mirror of https://github.com/python/cpython
1334 lines
60 KiB
TeX
1334 lines
60 KiB
TeX
\documentclass{howto}
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% $Id$
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\title{What's New in Python 2.0}
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\release{1.02}
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\author{A.M. Kuchling and Moshe Zadka}
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\authoraddress{\email{amk@amk.ca}, \email{moshez@twistedmatrix.com} }
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\begin{document}
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\maketitle\tableofcontents
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\section{Introduction}
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A new release of Python, version 2.0, was released on October 16, 2000. This
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article covers the exciting new features in 2.0, highlights some other
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useful changes, and points out a few incompatible changes that may require
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rewriting code.
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Python's development never completely stops between releases, and a
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steady flow of bug fixes and improvements are always being submitted.
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A host of minor fixes, a few optimizations, additional docstrings, and
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better error messages went into 2.0; to list them all would be
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impossible, but they're certainly significant. Consult the
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publicly-available CVS logs if you want to see the full list. This
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progress is due to the five developers working for
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PythonLabs are now getting paid to spend their days fixing bugs,
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and also due to the improved communication resulting
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from moving to SourceForge.
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% ======================================================================
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\section{What About Python 1.6?}
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Python 1.6 can be thought of as the Contractual Obligations Python
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release. After the core development team left CNRI in May 2000, CNRI
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requested that a 1.6 release be created, containing all the work on
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Python that had been performed at CNRI. Python 1.6 therefore
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represents the state of the CVS tree as of May 2000, with the most
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significant new feature being Unicode support. Development continued
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after May, of course, so the 1.6 tree received a few fixes to ensure
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that it's forward-compatible with Python 2.0. 1.6 is therefore part
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of Python's evolution, and not a side branch.
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So, should you take much interest in Python 1.6? Probably not. The
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1.6final and 2.0beta1 releases were made on the same day (September 5,
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2000), the plan being to finalize Python 2.0 within a month or so. If
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you have applications to maintain, there seems little point in
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breaking things by moving to 1.6, fixing them, and then having another
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round of breakage within a month by moving to 2.0; you're better off
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just going straight to 2.0. Most of the really interesting features
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described in this document are only in 2.0, because a lot of work was
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done between May and September.
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% ======================================================================
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\section{New Development Process}
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The most important change in Python 2.0 may not be to the code at all,
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but to how Python is developed: in May 2000 the Python developers
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began using the tools made available by SourceForge for storing
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source code, tracking bug reports, and managing the queue of patch
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submissions. To report bugs or submit patches for Python 2.0, use the
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bug tracking and patch manager tools available from Python's project
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page, located at \url{http://sourceforge.net/projects/python/}.
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The most important of the services now hosted at SourceForge is the
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Python CVS tree, the version-controlled repository containing the
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source code for Python. Previously, there were roughly 7 or so people
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who had write access to the CVS tree, and all patches had to be
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inspected and checked in by one of the people on this short list.
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Obviously, this wasn't very scalable. By moving the CVS tree to
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SourceForge, it became possible to grant write access to more people;
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as of September 2000 there were 27 people able to check in changes, a
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fourfold increase. This makes possible large-scale changes that
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wouldn't be attempted if they'd have to be filtered through the small
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group of core developers. For example, one day Peter Schneider-Kamp
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took it into his head to drop K\&R C compatibility and convert the C
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source for Python to ANSI C. After getting approval on the python-dev
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mailing list, he launched into a flurry of checkins that lasted about
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a week, other developers joined in to help, and the job was done. If
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there were only 5 people with write access, probably that task would
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have been viewed as ``nice, but not worth the time and effort needed''
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and it would never have gotten done.
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The shift to using SourceForge's services has resulted in a remarkable
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increase in the speed of development. Patches now get submitted,
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commented on, revised by people other than the original submitter, and
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bounced back and forth between people until the patch is deemed worth
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checking in. Bugs are tracked in one central location and can be
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assigned to a specific person for fixing, and we can count the number
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of open bugs to measure progress. This didn't come without a cost:
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developers now have more e-mail to deal with, more mailing lists to
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follow, and special tools had to be written for the new environment.
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For example, SourceForge sends default patch and bug notification
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e-mail messages that are completely unhelpful, so Ka-Ping Yee wrote an
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HTML screen-scraper that sends more useful messages.
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The ease of adding code caused a few initial growing pains, such as
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code was checked in before it was ready or without getting clear
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agreement from the developer group. The approval process that has
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emerged is somewhat similar to that used by the Apache group.
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Developers can vote +1, +0, -0, or -1 on a patch; +1 and -1 denote
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acceptance or rejection, while +0 and -0 mean the developer is mostly
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indifferent to the change, though with a slight positive or negative
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slant. The most significant change from the Apache model is that the
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voting is essentially advisory, letting Guido van Rossum, who has
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Benevolent Dictator For Life status, know what the general opinion is.
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He can still ignore the result of a vote, and approve or
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reject a change even if the community disagrees with him.
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Producing an actual patch is the last step in adding a new feature,
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and is usually easy compared to the earlier task of coming up with a
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good design. Discussions of new features can often explode into
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lengthy mailing list threads, making the discussion hard to follow,
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and no one can read every posting to python-dev. Therefore, a
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relatively formal process has been set up to write Python Enhancement
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Proposals (PEPs), modelled on the Internet RFC process. PEPs are
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draft documents that describe a proposed new feature, and are
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continually revised until the community reaches a consensus, either
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accepting or rejecting the proposal. Quoting from the introduction to
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PEP 1, ``PEP Purpose and Guidelines'':
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\begin{quotation}
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PEP stands for Python Enhancement Proposal. A PEP is a design
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document providing information to the Python community, or
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describing a new feature for Python. The PEP should provide a
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concise technical specification of the feature and a rationale for
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the feature.
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We intend PEPs to be the primary mechanisms for proposing new
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features, for collecting community input on an issue, and for
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documenting the design decisions that have gone into Python. The
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PEP author is responsible for building consensus within the
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community and documenting dissenting opinions.
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\end{quotation}
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Read the rest of PEP 1 for the details of the PEP editorial process,
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style, and format. PEPs are kept in the Python CVS tree on
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SourceForge, though they're not part of the Python 2.0 distribution,
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and are also available in HTML form from
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\url{http://www.python.org/peps/}. As of September 2000,
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there are 25 PEPS, ranging from PEP 201, ``Lockstep Iteration'', to
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PEP 225, ``Elementwise/Objectwise Operators''.
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% ======================================================================
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\section{Unicode}
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The largest new feature in Python 2.0 is a new fundamental data type:
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Unicode strings. Unicode uses 16-bit numbers to represent characters
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instead of the 8-bit number used by ASCII, meaning that 65,536
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distinct characters can be supported.
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The final interface for Unicode support was arrived at through
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countless often-stormy discussions on the python-dev mailing list, and
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mostly implemented by Marc-Andr\'e Lemburg, based on a Unicode string
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type implementation by Fredrik Lundh. A detailed explanation of the
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interface was written up as \pep{100}, ``Python Unicode Integration''.
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This article will simply cover the most significant points about the
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Unicode interfaces.
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In Python source code, Unicode strings are written as
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\code{u"string"}. Arbitrary Unicode characters can be written using a
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new escape sequence, \code{\e u\var{HHHH}}, where \var{HHHH} is a
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4-digit hexadecimal number from 0000 to FFFF. The existing
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\code{\e x\var{HHHH}} escape sequence can also be used, and octal
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escapes can be used for characters up to U+01FF, which is represented
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by \code{\e 777}.
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Unicode strings, just like regular strings, are an immutable sequence
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type. They can be indexed and sliced, but not modified in place.
