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I've been playing around with C++0x's auto keyword and tried the following.

std::unique_ptr<auto> ptr(new int(0));

I tried compiling it with g++ 4.4.5 and got

error: invalid use of auto

Judging by eye, auto can easily be inferred to int.

My guess is the type inference and the template engine don't talk to each other. Otherwise, the template engine would know to instantiate the template class with int as the type parameter.

Another guess is from the standard, I see this.

A member shall not be declared with auto, extern or register storage class.

But I thought that was the auto as in local variables, not as in auto used to deduce types.

And my last guess is that the compiler thinks this is an auto storage class, not auto for type deduction.

Is there a reason behind this stated in the standard?

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Note: that quote "a member shall not..." is not from C++0X. auto is not a storage class specifier in that standard. N3290: "A member shall not be declared with the extern or register storage-class-specifier." –  Mat Jul 27 '11 at 20:59
It could also be std::unique_ptr<int[]> ptr(new int(0));, so your proof of concept is wrong. –  GManNickG Jul 27 '11 at 21:00
@GMan: Are you sure. Note it is a single value. –  Loki Astari Jul 27 '11 at 21:05
@Martin: Both std::unique_ptr<int> and std::unique_ptr<int[]> have a constructor taking an int*. Note that even new int[100000000] still just looks like an int* after the fact. This problem is fundamental to the language. The solution would require arrays truly be there own type, so dynamically allocated arrays would be an array type, not a pointer type. And this is just talking about std::unique_ptr<auto>(...), who knows about the general case of the problem. –  GManNickG Jul 27 '11 at 21:10
@Thomas : That's true in C++03, but not C++0x. –  ildjarn Jul 27 '11 at 21:52

4 Answers 4

up vote 5 down vote accepted

@dascandy has correctly identified what's wrong with your code. I'll try to provide some rationale:

You're expecting the compiler to infer unique_ptr<int> because the argument is an int*, and unique_ptr<int> has a constructor which accepts int*. For a moment let's ignore the fact that we're using std::unique_ptr, and just talk about a template class we wrote (and can specialize).

Why should the compiler infer unique_ptr<int>? The argument isn't int, it's int*. Why shouldn't it guess unique_ptr<int*>? Of course that would result in a compiler error, since unique_ptr<int*>'s constructor won't accept an int*. Unless I add a specialization:

class unique_ptr<int*>
    unique_ptr(int*) {}

Now unique_ptr<int*> would compile. How should the compiler know which to choose, unique_ptr<int> or unique_ptr<int*>? What if I add another specialization?

class unique_ptr<double>
    unique_ptr(int*) {}

The compiler now has three options to choose from, and it has to instantiate the template with every possible argument in order to find them. Clearly this is not feasible, especially with multiple template arguments and template recursion.

What you can do, is make a factory function which connects the inferred type to exactly one template instance:

template<typename T>
std::unique_ptr<T> make_unique(T* arg) { return arg; }

(of course, this won't work because unique_ptr cannot be copied. But the idea is valid, and used in e.g.make_shared and make_pair.)

Some examples of extreme ugliness:

One could argue that unique_ptr<shared_ptr<int>> is a valid match for this code.

Or how about:

template<typename T>
class unique_ptr
    explicit unique_ptr(T* arg);
    unique_ptr(int*, enable_if<(sizeof(T) > 16)>::type* = 0);
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"and it has to instantiate the template with every possible argument in order to find them" No, because it already knows what specializations exist. That said, it's ambiguous in the general case, as two specializations could each have template constructors, so neither is preferable. It's doable for some class templates, but I suspect it would only work some of the time in the general case. If a complex feature should be added to the language, it should work most or all of the time; so like you said, too complex to be feasible. –  GManNickG Jul 27 '11 at 21:05
template<typename T> std::unique_ptr<T> make_unique(T* arg) { return std::unique_ptr<T>(arg); } would work just fine, since unique_ptr is movable (but its constructor is explicit). –  ildjarn Jul 27 '11 at 21:10
@GMan: Consider partial specialization and template recursion... the number of specializations potentially introduced is unbounded. What about a template using enable_if and a type trait? In the general case, the compiler has to instantiate with every possible argument. –  Ben Voigt Jul 27 '11 at 21:11
@Ben: There's still always a finite number of specializations to check. If that weren't the case the compiler wouldn't be able to process them at all. –  GManNickG Jul 27 '11 at 21:12
@GMan: Right now, there's a finite number of specializations to check, because the template argument is provided by the programmer. –  Ben Voigt Jul 27 '11 at 21:14

That's because it has to determine the class on which to call a constructor before determining what to do with its arguments. If you make the constructor a template, it'll just work like any other template function - auto-deducing arguments.

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Correct -- type deduction doesn't work for template classes. Usually you end up using a factory function as a workaround, e.g. auto ptr(make_unique(new int(0))); –  Ben Voigt Jul 27 '11 at 20:56

Just want to add that a solution already exists for most cases:

template <typename T>
std::unique_ptr<T> unique_ptr_auto(T* ptr)
    // fails to handle std::unique_ptr<T[]>, not deducible from pointer
    return std::unique_ptr<T>(ptr);

auto ptr = unique_ptr_auto(new int(0));

A bit more verbose, obviously, but you get the idea. These "generator functions" are quite common.

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unique_ptr isn't copyable, is it? –  Ben Voigt Jul 27 '11 at 21:09
@Ben : It's movable. –  ildjarn Jul 27 '11 at 21:11
@Ben Voigt: No, it isn't, but it doesn't have to be for this particular code sample to operate correctly. –  Puppy Jul 27 '11 at 21:11

This (or similar) was proposed for the Standard. The proposed functionality looked something like:

std::vector<int> GetMahVector();
std::vector<auto> var = GetMahVector();

However, it was rejected. Why it was rejected, well, you'd have to dig up the relevant Standard process documents, if possible.

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Ah, so it is actually documented somewhere. Thank you! –  Russell Jul 27 '11 at 21:20
This restricted version wouldn't be very useful, you can already say auto var = GetMahVector(); –  Ben Voigt Jul 27 '11 at 22:12
@BenVoigt would definitely be useful for redability in some case –  log0 Oct 31 '14 at 10:29
The current proposal (for C++17) for this syntax is open-std.org/jtc1/sc22/wg21/docs/papers/2015/n4377.pdf . The proposal contains a whole of things all related to templates, but this syntax is buried in there as well. –  David Stone Mar 23 at 3:36

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