I'd like to compare STL strings that are allocated with different allocators, e.g. an ordinary std::string with a string using a custom STL allocator. Unfortunately, it seems that usual operator==() doesn't work in this case:

// Custom STL allocator to allocate char's for string class
typedef MyAllocator<char> MyCharAllocator;

// Define an instance of this allocator
MyCharAllocator myAlloc;

// An STL string with custom allocator
typedef std::basic_string

std::string s1("Hello");
CustomAllocString s2("Hello", myAlloc);

if (s1 == s2)  // <--- ERROR: doesn't compile

In particular, MSVC10 (VS2010 SP1) emits the following error message:

error C2678: binary '==' : no operator found which takes a left-hand operand of type 'std::string' (or there is no acceptable conversion)

So, a lower-level (less readable) code like this:

if (strcmp(s1.c_str(), s2.c_str()) == 0)

should be used.

(This is also particularly annoying in cases where e.g. there are std::vector's of differently-allocated strings, where the usual simple v[i] == w[j] syntax can't be used.)

This doesn't seem very good to me, since a custom allocator changes the way string memory is requested, but the interface of a string class (including comparison with operator==()) is independent from the particular way a string allocates its memory.

Is there something I am missing here? Is it possible to keep the C++ high-level interface and operator overloads in this case?

  • 16
    Hey, look. A good question. Oct 9 '12 at 18:08

Use std::lexicographical_compare for less-than comparison:

bool const lt = std::lexicographical_compare(s1.begin(), s1.end(),
                                             s2.begin(), s2.end());

For equality comparison you can use std::equal:

bool const e = s1.length() == s2.length() &&
               std::equal(s1.begin(), s1.end(), s2.begin());

Alternatively, you can just fall back on strcmp (or actually memcmp, since that has the correct seman­tics; remember that the C++ string is more general than a C string), as you suggested, which can poten­tially employ some lower-level magic like comparing an entire machine word at a time (though the above algorithm may also be specialized thus). Measure and compare, I'd say. For short strings, the standard library algorithms are at least nicely self-descriptive.

Based on @Dietmar's idea below, you could wrap those functions into a templated overload:

#include <string>
#include <algorithm>

template <typename TChar,
          typename TTraits1, typename TAlloc1,
          typename TTraits2, typename TAlloc2>
bool operator==(std::basic_string<TChar, TTraits1, TAlloc1> const & s1,
                std::basic_string<TChar, TTraits2, TAlloc2> const & s2)
    return s1.length() == s2.length() &&
           std::equal(s1.begin(), s1.end(), s2.begin());

Usage example:

#include <ext/malloc_allocator.h>
int main()
    std::string a("hello");
    std::basic_string<char, std::char_traits<char>, __gnu_cxx::malloc_allocator<char>> b("hello");
    return a == b;

In fact, you could define such an overload for most standard containers. You could even template it on a template, but that would be extreme.

  • 4
    Another approach would be s1.compare(s2.c_str())
    – AFoglia
    Oct 9 '12 at 18:17
  • 2
    Seems like a reasonable workaround, but the question seems to be "Is it possible to keep the C++ high-level interface and operator overloads in this case?", not "how can I compare 2 such strings using other STL functions"
    – Rollie
    Oct 9 '12 at 18:33
  • 3
    @MarkRansom: No, why? All I care about is that the char types are the same so that I can compare them.
    – Kerrek SB
    Oct 9 '12 at 19:28
  • 2
    @KerrekSB: I think the issue is that the traits say how to compare the strings. I'm not sure how relevant that is here. Oct 9 '12 at 19:34
  • 2
    @Kerrek: But there's readability to be gained. You can just throw out the enable_if, since it's implied from charT being used for both strings.
    – Xeo
    Oct 9 '12 at 20:41

