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What is the purpose of __slots__ in Python — especially with respect to when would I want to use it and when not?

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Jeb, the accepted answer below is incorrect & incomplete for multiple reasons, and I do have a comprehensive answer below for you: stackoverflow.com/a/28059785/541136 – Aaron Hall Jun 17 at 20:36
up vote 240 down vote accepted

Quoting Jacob Hallen:

The proper use of __slots__ is to save space in objects. Instead of having a dynamic dict that allows adding attributes to objects at anytime, there is a static structure which does not allow additions after creation. This saves the overhead of one dict for every object that uses slots. While this is sometimes a useful optimization, it would be completely unnecessary if the Python interpreter was dynamic enough so that it would only require the dict when there actually were additions to the object.

Unfortunately there is a side effect to slots. They change the behavior of the objects that have slots in a way that can be abused by control freaks and static typing weenies. This is bad, because the control freaks should be abusing the metaclasses and the static typing weenies should be abusing decorators, since in Python, there should be only one obvious way of doing something.

Making CPython smart enough to handle saving space without __slots__ is a major undertaking, which is probably why it is not on the list of changes for P3k (yet).

share|improve this answer
I'd like to see some elaboration on the "static typing"/decorator point, sans pejoratives. Quoting absent third parties is unhelpful. __slots__ doesn't address the same issues as static typing. For example, in C++, it is not the declaration of a member variable is being restricted, it is the assignment of an unintended type (and compiler enforced) to that variable. I'm not condoning the use of __slots__, just interested in the conversation. Thanks! – hiwaylon Nov 28 '11 at 17:54
Python 3.3 fiinally got around to sme of the meory saving without __slots__by the use of shared key dictionaries for instances: python.org/dev/peps/pep-0412 – jsbueno Feb 7 '13 at 17:09
One must also consider the observations Fredrik Lundh makes later in the same thread regarding the performance of dictionary lookup vs. object attributes — so the overhead of a __dict__ might be a completely reasonable trade-off depending on usage. – martineau May 24 at 18:54
Answer by Aaron Hall below is much better: stackoverflow.com/a/28059785/618045 – Sklavit Jul 14 at 8:10
@Sklavit Agreed. I would be happy if Aaron Hall's post would be the accepted answer. – Jeff Bauer Jul 14 at 14:03

You would want to use __slots__ if you are going to instantiate a lot (hundreds, thousands) of objects of the same class. __slots__ only exists as a memory optimization tool.

It's highly discouraged to use __slots__ for constraining attribute creation, and in general you want to avoid it because it breaks pickle, along with some other introspection features of python.

share|improve this answer
What are the "other introspection features of python"? – Rob Bednark Jan 8 '15 at 17:16
@RobBednark __dict__ doesn't exist for objects whose class has __slots__. – Kroltan Mar 3 '15 at 14:57
I think it's misinformation to state that it breaks pickle. – Aaron Hall Apr 1 at 16:09
Can you elaborate? Do you mean: (a) it doesn't actually break pickle, (b) it breaks pickle, but that's easy to fix, (c) you shouldn't be using pickle anyways, or (d) something else? :) – Ryan Apr 2 at 20:46
I demonstrate pickling a slotted object below. – Aaron Hall May 2 at 15:08

In Python, what is the purpose of __slots__ and what are the cases one should avoid this?


The special attribute __slots__ allows you to explicitly state in your code which instance attributes you expect your object instances to have, with the expected results:

  1. faster attribute access.
  2. potential space savings in memory.


  • To have attributes named in __slots__ to actually be stored in slots instead of a __dict__, a class must inherit from object.

  • To prevent the creation of a __dict__, you must inherit from object and all classes in the inheritance must declare __slots__ and none of them can have a '__dict__' entry - and they cannot use multiple inheritance.

There are a lot of details if you wish to keep reading.

Why use __slots__: Faster attribute access.

The creator of Python, Guido van Rossum, states that he actually created __slots__ for faster attribute access.

It is trivial to demonstrate measurably significant faster access:

import timeit

class Foo(object): __slots__ = 'foo',

class Bar(object): pass

slotted = Foo()
not_slotted = Bar()

def get_set_delete_fn(obj):
    def get_set_delete():
        obj.foo = 'foo'
        del obj.foo
    return get_set_delete


>>> min(timeit.repeat(get_set_delete_fn(slotted)))
>>> min(timeit.repeat(get_set_delete_fn(not_slotted)))

The slotted access is almost 30% faster in Python 3.5 on Ubuntu.

