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I've occasionally heard that with generics, Java didn't get it right. (nearest reference, here)

Pardon my inexperience, but what would have made them better?

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I see no reason to close this; with all the crap going around about generics, having some clarification between the differences between Java and C# might help people trying to dodge the ill-informed mudslinging. –  Rob Feb 7 '09 at 0:46

13 Answers 13

up vote 98 down vote accepted


  • Type information is lost at compile time, so at execution time you can't tell what type it's "meant" to be
  • Can't be used for value types (this is a biggie - in .NET a List<byte> really is backed by a byte[] for example, and no boxing is required)
  • Syntax for calling generic methods sucks (IMO)
  • Syntax for constraints can get confusing
  • Wildcarding is generally confusing
  • Various restrictions due to the above - casting etc


  • Wildcarding allows covariance/contravariance to be specified at calling side, which is very neat in many situations
  • It's better than nothing!
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Also good: didn't break existing code when introduced. –  Paul Tomblin Feb 6 '09 at 18:22
@Paul: I think I would have actually preferred a temporary breakage but a decent API afterwards. Or take the .NET route and introduce new collection types. (.NET generics in 2.0 didn't break 1.1 apps.) –  Jon Skeet Feb 7 '09 at 11:13
With a big existing code base, I like the fact that I can start change the signature of one method to use generics without changing everybody who calls it. –  Paul Tomblin Feb 7 '09 at 15:09
But the downsides of that are huge, and permanent. There's a big short term win, and a long term loss IMO. –  Jon Skeet Feb 7 '09 at 16:32
Jon - "It's better than nothing" is subjective :) –  MetroidFan2002 Mar 9 '09 at 17:05

The biggest problem is that Java generics are a compile-time only thing, and you can subvert it at run-time. C# is praised because it does more run-time checking. There is some really good discussion in this post, and it links to other discussions.

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  1. Runtime implementation (ie not type erasure);
  2. The ability to use primitive types (this is related to (1));
  3. While the wildcarding is useful the syntax and knowing when to use it is something that stumps a lot of people. and
  4. No performance improvement (because of (1); Java generics are syntactic sugar for castingi Objects).

(1) leads to some very strange behaviour. The best example I can think of is. Assume:

public class MyClass<T> {
  T getStuff() { ... }
  List<String> getOtherStuff() { ... }

then declare two variables:

MyClass<T> m1 = ...
MyClass m2 = ...

Now call getOtherStuff():

List<String> list1 = m1.getOtherStuff(); 
List<String> list2 = m2.getOtherStuff(); 

The second has its generic type argument stripped off by the compiler because it is a raw type (meaning the parameterized type isn't supplied) even though it has nothing to do with the parameterized type.

I'll also mention my favourite declaration from the JDK:

public class Enum<T extends Enum<T>>

Apart from wildcarding (which is a mixed bag) I just think the .Net generics are better.

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But the compiler will tell you, particularly with the rawtypes lint option. –  Tom Hawtin - tackline Feb 6 '09 at 14:56
Wow, that blew my mind for a few seconds. +1 –  sdellysse Feb 6 '09 at 14:59
Sorry, why is the last line a compile error? I'm messing around with it in Eclipse & can't get it to fail there - if I add enough stuff for the rest of it to compile. –  oconnor0 Feb 4 '10 at 21:44
public class Redundancy<R extends Redundancy<R>> ;) –  java.is.for.desktop Aug 8 '10 at 1:00
@oconnor0 It's not a compilation failure, but a compiler warning, for no apparent reason : The expression of type List needs unchecked conversion to conform to List<String> –  artbristol Nov 5 '12 at 11:16

The main problem is that Java doesn't actually have generics at runtime. It's a compile time feature.

When you create a generic class in Java they use a method called "Type Erasure" to actually remove all of the generic types from the class and essentially replace them with Object. The mile high version of generics is that the compiler simply inserts casts to the specified generic type whenever it appears in the method body.

This has a lot of downsides. One of the biggest, IMHO, is that you can't use reflection to inspect a generic type. Types are not actually generic in the byte code and hence can't be inspected as generics.

