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delete new std :: string [2];
delete [] new std :: string;

Everyone knows the first is an error. If the second wasn't an error, we wouldn't need two distinct operators.

Now consider:

std :: unique_ptr <int> x (new int [2]);
std :: unique_ptr <int> y (new int);

Does x know to use delete[] as opposed to delete?

Background: this question floated through my head when I thought array type qualification of pointers would be a handy language feature.

int *[] foo = new int [2]; // OK
int *   bar = new int;     // OK
delete [] foo;             // OK
delete bar;                // OK
foo = new int;             // Compile error
bar = new int[2];          // Compile error
delete foo;                // Compile error
delete [] bar;             // Compile error
share|improve this question
Instead of modifying the array type qualifier (which already exists) to work the way you show, it would be better to just eliminate all the implicit type conversions that cause all the problems with arrays. For example new int[2] ought to return a value of type int (*)[2]. Anyway, it's too late to fix all the problems with native arrays, but you can use std::array and avoid ever having to deal with them. std::array works like native arrays should work and you never have to use new[] or delete[]. – bames53 Jan 20 '12 at 19:46
@bames53, There is a limitation with std::array. You can do new int[n], but you can't do std::array<int,n>. (Unless n is known at compile time). But still, I avoid native arrays!# – Aaron McDaid Jan 22 '12 at 15:24
@AaronMcDaid Yeah, use std::vector if you need dynamic allocation. – bames53 Jan 23 '12 at 14:50
up vote 27 down vote accepted

Unfortunately, they don't know what delete to use therefore they use delete. That's why for each smart pointer we have a smart array counterpart.

std::shared_ptr uses delete
std::shared_array uses delete[]

So, your line

std :: unique_ptr <int> x (new int [2]);

actually causes undefined behavior.

Incidentally, if you write

std :: unique_ptr<int[]> p(new int[2]);

then delete[] will be used since you've explicitly requested that. However, the following line will still be UB.

std :: unique_ptr<int[]> p(new int);

The reason that they can't choose between delete and delete[] is that new int and new int[2] are exactly of the same type - int*.

Here's a related question of using correct deleters in case of smart_ptr<void> and smart_ptr<Base> when Base has no virtual destructor.

share|improve this answer
@tenfour: Because the types are exactly the same! – Armen Tsirunyan Jan 20 '12 at 11:51
@tenfour: (new int) and (new int[2]) both have type int*, there's no way to distinguish them for template specialization. – Fred Foo Jan 20 '12 at 11:51
I'm amazed nobody mentioned yet that we have no std::shared_array.. – Xeo Jan 20 '12 at 12:48
@spraff: Nope, shared_ptr has no specialization for T[]. – Xeo Jan 20 '12 at 14:22
-1: For talking about std::shared_array that doesn't exist. – Nicol Bolas Jan 20 '12 at 19:20

There is no "magical" way to detect whether a int* refers to:

  • a single heap allocated integer
  • a heap allocated array
  • an integer in a heap allocated array

The information was lost by the type system and no runtime method (portable) can fix it. It's infuriating and a serious design flaw (*) in C that C++ inherited (for the sake of compatibility, some say).

However, there are some ways of dealing with arrays in smart pointers.

First, your unique_ptr type is incorrect to deal with an array, you should be using:

std::unique_ptr<int[]> p(new int[10]);

which is meant to call delete[]. I know there is talk of implementing a specific warning in Clang to catch obvious mismatches with unique_ptr: it's a quality of implementation issue (the Standard merely says it's UB), and not all cases can be covered without WPA.

Second, a boost::shared_ptr can have a custom deleter which could if you design it to call the correct delete[] operator. However, there is a boost::shared_array especially designed for this. Once again, detection of mismatches is a quality of implementation issue. std::shared_ptr suffers the same issue (edited after ildjarn's remark).

I agree that it's not pretty. It seems so obnoxious that a design flaw (*) from the origins of C haunts us today still.