>>> 0.3664822799983085 / 0.2846834529991611

In Python 2 on Windows I have measured it about 15% faster.

Why use __slots__: Memory Savings

Another purpose of __slots__ is to reduce the space in memory that each object instance takes up.

The documentation clearly states the reasons behind this:

By default, instances of both old and new-style classes have a dictionary for attribute storage. This wastes space for objects having very few instance variables. The space consumption can become acute when creating large numbers of instances.

The default can be overridden by defining __slots__ in a new-style class definition. The __slots__ declaration takes a sequence of instance variables and reserves just enough space in each instance to hold a value for each variable. Space is saved because __dict__ is not created for each instance.

To verify this, using the Anaconda distribution of Python 2.7 on Ubuntu Linux, with guppy.hpy (aka heapy) and sys.getsizeof, the size of a class instance without __slots__ declared, and nothing else, is 64 bytes. That does not include the __dict__. Thank you Python for lazy evaluation again, the __dict__ is apparently not called into existence until it is referenced, but classes without data are usually useless. When called into existence, the __dict__ attribute is a minimum of 280 bytes additionally.

In contrast, a class instance with __slots__ declared to be () (no data) is only 16 bytes, and 56 total bytes with one item in slots, 64 with two.

I tested when my particular implementation of dicts size up by enumerating alphabet characters into a dict, and on the sixth item it climbs to 1048, 22 to 3352, then 85 to 12568 (rather impractical to put that many attributes on a single class, probably violating the single responsibility principle there.)

attrs  __slots__    no slots declared + __dict__
none       16        64 (+ 280 if __dict__ referenced)
one        56        64 + 280
two        64        64 + 280
six        96        64 + 1048
22        224        64 + 3352

So we see how nicely __slots__ scale for instances to save us memory, and that is the reason you would want to use __slots__.

Demonstration of __slots__:

To prevent the creation of a __dict__, you must subclass object:

>>> class Base(object): __slots__ = ()
>>> b = Base()
>>> b.a = 'a'
Traceback (most recent call last):
  File "<pyshell#38>", line 1, in <module>
    b.a = 'a'
AttributeError: 'Base' object has no attribute 'a'

Or another class that defines __slots__

>>> class Child(Base): __slots__ = ('a',)
>>> c = Child()
>>> c.a = 'a'
>>> c.b = 'b'
Traceback (most recent call last):
  File "<pyshell#42>", line 1, in <module>
    c.b = 'b'
AttributeError: 'Child' object has no attribute 'b'

To allow __dict__ creation while subclassing slotted objects, just add '__dict__' to the __slots__:

>>> class SlottedWithDict(Child): __slots__ = ('__dict__', 'b')
>>> swd = SlottedWithDict()
>>> swd.a = 'a'
>>> swd.b = 'b'
>>> swd.c = 'c'
>>> swd.__dict__
{'c': 'c'}

Or you don't even need to declare slots in your subclass, and you will still use slots from the parents, but not restrict the creation of a __dict__:

>>> class NoSlots(Child): pass
>>> ns = NoSlots()
>>> ns.a = 'a'
>>> ns.b = 'b'
>>> ns.__dict__
{'b': 'b'}

However, __slots__ may cause problems for multiple inheritance:

>>> class BaseA(object): __slots__ = ('a',)
>>> class BaseB(object): __slots__ = ('b',)
>>> class Child(BaseA, BaseB): __slots__ = ()
Traceback (most recent call last):
  File "<pyshell#68>", line 1, in <module>
    class Child(BaseA, BaseB): __slots__ = ()
TypeError: Error when calling the metaclass bases
    multiple bases have instance lay-out conflict

If you run into this problem, just remove __slots__, and put it back in where you have a lot of instances.

>>> class BaseA(object): __slots__ = ()
>>> class BaseB(object): __slots__ = ()
>>> class Child(BaseA, BaseB): __slots__ = ('a', 'b')
>>> c = Child
>>> c.a = 'a'
>>> c.b = 'b'
>>> c.c = 'c'
>>> c.__dict__
<dictproxy object at 0x10C944B0>
>>> c.__dict__['c']

Add '__dict__' to __slots__ to get dynamic assignment:

class Foo(object):
    __slots__ = 'bar', 'baz', '__dict__'

and now:

>>> foo = Foo()
>>> foo.boink = 'boink'

So with '__dict__' in slots we lose some of the size benefits with the upside of having dynamic assignment and still having slots for the names we do expect.

