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1345 lines
42 KiB
Plaintext
1345 lines
42 KiB
Plaintext
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/*
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[The "BSD licence"]
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Copyright (c) 2005-2006 Terence Parr
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All rights reserved.
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Redistribution and use in source and binary forms, with or without
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modification, are permitted provided that the following conditions
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are met:
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1. Redistributions of source code must retain the above copyright
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notice, this list of conditions and the following disclaimer.
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2. Redistributions in binary form must reproduce the above copyright
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notice, this list of conditions and the following disclaimer in the
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documentation and/or other materials provided with the distribution.
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3. The name of the author may not be used to endorse or promote products
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derived from this software without specific prior written permission.
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THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
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IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
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OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
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IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
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INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
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NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
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DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
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THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
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(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
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THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
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*/
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group Java implements ANTLRCore;
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javaTypeInitMap ::= [
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"int":"0",
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"long":"0",
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"float":"0.0f",
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"double":"0.0",
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"boolean":"false",
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"byte":"0",
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"short":"0",
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"char":"0",
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default:"null" // anything other than an atomic type
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]
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/** The overall file structure of a recognizer; stores methods for rules
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* and cyclic DFAs plus support code.
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*/
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outputFile(LEXER,PARSER,TREE_PARSER, actionScope, actions,
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docComment, recognizer,
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name, tokens, tokenNames, rules, cyclicDFAs,
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bitsets, buildTemplate, buildAST, rewriteMode, profile,
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backtracking, synpreds, memoize, numRules,
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fileName, ANTLRVersion, generatedTimestamp, trace,
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scopes, superClass, literals) ::=
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<<
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// $ANTLR <ANTLRVersion> <fileName> <generatedTimestamp>
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<actions.(actionScope).header>
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<@imports>
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import org.antlr.runtime.*;
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<if(TREE_PARSER)>
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import org.antlr.runtime.tree.*;
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<endif>
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import java.util.Stack;
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import java.util.List;
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import java.util.ArrayList;
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<if(backtracking)>
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import java.util.Map;
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import java.util.HashMap;
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<endif>
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<@end>
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<docComment>
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<recognizer>
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>>
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lexer(grammar, name, tokens, scopes, rules, numRules, labelType="Token",
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filterMode, superClass="Lexer") ::= <<
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public class <grammar.recognizerName> extends <@superClassName><superClass><@end> {
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<tokens:{public static final int <it.name>=<it.type>;}; separator="\n">
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<scopes:{<if(it.isDynamicGlobalScope)><globalAttributeScope(scope=it)><endif>}>
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<actions.lexer.members>
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// delegates
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<grammar.delegates:
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{g|public <g.recognizerName> <g:delegateName()>;}; separator="\n">
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// delegators
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<grammar.delegators:
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{g|public <g.recognizerName> <g:delegateName()>;}; separator="\n">
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<last(grammar.delegators):{g|public <g.recognizerName> gParent;}>
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public <grammar.recognizerName>() {;} <! needed by subclasses !>
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public <grammar.recognizerName>(CharStream input<grammar.delegators:{g|, <g.recognizerName> <g:delegateName()>}>) {
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this(input, new RecognizerSharedState()<grammar.delegators:{g|, <g:delegateName()>}>);
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}
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public <grammar.recognizerName>(CharStream input, RecognizerSharedState state<grammar.delegators:{g|, <g.recognizerName> <g:delegateName()>}>) {
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super(input,state);
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<if(memoize)>
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<if(grammar.grammarIsRoot)>
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state.ruleMemo = new HashMap[<numRules>+1];<\n> <! index from 1..n !>
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<endif>
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<endif>
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<grammar.directDelegates:
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{g|<g:delegateName()> = new <g.recognizerName>(input, state<trunc(g.delegators):{p|, <p:delegateName()>}>, this);}; separator="\n">
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<grammar.delegators:
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{g|this.<g:delegateName()> = <g:delegateName()>;}; separator="\n">
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<last(grammar.delegators):{g|gParent = <g:delegateName()>;}>
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}
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public String getGrammarFileName() { return "<fileName>"; }
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<if(filterMode)>
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<filteringNextToken()>
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<endif>
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<rules; separator="\n\n">
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<synpreds:{p | <lexerSynpred(p)>}>
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<cyclicDFAs:{dfa | protected DFA<dfa.decisionNumber> dfa<dfa.decisionNumber> = new DFA<dfa.decisionNumber>(this);}; separator="\n">
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<cyclicDFAs:cyclicDFA()> <! dump tables for all DFA !>
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}
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>>
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/** A override of Lexer.nextToken() that backtracks over mTokens() looking
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* for matches. No error can be generated upon error; just rewind, consume
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* a token and then try again. backtracking needs to be set as well.
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* Make rule memoization happen only at levels above 1 as we start mTokens
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* at backtracking==1.
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*/
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filteringNextToken() ::= <<
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public Token nextToken() {
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while (true) {
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if ( input.LA(1)==CharStream.EOF ) {
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return Token.EOF_TOKEN;
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}
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state.token = null;
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state.channel = Token.DEFAULT_CHANNEL;
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state.tokenStartCharIndex = input.index();
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state.tokenStartCharPositionInLine = input.getCharPositionInLine();
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state.tokenStartLine = input.getLine();
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state.text = null;
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try {
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int m = input.mark();
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state.backtracking=1; <! means we won't throw slow exception !>
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state.failed=false;
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mTokens();
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state.backtracking=0;
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<! mTokens backtracks with synpred at backtracking==2
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and we set the synpredgate to allow actions at level 1. !>
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if ( state.failed ) {
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input.rewind(m);
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input.consume(); <! advance one char and try again !>
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}
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else {
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emit();
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return state.token;
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}
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}
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catch (RecognitionException re) {
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// shouldn't happen in backtracking mode, but...
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reportError(re);
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recover(re);
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}
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}
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}
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public void memoize(IntStream input,
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int ruleIndex,
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int ruleStartIndex)
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{
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if ( state.backtracking>1 ) super.memoize(input, ruleIndex, ruleStartIndex);
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}
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public boolean alreadyParsedRule(IntStream input, int ruleIndex) {
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if ( state.backtracking>1 ) return super.alreadyParsedRule(input, ruleIndex);
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return false;
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}
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>>
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filteringActionGate() ::= "state.backtracking==1"
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/** How to generate a parser */
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genericParser(grammar, name, scopes, tokens, tokenNames, rules, numRules,
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bitsets, inputStreamType, superClass,
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ASTLabelType="Object", labelType, members, rewriteElementType) ::= <<
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public class <grammar.recognizerName> extends <@superClassName><superClass><@end> {
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<if(grammar.grammarIsRoot)>
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public static final String[] tokenNames = new String[] {
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"\<invalid>", "\<EOR>", "\<DOWN>", "\<UP>", <tokenNames; separator=", ">
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};<\n>
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<endif>
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<tokens:{public static final int <it.name>=<it.type>;}; separator="\n">
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// delegates
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<grammar.delegates:
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{g|public <g.recognizerName> <g:delegateName()>;}; separator="\n">
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// delegators
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<grammar.delegators:
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{g|public <g.recognizerName> <g:delegateName()>;}; separator="\n">
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<last(grammar.delegators):{g|public <g.recognizerName> gParent;}>
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<scopes:{<if(it.isDynamicGlobalScope)><globalAttributeScope(scope=it)><endif>}>
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<@members>
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<! WARNING. bug in ST: this is cut-n-paste into Dbg.stg !>
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public <grammar.recognizerName>(<inputStreamType> input<grammar.delegators:{g|, <g.recognizerName> <g:delegateName()>}>) {
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this(input, new RecognizerSharedState()<grammar.delegators:{g|, <g:delegateName()>}>);
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}
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public <grammar.recognizerName>(<inputStreamType> input, RecognizerSharedState state<grammar.delegators:{g|, <g.recognizerName> <g:delegateName()>}>) {
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super(input, state);
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<parserCtorBody()>
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<grammar.directDelegates:
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{g|<g:delegateName()> = new <g.recognizerName>(input, state<trunc(g.delegators):{p|, <p:delegateName()>}>, this);}; separator="\n">
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<grammar.indirectDelegates:{g | <g:delegateName()> = <g.delegator:delegateName()>.<g:delegateName()>;}; separator="\n">
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<last(grammar.delegators):{g|gParent = <g:delegateName()>;}>
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}
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<@end>
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public String[] getTokenNames() { return <grammar.composite.rootGrammar.recognizerName>.tokenNames; }
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public String getGrammarFileName() { return "<fileName>"; }
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<members>
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<rules; separator="\n\n">
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<! generate rule/method definitions for imported rules so they
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appear to be defined in this recognizer. !>
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// Delegated rules
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<grammar.delegatedRules:{ruleDescriptor|
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public <returnType()> <ruleDescriptor.name>(<ruleDescriptor.parameterScope:parameterScope(scope=it)>) throws RecognitionException \{ <if(ruleDescriptor.hasReturnValue)>return <endif><ruleDescriptor.grammar:delegateName()>.<ruleDescriptor.name>(<ruleDescriptor.parameterScope.attributes:{a|<a.name>}; separator=", ">); \}}; separator="\n">
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<synpreds:{p | <synpred(p)>}>
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<cyclicDFAs:{dfa | protected DFA<dfa.decisionNumber> dfa<dfa.decisionNumber> = new DFA<dfa.decisionNumber>(this);}; separator="\n">
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<cyclicDFAs:cyclicDFA()> <! dump tables for all DFA !>
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<bitsets:bitset(name={FOLLOW_<it.name>_in_<it.inName><it.tokenIndex>},
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words64=it.bits)>
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}
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>>
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parserCtorBody() ::= <<
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<if(memoize)>
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<if(grammar.grammarIsRoot)>
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this.state.ruleMemo = new HashMap[<length(grammar.allImportedRules)>+1];<\n> <! index from 1..n !>
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<endif>
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<endif>
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<grammar.delegators:
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{g|this.<g:delegateName()> = <g:delegateName()>;}; separator="\n">
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>>
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parser(grammar, name, scopes, tokens, tokenNames, rules, numRules, bitsets, ASTLabelType="Object", superClass="Parser", labelType="Token", members={<actions.parser.members>}) ::= <<
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<genericParser(inputStreamType="TokenStream", rewriteElementType="Token", ...)>
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>>
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/** How to generate a tree parser; same as parser except the input
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* stream is a different type.
