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I need to store a list of various properties of an object. Property consists of a name and data, which can be of any datatype.

I know I can make a class "Property", and extend it with different PropertySubClasses which only differ with the datatype they are storing, but it does not feel right.

class Property
     Property(std::string name);
     virtual ~Property();

     std::string m_name;

class PropertyBoolean : Property
     PropertyBoolean(std::string name, bool data);

     bool m_data;

class PropertyFloat : Property
     PropertyFloat(std::string name, float data);

     float m_data;

class PropertyVector : Property
     PropertyVector(std::string name, std::vector<float> data);

     std::vector<float> m_data;

Now I can store all kinds of properties in a


and to get the data, I can cast the object to the subclass. Or I can make a pure virtual function to do something with the data inside the function without the need of casting.

Anyways, this does not feel right to create these different kind of subclasses which only differ by the data type they are storing. Is there any other convenient way to achieve similar behavior?

I do not have access to Boost.

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Similar to what you want using Boost.Variant: stackoverflow.com/questions/1358427/… –  AraK Aug 24 '10 at 17:53
Seems that templates is the way to go. Have you considered them ? –  Tom Aug 24 '10 at 18:04
possible duplicate of how do you make a heterogeneous boost::map? –  Loki Astari Aug 24 '10 at 18:34
Same problem as "how do you make a heterogeneous boost::map?" just swap list for map. stackoverflow.com/questions/3559412/… –  Loki Astari Aug 24 '10 at 18:35
If boost is not an option, then implement your own variant / any. The latter should use inheritance under the hood, but the polymorphism is hidden away from the user giving the object normal value semantics. And it has a smart "cast" function of its own to determine the stored type. –  UncleBens Aug 24 '10 at 19:40

7 Answers 7

up vote 14 down vote accepted

C++ is a multi-paradigm language. It shines brightest and is most powerful where paradigms are mixed.

class Property
    Property(const std::string& name) //note: we don't lightly copy strings in C++
      : m_name(name) {}
    virtual ~Property() {}
    std::string m_name;

template< typename T >
class TypedProperty : public Property
    TypedProperty (const std::string& name, const T& data)
      : Property(name), m_data(data);
    T m_data;

typedef std::vector< std::shared_ptr<Property> > property_list_type;

Edit: Why using std::shared_ptr<Property> instead of Property*?
Consider this code:

void f()
  std::vector<Property*> my_property_list;
  for(unsigned int u=0; u<10; ++u)
    my_property_list.push_back(new Property(u));


  for(std::vector<Property*>::iterator it=my_property_list.begin();
                                      it!=my_property_list.end(); ++it)
    delete *it;

That for loop there attempts to cleanup, deleting all the properties in the vector, just before it goes out of scope and takes all the pointers with it.
Now, while this might seem fine for a novice, if you're an only mildly experienced C++ developer, that code should raise alarm bells as soon as you look at it.

The problem is that the call to use_property_list() might throw an exception. If so, the function f() will be left right away. In order to properly cleanup, the destructors for all automatic objects created in f() will be called. That is, my_property_list will be properly destroyed. std::vector's destructor will then nicely cleanup the data it holds. However, it holds pointers, and how should std::vector know whether these pointers are the last ones referencing their objects?
Since it doesn't know, it won't delete the objects, it will only destroy the pointers when it destroys its content, leaving you with objects on the heap that you don't have any pointers to anymore. This is what's called a "leak".

In order to avoid that, you would need to catch all exceptions, clean up the properties, and the rethrow the exception. But then, ten years from now, someone has to add a new feature to the 10MLoC application this has grown to, and, being in a hurry, adds code which leaves that function prematurely when some condition holds. The code is tested and it works and doesn't crash - only the server it's part of now leaks a few bytes an hour, making it crash due to being out of memory about once a week. Finding that makes for many hours of fine debugging.

Bottom line: Never manage resources manually, always wrap them in objects of a class designed to handle exactly one instance of such a resource. For dynamically allocated objects, those handles are called "smart pointer", and the most used one is shared_ptr.

share|improve this answer
But std::shared_ptr isn't part of C++ yet. And if he isn't allowed to use Boost, he most likely won't be allowed to use the TR1 extensions nor C++0x either. –  phlipsy Aug 25 '10 at 7:33
@phlipsy: Oh, I simply overlooked the statement about boost. That's dumb. Anyway, if a shop doesn't allow boost, they'll have to have their own smart pointer anyway - as bad as this usually is, it's still better than having no smart pointer. Also, some compilers already support std::shared_ptr. –  sbi Aug 25 '10 at 8:48
What's the point of shared_ptr here compared to regular pointer? –  hasdf Aug 25 '10 at 15:59
@hasdf: std::shared_ptr is a "smart pointer". It allows an arbitrary number of std::shared_ptr instances to share the same objects, but will automatically delete the object when the last std::shared_ptr instance referring to dies. –  sbi Aug 25 '10 at 16:13
Well, can't I just easily use "delete" to delete the object? –  hasdf Aug 27 '10 at 16:31

A lower-level way is to use a union

class Property
  union {
    int int_data;
    bool bool_data;
    std::cstring* string_data;
  enum { INT_PROP, BOOL_PROP, STRING_PROP } data_type;
  // ... more smarts ...

