I came across PECS (short for Producer extends and Consumer super) while reading up on generics.

Can someone explain to me how to use PECS to resolve confusion between extends and super?

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    A very good explanation with an example @ youtube.com/watch?v=34oiEq9nD0M&feature=youtu.be&t=1630 which explains super part but, gives an idea of another. – lupchiazoem Jan 20 '19 at 6:22

13 Answers 13


tl;dr: "PECS" is from the collection's point of view. If you are only pulling items from a generic collection, it is a producer and you should use extends; if you are only stuffing items in, it is a consumer and you should use super. If you do both with the same collection, you shouldn't use either extends or super.

Suppose you have a method that takes as its parameter a collection of things, but you want it to be more flexible than just accepting a Collection<Thing>.

Case 1: You want to go through the collection and do things with each item.
Then the list is a producer, so you should use a Collection<? extends Thing>.

The reasoning is that a Collection<? extends Thing> could hold any subtype of Thing, and thus each element will behave as a Thing when you perform your operation. (You actually cannot add anything to a Collection<? extends Thing>, because you cannot know at runtime which specific subtype of Thing the collection holds.)

Case 2: You want to add things to the collection.
Then the list is a consumer, so you should use a Collection<? super Thing>.

The reasoning here is that unlike Collection<? extends Thing>, Collection<? super Thing> can always hold a Thing no matter what the actual parameterized type is. Here you don't care what is already in the list as long as it will allow a Thing to be added; this is what ? super Thing guarantees.

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    I'm always trying to think about it this way: A producer is allowed to produce something more specific, hence extends, a consumer is allowed to accept something more general, hence super. – Feuermurmel May 7 '13 at 13:11
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    Another way to remember the producer/consumer distinction is to think of a method signature. If you have a method doSomethingWithList(List list), you are consuming the list and so will need covariance / extends (or an invariant List). On the other hand if your method is List doSomethingProvidingList, then you are producing the List and will need contravariance / super (or an invariant List). – Raman Jan 24 '14 at 19:20
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    @MichaelMyers: Why can't we simply use a parameterized type for both these cases? Is there any specific advantage of using wildcards here, or is it just a means of improving readability similar to, say, using references to const as method parameters in C++ to signify that the method does not modify the arguments? – Chatterjee May 24 '14 at 6:27
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    @Raman, I think you just confused it. In doSthWithList( you can have List<? super Thing> ), since you are a consumer, you can use super (remember, CS). However, it's List<? extends Thing> getList() since you are allowed to return something more specific when producing (PE). – masterxilo May 27 '14 at 19:08
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    @AZ_ I share your sentiment. If a method do get() from the list, the method would be considered a Consumer<T>, and the list is considered a provider; but the rule of PECS is “from the list’s point of view”, thus ‘extends’ is called for. It should be GEPS: get extends; put super. – Treefish Zhang May 4 '19 at 13:14

The principles behind this in computer science is called

  • Covariance: ? extends MyClass,
  • Contravariance: ? super MyClass and
  • Invariance/non-variance: MyClass

The picture below should explain the concept. Picture courtesy: Andrey Tyukin

Covariance vs Contravariance

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    Hey everyone. I'm Andrey Tyukin, I just wanted to confirm that anoopelias & DaoWen contacted me and obtained my permission to use the sketch, it's licensed under (CC)-BY-SA. Thx @ Anoop for giving it a second life^^ @Brian Agnew: (on "few votes"): That's because it's a sketch for Scala, it uses Scala syntax and assumes declaration-site variance, which is quite different to Java's weird call-site variance... Maybe I should write a more detailed answer that clearly shows how this sketch applies to Java... – Andrey Tyukin Jun 15 '14 at 23:11
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    This is one of the simplest and clearest explanations for Covariance and Contravariance that I have ever found! – cs4r May 1 '17 at 12:35
  • @Andrey Tyukin Hi, I also want to use this image. How can I contact you? – slouc Jun 2 '17 at 8:06
  • If you have any questions about this illustration, we can discuss them in the chatroom: chat.stackoverflow.com/rooms/145734/… – Andrey Tyukin Jun 2 '17 at 17:16
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PECS (Producer extends and Consumer super)

mnemonic → Get and Put principle.

