mirror of https://github.com/python/cpython
774 lines
33 KiB
ReStructuredText
774 lines
33 KiB
ReStructuredText
======================
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Design and History FAQ
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======================
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.. only:: html
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.. contents::
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Why does Python use indentation for grouping of statements?
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-----------------------------------------------------------
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Guido van Rossum believes that using indentation for grouping is extremely
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elegant and contributes a lot to the clarity of the average Python program.
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Most people learn to love this feature after a while.
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Since there are no begin/end brackets there cannot be a disagreement between
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grouping perceived by the parser and the human reader. Occasionally C
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programmers will encounter a fragment of code like this::
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if (x <= y)
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x++;
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y--;
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z++;
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Only the ``x++`` statement is executed if the condition is true, but the
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indentation leads many to believe otherwise. Even experienced C programmers will
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sometimes stare at it a long time wondering as to why ``y`` is being decremented even
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for ``x > y``.
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Because there are no begin/end brackets, Python is much less prone to
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coding-style conflicts. In C there are many different ways to place the braces.
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After becoming used to reading and writing code using a particular style,
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it is normal to feel somewhat uneasy when reading (or being required to write)
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in a different one.
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Many coding styles place begin/end brackets on a line by themselves. This makes
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programs considerably longer and wastes valuable screen space, making it harder
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to get a good overview of a program. Ideally, a function should fit on one
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screen (say, 20--30 lines). 20 lines of Python can do a lot more work than 20
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lines of C. This is not solely due to the lack of begin/end brackets -- the
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lack of declarations and the high-level data types are also responsible -- but
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the indentation-based syntax certainly helps.
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Why am I getting strange results with simple arithmetic operations?
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-------------------------------------------------------------------
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See the next question.
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Why are floating-point calculations so inaccurate?
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--------------------------------------------------
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Users are often surprised by results like this::
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>>> 1.2 - 1.0
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0.19999999999999996
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and think it is a bug in Python. It's not. This has little to do with Python,
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and much more to do with how the underlying platform handles floating-point
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numbers.
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The :class:`float` type in CPython uses a C ``double`` for storage. A
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:class:`float` object's value is stored in binary floating-point with a fixed
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precision (typically 53 bits) and Python uses C operations, which in turn rely
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on the hardware implementation in the processor, to perform floating-point
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operations. This means that as far as floating-point operations are concerned,
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Python behaves like many popular languages including C and Java.
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Many numbers that can be written easily in decimal notation cannot be expressed
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exactly in binary floating-point. For example, after::
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>>> x = 1.2
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the value stored for ``x`` is a (very good) approximation to the decimal value
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``1.2``, but is not exactly equal to it. On a typical machine, the actual
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stored value is::
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1.0011001100110011001100110011001100110011001100110011 (binary)
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which is exactly::
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1.1999999999999999555910790149937383830547332763671875 (decimal)
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The typical precision of 53 bits provides Python floats with 15--16
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decimal digits of accuracy.
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For a fuller explanation, please see the :ref:`floating point arithmetic
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<tut-fp-issues>` chapter in the Python tutorial.
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Why are Python strings immutable?
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---------------------------------
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There are several advantages.
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One is performance: knowing that a string is immutable means we can allocate
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space for it at creation time, and the storage requirements are fixed and
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unchanging. This is also one of the reasons for the distinction between tuples
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and lists.
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Another advantage is that strings in Python are considered as "elemental" as
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numbers. No amount of activity will change the value 8 to anything else, and in
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Python, no amount of activity will change the string "eight" to anything else.
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.. _why-self:
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Why must 'self' be used explicitly in method definitions and calls?
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-------------------------------------------------------------------
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The idea was borrowed from Modula-3. It turns out to be very useful, for a
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variety of reasons.
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First, it's more obvious that you are using a method or instance attribute
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instead of a local variable. Reading ``self.x`` or ``self.meth()`` makes it
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absolutely clear that an instance variable or method is used even if you don't
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know the class definition by heart. In C++, you can sort of tell by the lack of
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a local variable declaration (assuming globals are rare or easily recognizable)
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-- but in Python, there are no local variable declarations, so you'd have to
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look up the class definition to be sure. Some C++ and Java coding standards
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call for instance attributes to have an ``m_`` prefix, so this explicitness is
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still useful in those languages, too.