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*/
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treeParser(grammar, name, scopes, tokens, tokenNames, globalAction, rules, numRules, bitsets, labelType={<ASTLabelType>}, ASTLabelType="Object", superClass="TreeParser", members={<actions.treeparser.members>}) ::= <<
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<genericParser(inputStreamType="TreeNodeStream", rewriteElementType="Node", ...)>
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>>
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/** A simpler version of a rule template that is specific to the imaginary
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* rules created for syntactic predicates. As they never have return values
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* nor parameters etc..., just give simplest possible method. Don't do
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* any of the normal memoization stuff in here either; it's a waste.
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* As predicates cannot be inlined into the invoking rule, they need to
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* be in a rule by themselves.
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*/
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synpredRule(ruleName, ruleDescriptor, block, description, nakedBlock) ::=
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<<
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// $ANTLR start <ruleName>
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public final void <ruleName>_fragment(<ruleDescriptor.parameterScope:parameterScope(scope=it)>) throws RecognitionException {
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<if(trace)>
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traceIn("<ruleName>_fragment", <ruleDescriptor.index>);
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try {
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<block>
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}
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finally {
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traceOut("<ruleName>_fragment", <ruleDescriptor.index>);
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}
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<else>
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<block>
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<endif>
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}
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// $ANTLR end <ruleName>
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>>
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synpred(name) ::= <<
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public final boolean <name>() {
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state.backtracking++;
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<@start()>
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int start = input.mark();
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try {
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<name>_fragment(); // can never throw exception
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} catch (RecognitionException re) {
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System.err.println("impossible: "+re);
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}
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boolean success = !state.failed;
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input.rewind(start);
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<@stop()>
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state.backtracking--;
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state.failed=false;
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return success;
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}<\n>
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>>
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lexerSynpred(name) ::= <<
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<synpred(name)>
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>>
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ruleMemoization(name) ::= <<
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<if(memoize)>
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if ( state.backtracking>0 && alreadyParsedRule(input, <ruleDescriptor.index>) ) { return <ruleReturnValue()>; }
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<endif>
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>>
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|
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/** How to test for failure and return from rule */
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checkRuleBacktrackFailure() ::= <<
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<if(backtracking)>if (state.failed) return <ruleReturnValue()>;<endif>
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>>
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|
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/** This rule has failed, exit indicating failure during backtrack */
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|
ruleBacktrackFailure() ::= <<
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<if(backtracking)>if (state.backtracking>0) {state.failed=true; return <ruleReturnValue()>;}<endif>
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|
>>
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|
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/** How to generate code for a rule. This includes any return type
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* data aggregates required for multiple return values.
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*/
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rule(ruleName,ruleDescriptor,block,emptyRule,description,exceptions,finally,memoize) ::= <<
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<ruleAttributeScope(scope=ruleDescriptor.ruleScope)>
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|
<returnScope(scope=ruleDescriptor.returnScope)>
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|
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|
// $ANTLR start "<ruleName>"
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|
// <fileName>:<description>
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|
public final <returnType()> <ruleName>(<ruleDescriptor.parameterScope:parameterScope(scope=it)>) throws RecognitionException {
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<if(trace)>traceIn("<ruleName>", <ruleDescriptor.index>);<endif>
|
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|
<ruleScopeSetUp()>
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|
<ruleDeclarations()>
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|
<ruleLabelDefs()>
|
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|
<ruleDescriptor.actions.init>
|
||
|
<@preamble()>
|
||
|
try {
|
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|
<ruleMemoization(name=ruleName)>
|
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|
<block>
|
||
|
<ruleCleanUp()>
|
||
|
<(ruleDescriptor.actions.after):execAction()>
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|
}
|
||
|
<if(exceptions)>
|
||
|
<exceptions:{e|<catch(decl=e.decl,action=e.action)><\n>}>
|
||
|
<else>
|
||
|
<if(!emptyRule)>
|
||
|
<if(actions.(actionScope).rulecatch)>
|
||
|
<actions.(actionScope).rulecatch>
|
||
|
<else>
|
||
|
catch (RecognitionException re) {
|
||
|
reportError(re);
|
||
|
recover(input,re);
|
||
|
<@setErrorReturnValue()>
|
||
|
}<\n>
|
||
|
<endif>
|
||
|
<endif>
|
||
|
<endif>
|
||
|
finally {
|
||
|
<if(trace)>traceOut("<ruleName>", <ruleDescriptor.index>);<endif>
|
||
|
<memoize()>
|
||
|
<ruleScopeCleanUp()>
|
||
|
<finally>