Great overview of the differences here: http://www.jprl.com/Blog/archive/development/2007/Aug-31.html

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I am not sure why you were down-voted. From what I understand you are right, and that link is very informative. Up-voted. –  Jason Jackson Feb 6 '09 at 15:06
@Jason, thanks. There was a typo in my original version, I guess I was downvoted for that. –  JaredPar Feb 6 '09 at 15:10
Err, because you can use reflection to look at a generic type, a generic method signature. You just can't use reflection to inspect the generic information associated with a parametrized instance. For example, if I have a class with a method foo(List<String>), I can reflectively find "String" –  oxbow_lakes Feb 6 '09 at 16:35
There are lots of articles that say type erasure makes finding the actual type parameters impossible. Lets say: Object x = new X[Y](); can you show how, given x, to find the type Y? –  user48956 Dec 6 '13 at 21:37

Ignoring the whole type erasure mess, generics as specified just don't work.

This compiles:

List<Integer> x = Collections.emptyList();

But this is a syntax error:


Where foo is defined as:

void foo(List<Integer> x) { /* method body not important */ }

So whether an expression type checks depends on whether it is being assigned to a local variable or an actual parameter of a method call. How crazy is that?

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The inconsistent inference by javac is crap. –  mP. Nov 17 '09 at 0:27
I would assume that the reason that the latter form is rejected is because there might be more than one version of "foo" due to method overloading. –  Jason Creighton Oct 28 '10 at 22:25

I'm going to throw out a really controversial opinion. Generics complicate the language and complicate the code. For example, let's say that I have a map that maps a string to a list of strings. In the old days, I could declare this simply as

Map someMap;

Now, I have to declare it as

Map<String, List<String>> someMap;

And every time I pass it into some method, I have to repeat that big long declaration all over again. In my opinion, all that extra typing distracts the developer and takes him out of "the zone". Also, when code is filled with lots of cruft, sometimes it's hard to come back to it later and quickly sift through all the cruft to find the important logic.

Java already has a bad reputation for being one of the most verbose languages in common use, and generics just add to that problem.

And what do you really buy for all that extra verbosity? How many times have you really had problems where someone put an Integer into a collection that's supposed to hold Strings, or where someone tried to pull a String out of a collection of Integers? In my 10 years of experience working at building commercial Java applications, this has just never been a big source of errors. So, I'm not really sure what you're getting for the extra verbosity. It really just strikes me as extra bureaucratic baggage.

Now I'm going to get really controversial. What I see as the biggest problem with collections in Java 1.4 is the necessity to typecast everywhere. I view those typecasts as extra, verbose cruft that have many of the same problems as generics. So, for example, I can't just do

List someList = someMap.get("some key");

I have to do

List someList = (List) someMap.get("some key");

The reason, of course, is that get() returns an Object which is a supertype of List. So the assignment can't be made without a typecast. Again, think about how much that rule really buys you. From my experience, not much.

I think Java would have been way better off if 1) it had not added generics but 2) instead had allowed implicit casting from a supertype to a subtype. Let incorrect casts be caught at runtime. Then I could have had the simplicity of defining

Map someMap;

and later doing

List someList = someMap.get("some key");

all the cruft would be gone, and I really don't think I'd be introducing a big new source of bugs into my code.

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Sorry, I disagree with just about everything you said. But I'm not going to vote it down because you argue it well. –  Paul Tomblin Feb 7 '09 at 1:44
Of course, there are plenty of examples of large, successful systems built in languages like Python and Ruby that do exactly what I suggested in my answer. –  Clint Miller Feb 7 '09 at 15:14
I think my whole objection to this type of idea is not that it's a bad idea per se, but rather that as modern languages such as Python and Ruby make life easier and easier for developers, developers in turn get intellectually complacent and eventually have a lower comprehension of their own code. –  Dan Tao Jan 29 '10 at 18:10
"And what do you really buy for all that extra verbosity? ..." It tells the poor maintenance programmer what's supposed to be in those collections. I have found this to be an issue working with commercial Java applications. –  richj Feb 13 '10 at 20:54
"How many times have you really had problems where someone put an [x] into a collection that's supposed to hold [y]s?" - Oh boy I have lost count! Also even if there is no bug it is a readability killer. And scanning many files to find out what the object is going to be (or debugging) really does pull me out of the zone. You might like Haskell - even strong typing but less cruft (because types are inferred). –  Martin Capodici yesterday

