There are two situations where it matters whether a member is
- If a derived class could benefit from using a member, making the member `protected` would allow it to do so, while making it `private` would deny it that benefit.
- If a future version of the base class could benefit by not having the member behave as it does in the present version, making the member `private` would allow that future version to change the behavior (or eliminate the member entirely), while making it `protected` would require all future versions of the class to keep the same behavior, thus denying them the benefit that could be reaped from changing it.
If one can imagine a realistic scenario where a derived class might benefit from being able to access the member, and cannot imagine a scenario where the base class might benefit from changing its behavior, then the member should be
protected [assuming, of course, that it shouldn't be public]. If one cannot imagine a scenario where a derived class would get much benefit from accessing the member directly, but one can imagine scenarios where a future version of the base class might benefit by changing it, then it should be
private. Those cases are pretty clear and straightforward.
If there isn't any plausible scenario where the base class would benefit from changing the member, I would suggest that one should lean toward making it
protected. Some would say the "YAGNI" (You Ain't Gonna Need It) principle favors
private, but I disagree. If you're is expecting others to inherit the class, making a member private doesn't assume "YAGNI", but rather "HAGNI" (He's Not Gonna Need It). Unless "you" are going to need to change the behavior of the item in a future version of the class, "you" ain't gonna need it to be
private. By contrast, in many cases you'll have no way of predicting what consumers of your class might need. That doesn't mean one should make members
protected without first trying to identify ways one might benefit from changing them, since
YAGNI isn't really applicable to either decision. YAGNI applies in cases where it will be possible to deal with a future need if and when it is encountered, so there's no need to deal with it now. A decision to make a member of a class which is given to other programmers
protected implies a decision as to which type of potential future need will be provided for, and will make it difficult to provide for the other.
Sometimes both scenarios will be plausible, in which case it may be helpful to offer two classes--one of which exposes the members in question and a class derived from that which does not (there's no standard idiomatic was for a derived class to hide members inherited from its parent, though declaring new members which have the same names but no compilable functionality and are marked with an
Obsolete attribute would have that effect). As an example of the trade-offs involved, consider
List<T>. If the type exposed the backing array as a protected member, it would be possible to define a derived type
CompareExchangeableList<T> where T:Class which included a member
T CompareExchangeItem(index, T T newValue, T oldvalue) which would return
Interlocked.CompareExchange(_backingArray[index], newValue, oldValue); such a type could be used by any code which expected a
List<T>, but code which knew the instance was a
CompareExchangeableList<T> could use the
CompareExchangeItem on it. Unfortunately, because
List<T> does not expose the backing array to derived classes, it is impossible to define a type which allows
CompareExchange on list items but which would still be useable by code expecting a
Still, that's not to imply that exposing the backing array would have been completely without cost; even though all extant implementations of
List<T> use a single backing array, Microsoft might implement future versions to use multiple arrays when a list would otherwise grow beyond 84K, so as to avoid the inefficiencies associated with the Large Object Heap. If the backing array was exposed as protected member, it would be impossible to implement such a change without breaking any code that relied upon that member.
Actually, the ideal thing might have been to balance those interests by providing a protected member which, given a list-item index, will return an array segment which contains the indicated item. If there's only one array, the method would always return a reference to that array, with an offset of zero, a starting subscript of zero, and a length equal to the list length. If a future version of
List<T> split the array into multiple pieces, the method could allow derived classes to efficiently access segments of the array in ways that would not be possible without such access [e.g. using
List<T> could change the way it manages its backing store without breaking properly-written derived classes. Improperly-written derived classes could get broken if the base implementation changes, but that's the fault of the derived class, not the base.