(*) some will say that C leans heavily toward avoiding overhead and this would have added an overhead. I partly disagree: malloc always know the size of the block, after all.

share|improve this answer
I think that the reason in C is a bit more complex. If dynamically allocated arrays yielded different types (as auto allocated do size being part of the type) then you could not write a strlen function to manage all liberals, for example, and there are no overloads in C. The alternative would be having a single array type that contained the size as a member, but that would make mapping hardware with arrays hard (were would you store the size? maintain size and a pointer to the data? that would leave us in square one: a pointer refers to either one or more elements...) – David Rodríguez - dribeas Jan 20 '12 at 13:05
BTW: I the list of options, don't forget that a pointer can also refer to auto or static memory, or shared memory, hardware addresses... Each of which has the two possibilities: array or single element (which can belong to an array) +1 – David Rodríguez - dribeas Jan 20 '12 at 13:08
C, having no function overloading and no templates, doesn't really need strict type distinctions as much as C++ does. – dan04 Jan 20 '12 at 15:32
@MatthieuM. I agree that in C++ it is a non-issue, and also that having a proper array type in C would have helped removing many bugs, but in a systems language you need to be able to access raw areas in memory as if they were arrays and do so without having to embed a size that might not fit the memory layout of the hardware. Now, that does not mean that there could not be an array type and a buffer (or raw_array) type. Then again, you might need to duplicate otherwise similar code to handle the two variants... I am not argueing, just bringing up potential design issues. – David Rodríguez - dribeas Jan 20 '12 at 18:04
@Matthieu You're making the mistake of assuming that the purpose of C is to be a high-level language that protects you from the consequences of poor programming. That is not true. C is there to make it less painful to write low-level code; some of the enormously nasty things you can do in C are there because they're needed to make complex apps work at all. (This was especially true on smaller machines where the cost of overheads could mean the difference between something that would fit in memory and something that wouldn't.) – Donal Fellows Jan 21 '12 at 10:00

std::unique_ptr is not meant for array as I quote latest boost document:

Normally, a shared_ptr cannot correctly hold a pointer to a dynamically allocated array. See shared_array for that usage.

If you want to memory management for array of pointer, you have a few options depend on your requirement:

  1. Use boost::shared_array
  2. Use std::vector of boost::shared_ptr
  3. Use boost pointer container like boost::ptr_vector
share|improve this answer
I suppose the mutual exclusion of member operator[](size_t) and operator*() would be a good clue. – spraff Jan 20 '12 at 14:17
You're backing up your claim about unique_ptr with a quote about shared_ptr. Weird. – sellibitze Jan 22 '12 at 14:57
std::unique_ptr is specialized for array types and will use delete[] if you specify one (e.g., std::unique_ptr<int[]>). std::vector is a better option though. I don't see any need for shared_array – bames53 Jan 23 '12 at 14:49

From Microsoft's documentation:

(A partial specialization unique_ptr<Type[]> manages array objects allocated with new[], and has the default deleter default_delete<Type[]>, specialized to call delete[] _Ptr.)

I added the two final square brackets, seems like a typo as it doesn't make sense without them.

share|improve this answer
Reading Armen Tsirunyan's answer, I don't know what to make of this. I'll let it stand, as an interesting point. Perhaps I'm missing something fundamental. – unwind Jan 20 '12 at 11:57
I think MSDN means that if you write shared_ptr<int[]> p(new int[2]) then delete[] will be used. But if you write shared_ptr<int> p (new int[2]) this will result in UB. – Armen Tsirunyan Jan 20 '12 at 12:00
I suppose you could write something like shared_ptr<int>i=shared_ptr<int>::allocate() and shared_ptr<int[]>i=shared_ptr<int[]>::allocate(n) and prohibit construction from raw pointers. (For your own shared_ptr, I mean.) – spraff Jan 20 '12 at 14:15
@ArmenTsirunyan: Didn't you mean to write "unique_ptr"? – sellibitze Jan 22 '12 at 14:55

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