/*
 * Copyright (c) 2012-2017 The ANTLR Project. All rights reserved.
 * Use of this file is governed by the BSD 3-clause license that
 * can be found in the LICENSE.txt file in the project root.
 */

package org.antlr.v4.runtime;

import org.antlr.v4.runtime.atn.ATN;
import org.antlr.v4.runtime.atn.ATNState;
import org.antlr.v4.runtime.atn.RuleTransition;
import org.antlr.v4.runtime.misc.IntervalSet;
import org.antlr.v4.runtime.misc.Pair;

This is the default implementation of ANTLRErrorStrategy used for error reporting and recovery in ANTLR parsers. /**
 * This is the default implementation of {@link ANTLRErrorStrategy} used for
 * error reporting and recovery in ANTLR parsers.
 */
public class DefaultErrorStrategy implements ANTLRErrorStrategy {
	
Indicates whether the error strategy is currently "recovering from an
error". This is used to suppress reporting multiple error messages while
attempting to recover from a detected syntax error.
See Also:
inErrorRecoveryMode/**
	 * Indicates whether the error strategy is currently "recovering from an
	 * error". This is used to suppress reporting multiple error messages while
	 * attempting to recover from a detected syntax error.
	 *
	 * @see #inErrorRecoveryMode
	 */
	protected boolean errorRecoveryMode = false;

	
The index into the input stream where the last error occurred.
	This is used to prevent infinite loops where an error is found
 but no token is consumed during recovery...another error is found,
 ad nauseum.  This is a failsafe mechanism to guarantee that at least
 one token/tree node is consumed for two errors.
/** The index into the input stream where the last error occurred.
	 * 	This is used to prevent infinite loops where an error is found
	 *  but no token is consumed during recovery...another error is found,
	 *  ad nauseum.  This is a failsafe mechanism to guarantee that at least
	 *  one token/tree node is consumed for two errors.
	 */
	protected int lastErrorIndex = -1;

	protected IntervalSet lastErrorStates;

	
This field is used to propagate information about the lookahead following
the previous match. Since prediction prefers completing the current rule
to error recovery efforts, error reporting may occur later than the
original point where it was discoverable. The original context is used to
compute the true expected sets as though the reporting occurred as early
as possible.
/**
	 * This field is used to propagate information about the lookahead following
	 * the previous match. Since prediction prefers completing the current rule
	 * to error recovery efforts, error reporting may occur later than the
	 * original point where it was discoverable. The original context is used to
	 * compute the true expected sets as though the reporting occurred as early
	 * as possible.
	 */
	protected ParserRuleContext nextTokensContext;

	
See Also:
nextTokensContext/**
	 * @see #nextTokensContext
	 */
	protected int nextTokensState;

	
{@inheritDoc}
The default implementation simply calls endErrorCondition to ensure that the handler is not in error recovery mode.
/**
	 * {@inheritDoc}
	 *
	 * <p>The default implementation simply calls {@link #endErrorCondition} to
	 * ensure that the handler is not in error recovery mode.</p>
	 */
	@Override
	public void reset(Parser recognizer) {
		endErrorCondition(recognizer);
	}

	
This method is called to enter error recovery mode when a recognition
exception is reported.
Params:
recognizer – the parser instance/**
	 * This method is called to enter error recovery mode when a recognition
	 * exception is reported.
	 *
	 * @param recognizer the parser instance
	 */
	protected void beginErrorCondition(Parser recognizer) {
		errorRecoveryMode = true;
	}

	
{@inheritDoc}
/**
	 * {@inheritDoc}
	 */
	@Override
	public boolean inErrorRecoveryMode(Parser recognizer) {
		return errorRecoveryMode;
	}

	
This method is called to leave error recovery mode after recovering from
a recognition exception.
Params:
recognizer – /**
	 * This method is called to leave error recovery mode after recovering from
	 * a recognition exception.
	 *
	 * @param recognizer
	 */
	protected void endErrorCondition(Parser recognizer) {
		errorRecoveryMode = false;
		lastErrorStates = null;
		lastErrorIndex = -1;
	}

	
{@inheritDoc}
The default implementation simply calls endErrorCondition.
/**
	 * {@inheritDoc}
	 *
	 * <p>The default implementation simply calls {@link #endErrorCondition}.</p>
	 */
	@Override
	public void reportMatch(Parser recognizer) {
		endErrorCondition(recognizer);
	}

	
{@inheritDoc}
The default implementation returns immediately if the handler is already in error recovery mode. Otherwise, it calls beginErrorCondition and dispatches the reporting task based on the runtime type of e according to the following table.

