/*******************************************************************************
* Copyright (c) 2009-2011 CWI
* All rights reserved. This program and the accompanying materials
* are made available under the terms of the Eclipse Public License v1.0
* which accompanies this distribution, and is available at
* http://www.eclipse.org/legal/epl-v10.html
*
* Contributors:
* * Arnold Lankamp - Arnold.Lankamp@cwi.nl
*******************************************************************************/
package org.rascalmpl.test.parser;
import java.io.IOException;
import java.io.StringReader;
import org.rascalmpl.parser.gtd.SGTDBF;
import org.rascalmpl.parser.gtd.result.out.DefaultNodeFlattener;
import org.rascalmpl.parser.gtd.stack.AbstractStackNode;
import org.rascalmpl.parser.gtd.stack.ListStackNode;
import org.rascalmpl.parser.gtd.stack.LiteralStackNode;
import org.rascalmpl.parser.gtd.stack.NonTerminalStackNode;
import org.rascalmpl.parser.uptr.UPTRNodeFactory;
import org.rascalmpl.value.IConstructor;
import org.rascalmpl.value.ISourceLocation;
import org.rascalmpl.value.IValue;
import org.rascalmpl.value.io.StandardTextReader;
import org.rascalmpl.values.ValueFactoryFactory;
import org.rascalmpl.values.uptr.ITree;
import org.rascalmpl.values.uptr.RascalValueFactory;
/*
* S ::= A*B*A*
* A ::= a
* B ::= b
*/
@SuppressWarnings({"unchecked", "cast"})
public class ListOverlap extends SGTDBF<IConstructor, ITree, ISourceLocation> implements IParserTest{
private final static IConstructor SYMBOL_START_S = VF.constructor(RascalValueFactory.Symbol_Sort, VF.string("S"));
private final static IConstructor SYMBOL_A = VF.constructor(RascalValueFactory.Symbol_Sort, VF.string("A"));
private final static IConstructor SYMBOL_B = VF.constructor(RascalValueFactory.Symbol_Sort, VF.string("B"));
private final static IConstructor SYMBOL_STAR_LIST_A = VF.constructor(RascalValueFactory.Symbol_IterStar, SYMBOL_A);
private final static IConstructor SYMBOL_STAR_LIST_B = VF.constructor(RascalValueFactory.Symbol_IterStar, SYMBOL_B);
private final static IConstructor SYMBOL_b = VF.constructor(RascalValueFactory.Symbol_Lit, VF.string("b"));
private final static IConstructor SYMBOL_a = VF.constructor(RascalValueFactory.Symbol_Lit, VF.string("a"));
private final static IConstructor SYMBOL_char_a = VF.constructor(RascalValueFactory.Symbol_CharClass, VF.list(VF.constructor(RascalValueFactory.CharRange_Single, VF.integer(97))));
private final static IConstructor SYMBOL_char_b = VF.constructor(RascalValueFactory.Symbol_CharClass, VF.list(VF.constructor(RascalValueFactory.CharRange_Single, VF.integer(98))));
private final static IConstructor PROD_S_STARLISTASTARLISTBSTARLISTA = VF.constructor(RascalValueFactory.Production_Default, SYMBOL_START_S, VF.list(SYMBOL_STAR_LIST_A, SYMBOL_STAR_LIST_B, SYMBOL_STAR_LIST_A), VF.set());
private final static IConstructor PROD_STARLISTA = VF.constructor(RascalValueFactory.Production_Regular, SYMBOL_STAR_LIST_A);
private final static IConstructor PROD_STARLISTB = VF.constructor(RascalValueFactory.Production_Regular, SYMBOL_STAR_LIST_B);
private final static IConstructor PROD_A_a = VF.constructor(RascalValueFactory.Production_Default, SYMBOL_A, VF.list(SYMBOL_a), VF.set());
private final static IConstructor PROD_B_b = VF.constructor(RascalValueFactory.Production_Default, SYMBOL_B, VF.list(SYMBOL_b), VF.set());
private final static IConstructor PROD_a_a = VF.constructor(RascalValueFactory.Production_Default, SYMBOL_a, VF.list(SYMBOL_char_a), VF.set());
