--- /dev/null
+/*******************************************************************************
+ * Copyright (c) 2000, 2004 IBM Corporation and others.
+ * All rights reserved. This program and the accompanying materials
+ * are made available under the terms of the Common Public License v1.0
+ * which accompanies this distribution, and is available at
+ * http://www.eclipse.org/legal/cpl-v10.html
+ *
+ * Contributors:
+ * IBM Corporation - initial API and implementation
+ *******************************************************************************/
+package org.eclipse.jdt.internal.compiler.parser.diagnose;
+
+import org.eclipse.jdt.core.compiler.CharOperation;
+import org.eclipse.jdt.internal.compiler.parser.Parser;
+import org.eclipse.jdt.internal.compiler.parser.ParserBasicInformation;
+import org.eclipse.jdt.internal.compiler.parser.TerminalTokens;
+import org.eclipse.jdt.internal.compiler.problem.ProblemReporter;
+
+public class DiagnoseParser implements ParserBasicInformation, TerminalTokens {
+ private static final boolean DEBUG = false;
+
+ private static final String EMPTY_STRING = ""; //$NON-NLS-1$
+ private static final int STACK_INCREMENT = 256;
+
+// private static final int ERROR_CODE = 1;
+ private static final int BEFORE_CODE = 2;
+ private static final int INSERTION_CODE = 3;
+ private static final int INVALID_CODE = 4;
+ private static final int SUBSTITUTION_CODE = 5;
+ private static final int DELETION_CODE = 6;
+ private static final int MERGE_CODE = 7;
+ private static final int MISPLACED_CODE = 8;
+ private static final int SCOPE_CODE = 9;
+ private static final int SECONDARY_CODE = 10;
+ private static final int EOF_CODE = 11;
+
+ private static final int BUFF_UBOUND = 31;
+ private static final int BUFF_SIZE = 32;
+ private static final int MAX_DISTANCE = 30;
+ private static final int MIN_DISTANCE = 3;
+
+ private LexStream lexStream;
+ private int errorToken;
+ private int errorTokenStart;
+
+ private int currentToken = 0;
+
+ private int stackLength;
+ private int stateStackTop;
+ private int[] stack;
+
+ private int[] locationStack;
+ private int[] locationStartStack;
+
+ private int tempStackTop;
+ private int[] tempStack;
+
+ private int prevStackTop;
+ private int[] prevStack;
+ private int nextStackTop;
+ private int[] nextStack;
+
+ private int scopeStackTop;
+ private int[] scopeIndex;
+ private int[] scopePosition;
+
+ int[] list = new int[NUM_SYMBOLS + 1];
+ int[] buffer = new int[BUFF_SIZE];
+
+ private static final int NIL = -1;
+ int[] stateSeen;
+
+ int statePoolTop;
+ StateInfo[] statePool;
+
+ private Parser parser;
+
+ private class RepairCandidate {
+ public int symbol;
+ public int location;
+
+ public RepairCandidate(){
+ this.symbol = 0;
+ this.location = 0;
+ }
+ }
+
+ private class PrimaryRepairInfo {
+ public int distance;
+ public int misspellIndex;
+ public int code;
+ public int bufferPosition;
+ public int symbol;
+
+ public PrimaryRepairInfo(){
+ this.distance = 0;
+ this.misspellIndex = 0;
+ this.code = 0;
+ this.bufferPosition = 0;
+ this.symbol = 0;
+ }
+
+ public PrimaryRepairInfo copy(){
+ PrimaryRepairInfo c = new PrimaryRepairInfo();
+ c.distance = this.distance;
+ c.misspellIndex = this.misspellIndex;
+ c.code = this.code;
+ c.bufferPosition = this .bufferPosition;
+ c.symbol = this.symbol;
+ return c;
+
+ }
+ }
+
+ private class SecondaryRepairInfo {
+ public int code;
+ public int distance;
+ public int bufferPosition;
+ public int stackPosition;
+ public int numDeletions;
+ public int symbol;
+
+ boolean recoveryOnNextStack;
+ }
+
+ private class StateInfo {
+ int state;
+ int next;
+
+ public StateInfo(int state, int next){
+ this.state = state;
+ this.next = next;
+ }
+ }
+
+ public DiagnoseParser(Parser parser, int firstToken, int start, int end) {
+ this(parser, firstToken, start, end, new int[0], new int[0], new int[0]);
+ }
+
+ public DiagnoseParser(Parser parser, int firstToken, int start, int end, int[] intervalStartToSkip, int[] intervalEndToSkip, int[] intervalFlagsToSkip) {
+ this.parser = parser;
+ this.lexStream = new LexStream(BUFF_SIZE, parser.scanner, intervalStartToSkip, intervalEndToSkip, intervalFlagsToSkip, firstToken, start, end);
+ }
+
+ private ProblemReporter problemReporter(){
+ return parser.problemReporter();
+ }
+
+ private void reallocateStacks() {
+ int old_stack_length = stackLength;
+
+ stackLength += STACK_INCREMENT;
+
+ if(old_stack_length == 0){
+ stack = new int[stackLength];
+ locationStack = new int[stackLength];
+ locationStartStack = new int[stackLength];
+ tempStack = new int[stackLength];
+ prevStack = new int[stackLength];
+ nextStack = new int[stackLength];
+ scopeIndex = new int[stackLength];
+ scopePosition = new int[stackLength];
+ } else {
+ System.arraycopy(stack, 0, stack = new int[stackLength], 0, old_stack_length);
+ System.arraycopy(locationStack, 0, locationStack = new int[stackLength], 0, old_stack_length);
+ System.arraycopy(locationStartStack, 0, locationStartStack = new int[stackLength], 0, old_stack_length);
+ System.arraycopy(tempStack, 0, tempStack = new int[stackLength], 0, old_stack_length);
+ System.arraycopy(prevStack, 0, prevStack = new int[stackLength], 0, old_stack_length);
+ System.arraycopy(nextStack, 0, nextStack = new int[stackLength], 0, old_stack_length);
+ System.arraycopy(scopeIndex, 0, scopeIndex = new int[stackLength], 0, old_stack_length);
+ System.arraycopy(scopePosition, 0, scopePosition = new int[stackLength], 0, old_stack_length);
+ }
+ return;
+ }
+
+
+ public void diagnoseParse() {
+ lexStream.reset();
+
+ currentToken = lexStream.getToken();
+
+ int prev_pos;
+ int pos;
+ int next_pos;
+ int act = START_STATE;
+
+ reallocateStacks();
+
+ //
+ // Start parsing
+ //
+ stateStackTop = 0;
+ stack[stateStackTop] = act;
+
+ int tok = lexStream.kind(currentToken);
+ locationStack[stateStackTop] = currentToken;
+ locationStartStack[stateStackTop] = lexStream.start(currentToken);
+
+ boolean forceRecoveryAfterLBracketMissing = false;
+// int forceRecoveryToken = -1;
+
+ //
+ // Process a terminal
+ //
+ do {
+ //
+ // Synchronize state stacks and update the location stack
+ //
+ prev_pos = -1;
+ prevStackTop = -1;
+
+ next_pos = -1;
+ nextStackTop = -1;
+
+ pos = stateStackTop;
+ tempStackTop = stateStackTop - 1;
+ for (int i = 0; i <= stateStackTop; i++)
+ tempStack[i] = stack[i];
+
+ act = Parser.tAction(act, tok);
+ //
+ // When a reduce action is encountered, we compute all REDUCE
+ // and associated goto actions induced by the current token.
+ // Eventually, a SHIFT, SHIFT-REDUCE, ACCEPT or ERROR action is
+ // computed...
+ //
+ while (act <= NUM_RULES) {
+ do {
+ tempStackTop -= (Parser.rhs[act]-1);
+ act = Parser.ntAction(tempStack[tempStackTop], Parser.lhs[act]);
+ } while(act <= NUM_RULES);
+ //
+ // ... Update the maximum useful position of the
+ // (STATE_)STACK, push goto state into stack, and
+ // compute next action on current symbol ...
+ //
+ if (tempStackTop + 1 >= stackLength)
+ reallocateStacks();
+ pos = pos < tempStackTop ? pos : tempStackTop;
+ tempStack[tempStackTop + 1] = act;
+ act = Parser.tAction(act, tok);
+ }
+
+ //
+ // At this point, we have a shift, shift-reduce, accept or error
+ // action. STACK contains the configuration of the state stack
+ // prior to executing any action on curtok. next_stack contains
+ // the configuration of the state stack after executing all
+ // reduce actions induced by curtok. The variable pos indicates
+ // the highest position in STACK that is still useful after the
+ // reductions are executed.
+ //
+ while(act > ERROR_ACTION || act < ACCEPT_ACTION) { // SHIFT-REDUCE action or SHIFT action ?
+ nextStackTop = tempStackTop + 1;
+ for (int i = next_pos + 1; i <= nextStackTop; i++)
+ nextStack[i] = tempStack[i];
+
+ for (int i = pos + 1; i <= nextStackTop; i++) {
+ locationStack[i] = locationStack[stateStackTop];
+ locationStartStack[i] = locationStartStack[stateStackTop];
+ }
+
+ //
+ // If we have a shift-reduce, process it as well as
+ // the goto-reduce actions that follow it.
+ //
+ if (act > ERROR_ACTION) {
+ act -= ERROR_ACTION;
+ do {
+ nextStackTop -= (Parser.rhs[act]-1);
+ act = Parser.ntAction(nextStack[nextStackTop], Parser.lhs[act]);
+ } while(act <= NUM_RULES);
+ pos = pos < nextStackTop ? pos : nextStackTop;
+ }
+
+ if (nextStackTop + 1 >= stackLength)
+ reallocateStacks();
+
+ tempStackTop = nextStackTop;
+ nextStack[++nextStackTop] = act;
+ next_pos = nextStackTop;
+
+ //
+ // Simulate the parser through the next token without
+ // destroying STACK or next_stack.
