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C defines at least 3 levels of "constant expression":

  • constant expression (unqualified)
  • arithmetic constant expression
  • integer constant expression

6.6 paragraph 3 reads:

Constant expressions shall not contain assignment, increment, decrement, function-call, or comma operators, except when they are contained within a subexpression that is not evaluated.

So does this mean 1,2 is not a constant expression?

Paragraph 8 reads:

An arithmetic constant expression shall have arithmetic type and shall only have operands that are integer constants, floating constants, enumeration constants, character constants, and sizeof expressions. Cast operators in an arithmetic constant expression shall only convert arithmetic types to arithmetic types, except as part of an operand to a sizeof operator whose result is an integer constant.

What are the operands in (union { uint32_t i; float f; }){ 1 }.f? If 1 is the operand, then this is presumably an arithmetic constant expression, but if { 1 } is the operand, then it's clearly not.

Edit: Another interesting observation: 7.17 paragraph 3 requires the result of offsetof to be an integer constant expression of type size_t, but the standard implementations of offsetof, as far as I can tell, are not required to be integer constant expressions by the standard. This is of course okay since an implementation is allowed (under 6.6 paragraph 10) to accept other forms of constant expressions, or implement the offsetof macro as __builtin_offsetof rather than via pointer subtraction. The essence of this observation, though, is that if you want to use offsetof in a context where an integer constant expression is required, you really need to use the macro provided by the implementation and not roll your own.

share|improve this question
In 1,2 I think 1 is a constant expression and 2 is a contant expression. – Pawel Zubrycki Feb 4 '11 at 0:17
@Chris: Unions are valid as compound literals, but I question whether the result can be an arithmetic constant expression. @Pawel: My question there was about the expression 1,2 which uses the comma operator, which for some reason I can't explain seems to have been excluded from the operators allowed in constant expressions. – R.. Feb 4 '11 at 0:27
@R.. - I found that out about a minute ago after checking for myself, and deleted my comment. – Chris Lutz Feb 4 '11 at 0:28
@R..: Because there are two constant expressions, not one. Comma is excluded to separate expressions. – Pawel Zubrycki Feb 4 '11 at 0:45
@Pawel - 1,2 is a single expression. It is comprised of two integer literals, 1 and 2, as arguments to the comma operator (6.5.17) to create one expression. R..'s question is, if both 1 and 2 are constant expressions, why is 1,2 a non-constant expression? – Chris Lutz Feb 4 '11 at 1:28
up vote 1 down vote accepted

Based on your reading, 1,2 isn't a constant expression. I don't know why it isn't, just that I agree with you that it isn't (despite the fact that it probably should be).

6.5.2 specifies compound literals as a postfix operator. So in

(union { uint32_t i; float f; }){ 1 }.f

The operands are (union { uint32_t i; float f; }){ 1 } and f to the . operator. It is not an arithmetic constant expression, since the first argument is a union type, but it is a constant expression.

UPDATE: I was basing this on a different interpretation of the standard.

My previous reasoning was that (union { uint32_t i; float f; }){ 1 }.f met the criteria for a constant expression, and was therefore a constant expression. I still think it meets the criteria for a constant expression (6.6 paragraph 3) but that it is not any of the standard types of constant expressions (integer, arithmetic, or address) and is therefore only subject to being a constant expression by 6.6 paragraph 10, which allows implementation-defined constant expressions.

I'd also been meaning to get to your edit. I was going to argue that the "hack" implementation of offsetof was a constant expression, but I think it's the same as above: it meets the criteria for a constant expression (and possibly an address constant) but is not an integer constant expression, and is therefore invalid outside of 6.6 paragraph 10.

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I wonder how the left hand operand of the . operrator can be a constant expression. It's a union type as you said. Initialization is performed without using an arithmetic operator, but it looks mighty suspicious. – Windows programmer Feb 4 '11 at 6:09
@Windows programmer - See for a description of compound literals (added in C99) and 6.6 for a description of constant expressions. As far as I can tell it meets the requirements. – Chris Lutz Feb 4 '11 at 6:34
Now I wonder if "abcdef"[2] is a constant expression with value 'c'. I'm pretty sure that used to be regarded as not being a constant expression, but I can't find the reason now. – Windows programmer Feb 4 '11 at 6:35
@Windows programmer: paragraph 7 lists the types of constant expressions: arithmetic, null pointer, address constant, and address plus offset. Of these, strings could only be valid in the last 2, and the rules for them explicitly forbid any access to the value of an object. So "abcdef"[2] is not a constant expression. – R.. Feb 4 '11 at 7:08
Accepted this answer because it seems to answer my specific questions. But I'd still be happy to hear more on the topic. – R.. Feb 4 '11 at 7:16

If 1,2 would be a constant expression, this would allow code like this to compile:

{ // code        // How the compiler interprets:
  int a[10, 10]; // int a[10];

  a[5, 8] = 42;  // a[8] = 42;

I don't know whether it is the real reason, but I can imagine that emitting an error for this (common?) mistake was considered more important than turning 1,2 into a constant expression.

UPDATE: As R. points out in a comment, the code about is not longer a compiler error since the introduction of VLAs.

share|improve this answer
That's a common mistake? – Chris Lutz Feb 4 '11 at 6:06
@Chris More common than the need for 1,2 to be a constant-expression. – Sjoerd Feb 4 '11 at 6:07
Obviously a comma in an initializer is not a comma operator; this has nothing to do with whether the comma operator is valid in a constant expression. Just like in a function argument list, you need parentheses to use a comma operator in such contexts. Note that the comma operator is perfectly valid in initializers for automatic variables, e.g. int x = (1,2); – R.. Feb 4 '11 at 6:40
@Sjoerd: I would say the need to use a comma operator in a constant expression could be very real with macros. Suppose you have a macro whose implementation under certain #ifdef doesn't use one of its arguments. In order to ensure that it still evaluates each argument exactly once, you might do something like #define FOO(a,b) ((a),BAR((b))). If not for the arbitrary rule that comma is not valid in constant expressions, FOO could be used in static initializers. – R.. Feb 4 '11 at 6:42
@Windows programmer: I'm assuming the same macro might be useful both for constant expressions and runtime use. And your 0*(a) trick breaks as soon as I tell you a has a non-arithmetic type... :-) – R.. Feb 4 '11 at 7:15

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