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Python 2.x gotcha’s and landmines

Today I was bitten again by mutable default arguments after many years. I usually don't use mutable default arguments unless needed, but I think with time I forgot about that. Today in the application I added tocElements=[] in a PDF generation function's argument list and now "Table of Contents" gets longer and longer after each invocation of "generate pdf". :)

What else should I add to my list of things to MUST avoid?

  • Always import modules the same way, e.g. from y import x and import x are treated as different modules.

  • Do not use range in place of lists because range() will become an iterator anyway, the following will fail:

    myIndexList = [0, 1, 3]
    isListSorted = myIndexList == range(3)  # will fail in 3.0
    isListSorted = myIndexList == list(range(3))  # will not
    

    Same thing can be mistakenly done with xrange:

    myIndexList == xrange(3)
    
  • Be careful catching multiple exception types:

    try:
        raise KeyError("hmm bug")
    except KeyError, TypeError:
        print TypeError
    

    This prints "hmm bug", though it is not a bug; it looks like we are catching exceptions of both types, but instead we are catching KeyError only as variable TypeError, use this instead:

    try:
        raise KeyError("hmm bug")
    except (KeyError, TypeError):
        print TypeError
    
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marked as duplicate by Donal Fellows, voyager, Brian, danben, Graviton Aug 1 '10 at 2:38

This question has been asked before and already has an answer. If those answers do not fully address your question, please ask a new question.

1  
stackoverflow.com/questions/530530/… - isn't this question the original one? –  zeroDivisible Jul 16 '09 at 5:22
3  
Do use range() as a list in Python 2.x. It is a job for 2to3 script to convert it to list(range()) in Python 3.x –  J.F. Sebastian May 2 '10 at 16:55
3  
@Narek: What is a "normal" programming language? –  voyager Jul 27 '10 at 21:27
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35 Answers 35

Don't use index to loop over a sequence

Don't :

for i in range(len(tab)) :
    print tab[i]

Do :

for elem in tab :
    print elem

For will automate most iteration operations for you.

Use enumerate if you really need both the index and the element.

for i, elem in enumerate(tab):
     print i, elem

Be careful when using "==" to check against True or False

if (var == True) :
    # this will execute if var is True or 1, 1.0, 1L

if (var != True) :
    # this will execute if var is neither True nor 1

if (var == False) :
    # this will execute if var is False or 0 (or 0.0, 0L, 0j)

if (var == None) :
    # only execute if var is None

if var :
    # execute if var is a non-empty string/list/dictionary/tuple, non-0, etc

if not var :
    # execute if var is "", {}, [], (), 0, None, etc.

if var is True :
    # only execute if var is boolean True, not 1

if var is False :
    # only execute if var is boolean False, not 0

if var is None :
    # same as var == None

Do not check if you can, just do it and handle the error

Pythonistas usually say "It's easier to ask for forgiveness than permission".

Don't :

if os.path.isfile(file_path) :
    file = open(file_path)
else :
    # do something

Do :

try :
    file =  open(file_path)
except OSError as e:
    # do something

Or even better with python 2.6 / 3:

with open(file_path) as file :

It is much better because it's much more generical. You can apply "try / except" to almost anything. You don't need to care about what to do to prevent it, just about the error you are risking.

Do not check against type

Python is dynamically typed, therefore checking for type makes you lose flexibility. Instead, use duck typing by checking behavior. E.G, you expect a string in a function, then use str() to convert any object in a string. You expect a list, use list() to convert any iterable in a list.

Don't :

def foo(name) :
    if isinstance(name, str) :
        print name.lower()

def bar(listing) :
    if isinstance(listing, list) :
        listing.extend((1, 2, 3))
        return ", ".join(listing)

Do :

def foo(name) :
    print str(name).lower()

def bar(listing) :
    l = list(listing)
    l.extend((1, 2, 3))
    return ", ".join(l)

Using the last way, foo will accept any object. Bar will accept strings, tuples, sets, lists and much more. Cheap DRY :-)

Don't mix spaces and tabs

Just don't. You would cry.

Use object as first parent

This is tricky, but it will bite you as your program grows. There are old and new classes in Python 2.x. The old ones are, well, old. They lack some features, and can have awkward behavior with inheritance. To be usable, any of your class must be of the "new style". To do so, make it inherit from "object" :

Don't :

class Father :
    pass

class Child(Father) :
    pass

Do :

class Father(object) :
    pass


class Child(Father) :
    pass

In Python 3.x all classes are new style so you don't need to do that.

