Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

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:

share

locked by Bill the Lizard Mar 9 '12 at 23:54

This question exists because it has historical significance, but it is not considered a good, on-topic question for this site, so please do not use it as evidence that you can ask similar questions here. This question and its answers are frozen and cannot be changed. More info: help center.

closed as not constructive by David, Cody Gray, casperOne Feb 20 '12 at 20:09

As it currently stands, this question is not a good fit for our Q&A format. We expect answers to be supported by facts, references, or expertise, but this question will likely solicit debate, arguments, polling, or extended discussion. If you feel that this question can be improved and possibly reopened, visit the help center for guidance.If this question can be reworded to fit the rules in the help center, please edit the question.

191 Answers 191

A slight misfeature of python. The normal fast way to join a list of strings together is,

''.join(list_of_strings)
share
20  
there are very good reasons that this is a method of string instead of a method of list. this allows the same function to join any iterable, instead of duplicating join for every iterable type. –  Christian Oudard Jan 2 '09 at 18:37
10  
If this is too ugly for you to cope with, you can write the very same thing as str.join('',list_of_strings) but other pythonistas may scorn you for trying to write java. –  IfLoop Nov 17 '09 at 19:04

Creating enums

In Python, you can do this to quickly create an enumeration:

>>> FOO, BAR, BAZ = range(3)
>>> FOO
0

But the "enums" don't have to have integer values. You can even do this:

class Colors(object):
    RED, GREEN, BLUE, YELLOW = (255,0,0), (0,255,0), (0,0,255), (0,255,255)

#now Colors.RED is a 3-tuple that returns the 24-bit 8bpp RGB 
#value for saturated red
share

The Object Data Model

You can override any operator in the language for your own classes. See this page for a complete list. Some examples:

  • You can override any operator (* + - / // % ^ == < > <= >= . etc.). All this is done by overriding __mul__, __add__, etc. in your objects. You can even override things like __rmul__ to handle separately your_object*something_else and something_else*your_object. . is attribute access (a.b), and can be overridden to handle any arbitrary b by using __getattr__. Also included here is a(…) using __call__.

  • You can create your own slice syntax (a[stuff]), which can be very complicated and quite different from the standard syntax used in lists (numpy has a good example of the power of this in their arrays) using any combination of ,, :, and that you like, using Slice objects.

  • Handle specially what happens with many keywords in the language. Included are del, in, import, and not.

  • Handle what happens when many built in functions are called with your object. The standard __int__, __str__, etc. go here, but so do __len__, __reversed__, __abs__, and the three argument __pow__ (for modular exponentiation).

share

"Unpacking" to function parameters

def foo(a, b, c):
        print a, b, c

bar = (3, 14, 15)
foo(*bar)

When executed prints:

3 14 15
share
1  
This is the canonical alternative to the old "apply()" built-in. –  Jim Dennis Jun 25 '10 at 23:11

The reversed() builtin. It makes iterating much cleaner in many cases.

quick example:

for i in reversed([1, 2, 3]):
    print(i)

produces:

3
2
1

However, reversed() also works with arbitrary iterators, such as lines in a file, or generator expressions.

share

The Zen of Python

>>> import this
The Zen of Python, by Tim Peters

Beautiful is better than ugly.
Explicit is better than implicit.
Simple is better than complex.
Complex is better than complicated.
Flat is better than nested.
Sparse is better than dense.
Readability counts.
Special cases aren't special enough to break the rules.
Although practicality beats purity.
Errors should never pass silently.
Unless explicitly silenced.
In the face of ambiguity, refuse the temptation to guess.
There should be one-- and preferably only one --obvious way to do it.
Although that way may not be obvious at first unless you're Dutch.
Now is better than never.
Although never is often better than *right* now.
If the implementation is hard to explain, it's a bad idea.
If the implementation is easy to explain, it may be a good idea.
Namespaces are one honking great idea -- let's do more of those!
share

Changing function label at run time:

>>> class foo:
...   def normal_call(self): print "normal_call"
...   def call(self): 
...     print "first_call"
...     self.call = self.normal_call

>>> y = foo()
>>> y.call()
first_call
>>> y.call()
normal_call
>>> y.call()
normal_call
...
share

string-escape and unicode-escape encodings

Lets say you have a string from outer source, that contains \n, \t and so on. How to transform them into new-line or tab? Just decode string using string-escape encoding!

