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I am a C# newbie and I just encounter a problem. There is a difference between C# and Java when dealing with the ternary operator (? :).

In the following code segment, why does the 4th line not work? The compiler shows an error message of there is no implicit conversion between 'int' and 'string'. The 5th line does not work as well. Both Lists are objects, aren't they?

int two = 2;
double six = 6.0;
Write(two > six ? two : six); //param: double
Write(two > six ? two : "6"); //param: not object
Write(two > six ? new List<int>() : new List<string>()); //param: not object

However, the same code works in Java:

int two = 2;
double six = 6.0;
System.out.println(two > six ? two : six); //param: double
System.out.println(two > six ? two : "6"); //param: Object
System.out.println(two > six ? new ArrayList<Integer>()
                   : new ArrayList<String>()); //param: Object

What language feature in C# is missing? If any, why is it not added?

share|improve this question
4  
As per msdn.microsoft.com/en-us/library/ty67wk28.aspx "Either the type of first_expression and second_expression must be the same, or an implicit conversion must exist from one type to the other." – Egor Feb 5 at 18:19
2  
I haven't done C# in a while, but doesn't the message you quote say it? The two branches of the ternary have to return the same data type. You're giving it an int and a String. C# doesn't know how to automagically convert an int to a String. You need to put an explicit type conversion on it. – Jay Feb 5 at 18:20
2  
@blackr1234 Because an int is not an object. It's a primitive. – Code-Apprentice Feb 5 at 18:22
3  
@Code-Apprentice yes they are very different indeed - C# has runtime reification, so the lists are of unrelated types. Oh, and you could also throw generic interface covariance/contravariance into the mix if you wanted to, to introduce some level of relationship ;) – Lucas Trzesniewski Feb 5 at 23:34
3  
For the OP's benefit: type erasure in Java means that ArrayList<String> and ArrayList<Integer> become just ArrayList in the bytecode. This means that they appear to be the exact same type at run-time. Apparently in C# they are different types. – Code-Apprentice Feb 5 at 23:38
up vote 97 down vote accepted

Looking through the C# 5 Language Specification section 7.14: Conditional Operator we can see the following:

  • If x has type X and y has type Y then

    • If an implicit conversion (§6.1) exists from X to Y, but not from Y to X, then Y is the type of the conditional expression.

    • If an implicit conversion (§6.1) exists from Y to X, but not from X to Y, then X is the type of the conditional expression.

    • Otherwise, no expression type can be determined, and a compile-time error occurs

In other words: it tries to find whether or not x and y can be converted to eachother and if not, a compilation error occurs. In our case int and string have no explicit or implicit conversion so it won't compile.

Contrast this with the Java 7 Language Specification section 15.25: Conditional Operator:

  • If the second and third operands have the same type (which may be the null type), then that is the type of the conditional expression. (NO)
  • If one of the second and third operands is of primitive type T, and the type of the other is the result of applying boxing conversion (§5.1.7) to T, then the type of the conditional expression is T. (NO)
  • If one of the second and third operands is of the null type and the type of the other is a reference type, then the type of the conditional expression is that reference type. (NO)
  • Otherwise, if the second and third operands have types that are convertible (§5.1.8) to numeric types, then there are several cases: (NO)
  • Otherwise, the second and third operands are of types S1 and S2 respectively. Let T1 be the type that results from applying boxing conversion to S1, and let T2 be the type that results from applying boxing conversion to S2.
    The type of the conditional expression is the result of applying capture conversion (§5.1.10) to lub(T1, T2) (§15.12.2.7). (YES)

And, looking at section 15.12.2.7. Inferring Type Arguments Based on Actual Arguments we can see it tries to find a common ancestor that will serve as the type used for the call which lands it with Object. Object is an acceptable argument so the call will work.

share|improve this answer
1  
I read the C# specification as saying there must be an implicit conversion in at least one direction. The compiler error occurs only when there is no implicit conversion in either direction. – Code-Apprentice Feb 5 at 18:56
1  
Of course, this is still the most complete answer since you quote directly from the specifications. – Code-Apprentice Feb 5 at 18:56
    
