Source Code Cross Referenced for NativeRegExp.java in  » IDE-Netbeans » library » org » mozilla » javascript » regexp » Java Source Code / Java DocumentationJava Source Code and Java Documentation

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Java Source Code / Java Documentation » IDE Netbeans » library » org.mozilla.javascript.regexp 
Source Cross Referenced  Class Diagram Java Document (Java Doc) 


0001:        /* -*- Mode: java; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 4 -*-
0002:         *
0003:         * ***** BEGIN LICENSE BLOCK *****
0004:         * Version: MPL 1.1/GPL 2.0
0005:         *
0006:         * The contents of this file are subject to the Mozilla Public License Version
0007:         * 1.1 (the "License"); you may not use this file except in compliance with
0008:         * the License. You may obtain a copy of the License at
0009:         * http://www.mozilla.org/MPL/
0010:         *
0011:         * Software distributed under the License is distributed on an "AS IS" basis,
0012:         * WITHOUT WARRANTY OF ANY KIND, either express or implied. See the License
0013:         * for the specific language governing rights and limitations under the
0014:         * License.
0015:         *
0016:         * The Original Code is Rhino code, released
0017:         * May 6, 1998.
0018:         *
0019:         * The Initial Developer of the Original Code is
0020:         * Netscape Communications Corporation.
0021:         * Portions created by the Initial Developer are Copyright (C) 1997-1999
0022:         * the Initial Developer. All Rights Reserved.
0023:         *
0024:         * Contributor(s):
0025:         *   Norris Boyd
0026:         *   Igor Bukanov
0027:         *   Brendan Eich
0028:         *   Matthias Radestock
0029:         *
0030:         * Alternatively, the contents of this file may be used under the terms of
0031:         * the GNU General Public License Version 2 or later (the "GPL"), in which
0032:         * case the provisions of the GPL are applicable instead of those above. If
0033:         * you wish to allow use of your version of this file only under the terms of
0034:         * the GPL and not to allow others to use your version of this file under the
0035:         * MPL, indicate your decision by deleting the provisions above and replacing
0036:         * them with the notice and other provisions required by the GPL. If you do
0037:         * not delete the provisions above, a recipient may use your version of this
0038:         * file under either the MPL or the GPL.
0039:         *
0040:         * ***** END LICENSE BLOCK ***** */
0041:
0042:        package org.mozilla.javascript.regexp;
0043:
0044:        import java.io.Serializable;
0045:
0046:        import org.mozilla.javascript.Context;
0047:        import org.mozilla.javascript.Function;
0048:        import org.mozilla.javascript.IdFunctionObject;
0049:        import org.mozilla.javascript.IdScriptableObject;
0050:        import org.mozilla.javascript.Kit;
0051:        import org.mozilla.javascript.ScriptRuntime;
0052:        import org.mozilla.javascript.Scriptable;
0053:        import org.mozilla.javascript.ScriptableObject;
0054:        import org.mozilla.javascript.Undefined;
0055:
0056:        /**
0057:         * This class implements the RegExp native object.
0058:         *
0059:         * Revision History:
0060:         * Implementation in C by Brendan Eich
0061:         * Initial port to Java by Norris Boyd from jsregexp.c version 1.36
0062:         * Merged up to version 1.38, which included Unicode support.
0063:         * Merged bug fixes in version 1.39.
0064:         * Merged JSFUN13_BRANCH changes up to 1.32.2.13
0065:         *
0066:         * @author Brendan Eich
0067:         * @author Norris Boyd
0068:         */
0069:
0070:        public class NativeRegExp extends IdScriptableObject implements 
0071:                Function {
0072:            static final long serialVersionUID = 4965263491464903264L;
0073:
0074:            private static final Object REGEXP_TAG = new Object();
0075:
0076:            public static final int JSREG_GLOB = 0x1; // 'g' flag: global
0077:            public static final int JSREG_FOLD = 0x2; // 'i' flag: fold
0078:            public static final int JSREG_MULTILINE = 0x4; // 'm' flag: multiline
0079:
0080:            //type of match to perform
0081:            public static final int TEST = 0;
0082:            public static final int MATCH = 1;
0083:            public static final int PREFIX = 2;
0084:
0085:            private static final boolean debug = false;
0086:
0087:            private static final byte REOP_EMPTY = 0; /* match rest of input against rest of r.e. */
0088:            private static final byte REOP_ALT = 1; /* alternative subexpressions in kid and next */
0089:            private static final byte REOP_BOL = 2; /* beginning of input (or line if multiline) */
0090:            private static final byte REOP_EOL = 3; /* end of input (or line if multiline) */
0091:            private static final byte REOP_WBDRY = 4; /* match "" at word boundary */
0092:            private static final byte REOP_WNONBDRY = 5; /* match "" at word non-boundary */
0093:            private static final byte REOP_QUANT = 6; /* quantified atom: atom{1,2} */
0094:            private static final byte REOP_STAR = 7; /* zero or more occurrences of kid */
0095:            private static final byte REOP_PLUS = 8; /* one or more occurrences of kid */
0096:            private static final byte REOP_OPT = 9; /* optional subexpression in kid */
0097:            private static final byte REOP_LPAREN = 10; /* left paren bytecode: kid is u.num'th sub-regexp */
0098:            private static final byte REOP_RPAREN = 11; /* right paren bytecode */
0099:            private static final byte REOP_DOT = 12; /* stands for any character */
0100:            private static final byte REOP_CCLASS = 13; /* character class: [a-f] */
0101:            private static final byte REOP_DIGIT = 14; /* match a digit char: [0-9] */
0102:            private static final byte REOP_NONDIGIT = 15; /* match a non-digit char: [^0-9] */
0103:            private static final byte REOP_ALNUM = 16; /* match an alphanumeric char: [0-9a-z_A-Z] */
0104:            private static final byte REOP_NONALNUM = 17; /* match a non-alphanumeric char: [^0-9a-z_A-Z] */
0105:            private static final byte REOP_SPACE = 18; /* match a whitespace char */
0106:            private static final byte REOP_NONSPACE = 19; /* match a non-whitespace char */
0107:            private static final byte REOP_BACKREF = 20; /* back-reference (e.g., \1) to a parenthetical */
0108:            private static final byte REOP_FLAT = 21; /* match a flat string */
0109:            private static final byte REOP_FLAT1 = 22; /* match a single char */
0110:            private static final byte REOP_JUMP = 23; /* for deoptimized closure loops */
0111:            private static final byte REOP_DOTSTAR = 24; /* optimize .* to use a single opcode */
0112:            private static final byte REOP_ANCHOR = 25; /* like .* but skips left context to unanchored r.e. */
0113:            private static final byte REOP_EOLONLY = 26; /* $ not preceded by any pattern */
0114:            private static final byte REOP_UCFLAT = 27; /* flat Unicode string; len immediate counts chars */
0115:            private static final byte REOP_UCFLAT1 = 28; /* single Unicode char */
0116:            private static final byte REOP_UCCLASS = 29; /* Unicode character class, vector of chars to match */
0117:            private static final byte REOP_NUCCLASS = 30; /* negated Unicode character class */
0118:            private static final byte REOP_BACKREFi = 31; /* case-independent REOP_BACKREF */
0119:            private static final byte REOP_FLATi = 32; /* case-independent REOP_FLAT */
0120:            private static final byte REOP_FLAT1i = 33; /* case-independent REOP_FLAT1 */
0121:            private static final byte REOP_UCFLATi = 34; /* case-independent REOP_UCFLAT */
0122:            private static final byte REOP_UCFLAT1i = 35; /* case-independent REOP_UCFLAT1 */
0123:            private static final byte REOP_ANCHOR1 = 36; /* first-char discriminating REOP_ANCHOR */
0124:            private static final byte REOP_NCCLASS = 37; /* negated 8-bit character class */
0125:            private static final byte REOP_DOTSTARMIN = 38; /* ungreedy version of REOP_DOTSTAR */
0126:            private static final byte REOP_LPARENNON = 39; /* non-capturing version of REOP_LPAREN */
0127:            private static final byte REOP_RPARENNON = 40; /* non-capturing version of REOP_RPAREN */
0128:            private static final byte REOP_ASSERT = 41; /* zero width positive lookahead assertion */
0129:            private static final byte REOP_ASSERT_NOT = 42; /* zero width negative lookahead assertion */
0130:            private static final byte REOP_ASSERTTEST = 43; /* sentinel at end of assertion child */
0131:            private static final byte REOP_ASSERTNOTTEST = 44; /* sentinel at end of !assertion child */
0132:            private static final byte REOP_MINIMALSTAR = 45; /* non-greedy version of * */
0133:            private static final byte REOP_MINIMALPLUS = 46; /* non-greedy version of + */
0134:            private static final byte REOP_MINIMALOPT = 47; /* non-greedy version of ? */
0135:            private static final byte REOP_MINIMALQUANT = 48; /* non-greedy version of {} */
0136:            private static final byte REOP_ENDCHILD = 49; /* sentinel at end of quantifier child */
0137:            private static final byte REOP_CLASS = 50; /* character class with index */
0138:            private static final byte REOP_REPEAT = 51; /* directs execution of greedy quantifier */
0139:            private static final byte REOP_MINIMALREPEAT = 52; /* directs execution of non-greedy quantifier */
0140:            private static final byte REOP_END = 53;
0141:
0142:            public static void init(Context cx, Scriptable scope, boolean sealed) {
0143:
0144:                NativeRegExp proto = new NativeRegExp();
0145:                proto.re = (RECompiled) compileRE(cx, "", null, false);
0146:                proto.activatePrototypeMap(MAX_PROTOTYPE_ID);
0147:                proto.setParentScope(scope);
0148:                proto.setPrototype(getObjectPrototype(scope));
0149:
0150:                NativeRegExpCtor ctor = new NativeRegExpCtor();
0151:                // Bug #324006: ECMA-262 15.10.6.1 says "The initial value of
0152:                // RegExp.prototype.constructor is the builtin RegExp constructor." 
