# Introduction to Python classes and objects We have now learned how to run some simple Python code from inside (and outside) your game server. We have also taken a look at what our game dir looks and what is where. Now we'll start to use it. ## Importing things In a [previous lesson](./Beginner-Tutorial-Python-basic-introduction.md#importing-code-from-other-modules) we already learned how to import resources into our code. Now we'll dive a little deeper. No one writes something as big as an online game in one single huge file. Instead one breaks up the code into separate files (modules). Each module is dedicated to different purposes. Not only does it make things cleaner, organized and easier to understand. Splitting code also makes it easier to re-use - you just import the resources you need and know you only get just what you requested. This makes it easier to spot errors and to know what code is good and which has issues. > Evennia itself uses your code in the same way - you just tell it where a particular type of code is, and it will import and use it (often instead of its defaults). Here's a familiar example: > py import world.test ; world.test.hello_world(me) Hello World! In this example, on your hard drive, the files looks like this: ``` mygame/ world/ test.py <- inside this file is a function hello_world ``` If you followed earlier tutorial lessons, the `mygame/world/test.py` file should look like this (if not, make it so): ```python def hello_world(who): who.msg("Hello World!") ``` ```{sidebar} Whitespace matters in Python! - Indentation matters in Python - So does capitalization - Use 4 `spaces` to indent, not tabs - Empty lines are fine - Anything on a line after a `#` is a `comment`, ignored by Python ``` To reiterate, the _python_path_ describes the relation between Python resources, both between and inside Python _modules_ (that is, files ending with .py). Paths use `.` and always skips the `.py` file endings. Also, Evennia already knows to start looking for python resources inside `mygame/` so this should never be included. import world.test The `import` Python instruction loads `world.test` so you have it available. You can now go "into" this module to get to the function you want: world.test.hello_world(me) Using `import` like this means that you have to specify the full `world.test` every time you want to get to your function. Here's an alternative: from world.test import hello_world The `from ... import ...` is very, very common as long as you want to get something with a longer python path. It imports `hello_world` directly, so you can use it right away! > py from world.test import hello_world ; hello_world(me) Hello World! Let's say your `test.py` module had a bunch of interesting functions. You could then import them all one by one: from world.test import hello_world, my_func, awesome_func If there were _a lot_ of functions, you could instead just import `test` and get the function from there when you need (without having to give the full `world.test` every time): > from world import test ; test.hello_world(me) Hello World! You can also _rename_ stuff you import. Say for example that the module you import to already has a function `hello_world` but we also want to use the one from `world/test.py`: from world.test import hello_world as test_hello_world The form `from ... import ... as ...` renames the import. > from world.test import hello_world as hw ; hw(me) Hello World! > Avoid renaming unless it's to avoid a name-collistion like above - you want to make things as easy to read as possible, and renaming adds another layer of potential confusion. In [the basic intro to Python](./Beginner-Tutorial-Python-basic-introduction.md) we learned how to open the in-game multi-line interpreter. > py Evennia Interactive Python mode Python 3.7.1 (default, Oct 22 2018, 11:21:55) [GCC 8.2.0] on Linux [py mode - quit() to exit] You now only need to import once to use the imported function over and over. > from world.test import hello_world > hello_world(me) Hello World! > hello_world(me) Hello World! > hello_world(me) Hello World! > quit() Closing the Python console. ```{sidebar} Alternative to py If you find entering multiple lines in the `py` command clunky (a traditional mud client is pretty limited for this kind of thing) you can also `cd` to your `mygame` folder and run `evennia shell`. You will end up in a python shell where Evennia is available. If you do `pip install ipython` you'll get an even more modern python shell to use. This works outside the game but `print` will show in the same way. ``` The same goes when writing code in a module - in most Python modules you will see a bunch of imports at the top, resources that are then used by all code in that module. ## On classes and objects Now that we know about imports, let look at a real Evennia module and try to understand it. Open `mygame/typeclasses/scripts.py` in your text editor of choice. ```python # mygame/typeclasses/script.py """ module docstring """ from evennia import DefaultScript class Script(DefaultScript): """ class docstring """ pass ``` ```{sidebar} Docstrings vs Comments A docstring is not the same as a comment (created by `#`). A docstring is not ignored by Python but is an integral part of the thing it is documenting (the module and the class in this case). For example, we read docstrings to help text for [API documentation](../../../Evennia-API.md); we could not do that with comments. ``` The real file is much longer but we can ignore the multi-line strings (`""" ... """`). These serve as documentation-strings, or _docstrings_ for the module (at the top) and the `class` below. Below the