| :tocdepth: 2 |
| |
| =============== |
| Programming FAQ |
| =============== |
| |
| .. only:: html |
| |
| .. contents:: |
| |
| 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 :mod:`documented in the Library |
| Reference Manual <pdb>`. 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 <http://sourceforge.net/projects/pywin32/>`__ project and |
| as a part of the ActivePython distribution (see |
| http://www.activestate.com/Products/ActivePython/index.html). |
| |
| `Boa Constructor <http://boa-constructor.sourceforge.net/>`_ 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 <http://www.die-offenbachs.de/eric/index.html>`_ 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 <http://www.logilab.org/projects/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 <http://starship.python.net/crew/pirx>`_ |
| 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 |
| <http://www.pythonware.com/products/python/squeeze>`_ and Anthony Tuininga's |
| `cx_Freeze <http://starship.python.net/crew/atuining/cx_Freeze/index.html>`_. |
| |
| |
| 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`. |
| |
| |
| 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 |
| |
| You can do a similar thing in a nested scope using the :keyword:`nonlocal` |
| keyword: |
| |
| >>> def foo(): |
| ... x = 10 |
| ... def bar(): |
| ... nonlocal x |
| ... print(x) |
| ... x += 1 |
| ... bar() |
| ... print(x) |
| >>> foo() |
| 10 |
| 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 :keyword:`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 :mod:`tkinter`, and :mod:`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 ``from . import m2``, even though it's legal. Write ``from package.sub |
| import m2`` instead. 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 :data:`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) |
| |
| |
| .. index:: |
| single: argument; difference from parameter |
| single: parameter; difference from argument |
| |
| .. _faq-argument-vs-parameter: |
| |
| What is the difference between arguments and parameters? |
| -------------------------------------------------------- |
| |
| :term:`Parameters <parameter>` are defined by the names that appear in a |
| function definition, whereas :term:`arguments <argument>` 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 :func:`copy.copy` or :func:`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 :meth:`~dict.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 object at 0x16D07CC> |
| print(a) |
| <__main__.A object 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, there is. The syntax is as follows:: |
| |
| [on_true] if [expression] else [on_false] |
| |
| x, y = 50, 25 |
| small = x if x < y else y |
| |
| Before this syntax was introduced in Python 2.5, a common idiom was to use |
| logical operators:: |
| |
| [expression] and [on_true] or [on_false] |
| |
| However, this idiom is unsafe, as it can give wrong results when *on_true* |
| has a false boolean value. Therefore, it is always better to use |
| the ``... if ... else ...`` form. |
| |
| |
| Is it possible to write obfuscated one-liners in Python? |
| -------------------------------------------------------- |
| |
| Yes. Usually this is done by nesting :keyword:`lambda` within |
| :keyword:`lambda`. See the following three examples, due to Ulf Bartelt:: |
| |
| from functools import reduce |
| |
| # Primes < 1000 |
| print(list(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(list(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. |
| |
| |
| How do I convert a string to a number? |
| -------------------------------------- |
| |
| For integers, use the built-in :func:`int` type constructor, e.g. ``int('144') |
| == 144``. Similarly, :func:`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 :exc:`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 :func:`eval` if all you need is to convert |
| strings to numbers. :func:`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. |
| |
| :func:`eval` also has the effect of interpreting numbers as Python expressions, |
| so that e.g. ``eval('09')`` gives a syntax error because Python does not allow |
| leading '0' in a decimal number (except '0'). |
| |
| |
| 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 :func:`str`. If you want a hexadecimal or octal representation, use |
| the built-in functions :func:`hex` or :func:`oct`. For fancy formatting, see |
| the :ref:`string-formatting` section, e.g. ``"{:04d}".format(144)`` yields |
| ``'0144'`` and ``"{:.3f}".format(1/3)`` yields ``'0.333'``. |
| |
| |
| How do I modify a string in place? |
| ---------------------------------- |
| |
| You can't, because strings are immutable. In most situations, you should |
