2007-08-15 11:28:01 -03:00
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.. _introduction:
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************
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Introduction
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************
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This reference manual describes the Python programming language. It is not
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intended as a tutorial.
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While I am trying to be as precise as possible, I chose to use English rather
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than formal specifications for everything except syntax and lexical analysis.
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This should make the document more understandable to the average reader, but
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will leave room for ambiguities. Consequently, if you were coming from Mars and
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tried to re-implement Python from this document alone, you might have to guess
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things and in fact you would probably end up implementing quite a different
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language. On the other hand, if you are using Python and wonder what the precise
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rules about a particular area of the language are, you should definitely be able
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to find them here. If you would like to see a more formal definition of the
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language, maybe you could volunteer your time --- or invent a cloning machine
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:-).
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It is dangerous to add too many implementation details to a language reference
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document --- the implementation may change, and other implementations of the
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same language may work differently. On the other hand, there is currently only
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one Python implementation in widespread use (although alternate implementations
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exist), and its particular quirks are sometimes worth being mentioned,
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especially where the implementation imposes additional limitations. Therefore,
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you'll find short "implementation notes" sprinkled throughout the text.
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Every Python implementation comes with a number of built-in and standard
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modules. These are documented in :ref:`library-index`. A few built-in modules
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are mentioned when they interact in a significant way with the language
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definition.
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.. _implementations:
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Alternate Implementations
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=========================
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Though there is one Python implementation which is by far the most popular,
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there are some alternate implementations which are of particular interest to
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different audiences.
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Known implementations include:
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CPython
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This is the original and most-maintained implementation of Python, written in C.
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New language features generally appear here first.
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Jython
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Python implemented in Java. This implementation can be used as a scripting
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language for Java applications, or can be used to create applications using the
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Java class libraries. It is also often used to create tests for Java libraries.
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More information can be found at `the Jython website <http://www.jython.org/>`_.
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Python for .NET
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This implementation actually uses the CPython implementation, but is a managed
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.NET application and makes .NET libraries available. It was created by Brian
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Lloyd. For more information, see the `Python for .NET home page
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<http://pythonnet.sourceforge.net>`_.
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IronPython
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An alternate Python for .NET. Unlike Python.NET, this is a complete Python
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implementation that generates IL, and compiles Python code directly to .NET
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assemblies. It was created by Jim Hugunin, the original creator of Jython. For
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more information, see `the IronPython website <http://www.ironpython.com/>`_.
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PyPy
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An implementation of Python written completely in Python. It supports several
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advanced features not found in other implementations like stackless support
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and a Just in Time compiler. One of the goals of the project is to encourage
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experimentation with the language itself by making it easier to modify the
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interpreter (since it is written in Python). Additional information is
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available on `the PyPy project's home page <http://pypy.org/>`_.
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Each of these implementations varies in some way from the language as documented
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in this manual, or introduces specific information beyond what's covered in the
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standard Python documentation. Please refer to the implementation-specific
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documentation to determine what else you need to know about the specific
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implementation you're using.
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.. _notation:
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Notation
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========
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.. index::
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single: BNF
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single: grammar
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single: syntax
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single: notation
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The descriptions of lexical analysis and syntax use a modified BNF grammar
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notation. This uses the following style of definition:
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.. productionlist:: *
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name: `lc_letter` (`lc_letter` | "_")*
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lc_letter: "a"..."z"
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The first line says that a ``name`` is an ``lc_letter`` followed by a sequence
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of zero or more ``lc_letter``\ s and underscores. An ``lc_letter`` in turn is
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any of the single characters ``'a'`` through ``'z'``. (This rule is actually
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adhered to for the names defined in lexical and grammar rules in this document.)
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Each rule begins with a name (which is the name defined by the rule) and
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``::=``. A vertical bar (``|``) is used to separate alternatives; it is the
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least binding operator in this notation. A star (``*``) means zero or more
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repetitions of the preceding item; likewise, a plus (``+``) means one or more
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repetitions, and a phrase enclosed in square brackets (``[ ]``) means zero or
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one occurrences (in other words, the enclosed phrase is optional). The ``*``
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and ``+`` operators bind as tightly as possible; parentheses are used for
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grouping. Literal strings are enclosed in quotes. White space is only
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meaningful to separate tokens. Rules are normally contained on a single line;
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rules with many alternatives may be formatted alternatively with each line after
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the first beginning with a vertical bar.
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.. index::
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single: lexical definitions
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single: ASCII@ASCII
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In lexical definitions (as the example above), two more conventions are used:
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Two literal characters separated by three dots mean a choice of any single
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character in the given (inclusive) range of ASCII characters. A phrase between
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angular brackets (``<...>``) gives an informal description of the symbol
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defined; e.g., this could be used to describe the notion of 'control character'
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if needed.
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Even though the notation used is almost the same, there is a big difference
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between the meaning of lexical and syntactic definitions: a lexical definition
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operates on the individual characters of the input source, while a syntax
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definition operates on the stream of tokens generated by the lexical analysis.
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All uses of BNF in the next chapter ("Lexical Analysis") are lexical
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definitions; uses in subsequent chapters are syntactic definitions.
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