What’s New in Python 2.2
Author: | A.M. Kuchling |
---|
Introduction
This article explains the new features in Python 2.2.2, released on October 14, 2002. Python 2.2.2 is a bugfix release of Python 2.2, originally released on December 21, 2001.
Python 2.2 can be thought of as the “cleanup release”. There are some features such as generators and iterators that are completely new, but most of the changes, significant and far-reaching though they may be, are aimed at cleaning up irregularities and dark corners of the language design.
This article doesn’t attempt to provide a complete specification of the new features, but instead provides a convenient overview. For full details, you should refer to the documentation for Python 2.2, such as the Python Library Reference and the Python Reference Manual. If you want to understand the complete implementation and design rationale for a change, refer to the PEP for a particular new feature.
PEPs 252 and 253: Type and Class Changes
The largest and most far-reaching changes in Python 2.2 are to Python’s model of objects and classes. The changes should be backward compatible, so it’s likely that your code will continue to run unchanged, but the changes provide some amazing new capabilities. Before beginning this, the longest and most complicated section of this article, I’ll provide an overview of the changes and offer some comments.
A long time ago I wrote a Web page listing flaws in Python’s design. One of the
most significant flaws was that it’s impossible to subclass Python types
implemented in C. In particular, it’s not possible to subclass built-in types,
so you can’t just subclass, say, lists in order to add a single useful method to
them. The UserList
module provides a class that supports all of the
methods of lists and that can be subclassed further, but there’s lots of C code
that expects a regular Python list and won’t accept a UserList
instance.
Python 2.2 fixes this, and in the process adds some exciting new capabilities. A brief summary:
- You can subclass built-in types such as lists and even integers, and your subclasses should work in every place that requires the original type.
- It’s now possible to define static and class methods, in addition to the instance methods available in previous versions of Python.
- It’s also possible to automatically call methods on accessing or setting an
instance attribute by using a new mechanism called properties. Many uses
of
__getattr__()
can be rewritten to use properties instead, making the resulting code simpler and faster. As a small side benefit, attributes can now have docstrings, too. - The list of legal attributes for an instance can be limited to a particular set using slots, making it possible to safeguard against typos and perhaps make more optimizations possible in future versions of Python.
Some users have voiced concern about all these changes. Sure, they say, the new features are neat and lend themselves to all sorts of tricks that weren’t possible in previous versions of Python, but they also make the language more complicated. Some people have said that they’ve always recommended Python for its simplicity, and feel that its simplicity is being lost.
Personally, I think there’s no need to worry. Many of the new features are quite esoteric, and you can write a lot of Python code without ever needed to be aware of them. Writing a simple class is no more difficult than it ever was, so you don’t need to bother learning or teaching them unless they’re actually needed. Some very complicated tasks that were previously only possible from C will now be possible in pure Python, and to my mind that’s all for the better.
I’m not going to attempt to cover every single corner case and small change that were required to make the new features work. Instead this section will paint only the broad strokes. See section Related Links, “Related Links”, for further sources of information about Python 2.2’s new object model.
Old and New Classes
First, you should know that Python 2.2 really has two kinds of classes: classic or old-style classes, and new-style classes. The old-style class model is exactly the same as the class model in earlier versions of Python. All the new features described in this section apply only to new-style classes. This divergence isn’t intended to last forever; eventually old-style classes will be dropped, possibly in Python 3.0.
So how do you define a new-style class? You do it by subclassing an existing
new-style class. Most of Python’s built-in types, such as integers, lists,
dictionaries, and even files, are new-style classes now. A new-style class
named object
, the base class for all built-in types, has also been
added so if no built-in type is suitable, you can just subclass
object
:
class C(object):
def __init__ (self):
...
...
This means that class
statements that don’t have any base classes are
always classic classes in Python 2.2. (Actually you can also change this by
setting a module-level variable named __metaclass__
— see PEP 253
for the details — but it’s easier to just subclass object
.)
The type objects for the built-in types are available as built-ins, named using
a clever trick. Python has always had built-in functions named int()
,
float()
, and str()
. In 2.2, they aren’t functions any more, but
type objects that behave as factories when called.
>>> int
<type 'int'>
>>> int('123')
123
To make the set of types complete, new type objects such as dict()
and
file()
have been added. Here’s a more interesting example, adding a
lock()
method to file objects:
class LockableFile(file):
def lock (self, operation, length=0, start=0, whence=0):
import fcntl
return fcntl.lockf(self.fileno(), operation,
length, start, whence)
The now-obsolete posixfile
module contained a class that emulated all of
a file object’s methods and also added a lock()
method, but this class
couldn’t be passed to internal functions that expected a built-in file,
something which is possible with our new LockableFile
.
Descriptors
In previous versions of Python, there was no consistent way to discover what
attributes and methods were supported by an object. There were some informal
conventions, such as defining __members__
and __methods__
attributes that were lists of names, but often the author of an extension type
or a class wouldn’t bother to define them. You could fall back on inspecting
the __dict__
of an object, but when class inheritance or an arbitrary
__getattr__()
hook were in use this could still be inaccurate.
The one big idea underlying the new class model is that an API for describing the attributes of an object using descriptors has been formalized. Descriptors specify the value of an attribute, stating whether it’s a method or a field. With the descriptor API, static methods and class methods become possible, as well as more exotic constructs.
Attribute descriptors are objects that live inside class objects, and have a few attributes of their own:
__name__
is the attribute’s name.__doc__
is the attribute’s docstring.__get__(object)
is a method that retrieves the attribute value from object.__set__(object, value)
sets the attribute on object to value.__delete__(object, value)
deletes the value attribute of object.
