Doc/lib/libregex.tex - platform/external/python/cpython3 - Gitiles

 \section{\module{regex} ---
          Regular expression search and match operations.}
 \declaremodule{builtin}{regex}

 \modulesynopsis{Regular expression search and match operations.}


 This module provides regular expression matching operations similar to
 those found in Emacs.

 \strong{Obsolescence note:}
 This module is obsolete as of Python version 1.5; it is still being
 maintained because much existing code still uses it.  All new code in
 need of regular expressions should use the new
 \code{re}\refstmodindex{re} module, which supports the more powerful
 and regular Perl-style regular expressions.  Existing code should be
 converted.  The standard library module
 \code{reconvert}\refstmodindex{reconvert} helps in converting
 \code{regex} style regular expressions to \code{re}\refstmodindex{re}
 style regular expressions.  (For more conversion help, see Andrew
 Kuchling's\index{Kuchling, Andrew} ``\module{regex-to-re} HOWTO'' at
 \url{http://www.python.org/doc/howto/regex-to-re/}.)

 By default the patterns are Emacs-style regular expressions
 (with one exception).  There is
 a way to change the syntax to match that of several well-known
 \UNIX{} utilities.  The exception is that Emacs' \samp{\e s}
 pattern is not supported, since the original implementation references
 the Emacs syntax tables.

 This module is 8-bit clean: both patterns and strings may contain null
 bytes and characters whose high bit is set.

 \strong{Please note:} There is a little-known fact about Python string
 literals which means that you don't usually have to worry about
 doubling backslashes, even though they are used to escape special
 characters in string literals as well as in regular expressions.  This
 is because Python doesn't remove backslashes from string literals if
 they are followed by an unrecognized escape character.
 \emph{However}, if you want to include a literal \dfn{backslash} in a
 regular expression represented as a string literal, you have to
 \emph{quadruple} it or enclose it in a singleton character class.
 E.g.\  to extract \LaTeX\ \samp{\e section\{\textrm{\ldots}\}} headers
 from a document, you can use this pattern:
 \code{'[\e ]section\{\e (.*\e )\}'}.  \emph{Another exception:}
 the escape sequece \samp{\e b} is significant in string literals
 (where it means the ASCII bell character) as well as in Emacs regular
 expressions (where it stands for a word boundary), so in order to
 search for a word boundary, you should use the pattern \code{'\e \e b'}.
 Similarly, a backslash followed by a digit 0-7 should be doubled to
 avoid interpretation as an octal escape.

 \subsection{Regular Expressions}

 A regular expression (or RE) specifies a set of strings that matches
 it; the functions in this module let you check if a particular string
 matches a given regular expression (or if a given regular expression
 matches a particular string, which comes down to the same thing).

 Regular expressions can be concatenated to form new regular
 expressions; if \emph{A} and \emph{B} are both regular expressions,
 then \emph{AB} is also an regular expression.  If a string \emph{p}
 matches A and another string \emph{q} matches B, the string \emph{pq}
 will match AB.  Thus, complex expressions can easily be constructed
 from simpler ones like the primitives described here.  For details of
 the theory and implementation of regular expressions, consult almost
 any textbook about compiler construction.

 % XXX The reference could be made more specific, say to
 % "Compilers: Principles, Techniques and Tools", by Alfred V. Aho,
 % Ravi Sethi, and Jeffrey D. Ullman, or some FA text.

 A brief explanation of the format of regular expressions follows.

 Regular expressions can contain both special and ordinary characters.
 Ordinary characters, like '\code{A}', '\code{a}', or '\code{0}', are
 the simplest regular expressions; they simply match themselves.  You
 can concatenate ordinary characters, so '\code{last}' matches the
 characters 'last'.  (In the rest of this section, we'll write RE's in
 \code{this special font}, usually without quotes, and strings to be
 matched 'in single quotes'.)

 Special characters either stand for classes of ordinary characters, or
 affect how the regular expressions around them are interpreted.

