I'm building a series of predicates that duplicate lots of code, and so are being changed into a single template function class based on the std::unary_function
. The idea is that my class interface requires methods such as Element_t Element()
and std::string Name()
to be defined, so the predicate template arguments are the object type and a value type to which comparison will be made as follows:
// generic predicate for comparing an attribute of object pointers to a specified test value
template <class U, typename R>
class mem_fun_eq : public std::unary_function <U*, bool> {
private:
typedef R (U::*fn_t)();
fn_t fn;
R val;
public:
explicit mem_fun_eq (fn_t f, R& r) : fn(f), val(r) { }
bool operator() (U * u) const {
return (u->*fn)() == val;
}
};
Thus, if I have:
class Atom {
public:
const Element_t& Element() const { return _element; }
const std::string& Name() const { return _name; }
};
I would like to perform a search on a container of Atom
s and check for either the Name
or Element
equality using my template predicate like so:
typedef std::string (Atom::*fn)() const;
Atom_it it = std::find_if( _atoms.begin(), _atoms.end(), mem_fun_e开发者_Go百科q <Atom, std::string> ((fn)&Atom::Name, atomname));
but compiling this returns the following error on the std::find_if
line:
error: address of overloaded function with no contextual type information
Also, trying to form the same predicate for a check of the Element()
as such:
typedef Atom::Element_t& (Atom::*fn)() const;
Atom_it it = std::find_if(_atoms.begin(), _atoms.end(), mem_fun_eq <Atom, Atom::Element_t> ((fn)&Atom::Element, elmt);
creates a different error!
error: no matching function for call to ‘mem_fun_eq<Atom, Atom::Element_t>::mem_fun_eq(Atom::Element_t& (Atom::*)()const, const Atom::Element_t&)’
note: candidates are: mem_fun_eq<U, R>::mem_fun_eq(R (U::*)(), R&) [with U = Atom, R = Atom::Element_t]
note: mem_fun_eq<Atom, Atom::Element_t>::mem_fun_eq(const mem_fun_eq<Atom, Atom::Element_t>&)
Firstly, am I reinventing the wheel with this predicate? Is there something in the STL that I've missed that does the same job in a single class? I can always break the predicate down into several more specific ones, but I'm trying to avoid that.
Secondly, can you help me with the compiler errors?
I don't know of any easy way to do this using the bits provided with the STL. There is probably some clever boost way, using iterator adapters, or boost::lambda, but personally I wouldn't go that way.
Obviously C++0x lambdas will make all this easy.
Your problem is attempting to cast a function like this:
const std::string&(Atom::*)()
into a function like this:
std::string (Atom::*)()
If you replace your typedef R (U::*fn_t)();
with typedef const R& (U::*fn_t)() const;
then it should work.
The following avoids this problem and also provides type inference so that you can just write mem_fun_eq(&Atom::Name, atomname)
. It compiles for me, although I haven't tested it.
template<typename U, typename R, typename S>
class mem_fun_eq_t : public std::unary_function<U const*, bool>
{
private:
R (U::*fn_)() const;
S val_;
public:
mem_fun_eq_t(R (U::*fn )() const, S val) : fn_(fn), val_(val){}
bool operator()(U * u)
{
return (u->*fn_)() == val_;
}
};
template<typename U, typename R, typename S>
mem_fun_eq_t<U, R, S> mem_fun_eq(R (U::*fn)() const, S val)
{
return mem_fun_eq_t<U, R, S>(fn, val);
}
Have you thought of trying to mix in a mem_fun_ref
or mem_fun
object in place of the member function call?
Basically, you call on mem_fun
to create an object that accepts two arguments T*
and a template argument to the function A
if it has one (or void if it doesn't). Hence you combine it like so:
template<typename MemFunc, typename CompareType, typename T>
struct MyPredicate{
MyPredicate(MemFunc _functionObj, CompareType _value)
: m_Value(_value),
m_Function(_functionObj){}
bool operator()(const T &_input){
return m_Value == m_Function(_input);
}
private:
MemFunc m_Function;
CompareType m_Value;
};
Edit:
Ok, that's not completely working so why not have:
struct NamePred: binary_function<Atom*,string,bool>{
bool operator()(Atom *_obj, string _val){
return _obj->Name() == _val;
};
};
then use bind2nd
find_if( atoms.begin(), atoms.end(), bind2nd( NamePred, "yo" ) );
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