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Unicode strings have an \method{encode( \optional{encoding} )} method
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that returns an 8-bit string in the desired encoding. Encodings are
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named by strings, such as \code{'ascii'}, \code{'utf-8'},
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\code{'iso-8859-1'}, or whatever. A codec API is defined for
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implementing and registering new encodings that are then available
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throughout a Python program. If an encoding isn't specified, the
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default encoding is usually 7-bit ASCII, though it can be changed for
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your Python installation by calling the
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\function{sys.setdefaultencoding(\var{encoding})} function in a
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customised version of \file{site.py}.
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Combining 8-bit and Unicode strings always coerces to Unicode, using
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the default ASCII encoding; the result of \code{'a' + u'bc'} is
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\code{u'abc'}.
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New built-in functions have been added, and existing built-ins
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modified to support Unicode:
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\begin{itemize}
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\item \code{unichr(\var{ch})} returns a Unicode string 1 character
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long, containing the character \var{ch}.
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\item \code{ord(\var{u})}, where \var{u} is a 1-character regular or Unicode string, returns the number of the character as an integer.
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\item \code{unicode(\var{string} \optional{, \var{encoding}}
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\optional{, \var{errors}} ) } creates a Unicode string from an 8-bit
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string. \code{encoding} is a string naming the encoding to use.
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The \code{errors} parameter specifies the treatment of characters that
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are invalid for the current encoding; passing \code{'strict'} as the
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value causes an exception to be raised on any encoding error, while
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\code{'ignore'} causes errors to be silently ignored and
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\code{'replace'} uses U+FFFD, the official replacement character, in
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case of any problems.
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\item The \keyword{exec} statement, and various built-ins such as
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\code{eval()}, \code{getattr()}, and \code{setattr()} will also
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accept Unicode strings as well as regular strings. (It's possible
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that the process of fixing this missed some built-ins; if you find a
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built-in function that accepts strings but doesn't accept Unicode
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strings at all, please report it as a bug.)
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\end{itemize}
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A new module, \module{unicodedata}, provides an interface to Unicode
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character properties. For example, \code{unicodedata.category(u'A')}
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returns the 2-character string 'Lu', the 'L' denoting it's a letter,
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and 'u' meaning that it's uppercase.
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\code{u.bidirectional(u'\e x0660')} returns 'AN', meaning that U+0660 is
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an Arabic number.
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The \module{codecs} module contains functions to look up existing encodings
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and register new ones. Unless you want to implement a
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new encoding, you'll most often use the
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\function{codecs.lookup(\var{encoding})} function, which returns a
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4-element tuple: \code{(\var{encode_func},
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\var{decode_func}, \var{stream_reader}, \var{stream_writer})}.
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\begin{itemize}
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\item \var{encode_func} is a function that takes a Unicode string, and
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returns a 2-tuple \code{(\var{string}, \var{length})}. \var{string}
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is an 8-bit string containing a portion (perhaps all) of the Unicode
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string converted into the given encoding, and \var{length} tells you
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how much of the Unicode string was converted.
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\item \var{decode_func} is the opposite of \var{encode_func}, taking
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an 8-bit string and returning a 2-tuple \code{(\var{ustring},
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\var{length})}, consisting of the resulting Unicode string
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\var{ustring} and the integer \var{length} telling how much of the
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8-bit string was consumed.
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\item \var{stream_reader} is a class that supports decoding input from
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a stream. \var{stream_reader(\var{file_obj})} returns an object that
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supports the \method{read()}, \method{readline()}, and
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\method{readlines()} methods. These methods will all translate from
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the given encoding and return Unicode strings.
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\item \var{stream_writer}, similarly, is a class that supports
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encoding output to a stream. \var{stream_writer(\var{file_obj})}
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returns an object that supports the \method{write()} and
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\method{writelines()} methods. These methods expect Unicode strings,
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translating them to the given encoding on output.
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\end{itemize}
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For example, the following code writes a Unicode string into a file,
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encoding it as UTF-8:
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\begin{verbatim}
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import codecs
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unistr = u'\u0660\u2000ab ...'
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(UTF8_encode, UTF8_decode,
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UTF8_streamreader, UTF8_streamwriter) = codecs.lookup('UTF-8')
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output = UTF8_streamwriter( open( '/tmp/output', 'wb') )
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output.write( unistr )
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output.close()
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\end{verbatim}
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The following code would then read UTF-8 input from the file:
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\begin{verbatim}
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input = UTF8_streamreader( open( '/tmp/output', 'rb') )
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print repr(input.read())
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input.close()
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\end{verbatim}
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Unicode-aware regular expressions are available through the
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\module{re} module, which has a new underlying implementation called
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SRE written by Fredrik Lundh of Secret Labs AB.
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A \code{-U} command line option was added which causes the Python
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compiler to interpret all string literals as Unicode string literals.
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This is intended to be used in testing and future-proofing your Python
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code, since some future version of Python may drop support for 8-bit
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strings and provide only Unicode strings.
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% ======================================================================
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\section{List Comprehensions}
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Lists are a workhorse data type in Python, and many programs
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manipulate a list at some point. Two common operations on lists are
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to loop over them, and either pick out the elements that meet a
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certain criterion, or apply some function to each element. For
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example, given a list of strings, you might want to pull out all the
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strings containing a given substring, or strip off trailing whitespace
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from each line.
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The existing \function{map()} and \function{filter()} functions can be
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used for this purpose, but they require a function as one of their
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arguments. This is fine if there's an existing built-in function that
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can be passed directly, but if there isn't, you have to create a
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little function to do the required work, and Python's scoping rules
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make the result ugly if the little function needs additional
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information. Take the first example in the previous paragraph,
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finding all the strings in the list containing a given substring. You
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could write the following to do it:
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\begin{verbatim}
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# Given the list L, make a list of all strings
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# containing the substring S.
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sublist = filter( lambda s, substring=S:
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string.find(s, substring) != -1,
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L)
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\end{verbatim}
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Because of Python's scoping rules, a default argument is used so that
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the anonymous function created by the \keyword{lambda} statement knows
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what substring is being searched for. List comprehensions make this
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cleaner:
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\begin{verbatim}
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sublist = [ s for s in L if string.find(s, S) != -1 ]
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\end{verbatim}
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List comprehensions have the form:
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\begin{verbatim}
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[ expression for expr in sequence1
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for expr2 in sequence2 ...
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for exprN in sequenceN
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if condition
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\end{verbatim}
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The \keyword{for}...\keyword{in} clauses contain the sequences to be
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iterated over. The sequences do not have to be the same length,
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because they are \emph{not} iterated over in parallel, but
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from left to right; this is explained more clearly in the following
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paragraphs. The elements of the generated list will be the successive
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values of \var{expression}. The final \keyword{if} clause is
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optional; if present, \var{expression} is only evaluated and added to
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the result if \var{condition} is true.
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To make the semantics very clear, a list comprehension is equivalent
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to the following Python code:
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\begin{verbatim}
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for expr1 in sequence1:
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for expr2 in sequence2:
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...
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for exprN in sequenceN:
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if (condition):
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# Append the value of
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# the expression to the
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# resulting list.
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\end{verbatim}
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This means that when there are \keyword{for}...\keyword{in} clauses,
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the resulting list will be equal to the product of the lengths of all
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the sequences. If you have two lists of length 3, the output list is
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9 elements long:
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\begin{verbatim}
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seq1 = 'abc'
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seq2 = (1,2,3)
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>>> [ (x,y) for x in seq1 for y in seq2]
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[('a', 1), ('a', 2), ('a', 3), ('b', 1), ('b', 2), ('b', 3), ('c', 1),
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('c', 2), ('c', 3)]
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\end{verbatim}
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To avoid introducing an ambiguity into Python's grammar, if
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\var{expression} is creating a tuple, it must be surrounded with
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parentheses. The first list comprehension below is a syntax error,
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while the second one is correct:
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\begin{verbatim}
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# Syntax error
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[ x,y for x in seq1 for y in seq2]
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# Correct
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[ (x,y) for x in seq1 for y in seq2]
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\end{verbatim}
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The idea of list comprehensions originally comes from the functional
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programming language Haskell (\url{http://www.haskell.org}). Greg
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Ewing argued most effectively for adding them to Python and wrote the
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initial list comprehension patch, which was then discussed for a
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seemingly endless time on the python-dev mailing list and kept
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up-to-date by Skip Montanaro.
