I can't find a definitive answer for this. AFAIK, you can't have multiple __init__ functions in a Python class. So how do I solve this problem?

Suppose I have an class called Cheese with the number_of_holes property. How can I have two ways of creating cheese-objects...

  1. one that takes a number of holes like this: parmesan = Cheese(num_holes = 15)
  2. and one that takes no arguments and just randomizes the number_of_holes property: gouda = Cheese()

I can think of only one way to do this, but that seems kinda clunky:

class Cheese():
    def __init__(self, num_holes = 0):
        if (num_holes == 0):
            # randomize number_of_holes
        else:
            number_of_holes = num_holes

What do you say? Is there another way?

  • 1
    @BobStein I don't agree with that duplicate. There's a difference between overloading based on argument type, and overloading based on the presence/absence of arguments. – Aran-Fey Jul 11 at 12:17
  • 1
    You're right @Aran-Fey. So I suggest the title is too broad. Maybe "What's the Pythonic way to do the Java/C++ trick of multiple constructors based on optional arguments" – Bob Stein Jul 11 at 14:02

11 Answers 11

up vote 689 down vote accepted

Actually None is much better for "magic" values:

class Cheese():
    def __init__(self, num_holes = None):
        if num_holes is None:
            ...

Now if you want complete freedom of adding more parameters:

class Cheese():
    def __init__(self, *args, **kwargs):
        #args -- tuple of anonymous arguments
        #kwargs -- dictionary of named arguments
        self.num_holes = kwargs.get('num_holes',random_holes())

To better explain the concept of *args and **kwargs (you can actually change these names):

def f(*args, **kwargs):
   print 'args: ', args, ' kwargs: ', kwargs

>>> f('a')
args:  ('a',)  kwargs:  {}
>>> f(ar='a')
args:  ()  kwargs:  {'ar': 'a'}
>>> f(1,2,param=3)
args:  (1, 2)  kwargs:  {'param': 3}

http://docs.python.org/reference/expressions.html#calls

  • 23
    For those interested, kwargs stands for keyword arguments (seems logic once you know it). :) – tleb Aug 3 '16 at 6:29
  • There are moments that *args and **kwargs are an overkill. At most constructors, you want to know what your arguments are. – user989762 Apr 28 at 9:26

Using num_holes=None as the default is fine if you are going to have just __init__.

If you want multiple, independent "constructors", you can provide these as class methods. These are usually called factory methods. In this case you could have the default for num_holes be 0.

class Cheese(object):
    def __init__(self, num_holes=0):
        "defaults to a solid cheese"
        self.number_of_holes = num_holes

    @classmethod
    def random(cls):
        return cls(randint(0, 100))

    @classmethod
    def slightly_holey(cls):
        return cls(randint((0,33))

    @classmethod
    def very_holey(cls):
        return cls(randint(66, 100))

Now create object like this:

gouda = Cheese()
emmentaler = Cheese.random()
leerdammer = Cheese.slightly_holey()
  • 21
    I think this is cleaner as well. Here's a link to an even clearer explication, IMHO -- from a comp.lang.python post, "Re: Multiple constructors" by Alex Martelli. coding.derkeiler.com/Archive/Python/comp.lang.python/2005-02/… – ariddell Oct 25 '09 at 17:58
  • +1 for the nice example of @classmethod. But as answer to the original question I prefer the accepted solution, because in my opinion it is more in the direction of having multiple constructors (or overloading them, in other languages). – rmbianchi Dec 9 '11 at 13:35
  • 12
    @rmbianchi: The accepted answer may be more in line with other languages, but it is also less pythonic: @classmethods are the pythonic way of implementing multiple contstructors. – Ethan Furman Mar 22 '12 at 1:34
  • @EthanFurman: I like your cheese and thanks for the improved code. This is really better, using the __init__() constructor directly. – Ber Mar 26 '12 at 16:49
  • 10
    @Bepetersn There are instance methods (the normal ones), which have an instance object referenced as self. Then there are class methods (using @classmethod) which have a reference to the class object as cls. An finally there are static methods (declared with @staticmethod) which have neither of those references. Static methods are just like functions at module level, except they live in the class' name space. – Ber Apr 22 '13 at 11:10

All of these answers are excellent if you want to use optional parameters, but another Pythonic possibility is to use a classmethod to generate a factory-style pseudo-constructor:

def __init__(self, num_holes):