NoViableAltException: Dispatches the call to reportNoViableAlternative
InputMismatchException: Dispatches the call to reportInputMismatch
FailedPredicateException: Dispatches the call to reportFailedPredicate
All other types: calls Parser.notifyErrorListeners to report the exception

/**
	 * {@inheritDoc}
	 *
	 * <p>The default implementation returns immediately if the handler is already
	 * in error recovery mode. Otherwise, it calls {@link #beginErrorCondition}
	 * and dispatches the reporting task based on the runtime type of {@code e}
	 * according to the following table.</p>
	 *
	 * <ul>
	 * <li>{@link NoViableAltException}: Dispatches the call to
	 * {@link #reportNoViableAlternative}</li>
	 * <li>{@link InputMismatchException}: Dispatches the call to
	 * {@link #reportInputMismatch}</li>
	 * <li>{@link FailedPredicateException}: Dispatches the call to
	 * {@link #reportFailedPredicate}</li>
	 * <li>All other types: calls {@link Parser#notifyErrorListeners} to report
	 * the exception</li>
	 * </ul>
	 */
	@Override
	public void reportError(Parser recognizer,
							RecognitionException e)
	{
		// if we've already reported an error and have not matched a token
		// yet successfully, don't report any errors.
		if (inErrorRecoveryMode(recognizer)) {
//			System.err.print("[SPURIOUS] ");
			return; // don't report spurious errors
		}
		beginErrorCondition(recognizer);
		if ( e instanceof NoViableAltException ) {
			reportNoViableAlternative(recognizer, (NoViableAltException) e);
		}
		else if ( e instanceof InputMismatchException ) {
			reportInputMismatch(recognizer, (InputMismatchException)e);
		}
		else if ( e instanceof FailedPredicateException ) {
			reportFailedPredicate(recognizer, (FailedPredicateException)e);
		}
		else {
			System.err.println("unknown recognition error type: "+e.getClass().getName());
			recognizer.notifyErrorListeners(e.getOffendingToken(), e.getMessage(), e);
		}
	}

	
{@inheritDoc}
The default implementation resynchronizes the parser by consuming tokens
until we find one in the resynchronization set--loosely the set of tokens
that can follow the current rule.
/**
	 * {@inheritDoc}
	 *
	 * <p>The default implementation resynchronizes the parser by consuming tokens
	 * until we find one in the resynchronization set--loosely the set of tokens
	 * that can follow the current rule.</p>
	 */
	@Override
	public void recover(Parser recognizer, RecognitionException e) {
//		System.out.println("recover in "+recognizer.getRuleInvocationStack()+
//						   " index="+recognizer.getInputStream().index()+
//						   ", lastErrorIndex="+
//						   lastErrorIndex+
//						   ", states="+lastErrorStates);
		if ( lastErrorIndex==recognizer.getInputStream().index() &&
			lastErrorStates != null &&
			lastErrorStates.contains(recognizer.getState()) ) {
			// uh oh, another error at same token index and previously-visited
			// state in ATN; must be a case where LT(1) is in the recovery
			// token set so nothing got consumed. Consume a single token
			// at least to prevent an infinite loop; this is a failsafe.
//			System.err.println("seen error condition before index="+
//							   lastErrorIndex+", states="+lastErrorStates);
//			System.err.println("FAILSAFE consumes "+recognizer.getTokenNames()[recognizer.getInputStream().LA(1)]);
			recognizer.consume();
		}
		lastErrorIndex = recognizer.getInputStream().index();
		if ( lastErrorStates==null ) lastErrorStates = new IntervalSet();
		lastErrorStates.add(recognizer.getState());
		IntervalSet followSet = getErrorRecoverySet(recognizer);
		consumeUntil(recognizer, followSet);
	}

	
The default implementation of ANTLRErrorStrategy.sync makes sure that the current lookahead symbol is consistent with what were expecting at this point in the ATN. You can call this anytime but ANTLR only generates code to check before subrules/loops and each iteration. 
Implements Jim Idle's magic sync mechanism in closures and optional
subrules. E.g.,
a : sync ( stuff sync )* ;
sync : {consume to what can follow sync} ;
 At the start of a sub rule upon error, sync performs single token deletion, if possible. If it can't do that, it bails on the current rule and uses the default error recovery, which consumes until the resynchronization set of the current rule. 
If the sub rule is optional ((...)?, (...)*, or block with an empty alternative), then the expected set includes what follows the subrule.
During loop iteration, it consumes until it sees a token that can start a
sub rule or what follows loop. Yes, that is pretty aggressive. We opt to
stay in the loop as long as possible.
ORIGINS
Previous versions of ANTLR did a poor job of their recovery within loops.
A single mismatch token or missing token would force the parser to bail
out of the entire rules surrounding the loop. So, for rule
classDef : 'class' ID '{' member* '}'