This principle states that:

  • Use an extends wildcard when you only get values out of a structure.
  • Use a super wildcard when you only put values into a structure.
  • And don’t use a wildcard when you both get and put.

Example in Java:

class Super {

    Object testCoVariance(){ return null;} //Covariance of return types in the subtype.
    void testContraVariance(Object parameter){} // Contravariance of method arguments in the subtype.

class Sub extends Super {

    String testCoVariance(){ return null;} //compiles successfully i.e. return type is don't care(String is subtype of Object) 
    void testContraVariance(String parameter){} //doesn't support even though String is subtype of Object


Liskov substitution principle: if S is a subtype of T, then objects of type T may be replaced with objects of type S.

Within the type system of a programming language, a typing rule

  • covariant if it preserves the ordering of types (≤), which orders types from more specific to more generic;
  • contravariant if it reverses this ordering;
  • invariant or nonvariant if neither of these applies.

Covariance and contravariance

  • Read-only data types (sources) can be covariant;
  • write-only data types (sinks) can be contravariant.
  • Mutable data types which act as both sources and sinks should be invariant.

To illustrate this general phenomenon, consider the array type. For the type Animal we can make the type Animal[]

  • covariant: a Cat[] is an Animal[];
  • contravariant: an Animal[] is a Cat[];
  • invariant: an Animal[] is not a Cat[] and a Cat[] is not an Animal[].

Java Examples:

Object name= new String("prem"); //works
List<Number> numbers = new ArrayList<Integer>();//gets compile time error

Integer[] myInts = {1,2,3,4};
Number[] myNumber = myInts;
myNumber[0] = 3.14; //attempt of heap pollution i.e. at runtime gets java.lang.ArrayStoreException: java.lang.Double(we can fool compiler but not run-time)

List<String> list=new ArrayList<>();
List<Object> listObject=list; //Type mismatch: cannot convert from List<String> to List<Object> at Compiletime  

more examples

bounded(i.e. heading toward somewhere) wildcard : There are 3 different flavours of wildcards:

  • In-variance/Non-variance: ? or ? extends Object - Unbounded Wildcard. It stands for the family of all types. Use when you both get and put.
  • Co-variance: ? extends T (the family of all types that are subtypes of T) - a wildcard with an upper bound. T is the upper-most class in the inheritance hierarchy. Use an extends wildcard when you only Get values out of a structure.
  • Contra-variance: ? super T ( the family of all types that are supertypes of T) - a wildcard with a lower bound. T is the lower-most class in the inheritance hierarchy. Use a super wildcard when you only Put values into a structure.

Note: wildcard ? means zero or one time, represents an unknown type. The wildcard can be used as the type of a parameter, never used as a type argument for a generic method invocation, a generic class instance creation.(i.e. when used wildcard that reference not used in elsewhere in program like we use T)

enter image description here

class Shape { void draw() {}}

class Circle extends Shape {void draw() {}}

class Square extends Shape {void draw() {}}

class Rectangle extends Shape {void draw() {}}

public class Test {
   * Example for an upper bound wildcard (Get values i.e Producer `extends`)
   * */  

    public void testCoVariance(List<? extends Shape> list) {
        list.add(new Shape()); // Error:  is not applicable for the arguments (Shape) i.e. inheritance is not supporting
        list.add(new Circle()); // Error:  is not applicable for the arguments (Circle) i.e. inheritance is not supporting
        list.add(new Square()); // Error:  is not applicable for the arguments (Square) i.e. inheritance is not supporting
        list.add(new Rectangle()); // Error:  is not applicable for the arguments (Rectangle) i.e. inheritance is not supporting
        Shape shape= list.get(0);//compiles so list act as produces only