For example, when you write obj.x
, the steps that Python actually performs
are:
descriptor = obj.__class__.x
descriptor.__get__(obj)
For methods, descriptor.__get__()
returns a temporary object that’s
callable, and wraps up the instance and the method to be called on it. This is
also why static methods and class methods are now possible; they have
descriptors that wrap up just the method, or the method and the class. As a
brief explanation of these new kinds of methods, static methods aren’t passed
the instance, and therefore resemble regular functions. Class methods are
passed the class of the object, but not the object itself. Static and class
methods are defined like this:
class C(object):
def f(arg1, arg2):
...
f = staticmethod(f)
def g(cls, arg1, arg2):
...
g = classmethod(g)
The staticmethod()
function takes the function f()
, and returns it
wrapped up in a descriptor so it can be stored in the class object. You might
expect there to be special syntax for creating such methods (def static f
,
defstatic f()
, or something like that) but no such syntax has been defined
yet; that’s been left for future versions of Python.
More new features, such as slots and properties, are also implemented as new kinds of descriptors, and it’s not difficult to write a descriptor class that does something novel. For example, it would be possible to write a descriptor class that made it possible to write Eiffel-style preconditions and postconditions for a method. A class that used this feature might be defined like this:
from eiffel import eiffelmethod
class C(object):
def f(self, arg1, arg2):
# The actual function
...
def pre_f(self):
# Check preconditions
...
def post_f(self):
# Check postconditions
...
f = eiffelmethod(f, pre_f, post_f)
Note that a person using the new eiffelmethod()
doesn’t have to understand
anything about descriptors. This is why I think the new features don’t increase
the basic complexity of the language. There will be a few wizards who need to
know about it in order to write eiffelmethod()
or the ZODB or whatever,
but most users will just write code on top of the resulting libraries and ignore
the implementation details.
Multiple Inheritance: The Diamond Rule
Multiple inheritance has also been made more useful through changing the rules under which names are resolved. Consider this set of classes (diagram taken from PEP 253 by Guido van Rossum):
class A:
^ ^ def save(self): ...
/ \
/ \
/ \
/ \
class B class C:
^ ^ def save(self): ...
\ /
\ /
\ /
\ /
class D
The lookup rule for classic classes is simple but not very smart; the base
classes are searched depth-first, going from left to right. A reference to
D.save()
will search the classes D
, B
, and then
A
, where save()
would be found and returned. C.save()
would never be found at all. This is bad, because if C
‘s save()
method is saving some internal state specific to C
, not calling it will
result in that state never getting saved.
New-style classes follow a different algorithm that’s a bit more complicated to explain, but does the right thing in this situation. (Note that Python 2.3 changes this algorithm to one that produces the same results in most cases, but produces more useful results for really complicated inheritance graphs.)
- List all the base classes, following the classic lookup rule and include a
class multiple times if it’s visited repeatedly. In the above example, the list
of visited classes is [
D
,B
,A
,C
,A
]. - Scan the list for duplicated classes. If any are found, remove all but one
occurrence, leaving the last one in the list. In the above example, the list
becomes [
D
,B
,C
,A
] after dropping duplicates.
Following this rule, referring to D.save()
will return C.save()
,
which is the behaviour we’re after. This lookup rule is the same as the one
followed by Common Lisp. A new built-in function, super()
, provides a way
to get at a class’s superclasses without having to reimplement Python’s
algorithm. The most commonly used form will be super(class, obj)
, which
returns a bound superclass object (not the actual class object). This form
will be used in methods to call a method in the superclass; for example,
D
‘s save()
method would look like this:
class D (B,C):
def save (self):
# Call superclass .save()
super(D, self).save()
# Save D's private information here
...
super()
can also return unbound superclass objects when called as
super(class)
or super(class1, class2)
, but this probably won’t
often be useful.
Attribute Access
A fair number of sophisticated Python classes define hooks for attribute access
using __getattr__()
; most commonly this is done for convenience, to make
code more readable by automatically mapping an attribute access such as
obj.parent
into a method call such as obj.get_parent
. Python 2.2 adds
some new ways of controlling attribute access.
First, __getattr__(attr_name)
is still supported by new-style classes,
and nothing about it has changed. As before, it will be called when an attempt
is made to access obj.foo
and no attribute named foo
is found in the
instance’s dictionary.
New-style classes also support a new method,
__getattribute__(attr_name)
. The difference between the two methods is
that __getattribute__()
is always called whenever any attribute is
accessed, while the old __getattr__()
is only called if foo
isn’t
found in the instance’s dictionary.
However, Python 2.2’s support for properties will often be a simpler way
to trap attribute references. Writing a __getattr__()
method is
complicated because to avoid recursion you can’t use regular attribute accesses
inside them, and instead have to mess around with the contents of
__dict__
. __getattr__()
methods also end up being called by Python
when it checks for other methods such as __repr__()
or __coerce__()
,
and so have to be written with this in mind. Finally, calling a function on
every attribute access results in a sizable performance loss.
property
is a new built-in type that packages up three functions that
get, set, or delete an attribute, and a docstring. For example, if you want to
define a size
attribute that’s computed, but also settable, you could
write:
class C(object):
def get_size (self):
result = ... computation ...
return result
def set_size (self, size):
... compute something based on the size
and set internal state appropriately ...
