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What are the lesser-known but useful features of the Python programming language?

  • Try to limit answers to Python core.
  • One feature per answer.
  • Give an example and short description of the feature, not just a link to documentation.
  • Label the feature using a title as the first line.

Quick links to answers:


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191 Answers 191

Access Dictionary elements as attributes (properties). so if an a1=AttrDict() has key 'name' -> instead of a1['name'] we can easily access name attribute of a1 using ->

class AttrDict(dict):

    def __getattr__(self, name):
        if name in self:
            return self[name]
        raise AttributeError('%s not found' % name)

    def __setattr__(self, name, value):
        self[name] = value

    def __delattr__(self, name):
        del self[name]

person = AttrDict({'name': 'John Doe', 'age': 66})
print person['name']
print = 'Frodo G'

del person.age

print person
no title or explanation? where is the hidden feature here? – Sanjay Manohar Sep 8 '10 at 4:15

A module exports EVERYTHING in its namespace

Including names imported from other modules!

# this is ""
from operator import *
from inspect  import *

Now test what's importable from the module.

>>> import answer42
>>> answer42.__dict__.keys()
['gt', 'imul', 'ge', 'setslice', 'ArgInfo', 'getfile', 'isCallable', 'getsourcelines', 'CO_OPTIMIZED', 'le', 're', 'isgenerator', 'ArgSpec', 'imp', 'lt', 'delslice', 'BlockFinder', 'getargspec', 'currentframe', 'CO_NOFREE', 'namedtuple', 'rshift', 'string', 'getframeinfo', '__file__', 'strseq', 'iconcat', 'getmro', 'mod', 'getcallargs', 'isub', 'getouterframes', 'isdatadescriptor', 'modulesbyfile', 'setitem', 'truth', 'Attribute', 'div', 'CO_NESTED', 'ixor', 'getargvalues', 'ismemberdescriptor', 'getsource', 'isMappingType', 'eq', 'index', 'xor', 'sub', 'getcomments', 'neg', 'getslice', 'isframe', '__builtins__', 'abs', 'getmembers', 'mul', 'getclasstree', 'irepeat', 'is_', 'getitem', 'indexOf', 'Traceback', 'findsource', 'ModuleInfo', 'ipow', 'TPFLAGS_IS_ABSTRACT', 'or_', 'joinseq', 'is_not', 'itruediv', 'getsourcefile', 'dis', 'os', 'iand', 'countOf', 'getinnerframes', 'pow', 'pos', 'and_', 'lshift', '__name__', 'sequenceIncludes', 'isabstract', 'isbuiltin', 'invert', 'contains', 'add', 'isSequenceType', 'irshift', 'types', 'tokenize', 'isfunction', 'not_', 'istraceback', 'getmoduleinfo', 'isgeneratorfunction', 'getargs', 'CO_GENERATOR', 'cleandoc', 'classify_class_attrs', 'EndOfBlock', 'walktree', '__doc__', 'getmodule', 'isNumberType', 'ilshift', 'ismethod', 'ifloordiv', 'formatargvalues', 'indentsize', 'getmodulename', 'inv', 'Arguments', 'iscode', 'CO_NEWLOCALS', 'formatargspec', 'iadd', 'getlineno', 'imod', 'CO_VARKEYWORDS', 'ne', 'idiv', '__package__', 'CO_VARARGS', 'attrgetter', 'methodcaller', 'truediv', 'repeat', 'trace', 'isclass', 'ior', 'ismethoddescriptor', 'sys', 'isroutine', 'delitem', 'stack', 'concat', 'getdoc', 'getabsfile', 'ismodule', 'linecache', 'floordiv', 'isgetsetdescriptor', 'itemgetter', 'getblock']
>>> from answer42 import getmembers
>>> getmembers
<function getmembers at 0xb74b2924>

That's a good reason not to from x import * and to define __all__ =.

