
Programming FAQ
***************


General Questions
=================


Is there a source code level debugger with breakpoints, single-stepping, etc.?
------------------------------------------------------------------------------

Yes.

The pdb module is a simple but adequate console-mode debugger for
Python. It is part of the standard Python library, and is ``documented
in the Library Reference Manual``. You can also write your own
debugger by using the code for pdb as an example.

The IDLE interactive development environment, which is part of the
standard Python distribution (normally available as
Tools/scripts/idle), includes a graphical debugger.  There is
documentation for the IDLE debugger at
http://www.python.org/idle/doc/idle2.html#Debugger.

PythonWin is a Python IDE that includes a GUI debugger based on pdb.
The Pythonwin debugger colors breakpoints and has quite a few cool
features such as debugging non-Pythonwin programs.  Pythonwin is
available as part of the Python for Windows Extensions project and as
a part of the ActivePython distribution (see
http://www.activestate.com/Products/ActivePython/index.html).

Boa Constructor is an IDE and GUI builder that uses wxWidgets.  It
offers visual frame creation and manipulation, an object inspector,
many views on the source like object browsers, inheritance
hierarchies, doc string generated html documentation, an advanced
debugger, integrated help, and Zope support.

Eric is an IDE built on PyQt and the Scintilla editing component.

Pydb is a version of the standard Python debugger pdb, modified for
use with DDD (Data Display Debugger), a popular graphical debugger
front end.  Pydb can be found at http://bashdb.sourceforge.net/pydb/
and DDD can be found at http://www.gnu.org/software/ddd.

There are a number of commercial Python IDEs that include graphical
debuggers. They include:

* Wing IDE (http://wingware.com/)

* Komodo IDE (http://www.activestate.com/Products/Komodo)


Is there a tool to help find bugs or perform static analysis?
-------------------------------------------------------------

Yes.

PyChecker is a static analysis tool that finds bugs in Python source
code and warns about code complexity and style.  You can get PyChecker
from http://pychecker.sf.net.

Pylint is another tool that checks if a module satisfies a coding
standard, and also makes it possible to write plug-ins to add a custom
feature.  In addition to the bug checking that PyChecker performs,
Pylint offers some additional features such as checking line length,
whether variable names are well-formed according to your coding
standard, whether declared interfaces are fully implemented, and more.
http://www.logilab.org/card/pylint_manual provides a full list of
Pylint's features.


How can I create a stand-alone binary from a Python script?
-----------------------------------------------------------

You don't need the ability to compile Python to C code if all you want
is a stand-alone program that users can download and run without
having to install the Python distribution first.  There are a number
of tools that determine the set of modules required by a program and
bind these modules together with a Python binary to produce a single
executable.

One is to use the freeze tool, which is included in the Python source
tree as ``Tools/freeze``. It converts Python byte code to C arrays; a
C compiler you can embed all your modules into a new program, which is
then linked with the standard Python modules.

It works by scanning your source recursively for import statements (in
both forms) and looking for the modules in the standard Python path as
well as in the source directory (for built-in modules).  It then turns
the bytecode for modules written in Python into C code (array
initializers that can be turned into code objects using the marshal
module) and creates a custom-made config file that only contains those
built-in modules which are actually used in the program.  It then
compiles the generated C code and links it with the rest of the Python
interpreter to form a self-contained binary which acts exactly like
your script.

Obviously, freeze requires a C compiler.  There are several other
utilities which don't. One is Thomas Heller's py2exe (Windows only) at

   http://www.py2exe.org/

Another is Christian Tismer's SQFREEZE which appends the byte code to
a specially-prepared Python interpreter that can find the byte code in
the executable.

Other tools include Fredrik Lundh's Squeeze and Anthony Tuininga's
cx_Freeze.


Are there coding standards or a style guide for Python programs?
----------------------------------------------------------------

Yes.  The coding style required for standard library modules is
documented as **PEP 8**.


My program is too slow. How do I speed it up?
---------------------------------------------

That's a tough one, in general.  There are many tricks to speed up
Python code; consider rewriting parts in C as a last resort.

In some cases it's possible to automatically translate Python to C or
x86 assembly language, meaning that you don't have to modify your code
to gain increased speed.

Pyrex can compile a slightly modified version of Python code into a C
extension, and can be used on many different platforms.

Psyco is a just-in-time compiler that translates Python code into x86
assembly language.  If you can use it, Psyco can provide dramatic
speedups for critical functions.

The rest of this answer will discuss various tricks for squeezing a
bit more speed out of Python code.  *Never* apply any optimization
tricks unless you know you need them, after profiling has indicated
that a particular function is the heavily executed hot spot in the
code.  Optimizations almost always make the code less clear, and you
shouldn't pay the costs of reduced clarity (increased development
time, greater likelihood of bugs) unless the resulting performance
benefit is worth it.

There is a page on the wiki devoted to performance tips.

Guido van Rossum has written up an anecdote related to optimization at
http://www.python.org/doc/essays/list2str.html.

One thing to notice is that function and (especially) method calls are
rather expensive; if you have designed a purely OO interface with lots
of tiny functions that don't do much more than get or set an instance
variable or call another method, you might consider using a more
direct way such as directly accessing instance variables.  Also see
the standard module ``profile`` which makes it possible to find out
where your program is spending most of its time (if you have some
patience -- the profiling itself can slow your program down by an
order of magnitude).

Remember that many standard optimization heuristics you may know from
other programming experience may well apply to Python.  For example it
may be faster to send output to output devices using larger writes
rather than smaller ones in order to reduce the overhead of kernel
system calls.  Thus CGI scripts that write all output in "one shot"
may be faster than those that write lots of small pieces of output.

Also, be sure to use Python's core features where appropriate.  For
example, slicing allows programs to chop up lists and other sequence
objects in a single tick of the interpreter's mainloop using highly
optimized C implementations. Thus to get the same effect as:

   L2 = []
   for i in range(3):
       L2.append(L1[i])

it is much shorter and far faster to use

   L2 = list(L1[:3])  # "list" is redundant if L1 is a list.

Note that the functionally-oriented built-in functions such as
``map()``, ``zip()``, and friends can be a convenient accelerator for
loops that perform a single task.  For example to pair the elements of
two lists together:

   >>> zip([1, 2, 3], [4, 5, 6])
   [(1, 4), (2, 5), (3, 6)]

or to compute a number of sines:

   >>> map(math.sin, (1, 2, 3, 4))
   [0.841470984808, 0.909297426826, 0.14112000806, -0.756802495308]

The operation completes very quickly in such cases.

Other examples include the ``join()`` and ``split()`` *methods of
string objects*. For example if s1..s7 are large (10K+) strings then
``"".join([s1,s2,s3,s4,s5,s6,s7])`` may be far faster than the more
obvious ``s1+s2+s3+s4+s5+s6+s7``, since the "summation" will compute
many subexpressions, whereas ``join()`` does all the copying in one
pass.  For manipulating strings, use the ``replace()`` and the
``format()`` *methods on string objects*.  Use regular expressions
only when you're not dealing with constant string patterns.  You may
still use *the old % operations* ``string % tuple`` and ``string %
dictionary``.

Be sure to use the ``list.sort()`` built-in method to do sorting, and
see the sorting mini-HOWTO for examples of moderately advanced usage.
``list.sort()`` beats other techniques for sorting in all but the most
extreme circumstances.