# Define a property. The 'delete this attribute'
# method is defined as None, so the attribute
# can't be deleted.
size = property(get_size, set_size,
None,
"Storage size of this instance")
That is certainly clearer and easier to write than a pair of
__getattr__()
/__setattr__()
methods that check for the size
attribute and handle it specially while retrieving all other attributes from the
instance’s __dict__
. Accesses to size
are also the only ones
which have to perform the work of calling a function, so references to other
attributes run at their usual speed.
Finally, it’s possible to constrain the list of attributes that can be
referenced on an object using the new __slots__
class attribute. Python
objects are usually very dynamic; at any time it’s possible to define a new
attribute on an instance by just doing obj.new_attr=1
. A new-style class
can define a class attribute named __slots__
to limit the legal
attributes to a particular set of names. An example will make this clear:
>>> class C(object):
... __slots__ = ('template', 'name')
...
>>> obj = C()
>>> print obj.template
None
>>> obj.template = 'Test'
>>> print obj.template
Test
>>> obj.newattr = None
Traceback (most recent call last):
File "<stdin>", line 1, in ?
AttributeError: 'C' object has no attribute 'newattr'
Note how you get an AttributeError
on the attempt to assign to an
attribute not listed in __slots__
.
PEP 234: Iterators
Another significant addition to 2.2 is an iteration interface at both the C and Python levels. Objects can define how they can be looped over by callers.
In Python versions up to 2.1, the usual way to make for item in obj
work is
to define a __getitem__()
method that looks something like this:
def __getitem__(self, index):
return <next item>
__getitem__()
is more properly used to define an indexing operation on an
object so that you can write obj[5]
to retrieve the sixth element. It’s a
bit misleading when you’re using this only to support for
loops.
Consider some file-like object that wants to be looped over; the index
parameter is essentially meaningless, as the class probably assumes that a
series of __getitem__()
calls will be made with index incrementing by
one each time. In other words, the presence of the __getitem__()
method
doesn’t mean that using file[5]
to randomly access the sixth element will
work, though it really should.
In Python 2.2, iteration can be implemented separately, and __getitem__()
methods can be limited to classes that really do support random access. The
basic idea of iterators is simple. A new built-in function, iter(obj)
or iter(C, sentinel)
, is used to get an iterator. iter(obj)
returns
an iterator for the object obj, while iter(C, sentinel)
returns an
iterator that will invoke the callable object C until it returns sentinel to
signal that the iterator is done.
Python classes can define an __iter__()
method, which should create and
return a new iterator for the object; if the object is its own iterator, this
method can just return self
. In particular, iterators will usually be their
own iterators. Extension types implemented in C can implement a tp_iter
function in order to return an iterator, and extension types that want to behave
as iterators can define a tp_iternext
function.
So, after all this, what do iterators actually do? They have one required
method, next()
, which takes no arguments and returns the next value. When
there are no more values to be returned, calling next()
should raise the
StopIteration
exception.
>>> L = [1,2,3]
>>> i = iter(L)
>>> print i
<iterator object at 0x8116870>
>>> i.next()
1
>>> i.next()
2
>>> i.next()
3
>>> i.next()
Traceback (most recent call last):
File "<stdin>", line 1, in ?
StopIteration
>>>
In 2.2, Python’s for
statement no longer expects a sequence; it
expects something for which iter()
will return an iterator. For backward
compatibility and convenience, an iterator is automatically constructed for
sequences that don’t implement __iter__()
or a tp_iter
slot, so
for i in [1,2,3]
will still work. Wherever the Python interpreter loops
over a sequence, it’s been changed to use the iterator protocol. This means you
can do things like this:
>>> L = [1,2,3]
>>> i = iter(L)
>>> a,b,c = i
>>> a,b,c
(1, 2, 3)
Iterator support has been added to some of Python’s basic types. Calling
iter()
on a dictionary will return an iterator which loops over its keys:
>>> m = {'Jan': 1, 'Feb': 2, 'Mar': 3, 'Apr': 4, 'May': 5, 'Jun': 6,
... 'Jul': 7, 'Aug': 8, 'Sep': 9, 'Oct': 10, 'Nov': 11, 'Dec': 12}
>>> for key in m: print key, m[key]
...
Mar 3
Feb 2
Aug 8
Sep 9
May 5
Jun 6
Jul 7
Jan 1
Apr 4
Nov 11
Dec 12
Oct 10
That’s just the default behaviour. If you want to iterate over keys, values, or
key/value pairs, you can explicitly call the iterkeys()
,
itervalues()
, or iteritems()
methods to get an appropriate iterator.
In a minor related change, the in
operator now works on dictionaries,
so key in dict
is now equivalent to dict.has_key(key)
.
Files also provide an iterator, which calls the readline()
method until
there are no more lines in the file. This means you can now read each line of a
file using code like this:
for line in file:
# do something for each line
...
Note that you can only go forward in an iterator; there’s no way to get the
previous element, reset the iterator, or make a copy of it. An iterator object
could provide such additional capabilities, but the iterator protocol only
requires a next()
method.
See also
- PEP 234 - Iterators
- Written by Ka-Ping Yee and GvR; implemented by the Python Labs crew, mostly by GvR and Tim Peters.
PEP 255: Simple Generators
Generators are another new feature, one that interacts with the introduction of iterators.
You’re doubtless familiar with how function calls work in Python or C. When you
call a function, it gets a private namespace where its local variables are
created. When the function reaches a return
statement, the local
variables are destroyed and the resulting value is returned to the caller. A
later call to the same function will get a fresh new set of local variables.
But, what if the local variables weren’t thrown away on exiting a function?
What if you could later resume the function where it left off? This is what
generators provide; they can be thought of as resumable functions.
