I have been programming in python for about two years; mostly data stuff (pandas, mpl, numpy), but also automation scripts and small web apps. I'm trying to become a better programmer and increase my python knowledge and one of the things that bothers me is that I have never used a class (outside of copying random flask code for small web apps). I generally understand what they are, but I can't seem to wrap my head around why I would need them over a simple function.

To add specificity to my question: I write tons of automated reports which always involve pulling data from multiple data sources (mongo, sql, postgres, apis), performing a lot or a little data munging and formatting, writing the data to csv/excel/html, send it out in an email. The scripts range from ~250 lines to ~600 lines. Would there be any reason for me to use classes to do this and why?

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    there is nothing wrong to code with no classes if you can manage your code nicer. OOP programmers tend to exaggerate the problems due to the constraints from the language design or superficial understanding of different patterns.
    – Jason Hu
    Commented Oct 12, 2015 at 3:37
  • 1
    If a procedural design with the call stack gets it done you don't need to bring classes into the picture, especially if you're only doing procedural stuff with the class anyways. I've always felt you should use the minimal representation to get to job done and only invoke more powerful logical/semantic structures when necessary. To mobilize more complexity in solutions that exceed the level of complexity in the problem itself is to me an antipattern, something in the direction of over-engineering. Which solution presents the minimal cognitive load comes into play too.
    – jxramos
    Commented Mar 5 at 18:19

6 Answers 6


Classes are the pillar of Object Oriented Programming. OOP is highly concerned with code organization, reusability, and encapsulation.

First, a disclaimer: OOP is partially in contrast to Functional Programming, which is a different paradigm used a lot in Python. Not everyone who programs in Python (or surely most languages) uses OOP. You can do a lot in Java 8 that isn't very Object Oriented. If you don't want to use OOP, then don't. If you're just writing one-off scripts to process data that you'll never use again, then keep writing the way you are.

However, there are a lot of reasons to use OOP.

Some reasons:

  • Organization: OOP defines well known and standard ways of describing and defining both data and procedure in code. Both data and procedure can be stored at varying levels of definition (in different classes), and there are standard ways about talking about these definitions. That is, if you use OOP in a standard way, it will help your later self and others understand, edit, and use your code. Also, instead of using a complex, arbitrary data storage mechanism (dicts of dicts or lists or dicts or lists of dicts of sets, or whatever), you can name pieces of data structures and conveniently refer to them.

  • State: OOP helps you define and keep track of state. For instance, in a classic example, if you're creating a program that processes students (for instance, a grade program), you can keep all the info you need about them in one spot (name, age, gender, grade level, courses, grades, teachers, peers, diet, special needs, etc.), and this data is persisted as long as the object is alive, and is easily accessible. In contrast, in pure functional programming, state is never mutated in place.

  • Encapsulation: With encapsulation, procedure and data are stored together. Methods (an OOP term for functions) are defined right alongside the data that they operate on and produce. In a language like Java that allows for access control, or in Python, depending upon how you describe your public API, this means that methods and data can be hidden from the user. What this means is that if you need or want to change code, you can do whatever you want to the implementation of the code, but keep the public APIs the same.

  • Inheritance: Inheritance allows you to define data and procedure in one place (in one class), and then override or extend that functionality later. For instance, in Python, I often see people creating subclasses of the dict class in order to add additional functionality. A common change is overriding the method that throws an exception when a key is requested from a dictionary that doesn't exist to give a default value based on an unknown key. This allows you to extend your own code now or later, allow others to extend your code, and allows you to extend other people's code.

  • Reusability: All of these reasons and others allow for greater reusability of code. Object oriented code allows you to write solid (tested) code once, and then reuse over and over. If you need to tweak something for your specific use case, you can inherit from an existing class and overwrite the existing behavior. If you need to change something, you can change it all while maintaining the existing public method signatures, and no one is the wiser (hopefully).

Again, there are several reasons not to use OOP, and you don't need to. But luckily with a language like Python, you can use just a little bit or a lot, it's up to you.