This was actually only changed with Java 5 (I think, might have been 6). Before that Java had exactly the same behavior as C#. Due to the way enums are implemented this probably caused even more surprises in Java than C# though so a good change all along. – Voo Feb 5 at 19:34
    
@Voo: FYI, Java 5 and Java 6 have the same spec version (The Java Language Specification, Third Edition), so it definitely didn't change in Java 6. – ruakh Feb 7 at 21:16

The given answers are good; I would add to them that this rule of C# is a consequence of a more general design guideline. When asked to infer the type of an expression from one of several choices, C# chooses the unique best of them. That is, if you give C# some choices like "Giraffe, Mammal, Animal" then it might choose the most general -- Animal -- or it might choose the most specific -- Giraffe -- depending on the circumstances. But it must choose one of the choices it was actually given. C# never says "my choices are between Cat and Dog, therefore I will deduce that Animal is the best choice". That wasn't a choice given, so C# cannot choose it.

In the case of the ternary operator C# tries to choose the more general type of int and string, but neither is the more general type. Rather than picking a type that was not a choice in the first place, like object, C# decides that no type can be inferred.

I note also that this is in keeping with another design principle of C#: if something looks wrong, tell the developer. The language does not say "I'm going to guess what you meant and muddle on through if I can". The language says "I think you've written something confusing here, and I'm going to tell you about that."

Also, I note that C# does not reason from the variable to the assigned value, but rather the other direction. C# does not say "you're assigning to an object variable therefore the expression must be convertible to object, therefore I will make sure that it is". Rather, C# says "this expression must have a type, and I must be able to deduce that the type is compatible with object". Since the expression does not have a type, an error is produced.

share|improve this answer
6  
I got past the first paragraph wondering why the sudden covariance/contravariance interest, then I started to agree more on the second paragraph, then I saw who wrote the answer... Should have guessed sooner. Have you ever noticed exactly how much you use 'Giraffe' as an example? You must really like Giraffes. – Pharap Feb 6 at 6:36
21  
Giraffes are awesome! – Eric Lippert Feb 6 at 6:39
9  
@Pharap: In all seriousness, there are pedagogical reasons why I use giraffe so much. First of all, giraffes are well-known around the world. Second, it's a kind of fun-to-say word, and they are so odd looking that it's a memorable image. Third, using, say, "giraffe" and "turtle" in the same analogy emphasizes strongly "these two classes, though they may share a base class, are very different animals with very different characteristics". Questions about type systems often have examples where the types are logically very similar, which drives your intuition the wrong way. – Eric Lippert Feb 6 at 14:56
7  
@Pharap: That is, the question is usually something like "why can't a list of customer invoice provider factories be used as a list of invoice provider factories?" and your intuition says "yeah, those are basically the same thing", but when you say "why can't a room full of giraffes be used as a room full of mammals?" then it becomes much more of an intuitive analogy to say "because a room full of mammals can contain a tiger, a room full of giraffes cannot". – Eric Lippert Feb 6 at 14:58
6  
@Eric I originally ran into this problem with int? b = (a != 0 ? a : (int?) null). There's also this question, along with all the linked questions on the side. If you continue following the links, there's quite a few. In comparison, I've never heard of someone running into a real-world issue with the way Java does it. – BlueRaja - Danny Pflughoeft Feb 7 at 0:38

Regarding the generics part:

two > six ? new List<int>() : new List<string>()

In C#, the compiler tries to convert the right-hand expression parts to some common type; since List<int> and List<string> are two distinct constructed types, one can't be converted to the other.

In Java, the compiler tries to find a common supertype instead of converting, so the compilation of the code involves the implicit use of wildcards and type erasure;

two > six ? new ArrayList<Integer>() : new ArrayList<String>()

has the compile type of ArrayList<?> (actually, it can be also ArrayList<? extends Serializable> or ArrayList<? extends Comparable<?>>, depending on use context, since they are both common generic supertypes) and runtime type of raw ArrayList (since it's the common raw supertype).