When you inherit from an object that isn't slotted, you get the same sort of semantics when you use __slots__ - names that are in __slots__ point to slotted values, while any other values are put in the instance's __dict__.

Avoiding __slots__ because you want to be able to add attributes on the fly is actually not a good reason - just add "__dict__" to your __slots__ if this is required.

Set to empty tuple when subclassing a namedtuple:

The namedtuple builtin make immutable instances that are very lightweight (essentially, the size of tuples) but to get the benefits, you need to do it yourself if you subclass them:

from collections import namedtuple
class MyNT(namedtuple('MyNT', 'bar baz')):
    """MyNT is an immutable and lightweight object"""
    __slots__ = ()


>>> nt = MyNT('bar', 'baz')
>>> nt.bar
>>> nt.baz

Cases to avoid slots:

  • Avoid them when you want to perform __class__ assignment with another class that doesn't have them (and you can't add them).
  • Avoid them if you want to subclass variable length builtins like long, tuple, or str, and you want to add attributes to them.
  • Avoid them if you insist on providing default values via class attributes for instance variables.
  • Avoid them for parent classes in the case of multiple inheritance - you can reinsert them for a child where you have a lot of instances.

You may be able to tease out further caveats from the rest of the __slots__ documentation, which follows:


This class variable can be assigned a string, iterable, or sequence of strings with variable names used by instances. If defined in a new-style class, __slots__ reserves space for the declared variables and prevents the automatic creation of __dict__ and __weakref__ for each instance.

Notes on using __slots__

  • When inheriting from a class without __slots__, the __dict__ attribute of that class will always be accessible, so a __slots__ definition in the subclass is meaningless.

  • Without a __dict__ variable, instances cannot be assigned new variables not listed in the __slots__ definition. Attempts to assign to an unlisted variable name raises AttributeError. If dynamic assignment of new variables is desired, then add '__dict__' to the sequence of strings in the __slots__ declaration.

    Changed in version 2.3: Previously, adding '__dict__' to the __slots__ declaration would not enable the assignment of new attributes not specifically listed in the sequence of instance variable names.

  • Without a __weakref__ variable for each instance, classes defining __slots__ do not support weak references to its instances. If weak reference support is needed, then add '__weakref__' to the sequence of strings in the __slots__ declaration.

    Changed in version 2.3: Previously, adding '__weakref__' to the __slots__ declaration would not enable support for weak references.

  • __slots__ are implemented at the class level by creating descriptors (Implementing Descriptors) for each variable name. As a result, class attributes cannot be used to set default values for instance variables defined by __slots__; otherwise, the class attribute would overwrite the descriptor assignment.

  • The action of a __slots__ declaration is limited to the class where it is defined. As a result, subclasses will have a __dict__ unless they also define __slots__ (which must only contain names of any additional slots).

  • If a class defines a slot also defined in a base class, the instance variable defined by the base class slot is inaccessible (except by retrieving its descriptor directly from the base class). This renders the meaning of the program undefined. In the future, a check may be added to prevent this.

  • Nonempty __slots__ does not work for classes derived from “variable-length” built-in types such as long, str and tuple.

  • Any non-string iterable may be assigned to __slots__. Mappings may also be used; however, in the future, special meaning may be assigned to the values corresponding to each key.

  • __class__ assignment works only if both classes have the same __slots__.

    Changed in version 2.6: Previously, __class__ assignment raised an error if either new or old class had __slots__.

Critiques of other answers

The current top answers cite outdated information and are quite hand-wavy and miss the mark in some important ways.

Pickling, __slots__ doesn't break

When pickling a slotted object, you may find it complains with a misleading TypeError:

>>> pickle.loads(pickle.dumps(f))
TypeError: a class that defines __slots__ without defining __getstate__ cannot be pickled

This is actually incorrect. This message comes from the oldest protocol, which is the default. You can select the latest protocol with the -1 argument. In Python 2.7 this would be 2 (which was introduced in 2.3), and in 3.6 it is 4.

