# Tag Info

51

It's certainly related to polymorphism. I wouldn't say they're just "another word" for polymorphism though - they're about very specific situations, where you can treat one type as if it were another type in a certain context. For instance, with normal polymorphism you can treat any reference to a Banana as a reference to a Fruit - but that doesn't mean you ...

50

Q[A <: B] means that class Q can take any class A that is a subclass of B. Q[+B] means that Q can take any class, but if A is a subclass of B, then Q[A] is considered to be a subclass of Q[B]. Q[+A <: B] means that class Q can only take subclasses of B as well as propagating the subclass relationship. The first is useful when you want to do ...

33

Thanks for all the shout-outs, guys. Jon and Rasmus's answers are fine, I would just add a quick technical note. When speaking casually and informally, yes, people use "covariance" and "contravariance" to refer to a specific kind of polymorphism. That is, the kind of polymorphism where you treat a sequence of spiders as though it were a sequence of ...

22

The problem is that GenericTraversableTemplate is used twice: once for mutable collections (where its type parameter should be invariant), and once for immutable collections (where covariance is invariably king). GenericTraversableTemplate's typechecks assuming either covariance or invariance for the A type parameter. However, when we inherit it in a ...

19

In the case of List, it B <: A does indeed imply List[B] <: List[A], because List's type parameter is covariant. Making a type parameter covariant means that it can only show up in covariant positions in the definition of List, i.e. it can only show up as the return type of a method, not as the type of a parameter. The "tour of Scala" contains a ...

18

"out" means, roughly speaking, "only appears in output positions". "in" means, roughly speaking, "only appears in input positions". The real story is a bit more complicated than that, but the keywords were chosen because most of the time this is the case. Consider a method of an interface or the method represented by a delegate: delegate void ...

16

I am just going to answer the differences between declaration-site and use-site variance, since, while C# and Java generics differ in many other ways, those differences are mostly orthogonal to variance. First off, if I remember correctly use-site variance is strictly more powerful than declaration-site variance (although at the cost of concision), or at ...

15

You can think about co- and contravariance as being an advanced form of polymorphism. Not only can you use a child-class as if it was its parent-class, with co- and contravariance, the polymorphism extends to classes that relates to the polymorphic classes. Imagine two classes: public class Pet { /*...*/ } public class Cat:Pet { /*...*/ } Polymorphism is ...

15

On the pure issue of contra-variance Adding contra-variance to a language opens a whole lot of potential problems or unclean solutions and offers very little advantage as it can be easily simulated without language support: struct A {}; struct B : A {}; struct C { virtual void f( B& ); }; struct D : C { virtual void f( A& ); // this ...

15

As others have said, it is logically inconsistent for a generic type to be both covariant and contravariant. There are some excellent answers here so far, but let me add two more. First off, read my article on the subject of variance "validity": http://blogs.msdn.com/b/ericlippert/archive/2009/12/03/exact-rules-for-variance-validity.aspx By definition, if ...

13

It's complicated. The call to b.Clone clearly must invoke BC. There is no interface involved here at all! The method to call is determined entirely by compile-time analysis. Therefore it must return an instance of Base. This one is not very interesting. The call to cb.Clone by contrast is extremely interesting. There are two things we have to establish ...

12

Most people seem to prefer declaration-site variance, because it makes it easier for users of the library (while making it a bit harder for the library developer, although I would argue that the library developer has to think about variance regardless of where the variance is actually written.) But keep in mind, that neither Java nor C# are examples of good ...

12

If a type is naturally covariant or contravariant you should declare it so. Your users will thank you for it. The use-site variance is indeed mostly there because of Java. More precisely, a type such as Array[T <: Number] is treated as a shorthand for an existential type: ArrayBuffer[T] forSome { type T <: Number } Existential types have a pretty ...

12

What you are seeing is the difference between sample variance and population variance and nothing to do with floating point precision or the accuracy of C#'s floating point implementation. You are calculating population variance. Excel and that web site are calculating sample variance. Var and VarP are distinct calculations and you do need to be careful ...

11

This part of the spec -- you are referring to section 13.1.3.1 of the C# 4 specification, which perhaps you ought to have mentioned somewhere in your question -- is unfortunate, and I apologize. Mads and I meant well, but I've never been thrilled with how this part of the spec turned out. We were attempting to come up with a more intuitive and ...