Don't initialize class attributes outside the __init__ method

People coming from other languages find it tempting because that what you do the job in Java or PHP. You write the class name, then list your attributs and give them a default value. It seems to work in Python, however, this doesn't work the way you think.

Doing that will setup class attributes (static attributes), then when you will try to get the object attribute, it will gives you its value unless it's empty. In that case it will return the class attributes.

It implies two big hazards :

  • If the class attribute is changed, then the initial value is changed.
  • If you set a mutable object as a default value, you'll get the same object shared across instances.

Don't (unless you want static) :

class Car(object):
    color = "red"
    wheels = [wheel(), Wheel(), Wheel(), Wheel()]

Do :

class Car(object):
    def __init__(self):
        self.color = "red"
        self.wheels = [wheel(), Wheel(), Wheel(), Wheel()]
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5  
In your "just do it and correct the error" stanza, you have an except: block which is evilbadscary. Always catch the minimal subset of errors to avoid wierd debugging gotchas in larger programs, so in your example replace except: with except IOError as E: (Always worth grabbing the exception instance for inspection too ;)) –  richo Jan 4 '10 at 3:16
1  
Thanks. This is very helpful. –  jpartogi Jan 7 '10 at 6:28
1  
Most of these are quite general programming gotchas: they are not very specific to Python. –  EOL May 3 '10 at 9:29
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When you need a population of arrays you might be tempted to type something like this:

>>> a=[[1,2,3,4,5]]*4

And sure enough it will give you what you expect when you look at it

>>> from pprint import pprint
>>> pprint(a)

[[1, 2, 3, 4, 5],
 [1, 2, 3, 4, 5],
 [1, 2, 3, 4, 5],
 [1, 2, 3, 4, 5]]

But don't expect the elements of your population to be seperate objects:

>>> a[0][0] = 2
>>> pprint(a)

[[2, 2, 3, 4, 5],
 [2, 2, 3, 4, 5],
 [2, 2, 3, 4, 5],
 [2, 2, 3, 4, 5]]

Unless this is what you need...

It is worth mentioning a workaround:

a = [[1,2,3,4,5] for _ in range(4)]
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17  
It is worth mentioning a workaround: a = [[1,2,3,4,5] for _ in range(4)] –  J.F. Sebastian Jun 22 '09 at 6:12
5  
I would not use _ in the expression. First it has a special meaning to the interactive interpreter. Second, it's not totally obvious that what you mean is that you are ignoring the loop variable. how about changing it to ignored or some such? –  IfLoop Jul 27 '09 at 17:30
1  
I would just use 'i' for that variable. –  MatrixFrog Jan 4 '10 at 2:46
2  
What does _ mean to the interpreter? –  orokusaki Jan 7 '10 at 6:29
1  
In the interactive interpreter _ is the output of your last command. –  Jorisslob Jan 25 '10 at 12:57
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Python Language Gotchas -- things that fail in very obscure ways

  • Using mutable default arguments.

  • Leading zeroes mean octal. 09 is a very obscure syntax error in Python 2.x

  • Misspelling overridden method names in a superclass or subclass. The superclass misspelling mistake is worse, because none of the subclasses override it correctly.

Python Design Gotchas

  • Spending time on introspection (e.g. trying to automatically determine types or superclass identity or other stuff). First, it's obvious from reading the source. More importantly, time spent on weird Python introspection usually indicates a fundamental failure to grasp polymorphism. 80% of the Python introspection questions on SO are failure to get Polymorphism.

  • Spending time on code golf. Just because your mental model of your application is four keywords ("do", "what", "I", "mean"), doesn't mean you should build a hyper-complex introspective decorator-driven framework to do that. Python allows you to take DRY to a level that is silliness. The rest of the Python introspection questions on SO attempts to reduce complex problems to code golf exercises.

  • Monkeypatching.

  • Failure to actually read through the standard library, and reinventing the wheel.

  • Conflating interactive type-as-you go Python with a proper program. While you're typing interactively, you may lose track of a variable and have to use globals(). Also, while you're typing, almost everything is global. In proper programs, you'll never "lose track of" a variable, and nothing will be global.

