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This question is in my exam revision, and I'm wondering if I'm on the right track with it, It is from the C++ primer text book.

How are UML model relationships coded in C++?

Public inheritance allows you to model IS-A relationships, with derived classes being able to reuse code of base classes. Another approach is to use containment, which is the relationship between objects where one object owns or has the other object. This models HAS-A relationships.

For example:

  • Car has or owns Motor
  • When Car is built, it's motor is also built
  • When Car is destroyed, its motor is also destroyed.

    class Car 
            Motor *motor;
                 motor = new Motor(); 
                 delete motor; 
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C++ is not Java, there is no need to dynamically allocate a Motor in your example. –  john Oct 27 '12 at 15:28

3 Answers 3

With C++ it's easier to build composition relations than with Java. In the simplest case, the contained object is just a value member:

class Car {
  Motor motor;
  // No explicit construction/destruction required

It gets more complicated when you want to contain an AbstractMotor whose dynamic type is determined by the caller using dependency injection. To model composition in this case, you can use unique_ptr:

class Car {
  explicit Car(std::unique_ptr<AbstractMotor> motor): motor(std::move(motor)) { }
  std::unique_ptr<AbstractMotor> motor;  // Still no explicit destruction required

unique_ptr ensures that your Car is the unique owner of the Motor, and that Motor's lifetime is bound to the Car object.

Try to avoid using raw pointers when an objects owns another object. With unique_ptr, it shouldn't be necessary to implement nontrivial destructors or use the delete operator at all.

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I wouldn't add much to your answer.

As far as IS-A relationship is concerned, public inheritance of is the tool in C++ (it gets tricky when using templates though and not always works as expected). When it comes to HAS-A relationship then class members are the solution. To be really precise, I'd use a Motor motor member (not a pointer), since this even more strongly emphasizes the relation between the two. And as far as pointer can be null, a member will always be constructed and destroyed.


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Public inheritance allows you to model IS-A relationships, with derived classes being able to reuse code of base classes.

That is a common misconception. The point of inheritance is not being able to reuse code of base classes, but rather leverage existing code that handles the base type providing different behaviors. That is, at least in OO theory.

C++ is a powerful flexible language, and there is no single mapping of UML to the language (this is where those expecting code generation from UML will fail once and again, UML does not capture some of the fine grained details).

Generalization and Realization are both implemented through inheritance0 in C++, although in other languages they differ. As an example, in Java generalization is implemented through inheritance (extends) and realization through interface implementation (implements).

Composition this is the has-a relationship and is commonly implemented through value members of a class. Note that this is not the only implementation1.

Aggregation can be implemented through pointer2 and reference members, depending on other criteria including the relative lifetimes of the two objects and whether the reference can be reset to a different object.

Use is not explicitly modeled, but rather happens. The use relationship can be present in the interface (a function that takes or returns an object of a different type uses that type), or the implementation (a function that in its definition uses a different type --instantiates an object of that type for some purpose) also uses the type. Some people consider these two as different variants of use, with the first one being more strict than the second, as it adds a tighter coupling from the used type to external code that uses your type itself.

Finally, with templates there are multiple other options. For example, there is no relationship between std::vector<>::iterator and std::deque<>::iterator in the language, but they model the concept of RandomAccessIterator in the language, and a template that was designed to work with a RandomAccessIterator can use both of them (for example, std::sort) From the point of view of std::sort both are random access iterators, the relationship is Generalization of that concept, although that is not present in the code at all (it will be if they finally end up adding some flavor of concepts to the language).

0) In general, we would be talking only of public inheritance, but that need not be the case. A type that inherits publicly from a different type is obviously generalizing/*realizing* another type/interface, but that can also happen through private inheritance. One thing that is not commonly presented when teaching OO is that a class has two separate interfaces. On the one side there is a public interface through which users of your type interact with your object. On the other side there is a virtual interface, that is the contract between your type and other types that extend your behavior. A common idiom in C++ is the NVI Non-virtual interface, that tries to exploit this by forcing a separation: no public virtual functions imply that the public and virtual interfaces are completely isolated. In the same way, a type T might not have a public is-a relationship with a base, although internally it can pass references or pointers to the base type to other subsystems. For those subsystems the type T is-a base. Protected inheritance can be ignored as it is considered useless with no motivating usage example.

1) In some cases, driven by other needs, it can be implemented with members of pointer type, as long as they are allocated on construction and released on destruction of the enclosing type. In some cases inheritance is abused to do composition and perform size optimizations (empty base optimization). For example, instead of holding a comparator, a std::map can inherit from the comparator (using SFINAE to detect when the comparator is a functor). If the type of the comparator has no state which is quite frequent, the compiler can place the comparator and the first member of the std::map in the same memory location (i.e. the comparator will not take any space).

2) Consider the term pointer in a general sense that includes smart pointers.

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