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Second, it means that no special syntax is necessary if you want to explicitly
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reference or call the method from a particular class. In C++, if you want to
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use a method from a base class which is overridden in a derived class, you have
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to use the ``::`` operator -- in Python you can write
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``baseclass.methodname(self, <argument list>)``. This is particularly useful
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for :meth:`__init__` methods, and in general in cases where a derived class
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method wants to extend the base class method of the same name and thus has to
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call the base class method somehow.
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Finally, for instance variables it solves a syntactic problem with assignment:
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since local variables in Python are (by definition!) those variables to which a
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value is assigned in a function body (and that aren't explicitly declared
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global), there has to be some way to tell the interpreter that an assignment was
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meant to assign to an instance variable instead of to a local variable, and it
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should preferably be syntactic (for efficiency reasons). C++ does this through
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declarations, but Python doesn't have declarations and it would be a pity having
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to introduce them just for this purpose. Using the explicit ``self.var`` solves
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this nicely. Similarly, for using instance variables, having to write
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``self.var`` means that references to unqualified names inside a method don't
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have to search the instance's directories. To put it another way, local
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variables and instance variables live in two different namespaces, and you need
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to tell Python which namespace to use.
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.. _why-can-t-i-use-an-assignment-in-an-expression:
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Why can't I use an assignment in an expression?
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-----------------------------------------------
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Starting in Python 3.8, you can!
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Assignment expressions using the walrus operator `:=` assign a variable in an
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expression::
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while chunk := fp.read(200):
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print(chunk)
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See :pep:`572` for more information.
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Why does Python use methods for some functionality (e.g. list.index()) but functions for other (e.g. len(list))?
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----------------------------------------------------------------------------------------------------------------
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As Guido said:
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(a) For some operations, prefix notation just reads better than
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postfix -- prefix (and infix!) operations have a long tradition in
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mathematics which likes notations where the visuals help the
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mathematician thinking about a problem. Compare the easy with which we
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rewrite a formula like x*(a+b) into x*a + x*b to the clumsiness of
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doing the same thing using a raw OO notation.
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(b) When I read code that says len(x) I *know* that it is asking for
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the length of something. This tells me two things: the result is an
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integer, and the argument is some kind of container. To the contrary,
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when I read x.len(), I have to already know that x is some kind of
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container implementing an interface or inheriting from a class that
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has a standard len(). Witness the confusion we occasionally have when
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a class that is not implementing a mapping has a get() or keys()
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method, or something that isn't a file has a write() method.
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-- https://mail.python.org/pipermail/python-3000/2006-November/004643.html
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Why is join() a string method instead of a list or tuple method?
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----------------------------------------------------------------
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Strings became much more like other standard types starting in Python 1.6, when
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methods were added which give the same functionality that has always been
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available using the functions of the string module. Most of these new methods
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have been widely accepted, but the one which appears to make some programmers
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feel uncomfortable is::
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", ".join(['1', '2', '4', '8', '16'])
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which gives the result::
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"1, 2, 4, 8, 16"
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There are two common arguments against this usage.
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The first runs along the lines of: "It looks really ugly using a method of a
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string literal (string constant)", to which the answer is that it might, but a
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string literal is just a fixed value. If the methods are to be allowed on names
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bound to strings there is no logical reason to make them unavailable on
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literals.
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The second objection is typically cast as: "I am really telling a sequence to
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join its members together with a string constant". Sadly, you aren't. For some
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reason there seems to be much less difficulty with having :meth:`~str.split` as
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a string method, since in that case it is easy to see that ::
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"1, 2, 4, 8, 16".split(", ")
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is an instruction to a string literal to return the substrings delimited by the
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given separator (or, by default, arbitrary runs of white space).
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:meth:`~str.join` is a string method because in using it you are telling the
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separator string to iterate over a sequence of strings and insert itself between
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adjacent elements. This method can be used with any argument which obeys the
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rules for sequence objects, including any new classes you might define yourself.
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Similar methods exist for bytes and bytearray objects.
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How fast are exceptions?
