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I read an interesting Article/Thread/Discussion from here and i got following questions:

  • What are the limitations of Java/C# generics?
  • What is possible with C++ Templates that is impossible with Java/C# generics?

Edit 1 More recommended questions by Eric Lippert

  • What are some patterns that are possible with C# generics but impossible with C++ templates?
  • What's the difference between C#'s true generic types and Java's type erasure generic types?
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closed as not constructive by Bo Persson, edA-qa mort-ora-y, PaRiMaL RaJ, Peter Ritchie, Mario Sannum Apr 7 '13 at 21:17

As it currently stands, this question is not a good fit for our Q&A format. We expect answers to be supported by facts, references, or expertise, but this question will likely solicit debate, arguments, polling, or extended discussion. If you feel that this question can be improved and possibly reopened, visit the help center for guidance.If this question can be reworded to fit the rules in the help center, please edit the question.

An interesting third question that you might ask is "what are some patterns that are possible with C# generics that are impossible with C++ templates?" and a fourth question that you might ask is "what's the difference between C#'s true generic types and Java's type erasure generic types?" – Eric Lippert Apr 7 '13 at 0:40
I think it's helpful not to confuse the naming here, C# and Java don't have templates and standard C++ doesn't have generics. – svick Apr 7 '13 at 1:02
what a noob fault from me, good point – Quonux Apr 7 '13 at 1:05
possible duplicate of… – nawfal Jan 1 '14 at 13:55
Just curious why this wasn't moved to Programmers. It's definitely a valid question there. But I also think this is a valid question here. He's asking for a compare/contrast of C++ Templates vs C# Generics vs Java Generics. It's not asking for which one is better, it's asking for a fact based assessment of the differences. – Michael Brown Jun 24 '14 at 19:19
up vote 7 down vote accepted

First off, you might want to read my 2009 article on this subject.

The primary difference to my mind between C++ templates and C# generics is that C++ templates actually completely recompile the code upon construction of the template. The pros and cons of the C++ approach are many:

  • PRO: You can effectively create constraints like "the type argument T must have an addition operator"; if the code contains a couple of Ts added to each other then the template will not compile if you construct it with a type argument that doesn't permit addition.

  • CON: You can accidentally create undocumented constraints like "the type argument T must have an addition operator".

In C# you have to say what the constraints are which helps the user, but you are limited to only a small set of possible constraints: interfaces, base classes, value vs reference type and default constructor constraints, and that's all.

  • PRO: Semantic analysis can be completely different for two different constructions. If you want that, that's awesome.

  • CON: Semantic analysis can be completely different for two different constructions. If you don't want that, that's a bug waiting to happen.

In C# the semantic analysis is done once no matter how many times the type is constructed, and it is therefore required to work with any type argument that meets the constraints, not just the type arguments that are actually supplied.

  • PRO: You only generate the code for exactly the constructions you need.

  • CON: You generate the code for all the constructions you use.

Templates can cause codegen to get large. In C#, the IL for a generic type is generated once, and then at runtime the jitter does codegen for all the types your program uses. This has a small performance cost, but it is mitigated somewhat by the fact that the jitter actually only generates code once for all reference type arguments. So if you have List<object> and List<string> then the jitted code is only generated once and used for both. List<int> and List<short> by contrast jits the code twice.

  • PRO: when you use a template library, you have the source code right there.

  • CON: to use a template library you have to have the source code.

In C#, generic types are first-class types. If you stick them in a library, you can use that library anywhere without having to ship the source code.

And finally:

  • PRO: Templates permit template metaprogramming.

  • CON: Template metaprogramming is hard to understand for novices.

  • CON: The template system actually does not permit some type topologies that are extremely straightforward in a generic system.

For example, I imagine that it would be difficult to do something like this in C++:

class D<T> 
    class S { }
    D<D<T>.S> ds;

In C# generics, no problem. At runtime the type is only built once for all reference type arguments.

But in C++ templates, what happens when you have D<int>? The interior type constructs a field of type D<D<int>.S>, so we need to construct that type. But that type constructs a field of type D<D<D<int>.S>.S>... and so on to infinity.

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You might want to make clear that all your "pro" items are "advantage C++", even when the preceding paragraph talks about C#. Another thing that's worth mentioning is that C# expects to run on a framework in which all class-object instances have a single run-time type which is independent of the compile-time type of a reference to it, and which can create type descriptors at runtime. It would be possible in .net to write code that--without Reflection--would take an arbitrary string and generate an instance of a generic class with a static member that would return that string. – supercat Apr 9 '13 at 15:13
Better yet, the routine could accept a generic object that implements interface that includes a method with a generic type parameter, and could call the method with an instance of the appropriate type. The simplest way to envision things would be if the string were limited to characters A-Z, given the parameter "ERIC"the code might effectively call PassedInObject.Invoke(new Thing<E<R<I<C<Root>>>>()); There's practically no limit to the number of classes that such code could generate, but the run-time would only have to generate the ones that were actually used. – supercat Apr 9 '13 at 15:17

What are the limitations of Java/C# generics?

