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my problem is the following: I have a C library which contain several versions of each function according to which data type they are working with e.g.:

void add(double *a, double *b, double *c);

and

void sadd(float *a, float *b, float *c);

Now, having an external C++ template function, I would like to be able to do something like:

template<class T>
void myfunc(/*params*/)
{
 // Obtain a,b,c of type T* from params

/*
 If T is double call add(a,b,c);
 else if T is float call sadd(a,b,c).
*/ 
}

I am aware that It can be done by specialized template functions like:

template<>
void myfunc<double>(/*params*/)
{
  // Obtain a,b,c of type double* from params
  add(a,b,c);
}

and so on, but it is not really an option since the whole point of introducing the templated C++ function was to reduce code repetition and the "// Obtain a,b,c of type T* from params" part can be really long.

Does this problem have a simple solution?

Thanks

Zdenek

share|improve this question
    
you can use polymorphism functions –  MOHAMED Apr 18 '13 at 17:04
1  
The short answer is no. If the code was all C++, so you overloaded add for double * and float * params, that would work, but with "hand overloading" using separate names for each, you're also going to have to generate the calling code for each separately. –  Jerry Coffin Apr 18 '13 at 17:06
    
The point of templates here is not just "to reduce code". The most important part here is type deduction. –  Named Apr 18 '13 at 17:09
    
Or you can use function pointers (with downsides). But you'll have to list (repeat) the names of the C functions somewhere in your code. –  dyp Apr 18 '13 at 17:09
    
Yes, that was what I was afraid of. I think I can do simple C++ template wrapper for the C library. –  Zdenek Prusa Apr 18 '13 at 17:11

2 Answers 2

up vote 8 down vote accepted

Define overloaded C++ forwarders:

inline void forward_add(double *a, double *b, double *c) { add( a, b, c ); }
inline void forward_add(float *a, float *b, float *c) { sadd( a, b, c ); }

template<class T>
void myfunc(/*params*/)
{
   // Obtain a,b,c of type T* from params
   forward_add( a, b, c );
}
share|improve this answer
    
Might be worthwhile to pass by const reference to the templated function. –  Captain Obvlious Apr 18 '13 at 17:13
    
@CaptainObvlious Not in case of the OPs C functions. There might be other cases where this should be considered, but here it wouldn't make any difference. –  Daniel Frey Apr 18 '13 at 17:15
    
Well, the myfunc should not be even aware of sadd, as it requires adding more boilerplate code when adding support for more data types and I need something universal for all functions from the C library. –  Zdenek Prusa Apr 18 '13 at 17:19
    
@DanielFrey True. If he needs to deal with rvalues he can just overload myfunc and go about his merry way. –  Captain Obvlious Apr 18 '13 at 17:20
    
@ZdenekPrusa myfunc is only aware of forward_add, you just limit the visibility of sadd to the one-line forwarder. You will have to specify sadd somewhere. Or maybe I don't fully understand your requirements... :-/ –  Daniel Frey Apr 18 '13 at 17:23

Somewhere you have to tell the compiler that sadd and add are related.

One approach is a traits class template struct math;

template<>
struct math<double> {
  static void add(double *a, double *b, double *c) {
    return ::add(a, b, c);
  }
};
template<>
struct math<float> {
  static void add(float*a, float*b, float*c) {
    return ::sadd(a, b, c);
  }
};

where you use it like:

template<class T>
void myfunc(/*params*/)
{
  // Obtain a,b,c of type T* from params

  math<T>::add( a, b, c );
}

this has the advantage and disadvantage of putting all of your type-based refactoring into one spot.

Another approach is to create free standing C++ functions with overloads for double and float. This has the advantage and disadvantage of allowing your code to be spread over multiple spots.

void math_add( double* a, double* b, double* c ) {
  add(a,b,c);
}
void math_add( float* a, float* b, float* c ) {
  sadd(a,b,c);
}

Now, suppose all of your functions share the same pattern of name -- foo for double and sfoo for float. In that case, text based code generation can be used to ease some of the above "write an overload" code.