input with an extra token between members would force the parser to
consume until it found the next class definition rather than the next
member definition of the current class.
This functionality cost a little bit of effort because the parser has to
compare token set at the start of the loop and at each iteration. If for
some reason speed is suffering for you, you can turn off this
functionality by simply overriding this method as a blank { }.
/**
	 * The default implementation of {@link ANTLRErrorStrategy#sync} makes sure
	 * that the current lookahead symbol is consistent with what were expecting
	 * at this point in the ATN. You can call this anytime but ANTLR only
	 * generates code to check before subrules/loops and each iteration.
	 *
	 * <p>Implements Jim Idle's magic sync mechanism in closures and optional
	 * subrules. E.g.,</p>
	 *
	 * <pre>
	 * a : sync ( stuff sync )* ;
	 * sync : {consume to what can follow sync} ;
	 * </pre>
	 *
	 * At the start of a sub rule upon error, {@link #sync} performs single
	 * token deletion, if possible. If it can't do that, it bails on the current
	 * rule and uses the default error recovery, which consumes until the
	 * resynchronization set of the current rule.
	 *
	 * <p>If the sub rule is optional ({@code (...)?}, {@code (...)*}, or block
	 * with an empty alternative), then the expected set includes what follows
	 * the subrule.</p>
	 *
	 * <p>During loop iteration, it consumes until it sees a token that can start a
	 * sub rule or what follows loop. Yes, that is pretty aggressive. We opt to
	 * stay in the loop as long as possible.</p>
	 *
	 * <p><strong>ORIGINS</strong></p>
	 *
	 * <p>Previous versions of ANTLR did a poor job of their recovery within loops.
	 * A single mismatch token or missing token would force the parser to bail
	 * out of the entire rules surrounding the loop. So, for rule</p>
	 *
	 * <pre>
	 * classDef : 'class' ID '{' member* '}'
	 * </pre>
	 *
	 * input with an extra token between members would force the parser to
	 * consume until it found the next class definition rather than the next
	 * member definition of the current class.
	 *
	 * <p>This functionality cost a little bit of effort because the parser has to
	 * compare token set at the start of the loop and at each iteration. If for
	 * some reason speed is suffering for you, you can turn off this
	 * functionality by simply overriding this method as a blank { }.</p>
	 */
	@Override
	public void sync(Parser recognizer) throws RecognitionException {
		ATNState s = recognizer.getInterpreter().atn.states.get(recognizer.getState());
//		System.err.println("sync @ "+s.stateNumber+"="+s.getClass().getSimpleName());
		// If already recovering, don't try to sync
		if (inErrorRecoveryMode(recognizer)) {
			return;
		}

        TokenStream tokens = recognizer.getInputStream();
        int la = tokens.LA(1);

        // try cheaper subset first; might get lucky. seems to shave a wee bit off
		IntervalSet nextTokens = recognizer.getATN().nextTokens(s);
		if (nextTokens.contains(la)) {
			// We are sure the token matches
			nextTokensContext = null;
			nextTokensState = ATNState.INVALID_STATE_NUMBER;
			return;
		}

		if (nextTokens.contains(Token.EPSILON)) {
			if (nextTokensContext == null) {
				// It's possible the next token won't match; information tracked
				// by sync is restricted for performance.
				nextTokensContext = recognizer.getContext();
				nextTokensState = recognizer.getState();
			}
			return;
		}

		switch (s.getStateType()) {
		case ATNState.BLOCK_START:
		case ATNState.STAR_BLOCK_START:
		case ATNState.PLUS_BLOCK_START:
		case ATNState.STAR_LOOP_ENTRY:
			// report error and recover if possible
			if ( singleTokenDeletion(recognizer)!=null ) {
				return;
			}

			throw new InputMismatchException(recognizer);

		case ATNState.PLUS_LOOP_BACK:
		case ATNState.STAR_LOOP_BACK:
//			System.err.println("at loop back: "+s.getClass().getSimpleName());
			reportUnwantedToken(recognizer);
			IntervalSet expecting = recognizer.getExpectedTokens();
			IntervalSet whatFollowsLoopIterationOrRule =
				expecting.or(getErrorRecoverySet(recognizer));
			consumeUntil(recognizer, whatFollowsLoopIterationOrRule);
			break;

		default:
			// do nothing if we can't identify the exact kind of ATN state
			break;
		}
	}

	
This is called by reportError when the exception is a NoViableAltException. 
Params:
recognizer – the parser instance
e – the recognition exception
See Also:
reportError/**
	 * This is called by {@link #reportError} when the exception is a
	 * {@link NoViableAltException}.
	 *
	 * @see #reportError
	 *
	 * @param recognizer the parser instance
	 * @param e the recognition exception
	 */
	protected void reportNoViableAlternative(Parser recognizer,
											 NoViableAltException e)
	{
		TokenStream tokens = recognizer.getInputStream();
		String input;
		if ( tokens!=null ) {
			if ( e.getStartToken().getType()==Token.EOF ) input = "<EOF>";
			else input = tokens.getText(e.getStartToken(), e.getOffendingToken());
		}
		else {
			input = "<unknown input>";
		}
		String msg = "no viable alternative at input "+escapeWSAndQuote(input);
		recognizer.notifyErrorListeners(e.getOffendingToken(), msg, e);
	}