0153:                proto.put("constructor", proto, ctor);
0154:
0155:                ScriptRuntime.setFunctionProtoAndParent(ctor, scope);
0156:
0157:                ctor.setImmunePrototypeProperty(proto);
0158:
0159:                if (sealed) {
0160:                    proto.sealObject();
0161:                    ctor.sealObject();
0162:                }
0163:
0164:                defineProperty(scope, "RegExp", ctor, ScriptableObject.DONTENUM);
0165:            }
0166:
0167:            NativeRegExp(Scriptable scope, Object regexpCompiled) {
0168:                this .re = (RECompiled) regexpCompiled;
0169:                this .lastIndex = 0;
0170:                ScriptRuntime.setObjectProtoAndParent(this , scope);
0171:            }
0172:
0173:            public String getClassName() {
0174:                return "RegExp";
0175:            }
0176:
0177:            public Object call(Context cx, Scriptable scope,
0178:                    Scriptable this Obj, Object[] args) {
0179:                return execSub(cx, scope, args, MATCH);
0180:            }
0181:
0182:            public Scriptable construct(Context cx, Scriptable scope,
0183:                    Object[] args) {
0184:                return (Scriptable) execSub(cx, scope, args, MATCH);
0185:            }
0186:
0187:            Scriptable compile(Context cx, Scriptable scope, Object[] args) {
0188:                if (args.length > 0 && args[0] instanceof  NativeRegExp) {
0189:                    if (args.length > 1 && args[1] != Undefined.instance) {
0190:                        // report error
0191:                        throw ScriptRuntime
0192:                                .typeError0("msg.bad.regexp.compile");
0193:                    }
0194:                    NativeRegExp thatObj = (NativeRegExp) args[0];
0195:                    this .re = thatObj.re;
0196:                    this .lastIndex = thatObj.lastIndex;
0197:                    return this ;
0198:                }
0199:                String s = args.length == 0 ? "" : ScriptRuntime
0200:                        .toString(args[0]);
0201:                String global = args.length > 1
0202:                        && args[1] != Undefined.instance ? ScriptRuntime
0203:                        .toString(args[1]) : null;
0204:                this .re = (RECompiled) compileRE(cx, s, global, false);
0205:                this .lastIndex = 0;
0206:                return this ;
0207:            }
0208:
0209:            public String toString() {
0210:                StringBuffer buf = new StringBuffer();
0211:                buf.append('/');
0212:                if (re.source.length != 0) {
0213:                    buf.append(re.source);
0214:                } else {
0215:                    // See bugzilla 226045
0216:                    buf.append("(?:)");
0217:                }
0218:                buf.append('/');
0219:                if ((re.flags & JSREG_GLOB) != 0)
0220:                    buf.append('g');
0221:                if ((re.flags & JSREG_FOLD) != 0)
0222:                    buf.append('i');
0223:                if ((re.flags & JSREG_MULTILINE) != 0)
0224:                    buf.append('m');
0225:                return buf.toString();
0226:            }
0227:
0228:            NativeRegExp() {
0229:            }
0230:
0231:            private static RegExpImpl getImpl(Context cx) {
0232:                return (RegExpImpl) ScriptRuntime.getRegExpProxy(cx);
0233:            }
0234:
0235:            private Object execSub(Context cx, Scriptable scopeObj,
0236:                    Object[] args, int matchType) {
0237:                RegExpImpl reImpl = getImpl(cx);
0238:                String str;
0239:                if (args.length == 0) {
0240:                    str = reImpl.input;
0241:                    if (str == null) {
0242:                        reportError("msg.no.re.input.for", toString());
0243:                    }
0244:                } else {
0245:                    str = ScriptRuntime.toString(args[0]);
0246:                }
0247:                double d = ((re.flags & JSREG_GLOB) != 0) ? lastIndex : 0;
0248:
0249:                Object rval;
0250:                if (d < 0 || str.length() < d) {
0251:                    lastIndex = 0;
0252:                    rval = null;
0253:                } else {
0254:                    int indexp[] = { (int) d };
0255:                    rval = executeRegExp(cx, scopeObj, reImpl, str, indexp,
0256:                            matchType);
0257:                    if ((re.flags & JSREG_GLOB) != 0) {
0258:                        lastIndex = (rval == null || rval == Undefined.instance) ? 0
0259:                                : indexp[0];
0260:                    }
0261:                }
0262:                return rval;
0263:            }
0264:
0265:            static Object compileRE(Context cx, String str, String global,
0266:                    boolean flat) {
0267:                RECompiled regexp = new RECompiled();
0268:                regexp.source = str.toCharArray();
0269:                int length = str.length();
0270:
0271:                int flags = 0;
0272:                if (global != null) {
0273:                    for (int i = 0; i < global.length(); i++) {
0274:                        char c = global.charAt(i);
0275:                        if (c == 'g') {
0276:                            flags |= JSREG_GLOB;
0277:                        } else if (c == 'i') {
0278:                            flags |= JSREG_FOLD;
0279:                        } else if (c == 'm') {
0280:                            flags |= JSREG_MULTILINE;
0281:                        } else {
0282:                            reportError("msg.invalid.re.flag", String
0283:                                    .valueOf(c));
0284:                        }
0285:                    }
0286:                }
0287:                regexp.flags = flags;
0288:
0289:                CompilerState state = new CompilerState(cx, regexp.source,
0290:                        length, flags);
0291:                if (flat && length > 0) {
0292:                    if (debug) {
0293:                        System.out.println("flat = \"" + str + "\"");
0294:                    }
0295:                    state.result = new RENode(REOP_FLAT);
0296:                    state.result.chr = state.cpbegin[0];
0297:                    state.result.length = length;
0298:                    state.result.flatIndex = 0;
0299:                    state.progLength += 5;
0300:                } else if (!parseDisjunction(state))
0301:                    return null;
0302:
0303:                regexp.program = new byte[state.progLength + 1];
0304:                if (state.classCount != 0) {
0305:                    regexp.classList = new RECharSet[state.classCount];
0306:                    regexp.classCount = state.classCount;
0307:                }
0308:                int endPC = emitREBytecode(state, regexp, 0, state.result);
0309:                regexp.program[endPC++] = REOP_END;
0310:
0311:                if (debug) {
0312:                    System.out.println("Prog. length = " + endPC);
0313:                    for (int i = 0; i < endPC; i++) {
0314:                        System.out.print(regexp.program[i]);
0315:                        if (i < (endPC - 1))
0316:                            System.out.print(", ");
0317:                    }
0318:                    System.out.println();
0319:                }
0320:                regexp.parenCount = state.parenCount;
0321:
0322:                // If re starts with literal, init anchorCh accordingly
0323:                switch (regexp.program[0]) {
0324:                case REOP_UCFLAT1:
0325:                case REOP_UCFLAT1i:
0326:                    regexp.anchorCh = (char) getIndex(regexp.program, 1);
0327:                    break;
0328:                case REOP_FLAT1:
0329:                case REOP_FLAT1i:
0330:                    regexp.anchorCh = (char) (regexp.program[1] & 0xFF);
0331:                    break;
0332:                case REOP_FLAT:
0333:                case REOP_FLATi:
0334:                    int k = getIndex(regexp.program, 1);
0335:                    regexp.anchorCh = regexp.source[k];
0336:                    break;
0337:                }
0338:
0339:                if (debug) {
0340:                    if (regexp.anchorCh >= 0) {
0341:                        System.out.println("Anchor ch = '"
0342:                                + (char) regexp.anchorCh + "'");
0343:                    }
0344:                }
0345:                return regexp;
0346:            }
0347:
0348:            static boolean isDigit(char c) {
0349:                return '0' <= c && c <= '9';
0350:            }
0351:
0352:            private static boolean isWord(char c) {
0353:                return Character.isLetter(c) || isDigit(c) || c == '_';
0354:            }
0355:
0356:            private static boolean isLineTerm(char c) {
0357:                return ScriptRuntime.isJSLineTerminator(c);
0358:            }
0359:
0360:            private static boolean isREWhiteSpace(int c) {
0361:                return (c == '\u0020' || c == '\u0009' || c == '\n'
0362:                        || c == '\r' || c == 0x2028 || c == 0x2029
0363:                        || c == '\u000C' || c == '\u000B' || c == '\u00A0' || Character
0364:                        .getType((char) c) == Character.SPACE_SEPARATOR);
0365:            }
0366:
0367:            /*
0368:             *
0369:             * 1. If IgnoreCase is false, return ch.
0370:             * 2. Let u be ch converted to upper case as if by calling
0371:             *    String.prototype.toUpperCase on the one-character string ch.
0372:             * 3. If u does not consist of a single character, return ch.
0373:             * 4. Let cu be u's character.
0374:             * 5. If ch's code point value is greater than or equal to decimal 128 and cu's
0375:             *    code point value is less than decimal 128, then return ch.