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1  
What other alternatives are there for MonkeyPatching when 3rd part lib has some bug? –  Anurag Uniyal Jun 18 '09 at 11:06
8  
It's python: you have the source. If 3rd party lib has a bug, you can just fix it. –  S.Lott Jun 18 '09 at 12:19
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Mutating a default argument:

def foo(bar=[]):
    bar.append('baz')
    return bar

The default value is evaluated only once, and not every time the function is called. Repeated calls to foo() would return ['baz'], ['baz', 'baz'], ['baz', 'baz', 'baz'], ...

If you want to mutate bar do something like this:

def foo(bar=None):
    if bar is None:
        bar = []

    bar.append('baz')
    return bar

Or, if you like arguments to be final:

def foo(bar=[]):
    not_bar = bar[:]

    not_bar.append('baz')
    return not_bar
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6  
Hu ? This is IN THE QUESTION. –  e-satis Nov 24 '09 at 23:58
4  
Yes, it's in the question, but not explained so thoroughly and not with workaround solutions. +1 from me. –  Mark Ransom Jan 4 '10 at 3:56
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I don´t know whether this is a common mistake, but while python doesn´t has increment and decrement operators, double signs are allowed, so

++i

and

--i

is syntactically correct code, but doesn´t do anything.

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4  
Should probably note that python increment/decrement is done with i += 1, i -= 1. (Inplace of ++i, ==i or i++, i--). –  monkut Aug 24 '09 at 8:16
1  
The relevant production rule of the python grammar is u_expr ::= power | "-" u_expr | "+" u_expr | "~" u_expr (See docs.python.org/reference/…) –  Jochen Walter Aug 24 '09 at 11:07
1  
The whole point is, that '--' and '++' here are not in-/decrement operators but are doubled signs for the following numbers. Hence --i is equivalent to -(-i) == i. Therefore you can also write ---i = -i, which is the reason, why Python has no in-/decrement operators. (You would have undefined behaviour, if it had.) –  Boldewyn Jan 15 '10 at 11:16
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Rolling your own code before looking in the standard library. For example, writing this:

def repeat_list(items):
    while True:
        for item in items:
            yield item

When you could just use this:

from itertools import cycle

Examples of frequently overlooked modules (besides itertools) include:

  • optparse for creating command line parsers
  • ConfigParser for reading configuration files in a standard manner
  • tempfile for creating and managing temporary files
  • shelve for storing Python objects to disk, handy when a full fledged database is overkill
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1  
I would add shutil and glob to that list –  André May 2 '10 at 14:55
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The another one could be to avoid using keywords as your own identifiers. Also it's always good to not use from somemodule import *

BTW, wouldn't it be better to post it to community wiki?

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1  
specifically I would avoid using from ... import * in modules. In top level scripts I think it's just fine. –  IfLoop Jul 27 '09 at 17:29
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Surprised that nobody said this

Mix tab and spaces when indenting.

really, it's a killer. believe me. In particular if it runs.

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5  
Somebody did, actually. –  e-satis Nov 25 '09 at 0:06
3  
@e-satis: Not if you read the answers chronologically. –  Boldewyn Jan 15 '10 at 11:20
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If you're coming from C++, realize that variables declared in a class definition are static. You can initialize nonstatic members in the init method.

Example:

class MyClass:
  static_member = 1

  def __init__(self):
    self.non_static_member = random()
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Not using functional tools. This isn't just a mistake from a style standpoint, it's a mistake from a speed standpoint because a lot of the functional tools are optimized in C.

This is the most common example:

temporary = []
for item in itemlist:
    temporary.append(somefunction(item))
itemlist = temporary

The correct way to do it:

itemlist = map(somefunction, itemlist)

The just as correct way to do it:

itemlist = [somefunction(x) for x in itemlist]

And if you only need the processed items available one at a time, rather than all at once, you can save memory and improve speed by using the iterable equivalents

# itertools-based iterator
itemiter = itertools.imap(somefunction, itemlist)
# generator expression-based iterator
itemiter = (somefunction(x) for x in itemlist)
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Importing re and using the full regular expression approach to string matching/transformation, when perfectly good string methods exist for every common operation (e.g. capitalisation, simple matching/searching).

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Last link is the original one, this SO question is an duplicate.

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Normal copying (assigning) is done by reference, so filling a container by adapting the same object and inserting, ends up with a container with references to the last added object. Use copy.deepcopy instead.

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Using the %s formatter in error messages. In almost every circumstance, %r should be used.

