Question

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 bold title as the first line

Answer 1

Not an out-of-the-box feature, but Pyrex is incredibly useful.

Answer 2

Get the python regex parse tree to debug your regex

Regular expression are a great feature of python, but debugging them can be a pain, and it's just too easy to get a regex wrong.

Fortunately, python have a really hidden feature to print the regex parse tree, by passing the undocumented, experimental, hidden flag re.DEBUG (actually, 128) to re.compile

>>> re.compile("^\[font(?:=(?P<size>[-+][0-9]{1,2}))?\](.*?)[/font]",
    re.DEBUG)
at at_beginning
literal 91
literal 102
literal 111
literal 110
literal 116
max_repeat 0 1
  subpattern None
    literal 61
    subpattern 1
      in
        literal 45
        literal 43
      max_repeat 1 2
        in
          range (48, 57)
literal 93
subpattern 2
  min_repeat 0 65535
    any None
in
  literal 47
  literal 102
  literal 111
  literal 110
  literal 116

Once you understand the syntax, you can spot your errors. There we can see that i forgot to escape the [] in [/font].

Of course you can combine it with whatever flags you want, like commented regexes :

>>> re.compile("""
 ^              # start of a line
 \[font         # the font tag
 (?:=(?P<size>  # optional [font=+size]
 [-+][0-9]{1,2} # size specification
 ))?
 \]             # end of tag
 (.*?)          # text beetween the tags
 \[/font\]      # end of the tag
 """, re.DEBUG+re.VERBOSE+re.DOTALL)

Answer 3

Built-in base64, zlib, and rot13 codecs

Strings have encode and decode methods. Usually this is used for converting str to unicode and vice versa, e.g. with u = s.encode('utf8'). But there are some other handy builtin codecs. Compression and decompression with zlib (and bz2) is available without an explicit import:

>>> s = 'a' * 100
>>> s.encode('zlib')
'x\x9cKL\xa4=\x00\x00zG%\xe5'

Similarly you can encode and decode base64:

>>> 'Hello world'.encode('base64')
'SGVsbG8gd29ybGQ=\n'
>>> 'SGVsbG8gd29ybGQ=\n'.decode('base64')
'Hello world'

And, of course, you can rot13:

>>> 'Secret message'.encode('rot13')
'Frperg zrffntr'

Answer 4

Obviously, the antigravity module. xkcd #353

Answer 5

Generators

I think that a lot of beginning Python developers pass over generators without really grasping what they're for or getting any sense of their power. It wasn't until I read David M. Beazley's PyCon presentation on generators (it's available here) that I realized how useful (essential, really) they are. That presentation illuminated what was for me an entirely new way of programming, and I recommend it to anyone who doesn't have a deep understanding of generators.

Answer 6

Interactive Interpreter Tab Completion

try:
    import readline
except ImportError:
    print "Unable to load readline module."
else:
    import rlcompleter
    readline.parse_and_bind("tab: complete")


>>> class myclass:
...    def function(self):
...       print "my function"
... 
>>> class_instance = myclass()
>>> class_instance.<TAB>
class_instance.__class__   class_instance.__module__
class_instance.__doc__     class_instance.function
>>> class_instance.f<TAB>unction()

You will also have to set a PYTHONSTARTUP environment variable.

Answer 7

Python has GOTO

...and it's implemented by external pure-Python module :)

from goto import goto, label
for i in range(1, 10):
    for j in range(1, 20):
        for k in range(1, 30):
            print i, j, k
            if k == 3:
                goto .end # breaking out from a deeply nested loop
label .end
print "Finished"

Answer 8

Taking advantage of python's dynamic nature to have an apps config files in python syntax. For example if you had the following in a config file:

{
  "name1": "value1",
  "name2": "value2"
}

Then you could trivially read it like:

config = eval(open("filename").read())

Answer 9

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

Answer 10

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

''.join(list_of_strings)

Answer 11

import antigravity

Answer 12

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 "
      privateMethod('foo')

    self.privilegedMethod = privilegedMethod

  def publicMethod(self):
    print self.publicData

And here's a contrived example of its use:

>>> obj = MyClass()
>>> obj.publicMethod()
123
>>> obj.publicData = 'World'
>>> obj.publicMethod()
World
>>> 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.

Answer 13

Using keyword arguments as assignments

Sometimes one wants to build a range of functions depending on one or more parameters. However this might easily lead to closures all referring to the same object and value:

funcs = [] 
for k in range(10):
     funcs.append( lambda: k)

>>> funcs[0]()
9
>>> funcs[7]()
9

This behaviour can be avoided by turning the lambda expression into a function depending only on its arguments. A keyword parameter stores the current value that is bound to it. The function call doesn't have to be altered:

funcs = [] 
for k in range(10):
     funcs.append( lambda k = k: k)

>>> funcs[0]()
0
>>> funcs[7]()
7

Answer 14

Method replacement for object instance

You can replace methods of already created object instances. It allows you to create object instance with different (exceptional) functionality:

>>> class C(object):
...     def fun(self):
...         print "C.a", self
...
>>> inst = C()
>>> inst.fun()  # C.a method is executed
C.a <__main__.C object at 0x00AE74D0>
>>> instancemethod = type(C.fun)
>>>
>>> def fun2(self):
...     print "fun2", self
...
>>> inst.fun = instancemethod(fun2, inst, C)  # Now we are replace C.a by fun2
>>> inst.fun()  # ... and fun2 is executed
fun2 <__main__.C object at 0x00AE74D0>

As we can C.a was replaced by fun2() in inst instance (self didn't change).