Java generics are checked for correctness at compile time and then all type information is removed (the process is called type erasure. Thus, generic List<Integer> will be reduced to its raw type, non-generic List, which can contain objects of arbitrary class.

This results in being able to insert arbitrary objects to the list at runtime, as well as it's now impossible to tell what types were used as generic parameters. The latter in turn results in

ArrayList<Integer> li = new ArrayList<Integer>();
ArrayList<Float> lf = new ArrayList<Float>();
if(li.getClass() == lf.getClass()) // evaluates to true
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The introduction of generics into Java was a difficult task because the architects were trying to balance functionality, ease of use, and backward compatibility with legacy code. Quite expectedly, compromises had to be made.

There are some who also feel that Java's implementation of generics increased the complexity of the language to an unacceptable level (see Ken Arnold's "Generics Considered Harmful"). Angelika Langer's Generics FAQs gives a pretty good idea as to how complicated things can become.

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+1 for Angelika Langer –  Graham Griffiths Aug 19 '13 at 16:07

Java doesn't enforce Generics at run time, only at compile time.

This means that you can do interesting things like adding the wrong types to generic Collections.

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The compiler will tell you that you have screwed up if you manage that. –  Tom Hawtin - tackline Feb 6 '09 at 14:51
@Tom - not necessarily. There are ways of fooling the compiler. –  Paul Tomblin Feb 6 '09 at 14:52
Do you not listen to what the compiler tells you?? (see my first comment) –  Tom Hawtin - tackline Feb 6 '09 at 15:15
@Tom, if you have an ArrayList<String> and you pass it to an old-style method (say, legacy or third party code) that takes a simple List, that method can then add anything it likes to that List. If it enforced at runtime, you'd get an exception. –  Paul Tomblin Feb 6 '09 at 19:23
static void addToList(List list) { list.add(1); } List<String> list = new ArrayList<String>(); addToList(list); That compiles, and even works at runtime. The only time you see a problem is when you remove from the list expecting a string and get an int. –  Laplie Feb 7 '09 at 0:12

I wish this was a wiki so I could add to other people... but...


  • Type Erasure (no runtime availability)
  • No support for primative types
  • Incompatability with Annotations (they were both added in 1.5 I'm still not sure why annotations don't allow generics aside from rushing the features)
  • Incompatability with Arrays. (Sometimes I really want to do somthing like Class<? extends MyObject>[], but I'm not allowed)
  • Wierd wildcard syntax and behavior
  • The fact that generic support is inconsistant across Java classes. They added it to most of the collections methods, but every once in a while, you run into an instance where its not there.
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Another side effect of them being compile-time and not run time is that you can't call the constructor of the generic type. So you can't use them to implement a generic factory...

   public class MyClass {
     public T getStuff() {
       return new T();


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Java generics are compile-time only and are compiled into non-generic code. In C#, the actual compiled MSIL is generic. This has huge implications for performance because Java still casts during runtime. See here for more.

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If you listen to Java Posse #279 - Interview with Joe Darcy and Alex Buckley, they talk about this issue. That also links to a Neal Gafter blog post titled Reified Generics for Java that says:

Many people are unsatisfied with the restrictions caused by the way generics are implemented in Java. Specifically, they are unhappy that generic type parameters are not reified: they are not available at runtime. Generics are implemented using erasure, in which generic type parameters are simply removed at runtime.

That blog post, references an older entry, Puzzling Through Erasure: answer section, that stressed the point about migration compatibility in the requirements.

The goal was to provide backwards compatibility of both source and object code, and also migration compatibility.

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