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This is a followup on a thread I thought was resolved yesterday. Yesterday I was having problems with my code in the following case:

using System;
using System.Collections.Generic;
using System.Linq;
using System.Text;

namespace ConsoleApplication3
    class Program
        class Bar
            int v;

            public Bar(int v) { this.v = v; }
            public override string ToString() { return v.ToString(); }

        static void Main(string[] args)
            Foo(1, 2, 3);
            Foo(new int[] { 1, 2, 3 });
            Foo(new Bar(1), new Bar(2), new Bar(3));
            Foo(new Bar[] { new Bar(1), new Bar(2), new Bar(3) });

        static void Foo(params object[] objs)
            Console.WriteLine("New call to Foo: ");
            foreach(object o in objs)
                Console.WriteLine("Type = " + o.GetType() + ", value = "+o.ToString());

If you run this you can see a problem with the last call to Foo. The fact that the argument is a vector is "lost".

So.... anyone know how to report a C# compiler bug? Or would this be considered a reflection bug?

(What a relief: I was bummed to think I had wasted time here with a bug of my own. In fact it is a C# bug after all, and I'm vindicated! And how often do we get to see actual C# compiler bugs these days? Not common...)

share|improve this question

closed as too localized by casperOne Mar 17 '12 at 19:20

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I think that C# 5 is in beta release... – Senad Meškin Mar 14 '12 at 20:23
Could you please post the full source code of your test? – Adriano Repetti Mar 14 '12 at 20:23
There's a bug in your code, one right parenthesis too much at new Foobar(3)), isn't it? – Tim Schmelter Mar 14 '12 at 20:34
It's pretty unclear what you consider the bug, but it doesn't work any differently in earlier compiler versions. Try it. If you want just a single argument to be passed then you'll have to hit the compiler over the head with Foo(new object[] { new FooBar[] {...} }); – Hans Passant Mar 14 '12 at 20:53
This is not a C# compiler bug. – Eric Lippert Mar 14 '12 at 21:15

5 Answers 5

up vote 7 down vote accepted

I would expect these two calls to function identically- a params argument is an array in the called method. Jon Skeet's example in the previous question works because an array of int's is not covariant to an array of objects (and so is treated as new Object[] { new Int[] {1,2,3} }), but in this example an array of FooBars is covariant to an array of objects, and so your parameter is expanded into the objs argument.

Wikipedia of all things covers this exact case: Covariance and contravariance (computer science)

Sorry but I am sure that this is not a compiler bug.


You can achieve what you want thus:

Foo(new Object[] { new Bar[] { new Bar(1), new Bar(2), new Bar(3) } });

NEW EDIT (other author):

Or simply use:

Foo((Object)new Bar[] { new Bar(1), new Bar(2), new Bar(3) });
share|improve this answer
I love PL people. But in this particular case they clearly have talked themselves into a mistake! – Ken Birman Mar 14 '12 at 20:43
Sorry- I don't understand that last comment – Chris Shain Mar 14 '12 at 20:44
Clearly there should be a way to use params to figure out exactly what the argument to a method was. By adopting this definition, the C# 5.0 guys have created a case that cannot be correctly handled using params. So while you are clearly right (just read the Wikipedia page) the definition being used is clearly wrong! Anyhow, is there a way to do what I actually am trying to do? – Ken Birman Mar 14 '12 at 20:47
@KenBirman - I think this really comes down to why do you need to know exactly what it was called with? I can not think of many practical situations where this is the case. For the cases where it is needed, you can do that via the Dynamic namespace as Jon Skeet pointed out – John Mar 14 '12 at 20:49
In Isis2, people build parallel applications. Suppose someone queries a set of servers and each returns, say, URLs that match some pattern (each searching a separate corpus). Some find 2 matches, some 4. I'm unable to extract the type signature hence unable to return sensible lists of responses for the caller. In effect, I can't distinguish g.Reply("url1", "url2") from g.Reply(vector-of-urls); Of course I support the general case, not just strings. – Ken Birman Mar 14 '12 at 20:58

The C# 4.0 specification is quite explicit in how this all plays out. says that if a function with params can be applied either in normal form (ignoring the params keyword) or expanded form (using the params keyword), then normal form wins.

Assuming Foo was declared as Foo(params object[] args), then the call Foo(new Foobar[] {new Foobar(1), new Foobar(2), new Foobar(3)) }); is applicable in normal form, since Foobar[] is implicitly convertible to object[] (6.1.6 clause 5). Therefore, the normal form is used and the expanded form is ignored.

(I'm assuming that C# 5.0 did not change this part of the language.)

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See section of the C# spec: Applicable function member

A function member is said to be an applicable function member with respect to an argument list A when all of the following are true:

  • Each argument in A corresponds to a parameter in the function member declaration as described in §, and any parameter to which no argument corresponds is an optional parameter.
  • For each argument in A, the parameter passing mode of the argument (i.e., value, ref, or out) is identical to the parameter passing mode of the corresponding parameter, and
    • for a value parameter or a parameter array, an implicit conversion (§6.1) exists from the argument to the type of the corresponding parameter, or
    • [... some irrelevant material concerning ref and out parameters ...]

For a function member that includes a parameter array, if the function member is applicable by the above rules, it is said to be applicable in its normal form. If a function member that includes a parameter array is not applicable in its normal form, the function member may instead be applicable in its expanded form[.]

Because the array you passed can be implicitly converted to object[], and because overload resolution prefers "normal" form over "expanded" form, the behavior you observe conforms to the specification, and there is no bug.