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||
|
}
|
||
|
<@postamble()>
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|
return <ruleReturnValue()>;
|
||
|
}
|
||
|
// $ANTLR end "<ruleName>"
|
||
|
>>
|
||
|
|
||
|
catch(decl,action) ::= <<
|
||
|
catch (<e.decl>) {
|
||
|
<e.action>
|
||
|
}
|
||
|
>>
|
||
|
|
||
|
ruleDeclarations() ::= <<
|
||
|
<if(ruleDescriptor.hasMultipleReturnValues)>
|
||
|
<returnType()> retval = new <returnType()>();
|
||
|
retval.start = input.LT(1);<\n>
|
||
|
<else>
|
||
|
<ruleDescriptor.returnScope.attributes:{ a |
|
||
|
<a.type> <a.name> = <if(a.initValue)><a.initValue><else><initValue(a.type)><endif>;
|
||
|
}>
|
||
|
<endif>
|
||
|
<if(memoize)>
|
||
|
int <ruleDescriptor.name>_StartIndex = input.index();
|
||
|
<endif>
|
||
|
>>
|
||
|
|
||
|
ruleScopeSetUp() ::= <<
|
||
|
<ruleDescriptor.useScopes:{<it>_stack.push(new <it>_scope());}; separator="\n">
|
||
|
<ruleDescriptor.ruleScope:{<it.name>_stack.push(new <it.name>_scope());}; separator="\n">
|
||
|
>>
|
||
|
|
||
|
ruleScopeCleanUp() ::= <<
|
||
|
<ruleDescriptor.useScopes:{<it>_stack.pop();}; separator="\n">
|
||
|
<ruleDescriptor.ruleScope:{<it.name>_stack.pop();}; separator="\n">
|
||
|
>>
|
||
|
|
||
|
ruleLabelDefs() ::= <<
|
||
|
<[ruleDescriptor.tokenLabels,ruleDescriptor.tokenListLabels]
|
||
|
:{<labelType> <it.label.text>=null;}; separator="\n"
|
||
|
>
|
||
|
<[ruleDescriptor.tokenListLabels,ruleDescriptor.ruleListLabels]
|
||
|
:{List list_<it.label.text>=null;}; separator="\n"
|
||
|
>
|
||
|
<ruleDescriptor.ruleLabels:ruleLabelDef(label=it); separator="\n">
|
||
|
<ruleDescriptor.ruleListLabels:{ll|<ruleLabelType(referencedRule=ll.referencedRule)> <ll.label.text> = null;}; separator="\n">
|
||
|
>>
|
||
|
|
||
|
lexerRuleLabelDefs() ::= <<
|
||
|
<[ruleDescriptor.tokenLabels,
|
||
|
ruleDescriptor.tokenListLabels,
|
||
|
ruleDescriptor.ruleLabels]
|
||
|
:{<labelType> <it.label.text>=null;}; separator="\n"
|
||
|
>
|
||
|
<ruleDescriptor.charLabels:{int <it.label.text>;}; separator="\n">
|
||
|
<[ruleDescriptor.tokenListLabels,
|
||
|
ruleDescriptor.ruleListLabels,
|
||
|
ruleDescriptor.ruleListLabels]
|
||
|
:{List list_<it.label.text>=null;}; separator="\n"
|
||
|
>
|
||
|
>>
|
||
|
|
||
|
ruleReturnValue() ::= <<
|
||
|
<if(!ruleDescriptor.isSynPred)>
|
||
|
<if(ruleDescriptor.hasReturnValue)>
|
||
|
<if(ruleDescriptor.hasSingleReturnValue)>
|
||
|
<ruleDescriptor.singleValueReturnName>
|
||
|
<else>
|
||
|
retval
|
||
|
<endif>
|
||
|
<endif>
|
||
|
<endif>
|
||
|
>>
|
||
|
|
||
|
ruleCleanUp() ::= <<
|
||
|
<if(ruleDescriptor.hasMultipleReturnValues)>
|
||
|
<if(!TREE_PARSER)>
|
||
|
retval.stop = input.LT(-1);<\n>
|
||
|
<endif>
|
||
|
<endif>
|
||
|
>>
|
||
|
|
||
|
memoize() ::= <<
|
||
|
<if(memoize)>
|
||
|
<if(backtracking)>
|
||
|
if ( state.backtracking>0 ) { memoize(input, <ruleDescriptor.index>, <ruleDescriptor.name>_StartIndex); }
|
||
|
<endif>
|
||
|
<endif>
|
||
|
>>
|
||
|
|
||
|
/** How to generate a rule in the lexer; naked blocks are used for
|
||
|
* fragment rules.
|
||
|
*/
|
||
|
lexerRule(ruleName,nakedBlock,ruleDescriptor,block,memoize) ::= <<
|
||
|
// $ANTLR start "<ruleName>"
|
||
|
public final void m<ruleName>(<ruleDescriptor.parameterScope:parameterScope(scope=it)>) throws RecognitionException {
|
||
|
<if(trace)>traceIn("<ruleName>", <ruleDescriptor.index>);<endif>
|
||
|
<ruleScopeSetUp()>
|
||
|
<ruleDeclarations()>
|
||
|
try {
|
||
|
<if(nakedBlock)>
|
||
|
<ruleMemoization(name=ruleName)>
|
||
|
<lexerRuleLabelDefs()>
|
||
|
<ruleDescriptor.actions.init>
|
||
|
<block><\n>
|
||
|
<else>
|
||
|
int _type = <ruleName>;
|
||
|
int _channel = DEFAULT_TOKEN_CHANNEL;
|
||
|
<ruleMemoization(name=ruleName)>
|
||
|
<lexerRuleLabelDefs()>
|
||
|
<ruleDescriptor.actions.init>
|
||
|
<block>
|
||
|
<ruleCleanUp()>
|
||
|
state.type = _type;
|
||
|
state.channel = _channel;
|
||
|
<(ruleDescriptor.actions.after):execAction()>
|
||
|
<endif>
|
||
|
}
|
||
|
finally {
|
||
|
<if(trace)>traceOut("<ruleName>", <ruleDescriptor.index>);<endif>
|
||
|
<ruleScopeCleanUp()>
|
||
|
<memoize()>
|
||
|
}
|
||
|
}
|
||
|
// $ANTLR end "<ruleName>"
|
||
|
>>
|
||
|
|
||
|
/** How to generate code for the implicitly-defined lexer grammar rule
|
||
|
* that chooses between lexer rules.
|
||
|
*/
|
||
|
tokensRule(ruleName,nakedBlock,args,block,ruleDescriptor) ::= <<
|
||
|
public void mTokens() throws RecognitionException {
|
||
|
<block><\n>
|
||
|
}
|
||
|
>>
|
||
|
|
||
|
// S U B R U L E S
|
||
|
|
||
|
/** A (...) subrule with multiple alternatives */
|
||
|
block(alts,decls,decision,enclosingBlockLevel,blockLevel,decisionNumber,maxK,maxAlt,description) ::= <<
|
||
|
// <fileName>:<description>
|
||
|
int alt<decisionNumber>=<maxAlt>;
|
||
|
<decls>
|
||
|
<@predecision()>
|
||
|
<decision>
|
||
|
<@postdecision()>
|
||
|
<@prebranch()>
|
||
|
switch (alt<decisionNumber>) {
|
||
|
<alts:altSwitchCase()>
|
||
|
}
|
||
|
<@postbranch()>
|
||
|
>>
|
||
|
|
||
|
/** A rule block with multiple alternatives */
|
||
|
ruleBlock(alts,decls,decision,enclosingBlockLevel,blockLevel,decisionNumber,maxK,maxAlt,description) ::= <<
|
||
|
// <fileName>:<description>
|
||
|
int alt<decisionNumber>=<maxAlt>;
|
||
|
<decls>
|
||
|
<@predecision()>
|
||
|
<decision>
|
||
|
<@postdecision()>
|
||
|
switch (alt<decisionNumber>) {
|
||
|
<alts:altSwitchCase()>
|
||
|
}
|
||
|
>>
|
||
|
|
||
|
ruleBlockSingleAlt(alts,decls,decision,enclosingBlockLevel,blockLevel,decisionNumber,description) ::= <<
|
||
|
// <fileName>:<description>
|
||
|
<decls>
|
||
|
<@prealt()>
|
||
|
<alts>
|
||
|
<@postalt()>
|
||
|
>>
|
||
|
|
||
|
/** A special case of a (...) subrule with a single alternative */
|
||
|
blockSingleAlt(alts,decls,decision,enclosingBlockLevel,blockLevel,decisionNumber,description) ::= <<
|
||
|
// <fileName>:<description>
|
||
|
<decls>
|
||
|
<@prealt()>
|
||
|
<alts>
|
||
|
<@postalt()>
|
||
|
>>
|
||
|
|
||
|
/** A (..)+ block with 1 or more alternatives */
|
||
|
positiveClosureBlock(alts,decls,decision,enclosingBlockLevel,blockLevel,decisionNumber,maxK,maxAlt,description) ::= <<
|
||
|
// <fileName>:<description>
|
||
|
int cnt<decisionNumber>=0;
|
||
|
<decls>
|
||
|
<@preloop()>
|
||
|
loop<decisionNumber>:
|
||
|
do {
|
||
|
int alt<decisionNumber>=<maxAlt>;
|
||
|
<@predecision()>
|
||
|
<decision>
|
||
|
<@postdecision()>
|
||
|
switch (alt<decisionNumber>) {
|
||
|
<alts:altSwitchCase()>
|
||
|
default :
|
||
|
if ( cnt<decisionNumber> >= 1 ) break loop<decisionNumber>;
|
||
|
<ruleBacktrackFailure()>
|
||
|
EarlyExitException eee =
|
||
|
new EarlyExitException(<decisionNumber>, input);
|
||
|
<@earlyExitException()>
|
||
|
throw eee;
|
||
|
}
|
||
|
cnt<decisionNumber>++;
|
||
|
} while (true);
|
||
|
<@postloop()>
|
||
|
>>
|
||
|
|
||
|
positiveClosureBlockSingleAlt ::= positiveClosureBlock
|
||
|
|
||
|
/** A (..)* block with 1 or more alternatives */
|
||
|
closureBlock(alts,decls,decision,enclosingBlockLevel,blockLevel,decisionNumber,maxK,maxAlt,description) ::= <<
|
||
|
// <fileName>:<description>
|
||
|
<decls>
|
||
|
<@preloop()>
|
||
|
loop<decisionNumber>:
|
||
|
do {
|
||
|
int alt<decisionNumber>=<maxAlt>;
|
||
|
<@predecision()>
|
||
|
<decision>
|
||
|
<@postdecision()>
|
||
|
switch (alt<decisionNumber>) {
|
||
|
<alts:altSwitchCase()>
|
||
|
default :
|
||
|
break loop<decisionNumber>;
|
||
|
}
|
||
|
} while (true);
|
||
|
<@postloop()>
|
||
|
>>
|
||
|
|
||
|
closureBlockSingleAlt ::= closureBlock
|
||
|
|
||
|
/** Optional blocks (x)? are translated to (x|) by before code generation
|
||
|
* so we can just use the normal block template
|
||
|
*/
|
||
|
optionalBlock ::= block
|
||
|
|
||
|
optionalBlockSingleAlt ::= block
|
||
|
|
||
|
/** A case in a switch that jumps to an alternative given the alternative
|
||
|
* number. A DFA predicts the alternative and then a simple switch
|
||
|
* does the jump to the code that actually matches that alternative.
