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I'm attempting to use std::unique_ptr in order to store the integer handle to some opaque objects. For this purpose, I have defined a custom deleter type which does typedef int pointer in order to override the raw pointer type to int instead of int*. This process is described in the last section of this site: http://asawicki.info/news_1494_unique_ptr_in_visual_c_2010.html

Here is some sample code to better illustrate what I'm attempting to do:

#include <memory>
#include <iostream>

static void close(int p)
    std::cout << p << " has been deleted!" << std::endl;

struct handle_deleter
    typedef int pointer;
    void operator()(pointer p) { close(p); }

typedef std::unique_ptr< int, handle_deleter> unique_handle;

int main(int argc, char *argv[])
    unique_handle handle(1);

    return 0;

When I compile this code using GCC 4.7.2, I get the following error:

In file included from /usr/lib/gcc/x86_64-redhat-linux/4.7.2/../../../../include/c++/4.7.2/memory:86:0,
                 from unique_ptr_test.cpp:1:
/usr/lib/gcc/x86_64-redhat-linux/4.7.2/../../../../include/c++/4.7.2/bits/unique_ptr.h: In instantiation of ‘std::unique_ptr<_Tp, _Dp>::~unique_ptr() [with _Tp = int; _Dp = handle_deleter]’:
unique_ptr_test.cpp:19:23:   required from here
/usr/lib/gcc/x86_64-redhat-linux/4.7.2/../../../../include/c++/4.7.2/bits/unique_ptr.h:172:2: error: invalid operands of types ‘int’ and ‘std::nullptr_t’ to binary ‘operator!=’

The code of the ~unique_ptr procedure reads as follows:

// Destructor.
~unique_ptr() noexcept
    auto& __ptr = std::get<0>(_M_t);
    if (__ptr != nullptr)
    __ptr = pointer();

According to me, the check against nullptr does not make sense since the raw pointer type is int (and not int* due to overriding it in HandleDeleter). Strangely enough, this code compiles with no error under GCC 4.6.1. Upon execution, the sample displays "1 has been deleted!" as expected.

I was wondering if there is any detail I'm overlooking or if it really is a bug within GCC's STL implementation of unique_ptr.



share|improve this question
Pro tip: First search the error in your code / understanding, and don't instantly blame the implementation to be "broken". Now, Deleter::pointer must fulfill the Nullable Pointer requirement. This includes comparision against nullptr, since std::unique_ptr is specified to only call the deleter if get() != nullptr. IOW, you'll just have to wrap your int and use that as the pointer type. –  Xeo Dec 28 '12 at 2:17
std::unique_ptr<T> means a pointer to T. There is no way to have std::unique_ptr<T>::pointer be int. In other words, you're forgetting the implicit asterisk applied to the first template argument. –  GManNickG Dec 28 '12 at 2:20
@Xeo: Why isn't that an answer! :-) –  Howard Hinnant Dec 28 '12 at 2:25
@Xeo: Thanks for the tip, although I can honestly say that I usually do what you mention (blame my own code first). I really meant "broken" in the sense that what used to compile correctly with a prior version of GCC now fails to compile due to some behaviour changes in the unique_ptr implementation. This applies to the code in the link I provided as well as similar code samples for unique_ptr I've seen on numerous websites. I confess to the bad choice of words, however. –  pmjobin Dec 28 '12 at 2:36
@GManNickG: This is purely a semantic issue. A handle is basically a special kind of opaque pointer. Beside, if one cannot use anything except T* for the raw pointer type, then why is it explicitly allowed to override the std::unique_ptr<T>::pointer typedef by using a custom deleter? –  pmjobin Dec 28 '12 at 2:52

1 Answer 1

up vote 7 down vote accepted

As I said in my comment, if the deleter type you pass has a nested pointer typedef, it must fulfill the NullablePointer requirements: [unique.ptr.single] p3

If the type remove_reference<D>::type::pointer exists, then unique_ptr<T, D>::pointer shall be a synonym for remove_reference<D>::type::pointer. Otherwise unique_ptr<T, D>::pointer shall be a synonym for T*. The type unique_ptr<T, D>::pointer shall satisfy the requirements of NullablePointer (

And § then lists all the requirements a type has to fulfill to be a NullablePointer. Certain semantics are listed in a table, where:

u denotes an identifier, t denotes a non-const lvalue of type P, a and b denote values of type (possibly const) P, and np denotes a value of type (possibly const) std::nullptr_t.

Expression    Return type                         Operational semantics
P u(np);                                          post: u == nullptr
P u = np;
P(np)                                             post: P(np) == nullptr
t = np        P&                                  post: t == nullptr
a != b        contextually convertible to bool    !(a == b)
a == np       contextually convertible to bool    a == P()
np == a
a != np       contextually convertible to bool    !(a == np)
np != a

Now, the simplest solution is to wrap your int in a type that provides these semantics:

#include <cstddef> // std::nullptr_t

struct handle{
  handle() : value(0){}
  handle(std::nullptr_t) : value(0){}
  /*explicit*/ handle(int v) : value(v){} // make it explicit if you need it
  // special members can be generated

  handle& operator=(std::nullptr_t){ value = 0; return *this; }

  // contextual conversion to bool
  explicit operator bool() const{ return value != 0; }

  int value;

bool operator==(handle lhs, handle rhs){ return lhs.value == rhs.value; }
bool operator!=(handle lhs, handle rhs){ return lhs.value != rhs.value; }
// comparision against 'nullptr' is handled by the above operators
// since 'nullptr' can be implicitly converted to 'handle'
share|improve this answer
Note that you may want to specifically handle comparision against nullptr after all, if 0 is a meaningful value for your handle. Or if you have any non-meaningful value, set value to that in the nullptr constructor. –  Xeo Dec 28 '12 at 10:18
Thank you for the in depth explanations. Now, I can clearly see why this approach is wrong. I thought I could save some work by using (coercing) std::unique_ptr to store the integer handles. Perhaps it would've been easier to implement unique_handle from scratch after all. :) –  pmjobin Dec 28 '12 at 15:34

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