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I want to use a template to convert between different sample types

template<class T,class U>
void convert(const T* source, U* dest, size_t n)
    {
    do
        {
        double G=double(max(*dest))/max(*source);
        T diff=max(*source) - min(*source);
        *dest=U(makeUnsigned(*source - min(*source))*G/makeUnsigned(diff)
              +makeUnsigned(max(*source) - *source)*double(min(*dest))/makeUnsigned(diff));

        ++dest;
        ++source;
        --n;
        }
    while(n!=0);
    }

Now, I want an auto-generated matrix so I can

convert[from][to](source,dest,n);

where each element reffers to the right version. I know that I have to cast function pointers here (each element needs to be pointer to function taking const void*,void* size_t which is equivalent anyway).

Can I do that?

share|improve this question
    
I don't understand. convert is a function; what is convert[from][to] supposed to do? Or do you mean convert<from, to>? –  Joseph Mansfield Apr 7 '13 at 13:10
    
@sftrabbit An auto-generated matrix of callable items so I do not need MxN cases in nested switch-case –  user877329 Apr 7 '13 at 13:12

1 Answer 1

First, write this:

template<typename T, typename U>
U convert( T const& src );

because everything else should be written with template metaprogramming. The nice thing about doing this is you can specialize your convert<int, double> and your convert<std::string, int> if you need to.

Next, write this:

template<typename T, typename U>
void convert_buffer( T const* src, U* dest, size_t n );

which simply calls convert above in a loop. I split this into two functions, because the possibly non-uniform code goes in convert, and calling a function with its body visible has basically zero overhead.

And then write this:

typedef void(*blind_converter)(void const*, void*, size_t);
template<typename T, typename U>
void convert_blind_buffer( void const* src, void* dest, size_t n ) {
  return convert_buffer( reinterpret_cast<T const*>(src), reinterpret_cast<U*>(dest), n );
}

which encapsulates the casting, and doesn't require you to do a theoretically invalid pointer type cast. It is "convert blind" a buffer -- blind, in that it takes void*s.

Next, we don't want to maintain your NxN array manually. A type to store your ordered list of types:

template<typename... Ts>
struct type_list {};

And then we write some metaprogramming to build the NxN array:

template<typename Src, typename DestList>
struct make_convert_one_way;
template<typename Src, typename... Ds>
struct make_convert_one_way< Src, type_list<Ds...> > {
  std::array< blind_converter, sizeof...(Ds) > operator()() const {
    return { convert_blind_buffer< Src, Ds >... };
  }
};

template<typename list>
struct make_convert_array;

template<typename... Ts>
struct make_convert_array< type_list<Ts...> > {
  std::array< std::array<blind_converter, sizeof...(Ts) >, sizeof...(Ts) > operator()() const {
    return { make_convert_one_way< Ts, type_list<Ts...> >... };
  }
};

typedef type_list< int, char, double > my_list;
auto convert_array = make_convert_array<my_list>()();

or something along those lines.

If your source and dest types are not uniform, the above would have to be modified to take two type_lists, but there isn't anything fundamentally difficult about it.

The next useful thing would be the ability to map from a type to an index in the above array, because maintaining that should be the compiler's job.

template<typename T, typename List, typename=void>
struct index_of;
template<typename T, typename T0, typename... Ts>
struct index_of<T, type_list<T0, Ts...>, typename std::enable_if<
  std::is_same<T, T0>::value
>::type >: std::integral_constant< std::size_t, 0 > {};
template<typename T, typename T0, typename... Ts>
struct index_of<T, type_list<T0, Ts...>, typename std::enable_if<
  !std::is_same<T, T0>::value
>::type >: std::integral_constant< std::size_t, index_of<T, type_list<Ts...>::value+1 > {};

which lets you do this:

static_assert( index_of< int, my_list >::value == 0, "all is well!" );

Now, you might want to wrap this up in some type dressing. A strategy might look like this:

template<typename List>
struct EnumDressing;
template<typename... Ts>
struct EnumDressing<type_list<Ts...>> {
  enum type {
    e_begin = 0,
    e_end = sizeof...(Ts),
  };
  template<typename T>
  static constexpr type value() {
    return static_cast<type>( index_of<T, type_list<Ts...> >::value );
  }
};

where we have the EnumDressing<my_list>::type as the type of an enum that represents integer names for your types, and the values of it can be gotten via EnumDressing<my_list>::value<int>(). Naturally you clean this up with typedefs:

typedef EnumDressing<my_list> Types;
typedef Types::type eType;

struct typed_array {
  eType type;
  void* buff;
  size_t n;
};
void do_convert( typed_array src, typed_array dst) {
  Assert(src.n == dst.n);
  convert_array[ src.type ][ dst.type ]( src.buff, dst.buff, std::min( src.n, dst.n ) );
}
template<typename T, size_t N>
typed_array make_typed_array( T (&arr)[N] ) {
  return { Types::value<T>(), reinterpret_cast<void*>( &arr[0] ), N };
}

int main() {
  double d[100];
  int i[100];
  do_convert( make_typed_array( d ), make_typed_array( i ) );
}

with naturally actual use cases separating the creation of the typed_array from its use.

share|improve this answer
    
I need to learn more about variadic templates... –  user877329 Apr 7 '13 at 14:45

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