	
This is called by reportError when the exception is an InputMismatchException. 
Params:
recognizer – the parser instance
e – the recognition exception
See Also:
reportError/**
	 * This is called by {@link #reportError} when the exception is an
	 * {@link InputMismatchException}.
	 *
	 * @see #reportError
	 *
	 * @param recognizer the parser instance
	 * @param e the recognition exception
	 */
	protected void reportInputMismatch(Parser recognizer,
									   InputMismatchException e)
	{
		String msg = "mismatched input "+getTokenErrorDisplay(e.getOffendingToken())+
		" expecting "+e.getExpectedTokens().toString(recognizer.getVocabulary());
		recognizer.notifyErrorListeners(e.getOffendingToken(), msg, e);
	}

	
This is called by reportError when the exception is a FailedPredicateException. 
Params:
recognizer – the parser instance
e – the recognition exception
See Also:
reportError/**
	 * This is called by {@link #reportError} when the exception is a
	 * {@link FailedPredicateException}.
	 *
	 * @see #reportError
	 *
	 * @param recognizer the parser instance
	 * @param e the recognition exception
	 */
	protected void reportFailedPredicate(Parser recognizer,
										 FailedPredicateException e)
	{
		String ruleName = recognizer.getRuleNames()[recognizer._ctx.getRuleIndex()];
		String msg = "rule "+ruleName+" "+e.getMessage();
		recognizer.notifyErrorListeners(e.getOffendingToken(), msg, e);
	}

	
This method is called to report a syntax error which requires the removal of a token from the input stream. At the time this method is called, the erroneous symbol is current LT(1) symbol and has not yet been removed from the input stream. When this method returns, recognizer is in error recovery mode. 
This method is called when singleTokenDeletion identifies single-token deletion as a viable recovery strategy for a mismatched input error.
The default implementation simply returns if the handler is already in error recovery mode. Otherwise, it calls beginErrorCondition to enter error recovery mode, followed by calling Parser.notifyErrorListeners.
Params:
recognizer – the parser instance/**
	 * This method is called to report a syntax error which requires the removal
	 * of a token from the input stream. At the time this method is called, the
	 * erroneous symbol is current {@code LT(1)} symbol and has not yet been
	 * removed from the input stream. When this method returns,
	 * {@code recognizer} is in error recovery mode.
	 *
	 * <p>This method is called when {@link #singleTokenDeletion} identifies
	 * single-token deletion as a viable recovery strategy for a mismatched
	 * input error.</p>
	 *
	 * <p>The default implementation simply returns if the handler is already in
	 * error recovery mode. Otherwise, it calls {@link #beginErrorCondition} to
	 * enter error recovery mode, followed by calling
	 * {@link Parser#notifyErrorListeners}.</p>
	 *
	 * @param recognizer the parser instance
	 */
	protected void reportUnwantedToken(Parser recognizer) {
		if (inErrorRecoveryMode(recognizer)) {
			return;
		}

		beginErrorCondition(recognizer);

		Token t = recognizer.getCurrentToken();
		String tokenName = getTokenErrorDisplay(t);
		IntervalSet expecting = getExpectedTokens(recognizer);
		String msg = "extraneous input "+tokenName+" expecting "+
			expecting.toString(recognizer.getVocabulary());
		recognizer.notifyErrorListeners(t, msg, null);
	}

	
This method is called to report a syntax error which requires the insertion of a missing token into the input stream. At the time this method is called, the missing token has not yet been inserted. When this method returns, recognizer is in error recovery mode. 
This method is called when singleTokenInsertion identifies single-token insertion as a viable recovery strategy for a mismatched input error.
The default implementation simply returns if the handler is already in error recovery mode. Otherwise, it calls beginErrorCondition to enter error recovery mode, followed by calling Parser.notifyErrorListeners.
Params:
recognizer – the parser instance/**
	 * This method is called to report a syntax error which requires the
	 * insertion of a missing token into the input stream. At the time this
	 * method is called, the missing token has not yet been inserted. When this
	 * method returns, {@code recognizer} is in error recovery mode.
	 *
	 * <p>This method is called when {@link #singleTokenInsertion} identifies
	 * single-token insertion as a viable recovery strategy for a mismatched
	 * input error.</p>
	 *
	 * <p>The default implementation simply returns if the handler is already in
	 * error recovery mode. Otherwise, it calls {@link #beginErrorCondition} to
	 * enter error recovery mode, followed by calling
	 * {@link Parser#notifyErrorListeners}.</p>
	 *
	 * @param recognizer the parser instance
	 */
	protected void reportMissingToken(Parser recognizer) {
		if (inErrorRecoveryMode(recognizer)) {
			return;
		}

		beginErrorCondition(recognizer);