  # do stuff with the number

@classmethod
def fromRandom(cls):

  return cls( # some-random-number )

Why do you think your solution is "clunky"? Personally I would prefer one constructor with default values over multiple overloaded constructors in situations like yours (Python does not support method overloading anyway):

def __init__(self, num_holes=None):
    if num_holes is None:
        # Construct a gouda
    else:
        # custom cheese
    # common initialization

For really complex cases with lots of different constructors, it might be cleaner to use different factory functions instead:

@classmethod
def create_gouda(cls):
    c = Cheese()
    # ...
    return c

@classmethod
def create_cheddar(cls):
    # ...

In your cheese example you might want to use a Gouda subclass of Cheese though...

  • 1
    Factory functions use cls: use cls instead of Cheese. If not, what is the point of using class methods instead of static methods? – rools Aug 2 at 11:53

Those are good ideas for your implementation, but if you are presenting a cheese making interface to a user. They don't care how many holes the cheese has or what internals go into making cheese. The user of your code just wants "gouda" or "parmesean" right?

So why not do this:

# cheese_user.py
from cheeses import make_gouda, make_parmesean

gouda = make_gouda()
paremesean = make_parmesean()

And then you can use any of the methods above to actually implement the functions:

# cheeses.py
class Cheese(object):
    def __init__(self, *args, **kwargs):
        #args -- tuple of anonymous arguments
        #kwargs -- dictionary of named arguments
        self.num_holes = kwargs.get('num_holes',random_holes())

def make_gouda():
    return Cheese()

def make_paremesean():
    return Cheese(num_holes=15)

This is a good encapsulation technique, and I think it is more Pythonic. To me this way of doing things fits more in line more with duck typing. You are simply asking for a gouda object and you don't really care what class it is.

  • 1
    I tend to opt for this approach because it is remarkably similar to the Factory Method pattern. – 2rs2ts May 30 '13 at 0:21
  • make_gouda, make_parmesan should be classmethods of class Cheese – smci Jul 17 at 23:11

The best answer is the one above about default arguments, but I had fun writing this, and it certainly does fit the bill for "multiple constructors". Use at your own risk.

What about the new method.

"Typical implementations create a new instance of the class by invoking the superclass’s new() method using super(currentclass, cls).new(cls[, ...]) with appropriate arguments and then modifying the newly-created instance as necessary before returning it."

So you can have the new method modify your class definition by attaching the appropriate constructor method.

class Cheese(object):
    def __new__(cls, *args, **kwargs):

        obj = super(Cheese, cls).__new__(cls)
        num_holes = kwargs.get('num_holes', random_holes())

        if num_holes == 0:
            cls.__init__ = cls.foomethod
        else:
            cls.__init__ = cls.barmethod

        return obj

    def foomethod(self, *args, **kwargs):
        print "foomethod called as __init__ for Cheese"

    def barmethod(self, *args, **kwargs):
        print "barmethod called as __init__ for Cheese"

if __name__ == "__main__":
    parm = Cheese(num_holes=5)
  • 7
    This is the sort of code that gives me nightmares about working in dynamic languages--not to say that there's anything inherently wrong with it, only that it violates some key assumptions I would make about a class. – Yes - that Jake. Mar 30 '09 at 16:07
  • 6
    It's also not thread-safe. – javawizard Nov 22 '13 at 0:11
  • 1
    @javawizard Would it be easy to explain in a comment what makes it non thread-safe, or give a pointer so I can read about it somewhere else? – Reti43 Dec 14 '14 at 9:04
  • 5
    @Reti43 Say two threads try to create cheeses at the same time, one with Cheese(0) and one with Cheese(1). It's possible that thread 1 might run cls.__init__ = cls.foomethod, but then thread 2 might run cls.__init__ = cls.barmethod before thread 1 gets any further. Both threads will then end up calling barmethod, which isn't what you want. – javawizard Dec 14 '14 at 9:23

One should definitely prefer the solutions already posted, but since no one mentioned this solution yet, I think it is worth mentioning for completeness.

The @classmethod approach can be modified to provide an alternative constructor which does not invoke the default constructor (__init__). Instead, an instance is created using __new__.

This could be used if the type of initialization cannot be selected based on the type of the constructor argument, and the constructors do not share code.

