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null coalescing operator is right associative, which means an expression of the form

first ?? second ??third

is evaluated as

first ?? (second ?? third)

Based on the above rule, I think the following translation is not correct.

From:

Address contact = user.ContactAddress;
if (contact == null)
{
    contact = order.ShippingAddress;
    if (contact == null)
    {
        contact = user.BillingAddress;
    }
}

To:

Address contact = user.ContactAddress ??
                  order.ShippingAddress ??
                  user.BillingAddress;

Instead, I think the following is right one (Please correct me if I am wrong)

Address contact = (user.ContactAddress ?? order.ShippingAddress) ??
                   user.BillingAddress;
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4 Answers

up vote 25 down vote accepted

The spec is actually self-contradictory on this one.

Section 7.13 of the C# 4 spec states:

The null coalescing operator is right-associative, meaning that operations are grouped from right to left. For example, an expression of the form a ?? b ?? c is evaluated as a ?? (b ?? c).

On the other hand, as has been pointed out, 7.3.1 claims that:

Except for the assignment operators, all binary operators are left-associative

I entirely agree that for simple cases it doesn't matter how you do the grouping... but there may be cases where it really matters due to implicit type conversions doing interesting things if the operands have different types.

I'll consider it further, ping Mads and Eric, and add an erratum for the relevant section of C# in Depth (which inspired this question).

EDIT: Okay, I've now got an example where it does matter... and the null coalescing operator is definitely right-associative, at least in the MS C# 4 compiler. Code:

using System;

public struct Foo
{
    public static implicit operator Bar(Foo input)
    {
        Console.WriteLine("Foo to Bar");
        return new Bar();
    }

    public static implicit operator Baz(Foo input)
    {
        Console.WriteLine("Foo to Baz");
        return new Baz();
    }
}

public struct Bar
{
    public static implicit operator Baz(Bar input)
    {
        Console.WriteLine("Bar to Baz");
        return new Baz();
    }
}

public struct Baz
{
}


class Test
{
    static void Main()
    {
        Foo? x = new Foo();
        Bar? y = new Bar();
        Baz? z = new Baz();

        Console.WriteLine("Unbracketed:");
        Baz? a = x ?? y ?? z;
        Console.WriteLine("Grouped to the left:");
        Baz? b = (x ?? y) ?? z;
        Console.WriteLine("Grouped to the right:");
        Baz? c = x ?? (y ?? z);
    }
}

Output:

Unbracketed:
Foo to Baz
Grouped to the left:
Foo to Bar
Foo to Bar
Bar to Baz
Grouped to the right:
Foo to Baz

In other words,

x ?? y ?? z

behaves the same as

x ?? (y ?? z)

but not the same as

(x ?? y) ?? z

I'm not currently sure why there are two conversions from Foo to Bar when using (x ?? y) ?? z - I need to check that out more carefully...

EDIT: I now have another question to cover the double conversion...

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+1, that is certainly an interesting corner case. I'll update my answer to be less "authoritative" in statements involving "identical". –  user7116 Jun 6 '11 at 18:54
    
@sixlettervariables: It's getting even more interesting, actually. There are some really weird things going on around custom conversions. I'll be posting a question later on... –  Jon Skeet Jun 6 '11 at 18:58
    
check out the IL generation for nullable structs in your scenario. Odd reuse of x leads to the multiple "Foo to Bar". –  user7116 Jun 6 '11 at 19:11
    
@sixlettervariables: Yes, but I'm not sure it's right... –  Jon Skeet Jun 6 '11 at 19:12
    
I agree. I can't figure out why it thinks that is useful. –  user7116 Jun 6 '11 at 19:15
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Jon's answer is correct.

Just to be clear: the ?? operator in C# is right associative. I have just gone through the binary operator parser and verified that the parser treats ?? as right-associative.

As Jon points out, the spec says both that the ?? operator is right-associative, and that all binary operators except assignment are left-associative. Since the spec contradicts itself, clearly only one of these can be right. I will have the spec amended to say something like:

Except for the simple assignment, compound assignment and null coalescing operators, all binary operators are left-associative

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so, @Eric, Are issues like this (specification contradiction) considered "bugs" in your parlance at Microsoft ? How do you call them ? –  Attilah Aug 9 '12 at 14:37
1  
Just read another question and realized that in a sense, the => operator is right-associative too. This is because it's legal to write Func<int, Func<int, int>> f = x => y => 0; so there are "implicit" parantheses to the right. But of course this is not "true" right-associativity because parentheses to the left would never be meaningful. So I'm not sure if you consider this an additional "exception" that will have to be added to the specification? –  Jeppe Stig Nielsen Sep 17 '12 at 19:38
    
(addition) But also with x = y = 0 it is never meaningful to put the parentheses to the left, so there's really no difference. If the assignment operator = is to be called right-associative, then so is the lambda operator =>, isn't it? –  Jeppe Stig Nielsen Sep 17 '12 at 19:42
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I can't see how it matters, both:

(a ?? b) ?? c

and

a ?? (b ?? c)

have the same result!

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They do when the types of a, b and c are the same. But suppose the types are A, B and C, and there are implicit conversions from A to B, A to C and B to C... then what happens? See my answer :) –  Jon Skeet Jun 6 '11 at 18:48
    
@Jon: I did think of that, then looked at the question again and decided it's irrelevant. But I do applaud you for digging in and determining the actual observable associativity. –  Ben Voigt Jun 6 '11 at 19:20
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Both work as expected and are effectively identical because the expressions involve simple types (thank you @Jon Skeet). It will chain to the first non-null from left to right in your examples.

The precedence (thanks @Ben Voigt) is more interesting when combining this operator with operators of different precedence:

value = A ?? B ? C : D ?? E;

Basically, associativity is expressed inherently through operator precedence or through user introduced sub-expressions (parentheses).

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I still don't think the associativity matters, only the precedence. The ternary operator has higher precedence, hence it's: A ?? (B ? C : D) ?? E. And it still doesn't matter whether it's (A ?? (B ? C : D) )?? E or A ?? ((B ? C : D) ?? E) –  Ben Voigt Jun 4 '11 at 17:08
1  
OMFG, PLEASE do not EVER write this in any code that I will ever have to read!!! Yes, I realize that you are only illustrating your point. –  DOK Jun 4 '11 at 17:08
1  
@sixletter: Oh drat: I just looked that up, and managed to forget in between browser tabs :(. Then it's (A ?? B)? C : (D ?? E) and there are no adjacent operations of equal precedence, so the associativity rule isn't even applied. –  Ben Voigt Jun 4 '11 at 17:26
2  
@sixletter: There's no other way to illustrate precedence than confusing code, and there's no other use for confusing code than illustration of precedence (and motivation for adding parentheses even when not strictly necessary). –  Ben Voigt Jun 4 '11 at 17:37
1  
@sixlettervariables: They're not effectively identical when the types are different and conversions get involved. See my answer. –  Jon Skeet Jun 6 '11 at 18:49
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