Here’s the simplest example of a generator function:
def generate_ints(N):
for i in range(N):
yield i
A new keyword, yield
, was introduced for generators. Any function
containing a yield
statement is a generator function; this is
detected by Python’s bytecode compiler which compiles the function specially as
a result. Because a new keyword was introduced, generators must be explicitly
enabled in a module by including a from __future__ import generators
statement near the top of the module’s source code. In Python 2.3 this
statement will become unnecessary.
When you call a generator function, it doesn’t return a single value; instead it
returns a generator object that supports the iterator protocol. On executing
the yield
statement, the generator outputs the value of i
,
similar to a return
statement. The big difference between
yield
and a return
statement is that on reaching a
yield
the generator’s state of execution is suspended and local
variables are preserved. On the next call to the generator’s next()
method,
the function will resume executing immediately after the yield
statement. (For complicated reasons, the yield
statement isn’t
allowed inside the try
block of a try
...finally
statement; read PEP 255 for a full explanation of the
interaction between yield
and exceptions.)
Here’s a sample usage of the generate_ints()
generator:
>>> gen = generate_ints(3)
>>> gen
<generator object at 0x8117f90>
>>> gen.next()
0
>>> gen.next()
1
>>> gen.next()
2
>>> gen.next()
Traceback (most recent call last):
File "<stdin>", line 1, in ?
File "<stdin>", line 2, in generate_ints
StopIteration
You could equally write for i in generate_ints(5)
, or a,b,c =
generate_ints(3)
.
Inside a generator function, the return
statement can only be used
without a value, and signals the end of the procession of values; afterwards the
generator cannot return any further values. return
with a value, such
as return 5
, is a syntax error inside a generator function. The end of the
generator’s results can also be indicated by raising StopIteration
manually, or by just letting the flow of execution fall off the bottom of the
function.
You could achieve the effect of generators manually by writing your own class
and storing all the local variables of the generator as instance variables. For
example, returning a list of integers could be done by setting self.count
to
0, and having the next()
method increment self.count
and return it.
However, for a moderately complicated generator, writing a corresponding class
would be much messier. Lib/test/test_generators.py
contains a number of
more interesting examples. The simplest one implements an in-order traversal of
a tree using generators recursively.
# A recursive generator that generates Tree leaves in in-order.
def inorder(t):
if t:
for x in inorder(t.left):
yield x
yield t.label
for x in inorder(t.right):
yield x
Two other examples in Lib/test/test_generators.py
produce solutions for
the N-Queens problem (placing $N$ queens on an $NxN$ chess board so that no
queen threatens another) and the Knight’s Tour (a route that takes a knight to
every square of an $NxN$ chessboard without visiting any square twice).
The idea of generators comes from other programming languages, especially Icon (https://www.cs.arizona.edu/icon/), where the idea of generators is central. In Icon, every expression and function call behaves like a generator. One example from “An Overview of the Icon Programming Language” at https://www.cs.arizona.edu/icon/docs/ipd266.htm gives an idea of what this looks like:
sentence := "Store it in the neighboring harbor"
if (i := find("or", sentence)) > 5 then write(i)
In Icon the find()
function returns the indexes at which the substring
“or” is found: 3, 23, 33. In the if
statement, i
is first
assigned a value of 3, but 3 is less than 5, so the comparison fails, and Icon
retries it with the second value of 23. 23 is greater than 5, so the comparison
now succeeds, and the code prints the value 23 to the screen.
Python doesn’t go nearly as far as Icon in adopting generators as a central concept. Generators are considered a new part of the core Python language, but learning or using them isn’t compulsory; if they don’t solve any problems that you have, feel free to ignore them. One novel feature of Python’s interface as compared to Icon’s is that a generator’s state is represented as a concrete object (the iterator) that can be passed around to other functions or stored in a data structure.
See also
- PEP 255 - Simple Generators
- Written by Neil Schemenauer, Tim Peters, Magnus Lie Hetland. Implemented mostly by Neil Schemenauer and Tim Peters, with other fixes from the Python Labs crew.
PEP 237: Unifying Long Integers and Integers
In recent versions, the distinction between regular integers, which are 32-bit
values on most machines, and long integers, which can be of arbitrary size, was
becoming an annoyance. For example, on platforms that support files larger than
2**32
bytes, the tell()
method of file objects has to return a long
integer. However, there were various bits of Python that expected plain integers
and would raise an error if a long integer was provided instead. For example,
in Python 1.5, only regular integers could be used as a slice index, and
'abc'[1L:]
would raise a TypeError
exception with the message ‘slice
index must be int’.
Python 2.2 will shift values from short to long integers as required. The ‘L’
suffix is no longer needed to indicate a long integer literal, as now the
compiler will choose the appropriate type. (Using the ‘L’ suffix will be
discouraged in future 2.x versions of Python, triggering a warning in Python
2.4, and probably dropped in Python 3.0.) Many operations that used to raise an
OverflowError
will now return a long integer as their result. For
example:
>>> 1234567890123
1234567890123L
>>> 2 ** 64
18446744073709551616L
In most cases, integers and long integers will now be treated identically. You
can still distinguish them with the type()
built-in function, but that’s
rarely needed.
See also
- PEP 237 - Unifying Long Integers and Integers
- Written by Moshe Zadka and Guido van Rossum. Implemented mostly by Guido van Rossum.
PEP 238: Changing the Division Operator
The most controversial change in Python 2.2 heralds the start of an effort to
fix an old design flaw that’s been in Python from the beginning. Currently
Python’s division operator, /
, behaves like C’s division operator when
presented with two integer arguments: it returns an integer result that’s
truncated down when there would be a fractional part. For example, 3/2
is
1, not 1.5, and (-1)/2
is -1, not -0.5. This means that the results of
division can vary unexpectedly depending on the type of the two operands and
because Python is dynamically typed, it can be difficult to determine the
possible types of the operands.