| simply construct a new string from the various parts you want to assemble |
| it from. However, if you need an object with the ability to modify in-place |
| unicode data, try using a :class:`io.StringIO` object or the :mod:`array` |
| module:: |
| |
| >>> import io |
| >>> s = "Hello, world" |
| >>> sio = io.StringIO(s) |
| >>> sio.getvalue() |
| 'Hello, world' |
| >>> sio.seek(7) |
| 7 |
| >>> sio.write("there!") |
| 6 |
| >>> sio.getvalue() |
| 'Hello, there!' |
| |
| >>> import array |
| >>> a = array.array('u', s) |
| >>> print(a) |
| array('u', 'Hello, world') |
| >>> a[0] = 'y' |
| >>> print(a) |
| array('u', 'yello, world') |
| >>> a.tounicode() |
| '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 :func:`getattr`:: |
| |
| import foo |
| getattr(foo, 'bar')() |
| |
| Note that :func:`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 :func:`locals` or :func:`eval` to resolve the function name:: |
| |
| def myFunc(): |
| print("hello") |
| |
| fname = "myFunc" |
| |
| f = locals()[fname] |
| f() |
| |
| f = eval(fname) |
| f() |
| |
| Note: Using :func:`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? |
| ------------------------------------------------------------------------------------- |
| |
| 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. |
| |
| |
| 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 :meth:`~str.split` method of string objects |
| and then convert decimal strings to numeric values using :func:`int` or |
| :func:`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 :c:func:`sscanf` and better suited for the task. |
| |
| |
| What does 'UnicodeDecodeError' or 'UnicodeEncodeError' error mean? |
| ------------------------------------------------------------------- |
| |
| See the :ref:`unicode-howto`. |
| |
| |
| Performance |
| =========== |
| |
| My program is too slow. How do I speed it up? |
| --------------------------------------------- |
| |
| That's a tough one, in general. First, here are a list of things to |
| remember before diving further: |
| |
| * Performance characteristics vary across Python implementations. This FAQ |
| focusses on :term:`CPython`. |
| * Behaviour can vary across operating systems, especially when talking about |
| I/O or multi-threading. |
| * You should always find the hot spots in your program *before* attempting to |
| optimize any code (see the :mod:`profile` module). |
| * Writing benchmark scripts will allow you to iterate quickly when searching |
| for improvements (see the :mod:`timeit` module). |
| * It is highly recommended to have good code coverage (through unit testing |
| or any other technique) before potentially introducing regressions hidden |
| in sophisticated optimizations. |
| |
| That being said, there are many tricks to speed up Python code. Here are |
| some general principles which go a long way towards reaching acceptable |
| performance levels: |
| |
| * Making your algorithms faster (or changing to faster ones) can yield |
| much larger benefits than trying to sprinkle micro-optimization tricks |
| all over your code. |
| |
| * Use the right data structures. Study documentation for the :ref:`bltin-types` |
| and the :mod:`collections` module. |
| |
| * When the standard library provides a primitive for doing something, it is |
| likely (although not guaranteed) to be faster than any alternative you |
| may come up with. This is doubly true for primitives written in C, such |
| as builtins and some extension types. For example, be sure to use |
| either the :meth:`list.sort` built-in method or the related :func:`sorted` |
| function to do sorting (and see the |
| `sorting mini-HOWTO <http://wiki.python.org/moin/HowTo/Sorting>`_ for examples |
| of moderately advanced usage). |
| |
| * Abstractions tend to create indirections and force the interpreter to work |
| more. If the levels of indirection outweigh the amount of useful work |
| done, your program will be slower. You should avoid excessive abstraction, |
| especially under the form of tiny functions or methods (which are also often |
| detrimental to readability). |
| |
| If you have reached the limit of what pure Python can allow, there are tools |
| to take you further away. For example, `Cython <http://cython.org>`_ can |
| compile a slightly modified version of Python code into a C extension, and |
| can be used on many different platforms. Cython can take advantage of |
| compilation (and optional type annotations) to make your code significantly |
| faster than when interpreted. If you are confident in your C programming |
| skills, you can also :ref:`write a C extension module <extending-index>` |
| yourself. |
| |
| .. seealso:: |
| The wiki page devoted to `performance tips |
