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Sorry if this question is a bit general but its been bugging me because I don't fully understand it. I'm a python newbie and all my programming so far has been functions and I'm starting to look at using classes(since I'm incorporating some other people's code into my programs).

I understand the idea behind classes(creates basically a function that you can modify for different a car class that you can change the color depending on your needs). I'm having trouble understanding the Initialization of the classes. What's the point of them and how do we know what to include in them? Does writing in classes require a different type of thinking versus creating functions(I figured I could just create functions and then just wrap them in a class so I can re-use them..will that work)?

Here's an example:

class crawler:
  # Initialize the crawler with the name of database
  def __init__(self,dbname):

  def __del__(self):

  def dbcommit(self):

#then the code that I understand starts....

Or another code sample:

class bicluster:
  def __init__(self,vec,left=None,right=None,distance=0.0,id=None):

There is so many of these I come across(when trying to read other people's code) but I'm somewhat at a loss to understand the logic in creating them. I'm sorry if this question is super basic, I searched around because I feel I should know this but I'm pretty confused. Any clarification on how this works would be great.

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up vote 89 down vote accepted

By what you wrote, you are missing a critical piece of understanding: the difference between a class and an object. __init__ doesn't initialize a class, it initializes an instance of a class or an object. Each dog has colour, but dogs as a class don't. Each dog has four or fewer feet, but the class of dogs doesn't. The class is a concept of an object. When you see Fido and Spot, you recognise their similarity, their doghood. That's the class.

When you say

class Dog:
    def __init__(self, legs, colour):
        self.legs = legs
        self.colour = colour

fido = Dog(4, "brown")
spot = Dog(3, "mostly yellow")

You're saying, Fido is a brown dog with 4 legs while Spot is a bit of a cripple and is mostly yellow. The __init__ function is called a constructor, or initializer, and is automatically called when you create a new instance of a class. Within that function, the newly created object is assigned to the parameter self. The notation self.legs is an attribute called legs of the object in the variable self. Attributes are kind of like variables, but they describe the state of an object, or particular actions (functions) available to the object.

However, notice that you don't set colour for the doghood itself - it's an abstract concept. There are attributes that make sense on classes. For instance, population_size is one such - it doesn't make sense to count the Fido because Fido is always one. It does make sense to count dogs. Let us say there're 200 million dogs in the world. It's the property of the Dog class. Fido has nothing to do with the number 200 million, nor does Spot. It's called a "class attribute", as opposed to "instance attributes" that are colour or legs above.

Now, to something less canine and more programming-related. As I write below, class to add things is not sensible - what is it a class of? Classes in Python make up of collections of different data, that behave similarly. Class of dogs consists of Fido and Spot and 199999999998 other animals similar to them, all of them peeing on lampposts. What does the class for adding things consist of? By what data inherent to them do they differ? And what actions do they share?

However, numbers... those are more interesting subjects. Say, Integers. There's a lot of them, a lot more than dogs. I know that Python already has integers, but let's play dumb and "implement" them again (by cheating and using Python's integers).

So, Integers are a class. They have some data (value), and some behaviours ("add me to this other number"). Let's show this:

class MyInteger:
    def __init__(self, newvalue)
        # imagine self as an index card.
        # under the heading of "value", we will write
        # the contents of the variable newvalue.
        self.value = newvalue
    def add(self, other):
        # when an integer wants to add itself to another integer,
        # we'll take their values and add them together,
        # then make a new integer with the result value.
        return MyInteger(self.value + other.value)

three = MyInteger(3)
# three now contains an object of class MyInteger
# three.value is now 3
five = MyInteger(5)
# five now contains an object of class MyInteger
# five.value is now 5
eight = three.add(five)
# here, we invoked the three's behaviour of adding another integer
# now, eight.value is three.value + five.value = 3 + 5 = 8
print eight.value
# ==> 8

This is a bit fragile (we're assuming other will be a MyInteger), but we'll ignore now. In real code, we wouldn't; we'd test it to make sure, and maybe even coerce it ("you're not an integer? by golly, you have 10 nanoseconds to become one! 9... 8....")