Example:

class MyClass(set):

    def __init__(self, filename):
        self._value = load_from_file(filename)

    @classmethod
    def from_somewhere(cls, somename):
        obj = cls.__new__(cls)  # Does not call __init__
        obj._value = load_from_somewhere(somename)
        return obj
  • 1
    This is the solution that indeed provides independent constructors instead of fiddling with __init__'s arguments. However, could you provide some references, please, that this method is somehow officially approved or supported? How safe and reliable is it to call directly __new__ method? – Alexey Feb 20 at 14:11

Use num_holes=None as a default, instead. Then check for whether num_holes is None, and if so, randomize. That's what I generally see, anyway.

More radically different construction methods may warrant a classmethod that returns an instance of cls.

I'd use inheritance. Especially if there are going to be more differences than number of holes. Especially if Gouda will need to have different set of members then Parmesan.

class Gouda(Cheese):
    def __init__(self):
        super(Gouda).__init__(num_holes=10)


class Parmesan(Cheese):
    def __init__(self):
        super(Parmesan).__init__(num_holes=15) 

This is how I solved it for a YearQuarter class I had to create. I created an __init__ with a single parameter called value. The code for the __init__ just decides what type the value parameter is and process the data accordingly. In case you want multiple input parameters you just pack them into a single tuple and test for value being a tuple.

You use it like this:

>>> temp = YearQuarter(datetime.date(2017, 1, 18))
>>> print temp
2017-Q1
>>> temp = YearQuarter((2017, 1))
>>> print temp
2017-Q1

And this is how the __init__ and the rest of the class looks like:

import datetime


class YearQuarter:

    def __init__(self, value):
        if type(value) is datetime.date:
            self._year = value.year
            self._quarter = (value.month + 2) / 3
        elif type(value) is tuple:               
            self._year = int(value[0])
            self._quarter = int(value[1])           

    def __str__(self):
        return '{0}-Q{1}'.format(self._year, self._quarter)

You can expand the __init__ with multiple error messages of course. I omitted them for this example.

class Cheese:
    def __init__(self, *args, **kwargs):
        """A user-friendly initialiser for the general-purpose constructor.
        """
        ...

    def _init_parmesan(self, *args, **kwargs):
        """A special initialiser for Parmesan cheese.
        """
        ...

    def _init_gauda(self, *args, **kwargs):
        """A special initialiser for Gauda cheese.
        """
        ...

    @classmethod
    def make_parmesan(cls, *args, **kwargs):
        new = cls.__new__(cls)
        new._init_parmesan(*args, **kwargs)
        return new

    @classmethod
    def make_gauda(cls, *args, **kwargs):
        new = cls.__new__(cls)
        new._init_gauda(*args, **kwargs)
        return new
  • No. This is utterly unPythonic, it's like Java masquerading behind Python syntax. You want one single __init__ method, and the other class methods either call it as-is (cleanest) or handle special initialization actions via any helper classmethods and setters you need (ideally none). – smci Jul 17 at 23:18
  • I do not want a single __init__ method when I have multiple constructors with different initialisation routines. I do not see why someone would want it. "the other class methods either call it as-is" -- call what? The __init__ method? That would be strange to call __init__ explicitely IMO. – Alexey Jul 18 at 8:35
  • Alexey, it is utterly unPythonic to have multiple constructors, as in multiple _init... methods (see other answers on this question.) Worse still, in this case you don't even need to: you haven't shown how the code for _init_parmesan, _init_gouda differ, so there is zero reason not to common-case them. Anyway, the Pythonic way to do that is to supply non-default args to *args or **kwargs (e.g. Cheese(..., type='gouda'...), or if that can't handle everything, put the general code in __init__ and the less-commonly-used code in a classmethod make_whatever... and have it cal setters – smci Jul 18 at 21:42
  • "it is utterly unPythonic to have multiple constructors" -- the original question is still "What is a clean, pythonic way to have multiple constructors in Python?". I only showed how to have them, not why i would want them. – Alexey Jul 19 at 6:48
  • As to the question why i would want them, well, even namedtuple-produced classes have two constructors: the default one and _make. There are other examples when inheriting from built-in classes where using multiple constructors would be the only option, because despatching inside __init__ would not be an option. – Alexey Jul 19 at 6:55

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