11

You are right that the last rule is the hardest one to understand but I assure you it is not ambiguous. An example or two will help. Consider this type declaration: interface I<in T, out U, V> { ... } Is this type covariantly valid? I<string, object, int> { } Let's go through our definition. To determine if it is, we examine each type ...

10

You can't do this for all Traversables, as they don't guarantee that map returns anything more specific than Traversable. See Update 2 below. import collection.generic.CanBuildFrom import collection.TraversableLike class TraversableW[CC[X] <: TraversableLike[X, CC[X]], A](value: CC[A]) { def mapmap(f: A => A)(implicit cbf: CanBuildFrom[CC[A], A, ...

10

I found this collection: Covariance and Contravariance in C#, Part One Covariance and Contravariance in C#, Part Two: Array Covariance Covariance and Contravariance in C#, Part Three: Member Group Conversion Variance Covariance and Contravariance in C#, Part Four: Real Delegate Variance Covariance and Contravariance In C#, Part Five: Higher Order ...

10

There are different possible solutions for this, depending on whether I want to fix the problem only for C, or whether I want to fix the problem for the entire typeclass. For C only, instead of implicit object FooC ... we say: implicit def CIsFoo[T <: C]: Foo[T] = new Foo[T] { override def foo(t: T) { println("it's a C!") } } To fix all of Foo, make ...

10

I've run across this problem as well. There are some great posts out there in computing the running cumulative variance such as John Cooke's Accurately computing running variance post and the post from Digital explorations, Python code for computing sample and population variances, covariance and correlation coefficient. Just could not find any that were ...

9

Now what does it mean for a type to be covariant or contravariant? Isn't variance a property of a projection-of-types and not a property of types themselves? Yes, you are spot on. Well, you are almost spot on. Variance is a property of a projection of types with respect to a given relation on types. Consider these statements: The projection which ...

8

There are two things going on here: A function and a method are not the same thing Methods are not polymorphic in their parameters' types Your tester method is a method, not a Function1. It can be lifted into a function using the underscore syntax: val f = (new FooTest[String]).tester _ // Fasel => Bla This function will be contra-variant in its ...

8

You misunderstand Int with String. It is not the Union of Int and String, it is the intersection, and for Int and String it is empty. Not the sets of values that are Int with the set of values that are strings, but the set of values that have the characteristics of Int with the characteristics of String too. There are no such values. You can use ...

7

In my thesis I describe a calculus, Scalina, that has bounds & variance annotations as part of the kind language (an earlier version is also available as a workshop paper). The relevance to this discussion is the next step that I want to take in developing this calculus: build another layer on top of that so that you can abstract over bounds (easy) and ...

7

Covariance and contravariance are mutually exclusive. Your question is like asking if set A can be both a superset of set B and a subset of set B. In order for set A to be both a subset and superset of set B, set A must be equal to set B, so then you would just ask if set A is equal to set B. In other words, asking for covariance and contravariance on the ...

7

The line: Action<CalendarEventBase> emailCancelation = _trainingService.EmailTrainingCancellation; is actually expecting covariance, not contravariance. But that logically doesn't make sense; the method expects a TrainingEvent as input - how can you pass a more general type (CalendarEventBase) to it? This isn't legal: // What if the method wants ...

6

Hypothesis testing is the wrong tool to use to asses the validity of model assumptions. If the sample size is small, you have no power to detect any variance differences, even if the variance differences are large. If you have a large sample size you have power to detect even the most trivial deviations from equal variance, so you will almost always reject ...

6

There is a GenericParameterAttributes Enumeration that you can use to determine the variance flags on a generic type. To get the generic type, use typeof but omit the type parameters. Leave in the commas to indicate the number of parameters (code from the link): Type theType = typeof(Test<,>); Type[] typeParams = theType.GetGenericArguments(); You ...

6

If you're making these types of checks in a generic method, I'd rethink your design. The method is obviously not truly generic - if it were, you wouldn't need specific type checking... Situations like this typically can be handled more cleanly by a redesign. One alternative is often to provide an overload of the appropriate type. Other design ...

6

In the latter cases, the compiler assumes that you want this to work and actually says p(Crate( (new Apple): Fruit )) which is perfectly okay. It's the same as if you manually did val f: Fruit = new Apple // totally fine p(Crate(f)) // Also totally fine This is just a small part of the immense wizardry that the compiler applies to try ...

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