|
||
|
*/
|
||
|
altSwitchCase() ::= <<
|
||
|
case <i> :
|
||
|
<@prealt()>
|
||
|
<it>
|
||
|
break;<\n>
|
||
|
>>
|
||
|
|
||
|
/** An alternative is just a list of elements; at outermost level */
|
||
|
alt(elements,altNum,description,autoAST,outerAlt,treeLevel,rew) ::= <<
|
||
|
// <fileName>:<description>
|
||
|
{
|
||
|
<@declarations()>
|
||
|
<elements:element()>
|
||
|
<rew>
|
||
|
<@cleanup()>
|
||
|
}
|
||
|
>>
|
||
|
|
||
|
/** What to emit when there is no rewrite. For auto build
|
||
|
* mode, does nothing.
|
||
|
*/
|
||
|
noRewrite(rewriteBlockLevel, treeLevel) ::= ""
|
||
|
|
||
|
// E L E M E N T S
|
||
|
|
||
|
/** Dump the elements one per line */
|
||
|
element() ::= <<
|
||
|
<@prematch()>
|
||
|
<it.el><\n>
|
||
|
>>
|
||
|
|
||
|
/** match a token optionally with a label in front */
|
||
|
tokenRef(token,label,elementIndex,hetero) ::= <<
|
||
|
<if(label)><label>=(<labelType>)<endif>match(input,<token>,FOLLOW_<token>_in_<ruleName><elementIndex>); <checkRuleBacktrackFailure()>
|
||
|
>>
|
||
|
|
||
|
/** ids+=ID */
|
||
|
tokenRefAndListLabel(token,label,elementIndex,hetero) ::= <<
|
||
|
<tokenRef(...)>
|
||
|
<listLabel(elem=label,...)>
|
||
|
>>
|
||
|
|
||
|
listLabel(label,elem) ::= <<
|
||
|
if (list_<label>==null) list_<label>=new ArrayList();
|
||
|
list_<label>.add(<elem>);<\n>
|
||
|
>>
|
||
|
|
||
|
/** match a character */
|
||
|
charRef(char,label) ::= <<
|
||
|
<if(label)>
|
||
|
<label> = input.LA(1);<\n>
|
||
|
<endif>
|
||
|
match(<char>); <checkRuleBacktrackFailure()>
|
||
|
>>
|
||
|
|
||
|
/** match a character range */
|
||
|
charRangeRef(a,b,label) ::= <<
|
||
|
<if(label)>
|
||
|
<label> = input.LA(1);<\n>
|
||
|
<endif>
|
||
|
matchRange(<a>,<b>); <checkRuleBacktrackFailure()>
|
||
|
>>
|
||
|
|
||
|
/** For now, sets are interval tests and must be tested inline */
|
||
|
matchSet(s,label,elementIndex,postmatchCode="") ::= <<
|
||
|
<if(label)>
|
||
|
<if(LEXER)>
|
||
|
<label>= input.LA(1);<\n>
|
||
|
<else>
|
||
|
<label>=(<labelType>)input.LT(1);<\n>
|
||
|
<endif>
|
||
|
<endif>
|
||
|
if ( <s> ) {
|
||
|
input.consume();
|
||
|
<postmatchCode>
|
||
|
<if(!LEXER)>
|
||
|
state.errorRecovery=false;
|
||
|
<endif>
|
||
|
<if(backtracking)>state.failed=false;<endif>
|
||
|
}
|
||
|
else {
|
||
|
<ruleBacktrackFailure()>
|
||
|
MismatchedSetException mse = new MismatchedSetException(null,input);
|
||
|
<@mismatchedSetException()>
|
||
|
<if(LEXER)>
|
||
|
recover(mse);
|
||
|
throw mse;
|
||
|
<else>
|
||
|
throw mse;
|
||
|
<! use following code to make it recover inline; remove throw mse;
|
||
|
recoverFromMismatchedSet(input,mse,FOLLOW_set_in_<ruleName><elementIndex>);
|
||
|
!>
|
||
|
<endif>
|
||
|
}<\n>
|
||
|
>>
|
||
|
|
||
|
matchRuleBlockSet ::= matchSet
|
||
|
|
||
|
matchSetAndListLabel(s,label,elementIndex,postmatchCode) ::= <<
|
||
|
<matchSet(...)>
|
||
|
<listLabel(elem=label,...)>
|
||
|
>>
|
||
|
|
||
|
/** Match a string literal */
|
||
|
lexerStringRef(string,label) ::= <<
|
||
|
<if(label)>
|
||
|
int <label>Start = getCharIndex();
|
||
|
match(<string>); <checkRuleBacktrackFailure()>
|
||
|
<label> = new CommonToken(input, Token.INVALID_TOKEN_TYPE, Token.DEFAULT_CHANNEL, <label>Start, getCharIndex()-1);
|
||
|
<else>
|
||
|
match(<string>); <checkRuleBacktrackFailure()><\n>
|
||
|
<endif>
|
||
|
>>
|
||
|
|
||
|
wildcard(label,elementIndex) ::= <<
|
||
|
<if(label)>
|
||
|
<label>=(<labelType>)input.LT(1);<\n>
|
||
|
<endif>
|
||
|
matchAny(input); <checkRuleBacktrackFailure()>
|
||
|
>>
|
||
|
|
||
|
wildcardAndListLabel(label,elementIndex) ::= <<
|
||
|
<wildcard(...)>
|
||
|
<listLabel(elem=label,...)>
|
||
|
>>
|
||
|
|
||
|
/** Match . wildcard in lexer */
|
||
|
wildcardChar(label, elementIndex) ::= <<
|
||
|
<if(label)>
|
||
|
<label> = input.LA(1);<\n>
|
||
|
<endif>
|
||
|
matchAny(); <checkRuleBacktrackFailure()>
|
||
|
>>
|
||
|
|
||
|
wildcardCharListLabel(label, elementIndex) ::= <<
|
||
|
<wildcardChar(...)>
|
||
|
<listLabel(elem=label,...)>
|
||
|
>>
|
||
|
|
||
|
/** Match a rule reference by invoking it possibly with arguments
|
||
|
* and a return value or values. The 'rule' argument was the
|
||
|
* target rule name, but now is type Rule, whose toString is
|
||
|
* same: the rule name. Now though you can access full rule
|
||
|
* descriptor stuff.