Another common trick is to "push loops into functions or methods."
For example suppose you have a program that runs slowly and you use
the profiler to determine that a Python function ``ff()`` is being
called lots of times.  If you notice that ``ff()``:

   def ff(x):
       ... # do something with x computing result...
       return result

tends to be called in loops like:

   list = map(ff, oldlist)

or:

   for x in sequence:
       value = ff(x)
       ... # do something with value...

then you can often eliminate function call overhead by rewriting
``ff()`` to:

   def ffseq(seq):
       resultseq = []
       for x in seq:
           ... # do something with x computing result...
           resultseq.append(result)
       return resultseq

and rewrite the two examples to ``list = ffseq(oldlist)`` and to:

   for value in ffseq(sequence):
       ... # do something with value...

Single calls to ``ff(x)`` translate to ``ffseq([x])[0]`` with little
penalty. Of course this technique is not always appropriate and there
are other variants which you can figure out.

You can gain some performance by explicitly storing the results of a
function or method lookup into a local variable.  A loop like:

   for key in token:
       dict[key] = dict.get(key, 0) + 1

resolves ``dict.get`` every iteration.  If the method isn't going to
change, a slightly faster implementation is:

   dict_get = dict.get  # look up the method once
   for key in token:
       dict[key] = dict_get(key, 0) + 1

Default arguments can be used to determine values once, at compile
time instead of at run time.  This can only be done for functions or
objects which will not be changed during program execution, such as
replacing

   def degree_sin(deg):
       return math.sin(deg * math.pi / 180.0)

with

   def degree_sin(deg, factor=math.pi/180.0, sin=math.sin):
       return sin(deg * factor)

Because this trick uses default arguments for terms which should not
be changed, it should only be used when you are not concerned with
presenting a possibly confusing API to your users.


Core Language
=============


Why am I getting an UnboundLocalError when the variable has a value?
--------------------------------------------------------------------

It can be a surprise to get the UnboundLocalError in previously
working code when it is modified by adding an assignment statement
somewhere in the body of a function.

This code:

>>> x = 10
>>> def bar():
...     print x
>>> bar()
10

works, but this code:

>>> x = 10
>>> def foo():
...     print x
...     x += 1

results in an UnboundLocalError:

>>> foo()
Traceback (most recent call last):
  ...
UnboundLocalError: local variable 'x' referenced before assignment

This is because when you make an assignment to a variable in a scope,
that variable becomes local to that scope and shadows any similarly
named variable in the outer scope.  Since the last statement in foo
assigns a new value to ``x``, the compiler recognizes it as a local
variable.  Consequently when the earlier ``print x`` attempts to print
the uninitialized local variable and an error results.

In the example above you can access the outer scope variable by
declaring it global:

>>> x = 10
>>> def foobar():
...     global x
...     print x
...     x += 1
>>> foobar()
10

This explicit declaration is required in order to remind you that
(unlike the superficially analogous situation with class and instance
variables) you are actually modifying the value of the variable in the
outer scope:

>>> print x
11


What are the rules for local and global variables in Python?
------------------------------------------------------------

In Python, variables that are only referenced inside a function are
implicitly global.  If a variable is assigned a new value anywhere
within the function's body, it's assumed to be a local.  If a variable
is ever assigned a new value inside the function, the variable is
implicitly local, and you need to explicitly declare it as 'global'.

Though a bit surprising at first, a moment's consideration explains
this.  On one hand, requiring ``global`` for assigned variables
provides a bar against unintended side-effects.  On the other hand, if
``global`` was required for all global references, you'd be using
``global`` all the time.  You'd have to declare as global every
reference to a built-in function or to a component of an imported
module.  This clutter would defeat the usefulness of the ``global``
declaration for identifying side-effects.


Why do lambdas defined in a loop with different values all return the same result?
----------------------------------------------------------------------------------

Assume you use a for loop to define a few different lambdas (or even
plain functions), e.g.:

   >>> squares = []
   >>> for x in range(5):
   ...    squares.append(lambda: x**2)

This gives you a list that contains 5 lambdas that calculate ``x**2``.
You might expect that, when called, they would return, respectively,
``0``, ``1``, ``4``, ``9``, and ``16``.  However, when you actually
try you will see that they all return ``16``:

   >>> squares[2]()
   16
   >>> squares[4]()
   16

This happens because ``x`` is not local to the lambdas, but is defined
in the outer scope, and it is accessed when the lambda is called ---
not when it is defined.  At the end of the loop, the value of ``x`` is
``4``, so all the functions now return ``4**2``, i.e. ``16``.  You can
also verify this by changing the value of ``x`` and see how the
results of the lambdas change:

   >>> x = 8
   >>> squares[2]()
   64

In order to avoid this, you need to save the values in variables local
to the lambdas, so that they don't rely on the value of the global
``x``:

   >>> squares = []
   >>> for x in range(5):
   ...    squares.append(lambda n=x: n**2)

Here, ``n=x`` creates a new variable ``n`` local to the lambda and
computed when the lambda is defined so that it has the same value that
``x`` had at that point in the loop.  This means that the value of
``n`` will be ``0`` in the first lambda, ``1`` in the second, ``2`` in
the third, and so on. Therefore each lambda will now return the
correct result:

   >>> squares[2]()
   4
   >>> squares[4]()
   16

Note that this behaviour is not peculiar to lambdas, but applies to
regular functions too.


How do I share global variables across modules?
-----------------------------------------------

The canonical way to share information across modules within a single
program is to create a special module (often called config or cfg).
Just import the config module in all modules of your application; the
module then becomes available as a global name.  Because there is only
one instance of each module, any changes made to the module object get
reflected everywhere.  For example:

config.py:

   x = 0   # Default value of the 'x' configuration setting

mod.py:

   import config
   config.x = 1

main.py:

   import config
   import mod
   print config.x

Note that using a module is also the basis for implementing the
Singleton design pattern, for the same reason.


What are the "best practices" for using import in a module?
-----------------------------------------------------------

In general, don't use ``from modulename import *``.  Doing so clutters
the importer's namespace.  Some people avoid this idiom even with the
few modules that were designed to be imported in this manner.  Modules
designed in this manner include ``Tkinter``, and ``threading``.

Import modules at the top of a file.  Doing so makes it clear what
other modules your code requires and avoids questions of whether the
module name is in scope. Using one import per line makes it easy to
add and delete module imports, but using multiple imports per line
uses less screen space.

It's good practice if you import modules in the following order:

1. standard library modules -- e.g. ``sys``, ``os``, ``getopt``,
   ``re``

2. third-party library modules (anything installed in Python's site-
   packages directory) -- e.g. mx.DateTime, ZODB, PIL.Image, etc.

3. locally-developed modules

Never use relative package imports.  If you're writing code that's in
the ``package.sub.m1`` module and want to import ``package.sub.m2``,
do not just write ``import m2``, even though it's legal.  Write ``from
package.sub import m2`` instead.  Relative imports can lead to a
module being initialized twice, leading to confusing bugs.  See **PEP
328** for details.

It is sometimes necessary to move imports to a function or class to
avoid problems with circular imports.  Gordon McMillan says:

   Circular imports are fine where both modules use the "import
   <module>" form of import.  They fail when the 2nd module wants to
   grab a name out of the first ("from module import name") and the
   import is at the top level.  That's because names in the 1st are
   not yet available, because the first module is busy importing the
   2nd.