The only issue here is that the signatures of the functions can vary. If there are only a handful, simple macros would work:

#define MAKE_FUNCS( f ) \
  void CONCAT( math_, f ) ( double* a, double* b, double * c ) { \
    f ( a, b, c ); \
  } \
  void CONCAT( math_, f ) ( float* a, float* b, float* c ) { \
    CONCAT( f, s ) ( a, b, c ); \
  }

then just spam out MAKE_FUNCS for each function in your library you are trying to clone this way.

A downside (among many) is that it only supports a fixed set of signatures. We can fix this via perfect forwarding, a C++11 technique:

#define MAKE_FUNCS( f ) \
  template< typename... Args >\
  auto f ( Args&&... args ) \
    -> decltype(::f ( std::forward<Args>(args)... )) \
  { \
    ::f ( std::forward<Args>(args)... ); \
  } \
  template< typename... Args >\
  auto f ( Args&&... args ) \
    -> decltype(:: CONCAT( f, s ) ( std::forward<Args>(args)... )) \
  { \
    :: CONCAT( f, s ) ( std::forward<Args>(args)... ); \
  }

but this runs into SFINAE and identical signature problems. You can fix this by explicit expression SFINAE:

#include <utility>
#include <type_traits>
#include <cstddef>
#include <iostream>

#define CONCAT2( a, b ) a##b
#define CONCAT( a, b ) CONCAT2(a,b)

// SFINAE helper boilerplate:
template<typename T> struct is_type:std::true_type {};
template<std::size_t n> struct secret_enum { enum class type {}; };
template<bool b, std::size_t n>
using EnableIf = typename std::enable_if< b, typename secret_enum<n>::type >::type;

// Macro that takes a srcF name and a dstF name and an integer N and
// forwards arguments matching dstF's signature.  An integer N must be
// passed in with a distinct value for each srcF of the same name:
#define FORWARD_FUNC( srcF, dstF, N ) \
template< typename... Args, \
  EnableIf< is_type< \
    decltype( dstF ( std::forward<Args>(std::declval<Args>())... )) \
  >::value , N >... > \
auto srcF ( Args&&... args ) \
  -> decltype(dstF ( std::forward<Args>(args)... )) \
{ \
  dstF ( std::forward<Args>(args)... ); \
}

#define MAKE_FUNCS( f ) \
  FORWARD_FUNC( f, ::f, 0 ) \
  FORWARD_FUNC( f, :: CONCAT( f, s ), 1 )

void add( double* a, double* b, double* c) {*a = *b+*c;}
void adds( float* a, float* b, float* c) {*a = *b+*c;}
namespace math {
  MAKE_FUNCS(add)
}
int main() {
  double a, b = 2, c = 3;
  float af, bf = 3, cf = 5;
  math::add( &a, &b, &c );
  math::add( &af, &bf, &cf );
  std::cout << a << "=" << b << "+" << c << "\n";
  std::cout << af << "=" << bf << "+" << cf << "\n";
}

but as you can see, this is getting pretty obtuse, and there are not many compilers that can handle this level of C++11isms at this point. (I think the above should compile in gcc 4.8 and intel's latest, but not MSVC or clang 3.2)

Now you simply take each function in your library, and do a header file consisting of a pile of single-line boilerplate:

namespace mymath {
  MAKE_FUNCS( add )
  MAKE_FUNCS( sub )
  MAKE_FUNCS( chicken )
}
#undef MAKE_FUNCS

which you then call by saying mymath::add instead of add or adds.

This could also be done by other forms of textual code generation.

share|improve this answer
    
In your first MAKE_FUNCS macro, shouldn't the second function have float parameters? –  dyp Apr 18 '13 at 18:15
    
@DyP fixed! Thanks –  Yakk Apr 18 '13 at 18:18
    
@Yakk Thanks. Very thorough, but I got lost with the C++11... –  Zdenek Prusa Apr 18 '13 at 20:34
    
@ZdenekPrusa ya, it is a bit of a mess: Macros creating C++11 perfect forwarding SFINAE functions. I would avoid it as a solution, simply because nobody could figure out what it was doing... The only plus side is that, after all the hackery, the code that uses the hackery looks pretty. :) –  Yakk Apr 18 '13 at 20:47
    
@ZdenekPrusa made the template spew more understandable, and commented! –  Yakk Apr 18 '13 at 20:53

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