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I know that Python does not support method overloading, but I've run into a problem that I can't seem to solve in a nice Pythonic way.

I am making a game where a character needs to shoot a variety of bullets, but how do I write different functions for creating these bullets? For example suppose I have a function that creates a bullet travelling from point A to B with a given speed. I would write a function like this:

    def add_bullet(sprite, start, headto, speed):
        ... Code ...

But I want to write other functions for creating bullets like:

    def add_bullet(sprite, start, direction, speed):
    def add_bullet(sprite, start, headto, spead, acceleration):
    def add_bullet(sprite, script): # For bullets that are controlled by a script
    def add_bullet(sprite, curve, speed): # for bullets with curved paths
    ... And so on ...

And so on with many variations. Is there a better way to do it without using so many keyword arguments cause its getting kinda ugly fast. Renaming each function is pretty bad too because you get either add_bullet1, add_bullet2, or add_bullet_with_really_long_name.

To address some answers:

  1. No I can't create a Bullet class hierarchy because thats too slow. The actual code for managing bullets is in C and my functions are wrappers around C API.

  2. I know about the keyword arguments but checking for all sorts of combinations of parameters is getting annoying, but default arguments help allot like acceleration=0

share|improve this question
Works for only one parameter, but here (for people coming here from a search engine): docs.python.org/3/library/… –  leewangzhong Apr 15 '14 at 0:41
this seems like a good place for default values. you can set some to None and just check for them. the extra boolean impact seems negligable –  Andrew Scott Evans May 7 at 17:17

10 Answers 10

Python does support "method overloading" as you present it. In fact, what you just describe is trivial to implement in Python, in so many different ways, but I would go with:

class Character(object):
    # your character __init__ and other methods go here

    def add_bullet(self, sprite=default, start=default, 
                 direction=default, speed=default, accel=default, 
        # do stuff with your arguments

In the above code, default is a plausible default value for those arguments, or None. You can then call the method with only the arguments you are interested in, and Python will use the default values.

You could also do something like this:

class Character(object):
    # your character __init__ and other methods go here

    def add_bullet(self, **kwargs):
        # here you can unpack kwargs as (key, values) and
        # do stuff with them, and use some global dictionary
        # to provide default values and ensure that ``key``
        # is a valid argument...

        # do stuff with your arguments

Another alternative is to directly hook the desired function directly to the class or instance:

def some_implementation(self, arg1, arg2, arg3):
  # implementation
my_class.add_bullet = some_implementation_of_add_bullet

Yet another way is to use an abstract factory pattern:

class Character(object):
   def __init__(self, bfactory, *args, **kwargs):
       self.bfactory = bfactory
   def add_bullet(self):
       sprite = self.bfactory.sprite()
       speed = self.bfactory.speed()
       # do stuff with your sprite and speed

class pretty_and_fast_factory(object):
    def sprite(self):
       return pretty_sprite
    def speed(self):
       return 10000000000.0

my_character = Character(pretty_and_fast_factory(), a1, a2, kw1=v1, kw2=v2)
my_character.add_bullet() # uses pretty_and_fast_factory

# now, if you have another factory called "ugly_and_slow_factory" 
# you can change it at runtime in python by issuing
my_character.bfactory = ugly_and_slow_factory()

# In the last example you can see abstract factory and "method
# overloading" (as you call it) in action 
share|improve this answer
All these look as examples of variable arguments, rather than overloading. Since overloading allows you to have the same function, for different types as arguments. eg: sum(real_num1, real_num2) and sum(imaginary_num1, imaginary_num2) Will both have same calling syntax, but are actually expecting 2 different types as input, and the implementation has to change also internally –  Efren Sep 17 '13 at 6:21
Using the answer you would go with, how would you present to the caller which arguments make sense together? Just putting a bunch of arguments each with a default value may provide the same functionality but in terms of an API it is much less elegant –  Greg Ennis May 12 '14 at 14:43

You can use "roll-your-own" solution for function overloading. This one is copied from Guido van Rossum's article about multimethods (because there is little difference between mm and overloading in python):

registry = {}

class MultiMethod(object):
    def __init__(self, name):
        self.name = name
        self.typemap = {}
    def __call__(self, *args):
        types = tuple(arg.__class__ for arg in args) # a generator expression!
        function = self.typemap.get(types)
        if function is None:
            raise TypeError("no match")
        return function(*args)
    def register(self, types, function):
        if types in self.typemap:
            raise TypeError("duplicate registration")
        self.typemap[types] = function

def multimethod(*types):
    def register(function):
        name = function.__name__
        mm = registry.get(name)
        if mm is None:
            mm = registry[name] = MultiMethod(name)
        mm.register(types, function)
        return mm
    return register

The usage would be

from multimethods import multimethod
import unittest

# 'overload' makes more sense in this case
overload = multimethod

class Sprite(object):

class Point(object):

class Curve(object):

@overload(Sprite, Point, Direction, int)
def add_bullet(sprite, start, direction, speed):
    # ...