In this case, if the second module is only used in one function, then
the import can easily be moved into that function.  By the time the
import is called, the first module will have finished initializing,
and the second module can do its import.

It may also be necessary to move imports out of the top level of code
if some of the modules are platform-specific.  In that case, it may
not even be possible to import all of the modules at the top of the
file.  In this case, importing the correct modules in the
corresponding platform-specific code is a good option.

Only move imports into a local scope, such as inside a function
definition, if it's necessary to solve a problem such as avoiding a
circular import or are trying to reduce the initialization time of a
module.  This technique is especially helpful if many of the imports
are unnecessary depending on how the program executes.  You may also
want to move imports into a function if the modules are only ever used
in that function.  Note that loading a module the first time may be
expensive because of the one time initialization of the module, but
loading a module multiple times is virtually free, costing only a
couple of dictionary lookups.  Even if the module name has gone out of
scope, the module is probably available in ``sys.modules``.

If only instances of a specific class use a module, then it is
reasonable to import the module in the class's ``__init__`` method and
then assign the module to an instance variable so that the module is
always available (via that instance variable) during the life of the
object.  Note that to delay an import until the class is instantiated,
the import must be inside a method.  Putting the import inside the
class but outside of any method still causes the import to occur when
the module is initialized.


How can I pass optional or keyword parameters from one function to another?
---------------------------------------------------------------------------

Collect the arguments using the ``*`` and ``**`` specifiers in the
function's parameter list; this gives you the positional arguments as
a tuple and the keyword arguments as a dictionary.  You can then pass
these arguments when calling another function by using ``*`` and
``**``:

   def f(x, *args, **kwargs):
       ...
       kwargs['width'] = '14.3c'
       ...
       g(x, *args, **kwargs)

In the unlikely case that you care about Python versions older than
2.0, use ``apply()``:

   def f(x, *args, **kwargs):
       ...
       kwargs['width'] = '14.3c'
       ...
       apply(g, (x,)+args, kwargs)


What is the difference between arguments and parameters?
--------------------------------------------------------

*Parameters* are defined by the names that appear in a function
definition, whereas *arguments* are the values actually passed to a
function when calling it.  Parameters define what types of arguments a
function can accept.  For example, given the function definition:

   def func(foo, bar=None, **kwargs):
       pass

*foo*, *bar* and *kwargs* are parameters of ``func``.  However, when
calling ``func``, for example:

   func(42, bar=314, extra=somevar)

the values ``42``, ``314``, and ``somevar`` are arguments.


How do I write a function with output parameters (call by reference)?
---------------------------------------------------------------------

Remember that arguments are passed by assignment in Python.  Since
assignment just creates references to objects, there's no alias
between an argument name in the caller and callee, and so no call-by-
reference per se.  You can achieve the desired effect in a number of
ways.

1. By returning a tuple of the results:

      def func2(a, b):
          a = 'new-value'        # a and b are local names
          b = b + 1              # assigned to new objects
          return a, b            # return new values

      x, y = 'old-value', 99
      x, y = func2(x, y)
      print x, y                 # output: new-value 100

   This is almost always the clearest solution.

2. By using global variables.  This isn't thread-safe, and is not
   recommended.

3. By passing a mutable (changeable in-place) object:

      def func1(a):
          a[0] = 'new-value'     # 'a' references a mutable list
          a[1] = a[1] + 1        # changes a shared object

      args = ['old-value', 99]
      func1(args)
      print args[0], args[1]     # output: new-value 100

4. By passing in a dictionary that gets mutated:

      def func3(args):
          args['a'] = 'new-value'     # args is a mutable dictionary
          args['b'] = args['b'] + 1   # change it in-place

      args = {'a':' old-value', 'b': 99}
      func3(args)
      print args['a'], args['b']

5. Or bundle up values in a class instance:

      class callByRef:
          def __init__(self, **args):
              for (key, value) in args.items():
                  setattr(self, key, value)

      def func4(args):
          args.a = 'new-value'        # args is a mutable callByRef
          args.b = args.b + 1         # change object in-place

      args = callByRef(a='old-value', b=99)
      func4(args)
      print args.a, args.b

   There's almost never a good reason to get this complicated.

Your best choice is to return a tuple containing the multiple results.


How do you make a higher order function in Python?
--------------------------------------------------

You have two choices: you can use nested scopes or you can use
callable objects. For example, suppose you wanted to define
``linear(a,b)`` which returns a function ``f(x)`` that computes the
value ``a*x+b``.  Using nested scopes:

   def linear(a, b):
       def result(x):
           return a * x + b
       return result

Or using a callable object:

   class linear:

       def __init__(self, a, b):
           self.a, self.b = a, b

       def __call__(self, x):
           return self.a * x + self.b

In both cases,

   taxes = linear(0.3, 2)

gives a callable object where ``taxes(10e6) == 0.3 * 10e6 + 2``.

The callable object approach has the disadvantage that it is a bit
slower and results in slightly longer code.  However, note that a
collection of callables can share their signature via inheritance:

   class exponential(linear):
       # __init__ inherited
       def __call__(self, x):
           return self.a * (x ** self.b)

Object can encapsulate state for several methods:

   class counter:

       value = 0

       def set(self, x):
           self.value = x

       def up(self):
           self.value = self.value + 1

       def down(self):
           self.value = self.value - 1

   count = counter()
   inc, dec, reset = count.up, count.down, count.set

Here ``inc()``, ``dec()`` and ``reset()`` act like functions which
share the same counting variable.


How do I copy an object in Python?
----------------------------------

In general, try ``copy.copy()`` or ``copy.deepcopy()`` for the general
case. Not all objects can be copied, but most can.

Some objects can be copied more easily.  Dictionaries have a
``copy()`` method:

   newdict = olddict.copy()

Sequences can be copied by slicing:

   new_l = l[:]


How can I find the methods or attributes of an object?
------------------------------------------------------

For an instance x of a user-defined class, ``dir(x)`` returns an
alphabetized list of the names containing the instance attributes and
methods and attributes defined by its class.


How can my code discover the name of an object?
-----------------------------------------------

Generally speaking, it can't, because objects don't really have names.
Essentially, assignment always binds a name to a value; The same is
true of ``def`` and ``class`` statements, but in that case the value
is a callable. Consider the following code:

   class A:
       pass

   B = A

   a = B()
   b = a
   print b
   <__main__.A instance at 0x16D07CC>
   print a
   <__main__.A instance at 0x16D07CC>

Arguably the class has a name: even though it is bound to two names
and invoked through the name B the created instance is still reported
as an instance of class A.  However, it is impossible to say whether
the instance's name is a or b, since both names are bound to the same
value.

Generally speaking it should not be necessary for your code to "know
the names" of particular values. Unless you are deliberately writing
introspective programs, this is usually an indication that a change of
approach might be beneficial.

In comp.lang.python, Fredrik Lundh once gave an excellent analogy in
answer to this question:

   The same way as you get the name of that cat you found on your
   porch: the cat (object) itself cannot tell you its name, and it
   doesn't really care -- so the only way to find out what it's called
   is to ask all your neighbours (namespaces) if it's their cat
   (object)...