0376:             * 6. Return cu.
0377:             */
0378:            private static char upcase(char ch) {
0379:                if (ch < 128) {
0380:                    if ('a' <= ch && ch <= 'z') {
0381:                        return (char) (ch + ('A' - 'a'));
0382:                    }
0383:                    return ch;
0384:                }
0385:                char cu = Character.toUpperCase(ch);
0386:                if ((ch >= 128) && (cu < 128))
0387:                    return ch;
0388:                return cu;
0389:            }
0390:
0391:            private static char downcase(char ch) {
0392:                if (ch < 128) {
0393:                    if ('A' <= ch && ch <= 'Z') {
0394:                        return (char) (ch + ('a' - 'A'));
0395:                    }
0396:                    return ch;
0397:                }
0398:                char cl = Character.toLowerCase(ch);
0399:                if ((ch >= 128) && (cl < 128))
0400:                    return ch;
0401:                return cl;
0402:            }
0403:
0404:            /*
0405:             * Validates and converts hex ascii value.
0406:             */
0407:            private static int toASCIIHexDigit(int c) {
0408:                if (c < '0')
0409:                    return -1;
0410:                if (c <= '9') {
0411:                    return c - '0';
0412:                }
0413:                c |= 0x20;
0414:                if ('a' <= c && c <= 'f') {
0415:                    return c - 'a' + 10;
0416:                }
0417:                return -1;
0418:            }
0419:
0420:            /*
0421:             * Top-down regular expression grammar, based closely on Perl4.
0422:             *
0423:             *  regexp:     altern                  A regular expression is one or more
0424:             *              altern '|' regexp       alternatives separated by vertical bar.
0425:             */
0426:            private static boolean parseDisjunction(CompilerState state) {
0427:                if (!parseAlternative(state))
0428:                    return false;
0429:                char[] source = state.cpbegin;
0430:                int index = state.cp;
0431:                if (index != source.length && source[index] == '|') {
0432:                    RENode altResult;
0433:                    ++state.cp;
0434:                    altResult = new RENode(REOP_ALT);
0435:                    altResult.kid = state.result;
0436:                    if (!parseDisjunction(state))
0437:                        return false;
0438:                    altResult.kid2 = state.result;
0439:                    state.result = altResult;
0440:                    /* ALT, <next>, ..., JUMP, <end> ... JUMP <end> */
0441:                    state.progLength += 9;
0442:                }
0443:                return true;
0444:            }
0445:
0446:            /*
0447:             *  altern:     item                    An alternative is one or more items,
0448:             *              item altern             concatenated together.
0449:             */
0450:            private static boolean parseAlternative(CompilerState state) {
0451:                RENode headTerm = null;
0452:                RENode tailTerm = null;
0453:                char[] source = state.cpbegin;
0454:                while (true) {
0455:                    if (state.cp == state.cpend
0456:                            || source[state.cp] == '|'
0457:                            || (state.parenNesting != 0 && source[state.cp] == ')')) {
0458:                        if (headTerm == null) {
0459:                            state.result = new RENode(REOP_EMPTY);
0460:                        } else
0461:                            state.result = headTerm;
0462:                        return true;
0463:                    }
0464:                    if (!parseTerm(state))
0465:                        return false;
0466:                    if (headTerm == null)
0467:                        headTerm = state.result;
0468:                    else {
0469:                        if (tailTerm == null) {
0470:                            headTerm.next = state.result;
0471:                            tailTerm = state.result;
0472:                            while (tailTerm.next != null)
0473:                                tailTerm = tailTerm.next;
0474:                        } else {
0475:                            tailTerm.next = state.result;
0476:                            tailTerm = tailTerm.next;
0477:                            while (tailTerm.next != null)
0478:                                tailTerm = tailTerm.next;
0479:                        }
0480:                    }
0481:                }
0482:            }
0483:
0484:            /* calculate the total size of the bitmap required for a class expression */
0485:            private static boolean calculateBitmapSize(CompilerState state,
0486:                    RENode target, char[] src, int index, int end) {
0487:                char rangeStart = 0;
0488:                char c;
0489:                int n;
0490:                int nDigits;
0491:                int i;
0492:                int max = 0;
0493:                boolean inRange = false;
0494:
0495:                target.bmsize = 0;
0496:
0497:                if (index == end)
0498:                    return true;
0499:
0500:                if (src[index] == '^')
0501:                    ++index;
0502:
0503:                while (index != end) {
0504:                    int localMax = 0;
0505:                    nDigits = 2;
0506:                    switch (src[index]) {
0507:                    case '\\':
0508:                        ++index;
0509:                        c = src[index++];
0510:                        switch (c) {
0511:                        case 'b':
0512:                            localMax = 0x8;
0513:                            break;
0514:                        case 'f':
0515:                            localMax = 0xC;
0516:                            break;
0517:                        case 'n':
0518:                            localMax = 0xA;
0519:                            break;
0520:                        case 'r':
0521:                            localMax = 0xD;
0522:                            break;
0523:                        case 't':
0524:                            localMax = 0x9;
0525:                            break;
0526:                        case 'v':
0527:                            localMax = 0xB;
0528:                            break;
0529:                        case 'c':
0530:                            if (((index + 1) < end)
0531:                                    && Character.isLetter(src[index + 1]))
0532:                                localMax = (char) (src[index++] & 0x1F);
0533:                            else
0534:                                localMax = '\\';
0535:                            break;
0536:                        case 'u':
0537:                            nDigits += 2;
0538:                            // fall thru...
0539:                        case 'x':
0540:                            n = 0;
0541:                            for (i = 0; (i < nDigits) && (index < end); i++) {
0542:                                c = src[index++];
0543:                                n = Kit.xDigitToInt(c, n);
0544:                                if (n < 0) {
0545:                                    // Back off to accepting the original
0546:                                    // '\' as a literal
0547:                                    index -= (i + 1);
0548:                                    n = '\\';
0549:                                    break;
0550:                                }
0551:                            }
0552:                            localMax = n;
0553:                            break;
0554:                        case 'd':
0555:                            if (inRange) {
0556:                                reportError("msg.bad.range", "");
0557:                                return false;
0558:                            }
0559:                            localMax = '9';
0560:                            break;
0561:                        case 'D':
0562:                        case 's':
0563:                        case 'S':
0564:                        case 'w':
0565:                        case 'W':
0566:                            if (inRange) {
0567:                                reportError("msg.bad.range", "");
0568:                                return false;
0569:                            }
0570:                            target.bmsize = 65535;
0571:                            return true;
0572:                        case '0':
0573:                        case '1':
0574:                        case '2':
0575:                        case '3':
0576:                        case '4':
0577:                        case '5':
0578:                        case '6':
0579:                        case '7':
0580:                            /*
0581:                             *  This is a non-ECMA extension - decimal escapes (in this
0582:                             *  case, octal!) are supposed to be an error inside class
0583:                             *  ranges, but supported here for backwards compatibility.
0584:                             *
0585:                             */
0586:                            n = (c - '0');
0587:                            c = src[index];
0588:                            if ('0' <= c && c <= '7') {
0589:                                index++;
0590:                                n = 8 * n + (c - '0');
0591:                                c = src[index];
0592:                                if ('0' <= c && c <= '7') {
0593:                                    index++;
0594:                                    i = 8 * n + (c - '0');
0595:                                    if (i <= 0377)
0596:                                        n = i;
0597:                                    else
0598:                                        index--;
0599:                                }
0600:                            }
0601:                            localMax = n;
0602:                            break;
0603:
0604:                        default:
0605:                            localMax = c;
0606:                            break;
0607:                        }
0608:                        break;
0609:                    default:
0610:                        localMax = src[index++];
0611:                        break;
0612:                    }
0613:                    if (inRange) {
0614:                        if (rangeStart > localMax) {
0615:                            reportError("msg.bad.range", "");
0616:                            return false;
0617:                        }
0618:                        inRange = false;
0619:                    } else {
0620:                        if (index < (end - 1)) {
0621:                            if (src[index] == '-') {
0622:                                ++index;
0623:                                inRange = true;
0624:                                rangeStart = (char) localMax;
0625:                                continue;
0626:                            }
0627:                        }
0628:                    }
0629:                    if ((state.flags & JSREG_FOLD) != 0) {
0630:                        char cu = upcase((char) localMax);
0631:                        char cd = downcase((char) localMax);
0632:                        localMax = (cu >= cd) ? cu : cd;
0633:                    }
0634:                    if (localMax > max)
0635:                        max = localMax;
0636:                }
0637:                target.bmsize = max;
0638:                return true;
0639:            }
0640:
0641:            /*
0642:             *  item:       assertion               An item is either an assertion or
0643:             *              quantatom               a quantified atom.
0644:             *
0645:             *  assertion:  '^'                     Assertions match beginning of string
0646:             *                                      (or line if the class static property
0647:             *                                      RegExp.multiline is true).
0648:             *              '$'                     End of string (or line if the class
0649:             *                                      static property RegExp.multiline is
0650:             *                                      true).
0651:             *              '\b'                    Word boundary (between \w and \W).
0652:             *              '\B'                    Word non-boundary.
0653:             *
0654:             *  quantatom:  atom                    An unquantified atom.
0655:             *              quantatom '{' n ',' m '}'
0656:             *                                      Atom must occur between n and m times.
0657:             *              quantatom '{' n ',' '}' Atom must occur at least n times.