+ //
+ currentToken = lexStream.getToken();
+ tok = lexStream.kind(currentToken);
+ act = Parser.tAction(act, tok);
+ while(act <= NUM_RULES) {
+ //
+ // ... Process all goto-reduce actions following
+ // reduction, until a goto action is computed ...
+ //
+ do {
+ int lhs_symbol = Parser.lhs[act];
+ if(DEBUG) {
+ System.out.println(Parser.name[Parser.non_terminal_index[lhs_symbol]]);
+ }
+ tempStackTop -= (Parser.rhs[act]-1);
+ act = (tempStackTop > next_pos
+ ? tempStack[tempStackTop]
+ : nextStack[tempStackTop]);
+ act = Parser.ntAction(act, lhs_symbol);
+ } while(act <= NUM_RULES);
+
+ //
+ // ... Update the maximum useful position of the
+ // (STATE_)STACK, push GOTO state into stack, and
+ // compute next action on current symbol ...
+ //
+ if (tempStackTop + 1 >= stackLength)
+ reallocateStacks();
+
+ next_pos = next_pos < tempStackTop ? next_pos : tempStackTop;
+ tempStack[tempStackTop + 1] = act;
+ act = Parser.tAction(act, tok);
+ }
+
+// if((tok != TokenNameRBRACE || (forceRecoveryToken != currentToken && (lexStream.flags(currentToken) & LexStream.LBRACE_MISSING) != 0))
+// && (lexStream.flags(currentToken) & LexStream.IS_AFTER_JUMP) !=0) {
+// act = ERROR_ACTION;
+// if(forceRecoveryToken != currentToken
+// && (lexStream.flags(currentToken) & LexStream.LBRACE_MISSING) != 0) {
+// forceRecoveryAfterLBracketMissing = true;
+// forceRecoveryToken = currentToken;
+// }
+// }
+
+ //
+ // No error was detected, Read next token into
+ // PREVTOK element, advance CURTOK pointer and
+ // update stacks.
+ //
+ if (act != ERROR_ACTION) {
+ prevStackTop = stateStackTop;
+ for (int i = prev_pos + 1; i <= prevStackTop; i++)
+ prevStack[i] = stack[i];
+ prev_pos = pos;
+
+ stateStackTop = nextStackTop;
+ for (int i = pos + 1; i <= stateStackTop; i++)
+ stack[i] = nextStack[i];
+ locationStack[stateStackTop] = currentToken;
+ locationStartStack[stateStackTop] = lexStream.start(currentToken);
+ pos = next_pos;
+ }
+ }
+
+ //
+ // At this stage, either we have an ACCEPT or an ERROR
+ // action.
+ //
+ if (act == ERROR_ACTION) {
+ //
+ // An error was detected.
+ //
+ RepairCandidate candidate = errorRecovery(currentToken, forceRecoveryAfterLBracketMissing);
+
+ forceRecoveryAfterLBracketMissing = false;
+
+ if(parser.reportOnlyOneSyntaxError) {
+ return;
+ }
+
+ if(this.parser.problemReporter().options.maxProblemsPerUnit < this.parser.compilationUnit.compilationResult.problemCount) {
+ return;
+ }
+
+ act = stack[stateStackTop];
+
+ //
+ // If the recovery was successful on a nonterminal candidate,
+ // parse through that candidate and "read" the next token.
+ //
+ if (candidate.symbol == 0) {
+ break;
+ } else if (candidate.symbol > NT_OFFSET) {
+ int lhs_symbol = candidate.symbol - NT_OFFSET;
+ if(DEBUG) {
+ System.out.println(Parser.name[Parser.non_terminal_index[lhs_symbol]]);
+ }
+ act = Parser.ntAction(act, lhs_symbol);
+ while(act <= NUM_RULES) {
+ stateStackTop -= (Parser.rhs[act]-1);
+ act = Parser.ntAction(stack[stateStackTop], Parser.lhs[act]);
+ }
+ stack[++stateStackTop] = act;
+ currentToken = lexStream.getToken();
+ tok = lexStream.kind(currentToken);
+ locationStack[stateStackTop] = currentToken;
+ locationStartStack[stateStackTop] = lexStream.start(currentToken);
+ } else {
+ tok = candidate.symbol;
+ locationStack[stateStackTop] = candidate.location;
+ locationStartStack[stateStackTop] = lexStream.start(candidate.location);
+ }
+ }
+ } while (act != ACCEPT_ACTION);
+
+ return;
+ }
+
+ //
+// This routine is invoked when an error is encountered. It
+// tries to diagnose the error and recover from it. If it is
+// successful, the state stack, the current token and the buffer
+// are readjusted; i.e., after a successful recovery,
+// state_stack_top points to the location in the state stack
+// that contains the state on which to recover; curtok
+// identifies the symbol on which to recover.
+//
+// Up to three configurations may be available when this routine
+// is invoked. PREV_STACK may contain the sequence of states
+// preceding any action on prevtok, STACK always contains the
+// sequence of states preceding any action on curtok, and
+// NEXT_STACK may contain the sequence of states preceding any
+// action on the successor of curtok.
+//
+ private RepairCandidate errorRecovery(int error_token, boolean forcedError) {
+ this.errorToken = error_token;
+ this.errorTokenStart = lexStream.start(error_token);
+
+ int prevtok = lexStream.previous(error_token);
+ int prevtokKind = lexStream.kind(prevtok);
+
+ if(forcedError) {
+ int name_index = Parser.terminal_index[TokenNameLBRACE];
+
+ reportError(INSERTION_CODE, name_index, prevtok, prevtok);
+
+ RepairCandidate candidate = new RepairCandidate();
+ candidate.symbol = TokenNameLBRACE;
+ candidate.location = error_token;
+ lexStream.reset(error_token);
+
+ stateStackTop = nextStackTop;
+ for (int j = 0; j <= stateStackTop; j++) {
+ stack[j] = nextStack[j];
+ }
+ locationStack[stateStackTop] = error_token;
+ locationStartStack[stateStackTop] = lexStream.start(error_token);
+
+ return candidate;
+ }
+
+ //
+ // Try primary phase recoveries. If not successful, try secondary
+ // phase recoveries. If not successful and we are at end of the
+ // file, we issue the end-of-file error and quit. Otherwise, ...
+ //
+ RepairCandidate candidate = primaryPhase(error_token);
+ if (candidate.symbol != 0) {
+ return candidate;
+ }
+
+ candidate = secondaryPhase(error_token);
+ if (candidate.symbol != 0) {
+ return candidate;
+ }
+
+ if (lexStream.kind(error_token) == EOFT_SYMBOL) {
+ reportError(EOF_CODE,
+ Parser.terminal_index[EOFT_SYMBOL],
+ prevtok,
+ prevtok);
+ candidate.symbol = 0;
+ candidate.location = error_token;
+ return candidate;
+ }
+
+ //
+ // At this point, primary and (initial attempt at) secondary
+ // recovery did not work. We will now get into "panic mode" and
+ // keep trying secondary phase recoveries until we either find
+ // a successful recovery or have consumed the remaining input
+ // tokens.
+ //
+ while(lexStream.kind(buffer[BUFF_UBOUND]) != EOFT_SYMBOL) {
+ candidate = secondaryPhase(buffer[MAX_DISTANCE - MIN_DISTANCE + 2]);
+ if (candidate.symbol != 0) {
+ return candidate;
+ }
+ }
+
+ //
+ // We reached the end of the file while panicking. Delete all
+ // remaining tokens in the input.
+ //
+ int i;
+ for (i = BUFF_UBOUND; lexStream.kind(buffer[i]) == EOFT_SYMBOL; i--){/*empty*/}
+
+ reportError(DELETION_CODE,
+ Parser.terminal_index[prevtokKind],//Parser.terminal_index[lexStream.kind(prevtok)],
+ error_token,
+ buffer[i]);
+
+ candidate.symbol = 0;
+ candidate.location = buffer[i];
+
+ return candidate;
+ }
+
+//
+// This function tries primary and scope recovery on each
+// available configuration. If a successful recovery is found
+// and no secondary phase recovery can do better, a diagnosis is
+// issued, the configuration is updated and the function returns
+// "true". Otherwise, it returns "false".
+//
+ private RepairCandidate primaryPhase(int error_token) {
+ PrimaryRepairInfo repair = new PrimaryRepairInfo();
+ RepairCandidate candidate = new RepairCandidate();
+
+ //
+ // Initialize the buffer.
+ //
+ int i = (nextStackTop >= 0 ? 3 : 2);
+ buffer[i] = error_token;
+
+ for (int j = i; j > 0; j--)
+ buffer[j - 1] = lexStream.previous(buffer[j]);
+
+ for (int k = i + 1; k < BUFF_SIZE; k++)
+ buffer[k] = lexStream.next(buffer[k - 1]);
+
+ //
+ // If NEXT_STACK_TOP > 0 then the parse was successful on CURTOK
+ // and the error was detected on the successor of CURTOK. In
+ // that case, first check whether or not primary recovery is
+ // possible on next_stack ...
+ //
+ if (nextStackTop >= 0) {
+ repair.bufferPosition = 3;
+ repair = checkPrimaryDistance(nextStack, nextStackTop, repair);
+ }
+
+ //
+ // ... Next, try primary recovery on the current token...
+ //
+ PrimaryRepairInfo new_repair = repair.copy();
+
+ new_repair.bufferPosition = 2;
+ new_repair = checkPrimaryDistance(stack, stateStackTop, new_repair);
+ if (new_repair.distance > repair.distance || new_repair.misspellIndex > repair.misspellIndex) {
+ repair = new_repair;
+ }
+
+ //
+ // Finally, if prev_stack_top >= 0 then try primary recovery on
+ // the prev_stack configuration.