(The controversy is over whether this is really a design flaw, and whether it’s worth breaking existing code to fix this. It’s caused endless discussions on python-dev, and in July 2001 erupted into a storm of acidly sarcastic postings on comp.lang.python. I won’t argue for either side here and will stick to describing what’s implemented in 2.2. Read PEP 238 for a summary of arguments and counter-arguments.)
Because this change might break code, it’s being introduced very gradually. Python 2.2 begins the transition, but the switch won’t be complete until Python 3.0.
First, I’ll borrow some terminology from PEP 238. “True division” is the
division that most non-programmers are familiar with: 3/2 is 1.5, 1/4 is 0.25,
and so forth. “Floor division” is what Python’s /
operator currently does
when given integer operands; the result is the floor of the value returned by
true division. “Classic division” is the current mixed behaviour of /
; it
returns the result of floor division when the operands are integers, and returns
the result of true division when one of the operands is a floating-point number.
Here are the changes 2.2 introduces:
A new operator,
//
, is the floor division operator. (Yes, we know it looks like C++’s comment symbol.)//
always performs floor division no matter what the types of its operands are, so1 // 2
is 0 and1.0 // 2.0
is also 0.0.//
is always available in Python 2.2; you don’t need to enable it using a__future__
statement.By including a
from __future__ import division
in a module, the/
operator will be changed to return the result of true division, so1/2
is 0.5. Without the__future__
statement,/
still means classic division. The default meaning of/
will not change until Python 3.0.Classes can define methods called
__truediv__()
and__floordiv__()
to overload the two division operators. At the C level, there are also slots in thePyNumberMethods
structure so extension types can define the two operators.Python 2.2 supports some command-line arguments for testing whether code will work with the changed division semantics. Running python with
-Q warn
will cause a warning to be issued whenever division is applied to two integers. You can use this to find code that’s affected by the change and fix it. By default, Python 2.2 will simply perform classic division without a warning; the warning will be turned on by default in Python 2.3.
See also
- PEP 238 - Changing the Division Operator
- Written by Moshe Zadka and Guido van Rossum. Implemented by Guido van Rossum..
Unicode Changes
Python’s Unicode support has been enhanced a bit in 2.2. Unicode strings are
usually stored as UCS-2, as 16-bit unsigned integers. Python 2.2 can also be
compiled to use UCS-4, 32-bit unsigned integers, as its internal encoding by
supplying --enable-unicode=ucs4
to the configure script. (It’s also
possible to specify --disable-unicode
to completely disable Unicode
support.)
When built to use UCS-4 (a “wide Python”), the interpreter can natively handle
Unicode characters from U+000000 to U+110000, so the range of legal values for
the unichr()
function is expanded accordingly. Using an interpreter
compiled to use UCS-2 (a “narrow Python”), values greater than 65535 will still
cause unichr()
to raise a ValueError
exception. This is all
described in PEP 261, “Support for ‘wide’ Unicode characters”; consult it for
further details.
Another change is simpler to explain. Since their introduction, Unicode strings
have supported an encode()
method to convert the string to a selected
encoding such as UTF-8 or Latin-1. A symmetric decode([*encoding*])
method has been added to 8-bit strings (though not to Unicode strings) in 2.2.
decode()
assumes that the string is in the specified encoding and decodes
it, returning whatever is returned by the codec.
Using this new feature, codecs have been added for tasks not directly related to
Unicode. For example, codecs have been added for uu-encoding, MIME’s base64
encoding, and compression with the zlib
module:
>>> s = """Here is a lengthy piece of redundant, overly verbose,
... and repetitive text.
... """
>>> data = s.encode('zlib')
>>> data
'x\x9c\r\xc9\xc1\r\x80 \x10\x04\xc0?Ul...'
>>> data.decode('zlib')
'Here is a lengthy piece of redundant, overly verbose,\nand repetitive text.\n'
>>> print s.encode('uu')
begin 666 <data>
M2&5R92!I<R!A(&QE;F=T:'D@<&EE8V4@;V8@<F5D=6YD86YT+"!O=F5R;'D@
>=F5R8F]S92P*86YD(')E<&5T:71I=F4@=&5X="X*
end
>>> "sheesh".encode('rot-13')
'furrfu'
To convert a class instance to Unicode, a __unicode__()
method can be
defined by a class, analogous to __str__()
.
encode()
, decode()
, and __unicode__()
were implemented by
Marc-André Lemburg. The changes to support using UCS-4 internally were
implemented by Fredrik Lundh and Martin von Löwis.
See also
- PEP 261 - Support for ‘wide’ Unicode characters
- Written by Paul Prescod.
PEP 227: Nested Scopes
In Python 2.1, statically nested scopes were added as an optional feature, to be
enabled by a from __future__ import nested_scopes
directive. In 2.2 nested
scopes no longer need to be specially enabled, and are now always present. The
rest of this section is a copy of the description of nested scopes from my
“What’s New in Python 2.1” document; if you read it when 2.1 came out, you can
skip the rest of this section.
The largest change introduced in Python 2.1, and made complete in 2.2, is to Python’s scoping rules. In Python 2.0, at any given time there are at most three namespaces used to look up variable names: local, module-level, and the built-in namespace. This often surprised people because it didn’t match their intuitive expectations. For example, a nested recursive function definition doesn’t work:
def f():
...
def g(value):
...
return g(value-1) + 1
...