0658:             *              quantatom '{' n '}'     Atom must occur exactly n times.
0659:             *              quantatom '*'           Zero or more times (same as {0,}).
0660:             *              quantatom '+'           One or more times (same as {1,}).
0661:             *              quantatom '?'           Zero or one time (same as {0,1}).
0662:             *
0663:             *              any of which can be optionally followed by '?' for ungreedy
0664:             *
0665:             *  atom:       '(' regexp ')'          A parenthesized regexp (what matched
0666:             *                                      can be addressed using a backreference,
0667:             *                                      see '\' n below).
0668:             *              '.'                     Matches any char except '\n'.
0669:             *              '[' classlist ']'       A character class.
0670:             *              '[' '^' classlist ']'   A negated character class.
0671:             *              '\f'                    Form Feed.
0672:             *              '\n'                    Newline (Line Feed).
0673:             *              '\r'                    Carriage Return.
0674:             *              '\t'                    Horizontal Tab.
0675:             *              '\v'                    Vertical Tab.
0676:             *              '\d'                    A digit (same as [0-9]).
0677:             *              '\D'                    A non-digit.
0678:             *              '\w'                    A word character, [0-9a-z_A-Z].
0679:             *              '\W'                    A non-word character.
0680:             *              '\s'                    A whitespace character, [ \b\f\n\r\t\v].
0681:             *              '\S'                    A non-whitespace character.
0682:             *              '\' n                   A backreference to the nth (n decimal
0683:             *                                      and positive) parenthesized expression.
0684:             *              '\' octal               An octal escape sequence (octal must be
0685:             *                                      two or three digits long, unless it is
0686:             *                                      0 for the null character).
0687:             *              '\x' hex                A hex escape (hex must be two digits).
0688:             *              '\c' ctrl               A control character, ctrl is a letter.
0689:             *              '\' literalatomchar     Any character except one of the above
0690:             *                                      that follow '\' in an atom.
0691:             *              otheratomchar           Any character not first among the other
0692:             *                                      atom right-hand sides.
0693:             */
0694:
0695:            private static void doFlat(CompilerState state, char c) {
0696:                state.result = new RENode(REOP_FLAT);
0697:                state.result.chr = c;
0698:                state.result.length = 1;
0699:                state.result.flatIndex = -1;
0700:                state.progLength += 3;
0701:            }
0702:
0703:            private static int getDecimalValue(char c, CompilerState state,
0704:                    int maxValue, String overflowMessageId) {
0705:                boolean overflow = false;
0706:                int start = state.cp;
0707:                char[] src = state.cpbegin;
0708:                int value = c - '0';
0709:                for (; state.cp != state.cpend; ++state.cp) {
0710:                    c = src[state.cp];
0711:                    if (!isDigit(c)) {
0712:                        break;
0713:                    }
0714:                    if (!overflow) {
0715:                        int digit = c - '0';
0716:                        if (value < (maxValue - digit) / 10) {
0717:                            value = value * 10 + digit;
0718:                        } else {
0719:                            overflow = true;
0720:                            value = maxValue;
0721:                        }
0722:                    }
0723:                }
0724:                if (overflow) {
0725:                    reportError(overflowMessageId, String.valueOf(src, start,
0726:                            state.cp - start));
0727:                }
0728:                return value;
0729:            }
0730:
0731:            private static boolean parseTerm(CompilerState state) {
0732:                char[] src = state.cpbegin;
0733:                char c = src[state.cp++];
0734:                int nDigits = 2;
0735:                int parenBaseCount = state.parenCount;
0736:                int num, tmp;
0737:                RENode term;
0738:                int termStart;
0739:
0740:                switch (c) {
0741:                /* assertions and atoms */
0742:                case '^':
0743:                    state.result = new RENode(REOP_BOL);
0744:                    state.progLength++;
0745:                    return true;
0746:                case '$':
0747:                    state.result = new RENode(REOP_EOL);
0748:                    state.progLength++;
0749:                    return true;
0750:                case '\\':
0751:                    if (state.cp < state.cpend) {
0752:                        c = src[state.cp++];
0753:                        switch (c) {
0754:                        /* assertion escapes */
0755:                        case 'b':
0756:                            state.result = new RENode(REOP_WBDRY);
0757:                            state.progLength++;
0758:                            return true;
0759:                        case 'B':
0760:                            state.result = new RENode(REOP_WNONBDRY);
0761:                            state.progLength++;
0762:                            return true;
0763:                            /* Decimal escape */
0764:                        case '0':
0765:                            /*
0766:                             * Under 'strict' ECMA 3, we interpret \0 as NUL and don't accept octal.
0767:                             * However, (XXX and since Rhino doesn't have a 'strict' mode) we'll just
0768:                             * behave the old way for compatibility reasons.
0769:                             * (see http://bugzilla.mozilla.org/show_bug.cgi?id=141078)
0770:                             *
0771:                             */
0772:                            reportWarning(state.cx, "msg.bad.backref", "");
0773:                            /* octal escape */
0774:                            num = 0;
0775:                            while (state.cp < state.cpend) {
0776:                                c = src[state.cp];
0777:                                if ((c >= '0') && (c <= '7')) {
0778:                                    state.cp++;
0779:                                    tmp = 8 * num + (c - '0');
0780:                                    if (tmp > 0377)
0781:                                        break;
0782:                                    num = tmp;
0783:                                } else
0784:                                    break;
0785:                            }
0786:                            c = (char) (num);
0787:                            doFlat(state, c);
0788:                            break;
0789:                        case '1':
0790:                        case '2':
0791:                        case '3':
0792:                        case '4':
0793:                        case '5':
0794:                        case '6':
0795:                        case '7':
0796:                        case '8':
0797:                        case '9':
0798:                            termStart = state.cp - 1;
0799:                            num = getDecimalValue(c, state, 0xFFFF,
0800:                                    "msg.overlarge.backref");
0801:                            if (num > state.parenCount)
0802:                                reportWarning(state.cx, "msg.bad.backref", "");
0803:                            /*
0804:                             * n > 9 or > count of parentheses,
0805:                             * then treat as octal instead.
0806:                             */
0807:                            if ((num > 9) && (num > state.parenCount)) {
0808:                                state.cp = termStart;
0809:                                num = 0;
0810:                                while (state.cp < state.cpend) {
0811:                                    c = src[state.cp];
0812:                                    if ((c >= '0') && (c <= '7')) {
0813:                                        state.cp++;
0814:                                        tmp = 8 * num + (c - '0');
0815:                                        if (tmp > 0377)
0816:                                            break;
0817:                                        num = tmp;
0818:                                    } else
0819:                                        break;
0820:                                }
0821:                                c = (char) (num);
0822:                                doFlat(state, c);
0823:                                break;
0824:                            }
0825:                            /* otherwise, it's a back-reference */
0826:                            state.result = new RENode(REOP_BACKREF);
0827:                            state.result.parenIndex = num - 1;
0828:                            state.progLength += 3;
0829:                            break;
0830:                        /* Control escape */
0831:                        case 'f':
0832:                            c = 0xC;
0833:                            doFlat(state, c);
0834:                            break;
0835:                        case 'n':
0836:                            c = 0xA;
0837:                            doFlat(state, c);
0838:                            break;
0839:                        case 'r':
0840:                            c = 0xD;
0841:                            doFlat(state, c);
0842:                            break;
0843:                        case 't':
0844:                            c = 0x9;
0845:                            doFlat(state, c);
0846:                            break;
0847:                        case 'v':
0848:                            c = 0xB;
0849:                            doFlat(state, c);
0850:                            break;
0851:                        /* Control letter */
0852:                        case 'c':
0853:                            if (((state.cp + 1) < state.cpend)
0854:                                    && Character.isLetter(src[state.cp + 1]))
0855:                                c = (char) (src[state.cp++] & 0x1F);
0856:                            else {
0857:                                /* back off to accepting the original '\' as a literal */
0858:                                --state.cp;
0859:                                c = '\\';
0860:                            }
0861:                            doFlat(state, c);
0862:                            break;
0863:                        /* UnicodeEscapeSequence */
0864:                        case 'u':
0865:                            nDigits += 2;
0866:                            // fall thru...
0867:                            /* HexEscapeSequence */
0868:                        case 'x': {
0869:                            int n = 0;
0870:                            int i;
0871:                            for (i = 0; (i < nDigits)
0872:                                    && (state.cp < state.cpend); i++) {
0873:                                c = src[state.cp++];
0874:                                n = Kit.xDigitToInt(c, n);
0875:                                if (n < 0) {
0876:                                    // Back off to accepting the original
0877:                                    // 'u' or 'x' as a literal
0878:                                    state.cp -= (i + 2);
0879:                                    n = src[state.cp++];
0880:                                    break;
0881:                                }
0882:                            }
0883:                            c = (char) (n);
0884:                        }
0885:                            doFlat(state, c);
0886:                            break;
0887:                        /* Character class escapes */
0888:                        case 'd':
0889:                            state.result = new RENode(REOP_DIGIT);
0890:                            state.progLength++;
0891:                            break;
0892:                        case 'D':
0893:                            state.result = new RENode(REOP_NONDIGIT);
0894:                            state.progLength++;
0895:                            break;
0896:                        case 's':
0897:                            state.result = new RENode(REOP_SPACE);
0898:                            state.progLength++;
0899:                            break;
0900:                        case 'S':
0901:                            state.result = new RENode(REOP_NONSPACE);
0902:                            state.progLength++;
0903:                            break;
0904:                        case 'w':
0905:                            state.result = new RENode(REOP_ALNUM);
0906:                            state.progLength++;
0907:                            break;
0908:                        case 'W':
0909:                            state.result = new RENode(REOP_NONALNUM);
0910:                            state.progLength++;
0911:                            break;
0912:                        /* IdentityEscape */
0913:                        default:
0914:                            state.result = new RENode(REOP_FLAT);
0915:                            state.result.chr = c;
0916:                            state.result.length = 1;
0917:                            state.result.flatIndex = state.cp - 1;
0918:                            state.progLength += 3;
0919:                            break;
0920:                        }
0921:                        break;
0922:                    } else {
0923:                        /* a trailing '\' is an error */
0924:                        reportError("msg.trail.backslash", "");
0925:                        return false;
0926:                    }
0927:                case '(': {
0928:                    RENode result = null;
0929:                    termStart = state.cp;
0930:                    if (state.cp + 1 < state.cpend
0931:                            && src[state.cp] == '?'
