OOP is sitting on 4 "pillars":
Abstraction - Abstracting logic and concepts can easily be done by defining objects in class modules. Strictly speaking, abstraction is also achieved by using meaningful identifiers and extracting procedural code into methods (class members).
Here's an example of a procedure written in VBA that demonstrates abstraction:
Public Sub Test(ByVal checkin As Date, ByVal checkout As Date, ByVal custType As CustomerType)
Dim finder As New HotelFinder
Debug.Print finder.FindCheapestHotel(checkin, checkout, custType)
It's easy to tell what this
Test procedure does at a glance, because the abstraction level is very high: the implementation details are abstracted away into more specialized objects and methods.
Encapsulation - Classes can have private fields exposed by properties; classes can be made
PublicNotCreatable, effectively exposing types to other VBA projects - and with a little bit of effort (by exporting the class module, opening it in your favorite text editor, manually editing class attributes, and re-importing the module), you can achieve actual read-only types. The fact that there are no parameterized constructors is irrelevant - just write a factory method that takes all the parameters you like and return an instance. This is COM, and COM likes factories anyway.
Here's an example of how the
HotelFinder class from the above snippet encapsulates a
Collection object and only exposes it through a
Property Get accessor - code outside this class simply cannot
Set this reference, it's encapsulated:
Private Type TFinder
Hotels As Collection
Private this As TFinder
Public Property Get Hotels() As Collection
Set Hotels = this.Hotels
Private Sub Class_Initialize()
Set this.Hotels = New Collection
Private Sub Class_Terminate()
Set this.Hotels = Nothing
Implements lets you implement abstract interfaces (and concrete classes, too), and then you can write code against an
ISomething abstraction that can just as well be a
Foo or a
Bar both implement
ISomething) - and all the code ever needs to see is
ISomething. Method overloading is a language feature that VBA lacks, but overloading has nothing to do with polymorphism, which is the ability to present the same interface for differing underlying forms (data types).
Here's an example of applied polymorphism - the
LogManager.Register method is happy to work with any object that implements the
ILogger interface; here a
DebugLogger and a
FileLogger - two wildly different implementations of that interface, are being registered; when
LogManager.Log(ErrorLevel, Err.Description) is invoked later, the two implementations will each do their own thing;
DebugLogger will output to the immediate toolwindow, and
FileLogger will write an entry into a specified log file:
LogManager.Register DebugLogger.Create("MyLogger", DebugLevel)
LogManager.Register Filelogger.Create("TestLogger", ErrorLevel, "C:\Dev\VBA\log.txt")
Inheritance - VBA does not let you derive a type from another: inheritance is not supported.
Now the question is, can a language that doesn't support inheritance be qualified as "object-oriented"? It turns out composition is very often preferable to inheritance, which has a number of caveats. And VBA will let you compose objects to your heart's content.
Is VBA an OOP language?
Given all that's missing is inheritance, and that composition is preferable to inheritance, I'm tempted to answer "Yes". I've written full-blown OOP VBA code before (Model-View-Presenter with Unit-of-Work and Repository, anyone?), that I wouldn't have written any differently in a "real OOP" language that supports inheritance.
Here are a few examples, all 100% VBA:
The code in this last link was eventually ported to C#, and quickly evolved into a COM add-in for the VBA IDE that gives you refactorings, better navigation, code inspections, and other tools.
VBA is only as limiting as you make it.