+ //
+
+ if (prevStackTop >= 0) {
+ new_repair = repair.copy();
+ new_repair.bufferPosition = 1;
+ new_repair = checkPrimaryDistance(prevStack,prevStackTop, new_repair);
+ if (new_repair.distance > repair.distance || new_repair.misspellIndex > repair.misspellIndex) {
+ repair = new_repair;
+ }
+ }
+
+ //
+ // Before accepting the best primary phase recovery obtained,
+ // ensure that we cannot do better with a similar secondary
+ // phase recovery.
+ //
+ if (nextStackTop >= 0) {// next_stack available
+ if (secondaryCheck(nextStack,nextStackTop,3,repair.distance)) {
+ return candidate;
+ }
+ }
+ else if (secondaryCheck(stack, stateStackTop, 2, repair.distance)) {
+ return candidate;
+ }
+
+ //
+ // First, adjust distance if the recovery is on the error token;
+ // it is important that the adjustment be made here and not at
+ // each primary trial to prevent the distance tests from being
+ // biased in favor of deferred recoveries which have access to
+ // more input tokens...
+ //
+ repair.distance = repair.distance - repair.bufferPosition + 1;
+
+ //
+ // ...Next, adjust the distance if the recovery is a deletion or
+ // (some form of) substitution...
+ //
+ if (repair.code == INVALID_CODE ||
+ repair.code == DELETION_CODE ||
+ repair.code == SUBSTITUTION_CODE ||
+ repair.code == MERGE_CODE) {
+ repair.distance--;
+ }
+
+ //
+ // ... After adjustment, check if the most successful primary
+ // recovery can be applied. If not, continue with more radical
+ // recoveries...
+ //
+ if (repair.distance < MIN_DISTANCE) {
+ return candidate;
+ }
+
+ //
+ // When processing an insertion error, if the token preceeding
+ // the error token is not available, we change the repair code
+ // into a BEFORE_CODE to instruct the reporting routine that it
+ // indicates that the repair symbol should be inserted before
+ // the error token.
+ //
+ if (repair.code == INSERTION_CODE) {
+ if (buffer[repair.bufferPosition - 1] == 0) {
+ repair.code = BEFORE_CODE;
+ }
+ }
+
+ //
+ // Select the proper sequence of states on which to recover,
+ // update stack accordingly and call diagnostic routine.
+ //
+ if (repair.bufferPosition == 1) {
+ stateStackTop = prevStackTop;
+ for (int j = 0; j <= stateStackTop; j++) {
+ stack[j] = prevStack[j];
+ }
+ } else if (nextStackTop >= 0 && repair.bufferPosition >= 3) {
+ stateStackTop = nextStackTop;
+ for (int j = 0; j <= stateStackTop; j++) {
+ stack[j] = nextStack[j];
+ }
+ locationStack[stateStackTop] = buffer[3];
+ locationStartStack[stateStackTop] = lexStream.start(buffer[3]);
+ }
+
+ return primaryDiagnosis(repair);
+ }
+
+
+//
+// This function checks whether or not a given state has a
+// candidate, whose string representaion is a merging of the two
+// tokens at positions buffer_position and buffer_position+1 in
+// the buffer. If so, it returns the candidate in question;
+// otherwise it returns 0.
+//
+ private int mergeCandidate(int state, int buffer_position) {
+ char[] name1 = lexStream.name(buffer[buffer_position]);
+ char[] name2 = lexStream.name(buffer[buffer_position + 1]);
+
+ int len = name1.length + name2.length;
+
+ char[] str = CharOperation.concat(name1, name2);
+
+ for (int k = Parser.asi(state); Parser.asr[k] != 0; k++) {
+ int l = Parser.terminal_index[Parser.asr[k]];
+
+ if (len == Parser.name[l].length()) {
+ char[] name = Parser.name[l].toCharArray();
+
+ if (CharOperation.equals(str, name, false)) {
+ return Parser.asr[k];
+ }
+ }
+ }
+
+ return 0;
+ }
+
+
+//
+// This procedure takes as arguments a parsing configuration
+// consisting of a state stack (stack and stack_top) and a fixed
+// number of input tokens (starting at buffer_position) in the
+// input BUFFER; and some reference arguments: repair_code,
+// distance, misspell_index, candidate, and stack_position
+// which it sets based on the best possible recovery that it
+// finds in the given configuration. The effectiveness of a
+// a repair is judged based on two criteria:
+//
+// 1) the number of tokens that can be parsed after the repair
+// is applied: distance.
+// 2) how close to perfection is the candidate that is chosen:
+// misspell_index.
+// When this procedure is entered, distance, misspell_index and
+// repair_code are assumed to be initialized.
+//
+ private PrimaryRepairInfo checkPrimaryDistance(int stck[], int stack_top, PrimaryRepairInfo repair) {
+ int i, j, k, next_state, max_pos, act, root, symbol, tok;
+
+ //
+ // First, try scope and manual recovery.
+ //
+ PrimaryRepairInfo scope_repair = scopeTrial(stck, stack_top, repair.copy());
+ if (scope_repair.distance > repair.distance)
+ repair = scope_repair;
+
+ //
+ // Next, try merging the error token with its successor.
+ //
+ if(buffer[repair.bufferPosition] != 0 && buffer[repair.bufferPosition + 1] != 0) {// do not merge the first token
+ symbol = mergeCandidate(stck[stack_top], repair.bufferPosition);
+ if (symbol != 0) {
+ j = parseCheck(stck, stack_top, symbol, repair.bufferPosition+2);
+ if ((j > repair.distance) || (j == repair.distance && repair.misspellIndex < 10)) {
+ repair.misspellIndex = 10;
+ repair.symbol = symbol;
+ repair.distance = j;
+ repair.code = MERGE_CODE;
+ }
+ }
+ }
+
+ //
+ // Next, try deletion of the error token.
+ //
+ j = parseCheck(
+ stck,
+ stack_top,
+ lexStream.kind(buffer[repair.bufferPosition + 1]),
+ repair.bufferPosition + 2);
+ if (lexStream.kind(buffer[repair.bufferPosition]) == EOLT_SYMBOL &&
+ lexStream.afterEol(buffer[repair.bufferPosition+1])) {
+ k = 10;
+ } else {
+ k = 0;
+ }
+ if (j > repair.distance || (j == repair.distance && k > repair.misspellIndex)) {
+ repair.misspellIndex = k;
+ repair.code = DELETION_CODE;
+ repair.distance = j;
+ }
+
+ //
+ // Update the error configuration by simulating all reduce and
+ // goto actions induced by the error token. Then assign the top
+ // most state of the new configuration to next_state.
+ //
+ next_state = stck[stack_top];
+ max_pos = stack_top;
+ tempStackTop = stack_top - 1;
+
+ tok = lexStream.kind(buffer[repair.bufferPosition]);
+ lexStream.reset(buffer[repair.bufferPosition + 1]);
+ act = Parser.tAction(next_state, tok);
+ while(act <= NUM_RULES) {
+ do {
+ tempStackTop -= (Parser.rhs[act]-1);
+ symbol = Parser.lhs[act];
+ act = (tempStackTop > max_pos
+ ? tempStack[tempStackTop]
+ : stck[tempStackTop]);
+ act = Parser.ntAction(act, symbol);
+ } while(act <= NUM_RULES);
+ max_pos = max_pos < tempStackTop ? max_pos : tempStackTop;
+ tempStack[tempStackTop + 1] = act;
+ next_state = act;
+ act = Parser.tAction(next_state, tok);
+ }
+
+ //
+ // Next, place the list of candidates in proper order.
+ //
+ root = 0;
+ for (i = Parser.asi(next_state); Parser.asr[i] != 0; i++) {
+ symbol = Parser.asr[i];
+ if (symbol != EOFT_SYMBOL && symbol != ERROR_SYMBOL) {
+ if (root == 0) {
+ list[symbol] = symbol;
+ } else {
+ list[symbol] = list[root];
+ list[root] = symbol;
+ }
+ root = symbol;
+ }
+ }
+
+ if (stck[stack_top] != next_state) {
+ for (i = Parser.asi(stck[stack_top]); Parser.asr[i] != 0; i++) {
+ symbol = Parser.asr[i];
+ if (symbol != EOFT_SYMBOL && symbol != ERROR_SYMBOL && list[symbol] == 0) {
+ if (root == 0) {
+ list[symbol] = symbol;
+ } else {
+ list[symbol] = list[root];
+ list[root] = symbol;
+ }
+ root = symbol;
+ }
+ }
+ }
+
+ i = list[root];
+ list[root] = 0;
+ root = i;
+
+ //
+ // Next, try insertion for each possible candidate available in
+ // the current state, except EOFT and ERROR_SYMBOL.
+ //
+ symbol = root;
+ while(symbol != 0) {
+ if (symbol == EOLT_SYMBOL && lexStream.afterEol(buffer[repair.bufferPosition])) {
+ k = 10;
+ } else {
+ k = 0;
+ }
+ j = parseCheck(stck, stack_top, symbol, repair.bufferPosition);
+ if (j > repair.distance) {
+ repair.misspellIndex = k;
+ repair.distance = j;
+ repair.symbol = symbol;
+ repair.code = INSERTION_CODE;
+ } else if (j == repair.distance && k > repair.misspellIndex) {
+ repair.misspellIndex = k;
+ repair.distance = j;
+ repair.symbol = symbol;
+ repair.code = INSERTION_CODE;
+ } else if (j == repair.distance && k == repair.misspellIndex && isBetterSymbol(symbol, repair.symbol)) {
+ repair.misspellIndex = k;
+ repair.distance = j;
+ repair.symbol = symbol;
+ repair.code = INSERTION_CODE;
+ }
+
+ symbol = list[symbol];
+ }
+
+ //
+ // Next, Try substitution for each possible candidate available
+ // in the current state, except EOFT and ERROR_SYMBOL.
