% libparser.tex % % Introductory documentation for the new parser built-in module. % % Copyright 1995 Virginia Polytechnic Institute and State University % and Fred L. Drake, Jr. This copyright notice must be distributed on % all copies, but this document otherwise may be distributed as part % of the Python distribution. No fee may be charged for this document % in any representation, either on paper or electronically. This % restriction does not affect other elements in a distributed package % in any way. % \section{Built-in Module \sectcode{parser}} \bimodindex{parser} % ==== 2. ==== % Give a short overview of what the module does. % If it is platform specific, mention this. % Mention other important restrictions or general operating principles. The \code{parser} module provides an interface to Python's internal parser and byte-code compiler. The primary purpose for this interface is to allow Python code to edit the parse tree of a Python expression and create executable code from this. This can be better than trying to parse and modify an arbitrary Python code fragment as a string, and ensures that parsing is performed in a manner identical to the code forming the application. It's also faster. There are a few things to note about this module which are important to making use of the data structures created. This is not a tutorial on editing the parse trees for Python code. Most importantly, a good understanding of the Python grammar processed by the internal parser is required. For full information on the language syntax, refer to the Language Reference. The parser itself is created from a grammar specification defined in the file \code{Grammar/Grammar} in the standard Python distribution. The parse trees stored in the ``AST objects'' created by this module are the actual output from the internal parser when created by the \code{expr()} or \code{suite()} functions, described below. The AST objects created by \code{tuple2ast()} faithfully simulate those structures. Each element of the tuples returned by \code{ast2tuple()} has a simple form. Tuples representing non-terminal elements in the grammar always have a length greater than one. The first element is an integer which identifies a production in the grammar. These integers are given symbolic names in the C header file \code{Include/graminit.h} and the Python module \code{Lib/symbol.py}. Each additional element of the tuple represents a component of the production as recognized in the input string: these are always tuples which have the same form as the parent. An important aspect of this structure which should be noted is that keywords used to identify the parent node type, such as the keyword \code{if} in an \emph{if\_stmt}, are included in the node tree without any special treatment. For example, the \code{if} keyword is represented by the tuple \code{(1, 'if')}, where \code{1} is the numeric value associated with all \code{NAME} elements, including variable and function names defined by the user. Terminal elements are represented in much the same way, but without any child elements and the addition of the source text which was identified. The example of the \code{if} keyword above is representative. The various types of terminal symbols are defined in the C header file \code{Include/token.h} and the Python module \code{Lib/token.py}. The AST objects are not actually required to support the functionality of this module, but are provided for three purposes: to allow an application to amortize the cost of processing complex parse trees, to provide a parse tree representation which conserves memory space when compared to the Python tuple representation, and to ease the creation of additional modules in C which manipulate parse trees. A simple ``wrapper'' module may be created in Python if desired to hide the use of AST objects. % ==== 3. ==== % List the public functions defined by the module. Begin with a % standard phrase. You may also list the exceptions and other data % items defined in the module, insofar as they are important for the % user. The \code{parser} module defines the following functions: % ---- 3.1. ---- % Redefine the ``indexsubitem'' macro to point to this module % (alternatively, you can put this at the top of the file): \renewcommand{\indexsubitem}{(in module parser)} % ---- 3.2. ---- % For each function, use a ``funcdesc'' block. This has exactly two % parameters (each parameters is contained in a set of curly braces): % the first parameter is the function name (this automatically % generates an index entry); the second parameter is the function's % argument list. If there are no arguments, use an empty pair of % curly braces. If there is more than one argument, separate the % arguments with backslash-comma. Optional parts of the parameter % list are contained in \optional{...} (this generates a set of square % brackets around its parameter). Arguments are automatically set in % italics in the parameter list. Each argument should be mentioned at % least once in the description; each usage (even inside \code{...}) % should be enclosed in \var{...