>>> print s
Hello\nStack\toverflow
>>> print s.decode('string-escape')
Hello
Stack   overflow

Another problem. You have normal string with unicode literals like \u01245. How to make it work? Just decode string using unicode-escape encoding!

>>> s = '\u041f\u0440\u0438\u0432\u0456\u0442, \u0441\u0432\u0456\u0442!'
>>> print s
\u041f\u0440\u0438\u0432\u0456\u0442, \u0441\u0432\u0456\u0442!
>>> print unicode(s)
\u041f\u0440\u0438\u0432\u0456\u0442, \u0441\u0432\u0456\u0442!
>>> print unicode(s, 'unicode-escape')
Привіт, світ!
share

unzip un-needed in Python

Someone blogged about Python not having an unzip function to go with zip(). unzip is straight-forward to calculate because:

>>> t1 = (0,1,2,3)
>>> t2 = (7,6,5,4)
>>> [t1,t2] == zip(*zip(t1,t2))
True

On reflection though, I'd rather have an explicit unzip().

share
8  
def unzip(x): return zip(*x) Done! –  bukzor Jun 27 '10 at 17:07

Creating dictionary of two sequences that have related data

In [15]: t1 = (1, 2, 3)

In [16]: t2 = (4, 5, 6)

In [17]: dict (zip(t1,t2))
Out[17]: {1: 4, 2: 5, 3: 6}
share

Top Secret Attributes

>>> class A(object): pass
>>> a = A()
>>> setattr(a, "can't touch this", 123)
>>> dir(a)
['__class__', '__delattr__', '__dict__', '__doc__', '__format__', '__getattribute__', '__hash__', '__init__', '__module__', '__new__', '__reduce__', '__reduce_ex__', '__repr__', '__setattr__', '__sizeof__', '__str__', '__subclasshook__', '__weakref__', "can't touch this"]
>>> a.can't touch this # duh
  File "<stdin>", line 1
    a.can't touch this
                     ^
SyntaxError: EOL while scanning string literal
>>> getattr(a, "can't touch this")
123
>>> setattr(a, "__class__.__name__", ":O")
>>> a.__class__.__name__
'A'
>>> getattr(a, "__class__.__name__")
':O'
share
6  
AHHHH! Bad, bad, bad! –  asmeurer Dec 28 '10 at 6:03

namedtuple is a tuple

>>> node = namedtuple('node', "a b")
>>> node(1,2) + node(5,6)
(1, 2, 5, 6)
>>> (node(1,2), node(5,6))
(node(a=1, b=2), node(a=5, b=6))
>>> 

Some more experiments to respond to comments:

>>> from collections import namedtuple
>>> from operator import *
>>> mytuple = namedtuple('A', "a b")
>>> yourtuple = namedtuple('Z', "x y")
>>> mytuple(1,2) + yourtuple(5,6)
(1, 2, 5, 6)
>>> q = [mytuple(1,2), yourtuple(5,6)]
>>> q
[A(a=1, b=2), Z(x=5, y=6)]
>>> reduce(operator.__add__, q)
(1, 2, 5, 6)

So, namedtuple is an interesting subtype of tuple.

share
5  
Also fun is that you can feed the result of a namedtuple call directly into a class definition, as in class rectangle(namedtuple("rectangle", "width height")): in order to add custom methods –  Ben Blank Jan 10 '11 at 19:29

Dynamically added attributes

This might be useful if you think about adding some attributes to your classes just by calling them. This can be done by overriding the __getattribute__ member function which is called when the dot operand is used. So, let's see a dummy class for example:

class Dummy(object):
    def __getattribute__(self, name):
        f = lambda: 'Hello with %s'%name
        return f

When you instantiate a Dummy object and do a method call you’ll get the following:

>>> d = Dummy()
>>> d.b()
'Hello with b'

Finally, you can even set the attribute to your class so it can be dynamically defined. This could be useful if you work with Python web frameworks and want to do queries by parsing the attribute's name.

I have a gist at github with this simple code and its equivalent on Ruby made by a friend.

Take care!

share

Flattening a list with sum().

The sum() built-in function can be used to __add__ lists together, providing a handy way to flatten a list of lists:

Python 2.7.1 (r271:86832, May 27 2011, 21:41:45) 
[GCC 4.2.1 (Apple Inc. build 5664)] on darwin
Type "help", "copyright", "credits" or "license" for more information.
>>> l = [[1, 2, 3], [4, 5], [6], [7, 8, 9]]
>>> sum(l, [])
[1, 2, 3, 4, 5, 6, 7, 8, 9]
share

The Borg Pattern

This is a killer from Alex Martelli. All instances of Borg share state. This removes the need to employ the singleton pattern (instances don't matter when state is shared) and is rather elegant (but is more complicated with new classes).