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------------------------
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A try/except block is extremely efficient if no exceptions are raised. Actually
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catching an exception is expensive. In versions of Python prior to 2.0 it was
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common to use this idiom::
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try:
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value = mydict[key]
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except KeyError:
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mydict[key] = getvalue(key)
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value = mydict[key]
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This only made sense when you expected the dict to have the key almost all the
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time. If that wasn't the case, you coded it like this::
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if key in mydict:
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value = mydict[key]
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else:
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value = mydict[key] = getvalue(key)
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For this specific case, you could also use ``value = dict.setdefault(key,
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getvalue(key))``, but only if the ``getvalue()`` call is cheap enough because it
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is evaluated in all cases.
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Why isn't there a switch or case statement in Python?
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-----------------------------------------------------
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You can do this easily enough with a sequence of ``if... elif... elif... else``.
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For literal values, or constants within a namespace, you can also use a
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``match ... case`` statement.
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For cases where you need to choose from a very large number of possibilities,
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you can create a dictionary mapping case values to functions to call. For
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example::
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functions = {'a': function_1,
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'b': function_2,
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'c': self.method_1}
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func = functions[value]
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func()
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For calling methods on objects, you can simplify yet further by using the
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:func:`getattr` built-in to retrieve methods with a particular name::
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class MyVisitor:
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def visit_a(self):
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...
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def dispatch(self, value):
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method_name = 'visit_' + str(value)
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method = getattr(self, method_name)
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method()
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It's suggested that you use a prefix for the method names, such as ``visit_`` in
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this example. Without such a prefix, if values are coming from an untrusted
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source, an attacker would be able to call any method on your object.
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Can't you emulate threads in the interpreter instead of relying on an OS-specific thread implementation?
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--------------------------------------------------------------------------------------------------------
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Answer 1: Unfortunately, the interpreter pushes at least one C stack frame for
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each Python stack frame. Also, extensions can call back into Python at almost
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random moments. Therefore, a complete threads implementation requires thread
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support for C.
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Answer 2: Fortunately, there is `Stackless Python <https://github.com/stackless-dev/stackless/wiki>`_,
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which has a completely redesigned interpreter loop that avoids the C stack.
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Why can't lambda expressions contain statements?
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------------------------------------------------
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Python lambda expressions cannot contain statements because Python's syntactic
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framework can't handle statements nested inside expressions. However, in
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Python, this is not a serious problem. Unlike lambda forms in other languages,
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where they add functionality, Python lambdas are only a shorthand notation if
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you're too lazy to define a function.
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Functions are already first class objects in Python, and can be declared in a
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local scope. Therefore the only advantage of using a lambda instead of a
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locally-defined function is that you don't need to invent a name for the
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function -- but that's just a local variable to which the function object (which
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is exactly the same type of object that a lambda expression yields) is assigned!
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Can Python be compiled to machine code, C or some other language?
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-----------------------------------------------------------------
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`Cython <http://cython.org/>`_ compiles a modified version of Python with
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optional annotations into C extensions. `Nuitka <http://www.nuitka.net/>`_ is
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an up-and-coming compiler of Python into C++ code, aiming to support the full
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Python language. For compiling to Java you can consider
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`VOC <https://voc.readthedocs.io>`_.
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How does Python manage memory?
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------------------------------
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The details of Python memory management depend on the implementation. The
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standard implementation of Python, :term:`CPython`, uses reference counting to
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detect inaccessible objects, and another mechanism to collect reference cycles,
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periodically executing a cycle detection algorithm which looks for inaccessible
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cycles and deletes the objects involved. The :mod:`gc` module provides functions
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to perform a garbage collection, obtain debugging statistics, and tune the
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collector's parameters.
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Other implementations (such as `Jython <http://www.jython.org>`_ or
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`PyPy <http://www.pypy.org>`_), however, can rely on a different mechanism
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such as a full-blown garbage collector. This difference can cause some
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subtle porting problems if your Python code depends on the behavior of the
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reference counting implementation.
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In some Python implementations, the following code (which is fine in CPython)
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will probably run out of file descriptors::
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for file in very_long_list_of_files:
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f = open(file)
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c = f.read(1)
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Indeed, using CPython's reference counting and destructor scheme, each new
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assignment to *f* closes the previous file. With a traditional GC, however,
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those file objects will only get collected (and closed) at varying and possibly
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long intervals.
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If you want to write code that will work with any Python implementation,
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you should explicitly close the file or use the :keyword:`with` statement;
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this will work regardless of memory management scheme::
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for file in very_long_list_of_files:
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with open(file) as f:
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c = f.read(1)
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Why doesn't CPython use a more traditional garbage collection scheme?