An example of the student use case (no guarantee on code quality, just an example):

Object Oriented

class Student(object):
    def __init__(self, name, age, gender, level, grades=None):
        self.name = name
        self.age = age
        self.gender = gender
        self.level = level
        self.grades = grades or {}

    def setGrade(self, course, grade):
        self.grades[course] = grade

    def getGrade(self, course):
        return self.grades[course]

    def getGPA(self):
        return sum(self.grades.values())/len(self.grades)

# Define some students
john = Student("John", 12, "male", 6, {"math":3.3})
jane = Student("Jane", 12, "female", 6, {"math":3.5})

# Now we can get to the grades easily

Standard Dict

def calculateGPA(gradeDict):
    return sum(gradeDict.values())/len(gradeDict)

students = {}
# We can set the keys to variables so we might minimize typos
name, age, gender, level, grades = "name", "age", "gender", "level", "grades"
john, jane = "john", "jane"
math = "math"
students[john] = {}
students[john][age] = 12
students[john][gender] = "male"
students[john][level] = 6
students[john][grades] = {math:3.3}

students[jane] = {}
students[jane][age] = 12
students[jane][gender] = "female"
students[jane][level] = 6
students[jane][grades] = {math:3.5}

# At this point, we need to remember who the students are and where the grades are stored. Not a huge deal, but avoided by OOP.
  • Because of "yield" Python encapsulation is often cleaner with generators and context managers than with classes. Commented Oct 12, 2015 at 4:29
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    @meter I added an example. I hope it helps. The note here is that instead of having to rely on the keys of your dicts having the correct name, the Python interpreter makes this constraint for you if you mess up and forces you to use defined methods (though not defined fields (though Java and other OOP languages don't let you define fields outside of classes like Python)).
    – dantiston
    Commented Oct 12, 2015 at 5:34
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    @meter also, as an example of encapsulation: let's say today this implementation is fine because I only need to get the GPA for 50,000 students at my university once a term. Now tomorrow we get a grant and need to give the current GPA of every student every second (of course, nobody would ask for this, but just to make it computationally challenging). We could then "memoize" the GPA and only calculate it when it changes (for instance, by setting a variable in the setGrade method), other return a cached version. The user still uses getGPA() but the implementation has changed.
    – dantiston
    Commented Oct 12, 2015 at 5:37
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    @dantiston, this example needs collections.namedtuple. You can create a new type Student = collections.namedtuple("Student", "name, age, gender, level, grades"). And then you can create instances john = Student("John", 12, "male", grades = {'math':3.5}, level = 6). Notice that you use both positional and named arguments just as you would with creating of a class. This is a data type that's already implemented for you in Python. You can then refer to john[0] or john.name to get the 1st element of the tuple. You can get john's grades as john.grades.values() now. And it's already done for you. Commented Oct 12, 2015 at 9:11
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    for me encapsulation is a good enough reason to always use OOP. I struggle to see value is NOT using OOP for any reasonably sized coding project. I guess I need answers to the reverse question :)
    – San Jay
    Commented Oct 31, 2018 at 20:15

Whenever you need to maintain a state of your functions and it cannot be accomplished with generators (functions which yield rather than return). Generators maintain their own state.

If you want to override any of the standard operators, you need a class.

Whenever you have a use for a Visitor pattern, you'll need classes. Every other design pattern can be accomplished more effectively and cleanly with generators, context managers (which are also better implemented as generators than as classes) and POD types (dictionaries, lists and tuples, etc.).

If you want to write "pythonic" code, you should prefer context managers and generators over classes. It will be cleaner.

If you want to extend functionality, you will almost always be able to accomplish it with containment rather than inheritance.

As every rule, this has an exception. If you want to encapsulate functionality quickly (ie, write test code rather than library-level reusable code), you can encapsulate the state in a class. It will be simple and won't need to be reusable.

If you need a C++ style destructor (RAII), you definitely do NOT want to use classes. You want context managers.