|
||
|
*/
|
||
|
ruleRef(rule,label,elementIndex,args,scope) ::= <<
|
||
|
pushFollow(FOLLOW_<rule.name>_in_<ruleName><elementIndex>);
|
||
|
<if(label)><label>=<endif><if(scope)><scope:delegateName()>.<endif><rule.name>(<args; separator=", ">);<\n>
|
||
|
state._fsp--;
|
||
|
<checkRuleBacktrackFailure()>
|
||
|
>>
|
||
|
|
||
|
/** ids+=r */
|
||
|
ruleRefAndListLabel(rule,label,elementIndex,args,scope) ::= <<
|
||
|
<ruleRef(...)>
|
||
|
<listLabel(elem=label,...)>
|
||
|
>>
|
||
|
|
||
|
/** A lexer rule reference.
|
||
|
*
|
||
|
* The 'rule' argument was the target rule name, but now
|
||
|
* is type Rule, whose toString is same: the rule name.
|
||
|
* Now though you can access full rule descriptor stuff.
|
||
|
*/
|
||
|
lexerRuleRef(rule,label,args,elementIndex,scope) ::= <<
|
||
|
<if(label)>
|
||
|
int <label>Start<elementIndex> = getCharIndex();
|
||
|
<if(scope)><scope:delegateName()>.<endif>m<rule.name>(<args; separator=", ">); <checkRuleBacktrackFailure()>
|
||
|
<label> = new CommonToken(input, Token.INVALID_TOKEN_TYPE, Token.DEFAULT_CHANNEL, <label>Start<elementIndex>, getCharIndex()-1);
|
||
|
<else>
|
||
|
<if(scope)><scope:delegateName()>.<endif>m<rule.name>(<args; separator=", ">); <checkRuleBacktrackFailure()>
|
||
|
<endif>
|
||
|
>>
|
||
|
|
||
|
/** i+=INT in lexer */
|
||
|
lexerRuleRefAndListLabel(rule,label,args,elementIndex,scope) ::= <<
|
||
|
<lexerRuleRef(...)>
|
||
|
<listLabel(elem=label,...)>
|
||
|
>>
|
||
|
|
||
|
/** EOF in the lexer */
|
||
|
lexerMatchEOF(label,elementIndex) ::= <<
|
||
|
<if(label)>
|
||
|
int <label>Start<elementIndex> = getCharIndex();
|
||
|
match(EOF); <checkRuleBacktrackFailure()>
|
||
|
<labelType> <label> = new CommonToken(input, EOF, Token.DEFAULT_CHANNEL, <label>Start<elementIndex>, getCharIndex()-1);
|
||
|
<else>
|
||
|
match(EOF); <checkRuleBacktrackFailure()>
|
||
|
<endif>
|
||
|
>>
|
||
|
|
||
|
/** match ^(root children) in tree parser */
|
||
|
tree(root, actionsAfterRoot, children, nullableChildList,
|
||
|
enclosingTreeLevel, treeLevel) ::= <<
|
||
|
<root:element()>
|
||
|
<actionsAfterRoot:element()>
|
||
|
<if(nullableChildList)>
|
||
|
if ( input.LA(1)==Token.DOWN ) {
|
||
|
match(input, Token.DOWN, null); <checkRuleBacktrackFailure()>
|
||
|
<children:element()>
|
||
|
match(input, Token.UP, null); <checkRuleBacktrackFailure()>
|
||
|
}
|
||
|
<else>
|
||
|
match(input, Token.DOWN, null); <checkRuleBacktrackFailure()>
|
||
|
<children:element()>
|
||
|
match(input, Token.UP, null); <checkRuleBacktrackFailure()>
|
||
|
<endif>
|
||
|
>>
|
||
|
|
||
|
/** Every predicate is used as a validating predicate (even when it is
|
||
|
* also hoisted into a prediction expression).
|
||
|
*/
|
||
|
validateSemanticPredicate(pred,description) ::= <<
|
||
|
if ( !(<evalPredicate(...)>) ) {
|
||
|
<ruleBacktrackFailure()>
|
||
|
throw new FailedPredicateException(input, "<ruleName>", "<description>");
|
||
|
}
|
||
|
>>
|
||
|
|
||
|
// F i x e d D F A (if-then-else)
|
||
|
|
||
|
dfaState(k,edges,eotPredictsAlt,description,stateNumber,semPredState) ::= <<
|
||
|
int LA<decisionNumber>_<stateNumber> = input.LA(<k>);<\n>
|
||
|
<edges; separator="\nelse ">
|
||
|
else {
|
||
|
<if(eotPredictsAlt)>
|
||
|
alt<decisionNumber>=<eotPredictsAlt>;
|
||
|
<else>
|
||
|
<ruleBacktrackFailure()>
|
||
|
NoViableAltException nvae =
|
||
|
new NoViableAltException("<description>", <decisionNumber>, <stateNumber>, input);<\n>
|
||
|
<@noViableAltException()>
|
||
|
throw nvae;<\n>
|
||
|
<endif>
|
||
|
}
|
||
|
>>
|
||
|
|
||
|
/** Same as a normal DFA state except that we don't examine lookahead
|
||
|
* for the bypass alternative. It delays error detection but this
|
||
|
* is faster, smaller, and more what people expect. For (X)? people
|
||
|
* expect "if ( LA(1)==X ) match(X);" and that's it.
|
||
|
*/
|
||
|
dfaOptionalBlockState(k,edges,eotPredictsAlt,description,stateNumber,semPredState) ::= <<
|
||
|
int LA<decisionNumber>_<stateNumber> = input.LA(<k>);<\n>
|
||
|
<edges; separator="\nelse ">
|
||
|
>>
|
||
|
|
||
|
/** A DFA state that is actually the loopback decision of a closure
|
||
|
* loop. If end-of-token (EOT) predicts any of the targets then it
|
||
|
* should act like a default clause (i.e., no error can be generated).
|
||
|
* This is used only in the lexer so that for ('a')* on the end of a rule
|
||
|
* anything other than 'a' predicts exiting.
|
||
|
*/
|
||
|
dfaLoopbackState(k,edges,eotPredictsAlt,description,stateNumber,semPredState) ::= <<
|
||
|
int LA<decisionNumber>_<stateNumber> = input.LA(<k>);<\n>
|
||
|
<edges; separator="\nelse "><\n>
|
||
|
<if(eotPredictsAlt)>
|
||
|
<if(!edges)>
|
||
|
alt<decisionNumber>=<eotPredictsAlt>; <! if no edges, don't gen ELSE !>
|
||
|
<else>
|
||
|
else {
|
||
|
alt<decisionNumber>=<eotPredictsAlt>;
|
||
|
}<\n>
|
||
|
<endif>
|
||
|
<endif>
|
||
|
>>
|
||
|
|
||
|
/** An accept state indicates a unique alternative has been predicted */
|
||
|
dfaAcceptState(alt) ::= "alt<decisionNumber>=<alt>;"
|
||
|
|
||
|
/** A simple edge with an expression. If the expression is satisfied,
|
||
|
* enter to the target state. To handle gated productions, we may
|
||
|
* have to evaluate some predicates for this edge.
|
||
|
*/
|
||
|
dfaEdge(labelExpr, targetState, predicates) ::= <<
|
||
|
if ( (<labelExpr>) <if(predicates)>&& (<predicates>)<endif>) {
|
||
|
<targetState>
|
||
|
}
|
||
|
>>
|
||
|
|
||
|
// F i x e d D F A (switch case)
|
||
|
|
||
|
/** A DFA state where a SWITCH may be generated. The code generator
|
||
|
* decides if this is possible: CodeGenerator.canGenerateSwitch().