@overload(Sprite, Point, Point, int, int)
def add_bullet(sprite, start, headto, speed, acceleration):
    # ...

@overload(Sprite, str)
def add_bullet(sprite, script):
    # ...

@overload(Sprite, Curve, speed)
def add_bullet(sprite, curve, speed):
    # ...

Most restrictive limitations at the moment are:

  • methods are not supported, only functions that are not class members;
  • inheritance is not handled;
  • kwargs are not supported;
  • registering new functions should be done at import time thing is not thread-safe
share|improve this answer
+1 for decorators for extending the language in this use case. –  Eloims May 8 '13 at 15:18
+1 because this is a great idea (and probably what the OP should go with) --- I had never seen a multimethod implementation in Python. –  Escualo Feb 27 '14 at 5:56

This type of behaviour is typically solved (in OOP languages) using Polymorphism. Each type of bullet would be responsible for knowing how it travels. For instance:

class Bullet(object):
    def __init__(self):
        self.curve = None
        self.speed = None
        self.acceleration = None
        self.sprite_image = None

class RegularBullet(Bullet):
    def __init__(self):
        super(RegularBullet, self).__init__()
        self.speed = 10

class Grenade(Bullet):
    def __init__(self):
        super(Grenade, self).__init__()
        self.speed = 4
        self.curve = 3.5


def add_bullet(bullet):
    c_function(bullet.speed, bullet.curve, bullet.acceleration, bullet.sprite, bullet.x, bullet.y) 

void c_function(double speed, double curve, double accel, char[] sprite, ...) {
    if (speed != null && ...) regular_bullet(...)
    else if (...) curved_bullet(...)

Pass as many arguments to the c_function that exist, then do the job of determining which c function to call based on the values in the initial c function. So, python should only ever be calling the one c function. That one c function looks at the arguments, and then can delegate to other c functions appropriately.

You're essentially just using each subclass as a different data container, but by defining all the potential arguments on the base class, the subclasses are free to ignore the ones they do nothing with.

When a new type of bullet comes along, you can simply define one more property on the base, change the one python function so that it passes the extra property, and the one c_function that examines the arguments and delegates appropriately. Doesn't sound too bad I guess.

share|improve this answer
That was my initial approach, but for performance reasons I had to rewrite that code in C. –  Bullets Jun 22 '11 at 3:38
@Bullets, I would suggest that there may be a number of different options available to improve performance rather than writing a whole lot of c functions that probably won't be doing a whole lot. For example: creating an instance may be expensive, so maintain an object pool. Though I say this without knowing what you found to be too slow. Out of interest, what exactly was slow about this approach? Unless significant time is going to be spent in the C side of the boundary, I can't think that Python (itself) is the real problem. –  Josh Smeaton Jun 22 '11 at 3:51
Maybe there are other ways to improve the performance, but I am much better with C than with Python. The problem was calculating the motions of the bullets and detecting when they go out of screen bounds. I had a methods for calculating position of the bullet pos+v*t and then comparing to screen boundaries if x > 800 and so on. Calling these functions several hundred times per frame turned out to be unacceptably slow. It was something like 40 fps at 100% cpu with pure python to 60 fps with 5%-10% when done in C. –  Bullets Jun 22 '11 at 4:03
@Bullets, fair enough then. I'd still use the approach I went with for encapsulating data. Pass an instance of bullet to add_bullet, and extract all the fields that you need. I'll edit my answer. –  Josh Smeaton Jun 22 '11 at 4:13
@Bullets: You can combine your C functions and the OOP approach suggested by Josh using Cython. It allows early binding so there should not be a speed penalty. –  J.F. Sebastian Sep 5 '11 at 13:25

What you are asking for, is called multiple dispatch. See Julia language examples which demonstrates different types of dispatches.

However, before looking at that, we'll first tackle why overloading is not really what you want in python.

Why Not Overloading?

First one needs to understand the concept of overloading and why it's not applicable to python.

When working with languages that can discriminate data types at compile-time, selecting among the alternatives can occur at compile-time. The act of creating such alternative functions for compile-time selection is usually referred to as overloading a function. (Wikipedia)

Python is a dynamically typed language, so the concept of overloading simply does not apply to it. However, all is not lost, since we can create such alternative functions at run-time:

In programming languages that defer data type identification until run-time the selection among alternative functions must occur at run-time, based on the dynamically determined types of function arguments. Functions whose alternative implementations are selected in this manner are referred to most generally as multimethods. (Wikipedia)

So we should be able to do multimethods in python or, as it is alternatively called, multiple dispatch.