module doc string we have the _import_. In this case we are importing a resource from the core `evennia` library itself. We will dive into this later, for now we just treat this as a black box. The `class` named `Script` _ inherits_ from `DefaultScript`. As you can see `Script` is pretty much empty. All the useful code is actually in `DefaultScript` (`Script` _inherits_ that code unless it _overrides_ it with same-named code of its own). We need to do a little detour to understand what a 'class', an 'object' or 'instance' is. These are fundamental things to understand before you can use Evennia efficiently. ```{sidebar} OOP Classes, objects, instances and inheritance are fundamental to Python. This and some other concepts are often clumped together under the term Object-Oriented-Programming (OOP). ``` ### Classes and instances A 'class' can be seen as a 'template' for a 'type' of object. The class describes the basic functionality of everyone of that class. For example, we could have a class `Monster` which has resources for moving itself from room to room. Open a new file `mygame/typeclasses/monsters.py`. Add the following simple class: ```python class Monster: key = "Monster" def move_around(self): print(f"{self.key} is moving!") ``` Above we have defined a `Monster` class with one variable `key` (that is, the name) and one _method_ on it. A method is like a function except it sits "on" the class. It also always has at least one argument (almost always written as `self` although you could in principle use another name), which is a reference back to itself. So when we print `self.key` we are referring back to the `key` on the class. ```{sidebar} Terms - A `class` is a code template describing a 'type' of something - An `object` is an `instance` of a `class`. Like using a mold to cast tin soldiers, one class can be `instantiated` into any number of object-instances. Each instance does not need to be identical (much like each tin soldier can be painted differently). ``` A class is just a template. Before it can be used, we must create an _instance_ of the class. If `Monster` is a class, then an instance is `Fluffy`, a specific dragon individual. You instantiate by _calling_ the class, much like you would a function: fluffy = Monster() Let's try it in-game (we use `py` multi-line mode, it's easier) > py > from typeclasses.monsters import Monster > fluffy = Monster() > fluffy.move_around() Monster is moving! We created an _instance_ of `Monster`, which we stored in the variable `fluffy`. We then called the `move_around` method on fluffy to get the printout. > Note how we _didn't_ call the method as `fluffy.move_around(self)`. While the `self` has to be there when defining the method, we _never_ add it explicitly when we call the method (Python will add the correct `self` for us automatically behind the scenes). Let's create the sibling of Fluffy, Cuddly: > cuddly = Monster() > cuddly.move_around() Monster is moving! We now have two monsters and they'll hang around until with call `quit()` to exit this Python instance. We can have them move as many times as we want. But no matter how many monsters we create, they will all show the same printout since `key` is always fixed as "Monster". Let's make the class a little more flexible: ```python class Monster: def __init__(self, key): self.key = key def move_around(self): print(f"{self.key} is moving!") ``` The `__init__` is a special method that Python recognizes. If given, this handles extra arguments when you instantiate a new Monster. We have it add an argument `key` that we store on `self`. Now, for Evennia to see this code change, we need to reload the server. You can either do it this way: > quit() Python Console is closing. > reload Or you can use a separate terminal and restart from outside the game: ```{sidebar} On reloading Reloading with the python mode gets a little annoying since you need to redo everything after every reload. Just keep in mind that during regular development you will not be working this way. The in-game python mode is practical for quick fixes and experiments like this, but actual code is normally written externally, in python modules. ``` $ evennia reload (or restart) Either way you'll need to go into `py` again: > py > from typeclasses.monsters import Monster fluffy = Monster("Fluffy") fluffy.move_around() Fluffy is moving! Now we passed `"Fluffy"` as an argument to the class. This went into `__init__` and set `self.key`, which we later used to print with the right name! ### What's so good about objects? So far all we've seen a class do is to behave like our first `hello_world` function but being more complex. We could just have made a function: ```python def monster_move_around(key): print(f"{key} is moving!") ``` The difference between the function and an instance of a class (the object), is that the object retains _state_. Once you called the function it forgets everything about what you called it with last time. The object, on the other hand, remembers changes: > fluffy.key = "Fluffy, the red dragon" > fluffy.move_around() Fluffy, the red dragon is moving! The `fluffy` object's `key` was changed for as long as it's around. This makes objects extremely useful for representing and remembering collections of data - some of which can be other objects in turn. Some examples: - A player character with all its stats - A monster with HP - A chest with a number of gold coins in it - A room with other objects inside it - The current policy positions of a political party - A rule with methods for resolving challenges or roll dice - A multi-dimenstional data-point for a complex economic simulation - And so