It's amazing how much confusion has been created about the distinction between the UML part-whole-relationship concepts aggregation and composition. The main problem is the widespread misunderstanding (even among many expert software developers) that the concept of composition is defined by a life-cycle dependency between the whole and its parts such that the parts cannot exist without the whole. But this view is plain wrong, ignoring the UML definition of the term "composition" by confusing the defining charcteristic with an optional charcteristic. However, this confusion also points to a weakness, or incompleteness, of the UML definition, which does not account for lifecycle dependencies between components and composites. It's therefore important to understand how the UML definition can be enhanced by introducing a UML stereotype for <<inseparable>> compositions where components cannot be detached from their composite, and, thus, have to be destroyed whenever their composite is destroyed.
As Martin Fowler has explained, the main issue for characterizing composition is that "an object can only be the part of one composition relationship". This is also explained in the excellent blog post UML Composition vs Aggregation vs Association by Geert Bellekens. In addition to this defining characteristic of a composition (to have exclusive, or non-shareable, parts), a composition may also come with a life-cycle dependency between the composite and its components. In fact, there are two kinds of such dependencies:
- Whenever a component must always be attached to a composite, or, in other words, when it has a mandatory composite, as expressed by the "exactly one" multiplicity at the composite side of the composition line, then it must either be re-used in (or re-attached to) another composite, or destroyed, when its current composite is destroyed. This is exemplified by the composition between
Heart, shown in the diagram below. A heart is either destroyed or transplanted to another person, when its owner has died.
- Whenever a component cannot not be detached from its composite, or, in other words, when it is inseparable, then, and only then, the component has to be destroyed, when its composite is destroyed. An example of such a composition with inseparable parts is the composition between
In summary, life-cycle dependencies only apply to specific cases of composition, but not in general, they are therefore not a defining characteristic.
The UML spec states: "A part may be removed from a composite instance before the composite instance is deleted, and thus not be deleted as part of the composite instance." In the example of a
Engine composition, as shown in the following diagram, it's clearly the case that the engine can be detached from the car before the car is destroyed, in which case the engine is not destroyed and can be re-used. This is implied by the zero or one multiplicity at the composite side of the composition line.
Tthe multiplicity of a composition's association end at the composite side is either 1 or 0..1, depending on the fact if components have a mandatory composite (must be attached to a composite) or not. If components are iseparable, this implies that they have a mandatory composite.
An aggregation is another special form of association with the intended meaning of a part-whole-relationship, where the parts of a whole can be shared with other wholes. For instance, we can model an aggregation between the classes
Course, as shown in the following diagram, since a course is part of a degree program and a course can be shared among two or more degree programs (e.g. an engineering degree could share a C programmin course with a computer science degree).
However, the concept of an aggregation with shareable parts doesn't mean much, really, so it does not have any implications on the implementation and many developer therefore prefer not to use the white diamond in their class diagrams, but just model a plain association instead. The UML spec says: "Precise semantics of shared aggregation varies by application area and modeler".
The multiplicity of an aggregation's association end at the whole side may be any number (*) because a part may belong to, or shared among, any number of wholes.