Boost Pointer Container Library

Usage Guidelines

Choosing the right container

The recommended usage pattern of the container classes is the same as for normal standard containers.

ptr_vector, ptr_list and ptr_deque offer the programmer different complexity tradeoffs and should be used accordingly. ptr_vector is the type of sequence that should be used by default. ptr_list should be used when there are frequent insertions and deletions from the middle of the sequence and if the container is fairly large (eg. more than 100 elements). ptr_deque is the data structure of choice when most insertions and deletions take place at the beginning or at the end of the sequence. The special container ptr_array may be used when the size of the container is invariant and known at compile time.

An associative container supports unique keys if it may contain at most one element for each key. Otherwise, it supports equivalent keys. ptr_set and ptr_map support unique keys. ptr_multiset and ptr_multimap support equivalent keys.

Recommended practice for Object-Oriented Programming

Idiomatic Object-Oriented Programming in C++ looks a bit different from the way it is done in other languages. This is partly because C++ has both value and reference semantics, and partly because C++ is more flexible than other languages. Below is a list of recommendations that you are encouraged to follow:

1. Make base classes abstract and without data

This has the following advantages:

  1. It reduces coupling because you do not have to maintain or update state
  1. It helps you to avoid slicing
  1. It ensures you override the right function

You might also want to read the following articles:

2. Make virtual functions private and provide a non-virtual public forwarding function

In code:

class Polymorphic
{
private:
    virtual int do_foo() = 0;
    
public:
    int foo()
    {
        return do_foo();
    }
    ...
};      

This has the following advantages:

  1. It makes sure all calls to the virtual function always goes through one place in your code
  1. It enables you to check preconditions and postconditions inside the forwarding function

You might also want to read Herb Sutter's article Virtuality.

3. Derive your base class from boost::noncopyable

Having an abstact base class prevents slicing when the base class is involved, but it does not prevent it for classes further down the hierarchy. This is where boost::noncopyable is handy to use:

class Polymorphic : boost::noncopyable
{
  ...
};

4. Avoid null-pointers in containers (if possible)

By default the pointer containers do not allow you to store null-pointer in them. As you might know, this behavior can be changed explicitly with the use of boost::nullable.

The primary reason to avoid null-pointers is that you have to check for null-pointers every time the container is used. This extra checking is easy to forget, and it is somewhat contradictory to the spirit of OO where you replace special cases with dynamic dispatch.

Often, however, you need to place some special object in the container because you do not have enough information to construct a full object. In that case you might be able to use the Null Object pattern which simply dictates that you implement virtual functions from the abstract base-class as empty functions or with dummy return values. This means that your OO-code still does not need to worry about null-pointers.

You might want to read

Finally you might end up in a situation where not even the Null Object can help you. That is when you truly need container< nullable<T> >.


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Copyright:Thorsten Ottosen 2004-2006. Use, modification and distribution is subject to the Boost Software License, Version 1.0 (see LICENSE_1_0.txt).