 The special characters are:
 \begin{itemize}
 \item[\code{.}] (Dot.)  Matches any character except a newline.
 \item[\code{\^}] (Caret.)  Matches the start of the string.
 \item[\code{\$}] Matches the end of the string.
 \code{foo} matches both 'foo' and 'foobar', while the regular
 expression '\code{foo\$}' matches only 'foo'.
 \item[\code{*}] Causes the resulting RE to
 match 0 or more repetitions of the preceding RE.  \code{ab*} will
 match 'a', 'ab', or 'a' followed by any number of 'b's.
 \item[\code{+}] Causes the
 resulting RE to match 1 or more repetitions of the preceding RE.
 \code{ab+} will match 'a' followed by any non-zero number of 'b's; it
 will not match just 'a'.
 \item[\code{?}] Causes the resulting RE to
 match 0 or 1 repetitions of the preceding RE.  \code{ab?} will
 match either 'a' or 'ab'.

 \item[\code{\e}] Either escapes special characters (permitting you to match
 characters like '*?+\&\$'), or signals a special sequence; special
 sequences are discussed below.  Remember that Python also uses the
 backslash as an escape sequence in string literals; if the escape
 sequence isn't recognized by Python's parser, the backslash and
 subsequent character are included in the resulting string.  However,
 if Python would recognize the resulting sequence, the backslash should
 be repeated twice.

 \item[\code{[]}] Used to indicate a set of characters.  Characters can
 be listed individually, or a range is indicated by giving two
 characters and separating them by a '-'.  Special characters are
 not active inside sets.  For example, \code{[akm\$]}
 will match any of the characters 'a', 'k', 'm', or '\$'; \code{[a-z]} will
 match any lowercase letter.

 If you want to include a \code{]} inside a
 set, it must be the first character of the set; to include a \code{-},
 place it as the first or last character.

 Characters \emph{not} within a range can be matched by including a
 \code{\^} as the first character of the set; \code{\^} elsewhere will
 simply match the '\code{\^}' character.
 \end{itemize}

 The special sequences consist of '\code{\e}' and a character
 from the list below.  If the ordinary character is not on the list,
 then the resulting RE will match the second character.  For example,
 \code{\e\$} matches the character '\$'.  Ones where the backslash
 should be doubled in string literals are indicated.

 \begin{itemize}
 \item[\code{\e|}]\code{A\e|B}, where A and B can be arbitrary REs,
 creates a regular expression that will match either A or B.  This can
 be used inside groups (see below) as well.
 %
 \item[\code{\e( \e)}] Indicates the start and end of a group; the
 contents of a group can be matched later in the string with the
 \code{\e [1-9]} special sequence, described next.
 \end{itemize}

 \begin{fulllineitems}
 \item[\code{\e \e 1, ... \e \e 7, \e 8, \e 9}]
 Matches the contents of the group of the same
 number.  For example, \code{\e (.+\e ) \e \e 1} matches 'the the' or
 '55 55', but not 'the end' (note the space after the group).  This
 special sequence can only be used to match one of the first 9 groups;
 groups with higher numbers can be matched using the \code{\e v}
 sequence.  (\code{\e 8} and \code{\e 9} don't need a double backslash
 because they are not octal digits.)
 \end{fulllineitems}

 \begin{itemize}
 \item[\code{\e \e b}] Matches the empty string, but only at the
 beginning or end of a word.  A word is defined as a sequence of
 alphanumeric characters, so the end of a word is indicated by
 whitespace or a non-alphanumeric character.
 %
 \item[\code{\e B}] Matches the empty string, but when it is \emph{not} at the
 beginning or end of a word.
 %
 \item[\code{\e v}] Must be followed by a two digit decimal number, and
 matches the contents of the group of the same number.  The group
 number must be between 1 and 99, inclusive.
 %
 \item[\code{\e w}]Matches any alphanumeric character; this is
 equivalent to the set \code{[a-zA-Z0-9]}.
 %
 \item[\code{\e W}] Matches any non-alphanumeric character; this is
 equivalent to the set \code{[\^a-zA-Z0-9]}.
 \item[\code{\e <}] Matches the empty string, but only at the beginning of a
 word.  A word is defined as a sequence of alphanumeric characters, so
 the end of a word is indicated by whitespace or a non-alphanumeric
 character.
 \item[\code{\e >}] Matches the empty string, but only at the end of a
 word.

 \item[\code{\e \e \e \e}] Matches a literal backslash.