		Token t = recognizer.getCurrentToken();
		IntervalSet expecting = getExpectedTokens(recognizer);
		String msg = "missing "+expecting.toString(recognizer.getVocabulary())+
			" at "+getTokenErrorDisplay(t);

		recognizer.notifyErrorListeners(t, msg, null);
	}

	
{@inheritDoc}
The default implementation attempts to recover from the mismatched input by using single token insertion and deletion as described below. If the recovery attempt fails, this method throws an InputMismatchException.
EXTRA TOKEN (single token deletion)
LA(1) is not what we are looking for. If LA(2) has the right token, however, then assume LA(1) is some extra spurious token and delete it. Then consume and return the next token (which was the LA(2) token) as the successful result of the match operation.
This recovery strategy is implemented by singleTokenDeletion.
MISSING TOKEN (single token insertion)
If current token (at LA(1)) is consistent with what could come after the expected LA(1) token, then assume the token is missing and use the parser's TokenFactory to create it on the fly. The "insertion" is performed by returning the created token as the successful result of the match operation.
This recovery strategy is implemented by singleTokenInsertion.
EXAMPLE
For example, Input i=(3; is clearly missing the ')'. When the parser returns from the nested call to expr, it will have call chain:
stat → expr → atom
 and it will be trying to match the ')' at this point in the derivation: 
=> ID '=' '(' INT ')' ('+' atom)* ';'
                   ^
 The attempt to match ')' will fail when it sees ';' and call recoverInline. To recover, it sees that LA(1)==';' is in the set of tokens that can follow the ')' token reference in rule atom. It can assume that you forgot the ')'. /**
	 * {@inheritDoc}
	 *
	 * <p>The default implementation attempts to recover from the mismatched input
	 * by using single token insertion and deletion as described below. If the
	 * recovery attempt fails, this method throws an
	 * {@link InputMismatchException}.</p>
	 *
	 * <p><strong>EXTRA TOKEN</strong> (single token deletion)</p>
	 *
	 * <p>{@code LA(1)} is not what we are looking for. If {@code LA(2)} has the
	 * right token, however, then assume {@code LA(1)} is some extra spurious
	 * token and delete it. Then consume and return the next token (which was
	 * the {@code LA(2)} token) as the successful result of the match operation.</p>
	 *
	 * <p>This recovery strategy is implemented by {@link #singleTokenDeletion}.</p>
	 *
	 * <p><strong>MISSING TOKEN</strong> (single token insertion)</p>
	 *
	 * <p>If current token (at {@code LA(1)}) is consistent with what could come
	 * after the expected {@code LA(1)} token, then assume the token is missing
	 * and use the parser's {@link TokenFactory} to create it on the fly. The
	 * "insertion" is performed by returning the created token as the successful
	 * result of the match operation.</p>
	 *
	 * <p>This recovery strategy is implemented by {@link #singleTokenInsertion}.</p>
	 *
	 * <p><strong>EXAMPLE</strong></p>
	 *
	 * <p>For example, Input {@code i=(3;} is clearly missing the {@code ')'}. When
	 * the parser returns from the nested call to {@code expr}, it will have
	 * call chain:</p>
	 *
	 * <pre>
	 * stat &rarr; expr &rarr; atom
	 * </pre>
	 *
	 * and it will be trying to match the {@code ')'} at this point in the
	 * derivation:
	 *
	 * <pre>
	 * =&gt; ID '=' '(' INT ')' ('+' atom)* ';'
	 *                    ^
	 * </pre>
	 *
	 * The attempt to match {@code ')'} will fail when it sees {@code ';'} and
	 * call {@link #recoverInline}. To recover, it sees that {@code LA(1)==';'}
	 * is in the set of tokens that can follow the {@code ')'} token reference
	 * in rule {@code atom}. It can assume that you forgot the {@code ')'}.
	 */
	@Override
	public Token recoverInline(Parser recognizer)
		throws RecognitionException
	{
		// SINGLE TOKEN DELETION
		Token matchedSymbol = singleTokenDeletion(recognizer);
		if ( matchedSymbol!=null ) {
			// we have deleted the extra token.
			// now, move past ttype token as if all were ok
			recognizer.consume();
			return matchedSymbol;
		}

		// SINGLE TOKEN INSERTION
		if ( singleTokenInsertion(recognizer) ) {
			return getMissingSymbol(recognizer);
		}

