This example seems to compile with VC10 and gcc (though my version of gcc is very old).

EDIT: R. Martinho Fernandez tried this on gcc 4.7 and the behaviour is still the same.

struct Base
    operator double() const { return 0.0; }

struct foo
    foo(const char* c) {}

struct Something : public Base
    void operator[](const foo& f) {}

int main()
    Something d;

    return 0;

But clang complains:

test4.cpp:19:6: error: use of overloaded operator '[]' is ambiguous (with operand types 'Something' and 'const char [3]')
test4.cpp:13:10: note: candidate function
    void operator[](const foo& f) {}
test4.cpp:19:6: note: built-in candidate operator[](long, const char *)
test4.cpp:19:6: note: built-in candidate operator[](long, const restrict char *)
test4.cpp:19:6: note: built-in candidate operator[](long, const volatile char *)
test4.cpp:19:6: note: built-in candidate operator[](long, const volatile restrict char *)

The overload resolution is considering two possible functions from looking at this expression:

  • calling Something::operator[] (after a user defined conversion)
  • calling built in operator for const char* (think "32"[d]) (after a user defined conversion and standard conversion double to long).

If I had written d["32"] as d.operator[]("32"), then overload resolution won't even look at option 2, and clang will also compile fine.

EDIT: (clarification of questions)

This seems to be a complicated area in overload resolution, and because of that I'd appreciate very much answers that explain in detail the overload resolution in this case, and cite the standard (if there's some obscure/advanced likely to be unknown rule).

If clang is correct, I'm also interested in knowing why the two are ambiguous / one is not preferred over another. The answer likely would have to explain how overload resolution considers implicit conversions (both user defined and standard conversions) involved on the two candidates and why one is not better than the other.

Note: if operator double() is changed to operator bool(), all three (clang, vc, gcc) will refuse to compile with similar ambiguous error.

  • To clarify where the (possible) ambiguity comes from: a[b] is equivalent to b[a] when operator[] isn't overloaded. – Mike Seymour Jan 18 '12 at 18:05
  • Right, I was about to add that minutes ago. Will do, thanks. – ryaner Jan 18 '12 at 18:07
  • Since you mentioned your GCC is very old, I tried it on the yet to be released 4.7. It acts the same as yours: compile the original just fine, and error out with operator bool. – R. Martinho Fernandes Jan 18 '12 at 18:08
  • Thanks for trying it out. Will make an edit to reflect your effort. – ryaner Jan 18 '12 at 18:10
  • @MikeSeymour: a[b] is not equivalent to b[a] in this case (as a in this case is not const char* or convertible to it). What you are saying is this case : char a[100]; int b; then a[b] is equivalent to b[a]. – Nawaz Jan 18 '12 at 18:12

It should be easier to picture why the overload resolution is ambiguous by going through it step-by-step.

§13.5.5 [over.sub]

Thus, a subscripting expression x[y] is interpreted as x.operator[](y) for a class object x of type T if T::operator[](T1) exists and if the operator is selected as the best match function by the overload resolution mechanism (13.3.3).

Now, we first need an overload set. That's constructed according to §13.3.1 and contains member aswell as non-member functions. See this answer of mine for a more detailed explanation.

§13.3.1 [over.match.funcs]

p2 The set of candidate functions can contain both member and non-member functions to be resolved against the same argument list. So that argument and parameter lists are comparable within this heterogeneous set, a member function is considered to have an extra parameter, called the implicit object parameter, which represents the object for which the member function has been called. [...]

p3 Similarly, when appropriate, the context can construct an argument list that contains an implied object argument to denote the object to be operated on.

// abstract overload set (return types omitted since irrelevant)
f1(Something&, foo const&); // linked to Something::operator[](foo const&)
f2(std::ptrdiff_t, char const*); // linked to operator[](std::ptrdiff_t, char const*)
f3(char const*, std::ptrdiff_t); // linked to operator[](char const*, std::ptrdiff_t)

Then, an argument list is constructed:

// abstract argument list
(Something&, char const[3]) // 'Something&' is the implied object argument

And then the argument list is tested against every member of the overload set:

f1 -> identity match on argument 1, conversion required for argument 2
f2 -> conversion required for argument 1, conversion required for argument 2 (decay)
f3 -> argument 1 incompatible, argument 2 incompatible, discarded

Then, since we found out that there are implicit conversions required, we take a look at §13.3.3 [over.match.best] p1:

Define ICSi(F) as follows:

  • if F is a static member function, [...]; otherwise,
  • let ICSi(F) denote the implicit conversion sequence that converts the i-th argument in the list to the type of the i-th parameter of viable function F. defines the implicit conversion sequences and defines what it means for one implicit conversion sequence to be a better conversion sequence or worse conversion sequence than another.

Now let's construct those implicit conversion sequences for f1 and f2 in the overload set (§

ICS1(f1): 'Something&' -> 'Someting&', standard conversion sequence
ICS2(f1): 'char const[3]' -> 'foo const&', user-defined conversion sequence
ICS1(f2): 'Something&' -> 'std::ptrdiff_t', user-defined conversion sequence
ICS2(f2): 'char const[3]' -> 'char const*', standard conversion sequence

§ [over.ics.rank] p2

a standard conversion sequence ( is a better conversion sequence than a user-defined conversion sequence or an ellipsis conversion sequence.