0932:                            && ((c = src[state.cp + 1]) == '=' || c == '!' || c == ':')) {
0933:                        state.cp += 2;
0934:                        if (c == '=') {
0935:                            result = new RENode(REOP_ASSERT);
0936:                            /* ASSERT, <next>, ... ASSERTTEST */
0937:                            state.progLength += 4;
0938:                        } else if (c == '!') {
0939:                            result = new RENode(REOP_ASSERT_NOT);
0940:                            /* ASSERTNOT, <next>, ... ASSERTNOTTEST */
0941:                            state.progLength += 4;
0942:                        }
0943:                    } else {
0944:                        result = new RENode(REOP_LPAREN);
0945:                        /* LPAREN, <index>, ... RPAREN, <index> */
0946:                        state.progLength += 6;
0947:                        result.parenIndex = state.parenCount++;
0948:                    }
0949:                    ++state.parenNesting;
0950:                    if (!parseDisjunction(state))
0951:                        return false;
0952:                    if (state.cp == state.cpend || src[state.cp] != ')') {
0953:                        reportError("msg.unterm.paren", "");
0954:                        return false;
0955:                    }
0956:                    ++state.cp;
0957:                    --state.parenNesting;
0958:                    if (result != null) {
0959:                        result.kid = state.result;
0960:                        state.result = result;
0961:                    }
0962:                    break;
0963:                }
0964:                case ')':
0965:                    reportError("msg.re.unmatched.right.paren", "");
0966:                    return false;
0967:                case '[':
0968:                    state.result = new RENode(REOP_CLASS);
0969:                    termStart = state.cp;
0970:                    state.result.startIndex = termStart;
0971:                    while (true) {
0972:                        if (state.cp == state.cpend) {
0973:                            reportError("msg.unterm.class", "");
0974:                            return false;
0975:                        }
0976:                        if (src[state.cp] == '\\')
0977:                            state.cp++;
0978:                        else {
0979:                            if (src[state.cp] == ']') {
0980:                                state.result.kidlen = state.cp - termStart;
0981:                                break;
0982:                            }
0983:                        }
0984:                        state.cp++;
0985:                    }
0986:                    state.result.index = state.classCount++;
0987:                    /*
0988:                     * Call calculateBitmapSize now as we want any errors it finds
0989:                     * to be reported during the parse phase, not at execution.
0990:                     */
0991:                    if (!calculateBitmapSize(state, state.result, src,
0992:                            termStart, state.cp++))
0993:                        return false;
0994:                    state.progLength += 3; /* CLASS, <index> */
0995:                    break;
0996:
0997:                case '.':
0998:                    state.result = new RENode(REOP_DOT);
0999:                    state.progLength++;
1000:                    break;
1001:                case '*':
1002:                case '+':
1003:                case '?':
1004:                    reportError("msg.bad.quant", String
1005:                            .valueOf(src[state.cp - 1]));
1006:                    return false;
1007:                default:
1008:                    state.result = new RENode(REOP_FLAT);
1009:                    state.result.chr = c;
1010:                    state.result.length = 1;
1011:                    state.result.flatIndex = state.cp - 1;
1012:                    state.progLength += 3;
1013:                    break;
1014:                }
1015:
1016:                term = state.result;
1017:                if (state.cp == state.cpend) {
1018:                    return true;
1019:                }
1020:                boolean hasQ = false;
1021:                switch (src[state.cp]) {
1022:                case '+':
1023:                    state.result = new RENode(REOP_QUANT);
1024:                    state.result.min = 1;
1025:                    state.result.max = -1;
1026:                    /* <PLUS>, <parencount>, <parenindex>, <next> ... <ENDCHILD> */
1027:                    state.progLength += 8;
1028:                    hasQ = true;
1029:                    break;
1030:                case '*':
1031:                    state.result = new RENode(REOP_QUANT);
1032:                    state.result.min = 0;
1033:                    state.result.max = -1;
1034:                    /* <STAR>, <parencount>, <parenindex>, <next> ... <ENDCHILD> */
1035:                    state.progLength += 8;
1036:                    hasQ = true;
1037:                    break;
1038:                case '?':
1039:                    state.result = new RENode(REOP_QUANT);
1040:                    state.result.min = 0;
1041:                    state.result.max = 1;
1042:                    /* <OPT>, <parencount>, <parenindex>, <next> ... <ENDCHILD> */
1043:                    state.progLength += 8;
1044:                    hasQ = true;
1045:                    break;
1046:                case '{': /* balance '}' */
1047:                {
1048:                    int min = 0;
1049:                    int max = -1;
1050:                    int leftCurl = state.cp;
1051:
1052:                    /* For Perl etc. compatibility, if quntifier does not match
1053:                     * \{\d+(,\d*)?\} exactly back off from it
1054:                     * being a quantifier, and chew it up as a literal
1055:                     * atom next time instead.
1056:                     */
1057:
1058:                    c = src[++state.cp];
1059:                    if (isDigit(c)) {
1060:                        ++state.cp;
1061:                        min = getDecimalValue(c, state, 0xFFFF,
1062:                                "msg.overlarge.min");
1063:                        c = src[state.cp];
1064:                        if (c == ',') {
1065:                            c = src[++state.cp];
1066:                            if (isDigit(c)) {
1067:                                ++state.cp;
1068:                                max = getDecimalValue(c, state, 0xFFFF,
1069:                                        "msg.overlarge.max");
1070:                                c = src[state.cp];
1071:                                if (min > max) {
1072:                                    reportError("msg.max.lt.min", String
1073:                                            .valueOf(src[state.cp]));
1074:                                    return false;
1075:                                }
1076:                            }
1077:                        } else {
1078:                            max = min;
1079:                        }
1080:                        /* balance '{' */
1081:                        if (c == '}') {
1082:                            state.result = new RENode(REOP_QUANT);
1083:                            state.result.min = min;
1084:                            state.result.max = max;
1085:                            // QUANT, <min>, <max>, <parencount>,
1086:                            // <parenindex>, <next> ... <ENDCHILD>
1087:                            state.progLength += 12;
1088:                            hasQ = true;
1089:                        }
1090:                    }
1091:                    if (!hasQ) {
1092:                        state.cp = leftCurl;
1093:                    }
1094:                    break;
1095:                }
1096:                }
1097:                if (!hasQ)
1098:                    return true;
1099:
1100:                ++state.cp;
1101:                state.result.kid = term;
1102:                state.result.parenIndex = parenBaseCount;
1103:                state.result.parenCount = state.parenCount - parenBaseCount;
1104:                if ((state.cp < state.cpend) && (src[state.cp] == '?')) {
1105:                    ++state.cp;
1106:                    state.result.greedy = false;
1107:                } else
1108:                    state.result.greedy = true;
1109:                return true;
1110:            }
1111:
1112:            private static void resolveForwardJump(byte[] array, int from,
1113:                    int pc) {
1114:                if (from > pc)
1115:                    throw Kit.codeBug();
1116:                addIndex(array, from, pc - from);
1117:            }
1118:
1119:            private static int getOffset(byte[] array, int pc) {
1120:                return getIndex(array, pc);
1121:            }
1122:
1123:            private static int addIndex(byte[] array, int pc, int index) {
1124:                if (index < 0)
1125:                    throw Kit.codeBug();
1126:                if (index > 0xFFFF)
1127:                    throw Context.reportRuntimeError("Too complex regexp");
1128:                array[pc] = (byte) (index >> 8);
1129:                array[pc + 1] = (byte) (index);
1130:                return pc + 2;
1131:            }
1132:
1133:            private static int getIndex(byte[] array, int pc) {
1134:                return ((array[pc] & 0xFF) << 8) | (array[pc + 1] & 0xFF);
1135:            }
1136:
1137:            private static final int OFFSET_LEN = 2;
1138:            private static final int INDEX_LEN = 2;
1139:
1140:            private static int emitREBytecode(CompilerState state,
1141:                    RECompiled re, int pc, RENode t) {
1142:                RENode nextAlt;
1143:                int nextAltFixup, nextTermFixup;
1144:                byte[] program = re.program;
1145:
1146:                while (t != null) {
1147:                    program[pc++] = t.op;
1148:                    switch (t.op) {
1149:                    case REOP_EMPTY:
1150:                        --pc;
1151:                        break;
1152:                    case REOP_ALT:
1153:                        nextAlt = t.kid2;
1154:                        nextAltFixup = pc; /* address of next alternate */
1155:                        pc += OFFSET_LEN;
1156:                        pc = emitREBytecode(state, re, pc, t.kid);
1157:                        program[pc++] = REOP_JUMP;
1158:                        nextTermFixup = pc; /* address of following term */
1159:                        pc += OFFSET_LEN;
1160:                        resolveForwardJump(program, nextAltFixup, pc);
1161:                        pc = emitREBytecode(state, re, pc, nextAlt);
1162:
1163:                        program[pc++] = REOP_JUMP;
1164:                        nextAltFixup = pc;
1165:                        pc += OFFSET_LEN;
1166:
1167:                        resolveForwardJump(program, nextTermFixup, pc);
1168:                        resolveForwardJump(program, nextAltFixup, pc);
1169:                        break;
1170:                    case REOP_FLAT:
1171:                        /*
1172:                         * Consecutize FLAT's if possible.