		// even that didn't work; must throw the exception
		InputMismatchException e;
		if (nextTokensContext == null) {
			e = new InputMismatchException(recognizer);
		} else {
			e = new InputMismatchException(recognizer, nextTokensState, nextTokensContext);
		}

		throw e;
	}

	
This method implements the single-token insertion inline error recovery strategy. It is called by recoverInline if the single-token deletion strategy fails to recover from the mismatched input. If this method returns true, recognizer will be in error recovery mode. 
This method determines whether or not single-token insertion is viable by checking if the LA(1) input symbol could be successfully matched if it were instead the LA(2) symbol. If this method returns true, the caller is responsible for creating and inserting a token with the correct type to produce this behavior.
Params:
recognizer – the parser instance
Returns:
true if single-token insertion is a viable recovery strategy for the current mismatched input, otherwise false/**
	 * This method implements the single-token insertion inline error recovery
	 * strategy. It is called by {@link #recoverInline} if the single-token
	 * deletion strategy fails to recover from the mismatched input. If this
	 * method returns {@code true}, {@code recognizer} will be in error recovery
	 * mode.
	 *
	 * <p>This method determines whether or not single-token insertion is viable by
	 * checking if the {@code LA(1)} input symbol could be successfully matched
	 * if it were instead the {@code LA(2)} symbol. If this method returns
	 * {@code true}, the caller is responsible for creating and inserting a
	 * token with the correct type to produce this behavior.</p>
	 *
	 * @param recognizer the parser instance
	 * @return {@code true} if single-token insertion is a viable recovery
	 * strategy for the current mismatched input, otherwise {@code false}
	 */
	protected boolean singleTokenInsertion(Parser recognizer) {
		int currentSymbolType = recognizer.getInputStream().LA(1);
		// if current token is consistent with what could come after current
		// ATN state, then we know we're missing a token; error recovery
		// is free to conjure up and insert the missing token
		ATNState currentState = recognizer.getInterpreter().atn.states.get(recognizer.getState());
		ATNState next = currentState.transition(0).target;
		ATN atn = recognizer.getInterpreter().atn;
		IntervalSet expectingAtLL2 = atn.nextTokens(next, recognizer._ctx);
//		System.out.println("LT(2) set="+expectingAtLL2.toString(recognizer.getTokenNames()));
		if ( expectingAtLL2.contains(currentSymbolType) ) {
			reportMissingToken(recognizer);
			return true;
		}
		return false;
	}

	
This method implements the single-token deletion inline error recovery strategy. It is called by recoverInline to attempt to recover from mismatched input. If this method returns null, the parser and error handler state will not have changed. If this method returns non-null, recognizer will not be in error recovery mode since the
returned token was a successful match.
If the single-token deletion is successful, this method calls reportUnwantedToken to report the error, followed by Parser.consume to actually "delete" the extraneous token. Then, before returning reportMatch is called to signal a successful match.
Params:
recognizer – the parser instance
Returns:
the successfully matched Token instance if single-token deletion successfully recovers from the mismatched input, otherwise null/**
	 * This method implements the single-token deletion inline error recovery
	 * strategy. It is called by {@link #recoverInline} to attempt to recover
	 * from mismatched input. If this method returns null, the parser and error
	 * handler state will not have changed. If this method returns non-null,
	 * {@code recognizer} will <em>not</em> be in error recovery mode since the
	 * returned token was a successful match.
	 *
	 * <p>If the single-token deletion is successful, this method calls
	 * {@link #reportUnwantedToken} to report the error, followed by
	 * {@link Parser#consume} to actually "delete" the extraneous token. Then,
	 * before returning {@link #reportMatch} is called to signal a successful
	 * match.</p>
	 *
	 * @param recognizer the parser instance
	 * @return the successfully matched {@link Token} instance if single-token
	 * deletion successfully recovers from the mismatched input, otherwise
	 * {@code null}
	 */
	protected Token singleTokenDeletion(Parser recognizer) {
		int nextTokenType = recognizer.getInputStream().LA(2);
		IntervalSet expecting = getExpectedTokens(recognizer);
		if ( expecting.contains(nextTokenType) ) {
			reportUnwantedToken(recognizer);
			/*
			System.err.println("recoverFromMismatchedToken deleting "+
							   ((TokenStream)recognizer.getInputStream()).LT(1)+
							   " since "+((TokenStream)recognizer.getInputStream()).LT(2)+
							   " is what we want");
			*/
			recognizer.consume(); // simply delete extra token
			// we want to return the token we're actually matching
			Token matchedSymbol = recognizer.getCurrentToken();
			reportMatch(recognizer);  // we know current token is correct
			return matchedSymbol;
		}
		return null;
	}