For example, imagine code like this:

try:
    get_person(person)
except NoSuchPerson:
    logger.error("Person %s not found." %(person))

Printed this error:

ERROR: Person wolever not found.

It's impossible to tell if the person variable is the string "wolever", the unicode string u"wolever" or an instance of the Person class (which has __str__ defined as def __str__(self): return self.name). Whereas, if %r was used, there would be three different error messages:

...
logger.error("Person %r not found." %(person))

Would produce the much more helpful errors:

ERROR: Person 'wolever' not found.
ERROR: Person u'wolever' not found.
ERROR: Person  not found.

Another good reason for this is that paths are a whole lot easier to copy/paste. Imagine:

try:
    stuff = open(path).read()
except IOError:
    logger.error("Could not open %s" %(path))

If path is some path/with 'strange' "characters", the error message will be:

ERROR: Could not open some path/with 'strange' "characters"

Which is hard to visually parse and hard to copy/paste into a shell.

Whereas, if %r is used, the error would be:

ERROR: Could not open 'some path/with \'strange\' "characters"'

Easy to visually parse, easy to copy-paste, all around better.

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I would stop using deprecated methods in 2.6 so your app/script will be ready and easier to convert to python 3.

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A bad habit I had to train myself out of was using X and Y or Z for inline logic.

Unless you can 100% always guarantee that Y will be a true value, even when your code changes in 18 months time, you set yourself up for some unexpected behaviour.

Thankfully, in later versions you can use Y if X else Z.

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some personal opinions, but I find it best NOT to:

  • as said, use deprecated modules (use warnings for them)
  • overuse classes & inheritance (typical of static languages legacy maybe)
  • explicitly use declarative algorithms (as iteration with for vs use of itertools)
  • reimplement functions from the standard lib "because I don't need all of those features"
  • using features for the sake of it (reducing compatibility with older python versions)
  • using metaclasses when you really don't have to and more generally make things too "magic"
  • avoid using generators (i.e., use them)
  • (more personal) try to micro-optimize CPython code on a low-level basis. Better spend time on algorithms and then optimize by making a small C shared lib called by ctypes (it's so easy to gain 5x perf boosts on an inner loop)
  • use unnecessary lists when iterators would suffice
  • (controversial maybe now) code a project directly for 3.x before the libs you need are all available.

(edited : best to --> NOT to of course, duh.)

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4  
are you sure that it's "best to" and not "best not to"? –  SilentGhost Jun 18 '09 at 17:25
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Never assume that having a multi-threaded Python application and a SMP capable machine (for instance one equipped with a multi-core CPU) will give you the benefit of introducing true parallelism into your application. Most likely it will not because of GIL (Global Interpreter Lock) which synchronizes your application on the byte-code interpreter level.

There are some workarounds like taking advantage of SMP by putting the concurrent code in C API calls or using multiple processes (instead of threads) via wrappers (for instance like the one available at http://www.parallelpython.org) but if one needs true multi-threading in Python one should look at things like Jython, IronPython etc. (GIL is a feature of the CPython interpreter so other implementations are not affected).

According to Python 3000 FAQ (available at Artima) the above still stands even for the latest Python versions.

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2  
CPython has "True multithreading". What it doesn't have, thanks to the GIL, are threats that can be used for load balancing. But then again, threads where never intended for that. Threads were designed so that you could have locking calls without creating separate processes. However, with Unix and Javas heavy threads, load balancing with threads have become possible, and many people seem to think that this is how you "should" do it. –  Lennart Regebro Aug 24 '09 at 11:13
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++n and --n may not work as expected by people coming from C/Java background

++n is positive of a positive number which is positive = n

--n is negative of a negative number which is positive = n

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Somewhat related to the default mutable argument, how one checks for the "missing" case results in differences when an empty list is passed:

def func1(toc=None):
    if not toc:
        toc = []
    toc.append('bar')

def func2(toc=None):
    if toc is None:
        toc = []
    toc.append('bar')

def demo(toc, func):
    print func.__name__
    print '  before:', toc
    func(toc)
    print '  after:', toc

demo([], func1)
demo([], func2)

Here's the output:

func1
  before: []
  after: []
func2
  before: []
  after: ['bar']
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2  
A clearer way to say this is to say "When checking for None, use is None instead of not", as it's not only for missing cases, but any None testing. –  Lennart Regebro Aug 24 '09 at 8:45
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import this

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!

import not_this

Write ugly code.
Write implicit code.
Write complex code.
Write nested code.
Write dense code.
Write unreadable code.
Write special cases.
Strive for purity.
Ignore errors and exceptions.
Write optimal code before releasing.
Every implementation needs a flowchart.
Don't use namespaces.