+ //
+ symbol = root;
+
+ if(buffer[repair.bufferPosition] != 0) {// do not replace the first token
+ while(symbol != 0) {
+ if (symbol == EOLT_SYMBOL && lexStream.afterEol(buffer[repair.bufferPosition+1])) {
+ k = 10;
+ } else {
+ k = misspell(symbol, buffer[repair.bufferPosition]);
+ }
+ j = parseCheck(stck, stack_top, symbol, repair.bufferPosition+1);
+ if (j > repair.distance) {
+ repair.misspellIndex = k;
+ repair.distance = j;
+ repair.symbol = symbol;
+ repair.code = SUBSTITUTION_CODE;
+ } else if (j == repair.distance && k > repair.misspellIndex) {
+ repair.misspellIndex = k;
+ repair.symbol = symbol;
+ repair.code = SUBSTITUTION_CODE;
+ } else if (j == repair.distance && k > repair.misspellIndex && isBetterSymbol(symbol, repair.symbol)) {
+ repair.misspellIndex = k;
+ repair.symbol = symbol;
+ repair.code = SUBSTITUTION_CODE;
+ }
+ i = symbol;
+ symbol = list[symbol];
+ list[i] = 0; // reset element
+ }
+ }
+
+
+ //
+ // Next, we try to insert a nonterminal candidate in front of the
+ // error token, or substituting a nonterminal candidate for the
+ // error token. Precedence is given to insertion.
+ //
+ for (i = Parser.nasi(stck[stack_top]); Parser.nasr[i] != 0; i++) {
+ symbol = Parser.nasr[i] + NT_OFFSET;
+ j = parseCheck(stck, stack_top, symbol, repair.bufferPosition+1);
+ if (j > repair.distance) {
+ repair.misspellIndex = 0;
+ repair.distance = j;
+ repair.symbol = symbol;
+ repair.code = INVALID_CODE;
+ }
+
+ j = parseCheck(stck, stack_top, symbol, repair.bufferPosition);
+ if ((j > repair.distance) || (j == repair.distance && repair.code == INVALID_CODE)) {
+ repair.misspellIndex = 0;
+ repair.distance = j;
+ repair.symbol = symbol;
+ repair.code = INSERTION_CODE;
+ }
+ }
+
+ return repair;
+ }
+
+
+//
+// This procedure is invoked to issue a diagnostic message and
+// adjust the input buffer. The recovery in question is either
+// the insertion of one or more scopes, the merging of the error
+// token with its successor, the deletion of the error token,
+// the insertion of a single token in front of the error token
+// or the substitution of another token for the error token.
+//
+ private RepairCandidate primaryDiagnosis(PrimaryRepairInfo repair) {
+ int name_index;
+
+ //
+ // Issue diagnostic.
+ //
+ int prevtok = buffer[repair.bufferPosition - 1];
+ int curtok = buffer[repair.bufferPosition];
+
+ switch(repair.code) {
+ case INSERTION_CODE:
+ case BEFORE_CODE: {
+ if (repair.symbol > NT_OFFSET)
+ name_index = getNtermIndex(stack[stateStackTop],
+ repair.symbol,
+ repair.bufferPosition);
+ else name_index = getTermIndex(stack,
+ stateStackTop,
+ repair.symbol,
+ repair.bufferPosition);
+
+ int t = (repair.code == INSERTION_CODE ? prevtok : curtok);
+ reportError(repair.code, name_index, t, t);
+ break;
+ }
+ case INVALID_CODE: {
+ name_index = getNtermIndex(stack[stateStackTop],
+ repair.symbol,
+ repair.bufferPosition + 1);
+ reportError(repair.code, name_index, curtok, curtok);
+ break;
+ }
+ case SUBSTITUTION_CODE: {
+ if (repair.misspellIndex >= 6)
+ name_index = Parser.terminal_index[repair.symbol];
+ else
+ {
+ name_index = getTermIndex(stack, stateStackTop,
+ repair.symbol,
+ repair.bufferPosition + 1);
+ if (name_index != Parser.terminal_index[repair.symbol])
+ repair.code = INVALID_CODE;
+ }
+ reportError(repair.code, name_index, curtok, curtok);
+ break;
+ }
+ case MERGE_CODE: {
+ reportError(repair.code,
+ Parser.terminal_index[repair.symbol],
+ curtok,
+ lexStream.next(curtok));
+ break;
+ }
+ case SCOPE_CODE: {
+ for (int i = 0; i < scopeStackTop; i++) {
+ reportError(repair.code,
+ -scopeIndex[i],
+ locationStack[scopePosition[i]],
+ prevtok,
+ Parser.non_terminal_index[Parser.scope_lhs[scopeIndex[i]]]);
+ }
+
+ repair.symbol = Parser.scope_lhs[scopeIndex[scopeStackTop]] + NT_OFFSET;
+ stateStackTop = scopePosition[scopeStackTop];
+ reportError(repair.code,
+ -scopeIndex[scopeStackTop],
+ locationStack[scopePosition[scopeStackTop]],
+ prevtok,
+ getNtermIndex(stack[stateStackTop],
+ repair.symbol,
+ repair.bufferPosition)
+ );
+ break;
+ }
+ default: {// deletion
+ reportError(repair.code, Parser.terminal_index[ERROR_SYMBOL], curtok, curtok);
+ }
+ }
+
+ //
+ // Update buffer.
+ //
+ RepairCandidate candidate = new RepairCandidate();
+ switch (repair.code) {
+ case INSERTION_CODE:
+ case BEFORE_CODE:
+ case SCOPE_CODE: {
+ candidate.symbol = repair.symbol;
+ candidate.location = buffer[repair.bufferPosition];
+ lexStream.reset(buffer[repair.bufferPosition]);
+ break;
+ }
+ case INVALID_CODE:
+ case SUBSTITUTION_CODE: {
+ candidate.symbol = repair.symbol;
+ candidate.location = buffer[repair.bufferPosition];
+ lexStream.reset(buffer[repair.bufferPosition + 1]);
+ break;
+ }
+ case MERGE_CODE: {
+ candidate.symbol = repair.symbol;
+ candidate.location = buffer[repair.bufferPosition];
+ lexStream.reset(buffer[repair.bufferPosition + 2]);
+ break;
+ }
+ default: {// deletion
+ candidate.location = buffer[repair.bufferPosition + 1];
+ candidate.symbol =
+ lexStream.kind(buffer[repair.bufferPosition + 1]);
+ lexStream.reset(buffer[repair.bufferPosition + 2]);
+ break;
+ }
+ }
+
+ return candidate;
+ }
+
+
+//
+// This function takes as parameter an integer STACK_TOP that
+// points to a STACK element containing the state on which a
+// primary recovery will be made; the terminal candidate on which
+// to recover; and an integer: buffer_position, which points to
+// the position of the next input token in the BUFFER. The
+// parser is simulated until a shift (or shift-reduce) action
+// is computed on the candidate. Then we proceed to compute the
+// the name index of the highest level nonterminal that can
+// directly or indirectly produce the candidate.
+//
+ private int getTermIndex(int stck[], int stack_top, int tok, int buffer_position) {
+ //
+ // Initialize stack index of temp_stack and initialize maximum
+ // position of state stack that is still useful.
+ //
+ int act = stck[stack_top],
+ max_pos = stack_top,
+ highest_symbol = tok;
+
+ tempStackTop = stack_top - 1;
+
+ //
+ // Compute all reduce and associated actions induced by the
+ // candidate until a SHIFT or SHIFT-REDUCE is computed. ERROR
+ // and ACCEPT actions cannot be computed on the candidate in
+ // this context, since we know that it is suitable for recovery.
+ //
+ lexStream.reset(buffer[buffer_position]);
+ act = Parser.tAction(act, tok);
+ while(act <= NUM_RULES) {
+ //
+ // Process all goto-reduce actions following reduction,
+ // until a goto action is computed ...
+ //
+ do {
+ tempStackTop -= (Parser.rhs[act]-1);
+ int lhs_symbol = Parser.lhs[act];
+ act = (tempStackTop > max_pos
+ ? tempStack[tempStackTop]
+ : stck[tempStackTop]);
+ act = Parser.ntAction(act, lhs_symbol);
+ } while(act <= NUM_RULES);
+
+ //
+ // Compute new maximum useful position of (STATE_)stack,
+ // push goto state into the stack, and compute next
+ // action on candidate ...
+ //
+ max_pos = max_pos < tempStackTop ? max_pos : tempStackTop;
+ tempStack[tempStackTop + 1] = act;
+ act = Parser.tAction(act, tok);
+ }
+
+ //
+ // At this stage, we have simulated all actions induced by the
+ // candidate and we are ready to shift or shift-reduce it. First,
+ // set tok and next_ptr appropriately and identify the candidate
+ // as the initial highest_symbol. If a shift action was computed
+ // on the candidate, update the stack and compute the next
+ // action. Next, simulate all actions possible on the next input
+ // token until we either have to shift it or are about to reduce
+ // below the initial starting point in the stack (indicated by
+ // max_pos as computed in the previous loop). At that point,
+ // return the highest_symbol computed.
+ //
+ tempStackTop++; // adjust top of stack to reflect last goto
+ // next move is shift or shift-reduce.
+ int threshold = tempStackTop;
+
+ tok = lexStream.kind(buffer[buffer_position]);
+ lexStream.reset(buffer[buffer_position + 1]);
+
+ if (act > ERROR_ACTION) { // shift-reduce on candidate?