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|
% ======================================================================
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\section{Augmented Assignment}
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Augmented assignment operators, another long-requested feature, have
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been added to Python 2.0. Augmented assignment operators include
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\code{+=}, \code{-=}, \code{*=}, and so forth. For example, the
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statement \code{a += 2} increments the value of the variable
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\code{a} by 2, equivalent to the slightly lengthier \code{a = a + 2}.
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The full list of supported assignment operators is \code{+=},
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\code{-=}, \code{*=}, \code{/=}, \code{\%=}, \code{**=}, \code{\&=},
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\code{|=}, \verb|^=|, \code{>>=}, and \code{<<=}. Python classes can
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override the augmented assignment operators by defining methods named
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\method{__iadd__}, \method{__isub__}, etc. For example, the following
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\class{Number} class stores a number and supports using += to create a
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new instance with an incremented value.
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\begin{verbatim}
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class Number:
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def __init__(self, value):
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self.value = value
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def __iadd__(self, increment):
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return Number( self.value + increment)
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n = Number(5)
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n += 3
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print n.value
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\end{verbatim}
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The \method{__iadd__} special method is called with the value of the
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increment, and should return a new instance with an appropriately
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modified value; this return value is bound as the new value of the
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variable on the left-hand side.
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Augmented assignment operators were first introduced in the C
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programming language, and most C-derived languages, such as
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\program{awk}, C++, Java, Perl, and PHP also support them. The augmented
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assignment patch was implemented by Thomas Wouters.
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% ======================================================================
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\section{String Methods}
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Until now string-manipulation functionality was in the \module{string}
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module, which was usually a front-end for the \module{strop}
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module written in C. The addition of Unicode posed a difficulty for
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|
the \module{strop} module, because the functions would all need to be
|
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rewritten in order to accept either 8-bit or Unicode strings. For
|
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functions such as \function{string.replace()}, which takes 3 string
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arguments, that means eight possible permutations, and correspondingly
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complicated code.
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Instead, Python 2.0 pushes the problem onto the string type, making
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string manipulation functionality available through methods on both
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8-bit strings and Unicode strings.
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\begin{verbatim}
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>>> 'andrew'.capitalize()
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'Andrew'
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>>> 'hostname'.replace('os', 'linux')
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'hlinuxtname'
|
|
>>> 'moshe'.find('sh')
|
|
2
|
|
\end{verbatim}
|
|
|
|
One thing that hasn't changed, a noteworthy April Fools' joke
|
|
notwithstanding, is that Python strings are immutable. Thus, the
|
|
string methods return new strings, and do not modify the string on
|
|
which they operate.
|
|
|
|
The old \module{string} module is still around for backwards
|
|
compatibility, but it mostly acts as a front-end to the new string
|
|
methods.
|
|
|
|
Two methods which have no parallel in pre-2.0 versions, although they
|
|
did exist in JPython for quite some time, are \method{startswith()}
|
|
and \method{endswith}. \code{s.startswith(t)} is equivalent to \code{s[:len(t)]
|
|
== t}, while \code{s.endswith(t)} is equivalent to \code{s[-len(t):] == t}.
|
|
|
|
One other method which deserves special mention is \method{join}. The
|
|
\method{join} method of a string receives one parameter, a sequence of
|
|
strings, and is equivalent to the \function{string.join} function from
|
|
the old \module{string} module, with the arguments reversed. In other
|
|
words, \code{s.join(seq)} is equivalent to the old
|
|
\code{string.join(seq, s)}.
|
|
|
|
% ======================================================================
|
|
\section{Garbage Collection of Cycles}
|
|
|
|
The C implementation of Python uses reference counting to implement
|
|
garbage collection. Every Python object maintains a count of the
|
|
number of references pointing to itself, and adjusts the count as
|
|
references are created or destroyed. Once the reference count reaches
|
|
zero, the object is no longer accessible, since you need to have a
|
|
reference to an object to access it, and if the count is zero, no
|
|
references exist any longer.
|
|
|
|
Reference counting has some pleasant properties: it's easy to
|
|
understand and implement, and the resulting implementation is
|
|
portable, fairly fast, and reacts well with other libraries that
|
|
implement their own memory handling schemes. The major problem with
|
|
reference counting is that it sometimes doesn't realise that objects
|
|
are no longer accessible, resulting in a memory leak. This happens
|
|
when there are cycles of references.
|
|
|
|
Consider the simplest possible cycle,
|
|
a class instance which has a reference to itself:
|
|
|
|
\begin{verbatim}
|
|
instance = SomeClass()
|
|
instance.myself = instance
|
|
\end{verbatim}
|
|
|
|
After the above two lines of code have been executed, the reference
|
|
count of \code{instance} is 2; one reference is from the variable
|
|
named \samp{'instance'}, and the other is from the \samp{myself}
|
|
attribute of the instance.
|
|
|
|
If the next line of code is \code{del instance}, what happens? The
|
|
reference count of \code{instance} is decreased by 1, so it has a
|
|
reference count of 1; the reference in the \samp{myself} attribute
|
|
still exists. Yet the instance is no longer accessible through Python
|
|
code, and it could be deleted. Several objects can participate in a
|
|
cycle if they have references to each other, causing all of the
|
|
objects to be leaked.
|
|
|
|
Python 2.0 fixes this problem by periodically executing a cycle
|
|
detection algorithm which looks for inaccessible cycles and deletes
|
|
the objects involved. A new \module{gc} module provides functions to
|
|
perform a garbage collection, obtain debugging statistics, and tuning
|
|
the collector's parameters.
|
|
|
|
Running the cycle detection algorithm takes some time, and therefore
|
|
will result in some additional overhead. It is hoped that after we've
|
|
gotten experience with the cycle collection from using 2.0, Python 2.1
|
|
will be able to minimize the overhead with careful tuning. It's not
|
|
yet obvious how much performance is lost, because benchmarking this is
|
|
tricky and depends crucially on how often the program creates and
|
|
destroys objects. The detection of cycles can be disabled when Python
|
|
is compiled, if you can't afford even a tiny speed penalty or suspect
|
|
that the cycle collection is buggy, by specifying the
|
|
\samp{--without-cycle-gc} switch when running the \file{configure}
|
|
script.
|
|
|
|
Several people tackled this problem and contributed to a solution. An
|
|
early implementation of the cycle detection approach was written by
|
|
Toby Kelsey. The current algorithm was suggested by Eric Tiedemann
|
|
during a visit to CNRI, and Guido van Rossum and Neil Schemenauer
|
|
wrote two different implementations, which were later integrated by
|
|
Neil. Lots of other people offered suggestions along the way; the
|
|
March 2000 archives of the python-dev mailing list contain most of the
|
|
relevant discussion, especially in the threads titled ``Reference
|
|
cycle collection for Python'' and ``Finalization again''.
|
|
|
|
% ======================================================================
|
|
\section{Other Core Changes}
|
|
|
|
Various minor changes have been made to Python's syntax and built-in
|
|
functions. None of the changes are very far-reaching, but they're
|
|
handy conveniences.
|
|
|
|
\subsection{Minor Language Changes}
|
|
|
|
A new syntax makes it more convenient to call a given function
|
|
with a tuple of arguments and/or a dictionary of keyword arguments.