For example (test it yourself),

void test( List<?> list ) {
    System.out.println("foo");
}

void test( ArrayList<Integer> list ) { // note: can't use List<Integer> here
                                 // since both test() methods would clash after the erasure
    System.out.println("bar");
}

void test() {
    test( true ? new ArrayList<Object>() : new ArrayList<Object>() ); // foo
    test( true ? new ArrayList<Integer>() : new ArrayList<Object>() ); // foo 
    test( true ? new ArrayList<Integer>() : new ArrayList<Integer>() ); // bar
} // compiler automagically binds the correct generic QED
share|improve this answer
    
Actually Write(two > six ? new List<object>() : new List<string>()); does not work either. – blackr1234 Feb 5 at 19:06
2  
@blackr1234 exactly: I didn't want to repeat what other answers already said, but the ternary expression needs to evaluate to a type, and the compiler won't attempt to find the "lowest common denominator" of the two. – Mat's Mug Feb 5 at 19:08
1  
Actually, this is not about type erasure, but about wildcard types. The erasures of ArrayList<String> and ArrayList<Integer> would be ArrayList (the raw type), but the inferred type for this ternary operator is ArrayList<?> (the wildcard type). More generally, that the Java runtime implements generics through type erasure has no effect on the compile time type of an expression. – meriton Feb 6 at 0:43
1  
@vaxquis thanks! I'm a C# guy, Java generics confuse me ;-) – Mat's Mug Feb 6 at 1:14
2  
Actually, the type of two > six ? new ArrayList<Integer>() : new ArrayList<String>() is ArrayList<? extends Serializable&Comparable<?>> which means you may assign it to a variable of type ArrayList<? extends Serializable> as well as a variable of type ArrayList<? extends Comparable<?>>, but of course ArrayList<?>, which is equivalent to ArrayList<? extends Object>, works as well. – Holger Feb 6 at 19:02

In both Java and C# (and most other languages), the result of an expression has a type. In the case of the ternary operator, there are two possible subexpressions evaluated for the result and both must have the same type. In the case of Java, an int variable can be converted to an Integer by autoboxing. Now since both Integer and String inherit from Object, they can be converted to the same type by a simple narrowing conversion.

On the other hand, in C#, an int is a primitive and there is not implicit conversion to string or any other object.

share|improve this answer
    
Thanks for the answer. Autoboxing is what I am currently thinking of. Doesn't C# allow autoboxing? – blackr1234 Feb 5 at 18:23
2  
I don't think this is correct as boxing an int to an object is perfectly possible in C#. The difference here is, I believe, that C# just takes a very laidback approach at determining whether it is allowed or not. – Jeroen Vannevel Feb 5 at 18:40
9  
This has nothing to do with auto boxing, which would happen just as much in C#. The difference is that C# does not try to find a common supertype while Java (since Java 5 only!) does. You can easily test that by trying to see what happens if you try it with 2 custom classes (which both inherit from object obviously). Also there is an implicit conversion from int to object. – Voo Feb 5 at 19:35
3  
And to nitpick just a bit more: The conversion from Integer/String to Object is not a narrowing conversion, it's the exact opposite :-) – Voo Feb 5 at 19:44
1  
Integer and String also implement Serializable and Comparable so assignments to either of them will work as well, e.g. Comparable<?> c=condition? 6: "6"; or List<? extends Serializable> l = condition? new ArrayList<Integer>(): new ArrayList<String>(); are legal Java code. – Holger Feb 6 at 19:07

This is pretty straightforward. There is no implicit conversion between string and int. the ternary operator needs the last two operands to have the same type.

Try:

Write(two > six ? two.ToString() : "6");
share|improve this answer
10  
The question is what causes the difference between Java and C#. This does not answer the question. – Jeroen Vannevel Feb 5 at 18:21

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