10

Is there an idiom for a strict typedef in C++, possibly using templates?

Something like:

template <class base_type, int N> struct new_type{
    base_type p;
    explicit new_type(base_type i = base_type()) : p(i) {}
};

typedef new_type<int, __LINE__> x_coordinate;
typedef new_type<int, __LINE__> y_coordinate;

So I can make something like this a compile time error:

x_coordinate x(5);
y_coordinate y(6);

x = y; // whoops

The __LINE__ in there looks like it might be trouble, but I'd prefer not to have to manually create a set of constants merely to keep each type unique.

4
  • 1
    Coordinates are not a very good application for this. A product of two coordinates is not a coordinate, etc. You may want to look at Boost.Units instead. Feb 21, 2013 at 15:40
  • 3
    I deleted my answer which suggested BOOST_STRONG_TYPEDEF, because apparently that works for overload resolution but does not generate compilation errors on cross-assignment. Feb 21, 2013 at 15:42
  • I question the value of what you want to do. What happens when you want to perform a rotation for example? x = sin(theta)*y + cos(theta)*x should be entirely valid. Feb 21, 2013 at 16:46
  • this is mostly needed for base_type == int, but if casting to/from int are provided, the whole purpose is lost. The solution is to provide only either 'to' or 'from' casting, and do the other side using a fn
    – vrdhn
    Aug 4, 2014 at 6:48

3 Answers 3

7

I'm using something similar in my project. Only I use type tagging instead of int. Works well in my particular application.

template <class base_type, class tag> class new_type{     
  public:   
    explicit new_type(base_type i = base_type()) : p(i) {}

    //
    // All sorts of constructors and overloaded operators
    // to make it behave like built-in type
    //

  private:
     base_type p;
};

typedef new_type<int, class TAG_x_coordinate> x_coordinate;
typedef new_type<int, class TAG_y_coordinate> y_coordinate;

Note that TAG_* classes don't need to be defined anywhere, they are just tags

x_coordinate x (1);
y_coordinate y (2);

x = y; // error
3
  • I think this would look nicer with a simple "#define new_type(base, tag) typedef new_type<##base, class TAG_##tag> tag;"
    – slacy
    Mar 13, 2013 at 23:55
  • 2
    @slacy dunno, I find macros ugly and avoid them
    – user1773602
    Mar 14, 2013 at 11:25
  • Macros aren't just ugly; they also cause problems due to not obeying scope. They're a last resort for me. (If you want to use it for something like this, consider using #undef afterwards. However, this can cause other problems if someone else defined that macro because you'll undefine theirs. So then you want to check to make sure no one else defined a macro by the same name. Etc. etc.)
    – Keith M
    Dec 20, 2018 at 23:33
2

No. There are proposals for it to go into the next standard (C++14, or perhaps C++17), but not in C++11.

5
  • 1
    -1: He didn't ask whether it's in the language, and there are ways to do it in "user space". Therefore, this answer is incorrect. Feb 21, 2013 at 15:26
  • There are no ways to do it in user space that are the same as the language feature being proposed.
    – Puppy
    Feb 21, 2013 at 18:34
  • What about that are the same as what is stated in the question? Now that Angew's answer has been invalidated I am open to the possibility, but require your input here. Feb 21, 2013 at 20:00
  • Because the new_type doesn't actually behave like it's original type in many scenarios. For example, you can't do new_type<std::string, ...>().c_str();.
    – Puppy
    Feb 22, 2013 at 14:30
  • @Puppy The question doesn't mention C++11 specifically, but I see your answer was written in 2013. Would you consider updating it? (Did something make it in?)
    – Keith M
    Dec 20, 2018 at 23:30
0

With C++11:

#include <stdio.h>

struct dummy {};

struct NotMineType
{
    NotMineType(dummy) {}
};

template <int N>
struct type_scope
{
    struct MyOwnType
    {
    };

    struct ConvertedToMineType : NotMineType
    {
        template <typename ...Args>
        ConvertedToMineType(Args... args) : NotMineType(args...) {};
    };

    enum myint : int {};
};

typedef type_scope<0>::MyOwnType x1;
typedef type_scope<1>::MyOwnType x2;

typedef type_scope<0>::ConvertedToMineType y1;
typedef type_scope<1>::ConvertedToMineType y2;

typedef type_scope<0>::myint i1;
typedef type_scope<1>::myint i2;

void foo(x1) { printf("x1\n"); }
void foo(x2) { printf("x2\n"); }
void foo(y1) { printf("y1\n"); }
void foo(y2) { printf("y2\n"); }
void foo(i1) { printf("i1\n"); }
void foo(i2) { printf("i2\n"); }

int main()
{
    foo(x1());
    foo(x2());
    foo(y1(dummy()));
    foo(y2(dummy()));
    foo(i1());
    foo(i2());
}

Output:

x1
x2
y1
y2
i1
i2

Compilers:

Visual Studio 2015, GCC 4.8.x

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