The function g()
will always raise a NameError
exception, because
the binding of the name g
isn’t in either its local namespace or in the
module-level namespace. This isn’t much of a problem in practice (how often do
you recursively define interior functions like this?), but this also made using
the lambda
statement clumsier, and this was a problem in practice.
In code which uses lambda
you can often find local variables being
copied by passing them as the default values of arguments.
def find(self, name):
"Return list of any entries equal to 'name'"
L = filter(lambda x, name=name: x == name,
self.list_attribute)
return L
The readability of Python code written in a strongly functional style suffers greatly as a result.
The most significant change to Python 2.2 is that static scoping has been added
to the language to fix this problem. As a first effect, the name=name
default argument is now unnecessary in the above example. Put simply, when a
given variable name is not assigned a value within a function (by an assignment,
or the def
, class
, or import
statements),
references to the variable will be looked up in the local namespace of the
enclosing scope. A more detailed explanation of the rules, and a dissection of
the implementation, can be found in the PEP.
This change may cause some compatibility problems for code where the same variable name is used both at the module level and as a local variable within a function that contains further function definitions. This seems rather unlikely though, since such code would have been pretty confusing to read in the first place.
One side effect of the change is that the from module import *
and
exec
statements have been made illegal inside a function scope under
certain conditions. The Python reference manual has said all along that from
module import *
is only legal at the top level of a module, but the CPython
interpreter has never enforced this before. As part of the implementation of
nested scopes, the compiler which turns Python source into bytecodes has to
generate different code to access variables in a containing scope. from
module import *
and exec
make it impossible for the compiler to
figure this out, because they add names to the local namespace that are
unknowable at compile time. Therefore, if a function contains function
definitions or lambda
expressions with free variables, the compiler
will flag this by raising a SyntaxError
exception.
To make the preceding explanation a bit clearer, here’s an example:
x = 1
def f():
# The next line is a syntax error
exec 'x=2'
def g():
return x
Line 4 containing the exec
statement is a syntax error, since
exec
would define a new local variable named x
whose value should
be accessed by g()
.
This shouldn’t be much of a limitation, since exec
is rarely used in
most Python code (and when it is used, it’s often a sign of a poor design
anyway).
See also
- PEP 227 - Statically Nested Scopes
- Written and implemented by Jeremy Hylton.
New and Improved Modules
The
xmlrpclib
module was contributed to the standard library by Fredrik Lundh, providing support for writing XML-RPC clients. XML-RPC is a simple remote procedure call protocol built on top of HTTP and XML. For example, the following snippet retrieves a list of RSS channels from the O’Reilly Network, and then lists the recent headlines for one channel:import xmlrpclib s = xmlrpclib.Server( 'http://www.oreillynet.com/meerkat/xml-rpc/server.php') channels = s.meerkat.getChannels() # channels is a list of dictionaries, like this: # [{'id': 4, 'title': 'Freshmeat Daily News'} # {'id': 190, 'title': '32Bits Online'}, # {'id': 4549, 'title': '3DGamers'}, ... ] # Get the items for one channel items = s.meerkat.getItems( {'channel': 4} ) # 'items' is another list of dictionaries, like this: # [{'link': 'http://freshmeat.net/releases/52719/', # 'description': 'A utility which converts HTML to XSL FO.', # 'title': 'html2fo 0.3 (Default)'}, ... ]
The
SimpleXMLRPCServer
module makes it easy to create straightforward XML-RPC servers. See http://www.xmlrpc.com/ for more information about XML-RPC.The new
hmac
module implements the HMAC algorithm described by RFC 2104. (Contributed by Gerhard Häring.)Several functions that originally returned lengthy tuples now return pseudo-sequences that still behave like tuples but also have mnemonic attributes such as memberst_mtime or
tm_year
. The enhanced functions includestat()
,fstat()
,statvfs()
, andfstatvfs()
in theos
module, andlocaltime()
,gmtime()
, andstrptime()
in thetime
module.For example, to obtain a file’s size using the old tuples, you’d end up writing something like
file_size = os.stat(filename)[stat.ST_SIZE]
, but now this can be written more clearly asfile_size = os.stat(filename).st_size
.The original patch for this feature was contributed by Nick Mathewson.
The Python profiler has been extensively reworked and various errors in its output have been corrected. (Contributed by Fred L. Drake, Jr. and Tim Peters.)