+ act -= ERROR_ACTION;
+ } else {
+ tempStack[tempStackTop + 1] = act;
+ act = Parser.tAction(act, tok);
+ }
+
+ while(act <= NUM_RULES) {
+ //
+ // Process all goto-reduce actions following reduction,
+ // until a goto action is computed ...
+ //
+ do {
+ tempStackTop -= (Parser.rhs[act]-1);
+
+ if (tempStackTop < threshold) {
+ return (highest_symbol > NT_OFFSET
+ ? Parser.non_terminal_index[highest_symbol - NT_OFFSET]
+ : Parser.terminal_index[highest_symbol]);
+ }
+
+ int lhs_symbol = Parser.lhs[act];
+ if (tempStackTop == threshold)
+ highest_symbol = lhs_symbol + NT_OFFSET;
+ act = (tempStackTop > max_pos
+ ? tempStack[tempStackTop]
+ : stck[tempStackTop]);
+ act = Parser.ntAction(act, lhs_symbol);
+ } while(act <= NUM_RULES);
+
+ tempStack[tempStackTop + 1] = act;
+ act = Parser.tAction(act, tok);
+ }
+
+ return (highest_symbol > NT_OFFSET
+ ? Parser.non_terminal_index[highest_symbol - NT_OFFSET]
+ : Parser.terminal_index[highest_symbol]);
+ }
+
+//
+// This function takes as parameter a starting state number:
+// start, a nonterminal symbol, A (candidate), and an integer,
+// buffer_position, which points to the position of the next
+// input token in the BUFFER.
+// It returns the highest level non-terminal B such that
+// B =>*rm A. I.e., there does not exists a nonterminal C such
+// that C =>+rm B. (Recall that for an LALR(k) grammar if
+// C =>+rm B, it cannot be the case that B =>+rm C)
+//
+ private int getNtermIndex(int start, int sym, int buffer_position) {
+ int highest_symbol = sym - NT_OFFSET,
+ tok = lexStream.kind(buffer[buffer_position]);
+ lexStream.reset(buffer[buffer_position + 1]);
+
+ //
+ // Initialize stack index of temp_stack and initialize maximum
+ // position of state stack that is still useful.
+ //
+ tempStackTop = 0;
+ tempStack[tempStackTop] = start;
+
+ int act = Parser.ntAction(start, highest_symbol);
+ if (act > NUM_RULES) { // goto action?
+ tempStack[tempStackTop + 1] = act;
+ act = Parser.tAction(act, tok);
+ }
+
+ while(act <= NUM_RULES) {
+ //
+ // Process all goto-reduce actions following reduction,
+ // until a goto action is computed ...
+ //
+ do {
+ tempStackTop -= (Parser.rhs[act]-1);
+ if (tempStackTop < 0)
+ return Parser.non_terminal_index[highest_symbol];
+ if (tempStackTop == 0)
+ highest_symbol = Parser.lhs[act];
+ act = Parser.ntAction(tempStack[tempStackTop], Parser.lhs[act]);
+ } while(act <= NUM_RULES);
+ tempStack[tempStackTop + 1] = act;
+ act = Parser.tAction(act, tok);
+ }
+
+ return Parser.non_terminal_index[highest_symbol];
+ }
+
+ private boolean isBetterSymbol(int symbol, int actualSymbol) {
+// switch (actualSymbol) {
+// case TokenNameinterface :
+// if(symbol == TokenNameclass) {
+// return true;
+// }
+// break;
+// }
+ return false;
+ }
+
+//
+// Check whether or not there is a high probability that a
+// given string is a misspelling of another.
+// Certain singleton symbols (such as ":" and ";") are also
+// considered to be misspelling of each other.
+//
+ private int misspell(int sym, int tok) {
+
+
+ //
+ //
+ //
+ char[] name = Parser.name[Parser.terminal_index[sym]].toCharArray();
+ int n = name.length;
+ char[] s1 = new char[n + 1];
+ for (int k = 0; k < n; k++) {
+ char c = name[k];
+ s1[k] = Character.toLowerCase(c);
+ }
+ s1[n] = '\0';
+
+ //
+ //
+ //
+ char[] tokenName = lexStream.name(tok);
+ int len = tokenName.length;
+ int m = len < MAX_NAME_LENGTH ? len : MAX_NAME_LENGTH;
+ char[] s2 = new char[m + 1];
+ for (int k = 0; k < m; k++) {
+ char c = tokenName[k];
+ s2[k] = Character.toLowerCase(c);
+ }
+ s2[m] = '\0';
+
+ //
+ // Singleton mispellings:
+ //
+ // ; <----> ,
+ //
+ // ; <----> :
+ //
+ // . <----> ,
+ //
+ // ' <----> "
+ //
+ //
+ if (n == 1 && m == 1) {
+ if ((s1[0] == ';' && s2[0] == ',') ||
+ (s1[0] == ',' && s2[0] == ';') ||
+ (s1[0] == ';' && s2[0] == ':') ||
+ (s1[0] == ':' && s2[0] == ';') ||
+ (s1[0] == '.' && s2[0] == ',') ||
+ (s1[0] == ',' && s2[0] == '.') ||
+ (s1[0] == '\'' && s2[0] == '\"') ||
+ (s1[0] == '\"' && s2[0] == '\'')) {
+ return 3;
+ }
+ }
+
+ //
+ // Scan the two strings. Increment "match" count for each match.
+ // When a transposition is encountered, increase "match" count
+ // by two but count it as an error. When a typo is found, skip
+ // it and count it as an error. Otherwise we have a mismatch; if
+ // one of the strings is longer, increment its index, otherwise,
+ // increment both indices and continue.
+ //
+ // This algorithm is an adaptation of a boolean misspelling
+ // algorithm proposed by Juergen Uhl.
+ //
+ int count = 0;
+ int prefix_length = 0;
+ int num_errors = 0;
+
+ int i = 0;
+ int j = 0;
+ while ((i < n) && (j < m)) {
+ if (s1[i] == s2[j]) {
+ count++;
+ i++;
+ j++;
+ if (num_errors == 0) {
+ prefix_length++;
+ }
+ } else if (s1[i+1] == s2[j] && s1[i] == s2[j+1]) {
+ count += 2;
+ i += 2;
+ j += 2;
+ num_errors++;
+ } else if (s1[i+1] == s2[j+1]) {
+ i++;
+ j++;
+ num_errors++;
+ } else {
+ if ((n - i) > (m - j)) {
+ i++;
+ } else if ((m - j) > (n - i)) {
+ j++;
+ } else {
+ i++;
+ j++;
+ }
+ num_errors++;
+ }
+ }
+
+ if (i < n || j < m)
+ num_errors++;
+
+ if (num_errors > ((n < m ? n : m) / 6 + 1))
+ count = prefix_length;
+
+ return(count * 10 / ((n < len ? len : n) + num_errors));
+ }
+
+ private PrimaryRepairInfo scopeTrial(int stck[], int stack_top, PrimaryRepairInfo repair) {
+ stateSeen = new int[stackLength];
+ for (int i = 0; i < stackLength; i++)
+ stateSeen[i] = NIL;
+
+ statePoolTop = 0;
+ statePool = new StateInfo[stackLength];
+
+ scopeTrialCheck(stck, stack_top, repair, 0);
+
+ stateSeen = null;
+ statePoolTop = 0;
+
+ repair.code = SCOPE_CODE;
+ repair.misspellIndex = 10;
+
+ return repair;
+ }
+
+ private void scopeTrialCheck(int stck[], int stack_top, PrimaryRepairInfo repair, int indx) {
+ if(indx > 20) return; // avoid too much recursive call to improve performance
+
+ int act = stck[stack_top];
+
+ for (int i = stateSeen[stack_top]; i != NIL; i = statePool[i].next) {
+ if (statePool[i].state == act) return;
+ }
+
+ int old_state_pool_top = statePoolTop++;
+ if(statePoolTop >= statePool.length) {
+ System.arraycopy(statePool, 0, statePool = new StateInfo[statePoolTop * 2], 0, statePoolTop);
+ }
+
+ statePool[old_state_pool_top] = new StateInfo(act, stateSeen[stack_top]);
+ stateSeen[stack_top] = old_state_pool_top;
+
+ for (int i = 0; i < SCOPE_SIZE; i++) {
+ //
+ // Use the scope lookahead symbol to force all reductions
+ // inducible by that symbol.
+ //
+ act = stck[stack_top];
+ tempStackTop = stack_top - 1;
+ int max_pos = stack_top;
+ int tok = Parser.scope_la[i];
+ lexStream.reset(buffer[repair.bufferPosition]);
+ act = Parser.tAction(act, tok);
+ while(act <= NUM_RULES) {
+ //
+ // ... Process all goto-reduce actions following
+ // reduction, until a goto action is computed ...
+ //
+ do {
+ tempStackTop -= (Parser.rhs[act]-1);
+ int lhs_symbol = Parser.lhs[act];
+ act = (tempStackTop > max_pos
+ ? tempStack[tempStackTop]
+ : stck[tempStackTop]);
+ act = Parser.ntAction(act, lhs_symbol);
+ } while(act <= NUM_RULES);
+ if (tempStackTop + 1 >= stackLength)
+ return;
+ max_pos = max_pos < tempStackTop ? max_pos : tempStackTop;
+ tempStack[tempStackTop + 1] = act;
+ act = Parser.tAction(act, tok);
+ }
+
+ //
+ // If the lookahead symbol is parsable, then we check
+ // whether or not we have a match between the scope
+ // prefix and the transition symbols corresponding to
+ // the states on top of the stack.