Multiple dispatch

The multimethods are also called multiple dispatch:

Multiple dispatch or multimethods is the feature of some object-oriented programming languages in which a function or method can be dynamically dispatched based on the run time (dynamic) type of more than one of its arguments. (Wikipedia)

Python does not support this out of the box*. But, as it happens, there is an excellent python package called multipledispatch that does exactly that.

* Python 3 currently supports single dispatch


Here is how we might use multipledispatch package to implemented your methods:

>>> from multipledispatch import dispatch
>>> from collections import namedtuple  
>>> from types import *  # we can test for lambda type, e.g.:
>>> type(lambda a: 1) == LambdaType

>>> Sprite = namedtuple('Sprite', ['name'])
>>> Point = namedtuple('Point', ['x', 'y'])
>>> Curve = namedtuple('Curve', ['x', 'y', 'z'])
>>> Vector = namedtuple('Vector', ['x','y','z'])

>>> @dispatch(Sprite, Point, Vector, int)
... def add_bullet(sprite, start, direction, speed):
...     print("Called Version 1")
>>> @dispatch(Sprite, Point, Point, int, float)
... def add_bullet(sprite, start, headto, speed, acceleration):
...     print("Called version 2")
>>> @dispatch(Sprite, LambdaType)
... def add_bullet(sprite, script):
...     print("Called version 3")
>>> @dispatch(Sprite, Curve, int)
... def add_bullet(sprite, curve, speed):
...     print("Called version 4")

>>> sprite = Sprite('Turtle')
>>> start = Point(1,2)
>>> direction = Vector(1,1,1)
>>> speed = 100 #km/h
>>> acceleration = 5.0 #m/s
>>> script = lambda sprite: sprite.x * 2
>>> curve = Curve(3, 1, 4)
>>> headto = Point(100, 100) # somewhere far away

>>> add_bullet(sprite, start, direction, speed)
Called Version 1

>>> add_bullet(sprite, start, headto, speed, acceleration)
Called version 2

>>> add_bullet(sprite, script)
Called version 3

>>> add_bullet(sprite, curve, speed)
Called version 4
share|improve this answer

A possible option is to use the multipledispatch module as detailed here: http://matthewrocklin.com/blog/work/2014/02/25/Multiple-Dispatch/

Instead of doing this:

def add(self, other):
    if isinstance(other, Foo):
    elif isinstance(other, Bar):
        raise NotImplementedError()

You can do this:

from multipledispatch import dispatch
@dispatch(int, int)
def add(x, y):
    return x + y    

@dispatch(object, object)
def add(x, y):
    return "%s + %s" % (x, y)

with resulting usage:

>>> add(1, 2)

>>> add(1, 'hello')
'1 + hello'
share|improve this answer
Why doesn't this get more votes? I'm guessing due to lack of examples... I've created an answer with an example of how to implement a solution to OP's problem with multipledispatch package. –  drozzy Mar 17 at 5:37

Either use multiple keyword arguments in the definition, or create a Bullet hierarchy whose instances are passed to the function.

share|improve this answer
I was going to suggest the second approach: make some BulletParams... classes to specify the bullet details. –  John Zwinck Jun 22 '11 at 3:15
Can you elaborate on this? I tried to create a class hierarchy with different bullets but this does not work, because Python is too slow. It can't calculate the motions of the required number of bullets fast enough, so I had to write that part in C. All the add_bullet variants just call the corresponding C function. –  Bullets Jun 22 '11 at 3:24

I think your basic requirement is to have a C/C++ like syntax in python with the least headache possible. Although I liked Alexander Poluektov's answer it doesn't work for classes.

The following should work for classes. It works by distinguishing by the number of non keyword arguments (but doesn't support distinguishing by type):

class TestOverloading(object):
    def overloaded_function(self, *args, **kwargs):
        # Call the function that has the same number of non-keyword arguments.  
        getattr(self, "_overloaded_function_impl_" + str(len(args)))(*args, **kwargs)

    def _overloaded_function_impl_3(self, sprite, start, direction, **kwargs):
        print "This is overload 3"
        print "Sprite: %s" % str(sprite)
        print "Start: %s" % str(start)
        print "Direction: %s" % str(direction)

    def _overloaded_function_impl_2(self, sprite, script):
        print "This is overload 2"
        print "Sprite: %s" % str(sprite)
        print "Script: "
        print script

And it can be used simply like this:

test = TestOverloading()

test.overloaded_function("I'm a Sprite", 0, "Right")
test.overloaded_function("I'm another Sprite", "while x == True: print 'hi'")