The value of foo can be reassigned in any instance and all will be updated, you can even reassign the entire dict. Borg is the perfect name, read more here.

class Borg:
    __shared_state = {'foo': 'bar'}
    def __init__(self):
        self.__dict__ = self.__shared_state
    # rest of your class here

This is perfect for sharing an eventlet.GreenPool to control concurrency.

share

pdb — The Python Debugger

As a programmer, one of the first things that you need for serious program development is a debugger. Python has one built-in which is available as a module called pdb (for "Python DeBugger", naturally!).

http://docs.python.org/library/pdb.html

share

threading.enumerate() gives access to all Thread objects in the system and sys._current_frames() returns the current stack frames of all threads in the system, so combine these two and you get Java style stack dumps:

def dumpstacks(signal, frame):
    id2name = dict([(th.ident, th.name) for th in threading.enumerate()])
    code = []
    for threadId, stack in sys._current_frames().items():
        code.append("\n# Thread: %s(%d)" % (id2name[threadId], threadId))
        for filename, lineno, name, line in traceback.extract_stack(stack):
            code.append('File: "%s", line %d, in %s' % (filename, lineno, name))
            if line:
                code.append("  %s" % (line.strip()))
    print "\n".join(code)

import signal
signal.signal(signal.SIGQUIT, dumpstacks)

Do this at the beginning of a multi-threaded python program and you get access to current state of threads at any time by sending a SIGQUIT. You may also choose signal.SIGUSR1 or signal.SIGUSR2.

See

share

inspect module is also a cool feature.

share

Reloading modules enables a "live-coding" style. But class instances don't update. Here's why, and how to get around it. Remember, everything, yes, everything is an object.

>>> from a_package import a_module
>>> cls = a_module.SomeClass
>>> obj = cls()
>>> obj.method()
(old method output)

Now you change the method in a_module.py and want to update your object.

>>> reload(a_module)
>>> a_module.SomeClass is cls
False # Because it just got freshly created by reload.
>>> obj.method()
(old method output)

Here's one way to update it (but consider it running with scissors):

>>> obj.__class__ is cls
True # it's the old class object
>>> obj.__class__ = a_module.SomeClass # pick up the new class
>>> obj.method()
(new method output)

This is "running with scissors" because the object's internal state may be different than what the new class expects. This works for really simple cases, but beyond that, pickle is your friend. It's still helpful to understand why this works, though.

share
1  
+1 for suggesting pickle (or cPickle). It was really helpful for me, some weeks ago. –  Denilson Sá Aug 20 '10 at 20:51

Backslashes inside raw strings can still escape quotes. See this:

>>> print repr(r"aaa\"bbb")
'aaa\\"bbb'

Note that both the backslash and the double-quote are present in the final string.

As consequence, you can't end a raw string with a backslash:

>>> print repr(r"C:\")
SyntaxError: EOL while scanning string literal
>>> print repr(r"C:\"")
'C:\\"'

This happens because raw strings were implemented to help writing regular expressions, and not to write Windows paths. Read a long discussion about this at Gotcha — backslashes in Windows filenames.

share
2  
Note that the backslash is still part of the string afterwards... So one might not regard this as regular escaping. –  huin Aug 21 '10 at 7:18

Operators can be called as functions:

from operator import add
print reduce(add, [1,2,3,4,5,6])
share

infinite recursion in list

>>> a = [1,2]
>>> a.append(a)
>>> a
[1, 2, [...]]
>>> a[2]
[1, 2, [...]]
>>> a[2][2][2][2][2][2][2][2][2] == a
True
share

...that dict.get() has a default value of None, thereby avoiding KeyErrors:

In [1]: test = { 1 : 'a' }

In [2]: test[2]
---------------------------------------------------------------------------
<type 'exceptions.KeyError'>              Traceback (most recent call last)

&lt;ipython console&gt; in <module>()

<type 'exceptions.KeyError'>: 2

In [3]: test.get( 2 )

In [4]: test.get( 1 )
Out[4]: 'a'

In [5]: test.get( 2 ) == None
Out[5]: True

and even to specify this 'at the scene':

In [6]: test.get( 2, 'Some' ) == 'Some'
Out[6]: True

And you can use setdefault() to have a value set and returned if it doesn't exist:

>>> a = {}
>>> b = a.setdefault('foo', 'bar')
>>> a
{'foo': 'bar'}
>>> b
'bar
share

Builtin methods or functions don't implement the descriptor protocol which makes it impossible to do stuff like this:

>>> class C(object):
...  id = id
... 
>>> C().id()
Traceback (most recent call last):
  File "<stdin>", line 1, in <module>
TypeError: id() takes exactly one argument (0 given)

However you can create a small bind descriptor that makes this possible:

>>> from types import MethodType
>>> class bind(object):
...  def __init__(self, callable):
...   self.callable = callable
...  def __get__(self, obj, type=None):
...   if obj is None:
...    return self
...   return MethodType(self.callable, obj, type)
... 
>>> class C(object):
...  id = bind(id)
... 
>>> C().id()
7414064
share
1  
It's simpler and easier to do this as a property, in this case: class C(object): id = property(id) –  Piet Delport Oct 2 '10 at 22:56

Nested Function Parameter Re-binding

def create_printers(n):
    for i in xrange(n):
        def printer(i=i): # Doesn't work without the i=i
            print i
        yield printer
share
1  
I think what @kaizer.se is saying is that when you omit the i=i the i in the printer function references the i from the for loop rather than the local i that is created when a new printer function is created with the i=i keyword arg. So it still does work (it yields functions, each with access to a closure) but it doesn't work in the way you'd expect without explicitly creating a local variable. –  Sean Vieira Mar 9 '11 at 22:57

You can override the mro of a class with a metaclass

>>> class A(object):
...     def a_method(self):
...         print("A")
... 
>>> class B(object):
...     def b_method(self):
...         print("B")
... 
>>> class MROMagicMeta(type):
...     def mro(cls):
...         return (cls, B, object)
... 
>>> class C(A, metaclass=MROMagicMeta):
...     def c_method(self):
...         print("C")
... 
>>> cls = C()
>>> cls.c_method()
C
>>> cls.a_method()
Traceback (most recent call last):
 File "<stdin>", line 1, in <module>
AttributeError: 'C' object has no attribute 'a_method'
>>> cls.b_method()
B
>>> type(cls).__bases__
(<class '__main__.A'>,)
>>> type(cls).__mro__
(<class '__main__.C'>, <class '__main__.B'>, <class 'object'>)

It's probably hidden for a good reason. :)

share
2  
That's playing with fire, and asking for ethernal damnation. Better have good reason ;) –  gorsky Dec 18 '09 at 10:20

Objects of small intgers (-5 .. 256) never created twice:


>>> a1 = -5; b1 = 256
>>> a2 = -5; b2 = 256
>>> id(a1) == id(a2), id(b1) == id(b2)
(True, True)
>>>
>>> c1 = -6; d1 = 257
>>> c2 = -6; d2 = 257
>>> id(c1) == id(c2), id(d1) == id(d2)
(False, False)
>>>

Edit: List objects never destroyed (only objects in lists). Python has array in which it keeps up to 80 empty lists. When you destroy list object - python puts it to that array and when you create new list - python gets last puted list from this array:


>>> a = [1,2,3]; a_id = id(a)
>>> b = [1,2,3]; b_id = id(b)
>>> del a; del b
>>> c = [1,2,3]; id(c) == b_id
True
>>> d = [1,2,3]; id(d) == a_id
True
>>>

share
5  
This feature is implementation dependent, so you shouldn't rely on it. –  Denis Otkidach Oct 27 '09 at 15:36

You can decorate functions with classes - replacing the function with a class instance:

class countCalls(object):
    """ decorator replaces a function with a "countCalls" instance
    which behaves like the original function, but keeps track of calls

    >>> @countCalls
    ... def doNothing():
    ...     pass
    >>> doNothing()
    >>> doNothing()
    >>> print doNothing.timesCalled
    2
    """
    def __init__ (self, functionToTrack):
        self.functionToTrack = functionToTrack
        self.timesCalled = 0
    def __call__ (self, *args, **kwargs):
        self.timesCalled += 1
        return self.functionToTrack(*args, **kwargs)
share

Manipulating Recursion Limit

Getting or setting the maximum depth of recursion with sys.getrecursionlimit() & sys.setrecursionlimit().

We can limit it to prevent a stack overflow caused by infinite recursion.

share

Not the answer you're looking for? Browse other questions tagged or ask your own question.