| <http://wiki.python.org/moin/PythonSpeed/PerformanceTips>`_. |
| |
| .. _efficient_string_concatenation: |
| |
| What is the most efficient way to concatenate many strings together? |
| -------------------------------------------------------------------- |
| |
| :class:`str` and :class:`bytes` objects are immutable, therefore concatenating |
| many strings together is inefficient as each concatenation creates a new |
| object. In the general case, the total runtime cost is quadratic in the |
| total string length. |
| |
| To accumulate many :class:`str` objects, the recommended idiom is to place |
| them into a list and call :meth:`str.join` at the end:: |
| |
| chunks = [] |
| for s in my_strings: |
| chunks.append(s) |
| result = ''.join(chunks) |
| |
| (another reasonably efficient idiom is to use :class:`io.StringIO`) |
| |
| To accumulate many :class:`bytes` objects, the recommended idiom is to extend |
| a :class:`bytearray` object using in-place concatenation (the ``+=`` operator):: |
| |
| result = bytearray() |
| for b in my_bytes_objects: |
| result += b |
| |
| |
| 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 :func:`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 :func:`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 set keys (i.e. they are all |
| :term:`hashable`) this is often faster :: |
| |
| 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 |
| <http://www.numpy.org/>`_ 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] |
| |
| |
| 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] |
| |
| For versions prior to 3.0, 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 an iterator 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 = sorted(pairs) |
| >>> pairs |
| [("I'm", 'else'), ('by', 'sort'), ('sorting', 'to'), ('what', 'something')] |
| >>> 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 :ref:`why-self`. |
| |
| |
| 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, float, complex))``. |
| |
| Note that most programs do not use :func:`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 :ref:`the language reference <attribute-access>` |
| 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 :meth:`__setattr__` |
| method too, and it must do so carefully. The basic implementation of |
| :meth:`__setattr__` is roughly equivalent to the following:: |
| |
| class X: |
| ... |
| def __setattr__(self, name, value): |
| self.__dict__[name] = value |
| ... |
| |
| Most :meth:`__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? |
| -------------------------------------------------------------------------------------- |
| |
| Use the built-in :func:`super` function:: |
| |
| class Derived(Base): |
| def meth (self): |
| super(Derived, self).meth() |
| |
| For version prior to 3.0, you may be 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:: |
| |
| 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 |
| |
| .. code-block:: c |
| |
| 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 :meth:`__del__` -- it simply |
| decrements the object's reference count, and if this reaches zero |
| :meth:`__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 :meth:`__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 :meth:`__del__` |
| methods are executed is arbitrary. You can run :func:`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 :meth:`__del__` directly -- :meth:`__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 :mod:`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!). |
| |
| .. XXX relevant for Python 3? |
| |
| 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 :func:`sys.exc_clear` will take care of this by clearing |
| the last recorded exception. |
| |
| Finally, if your :meth:`__del__` method raises an exception, a warning message |
| is printed to :data:`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. |
| |
| |
| 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 :mod:`py_compile` and |
| :mod:`compileall` modules. |
| |
| The :mod:`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 :mod:`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 :mod:`importlib` for a convenience function called |
| :func:`~importlib.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 imp |
| import modname |
| imp.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 imp |
| >>> import cls |
| >>> c = cls.C() # Create an instance of C |
| >>> imp.reload(cls) |
| <module 'cls' from 'cls.py'> |
| >>> isinstance(c, cls.C) # isinstance is false?!? |
| False |
| |
| The nature of the problem is made clear if you print out the "identity" of the |
| class objects: |
| |
| >>> hex(id(c.__class__)) |
| '0x7352a0' |
| >>> hex(id(cls.C)) |
| '0x4198d0' |