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476 lines
14 KiB
Plaintext
\input texinfo @c -*-texinfo-*-
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@c %**start of header
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@setfilename ../../info/bovine.info
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@set TITLE Bovine parser development
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@set AUTHOR Eric M. Ludlam, David Ponce, and Richard Y. Kim
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@settitle @value{TITLE}
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@include docstyle.texi
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@c *************************************************************************
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@c @ Header
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@c *************************************************************************
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@c Merge all indexes into a single index for now.
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@c We can always separate them later into two or more as needed.
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@syncodeindex vr cp
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@syncodeindex fn cp
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@syncodeindex ky cp
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@syncodeindex pg cp
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@syncodeindex tp cp
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@c @footnotestyle separate
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@c @paragraphindent 2
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@c @@smallbook
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@c %**end of header
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@copying
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Copyright @copyright{} 1999--2004, 2012--2016 Free Software Foundation, Inc.
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@quotation
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Permission is granted to copy, distribute and/or modify this document
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under the terms of the GNU Free Documentation License, Version 1.3 or
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any later version published by the Free Software Foundation; with no
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Invariant Sections, with the Front-Cover Texts being ``A GNU Manual,''
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and with the Back-Cover Texts as in (a) below. A copy of the license
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is included in the section entitled ``GNU Free Documentation License''.
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(a) The FSF's Back-Cover Text is: ``You have the freedom to copy and
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modify this GNU manual.''
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@end quotation
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@end copying
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@dircategory Emacs misc features
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@direntry
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* Bovine: (bovine). Semantic bovine parser development.
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@end direntry
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@iftex
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@finalout
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@end iftex
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@c @setchapternewpage odd
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@c @setchapternewpage off
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@titlepage
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@sp 10
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@title @value{TITLE}
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@author by @value{AUTHOR}
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@page
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@vskip 0pt plus 1 fill
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@insertcopying
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@end titlepage
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@page
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@macro semantic{}
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@i{Semantic}
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@end macro
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@c *************************************************************************
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@c @ Document
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@c *************************************************************************
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@contents
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@node top
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@top @value{TITLE}
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The @dfn{bovine} parser is the original @semantic{} parser, and is an
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implementation of an @acronym{LL} parser. It is good for simple
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languages. It has many conveniences making grammar writing easy. The
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conveniences make it less powerful than a Bison-like @acronym{LALR}
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parser. For more information, @inforef{Top, The Wisent Parser Manual,
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wisent}.
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Bovine @acronym{LL} grammars are stored in files with a @file{.by}
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extension. When compiled, the contents is converted into a file of
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the form @file{NAME-by.el}. This, in turn is byte compiled.
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@inforef{top, Grammar Framework Manual, grammar-fw}.
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@ifnottex
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@insertcopying
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@end ifnottex
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@menu
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* Starting Rules:: The starting rules for the grammar.
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* Bovine Grammar Rules:: Rules used to parse a language.
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* Optional Lambda Expression:: Actions to take when a rule is matched.
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* Bovine Examples:: Simple Samples.
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* GNU Free Documentation License:: The license for this documentation.
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@c * Index::
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@end menu
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@node Starting Rules
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@chapter Starting Rules
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In Bison, one and only one nonterminal is designated as the ``start''
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symbol. In @semantic{}, one or more nonterminals can be designated as
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the ``start'' symbol. They are declared following the @code{%start}
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keyword separated by spaces. @inforef{start Decl, ,grammar-fw}.
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If no @code{%start} keyword is used in a grammar, then the very first
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is used. Internally the first start nonterminal is targeted by the
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reserved symbol @code{bovine-toplevel}, so it can be found by the
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parser harness.
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To find locally defined variables, the local context handler needs to
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parse the body of functional code. The @code{scopestart} declaration
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specifies the name of a nonterminal used as the goal to parse a local
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context, @inforef{scopestart Decl, ,grammar-fw}. Internally the
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scopestart nonterminal is targeted by the reserved symbol
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@code{bovine-inner-scope}, so it can be found by the parser harness.
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@node Bovine Grammar Rules
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@chapter Bovine Grammar Rules
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The rules are what allow the compiler to create tags from a language
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file. Once the setup is done in the prologue, you can start writing
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rules. @inforef{Grammar Rules, ,grammar-fw}.
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@example
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@var{result} : @var{components1} @var{optional-semantic-action1})
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| @var{components2} @var{optional-semantic-action2}
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;
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@end example
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@var{result} is a nonterminal, that is a symbol synthesized in your grammar.
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@var{components} is a list of elements that are to be matched if @var{result}
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is to be made. @var{optional-semantic-action} is an optional sequence
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of simplified Emacs Lisp expressions for concocting the parse tree.