1173:                         */
1174:                        if (t.flatIndex != -1) {
1175:                            while ((t.next != null)
1176:                                    && (t.next.op == REOP_FLAT)
1177:                                    && ((t.flatIndex + t.length) == t.next.flatIndex)) {
1178:                                t.length += t.next.length;
1179:                                t.next = t.next.next;
1180:                            }
1181:                        }
1182:                        if ((t.flatIndex != -1) && (t.length > 1)) {
1183:                            if ((state.flags & JSREG_FOLD) != 0)
1184:                                program[pc - 1] = REOP_FLATi;
1185:                            else
1186:                                program[pc - 1] = REOP_FLAT;
1187:                            pc = addIndex(program, pc, t.flatIndex);
1188:                            pc = addIndex(program, pc, t.length);
1189:                        } else {
1190:                            if (t.chr < 256) {
1191:                                if ((state.flags & JSREG_FOLD) != 0)
1192:                                    program[pc - 1] = REOP_FLAT1i;
1193:                                else
1194:                                    program[pc - 1] = REOP_FLAT1;
1195:                                program[pc++] = (byte) (t.chr);
1196:                            } else {
1197:                                if ((state.flags & JSREG_FOLD) != 0)
1198:                                    program[pc - 1] = REOP_UCFLAT1i;
1199:                                else
1200:                                    program[pc - 1] = REOP_UCFLAT1;
1201:                                pc = addIndex(program, pc, t.chr);
1202:                            }
1203:                        }
1204:                        break;
1205:                    case REOP_LPAREN:
1206:                        pc = addIndex(program, pc, t.parenIndex);
1207:                        pc = emitREBytecode(state, re, pc, t.kid);
1208:                        program[pc++] = REOP_RPAREN;
1209:                        pc = addIndex(program, pc, t.parenIndex);
1210:                        break;
1211:                    case REOP_BACKREF:
1212:                        pc = addIndex(program, pc, t.parenIndex);
1213:                        break;
1214:                    case REOP_ASSERT:
1215:                        nextTermFixup = pc;
1216:                        pc += OFFSET_LEN;
1217:                        pc = emitREBytecode(state, re, pc, t.kid);
1218:                        program[pc++] = REOP_ASSERTTEST;
1219:                        resolveForwardJump(program, nextTermFixup, pc);
1220:                        break;
1221:                    case REOP_ASSERT_NOT:
1222:                        nextTermFixup = pc;
1223:                        pc += OFFSET_LEN;
1224:                        pc = emitREBytecode(state, re, pc, t.kid);
1225:                        program[pc++] = REOP_ASSERTNOTTEST;
1226:                        resolveForwardJump(program, nextTermFixup, pc);
1227:                        break;
1228:                    case REOP_QUANT:
1229:                        if ((t.min == 0) && (t.max == -1))
1230:                            program[pc - 1] = (t.greedy) ? REOP_STAR
1231:                                    : REOP_MINIMALSTAR;
1232:                        else if ((t.min == 0) && (t.max == 1))
1233:                            program[pc - 1] = (t.greedy) ? REOP_OPT
1234:                                    : REOP_MINIMALOPT;
1235:                        else if ((t.min == 1) && (t.max == -1))
1236:                            program[pc - 1] = (t.greedy) ? REOP_PLUS
1237:                                    : REOP_MINIMALPLUS;
1238:                        else {
1239:                            if (!t.greedy)
1240:                                program[pc - 1] = REOP_MINIMALQUANT;
1241:                            pc = addIndex(program, pc, t.min);
1242:                            // max can be -1 which addIndex does not accept
1243:                            pc = addIndex(program, pc, t.max + 1);
1244:                        }
1245:                        pc = addIndex(program, pc, t.parenCount);
1246:                        pc = addIndex(program, pc, t.parenIndex);
1247:                        nextTermFixup = pc;
1248:                        pc += OFFSET_LEN;
1249:                        pc = emitREBytecode(state, re, pc, t.kid);
1250:                        program[pc++] = REOP_ENDCHILD;
1251:                        resolveForwardJump(program, nextTermFixup, pc);
1252:                        break;
1253:                    case REOP_CLASS:
1254:                        pc = addIndex(program, pc, t.index);
1255:                        re.classList[t.index] = new RECharSet(t.bmsize,
1256:                                t.startIndex, t.kidlen);
1257:                        break;
1258:                    default:
1259:                        break;
1260:                    }
1261:                    t = t.next;
1262:                }
1263:                return pc;
1264:            }
1265:
1266:            private static void pushProgState(REGlobalData gData, int min,
1267:                    int max, REBackTrackData backTrackLastToSave,
1268:                    int continuation_pc, int continuation_op) {
1269:                gData.stateStackTop = new REProgState(gData.stateStackTop, min,
1270:                        max, gData.cp, backTrackLastToSave, continuation_pc,
1271:                        continuation_op);
1272:            }
1273:
1274:            private static REProgState popProgState(REGlobalData gData) {
1275:                REProgState state = gData.stateStackTop;
1276:                gData.stateStackTop = state.previous;
1277:                return state;
1278:            }
1279:
1280:            private static void pushBackTrackState(REGlobalData gData, byte op,
1281:                    int target) {
1282:                gData.backTrackStackTop = new REBackTrackData(gData, op, target);
1283:            }
1284:
1285:            /*
1286:             *   Consecutive literal characters.
1287:             */
1288:            private static boolean flatNMatcher(REGlobalData gData,
1289:                    int matchChars, int length, char[] chars, int end) {
1290:                if ((gData.cp + length) > end)
1291:                    return false;
1292:                for (int i = 0; i < length; i++) {
1293:                    if (gData.regexp.source[matchChars + i] != chars[gData.cp
1294:                            + i]) {
1295:                        return false;
1296:                    }
1297:                }
1298:                gData.cp += length;
1299:                return true;
1300:            }
1301:
1302:            private static boolean flatNIMatcher(REGlobalData gData,
1303:                    int matchChars, int length, char[] chars, int end) {
1304:                if ((gData.cp + length) > end)
1305:                    return false;
1306:                for (int i = 0; i < length; i++) {
1307:                    if (upcase(gData.regexp.source[matchChars + i]) != upcase(chars[gData.cp
1308:                            + i])) {
1309:                        return false;
1310:                    }
1311:                }
1312:                gData.cp += length;
1313:                return true;
1314:            }
1315:
1316:            /*
1317:            1. Evaluate DecimalEscape to obtain an EscapeValue E.
1318:            2. If E is not a character then go to step 6.
1319:            3. Let ch be E's character.
1320:            4. Let A be a one-element RECharSet containing the character ch.
1321:            5. Call CharacterSetMatcher(A, false) and return its Matcher result.
1322:            6. E must be an integer. Let n be that integer.
1323:            7. If n=0 or n>NCapturingParens then throw a SyntaxError exception.
1324:            8. Return an internal Matcher closure that takes two arguments, a State x
1325:               and a Continuation c, and performs the following:
1326:                1. Let cap be x's captures internal array.
1327:                2. Let s be cap[n].
1328:                3. If s is undefined, then call c(x) and return its result.
1329:                4. Let e be x's endIndex.
1330:                5. Let len be s's length.
1331:                6. Let f be e+len.
1332:                7. If f>InputLength, return failure.
1333:                8. If there exists an integer i between 0 (inclusive) and len (exclusive)
1334:                   such that Canonicalize(s[i]) is not the same character as
1335:                   Canonicalize(Input [e+i]), then return failure.
1336:                9. Let y be the State (f, cap).
1337:                10. Call c(y) and return its result.
