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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:

        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:

        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.

stackoverflow.com/questions/530530/… - isn't this question the original one? –  zeroDivisible Jul 16 '09 at 5:22
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
@Narek: What is a "normal" programming language? –  voyager Jul 27 '10 at 21:27

35 Answers 35

Creating a local module with the same name as one from the stdlib. This is almost always done by accident (as reported in this question), but usually results in cryptic error messages.

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Promiscuous Exception Handling

This is something that I see a surprising amount in production code and it makes me cringe.

    do_something() # do_something can raise a lot errors e.g. files, sockets
    pass # who cares we'll just ignore it

Was the exception the one you want suppress, or is it more serious? But there are more subtle cases. That can make you pull your hair out trying to figure out.

except AttributeError: # baz() may return None or an incompatible *duck type*

The problem is foo or baz could be the culprits too. I think this can be more insidious in that this is idiomatic python where you are checking your types for proper methods. But each method call has chance to return something unexpected and suppress bugs that should be raising exceptions.

Knowing what exceptions a method can throw are not always obvious. For example, urllib and urllib2 use socket which has its own exceptions that percolate up and rear their ugly head when you least expect it.

Exception handling is a productivity boon in handling errors over system level languages like C. But I have found suppressing exceptions improperly can create truly mysterious debugging sessions and take away a major advantage interpreted languages provide.

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This has been mentioned already, but I'd like to elaborate a bit on class attribute mutability.

When you define a member attribute, then every time you instance that class it gets an attribute that's a shallow copy of the class attribute.

So if you have something like

class Test(object):
   myAttr = 1
instA = Test()
instB = Test()
instB.myAttr = 2

It will behave as expected.

>>> instA.myAttr
>>> instB.myAttr

The problem comes when you have class attributes that are mutable. Since instantiation just did a shallow copy, all instances are going to just have a reference pointing to the same object.

class Test(object):
instA = Test()
instB = Test()
>>> instA.myAttr

But the references are actual members of the instance, so as long as you are actually assigning something new to the attribute you are ok.

You can get around this by making a deep copy of mutable variables during the init function

import copy
class Test(object):
   myAttr = [1,2,3]
   def __init__(self):
      self.myAttr = copy.deepcopy(self.myAttr)
instA = Test()
instB = Test()
instB.myAttr[0] = 5
>>> instA.myAttr
>>> instB.myAttr

It might be possible to write a decorator that would automatically deepcopy all your class attributes during init, but I don't know offhand of one that is provided anywhere.

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Algorithm blogs has a good post about Python performance issues and how to avoid them: 10 Python Optimization Tips and Issues

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Class attributes

Some answers above are incorrect or unclear about class attributes.

They do not become instance attributes, but are readable using the same syntax as instance attributes. They can be changed by accessing them via the class name.

class MyClass:
    attrib = 1                         # class attributes named 'attrib'
    another = 2                        # and 'another'
    def __init__(self):
        self.instattr = 3              # creates instance attributes
        self.attrib = 'instance'      

mc0 = MyClass()
mc1 = MyClass()

print mc.attrib    # 'instance'
print mc.another   # '2'

MyClass.another = 5  # change class attributes
MyClass.attrib = 21  # <- masked by instance attribute of same name

print mc.attrib    # 'instance'   unchanged instance attribute
print mc.another   # '5'          changed class attribute

Class attributes can be used as sort of default values for instance attributes, masked later by instance attributes of the same name with a different value.

Intermediate scope local variables

A more difficult matter to understand is the scoping of variables in nested functions.

In the following example, y is unwritable from anywhere other than function 'outer'. x is readable and writable from anywhere, as it is declared global in each function. z is readable and writable in 'inner*' only. y is readable in 'outer' and 'inner*', but not writable except in 'outer'.

x = 1
def outer():
    global x
    y = 2
    def inner1():
        global x, y
        y = y+1  # creates new global variable with value=3
    def inner2():
        global x
        y = y+1  # creates new local variable with value=3

I believe that Python 3 includes an 'outer' keyword for such 'outside this function but not global' cases. In Python 2.#, you are stuck with either making y global, or making it a mutable parameter to 'inner'.

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