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Note: I know similar questions to this have been asked on SO before, but I did not find them helpful or very clear.

Second note: For the scope of this project/assignment, I'm trying to avoid third party libraries, such as Boost.

I am trying to see if there is a way I can have a single vector hold multiple types, in each of its indices. For example, say I have the following code sample:

vector<something magical to hold various types> vec;
int x = 3;
string hi = "Hello World";
MyStruct s = {3, "Hi", 4.01};

vec.push_back(x);
vec.push_back(hi);
vec.push_back(s);

I've heard vector<void*> could work, but then it gets tricky with memory allocation and then there is always the possibility that certain portions in nearby memory could be unintentionally overridden if a value inserted into a certain index is larger than expected.

In my actual application, I know what possible types may be inserted into a vector, but these types do not all derive from the same super class, and there is no guarantee that all of these types will be pushed onto the vector or in what order.

Is there a way that I can safely accomplish the objective I demonstrated in my code sample?

Thank you for your time.

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@chris Sorry I wasn't clear. For the scope of this project/assignment, I'm trying to avoid third party libraries. I've updated my question. –  spryno724 Nov 19 '12 at 20:44
    
Well, I don't know how well it'll work, but you can have a structure with a type member and a union of all of the possible types. –  chris Nov 19 '12 at 20:45
3  
If you are mandating you cannot know what is actually being pushed can we assume this vector doesn't own anything besides pointers? Without some way of establishing type-info at the owner-level, you're somewhat screwed in properly managing cleanup or erasure. A struct with a pointer + destructor reference is conceivable, but at that time you have to start asking yourself wth is the real data model being serviced here? –  WhozCraig Nov 19 '12 at 20:49
    
Do you actually want completely random data, or do these have some sort of relationship? If there's some sort of type hierarchy, you can store a pointer to the more generic type they all share, and you can use shared_ptr to make the memory less messy. –  Brendan Long Nov 19 '12 at 20:50
    
@BrendanLong Assuming that this vector would be returned from a member function, are pointers like you are talking about really possible? –  spryno724 Nov 19 '12 at 20:52
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3 Answers

up vote 3 down vote accepted

In order to do that, you'll definitely need a wrapper class to somehow conceal the type information of your objects from the vector.

It's probably also good to have this class throw an exception when you try to get Type-A back when you have previously stored a Type-B into it.

Here is part of the Holder class from one of my projects. You can probably start from here.

Note: due to the use of unrestricted unions, this only works in C++11. More information about this can be found here: What are Unrestricted Unions proposed in C++0x?

class Holder {
public:
    enum Type {
        BOOL,
        INT,
        STRING,
        // Other types you want to store into vector.
    };

    template<typename T>
    Holder (Type type, T val);

    ~Holder () {
        // You want to properly destroy
        // union members below that have non-trivial constructors
    }

    operator bool () const {
        if (type_ != BOOL) {
           throw SomeException();
        }
        return impl_.bool_;
    }
    // Do the same for other operators
    // Or maybe use templates?

private:
    union Impl {
        bool   bool_;
        int    int_;
        string string_;

        Impl() { new(&string_) string; }
    } impl_;

    Type type_;

    // Other stuff.
};
share|improve this answer
    
I'm pretty sure you can't put std::string in a union because of 9.5/1 which says you can't do that if it has a non-trivial constructor, copy constructor, destructor, or copy assignment operator. –  Mark B Nov 19 '12 at 21:04
2  
you can now in c++11, which has all the goodness :p You can refer to it at wikipedia. –  BeyondSora Nov 19 '12 at 21:05
2  
You should probably note that this is a C++11-only solution in your answer then, as well as noting that you'll have to use placement new and explicit destruction to use the string member safely. –  Mark B Nov 19 '12 at 21:09
    
modified my answer to state it is C++11-only :-) –  BeyondSora Nov 19 '12 at 21:11
    
Did someone profile this code? This solution seems clean but is it faster or slower than the traditional polymorphism + virtual or dynamic_cast<>? –  filsmick Jun 20 at 8:49
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The objects hold by the std::vector<T> need to be of a homogenous type. If you need to put objects of different type into one vector you need somehow erase their type and make them all look similar. You could use the moral equivalent of boost::any or boost::variant<...>. The idea of boost::any is to encapsulate a type hierarchy, storing a pointer to the base but pointing to a templatized derived. A very rough and incomplete outline looks something like this:

#include <algorithm>
#include <iostream>

class any
{
private:
    struct base {
        virtual ~base() {}
        virtual base* clone() const = 0;
    };
    template <typename T>
    struct data: base {
        data(T const& value): value_(value) {}
        base* clone() const { return new data<T>(*this); }
        T value_;
    };
    base* ptr_;
public:
    template <typename T> any(T const& value): ptr_(new data<T>(value)) {}
    any(any const& other): ptr_(other.ptr_->clone()) {}
    any& operator= (any const& other) {
        any(other).swap(*this);
        return *this;
    }
    ~any() { delete this->ptr_; }
    void swap(any& other) { std::swap(this->ptr_, other.ptr_); }

    template <typename T>
    T& get() {
        return dynamic_cast<data<T>&>(*this->ptr_).value_;
    }
};

int main()
{
    any a0(17);
    any a1(3.14);
    try { a0.get<double>(); } catch (...) {}
    a0 = a1;
    std::cout << a0.get<double>() << "\n";
}
share|improve this answer
    
+1, good answer. Though remember in data, clone() should be data<T>* clone() const as it is covariant :) But this is arguably the better answer than the accepted answer. –  Moo-Juice Mar 3 '13 at 10:45
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As suggested you can use various forms of unions, variants, etc. Depending on what you want to do with your stored objects, external polymorphism could do exactly what you want, if you can define all necessary operations in a base class interface.

Here's an example if all we want to do is print the objects to the console:

#include <iostream>
#include <string>
#include <vector>
#include <memory>

class any_type
{
public:
   virtual ~any_type() {}
   virtual void print() = 0;
};

template <class T>
class concrete_type : public any_type
{
public:
   concrete_type(const T& value) : value_(value)
   {}

   virtual void print()
   {
      std::cout << value_ << '\n';
   }
private:
   T value_;
};

int main()
{
   std::vector<std::unique_ptr<any_type>> v(2);

   v[0].reset(new concrete_type<int>(99));
   v[1].reset(new concrete_type<std::string>("Bottles of Beer"));

   for(size_t x = 0; x < 2; ++x)
   {
      v[x]->print();
   }

   return 0;
}
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