|
|
In Python 1.5 and earlier, you'd use the \function{apply()}
|
|
built-in function: \code{apply(f, \var{args}, \var{kw})} calls the
|
|
function \function{f()} with the argument tuple \var{args} and the
|
|
keyword arguments in the dictionary \var{kw}. \function{apply()}
|
|
is the same in 2.0, but thanks to a patch from
|
|
Greg Ewing, \code{f(*\var{args}, **\var{kw})} as a shorter
|
|
and clearer way to achieve the same effect. This syntax is
|
|
symmetrical with the syntax for defining functions:
|
|
|
|
\begin{verbatim}
|
|
def f(*args, **kw):
|
|
# args is a tuple of positional args,
|
|
# kw is a dictionary of keyword args
|
|
...
|
|
\end{verbatim}
|
|
|
|
The \keyword{print} statement can now have its output directed to a
|
|
file-like object by following the \keyword{print} with
|
|
\verb|>> file|, similar to the redirection operator in Unix shells.
|
|
Previously you'd either have to use the \method{write()} method of the
|
|
file-like object, which lacks the convenience and simplicity of
|
|
\keyword{print}, or you could assign a new value to
|
|
\code{sys.stdout} and then restore the old value. For sending output to standard error,
|
|
it's much easier to write this:
|
|
|
|
\begin{verbatim}
|
|
print >> sys.stderr, "Warning: action field not supplied"
|
|
\end{verbatim}
|
|
|
|
Modules can now be renamed on importing them, using the syntax
|
|
\code{import \var{module} as \var{name}} or \code{from \var{module}
|
|
import \var{name} as \var{othername}}. The patch was submitted by
|
|
Thomas Wouters.
|
|
|
|
A new format style is available when using the \code{\%} operator;
|
|
'\%r' will insert the \function{repr()} of its argument. This was
|
|
also added from symmetry considerations, this time for symmetry with
|
|
the existing '\%s' format style, which inserts the \function{str()} of
|
|
its argument. For example, \code{'\%r \%s' \% ('abc', 'abc')} returns a
|
|
string containing \verb|'abc' abc|.
|
|
|
|
Previously there was no way to implement a class that overrode
|
|
Python's built-in \keyword{in} operator and implemented a custom
|
|
version. \code{\var{obj} in \var{seq}} returns true if \var{obj} is
|
|
present in the sequence \var{seq}; Python computes this by simply
|
|
trying every index of the sequence until either \var{obj} is found or
|
|
an \exception{IndexError} is encountered. Moshe Zadka contributed a
|
|
patch which adds a \method{__contains__} magic method for providing a
|
|
custom implementation for \keyword{in}. Additionally, new built-in
|
|
objects written in C can define what \keyword{in} means for them via a
|
|
new slot in the sequence protocol.
|
|
|
|
Earlier versions of Python used a recursive algorithm for deleting
|
|
objects. Deeply nested data structures could cause the interpreter to
|
|
fill up the C stack and crash; Christian Tismer rewrote the deletion
|
|
logic to fix this problem. On a related note, comparing recursive
|
|
objects recursed infinitely and crashed; Jeremy Hylton rewrote the
|
|
code to no longer crash, producing a useful result instead. For
|
|
example, after this code:
|
|
|
|
\begin{verbatim}
|
|
a = []
|
|
b = []
|
|
a.append(a)
|
|
b.append(b)
|
|
\end{verbatim}
|
|
|
|
The comparison \code{a==b} returns true, because the two recursive
|
|
data structures are isomorphic. See the thread ``trashcan
|
|
and PR\#7'' in the April 2000 archives of the python-dev mailing list
|
|
for the discussion leading up to this implementation, and some useful
|
|
relevant links.
|
|
% Starting URL:
|
|
% http://www.python.org/pipermail/python-dev/2000-April/004834.html
|
|
|
|
Note that comparisons can now also raise exceptions. In earlier
|
|
versions of Python, a comparison operation such as \code{cmp(a,b)}
|
|
would always produce an answer, even if a user-defined
|
|
\method{__cmp__} method encountered an error, since the resulting
|
|
exception would simply be silently swallowed.
|
|
|
|
Work has been done on porting Python to 64-bit Windows on the Itanium
|
|
processor, mostly by Trent Mick of ActiveState. (Confusingly,
|
|
\code{sys.platform} is still \code{'win32'} on Win64 because it seems
|
|
that for ease of porting, MS Visual C++ treats code as 32 bit on Itanium.)
|
|
PythonWin also supports Windows CE; see the Python CE page at
|
|
\url{http://starship.python.net/crew/mhammond/ce/} for more
|
|
information.
|
|
|
|
Another new platform is Darwin/MacOS X; inital support for it is in
|
|
Python 2.0. Dynamic loading works, if you specify ``configure
|
|
--with-dyld --with-suffix=.x''. Consult the README in the Python
|
|
source distribution for more instructions.
|
|
|
|
An attempt has been made to alleviate one of Python's warts, the
|
|
often-confusing \exception{NameError} exception when code refers to a
|
|
local variable before the variable has been assigned a value. For
|
|
example, the following code raises an exception on the \keyword{print}
|
|
statement in both 1.5.2 and 2.0; in 1.5.2 a \exception{NameError}
|
|
exception is raised, while 2.0 raises a new
|
|
\exception{UnboundLocalError} exception.
|
|
\exception{UnboundLocalError} is a subclass of \exception{NameError},
|
|
so any existing code that expects \exception{NameError} to be raised
|
|
should still work.
|
|
|
|
\begin{verbatim}
|
|
def f():
|
|
print "i=",i
|
|
i = i + 1
|
|
f()
|
|
\end{verbatim}
|
|
|
|
Two new exceptions, \exception{TabError} and
|
|
\exception{IndentationError}, have been introduced. They're both
|
|
subclasses of \exception{SyntaxError}, and are raised when Python code
|
|
is found to be improperly indented.
|
|
|
|
\subsection{Changes to Built-in Functions}
|
|
|
|
A new built-in, \function{zip(\var{seq1}, \var{seq2}, ...)}, has been
|
|
added. \function{zip()} returns a list of tuples where each tuple
|
|
contains the i-th element from each of the argument sequences. The
|
|
difference between \function{zip()} and \code{map(None, \var{seq1},
|
|
\var{seq2})} is that \function{map()} pads the sequences with
|
|
\code{None} if the sequences aren't all of the same length, while
|
|
\function{zip()} truncates the returned list to the length of the
|
|
shortest argument sequence.
|
|
|
|
The \function{int()} and \function{long()} functions now accept an
|
|
optional ``base'' parameter when the first argument is a string.
|
|
\code{int('123', 10)} returns 123, while \code{int('123', 16)} returns
|
|
291. \code{int(123, 16)} raises a \exception{TypeError} exception
|
|
with the message ``can't convert non-string with explicit base''.
|
|
|
|
A new variable holding more detailed version information has been
|
|
added to the \module{sys} module. \code{sys.version_info} is a tuple
|
|
\code{(\var{major}, \var{minor}, \var{micro}, \var{level},
|
|
\var{serial})} For example, in a hypothetical 2.0.1beta1,
|
|
\code{sys.version_info} would be \code{(2, 0, 1, 'beta', 1)}.
|
|
\var{level} is a string such as \code{"alpha"}, \code{"beta"}, or
|
|
\code{"final"} for a final release.
|
|
|
|
Dictionaries have an odd new method, \method{setdefault(\var{key},
|
|
\var{default})}, which behaves similarly to the existing
|
|
\method{get()} method. However, if the key is missing,
|
|
\method{setdefault()} both returns the value of \var{default} as
|
|
\method{get()} would do, and also inserts it into the dictionary as
|
|
the value for \var{key}. Thus, the following lines of code:
|
|
|
|
\begin{verbatim}
|
|
if dict.has_key( key ): return dict[key]
|
|
else:
|
|
dict[key] = []
|
|
return dict[key]
|
|
\end{verbatim}
|
|
|
|
can be reduced to a single \code{return dict.setdefault(key, [])} statement.