Java generics are limited because it is not possible to do some tricks like in C++.

To proof the claim here is an C++ example that is impossible to reproduce with templates alone in Java.

Policy based programming is a way to restrict the use of an (templated) class to other (possible) templated classes on inheritence at compile time.

What is the big deal of compile time generics vs runtime generics?

The deal is that the compiler knows everything about the possible runtime behaviour of the class/templates so it can do heavy optimizations that are (currently) impossible with an C#/Java/whatever runtime environment/compiler.

A other good side of this is that the compiler can ensure that the instatiation of a combination of the templates is valid which means that there is no possibility that runtime-errors can happen like in Java/C# when the programmer want to instatiate new objects with an invalid combination.

What is the downside of C++ generics?

The downside is that the templates can get really complicated to read and understand and debug. This is (maybe) one of the reasons why the Java developers didn't want to have such a beast in a language.

What is possible with C++ Generics that is impossible with Java/C# generics?

In C++ is is possible to use other templates as template parameters which is impossible in C#/Java and which allows elegant tricks like template-metaprogramming.

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At least the linked example for policy based desing would work with C# generics. You just need to add constraints (like where TOutputPolicy : IOutputPolicy) so the used methods are known to exist. But in general you're right that templates are much more powerful: They have turing completeness during compile time using enum/struct combinations as base data type. (you may have to increase your compilers template depth). – mbx Apr 7 '13 at 0:45
Is there actually something about C++ templates that makes them harder to understand than generics? Or is it just the way they are used in STL? – svick Apr 7 '13 at 1:03
With C++ templates you can call methods, that the TemplateParameter may not has (well, you cannot - you'll get nasty compiler errors but at least IDEs I used didn't tell me before compiling). In C# this requires an interface constraint so your template class can only use methods/properties that are defined in that interface. see msdn – mbx Apr 7 '13 at 1:10

The motivation for Java Generics was always to provide type safety, while keeping backwards compatibility. Sun implemented generics by adding type checks and then erasing the generic type as part of compilation. Code like:

// This applies to JDK 1.5, so I won't use <>.
List<Number> list = new ArrayList<Number>();
list.add(new BigDecimal("1.23456789");

is equivalent to

List list = new ArrayList();
Double temp = new Double(2.0); // boxing
if (!temp instanceof Number) throw new ClassCastException();
// Similar for -2 and the BigDecimal.

No knowledge of the type of list makes it into the runtime classes, but some of the instanceofs may be dropped by the compiler as being safe.

Since the compiler does not write the generic types into the compiled class files, and so the above list.getClass() == ArrayList.class, there can be no template specializations as in C++. List<Boolean> cannot be packed into a sequence of bits. All generic types are types, unlike templates in C++ like:

template<int length, int time, int mass>
class measurement {...}

which can be used for dimensional analysis, and to keep people from adding lengths to areas.

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According to MSDN the key differences between C# generics and C++ templates are:

  • C# generics do not provide the same amount of flexibility as C++ templates. For example, it is not possible to call arithmetic operators in a C# generic class, although it is possible to call user defined operators.
  • C# does not allow non-type template parameters, such as template C {}.
  • C# does not support explicit specialization; that is, a custom implementation of a template for a specific type.
  • C# does not support partial specialization: a custom implementation for a subset of the type arguments.
  • C# does not allow the type parameter to be used as the base class for the generic type.
  • C# does not allow type parameters to have default types.
  • In C#, a generic type parameter cannot itself be a generic, although constructed types can be used as generics. C++ does allow template parameters.

Yet there are cases where you can work around some of these issues by using extension methods.

Possible with C++ generics, neither with C# generics nor Java generics: true template metaprogramming (turing complete at compile time).

#include <iostream>
template<unsigned U>
struct Fac{ enum { value = U * Fac<U-1>::value};};
struct Fac<0>{ enum { value = 1};};
template<unsigned U>
struct Fib{ enum {value = (Fib<U-1>::value + Fib<U-2>::value)};};
struct Fib<0>{ enum {value = 0};};
struct Fib<1>{ enum {value = 1};};
template<unsigned U>
void show(){
    std::cout << "Fib(" << U << ")=" << Fib<U>::value << "\t" << "Fac(" << U << ")=" << Fac<U>::value << std::endl;
void show<0>(){}

int main(int argc, char** argv){


The C++ standard hadn't had constraints on type parameters while C# and Java have. Boost has something like that (Boost Concept Check Library). But since C++11 you now can use <type_traits> to get something similar.

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