34

I know that Java's type system is unsound (it fails to type check constructs that are semantically legal) and undecidable (it fails to type check some construct).

For instance, if you copy/paste the following snippet in a class and compile it, the compiler will crash with a StackOverflowException (how apt). This is undecidability.

static class ListX<T> {}
static class C<P> extends ListX<ListX<? super C<C<P>>>> {}
ListX<? super C<Byte>> crash = new C<Byte>();

Java uses wildcards with type bounds, which are a form of use-site variance. C# on the other hand, uses declaration site variance annotation (with the in and out keywords). It is known that declaration-site variance is weaker than use-site variance (use-site variance can express everything declaration-site variance can, and more -- on the down side, it's much more verbose).

So my question is: Is C# type system sound and decidable? If not, why?

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    Actually, a bit more search turned out this: research.microsoft.com/en-us/um/people/akenn/generics/… which states that C# type system is undecidable (as well as that of Java and Scala) and goes on to give some insight on why. – Norswap May 29 '14 at 17:34
  • Not sure if this quite qualifies as the type system as being unsound, but you can cause the C# compiler to emit arbitrarily large assemblies with only a few lines. See this question. – Mike Zboray May 29 '14 at 17:46
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    @mikez type checking doesn't have anything to do with code generation. Anyway, Norswap, since you found your answer you should post it, with a reference to that link (yes it is perfectly acceptable). – Bakuriu May 29 '14 at 18:54
20

Is C# type system decidable?

A type system is "decidable" if the compiler is in theory always able to decide whether the program type checks or not in finite time.

It depends on what restrictions you put on the type system. Some of the C# type system's designers have a paper on the subject that you will likely find interesting:

https://www.microsoft.com/en-us/research/publication/on-decidability-of-nominal-subtyping-with-variance/

In practice, the C# 4.0 and 5.0 compilers do not implement the infinitary type detector described in the paper; rather, they go into unbounded recursion and crash.

I considered adding such code to Roslyn but do not recall a this time whether it got in or not; I'll check the source code when I'm back in my office next week.

A more gentle introduction to the problem can be found in my article here:

http://blogs.msdn.com/b/ericlippert/archive/2008/05/07/covariance-and-contravariance-part-twelve-to-infinity-but-not-beyond.aspx

UPDATE: The question asked by Andrew in the original paper -- is convertibility checking in a world with nominal subtyping and contravariant generics decidable in general? -- has recently been answered. It is not. See https://arxiv.org/abs/1605.05274. I am pleased to note that the author noticed one of my posts on the subject -- not this one -- and was inspired to attack the problem.

UPDATE: A commenter points out that I answered the question about decidability but not soundness.

Is the C# type system sound?

A type system is "sound" if we are guaranteed that a program which type checks at compile time has no type errors at runtime.

No, the C# type system is not sound, thanks to array covariance, my least favourite feature:

Giraffe[] giraffes = new[] { new Giraffe() };
Animal[] animals = giraffes; // This is legal!
animals[0] = new Tiger(); // crashes at runtime with a type error

The idea here is that most methods that takes arrays only read the array, they do not write it, and it is safe to read an animal out of an array of giraffes. Java allows this, and so the CLR allows it because the CLR designers wanted to be able to implement variations on Java. C# allows it because the CLR allows it. The consequence is that every time you write anything into an array of a base class, the runtime must do a check to verify that the array is not an array of an incompatible derived class. The common case gets slower so that the rare error case can get an exception.

That brings up a good point though: C# is at least well-defined as to the consequences of a type error. Type errors at runtime produce sane behaviour in the form of exceptions. It's not like C or C++ where the compiler can and will blithely generate code that does arbitrarily crazy things.

There are a few other ways in which the C# type system is unsound by design.

  • The C# type system does not (yet!) track nullity of reference types. If you consider getting a null reference exception to be a kind of runtime type error, then C# is very unsound in that it does almost nothing to prevent this kind of error. There will likely be work done to address this in C# 8, but it will not be sound.

  • Many cast expressions allow the user to override the type system and declare "I know this expression will be of a more specific type at runtime, and if I'm wrong, throw an exception". (Some casts mean the opposite: "I know this expression is of type X, please generate code to convert it to an equivalent value of type Y". Those are generally safe.) Since this is a place where the developer is specifically saying that they know better than the type system, one can hardly blame the type system for the resulting crash.

