89

Can anyone amend namedtuple or provide an alternative class so that it works for mutable objects?

Primarily for readability, I would like something similar to namedtuple that does this:

from Camelot import namedgroup

Point = namedgroup('Point', ['x', 'y'])
p = Point(0, 0)
p.x = 10

>>> p
Point(x=10, y=0)

>>> p.x *= 10
Point(x=100, y=0)

It must be possible to pickle the resulting object. And per the characteristics of named tuple, the ordering of the output when represented must match the order of the parameter list when constructing the object.

  • 5
    You could make a very simple Point class that did this. – 101 Mar 26 '15 at 23:00
  • 3
    See also: stackoverflow.com/q/5131044. Is there a reason you can't just use a dictionary? – senshin Mar 26 '15 at 23:01
  • @senshin Thanks for the link. I prefer not to use a dictionary for the reason pointed out in it. That response also linked to code.activestate.com/recipes/…, which is pretty close to what I'm after. – Alexander Mar 26 '15 at 23:47
  • Unlike with namedtuples, it appears you have no need to be able to reference the attributes by index, i.e. so p[0] and p[1] would be alternate ways to reference x and y respectively, correct? – martineau Mar 31 '15 at 9:35
  • 1
    A mutable namedtuple is called a class. – gbtimmon Apr 10 '17 at 19:12

10 Answers 10

92
+50

There is a mutable alternative to collections.namedtuple - recordclass.

It has the same API and memory footprint as namedtuple and it supports assignments (It should be faster as well). For example:

from recordclass import recordclass

Point = recordclass('Point', 'x y')

>>> p = Point(1, 2)
>>> p
Point(x=1, y=2)
>>> print(p.x, p.y)
1 2
>>> p.x += 2; p.y += 3; print(p)
Point(x=3, y=5)

For python 3.6 and higher recordclass (since 0.5) support typehints:

from recordclass import recordclass, RecordClass

class Point(RecordClass):
   x: int
   y: int

>>> Point.__annotations__
{'x':int, 'y':int}
>>> p = Point(1, 2)
>>> p
Point(x=1, y=2)
>>> print(p.x, p.y)
1 2
>>> p.x += 2; p.y += 3; print(p)
Point(x=3, y=5)

There is a more complete example (it also includes performance comparisons).

Since 0.9 recordclass library provides another variant -- recordclass.structclass factory function. It can produce classes, whose instances occupy less memory than __slots__-based instances. This is can be important for the instances with attribute values, which has not intended to have reference cycles. Here is an illustrative example.

  • 2
    Like it. 'This library actually is a “proof of concept” for the problem of “mutable” alternative of named tuple.` – Alexander Apr 2 '15 at 19:29
  • recordclass is slower, takes more memory, and requires C-extensions as compared with Antti Haapala's recipe and namedlist. – GrantJ Dec 20 '16 at 19:20
  • recordclass is a mutable version of collection.namedtuple that inherits it's api, memory footprint, but support assignments. namedlist is actually instance of python class with slots. It's more usefull if you don't need fast access to it's fields by index. – intellimath Dec 20 '16 at 19:34
  • Attribute access for recordclass instance (python 3.5.2) is about 2-3% slower than for namedlist – intellimath Dec 20 '16 at 19:54
  • When using namedtuple and simple class creation Point = namedtuple('Point', 'x y'), Jedi can autocomplete attributes, while this is not the case for recordclass. If I use the longer creation code (based on RecordClass), then Jedi understands the Point class, but not its constructor or attributes... Is there a way to get recordclass to work nicely with Jedi? – PhilMacKay Jan 10 at 20:51
21

It seems like the answer to this question is no.

Below is pretty close, but it's not technically mutable. This is creating a new namedtuple() instance with an updated x value:

Point = namedtuple('Point', ['x', 'y'])
p = Point(0, 0)
p = p._replace(x=10) 

On the other hand, you can create a simple class using __slots__ that should work well for frequently updating class instance attributes:

class Point:
    __slots__ = ['x', 'y']
    def __init__(self, x, y):
        self.x = x
        self.y = y

To add to this answer, I think __slots__ is good use here because it's memory efficient when you create lots of class instances. The only downside is that you can't create new class attributes.

Here's one relevant thread that illustrates the memory efficiency - Dictionary vs Object - which is more efficient and why?