   ....and don't be surprised if you'll find that it's known by many
   names, or no name at all!


What's up with the comma operator's precedence?
-----------------------------------------------

Comma is not an operator in Python.  Consider this session:

   >>> "a" in "b", "a"
   (False, 'a')

Since the comma is not an operator, but a separator between
expressions the above is evaluated as if you had entered:

   ("a" in "b"), "a"

not:

   "a" in ("b", "a")

The same is true of the various assignment operators (``=``, ``+=``
etc).  They are not truly operators but syntactic delimiters in
assignment statements.


Is there an equivalent of C's "?:" ternary operator?
----------------------------------------------------

Yes, this feature was added in Python 2.5. The syntax would be as
follows:

   [on_true] if [expression] else [on_false]

   x, y = 50, 25

   small = x if x < y else y

For versions previous to 2.5 the answer would be 'No'.


Is it possible to write obfuscated one-liners in Python?
--------------------------------------------------------

Yes.  Usually this is done by nesting ``lambda`` within ``lambda``.
See the following three examples, due to Ulf Bartelt:

   # Primes < 1000
   print filter(None,map(lambda y:y*reduce(lambda x,y:x*y!=0,
   map(lambda x,y=y:y%x,range(2,int(pow(y,0.5)+1))),1),range(2,1000)))

   # First 10 Fibonacci numbers
   print map(lambda x,f=lambda x,f:(f(x-1,f)+f(x-2,f)) if x>1 else 1: f(x,f),
   range(10))

   # Mandelbrot set
   print (lambda Ru,Ro,Iu,Io,IM,Sx,Sy:reduce(lambda x,y:x+y,map(lambda y,
   Iu=Iu,Io=Io,Ru=Ru,Ro=Ro,Sy=Sy,L=lambda yc,Iu=Iu,Io=Io,Ru=Ru,Ro=Ro,i=IM,
   Sx=Sx,Sy=Sy:reduce(lambda x,y:x+y,map(lambda x,xc=Ru,yc=yc,Ru=Ru,Ro=Ro,
   i=i,Sx=Sx,F=lambda xc,yc,x,y,k,f=lambda xc,yc,x,y,k,f:(k<=0)or (x*x+y*y
   >=4.0) or 1+f(xc,yc,x*x-y*y+xc,2.0*x*y+yc,k-1,f):f(xc,yc,x,y,k,f):chr(
   64+F(Ru+x*(Ro-Ru)/Sx,yc,0,0,i)),range(Sx))):L(Iu+y*(Io-Iu)/Sy),range(Sy
   ))))(-2.1, 0.7, -1.2, 1.2, 30, 80, 24)
   #    \___ ___/  \___ ___/  |   |   |__ lines on screen
   #        V          V      |   |______ columns on screen
   #        |          |      |__________ maximum of "iterations"
   #        |          |_________________ range on y axis
   #        |____________________________ range on x axis

Don't try this at home, kids!


Numbers and strings
===================


How do I specify hexadecimal and octal integers?
------------------------------------------------

To specify an octal digit, precede the octal value with a zero, and
then a lower or uppercase "o".  For example, to set the variable "a"
to the octal value "10" (8 in decimal), type:

   >>> a = 0o10
   >>> a
   8

Hexadecimal is just as easy.  Simply precede the hexadecimal number
with a zero, and then a lower or uppercase "x".  Hexadecimal digits
can be specified in lower or uppercase.  For example, in the Python
interpreter:

   >>> a = 0xa5
   >>> a
   165
   >>> b = 0XB2
   >>> b
   178


Why does -22 // 10 return -3?
-----------------------------

It's primarily driven by the desire that ``i % j`` have the same sign
as ``j``. If you want that, and also want:

   i == (i // j) * j + (i % j)

then integer division has to return the floor.  C also requires that
identity to hold, and then compilers that truncate ``i // j`` need to
make ``i % j`` have the same sign as ``i``.

There are few real use cases for ``i % j`` when ``j`` is negative.
When ``j`` is positive, there are many, and in virtually all of them
it's more useful for ``i % j`` to be ``>= 0``.  If the clock says 10
now, what did it say 200 hours ago?  ``-190 % 12 == 2`` is useful;
``-190 % 12 == -10`` is a bug waiting to bite.

Note: On Python 2, ``a / b`` returns the same as ``a // b`` if
  ``__future__.division`` is not in effect.  This is also known as
  "classic" division.


How do I convert a string to a number?
--------------------------------------

For integers, use the built-in ``int()`` type constructor, e.g.
``int('144') == 144``.  Similarly, ``float()`` converts to floating-
point, e.g. ``float('144') == 144.0``.

By default, these interpret the number as decimal, so that
``int('0144') == 144`` and ``int('0x144')`` raises ``ValueError``.
``int(string, base)`` takes the base to convert from as a second
optional argument, so ``int('0x144', 16) == 324``.  If the base is
specified as 0, the number is interpreted using Python's rules: a
leading '0' indicates octal, and '0x' indicates a hex number.

Do not use the built-in function ``eval()`` if all you need is to
convert strings to numbers.  ``eval()`` will be significantly slower
and it presents a security risk: someone could pass you a Python
expression that might have unwanted side effects.  For example,
someone could pass ``__import__('os').system("rm -rf $HOME")`` which
would erase your home directory.

``eval()`` also has the effect of interpreting numbers as Python
expressions, so that e.g. ``eval('09')`` gives a syntax error because
Python regards numbers starting with '0' as octal (base 8).


How do I convert a number to a string?
--------------------------------------

To convert, e.g., the number 144 to the string '144', use the built-in
type constructor ``str()``.  If you want a hexadecimal or octal
representation, use the built-in functions ``hex()`` or ``oct()``.
For fancy formatting, see the *Format String Syntax* section, e.g.
``"{:04d}".format(144)`` yields ``'0144'`` and
``"{:.3f}".format(1/3)`` yields ``'0.333'``.  You may also use *the %
operator* on strings.  See the library reference manual for details.


How do I modify a string in place?
----------------------------------

You can't, because strings are immutable.  If you need an object with
this ability, try converting the string to a list or use the array
module:

   >>> import io
   >>> s = "Hello, world"
   >>> a = list(s)
   >>> print a
   ['H', 'e', 'l', 'l', 'o', ',', ' ', 'w', 'o', 'r', 'l', 'd']
   >>> a[7:] = list("there!")
   >>> ''.join(a)
   'Hello, there!'

   >>> import array
   >>> a = array.array('c', s)
   >>> print a
   array('c', 'Hello, world')
   >>> a[0] = 'y'; print a
   array('c', 'yello, world')
   >>> a.tostring()
   'yello, world'


How do I use strings to call functions/methods?
-----------------------------------------------

There are various techniques.

* The best is to use a dictionary that maps strings to functions.  The
  primary advantage of this technique is that the strings do not need
  to match the names of the functions.  This is also the primary
  technique used to emulate a case construct:

     def a():
         pass

     def b():
         pass

     dispatch = {'go': a, 'stop': b}  # Note lack of parens for funcs

     dispatch[get_input()]()  # Note trailing parens to call function

* Use the built-in function ``getattr()``:

     import foo
     getattr(foo, 'bar')()

  Note that ``getattr()`` works on any object, including classes,
  class instances, modules, and so on.