How is that a hidden feature? __all__ exists to limit what's exported, and it's even in the tutorial. – Cat Plus Plus Jan 13 '11 at 0:34
@PiotrLegnica Did you know that a module exports also what it imports unless _all_ is used? It is unlike most languages with modules, and I haven't read about the "feature" in the documentation, so, for me, it qualifies as hidden. – Apalala Jan 13 '11 at 1:05

Unicode identifier in Python3:

>>> 'Unicode字符_تكوين_Variable'.isidentifier()
>>> Unicode字符_تكوين_Variable='Python3 rules!'
>>> Unicode字符_تكوين_Variable
'Python3 rules!'
Of course, using non-ascii characters in python source code for any reason except to spell contributor names in the header documentation is in violation of pep-8 code style rules. – SingleNegationElimination Jul 28 '11 at 14:19

Python have exceptions for very unexpected things:


This let you import an alternative if a lib is missing

    import json
except ImportError:
    import simplejson as json


For loops do this internally, and catch StopIteration:

Traceback (most recent call last):
  File "<pyshell#4>", line 1, in <module>


>>> try:
...     assert []
... except AssertionError:
...     print "This list should not be empty"
This list should not be empty

While this is more verbose for one check, multiple checks mixing exceptions and boolean operators with the same error message can be shortened this way.


Everything is dynamic

"There is no compile-time". Everything in Python is runtime. A module is 'defined' by executing the module's source top-to-bottom, just like a script, and the resulting namespace is the module's attribute-space. Likewise, a class is 'defined' by executing the class body top-to-bottom, and the resulting namespace is the class's attribute-space. A class body can contain completely arbitrary code -- including import statements, loops and other class statements. Creating a class, function or even module 'dynamically', as is sometimes asked for, isn't hard; in fact, it's impossible to avoid, since everything is 'dynamic'.


Objects in boolean context

Empty tuples, lists, dicts, strings and many other objects are equivalent to False in boolean context (and non-empty are equivalent to True).

empty_tuple = ()
empty_list = []
empty_dict = {}
empty_string = ''
empty_set = set()
if empty_tuple or empty_list or empty_dict or empty_string or empty_set:
  print 'Never happens!'

This allows logical operations to return one of it's operands instead of True/False, which is useful in some situations:

s = t or "Default value" # s will be assigned "Default value"
                         # if t is false/empty/none
actually this is discouraged, you should use the "new" s = t if t else "default value" – Tom Aug 27 '09 at 10:52

Private methods and data hiding (encapsulation)

There's a common idiom in Python of denoting methods and other class members that are not intended to be part of the class's external API by giving them names that start with underscores. This is convenient and works very well in practice, but it gives the false impression that Python does not support true encapsulation of private code and/or data. In fact, Python automatically gives you lexical closures, which make it very easy to encapsulate data in a much more bulletproof way when the situation really warrants it. Here's a contrived example of a class that makes use of this technique:

class MyClass(object):
  def __init__(self):

    privateData = {}

    self.publicData = 123

    def privateMethod(k):
      print privateData[k] + self.publicData

    def privilegedMethod():
      privateData['foo'] = "hello "

    self.privilegedMethod = privilegedMethod

  def publicMethod(self):
    print self.publicData

And here's a contrived example of its use:

>>> obj = MyClass()
>>> obj.publicMethod()
>>> obj.publicData = 'World'
>>> obj.publicMethod()
>>> obj.privilegedMethod()
hello World
>>> obj.privateMethod()
Traceback (most recent call last):
  File "<stdin>", line 1, in <module>
AttributeError: 'MyClass' object has no attribute 'privateMethod'
>>> obj.privateData
Traceback (most recent call last):
  File "<stdin>", line 1, in <module>
AttributeError: 'MyClass' object has no attribute 'privateData'

The key is that privateMethod and privateData aren't really attributes of obj at all, so they can't be accessed from outside, nor do they show up in dir() or similar. They're local variables in the constructor, completely inaccessible outside of __init__. However, because of the magic of closures, they really are per-instance variables with the same lifetime as the object with which they're associated, even though there's no way to access them from outside except (in this example) by invoking privilegedMethod. Often this sort of very strict encapsulation is overkill, but sometimes it really can be very handy for keeping an API or a namespace squeaky clean.