|
|
|
|
The interpreter sets a maximum recursion depth in order to catch
|
|
runaway recursion before filling the C stack and causing a core dump
|
|
or GPF.. Previously this limit was fixed when you compiled Python,
|
|
but in 2.0 the maximum recursion depth can be read and modified using
|
|
\function{sys.getrecursionlimit} and \function{sys.setrecursionlimit}.
|
|
The default value is 1000, and a rough maximum value for a given
|
|
platform can be found by running a new script,
|
|
\file{Misc/find_recursionlimit.py}.
|
|
|
|
% ======================================================================
|
|
\section{Porting to 2.0}
|
|
|
|
New Python releases try hard to be compatible with previous releases,
|
|
and the record has been pretty good. However, some changes are
|
|
considered useful enough, usually because they fix initial design decisions that
|
|
turned out to be actively mistaken, that breaking backward compatibility
|
|
can't always be avoided. This section lists the changes in Python 2.0
|
|
that may cause old Python code to break.
|
|
|
|
The change which will probably break the most code is tightening up
|
|
the arguments accepted by some methods. Some methods would take
|
|
multiple arguments and treat them as a tuple, particularly various
|
|
list methods such as \method{.append()} and \method{.insert()}.
|
|
In earlier versions of Python, if \code{L} is a list, \code{L.append(
|
|
1,2 )} appends the tuple \code{(1,2)} to the list. In Python 2.0 this
|
|
causes a \exception{TypeError} exception to be raised, with the
|
|
message: 'append requires exactly 1 argument; 2 given'. The fix is to
|
|
simply add an extra set of parentheses to pass both values as a tuple:
|
|
\code{L.append( (1,2) )}.
|
|
|
|
The earlier versions of these methods were more forgiving because they
|
|
used an old function in Python's C interface to parse their arguments;
|
|
2.0 modernizes them to use \function{PyArg_ParseTuple}, the current
|
|
argument parsing function, which provides more helpful error messages
|
|
and treats multi-argument calls as errors. If you absolutely must use
|
|
2.0 but can't fix your code, you can edit \file{Objects/listobject.c}
|
|
and define the preprocessor symbol \code{NO_STRICT_LIST_APPEND} to
|
|
preserve the old behaviour; this isn't recommended.
|
|
|
|
Some of the functions in the \module{socket} module are still
|
|
forgiving in this way. For example, \function{socket.connect(
|
|
('hostname', 25) )} is the correct form, passing a tuple representing
|
|
an IP address, but \function{socket.connect( 'hostname', 25 )} also
|
|
works. \function{socket.connect_ex()} and \function{socket.bind()} are
|
|
similarly easy-going. 2.0alpha1 tightened these functions up, but
|
|
because the documentation actually used the erroneous multiple
|
|
argument form, many people wrote code which would break with the
|
|
stricter checking. GvR backed out the changes in the face of public
|
|
reaction, so for the \module{socket} module, the documentation was
|
|
fixed and the multiple argument form is simply marked as deprecated;
|
|
it \emph{will} be tightened up again in a future Python version.
|
|
|
|
The \code{\e x} escape in string literals now takes exactly 2 hex
|
|
digits. Previously it would consume all the hex digits following the
|
|
'x' and take the lowest 8 bits of the result, so \code{\e x123456} was
|
|
equivalent to \code{\e x56}.
|
|
|
|
The \exception{AttributeError} and \exception{NameError} exceptions
|
|
have a more friendly error message, whose text will be something like
|
|
\code{'Spam' instance has no attribute 'eggs'} or \code{name 'eggs' is
|
|
not defined}. Previously the error message was just the missing
|
|
attribute name \code{eggs}, and code written to take advantage of this
|
|
fact will break in 2.0.
|
|
|
|
Some work has been done to make integers and long integers a bit more
|
|
interchangeable. In 1.5.2, large-file support was added for Solaris,
|
|
to allow reading files larger than 2Gb; this made the \method{tell()}
|
|
method of file objects return a long integer instead of a regular
|
|
integer. Some code would subtract two file offsets and attempt to use
|
|
the result to multiply a sequence or slice a string, but this raised a
|
|
\exception{TypeError}. In 2.0, long integers can be used to multiply
|
|
or slice a sequence, and it'll behave as you'd intuitively expect it
|
|
to; \code{3L * 'abc'} produces 'abcabcabc', and \code{
|
|
(0,1,2,3)[2L:4L]} produces (2,3). Long integers can also be used in
|
|
various contexts where previously only integers were accepted, such
|
|
as in the \method{seek()} method of file objects, and in the formats
|
|
supported by the \verb|%| operator (\verb|%d|, \verb|%i|, \verb|%x|,
|
|
etc.). For example, \code{"\%d" \% 2L**64} will produce the string
|
|
\samp{18446744073709551616}.
|
|
|
|
The subtlest long integer change of all is that the \function{str()}
|
|
of a long integer no longer has a trailing 'L' character, though
|
|
\function{repr()} still includes it. The 'L' annoyed many people who
|
|
wanted to print long integers that looked just like regular integers,
|
|
since they had to go out of their way to chop off the character. This
|
|
is no longer a problem in 2.0, but code which does \code{str(longval)[:-1]} and assumes the 'L' is there, will now lose
|
|
the final digit.
|
|
|
|
Taking the \function{repr()} of a float now uses a different
|
|
formatting precision than \function{str()}. \function{repr()} uses
|
|
\code{\%.17g} format string for C's \function{sprintf()}, while
|
|
\function{str()} uses \code{\%.12g} as before. The effect is that
|
|
\function{repr()} may occasionally show more decimal places than
|
|
\function{str()}, for certain numbers.
|
|
For example, the number 8.1 can't be represented exactly in binary, so
|
|
\code{repr(8.1)} is \code{'8.0999999999999996'}, while str(8.1) is
|
|
\code{'8.1'}.
|
|
|
|
The \code{-X} command-line option, which turned all standard
|
|
exceptions into strings instead of classes, has been removed; the
|
|
standard exceptions will now always be classes. The
|
|
\module{exceptions} module containing the standard exceptions was
|
|
translated from Python to a built-in C module, written by Barry Warsaw
|
|
and Fredrik Lundh.
|
|
|
|
% Commented out for now -- I don't think anyone will care.
|
|
%The pattern and match objects provided by SRE are C types, not Python
|
|
%class instances as in 1.5. This means you can no longer inherit from
|
|
%\class{RegexObject} or \class{MatchObject}, but that shouldn't be much
|
|
%of a problem since no one should have been doing that in the first
|
|
%place.
|
|
|
|
% ======================================================================
|
|
\section{Extending/Embedding Changes}
|
|
|
|
Some of the changes are under the covers, and will only be apparent to
|
|
people writing C extension modules or embedding a Python interpreter
|
|
in a larger application. If you aren't dealing with Python's C API,
|
|
you can safely skip this section.
|
|
|
|
The version number of the Python C API was incremented, so C
|
|
extensions compiled for 1.5.2 must be recompiled in order to work with
|
|
2.0. On Windows, it's not possible for Python 2.0 to import a third
|
|
party extension built for Python 1.5.x due to how Windows DLLs work,
|
|
so Python will raise an exception and the import will fail.
|
|
|
|
Users of Jim Fulton's ExtensionClass module will be pleased to find
|
|
out that hooks have been added so that ExtensionClasses are now
|
|
supported by \function{isinstance()} and \function{issubclass()}.
|
|
This means you no longer have to remember to write code such as
|
|
\code{if type(obj) == myExtensionClass}, but can use the more natural
|
|
\code{if isinstance(obj, myExtensionClass)}.