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10  
For a second I thought there was another easter egg in the stdlib that I hadn't known about; but then I tried import not_this and got an ImportError –  Marius Gedminas Jul 27 '09 at 18:45
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The very first mistake before you even start: Don't be afraid of whitespace.

When you show someone a piece of Python code, they are impressed until you tell them that they have to indent correctly. For some reason, most people feel that a language shouldn't force a certain style on them while all of them will indent the code nonetheless.

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5  
Funny thing is, I wouldn't ever touch somebody's nasty Java code with all that shi* everywhere, and incorrect indentation. It's so terrible to read. I have always indented correctly, so when I picked up Python it was like a god-sent. –  orokusaki Jan 7 '10 at 6:31
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I've started learning Python as well and one of the bigest mistakes I made is constantly using C++/C# indexed "for" loop. Python have for(i ; i < length ; i++) type loop and for a good reason - most of the time there are better ways to do there same thing.

Example: I had a method that iterated over a list and returned the indexes of selected items:

for i in range(len(myList)):
    if myList[i].selected:
        retVal.append(i)

Instead Python has list comprehension that solves the same problem in a more elegant and easy to read way:

retVal = [index for index, item in enumerate(myList) if item.selected]
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Similar to mutable default arguments is the mutable class attribute.

>>> class Classy:
...    foo = []
...    def add(self, value):
...        self.foo.append(value)
... 
>>> instance1 = Classy()
>>> instance2 = Classy()
>>> instance1.add("Foo!")
>>> instance2.foo
['Foo!']
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my_variable = [something]
...
my_varaible = f(my_variable)
...
use my_variable and thinking it contains the result from f, and not the initial value

Python won't warn you in any way that on the second assignment you misspelled the variable name and created a new one.

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You've mentioned default arguments... One that's almost as bad as mutable default arguments: default values which aren't None.

Consider a function which will cook some food:

def cook(breakfast="spam"):
    arrange_ingredients_for(breakfast)
    heat_ingredients_for(breakfast)
    serve(breakfast)

Because it specifies a default value for breakfast, it is impossible for some other function to say "cook your default breakfast" without a special-case:

def order(breakfast=None):
    if breakfast is None:
        cook()
    else:
        cook(breakfast)

However, this could be avoided if cook used None as a default value:

def cook(breakfast=None):
    if breakfast is None:
        breakfast = "spam"

def order(breakfast=None):
    cook(breakfast)

A good example of this is Django bug #6988. Django's caching module had a "save to cache" function which looked like this:

def set(key, value, timeout=0):
    if timeout == 0:
        timeout = settings.DEFAULT_TIMEOUT
    _caching_backend.set(key, value, timeout)

But, for the memcached backend, a timeout of 0 means "never timeout"… Which, as you can see, would be impossible to specify.

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Don't modify a list while iterating over it.

odd = lambda x : bool(x % 2)
numbers = range(10)
for i in range(len(numbers)):
    if odd(numbers[i]):
        del numbers[i]

One common suggestion to work around this problem is to iterate over the list in reverse:

for i in range(len(numbers)-1,0,-1):
    if odd(numbers[i]):
        del numbers[i]

But even better is to use a list comprehension to build a new list to replace the old:

numbers[:] = [n for n in numbers if not odd(n)]
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Common pitfall: Default arguments are evaluated once:

def x(a, l=[]):
    l.append(a)
    return l

print x(1)
print x(2)

prints:

[1]
[1, 2]

i.e. you always get the same list.

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Similar to mutable default arguments is the mutable class attribute.

>>> class Classy:
...    foo = []
...    def add(self, value):
...        self.foo.append(value)
... 
>>> instance1 = Classy()
>>> instance2 = Classy()
>>> instance1.add("Foo!")
>>> instance2.foo
['Foo!']

Not what you expect.

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1  
I'd say exactly what you expect. –  SilentGhost Aug 24 '09 at 8:52
1  
Yeah, once you understand what's going on, yes. As a Python newbie, no... –  Lennart Regebro Aug 24 '09 at 9:06
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