  This is used in several places in the standard library, like this:

     class Foo:
         def do_foo(self):
             ...

         def do_bar(self):
             ...

     f = getattr(foo_instance, 'do_' + opname)
     f()

* Use ``locals()`` or ``eval()`` to resolve the function name:

     def myFunc():
         print "hello"

     fname = "myFunc"

     f = locals()[fname]
     f()

     f = eval(fname)
     f()

  Note: Using ``eval()`` is slow and dangerous.  If you don't have
  absolute control over the contents of the string, someone could pass
  a string that resulted in an arbitrary function being executed.


Is there an equivalent to Perl's chomp() for removing trailing newlines from strings?
-------------------------------------------------------------------------------------

Starting with Python 2.2, you can use ``S.rstrip("\r\n")`` to remove
all occurrences of any line terminator from the end of the string
``S`` without removing other trailing whitespace.  If the string ``S``
represents more than one line, with several empty lines at the end,
the line terminators for all the blank lines will be removed:

   >>> lines = ("line 1 \r\n"
   ...          "\r\n"
   ...          "\r\n")
   >>> lines.rstrip("\n\r")
   'line 1 '

Since this is typically only desired when reading text one line at a
time, using ``S.rstrip()`` this way works well.

For older versions of Python, there are two partial substitutes:

* If you want to remove all trailing whitespace, use the ``rstrip()``
  method of string objects.  This removes all trailing whitespace, not
  just a single newline.

* Otherwise, if there is only one line in the string ``S``, use
  ``S.splitlines()[0]``.


Is there a scanf() or sscanf() equivalent?
------------------------------------------

Not as such.

For simple input parsing, the easiest approach is usually to split the
line into whitespace-delimited words using the ``split()`` method of
string objects and then convert decimal strings to numeric values
using ``int()`` or ``float()``.  ``split()`` supports an optional
"sep" parameter which is useful if the line uses something other than
whitespace as a separator.

For more complicated input parsing, regular expressions are more
powerful than C's ``sscanf()`` and better suited for the task.


What does 'UnicodeError: ASCII [decoding,encoding] error: ordinal not in range(128)' mean?
------------------------------------------------------------------------------------------

This error indicates that your Python installation can handle only
7-bit ASCII strings.  There are a couple ways to fix or work around
the problem.

If your programs must handle data in arbitrary character set
encodings, the environment the application runs in will generally
identify the encoding of the data it is handing you.  You need to
convert the input to Unicode data using that encoding.  For example, a
program that handles email or web input will typically find character
set encoding information in Content-Type headers.  This can then be
used to properly convert input data to Unicode. Assuming the string
referred to by ``value`` is encoded as UTF-8:

   value = unicode(value, "utf-8")

will return a Unicode object.  If the data is not correctly encoded as
UTF-8, the above call will raise a ``UnicodeError`` exception.

If you only want strings converted to Unicode which have non-ASCII
data, you can try converting them first assuming an ASCII encoding,
and then generate Unicode objects if that fails:

   try:
       x = unicode(value, "ascii")
   except UnicodeError:
       value = unicode(value, "utf-8")
   else:
       # value was valid ASCII data
       pass

It's possible to set a default encoding in a file called
``sitecustomize.py`` that's part of the Python library.  However, this
isn't recommended because changing the Python-wide default encoding
may cause third-party extension modules to fail.

Note that on Windows, there is an encoding known as "mbcs", which uses
an encoding specific to your current locale.  In many cases, and
particularly when working with COM, this may be an appropriate default
encoding to use.


Sequences (Tuples/Lists)
========================


How do I convert between tuples and lists?
------------------------------------------

The type constructor ``tuple(seq)`` converts any sequence (actually,
any iterable) into a tuple with the same items in the same order.

For example, ``tuple([1, 2, 3])`` yields ``(1, 2, 3)`` and
``tuple('abc')`` yields ``('a', 'b', 'c')``.  If the argument is a
tuple, it does not make a copy but returns the same object, so it is
cheap to call ``tuple()`` when you aren't sure that an object is
already a tuple.

The type constructor ``list(seq)`` converts any sequence or iterable
into a list with the same items in the same order.  For example,
``list((1, 2, 3))`` yields ``[1, 2, 3]`` and ``list('abc')`` yields
``['a', 'b', 'c']``.  If the argument is a list, it makes a copy just
like ``seq[:]`` would.


What's a negative index?
------------------------

Python sequences are indexed with positive numbers and negative
numbers.  For positive numbers 0 is the first index 1 is the second
index and so forth.  For negative indices -1 is the last index and -2
is the penultimate (next to last) index and so forth.  Think of
``seq[-n]`` as the same as ``seq[len(seq)-n]``.

Using negative indices can be very convenient.  For example ``S[:-1]``
is all of the string except for its last character, which is useful
for removing the trailing newline from a string.


How do I iterate over a sequence in reverse order?
--------------------------------------------------

Use the ``reversed()`` built-in function, which is new in Python 2.4:

   for x in reversed(sequence):
       ... # do something with x...

This won't touch your original sequence, but build a new copy with
reversed order to iterate over.

With Python 2.3, you can use an extended slice syntax:

   for x in sequence[::-1]:
       ... # do something with x...


How do you remove duplicates from a list?
-----------------------------------------

See the Python Cookbook for a long discussion of many ways to do this:

   http://aspn.activestate.com/ASPN/Cookbook/Python/Recipe/52560

If you don't mind reordering the list, sort it and then scan from the
end of the list, deleting duplicates as you go:

   if mylist:
       mylist.sort()
       last = mylist[-1]
       for i in range(len(mylist)-2, -1, -1):
           if last == mylist[i]:
               del mylist[i]
           else:
               last = mylist[i]

If all elements of the list may be used as dictionary keys (i.e. they
are all hashable) this is often faster

   d = {}
   for x in mylist:
       d[x] = 1
   mylist = list(d.keys())

In Python 2.5 and later, the following is possible instead:

   mylist = list(set(mylist))

This converts the list into a set, thereby removing duplicates, and
then back into a list.


How do you make an array in Python?
-----------------------------------

Use a list:

   ["this", 1, "is", "an", "array"]

Lists are equivalent to C or Pascal arrays in their time complexity;
the primary difference is that a Python list can contain objects of
many different types.

The ``array`` module also provides methods for creating arrays of
fixed types with compact representations, but they are slower to index
than lists.  Also note that the Numeric extensions and others define
array-like structures with various characteristics as well.

To get Lisp-style linked lists, you can emulate cons cells using
tuples:

   lisp_list = ("like",  ("this",  ("example", None) ) )

If mutability is desired, you could use lists instead of tuples.  Here
the analogue of lisp car is ``lisp_list[0]`` and the analogue of cdr
is ``lisp_list[1]``.  Only do this if you're sure you really need to,
because it's usually a lot slower than using Python lists.


How do I create a multidimensional list?
----------------------------------------

You probably tried to make a multidimensional array like this:

   >>> A = [[None] * 2] * 3

This looks correct if you print it:

   >>> A
   [[None, None], [None, None], [None, None]]

But when you assign a value, it shows up in multiple places:

>>> A[0][0] = 5
>>> A
[[5, None], [5, None], [5, None]]

The reason is that replicating a list with ``*`` doesn't create
copies, it only creates references to the existing objects.  The
``*3`` creates a list containing 3 references to the same list of
length two.  Changes to one row will show in all rows, which is almost
certainly not what you want.