+ //
+ if (act != ERROR_ACTION) {
+ int j, k;
+ k = Parser.scope_prefix[i];
+ for (j = tempStackTop + 1;
+ j >= (max_pos + 1) &&
+ Parser.in_symbol(tempStack[j]) == Parser.scope_rhs[k]; j--) {
+ k++;
+ }
+ if (j == max_pos) {
+ for (j = max_pos;
+ j >= 1 && Parser.in_symbol(stck[j]) == Parser.scope_rhs[k];
+ j--) {
+ k++;
+ }
+ }
+ //
+ // If the prefix matches, check whether the state
+ // newly exposed on top of the stack, (after the
+ // corresponding prefix states are popped from the
+ // stack), is in the set of "source states" for the
+ // scope in question and that it is at a position
+ // below the threshold indicated by MARKED_POS.
+ //
+ int marked_pos = (max_pos < stack_top ? max_pos + 1 : stack_top);
+ if (Parser.scope_rhs[k] == 0 && j < marked_pos) { // match?
+ int stack_position = j;
+ for (j = Parser.scope_state_set[i];
+ stck[stack_position] != Parser.scope_state[j] &&
+ Parser.scope_state[j] != 0;
+ j++){/*empty*/}
+ //
+ // If the top state is valid for scope recovery,
+ // the left-hand side of the scope is used as
+ // starting symbol and we calculate how far the
+ // parser can advance within the forward context
+ // after parsing the left-hand symbol.
+ //
+ if (Parser.scope_state[j] != 0) { // state was found
+ int previous_distance = repair.distance;
+ int distance = parseCheck(stck,
+ stack_position,
+ Parser.scope_lhs[i]+NT_OFFSET,
+ repair.bufferPosition);
+ //
+ // if the recovery is not successful, we
+ // update the stack with all actions induced
+ // by the left-hand symbol, and recursively
+ // call SCOPE_TRIAL_CHECK to try again.
+ // Otherwise, the recovery is successful. If
+ // the new distance is greater than the
+ // initial SCOPE_DISTANCE, we update
+ // SCOPE_DISTANCE and set scope_stack_top to INDX
+ // to indicate the number of scopes that are
+ // to be applied for a succesful recovery.
+ // NOTE that this procedure cannot get into
+ // an infinite loop, since each prefix match
+ // is guaranteed to take us to a lower point
+ // within the stack.
+ //
+ if ((distance - repair.bufferPosition + 1) < MIN_DISTANCE) {
+ int top = stack_position;
+ act = Parser.ntAction(stck[top], Parser.scope_lhs[i]);
+ while(act <= NUM_RULES) {
+ top -= (Parser.rhs[act]-1);
+ act = Parser.ntAction(stck[top], Parser.lhs[act]);
+ }
+ top++;
+
+ j = act;
+ act = stck[top]; // save
+ stck[top] = j; // swap
+ scopeTrialCheck(stck, top, repair, indx+1);
+ stck[top] = act; // restore
+ } else if (distance > repair.distance) {
+ scopeStackTop = indx;
+ repair.distance = distance;
+ }
+
+ if (lexStream.kind(buffer[repair.bufferPosition]) == EOFT_SYMBOL &&
+ repair.distance == previous_distance) {
+ scopeStackTop = indx;
+ repair.distance = MAX_DISTANCE;
+ }
+
+ //
+ // If this scope recovery has beaten the
+ // previous distance, then we have found a
+ // better recovery (or this recovery is one
+ // of a list of scope recoveries). Record
+ // its information at the proper location
+ // (INDX) in SCOPE_INDEX and SCOPE_STACK.
+ //
+ if (repair.distance > previous_distance) {
+ scopeIndex[indx] = i;
+ scopePosition[indx] = stack_position;
+ return;
+ }
+ }
+ }
+ }
+ }
+ }
+//
+// This function computes the ParseCheck distance for the best
+// possible secondary recovery for a given configuration that
+// either deletes none or only one symbol in the forward context.
+// If the recovery found is more effective than the best primary
+// recovery previously computed, then the function returns true.
+// Only misplacement, scope and manual recoveries are attempted;
+// simple insertion or substitution of a nonterminal are tried
+// in CHECK_PRIMARY_DISTANCE as part of primary recovery.
+//
+ private boolean secondaryCheck(int stck[], int stack_top, int buffer_position, int distance) {
+ int top, j;
+
+ for (top = stack_top - 1; top >= 0; top--) {
+ j = parseCheck(stck, top,
+ lexStream.kind(buffer[buffer_position]),
+ buffer_position + 1);
+ if (((j - buffer_position + 1) > MIN_DISTANCE) && (j > distance))
+ return true;
+ }
+
+ PrimaryRepairInfo repair = new PrimaryRepairInfo();
+ repair.bufferPosition = buffer_position + 1;
+ repair.distance = distance;
+ repair = scopeTrial(stck, stack_top, repair);
+ if ((repair.distance - buffer_position) > MIN_DISTANCE && repair.distance > distance)
+ return true;
+ return false;
+ }
+
+
+//
+// Secondary_phase is a boolean function that checks whether or
+// not some form of secondary recovery is applicable to one of
+// the error configurations. First, if "next_stack" is available,
+// misplacement and secondary recoveries are attempted on it.
+// Then, in any case, these recoveries are attempted on "stack".
+// If a successful recovery is found, a diagnosis is issued, the
+// configuration is updated and the function returns "true".
+// Otherwise, the function returns false.
+//
+ private RepairCandidate secondaryPhase(int error_token) {
+ SecondaryRepairInfo repair = new SecondaryRepairInfo();
+ SecondaryRepairInfo misplaced = new SecondaryRepairInfo();
+
+ RepairCandidate candidate = new RepairCandidate();
+
+ int i, j, k, top;
+ int next_last_index = 0;
+ int last_index;
+
+ candidate.symbol = 0;
+
+ repair.code = 0;
+ repair.distance = 0;
+ repair.recoveryOnNextStack = false;
+
+ misplaced.distance = 0;
+ misplaced.recoveryOnNextStack = false;
+
+ //
+ // If the next_stack is available, try misplaced and secondary
+ // recovery on it first.
+ //
+ if (nextStackTop >= 0) {
+ int save_location;
+
+ buffer[2] = error_token;
+ buffer[1] = lexStream.previous(buffer[2]);
+ buffer[0] = lexStream.previous(buffer[1]);
+
+ for (k = 3; k < BUFF_UBOUND; k++)
+ buffer[k] = lexStream.next(buffer[k - 1]);
+
+ buffer[BUFF_UBOUND] = lexStream.badtoken();// elmt not available
+
+ //
+ // If we are at the end of the input stream, compute the
+ // index position of the first EOFT symbol (last useful
+ // index).
+ //
+ for (next_last_index = MAX_DISTANCE - 1;
+ next_last_index >= 1 &&
+ lexStream.kind(buffer[next_last_index]) == EOFT_SYMBOL;
+ next_last_index--){/*empty*/}
+ next_last_index = next_last_index + 1;
+
+ save_location = locationStack[nextStackTop];
+ int save_location_start = locationStartStack[nextStackTop];
+ locationStack[nextStackTop] = buffer[2];
+ locationStartStack[nextStackTop] = lexStream.start(buffer[2]);
+ misplaced.numDeletions = nextStackTop;
+ misplaced = misplacementRecovery(nextStack, nextStackTop,
+ next_last_index,
+ misplaced, true);
+ if (misplaced.recoveryOnNextStack)
+ misplaced.distance++;
+
+ repair.numDeletions = nextStackTop + BUFF_UBOUND;
+ repair = secondaryRecovery(nextStack, nextStackTop,
+ next_last_index,
+ repair, true);
+ if (repair.recoveryOnNextStack)
+ repair.distance++;
+
+ locationStack[nextStackTop] = save_location;
+ locationStartStack[nextStackTop] = save_location_start;
+ } else { // next_stack not available, initialize ...
+ misplaced.numDeletions = stateStackTop;
+ repair.numDeletions = stateStackTop + BUFF_UBOUND;
+ }
+
+ //
+ // Try secondary recovery on the "stack" configuration.
+ //
+ buffer[3] = error_token;
+
+ buffer[2] = lexStream.previous(buffer[3]);
+ buffer[1] = lexStream.previous(buffer[2]);
+ buffer[0] = lexStream.previous(buffer[1]);
+
+ for (k = 4; k < BUFF_SIZE; k++)
+ buffer[k] = lexStream.next(buffer[k - 1]);
+
+ for (last_index = MAX_DISTANCE - 1;
+ last_index >= 1 && lexStream.kind(buffer[last_index]) == EOFT_SYMBOL;
+ last_index--){/*empty*/}
+ last_index++;
+
+ misplaced = misplacementRecovery(stack, stateStackTop,
+ last_index,
+ misplaced, false);
+
+ repair = secondaryRecovery(stack, stateStackTop,
+ last_index, repair, false);
+
+ //
+ // If a successful misplaced recovery was found, compare it with
+ // the most successful secondary recovery. If the misplaced
+ // recovery either deletes fewer symbols or parse-checks further
+ // then it is chosen.
+ //
+ if (misplaced.distance > MIN_DISTANCE) {
+ if (misplaced.numDeletions <= repair.numDeletions ||
+ (misplaced.distance - misplaced.numDeletions) >=
+ (repair.distance - repair.numDeletions)) {
+ repair.code = MISPLACED_CODE;
+ repair.stackPosition = misplaced.stackPosition;
+ repair.bufferPosition = 2;
+ repair.numDeletions = misplaced.numDeletions;
+ repair.distance = misplaced.distance;
+ repair.recoveryOnNextStack = misplaced.recoveryOnNextStack;
+ }
+ }
+
+ //
+ // If the successful recovery was on next_stack, update: stack,
+ // buffer, location_stack and last_index.