In Python 2.x, the only way to have mutable private state is with a mutable object (such as the dict in this example). Many people have remarked on how annoying this can be. Python 3.x will remove this restriction by introducing the nonlocal keyword described in PEP 3104.

this is almost never a good idea. – Christian Oudard Jan 2 '09 at 18:38
"They're local variables in the constructor, completely inaccessible outside of init." Not true: >>> [c.cell_contents for c in obj.privilegedMethod.func_closure] --> [{'foo': 'hello '}, <function privateMethod at 0x65530>] – Miles Jun 22 '09 at 1:34

Functional support.

Generators and generator expressions, specifically.

Ruby made this mainstream again, but Python can do it just as well. Not as ubiquitous in the libraries as in Ruby, which is too bad, but I like the syntax better, it's simpler.

Because they're not as ubiquitous, I don't see as many examples out there on why they're useful, but they've allowed me to write cleaner, more efficient code.


If you've renamed a class in your application where you're loading user-saved files via Pickle, and one of the renamed classes are stored in a user's old save, you will not be able to load in that pickled file.

However, simply add in a reference to your class definition and everything's good:

e.g., before:

class Bleh:


class Blah:

so, your user's pickled saved file contains a reference to Bleh, which doesn't exist due to the rename. The fix?

Bleh = Blah



Simulating the tertiary operator using and and or.

and and or operators in python return the objects themselves rather than Booleans. Thus:

In [18]: a = True

In [19]: a and 3 or 4
Out[19]: 3

In [20]: a = False

In [21]: a and 3 or 4
Out[21]: 4

However, Py 2.5 seems to have added an explicit tertiary operator

    In [22]: a = 5 if True else '6'

    In [23]: a
    Out[23]: 5

Well, this works if you are sure that your true clause does not evaluate to False. example:

>>> def foo(): 
...     print "foo"
...     return 0
>>> def bar(): 
...     print "bar"
...     return 1
>>> 1 and foo() or bar()

To get it right, you've got to just a little bit more:

>>> (1 and [foo()] or [bar()])[0]

However, this isn't as pretty. if your version of python supports it, use the conditional operator.

>>> foo() if True or bar()
Careful with that: >>> a and "" or ":(" you'll always get a frowny face back, no matter if a is true or false – Marius Gedminas Jun 18 '09 at 19:00
(falseValue, trueValue)[cond] is a cleaner (IMO) way to simulate a ternary operator. – Wallacoloo May 16 '10 at 7:09

The fact that EVERYTHING is an object, and as such is extensible. I can add member variables as metadata to a function that I define:

>>> def addInts(x,y): 
...    return x + y
>>> addInts.params = ['integer','integer']
>>> addInts.returnType = 'integer'

This can be very useful for writing dynamic unit tests, e.g.

Most things are objects; and some objects do not take property assignments so happily. – user166390 Oct 21 '09 at 19:02

Simple way to test if a key is in a dict:

>>> 'key' in { 'key' : 1 }

>>> d = dict(key=1, key2=2)
>>> if 'key' in d:
...     print 'Yup'
This is hopefully not hidden for any non-new Python coder! – u0b34a0f6ae Feb 15 '10 at 12:10
** Using sets to reference contents in sets of frozensets**

As you probably know, sets are mutable and thus not hashable, so it's necessary to use frozensets if you want to make a set of sets (or use sets as dictionary keys):

>>> fabc = frozenset('abc')
>>> fxyz = frozenset('xyz')
>>> mset = set((fabc, fxyz))
>>> mset
{frozenset({'a', 'c', 'b'}), frozenset({'y', 'x', 'z'})}

However, it's possible to test for membership and remove/discard members using just ordinary sets:

>>> abc = set('abc')
>>> abc in mset
>>> mset.remove(abc)
>>> mset
{frozenset({'y', 'x', 'z'})}

To quote from the Python Standard Library docs:

Note, the elem argument to the __contains__(), remove(), and discard() methods may be a set. To support searching for an equivalent frozenset, the elem set is temporarily mutated during the search and then restored. During the search, the elem set should not be read or mutated since it does not have a meaningful value.