So ICS1(f1) is better than ICS1(f2) and ICS2(f1) is worse than ICS2(f2).
Conversely, ICS1(f2) is worse than ICS1(f1) and ICS2(f2) is better than ICS2(f1).

§13.3.3 [over.match.best]

p1 (cont.) Given these definitions, a viable function F1 is defined to be a better function than another viable function F2 if for all arguments i, ICSi(F1) is not a worse conversion sequence than ICSi(F2), and then [...]

p2 If there is exactly one viable function that is a better function than all other viable functions, then it is the one selected by overload resolution; otherwise the call is ill-formed.

Well, f*ck. :) As such, Clang is correct in rejecting that code.


It seems there is no question that both Something::operator[](const foo& f) and the built-in operator[](long, const char *) are viable candidate functions (13.3.2) for overload resolution. The types of real arguments are Something and const char*, and implicit conversion sequences (ICFs) I think are:

  • for Something::operator[](const foo& f): (1-1) identity conversion, and (1-2) foo("32") through foo::foo(const char*);
  • for operator[](long, const char *): (2-1) long(double(d)) through Something::operator double() const (inherited from Base), and (2-2) identity conversion.

Now if we rank these ICFs according to (, we can see that (1-1) is a better conversion than (2-1), and (1-2) is a worse conversion than (2-2). According to the definition in (13.3.3),

a viable function F1 is defined to be a better function than another viable function F2 if for all arguments i, ICSi(F1) is not a worse conversion sequence than ICSi(F2), ...

Therefore, neither of the considered two candidate functions is better than the other one, and thus the call is ill-formed. I.e. Clang appears to be correct, and the code should not compile.


It would seem from 13.6 in the C++11 spec that clang is correct here:

13.6 Built-in operators [over.built]

The candidate operator functions that represent the built-in operators defined in Clause 5 are specified in this subclause. These candidate functions participate in the operator overload resolution process as described in and are used for no other purpose. [ Note: Because built-in operators take only operands with non-class type, and operator overload resolution occurs only when an operand expression originally has class or enumeration type, operator overload resolution can resolve to a built-in operator only when an operand has a class type that has a user-defined conversion to a non-class type appropriate for the operator, or when an operand has an enumeration type that can be converted to a type appropriate for the operator. Also note that some of the candidate operator functions given in this subclause are more permissive than the built-in operators themselves. As described in, after a built-in operator is selected by overload resolution the expression is subject to the requirements for the built-in operator given in Clause 5, and therefore to any additional semantic constraints given there. If there is a user-written candidate with the same name and parameter types as a built-in candidate operator function, the built-in operator function is hidden and is not included in the set of candidate functions. — end note ]


For every cv-qualified or cv-unqualified object type T there exist candidate operator functions of the form

T& operator[](T *, std::ptrdiff_t);

T& operator[](std::ptrdiff_t, T *);


Once you get past which operator functions exist, this just becomes standard overload resolution as described by section 13.3 of the standard -- about 10 pages of details, but the gist of it is that for a function call to not be ambiguous, there needs to be a single function that is at least as good a match as all the possible, viable functions on every argument, and a better match than the others on at least one argument. There's a lot of spec detail on exactly what 'better' means, but it boils down to (in this case) a match not requiring any user-defined conversion operator or object constructor is better than one which does.

So in this case, there are two viable matches:

void Something::operator[](const foo& f)
operator[](long, const char *)

The first is a better match for the first argument, while the second is a better match for the second. So unless there's some other function that is better than both of these, its ambiguous.

That latter point is a possble workaround -- add:

void operator[](const char *a) { return (*this)[foo(a)]; }

to class Something

  • I don't understand why it was important to ever have T& operator[](std::ptrdiff_t, T *); in C. – Neil G Jan 18 '12 at 19:02
  • If I'm understanding this correctly. This explains why the built in operator is considered. But I'm also interested in why clang thinks the two are ambiguous and are not preferring one over another. I didn't say that in my question. I will add it. – ryaner Jan 18 '12 at 19:03
  • Also for all we know, gcc and VC10 might also have considered the built in operators during overload resolution but think that it is not ambiguous and choose to call Something::operator[] , thus compilation succeeds, whereas clang thinks that the two are ambiguous (doesn't prefer one over another). – ryaner Jan 18 '12 at 19:15
  • @Neil G: C doesn't have operator[] at all -- a[b] is syntactic shorthand for *(a+b) and is converted to the latter before even considering types. I guess your question equivalent to "why allow int+pointer as well as pointer+int", which I guess is just easier as + is normally commutative – Chris Dodd Jan 18 '12 at 21:36
  • @ChrisDodd: Okay. I think that C and C++ should be fixed so that a[b] is always a a[b] operator, and that that operator should not exist for a is a numeric type. – Neil G Jan 18 '12 at 21:43

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.