The suggested approach is to create a list of the desired length first
and then fill in each element with a newly created list:

   A = [None] * 3
   for i in range(3):
       A[i] = [None] * 2

This generates a list containing 3 different lists of length two.  You
can also use a list comprehension:

   w, h = 2, 3
   A = [[None] * w for i in range(h)]

Or, you can use an extension that provides a matrix datatype; Numeric
Python is the best known.


How do I apply a method to a sequence of objects?
-------------------------------------------------

Use a list comprehension:

   result = [obj.method() for obj in mylist]

More generically, you can try the following function:

   def method_map(objects, method, arguments):
       """method_map([a,b], "meth", (1,2)) gives [a.meth(1,2), b.meth(1,2)]"""
       nobjects = len(objects)
       methods = map(getattr, objects, [method]*nobjects)
       return map(apply, methods, [arguments]*nobjects)


Why does a_tuple[i] += ['item'] raise an exception when the addition works?
---------------------------------------------------------------------------

This is because of a combination of the fact that augmented assignment
operators are *assignment* operators, and the difference between
mutable and immutable objects in Python.

This discussion applies in general when augmented assignment operators
are applied to elements of a tuple that point to mutable objects, but
we'll use a ``list`` and ``+=`` as our exemplar.

If you wrote:

   >>> a_tuple = (1, 2)
   >>> a_tuple[0] += 1
   Traceback (most recent call last):
      ...
   TypeError: 'tuple' object does not support item assignment

The reason for the exception should be immediately clear: ``1`` is
added to the object ``a_tuple[0]`` points to (``1``), producing the
result object, ``2``, but when we attempt to assign the result of the
computation, ``2``, to element ``0`` of the tuple, we get an error
because we can't change what an element of a tuple points to.

Under the covers, what this augmented assignment statement is doing is
approximately this:

   >>> result = a_tuple[0] + 1
   >>> a_tuple[0] = result
   Traceback (most recent call last):
     ...
   TypeError: 'tuple' object does not support item assignment

It is the assignment part of the operation that produces the error,
since a tuple is immutable.

When you write something like:

   >>> a_tuple = (['foo'], 'bar')
   >>> a_tuple[0] += ['item']
   Traceback (most recent call last):
     ...
   TypeError: 'tuple' object does not support item assignment

The exception is a bit more surprising, and even more surprising is
the fact that even though there was an error, the append worked:

   >>> a_tuple[0]
   ['foo', 'item']

To see why this happens, you need to know that (a) if an object
implements an ``__iadd__`` magic method, it gets called when the
``+=`` augmented assignment is executed, and its return value is what
gets used in the assignment statement; and (b) for lists, ``__iadd__``
is equivalent to calling ``extend`` on the list and returning the
list.  That's why we say that for lists, ``+=`` is a "shorthand" for
``list.extend``:

   >>> a_list = []
   >>> a_list += [1]
   >>> a_list
   [1]

This is equivalent to:

   >>> result = a_list.__iadd__([1])
   >>> a_list = result

The object pointed to by a_list has been mutated, and the pointer to
the mutated object is assigned back to ``a_list``.  The end result of
the assignment is a no-op, since it is a pointer to the same object
that ``a_list`` was previously pointing to, but the assignment still
happens.

Thus, in our tuple example what is happening is equivalent to:

   >>> result = a_tuple[0].__iadd__(['item'])
   >>> a_tuple[0] = result
   Traceback (most recent call last):
     ...
   TypeError: 'tuple' object does not support item assignment

The ``__iadd__`` succeeds, and thus the list is extended, but even
though ``result`` points to the same object that ``a_tuple[0]``
already points to, that final assignment still results in an error,
because tuples are immutable.


Dictionaries
============


How can I get a dictionary to display its keys in a consistent order?
---------------------------------------------------------------------

You can't.  Dictionaries store their keys in an unpredictable order,
so the display order of a dictionary's elements will be similarly
unpredictable.

This can be frustrating if you want to save a printable version to a
file, make some changes and then compare it with some other printed
dictionary.  In this case, use the ``pprint`` module to pretty-print
the dictionary; the items will be presented in order sorted by the
key.

A more complicated solution is to subclass ``dict`` to create a
``SortedDict`` class that prints itself in a predictable order.
Here's one simpleminded implementation of such a class:

   class SortedDict(dict):
       def __repr__(self):
           keys = sorted(self.keys())
           result = ("{!r}: {!r}".format(k, self[k]) for k in keys)
           return "{{{}}}".format(", ".join(result))

       __str__ = __repr__

This will work for many common situations you might encounter, though
it's far from a perfect solution. The largest flaw is that if some
values in the dictionary are also dictionaries, their values won't be
presented in any particular order.


I want to do a complicated sort: can you do a Schwartzian Transform in Python?
------------------------------------------------------------------------------

The technique, attributed to Randal Schwartz of the Perl community,
sorts the elements of a list by a metric which maps each element to
its "sort value". In Python, just use the ``key`` argument for the
``sort()`` method:

   Isorted = L[:]
   Isorted.sort(key=lambda s: int(s[10:15]))

The ``key`` argument is new in Python 2.4, for older versions this
kind of sorting is quite simple to do with list comprehensions.  To
sort a list of strings by their uppercase values:

   tmp1 = [(x.upper(), x) for x in L]  # Schwartzian transform
   tmp1.sort()
   Usorted = [x[1] for x in tmp1]

To sort by the integer value of a subfield extending from positions
10-15 in each string:

   tmp2 = [(int(s[10:15]), s) for s in L]  # Schwartzian transform
   tmp2.sort()
   Isorted = [x[1] for x in tmp2]

Note that Isorted may also be computed by

   def intfield(s):
       return int(s[10:15])

   def Icmp(s1, s2):
       return cmp(intfield(s1), intfield(s2))

   Isorted = L[:]
   Isorted.sort(Icmp)

but since this method calls ``intfield()`` many times for each element
of L, it is slower than the Schwartzian Transform.


How can I sort one list by values from another list?
----------------------------------------------------

Merge them into a single list of tuples, sort the resulting list, and
then pick out the element you want.

   >>> list1 = ["what", "I'm", "sorting", "by"]
   >>> list2 = ["something", "else", "to", "sort"]
   >>> pairs = zip(list1, list2)
   >>> pairs
   [('what', 'something'), ("I'm", 'else'), ('sorting', 'to'), ('by', 'sort')]
   >>> pairs.sort()
   >>> result = [ x[1] for x in pairs ]
   >>> result
   ['else', 'sort', 'to', 'something']

An alternative for the last step is:

   >>> result = []
   >>> for p in pairs: result.append(p[1])

If you find this more legible, you might prefer to use this instead of
the final list comprehension.  However, it is almost twice as slow for
long lists.  Why? First, the ``append()`` operation has to reallocate
memory, and while it uses some tricks to avoid doing that each time,
it still has to do it occasionally, and that costs quite a bit.
Second, the expression "result.append" requires an extra attribute
lookup, and third, there's a speed reduction from having to make all
those function calls.


Objects
=======


What is a class?
----------------

A class is the particular object type created by executing a class
statement. Class objects are used as templates to create instance
objects, which embody both the data (attributes) and code (methods)
specific to a datatype.