much more! ### Classes can have children Classes can _inherit_ from each other. A "child" class will inherit everything from its "parent" class. But if the child adds something with the same name as its parent, it will _override_ whatever it got from its parent. Let's expand `mygame/typeclasses/monsters.py` with another class: ```python class Monster: """ This is a base class for Monster. """ def __init__(self, key): self.key = key def move_around(self): print(f"{self.key} is moving!") class Dragon(Monster): """ This is a dragon monster. """ def move_around(self): print(f"{self.key} flies through the air high above!") def firebreath(self): """ Let our dragon breathe fire. """ print(f"{self.key} breathes fire!") ``` We added some docstrings for clarity. It's always a good idea to add doc strings; you can do so also for methods, as exemplified for the new `firebreath` method. We created the new class `Dragon` but we also specified that `Monster` is the _parent_ of `Dragon` but adding the parent in parenthesis. `class Classname(Parent)` is the way to do this. ```{sidebar} Multi-inheritance It's possible to add more comma-separated parents to a class. We show an example of such 'multiple inheritance' last in this lesson. You should usually avoid yourself setting up multiple inheritance until you know what you are doing. A single parent will be enough for almost every case you'll need. ``` Let's try out our new class. First `reload` the server and then: > py > from typeclasses.monsters import Dragon > smaug = Dragon("Smaug") > smaug.move_around() Smaug flies through the air high above! > smaug.firebreath() Smaug breathes fire! Because we didn't (re)implement `__init__` in `Dragon`, we got the one from `Monster`. We did implement our own `move_around` in `Dragon`, so it _overrides_ the one in `Monster`. And `firebreath` is only available for `Dragon`s. Having that on `Monster` would not have made much sense, since not every monster can breathe fire. One can also force a class to use resources from the parent even if you are overriding some of it. This is done with the `super()` method. Modify your `Dragon` class as follows: ```python # ... class Dragon(Monster): def move_around(self): super().move_around() print("The world trembles.") # ... ``` > Keep `Monster` and the `firebreath` method. The `# ...` above indicates the rest of the code is unchanged. The `super().move_around()` line means that we are calling `move_around()` on the parent of the class. So in this case, we will call `Monster.move_around` first, before doing our own thing. To see, `reload` the server and then: > py > from typeclasses.monsters import Dragon > smaug = Dragon("Smaug") > smaug.move_around() Smaug is moving! The world trembles. We can see that `Monster.move_around()` is called first and prints "Smaug is moving!", followed by the extra bit about the trembling world from the `Dragon` class. Inheritance is a powerful concept. It allows you to organize and re-use code while only adding the special things you want to change. Evennia uses this a lot. ### A look at multiple inheritance Open `mygame/typeclasses/objects.py` in your text editor of choice. ```python """ module docstring """ from evennia import DefaultObject class ObjectParent: """ class docstring """ pass class Object(ObjectParent, DefaultObject): """ class docstring """ pass ``` In this module we have an empty `class` named `ObjectParent`. It doesn't do anything, its only code (except the docstring) is `pass` which means, well, to pass and don't do anything. Since it also doesn't _inherit_ from anything, it's just an empty container. The `class` named `Object`_ inherits_ from `ObjectParent` and `DefaultObject`. Normally a class only has one parent, but here there are two. We already learned that a child inherits everything from a parent unless it overrides it. When there are more than one parents ("multiple inheritance"), inheritance happens from left to right. So if `obj` is an instance of `Object` and we try to access `obj.foo`, Python will first check if the `Object` class has a property/method `foo`. Next it will check if `ObjectParent` has it. Finally, it will check in `DefaultObject`. If neither have it, you get an error. Why has Evennia set up an empty class parent like this? To answer, let's check out another module, `mygame/typeclasses/rooms.py`: ```python """ ... """ from evennia.objects.objects import DefaultRoom from .objects import ObjectParent class Room(ObjectParent, DefaultRoom): """ ... """ pass ``` Here we see that a `Room` inherits from the same `ObjectParent` (imported from `objects.py`) along with a `DefaultRoom` parent from the `evennia` library. You'll find the same is true for `Character` and `Exit` as well. These are all examples of 'in-game objects', so they could well have a lot in common. The precense of `ObjectParent` gives you an (optional) way to add code that _should be the same for all those in-game entities_. Just put that code in `ObjectParent` and all the objects, characters, rooms and exits will automatically have it as well! We will get back to the `objects.py` module in the [next lesson](./Beginner-Tutorial-Learning-Typeclasses.md). ## Summary We have created our first dragons from classes. We have learned a little about how you _instantiate_ a class into an _object_. We have seen some examples of _inheritance_ and we tested to _override_ a method in the parent with one in the child class. We also used `super()` to good effect. We have used pretty much raw Python so far. In the coming lessons we'll start to look at the extra bits that Evennia provides. But first we need to learn just where to find everything.