|
|
|
|
The \file{Python/importdl.c} file, which was a mass of \#ifdefs to
|
|
support dynamic loading on many different platforms, was cleaned up
|
|
and reorganised by Greg Stein. \file{importdl.c} is now quite small,
|
|
and platform-specific code has been moved into a bunch of
|
|
\file{Python/dynload_*.c} files. Another cleanup: there were also a
|
|
number of \file{my*.h} files in the Include/ directory that held
|
|
various portability hacks; they've been merged into a single file,
|
|
\file{Include/pyport.h}.
|
|
|
|
Vladimir Marangozov's long-awaited malloc restructuring was completed,
|
|
to make it easy to have the Python interpreter use a custom allocator
|
|
instead of C's standard \function{malloc()}. For documentation, read
|
|
the comments in \file{Include/pymem.h} and
|
|
\file{Include/objimpl.h}. For the lengthy discussions during which
|
|
the interface was hammered out, see the Web archives of the 'patches'
|
|
and 'python-dev' lists at python.org.
|
|
|
|
Recent versions of the GUSI development environment for MacOS support
|
|
POSIX threads. Therefore, Python's POSIX threading support now works
|
|
on the Macintosh. Threading support using the user-space GNU \texttt{pth}
|
|
library was also contributed.
|
|
|
|
Threading support on Windows was enhanced, too. Windows supports
|
|
thread locks that use kernel objects only in case of contention; in
|
|
the common case when there's no contention, they use simpler functions
|
|
which are an order of magnitude faster. A threaded version of Python
|
|
1.5.2 on NT is twice as slow as an unthreaded version; with the 2.0
|
|
changes, the difference is only 10\%. These improvements were
|
|
contributed by Yakov Markovitch.
|
|
|
|
Python 2.0's source now uses only ANSI C prototypes, so compiling Python now
|
|
requires an ANSI C compiler, and can no longer be done using a compiler that
|
|
only supports K\&R C.
|
|
|
|
Previously the Python virtual machine used 16-bit numbers in its
|
|
bytecode, limiting the size of source files. In particular, this
|
|
affected the maximum size of literal lists and dictionaries in Python
|
|
source; occasionally people who are generating Python code would run
|
|
into this limit. A patch by Charles G. Waldman raises the limit from
|
|
\verb|2^16| to \verb|2^{32}|.
|
|
|
|
Three new convenience functions intended for adding constants to a
|
|
module's dictionary at module initialization time were added:
|
|
\function{PyModule_AddObject()}, \function{PyModule_AddIntConstant()},
|
|
and \function{PyModule_AddStringConstant()}. Each of these functions
|
|
takes a module object, a null-terminated C string containing the name
|
|
to be added, and a third argument for the value to be assigned to the
|
|
name. This third argument is, respectively, a Python object, a C
|
|
long, or a C string.
|
|
|
|
A wrapper API was added for Unix-style signal handlers.
|
|
\function{PyOS_getsig()} gets a signal handler and
|
|
\function{PyOS_setsig()} will set a new handler.
|
|
|
|
% ======================================================================
|
|
\section{Distutils: Making Modules Easy to Install}
|
|
|
|
Before Python 2.0, installing modules was a tedious affair -- there
|
|
was no way to figure out automatically where Python is installed, or
|
|
what compiler options to use for extension modules. Software authors
|
|
had to go through an arduous ritual of editing Makefiles and
|
|
configuration files, which only really work on Unix and leave Windows
|
|
and MacOS unsupported. Python users faced wildly differing
|
|
installation instructions which varied between different extension
|
|
packages, which made adminstering a Python installation something of a
|
|
chore.
|
|
|
|
The SIG for distribution utilities, shepherded by Greg Ward, has
|
|
created the Distutils, a system to make package installation much
|
|
easier. They form the \module{distutils} package, a new part of
|
|
Python's standard library. In the best case, installing a Python
|
|
module from source will require the same steps: first you simply mean
|
|
unpack the tarball or zip archive, and the run ``\code{python setup.py
|
|
install}''. The platform will be automatically detected, the compiler
|
|
will be recognized, C extension modules will be compiled, and the
|
|
distribution installed into the proper directory. Optional
|
|
command-line arguments provide more control over the installation
|
|
process, the distutils package offers many places to override defaults
|
|
-- separating the build from the install, building or installing in
|
|
non-default directories, and more.
|
|
|
|
In order to use the Distutils, you need to write a \file{setup.py}
|
|
script. For the simple case, when the software contains only .py
|
|
files, a minimal \file{setup.py} can be just a few lines long:
|
|
|
|
\begin{verbatim}
|
|
from distutils.core import setup
|
|
setup (name = "foo", version = "1.0",
|
|
py_modules = ["module1", "module2"])
|
|
\end{verbatim}
|
|
|
|
The \file{setup.py} file isn't much more complicated if the software
|
|
consists of a few packages:
|
|
|
|
\begin{verbatim}
|
|
from distutils.core import setup
|
|
setup (name = "foo", version = "1.0",
|
|
packages = ["package", "package.subpackage"])
|
|
\end{verbatim}
|
|
|
|
A C extension can be the most complicated case; here's an example taken from
|
|
the PyXML package:
|
|
|
|
|
|
\begin{verbatim}
|
|
from distutils.core import setup, Extension
|
|
|
|
expat_extension = Extension('xml.parsers.pyexpat',
|
|
define_macros = [('XML_NS', None)],
|
|
include_dirs = [ 'extensions/expat/xmltok',
|
|
'extensions/expat/xmlparse' ],
|
|
sources = [ 'extensions/pyexpat.c',
|
|
'extensions/expat/xmltok/xmltok.c',
|
|
'extensions/expat/xmltok/xmlrole.c',
|
|
]
|
|
)
|
|
setup (name = "PyXML", version = "0.5.4",
|
|
ext_modules =[ expat_extension ] )
|
|
\end{verbatim}
|
|
|
|
The Distutils can also take care of creating source and binary
|
|
distributions. The ``sdist'' command, run by ``\code{python setup.py
|
|
sdist}', builds a source distribution such as \file{foo-1.0.tar.gz}.
|
|
Adding new commands isn't difficult, ``bdist_rpm'' and
|
|
``bdist_wininst'' commands have already been contributed to create an
|
|
RPM distribution and a Windows installer for the software,
|
|
respectively. Commands to create other distribution formats such as
|
|
Debian packages and Solaris \file{.pkg} files are in various stages of
|
|
development.
|
|
|
|
All this is documented in a new manual, \textit{Distributing Python
|
|
Modules}, that joins the basic set of Python documentation.
|
|
|
|
% ======================================================================
|
|
\section{XML Modules}
|
|
|
|
Python 1.5.2 included a simple XML parser in the form of the
|
|
\module{xmllib} module, contributed by Sjoerd Mullender. Since
|
|
1.5.2's release, two different interfaces for processing XML have
|
|
become common: SAX2 (version 2 of the Simple API for XML) provides an
|
|
event-driven interface with some similarities to \module{xmllib}, and
|
|
the DOM (Document Object Model) provides a tree-based interface,
|
|
transforming an XML document into a tree of nodes that can be
|
|
traversed and modified. Python 2.0 includes a SAX2 interface and a
|
|
stripped-down DOM interface as part of the \module{xml} package.
|
|
Here we will give a brief overview of these new interfaces; consult
|
|
the Python documentation or the source code for complete details.
|
|
The Python XML SIG is also working on improved documentation.
|
|
|
|
\subsection{SAX2 Support}
|
|
|
|
SAX defines an event-driven interface for parsing XML. To use SAX,
|
|
you must write a SAX handler class. Handler classes inherit from
|
|
various classes provided by SAX, and override various methods that
|
|
will then be called by the XML parser. For example, the
|
|
\method{startElement} and \method{endElement} methods are called for
|
|
every starting and end tag encountered by the parser, the
|
|
\method{characters()} method is called for every chunk of character
|
|
data, and so forth.