We could even define fractions. Fractions also know how to add themselves.

class MyFraction:
    def __init__(self, newnumerator, newdenominator)
        self.numerator = newnumerator
        self.denominator = newdenominator
        # because every fraction is described by these two things
    def add(self, other):
        newdenominator = self.denominator * other.denominator
        newnumerator = self.numerator * other.denominator + self.denominator * other.numerator
        return MyFraction(newnumerator, newdenominator)

There's even more fractions than integers (not really, but computers don't know that). Let's make two:

half = MyFraction(1, 2)
third = MyFraction(1, 3)
five_sixths = half.add(third)
print five_sixths.numerator
# ==> 5
print five_sixths.denominator
# ==> 6

You're not actually declaring anything here. Attributes are like a new kind of variable. Normal variables only have one value. Let us say you write colour = "grey". You can't have another variable named colour that is "fuchsia" - not in the same place in the code.

Arrays solve that to a degree. If you say colour = ["grey", "fuchsia"], you have stacked two colours into the variable, but you distinguish them by their position (0, or 1, in this case).

Attributes are variables that are bound to an object. Like with arrays, we can have plenty colour variables, on different dogs. So, fido.colour is one variable, but spot.colour is another. The first one is bound to the object within the variable fido; the second, spot. Now, when you call Dog(4, "brown"), or three.add(five), there will always be an invisible parameter, which will be assigned to the dangling extra one at the front of the parameter list. It is conventionally called self, and will get the value of the object in front of the dot. Thus, within the Dog's __init__ (constructor), self will be whatever the new Dog will turn out to be; within MyInteger's add, self will be bound to the object in the variable three. Thus, three.value will be the same variable outside the add, as self.value within the add.

If I say the_mangy_one = fido, I will start referring to the object known as fido with yet another name. From now on, fido.colour is exactly the same variable as the_mangy_one.colour.

So, the things inside the __init__. You can think of them as noting things into the Dog's birth certificate. colour by itself is a random variable, could contain anything. fido.colour or self.colour is like a form field on the Dog's identity sheet; and __init__ is the clerk filling it out for the first time.

Any clearer?

EDIT: Expanding on the comment below:

You mean a list of objects, don't you?

First of all, fido is actually not an object. It is a variable, which is currently containing an object, just like when you say x = 5, x is a variable currently containing the number five. If you later change your mind, you can do fido = Cat(4, "pleasing") (as long as you've created a class Cat), and fido would from then on "contain" a cat object. If you do fido = x, it will then contain the number five, and not an animal object at all.

A class by itself doesn't know its instances unless you specifically write code to keep track of them. For instance:

class Cat:
    census = []

    def __init(self, legs, colour):
        self.colour = colour
        self.legs = legs

Here, census is a class-level attribute of Cat class.

fluffy = Cat(4, "white")
spark = Cat(4, "fiery")
# ==> [<__main__.Cat instance at 0x108982cb0>, <__main__.Cat instance at 0x108982e18>]
# or something like that

Note that you won't get [fluffy, sparky]. Those are just variable names. If you want cats themselves to have names, you have to make a separate attribute for the name, and then override the __str__ method to return this name. This method's (i.e. class-bound function, just like add or __init__) purpose is to describe how to convert the object to a string, like when you print it out.