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---------------------------------------------------------------------
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For one thing, this is not a C standard feature and hence it's not portable.
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(Yes, we know about the Boehm GC library. It has bits of assembler code for
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*most* common platforms, not for all of them, and although it is mostly
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transparent, it isn't completely transparent; patches are required to get
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Python to work with it.)
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Traditional GC also becomes a problem when Python is embedded into other
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applications. While in a standalone Python it's fine to replace the standard
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malloc() and free() with versions provided by the GC library, an application
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embedding Python may want to have its *own* substitute for malloc() and free(),
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and may not want Python's. Right now, CPython works with anything that
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implements malloc() and free() properly.
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Why isn't all memory freed when CPython exits?
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----------------------------------------------
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Objects referenced from the global namespaces of Python modules are not always
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deallocated when Python exits. This may happen if there are circular
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references. There are also certain bits of memory that are allocated by the C
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library that are impossible to free (e.g. a tool like Purify will complain about
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these). Python is, however, aggressive about cleaning up memory on exit and
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does try to destroy every single object.
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If you want to force Python to delete certain things on deallocation use the
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:mod:`atexit` module to run a function that will force those deletions.
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Why are there separate tuple and list data types?
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-------------------------------------------------
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Lists and tuples, while similar in many respects, are generally used in
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fundamentally different ways. Tuples can be thought of as being similar to
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Pascal records or C structs; they're small collections of related data which may
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be of different types which are operated on as a group. For example, a
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Cartesian coordinate is appropriately represented as a tuple of two or three
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numbers.
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Lists, on the other hand, are more like arrays in other languages. They tend to
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hold a varying number of objects all of which have the same type and which are
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operated on one-by-one. For example, ``os.listdir('.')`` returns a list of
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strings representing the files in the current directory. Functions which
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operate on this output would generally not break if you added another file or
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two to the directory.
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Tuples are immutable, meaning that once a tuple has been created, you can't
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replace any of its elements with a new value. Lists are mutable, meaning that
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you can always change a list's elements. Only immutable elements can be used as
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dictionary keys, and hence only tuples and not lists can be used as keys.
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How are lists implemented in CPython?
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-------------------------------------
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CPython's lists are really variable-length arrays, not Lisp-style linked lists.
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The implementation uses a contiguous array of references to other objects, and
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keeps a pointer to this array and the array's length in a list head structure.
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This makes indexing a list ``a[i]`` an operation whose cost is independent of
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the size of the list or the value of the index.
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When items are appended or inserted, the array of references is resized. Some
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cleverness is applied to improve the performance of appending items repeatedly;
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when the array must be grown, some extra space is allocated so the next few
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times don't require an actual resize.
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How are dictionaries implemented in CPython?
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--------------------------------------------
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CPython's dictionaries are implemented as resizable hash tables. Compared to
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B-trees, this gives better performance for lookup (the most common operation by
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far) under most circumstances, and the implementation is simpler.
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Dictionaries work by computing a hash code for each key stored in the dictionary
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using the :func:`hash` built-in function. The hash code varies widely depending
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on the key and a per-process seed; for example, "Python" could hash to
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-539294296 while "python", a string that differs by a single bit, could hash
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to 1142331976. The hash code is then used to calculate a location in an
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internal array where the value will be stored. Assuming that you're storing
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keys that all have different hash values, this means that dictionaries take
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constant time -- O(1), in Big-O notation -- to retrieve a key.
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Why must dictionary keys be immutable?
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--------------------------------------
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The hash table implementation of dictionaries uses a hash value calculated from
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the key value to find the key. If the key were a mutable object, its value
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could change, and thus its hash could also change. But since whoever changes
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the key object can't tell that it was being used as a dictionary key, it can't
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move the entry around in the dictionary. Then, when you try to look up the same
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object in the dictionary it won't be found because its hash value is different.
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If you tried to look up the old value it wouldn't be found either, because the
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value of the object found in that hash bin would be different.
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If you want a dictionary indexed with a list, simply convert the list to a tuple
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first; the function ``tuple(L)`` creates a tuple with the same entries as the
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list ``L``. Tuples are immutable and can therefore be used as dictionary keys.