  • 1
    @DmitryRubanovich closures are not implemented via generators in Python. Commented Jan 6, 2018 at 22:31
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    @DmitryRubanovich I was referring to "closures are implemented as generators in Python", which is not true. Closures are far more flexible. Generators are bound to return a Generator instance (a special iterator), while closures can have any signature. You can basically avoid classes most of the time by creating closures. And closures are not merely "functions defined in the context of other functions". Commented Jan 6, 2018 at 22:45
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    @Eli Korvigo, in fact, generators are a significant leap syntactically. They create an abstraction of a queue in the same way that functions are abstractions of a stack. And most data flow can pieced together from the stack/queue primitives. Commented Jan 6, 2018 at 23:36
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    @DmitryRubanovich we are talking apples and oranges here. I'm saying, that generators are useful in a very limited number of cases and can in no way be considered a substitution for general purpose stateful callables. You are telling me, how great they are, without contradicting my points. Commented Jan 6, 2018 at 23:38
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    @Eli Korvigo, and I am saying that callables are only generalizations of functions. Which themselves are syntactic sugar over processing of stacks. While generators are syntactic sugar over processing of queues. But it is this improvement in syntax that allows for more complicated constructs to be built up easily and with more clear syntax. '.next()' is almost never used, btw. Commented Jan 6, 2018 at 23:44

I think you do it right. Classes are reasonable when you need to simulate some business logic or difficult real-life processes with difficult relations. As example:

  • Several functions with share state
  • More than one copy of the same state variables
  • To extend the behavior of an existing functionality

I also suggest you to watch this classic video

  • 3
    There is no need to use a class when a callback function needs a persistent state in Python. Using Python's yield instead of return makes a function re-entrant. Commented Oct 12, 2015 at 9:25
  • I second the recommendation for the Stop Writing Classes talk by Jack Diederich. Coming from a Java background as the first programming language I was stuck in the OOP paradigm with the whole when you have a hammer everything looks like a nail mentality. With python I started to enter into the mindset of matching the solution complexity to the problem complexity and thinking about a semantic alignment between the two that seeks to invoke nothing more and obviously nothing less in order to solve the problem at hand.
    – jxramos
    Commented Mar 5 at 18:26
  • To share a concrete example take python comprehensions, you can often accomplish the same thing with a for loop but a for loop is more general and covers a broader solution space. A comp will only give you a container at the end of the day. So right when you see the signature of a comprehension you know "I'm getting a container back", when you see the signature of a for loop you need to keep the mind open longer to digest what exactly the for loop is accomplishing. One has a broader mental model, one is shallower. Using the minimal shallowest solution fit is good in python or in any language
    – jxramos
    Commented Mar 5 at 18:29

dantiston gives a great answer on why OOP can be useful. However, it is worth noting that OOP is not necessary a better choice most cases it is used. OOP has the advantage of combining data and methods together. In terms of application, I would say that use OOP only if all the functions/methods are dealing and only dealing with a particular set of data and nothing else.

Consider a functional programming refactoring of dentiston's example:

def dictMean( nums ):
    return sum(nums.values())/len(nums)
# It's good to include automatic tests for production code, to ensure that updates don't break old codes
assert( dictMean({'math':3.3,'science':3.5})==3.4 )

john = {'name':'John', 'age':12, 'gender':'male', 'level':6, 'grades':{'math':3.3}}

# setGrade

# getGrade

# getGPA

At a first look, it seems like all the 3 methods exclusively deal with GPA, until you realize that Student.getGPA() can be generalized as a function to compute mean of a dict, and re-used on other problems, and the other 2 methods reinvent what dict can already do.

The functional implementation gains:

  1. Simplicity. No boilerplate class or selfs.
  2. Easily add automatic test code right after each function for easy maintenance.
  3. Easily split into several programs as your code scales.
  4. Reusability for purposes other than computing GPA.

The functional implementation loses:

  1. Typing in 'name', 'age', 'gender' in dict key each time is not very DRY (don't repeat yourself). It's possible to avoid that by changing dict to a list. Sure, a list is less clear than a dict, but this is a none issue if you include an automatic test code below anyway.

Issues this example doesn't cover:

  1. OOP inheritance can be supplanted by function callback.
  2. Calling an OOP class has to create an instance of it first. This can be boring when you don't have data in __init__(self).

A class defines a real world entity. If you are working on something that exists individually and has its own logic that is separate from others, you should create a class for it. For example, a class that encapsulates database connectivity.

If this not the case, no need to create class


It depends on your idea and design. If you are a good designer, then OOPs will come out naturally in the form of various design patterns.

For simple script-level processing, OOPs can be overhead.

Simply consider the basic benefits of OOPs like reusability and extendability and make sure if they are needed or not.

OOPs make complex things simpler and simpler things complex.

Simply keep the things simple in either way using OOPs or not using OOPs. Whichever is simpler, use that.

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