 % In Emacs, the following two are start of buffer/end of buffer.  In
 % Python they seem to be synonyms for ^$.
 \item[\code{\e `}] Like \code{\^}, this only matches at the start of the
 string.
 \item[\code{\e \e '}] Like \code{\$}, this only matches at the end of
 the string.
 % end of buffer
 \end{itemize}

 \subsection{Module Contents}
 \nodename{Contents of Module regex}

 The module defines these functions, and an exception:


 \begin{funcdesc}{match}{pattern, string}
   Return how many characters at the beginning of \var{string} match
   the regular expression \var{pattern}.  Return \code{-1} if the
   string does not match the pattern (this is different from a
   zero-length match!).
 \end{funcdesc}

 \begin{funcdesc}{search}{pattern, string}
   Return the first position in \var{string} that matches the regular
   expression \var{pattern}.  Return \code{-1} if no position in the string
   matches the pattern (this is different from a zero-length match
   anywhere!).
 \end{funcdesc}

 \begin{funcdesc}{compile}{pattern\optional{, translate}}
   Compile a regular expression pattern into a regular expression
   object, which can be used for matching using its \code{match()} and
   \code{search()} methods, described below.  The optional argument
   \var{translate}, if present, must be a 256-character string
   indicating how characters (both of the pattern and of the strings to
   be matched) are translated before comparing them; the \var{i}-th
   element of the string gives the translation for the character with
   \ASCII{} code \var{i}.  This can be used to implement
   case-insensitive matching; see the \code{casefold} data item below.

   The sequence

 \begin{verbatim}
 prog = regex.compile(pat)
 result = prog.match(str)
 \end{verbatim}
 %
 is equivalent to

 \begin{verbatim}
 result = regex.match(pat, str)
 \end{verbatim}

 but the version using \code{compile()} is more efficient when multiple
 regular expressions are used concurrently in a single program.  (The
 compiled version of the last pattern passed to \code{regex.match()} or
 \code{regex.search()} is cached, so programs that use only a single
 regular expression at a time needn't worry about compiling regular
 expressions.)
 \end{funcdesc}

 \begin{funcdesc}{set_syntax}{flags}
   Set the syntax to be used by future calls to \code{compile()},
   \code{match()} and \code{search()}.  (Already compiled expression
   objects are not affected.)  The argument is an integer which is the
   OR of several flag bits.  The return value is the previous value of
   the syntax flags.  Names for the flags are defined in the standard
   module \code{regex_syntax}\refstmodindex{regex_syntax}; read the
   file \file{regex_syntax.py} for more information.
 \end{funcdesc}

 \begin{funcdesc}{get_syntax}{}
   Returns the current value of the syntax flags as an integer.
 \end{funcdesc}

 \begin{funcdesc}{symcomp}{pattern\optional{, translate}}
 This is like \code{compile()}, but supports symbolic group names: if a
 parenthesis-enclosed group begins with a group name in angular
 brackets, e.g. \code{'\e(<id>[a-z][a-z0-9]*\e)'}, the group can
 be referenced by its name in arguments to the \code{group()} method of
 the resulting compiled regular expression object, like this:
 \code{p.group('id')}.  Group names may contain alphanumeric characters
 and \code{'_'} only.
 \end{funcdesc}

 \begin{excdesc}{error}
   Exception raised when a string passed to one of the functions here
   is not a valid regular expression (e.g., unmatched parentheses) or
   when some other error occurs during compilation or matching.  (It is
   never an error if a string contains no match for a pattern.)
 \end{excdesc}

 \begin{datadesc}{casefold}
 A string suitable to pass as the \var{translate} argument to
 \code{compile()} to map all upper case characters to their lowercase
 equivalents.
 \end{datadesc}

 \noindent
 Compiled regular expression objects support these methods:

 \setindexsubitem{(regex method)}
 \begin{funcdesc}{match}{string\optional{, pos}}
   Return how many characters at the beginning of \var{string} match
   the compiled regular expression.  Return \code{-1} if the string
   does not match the pattern (this is different from a zero-length
   match!).

   The optional second parameter, \var{pos}, gives an index in the string
   where the search is to start; it defaults to \code{0}.  This is not
   completely equivalent to slicing the string; the \code{'\^'} pattern
   character matches at the real beginning of the string and at positions
   just after a newline, not necessarily at the index where the search
   is to start.
 \end{funcdesc}

 \begin{funcdesc}{search}{string\optional{, pos}}
   Return the first position in \var{string} that matches the regular
   expression \code{pattern}.  Return \code{-1} if no position in the
   string matches the pattern (this is different from a zero-length
   match anywhere!).

