getVersion() returns a String rather than an Optional object.


  • 1
    the question was about Stream.map and Stream.flatMap & not about Optional.map anfd Optional.flatMap – djames Jun 13 '17 at 16:26
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    But it helped me a lot to understand my problems with optional and flatmap, thanks a lot! – Loïc Jun 14 '17 at 6:58
  • 2
    @djames, it's a perfectly valid answer, read it starting from paragraph "With streams, the flatMap method takes a function as an argument..." :) – skwisgaar Sep 19 '17 at 22:19
  • I think this is a very useful addition to some of the other answers here. – Mz A Dec 9 '17 at 7:33
  • flatMap() version also throws nullpointerexception if soundCard is null. So where's the promised benefit of Optional? – Ekaterina Aug 23 '18 at 6:42

Map:- This method takes one Function as an argument and returns a new stream consisting of the results generated by applying the passed function to all the elements of the stream.

Let's imagine, I have a list of integer values ( 1,2,3,4,5 ) and one function interface whose logic is square of the passed integer. ( e -> e * e ).

List<Integer> intList = Arrays.asList(1, 2, 3, 4, 5);

List<Integer> newList = intList.stream().map( e -> e * e ).collect(Collectors.toList());



[1, 4, 9, 16, 25]

As you can see, an output is a new stream whose values are square of values of the input stream.

[1, 2, 3, 4, 5] -> apply e -> e * e -> [ 1*1, 2*2, 3*3, 4*4, 5*5 ] -> [1, 4, 9, 16, 25 ]


FlatMap :- This method takes one Function as an argument, this function accepts one parameter T as an input argument and returns one stream of parameter R as a return value. When this function is applied to each element of this stream, it produces a stream of new values. All the elements of these new streams generated by each element are then copied to a new stream, which will be a return value of this method.

Let's image, I have a list of student objects, where each student can opt for multiple subjects.

List<Student> studentList = new ArrayList<Student>();

  studentList.add(new Student("Robert","5st grade", Arrays.asList(new String[]{"history","math","geography"})));
  studentList.add(new Student("Martin","8st grade", Arrays.asList(new String[]{"economics","biology"})));
  studentList.add(new Student("Robert","9st grade", Arrays.asList(new String[]{"science","math"})));

  Set<Student> courses = studentList.stream().flatMap( e -> e.getCourse().stream()).collect(Collectors.toSet());



[economics, biology, geography, science, history, math]

As you can see, an output is a new stream whose values are a collection of all the elements of the streams return by each element of the input stream.

[ S1 , S2 , S3 ] -> [ {"history","math","geography"}, {"economics","biology"}, {"science","math"} ] -> take unique subjects -> [economics, biology, geography, science, history, math]


  • could make a difference if you provide code instead of just provinding doc link – Charles-Antoine Fournel Feb 10 '17 at 11:03

I am not very sure I am supposed to answer this, but every time I face someone that does not understand this, I use the same example.

Imagine you have an apple. A map is transforming that apple to apple-juice for example or a one-to-one mapping.

Take that same apple and get only the seeds out of it, that is what flatMap does, or a one to many, one apple as input, many seeds as output.

  • 2
    That's an interesting example :) – cassiomolin Sep 9 '18 at 21:23
  • For the flatMap case, do you first collect the seeds from each apple in separate bags, one bag per apple, before you pour all of the bags into a single bag? – Derek Mahar Dec 12 '18 at 16:04
  • @DerekMahar it used to be a poor into a single bag before java-10, meaning flatmap was not really lazy, but since java-10 it is lazy – Eugene Dec 12 '18 at 16:09

map() and flatMap()

  1. map()

Just takes a Function a lambda param where T is element and R the return element built using T. At the end we'll have a Stream with objects of Type R. A simple example can be:

  .map(myInt -> "preFix_"+myInt)

It simply takes elements 1 to 5 of Type Integer, uses each element to build a new element from type String with value "prefix_"+integer_value and prints it out.

  1. flatMap()

It is useful to know that flapMap() takes a function F<T, R> where

  • T is a type from which a Stream can be built from/with. It can be a List (T.stream()), an array (Arrays.stream(someArray)), etc.. anything that from which a Stream can be with/or form. in the example below each dev has many languages, so dev. Languages is a List and will use a lambda parameter.

  • R is the resulting Stream that will be built using T. Knowing that we have many instances of T, we will naturally have many Streams from R. All these Streams from Type R will now be combined into one single 'flat' Stream from Type R.