        /*You can't add a Shape,Circle,Square,Rectangle to a List<? extends Shape> 
         * You can get an object and know that it will be an Shape
* Example for  a lower bound wildcard (Put values i.e Consumer`super`)
* */
    public void testContraVariance(List<? super Shape> list) {
        list.add(new Shape());//compiles i.e. inheritance is supporting
        list.add(new Circle());//compiles i.e. inheritance is  supporting
        list.add(new Square());//compiles i.e. inheritance is supporting
        list.add(new Rectangle());//compiles i.e. inheritance is supporting
        Shape shape= list.get(0); // Error: Type mismatch, so list acts only as consumer
        Object object= list.get(0); // gets an object, but we don't know what kind of Object it is.

        /*You can add a Shape,Circle,Square,Rectangle to a List<? super Shape> 
        * You can't get an Shape(but can get Object) and don't know what kind of Shape it is.

generics and examples

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  • Hey, I just wanted to know what you meant with the last sentense: "If you think my analogy is wrong please update". Do you mean if it is ethically wrong (which is subjective) or if it is wrong in the context of programming (which is objective: no, it's not wrong)? I would like to replace it with a more neutral example which is universally acceptable independent of cultural norms and ethical believes; If that is OK with you. – Neuron Apr 29 '18 at 6:12
  • at last I could get it. Nice explanation. – Oleg Kuts Apr 12 '19 at 12:36
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    @Premraj, In-variance/Non-variance: ? or ? extends Object - Unbounded Wildcard. It stands for the family of all types. Use when you both get and put., I cannot add element to List<?> or List<? extends Object>, so I don't understand why it can be Use when you both get and put. – LiuWenbin_NO. May 17 '19 at 4:05
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    @LiuWenbin_NO. - That part of the answer is misleading. ? - the "unbounded wildcard" - corresponds with the exact opposite of invariance. Please refer to the following documentation: docs.oracle.com/javase/tutorial/java/generics/… which states: In the case where the code needs to access the variable as both an "in" and an "out" variable, do not use a wildcard. (They are using "in" and "out" as synonymous with "get" and "put"). With the exception of null you can't add to a Collection parameterized with ?. – mouselabs Apr 16 at 18:39
public class Test {

    public class A {}

    public class B extends A {}

    public class C extends B {}

    public void testCoVariance(List<? extends B> myBlist) {
        B b = new B();
        C c = new C();
        myBlist.add(b); // does not compile
        myBlist.add(c); // does not compile
        A a = myBlist.get(0); 

    public void testContraVariance(List<? super B> myBlist) {
        B b = new B();
        C c = new C();
        A a = myBlist.get(0); // does not compile
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  • So "? extends B" should be interpreted as "? B extends". It's something that B extends so that would include all the super classes of B up to Object, excluding B itself. Thanks for the code! – Saurabh Patil May 30 '16 at 3:47
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    @SaurabhPatil No, ? extends B means B and anything extending B. – asgs Sep 28 '16 at 6:16

As I explain in my answer to another question, PECS is a mnemonic device created by Josh Bloch to help remember Producer extends, Consumer super.

This means that when a parameterized type being passed to a method will produce instances of T (they will be retrieved from it in some way), ? extends T should be used, since any instance of a subclass of T is also a T.

When a parameterized type being passed to a method will consume instances of T (they will be passed to it to do something), ? super T should be used because an instance of T can legally be passed to any method that accepts some supertype of T. A Comparator<Number> could be used on a Collection<Integer>, for example. ? extends T would not work, because a Comparator<Integer> could not operate on a Collection<Number>.

Note that generally you should only be using ? extends T and ? super T for the parameters of some method. Methods should just use T as the type parameter on a generic return type.