1338:             */
1339:            private static boolean backrefMatcher(REGlobalData gData,
1340:                    int parenIndex, char[] chars, int end) {
1341:                int len;
1342:                int i;
1343:                int parenContent = gData.parens_index(parenIndex);
1344:                if (parenContent == -1)
1345:                    return true;
1346:
1347:                len = gData.parens_length(parenIndex);
1348:                if ((gData.cp + len) > end)
1349:                    return false;
1350:
1351:                if ((gData.regexp.flags & JSREG_FOLD) != 0) {
1352:                    for (i = 0; i < len; i++) {
1353:                        if (upcase(chars[parenContent + i]) != upcase(chars[gData.cp
1354:                                + i]))
1355:                            return false;
1356:                    }
1357:                } else {
1358:                    for (i = 0; i < len; i++) {
1359:                        if (chars[parenContent + i] != chars[gData.cp + i])
1360:                            return false;
1361:                    }
1362:                }
1363:                gData.cp += len;
1364:                return true;
1365:            }
1366:
1367:            /* Add a single character to the RECharSet */
1368:            private static void addCharacterToCharSet(RECharSet cs, char c) {
1369:                int byteIndex = (c / 8);
1370:                if (c > cs.length)
1371:                    throw new RuntimeException();
1372:                cs.bits[byteIndex] |= 1 << (c & 0x7);
1373:            }
1374:
1375:            /* Add a character range, c1 to c2 (inclusive) to the RECharSet */
1376:            private static void addCharacterRangeToCharSet(RECharSet cs,
1377:                    char c1, char c2) {
1378:                int i;
1379:
1380:                int byteIndex1 = (c1 / 8);
1381:                int byteIndex2 = (c2 / 8);
1382:
1383:                if ((c2 > cs.length) || (c1 > c2))
1384:                    throw new RuntimeException();
1385:
1386:                c1 &= 0x7;
1387:                c2 &= 0x7;
1388:
1389:                if (byteIndex1 == byteIndex2) {
1390:                    cs.bits[byteIndex1] |= ((0xFF) >> (7 - (c2 - c1))) << c1;
1391:                } else {
1392:                    cs.bits[byteIndex1] |= 0xFF << c1;
1393:                    for (i = byteIndex1 + 1; i < byteIndex2; i++)
1394:                        cs.bits[i] = (byte) 0xFF;
1395:                    cs.bits[byteIndex2] |= (0xFF) >> (7 - c2);
1396:                }
1397:            }
1398:
1399:            /* Compile the source of the class into a RECharSet */
1400:            private static void processCharSet(REGlobalData gData,
1401:                    RECharSet charSet) {
1402:                synchronized (charSet) {
1403:                    if (!charSet.converted) {
1404:                        processCharSetImpl(gData, charSet);
1405:                        charSet.converted = true;
1406:                    }
1407:                }
1408:            }
1409:
1410:            private static void processCharSetImpl(REGlobalData gData,
1411:                    RECharSet charSet) {
1412:                int src = charSet.startIndex;
1413:                int end = src + charSet.strlength;
1414:
1415:                char rangeStart = 0, this Ch;
1416:                int byteLength;
1417:                char c;
1418:                int n;
1419:                int nDigits;
1420:                int i;
1421:                boolean inRange = false;
1422:
1423:                charSet.sense = true;
1424:                byteLength = (charSet.length / 8) + 1;
1425:                charSet.bits = new byte[byteLength];
1426:
1427:                if (src == end)
1428:                    return;
1429:
1430:                if (gData.regexp.source[src] == '^') {
1431:                    charSet.sense = false;
1432:                    ++src;
1433:                }
1434:
1435:                while (src != end) {
1436:                    nDigits = 2;
1437:                    switch (gData.regexp.source[src]) {
1438:                    case '\\':
1439:                        ++src;
1440:                        c = gData.regexp.source[src++];
1441:                        switch (c) {
1442:                        case 'b':
1443:                            this Ch = 0x8;
1444:                            break;
1445:                        case 'f':
1446:                            this Ch = 0xC;
1447:                            break;
1448:                        case 'n':
1449:                            this Ch = 0xA;
1450:                            break;
1451:                        case 'r':
1452:                            this Ch = 0xD;
1453:                            break;
1454:                        case 't':
1455:                            this Ch = 0x9;
1456:                            break;
1457:                        case 'v':
1458:                            this Ch = 0xB;
1459:                            break;
1460:                        case 'c':
1461:                            if (((src + 1) < end)
1462:                                    && isWord(gData.regexp.source[src + 1]))
1463:                                this Ch = (char) (gData.regexp.source[src++] & 0x1F);
1464:                            else {
1465:                                --src;
1466:                                this Ch = '\\';
1467:                            }
1468:                            break;
1469:                        case 'u':
1470:                            nDigits += 2;
1471:                            // fall thru
1472:                        case 'x':
1473:                            n = 0;
1474:                            for (i = 0; (i < nDigits) && (src < end); i++) {
1475:                                c = gData.regexp.source[src++];
1476:                                int digit = toASCIIHexDigit(c);
1477:                                if (digit < 0) {
1478:                                    /* back off to accepting the original '\'
1479:                                     * as a literal
1480:                                     */
1481:                                    src -= (i + 1);
1482:                                    n = '\\';
1483:                                    break;
1484:                                }
1485:                                n = (n << 4) | digit;
1486:                            }
1487:                            this Ch = (char) (n);
1488:                            break;
1489:                        case '0':
1490:                        case '1':
1491:                        case '2':
1492:                        case '3':
1493:                        case '4':
1494:                        case '5':
1495:                        case '6':
1496:                        case '7':
1497:                            /*
1498:                             *  This is a non-ECMA extension - decimal escapes (in this
1499:                             *  case, octal!) are supposed to be an error inside class
1500:                             *  ranges, but supported here for backwards compatibility.
1501:                             *
1502:                             */
1503:                            n = (c - '0');
1504:                            c = gData.regexp.source[src];
1505:                            if ('0' <= c && c <= '7') {
1506:                                src++;
1507:                                n = 8 * n + (c - '0');
1508:                                c = gData.regexp.source[src];
1509:                                if ('0' <= c && c <= '7') {
1510:                                    src++;
1511:                                    i = 8 * n + (c - '0');
1512:                                    if (i <= 0377)
1513:                                        n = i;
1514:                                    else
1515:                                        src--;
1516:                                }
1517:                            }
1518:                            this Ch = (char) (n);
1519:                            break;
1520:
1521:                        case 'd':
1522:                            addCharacterRangeToCharSet(charSet, '0', '9');
1523:                            continue; /* don't need range processing */
1524:                        case 'D':
1525:                            addCharacterRangeToCharSet(charSet, (char) 0,
1526:                                    (char) ('0' - 1));
1527:                            addCharacterRangeToCharSet(charSet,
1528:                                    (char) ('9' + 1), (char) (charSet.length));
1529:                            continue;
1530:                        case 's':
1531:                            for (i = charSet.length; i >= 0; i--)
1532:                                if (isREWhiteSpace(i))
1533:                                    addCharacterToCharSet(charSet, (char) (i));
1534:                            continue;
1535:                        case 'S':
1536:                            for (i = charSet.length; i >= 0; i--)
1537:                                if (!isREWhiteSpace(i))
1538:                                    addCharacterToCharSet(charSet, (char) (i));
1539:                            continue;
1540:                        case 'w':
1541:                            for (i = charSet.length; i >= 0; i--)
1542:                                if (isWord((char) i))
1543:                                    addCharacterToCharSet(charSet, (char) (i));
1544:                            continue;
1545:                        case 'W':
1546:                            for (i = charSet.length; i >= 0; i--)
1547:                                if (!isWord((char) i))
1548:                                    addCharacterToCharSet(charSet, (char) (i));
1549:                            continue;
1550:                        default:
1551:                            this Ch = c;
1552:                            break;
1553:
1554:                        }
1555:                        break;
1556:
1557:                    default:
1558:                        this Ch = gData.regexp.source[src++];
1559:                        break;
1560:
1561:                    }
1562:                    if (inRange) {
1563:                        if ((gData.regexp.flags & JSREG_FOLD) != 0) {
1564:                            addCharacterRangeToCharSet(charSet,
1565:                                    upcase(rangeStart), upcase(this Ch));
1566:                            addCharacterRangeToCharSet(charSet,
1567:                                    downcase(rangeStart), downcase(this Ch));
1568:                        } else {
1569:                            addCharacterRangeToCharSet(charSet, rangeStart,
1570:                                    this Ch);
1571:                        }
1572:                        inRange = false;
1573:                    } else {
1574:                        if ((gData.regexp.flags & JSREG_FOLD) != 0) {
1575:                            addCharacterToCharSet(charSet, upcase(this Ch));
1576:                            addCharacterToCharSet(charSet, downcase(this Ch));
1577:                        } else {
1578:                            addCharacterToCharSet(charSet, this Ch);
1579:                        }
1580:                        if (src < (end - 1)) {
1581:                            if (gData.regexp.source[src] == '-') {
1582:                                ++src;
1583:                                inRange = true;
1584:                                rangeStart = this Ch;
1585:                            }
1586:                        }
1587:                    }
1588:                }
1589:            }
1590:
1591:            /*
1592:             *   Initialize the character set if it this is the first call.