>>> pickle.loads(pickle.dumps(f, -1))
<__main__.Foo object at 0x1129C770>

in Python 2.7:

>>> pickle.loads(pickle.dumps(f, 2))
<__main__.Foo object at 0x1129C770>

in Python 3.6

>>> pickle.loads(pickle.dumps(f, 4))
<__main__.Foo object at 0x1129C770>

So I would keep this in mind, as it is a solved problem.

Critique of the accepted answer

The first paragraph is half short explanation, half predictive. Here's the only part that actually answers the question

The proper use of slots is to save space in objects. Instead of having a dynamic dict that allows adding attributes to objects at anytime, there is a static structure which does not allow additions after creation. This saves the overhead of one dict for every object that uses slots

The second half is wishful thinking, and off the mark:

While this is sometimes a useful optimization, it would be completely unnecessary if the Python interpreter was dynamic enough so that it would only require the dict when there actually were additions to the object.

Python actually does something similar to this, only creating the __dict__ when it is accessed, but creating lots of objects with no data is fairly ridiculous.

The second paragraph oversimplifies and misses actual reasons to avoid __slots__. The below is not a real reason to avoid slots (for actual reasons, see the rest of my answer above.):

They change the behavior of the objects that have slots in a way that can be abused by control freaks and static typing weenies.

It then goes on to discuss other ways of accomplishing that perverse goal with Python, not discussing anything to do with __slots__.

The third paragraph is more wishful thinking. Together it is mostly off-the-mark content that the answerer didn't even author and contributes to ammunition for critics of the site.

Memory usage evidence

Create some normal objects and slotted objects:

>>> class Foo(object): pass
>>> class Bar(object): __slots__ = ()

Instantiate a million of them:

>>> foos = [Foo() for f in xrange(1000000)]
>>> bars = [Bar() for b in xrange(1000000)]

Inspect with guppy.hpy().heap():

>>> guppy.hpy().heap()
Partition of a set of 2028259 objects. Total size = 99763360 bytes.
 Index  Count   %     Size   % Cumulative  % Kind (class / dict of class)
     0 1000000  49 64000000  64  64000000  64 __main__.Foo
     1     169   0 16281480  16  80281480  80 list
     2 1000000  49 16000000  16  96281480  97 __main__.Bar
     3   12284   1   987472   1  97268952  97 str

Access the regular objects and their __dict__ and inspect again:

>>> for f in foos:
...     f.__dict__
>>> guppy.hpy().heap()
Partition of a set of 3028258 objects. Total size = 379763480 bytes.
 Index  Count   %      Size    % Cumulative  % Kind (class / dict of class)
     0 1000000  33 280000000  74 280000000  74 dict of __main__.Foo
     1 1000000  33  64000000  17 344000000  91 __main__.Foo
     2     169   0  16281480   4 360281480  95 list
     3 1000000  33  16000000   4 376281480  99 __main__.Bar
     4   12284   0    987472   0 377268952  99 str

This is consistent with the history of Python, from Unifying types and classes in Python 2.2

If you subclass a built-in type, extra space is automatically added to the instances to accomodate __dict__ and __weakrefs__. (The __dict__ is not initialized until you use it though, so you shouldn't worry about the space occupied by an empty dictionary for each instance you create.) If you don't need this extra space, you can add the phrase "__slots__ = []" to your class.

share|improve this answer
On my machine, I can add slots to ints on Python 2.7 and strings on Python 3.4, but not vice-versa. At one point, everybody seemed to agree that strings shouldn't be slottable, but here we are. Do you know if it was consciously decided to allow this (slots in strings on Python 3), or if it is a fluke in the current implementation? – Patrick Maupin Jul 25 '15 at 16:36
This answer seems to cover everything except pickling. You can't pickle an object with __slots__ by default, but can add support with __getstate__ and __setstate__. – camomilk Jan 27 at 19:40
@camomilk That's for the old protocol of pickling (not sure about __setstate__), you can get the newest protocol (which handles slots) with the -1 argument. For example, this slotted object without __getstate__: >>> pickle.loads(pickle.dumps(f, -1)) <__main__.Foo object at 0xffec882c> >>> pickle.loads(pickle.dumps(f, -1)).foo 'foo' --- I'll add info about that and address your concerns to this answer later. But see stackoverflow.com/questions/2204155 for now. – Aaron Hall Jan 27 at 20:01
Is there a reason why you wrote this (0.2846834529991611 ** -1 )/(0.3664822799983085 ** -1) instead of just 0.3664822799983085/0.2846834529991611? – mike Jul 2 at 7:27
@mike It was an artifact of how I mentally derived it, I realized it later, but wasn't in a position to address it and promptly forgot about it. Thanks for reminding me! – Aaron Hall Jul 2 at 21:40

