127

I have a main class that has a ton of different functions in it. It's getting hard to manage. I'd like to be able to separate those functions into a separate file, but I'm finding it hard to come up with a good way to do so.

Here's what I've done so far:

File main.py

import separate

class MainClass(object):
    self.global_var_1 = ...
    self.global_var_2 = ...

    def func_1(self, x, y):
        ...
    def func_2(self, z):
        ...
    # tons of similar functions, and then the ones I moved out:

    def long_func_1(self, a, b):
        return separate.long_func_1(self, a, b)

File separate.py

def long_func_1(obj, a, b):
    if obj.global_var_1:
        ...
    obj.func_2(z)
    ...
    return ...
# Lots of other similar functions that use info from MainClass

I do this because if I do:

obj_1 = MainClass()

I want to be able to do:

obj_1.long_func_1(a, b)

instead of:

separate.long_func_1(obj_1, a, b)

I know this seems kind of nit-picky, but I want just about all of the code to start with obj_1., so there isn't confusion.

Is there a better solution that what I'm currently doing? The only issues that I have with my current setup are:

  1. I have to change arguments for both instances of the function
  2. It seems needlessly repetitive

I know this has been asked a couple of times, but I couldn't quite understand the previous answers and/or I don't think the solution quite represents what I'm shooting for. I'm still pretty new to Python, so I'm having a tough time figuring this out.

7
  • 13
    If you are new to Python, just stick to the conventions and keep all methods for a class in the same file.
    – Martijn Pieters
    Commented Nov 29, 2017 at 21:09
  • 5
    If you must group your methods into separate modules, use inheritance; create a base class in one module, import it and subclass it in the other.
    – Martijn Pieters
    Commented Nov 29, 2017 at 21:11
  • 4
    @MartijnPieters I know I could do that, but none of the functions within the class are finalized, so I find myself scrolling a lot to find the appropriate one, which takes more time than I'd like simply because there's so many.
    – user7729352
    Commented Nov 29, 2017 at 21:11
  • 4
    That's not a problem to be solved by changing the code; that's a problem to be solved by using an IDE which allows you to jump to the location of a function. (Or use your text editor's "find" functionality.)
    – David Z
    Commented Nov 29, 2017 at 21:31
  • 3
    If a file is not enough for all the methods, then likely you have a problem with the design. The class is too heavy and probably splitting it into two or three classes (and files) is the solution.
    – trinchet
    Commented Nov 29, 2017 at 21:33

4 Answers 4

174

Here is how I do it:

  1. Class (or group of) is actually a full module. You don't have to do it this way, but if you're splitting a class on multiple files I think this is 'cleanest' (opinion).

  2. The definition is in __init__.py, methods are split into files by a meaningful grouping.

  3. A method file is just a regular Python file with functions, except you can't forget 'self' as a first argument. You can have auxiliary methods here, both taking self and not.

  4. Methods are imported directly into the class definition.

Suppose my class is some fitting GUI (this is actually what I did this for first time). So my file hierarchy may look something like

mymodule/
     __init__.py
     _plotstuff.py
     _fitstuff.py
     _datastuff.py

So plot stuff will have plotting methods, fit stuff contains fitting methods, and data stuff contains methods for loading and handling of data - you get the point. By convention I mark the files with a _ to indicate these really aren't meant to be imported directly anywhere outside the module. So _plotsuff.py for example may look like:

def plot(self,x,y):
     #body
def clear(self):
     #body

etc. Now the important thing is file __init__.py:

class Fitter(object):
     def __init__(self,whatever):
         self.field1 = 0
         self.field2 = whatever

     # Imported methods
     from ._plotstuff import plot, clear
     from ._fitstuff  import fit
     from ._datastuff import load

     # static methods need to be set
     from ._static_example import something
     something = staticmethod(something)

     # Some more small functions
     def printHi(self):
         print("Hello world")

Tom Sawyer mentions PEP-8 recommends putting all imports at the top, so you may wish to put them before __init__, but I prefer it this way. I have to say, my Flake8 checker does not complain, so likely this is PEP-8 compliant.

