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package persistence.antlr;

/* ANTLR Translator Generator
 * Project led by Terence Parr at http://www.jGuru.com
 * Software rights: http://www.antlr.org/license.html
 *
 */

import persistence.antlr.collections.impl.BitSet;
import persistence.antlr.collections.impl.Vector;

/**This object holds all information needed to represent
 * the lookahead for any particular lookahead computation
 * for a single lookahead depth.  Final lookahead
 * information is a simple bit set, but intermediate
 * stages need computation cycle and FOLLOW information.
 *
 * 

* Concerning the cycle variable. * If lookahead is computed for a RuleEnd node, then * computation is part of a FOLLOW cycle for this rule. * If lookahead is computed for a RuleBlock node, the * computation is part of a FIRST cycle to this rule. * *

* Concerning the epsilonDepth variable. * This is not the depth relative to the rule reference * that epsilon was encountered. That value is *

 * 		initial_k - epsilonDepth + 1
 * 
* Also, lookahead depths past rule ref for local follow are: *
 * 		initial_k - (initial_k - epsilonDepth)
 * 
* Used for rule references. If we try * to compute look(k, ruleref) and there are fewer * than k lookahead terminals before the end of the * the rule, epsilon will be returned (don't want to * pass the end of the rule). We must track when the * the lookahead got stuck. For example, *
 * 		a : b A B E F G;
 * 		b : C ;
 * 
* LOOK(5, ref-to(b)) is {} with depth = 4, which * indicates that at 2 (5-4+1) tokens ahead, end of rule was reached. * Therefore, the token at 4=5-(5-4) past rule ref b must be * included in the set == F. * The situation is complicated by the fact that a computation * may hit the end of a rule at many different depths. For example, *
 * 		a : b A B C ;
 * 		b : E F		// epsilon depth of 1 relative to initial k=3
 * 		  | G		// epsilon depth of 2
 * 		  ;
 * 
* Here, LOOK(3,ref-to(b)) returns epsilon, but the depths are * {1, 2}; i.e., 3-(3-1) and 3-(3-2). Those are the lookahead depths * past the rule ref needed for the local follow. * *

* This is null unless an epsilon is created. * * @see persistence.antlr.Lookahead#combineWith(Lookahead) */ public class Lookahead implements Cloneable { /** actual bitset of the lookahead */ BitSet fset; /** is this computation part of a computation cycle? */ String cycle; /** What k values were being computed when end of rule hit? */ BitSet epsilonDepth; /** Does this lookahead depth include Epsilon token type? This * is used to avoid having a bit in the set for Epsilon as it * conflicts with parsing binary files. */ boolean hasEpsilon = false; public Lookahead() { fset = new BitSet(); } /** create a new lookahead set with the LL(1) set to the parameter */ public Lookahead(BitSet p) { fset = p; } /** create an empty lookahead set, but with cycle */ public Lookahead(String c) { this(); cycle = c; } /** Make a deep copy of everything in this object */ public Object clone() { Lookahead p = null; try { p = (Lookahead)super.clone(); p.fset = (BitSet)fset.clone(); p.cycle = cycle; // strings are immutable if (epsilonDepth != null) { p.epsilonDepth = (BitSet)epsilonDepth.clone(); } } catch (CloneNotSupportedException e) { throw new InternalError(); } return p; } public void combineWith(Lookahead q) { if (cycle == null) { // track at least one cycle cycle = q.cycle; } if (q.containsEpsilon()) { hasEpsilon = true; } // combine epsilon depths if (epsilonDepth != null) { if (q.epsilonDepth != null) { epsilonDepth.orInPlace(q.epsilonDepth); } } else if (q.epsilonDepth != null) { epsilonDepth = (BitSet)q.epsilonDepth.clone(); } fset.orInPlace(q.fset); } public boolean containsEpsilon() { return hasEpsilon; } /** What is the intersection of two lookahead depths? * Only the Epsilon "bit" and bitset are considered. */ public Lookahead intersection(Lookahead q) { Lookahead p = new Lookahead(fset.and(q.fset)); if (this.hasEpsilon && q.hasEpsilon) { p.setEpsilon(); } return p; } public boolean nil() { return fset.nil() && !hasEpsilon; } public static Lookahead of(int el) { Lookahead look = new Lookahead(); look.fset.add(el); return look; } public void resetEpsilon() { hasEpsilon = false; } public void setEpsilon() { hasEpsilon = true; } public String toString() { String e = "",b,f = "",d = ""; b = fset.toString(","); if (containsEpsilon()) { e = "+"; } if (cycle != null) { f = "; FOLLOW(" + cycle + ")"; } if (epsilonDepth != null) { d = "; depths=" + epsilonDepth.toString(","); } return b + e + f + d; } public String toString(String separator, CharFormatter formatter) { String e = "",b,f = "",d = ""; b = fset.toString(separator, formatter); if (containsEpsilon()) { e = "+"; } if (cycle != null) { f = "; FOLLOW(" + cycle + ")"; } if (epsilonDepth != null) { d = "; depths=" + epsilonDepth.toString(","); } return b + e + f + d; } public String toString(String separator, CharFormatter formatter, Grammar g) { if (g instanceof LexerGrammar) { return toString(separator, formatter); } else { return toString(separator, g.tokenManager.getVocabulary()); } } public String toString(String separator, Vector vocab) { String b,f = "",d = ""; b = fset.toString(separator, vocab); if (cycle != null) { f = "; FOLLOW(" + cycle + ")"; } if (epsilonDepth != null) { d = "; depths=" + epsilonDepth.toString(","); } return b + f + d; } }





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