# Are C/C++ operator precedence & associativity rules ever violated?

Are operator precedence & associativity rules ever violated in any C/C++ expression?
If so, can you give an example?

Assume the claims of precedence and associativity rules are:

Each operator has a given precedence level, and each precedence level has a given associativity. If a sub-expression is seen by two operators where they expect an operand, it belongs to the one with higher precedence. Ties are broken by associativity.

### Edit: Background

The standard defines C/C++ expressions as a CFG, which is much more flexible than a precedence-based parser. For example, it would have been possible to give binary operators asymmetrical "precedence", which would have rendered any precedence table incorrect. However, it appears to me that the design of the grammar was constrained to uphold simple precedence rules. Here are some alleged "counterexamples" that I have come across:

### 1) a?b,c:d is not interpreted as (a?b),(c:d)

Some claim that the ?: operator exhibits different precedence towards its middle operand than towards its other operands, because a?b,c:d, for example, is not interpreted as (a?b),(c:d). However, neither b nor c occupies a position in which it appears to ?: as its inner operand. By that reasoning a[b+c] should be interpreted as (a[b)+(c]), which is ludicrous.

### 2) sizeof(int)*a is interpreted as (sizeof(int))*a rather than sizeof((int)(*a))

... because C disallows an uparenthesized cast as sizeof's operator. However, both of these interpretations conform to precedence rules. The confusion comes from the * operator's ambiguity (Is it the binary or the unary operator?). Precedence tables are not meant to resolve operator ambiguities. They are, after all, not operator-symbol-precedence tables. So the operator precedence rules themselves are intact.

### 3) a+b=c results in syntax error, not semantic error

a+b=c, according to the standard, is invalid C syntax. If C had had a precedence-based parser, it would only have been caught at the semantic level. In C, it so happens that any expression that is not a unary-expression cannot be l-valued. These semantically doomed LHS expressions therefore do not need to be accommodated syntactically. It makes no difference to the language as a whole, and precedence tables needn't be in the business of predicting the syntacticness/symanticness of the error that is going to result from an expression.

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Why do you ask? The rules are supposed to be "cast in concrete", but there's always the possibility (though remote) of a compiler bug. But far more often the rules are simply misinterpreted by the user. –  Hot Licks Nov 25 '12 at 13:57
@HotLicks - it's also possible that the "precedence rules" are wrong. The language definition doesn't talk about precedence. –  Pete Becker Nov 25 '12 at 14:14
What do you mean by, "the question is about the language, not the parser"? The syntax parser either correctly reflects the language specification, or else it's non-conforming. So any conforming syntax parser agrees with the language. What's "the parser", if not a conforming parser? –  Steve Jessop Nov 25 '12 at 14:41
@HotLicks I agree. See the added background. –  tennenrishin Nov 25 '12 at 18:34
@SteveJessop Syntax parser. C takes some syntactic shorcuts that affect the syntax without affecting the language. I've removed that sentence, and added example 3. –  tennenrishin Nov 25 '12 at 18:54

For one example, the usual precedence table says that sizeof and cast expressions have the same precedence. Both the table and the standard say that they associate right-to-left.

This simplification is fine when you're looking at, say, *&foo, which means the same as *(&foo).

It might also suggest to you that sizeof (int) 1 is legal C++ and that it means the same thing as sizeof( (int) 1 ). But it's not legal, because in fact sizeof( type-id ) is a special thing of its own in the grammar. Its existence prevents sizeof (int) 1 from being a sizeof expression whose operand is a cast-expression whose operand is 1.

So I think you could say that the "sizeof ( type-id )" production in the C++ grammar is an exception to what the usual precedence/associativity tables say. They do accurately describe the "sizeof unary-expression" production.

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+1 for finding something interesting! But as you suggest one could argue that the sizeof in sizeof(int) (like the = in int a=0) is not the operator that appears in the table. The operator precedence table is not a lexeme precedence table, after all. (It cannot even resolve operator ambiguities.) –  tennenrishin Nov 25 '12 at 19:05
@Isak: OK, but if the question is about the exact definition of what it means for a syntax to "obey precedence and associativity" then I don't think I'm interested in it. It is not possible to parse C expressions solely with a precedence parser following the rules in the table, that is clear. That's another way of saying that there are examples of C expressions whose parse isn't defined by the table. If they aren't "exceptions" then I don't think I understood the question. –  Steve Jessop Nov 25 '12 at 21:15
It is clear that the sizeof in sizeof(int) is not an operator, because int can't be an operand. The precedence table is about operators. (Note also that my question is not whether the system of constraints imposed by the precedence table is underdetermined, but whether they are ever violated. I.e. whether the precedence table is truly a property of the language.) –  tennenrishin Nov 25 '12 at 22:44
@Isak: in that case, if the question is, "is it possible to make 1 or more true statements about the C++ grammar, which are phrased in terms of operator precedence and associativity?" then I'm pretty sure the answer is "yes". The article you link to gives an example of why there's FUD about these tables, though. MSDN lists ?: on a precedence level of its own, above the assignment operators. The article points out that this is inaccurate with respect to true ? x : y = 5. If all else fails you can just leave out operators that could cause confusion and get an accurate but incomplete table. –  Steve Jessop Nov 26 '12 at 9:23
If you want to leave it out of the table, then you're constrained to say it's not an operator. Either way you're enlarging on the standard's fairly ad hoc approach to what is and is not an operator: it lists "sizeof (type-id)" as a production under "unary operators", it doesn't list either kind of sizeof as a unary-operator, and in 5.3.3/1, C++03 explicitly states that (int) is the operand of sizeof in sizeof(int), even though above you define that it is not an operand. Basically, you have to take some liberties with the terminology in the standard to produce that table. –  Steve Jessop Nov 26 '12 at 15:17

It depends on whether the "rules" are correct. The language definition doesn't talk about precedence, so the precedence tables you see in various places may or may not reflect what the language definition actually requires.

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Given the way the language is defined, does a precedence table exist that in no way contradicts the standard? See the added background. –  tennenrishin Nov 25 '12 at 18:43
@IsakduPreez - I've heard that precedence really doesn't capture the true rules, but I haven't looked into it. The standard is clear enough for me, without introducing unofficial reformulations. –  Pete Becker Nov 25 '12 at 19:49
A lot of redundant information goes into the definition of a CFG, if it is already known to be constrained by precedence rules. For most it would be a nightmare if all the binary operators could have different glue on each side. Why? –  tennenrishin Nov 25 '12 at 20:22

Until someone can find a counterexample, I'm going to put forward this as the default answer:

No, C/C++ precedence and associativity rules are never violated.

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