Unfortunately, and perhaps astonishingly, the same is not true of dictionaries:

>>> mdict = {fabc:1, fxyz:2}
>>> fabc in mdict
>>> abc in mdict
Traceback (most recent call last):
File "<interactive input>", line 1, in <module>
TypeError: unhashable type: 'set'

Python has "private" variables

Variables that start, but not end, with a double underscore become private, and not just by convention. Actually __var turns into _Classname__var, where Classname is the class in which the variable was created. They are not inherited and cannot be overriden.

>>> class A:
...     def __init__(self):
...             self.__var = 5
...     def getvar(self):
...             return self.__var
>>> a = A()
>>> a.__var
Traceback (most recent call last):
  File "", line 1, in 
AttributeError: A instance has no attribute '__var'
>>> a.getvar()
>>> dir(a)
['_A__var', '__doc__', '__init__', '__module__', 'getvar']
umm... not quite "real private variables". Nothing stops you from accessing _A__var... – Jake Feb 22 '11 at 22:18
In C++, it's a limitation of how the language addresses memory. If you want to risk crashing your program or inducing someone less familiar with the code to do so, that can't be prevented without breaking the C-language compatibility. Python's "member name mangling" isn't intended for use as a private variable mechanism. It's intended for public members which need to opt out of the normal inheritance/override rules. Calling it "private variable support" because one popular language is unable to offer full variable isolation only devalues the concept. – ssokolow Feb 23 '11 at 2:26

while not very pythonic you can write to a file using print

print>>outFile, 'I am Being Written'


This form is sometimes referred to as “print chevron.” In this form, the first expression after the >> must evaluate to a “file-like” object, specifically an object that has a write() method as described above. With this extended form, the subsequent expressions are printed to this file object. If the first expression evaluates to None, then sys.stdout is used as the file for output.

This syntax saw some updating in Python 3, so you can now do print('I am being writtten', file=outFile). I was just reading about the changes. So now it actually is much more pythonic. – shadowland Oct 25 '11 at 17:28

Print multiline strings one screenful at a time

Not really useful feature hidden in the site._Printer class, whose the license object is an instance. The latter, when called, prints the Python license. One can create another object of the same type, passing a string -- e.g. the content of a file -- as the second argument, and call it:


That would print the file content splitted by a certain number of lines at a time:

file row 21
file row 22
file row 23

Hit Return for more, or q (and Return) to quit:

If you use exec in a function the variable lookup rules change drastically. Closures are no longer possible but Python allows arbitrary identifiers in the function. This gives you a "modifiable locals()" and can be used to star-import identifiers. On the downside it makes every lookup slower because the variables end up in a dict rather than slots in the frame:

>>> def f():
...  exec "a = 42"
...  return a
>>> def g():
...  a = 42
...  return a
>>> import dis
>>> dis.dis(f)
  2           0 LOAD_CONST               1 ('a = 42')
              3 LOAD_CONST               0 (None)
              6 DUP_TOP             
              7 EXEC_STMT           

  3           8 LOAD_NAME                0 (a)
             11 RETURN_VALUE        
>>> dis.dis(g)
  2           0 LOAD_CONST               1 (42)
              3 STORE_FAST               0 (a)

  3           6 LOAD_FAST                0 (a)
              9 RETURN_VALUE
Just to nitpick: that only applies to bare exec. If you specify the namespace for it to use, eg "d={}; exec "a=42" in d" this won't happen. – Brian Sep 21 '08 at 22:48

The spam module in standard Python

It is used for testing purposes.