The standard only define operators using homogenous string types, i.e., all the template arguments need to match. However, you can define a suitable equality operator in the namespace where the allocator is defined: argument dependent look-up will find it there. If you choose to implement your own assignment operator, it would look something like this:

bool operator== (std::string const& s0,
                 std::basic_string<char, std::char_traits<char>, MyCharAllocator> const& s1) {
    return s0.size() == s1.size() && std::equal(s0.begin(), s0.end(), s1.begin()).first;

(plus a few other overloads). Taking this to next level, it may even be reasonable to define versions the various relational operators in terms of the container requirements and not restricting the template arguments:

namespace my_alloc {
    template <typename T> class allocator { ... };
    template <typename T0, typename T1>
    bool operator== (T0 const& c0, T1 const& c1) {
        return c0.size() == c1.size() && std::equal(c0.begin(), c0.end(), c1.end);

Obviously, the operators can be restricted to specific container types, differing only in their allocator template parameters.

With respect to why the standard doesn't define mixed type comparisons, the main reason behind not supporting mixed type comparison is probably that you actually don't want to mix allocators in your program in the first place! That is, if you need to use an allocator, you'd use an allocator type which encapsulates a dynamically polymorphic allocation policy and always use the resulting allocator type. The reasoning for this would be that otherwise you'd get either incompatible interface or you would need to make everything a template, i.e., you want to retain some level of vocabulary types being used. Of course, with using even just one additional allocator type, you'd have two vocabulary string types: the default instantiation and the instantiation for your special allocation.

That said, there is another potential reason to not support mixed type comparison: If operator==() really becomes a comparison between two values, as is the case if the allocators differ, it may give raise to a much broader definition of value equality: should std::vector<T>() == std::deque<T> be supported? If not, why would comparison between strings with different allocators be special? Of course, the allocator is a non-salient attribute of std::basic_string<C, T, A> which could be a good reason to ignore it. I'm not sure if mixed type comparison should be supported. It may be reasonable to support operators (this probably extends to other operators than operator==()) for container types differing only in their allocator type.

  • 5
    "If not, why would comparison between strings with different allocators be special?" Because they're both strings that store the same type of character. They may come from different memory, but the arrangement of that memory is the same. They operate on that memory in the exact same way, and the meaning of it is identical. By all rights, the allocator shouldn't even be part of the container's signature; the user of a type should neither know nor care where that type's memory comes from unless they have to. Oct 9 '12 at 18:35
  • 2
    "can be entirely different" That's my point: it shouldn't be. Just like the layout and implementation of std::shared_ptr doesn't change with allocators. Just like the layout and implementation of std::function doesn't change with allocators. This was a mistake by the C++ standards committee, one that they refuse to (or are unable to) fix. Oct 9 '12 at 18:49
  • 2
    @Nicol: You're missing that both shared_ptr and function need to resort to type erasure for that (yes, I know they already need that anyways, however, a container does not), which kinda necessitates dynamic memory allocation for objects bigger than two pointers (stateful allocators, anyone?). How would you allocate that memory? With the allocator you gave to the container? Nah, that's not what it should be used for. With yet another allocator that's passed (kinda like what shared_ptr's constructor can take)?
    – Xeo
    Oct 9 '12 at 18:55
  • 1
    std::function<T> and std::shared_ptr<T> both internally allocate some kind of object of some odd type. There is no extra overhead added by tying the allocation policy into this object. This isn't quite true for the various container types, although the preference would have been to remove allocators from the container interfaces. The proposal to remove allocators from the interface wasn't considered to be viable, however. Oct 9 '12 at 19:01
  • 1
    @DietmarKühl: in my particular case, the difference between std::string and std::basic_string<char, std::char_traits<char>, MyCharAllocator> is that MyCharAllocator is a pool allocator that just increases a pointer inside a big chunk of memory when it allocates. The string interface is the same (what changes is the way I get the memory for the string); I should be able to use a simple operator==() to do string comparisons; operator==() shouldn't care how I got the memory.
    – Mr.C64
    Oct 9 '12 at 19:11

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