How can I write a function "fmap", with this properties :
>>> l = [1, 2]; fmap(lambda x: 2*x, l)
[2, 4]
>>> l = (1, 2); fmap(lambda x: 2*x, l)
(2, 4)
>>> l = {1, 2}; fmap(lambda x: 2*x, l)
{2, 4}
(I search a kind of "fmap" in haskell, but in python3).
I have a very ugly solution, but there is certainly a solution more pythonic and generic ? :
def fmap(f, container):
t = container.__class__.__name__
g = map(f, container)
return eval(f"{t}(g)")
eval__class__ can also be used to instantiate new instances:
def mymap(f, contener):
t = contener.__class__
return t(map(f, contener))
This removes the need for eval, use of which is considered poor practice. As per @EliKorvigo's comment, you may prefer built-in type to a magic method:
def mymap(f, contener):
t = type(contener)
return t(map(f, contener))
As explained here and in the docs:
The return value is a type object and generally the same object as returned by
object.__class__.
"Generally the same" should be considered "equivalent" in the case of new-style classes.
You can check/test for an iterable in a couple of ways. Either use try / except to catch TypeError:
def mymap(f, contener):
try:
mapper = map(f, contener)
except TypeError:
return 'Input object is not iterable'
return type(contener)(mapper)
Or use collections.Iterable:
from collections import Iterable
def mymap(f, contener):
if isinstance(contener, Iterable):
return type(contener)(map(f, contener))
return 'Input object is not iterable'
This works specifically because built-in classes commonly used as containers such as list, set, tuple, collections.deque, etc, can be used to instantiate instances via a lazy iterable. Exceptions exist: for example, str(map(str.upper, 'hello')) will not work as you might expect even though str instances are iterable.
type(container)(map(...)) is a bit cleaner than accessing a magic attribute.
Jan 2, 2019 at 10:22
mymap(lambda x: x[0], {"A":"small","Example":"that","Does":"not","Work":"!"})
Jan 2, 2019 at 10:33
try/except code catches way too many cases. Each TypeError thrown in the execution of f within the map call will be caught and misinterpreted as "Input object is not iterable".
str. Or do you just take issue with the error message itself?
Using the type of the input as a converter is not necessarily working in all occasions. map is just using the "iterability" of its input to produce its output. In Python3 this is why map returns a generator instead of a list (which is just more fitting).
So a cleaner and more robust version would be one which explicitly expects the various possible inputs it can handle and which raises an error in all other cases:
def class_retaining_map(fun, iterable):
if type(iterable) is list: # not using isinstance(), see below for reasoning
return [ fun(x) for x in iterable ]
elif type(iterable) is set:
return { fun(x) for x in iterable }
elif type(iterable) is dict:
return { k: fun(v) for k, v in iterable.items() }
# ^^^ use .iteritems() in python2!
# and depending on your usecase this might be more fitting:
# return { fun(k): v for k, v in iterable.items() }
else:
raise TypeError("type %r not supported" % type(iterable))
You could add a case for all other iterable values in the else clause of cause:
else:
return (fun(x) for x in iterable)
But that would e. g. return an iterable for a subclass of set which might not be what you want.
Mind that I'm deliberately not using isinstance because that would make a list out of a subclass of list, for instance. I figure that this is explicitly not wanted in this case.
One could argue that anything which is a list (i. e. is a subclass of list) needs to comply to have a constructor which returns a thing of this type for an iteration of elements. And likewise for subclasses of set, dict (which must work for an iteration of pairs), etc. Then the code might look like this:
def class_retaining_map(fun, iterable):
if isinstance(iterable, (list, set)):
return type(iterable)(fun(x) for x in iterable)
elif isinstance(iterable, dict):
return type(iterable)((k, fun(v)) for k, v in iterable.items())
# ^^^ use .iteritems() in python2!
# and depending on your usecase this might be more fitting:
# return type(iterable)((fun(k), v) for k, v in iterable.items())
else:
raise TypeError("type %r not supported" % type(iterable))
type(iterable) == list instead of isinstance? I can think of very few cases were this is not a bad practice. And even then, you would use is instead of ==.