private final static IConstructor PROD_b_b = VF.constructor(RascalValueFactory.Production_Default, SYMBOL_b, VF.list(SYMBOL_char_b), VF.set());
private final static AbstractStackNode<IConstructor> NONTERMINAL_START_S = new NonTerminalStackNode<IConstructor>(AbstractStackNode.START_SYMBOL_ID, 0, "S");
private final static AbstractStackNode<IConstructor> NONTERMINAL_A0 = new NonTerminalStackNode<IConstructor>(0, 0, "A");
private final static AbstractStackNode<IConstructor> NONTERMINAL_B1 = new NonTerminalStackNode<IConstructor>(1, 0, "B");
private final static AbstractStackNode<IConstructor> NONTERMINAL_A2 = new NonTerminalStackNode<IConstructor>(2, 0, "A");
private final static AbstractStackNode<IConstructor>[] S_EXPECT_1 = (AbstractStackNode<IConstructor>[]) new AbstractStackNode[3];
static{
S_EXPECT_1[0] = new ListStackNode<IConstructor>(3, 0, PROD_STARLISTA, NONTERMINAL_A0, false);
S_EXPECT_1[0].setProduction(S_EXPECT_1);
S_EXPECT_1[1] = new ListStackNode<IConstructor>(4, 1, PROD_STARLISTB, NONTERMINAL_B1, false);
S_EXPECT_1[1].setProduction(S_EXPECT_1);
S_EXPECT_1[2] = new ListStackNode<IConstructor>(5, 2, PROD_STARLISTA, NONTERMINAL_A2, false);
S_EXPECT_1[2].setProduction(S_EXPECT_1);
S_EXPECT_1[2].setAlternativeProduction(PROD_S_STARLISTASTARLISTBSTARLISTA);
}
private final static AbstractStackNode<IConstructor>[] A_EXPECT_1 = (AbstractStackNode<IConstructor>[]) new AbstractStackNode[1];
static{
A_EXPECT_1[0] = new LiteralStackNode<IConstructor>(6, 0, PROD_a_a, new int[]{'a'});
A_EXPECT_1[0].setProduction(A_EXPECT_1);
A_EXPECT_1[0].setAlternativeProduction(PROD_A_a);
}
private final static AbstractStackNode<IConstructor>[] B_EXPECT_1 = (AbstractStackNode<IConstructor>[]) new AbstractStackNode[1];
static{
B_EXPECT_1[0] = new LiteralStackNode<IConstructor>(7, 0, PROD_b_b, new int[]{'b'});
B_EXPECT_1[0].setProduction(B_EXPECT_1);
B_EXPECT_1[0].setAlternativeProduction(PROD_B_b);
}
public ListOverlap(){
super();
}
public AbstractStackNode<IConstructor>[] S(){
return (AbstractStackNode<IConstructor>[]) new AbstractStackNode[]{S_EXPECT_1[0]};
}
public AbstractStackNode<IConstructor>[] A(){
return (AbstractStackNode<IConstructor>[]) new AbstractStackNode[]{A_EXPECT_1[0]};
}
public AbstractStackNode<IConstructor>[] B(){
return (AbstractStackNode<IConstructor>[]) new AbstractStackNode[]{B_EXPECT_1[0]};
}
public ITree executeParser(){
return parse(NONTERMINAL_START_S, null, "aab".toCharArray(), new DefaultNodeFlattener<IConstructor, ITree, ISourceLocation>(), new UPTRNodeFactory(true));
}
public IValue getExpectedResult() throws IOException{
String expectedInput = "appl(prod(sort(\"S\"),[\\iter-star(sort(\"A\")),\\iter-star(sort(\"B\")),\\iter-star(sort(\"A\"))],{}),[appl(regular(\\iter-star(sort(\"A\"))),[appl(prod(sort(\"A\"),[lit(\"a\")],{}),[appl(prod(lit(\"a\"),[\\char-class([single(97)])],{}),[char(97)])]),appl(prod(sort(\"A\"),[lit(\"a\")],{}),[appl(prod(lit(\"a\"),[\\char-class([single(97)])],{}),[char(97)])])]),appl(regular(\\iter-star(sort(\"B\"))),[appl(prod(sort(\"B\"),[lit(\"b\")],{}),[appl(prod(lit(\"b\"),[\\char-class([single(98)])],{}),[char(98)])])]),appl(regular(\\iter-star(sort(\"A\"))),[])])";
return new StandardTextReader().read(ValueFactoryFactory.getValueFactory(), RascalValueFactory.uptr, RascalValueFactory.Tree, new StringReader(expectedInput));
}
public static void main(String[] args){
ListOverlap lo = new ListOverlap();
IConstructor result = lo.executeParser();
System.out.println(result);
System.out.println("S(A*(A(a),A(a)),B*(B(b)),A*()) <- good");
}
}