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Some unacceptable solutions that have been proposed:
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- Hash lists by their address (object ID). This doesn't work because if you
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construct a new list with the same value it won't be found; e.g.::
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mydict = {[1, 2]: '12'}
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print(mydict[[1, 2]])
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would raise a :exc:`KeyError` exception because the id of the ``[1, 2]`` used in the
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second line differs from that in the first line. In other words, dictionary
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keys should be compared using ``==``, not using :keyword:`is`.
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- Make a copy when using a list as a key. This doesn't work because the list,
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being a mutable object, could contain a reference to itself, and then the
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copying code would run into an infinite loop.
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- Allow lists as keys but tell the user not to modify them. This would allow a
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class of hard-to-track bugs in programs when you forgot or modified a list by
|
|
accident. It also invalidates an important invariant of dictionaries: every
|
|
value in ``d.keys()`` is usable as a key of the dictionary.
|
|
|
|
- Mark lists as read-only once they are used as a dictionary key. The problem
|
|
is that it's not just the top-level object that could change its value; you
|
|
could use a tuple containing a list as a key. Entering anything as a key into
|
|
a dictionary would require marking all objects reachable from there as
|
|
read-only -- and again, self-referential objects could cause an infinite loop.
|
|
|
|
There is a trick to get around this if you need to, but use it at your own risk:
|
|
You can wrap a mutable structure inside a class instance which has both a
|
|
:meth:`__eq__` and a :meth:`__hash__` method. You must then make sure that the
|
|
hash value for all such wrapper objects that reside in a dictionary (or other
|
|
hash based structure), remain fixed while the object is in the dictionary (or
|
|
other structure). ::
|
|
|
|
class ListWrapper:
|
|
def __init__(self, the_list):
|
|
self.the_list = the_list
|
|
|
|
def __eq__(self, other):
|
|
return self.the_list == other.the_list
|
|
|
|
def __hash__(self):
|
|
l = self.the_list
|
|
result = 98767 - len(l)*555
|
|
for i, el in enumerate(l):
|
|
try:
|
|
result = result + (hash(el) % 9999999) * 1001 + i
|
|
except Exception:
|
|
result = (result % 7777777) + i * 333
|
|
return result
|
|
|
|
Note that the hash computation is complicated by the possibility that some
|
|
members of the list may be unhashable and also by the possibility of arithmetic
|
|
overflow.
|
|
|
|
Furthermore it must always be the case that if ``o1 == o2`` (ie ``o1.__eq__(o2)
|
|
is True``) then ``hash(o1) == hash(o2)`` (ie, ``o1.__hash__() == o2.__hash__()``),
|
|
regardless of whether the object is in a dictionary or not. If you fail to meet
|
|
these restrictions dictionaries and other hash based structures will misbehave.
|
|
|
|
In the case of ListWrapper, whenever the wrapper object is in a dictionary the
|
|
wrapped list must not change to avoid anomalies. Don't do this unless you are
|
|
prepared to think hard about the requirements and the consequences of not
|
|
meeting them correctly. Consider yourself warned.
|
|
|
|
|
|
Why doesn't list.sort() return the sorted list?
|
|
-----------------------------------------------
|
|
|
|
In situations where performance matters, making a copy of the list just to sort
|
|
it would be wasteful. Therefore, :meth:`list.sort` sorts the list in place. In
|
|
order to remind you of that fact, it does not return the sorted list. This way,
|
|
you won't be fooled into accidentally overwriting a list when you need a sorted
|
|
copy but also need to keep the unsorted version around.
|
|
|
|
If you want to return a new list, use the built-in :func:`sorted` function
|
|
instead. This function creates a new list from a provided iterable, sorts
|
|
it and returns it. For example, here's how to iterate over the keys of a
|
|
dictionary in sorted order::
|
|
|
|
for key in sorted(mydict):
|
|
... # do whatever with mydict[key]...
|
|
|
|
|
|
How do you specify and enforce an interface spec in Python?
|
|
-----------------------------------------------------------
|
|
|
|
An interface specification for a module as provided by languages such as C++ and
|
|
Java describes the prototypes for the methods and functions of the module. Many
|
|
feel that compile-time enforcement of interface specifications helps in the
|
|
construction of large programs.
