1

I really like the syntax of the "magic methods" or whatever they are called in Python, like

class foo:
    def __add__(self,other): #It can be called like c = a + b
        pass

The call

c = a + b

is then translated to

a.__add__(b)

Is it possible to mimic such behaviour for "non-magic" functions? In numerical computations I need the Kronecker product, and am eager to have "kron" function such that

kron(a,b) 

is in fact

a.kron(b)?

The use case is: I have two similar classes, say, matrix and vector, both having Kronecker product. I would like to call them

a = matrix()
b = matrix()
c = kron(a,b)

a = vector()
b = vector()
c = kron(a,b)

matrix and vector classes are defined in one .py file, thus share the common namespace. So, what is the best (Pythonic?) way to implement functions like above? Possible solutions:

1) Have one kron() functions and do type check

2) Have different namespaces

3) ?

6

The python default operator methods (__add__ and such) are hard-wired; python will look for them because the operator implementations look for them.

However, there is nothing stopping you from defining a kron function that does the same thing; look for __kron__ or __rkron__ on the objects passed to it:

def kron(a, b):
    if hasattr(a, '__kron__'):
        return a.__kron__(b)
    if hasattr(b, '__rkron__'):
        return b.__rkron__(a)
    # Default kron implementation here
    return complex_operation_on_a_and_b(a, b)
  • Thank you, that is exactly I was looking for. – Ivan Oseledets Jul 9 '12 at 8:48
  • 1
    For a complete solution, you might want to implement the full rule chain - ie, kr = a.__kron__(b); if kr is not NotImplemented: return kr (and same for b.__rkron__ - and give b first go if it is a subclass of type(a). But that might be overkill if you don't expect clients to make their own classes with their own strange definitions of something so domain specific. – lvc Jul 9 '12 at 9:19
4

What you're describing is multiple dispatch or multimethods. Magic methods is one way to implement them, but it's actually more usual to have an object that you can register type-specific implementations on.

For example, http://pypi.python.org/pypi/multimethod/ will let you write

@multimethod(matrix, matrix)
def kron(lhs, rhs):
    pass

@multimethod(vector, vector)
def kron(lhs, rhs):
    pass

It's quite easy to write a multimethod decorator yourself; the BDFL describes a typical implementation in an article. The idea is that the multimethod decorator associates the type signature and method with the method name in a registry, and replaces the method with a generated method that performs type lookup to find the best match.

3

Technically speaking, implementing something similar to the "standard" operator (and operator-like - think len() etc) behaviour is not difficult:

def kron(a, b):
    if hasattr(a, '__kron__'):
        return a.__kron__(b)
    elif hasattr(b, '__kron__'):
        return b.__kron__(a)
    else:
        raise TypeError("your error message here")

Now you just have to add a __kron__(self, other) method on the relevant types (assuming you have control over these types or they don't use slots or whatever else that would prevent adding methods outside the class statement's body).

Now I'd not use a __magic__ naming scheme as in my above snippet since this is supposed to be reserved for the language itself.

Another solution would be to maintain a type:specifici function mapping and have the "generic" kron function looking up the mapping, ie:

# kron.py
from somewhere import Matrix, Vector

def matrix_kron(a, b):
    # code here

def vector_kron(a, b):
    # code here

KRON_IMPLEMENTATIONS = dict(
    Matrix=matrix_kron,
    Vector=vector_kron,
    )

def kron(a, b):
    for typ in (type(a), type(b)):
        implementation = KRON_IMPLEMENTATION.get(typ, None)
        if implementation:
            return implementation(a, b)
    else:
        raise TypeError("your message here")

This solution doesn't work well with inheritance but it "less surprinsing" - doesn't require monkeypatching nor __magic__ name etc.

  • 1
    Why tie it to specific types? Now sub-classes or compatible imlementations are excluded. for type_, imp in KRON_IMPLEMENTATION.iteritems(): if isinstance(a, type_) would at least include sub-classes. – Martijn Pieters Jul 9 '12 at 8:18
  • 1
    Also, the __magic__ double-underscore names are not limited to python language features, per se. I think that if used as part of a documented API as hooks to override behaviour they are instantly recognizable as such. zope.interface uses __implemented__ and __provides__ for example. Thus __kron__ and __rkron__ fit the usage beautifully. – Martijn Pieters Jul 9 '12 at 8:29
  • @MartijnPieters : I did mention that the second solution wouldn't work with inheritance (and simple isinstance checks may break depending on type order in the sequence and possible diamond inheritance). wrt/ __magic__ names, the doc clearly states that these identifiers are reserved (docs.python.org/reference/…). Zope (and some other packages) don't respect this, but that's still not something to do without really good reasons - IOW : if you don't really need it, don't do it. – bruno desthuilliers Jul 9 '12 at 8:46
  • "Subject to breakage without warning" is something you have to deal with when upgrading major python versions anyway. – Martijn Pieters Jul 9 '12 at 8:49
0

I think having one single function that delegate the actual computation is a nice way to do it. If the Kronecker product only works on two similar classes, you can even do the type checking in the function :

def kron(a, b):
    if type(a) != type(b):
        raise TypeError('expected two instances of the same class, got %s and %s'%(type(a), type(b)))
    return a._kron_(b)

Then, you just need to define a _kron_ method on the class. This is only some basic example, you might want to improve it to handle more gracefully the cases where a class doesn't have the _kron_ method, or to handle subclasses.

Binary operations in the standart libary usually have a reverse dual (__add__ and __radd__), but since your operator only work for same type objects, it isn't useful here.

  • type(a) != type(b) is a really bad idea - it won't handle subclasses, let alone ducktyping and the checks will pass for, eg, kron('a', 'b') even though that doesn't make sense. If you really want to do type checking, you'd want to do: if not isinstance(a, matrix) or not isinstance(b, matrix):. But it would be better to just check for the magic method. – lvc Jul 9 '12 at 9:14
  • I know, I said it in my answer. We're in the case where kron is only defined for objects of the same type, thus the type check (which would be ugly in any other situation, I agree). – madjar Jul 9 '12 at 9:22

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