Jan 2, 2019 at 10:40
type(iterable) deliberately (see my last paragraph which I added late for the reason of this). I changed the use of == to the use of is which is slightly better in this case, you are right.
elif type(iterable) is str: return "".join(map(fun, iterable))
bytes in Python3 or unicode in Python2.
I search a kind of "fmap" in haskell, but in python3
First, let's discuss Haskell's fmap to understand, why it behaves the way it does, though I assume you are fairly familiar with Haskell considering the question. fmap is a generic method defined in the Functor type-class:
class Functor f where
fmap :: (a -> b) -> f a -> f b
...
Functors obey several important mathematical laws and have several methods derived from fmap, though the latter is sufficient for a minimal complete functor instance. In other words, in Haskell types belonging to the Functor type-class implement their own fmap functions (moreover, Haskell types can have multiple Functor implementations via newtype definitions). In Python we don't have type-classes, though we do have classes that, while less convenient in this case, allow us to simulate this behaviour. Unfortunately, with classes we can't add functionality to an already defined class without subclassing, which limits our ability to implement a generic fmap for all builtin types, though we can overcome it by explicitly checking for acceptable iterable types in our fmap implementation. It's also literally impossible to express higher-kinded types using Python's type system, but I digress.
To summarise, we've got several options:
Iterable types (@jpp's solution). It relies on constructors to convert an iterator returned by Python's map back into the original type. That is the duty of applying a function over the values inside a container is taken away from the container. This approach differs drastically from the functor interface: functors are supposed to handle the mapping themselves and handle additional metadata crucial to reconstruct the container.This is my take on the third solution
import abc
from typing import Generic, TypeVar, Callable, Union, \
Dict, List, Tuple, Set, Text
A = TypeVar('A')
B = TypeVar('B')
class Functor(Generic[A], metaclass=abc.ABCMeta):
@abc.abstractmethod
def fmap(self, f: Callable[[A], B]) -> 'Functor[B]':
raise NotImplemented
FMappable = Union[Functor, List, Tuple, Set, Dict, Text]
def fmap(f: Callable[[A], B], fmappable: FMappable) -> FMappable:
if isinstance(fmappable, Functor):
return fmappable.fmap(f)
if isinstance(fmappable, (List, Tuple, Set, Text)):
return type(fmappable)(map(f, fmappable))
if isinstance(fmappable, Dict):
return type(fmappable)(
(key, f(value)) for key, value in fmappable.items()
)
raise TypeError('argument fmappable is not an instance of FMappable')
Here is a demo
In [20]: import pandas as pd
In [21]: class FSeries(pd.Series, Functor):
...:
...: def fmap(self, f):
...: return self.apply(f).astype(self.dtype)
...:
In [22]: fmap(lambda x: x * 2, [1, 2, 3])
Out[22]: [2, 4, 6]
In [23]: fmap(lambda x: x * 2, {'one': 1, 'two': 2, 'three': 3})
Out[23]: {'one': 2, 'two': 4, 'three': 6}
In [24]: fmap(lambda x: x * 2, FSeries([1, 2, 3], index=['one', 'two', 'three']))
Out[24]:
one 2
two 4
three 6
dtype: int64
In [25]: fmap(lambda x: x * 2, pd.Series([1, 2, 3], index=['one', 'two', 'three']))
---------------------------------------------------------------------------
TypeError Traceback (most recent call last)
<ipython-input-27-1c4524f8e4b1> in <module>
----> 1 fmap(lambda x: x * 2, pd.Series([1, 2, 3], index=['one', 'two', 'three']))
<ipython-input-7-53b2d5fda1bf> in fmap(f, fmappable)
34 if isinstance(fmappable, Functor):
35 return fmappable.fmap(f)
---> 36 raise TypeError('argument fmappable is not an instance of FMappable')
37
38
TypeError: argument fmappable is not an instance of FMappable
This solution allows us to define multiple functors for the same type via subclassing:
In [26]: class FDict(dict, Functor):
...:
...: def fmap(self, f):
...: return {f(key): value for key, value in self.items()}
...:
...:
In [27]: fmap(lambda x: x * 2, FDict({'one': 1, 'two': 2, 'three': 3}))
Out[27]: {'oneone': 1, 'twotwo': 2, 'threethree': 3}
fmap(lambda x: x[0], {"A":"small","Example":"that","Does":"not","Work":"!"}).. and in any other case where the function changes the type...