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Using C++, I'm trying to create a generic container class to handle multiple data types. It's a common problem with a variety of solutions, but I've found nothing as... intuitive as I've grown accustomed to in languages like Python or even VB/VBA...

So here's my scenario:

I've built a DataContainer class based on boost::any which I use to store multiple data types of multiple elements. I use a map declared as:

std::map<std::string, DataContainer* (or DataContainerBase*)>

where DataContainer is a class that encapsulates an object of the type:

std::list<boost::any>

along with convenience functions for managing / accessing the list.

However, in the end, I'm still forced to do type conversions outside the data container.

For example, if I were to store a list of int values in the map, accessing them would require:

int value = boost::any_cast<int>(map["myValue"]->get());

I'd rather the boost code be contained entirely within the data container structure, so I would only need type:

int value = map["myValue"]->get();

or, worst-case:

int value = map["myValue"]->get<int>();

Of course, I could enumerate my data types and do something like:

int value = map["myValue"]->get( TYPE_INT );

or write type-specific get() functions:

getInt(), getString(), getBool() ... 

The problem with the last two options is that they are somewhat inflexible, requiring me to declare explicitly each type I wish to store in the container. The any_cast solution (which I have implemented and works) I suppose is fine, it's just... inelegant? I dunno. It seems I shouldn't need to employ the internal mechanics externally as well.

As I see it, passing the value without declaring the value type in the call to the DataContainer member function would require a void* solution (which is undesirable for obvious reasons), and using a "get()" call would require (so far as I can tell) a "virtual template" member function defined at the base class level, which, of course, isn't allowed.

As it is, I have a workable solution, and really, my use in this case is limited enough in scope that most any solutions will work well. But I am wondering if perhaps there's a more flexible way to manage a generic, multi-type data container than this.

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1  
Have a look on boost::variant too, maybe (?) this is what you're looking for. –  Kos Dec 20 '11 at 0:51
    
What's wrong with just a std::map<std::string, boost::any>? –  Kerrek SB Dec 20 '11 at 0:53
    
Also, since your DataContainer is under your control, why not just add a member function template <typename T> get_as() { return boost::any_cast<T>(get()); } to wrap the any-cast? Then you can say m["abc"]->get_as<int>(), as you suggested. Sounds simple enough. –  Kerrek SB Dec 20 '11 at 0:54
    
Haven't looked at boost::variant (though I noticed it). So far as a straight map goes, I'm tokenizing user input that may include vectors. Technically, the entire vector is, itself, a complete token when I'm validating the input (the DataContainer provides that degree of atomicity), but I want the individual elements to be separate as well, hence the std::list. Otherwise, any other token (scalar numeric, or word), would create a one-element list, which would be the same as a map<string, boost::any>. –  Joel Graff Dec 20 '11 at 2:43

3 Answers 3

up vote 5 down vote accepted

If you want to introduce some sugar for this:

int value = boost::any_cast<int>(map["myValue"]->get());

then you might want to make the get() function to return a proxy object, defined +- like this:

struct Proxy {
    boost::any& value;
    Proxy(boost::any& value) : value(value) {}

    template<typename T>
    operator T() {
        return boost::any_cast<T>(value);
    }
};

Then this syntax would work:

int value = map["myValue"]->get();
// returns a proxy which gets converted by any_cast<int>

However I recommend to keep things explicit and just use that syntax:

int value = map["myValue"]->get<int>();

Here get doesn't return a proxy object with a template method, but is a template method itself (but does the same as the template conversion operator shown above).

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@JoelGraff If i am not off by to much you might even get away with just get() in the second case thanks to automatic template parameter deduction. you might consider to store the DataCOntainer directly to save one level of indirection. A list instant itself shoudl be pretty small (only the head), the elements are on the heap anyway. –  ted Dec 20 '11 at 1:02
    
I believe auto parameter deduction only works for the parameters, not the return type. –  Kos Dec 20 '11 at 1:04
    
you are right, look at this stackoverflow.com/a/2612979/258418, it also points out ways to leave out one type through workarounds, however this is only interesting for rather complex types –  ted Dec 20 '11 at 1:09
    
Yah, UncleBens' solution looks the same as what I've mentioned here. –  Kos Dec 20 '11 at 1:12
    
Ok, that makes sense. Frankly, I prefer to be explicit, but verbosity gets hard to manage, so it's a constant battle for me to strike the balance... But I think a get<T>() solution is probably best. –  Joel Graff Dec 20 '11 at 3:05

Today I have done some source code for the purpose you want. I know that this question is so old, but maybe this little piece of code is helpful for someone. It is mainly based on boost:any.

/*
 * AnyValueMap.hpp
 *
 *  Created on: Jun 3, 2013
 *      Author: alvaro
 */

#ifndef ANYVALUEMAP_HPP_
#define ANYVALUEMAP_HPP_

#include <map>
#include <boost/any.hpp>

using namespace std;

template <class T>
class AnyValueMap {

public:
    AnyValueMap(){}

    virtual ~AnyValueMap(){}

private:
    map<T, boost::any> container_;

    typedef typename map<T, boost::any>::iterator map_iterator;
    typedef typename map<T, boost::any>::const_iterator map_const_iterator;

public:

    bool containsKey(const T key) const
    {
        return container_.find(key) != container_.end();
    }

    bool remove(const T key)
    {
        map_iterator it = container_.find(key);
        if(it != container_.end())
        {
            container_.erase(it);
            return true;
        }
        return false;
    }

    template <class V>
    V getValue(const T key, const V defaultValue) const
    {
        map_const_iterator it = container_.find(key);
        if(it != container_.end())
        {
            return boost::any_cast<V>(it->second);
        }
        return defaultValue;
    }

    template <class V>
    V getValue(const T key) const
    {
        return boost::any_cast<V>(container_.at(key));
    }

    template <class V>
    void setValue(const T key, const V value)
    {
        container_[key] = value;
    }
};

#endif /* ANYVALUEMAP_HPP_ */

A simple usage example:

AnyValueMap<unsigned long> myMap;
myMap.setValue<double>(365, 1254.33);
myMap.setValue<int>(366, 55);
double storedDoubleValue = myMap.getValue<double>(365);
int storedIntValue = myMap.getValue<int>(366);
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Try UniversalContainer. The UniversalContainer class is an attempt to provide a class which can act in a manner similar to the untyped variables, arrays, and hash-maps found in popular scripting languages such as perl and PHP.

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3  
Cannot open the link: 404 Not Found –  afriza Mar 31 '14 at 4:18

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