The
socket
module can be compiled to support IPv6; specify the--enable-ipv6
option to Python’s configure script. (Contributed by Jun-ichiro “itojun” Hagino.)Two new format characters were added to the
struct
module for 64-bit integers on platforms that support the Clong long
type.q
is for a signed 64-bit integer, andQ
is for an unsigned one. The value is returned in Python’s long integer type. (Contributed by Tim Peters.)In the interpreter’s interactive mode, there’s a new built-in function
help()
that uses thepydoc
module introduced in Python 2.1 to provide interactive help.help(object)
displays any available help text about object.help()
with no argument puts you in an online help utility, where you can enter the names of functions, classes, or modules to read their help text. (Contributed by Guido van Rossum, using Ka-Ping Yee’spydoc
module.)Various bugfixes and performance improvements have been made to the SRE engine underlying the
re
module. For example, there.sub()
andre.split()
functions have been rewritten in C. Another contributed patch speeds up certain Unicode character ranges by a factor of two, and a newfinditer()
method that returns an iterator over all the non-overlapping matches in a given string. (SRE is maintained by Fredrik Lundh. The BIGCHARSET patch was contributed by Martin von Löwis.)The
smtplib
module now supports RFC 2487, “Secure SMTP over TLS”, so it’s now possible to encrypt the SMTP traffic between a Python program and the mail transport agent being handed a message.smtplib
also supports SMTP authentication. (Contributed by Gerhard Häring.)The
imaplib
module, maintained by Piers Lauder, has support for several new extensions: the NAMESPACE extension defined in RFC 2342, SORT, GETACL and SETACL. (Contributed by Anthony Baxter and Michel Pelletier.)The
rfc822
module’s parsing of email addresses is now compliant with RFC 2822, an update to RFC 822. (The module’s name is not going to be changed torfc2822
.) A new package,email
, has also been added for parsing and generating e-mail messages. (Contributed by Barry Warsaw, and arising out of his work on Mailman.)The
difflib
module now contains a newDiffer
class for producing human-readable lists of changes (a “delta”) between two sequences of lines of text. There are also two generator functions,ndiff()
andrestore()
, which respectively return a delta from two sequences, or one of the original sequences from a delta. (Grunt work contributed by David Goodger, from ndiff.py code by Tim Peters who then did the generatorization.)New constants
ascii_letters
,ascii_lowercase
, andascii_uppercase
were added to thestring
module. There were several modules in the standard library that usedstring.letters
to mean the ranges A-Za-z, but that assumption is incorrect when locales are in use, becausestring.letters
varies depending on the set of legal characters defined by the current locale. The buggy modules have all been fixed to useascii_letters
instead. (Reported by an unknown person; fixed by Fred L. Drake, Jr.)The
mimetypes
module now makes it easier to use alternative MIME-type databases by the addition of aMimeTypes
class, which takes a list of filenames to be parsed. (Contributed by Fred L. Drake, Jr.)A
Timer
class was added to thethreading
module that allows scheduling an activity to happen at some future time. (Contributed by Itamar Shtull-Trauring.)
Interpreter Changes and Fixes
Some of the changes only affect people who deal with the Python interpreter at the C level because they’re writing Python extension modules, embedding the interpreter, or just hacking on the interpreter itself. If you only write Python code, none of the changes described here will affect you very much.
Profiling and tracing functions can now be implemented in C, which can operate at much higher speeds than Python-based functions and should reduce the overhead of profiling and tracing. This will be of interest to authors of development environments for Python. Two new C functions were added to Python’s API,
PyEval_SetProfile()
andPyEval_SetTrace()
. The existingsys.setprofile()
andsys.settrace()
functions still exist, and have simply been changed to use the new C-level interface. (Contributed by Fred L. Drake, Jr.)Another low-level API, primarily of interest to implementors of Python debuggers and development tools, was added.
PyInterpreterState_Head()
andPyInterpreterState_Next()
let a caller walk through all the existing interpreter objects;PyInterpreterState_ThreadHead()
andPyThreadState_Next()
allow looping over all the thread states for a given interpreter. (Contributed by David Beazley.)The C-level interface to the garbage collector has been changed to make it easier to write extension types that support garbage collection and to debug misuses of the functions. Various functions have slightly different semantics, so a bunch of functions had to be renamed. Extensions that use the old API will still compile but will not participate in garbage collection, so updating them for 2.2 should be considered fairly high priority.
To upgrade an extension module to the new API, perform the following steps:
Rename
Py_TPFLAGS_GC()
toPyTPFLAGS_HAVE_GC()
.- Use
PyObject_GC_New()
orPyObject_GC_NewVar()
to allocate objects, and
PyObject_GC_Del()
to deallocate them.
- Use
- Rename
PyObject_GC_Init()
toPyObject_GC_Track()
and PyObject_GC_Fini()
toPyObject_GC_UnTrack()
.
- Rename
Remove
PyGC_HEAD_SIZE()
from object size calculations.Remove calls to
PyObject_AS_GC()
andPyObject_FROM_GC()
.A new
et
format sequence was added toPyArg_ParseTuple()
;et
takes both a parameter and an encoding name, and converts the parameter to the given encoding if the parameter turns out to be a Unicode string, or leaves it alone if it’s an 8-bit string, assuming it to already be in the desired encoding. This differs from thees
format character, which assumes that 8-bit strings are in Python’s default ASCII encoding and converts them to the specified new encoding. (Contributed by M.-A. Lemburg, and used for the MBCS support on Windows described in the following section.)A different argument parsing function,
PyArg_UnpackTuple()
, has been added that’s simpler and presumably faster. Instead of specifying a format string, the caller simply gives the minimum and maximum number of arguments expected, and a set of pointers toPyObject*
variables that will be filled in with argument values.Two new flags
METH_NOARGS
andMETH_O
are available in method definition tables to simplify implementation of methods with no arguments or a single untyped argument. Calling such methods is more efficient than calling a corresponding method that usesMETH_VARARGS
. Also, the oldMETH_OLDARGS
style of writing C methods is now officially deprecated.Two new wrapper functions,
PyOS_snprintf()
andPyOS_vsnprintf()
were added to provide cross-platform implementations for the relatively newsnprintf()
andvsnprintf()
C lib APIs. In contrast to the standardsprintf()
andvsprintf()
functions, the Python versions check the bounds of the buffer used to protect against buffer overruns. (Contributed by M.-A. Lemburg.)The
_PyTuple_Resize()
function has lost an unused parameter, so now it takes 2 parameters instead of 3. The third argument was never used, and can simply be discarded when porting code from earlier versions to Python 2.2.
