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I'm using libgc, a garbage collector for C and C++. To make STL containers garbage collectible one must use the gc_allocator.

Instead of writing

std::vector<MyType>

one has to write

std::vector<MyType,gc_allocator<MyType> >

Could there be a way to define something like

template<class T> typedef std::vector<T,gc_allocator<T> > gc_vector<T>;

I checked some time ago and found out it was not possible. But I may have been wrong or there might be another way around.

Defining maps in this way is particularly unpleasing.

std::map<Key,Val>

becomes

std::map<Key,Val, std::less<Key>, gc_allocator< std::pair<const Key, Val> > >

EDIT: After trying the use of macro I found out the following code breaks it:

#define gc_vector(T) std::vector<T, gc_allocator<T> >
typedef gc_vector( std::pair< int, float > ) MyVector;

The comma inside the templated type definition is interpreted as a macro argument separator.

So it seems the inner class/struct is the best solution.

Here is an example on how it will be done in C++0X

// standard vector using my allocator
template<class T>
using gc_vector = std::vector<T, gc_allocator<T> >;

// allocates elements using My_alloc
gc_vector <double> fib = { 1, 2, 3, 5, 8, 13 };

// verbose and fib are of the same type
vector<int, gc_vector <int>> verbose = fib;
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why do you say that the TypeHelper solution requires you to redefine constructors? It's nothing more than a shortcut on a typedef... –  Paolo Tedesco Mar 16 '09 at 11:21
    
Oops, you are right. It's good you clarified this in your answer. I was told that C++0X will provide a better solution by use of the 'using' keyword. Do you know how this would work ? –  chmike Mar 16 '09 at 13:01
    
C++0x will provide template aliases, which will provide a way to do exactly what you want. open-std.org/jtc1/sc22/wg21/docs/papers/2007/n2258.pdf –  Luc Touraille Mar 16 '09 at 16:02

4 Answers 4

up vote 23 down vote accepted

You cannot use a "templated typedef", but you can use a convenience class/struct with an inner type:

template<typename T>
struct TypeHelper{
    typedef std::vector<T,gc_allocator<T> > Vector;
};

and then use in your code

TypeHelper<MyType>::Vector v;
TypeHelper<MyType>::Vector::iterator it;

And something similar for the map:

template<typename K,typename V>
struct MapHelper{
    typedef std::map<K, V, gc_allocator<K,V> > Map;
};

EDIT - @Vijay: I don't know if there's another possible workaround, that's how I would do it; a macro might give you a more compact notation, but personally I wouldn't like it:

#define GCVECTOR(T) std::vector<T,gc_allocator<T> >

EDIT - @chmike: Please note that the TypeHelper solution does not require you to redefine constructors!

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Is there any other work-around available ? –  Warrior Mar 16 '09 at 9:43
1  
Yeap, there is. Inheritance is much neater is this very case. –  sharptooth Mar 16 '09 at 9:49
    
@sharptooth: it's true that inheritance in this case gives you the best notation and avoids the use of a macro, but its usage is debatable, as pointed out in the comments to your answer. –  Paolo Tedesco Mar 16 '09 at 9:56
    
I'm patiently waiting for any proof of potential problems. –  sharptooth Mar 16 '09 at 10:02
1  
You could add in your answer that template typedefs (aka template aliases) will be included in C++0x (however, it's not supported by gcc yet) open-std.org/jtc1/sc22/wg21/docs/papers/2007/n2258.pdf. –  Luc Touraille Mar 16 '09 at 16:02

You can publicly inherit:

template<class T>
class gc_vector<T> : public std::vector<T, gc_allocator<T> >
{
    public:
    // You'll have to redeclare all std::vector's constructors here so that
    // they just pass arguments to corresponding constructors of std::vector
};

This solves your problem completely. The derived type can be used everywhere where the base type can be used, and there's no implementation overhead with any decent compiler.

The fact that std::vector has non-virtual destructor might lead to undefined behaviour according to C++ standard if you ever try to delete a derived class variable through a pointer to base class variable.

In real world this shouldn't matter in this particular case - the derived class has nothing new added compared to the base class and therefore the destructor for the derived class just calls the destructor for the base class. Proceed with paranoia, port carefully anyway.

If you never allocate this class variables on heap (and it's typical to allocate vector variables on stack and as members of other classes) the non-virtual destructor problem doesn't affect you.

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3  
Nope, it doesn't matter in this case. The derived has no new data members compared to the base, so there's no difference between delete for Base* and Derived*. The derived constructor just calls the base constructor anyway. –  sharptooth Mar 16 '09 at 9:42
2  
@sharptooth - it does matter - what you suggest may happen, but the standard says it is UB. –  anon Mar 16 '09 at 9:58
1  
Well, I hope that the standard is not the replacement for logic and common sense. Can you show an example of why this very case may cause problems? –  sharptooth Mar 16 '09 at 10:01
2  
There is no common sense in relying on undefined behavior. It's inherently unportable regardless of what one implementation happens to do. So yes, the standard is a replacement for "common sense" in this case. –  Dan Olson Mar 16 '09 at 10:26
1  
It's hard to give an example of undefined behavior. A conforming implementation could delete the contents of your hard disk if it felt like it. If you try it on all reasonable systems and it works as expected, feel free to use it knowing it's undefined. As a rule, though, I'd steer clear of UB. –  Dan Olson Mar 16 '09 at 10:34

You can use C++11 templated type aliasing using using e.g. like this

template <typename T>
using gc_vector = std::vector<T, gc_allocator<T>>;

Note: I know this is an old question but since it has quite many upvotes and as it turns up in search results I thought it deserved an updated answer.

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It can be done with a MACRO, if you're willing to push your compiler to its limits. I did it while implementing C++ equivalents for Java's "Future" and "Callable" classes. Our library uses reference-counted objects, so "Reference<T>" is itself a template class where "T" derives from "ReferencedObject".

1. Create your template Classes. Mine are:

    template<typename T>
    class Callable {
    private:

    public:
        virtual T Call() = 0;
    };

    template<typename T> CountedFuture : public ReferencedObject {
    private:
       Callable<T>* theTask;
       T            theResult;

    public:
       T Get() { 
          // Run task if necessary ...
          if(task) {
             theResult = theTask->Call();
             delete theTask;
          }
          return theResult;
       }
    };

2. In the application code I'm using references, so I define the macro:

   #define Future(T) Reference<CountedFuture<T>>

The beauty of this is that is that the Macro does exactly what you'd want from a "template typedef", the downsides being that you can't use "<>" for your type parameter(s) and there is no type inference.

3. I can now use the Macro wherever I would use a template, like in functions:

   Future(char*) DoSomething() { ... }
   bool          TestSomething(Future(std::string) f) { .... }
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