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I spent some time investigating the collections.namedtuple module a few weeks ago. The module uses a factory function which populates the dynamic data (the name of the new namedtuple class, and the class attribute names) into a very large string. Then exec is executed with the string (which represents the code) as the argument, and the new class is returned.

Does anyone know why it was done this way, when there is a specific tool for this kind of thing readily available, i.e. the metaclass? I haven't tried to do it myself, but it seems like everything that is happening in the namedtuple module could have been easily accomplished using a namedtuple metaclass, like so:

class namedtuple(type):

etc etc.

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20
+200

There are some hints in the issue 3974. The author proposed a new way to create named tuples, which was rejected with the following comments:

It seems the benefit of the original version is that it's faster, thanks to hardcoding critical methods. - Antoine Pitrou

There is nothing unholy about using exec. Earlier versions used other approaches and they proved unnecessarily complex and had unexpected problems. It is a key feature for named tuples that they are exactly equivalent to a hand-written class. - Raymond Hettinger

Additionally, here is the part of the description of the original namedtuple recipe:

... the recipe has evolved to its current exec-style where we get all of Python's high-speed builtin argument checking for free. The new style of building and exec-ing a template made both the __new__ and __repr__ functions faster and cleaner than in previous versions of this recipe.

If you're looking for some alternative implementations:

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  • 1
    hmmm. this certainly answers the question in general, but i'd be curious to know what these unexpected problems where. depending on what they were, the problems might be with metaclasses themselves, in which case maybe they should be fixed. it also seems the reply to that comment 2.5 years later brings up some real issues some people may have. in any case, thanks for the link - a lot of information there. – Rick supports Monica Jan 28 '15 at 4:50
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    I've never really bought this. It's always seemed to me that the answer is "because Raymond Hettinger is okay with using weird hacks". – BrenBarn Jan 28 '15 at 5:03
  • as someone who is learning, it really gives me pause to see something like this in the standard library. i had assumed that the standard library would be a good place to examine what "good code" should look like. but using exec in this manner just seems, as the commenter said above, like a hack, and it's kind of disappointing. metaclasses are pretty awesome, but if the standard library itself eschews using them in such an obvious situation, what's the point in having them? – Rick supports Monica Jan 28 '15 at 5:09
  • Yeah, built for speed this could be yet another – Antti Haapala Jan 28 '15 at 5:52
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    The stdlib is not the place to look for "good code" -- especially as the language evolves. Updating the stdlib to follow new practices or take advantage of new modules is rife with opportunities to introduce new bugs, so it is rarely done. – Ethan Furman Apr 7 '16 at 19:03
4

As a sidenote: The other objection I see most often against using exec is that some locations (read companies) disable it for security reasons.

Besides an advanced Enum and NamedConstant, the aenum library* also has NamedTuple which is metaclass-based.


* aenum is written by the author of enum and the enum34 backport.

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Here is another approach.

""" Subclass of tuple with named fields """
from operator import itemgetter
from inspect import signature

class MetaTuple(type):
    """ metaclass for NamedTuple """

    def __new__(mcs, name, bases, namespace):
        cls = type.__new__(mcs, name, bases, namespace)
        names = signature(cls._signature).parameters.keys()
        for i, key in enumerate(names):
            setattr(cls, key, property(itemgetter(i)))
        return cls

class NamedTuple(tuple, metaclass=MetaTuple):
    """ Subclass of tuple with named fields """

    @staticmethod
    def _signature():
        " Override in subclass "

    def __new__(cls, *args):
        new = super().__new__(cls, *args)
        if len(new) == len(signature(cls._signature).parameters):
            return new
        return new._signature(*new)

if __name__ == '__main__':
    class Point(NamedTuple):
        " Simple test "
        @staticmethod
        def _signature(x, y, z): # pylint: disable=arguments-differ
            " Three coordinates "
    print(Point((1, 2, 4)))

If this approach has any virtue at all, it's the simplicity. It would be simpler yet without NamedTuple.__new__, which serves only the purpose of enforcing the element count. Without that, it happily allows additional anonymous elements past the named ones, and the primary effect of omitting elements is the IndexError on omitted elements when accessing them by name (with a little work that could be translated to an AttributeError). The error message for an incorrect element count is a bit strange, but it gets the point across. I wouldn't expect this to work with Python 2.

There is room for further complication, such as a __repr__ method. I have no idea how the performance compares to other implementations (caching the signature length might help), but I much prefer the calling convention as compared to the native namedtuple implementation.

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There is another reason that none of the other answers hit upon*.

A class can only have 1 metaclass. One reason for this is the metaclass acts as the factory that creates the class. It isn't possible to mix factories together willy nilly. You must create either a "combinatory factory" that knows how to call the multiple factories in the correct order, or a "child factory" that knows about the "parent factory", and uses it correctly.

If the namedtuple used its own metaclass, inheritance involving any other metaclass would break:

>>> class M1(type): ...
...
>>> class M2(type): ...
...
>>> class C1(metaclass=M1): ...
...
>>> class C2(metaclass=M2): ...
...
>>> class C(C1, C2): ...
...
Traceback (most recent call last):
  File "<stdin>", line 1, in <module>
TypeError: metaclass conflict: the metaclass of a derived class must be a (non-strict) subclass of the metaclasses of all its bases

Instead, if you wanted to have your own metaclass and inherit from a namedtuple class, you'd have to use some sort of so-called namedtuple_meta metaclass to do that:

from namedtuple import namedtuple_meta  # pretending this exists

class MyMeta(type): ...

class MyMetaWithNT(namedtuple_meta, MyMeta): ...

class C(metaclass=MyMetaWithNT): ...

..or just inherit the custom metaclass from namedtuple_meta directly:

class MyMeta(namedtuple_meta): ...

class C(metaclass=MyMeta): ...

This looks easy at first, but writing your own mataclass that plays nicely with some (complicated) nt metaclass could be become problematic very quickly. This limitation would probably not come up all THAT often, but often enough that it would hinder the usage of namedtuple. So it is definitely an advantage to have all namedtuple classes be of the type type, and removing the complexity of a custom metaclass.


* Raymond Hettinger's comment does hint at it:

It is a key feature for named tuples that they are exactly equivalent to a hand-written class.

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