Other Changes and Fixes
As usual there were a bunch of other improvements and bugfixes scattered throughout the source tree. A search through the CVS change logs finds there were 527 patches applied and 683 bugs fixed between Python 2.1 and 2.2; 2.2.1 applied 139 patches and fixed 143 bugs; 2.2.2 applied 106 patches and fixed 82 bugs. These figures are likely to be underestimates.
Some of the more notable changes are:
The code for the MacOS port for Python, maintained by Jack Jansen, is now kept in the main Python CVS tree, and many changes have been made to support MacOS X.
The most significant change is the ability to build Python as a framework, enabled by supplying the
--enable-framework
option to the configure script when compiling Python. According to Jack Jansen, “This installs a self-contained Python installation plus the OS X framework “glue” into/Library/Frameworks/Python.framework
(or another location of choice). For now there is little immediate added benefit to this (actually, there is the disadvantage that you have to change your PATH to be able to find Python), but it is the basis for creating a full-blown Python application, porting the MacPython IDE, possibly using Python as a standard OSA scripting language and much more.”Most of the MacPython toolbox modules, which interface to MacOS APIs such as windowing, QuickTime, scripting, etc. have been ported to OS X, but they’ve been left commented out in
setup.py
. People who want to experiment with these modules can uncomment them manually.Keyword arguments passed to built-in functions that don’t take them now cause a
TypeError
exception to be raised, with the message “function takes no keyword arguments”.Weak references, added in Python 2.1 as an extension module, are now part of the core because they’re used in the implementation of new-style classes. The
ReferenceError
exception has therefore moved from theweakref
module to become a built-in exception.A new script,
Tools/scripts/cleanfuture.py
by Tim Peters, automatically removes obsolete__future__
statements from Python source code.An additional flags argument has been added to the built-in function
compile()
, so the behaviour of__future__
statements can now be correctly observed in simulated shells, such as those presented by IDLE and other development environments. This is described in PEP 264. (Contributed by Michael Hudson.)The new license introduced with Python 1.6 wasn’t GPL-compatible. This is fixed by some minor textual changes to the 2.2 license, so it’s now legal to embed Python inside a GPLed program again. Note that Python itself is not GPLed, but instead is under a license that’s essentially equivalent to the BSD license, same as it always was. The license changes were also applied to the Python 2.0.1 and 2.1.1 releases.
When presented with a Unicode filename on Windows, Python will now convert it to an MBCS encoded string, as used by the Microsoft file APIs. As MBCS is explicitly used by the file APIs, Python’s choice of ASCII as the default encoding turns out to be an annoyance. On Unix, the locale’s character set is used if
locale.nl_langinfo(CODESET)
is available. (Windows support was contributed by Mark Hammond with assistance from Marc-André Lemburg. Unix support was added by Martin von Löwis.)Large file support is now enabled on Windows. (Contributed by Tim Peters.)
The
Tools/scripts/ftpmirror.py
script now parses a.netrc
file, if you have one. (Contributed by Mike Romberg.)Some features of the object returned by the
xrange()
function are now deprecated, and trigger warnings when they’re accessed; they’ll disappear in Python 2.3.xrange
objects tried to pretend they were full sequence types by supporting slicing, sequence multiplication, and thein
operator, but these features were rarely used and therefore buggy. Thetolist()
method and thestart
,stop
, andstep
attributes are also being deprecated. At the C level, the fourth argument to thePyRange_New()
function,repeat
, has also been deprecated.There were a bunch of patches to the dictionary implementation, mostly to fix potential core dumps if a dictionary contains objects that sneakily changed their hash value, or mutated the dictionary they were contained in. For a while python-dev fell into a gentle rhythm of Michael Hudson finding a case that dumped core, Tim Peters fixing the bug, Michael finding another case, and round and round it went.
On Windows, Python can now be compiled with Borland C thanks to a number of patches contributed by Stephen Hansen, though the result isn’t fully functional yet. (But this is progress...)
Another Windows enhancement: Wise Solutions generously offered PythonLabs use of their InstallerMaster 8.1 system. Earlier PythonLabs Windows installers used Wise 5.0a, which was beginning to show its age. (Packaged up by Tim Peters.)
Files ending in
.pyw
can now be imported on Windows..pyw
is a Windows-only thing, used to indicate that a script needs to be run using PYTHONW.EXE instead of PYTHON.EXE in order to prevent a DOS console from popping up to display the output. This patch makes it possible to import such scripts, in case they’re also usable as modules. (Implemented by David Bolen.)On platforms where Python uses the C
dlopen()
function to load extension modules, it’s now possible to set the flags used bydlopen()
using thesys.getdlopenflags()
andsys.setdlopenflags()
functions. (Contributed by Bram Stolk.)The
pow()
built-in function no longer supports 3 arguments when floating-point numbers are supplied.pow(x, y, z)
returns(x**y) % z
, but this is never useful for floating point numbers, and the final result varies unpredictably depending on the platform. A call such aspow(2.0, 8.0, 7.0)
will now raise aTypeError
exception.
Acknowledgements
The author would like to thank the following people for offering suggestions, corrections and assistance with various drafts of this article: Fred Bremmer, Keith Briggs, Andrew Dalke, Fred L. Drake, Jr., Carel Fellinger, David Goodger, Mark Hammond, Stephen Hansen, Michael Hudson, Jack Jansen, Marc-André Lemburg, Martin von Löwis, Fredrik Lundh, Michael McLay, Nick Mathewson, Paul Moore, Gustavo Niemeyer, Don O’Donnell, Joonas Paalasma, Tim Peters, Jens Quade, Tom Reinhardt, Neil Schemenauer, Guido van Rossum, Greg Ward, Edward Welbourne.