|
||
|
*/
|
||
|
dfaStateSwitch(k,edges,eotPredictsAlt,description,stateNumber,semPredState) ::= <<
|
||
|
switch ( input.LA(<k>) ) {
|
||
|
<edges; separator="\n">
|
||
|
default:
|
||
|
<if(eotPredictsAlt)>
|
||
|
alt<decisionNumber>=<eotPredictsAlt>;
|
||
|
<else>
|
||
|
<ruleBacktrackFailure()>
|
||
|
NoViableAltException nvae =
|
||
|
new NoViableAltException("<description>", <decisionNumber>, <stateNumber>, input);<\n>
|
||
|
<@noViableAltException()>
|
||
|
throw nvae;<\n>
|
||
|
<endif>
|
||
|
}<\n>
|
||
|
>>
|
||
|
|
||
|
dfaOptionalBlockStateSwitch(k,edges,eotPredictsAlt,description,stateNumber,semPredState) ::= <<
|
||
|
switch ( input.LA(<k>) ) {
|
||
|
<edges; separator="\n">
|
||
|
}<\n>
|
||
|
>>
|
||
|
|
||
|
dfaLoopbackStateSwitch(k, edges,eotPredictsAlt,description,stateNumber,semPredState) ::= <<
|
||
|
switch ( input.LA(<k>) ) {
|
||
|
<edges; separator="\n"><\n>
|
||
|
<if(eotPredictsAlt)>
|
||
|
default:
|
||
|
alt<decisionNumber>=<eotPredictsAlt>;
|
||
|
break;<\n>
|
||
|
<endif>
|
||
|
}<\n>
|
||
|
>>
|
||
|
|
||
|
dfaEdgeSwitch(labels, targetState) ::= <<
|
||
|
<labels:{case <it>:}; separator="\n">
|
||
|
{
|
||
|
<targetState>
|
||
|
}
|
||
|
break;
|
||
|
>>
|
||
|
|
||
|
// C y c l i c D F A
|
||
|
|
||
|
/** The code to initiate execution of a cyclic DFA; this is used
|
||
|
* in the rule to predict an alt just like the fixed DFA case.
|
||
|
* The <name> attribute is inherited via the parser, lexer, ...
|
||
|
*/
|
||
|
dfaDecision(decisionNumber,description) ::= <<
|
||
|
alt<decisionNumber> = dfa<decisionNumber>.predict(input);
|
||
|
>>
|
||
|
|
||
|
/* Dump DFA tables as run-length-encoded Strings of octal values.
|
||
|
* Can't use hex as compiler translates them before compilation.
|
||
|
* These strings are split into multiple, concatenated strings.
|
||
|
* Java puts them back together at compile time thankfully.
|
||
|
* Java cannot handle large static arrays, so we're stuck with this
|
||
|
* encode/decode approach. See analysis and runtime DFA for
|
||
|
* the encoding methods.
|
||
|
*/
|
||
|
cyclicDFA(dfa) ::= <<
|
||
|
static final String DFA<dfa.decisionNumber>_eotS =
|
||
|
"<dfa.javaCompressedEOT; wrap="\"+\n \"">";
|
||
|
static final String DFA<dfa.decisionNumber>_eofS =
|
||
|
"<dfa.javaCompressedEOF; wrap="\"+\n \"">";
|
||
|
static final String DFA<dfa.decisionNumber>_minS =
|
||
|
"<dfa.javaCompressedMin; wrap="\"+\n \"">";
|
||
|
static final String DFA<dfa.decisionNumber>_maxS =
|
||
|
"<dfa.javaCompressedMax; wrap="\"+\n \"">";
|
||
|
static final String DFA<dfa.decisionNumber>_acceptS =
|
||
|
"<dfa.javaCompressedAccept; wrap="\"+\n \"">";
|
||
|
static final String DFA<dfa.decisionNumber>_specialS =
|
||
|
"<dfa.javaCompressedSpecial; wrap="\"+\n \"">}>";
|
||
|
static final String[] DFA<dfa.decisionNumber>_transitionS = {
|
||
|
<dfa.javaCompressedTransition:{s|"<s; wrap="\"+\n\"">"}; separator=",\n">
|
||
|
};
|
||
|
|
||
|
static final short[] DFA<dfa.decisionNumber>_eot = DFA.unpackEncodedString(DFA<dfa.decisionNumber>_eotS);
|
||
|
static final short[] DFA<dfa.decisionNumber>_eof = DFA.unpackEncodedString(DFA<dfa.decisionNumber>_eofS);
|
||
|
static final char[] DFA<dfa.decisionNumber>_min = DFA.unpackEncodedStringToUnsignedChars(DFA<dfa.decisionNumber>_minS);
|
||
|
static final char[] DFA<dfa.decisionNumber>_max = DFA.unpackEncodedStringToUnsignedChars(DFA<dfa.decisionNumber>_maxS);
|
||
|
static final short[] DFA<dfa.decisionNumber>_accept = DFA.unpackEncodedString(DFA<dfa.decisionNumber>_acceptS);
|
||
|
static final short[] DFA<dfa.decisionNumber>_special = DFA.unpackEncodedString(DFA<dfa.decisionNumber>_specialS);
|
||
|
static final short[][] DFA<dfa.decisionNumber>_transition;
|
||
|
|
||
|
static {
|
||
|
int numStates = DFA<dfa.decisionNumber>_transitionS.length;
|
||
|
DFA<dfa.decisionNumber>_transition = new short[numStates][];
|
||
|
for (int i=0; i\<numStates; i++) {
|
||
|
DFA<dfa.decisionNumber>_transition[i] = DFA.unpackEncodedString(DFA<dfa.decisionNumber>_transitionS[i]);
|
||
|
}
|
||
|
}
|
||
|
|
||
|
class DFA<dfa.decisionNumber> extends DFA {
|
||
|
|
||
|
public DFA<dfa.decisionNumber>(BaseRecognizer recognizer) {
|
||
|
this.recognizer = recognizer;
|
||
|
this.decisionNumber = <dfa.decisionNumber>;
|
||
|
this.eot = DFA<dfa.decisionNumber>_eot;
|
||
|
this.eof = DFA<dfa.decisionNumber>_eof;
|
||
|
this.min = DFA<dfa.decisionNumber>_min;
|
||
|
this.max = DFA<dfa.decisionNumber>_max;
|
||
|
this.accept = DFA<dfa.decisionNumber>_accept;
|
||
|
this.special = DFA<dfa.decisionNumber>_special;
|
||
|
this.transition = DFA<dfa.decisionNumber>_transition;
|
||
|
}
|
||
|
public String getDescription() {
|
||
|
return "<dfa.description>";
|
||
|
}
|
||
|
<@errorMethod()>
|
||
|
<if(dfa.specialStateSTs)>
|
||
|
public int specialStateTransition(int s, IntStream _input) throws NoViableAltException {
|
||
|
<if(LEXER)>
|
||
|
IntStream input = _input;
|
||
|
<endif>
|
||
|
<if(PARSER)>
|
||
|
TokenStream input = (TokenStream)_input;
|
||
|
<endif>
|
||
|
<if(TREE_PARSER)>
|
||
|
TreeNodeStream input = (TreeNodeStream)_input;
|
||
|
<endif>
|
||
|
int _s = s;
|
||
|
switch ( s ) {
|
||
|
<dfa.specialStateSTs:{state |
|
||
|
case <i0> : <! compressed special state numbers 0..n-1 !>
|
||
|
<state>}; separator="\n">
|
||
|
}
|
||
|
<if(backtracking)>
|
||
|
if (state.backtracking>0) {state.failed=true; return -1;}<\n>
|
||
|
<endif>
|
||
|
NoViableAltException nvae =
|
||
|
new NoViableAltException(getDescription(), <dfa.decisionNumber>, _s, input);
|
||
|
error(nvae);
|
||
|
throw nvae;
|
||
|
}<\n>
|
||
|
<endif>
|
||
|
}<\n>
|
||
|
>>
|
||
|
|
||
|
/** A state in a cyclic DFA; it's a special state and part of a big switch on
|
||
|
* state.
|
||
|
*/
|
||
|
cyclicDFAState(decisionNumber,stateNumber,edges,needErrorClause,semPredState) ::= <<
|
||
|
int LA<decisionNumber>_<stateNumber> = input.LA(1);<\n>
|
||
|
<if(semPredState)> <! get next lookahead symbol to test edges, then rewind !>
|
||
|
int index<decisionNumber>_<stateNumber> = input.index();
|
||
|
input.rewind();<\n>
|
||
|
<endif>
|
||
|
s = -1;
|
||
|
<edges; separator="\nelse ">
|
||
|
<if(semPredState)> <! return input cursor to state before we rewound !>
|
||
|
input.seek(index<decisionNumber>_<stateNumber>);<\n>
|
||
|
<endif>
|
||
|
if ( s>=0 ) return s;
|
||
|
break;
|
||
|
>>
|
||
|
|
||
|
/** Just like a fixed DFA edge, test the lookahead and indicate what
|
||
|
* state to jump to next if successful.