Alternatively we may use new module, but it's depreciated since Python 2.6:

>>> def fun3(self):
...     print "fun3", self
...
>>> import new
>>> inst.fun = new.instancemethod(fun3, inst, C)
>>> inst.fun()
fun3 <__main__.C object at 0x00AE74D0>

Node: This solution shouldn't be used as general replacement of inheritance mechanism! But it may be very handy in some specific situations (debugging, mocking).

Warning: This solution will not work for built-in types and for new style classes using slots.

Answer 15

Referencing a list comprehension as it is being built...

You can reference a list comprehension as it is being built by the symbol '_[1]'. For example, the following function unique-ifies a list of elements without changing their order by referencing its list comprehension.

def unique(my_list):
    return [x for x in my_list if x not in locals()['_[1]']]

Answer 16

set/frozenset

Probably an easily overlooked python builtin is "set/frozenset".

Useful when you have a list like this, [1,2,1,1,2,3,4] and only want the uniques like this [1,2,3,4].

Using set() that's exactly what you get:

>>> x = [1,2,1,1,2,3,4] 
>>> 
>>> set(x) 
set([1, 2, 3, 4]) 
>>>
>>> for i in set(x):
...     print i
...
1
2
3
4

And of course to get the number of uniques in a list:

>>> len(set([1,2,1,1,2,3,4]))
4

You can also find if a list is a subset of another list using, suprise, set().isasubset()

>>> set([1,2,3,4]).isasubset([0,1,2,3,4,5])
True

For more details: http://docs.python.org/library/stdtypes.html#set

Answer 17

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.

Answer 18

While debugging complex data structures pprint module comes handy.

Quoting from the docs..

>>> import pprint    
>>> stuff = sys.path[:]
>>> stuff.insert(0, stuff)
>>> pprint.pprint(stuff)
[<Recursion on list with id=869440>,
 '',
 '/usr/local/lib/python1.5',
 '/usr/local/lib/python1.5/test',
 '/usr/local/lib/python1.5/sunos5',
 '/usr/local/lib/python1.5/sharedmodules',
 '/usr/local/lib/python1.5/tkinter']

Answer 19

>>> from functools import partial
>>> bound_func = partial(range, 0, 10)
>>> bound_func()
[0, 1, 2, 3, 4, 5, 6, 7, 8, 9]
>>> bound_func(2)
[0, 2, 4, 6, 8]

not really a hidden feature but partial is extremely useful for having late evaluation of functions.

you can bind as many or as few parameters in the initial call to partial as you want, and call it with any remaining parameters later (in this example i've bound the begin/end args to range, but call it the second time with a step arg)

Answer 20

is_ok() and "Yes" or "No"

Answer 21

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

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

In [2]: test[2]
---------------------------------------------------------------------------
              Traceback (most recent call last)

<ipython console> in ()

: 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

Answer 22

You can easily transpose an array with zip.

a = [(1,2), (3,4)]
zip(*a)

Answer 23

Negative round

The round() function rounds a float number to given precision in decimal digits, but precision can be negative:

>>> str(round(1234.5678, -2))
'1200.0'
>>> str(round(1234.5678, 2))
'1234.57'

Note: round() always returns a float, str() used in the above example because floating point math is inexact, and under 2.x the second example can print as 1234.5700000000001. Also see the decimal module.

Answer 24

An interpreter within the interpreter

The standard library's code module let's you include your own read-eval-print loop inside a program, or run a whole nested interpreter. E.g. (copied my example from here)

$ python
Python 2.5.1 (r251:54863, Jan 17 2008, 19:35:17) 
[GCC 4.0.1 (Apple Inc. build 5465)] on darwin
Type "help", "copyright", "credits" or "license" for more information.
>>> shared_var = "Set in main console"
>>> import code
>>> ic = code.InteractiveConsole({ 'shared_var': shared_var })
>>> try:
...     ic.interact("My custom console banner!")
... except SystemExit, e:
...     print "Got SystemExit!"
... 
My custom console banner!
>>> shared_var
'Set in main console'
>>> shared_var = "Set in sub-console"
>>> sys.exit()
Got SystemExit!
>>> shared_var
'Set in main console'

This is extremely useful for situations where you want to accept scripted input from the user, or query the state of the VM in real-time.

TurboGears uses this to great effect by having a WebConsole from which you can query the state of you live web app.

Answer 25

Operator overloading for the set builtin:

>>> a = set([1,2,3,4])
>>> b = set([3,4,5,6])
>>> a | b # Union
{1, 2, 3, 4, 5, 6}
>>> a & b # Intersection
{3, 4}
>>> a < b # Subset
False
>>> a - b # Difference
{1, 2}
>>> a ^ b # Symmetric Difference
{1, 2, 5, 6}

More detail from the standard library reference: Set Types

Answer 26

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. :)

Answer 27

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.

Answer 28

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!

Answer 29

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

Answer 30

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
>>>