+ //
+ if (repair.recoveryOnNextStack) {
+ stateStackTop = nextStackTop;
+ for (i = 0; i <= stateStackTop; i++)
+ stack[i] = nextStack[i];
+
+ buffer[2] = error_token;
+ buffer[1] = lexStream.previous(buffer[2]);
+ buffer[0] = lexStream.previous(buffer[1]);
+
+ for (k = 3; k < BUFF_UBOUND; k++)
+ buffer[k] = lexStream.next(buffer[k - 1]);
+
+ buffer[BUFF_UBOUND] = lexStream.badtoken();// elmt not available
+
+ locationStack[nextStackTop] = buffer[2];
+ locationStartStack[nextStackTop] = lexStream.start(buffer[2]);
+ last_index = next_last_index;
+ }
+
+ //
+ // Next, try scope recoveries after deletion of one, two, three,
+ // four ... buffer_position tokens from the input stream.
+ //
+ if (repair.code == SECONDARY_CODE || repair.code == DELETION_CODE) {
+ PrimaryRepairInfo scope_repair = new PrimaryRepairInfo();
+
+ scope_repair.distance = 0;
+ for (scope_repair.bufferPosition = 2;
+ scope_repair.bufferPosition <= repair.bufferPosition &&
+ repair.code != SCOPE_CODE; scope_repair.bufferPosition++) {
+ scope_repair = scopeTrial(stack, stateStackTop, scope_repair);
+ j = (scope_repair.distance == MAX_DISTANCE
+ ? last_index
+ : scope_repair.distance);
+ k = scope_repair.bufferPosition - 1;
+ if ((j - k) > MIN_DISTANCE && (j - k) > (repair.distance - repair.numDeletions)) {
+ repair.code = SCOPE_CODE;
+ i = scopeIndex[scopeStackTop]; // upper bound
+ repair.symbol = Parser.scope_lhs[i] + NT_OFFSET;
+ repair.stackPosition = stateStackTop;
+ repair.bufferPosition = scope_repair.bufferPosition;
+ }
+ }
+ }
+
+ //
+ // If no successful recovery is found and we have reached the
+ // end of the file, check whether or not scope recovery is
+ // applicable at the end of the file after discarding some
+ // states.
+ //
+ if (repair.code == 0 && lexStream.kind(buffer[last_index]) == EOFT_SYMBOL) {
+ PrimaryRepairInfo scope_repair = new PrimaryRepairInfo();
+
+ scope_repair.bufferPosition = last_index;
+ scope_repair.distance = 0;
+ for (top = stateStackTop;
+ top >= 0 && repair.code == 0; top--)
+ {
+ scope_repair = scopeTrial(stack, top, scope_repair);
+ if (scope_repair.distance > 0)
+ {
+ repair.code = SCOPE_CODE;
+ i = scopeIndex[scopeStackTop]; // upper bound
+ repair.symbol = Parser.scope_lhs[i] + NT_OFFSET;
+ repair.stackPosition = top;
+ repair.bufferPosition = scope_repair.bufferPosition;
+ }
+ }
+ }
+
+ //
+ // If a successful repair was not found, quit! Otherwise, issue
+ // diagnosis and adjust configuration...
+ //
+ if (repair.code == 0)
+ return candidate;
+
+ secondaryDiagnosis(repair);
+
+ //
+ // Update buffer based on number of elements that are deleted.
+ //
+ switch(repair.code) {
+ case MISPLACED_CODE:
+ candidate.location = buffer[2];
+ candidate.symbol = lexStream.kind(buffer[2]);
+ lexStream.reset(lexStream.next(buffer[2]));
+
+ break;
+
+ case DELETION_CODE:
+ candidate.location = buffer[repair.bufferPosition];
+ candidate.symbol =
+ lexStream.kind(buffer[repair.bufferPosition]);
+ lexStream.reset(lexStream.next(buffer[repair.bufferPosition]));
+
+ break;
+
+ default: // SCOPE_CODE || SECONDARY_CODE
+ candidate.symbol = repair.symbol;
+ candidate.location = buffer[repair.bufferPosition];
+ lexStream.reset(buffer[repair.bufferPosition]);
+
+ break;
+ }
+
+ return candidate;
+ }
+
+
+//
+// This boolean function checks whether or not a given
+// configuration yields a better misplacement recovery than
+// the best misplacement recovery computed previously.
+//
+ private SecondaryRepairInfo misplacementRecovery(int stck[], int stack_top, int last_index, SecondaryRepairInfo repair, boolean stack_flag) {
+ int previous_loc = buffer[2];
+ int stack_deletions = 0;
+
+ for (int top = stack_top - 1; top >= 0; top--) {
+ if (locationStack[top] < previous_loc) {
+ stack_deletions++;
+ }
+ previous_loc = locationStack[top];
+
+ int j = parseCheck(stck, top, lexStream.kind(buffer[2]), 3);
+ if (j == MAX_DISTANCE) {
+ j = last_index;
+ }
+ if ((j > MIN_DISTANCE) && (j - stack_deletions) > (repair.distance - repair.numDeletions)) {
+ repair.stackPosition = top;
+ repair.distance = j;
+ repair.numDeletions = stack_deletions;
+ repair.recoveryOnNextStack = stack_flag;
+ }
+ }
+
+ return repair;
+ }
+
+
+//
+// This boolean function checks whether or not a given
+// configuration yields a better secondary recovery than the
+// best misplacement recovery computed previously.
+//
+ private SecondaryRepairInfo secondaryRecovery(int stck[],int stack_top, int last_index, SecondaryRepairInfo repair, boolean stack_flag) {
+ int previous_loc;
+ int stack_deletions = 0;
+
+ previous_loc = buffer[2];
+ for (int top = stack_top; top >= 0 && repair.numDeletions >= stack_deletions; top--) {
+ if (locationStack[top] < previous_loc) {
+ stack_deletions++;
+ }
+ previous_loc = locationStack[top];
+
+ for (int i = 2;
+ i <= (last_index - MIN_DISTANCE + 1) &&
+ (repair.numDeletions >= (stack_deletions + i - 1)); i++) {
+ int j = parseCheck(stck, top, lexStream.kind(buffer[i]), i + 1);
+
+ if (j == MAX_DISTANCE) {
+ j = last_index;
+ }
+ if ((j - i + 1) > MIN_DISTANCE) {
+ int k = stack_deletions + i - 1;
+ if ((k < repair.numDeletions) ||
+ (j - k) > (repair.distance - repair.numDeletions) ||
+ ((repair.code == SECONDARY_CODE) && (j - k) == (repair.distance - repair.numDeletions))) {
+ repair.code = DELETION_CODE;
+ repair.distance = j;
+ repair.stackPosition = top;
+ repair.bufferPosition = i;
+ repair.numDeletions = k;
+ repair.recoveryOnNextStack = stack_flag;
+ }
+ }
+
+ for (int l = Parser.nasi(stck[top]); l >= 0 && Parser.nasr[l] != 0; l++) {
+ int symbol = Parser.nasr[l] + NT_OFFSET;
+ j = parseCheck(stck, top, symbol, i);
+ if (j == MAX_DISTANCE) {
+ j = last_index;
+ }
+ if ((j - i + 1) > MIN_DISTANCE) {
+ int k = stack_deletions + i - 1;
+ if (k < repair.numDeletions || (j - k) > (repair.distance - repair.numDeletions)) {
+ repair.code = SECONDARY_CODE;
+ repair.symbol = symbol;
+ repair.distance = j;
+ repair.stackPosition = top;
+ repair.bufferPosition = i;
+ repair.numDeletions = k;
+ repair.recoveryOnNextStack = stack_flag;
+ }
+ }
+ }
+ }
+ }
+
+ return repair;
+ }
+
+
+//
+// This procedure is invoked to issue a secondary diagnosis and
+// adjust the input buffer. The recovery in question is either
+// an automatic scope recovery, a manual scope recovery, a
+// secondary substitution or a secondary deletion.
+//
+ private void secondaryDiagnosis(SecondaryRepairInfo repair) {
+ switch(repair.code) {
+ case SCOPE_CODE: {
+ if (repair.stackPosition < stateStackTop) {
+ reportError(DELETION_CODE,
+ Parser.terminal_index[ERROR_SYMBOL],
+ locationStack[repair.stackPosition],
+ buffer[1]);
+ }
+ for (int i = 0; i < scopeStackTop; i++) {
+ reportError(SCOPE_CODE,
+ -scopeIndex[i],
+ locationStack[scopePosition[i]],
+ buffer[1],
+ Parser.non_terminal_index[Parser.scope_lhs[scopeIndex[i]]]);
+ }
+
+ repair.symbol = Parser.scope_lhs[scopeIndex[scopeStackTop]] + NT_OFFSET;
+ stateStackTop = scopePosition[scopeStackTop];
+ reportError(SCOPE_CODE,
+ -scopeIndex[scopeStackTop],
+ locationStack[scopePosition[scopeStackTop]],
+ buffer[1],
+ getNtermIndex(stack[stateStackTop],
+ repair.symbol,
+ repair.bufferPosition)
+ );
+ break;
+ }
+ default: {
+ reportError(repair.code,
+ (repair.code == SECONDARY_CODE
+ ? getNtermIndex(stack[repair.stackPosition],
+ repair.symbol,
+ repair.bufferPosition)
+ : Parser.terminal_index[ERROR_SYMBOL]),
+ locationStack[repair.stackPosition],
+ buffer[repair.bufferPosition - 1]);
+ stateStackTop = repair.stackPosition;
+ }
+ }
+ }
+
+
+
+
+//
+// Try to parse until first_token and all tokens in BUFFER have
+// been consumed, or an error is encountered. Return the number
+// of tokens that were expended before the parse blocked.
+//
+ private int parseCheck(int stck[], int stack_top, int first_token, int buffer_position) {
+ int max_pos;
+ int indx;
+ int ct;
+ int act;
+
+ //
+ // Initialize pointer for temp_stack and initialize maximum
+ // position of state stack that is still useful.