|
||
|
*/
|
||
|
cyclicDFAEdge(labelExpr, targetStateNumber, edgeNumber, predicates) ::= <<
|
||
|
if ( (<labelExpr>) <if(predicates)>&& (<predicates>)<endif>) {s = <targetStateNumber>;}<\n>
|
||
|
>>
|
||
|
|
||
|
/** An edge pointing at end-of-token; essentially matches any char;
|
||
|
* always jump to the target.
|
||
|
*/
|
||
|
eotDFAEdge(targetStateNumber,edgeNumber, predicates) ::= <<
|
||
|
s = <targetStateNumber>;<\n>
|
||
|
>>
|
||
|
|
||
|
|
||
|
// D F A E X P R E S S I O N S
|
||
|
|
||
|
andPredicates(left,right) ::= "(<left>&&<right>)"
|
||
|
|
||
|
orPredicates(operands) ::= "(<first(operands)><rest(operands):{o | ||<o>}>)"
|
||
|
|
||
|
notPredicate(pred) ::= "!(<evalPredicate(...)>)"
|
||
|
|
||
|
evalPredicate(pred,description) ::= "(<pred>)"
|
||
|
|
||
|
evalSynPredicate(pred,description) ::= "<pred>()"
|
||
|
|
||
|
lookaheadTest(atom,k,atomAsInt) ::= "LA<decisionNumber>_<stateNumber>==<atom>"
|
||
|
|
||
|
/** Sometimes a lookahead test cannot assume that LA(k) is in a temp variable
|
||
|
* somewhere. Must ask for the lookahead directly.
|
||
|
*/
|
||
|
isolatedLookaheadTest(atom,k,atomAsInt) ::= "input.LA(<k>)==<atom>"
|
||
|
|
||
|
lookaheadRangeTest(lower,upper,k,rangeNumber,lowerAsInt,upperAsInt) ::= <<
|
||
|
(LA<decisionNumber>_<stateNumber>\>=<lower> && LA<decisionNumber>_<stateNumber>\<=<upper>)
|
||
|
>>
|
||
|
|
||
|
isolatedLookaheadRangeTest(lower,upper,k,rangeNumber,lowerAsInt,upperAsInt) ::= "(input.LA(<k>)\>=<lower> && input.LA(<k>)\<=<upper>)"
|
||
|
|
||
|
setTest(ranges) ::= "<ranges; separator=\"||\">"
|
||
|
|
||
|
// A T T R I B U T E S
|
||
|
|
||
|
globalAttributeScope(scope) ::= <<
|
||
|
<if(scope.attributes)>
|
||
|
protected static class <scope.name>_scope {
|
||
|
<scope.attributes:{<it.decl>;}; separator="\n">
|
||
|
}
|
||
|
protected Stack <scope.name>_stack = new Stack();<\n>
|
||
|
<endif>
|
||
|
>>
|
||
|
|
||
|
ruleAttributeScope(scope) ::= <<
|
||
|
<if(scope.attributes)>
|
||
|
protected static class <scope.name>_scope {
|
||
|
<scope.attributes:{<it.decl>;}; separator="\n">
|
||
|
}
|
||
|
protected Stack <scope.name>_stack = new Stack();<\n>
|
||
|
<endif>
|
||
|
>>
|
||
|
|
||
|
returnStructName() ::= "<it.name>_return"
|
||
|
|
||
|
returnType() ::= <<
|
||
|
<if(ruleDescriptor.hasMultipleReturnValues)>
|
||
|
<ruleDescriptor.grammar.recognizerName>.<ruleDescriptor:returnStructName()>
|
||
|
<else>
|
||
|
<if(ruleDescriptor.hasSingleReturnValue)>
|
||
|
<ruleDescriptor.singleValueReturnType>
|
||
|
<else>
|
||
|
void
|
||
|
<endif>
|
||
|
<endif>
|
||
|
>>
|
||
|
|
||
|
/** Generate the Java type associated with a single or multiple return
|
||
|
* values.
|
||
|
*/
|
||
|
ruleLabelType(referencedRule) ::= <<
|
||
|
<if(referencedRule.hasMultipleReturnValues)>
|
||
|
<referencedRule.grammar.recognizerName>.<referencedRule.name>_return
|
||
|
<else>
|
||
|
<if(referencedRule.hasSingleReturnValue)>
|
||
|
<referencedRule.singleValueReturnType>
|
||
|
<else>
|
||
|
void
|
||
|
<endif>
|
||
|
<endif>
|
||
|
>>
|
||
|
|
||
|
delegateName() ::= <<
|
||
|
<if(it.label)><it.label><else>g<it.name><endif>
|
||
|
>>
|
||
|
|
||
|
/** Using a type to init value map, try to init a type; if not in table
|
||
|
* must be an object, default value is "null".
|
||
|
*/
|
||
|
initValue(typeName) ::= <<
|
||
|
<javaTypeInitMap.(typeName)>
|
||
|
>>
|
||
|
|
||
|
/** Define a rule label including default value */
|
||
|
ruleLabelDef(label) ::= <<
|
||
|
<ruleLabelType(referencedRule=label.referencedRule)> <label.label.text> = <initValue(typeName=ruleLabelType(referencedRule=label.referencedRule))>;<\n>
|
||
|
>>
|
||
|
|
||
|
/** Define a return struct for a rule if the code needs to access its
|
||
|
* start/stop tokens, tree stuff, attributes, ... Leave a hole for
|
||
|
* subgroups to stick in members.
|
||
|
*/
|
||
|
returnScope(scope) ::= <<
|
||
|
<if(ruleDescriptor.hasMultipleReturnValues)>
|
||
|
public static class <ruleDescriptor:returnStructName()> extends <if(TREE_PARSER)>Tree<else>Parser<endif>RuleReturnScope {
|
||
|
<scope.attributes:{public <it.decl>;}; separator="\n">
|
||
|
<@ruleReturnMembers()>
|
||
|
};
|
||
|
<endif>
|
||
|
>>
|
||
|
|
||
|
parameterScope(scope) ::= <<
|
||
|
<scope.attributes:{<it.decl>}; separator=", ">
|
||
|
>>
|
||
|
|
||
|
parameterAttributeRef(attr) ::= "<attr.name>"
|
||
|
parameterSetAttributeRef(attr,expr) ::= "<attr.name> =<expr>;"
|
||
|
|
||
|
scopeAttributeRef(scope,attr,index,negIndex) ::= <<
|
||
|
<if(negIndex)>
|
||
|
((<scope>_scope)<scope>_stack.elementAt(<scope>_stack.size()-<negIndex>-1)).<attr.name>
|
||
|
<else>
|
||
|
<if(index)>
|
||
|
((<scope>_scope)<scope>_stack.elementAt(<index>)).<attr.name>
|
||
|
<else>
|
||
|
((<scope>_scope)<scope>_stack.peek()).<attr.name>
|
||
|
<endif>
|
||
|
<endif>
|
||
|
>>
|
||
|
|
||
|
scopeSetAttributeRef(scope,attr,expr,index,negIndex) ::= <<
|
||
|
<if(negIndex)>
|
||
|
((<scope>_scope)<scope>_stack.elementAt(<scope>_stack.size()-<negIndex>-1)).<attr.name> =<expr>;
|
||
|
<else>
|
||
|
<if(index)>
|
||
|
((<scope>_scope)<scope>_stack.elementAt(<index>)).<attr.name> =<expr>;
|
||
|
<else>
|
||
|
((<scope>_scope)<scope>_stack.peek()).<attr.name> =<expr>;
|
||
|
<endif>
|
||
|
<endif>
|
||
|
>>
|
||
|
|
||
|
/** $x is either global scope or x is rule with dynamic scope; refers
|
||
|
* to stack itself not top of stack. This is useful for predicates
|
||
|
* like {$function.size()>0 && $function::name.equals("foo")}?