The examples of Bachiri Taoufiq see its answer here are simple and easy to understanding. Just for clarity, let just say we have a team of developers:

dev_team = {dev_1,dev_2,dev_3}

, with each developer knowing many languages:

dev_1 = {lang_a,lang_b,lang_c},
dev_2 = {lang_d},
dev_2 = {lang_e,lang_f}

Applying Stream.map() on dev_team to get the languages of each dev:

dev_team.map(dev -> dev.getLanguages())

will give you this structure:


which is basically a List<List<Languages>> /Object[Languages[]]. Not so very pretty, nor Java8-like!!

with Stream.flatMap() you can 'flatten' things out as it takes the above structure
and turns it into {lang_a, lang_b, lang_c, lang_d, lang_e, lang_f}, which can basically used as List<Languages>/Language[]/ect...

so the end your code would make more sense like this:

   .stream()    /* {dev_1,dev_2,dev_3} */
   .map(dev -> dev.getLanguages()) /* {{lang_a,...,lang_c},{lang_d}{lang_e,lang_f}}} */
   .flatMap(languages ->  languages.stream()) /* {lang_a,...,lang_d, lang_e, lang_f} */

or simply:

       .stream()    /* {dev_1,dev_2,dev_3} */
       .flatMap(dev -> dev.getLanguages().stream()) /* {lang_a,...,lang_d, lang_e, lang_f} */

When to use map() and use flatMap():

  • Use map() when each element of type T from your stream is supposed to be mapped/transformed to a single element of type R. The result is a mapping of type (1 start element -> 1 end element) and new stream of elements of type R is returned.

  • Use flatMap() when each element of type T from your stream is supposed to mapped/transformed to a Collections of elements of type R. The result is a mapping of type (1 start element -> n end elements). These Collections are then merged (or flattened) to a new stream of elements of type R. This is useful for example to represent nested loops.

Pre Java 8:

List<Foo> myFoos = new ArrayList<Foo>();
    for(Foo foo: myFoos){
        for(Bar bar:  foo.getMyBars()){

Post Java 8

    .flat(foo -> foo.getMyBars().stream())
    .forEach(bar -> System.out.println(bar.getMyName()));

Also good analogy can be with C# if you familiar with. Basically C# Select similar to java map and C# SelectMany java flatMap. Same applies to Kotlin for collections.


This is very confusing for beginners. The basic difference is map emits one item for each entry in the list and flatMap is basically a map + flatten operation. To be more clear, use flatMap when you require more than one value, eg when you are expecting a loop to return arrays, flatMap will be really helpful in this case.

I have written a blog about this, you can check it out here.


Simple answer.

The map operation can produce a Stream of Stream.EX Stream<Stream<Integer>>

flatMap operation will only produce Stream of something. EX Stream<Integer>


Stream operations flatMap and map accept a function as input.

flatMap expects the function to return a new stream for each element of the stream and returns a stream which combines all the elements of the streams returned by the function for each element. In other words, with flatMap, for each element from the source, multiple elements will be created by the function. http://www.zoftino.com/java-stream-examples#flatmap-operation

map expects the function to return a transformed value and returns a new stream containing the transformed elements. In other words, with map, for each element from the source, one transformed element will be created by the function. http://www.zoftino.com/java-stream-examples#map-operation


flatMap() also takes advantage of partial lazy evaluation of streams. It will read the fist stream and only when required, will go to the next stream. The behaviour is explained in detail here: Is flatMap guaranteed to be lazy?


map() in Java 8

a stream consisting of the results of applying the given function to the elements of this stream. Map takes an input which describes how the value needs to be transformed into. Suppose we want to get the age of the Student whose name is Saurabh, till now we have only retrieved the complete object from the stream but how do we do this ? We can use map() to transform the Student Stream into the age stream as below.

int age = students.stream()
    .filter(student -> SAURABH.equals(student.getName()))
System.out.printf("*** Age of %s is %d\n",SAURABH, age);

Now lets try to get all the names of the students with the help of collect()

Set<String> names = students.stream()
       .map(Student::getName) // this will convert the Student Stream into String Stream by 
        // applying the getName()
System.out.printf("*** All the names from the list is %s\n",names);

map() vs flatMap()

Suppose we want to get all the courses available in students list then we can write the code as below:

Set<String> courses = students.stream()

**Here we will get a compilation error as below

Type mismatch: cannot convert from Set to Set To resolve this issue we use flatMap()**

flatMap() in Java 8

It returns a stream consisting of the results of replacing each element of this stream with the contents of a mapped stream produced by applying the provided mapping function to each element. flatMap will transform the stream of stream into simple stream. In below example we are using the flatMap to convert the Array of Stream into the String stream.

Set<String> courses = students.stream()

For more information you can refer to below links :



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