share|improve this answer
wow thanks..this actually made alot of sense to me so anything that makes something what it is, I need to pre-declare in the init function. In this case, Dog, has legs and colour. For example, if I made a class that added two numbers, I would declare self.firstnumber and self.secondnumber then just do firstnumber + secondnumber later on in the class to get the answer? – Lostsoul Dec 22 '11 at 20:23
Kind of. You could do that. But it hardly makes sense to make a class just to add things. Classes normally implement data with behaviours - pure behaviours are just functions. I'll expand the answer with something relevant; wait a bit. – Amadan Dec 22 '11 at 20:28
Thank you for the amazing answer. I see and understand the power of classes now. Sorry, if it sounds dumb. You just me realize I can sort data and maintain the state of many different things at once(whereas I would only track as many variables as I can create or more via loops). So say, I need to figure out the average number of legs per dog? Is there a way to retrieve a list of all objects I have created with a class so I can start a calucation like this? or should I also be maintaining a list of the classes I create(i.e. [fido, spot]) – Lostsoul Dec 23 '11 at 5:33
again, I need to thank you for the amazing answer. I'm re-reading it and its very well written and not only explain init to me but also helped me understand the benefits of classes. I can't thank you enough. – Lostsoul Dec 23 '11 at 5:35
Best answer that I have ever seen to any question. I learned more from this one answer than I have from several chapters of books on classes. Thanks. – Raw_Input May 28 '15 at 21:51

To contribute my 5 cents to the thorough explanation from Amadan.

Where classes are a description "of a type" in an abstract way. Objects are their realizations: the living breathing thing. In the object-orientated world there are principal ideas you can almost call the essence of everything. They are:

  1. encapsulation (won't elaborate on this)
  2. inheritance
  3. polymorphism

Objects have one, or more characteristics (= Attributes) and behaviours (= Methods). The behaviour mostly depends on the characteristics. Classes define what the behaviour should accomplish in a general way, but as long as the class is not realized (instantiated) as an object it remains an abstract concept of a possibility. Let me illustrate with the help of "inheritance" and "polymorphism".

    class Human:

        def love    
        def drink
        def laugh
        def do_your_special_thing                

    class Americans(Humans)
        def drink(beverage):
            if beverage != favourite_drink: print "You call that a drink?"
            else: print "Great!" 

    class French(Humans)
        def drink(beverage, cheese):
            if beverage == favourite_drink and cheese == None: print "No cheese?" 
            elif beverage != favourite_drink and cheese == None: print "Révolution!"

    class Brazilian(Humans)
        def do_your_special_thing

    class Germans(Humans)
        def drink(beverage):
            if favourite_drink != beverage: print "I need more beer"
            else: print "Lecker!" 

    class HighSchoolStudent(Americans):
        def __init__(self, name, age):
    = name
             self.age = age

jeff = HighSchoolStudent(name, age):
hans = Germans()
ronaldo = Brazilian()
amelie = French()

for friends in [jeff, hans, ronaldo]:

>>> True
>>> False

Some characteristics define human beings. But every nationality differs somewhat. So "national-types" are kinda Humans with extras. "Americans" are a type of "Humans " and inherit some abstract characteristics and behaviour from the human type (base-class) : thats inheritance. So all Humans can laugh and drink, therefore all child-classes can also! Inheritance (2).

But because they are all of the same kind (Type/base-class : Humans) you can exchange them sometimes: see the for-loop at the end. But they will expose an individual characteristic, and thats Polymorphism (3).

So each human has a favourite_drink, but every nationality tend towards a special kind of. If you subclass a nationality from the type of Humans you can overwrite the inherited behaviour as i have demonstrated above with the drink() Method. But thats still at the class-level and because of this it's still a generalization.

hans = German(favourite_drink = "Cola")

instantiates the class German and i "changed" a default characteristic at the beginning. (But if you call hans.drink('Milk') he would still print "I need more beer" - an obvious bug ... or maybe that's what i would call a feature if i would be a Employee of a bigger Company. ;-)! )

The characteristic of a type e.g. Germans (hans) are usually defined through the constructor (in python : __init__) at the moment of the instantiation. This is the point where you define a class to become an object. You could say breath life into an abstract concept (class) by filling it with individual characteristics and becoming an object.