Note the from ... import ... is particularly useful to hide some 'helper' functions to your methods you don't want accessible through objects of the class. I usually also place the custom exceptions for the class in the different files, but import them directly so they can be accessed as Fitter.myexception.

If this module is in your path then you can access your class with

from mymodule import Fitter
f = Fitter()
f.load('somefile') # Imported method
f.plot()           # Imported method

It is not completely intuitive, but not too difficult either. The short version for your specific problem was you were close - just move the import into the class, and use

from separate import long_func_1

and don't forget your self!

How to use super addendum

super() is a useful nifty function allowing parent method access in a simple and readable manner from the child object. These kind of classes are big to begin with, so inheritance not always make sense, but if it does come up:

  1. For methods defined in the class itself, within __init__.py, you can use super() normally, as is.

  2. If you define you method in another module (which is kind of the point here), you can't use super as is since the function is not defined in the context of your cell, and will fail. The way to handle this is to use the self argument, and add the context yourself:

    def print_super(self):
      print('Super is:', super(type(self), self))
    

    Note you cannot omit the second argument, since out of context super does not bind the object method (which you usually want for calls like super(...).__init__()).

  3. If this is something you want to do in many methods in different modules, you may want to provide a super method in the __init__.py file for use:

    def MySuper(self):
        return super()
    

usable by self in all methods.

37
  • 1
    @cowbert Outside, see tabbing. I'll add some example code to make it clear. You only need it to compile once with the class, not every object.
    – kabanus
    Commented Nov 29, 2017 at 21:55
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    I'd like to add as a general comment that sometimes it doesn't make sense to split a class into sub-classes, and refactoring long class code is something you may run into even in Python.
    – kabanus
    Commented Nov 29, 2017 at 22:02
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    Splitting a "class" into multiple files is also common ECMAScript pattern (using the var PseudoClass = PseudoClass || {} idiom), so if you are doing some fullstack development with Python middleware, it might make sense to split a Python class for various reasons.
    – cowbert
    Commented Nov 29, 2017 at 22:44
  • 2
    @Tian Yup, same as any method. Make a file, and import it from there (from .init1 import __init__, where init1.py contains def __init__(self...):...) etc. Next time I syggest trying out these things yourself (probably faster).
    – kabanus
    Commented Oct 9, 2019 at 8:29
  • 2
    Additionally, if the tools (linter, IDE etc.) complain or cannot handle our sensible choices, the problem is with the tools. Software architecture should be served by the tools not the opposite. BTW, the Python built-in libs themselves are plenty of examples of better choices, including name convention, than that recommended by PEP8 (which is intended for the language development, not as a sacred book for everything else).
    – dawid
    Commented Oct 22, 2020 at 23:32
24

I use the approach I found here. It shows many different approaches, but if you scroll down to the end, the preferred method is to basically go the opposite direction of @Martin Pieter's suggestion which is have a base class that inherits other classes with your methods in those classes.

So the folder structure is something like:

_DataStore/
    __init__.py
    DataStore.py
    _DataStore.py

So your base class would be:

File DataStore.py

import _DataStore

class DataStore(_DataStore.Mixin): # Could inherit many more mixins

    def __init__(self):
        self._a = 1
        self._b = 2
        self._c = 3

    def small_method(self):
        return self._a

Then your Mixin class:

File _DataStore.py

class Mixin:

    def big_method(self):
        return self._b

    def huge_method(self):
        return self._c

Your separate methods would be located in other appropriately named files, and in this example it is just _DataStore.

I am interested to hear what others think about this approach. I showed it to someone at work and they were scared by it, but it seemed to be a clean and easy way to separate a class into multiple files.