|
||
|
*/
|
||
|
isolatedDynamicScopeRef(scope) ::= "<scope>_stack"
|
||
|
|
||
|
/** reference an attribute of rule; might only have single return value */
|
||
|
ruleLabelRef(referencedRule,scope,attr) ::= <<
|
||
|
<if(referencedRule.hasMultipleReturnValues)>
|
||
|
(<scope>!=null?<scope>.<attr.name>:<initValue(attr.type)>)
|
||
|
<else>
|
||
|
<scope>
|
||
|
<endif>
|
||
|
>>
|
||
|
|
||
|
returnAttributeRef(ruleDescriptor,attr) ::= <<
|
||
|
<if(ruleDescriptor.hasMultipleReturnValues)>
|
||
|
retval.<attr.name>
|
||
|
<else>
|
||
|
<attr.name>
|
||
|
<endif>
|
||
|
>>
|
||
|
|
||
|
returnSetAttributeRef(ruleDescriptor,attr,expr) ::= <<
|
||
|
<if(ruleDescriptor.hasMultipleReturnValues)>
|
||
|
retval.<attr.name> =<expr>;
|
||
|
<else>
|
||
|
<attr.name> =<expr>;
|
||
|
<endif>
|
||
|
>>
|
||
|
|
||
|
/** How to translate $tokenLabel */
|
||
|
tokenLabelRef(label) ::= "<label>"
|
||
|
|
||
|
/** ids+=ID {$ids} or e+=expr {$e} */
|
||
|
listLabelRef(label) ::= "list_<label>"
|
||
|
|
||
|
|
||
|
// not sure the next are the right approach
|
||
|
|
||
|
tokenLabelPropertyRef_text(scope,attr) ::= "(<scope>!=null?<scope>.getText():null)"
|
||
|
tokenLabelPropertyRef_type(scope,attr) ::= "(<scope>!=null?<scope>.getType():0)"
|
||
|
tokenLabelPropertyRef_line(scope,attr) ::= "(<scope>!=null?<scope>.getLine():0)"
|
||
|
tokenLabelPropertyRef_pos(scope,attr) ::= "(<scope>!=null?<scope>.getCharPositionInLine():0)"
|
||
|
tokenLabelPropertyRef_channel(scope,attr) ::= "(<scope>!=null?<scope>.getChannel():0)"
|
||
|
tokenLabelPropertyRef_index(scope,attr) ::= "(<scope>!=null?<scope>.getTokenIndex():0)"
|
||
|
tokenLabelPropertyRef_tree(scope,attr) ::= "<scope>_tree"
|
||
|
tokenLabelPropertyRef_int(scope,attr) ::= "(<scope>!=null?Integer.valueOf(<scope>.getText()):0)"
|
||
|
|
||
|
ruleLabelPropertyRef_start(scope,attr) ::= "(<scope>!=null?((<labelType>)<scope>.start):null)"
|
||
|
ruleLabelPropertyRef_stop(scope,attr) ::= "(<scope>!=null?((<labelType>)<scope>.stop):null)"
|
||
|
ruleLabelPropertyRef_tree(scope,attr) ::= "(<scope>!=null?((<ASTLabelType>)<scope>.tree):null)"
|
||
|
ruleLabelPropertyRef_text(scope,attr) ::= <<
|
||
|
<if(TREE_PARSER)>
|
||
|
(<scope>!=null?(input.getTokenStream().toString(
|
||
|
input.getTreeAdaptor().getTokenStartIndex(<scope>.start),
|
||
|
input.getTreeAdaptor().getTokenStopIndex(<scope>.start))):null)
|
||
|
<else>
|
||
|
(<scope>!=null?input.toString(<scope>.start,<scope>.stop):null)
|
||
|
<endif>
|
||
|
>>
|
||
|
|
||
|
ruleLabelPropertyRef_st(scope,attr) ::= "(<scope>!=null?<scope>.st:null)"
|
||
|
|
||
|
/** Isolated $RULE ref ok in lexer as it's a Token */
|
||
|
lexerRuleLabel(label) ::= "<label>"
|
||
|
|
||
|
lexerRuleLabelPropertyRef_type(scope,attr) ::=
|
||
|
"(<scope>!=null?<scope>.getType():0)"
|
||
|
lexerRuleLabelPropertyRef_line(scope,attr) ::=
|
||
|
"(<scope>!=null?<scope>.getLine():0)"
|
||
|
lexerRuleLabelPropertyRef_pos(scope,attr) ::=
|
||
|
"(<scope>!=null?<scope>.getCharPositionInLine():-1)"
|
||
|
lexerRuleLabelPropertyRef_channel(scope,attr) ::=
|
||
|
"(<scope>!=null?<scope>.getChannel():0)"
|
||
|
lexerRuleLabelPropertyRef_index(scope,attr) ::=
|
||
|
"(<scope>!=null?<scope>.getTokenIndex():0)"
|
||
|
lexerRuleLabelPropertyRef_text(scope,attr) ::=
|
||
|
"(<scope>!=null?<scope>.getText():null)"
|
||
|
lexerRuleLabelPropertyRef_int(scope,attr) ::=
|
||
|
"(<scope>!=null?Integer.valueOf(<scope>.getText()):0)"
|
||
|
|
||
|
// Somebody may ref $template or $tree or $stop within a rule:
|
||
|
rulePropertyRef_start(scope,attr) ::= "((<labelType>)retval.start)"
|
||
|
rulePropertyRef_stop(scope,attr) ::= "((<labelType>)retval.stop)"
|
||
|
rulePropertyRef_tree(scope,attr) ::= "((<ASTLabelType>)retval.tree)"
|
||
|
rulePropertyRef_text(scope,attr) ::= <<
|
||
|
<if(TREE_PARSER)>
|
||
|
input.getTokenStream().toString(
|
||
|
input.getTreeAdaptor().getTokenStartIndex(retval.start),
|
||
|
input.getTreeAdaptor().getTokenStopIndex(retval.start))
|
||
|
<else>
|
||
|
input.toString(retval.start,input.LT(-1))
|
||
|
<endif>
|
||
|
>>
|
||
|
rulePropertyRef_st(scope,attr) ::= "retval.st"
|
||
|
|
||
|
lexerRulePropertyRef_text(scope,attr) ::= "getText()"
|
||
|
lexerRulePropertyRef_type(scope,attr) ::= "_type"
|
||
|
lexerRulePropertyRef_line(scope,attr) ::= "state.tokenStartLine"
|
||
|
lexerRulePropertyRef_pos(scope,attr) ::= "state.tokenStartCharPositionInLine"
|
||
|
lexerRulePropertyRef_index(scope,attr) ::= "-1" // undefined token index in lexer
|
||
|
lexerRulePropertyRef_channel(scope,attr) ::= "_channel"
|
||
|
lexerRulePropertyRef_start(scope,attr) ::= "state.tokenStartCharIndex"
|
||
|
lexerRulePropertyRef_stop(scope,attr) ::= "(getCharIndex()-1)"
|
||
|
lexerRulePropertyRef_int(scope,attr) ::= "Integer.valueOf(<scope>.getText())"
|
||
|
|
||
|
// setting $st and $tree is allowed in local rule. everything else
|
||
|
// is flagged as error
|
||
|
ruleSetPropertyRef_tree(scope,attr,expr) ::= "retval.tree =<expr>;"
|
||
|
ruleSetPropertyRef_st(scope,attr,expr) ::= "retval.st =<expr>;"
|
||
|
|
||
|
/** How to execute an action (only when not backtracking) */
|
||
|
execAction(action) ::= <<
|
||
|
<if(backtracking)>
|
||
|
<if(actions.(actionScope).synpredgate)>
|
||
|
if ( <actions.(actionScope).synpredgate> ) {
|
||
|
<action>
|
||
|
}
|
||
|
<else>
|
||
|
if ( state.backtracking==0 ) {
|
||
|
<action>
|
||
|
}
|
||
|
<endif>
|
||
|
<else>
|
||
|
<action>
|
||
|
<endif>
|
||
|
>>
|
||
|
|
||
|
/** How to always execute an action even when backtracking */
|
||
|
execForcedAction(action) ::= "<action>"
|
||
|
|
||
|
// M I S C (properties, etc...)
|
||
|
|
||
|
bitset(name, words64) ::= <<
|
||
|
public static final BitSet <name> = new BitSet(new long[]{<words64:{<it>L};separator=",">});<\n>
|
||
|
>>
|
||
|
|
||
|
codeFileExtension() ::= ".java"
|
||
|
|
||
|
true() ::= "true"
|
||
|
false() ::= "false"
|