	
Conjure up a missing token during error recovery.
 The recognizer attempts to recover from single missing
 symbols. But, actions might refer to that missing symbol.
 For example, x=ID {f($x);}. The action clearly assumes
 that there has been an identifier matched previously and that
 $x points at that token. If that token is missing, but
 the next token in the stream is what we want we assume that
 this token is missing and we keep going. Because we
 have to return some token to replace the missing token,
 we have to conjure one up. This method gives the user control
 over the tokens returned for missing tokens. Mostly,
 you will want to create something special for identifier
 tokens. For literals such as '{' and ',', the default
 action in the parser or tree parser works. It simply creates
 a CommonToken of the appropriate type. The text will be the token.
 If you change what tokens must be created by the lexer,
 override this method to create the appropriate tokens.
/** Conjure up a missing token during error recovery.
	 *
	 *  The recognizer attempts to recover from single missing
	 *  symbols. But, actions might refer to that missing symbol.
	 *  For example, x=ID {f($x);}. The action clearly assumes
	 *  that there has been an identifier matched previously and that
	 *  $x points at that token. If that token is missing, but
	 *  the next token in the stream is what we want we assume that
	 *  this token is missing and we keep going. Because we
	 *  have to return some token to replace the missing token,
	 *  we have to conjure one up. This method gives the user control
	 *  over the tokens returned for missing tokens. Mostly,
	 *  you will want to create something special for identifier
	 *  tokens. For literals such as '{' and ',', the default
	 *  action in the parser or tree parser works. It simply creates
	 *  a CommonToken of the appropriate type. The text will be the token.
	 *  If you change what tokens must be created by the lexer,
	 *  override this method to create the appropriate tokens.
	 */
	protected Token getMissingSymbol(Parser recognizer) {
		Token currentSymbol = recognizer.getCurrentToken();
		IntervalSet expecting = getExpectedTokens(recognizer);
		int expectedTokenType = Token.INVALID_TYPE;
		if ( !expecting.isNil() ) {
			expectedTokenType = expecting.getMinElement(); // get any element
		}
		String tokenText;
		if ( expectedTokenType== Token.EOF ) tokenText = "<missing EOF>";
		else tokenText = "<missing "+recognizer.getVocabulary().getDisplayName(expectedTokenType)+">";
		Token current = currentSymbol;
		Token lookback = recognizer.getInputStream().LT(-1);
		if ( current.getType() == Token.EOF && lookback!=null ) {
			current = lookback;
		}
		return
			recognizer.getTokenFactory().create(new Pair<TokenSource, CharStream>(current.getTokenSource(), current.getTokenSource().getInputStream()), expectedTokenType, tokenText,
							Token.DEFAULT_CHANNEL,
							-1, -1,
							current.getLine(), current.getCharPositionInLine());
	}


	protected IntervalSet getExpectedTokens(Parser recognizer) {
		return recognizer.getExpectedTokens();
	}

	
How should a token be displayed in an error message? The default
 is to display just the text, but during development you might
 want to have a lot of information spit out.  Override in that case
 to use t.toString() (which, for CommonToken, dumps everything about
 the token). This is better than forcing you to override a method in
 your token objects because you don't have to go modify your lexer
 so that it creates a new Java type.
/** How should a token be displayed in an error message? The default
	 *  is to display just the text, but during development you might
	 *  want to have a lot of information spit out.  Override in that case
	 *  to use t.toString() (which, for CommonToken, dumps everything about
	 *  the token). This is better than forcing you to override a method in
	 *  your token objects because you don't have to go modify your lexer
	 *  so that it creates a new Java type.
	 */
	protected String getTokenErrorDisplay(Token t) {
		if ( t==null ) return "<no token>";
		String s = getSymbolText(t);
		if ( s==null ) {
			if ( getSymbolType(t)==Token.EOF ) {
				s = "<EOF>";
			}
			else {
				s = "<"+getSymbolType(t)+">";
			}
		}
		return escapeWSAndQuote(s);
	}

	protected String getSymbolText(Token symbol) {
		return symbol.getText();
	}

	protected int getSymbolType(Token symbol) {
		return symbol.getType();
	}


	protected String escapeWSAndQuote(String s) {
//		if ( s==null ) return s;
		s = s.replace("\n","\\n");
		s = s.replace("\r","\\r");
		s = s.replace("\t","\\t");
		return "'"+s+"'";
	}