A class can be based on one or more other classes, called its base
class(es). It then inherits the attributes and methods of its base
classes. This allows an object model to be successively refined by
inheritance.  You might have a generic ``Mailbox`` class that provides
basic accessor methods for a mailbox, and subclasses such as
``MboxMailbox``, ``MaildirMailbox``, ``OutlookMailbox`` that handle
various specific mailbox formats.


What is a method?
-----------------

A method is a function on some object ``x`` that you normally call as
``x.name(arguments...)``.  Methods are defined as functions inside the
class definition:

   class C:
       def meth (self, arg):
           return arg * 2 + self.attribute


What is self?
-------------

Self is merely a conventional name for the first argument of a method.
A method defined as ``meth(self, a, b, c)`` should be called as
``x.meth(a, b, c)`` for some instance ``x`` of the class in which the
definition occurs; the called method will think it is called as
``meth(x, a, b, c)``.

See also *Why must 'self' be used explicitly in method definitions and
calls?*.


How do I check if an object is an instance of a given class or of a subclass of it?
-----------------------------------------------------------------------------------

Use the built-in function ``isinstance(obj, cls)``.  You can check if
an object is an instance of any of a number of classes by providing a
tuple instead of a single class, e.g. ``isinstance(obj, (class1,
class2, ...))``, and can also check whether an object is one of
Python's built-in types, e.g. ``isinstance(obj, str)`` or
``isinstance(obj, (int, long, float, complex))``.

Note that most programs do not use ``isinstance()`` on user-defined
classes very often.  If you are developing the classes yourself, a
more proper object-oriented style is to define methods on the classes
that encapsulate a particular behaviour, instead of checking the
object's class and doing a different thing based on what class it is.
For example, if you have a function that does something:

   def search(obj):
       if isinstance(obj, Mailbox):
           # ... code to search a mailbox
       elif isinstance(obj, Document):
           # ... code to search a document
       elif ...

A better approach is to define a ``search()`` method on all the
classes and just call it:

   class Mailbox:
       def search(self):
           # ... code to search a mailbox

   class Document:
       def search(self):
           # ... code to search a document

   obj.search()


What is delegation?
-------------------

Delegation is an object oriented technique (also called a design
pattern). Let's say you have an object ``x`` and want to change the
behaviour of just one of its methods.  You can create a new class that
provides a new implementation of the method you're interested in
changing and delegates all other methods to the corresponding method
of ``x``.

Python programmers can easily implement delegation.  For example, the
following class implements a class that behaves like a file but
converts all written data to uppercase:

   class UpperOut:

       def __init__(self, outfile):
           self._outfile = outfile

       def write(self, s):
           self._outfile.write(s.upper())

       def __getattr__(self, name):
           return getattr(self._outfile, name)

Here the ``UpperOut`` class redefines the ``write()`` method to
convert the argument string to uppercase before calling the underlying
``self.__outfile.write()`` method.  All other methods are delegated to
the underlying ``self.__outfile`` object.  The delegation is
accomplished via the ``__getattr__`` method; consult *the language
reference* for more information about controlling attribute access.

Note that for more general cases delegation can get trickier. When
attributes must be set as well as retrieved, the class must define a
``__setattr__()`` method too, and it must do so carefully.  The basic
implementation of ``__setattr__()`` is roughly equivalent to the
following:

   class X:
       ...
       def __setattr__(self, name, value):
           self.__dict__[name] = value
       ...

Most ``__setattr__()`` implementations must modify ``self.__dict__``
to store local state for self without causing an infinite recursion.


How do I call a method defined in a base class from a derived class that overrides it?
--------------------------------------------------------------------------------------

If you're using new-style classes, use the built-in ``super()``
function:

   class Derived(Base):
       def meth (self):
           super(Derived, self).meth()

If you're using classic classes: For a class definition such as
``class Derived(Base): ...`` you can call method ``meth()`` defined in
``Base`` (or one of ``Base``'s base classes) as ``Base.meth(self,
arguments...)``.  Here, ``Base.meth`` is an unbound method, so you
need to provide the ``self`` argument.


How can I organize my code to make it easier to change the base class?
----------------------------------------------------------------------

You could define an alias for the base class, assign the real base
class to it before your class definition, and use the alias throughout
your class.  Then all you have to change is the value assigned to the
alias.  Incidentally, this trick is also handy if you want to decide
dynamically (e.g. depending on availability of resources) which base
class to use.  Example:

   BaseAlias = <real base class>

   class Derived(BaseAlias):
       def meth(self):
           BaseAlias.meth(self)
           ...


How do I create static class data and static class methods?
-----------------------------------------------------------

Both static data and static methods (in the sense of C++ or Java) are
supported in Python.

For static data, simply define a class attribute.  To assign a new
value to the attribute, you have to explicitly use the class name in
the assignment:

   class C:
       count = 0   # number of times C.__init__ called

       def __init__(self):
           C.count = C.count + 1

       def getcount(self):
           return C.count  # or return self.count

``c.count`` also refers to ``C.count`` for any ``c`` such that
``isinstance(c, C)`` holds, unless overridden by ``c`` itself or by
some class on the base-class search path from ``c.__class__`` back to
``C``.

Caution: within a method of C, an assignment like ``self.count = 42``
creates a new and unrelated instance named "count" in ``self``'s own
dict.  Rebinding of a class-static data name must always specify the
class whether inside a method or not:

   C.count = 314

Static methods are possible since Python 2.2:

   class C:
       def static(arg1, arg2, arg3):
           # No 'self' parameter!
           ...
       static = staticmethod(static)

With Python 2.4's decorators, this can also be written as

   class C:
       @staticmethod
       def static(arg1, arg2, arg3):
           # No 'self' parameter!
           ...

However, a far more straightforward way to get the effect of a static
method is via a simple module-level function:

   def getcount():
       return C.count

If your code is structured so as to define one class (or tightly
related class hierarchy) per module, this supplies the desired
encapsulation.


How can I overload constructors (or methods) in Python?
-------------------------------------------------------

This answer actually applies to all methods, but the question usually
comes up first in the context of constructors.

In C++ you'd write

   class C {
       C() { cout << "No arguments\n"; }
       C(int i) { cout << "Argument is " << i << "\n"; }
   }

In Python you have to write a single constructor that catches all
cases using default arguments.  For example:

   class C:
       def __init__(self, i=None):
           if i is None:
               print "No arguments"
           else:
               print "Argument is", i

This is not entirely equivalent, but close enough in practice.

You could also try a variable-length argument list, e.g.

   def __init__(self, *args):
       ...

The same approach works for all method definitions.


I try to use __spam and I get an error about _SomeClassName__spam.
------------------------------------------------------------------

Variable names with double leading underscores are "mangled" to
provide a simple but effective way to define class private variables.
Any identifier of the form ``__spam`` (at least two leading
underscores, at most one trailing underscore) is textually replaced
with ``_classname__spam``, where ``classname`` is the current class
name with any leading underscores stripped.

This doesn't guarantee privacy: an outside user can still deliberately
access the "_classname__spam" attribute, and private values are
visible in the object's ``__dict__``.  Many Python programmers never
bother to use private variable names at all.


My class defines __del__ but it is not called when I delete the object.
-----------------------------------------------------------------------

There are several possible reasons for this.