|
|
|
|
Python 2.6 adds an :mod:`abc` module that lets you define Abstract Base Classes
|
|
(ABCs). You can then use :func:`isinstance` and :func:`issubclass` to check
|
|
whether an instance or a class implements a particular ABC. The
|
|
:mod:`collections.abc` module defines a set of useful ABCs such as
|
|
:class:`~collections.abc.Iterable`, :class:`~collections.abc.Container`, and
|
|
:class:`~collections.abc.MutableMapping`.
|
|
|
|
For Python, many of the advantages of interface specifications can be obtained
|
|
by an appropriate test discipline for components.
|
|
|
|
A good test suite for a module can both provide a regression test and serve as a
|
|
module interface specification and a set of examples. Many Python modules can
|
|
be run as a script to provide a simple "self test." Even modules which use
|
|
complex external interfaces can often be tested in isolation using trivial
|
|
"stub" emulations of the external interface. The :mod:`doctest` and
|
|
:mod:`unittest` modules or third-party test frameworks can be used to construct
|
|
exhaustive test suites that exercise every line of code in a module.
|
|
|
|
An appropriate testing discipline can help build large complex applications in
|
|
Python as well as having interface specifications would. In fact, it can be
|
|
better because an interface specification cannot test certain properties of a
|
|
program. For example, the :meth:`append` method is expected to add new elements
|
|
to the end of some internal list; an interface specification cannot test that
|
|
your :meth:`append` implementation will actually do this correctly, but it's
|
|
trivial to check this property in a test suite.
|
|
|
|
Writing test suites is very helpful, and you might want to design your code to
|
|
make it easily tested. One increasingly popular technique, test-driven
|
|
development, calls for writing parts of the test suite first, before you write
|
|
any of the actual code. Of course Python allows you to be sloppy and not write
|
|
test cases at all.
|
|
|
|
|
|
Why is there no goto?
|
|
---------------------
|
|
|
|
In the 1970s people realized that unrestricted goto could lead
|
|
to messy "spaghetti" code that was hard to understand and revise.
|
|
In a high-level language, it is also unneeded as long as there
|
|
are ways to branch (in Python, with ``if`` statements and ``or``,
|
|
``and``, and ``if-else`` expressions) and loop (with ``while``
|
|
and ``for`` statements, possibly containing ``continue`` and ``break``).
|
|
|
|
One can also use exceptions to provide a "structured goto"
|
|
that works even across
|
|
function calls. Many feel that exceptions can conveniently emulate all
|
|
reasonable uses of the "go" or "goto" constructs of C, Fortran, and other
|
|
languages. For example::
|
|
|
|
class label(Exception): pass # declare a label
|
|
|
|
try:
|
|
...
|
|
if condition: raise label() # goto label
|
|
...
|
|
except label: # where to goto
|
|
pass
|
|
...
|
|
|
|
This doesn't allow you to jump into the middle of a loop, but that's usually
|
|
considered an abuse of goto anyway. Use sparingly.
|
|
|
|
|
|
Why can't raw strings (r-strings) end with a backslash?
|
|
-------------------------------------------------------
|
|
|
|
More precisely, they can't end with an odd number of backslashes: the unpaired
|
|
backslash at the end escapes the closing quote character, leaving an
|
|
unterminated string.
|
|
|
|
Raw strings were designed to ease creating input for processors (chiefly regular
|
|
expression engines) that want to do their own backslash escape processing. Such
|
|
processors consider an unmatched trailing backslash to be an error anyway, so
|
|
raw strings disallow that. In return, they allow you to pass on the string
|
|
quote character by escaping it with a backslash. These rules work well when
|
|
r-strings are used for their intended purpose.
|
|
|
|
If you're trying to build Windows pathnames, note that all Windows system calls
|
|
accept forward slashes too::
|
|
|
|
f = open("/mydir/file.txt") # works fine!
|
|
|
|
If you're trying to build a pathname for a DOS command, try e.g. one of ::
|
|
|
|
dir = r"\this\is\my\dos\dir" "\\"
|
|
dir = r"\this\is\my\dos\dir\ "[:-1]
|
|
dir = "\\this\\is\\my\\dos\\dir\\"
|
|
|
|
|
|
Why doesn't Python have a "with" statement for attribute assignments?
|
|
---------------------------------------------------------------------
|
|
|
|
Python has a 'with' statement that wraps the execution of a block, calling code
|
|
on the entrance and exit from the block. Some languages have a construct that
|
|
looks like this::
|
|
|
|
with obj:
|
|
a = 1 # equivalent to obj.a = 1
|
|
total = total + 1 # obj.total = obj.total + 1
|
|
|
|
In Python, such a construct would be ambiguous.