There are also a handful of features that generate cast-like behaviour even though there is no cast in the code. For example, if you have a list of animals you can say

foreach(Giraffe g in animals)

and if there is a tiger in there, your program will crash. As the specification notes, the compiler simply inserts a cast on your behalf. (If you want to loop over all the giraffes and ignore the tigers, that's foreach(Giraffe g in animals.OfType<Giraffe>()).)

  • The unsafe subset of C# makes all bets off; you can break the rules of the runtime arbitrarily with it. Turning off a safety system turns a safety system off, so it should not be surprising that C# is not sound when you turn off soundness checking.
  • As far as I can tell this answers the 'decidability' part but not the 'soundness' part. If I understand correctly, the C# type system is unsound because of nulls? – Yawar May 9 '18 at 3:48
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    @yawar C# is not null safe yes. Also array covariance is unsound. But it is sound in the sense that you are guaranteed that you get an exception when you hit a type error at runtime. – Eric Lippert May 9 '18 at 4:22
4

It's not particularly hard to create problems that the C# complier cannot solve in a reasonable amount of time. Some of the problems it is posed with (often related to generics/type inference) are NP-hard problems. Eric Lippert describes one such example here:

class MainClass
{
    class T{}
    class F{}
    delegate void DT(T t);
    delegate void DF(F f);
    static void M(DT dt)
    {
        System.Console.WriteLine("true");
        dt(new T());
    }
    static void M(DF df)
    {
        System.Console.WriteLine("false");
        df(new F());
    }
    static T Or(T a1, T a2, T a3){return new T();}
    static T Or(T a1, T a2, F a3){return new T();}
    static T Or(T a1, F a2, T a3){return new T();}
    static T Or(T a1, F a2, F a3){return new T();}
    static T Or(F a1, T a2, T a3){return new T();}
    static T Or(F a1, T a2, F a3){return new T();}
    static T Or(F a1, F a2, T a3){return new T();}
    static F Or(F a1, F a2, F a3){return new F();}
    static T And(T a1, T a2){return new T();}
    static F And(T a1, F a2){return new F();}
    static F And(F a1, T a2){return new F();}
    static F And(F a1, F a2){return new F();}
    static F Not(T a){return new F();}
    static T Not(F a){return new T();}
    static void MustBeT(T t){}
    static void Main()
    {
        // Introduce enough variables and then encode any Boolean predicate:
        // eg, here we encode (!x3) & ((!x1) & ((x1 | x2 | x1) & (x2 | x3 | x2)))
        M(x1=>M(x2=>M(x3=>MustBeT(
          And(
            Not(x3), 
            And(
              Not(x1), 
              And(
                Or(x1, x2, x1), 
                Or(x2, x3, x2))))))));
    }
}
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    I don't see how your answer is related to the question. The OP asked about decidibility and soundness, not complexity of type checking in C#. – Bakuriu May 29 '14 at 18:52
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    @Bakuriu The code in question won't actually finish when given a non-trivial amount of input; it'll just sit there spinning for some technically finite, but extremely long period of time. For practical purposes, you can assert that it won't finish at all. – Servy May 29 '14 at 18:53
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    And who cares for practical purposes? The OP didn't ask "is C#'s type-system sound and decidable in a 10-minutes coffee break time?". – Bakuriu May 29 '14 at 19:01
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    @Bakuriu Who cares for theoretical purposes? I'd expect just about everyone to care for practical purposes. If the program I want to compile is going to take 20 years to complete then as far as I care, it isn't sound. The fact that if I wait long enough it must, in theory, complete isn't really relevant to me. – Servy Jun 2 '14 at 14:00
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    @Bakuriu That is an appropriate comment, which is in start contrast to your previous comment that nobody would care. Most everyone cares whether the compiler is practical. Very few people are interested in whether it will theoretically complete at some point in the distant future. Since that's the information that's useful for the vast majority of readers, I considered it worthy of an answer. If you disagree, that's your right. – Servy Jun 2 '14 at 14:23

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