The quoted content in the answer of this thread is a very succinct explanation why __slots__ is more memory efficient - Python slots

  • 1
    Close, but clunky. Let's say I wanted to do a += assignment, I would then need to do: p._replace(x = p.x + 10) vs. p.x += 10 – Alexander Mar 26 '15 at 23:19
  • 1
    yeah, it's not really changing the existing tuple, it's creating a new instance – kennes Mar 26 '15 at 23:25
19

The latest namedlist 1.7 passes all of your tests with both Python 2.7 and Python 3.5 as of Jan 11, 2016. It is a pure python implementation whereas the recordclass is a C extension. Of course, it depends on your requirements whether a C extension is preferred or not.

Your tests (but also see the note below):

from __future__ import print_function
import pickle
import sys
from namedlist import namedlist

Point = namedlist('Point', 'x y')
p = Point(x=1, y=2)

print('1. Mutation of field values')
p.x *= 10
p.y += 10
print('p: {}, {}\n'.format(p.x, p.y))

print('2. String')
print('p: {}\n'.format(p))

print('3. Representation')
print(repr(p), '\n')

print('4. Sizeof')
print('size of p:', sys.getsizeof(p), '\n')

print('5. Access by name of field')
print('p: {}, {}\n'.format(p.x, p.y))

print('6. Access by index')
print('p: {}, {}\n'.format(p[0], p[1]))

print('7. Iterative unpacking')
x, y = p
print('p: {}, {}\n'.format(x, y))

print('8. Iteration')
print('p: {}\n'.format([v for v in p]))

print('9. Ordered Dict')
print('p: {}\n'.format(p._asdict()))

print('10. Inplace replacement (update?)')
p._update(x=100, y=200)
print('p: {}\n'.format(p))

print('11. Pickle and Unpickle')
pickled = pickle.dumps(p)
unpickled = pickle.loads(pickled)
assert p == unpickled
print('Pickled successfully\n')

print('12. Fields\n')
print('p: {}\n'.format(p._fields))

print('13. Slots')
print('p: {}\n'.format(p.__slots__))

Output on Python 2.7

1. Mutation of field values  
p: 10, 12

2. String  
p: Point(x=10, y=12)

3. Representation  
Point(x=10, y=12) 

4. Sizeof  
size of p: 64 

5. Access by name of field  
p: 10, 12

6. Access by index  
p: 10, 12

7. Iterative unpacking  
p: 10, 12

8. Iteration  
p: [10, 12]

9. Ordered Dict  
p: OrderedDict([('x', 10), ('y', 12)])

10. Inplace replacement (update?)  
p: Point(x=100, y=200)

11. Pickle and Unpickle  
Pickled successfully

12. Fields  
p: ('x', 'y')

13. Slots  
p: ('x', 'y')

The only difference with Python 3.5 is that the namedlist has become smaller, the size is 56 (Python 2.7 reports 64).

Note that I have changed your test 10 for in-place replacement. The namedlist has a _replace() method which does a shallow copy, and that makes perfect sense to me because the namedtuple in the standard library behaves the same way. Changing the semantics of the _replace() method would be confusing. In my opinion the _update() method should be used for in-place updates. Or maybe I failed to understand the intent of your test 10?

  • There is important nuance. The namedlist store values in the list instance. The thing is that cpython's list is actually a dynamic array. By design, it allocates more memory than necessary in order to make mutation of the list cheaper. – intellimath Jun 2 '16 at 8:35
  • @intellimath namedlist is a bit of misnomer. It does not actually inherit from list and by default uses __slots__ optimization. When I measured, memory use was less than recordclass: 96 bytes vs 104 bytes for six fields on Python 2.7 – GrantJ Dec 20 '16 at 19:10
  • @GrantJ Yes. recorclass uses more memory because it's a tuple-like object with variable memory size. – intellimath Dec 20 '16 at 20:06
  • 1
    Anonymous downvotes are not helping anybody. What is wrong with the answer? Why the downvote? – Ali Dec 11 '18 at 20:25
  • I love the safety against typos that it provides with respect to types.SimpleNamespace. Unfortunately, pylint does not like it :-( – xverges Dec 21 '18 at 6:52
17

types.SimpleNamespace was introduced in Python 3.3 and supports the requested requirements.

from types import SimpleNamespace
t = SimpleNamespace(foo='bar')
t.ham = 'spam'
print(t)
namespace(foo='bar', ham='spam')
print(t.foo)
'bar'
import pickle
with open('/tmp/pickle', 'wb') as f:
    pickle.dump(t, f)
  • I've been looking for something like this for years. Great replacement for a dotted dict library like dotmap – axwell Jun 21 '18 at 4:11
  • Wow, for me it was very very very helpful, thanks! – Евгений Артеменко Oct 30 '18 at 21:18
  • This needs more upvotes. It’s exactly what the OP was looking for, it’s in the standard library, and it could not be simpler to use. Thanks! – Tom Zych Nov 25 '18 at 13:33
  • -1 The OP made it very clear with his tests what he needs and SimpleNamespace fails tests 6-10 (access by index, iterative unpacking, iteration, ordered dict, in-place replacement) and 12, 13 (fields, slots). Note that the documentation (that you linked in the answer) specifically says "SimpleNamespace may be useful as a replacement for class NS: pass. However, for a structured record type use namedtuple() instead." – Ali Dec 24 '18 at 12:33
8

As a very Pythonic alternative for this task, since Python-3.7, you can use dataclasses module that not only behaves like a mutable NamedTuple because they use normal class definitions they also support other classes features.