   The optional second parameter has the same meaning as for the
   \code{match()} method.
 \end{funcdesc}

 \begin{funcdesc}{group}{index, index, ...}
 This method is only valid when the last call to the \code{match()}
 or \code{search()} method found a match.  It returns one or more
 groups of the match.  If there is a single \var{index} argument,
 the result is a single string; if there are multiple arguments, the
 result is a tuple with one item per argument.  If the \var{index} is
 zero, the corresponding return value is the entire matching string; if
 it is in the inclusive range [1..99], it is the string matching the
 the corresponding parenthesized group (using the default syntax,
 groups are parenthesized using \code{{\e}(} and \code{{\e})}).  If no
 such group exists, the corresponding result is \code{None}.

 If the regular expression was compiled by \code{symcomp()} instead of
 \code{compile()}, the \var{index} arguments may also be strings
 identifying groups by their group name.
 \end{funcdesc}

 \noindent
 Compiled regular expressions support these data attributes:

 \setindexsubitem{(regex attribute)}

 \begin{datadesc}{regs}
 When the last call to the \code{match()} or \code{search()} method found a
 match, this is a tuple of pairs of indexes corresponding to the
 beginning and end of all parenthesized groups in the pattern.  Indices
 are relative to the string argument passed to \code{match()} or
 \code{search()}.  The 0-th tuple gives the beginning and end or the
 whole pattern.  When the last match or search failed, this is
 \code{None}.
 \end{datadesc}

 \begin{datadesc}{last}
 When the last call to the \code{match()} or \code{search()} method found a
 match, this is the string argument passed to that method.  When the
 last match or search failed, this is \code{None}.
 \end{datadesc}

 \begin{datadesc}{translate}
 This is the value of the \var{translate} argument to
 \code{regex.compile()} that created this regular expression object.  If
 the \var{translate} argument was omitted in the \code{regex.compile()}
 call, this is \code{None}.
 \end{datadesc}

 \begin{datadesc}{givenpat}
 The regular expression pattern as passed to \code{compile()} or
 \code{symcomp()}.
 \end{datadesc}

 \begin{datadesc}{realpat}
 The regular expression after stripping the group names for regular
 expressions compiled with \code{symcomp()}.  Same as \code{givenpat}
 otherwise.
 \end{datadesc}

 \begin{datadesc}{groupindex}
 A dictionary giving the mapping from symbolic group names to numerical
 group indexes for regular expressions compiled with \code{symcomp()}.
 \code{None} otherwise.
 \end{datadesc}
	\section{\module{regex} ---
	Regular expression search and match operations.}
	\declaremodule{builtin}{regex}

	\modulesynopsis{Regular expression search and match operations.}


	This module provides regular expression matching operations similar to
	those found in Emacs.

	\strong{Obsolescence note:}
	This module is obsolete as of Python version 1.5; it is still being
	maintained because much existing code still uses it. All new code in
	need of regular expressions should use the new
	\code{re}\refstmodindex{re} module, which supports the more powerful
	and regular Perl-style regular expressions. Existing code should be
	converted. The standard library module
	\code{reconvert}\refstmodindex{reconvert} helps in converting
	\code{regex} style regular expressions to \code{re}\refstmodindex{re}
	style regular expressions. (For more conversion help, see Andrew
	Kuchling's\index{Kuchling, Andrew} ``\module{regex-to-re} HOWTO'' at
	\url{http://www.python.org/doc/howto/regex-to-re/}.)

	By default the patterns are Emacs-style regular expressions
	(with one exception). There is
	a way to change the syntax to match that of several well-known
	\UNIX{} utilities. The exception is that Emacs' \samp{\e s}
	pattern is not supported, since the original implementation references
	the Emacs syntax tables.

	This module is 8-bit clean: both patterns and strings may contain null
	bytes and characters whose high bit is set.

	\strong{Please note:} There is a little-known fact about Python string
	literals which means that you don't usually have to worry about
	doubling backslashes, even though they are used to escape special
	characters in string literals as well as in regular expressions. This
	is because Python doesn't remove backslashes from string literals if
	they are followed by an unrecognized escape character.
	\emph{However}, if you want to include a literal \dfn{backslash} in a
	regular expression represented as a string literal, you have to
	\emph{quadruple} it or enclose it in a singleton character class.
	E.g.\ to extract \LaTeX\ \samp{\e section\{\textrm{\ldots}\}} headers
	from a document, you can use this pattern:
	\code{'[\e ]section\{\e (.*\e )\}'}. \emph{Another exception:}
	the escape sequece \samp{\e b} is significant in string literals
	(where it means the ASCII bell character) as well as in Emacs regular
	expressions (where it stands for a word boundary), so in order to
	search for a word boundary, you should use the pattern \code{'\e \e b'}.
	Similarly, a backslash followed by a digit 0-7 should be doubled to
	avoid interpretation as an octal escape.