Each python object has a __dict__ atttribute which is a dictionary containing all other attributes. e.g. when you type self.attr python is actually doing self.__dict__['attr']. As you can imagine using a dictionary to store attribute takes some extra space & time for accessing it.

However, when you use __slots__, any object created for that class won't have a __dict__ attribute. Instead, all attribute access is done directly via pointers.

So if want a C style structure rather than a full fledged class you can use __slots__ for compacting size of the objects & reducing attribute access time. A good example is a Point class containing attributes x & y. If you are going to have a lot of points, you can try using __slots__ in order to conserve some memory.

share|improve this answer
No, an instance of a class with __slots__ defined is not like a C-style structure. There is a class-level dictionary mapping attribute names to indexes, otherwise the following would not be possible: class A(object): __slots__= "value",\n\na=A(); setattr(a, 'value', 1) I really think this answer should be clarified (I can do that if you want). Also, I'm not certain that instance.__hidden_attributes[instance.__class__[attrname]] is faster than instance.__dict__[attrname]. – tzot Oct 15 '11 at 13:56
@tzot Can you clarify the answer? :) – C S Jun 12 '15 at 18:08
This is a very good answer! – Felippe Da Motta Raposo Jun 13 '15 at 14:56

In addition to the other answers, here is an example of using __slots__:

>>> class Test(object):   #Must be new-style class!
...  __slots__ = ['x', 'y']
>>> pt = Test()
>>> dir(pt)
['__class__', '__delattr__', '__doc__', '__getattribute__', '__hash__', 
 '__init__', '__module__', '__new__', '__reduce__', '__reduce_ex__', 
 '__repr__', '__setattr__', '__slots__', '__str__', 'x', 'y']
>>> pt.x
Traceback (most recent call last):
  File "<stdin>", line 1, in <module>
AttributeError: x
>>> pt.x = 1
>>> pt.x
>>> pt.z = 2
Traceback (most recent call last):
  File "<stdin>", line 1, in <module>
AttributeError: 'Test' object has no attribute 'z'
>>> pt.__dict__
Traceback (most recent call last):
  File "<stdin>", line 1, in <module>
AttributeError: 'Test' object has no attribute '__dict__'
>>> pt.__slots__
['x', 'y']

So, to implement __slots__, it only takes an extra line (and making your class a new-style class if it isn't already). This way you can reduce the memory footprint of those classes 5-fold, at the expense of having to write custom pickle code, if and when that becomes necessary.

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That's the first question with an actual example of code. Thanks! – DeFazer Jan 22 at 22:37

Slots are very useful for library calls to eliminate the "named method dispatch" when making function calls. This is mentioned in the SWIG documentation. For high performance libraries that want to reduce function overhead for commonly called functions using slots is much faster.

Now this may not be directly related to the OPs question. It is related more to building extensions than it does to using the slots syntax on an object. But it does help complete the picture for the usage of slots and some of the reasoning behind them.

share|improve this answer

You have —essentially— no use for __slots__.

The time when you think you might need __slots__, you actually want to use Lightweight or Flyweight design patterns. These are cases when you no longer want to use purely Python objects. Instead, you want a Python object-like wrapper around an array, struct or numpy array.

class Flyweight(object):
    def get(self, theData, index):
        return theData[index]
    def set(self, theData, index, value):
        theData[index]= value

The class-like wrapper has no attributes — it just provides methods that act on the underlying data. The methods can be reduced to class methods. Indeed, it could be reduced to just functions operating on the underlying array of data.