From PEP-0557:

Although they use a very different mechanism, Data Classes can be thought of as "mutable namedtuples with defaults". Because Data Classes use normal class definition syntax, you are free to use inheritance, metaclasses, docstrings, user-defined methods, class factories, and other Python class features.

A class decorator is provided which inspects a class definition for variables with type annotations as defined in PEP 526, "Syntax for Variable Annotations". In this document, such variables are called fields. Using these fields, the decorator adds generated method definitions to the class to support instance initialization, a repr, comparison methods, and optionally other methods as described in the Specification section. Such a class is called a Data Class, but there's really nothing special about the class: the decorator adds generated methods to the class and returns the same class it was given.

This feature is introduced in PEP-0557 that you can read about it in more details on provided documentation link.

Example:

In [20]: from dataclasses import dataclass

In [21]: @dataclass
    ...: class InventoryItem:
    ...:     '''Class for keeping track of an item in inventory.'''
    ...:     name: str
    ...:     unit_price: float
    ...:     quantity_on_hand: int = 0
    ...: 
    ...:     def total_cost(self) -> float:
    ...:         return self.unit_price * self.quantity_on_hand
    ...:    

Demo:

In [23]: II = InventoryItem('bisc', 2000)

In [24]: II
Out[24]: InventoryItem(name='bisc', unit_price=2000, quantity_on_hand=0)

In [25]: II.name = 'choco'

In [26]: II.name
Out[26]: 'choco'

In [27]: 

In [27]: II.unit_price *= 3

In [28]: II.unit_price
Out[28]: 6000

In [29]: II
Out[29]: InventoryItem(name='choco', unit_price=6000, quantity_on_hand=0)
  • 1
    It was made very clear with the tests in the OP what is needed and dataclass fails tests 6-10 (access by index, iterative unpacking, iteration, ordered dict, in-place replacement) and 12, 13 (fields, slots) in Python 3.7.1. – Ali Dec 24 '18 at 13:05
6

The following is a good solution for Python 3: A minimal class using __slots__ and Sequence abstract base class; does not do fancy error detection or such, but it works, and behaves mostly like a mutable tuple (except for typecheck).

from collections import Sequence

class NamedMutableSequence(Sequence):
    __slots__ = ()

    def __init__(self, *a, **kw):
        slots = self.__slots__
        for k in slots:
            setattr(self, k, kw.get(k))

        if a:
            for k, v in zip(slots, a):
                setattr(self, k, v)

    def __str__(self):
        clsname = self.__class__.__name__
        values = ', '.join('%s=%r' % (k, getattr(self, k))
                           for k in self.__slots__)
        return '%s(%s)' % (clsname, values)

    __repr__ = __str__

    def __getitem__(self, item):
        return getattr(self, self.__slots__[item])

    def __setitem__(self, item, value):
        return setattr(self, self.__slots__[item], value)

    def __len__(self):
        return len(self.__slots__)

class Point(NamedMutableSequence):
    __slots__ = ('x', 'y')

Example:

>>> p = Point(0, 0)
>>> p.x = 10
>>> p
Point(x=10, y=0)
>>> p.x *= 10
>>> p
Point(x=100, y=0)

If you want, you can have a method to create the class too (though using an explicit class is more transparent):

def namedgroup(name, members):
    if isinstance(members, str):
        members = members.split()
    members = tuple(members)
    return type(name, (NamedMutableSequence,), {'__slots__': members})

Example:

>>> Point = namedgroup('Point', ['x', 'y'])
>>> Point(6, 42)
Point(x=6, y=42)

In Python 2 you need to adjust it slightly - if you inherit from Sequence, the class will have a __dict__ and the __slots__ will stop from working.