	\subsection{Regular Expressions}

	A regular expression (or RE) specifies a set of strings that matches
	it; the functions in this module let you check if a particular string
	matches a given regular expression (or if a given regular expression
	matches a particular string, which comes down to the same thing).

	Regular expressions can be concatenated to form new regular
	expressions; if \emph{A} and \emph{B} are both regular expressions,
	then \emph{AB} is also an regular expression. If a string \emph{p}
	matches A and another string \emph{q} matches B, the string \emph{pq}
	will match AB. Thus, complex expressions can easily be constructed
	from simpler ones like the primitives described here. For details of
	the theory and implementation of regular expressions, consult almost
	any textbook about compiler construction.

	% XXX The reference could be made more specific, say to
	% "Compilers: Principles, Techniques and Tools", by Alfred V. Aho,
	% Ravi Sethi, and Jeffrey D. Ullman, or some FA text.

	A brief explanation of the format of regular expressions follows.

	Regular expressions can contain both special and ordinary characters.
	Ordinary characters, like '\code{A}', '\code{a}', or '\code{0}', are
	the simplest regular expressions; they simply match themselves. You
	can concatenate ordinary characters, so '\code{last}' matches the
	characters 'last'. (In the rest of this section, we'll write RE's in
	\code{this special font}, usually without quotes, and strings to be
	matched 'in single quotes'.)

	Special characters either stand for classes of ordinary characters, or
	affect how the regular expressions around them are interpreted.

	The special characters are:
	\begin{itemize}
	\item[\code{.}] (Dot.) Matches any character except a newline.
	\item[\code{\^}] (Caret.) Matches the start of the string.
	\item[\code{\$}] Matches the end of the string.
	\code{foo} matches both 'foo' and 'foobar', while the regular
	expression '\code{foo\$}' matches only 'foo'.
	\item[\code{*}] Causes the resulting RE to
	match 0 or more repetitions of the preceding RE. \code{ab*} will
	match 'a', 'ab', or 'a' followed by any number of 'b's.
	\item[\code{+}] Causes the
	resulting RE to match 1 or more repetitions of the preceding RE.
	\code{ab+} will match 'a' followed by any non-zero number of 'b's; it
	will not match just 'a'.
	\item[\code{?}] Causes the resulting RE to
	match 0 or 1 repetitions of the preceding RE. \code{ab?} will
	match either 'a' or 'ab'.

	\item[\code{\e}] Either escapes special characters (permitting you to match
	characters like '*?+\&\$'), or signals a special sequence; special
	sequences are discussed below. Remember that Python also uses the
	backslash as an escape sequence in string literals; if the escape
	sequence isn't recognized by Python's parser, the backslash and
	subsequent character are included in the resulting string. However,
	if Python would recognize the resulting sequence, the backslash should
	be repeated twice.

	\item[\code{[]}] Used to indicate a set of characters. Characters can
	be listed individually, or a range is indicated by giving two
	characters and separating them by a '-'. Special characters are
	not active inside sets. For example, \code{[akm\$]}
	will match any of the characters 'a', 'k', 'm', or '\$'; \code{[a-z]} will
	match any lowercase letter.

	If you want to include a \code{]} inside a
	set, it must be the first character of the set; to include a \code{-},
	place it as the first or last character.

	Characters \emph{not} within a range can be matched by including a
	\code{\^} as the first character of the set; \code{\^} elsewhere will
	simply match the '\code{\^}' character.
	\end{itemize}

	The special sequences consist of '\code{\e}' and a character
	from the list below. If the ordinary character is not on the list,
	then the resulting RE will match the second character. For example,
	\code{\e\$} matches the character '\$'. Ones where the backslash
	should be doubled in string literals are indicated.