share|improve this answer
What has Flyweight to do with slots? – oefe Jan 24 '09 at 22:46
@oefe: I certainly don't get your question. I can quote my answer, if it helps "when you think you might need slots, you actually want to use ... Flyweight design pattern". That's what Flyweight has to do with slots. Do you have a more specific question? – S.Lott Jan 24 '09 at 23:41
@oefe: Flyweight and __slots__ are both optimization techniques to save memory. __slots__ shows benefits when you have many many objects as well as Flyweight design pattern. The both solve the same problem. – J.F. Sebastian Nov 29 '09 at 20:51
Is there a available comparison between using slots and using Flyweight regarding memory consumption and speed? – kontulai Apr 23 '13 at 4:11
Although Flyweight is certainly useful in some contexts, believe it or not, the answer to "how can I reduce memory usage in Python when I create a zillion objects" is not always "don't use Python for your zillion objects." Sometimes __slots__ really is the answer, and as Evgeni points out, it can be added as a simple afterthought (e.g. you can focus on correctness first, and then add performance). – Patrick Maupin Jul 25 '15 at 16:19

An attribute of a class instance has 3 properties: the instance, the name of the attribute, and the value of the attribute.

In regular attribute access, the instance acts as a dictionary and the name of the attribute acts as the key in that dictionary looking up value.

instance(attribute) --> value

In __slots__ access, the name of the attribute acts as the dictionary and the instance acts as the key in the dictionary looking up value.

attribute(instance) --> value

In flyweight pattern, the name of the attribute acts as the dictionary and the value acts as the key in that dictionary looking up the instance.

attribute(value) --> instance

share|improve this answer
This is a good share, and won't fit well in a comment on one of the answers that also suggest flyweights, but it is not a complete answer to the question itself. In particular (in just context of the question): why Flyweight, and "what are the cases one should avoid ..." __slots__? – Merlyn Morgan-Graham Jul 25 '14 at 6:22
@Merlyn Morgan-Graham, it serves as a hint on which to pick: regular access, __slots__, or flyweight. – Dmitry Rubanovich Jul 26 '14 at 23:04

The original question was about general use cases not only about memory. So it should be mentioned here that you also get better performance when instantiating large amounts of objects - interesting e.g. when parsing large documents into objects or from a database.

Here is a comparison of creating object trees with a million entries, using slots and without slots. As a reference also the performance when using plain dicts for the trees (Py2.7.10 on OSX):

********** RUN 1 **********
1.96036410332 <class 'css_tree_select.element.Element'>
3.02922606468 <class 'css_tree_select.element.ElementNoSlots'>
2.90828204155 dict
********** RUN 2 **********
1.77050495148 <class 'css_tree_select.element.Element'>
3.10655999184 <class 'css_tree_select.element.ElementNoSlots'>
2.84120798111 dict
********** RUN 3 **********
1.84069895744 <class 'css_tree_select.element.Element'>
3.21540498734 <class 'css_tree_select.element.ElementNoSlots'>
2.59615707397 dict
********** RUN 4 **********
1.75041103363 <class 'css_tree_select.element.Element'>
3.17366290092 <class 'css_tree_select.element.ElementNoSlots'>
2.70941114426 dict

Test classes (ident, appart from slots):

class Element(object):
    __slots__ = ['_typ', 'id', 'parent', 'childs']
    def __init__(self, typ, id, parent=None):
        self._typ = typ
        self.id = id
        self.childs = []
        if parent:
            self.parent = parent

class ElementNoSlots(object): (same, w/o slots)

testcode, verbose mode:

na, nb, nc = 100, 100, 100
for i in (1, 2, 3, 4):
    print '*' * 10, 'RUN', i, '*' * 10
    # tree with slot and no slot:
    for cls in Element, ElementNoSlots:
        t1 = time.time()
        root = cls('root', 'root')
        for i in xrange(na):
            ela = cls(typ='a', id=i, parent=root)
            for j in xrange(nb):
                elb = cls(typ='b', id=(i, j), parent=ela)
                for k in xrange(nc):
                    elc = cls(typ='c', id=(i, j, k), parent=elb)
        to =  time.time() - t1
        print to, cls
        del root

    # ref: tree with dicts only:
    t1 = time.time()
    droot = {'childs': []}
    for i in xrange(na):
        ela =  {'typ': 'a', id: i, 'childs': []}
        for j in xrange(nb):
            elb =  {'typ': 'b', id: (i, j), 'childs': []}
            for k in xrange(nc):
                elc =  {'typ': 'c', id: (i, j, k), 'childs': []}
    td = time.time() - t1
    print td, 'dict'
    del droot
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