This is overload 3
Sprite: I'm a Sprite
Start: 0
Direction: Right

This is overload 2
Sprite: I'm another Sprite
while x == True: print 'hi'

share|improve this answer

I think aBulletclass hierarchy with the associated polymorphism is the way to go. You can effectively overload the base class constructor by using a metaclass so that calling the base class results in the creation of the appropriate subclass object. Below is some sample code to illustrate the essence of what I mean.

class BulletMeta(type):
    def __new__(cls, classname, bases, classdict):
        """ Create Bullet class or a subclass of it. """
        classobj = type.__new__(cls, classname, bases, classdict)
        if classname == 'Bullet':  # base class definition?
            classobj.registry = {}  # initialize class registry
                alias = classdict['alias']
            except KeyError:
                raise TypeError("Bullet subclass %s has no 'alias'" %
            if alias in Bullet.registry: # unique?
                raise TypeError("Bullet subclass %s's alias attribute "
                                "%r already in use" % (classname, alias))
            # register subclass under the specified alias
            classobj.registry[alias] = classobj

        return classobj

    # instance factory for subclasses
    # subclasses should only be instantiated by calls to the base class
    # with their subclass's alias as the first arg
    def __call__(cls, alias, *args, **kwargs):
        if cls != Bullet:
            raise TypeError("Bullet subclass %r objects should not to "
                            "be explicitly constructed." % cls.__name__)
        elif alias not in cls.registry: # Bullet subclass?
            raise NotImplementedError("Unknown Bullet subclass %r" %
        # create designated subclass object (call its __init__ method)
        subclass = cls.registry[alias]
        return type.__call__(subclass, *args, **kwargs)

class Bullet(object):
    __metaclass__ = BulletMeta
    # Presumably you'd define some abstract methods that all here
    # that would be supported by all subclasses.
    # These definitions could just raise NotImplementedError() or
    # implement the functionality is some sub-optimal generic way.
    # For example:
    def fire(self, *args, **kwargs):
        raise NotImplementedError(self.__class__.__name__ + ".fire() method")

    # abstract base class's __init__ should never be called
    # (if subclasses need to call super class's __init__(),
    # then then it might be implemented)
    def __init__(self, *args, **kwargs):
        raise NotImplementedError("Bullet is an abstract base class")

# subclass definitions
class Bullet1(Bullet):
    alias = 'B1'
    def __init__(self, sprite, start, direction, speed):
        print 'creating %s object' % self.__class__.__name__
    def fire(self, trajectory):
        print 'Bullet1 object fired with %s trajectory' % trajectory

class Bullet2(Bullet):
    alias = 'B2'
    def __init__(self, sprite, start, headto, spead, acceleration):
        print 'creating %s object' % self.__class__.__name__

class Bullet3(Bullet):
    alias = 'B3'
    def __init__(self, sprite, script): # script controlled bullets
        print 'creating %s object' % self.__class__.__name__

class Bullet4(Bullet):
    alias = 'B4'
    def __init__(self, sprite, curve, speed): # for bullets with curved paths
        print 'creating %s object' % self.__class__.__name__

class Sprite: pass
class Curve: pass

b1 = Bullet('B1', Sprite(), (10,20,30), 90, 600)             # creating Bullet1 object
b2 = Bullet('B2', Sprite(), (-30,17,94), (1,-1,-1), 600, 10) # creating Bullet2 object
b3 = Bullet('B3', Sprite(), 'bullet42.script')               # creating Bullet3 object
b4 = Bullet('B4', Sprite(), Curve(), 720)                    # creating Bullet4 object
b1.fire('uniform gravity') # Bullet1 object fired with uniform gravity trajectory
b2.fire('uniform gravity') # NotImplementedError: Bullet2.fire() method
share|improve this answer
Hmm this is still just a fancy way to name the functions as add_bullet1, add_bullet2 and so on. –  Bullets Jun 22 '11 at 16:57
@Bullets: Perhaps it is, or maybe it's just a slightly elaborate way to create a factory function. A nice thing about it is that it supports a hierarchy of Bullet subclasses without having to modify the base class or factory function every time you add another subtype. (Of course, if you're using C rather than C++, I guess you don't have classes.) You could also make a smarter metaclass that figured-out on its own what subclass to create based on the type and/or number of arguments passed (like C++ does to support overloading). –  martineau Jun 22 '11 at 19:13

Use keyword arguments with defaults. E.g.

def add_bullet(sprite, start=default, direction=default, script=default, speed=default):

In the case of a straight bullet versus a curved bullet, I'd add two functions: add_bullet_straight and add_bullet_curved.

share|improve this answer

By passing keyword args, http://www.saltycrane.com/blog/2008/01/how-to-use-args-and-kwargs-in-python/

def add_bullet(**kwargs):
    #check for the arguments listed above and do the proper things
share|improve this answer

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