	\begin{itemize}
	\item[\code{\e\|}]\code{A\e\|B}, where A and B can be arbitrary REs,
	creates a regular expression that will match either A or B. This can
	be used inside groups (see below) as well.
	%
	\item[\code{\e( \e)}] Indicates the start and end of a group; the
	contents of a group can be matched later in the string with the
	\code{\e [1-9]} special sequence, described next.
	\end{itemize}

	\begin{fulllineitems}
	\item[\code{\e \e 1, ... \e \e 7, \e 8, \e 9}]
	Matches the contents of the group of the same
	number. For example, \code{\e (.+\e ) \e \e 1} matches 'the the' or
	'55 55', but not 'the end' (note the space after the group). This
	special sequence can only be used to match one of the first 9 groups;
	groups with higher numbers can be matched using the \code{\e v}
	sequence. (\code{\e 8} and \code{\e 9} don't need a double backslash
	because they are not octal digits.)
	\end{fulllineitems}

	\begin{itemize}
	\item[\code{\e \e b}] Matches the empty string, but only at the
	beginning or end of a word. A word is defined as a sequence of
	alphanumeric characters, so the end of a word is indicated by
	whitespace or a non-alphanumeric character.
	%
	\item[\code{\e B}] Matches the empty string, but when it is \emph{not} at the
	beginning or end of a word.
	%
	\item[\code{\e v}] Must be followed by a two digit decimal number, and
	matches the contents of the group of the same number. The group
	number must be between 1 and 99, inclusive.
	%
	\item[\code{\e w}]Matches any alphanumeric character; this is
	equivalent to the set \code{[a-zA-Z0-9]}.
	%
	\item[\code{\e W}] Matches any non-alphanumeric character; this is
	equivalent to the set \code{[\^a-zA-Z0-9]}.
	\item[\code{\e <}] Matches the empty string, but only at the beginning of a
	word. A word is defined as a sequence of alphanumeric characters, so
	the end of a word is indicated by whitespace or a non-alphanumeric
	character.
	\item[\code{\e >}] Matches the empty string, but only at the end of a
	word.

	\item[\code{\e \e \e \e}] Matches a literal backslash.

	% In Emacs, the following two are start of buffer/end of buffer. In
	% Python they seem to be synonyms for ^$.
	\item[\code{\e `}] Like \code{\^}, this only matches at the start of the
	string.
	\item[\code{\e \e '}] Like \code{\$}, this only matches at the end of
	the string.
	% end of buffer
	\end{itemize}

	\subsection{Module Contents}
	\nodename{Contents of Module regex}

	The module defines these functions, and an exception:


	\begin{funcdesc}{match}{pattern, string}
	Return how many characters at the beginning of \var{string} match
	the regular expression \var{pattern}. Return \code{-1} if the
	string does not match the pattern (this is different from a
	zero-length match!).
	\end{funcdesc}

	\begin{funcdesc}{search}{pattern, string}
	Return the first position in \var{string} that matches the regular
	expression \var{pattern}. Return \code{-1} if no position in the string
	matches the pattern (this is different from a zero-length match
	anywhere!).
	\end{funcdesc}

	\begin{funcdesc}{compile}{pattern\optional{, translate}}
	Compile a regular expression pattern into a regular expression
	object, which can be used for matching using its \code{match()} and
	\code{search()} methods, described below. The optional argument
	\var{translate}, if present, must be a 256-character string
	indicating how characters (both of the pattern and of the strings to
	be matched) are translated before comparing them; the \var{i}-th
	element of the string gives the translation for the character with
	\ASCII{} code \var{i}. This can be used to implement
	case-insensitive matching; see the \code{casefold} data item below.

	The sequence

	\begin{verbatim}
	prog = regex.compile(pat)
	result = prog.match(str)
	\end{verbatim}
	%
	is equivalent to

	\begin{verbatim}
	result = regex.match(pat, str)
	\end{verbatim}

	but the version using \code{compile()} is more efficient when multiple
	regular expressions are used concurrently in a single program. (The
	compiled version of the last pattern passed to \code{regex.match()} or
	\code{regex.search()} is cached, so programs that use only a single
	regular expression at a time needn't worry about compiling regular
	expressions.)
	\end{funcdesc}

	\begin{funcdesc}{set_syntax}{flags}
	Set the syntax to be used by future calls to \code{compile()},
	\code{match()} and \code{search()}. (Already compiled expression
	objects are not affected.) The argument is an integer which is the
	OR of several flag bits. The return value is the previous value of
	the syntax flags. Names for the flags are defined in the standard
	module \code{regex_syntax}\refstmodindex{regex_syntax}; read the
	file \file{regex_syntax.py} for more information.
	\end{funcdesc}

	\begin{funcdesc}{get_syntax}{}
	Returns the current value of the syntax flags as an integer.
	\end{funcdesc}