	/*  Compute the error recovery set for the current rule.  During
	 *  rule invocation, the parser pushes the set of tokens that can
	 *  follow that rule reference on the stack; this amounts to
	 *  computing FIRST of what follows the rule reference in the
	 *  enclosing rule. See LinearApproximator.FIRST().
	 *  This local follow set only includes tokens
	 *  from within the rule; i.e., the FIRST computation done by
	 *  ANTLR stops at the end of a rule.
	 *
	 *  EXAMPLE
	 *
	 *  When you find a "no viable alt exception", the input is not
	 *  consistent with any of the alternatives for rule r.  The best
	 *  thing to do is to consume tokens until you see something that
	 *  can legally follow a call to r *or* any rule that called r.
	 *  You don't want the exact set of viable next tokens because the
	 *  input might just be missing a token--you might consume the
	 *  rest of the input looking for one of the missing tokens.
	 *
	 *  Consider grammar:
	 *
	 *  a : '[' b ']'
	 *    | '(' b ')'
	 *    ;
	 *  b : c '^' INT ;
	 *  c : ID
	 *    | INT
	 *    ;
	 *
	 *  At each rule invocation, the set of tokens that could follow
	 *  that rule is pushed on a stack.  Here are the various
	 *  context-sensitive follow sets:
	 *
	 *  FOLLOW(b1_in_a) = FIRST(']') = ']'
	 *  FOLLOW(b2_in_a) = FIRST(')') = ')'
	 *  FOLLOW(c_in_b) = FIRST('^') = '^'
	 *
	 *  Upon erroneous input "[]", the call chain is
	 *
	 *  a -> b -> c
	 *
	 *  and, hence, the follow context stack is:
	 *
	 *  depth     follow set       start of rule execution
	 *    0         <EOF>                    a (from main())
	 *    1          ']'                     b
	 *    2          '^'                     c
	 *
	 *  Notice that ')' is not included, because b would have to have
	 *  been called from a different context in rule a for ')' to be
	 *  included.
	 *
	 *  For error recovery, we cannot consider FOLLOW(c)
	 *  (context-sensitive or otherwise).  We need the combined set of
	 *  all context-sensitive FOLLOW sets--the set of all tokens that
	 *  could follow any reference in the call chain.  We need to
	 *  resync to one of those tokens.  Note that FOLLOW(c)='^' and if
	 *  we resync'd to that token, we'd consume until EOF.  We need to
	 *  sync to context-sensitive FOLLOWs for a, b, and c: {']','^'}.
	 *  In this case, for input "[]", LA(1) is ']' and in the set, so we would
	 *  not consume anything. After printing an error, rule c would
	 *  return normally.  Rule b would not find the required '^' though.
	 *  At this point, it gets a mismatched token error and throws an
	 *  exception (since LA(1) is not in the viable following token
	 *  set).  The rule exception handler tries to recover, but finds
	 *  the same recovery set and doesn't consume anything.  Rule b
	 *  exits normally returning to rule a.  Now it finds the ']' (and
	 *  with the successful match exits errorRecovery mode).
	 *
	 *  So, you can see that the parser walks up the call chain looking
	 *  for the token that was a member of the recovery set.
	 *
	 *  Errors are not generated in errorRecovery mode.
	 *
	 *  ANTLR's error recovery mechanism is based upon original ideas:
	 *
	 *  "Algorithms + Data Structures = Programs" by Niklaus Wirth
	 *
	 *  and
	 *
	 *  "A note on error recovery in recursive descent parsers":
	 *  http://portal.acm.org/citation.cfm?id=947902.947905
	 *
	 *  Later, Josef Grosch had some good ideas:
	 *
	 *  "Efficient and Comfortable Error Recovery in Recursive Descent
	 *  Parsers":
	 *  ftp://www.cocolab.com/products/cocktail/doca4.ps/ell.ps.zip
	 *
	 *  Like Grosch I implement context-sensitive FOLLOW sets that are combined
	 *  at run-time upon error to avoid overhead during parsing.
	 */
	protected IntervalSet getErrorRecoverySet(Parser recognizer) {
		ATN atn = recognizer.getInterpreter().atn;
		RuleContext ctx = recognizer._ctx;
		IntervalSet recoverSet = new IntervalSet();
		while ( ctx!=null && ctx.invokingState>=0 ) {
			// compute what follows who invoked us
			ATNState invokingState = atn.states.get(ctx.invokingState);
			RuleTransition rt = (RuleTransition)invokingState.transition(0);
			IntervalSet follow = atn.nextTokens(rt.followState);
			recoverSet.addAll(follow);
			ctx = ctx.parent;
		}
        recoverSet.remove(Token.EPSILON);
//		System.out.println("recover set "+recoverSet.toString(recognizer.getTokenNames()));
		return recoverSet;
	}

	
Consume tokens until one matches the given token set. /** Consume tokens until one matches the given token set. */
	protected void consumeUntil(Parser recognizer, IntervalSet set) {
//		System.err.println("consumeUntil("+set.toString(recognizer.getTokenNames())+")");
		int ttype = recognizer.getInputStream().LA(1);
		while (ttype != Token.EOF && !set.contains(ttype) ) {
            //System.out.println("consume during recover LA(1)="+getTokenNames()[input.LA(1)]);
//			recognizer.getInputStream().consume();
            recognizer.consume();
            ttype = recognizer.getInputStream().LA(1);
        }
    }
}