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    Does this principle only hold for Collections? It makes sense when one tries to correlate it with a list. If you think about the signature of sort(List<T>,Comparator<? super T>) ---> here the Comparator uses super so it means it is a consumer in PECS context. When you look at the implementation for instance like : public int compare(Person a, Person b) { return a.age < b.age ? -1 : a.age == b.age ? 0 : 1; } I feel like Person does not consume anything but produces age. That makes me confused. Is there a flaw in my reasoning or PECS only holds for Collections? – Fatih Arslan Feb 7 '19 at 14:26

In a nutshell, three easy rules to remember PECS:

  1. Use the <? extends T> wildcard if you need to retrieve object of type T from a collection.
  2. Use the <? super T> wildcard if you need to put objects of type T in a collection.
  3. If you need to satisfy both things, well, don’t use any wildcard. As simple as that.
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let's assume this hierarchy:

class Creature{}// X
class Animal extends Creature{}// Y
class Fish extends Animal{}// Z
class Shark extends Fish{}// A
class HammerSkark extends Shark{}// B
class DeadHammerShark extends HammerSkark{}// C

Let's clarify PE - Producer Extends:

List<? extends Shark> sharks = new ArrayList<>();

Why you cannot add objects that extend "Shark" in this list? like:

sharks.add(new HammerShark());//will result in compilation error

Since you have a list that can be of type A, B or C at runtime, you cannot add any object of type A, B or C in it because you can end up with a combination that is not allowed in java.
In practice, the compiler can indeed see at compiletime that you add a B:

sharks.add(new HammerShark());

...but it has no way to tell if at runtime, your B will be a subtype or supertype of the list type. At runtime the list type can be any of the types A, B, C. So you cannot end up adding HammerSkark (super type) in a list of DeadHammerShark for example.

*You will say: "OK, but why can't I add HammerSkark in it since it is the smallest type?". Answer: It is the smallest you know. But HammerSkark can be extended too by somebody else and you end up in the same scenario.

Let's clarify CS - Consumer Super:

In the same hierarchy we can try this:

List<? super Shark> sharks = new ArrayList<>();

What and why you can add to this list?

sharks.add(new Shark());
sharks.add(new DeadHammerShark());
sharks.add(new HammerSkark());

You can add the above types of objects because anything below shark(A,B,C) will always be subtypes of anything above shark (X,Y,Z). Easy to understand.

You cannot add types above Shark, because at runtime the type of added object can be higher in hierarchy than the declared type of the list(X,Y,Z). This is not allowed.

But why you cannot read from this list? (I mean you can get an element out of it, but you cannot assign it to anything other than Object o):

Object o;
o = sharks.get(2);// only assignment that works

Animal s;
s = sharks.get(2);//doen't work

At runtime, the type of list can be any type above A: X, Y, Z, ... The compiler can compile your assignment statement (which seems correct) but, at runtime the type of s (Animal) can be lower in hierarchy than the declared type of the list(which could be Creature, or higher). This is not allowed.

To sum up

We use <? super T> to add objects of types equal or below T to the List. We cannot read from it.
We use <? extends T> to read objects of types equal or below T from list. We cannot add element to it.

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(adding an answer because never enough examples with Generics wildcards)

       // Source 
       List<Integer> intList = Arrays.asList(1,2,3);
       List<Double> doubleList = Arrays.asList(2.78,3.14);
       List<Number> numList = Arrays.asList(1,2,2.78,3.14,5);

       // Destination
       List<Integer> intList2 = new ArrayList<>();
       List<Double> doublesList2 = new ArrayList<>();
       List<Number> numList2 = new ArrayList<>();

        // Works
        copyElements1(intList,intList2);         // from int to int
        copyElements1(doubleList,doublesList2);  // from double to double

     static <T> void copyElements1(Collection<T> src, Collection<T> dest) {
        for(T n : src){

     // Let's try to copy intList to its supertype
     copyElements1(intList,numList2); // error, method signature just says "T"
                                      // and here the compiler is given 
                                      // two types: Integer and Number, 
                                      // so which one shall it be?