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In bison, each time an element of @var{components} is found, it is
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@dfn{shifted} onto the parser stack. (The stack of matched elements.)
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When all @var{components}' elements have been matched, it is
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@dfn{reduced} to @var{result}. @xref{Algorithm,,, bison, The GNU Bison Manual}.
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A particular @var{result} written into your grammar becomes
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the parser's goal. It is designated by a @code{%start} statement
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(@pxref{Starting Rules}). The value returned by the associated
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@var{optional-semantic-action} is the parser's result. It should be
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a tree of @semantic{} @dfn{tags}, @inforef{Semantic Tags, ,
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semantic-appdev}.
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@var{components} is made up of symbols. A symbol such as @code{FOO}
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means that a syntactic token of class @code{FOO} must be matched.
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@menu
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* How Lexical Tokens Match::
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* Grammar-to-Lisp Details::
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* Order of components in rules::
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@end menu
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@node How Lexical Tokens Match
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@section How Lexical Tokens Match
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A lexical rule must be used to define how to match a lexical token.
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For instance:
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@example
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%keyword FOO "foo"
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@end example
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Means that @code{FOO} is a reserved language keyword, matched as such
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by looking up into a keyword table, @inforef{keyword Decl,
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,grammar-fw}. This is because @code{"foo"} will be converted to
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@code{FOO} in the lexical analysis stage. Thus the symbol @code{FOO}
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won't be available any other way.
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If we specify our token in this way:
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@example
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%token <symbol> FOO "foo"
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@end example
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then @code{FOO} will match the string @code{"foo"} explicitly, but it
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won't do so at the lexical level, allowing use of the text
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@code{"foo"} in other forms of regular expressions.
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In that case, @code{FOO} is a @code{symbol}-type token. To match, a
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@code{symbol} must first be encountered, and then it must
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@code{string-match "foo"}.
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@table @strong
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@item Caution:
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Be especially careful to remember that @code{"foo"}, and more
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generally the %token's match-value string, is a regular expression!
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@end table
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Non symbol tokens are also allowed. For example:
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@example
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%token <punctuation> PERIOD "[.]"
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filename : symbol PERIOD symbol
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;
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@end example
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@code{PERIOD} is a @code{punctuation}-type token that will explicitly
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match one period when used in the above rule.
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@table @strong
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@item Please Note:
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@code{symbol}, @code{punctuation}, etc., are predefined lexical token
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types, based on the @dfn{syntax class}-character associations
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currently in effect.
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@end table
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@node Grammar-to-Lisp Details
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@section Grammar-to-Lisp Details
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For the bovinator, lexical token matching patterns are @emph{inlined}.
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When the grammar-to-lisp converter encounters a lexical token
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declaration of the form:
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@example
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%token <@var{type}> @var{token-name} @var{match-value}
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@end example
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It substitutes every occurrences of @var{token-name} in rules, by its
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expanded form:
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@example
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@var{type} @var{match-value}
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@end example
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For example:
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@example
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%token <symbol> MOOSE "moose"
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find_a_moose: MOOSE
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;
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@end example
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Will generate this pseudo equivalent-rule:
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@example
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find_a_moose: symbol "moose" ;; invalid syntax!
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;
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@end example
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Thus, from the bovinator point of view, the @var{components} part of a
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rule is made up of symbols and strings. A string in the mix means
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that the previous symbol must have the additional constraint of
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exactly matching it, as described in @ref{How Lexical Tokens Match}.
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@table @strong
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@item Please Note:
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For the bovinator, this task was mixed into the language definition to
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simplify implementation, though Bison's technique is more efficient.
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@end table
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@node Order of components in rules
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@section Order of components in rules
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If a rule has multiple components, order is important, for example
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@example
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headerfile : symbol PERIOD symbol
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| symbol
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;
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@end example
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would match @samp{foo.h} or the @acronym{C++} header @samp{foo}.
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The bovine parser will first attempt to match the long form, and then
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the short form. If they were in reverse order, then the long form
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would never be tested.
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@c @xref{Default syntactic tokens}.
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@node Optional Lambda Expression
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@chapter Optional Lambda Expressions
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The @acronym{OLE} (@dfn{Optional Lambda Expression}) is converted into
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a bovine lambda. This lambda has special short-cuts to simplify
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reading the semantic action definition. An @acronym{OLE} like this:
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@example
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( $1 )
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@end example
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results in a lambda return which consists entirely of the string
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or object found by matching the first (zeroth) element of match.
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An @acronym{OLE} like this:
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@example
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( ,(foo $1) )
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@end example
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executes @code{foo} on the first argument, and then splices its return
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into the return list whereas:
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@example
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( (foo $1) )
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@end example
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executes @code{foo}, and that is placed in the return list.
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Here are other things that can appear inline:
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@table @code
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@item $1
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The first object matched.