|
|
|
|
The advantage of the event-driven approach is that that the whole
|
|
document doesn't have to be resident in memory at any one time, which
|
|
matters if you are processing really huge documents. However, writing
|
|
the SAX handler class can get very complicated if you're trying to
|
|
modify the document structure in some elaborate way.
|
|
|
|
For example, this little example program defines a handler that prints
|
|
a message for every starting and ending tag, and then parses the file
|
|
\file{hamlet.xml} using it:
|
|
|
|
\begin{verbatim}
|
|
from xml import sax
|
|
|
|
class SimpleHandler(sax.ContentHandler):
|
|
def startElement(self, name, attrs):
|
|
print 'Start of element:', name, attrs.keys()
|
|
|
|
def endElement(self, name):
|
|
print 'End of element:', name
|
|
|
|
# Create a parser object
|
|
parser = sax.make_parser()
|
|
|
|
# Tell it what handler to use
|
|
handler = SimpleHandler()
|
|
parser.setContentHandler( handler )
|
|
|
|
# Parse a file!
|
|
parser.parse( 'hamlet.xml' )
|
|
\end{verbatim}
|
|
|
|
For more information, consult the Python documentation, or the XML
|
|
HOWTO at \url{http://pyxml.sourceforge.net/topics/howto/xml-howto.html}.
|
|
|
|
\subsection{DOM Support}
|
|
|
|
The Document Object Model is a tree-based representation for an XML
|
|
document. A top-level \class{Document} instance is the root of the
|
|
tree, and has a single child which is the top-level \class{Element}
|
|
instance. This \class{Element} has children nodes representing
|
|
character data and any sub-elements, which may have further children
|
|
of their own, and so forth. Using the DOM you can traverse the
|
|
resulting tree any way you like, access element and attribute values,
|
|
insert and delete nodes, and convert the tree back into XML.
|
|
|
|
The DOM is useful for modifying XML documents, because you can create
|
|
a DOM tree, modify it by adding new nodes or rearranging subtrees, and
|
|
then produce a new XML document as output. You can also construct a
|
|
DOM tree manually and convert it to XML, which can be a more flexible
|
|
way of producing XML output than simply writing
|
|
\code{<tag1>}...\code{</tag1>} to a file.
|
|
|
|
The DOM implementation included with Python lives in the
|
|
\module{xml.dom.minidom} module. It's a lightweight implementation of
|
|
the Level 1 DOM with support for XML namespaces. The
|
|
\function{parse()} and \function{parseString()} convenience
|
|
functions are provided for generating a DOM tree:
|
|
|
|
\begin{verbatim}
|
|
from xml.dom import minidom
|
|
doc = minidom.parse('hamlet.xml')
|
|
\end{verbatim}
|
|
|
|
\code{doc} is a \class{Document} instance. \class{Document}, like all
|
|
the other DOM classes such as \class{Element} and \class{Text}, is a
|
|
subclass of the \class{Node} base class. All the nodes in a DOM tree
|
|
therefore support certain common methods, such as \method{toxml()}
|
|
which returns a string containing the XML representation of the node
|
|
and its children. Each class also has special methods of its own; for
|
|
example, \class{Element} and \class{Document} instances have a method
|
|
to find all child elements with a given tag name. Continuing from the
|
|
previous 2-line example:
|
|
|
|
\begin{verbatim}
|
|
perslist = doc.getElementsByTagName( 'PERSONA' )
|
|
print perslist[0].toxml()
|
|
print perslist[1].toxml()
|
|
\end{verbatim}
|
|
|
|
For the \textit{Hamlet} XML file, the above few lines output:
|
|
|
|
\begin{verbatim}
|
|
<PERSONA>CLAUDIUS, king of Denmark. </PERSONA>
|
|
<PERSONA>HAMLET, son to the late, and nephew to the present king.</PERSONA>
|
|
\end{verbatim}
|
|
|
|
The root element of the document is available as
|
|
\code{doc.documentElement}, and its children can be easily modified
|
|
by deleting, adding, or removing nodes:
|
|
|
|
\begin{verbatim}
|
|
root = doc.documentElement
|
|
|
|
# Remove the first child
|
|
root.removeChild( root.childNodes[0] )
|
|
|
|
# Move the new first child to the end
|
|
root.appendChild( root.childNodes[0] )
|
|
|
|
# Insert the new first child (originally,
|
|
# the third child) before the 20th child.
|
|
root.insertBefore( root.childNodes[0], root.childNodes[20] )
|
|
\end{verbatim}
|
|
|
|
Again, I will refer you to the Python documentation for a complete
|
|
listing of the different \class{Node} classes and their various methods.
|
|
|
|
\subsection{Relationship to PyXML}
|
|
|
|
The XML Special Interest Group has been working on XML-related Python
|
|
code for a while. Its code distribution, called PyXML, is available
|
|
from the SIG's Web pages at \url{http://www.python.org/sigs/xml-sig/}.
|
|
The PyXML distribution also used the package name \samp{xml}. If
|
|
you've written programs that used PyXML, you're probably wondering
|
|
about its compatibility with the 2.0 \module{xml} package.
|
|
|
|
The answer is that Python 2.0's \module{xml} package isn't compatible
|
|
with PyXML, but can be made compatible by installing a recent version
|
|
PyXML. Many applications can get by with the XML support that is
|
|
included with Python 2.0, but more complicated applications will
|
|
require that the full PyXML package will be installed. When
|
|
installed, PyXML versions 0.6.0 or greater will replace the
|
|
\module{xml} package shipped with Python, and will be a strict
|
|
superset of the standard package, adding a bunch of additional
|
|
features. Some of the additional features in PyXML include:
|
|
|
|
\begin{itemize}
|
|
\item 4DOM, a full DOM implementation
|
|
from FourThought, Inc.
|
|
\item The xmlproc validating parser, written by Lars Marius Garshol.
|
|
\item The \module{sgmlop} parser accelerator module, written by Fredrik Lundh.
|
|
\end{itemize}
|
|
|
|
% ======================================================================
|
|
\section{Module changes}
|
|
|
|
Lots of improvements and bugfixes were made to Python's extensive
|
|
standard library; some of the affected modules include
|
|
\module{readline}, \module{ConfigParser}, \module{cgi},
|
|
\module{calendar}, \module{posix}, \module{readline}, \module{xmllib},
|
|
\module{aifc}, \module{chunk, wave}, \module{random}, \module{shelve},
|
|
and \module{nntplib}. Consult the CVS logs for the exact
|
|
patch-by-patch details.
|
|
|
|
Brian Gallew contributed OpenSSL support for the \module{socket}
|
|
module. OpenSSL is an implementation of the Secure Socket Layer,
|
|
which encrypts the data being sent over a socket. When compiling
|
|
Python, you can edit \file{Modules/Setup} to include SSL support,
|
|
which adds an additional function to the \module{socket} module:
|
|
\function{socket.ssl(\var{socket}, \var{keyfile}, \var{certfile})},
|
|
which takes a socket object and returns an SSL socket. The
|
|
\module{httplib} and \module{urllib} modules were also changed to
|
|
support ``https://'' URLs, though no one has implemented FTP or SMTP
|
|
over SSL.
|
|
|
|
The \module{httplib} module has been rewritten by Greg Stein to
|
|
support HTTP/1.1. Backward compatibility with the 1.5 version of
|
|
\module{httplib} is provided, though using HTTP/1.1 features such as
|
|
pipelining will require rewriting code to use a different set of
|
|
interfaces.
|
|
|
|
The \module{Tkinter} module now supports Tcl/Tk version 8.1, 8.2, or
|
|
8.3, and support for the older 7.x versions has been dropped. The
|
|
Tkinter module now supports displaying Unicode strings in Tk widgets.
|
|
Also, Fredrik Lundh contributed an optimization which makes operations
|
|
like \code{create_line} and \code{create_polygon} much faster,
|
|
especially when using lots of coordinates.