The solution in Python 2 is to not inherit from Sequence, but object. If isinstance(Point, Sequence) == True is desired, you need to register the NamedMutableSequence as a base class to Sequence:

Sequence.register(NamedMutableSequence)
3

Let's implement this with dynamic type creation:

import copy
def namedgroup(typename, fieldnames):

    def init(self, **kwargs): 
        attrs = {k: None for k in self._attrs_}
        for k in kwargs:
            if k in self._attrs_:
                attrs[k] = kwargs[k]
            else:
                raise AttributeError('Invalid Field')
        self.__dict__.update(attrs)

    def getattribute(self, attr):
        if attr.startswith("_") or attr in self._attrs_:
            return object.__getattribute__(self, attr)
        else:
            raise AttributeError('Invalid Field')

    def setattr(self, attr, value):
        if attr in self._attrs_:
            object.__setattr__(self, attr, value)
        else:
            raise AttributeError('Invalid Field')

    def rep(self):
         d = ["{}={}".format(v,self.__dict__[v]) for v in self._attrs_]
         return self._typename_ + '(' + ', '.join(d) + ')'

    def iterate(self):
        for x in self._attrs_:
            yield self.__dict__[x]
        raise StopIteration()

    def setitem(self, *args, **kwargs):
        return self.__dict__.__setitem__(*args, **kwargs)

    def getitem(self, *args, **kwargs):
        return self.__dict__.__getitem__(*args, **kwargs)

    attrs = {"__init__": init,
                "__setattr__": setattr,
                "__getattribute__": getattribute,
                "_attrs_": copy.deepcopy(fieldnames),
                "_typename_": str(typename),
                "__str__": rep,
                "__repr__": rep,
                "__len__": lambda self: len(fieldnames),
                "__iter__": iterate,
                "__setitem__": setitem,
                "__getitem__": getitem,
                }

    return type(typename, (object,), attrs)

This checks the attributes to see if they are valid before allowing the operation to continue.

So is this pickleable? Yes if (and only if) you do the following:

>>> import pickle
>>> Point = namedgroup("Point", ["x", "y"])
>>> p = Point(x=100, y=200)
>>> p2 = pickle.loads(pickle.dumps(p))
>>> p2.x
100
>>> p2.y
200
>>> id(p) != id(p2)
True

The definition has to be in your namespace, and must exist long enough for pickle to find it. So if you define this to be in your package, it should work.

Point = namedgroup("Point", ["x", "y"])

Pickle will fail if you do the following, or make the definition temporary (goes out of scope when the function ends, say):

some_point = namedgroup("Point", ["x", "y"])

And yes, it does preserve the order of the fields listed in the type creation.

  • If you add an __iter__ method with for k in self._attrs_: yield getattr(self, k), that will support unpacking like a tuple. – snapshoe Apr 2 '15 at 0:06
  • It's also pretty easy to add __len__, __getitem__, and __setiem__ methods to support getting valus by index, like p[0]. With these last bits, this seems like the most complete and correct answer (to me anyway). – snapshoe Apr 2 '15 at 0:35
  • __len__ and __iter__ are good. __getitem__ and __setitem__ can really be mapped to self.__dict__.__setitem__ and self.__dict__.__getitem__ – MadMan2064 Apr 2 '15 at 1:14
2

If you want similar behavior as namedtuples but mutable try namedlist

Note that in order to be mutable it cannot be a tuple.

  • Thanks for the link. This looks like the closest so far, but I need to evaluate it in more detail. Btw, I'm totally aware tuples are immutable, which is why I'm looking for a solution like namedtuple. – Alexander Mar 31 '15 at 14:57
1

Tuples are by definition immutable.

You can however make a dictionary subclass where you can access the attributes with dot-notation;

In [1]: %cpaste
Pasting code; enter '--' alone on the line to stop or use Ctrl-D.
:class AttrDict(dict):
:
:    def __getattr__(self, name):
:        return self[name]
:
:    def __setattr__(self, name, value):
:        self[name] = value
:--

In [2]: test = AttrDict()

In [3]: test.a = 1

In [4]: test.b = True

In [5]: test
Out[5]: {'a': 1, 'b': True}
0

Provided performance is of little importance, one could use a silly hack like:

from collection import namedtuple

Point = namedtuple('Point', 'x y z')
mutable_z = Point(1,2,[3])
  • 1
    This answer isn't very well explained. It looks confusing if you don't understand the mutable nature of lists. --- In this example... to re-assign z, you have to call mutable_z.z.pop(0) then mutable_z.z.append(new_value). If you get this wrong, you'll end up with more than 1 element and your program will behave unexpectedly. – byxor Sep 19 '17 at 13:30
  • @byxor that, or you could just: mutable_z.z[0] = newValue. It is indeed a hack, as stated. – Srg Apr 28 '18 at 15:05
  • Oh yeah, I'm surprised I missed the more obvious way to re-assign it. – byxor Apr 28 '18 at 15:18

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