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@item ,$1
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The first object spliced into the list (assuming it is a list from a
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non-terminal).
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@item '$1
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The first object matched, placed in a list. I.e., @code{( $1 )}.
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@item foo
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The symbol @code{foo} (exactly as displayed).
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@item (foo)
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A function call to foo which is stuck into the return list.
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@item ,(foo)
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A function call to foo which is spliced into the return list.
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@item '(foo)
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A function call to foo which is stuck into the return list in a list.
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@item (EXPAND @var{$1} @var{nonterminal} @var{depth})
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A list starting with @code{EXPAND} performs a recursive parse on the
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token passed to it (represented by @samp{$1} above.) The
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@dfn{semantic list} is a common token to expand, as there are often
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interesting things in the list. The @var{nonterminal} is a symbol in
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your table which the bovinator will start with when parsing.
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@var{nonterminal}'s definition is the same as any other nonterminal.
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@var{depth} should be at least @samp{1} when descending into a
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semantic list.
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@item (EXPANDFULL @var{$1} @var{nonterminal} @var{depth})
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Is like @code{EXPAND}, except that the parser will iterate over
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@var{nonterminal} until there are no more matches. (The same way the
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parser iterates over the starting rule (@pxref{Starting Rules}). This
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lets you have much simpler rules in this specific case, and also lets
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you have positional information in the returned tokens, and error
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skipping.
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@item (ASSOC @var{symbol1} @var{value1} @var{symbol2} @var{value2} @dots{})
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This is used for creating an association list. Each @var{symbol} is
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included in the list if the associated @var{value} is non-@code{nil}.
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While the items are all listed explicitly, the created structure is an
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association list of the form:
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@example
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((@var{symbol1} . @var{value1}) (@var{symbol2} . @var{value2}) @dots{})
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@end example
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@item (TAG @var{name} @var{class} [@var{attributes}])
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This creates one tag in the current buffer.
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@table @var
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@item name
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Is a string that represents the tag in the language.
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@item class
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Is the kind of tag being create, such as @code{function}, or
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@code{variable}, though any symbol will work.
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@item attributes
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Is an optional set of labeled values such as @code{:constant-flag t :parent
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"parenttype"}.
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@end table
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@item (TAG-VARIABLE @var{name} @var{type} @var{default-value} [@var{attributes}])
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@itemx (TAG-FUNCTION @var{name} @var{type} @var{arg-list} [@var{attributes}])
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@itemx (TAG-TYPE @var{name} @var{type} @var{members} @var{parents} [@var{attributes}])
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@itemx (TAG-INCLUDE @var{name} @var{system-flag} [@var{attributes}])
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@itemx (TAG-PACKAGE @var{name} @var{detail} [@var{attributes}])
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@itemx (TAG-CODE @var{name} @var{detail} [@var{attributes}])
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Create a tag with @var{name} of respectively the class
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@code{variable}, @code{function}, @code{type}, @code{include},
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@code{package}, and @code{code}.
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See @inforef{Creating Tags, , semantic-appdev} for the lisp
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functions these translate into.
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@end table
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If the symbol @code{%quotemode backquote} is specified, then use
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@code{,@@} to splice a list in, and @code{,} to evaluate the expression.
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This lets you send @code{$1} as a symbol into a list instead of having
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it expanded inline.
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@node Bovine Examples
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@chapter Examples
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The rule:
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@example
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any-symbol: symbol
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;
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@end example
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is equivalent to
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@example
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any-symbol: symbol
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( $1 )
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;
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@end example
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which, if it matched the string @samp{"A"}, would return
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@example
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( "A" )
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@end example
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If this rule were used like this:
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@example
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%token <punctuation> EQUAL "="
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@dots{}
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assign: any-symbol EQUAL any-symbol
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( $1 $3 )
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;
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@end example
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it would match @samp{"A=B"}, and return
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@example
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( ("A") ("B") )
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@end example
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The letters @samp{A} and @samp{B} come back in lists because
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@samp{any-symbol} is a nonterminal, not an actual lexical element.
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To get a better result with nonterminals, use @asis{,} to splice lists
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in like this:
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@example
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%token <punctuation> EQUAL "="
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@dots{}
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assign: any-symbol EQUAL any-symbol
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( ,$1 ,$3 )
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;
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@end example
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which would return
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@example
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( "A" "B" )
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@end example
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@node GNU Free Documentation License
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@appendix GNU Free Documentation License
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@include doclicense.texi
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@c There is nothing to index at the moment.
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@ignore
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@node Index
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@unnumbered Index
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@printindex cp
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@end ignore
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@iftex
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@contents
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@summarycontents
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@end iftex
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@bye
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@c Following comments are for the benefit of ispell.
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@c LocalWords: bovinator inlined
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