|
|
|
|
The \module{curses} module has been greatly extended, starting from
|
|
Oliver Andrich's enhanced version, to provide many additional
|
|
functions from ncurses and SYSV curses, such as colour, alternative
|
|
character set support, pads, and mouse support. This means the module
|
|
is no longer compatible with operating systems that only have BSD
|
|
curses, but there don't seem to be any currently maintained OSes that
|
|
fall into this category.
|
|
|
|
As mentioned in the earlier discussion of 2.0's Unicode support, the
|
|
underlying implementation of the regular expressions provided by the
|
|
\module{re} module has been changed. SRE, a new regular expression
|
|
engine written by Fredrik Lundh and partially funded by Hewlett
|
|
Packard, supports matching against both 8-bit strings and Unicode
|
|
strings.
|
|
|
|
% ======================================================================
|
|
\section{New modules}
|
|
|
|
A number of new modules were added. We'll simply list them with brief
|
|
descriptions; consult the 2.0 documentation for the details of a
|
|
particular module.
|
|
|
|
\begin{itemize}
|
|
|
|
\item{\module{atexit}}:
|
|
For registering functions to be called before the Python interpreter exits.
|
|
Code that currently sets
|
|
\code{sys.exitfunc} directly should be changed to
|
|
use the \module{atexit} module instead, importing \module{atexit}
|
|
and calling \function{atexit.register()} with
|
|
the function to be called on exit.
|
|
(Contributed by Skip Montanaro.)
|
|
|
|
\item{\module{codecs}, \module{encodings}, \module{unicodedata}:} Added as part of the new Unicode support.
|
|
|
|
\item{\module{filecmp}:} Supersedes the old \module{cmp}, \module{cmpcache} and
|
|
\module{dircmp} modules, which have now become deprecated.
|
|
(Contributed by Gordon MacMillan and Moshe Zadka.)
|
|
|
|
\item{\module{gettext}:} This module provides internationalization
|
|
(I18N) and localization (L10N) support for Python programs by
|
|
providing an interface to the GNU gettext message catalog library.
|
|
(Integrated by Barry Warsaw, from separate contributions by Martin von
|
|
Loewis, Peter Funk, and James Henstridge.)
|
|
|
|
\item{\module{linuxaudiodev}:} Support for the \file{/dev/audio}
|
|
device on Linux, a twin to the existing \module{sunaudiodev} module.
|
|
(Contributed by Peter Bosch, with fixes by Jeremy Hylton.)
|
|
|
|
\item{\module{mmap}:} An interface to memory-mapped files on both
|
|
Windows and Unix. A file's contents can be mapped directly into
|
|
memory, at which point it behaves like a mutable string, so its
|
|
contents can be read and modified. They can even be passed to
|
|
functions that expect ordinary strings, such as the \module{re}
|
|
module. (Contributed by Sam Rushing, with some extensions by
|
|
A.M. Kuchling.)
|
|
|
|
\item{\module{pyexpat}:} An interface to the Expat XML parser.
|
|
(Contributed by Paul Prescod.)
|
|
|
|
\item{\module{robotparser}:} Parse a \file{robots.txt} file, which is
|
|
used for writing Web spiders that politely avoid certain areas of a
|
|
Web site. The parser accepts the contents of a \file{robots.txt} file,
|
|
builds a set of rules from it, and can then answer questions about
|
|
the fetchability of a given URL. (Contributed by Skip Montanaro.)
|
|
|
|
\item{\module{tabnanny}:} A module/script to
|
|
check Python source code for ambiguous indentation.
|
|
(Contributed by Tim Peters.)
|
|
|
|
\item{\module{UserString}:} A base class useful for deriving objects that behave like strings.
|
|
|
|
\item{\module{webbrowser}:} A module that provides a platform independent
|
|
way to launch a web browser on a specific URL. For each platform, various
|
|
browsers are tried in a specific order. The user can alter which browser
|
|
is launched by setting the \var{BROWSER} environment variable.
|
|
(Originally inspired by Eric S. Raymond's patch to \module{urllib}
|
|
which added similar functionality, but
|
|
the final module comes from code originally
|
|
implemented by Fred Drake as \file{Tools/idle/BrowserControl.py},
|
|
and adapted for the standard library by Fred.)
|
|
|
|
\item{\module{_winreg}:} An interface to the
|
|
Windows registry. \module{_winreg} is an adaptation of functions that
|
|
have been part of PythonWin since 1995, but has now been added to the core
|
|
distribution, and enhanced to support Unicode.
|
|
\module{_winreg} was written by Bill Tutt and Mark Hammond.
|
|
|
|
\item{\module{zipfile}:} A module for reading and writing ZIP-format
|
|
archives. These are archives produced by \program{PKZIP} on
|
|
DOS/Windows or \program{zip} on Unix, not to be confused with
|
|
\program{gzip}-format files (which are supported by the \module{gzip}
|
|
module)
|
|
(Contributed by James C. Ahlstrom.)
|
|
|
|
\item{\module{imputil}:} A module that provides a simpler way for
|
|
writing customised import hooks, in comparison to the existing
|
|
\module{ihooks} module. (Implemented by Greg Stein, with much
|
|
discussion on python-dev along the way.)
|
|
|
|
\end{itemize}
|
|
|
|
% ======================================================================
|
|
\section{IDLE Improvements}
|
|
|
|
IDLE is the official Python cross-platform IDE, written using Tkinter.
|
|
Python 2.0 includes IDLE 0.6, which adds a number of new features and
|
|
improvements. A partial list:
|
|
|
|
\begin{itemize}
|
|
\item UI improvements and optimizations,
|
|
especially in the area of syntax highlighting and auto-indentation.
|
|
|
|
\item The class browser now shows more information, such as the top
|
|
level functions in a module.
|
|
|
|
\item Tab width is now a user settable option. When opening an existing Python
|
|
file, IDLE automatically detects the indentation conventions, and adapts.
|
|
|
|
\item There is now support for calling browsers on various platforms,
|
|
used to open the Python documentation in a browser.
|
|
|
|
\item IDLE now has a command line, which is largely similar to
|
|
the vanilla Python interpreter.
|
|
|
|
\item Call tips were added in many places.
|
|
|
|
\item IDLE can now be installed as a package.
|
|
|
|
\item In the editor window, there is now a line/column bar at the bottom.
|
|
|
|
\item Three new keystroke commands: Check module (Alt-F5), Import
|
|
module (F5) and Run script (Ctrl-F5).
|
|
|
|
\end{itemize}
|
|
|
|
% ======================================================================
|
|
\section{Deleted and Deprecated Modules}
|
|
|
|
A few modules have been dropped because they're obsolete, or because
|
|
there are now better ways to do the same thing. The \module{stdwin}
|
|
module is gone; it was for a platform-independent windowing toolkit
|
|
that's no longer developed.
|
|
|
|
A number of modules have been moved to the
|
|
\file{lib-old} subdirectory:
|
|
\module{cmp}, \module{cmpcache}, \module{dircmp}, \module{dump},
|
|
\module{find}, \module{grep}, \module{packmail},
|
|
\module{poly}, \module{util}, \module{whatsound}, \module{zmod}.
|
|
If you have code which relies on a module that's been moved to
|
|
\file{lib-old}, you can simply add that directory to \code{sys.path}
|
|
to get them back, but you're encouraged to update any code that uses
|
|
these modules.
|
|
|
|
\section{Acknowledgements}
|
|
|
|
The authors would like to thank the following people for offering
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suggestions on various drafts of this article: David Bolen, Mark
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Hammond, Gregg Hauser, Jeremy Hylton, Fredrik Lundh, Detlef Lannert,
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Aahz Maruch, Skip Montanaro, Vladimir Marangozov, Tobias Polzin, Guido
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van Rossum, Neil Schemenauer, and Russ Schmidt.
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\end{document}
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