|
|
|
|
Other languages, such as Object Pascal, Delphi, and C++, use static types, so
|
|
it's possible to know, in an unambiguous way, what member is being assigned
|
|
to. This is the main point of static typing -- the compiler *always* knows the
|
|
scope of every variable at compile time.
|
|
|
|
Python uses dynamic types. It is impossible to know in advance which attribute
|
|
will be referenced at runtime. Member attributes may be added or removed from
|
|
objects on the fly. This makes it impossible to know, from a simple reading,
|
|
what attribute is being referenced: a local one, a global one, or a member
|
|
attribute?
|
|
|
|
For instance, take the following incomplete snippet::
|
|
|
|
def foo(a):
|
|
with a:
|
|
print(x)
|
|
|
|
The snippet assumes that "a" must have a member attribute called "x". However,
|
|
there is nothing in Python that tells the interpreter this. What should happen
|
|
if "a" is, let us say, an integer? If there is a global variable named "x",
|
|
will it be used inside the with block? As you see, the dynamic nature of Python
|
|
makes such choices much harder.
|
|
|
|
The primary benefit of "with" and similar language features (reduction of code
|
|
volume) can, however, easily be achieved in Python by assignment. Instead of::
|
|
|
|
function(args).mydict[index][index].a = 21
|
|
function(args).mydict[index][index].b = 42
|
|
function(args).mydict[index][index].c = 63
|
|
|
|
write this::
|
|
|
|
ref = function(args).mydict[index][index]
|
|
ref.a = 21
|
|
ref.b = 42
|
|
ref.c = 63
|
|
|
|
This also has the side-effect of increasing execution speed because name
|
|
bindings are resolved at run-time in Python, and the second version only needs
|
|
to perform the resolution once.
|
|
|
|
|
|
Why don't generators support the with statement?
|
|
------------------------------------------------
|
|
|
|
For technical reasons, a generator used directly as a context manager
|
|
would not work correctly. When, as is most common, a generator is used as
|
|
an iterator run to completion, no closing is needed. When it is, wrap
|
|
it as "contextlib.closing(generator)" in the 'with' statement.
|
|
|
|
|
|
Why are colons required for the if/while/def/class statements?
|
|
--------------------------------------------------------------
|
|
|
|
The colon is required primarily to enhance readability (one of the results of
|
|
the experimental ABC language). Consider this::
|
|
|
|
if a == b
|
|
print(a)
|
|
|
|
versus ::
|
|
|
|
if a == b:
|
|
print(a)
|
|
|
|
Notice how the second one is slightly easier to read. Notice further how a
|
|
colon sets off the example in this FAQ answer; it's a standard usage in English.
|
|
|
|
Another minor reason is that the colon makes it easier for editors with syntax
|
|
highlighting; they can look for colons to decide when indentation needs to be
|
|
increased instead of having to do a more elaborate parsing of the program text.
|
|
|
|
|
|
Why does Python allow commas at the end of lists and tuples?
|
|
------------------------------------------------------------
|
|
|
|
Python lets you add a trailing comma at the end of lists, tuples, and
|
|
dictionaries::
|
|
|
|
[1, 2, 3,]
|
|
('a', 'b', 'c',)
|
|
d = {
|
|
"A": [1, 5],
|
|
"B": [6, 7], # last trailing comma is optional but good style
|
|
}
|
|
|
|
|
|
There are several reasons to allow this.
|
|
|
|
When you have a literal value for a list, tuple, or dictionary spread across
|
|
multiple lines, it's easier to add more elements because you don't have to
|
|
remember to add a comma to the previous line. The lines can also be reordered
|
|
without creating a syntax error.
|
|
|
|
Accidentally omitting the comma can lead to errors that are hard to diagnose.
|
|
For example::
|
|
|
|
x = [
|
|
"fee",
|
|
"fie"
|
|
"foo",
|
|
"fum"
|
|
]
|
|
|
|
This list looks like it has four elements, but it actually contains three:
|
|
"fee", "fiefoo" and "fum". Always adding the comma avoids this source of error.
|
|
|
|
Allowing the trailing comma may also make programmatic code generation easier.
|