Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I'm trying to define a class template that can do some input/output operations (via operators << and >> from another class) on many data structures.

In short, I can do for example :

vector<int> x;
map<string,vector<vector<int>>> y;
const int z = 42;

FooStream fs;

Foo<decltype(x)> fx(x);
Foo<decltype(y)> fy(y);
Foo<decltype(z)> fz(z);

fs << fx << fy << fz >> fy >> fx;

My question is how can I reach this :

vector<int> x;
map<string,vector<vector<int>>> y;
const int z = 42;

FooStream fs;

fs << x << y << z >> y >> x;
//error : no operator found which takes a right-hand operand of type 'std::vector<_Ty>' (or there is no acceptable conversion)

FooStream::operator<< and >> should accept ever type T when the specialization Foo< T> is defined.

For more details, here's my (simplified) code.

class FooBase1{
protected:
    union p_type{const void *p1;void *p2;} p;
public:
    FooBase1(const void *v){p.p1 = v;};
    virtual void func1_() = 0;
};

class FooBase2 : public FooBase1{
public:
    FooBase2(void *v) : FooBase1(v){};
    virtual void func2_() = 0;
};

template<typename T,typename Enable=void>
class Foo{
public:
    typedef void generic;
};

template<typename T,typename E=void> struct is_generic                             : std::false_type{};
template<typename T>                 struct is_generic<T,typename Foo<T>::generic> : std::true_type {};

template<typename T,typename T2=void> struct enable_if_ng  : enable_if<!is_generic<T>::value,T2> {};

template<typename T> struct get_foo_type          {};
template<typename T> struct get_foo_type<Foo<T> > {typedef T type;};

#define DECLARE_FOO_SPECIALIZATION(Type)\
template<>\
class Foo<Type> : public FooBase2{\
public:\
    Foo(Type &v) : FooBase2(&v){}\
    virtual void func1_(){func1(*(const Type *)p.p2);}\
    virtual void func2_(){func2(*(Type *)p.p2);}\
    static void func1(const Type&){/*user defined*/}\
    static void func2(Type&){/*user defined*/}\
};
    //friend FooStream& operator>>(FooStream& fs,Type &f){Foo<Type>(f).func2_();return fs;} doesn't work

DECLARE_FOO_SPECIALIZATION(bool)
DECLARE_FOO_SPECIALIZATION(int)
DECLARE_FOO_SPECIALIZATION(long)
DECLARE_FOO_SPECIALIZATION(float)
DECLARE_FOO_SPECIALIZATION(double)
DECLARE_FOO_SPECIALIZATION(string)

template<typename T1>
class Foo<vector<T1>,typename enable_if_ng<T1>::type> : public FooBase2{
public:
    Foo(vector<T1> &v) : FooBase2(&v){}
    virtual void func1_(){func1(*(const vector<T1> *)p.p2);}
    virtual void func2_(){func2(*(vector<T1> *)p.p2);}
    static void func1(const vector<T1>&){/*user defined*/}
    static void func2(vector<T1>&){/*user defined*/}
};

template<typename T1,typename T2>
class Foo<map<T1,T2>,typename enable_if<!is_generic<T1>::value && !is_generic<T2>::value>::type> : public FooBase2{
public:
    Foo(map<T1,T2> &v) : FooBase2(&v){}
    virtual void func1_(){func1(*(const map<T1,T2> *)p.p2);}
    virtual void func2_(){func2(*(map<T1,T2> *)p.p2);}
    static void func1(const map<T1,T2>&){/*user defined*/}
    static void func2(map<T1,T2>&){/*user defined*/}
};

template<typename T1>
class Foo<const T1,typename enable_if_ng<T1>::type> : public FooBase1{
public:
    Foo(const T1 &v) : FooBase1(&v){}
    virtual void func1_(){func1(*(const T1 *)p.p1);}
    static void func1(const T1& v){Foo<T1>::func1(v);}
};

class FooStream{
public:
    FooStream(){};
    FooStream& operator<<(FooBase1 &f){f.func1_();return *this;};
    FooStream& operator>>(FooBase2 &f){f.func2_();return *this;};
};

(Additional questions : can I replace my macro DECLARE_FOO_SPECIALIZATION by something prettier with templates ? Should I change my class hierarchy ?)

Thank you.

share|improve this question
    
Maybe you can try to use parenthesis to order the evaluation. –  0x499602D2 Apr 23 '13 at 23:15
    
Post name needs fixing up. It's not related to the post. –  Mr Universe Apr 23 '13 at 23:22
    
@0x499602D2 : the operators << and >> are evaluated from left to right. But I have the same error message when I put only 1 parameter. –  Gilles Apr 23 '13 at 23:42
    
@Mr Universe : sorry I've just changed it, but do you have a better suggestion ? –  Gilles Apr 23 '13 at 23:49
1  
@Gilles to see if I understand the question before writing an answer, is it something like this you are looking for? IF a specialization of template<typename T> struct FooObj; is present you are allowed to pass a T to FooStream::operator<</>> –  Filip Roséen - refp Apr 24 '13 at 0:58

1 Answer 1

up vote 1 down vote accepted

This EnableIf doesn't work in many compilers, but you can use a more crude SFINAE trick there:

template<std::size_t n>
struct secret_enum { enum class type {}; };
template<bool b, std::size_t n = 0>
using EnableIf = typename std::enable_if< b, typename secret_enum<n>::type >::type;

template<typename T, bool b=true>
struct can_be_fooed : std::false_type {};
template<typename T>
struct can_be_fooed<T, std::is_same<Foo<T>, Foo<T>>::value>:std::true_type {};

class FooStream{
public:

  template<typename T, EnableIf<can_be_fooed<typename std::decay<T>::type>>...>
  FooStream& operator<<(T&&t){
    // body of <<, possibly involving wrapping the t in a Foo<T>?
  };
};

When testing this kind of code, stop doing 15 things on one line when the first one would fail. Test things a single step at a time. With template meta programming, you are debugging the compilation step -- by compiling things in byte sized chunks and checking at each step, you are doing the equivalent of stepping through your code.


Instead of your macro, create a traits class where the elements in question are the only ones that have a true. Then just use SFINAE to write one template that is turned on for only those types. Same number of lines of code, but no code generated by macro.

template<typename T> struct do_stuff : std::false_type {};
template<> struct do_stuff<int> : std::true_type {};
template<> struct do_stuff<bool> : std::true_type {};
// yada yada

template<typename T>
class Foo<T, typename=typename std::enable_if< do_stuff<T>::value >::type> : public FooBase2 {
public:
  Foo(T &v) : FooBase2(&v){}
  virtual void func1_(){func1(*(const T *)p.p2);}
  virtual void func2_(){func2(*(T *)p.p2);}\
  static void func1(const T&){/*user defined*/}\
  static void func2(T&){/*user defined*/}\
};
share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.