In addition to the workaround described by Chris Shain, you could also change Bar from a class to a struct; that makes the array no longer implicitly convertible to object[], so you'll get the behavior you desire.

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I'm accepting that the compiler implements the spec. But the spec clearly is buggy, as this example is illustrating in greater and greater clarity. How can it be that g.Reply(vector-of-Foos) is indistinguishable from g.Reply(Foo,Foo'...) and yet g.Reply(3, vector-of-foos) works as one would expect? Yes, I see why this works, any of us on this thread see that. But why in a profound philosophical sense is this the correct decision on how to infer the type? They had two paths in the woods... and took the wrong one. Then made it part of the spec. Still a mistake! – Ken Birman Mar 14 '12 at 21:13
@KenBirman it seems to me that the solution to your problem is to abandon the use of params and just take a single object[] argument; require your users to package the arguments into an array no matter what. Then there's no ambiguity. Also, I'd question the use of "buggy" here; if the language designers made a poor choice, then by all means call it a "poor choice". Certainly, the system as it works now has several useful properties. – phoog Mar 14 '12 at 21:19
@KenBirman: Design is always the process of compromising between numerous incompatible goals. What appears to you to be a "mistake" is certainly an unfortunate consequence of that design process, but you are not taking into account all the considerations that the designers had to take into account. Fundamentally the problem arises from the fact that unsafe array covariance only works on reference types. This is unfortunate, yes, but it is not a bug or a mistake; this was deliberately designed into the language by sensible people who had to make hard compromises. – Eric Lippert Mar 14 '12 at 21:27
@EricLippert - well, I'd say that in hindsight array covariance is a mistake in the CLR. From the C# perspective it's more justifiable since the underlying platform supports it (and matching the platform has some benefit). – kvb Mar 14 '12 at 21:40
@phoog: No, you are getting it backwards. The CLR supports it because the CLR wanted to be able to be the runtime for any possible Java-like language, so it supports a superset of the features of Java. Given that the CLR's common type system supports unsafe array covariance it is then natural for C# to support it as well; it would be a bit weird otherwise. (However, C# does not support all the covariance features of the common type system; for example, a cast from int[] to uint[] is illegal in C#, even though the CLR allows that conversion.) – Eric Lippert Mar 14 '12 at 21:55

I believe you are wrong Ken That's because int[] is not of object[] type, so the compiler assumes that the int[] is just one of arguments passed to the method.

here's how:

new Foobar[] { } is object[]; // true
new int[] { } is object[]; // false

update: you can make the method generic to let the compiler know struct/object type passes as params:

void Foo<T>(params T[] objs)
    foreach (T o in objs)
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Params is doing the type inference the other way around, Kamar! If your explanation held, then the 3rd, not the 4th, call would be the one that prints an undesired output – Ken Birman Mar 14 '12 at 20:50
this is how: in C# an instance of a struct is an object, however array of struct is not of type object[] – Kamyar Nazeri Mar 14 '12 at 20:56
Your best bet is to make the method generic, in that case compiler would decide on parameter type (struct/object) on the method call! check out the update – Kamyar Nazeri Mar 14 '12 at 20:57
Assumes (incorrectly) that the Reply is all of the same type. I often see, for example, g.Reply(quality, URL-list, ...). But this would work correctly. In fact the issue ONLY arises with a single argument that is a vector of user-defined objects and to me this highlights the absurdity of claiming that C# is correct to use this definition. – Ken Birman Mar 14 '12 at 21:09

So I'm going to suggest that the best answer is that I'm right and that this really is a compiler bug. While I see the point perfectly clearly, your explanation ignores the "params" keyword. In fact to use covariance this way, one MUST ignore the params keyword, as if it was unimportant. I postulate that there simply is no plausible explanation for compiling the code this way with Params present as a keyword on the type signature of Foo: to invoke your explanation you need to convince me that myClass[] should be type-matched to object[], but we shouldn't even be asking that question given the params construct. In fact, the more you think about this, the more clear that it is actually a genuine C# 5.0 compiler bug: the compiler is neglecting to apply the params keyword. The language spec doesn't actually need any change at all. I should get some kind of wierd badge, imho!

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Your analysis is incorrect; this is not a compiler bug. All of the other analyses are correct; Raymond Chen's answer is in my opinion the most clear of all of them. – Eric Lippert Mar 14 '12 at 21:48
@KenBirman: It is identical to an invocation of a method not using the params keyword. As Raymond correctly said, if a method is applicable in both its normal (ignore params) and its expanded (use params) form then the normal form wins. (Also, be careful. I suspect that "type argument" does not mean what you think it means.) – Eric Lippert Mar 14 '12 at 22:10
@KenBirman: Perhaps a justification will help. int M(bool b, params string[] p) { return b ? N(p) : O(p); } int N(params object[] q) {...} int O(params object[] r) {...}. The calls to N and O are applicable in their normal form. Obviously it would be a bug here to pass new object[] { p } as the argument to N or O. If we do not allow you to call N or O in normal form then it becomes impossible to write the method M. – Eric Lippert Mar 14 '12 at 22:17
Ken, in @EricLippert's example, N and O might be part of the class's public surface, and might need params for that reason, or might be library methods outside the programmer's control. The way out would be to consider the argument list (params object[] x) to be distinct from (object[] x) for the purpose of overload resolution. I suspect that would introduce more cost than benefit. For one thing, the params version of every such method would look the same: T M(params object[] a) { return M(a); } T M(object[] a) { // ... real logic here ... – phoog Mar 15 '12 at 14:35
@KenBirman, you are free to disagree how C# should behave. But that does not make the current behavior a bug. – svick Apr 3 '12 at 11:31

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