I'm not too happy with the existing answers so I'm adding my own:
When to avoid patterns
For a sufficiently simple application every design pattern is overkill. Assume you write a GUI application that displays a single button which when pressed shows "Hello world". In this case, design patterns like MVC, MVP, MVVM all add a lot of complexity, while not adding any value whatsoever.
In general, it is always a bad decision to introduce a design pattern just because it somewhat fits. Design patterns should be used to reduce complexity, either by directly reducing overall complexity, or by replacing unfamiliar complexity with familiar complexity. If the design pattern cannot reduce complexity in either of these 2 ways, do not use it.
To explain familiar and unfamiliar complexity, take the following 2 sequences of characters:
While the second character sequence is twice the length of the first sequence, it's easier to read, faster to write, and easier to remember than the first sequence, all because it's more familiar. The same holds true for familiar patterns in code.
Be conscious of the fact that some patterns may not be familiar to all developers who are going to work with the code in the future. In terms of the previous example, the following sequence may or may not be easier to remember than either of the sequences above, depending on the individual skills of the person remembering it: "3.14159265358979323846264338327950". In some cases where more advanced design patterns are involved, it only makes sense to use a design pattern if the maintenance developers are already familiar with it.
That said, let's dive into the topic of MVVM by means of an example. MVVM guides us how to distribute responsibilities between classes in a GUI application (or between layers - more about this later), with the goal of having a small number of classes, while keeping the number of responsibilities per class small and well defined.
'Proper' MVVM assumes at least a moderately complex application, which deals with data it gets from "somewhere". It may get the data from a database, a file, a web service, or from a myrad of other sources.
In our example, we have a View and a Model, but no ViewModel. The Model wraps a csv-file which it reads on startup and saves when the application shuts down, with all changes the user made to the data. The View displays the data from the Model in a table and lets the user edit the data.
Now we are asked to make a change to our application. The data consists of a 2-dimensional grid which already has a "price" column, which contains a price in USD. We need to add a new column which shows prices in Euro in addition to those in USD, based on a predefined exchange rate. The format of the csv-file must not change because other applications work with the file too.
A possible solution is to simply add the new column to the Model class. Because the Model saves all the data it exposes to the View to the csv, and we do not want a new Euro price column in the csv, the change to the Model would be non-trivial. It would also be harder to describe what the Model class does.
We could also make the change in the View, but our current application uses data binding to display the data directly as provided by our Model class. Because our GUI framework doesn't allow us to introduce an additional calculated column in a table when the table is data bound to a data source, we would need to make a significant change to the View to make this work, making the View a lot more complex.
There is no ViewModel in the application because until now the Model presented the data in exactly the way the View needed it. That is a good thing. Because the Model no longer presents the data in the way the View needs it, we now write a ViewModel. The new ViewModel subscribes to the Model, and exposes the Model's data to the View with an an extra column displaying the price in Euros. The View no longer knows the Model, it now only knows the ViewModel, which looks the same to the View as the Model did before - except that the exposed data contains a new read only column.
The next customer request is that we should not display the data as rows in a table, but instead display the information of each item (a.k.a. row) as a card/box, and display 20 boxes on the screen in a 4x5 grid, showing 20 boxes at a time. Because we kept the logic of the View simple, we simply replace the View entirely with a new class that does as the customer desires. If you came across this situation before, you know that there is another customer who preferred the old View. You now need to support both, but because all of the common business logic already happens to be in the ViewModel that is not much of an issue.
The next customer request is that we pull the exchange rate from the internet, rather than using a customer supplied exchange rate. This is the point where we revisit my earlier statement about a "layers". We don't change our Model class to provide an exchange rate. Instead we write (or find) a completely independent additional class that provides the exchange rate. That new class becomes part of the model layer, and our ViewModel consolidates the information of the csv-Model and the exchange-rate-Model, which it then presents to the View. For this change the old Model class and the View class do not even have to be touched.
If we hadn't introduced the ViewModel when we did but had instead waited until now to do so, the amount of work to introduce the ViewModel now would be higher because we need to remove significant amounts of functionality from both of the the Views and the Model and move the functionality into the ViewModel.
- MVVM guides us how to distribute responsibilities between classes in a GUI application.
- ViewModel projects the data from the Model into a format that fits the View.
- For trivial projects MVVM is unnecesary. Using only the View is sufficient.
- For simple projects, the ViewModel/Model split may be unnecessary.
- Model and ViewModel do not need to exist from the start and can be introduced when they are needed.
Afterword on Unit Tests
The primary purpose of MVVM is not that the code in the Model and the ViewModel can be put under Unit Test. The primary purpose of MVVM is that the code is broken up into classes with a small number of well defined responsibilities. One of several benefits of having code consisting of classes with a small number of well defined responsibilities is that it is easier to put the code under Unit Test. A much larger benefit is that the code is easier to understand, maintain, and modify.