But because every object is an instance of a class they share all some basic characteristic-types and some behaviour. This is a major advantage of the object-orientated concept.

To protect the characteristics of each object you encapsulate them - means you try to couple behaviour and characteristic and make it hard to manipulate it from outside the object. That's Encapsulation (1)

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It is just to initialize the instance's variables.

E.g. create a crawler instance with a specific database name (from your example above).

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I'm sorry, I don't really understand what that the example above..couldn't the developer just have added in his main code 'left=foo',etc.. – Lostsoul Dec 22 '11 at 20:10
You mean the default values of the function? left=None left will initialized to None if upon creation the left parameter isn't specified. – jldupont Dec 22 '11 at 20:13
I think its starting to make it like how you have to predeclare your variables in java "String left" or something? then once its initialized to the class, you can manipulate the values? Its just a bit confusing when compared to functions because I can just send values to functions and don't need to initialize anything in advance. – Lostsoul Dec 22 '11 at 20:19
@Lostsoul: left = foo would work - once. The point of classes is to do something sensible for every different crawler. Classes are not functions, nor something that can compare to functions (well, not until you're a lot more advanced and get into functional programming, but that'll just confuse you now). Read my answer for what classes actually are - you're still not getting it. – Amadan Dec 22 '11 at 20:22

The __init__ function is setting up all the member variables in the class. So once your bicluster is created you can access the member and get a value back:

mycluster = bicluster(...actual values go here...)
mycluster.left # returns the value passed in as 'left'

Check out the Python Docs for some info. You'll want to pick up an book on OO concepts to continue learning.

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Following with your car example: when you get a car, you just don't get a random car, I mean, you choose the color, the brand, number of seats, etc. And some stuff is also "initialize" without you choosing for it, like number of wheels or registration number.

class Car:
    def __init__(self, color, brand, number_of_seats):
        self.color = color
        self.brand = brand
        self.number_of_seats = number_of_seats
        self.number_of_wheels = 4
        self.registration_number = GenerateRegistrationNumber()

So, in the __init__ method you defining the attributes of the instance you're creating. So, if we want a blue Renault car, for 2 people, we would initialize or instance of Car like:

my_car = Car('blue', 'Renault', 2)

This way, we are creating an instance of the Car class. The __init__ is the one that is handling our specific attributes (like color or brand) and its generating the other attributes, like registration_number.

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Classes are objects with atributes (state, characteristic) and methods (functions, capacities) that are specific for that object (like the white color and fly powers,respectively, for a duck).

When you create an instance of a class, you can give it some initial personality (state or character like the name and the color of her dress for a newborn). You do this with __init__.

__init__ sets the instance characteristics automatically when you call

instance = MyClass(some_individual_traits)

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It seems like you need to use __init__ in Python if you want to correctly initialize mutable attributes of your instances.

See the following example:

>>> class EvilTest(object):
...     attr = []
>>> evil_test1 = EvilTest()
>>> evil_test2 = EvilTest()
>>> evil_test1.attr.append('strange')
>>> print "This is evil:", evil_test1.attr, evil_test2.attr
This is evil: ['strange'] ['strange']
>>> class GoodTest(object):
...     def __init__(self):
...         self.attr = []
>>> good_test1 = GoodTest()
>>> good_test2 = GoodTest()
>>> good_test1.attr.append('strange')
>>> print "This is good:", good_test1.attr, good_test2.attr
This is good: ['strange'] []

This is quite different in Java where each attribute is automatically initialized with a new value:

import java.util.ArrayList;
import java.lang.String;

class SimpleTest
    public ArrayList<String> attr = new ArrayList<String>();

class Main
    public static void main(String [] args)
        SimpleTest t1 = new SimpleTest();
        SimpleTest t2 = new SimpleTest();


        System.out.println(t1.attr + " " + t2.attr);

produces an output we intuitively expect:

[strange] []

But if you declare attr as static, it will act like Python:

[strange] [strange]
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