Doc/lib/libcodeop.tex - platform/external/python/cpython2 - Gitiles

 \section{\module{codeop} ---
          Compile Python code}

 % LaTeXed from excellent doc-string.

 \declaremodule{standard}{codeop}
 \sectionauthor{Moshe Zadka}{moshez@zadka.site.co.il}
 \sectionauthor{Michael Hudson}{mwh@python.net}
 \modulesynopsis{Compile (possibly incomplete) Python code.}

 The \module{codeop} module provides utilities upon which the Python
 read-eval-print loop can be emulated, as is done in the
 \refmodule{code} module.  As a result, you probably don't want to use
 the module directly; if you want to include such a loop in your
 program you probably want to use the \refmodule{code} module instead.

 There are two parts to this job:

 \begin{enumerate}
   \item Being able to tell if a line of input completes a Python
         statement: in short, telling whether to print
         `\code{>>>~}' or `\code{...~}' next.
   \item Remembering which future statements the user has entered, so
         subsequent input can be compiled with these in effect.
 \end{enumerate}

 The \module{codeop} module provides a way of doing each of these
 things, and a way of doing them both.

 To do just the former:

 \begin{funcdesc}{compile_command}
                 {source\optional{, filename\optional{, symbol}}}
 Tries to compile \var{source}, which should be a string of Python
 code and return a code object if \var{source} is valid
 Python code. In that case, the filename attribute of the code object
 will be \var{filename}, which defaults to \code{'<input>'}.
 Returns \code{None} if \var{source} is \emph{not} valid Python
 code, but is a prefix of valid Python code.

 If there is a problem with \var{source}, an exception will be raised.
 \exception{SyntaxError} is raised if there is invalid Python syntax,
 and \exception{OverflowError} or \exception{ValueError} if there is an
 invalid literal.

 The \var{symbol} argument determines whether \var{source} is compiled
 as a statement (\code{'single'}, the default) or as an expression
 (\code{'eval'}).  Any other value will cause \exception{ValueError} to
 be raised.

 \strong{Caveat:}
 It is possible (but not likely) that the parser stops parsing
 with a successful outcome before reaching the end of the source;
 in this case, trailing symbols may be ignored instead of causing an
 error.  For example, a backslash followed by two newlines may be
 followed by arbitrary garbage.  This will be fixed once the API
 for the parser is better.
 \end{funcdesc}

 \begin{classdesc}{Compile}{}
 Instances of this class have \method{__call__()} methods identical in
 signature to the built-in function \function{compile()}, but with the
 difference that if the instance compiles program text containing a
 \module{__future__} statement, the instance 'remembers' and compiles
 all subsequent program texts with the statement in force.
 \end{classdesc}

 \begin{classdesc}{CommandCompiler}{}
 Instances of this class have \method{__call__()} methods identical in
 signature to \function{compile_command()}; the difference is that if
 the instance compiles program text containing a \code{__future__}
 statement, the instance 'remembers' and compiles all subsequent
 program texts with the statement in force.
 \end{classdesc}

 A note on version compatibility: the \class{Compile} and
 \class{CommandCompiler} are new in Python 2.2.  If you want to enable
 the future-tracking features of 2.2 but also retain compatibility with
 2.1 and earlier versions of Python you can either write

 \begin{verbatim}
 try:
     from codeop import CommandCompiler
     compile_command = CommandCompiler()
     del CommandCompiler
 except ImportError:
     from codeop import compile_command
 \end{verbatim}

 which is a low-impact change, but introduces possibly unwanted global
 state into your program, or you can write:

 \begin{verbatim}
 try:
     from codeop import CommandCompiler
 except ImportError:
     def CommandCompiler():
         from codeop import compile_command
         return compile_command
 \end{verbatim}

 and then call \code{CommandCompiler} every time you need a fresh
 compiler object.
	\section{\module{codeop} ---
	Compile Python code}

	% LaTeXed from excellent doc-string.

	\declaremodule{standard}{codeop}
	\sectionauthor{Moshe Zadka}{moshez@zadka.site.co.il}
	\sectionauthor{Michael Hudson}{mwh@python.net}
	\modulesynopsis{Compile (possibly incomplete) Python code.}

	The \module{codeop} module provides utilities upon which the Python
	read-eval-print loop can be emulated, as is done in the
	\refmodule{code} module. As a result, you probably don't want to use
	the module directly; if you want to include such a loop in your
	program you probably want to use the \refmodule{code} module instead.

	There are two parts to this job:

	\begin{enumerate}
	\item Being able to tell if a line of input completes a Python
	statement: in short, telling whether to print
	`\code{>>>~}' or `\code{...~}' next.
	\item Remembering which future statements the user has entered, so
	subsequent input can be compiled with these in effect.
	\end{enumerate}

	The \module{codeop} module provides a way of doing each of these
	things, and a way of doing them both.

	To do just the former:

	\begin{funcdesc}{compile_command}
	{source\optional{, filename\optional{, symbol}}}
	Tries to compile \var{source}, which should be a string of Python
	code and return a code object if \var{source} is valid
	Python code. In that case, the filename attribute of the code object
	will be \var{filename}, which defaults to \code{'<input>'}.
	Returns \code{None} if \var{source} is \emph{not} valid Python
	code, but is a prefix of valid Python code.

	If there is a problem with \var{source}, an exception will be raised.
	\exception{SyntaxError} is raised if there is invalid Python syntax,
	and \exception{OverflowError} or \exception{ValueError} if there is an
	invalid literal.

	The \var{symbol} argument determines whether \var{source} is compiled
	as a statement (\code{'single'}, the default) or as an expression
	(\code{'eval'}). Any other value will cause \exception{ValueError} to
	be raised.

	\strong{Caveat:}
	It is possible (but not likely) that the parser stops parsing
	with a successful outcome before reaching the end of the source;
	in this case, trailing symbols may be ignored instead of causing an
	error. For example, a backslash followed by two newlines may be
	followed by arbitrary garbage. This will be fixed once the API
	for the parser is better.
	\end{funcdesc}

	\begin{classdesc}{Compile}{}
	Instances of this class have \method{__call__()} methods identical in
	signature to the built-in function \function{compile()}, but with the
	difference that if the instance compiles program text containing a
	\module{__future__} statement, the instance 'remembers' and compiles
	all subsequent program texts with the statement in force.
	\end{classdesc}

	\begin{classdesc}{CommandCompiler}{}
	Instances of this class have \method{__call__()} methods identical in
	signature to \function{compile_command()}; the difference is that if
	the instance compiles program text containing a \code{__future__}
	statement, the instance 'remembers' and compiles all subsequent
	program texts with the statement in force.
	\end{classdesc}

	A note on version compatibility: the \class{Compile} and
	\class{CommandCompiler} are new in Python 2.2. If you want to enable
	the future-tracking features of 2.2 but also retain compatibility with
	2.1 and earlier versions of Python you can either write

	\begin{verbatim}
	try:
	from codeop import CommandCompiler
	compile_command = CommandCompiler()
	del CommandCompiler
	except ImportError:
	from codeop import compile_command
	\end{verbatim}

	which is a low-impact change, but introduces possibly unwanted global
	state into your program, or you can write:

	\begin{verbatim}
	try:
	from codeop import CommandCompiler
	except ImportError:
	def CommandCompiler():
	from codeop import compile_command
	return compile_command
	\end{verbatim}

	and then call \code{CommandCompiler} every time you need a fresh
	compiler object.