Dunno why your other solution doesn't feel right, so I don't know if this way would feel better to you.

EDIT: Some more code to give an example of usage.

Property car = collection_of_properties.head();
if (car.data_type == Property::INT_PROP) {
  printf("The integer property is %d\n", car.int_data);
} // etc.

I'd probably put that sort of logic into a method of the class where possible. You'd also have members such as this constructor to keep the data and type field in sync:

Property::Property(bool value) {
  bool_data = value;
  data_type = BOOL_PROP;
share|improve this answer
Could you elaborate? I do not understand this –  hasdf Aug 24 '10 at 17:58
@hasdf: The union lets you store any of the constituent types, but only one at a time (basically all the members share the same region of memory). And then it's up to you to use the data_type field to keep track of what type is actually stored. –  casablanca Aug 24 '10 at 18:09

I suggest boost::variant or boost::any. [Related question]

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Boost is not an option. –  hasdf Aug 24 '10 at 17:58

Write a template class Property<T> that derives from Property with a data member of type T

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You still wouldn't be able to put them into an array or an stl container. Property<int> and Property<float> are entirely different types. –  Dima Aug 24 '10 at 18:03
@Dima: Yes, but in the example they are stored by pointer anyway. –  user180326 Aug 24 '10 at 18:04
@Dima: Not if they have a common superclass, which I think is what jdv meant by "derives from Property". –  Joey Adams Aug 24 '10 at 18:06
Right, you could have a collection of pointers to the base class. But then there is still a problem: to get the value of the property, you need to know which subclass it is. –  Dima Aug 24 '10 at 18:10
@jdv: I know, but this still feels wrong. Usually when you have to ask an object what class it is, that is an indication of a design flaw. –  Dima Aug 24 '10 at 18:54

You can probably do this with the Boost library, or you could create a class with a type code and a void pointer to the data, but it would mean giving up some of the type safety of C++. In other words, if you have a property "foo", whose value is an integer, and give it a string value instead, the compiler will not find the error for you.

I would recommend revisiting your design, and re-evaluating whether or not you really need so much flexibility. Do you really need to be able to handle properties of any type? If you can narrow it down to just a few types, you may be able to come up with a solution using inheritance or templates, without having to "fight the language".

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Another possible solution is to write a intermediate class managing the pointers to Property classes:

class Bla {
  Property* mp
  explicit Bla(Property* p) : mp(p) { }

  ~Bla() { delete p; }

  // The standard copy constructor
  // and assignment operator
  // aren't sufficient in this case:
  // They would only copy the 
  // pointer mp (shallow copy)
  Bla(const Bla* b) : mp(b.mp->clone()) { }

  Bla& operator = (Bla b) { // copy'n'swap trick
    return *this;

  void swap(Bla& b) {
    using std::swap; // #include <algorithm>
    swap(mp, b.mp);

  Property* operator -> () const {
    return mp;

  Property& operator * () const {
    return *mp;

You have to add a virtual clone method to your classes returning a pointer to a newly created copy of itself:

class StringProperty : public Property {
// ...
  // ...
  virtual Property* clone() { return new StringProperty(*this); }
  // ...

Then you'll be able to do this:

std::vector<Bla> v;
v.push_back(Bla(new StringProperty("Name", "Jon Doe")));
// ...
std::vector<Bla>::const_iterator i = v.begin();

Leaving the scope of v means that all Blas will be destroyed freeing automatically the pointers they're holding. Due to its overloaded dereferencing and indirection operator the class Bla behaves like an ordinary pointer. In the last line *i returns a reference to a Bla object and using -> means the same as if it was a pointer to a Property object.

A possible drawback of this approach is that you always get a heap operation (a new and a delete) if the intermediate objects must be copied around. This happens for example if you exceed the vector's capacity and all intermediate objects must be copied to a new piece of memory.

In the new standard (i.e. c++0x) you'll be able to use the unique_ptr template: It

  • can be used inside the standard containers (in contrast to the auto_ptr which must not be used in the standard containers),
  • offers the usually faster move semantics (it can easily passed around) and
  • takes care over the held pointers (it frees them automatically).
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I see that there are lots of shots at trying to solve your problem by now, but I have a feeling that you're looking in the wrong end - why do you actually want to do this in the first place? Is there some interesting functionality in the base class that you have omitted to specify?

The fact that you'd be forced to switch on a property type id to do what you want with a specific instance is a code smell, especially when the subclasses have absolutely nothing in common via the base class other than a name (which is the type id in this case).

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