}. \begin{funcdesc}{ast2tuple}{ast} This function accepts an AST object from the caller in \code{\var{ast}} and returns a Python tuple representing the equivelent parse tree. The resulting tuple representation can be used for inspection or the creation of a new parse tree in tuple form. This function does not fail so long as memory is available to build the tuple representation. \end{funcdesc} \begin{funcdesc}{compileast}{ast\optional{\, filename \code{= ''}}} The Python byte compiler can be invoked on an AST object to produce code objects which can be used as part of an \code{exec} statement or a call to the built-in \code{eval()} function. This function provides the interface to the compiler, passing the internal parse tree from \code{\var{ast}} to the parser, using the source file name specified by the \code{\var{filename}} parameter. The default value supplied for \code{\var{filename}} indicates that the source was an AST object. \end{funcdesc} \begin{funcdesc}{expr}{string} The \code{expr()} function parses the parameter \code{\var{string}} as if it were an input to \code{compile(\var{string}, 'eval')}. If the parse succeeds, an AST object is created to hold the internal parse tree representation, otherwise an appropriate exception is thrown. \end{funcdesc} \begin{funcdesc}{isexpr}{ast} When \code{\var{ast}} represents an \code{'eval'} form, this function returns a true value (\code{1}), otherwise it returns false (\code{0}). This is useful, since code objects normally cannot be queried for this information using existing built-in functions. Note that the code objects created by \code{compileast()} cannot be queried like this either, and are identical to those created by the built-in \code{compile()} function. \end{funcdesc} \begin{funcdesc}{issuite}{ast} This function mirrors \code{isexpr()} in that it reports whether an AST object represents a suite of statements. It is not safe to assume that this function is equivelent to \code{not isexpr(\var{ast})}, as additional syntactic fragments may be supported in the future. \end{funcdesc} \begin{funcdesc}{suite}{string} The \code{suite()} function parses the parameter \code{\var{string}} as if it were an input to \code{compile(\var{string}, 'exec')}. If the parse succeeds, an AST object is created to hold the internal parse tree representation, otherwise an appropriate exception is thrown. \end{funcdesc} \begin{funcdesc}{tuple2ast}{tuple} This function accepts a parse tree represented as a tuple and builds an internal representation if possible. If it can validate that the tree conforms to the Python syntax and all nodes are valid node types in the host version of Python, an AST object is created from the internal representation and returned to the called. If there is a problem creating the internal representation, or if the tree cannot be validated, a \code{ParserError} exception is thrown. An AST object created this way should not be assumed to compile correctly; normal exceptions thrown by compilation may still be initiated when the AST object is passed to \code{compileast()}. This will normally indicate problems not related to syntax (such as a \code{MemoryError} exception). \end{funcdesc} % --- 3.4. --- % Exceptions are described using a ``excdesc'' block. This has only % one parameter: the exception name. \subsection{Exceptions and Error Handling} The parser module defines a single exception, but may also pass other built-in exceptions from other portions of the Python runtime environment. See each function for information about the exceptions it can raise. \begin{excdesc}{ParserError} Exception raised when a failure occurs within the parser module. This is generally produced for validation failures rather than the built in \code{SyntaxError} thrown during normal parsing. The exception argument is either a string describing the reason of the failure or a tuple containing a tuple causing the failure from a parse tree passed to \code{tuple2ast()} and an explanatory string. Calls to \code{tuple2ast()} need to be able to handle either type of exception, while calls to other functions in the module will only need to be aware of the simple string values. \end{excdesc} Note that the functions \code{compileast()}, \code{expr()}, and \code{suite()} may throw exceptions which are normally thrown by the parsing and compilation process. These include the built in exceptions \code{MemoryError}, \code{OverflowError}, \code{SyntaxError}, and \code{SystemError}. In these cases, these exceptions carry all the meaning normally associated with them. Refer to the descriptions of each function for detailed information. % ---- 3.5. ---- % There is no standard block type for classes. I generally use % ``funcdesc'' blocks, since class instantiation looks very much like % a function call. % ==== 4. ==== % Now is probably a good time for a complete example. (Alternatively, % an example giving the flavor of the module may be given before the % detailed list of functions.) \subsection{Example} A simple example: \begin{verbatim} >>> import parser >>> ast = parser.expr('a + 5') >>> code = parser.compileast(ast) >>> a = 5 >>> eval(code) 10 \end{verbatim} \subsection{AST Objects} AST objects (returned by \code{expr()}, \code{suite()}, and \code{tuple2ast()}, described above) have no methods of their own. Some of the functions defined which accept an AST object as their first argument may change to object methods in the future. Ordered and equality comparisons are supported between AST objects. \renewcommand{\indexsubitem}{(ast method)} %\begin{funcdesc}{empty}{} %Empty the can into the trash. %\end{funcdesc}