     // PECS to the rescue!
     copyElements2(intList,numList2);  // possible

    // copy Integer (? extends T) to its supertype (Number is super of Integer)
    private static <T> void copyElements2(Collection<? extends T> src, 
                                          Collection<? super T> dest) {
        for(T n : src){
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This is the clearest, simplest way for me think of extends vs. super:

  • extends is for reading

  • super is for writing

I find "PECS" to be a non-obvious way to think of things regarding who is the "producer" and who is the "consumer". "PECS" is defined from the perspective of the data collection itself – the collection "consumes" if objects are being written to it (it is consuming objects from calling code), and it "produces" if objects are being read from it (it is producing objects to some calling code). This is counter to how everything else is named though. Standard Java APIs are named from the perspective of the calling code, not the collection itself. For example, a collection-centric view of java.util.List should have a method named "receive()" instead of "add()" – after all, the calling code adds the element, but the list itself receives the element.

I think it's more intuitive, natural and consistent to think of things from the perspective of the code that interacts with the collection – does the code "read from" or "write to" the collection? Following that, any code writing to the collection would be the "producer", and any code reading from the collection would be the "consumer".

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  • I've run into that same mental collision and would tend to agree except that PECS doesn't specify the naming of code and the type boundaries themselves are set on the Collection declarations. Moreover as far as naming is concerned you often have names for producing/consuming Collections like src and dst. So you're dealing with both code and containers at the same time and I've ended up thinking about it along those lines - "consuming code" consumes from a producing container, and "producing code" produces for a consuming container. – mouselabs Apr 17 at 7:02

The PECS "rule" just ensures that the following is legal:

  • Consumer: whatever ? is, it can legally refer to T
  • Producer: whatever ? is, it can legally be referred to by T

The typical pairing along the lines of List<? extends T> producer, List<? super T> consumer is simply ensuring that the compiler can enforce the standard "IS-A" inheritance relationship rules. If we could do so legally, it might be simpler to say <T extends ?>, <? extends T> (or better yet in Scala, as you can see above, it's [-T], [+T]. Unfortunately the best we can do is <? super T>, <? extends T>.

When I first encountered this and broke it down in my head the mechanics made sense but the code itself continued to look confusing to me - I kept thinking "it seems like the bounds shouldn't need to be inverted like that" - even though I was clear on the above - that it's simply about guaranteeing compliance with the standard rules of reference.

What helped me was looking at it using ordinary assignment as an analogy.

Consider the following (not production ready) toy code:

// copies the elements of 'producer' into 'consumer'
static <T> void copy(List<? extends T> producer, List<? super T> consumer) {
   for(T t : producer)

Illustrating this in terms of the assignment analogy, for consumer the ? wildcard (unknown type) is the reference - the "left hand side" of the assignment - and <? super T> ensures that whatever ? is, T "IS-A" ? - that T can be assigned to it, because ? is a super type (or at most the same type) as T.

For producer the concern is the same it's just inverted: producer's ? wildcard (unknown type) is the referent - the "right hand side" of the assignment - and <? extends T> ensures that whatever ? is, ? "IS-A" T - that it can be assigned to a T, because ? is a sub type (or at least the same type) as T.

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Remember this:

Consumer eat supper(super); Producer extends his parent's factory

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Using real life example (with some simplifications):

  1. Imagine a freight train with freight cars as analogy to a list.
  2. You can put a cargo in a freight car if the cargo has the same or smaller size than the freight car = <? super FreightCarSize>
  3. You can unload a cargo from a freight car if you have enough place (more than the size of the cargo) in your depot = <? extends DepotSize>
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Covariance: accept subtypes
Contravariance: accept supertypes

Covariant types are read-only, while contravariant types are write-only.

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