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I want make a class method that take std::vector reference as an argument. I want to use it with different types of data.

so I want to make function like:

void some_function(const std::vector & vect){ //do something with vector }

and I want use it with for example:

std::vector<int> v1;
some_function(v1);
std::vector<string> v2;
some_function(v2);

I hope that I made my point clear. Do I have to make template method like that:

template<class T>
void some_function(std::vector<T> & vect){}

or I can do it in other way? If I have to, tell me how I can write that method in class

Thanks for help!

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Yes, that's the way to do it. Or are you asking something else? –  jrok Sep 30 '13 at 12:31
2  
What's wrong with you suggested? –  Asaf Sep 30 '13 at 12:32

2 Answers 2

up vote 8 down vote accepted

The right way for a template function to accept any std::vector by const& is:

template<typename T, typename A>
void some_func( std::vector<T,A> const& vec ) {
}

the second argument is the "allocator", and in some advanced usage of std::vector it will not be the default one. If you just accept std::vector<T>, your some_func will reject std::vectors with alternative allocators.

Now, there are other ways to approach this that I will list quickly. I will list them in decreasing cost:benefit ratio -- the one above is probably what you want, and the next one is sometimes useful, and after that I will branch off into over engineered cases that are rarely worth considering (but might be useful in some corner cases).

You could accept an arbitrary type T by T&& then test to determine if typename std::remove_reference<T>::type is a kind of std::vector. This would allow you to do "perfect forwarding" of the incoming std::vector. It would also let you change the predicate you use to test to accept more than just a std::vector: for the most part, const& to std::vector probably just needs some arbitrary random-access container.

A ridiculously fancy way would be to do a two-step function. The second step takes a type-erased random-access range view (or just a range-view if you don't need random access) for a fixed type T with SFINAE to ensure that the incoming object is compatible, the first step deduces the container type of the passed in type and calls the second step in a SFINAE context (auto some_func(...)->decltype(...)).

As type erasure of std::vector<T> const& to a random-access range view of Ts doesn't lose much functionality, an advantage would be that you could guarantee that the body of your function is exactly the same for std::vector<T> const& and for T[n] and for std::array<T,n>.

It isn't a big advantage, especially for the boilerplate required.

C++1y may make this much easier, because the multi-step SFINAE above will collapse into a few requires clauses.

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This is correct.

template<class T>
void some_function(std::vector<T> & vect){}
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@Preetygeek Yes, you can do for only one function within a class. –  Neil Kirk Sep 30 '13 at 12:36
    
@Preety yes you can. –  rubenvb Sep 30 '13 at 12:37
    
OK, thanks a lot! –  Preetygeek Sep 30 '13 at 12:37
2  
Why so restrictive? template <typename T, typename A> void some_function(std::vector<T, A> & vect) ... –  Kerrek SB Sep 30 '13 at 12:48
1  
@KerrekSB Hm I've never thought of that before. I've also never needed it! –  Neil Kirk Sep 30 '13 at 12:49

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