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Consider this simple example:

template <class Type>
class smartref {
    smartref() : data(new Type) { }
    operator Type&(){ return *data; }
    Type* data;

class person {
    void think() { std::cout << "I am thinking"; }

int main() {
    smartref<person> p;
    p.think(); // why does not the compiler try substituting Type&?

How do conversion operators work in C++? (i.e) when does the compiler try substituting the type defined after the conversion operator?

share|improve this question
up vote 27 down vote accepted

Some random situations where conversion functions are used and not used follow.

First, note that conversion functions are never used to convert to the same class type or to a base class type.

Conversion during argument passing

Conversion during argument passing will use the rules for copy initialization. These rules just consider any conversion function, disregarding of whether converting to a reference or not.

struct B { };
struct A {
  operator B() { return B(); }
void f(B);
int main() { f(A()); } // called!

Argument passing is just one context of copy initialization. Another is the "pure" form using the copy initialization syntax

B b = A(); // called!

Conversion to reference

In the conditional operator, conversion to a reference type is possible, if the type converted to is an lvalue.

struct B { };
struct A {
  operator B&() { static B b; return b; }

int main() { B b; 0 ? b : A(); } // called!

Another conversion to reference is when you bind a reference, directly

struct B { };
struct A { 
  operator B&() { static B b; return b; }

B &b = A(); // called!

Conversion to function pointers

You may have a conversion function to a function pointer or reference, and when a call is made, then it might be used.

typedef void (*fPtr)(int);

void foo(int a);
struct test {
  operator fPtr() { return foo; }

int main() {
  test t; t(10); // called!

This thing can actually become quite useful sometimes.

Conversion to non class types

The implicit conversions that happen always and everywhere can use user defined conversions too. You may define a conversion function that returns a boolean value

struct test {
  operator bool() { return true; }

int main() {
  test t;
  if(t) { ... }

(The conversion to bool in this case can be made safer by the safe-bool idiom, to forbid conversions to other integer types.) The conversions are triggered anywhere where a built-in operator expects a certain type. Conversions may get into the way, though.

struct test {
  void operator[](unsigned int) { }
  operator char *() { static char c; return &c; }

int main() {
  test t; t[0]; // ambiguous

// (t).operator[] (unsigned int) : member
// operator[](T *, std::ptrdiff_t) : built-in

The call can be ambiguous, because for the member, the second parameter needs a conversion, and for the built-in operator, the first needs a user defined conversion. The other two parameters match perfectly respectively. The call can be non-ambiguous in some cases (ptrdiff_t needs be different from int then).

Conversion function template

Templates allow some nice things, but better be very cautious about them. The following makes a type convertible to any pointer type (member pointers aren't seen as "pointer types").

struct test {
  template<typename T>
  operator T*() { return 0; }

void *pv = test();
bool *pb = test();
share|improve this answer
Nice explanation, thanks very much man :) If I understood what you are saying, then the reason why my code doesn't compile is because the ambiguity which arise due to the fact that both smartref and person has the dot operator. I think this is almost the same as your second example of Conversion to non class types, right ? – AraK Aug 20 '09 at 19:51
Actually, you might notice that nowhere does litb's code use the "." operator. And so I don't think it addresses your original question. – anon Aug 20 '09 at 20:31
@Neil his original question was "How do conversion operators work in C++? (i.e) when does the compiler try substituting the type defined after the conversion operator?". – Johannes Schaub - litb Aug 20 '09 at 20:36
From the original code: p.think(); // why does not the compiler try substituting Type&? Which is surely asking why p (the thing before the dot) is not converted. – anon Aug 20 '09 at 20:43
@AraK, as Neil says, there is no conversion applied when you do "x.y" - by design. Of course, allowing a conversion like that would have problems, which include the question whether to access smartref or person's members. But my answer did not focus on this "x.y" problem - i focused on showing other cases when the compiler uses conversion functions, because that's how i understood your main question. – Johannes Schaub - litb Aug 20 '09 at 20:44

The "." operator is not overloadable in C++. And whenever you say x.y, no conversion will automatically be be performed on x.

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+1 for the fact that '.' can't be overloaded. – AraK Aug 20 '09 at 23:28

Implicit conversion (whether by conversion operators or non-explicit constructors) occurs when passing parameters to functions (including overloaded and default operators for classes). In addition to this, there are some implicit conversions performed on arithmetic types (so adding a char and a long results in the addition of two longs, with a long result).

Implicit conversion does not apply to the object on which a member function call is made: for the purposes of implicit conversion, "this" is not a function parameter.

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Conversions aren't magic. Just because A has a conversion to B and B has a foo method doesn't mean that will call B::foo().

The compiler tries to use a conversion in four situations

  1. You explicitly cast a variable to another type
  2. You pass the variable as an argument to a function that expects a different type in that position (operators count as functions here)
  3. You assign the variable to a variable of a different type
  4. You use the variable copy-construct or initialize a variable of a different type

There are three types of conversions, other than those involved with inheritance

  1. Built-in conversions (e.g. int-to-double)
  2. Implicit construction, where class B defines a constructor taking a single argument of type A, and does not mark it with the "explicit" keyword
  3. User-defined conversion operators, where class A defines an operator B (as in your example)

How the compiler decides which type of conversion to use and when (especially when there are multiple choices) is pretty involved, and I'd do a bad job of trying to condense it into an answer on SO. Section 12.3 of the C++ standard discusses implicit construction and user-defined conversion operators.

(There may be some conversion situations or methods that I haven't thought of, so please comment or edit them if you see something missing)

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You should do


The compiler doesn't have the information for automatically casting to person, so you need explicit casting.

If you would use something like

person pers = p;

Then the compiler has information for implicit casting to person.

You can have "casting" through constructors:

class A
   A( int );

A a = 10; // Looks like a cast from int to A

These are some brief examples. Casting (implicit, explicit, etc) needs more to explain. You can find details in serious C++ books (see the questions about C++ books on stack overflow for good titles, like this one).

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This could be improved with C++ casts. – Alex Chamberlain Dec 12 '12 at 19:51

The compiler will attempt one(!) user-defined cast (implicit ctor or cast operator) if you try to use an object (reference) of type T where U is required.

The . operator, however, will always try to access a member of the object (reference) on its left side. That's just the way it's defined. If you want something more fancy, that's what operator->() can be overloaded for.

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It should be noted however that operator-> can only be defined as a member function, and therefore no conversions (user-defined or otherwise) will be applicable to the expression on the right side of ->. – Pavel Minaev Aug 20 '09 at 19:56
Yes, I know. But what he wanted (smart reference) is a sibling to the smart pointer which cannot be done in C++, since the . operator cannot be overloaded. That's why I pointed out operator->. I guess I wasn't very clear, though. – sbi Aug 21 '09 at 9:59

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