6
  • 3
    I think it's a valid approach. You might also raise an exception in __init__ from the Mixin class to discourage users to instantiate the Mixin class.
    – mjspier
    Commented Nov 18, 2019 at 10:32
  • 2
    I have used mixins, probably too much. It is an easy way to keep file sizes down but lets class sizes be any size. The problem is you aren't refactoring the way you do with inheritance, rather, just making a mega-class. Whether using mixins or monkey patching, the downfall is your linter can't process it, so you have to find errors the hard way. For this one reason, subclassing is preferred, not to mention better encapsulation, et al.
    – Wyrmwood
    Commented Aug 27, 2020 at 22:58
  • 1
    This approach follows KISS (keep-it-simple-stupid) pattern, so for non-python programmers would be easier to understand what is going on. "working" does not always mean "maintainable".
    – xmantas
    Commented Sep 25, 2022 at 14:45
  • 1
    I'm using PyCharm, and it can't find any variables set in __init__ on the main class. The way I get around this is to add a type references to the top of the class with all the variables needed. Eg add company: Company in the class scope.
    – Dolan
    Commented Sep 29, 2022 at 0:11
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    @Dolan I wish I knew how precisely to add a so called type reference for that, but if I just add such type hints in global scope right after the class definition, PyCharm winds down its error indications. I'm just not sure what those type hints mean to the python interpreter.
    – matanox
    Commented Apr 25, 2023 at 14:57
9

Here is an implementation of Martijn Pieters's comment to use subclasses:

File main.py

from separate import BaseClass

class MainClass(BaseClass):
    def long_func_1(self, a, b):
        if self.global_var_1:
            ...
        self.func_2(z)
        ...
        return ...
    # Lots of other similar functions that use info from BaseClass

File separate.py

class BaseClass(object):

    # You almost always want to initialize instance variables in the `__init__` method.
    def __init__(self):
        self.global_var_1 = ...
        self.global_var_2 = ...

    def func_1(self, x, y):
        ...
    def func_2(self, z):
        ...
    # tons of similar functions, and then the ones I moved out:
    #
    # Why are there "tons" of _similar_ functions?
    # Remember that functions can be defined to take a
    # variable number of/optional arguments, lists/tuples
    # as arguments, dicts as arguments, etc.

from main import MainClass
m = MainClass()
m.func_1(1, 2)
....
0

I find it easier to work with multiple inheritance of Separate classes because it allows me to access all methods and variables from the Main class without the need to redefine them.

Each Separate class can be defined in a separate file, and will be designed to handle a specific purpose related to the Main class, rather than being applicable to other Separate classes.

There are a few tricks to handle typing properly and to prevent issues with circular imports. It is also important to ensure distinct names for methods and variables defined in the Main and Separate classes, this prevents any conflicts since they are all inherited by Main.

This is how it works:

File shared.py

# The following classes can be imported by both main and separate files    
class Shared1: ...
class Shared2: ...

File main.py

from shared import Shared1, Shared2
from _separate_1 import Separate1
from _separate_2 import Separate2

# Main will inherit all Separate1 and Separate2 methods
class Main(Separate1, Separate2):
    def __init__(self):
        # Note that using super().__init__() with multiple inheritance 
        # will only call the constructor of the first parent class. With
        # multiple inheritance we need to explicitly call the constructors 
        # of each parent class using their respective class names
        Separate1.__init__(self)
        Separate2.__init__(self)
        # global variables can also be used in the separate files
        self.global_var_1: Shared1 = ...
        self.global_var_2: Shared2 = ...
        # the following variables will be used only in this file
        self.var_1 = ...
        self.var_2 = ...
        ...
    
    # The following methods will only be used in this file, but they can
    # call any other methods or variables inherited from a Separate class
    def func_1(self, ...):
        ...
    def func_2(self, ...):
        ...

File _separate_1.py

from shared import Shared1, Shared2

class Separate1:
    # We can use type hints to refer to the global variables
    global_var_1: Shared1
    global_var_2: Shared2

    def __init__(self):
        # Variables defined here are mainly used in this file 
        self.var_3 = ...
        ...
    # The following functions will be inherited by the Main class
    def long_func_1(self, ...): ...
    def long_func_2(self, ...): ...

File _separate_2.py

from shared import Shared2

class Separate2:
    # global variables can be used by any Separate classes
    global_var_2: Shared2

    def __init__(self):
        # use distinct names for variables
        self.var_4 = ...

    # use distinct names for functions
    def long_func_3(self, ...): ...
    def long_func_4(self, ...): ...

And so on, hope it helps.

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