+ //
+ act = stck[stack_top];
+ if (first_token > NT_OFFSET) {
+ tempStackTop = stack_top;
+ max_pos = stack_top;
+ indx = buffer_position;
+ ct = lexStream.kind(buffer[indx]);
+ lexStream.reset(lexStream.next(buffer[indx]));
+ int lhs_symbol = first_token - NT_OFFSET;
+ act = Parser.ntAction(act, lhs_symbol);
+ if (act <= NUM_RULES) {
+ do {
+ tempStackTop -= (Parser.rhs[act]-1);
+ lhs_symbol = Parser.lhs[act];
+ act = (tempStackTop > max_pos
+ ? tempStack[tempStackTop]
+ : stck[tempStackTop]);
+ act = Parser.ntAction(act, lhs_symbol);
+ } while(act <= NUM_RULES);
+
+ max_pos = max_pos < tempStackTop ? max_pos : tempStackTop;
+ }
+ } else {
+ tempStackTop = stack_top - 1;
+ max_pos = tempStackTop;
+ indx = buffer_position - 1;
+ ct = first_token;
+ lexStream.reset(buffer[buffer_position]);
+ }
+
+ process_terminal: for (;;) {
+ if (++tempStackTop >= stackLength) // Stack overflow!!!
+ return indx;
+ tempStack[tempStackTop] = act;
+
+ act = Parser.tAction(act, ct);
+
+ if (act <= NUM_RULES) { // reduce action
+ tempStackTop--;
+ } else if (act < ACCEPT_ACTION || // shift action
+ act > ERROR_ACTION) { // shift-reduce action
+ if (indx == MAX_DISTANCE)
+ return indx;
+ indx++;
+ ct = lexStream.kind(buffer[indx]);
+ lexStream.reset(lexStream.next(buffer[indx]));
+ if (act > ERROR_ACTION) {
+ act -= ERROR_ACTION;
+ } else {
+ continue process_terminal;
+ }
+ } else if (act == ACCEPT_ACTION) { // accept action
+ return MAX_DISTANCE;
+ } else {
+ return indx; // error action
+ }
+
+ process_non_terminal:
+ do {
+ tempStackTop -= (Parser.rhs[act]-1);
+ int lhs_symbol = Parser.lhs[act];
+ act = (tempStackTop > max_pos
+ ? tempStack[tempStackTop]
+ : stck[tempStackTop]);
+ act = Parser.ntAction(act, lhs_symbol);
+ } while(act <= NUM_RULES);
+
+ max_pos = max_pos < tempStackTop ? max_pos : tempStackTop;
+ } // process_terminal;
+ }
+ private void reportError(int msgCode, int nameIndex, int leftToken, int rightToken) {
+ reportError(msgCode, nameIndex, leftToken, rightToken, 0);
+ }
+
+ private void reportError(int msgCode, int nameIndex, int leftToken, int rightToken, int scopeNameIndex) {
+ int lToken = (leftToken > rightToken ? rightToken : leftToken);
+
+ if (lToken < rightToken) {
+ reportSecondaryError(msgCode, nameIndex, lToken, rightToken, scopeNameIndex);
+ } else {
+ reportPrimaryError(msgCode, nameIndex, rightToken, scopeNameIndex);
+ }
+ }
+ private void reportPrimaryError(int msgCode, int nameIndex, int token, int scopeNameIndex) {
+ String name;
+ if (nameIndex >= 0) {
+ name = Parser.readableName[nameIndex];
+ } else {
+ name = EMPTY_STRING;
+ }
+
+ int errorStart = lexStream.start(token);
+ int errorEnd = lexStream.end(token);
+ int currentKind = lexStream.kind(token);
+ String errorTokenName = Parser.name[Parser.terminal_index[lexStream.kind(token)]];
+ char[] errorTokenSource = lexStream.name(token);
+
+ switch(msgCode) {
+ case BEFORE_CODE:
+ problemReporter().parseErrorInsertBeforeToken(
+ errorStart,
+ errorEnd,
+ currentKind,
+ errorTokenSource,
+ errorTokenName,
+ name);
+ break;
+ case INSERTION_CODE:
+ problemReporter().parseErrorInsertAfterToken(
+ errorStart,
+ errorEnd,
+ currentKind,
+ errorTokenSource,
+ errorTokenName,
+ name);
+ break;
+ case DELETION_CODE:
+ problemReporter().parseErrorDeleteToken(
+ errorStart,
+ errorEnd,
+ currentKind,
+ errorTokenSource,
+ errorTokenName);
+ break;
+ case INVALID_CODE:
+ if (name.length() == 0) {
+ problemReporter().parseErrorReplaceToken(
+ errorStart,
+ errorEnd,
+ currentKind,
+ errorTokenSource,
+ errorTokenName,
+ name);
+ } else {
+ problemReporter().parseErrorInvalidToken(
+ errorStart,
+ errorEnd,
+ currentKind,
+ errorTokenSource,
+ errorTokenName,
+ name);
+ }
+ break;
+ case SUBSTITUTION_CODE:
+ problemReporter().parseErrorReplaceToken(
+ errorStart,
+ errorEnd,
+ currentKind,
+ errorTokenSource,
+ errorTokenName,
+ name);
+ break;
+ case SCOPE_CODE:
+ StringBuffer buf = new StringBuffer();
+ for (int i = Parser.scope_suffix[- nameIndex]; Parser.scope_rhs[i] != 0; i++) {
+ buf.append(Parser.readableName[Parser.scope_rhs[i]]);
+ if (Parser.scope_rhs[i + 1] != 0) // any more symbols to print?
+ buf.append(' ');
+
+ }
+
+ if (scopeNameIndex != 0) {
+ problemReporter().parseErrorInsertToComplete(
+ errorStart,
+ errorEnd,
+ buf.toString(),
+ Parser.readableName[scopeNameIndex]);
+ } else {
+ problemReporter().parseErrorInsertToCompleteScope(
+ errorStart,
+ errorEnd,
+ buf.toString());
+ }
+
+ break;
+ case EOF_CODE:
+ problemReporter().parseErrorUnexpectedEnd(
+ errorStart,
+ errorEnd);
+ break;
+ case MERGE_CODE:
+ problemReporter().parseErrorMergeTokens(
+ errorStart,
+ errorEnd,
+ name);
+ break;
+ case MISPLACED_CODE:
+ problemReporter().parseErrorMisplacedConstruct(
+ errorStart,
+ errorEnd);
+ break;
+ default:
+ if (name.length() == 0) {
+ problemReporter().parseErrorNoSuggestion(
+ errorStart,
+ errorEnd,
+ currentKind,
+ errorTokenSource,
+ errorTokenName);
+ } else {
+ problemReporter().parseErrorReplaceToken(
+ errorStart,
+ errorEnd,
+ currentKind,
+ errorTokenSource,
+ errorTokenName,
+ name);
+ }
+ break;
+ }
+ }
+
+ private void reportSecondaryError(int msgCode, int nameIndex, int leftToken, int rightToken, int scopeNameIndex) {
+ String name;
+ if (nameIndex >= 0) {
+ name = Parser.readableName[nameIndex];
+ } else {
+ name = EMPTY_STRING;
+ }
+
+ int errorStart = -1;
+ if(lexStream.isInsideStream(leftToken)) {
+ if(leftToken == 0) {
+ errorStart = lexStream.start(leftToken + 1);
+ } else {
+ errorStart = lexStream.start(leftToken);
+ }
+ } else {
+ if(leftToken == errorToken) {
+ errorStart = errorTokenStart;
+ } else {
+ for (int i = 0; i <= stateStackTop; i++) {
+ if(locationStack[i] == leftToken) {
+ errorStart = locationStartStack[i];
+ }
+ }
+ }
+ if(errorStart == -1) {
+ errorStart = lexStream.start(rightToken);
+ }
+ }
+ int errorEnd = lexStream.end(rightToken);
+
+ switch(msgCode) {
+ case MISPLACED_CODE:
+ problemReporter().parseErrorMisplacedConstruct(
+ errorStart,
+ errorEnd);
+ break;
+ case SCOPE_CODE:
+ // error start is on the last token start
+ errorStart = lexStream.start(rightToken);
+
+ StringBuffer buf = new StringBuffer();
+ for (int i = Parser.scope_suffix[- nameIndex]; Parser.scope_rhs[i] != 0; i++) {
+ buf.append(Parser.readableName[Parser.scope_rhs[i]]);
+ if (Parser.scope_rhs[i+1] != 0)
+ buf.append(' ');
+ }
+ if (scopeNameIndex != 0) {
+ problemReporter().parseErrorInsertToComplete(
+ errorStart,
+ errorEnd,
+ buf.toString(),
+ Parser.readableName[scopeNameIndex]);
+ } else {
+ problemReporter().parseErrorInsertToCompletePhrase(
+ errorStart,
+ errorEnd,
+ buf.toString());
+ }
+ break;
+ case MERGE_CODE:
+ problemReporter().parseErrorMergeTokens(
+ errorStart,
+ errorEnd,
+ name);
+ break;
+ case DELETION_CODE:
+ problemReporter().parseErrorDeleteTokens(
+ errorStart,
+ errorEnd);
+ break;
+ default:
+ if (name.length() == 0) {
+ problemReporter().parseErrorNoSuggestionForTokens(
+ errorStart,
+ errorEnd);
+ } else {
+ problemReporter().parseErrorReplaceTokens(
+ errorStart,
+ errorEnd,
+ name);
+ }
+ }
+ return;
+ }
+
+ public String toString() {
+ StringBuffer res = new StringBuffer();
+
+ res.append(lexStream.toString());
+
+ return res.toString();
+ }
+}