I've picked it from ctypes tutorial. Try it yourself:

>>> import __hello__
Hello world...
>>> type(__hello__)
<type 'module'>
>>> from __phello__ import spam
Hello world...
Hello world...
>>> type(spam)
<type 'module'>
>>> help(spam)
Help on module __phello__.spam in __phello__:


sorry, why and how would you use this? – cmcginty Jul 20 '09 at 21:50
Your example is unclear. – Mikel Jan 24 '11 at 3:56

Memory Management

Python dynamically allocates memory and uses garbage collection to recover unused space. Once an object is out of scope, and no other variables reference it, it will be recovered. I do not have to worry about buffer overruns and slowly growing server processes. Memory management is also a feature of other dynamic languages but Python just does it so well.

Of course, we must watch out for circular references and keeping references to objects which are no longer needed, but weak references help a lot here.


Classes as first-class objects (shown through a dynamic class definition)

Note the use of the closure as well. If this particular example looks like a "right" approach to a problem, carefully reconsider ... several times :)

def makeMeANewClass(parent, value):
  class IAmAnObjectToo(parent):
    def theValue(self):
      return value
  return IAmAnObjectToo

Klass = makeMeANewClass(str, "fred")
o = Klass()
print isinstance(o, str)  # => True
print o.theValue()        # => fred

Regarding Nick Johnson's implementation of a Property class (just a demonstration of descriptors, of course, not a replacement for the built-in), I'd include a setter that raises an AttributeError:

class Property(object):
    def __init__(self, fget):
        self.fget = fget

    def __get__(self, obj, type):
        if obj is None:
            return self
        return self.fget(obj)

    def __set__(self, obj, value):
       raise AttributeError, 'Read-only attribute'

Including the setter makes this a data descriptor as opposed to a method/non-data descriptor. A data descriptor has precedence over instance dictionaries. Now an instance can't have a different object assigned to the property name, and attempts to assign to the property will raise an attribute error.


Not at all a hidden feature but still nice:

import os.path as op

root_dir = op.abspath(op.join(op.dirname(__file__), ".."))

Saves lots of characters when manipulating paths !


Ever used xrange(INT) instead of range(INT) .... It's got less memory usage and doesn't really depend on the size of the integer. Yey!! Isn't that good?

In Python 3, both are the same. – Wok May 27 '11 at 17:12

Not really a hidden feature but something that might come in handy.

for looping through items in a list pairwise

for x, y in zip(s, s[1:]):

The getattr built-in function :

>>> class C():
    def getMontys(self):
        self.montys = ['Cleese','Palin','Idle','Gilliam','Jones','Chapman']
        return self.montys

>>> c = C()
>>> getattr(c,'getMontys')()
['Cleese', 'Palin', 'Idle', 'Gilliam', 'Jones', 'Chapman']

Useful if you want to dispatch function depending on the context. See examples in Dive Into Python (Here)

>>> x=[1,1,2,'a','a',3]
>>> y = [ _x for _x in x if not _x in locals()['_[1]'] ]
>>> y
[1, 2, 'a', 3]

"locals()['_[1]']" is the "secret name" of the list being created. Very useful when state of list being built affects subsequent build decisions.

Ew. This 'name' of the result list depends on too many factors to really consider it more than abuse of a specific implementation (and specific to a particular version, to boot.) On top of that it's an O(n^2) algorithm. Yuck. – Thomas Wouters Sep 19 '08 at 13:31
Well, at least no one will claim this one isn't hidden. – I. J. Kennedy Oct 12 '10 at 22:35

mapreduce using map and reduce functions

create a simple sumproduct this way:

def sumprod(x,y):
    return reduce(lambda a,b:a+b, map(lambda a, b: a*b,x,y))


In [2]: sumprod([1,2,3],[4,5,6])
Out[2]: 32

Not a programming feature but is useful when using Python with bash or shell scripts.

python -c"import os; print(os.getcwd());"

See the python documentation here. Additional things to note when writing longer Python scripts can be seen in this discussion.


Python's positional and keyword expansions can be used on the fly, not just from a stored list.

l=lambda x,y,z:x+y+z
print l(*a)
print l(*[a[0],2,3])

It is usually more useful with things like this:


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