	\begin{funcdesc}{symcomp}{pattern\optional{, translate}}
	This is like \code{compile()}, but supports symbolic group names: if a
	parenthesis-enclosed group begins with a group name in angular
	brackets, e.g. \code{'\e(<id>[a-z][a-z0-9]*\e)'}, the group can
	be referenced by its name in arguments to the \code{group()} method of
	the resulting compiled regular expression object, like this:
	\code{p.group('id')}. Group names may contain alphanumeric characters
	and \code{'_'} only.
	\end{funcdesc}

	\begin{excdesc}{error}
	Exception raised when a string passed to one of the functions here
	is not a valid regular expression (e.g., unmatched parentheses) or
	when some other error occurs during compilation or matching. (It is
	never an error if a string contains no match for a pattern.)
	\end{excdesc}

	\begin{datadesc}{casefold}
	A string suitable to pass as the \var{translate} argument to
	\code{compile()} to map all upper case characters to their lowercase
	equivalents.
	\end{datadesc}

	\noindent
	Compiled regular expression objects support these methods:

	\setindexsubitem{(regex method)}
	\begin{funcdesc}{match}{string\optional{, pos}}
	Return how many characters at the beginning of \var{string} match
	the compiled regular expression. Return \code{-1} if the string
	does not match the pattern (this is different from a zero-length
	match!).

	The optional second parameter, \var{pos}, gives an index in the string
	where the search is to start; it defaults to \code{0}. This is not
	completely equivalent to slicing the string; the \code{'\^'} pattern
	character matches at the real beginning of the string and at positions
	just after a newline, not necessarily at the index where the search
	is to start.
	\end{funcdesc}

	\begin{funcdesc}{search}{string\optional{, pos}}
	Return the first position in \var{string} that matches the regular
	expression \code{pattern}. Return \code{-1} if no position in the
	string matches the pattern (this is different from a zero-length
	match anywhere!).

	The optional second parameter has the same meaning as for the
	\code{match()} method.
	\end{funcdesc}

	\begin{funcdesc}{group}{index, index, ...}
	This method is only valid when the last call to the \code{match()}
	or \code{search()} method found a match. It returns one or more
	groups of the match. If there is a single \var{index} argument,
	the result is a single string; if there are multiple arguments, the
	result is a tuple with one item per argument. If the \var{index} is
	zero, the corresponding return value is the entire matching string; if
	it is in the inclusive range [1..99], it is the string matching the
	the corresponding parenthesized group (using the default syntax,
	groups are parenthesized using \code{{\e}(} and \code{{\e})}). If no
	such group exists, the corresponding result is \code{None}.

	If the regular expression was compiled by \code{symcomp()} instead of
	\code{compile()}, the \var{index} arguments may also be strings
	identifying groups by their group name.
	\end{funcdesc}

	\noindent
	Compiled regular expressions support these data attributes:

	\setindexsubitem{(regex attribute)}

	\begin{datadesc}{regs}
	When the last call to the \code{match()} or \code{search()} method found a
	match, this is a tuple of pairs of indexes corresponding to the
	beginning and end of all parenthesized groups in the pattern. Indices
	are relative to the string argument passed to \code{match()} or
	\code{search()}. The 0-th tuple gives the beginning and end or the
	whole pattern. When the last match or search failed, this is
	\code{None}.
	\end{datadesc}

	\begin{datadesc}{last}
	When the last call to the \code{match()} or \code{search()} method found a
	match, this is the string argument passed to that method. When the
	last match or search failed, this is \code{None}.
	\end{datadesc}

	\begin{datadesc}{translate}
	This is the value of the \var{translate} argument to
	\code{regex.compile()} that created this regular expression object. If
	the \var{translate} argument was omitted in the \code{regex.compile()}
	call, this is \code{None}.
	\end{datadesc}

	\begin{datadesc}{givenpat}
	The regular expression pattern as passed to \code{compile()} or
	\code{symcomp()}.
	\end{datadesc}

	\begin{datadesc}{realpat}
	The regular expression after stripping the group names for regular
	expressions compiled with \code{symcomp()}. Same as \code{givenpat}
	otherwise.
	\end{datadesc}

	\begin{datadesc}{groupindex}
	A dictionary giving the mapping from symbolic group names to numerical
	group indexes for regular expressions compiled with \code{symcomp()}.
	\code{None} otherwise.
	\end{datadesc}