The del statement does not necessarily call ``__del__()`` -- it simply
decrements the object's reference count, and if this reaches zero
``__del__()`` is called.

If your data structures contain circular links (e.g. a tree where each
child has a parent reference and each parent has a list of children)
the reference counts will never go back to zero.  Once in a while
Python runs an algorithm to detect such cycles, but the garbage
collector might run some time after the last reference to your data
structure vanishes, so your ``__del__()`` method may be called at an
inconvenient and random time. This is inconvenient if you're trying to
reproduce a problem. Worse, the order in which object's ``__del__()``
methods are executed is arbitrary.  You can run ``gc.collect()`` to
force a collection, but there *are* pathological cases where objects
will never be collected.

Despite the cycle collector, it's still a good idea to define an
explicit ``close()`` method on objects to be called whenever you're
done with them.  The ``close()`` method can then remove attributes
that refer to subobjecs.  Don't call ``__del__()`` directly --
``__del__()`` should call ``close()`` and ``close()`` should make sure
that it can be called more than once for the same object.

Another way to avoid cyclical references is to use the ``weakref``
module, which allows you to point to objects without incrementing
their reference count. Tree data structures, for instance, should use
weak references for their parent and sibling references (if they need
them!).

If the object has ever been a local variable in a function that caught
an expression in an except clause, chances are that a reference to the
object still exists in that function's stack frame as contained in the
stack trace. Normally, calling ``sys.exc_clear()`` will take care of
this by clearing the last recorded exception.

Finally, if your ``__del__()`` method raises an exception, a warning
message is printed to ``sys.stderr``.


How do I get a list of all instances of a given class?
------------------------------------------------------

Python does not keep track of all instances of a class (or of a built-
in type). You can program the class's constructor to keep track of all
instances by keeping a list of weak references to each instance.


Why does the result of ``id()`` appear to be not unique?
--------------------------------------------------------

The ``id()`` builtin returns an integer that is guaranteed to be
unique during the lifetime of the object.  Since in CPython, this is
the object's memory address, it happens frequently that after an
object is deleted from memory, the next freshly created object is
allocated at the same position in memory.  This is illustrated by this
example:

>>> id(1000)
13901272
>>> id(2000)
13901272

The two ids belong to different integer objects that are created
before, and deleted immediately after execution of the ``id()`` call.
To be sure that objects whose id you want to examine are still alive,
create another reference to the object:

>>> a = 1000; b = 2000
>>> id(a)
13901272
>>> id(b)
13891296


Modules
=======


How do I create a .pyc file?
----------------------------

When a module is imported for the first time (or when the source is
more recent than the current compiled file) a ``.pyc`` file containing
the compiled code should be created in the same directory as the
``.py`` file.

One reason that a ``.pyc`` file may not be created is permissions
problems with the directory. This can happen, for example, if you
develop as one user but run as another, such as if you are testing
with a web server.  Creation of a .pyc file is automatic if you're
importing a module and Python has the ability (permissions, free
space, etc...) to write the compiled module back to the directory.

Running Python on a top level script is not considered an import and
no ``.pyc`` will be created.  For example, if you have a top-level
module ``foo.py`` that imports another module ``xyz.py``, when you run
``foo``, ``xyz.pyc`` will be created since ``xyz`` is imported, but no
``foo.pyc`` file will be created since ``foo.py`` isn't being
imported.

If you need to create ``foo.pyc`` -- that is, to create a ``.pyc``
file for a module that is not imported -- you can, using the
``py_compile`` and ``compileall`` modules.

The ``py_compile`` module can manually compile any module.  One way is
to use the ``compile()`` function in that module interactively:

   >>> import py_compile
   >>> py_compile.compile('foo.py')                 # doctest: +SKIP

This will write the ``.pyc`` to the same location as ``foo.py`` (or
you can override that with the optional parameter ``cfile``).

You can also automatically compile all files in a directory or
directories using the ``compileall`` module.  You can do it from the
shell prompt by running ``compileall.py`` and providing the path of a
directory containing Python files to compile:

   python -m compileall .


How do I find the current module name?
--------------------------------------

A module can find out its own module name by looking at the predefined
global variable ``__name__``.  If this has the value ``'__main__'``,
the program is running as a script.  Many modules that are usually
used by importing them also provide a command-line interface or a
self-test, and only execute this code after checking ``__name__``:

   def main():
       print 'Running test...'
       ...

   if __name__ == '__main__':
       main()


How can I have modules that mutually import each other?
-------------------------------------------------------

Suppose you have the following modules:

foo.py:

   from bar import bar_var
   foo_var = 1

bar.py:

   from foo import foo_var
   bar_var = 2

The problem is that the interpreter will perform the following steps:

* main imports foo

* Empty globals for foo are created

* foo is compiled and starts executing

* foo imports bar

* Empty globals for bar are created

* bar is compiled and starts executing

* bar imports foo (which is a no-op since there already is a module
  named foo)

* bar.foo_var = foo.foo_var

The last step fails, because Python isn't done with interpreting
``foo`` yet and the global symbol dictionary for ``foo`` is still
empty.

The same thing happens when you use ``import foo``, and then try to
access ``foo.foo_var`` in global code.

There are (at least) three possible workarounds for this problem.

Guido van Rossum recommends avoiding all uses of ``from <module>
import ...``, and placing all code inside functions.  Initializations
of global variables and class variables should use constants or built-
in functions only.  This means everything from an imported module is
referenced as ``<module>.<name>``.

Jim Roskind suggests performing steps in the following order in each
module:

* exports (globals, functions, and classes that don't need imported
  base classes)

* ``import`` statements

* active code (including globals that are initialized from imported
  values).

van Rossum doesn't like this approach much because the imports appear
in a strange place, but it does work.

Matthias Urlichs recommends restructuring your code so that the
recursive import is not necessary in the first place.

These solutions are not mutually exclusive.


__import__('x.y.z') returns <module 'x'>; how do I get z?
---------------------------------------------------------

Try:

   __import__('x.y.z').y.z

For more realistic situations, you may have to do something like

   m = __import__(s)
   for i in s.split(".")[1:]:
       m = getattr(m, i)

See ``importlib`` for a convenience function called
``import_module()``.


When I edit an imported module and reimport it, the changes don't show up.  Why does this happen?
-------------------------------------------------------------------------------------------------

For reasons of efficiency as well as consistency, Python only reads
the module file on the first time a module is imported.  If it didn't,
in a program consisting of many modules where each one imports the
same basic module, the basic module would be parsed and re-parsed many
times.  To force rereading of a changed module, do this:

   import modname
   reload(modname)

Warning: this technique is not 100% fool-proof.  In particular,
modules containing statements like

   from modname import some_objects

will continue to work with the old version of the imported objects.
If the module contains class definitions, existing class instances
will *not* be updated to use the new class definition.  This can
result in the following paradoxical behaviour:

>>> import cls
>>> c = cls.C()                # Create an instance of C
>>> reload(cls)
<module 'cls' from 'cls.pyc'>
>>> isinstance(c, cls.C)       # isinstance is false?!?
False

The nature of the problem is made clear if you print out the class
objects:

>>> c.__class__
<class cls.C at 0x7352a0>
>>> cls.C
<class cls.C at 0x4198d0>