1593:             *   Test the bit - if the ^ flag was specified, non-inclusion is a success
1594:             */
1595:            private static boolean classMatcher(REGlobalData gData,
1596:                    RECharSet charSet, char ch) {
1597:                if (!charSet.converted) {
1598:                    processCharSet(gData, charSet);
1599:                }
1600:
1601:                int byteIndex = ch / 8;
1602:                if (charSet.sense) {
1603:                    if ((charSet.length == 0)
1604:                            || ((ch > charSet.length) || ((charSet.bits[byteIndex] & (1 << (ch & 0x7))) == 0)))
1605:                        return false;
1606:                } else {
1607:                    if (!((charSet.length == 0) || ((ch > charSet.length) || ((charSet.bits[byteIndex] & (1 << (ch & 0x7))) == 0))))
1608:                        return false;
1609:                }
1610:                return true;
1611:            }
1612:
1613:            private static boolean executeREBytecode(REGlobalData gData,
1614:                    char[] chars, int end) {
1615:                int pc = 0;
1616:                byte program[] = gData.regexp.program;
1617:                int currentContinuation_op;
1618:                int currentContinuation_pc;
1619:                boolean result = false;
1620:
1621:                currentContinuation_pc = 0;
1622:                currentContinuation_op = REOP_END;
1623:                if (debug) {
1624:                    System.out.println("Input = \"" + new String(chars)
1625:                            + "\", start at " + gData.cp);
1626:                }
1627:                int op = program[pc++];
1628:                for (;;) {
1629:                    if (debug) {
1630:                        System.out.println("Testing at " + gData.cp + ", op = "
1631:                                + op);
1632:                    }
1633:                    switch (op) {
1634:                    case REOP_EMPTY:
1635:                        result = true;
1636:                        break;
1637:                    case REOP_BOL:
1638:                        if (gData.cp != 0) {
1639:                            if (gData.multiline
1640:                                    || ((gData.regexp.flags & JSREG_MULTILINE) != 0)) {
1641:                                if (!isLineTerm(chars[gData.cp - 1])) {
1642:                                    result = false;
1643:                                    break;
1644:                                }
1645:                            } else {
1646:                                result = false;
1647:                                break;
1648:                            }
1649:                        }
1650:                        result = true;
1651:                        break;
1652:                    case REOP_EOL:
1653:                        if (gData.cp != end) {
1654:                            if (gData.multiline
1655:                                    || ((gData.regexp.flags & JSREG_MULTILINE) != 0)) {
1656:                                if (!isLineTerm(chars[gData.cp])) {
1657:                                    result = false;
1658:                                    break;
1659:                                }
1660:                            } else {
1661:                                result = false;
1662:                                break;
1663:                            }
1664:                        }
1665:                        result = true;
1666:                        break;
1667:                    case REOP_WBDRY:
1668:                        result = ((gData.cp == 0 || !isWord(chars[gData.cp - 1])) ^ !((gData.cp < end) && isWord(chars[gData.cp])));
1669:                        break;
1670:                    case REOP_WNONBDRY:
1671:                        result = ((gData.cp == 0 || !isWord(chars[gData.cp - 1])) ^ ((gData.cp < end) && isWord(chars[gData.cp])));
1672:                        break;
1673:                    case REOP_DOT:
1674:                        result = (gData.cp != end && !isLineTerm(chars[gData.cp]));
1675:                        if (result) {
1676:                            gData.cp++;
1677:                        }
1678:                        break;
1679:                    case REOP_DIGIT:
1680:                        result = (gData.cp != end && isDigit(chars[gData.cp]));
1681:                        if (result) {
1682:                            gData.cp++;
1683:                        }
1684:                        break;
1685:                    case REOP_NONDIGIT:
1686:                        result = (gData.cp != end && !isDigit(chars[gData.cp]));
1687:                        if (result) {
1688:                            gData.cp++;
1689:                        }
1690:                        break;
1691:                    case REOP_SPACE:
1692:                        result = (gData.cp != end && isREWhiteSpace(chars[gData.cp]));
1693:                        if (result) {
1694:                            gData.cp++;
1695:                        }
1696:                        break;
1697:                    case REOP_NONSPACE:
1698:                        result = (gData.cp != end && !isREWhiteSpace(chars[gData.cp]));
1699:                        if (result) {
1700:                            gData.cp++;
1701:                        }
1702:                        break;
1703:                    case REOP_ALNUM:
1704:                        result = (gData.cp != end && isWord(chars[gData.cp]));
1705:                        if (result) {
1706:                            gData.cp++;
1707:                        }
1708:                        break;
1709:                    case REOP_NONALNUM:
1710:                        result = (gData.cp != end && !isWord(chars[gData.cp]));
1711:                        if (result) {
1712:                            gData.cp++;
1713:                        }
1714:                        break;
1715:                    case REOP_FLAT: {
1716:                        int offset = getIndex(program, pc);
1717:                        pc += INDEX_LEN;
1718:                        int length = getIndex(program, pc);
1719:                        pc += INDEX_LEN;
1720:                        result = flatNMatcher(gData, offset, length, chars, end);
1721:                    }
1722:                        break;
1723:                    case REOP_FLATi: {
1724:                        int offset = getIndex(program, pc);
1725:                        pc += INDEX_LEN;
1726:                        int length = getIndex(program, pc);
1727:                        pc += INDEX_LEN;
1728:                        result = flatNIMatcher(gData, offset, length, chars,
1729:                                end);
1730:                    }
1731:                        break;
1732:                    case REOP_FLAT1: {
1733:                        char matchCh = (char) (program[pc++] & 0xFF);
1734:                        result = (gData.cp != end && chars[gData.cp] == matchCh);
1735:                        if (result) {
1736:                            gData.cp++;
1737:                        }
1738:                    }
1739:                        break;
1740:                    case REOP_FLAT1i: {
1741:                        char matchCh = (char) (program[pc++] & 0xFF);
1742:                        result = (gData.cp != end && upcase(chars[gData.cp]) == upcase(matchCh));
1743:                        if (result) {
1744:                            gData.cp++;
1745:                        }
1746:                    }
1747:                        break;
1748:                    case REOP_UCFLAT1: {
1749:                        char matchCh = (char) getIndex(program, pc);
1750:                        pc += INDEX_LEN;
1751:                        result = (gData.cp != end && chars[gData.cp] == matchCh);
1752:                        if (result) {
1753:                            gData.cp++;
1754:                        }
1755:                    }
1756:                        break;
1757:                    case REOP_UCFLAT1i: {
1758:                        char matchCh = (char) getIndex(program, pc);
1759:                        pc += INDEX_LEN;
1760:                        result = (gData.cp != end && upcase(chars[gData.cp]) == upcase(matchCh));
1761:                        if (result) {
1762:                            gData.cp++;
1763:                        }
1764:                    }
1765:                        break;
1766:                    case REOP_ALT: {
1767:                        int nextpc;
1768:                        byte nextop;
1769:                        pushProgState(gData, 0, 0, null,
1770:                                currentContinuation_pc, currentContinuation_op);
1771:                        nextpc = pc + getOffset(program, pc);
1772:                        nextop = program[nextpc++];
1773:                        pushBackTrackState(gData, nextop, nextpc);
1774:                        pc += INDEX_LEN;
1775:                        op = program[pc++];
1776:                    }
1777:                        continue;
1778:
1779:                    case REOP_JUMP: {
1780:                        int offset;
1781:                        REProgState state = popProgState(gData);
1782:                        currentContinuation_pc = state.continuation_pc;
1783:                        currentContinuation_op = state.continuation_op;
1784:                        offset = getOffset(program, pc);
1785:                        pc += offset;
1786:                        op = program[pc++];
1787:                    }
1788:                        continue;
1789:
1790:                    case REOP_LPAREN: {
1791:                        int parenIndex = getIndex(program, pc);
1792:                        pc += INDEX_LEN;
1793:                        gData.set_parens(parenIndex, gData.cp, 0);
1794:                        op = program[pc++];
1795:                    }
1796:                        continue;
1797:                    case REOP_RPAREN: {
1798:                        int cap_index;
1799:                        int parenIndex = getIndex(program, pc);
1800:                        pc += INDEX_LEN;
1801:                        cap_index = gData.parens_index(parenIndex);
1802:                        gData.set_parens(parenIndex, cap_index, gData.cp
1803:                                - cap_index);
1804:                        if (parenIndex > gData.lastParen)
1805:                            gData.lastParen = parenIndex;
1806:                        op = program[pc++];
1807:                    }
1808:                        continue;
1809:                    case REOP_BACKREF: {
1810:                        int parenIndex = getIndex(program, pc);
1811:                        pc += INDEX_LEN;
1812:                        result = backrefMatcher(gData, parenIndex, chars, end);
1813:                    }
1814:                        break;
1815:
1816:                    case REOP_CLASS: {
1817:                        int index = getIndex(program, pc);
1818:                        pc += INDEX_LEN;
1819:                        if (gData.cp != end) {
1820:                            if (classMatcher(gData,
1821:                                    gData.regexp.classList[index],
1822:                                    chars[gData.cp])) {
1823:                                gData.cp++;
1824:                                result = true;
1825:                                break;
1826:                            }
1827:                        }
1828:                        result = false;
1829:                    }
1830:                        break;
1831:
1832:                    case REOP_ASSERT:
1833:                    case REOP_ASSERT_NOT: {
1834:                        byte testOp;
1835:                        pushProgState(gData, 0, 0, gData.backTrackStackTop,
1836:                                currentContinuation_pc, currentContinuation_op);
1837:                        if (op == REOP_ASSERT) {
1838:                            testOp = REOP_ASSERTTEST;
1839:                        } else {
1840:                            testOp = REOP_ASSERTNOTTEST;
1841:                        }
1842:                        pushBackTrackState(gData, testOp, pc
1843:                                + getOffset(program, pc));
1844:                        pc += INDEX_LEN;
1845:                        op = program[pc++];
1846:                    }
1847:                        continue;
1848:
1849:                    case REOP_ASSERTTEST:
1850:                    case REOP_ASSERTNOTTEST: {
1851:                        REProgState state = popProgState(gData);
1852:                        gData.cp = state.index;
1853:                        gData.backTrackStackTop = state.backTrack;
1854:                        currentContinuation_pc = state.continuation_pc;
1855:                        currentContinuation_op = state.continuation_op;
1856:                        if (result) {
1857:                            if (op == REOP_ASSERTTEST) {
1858:                                result = true;
1859:                            } else {
1860:                                result = false;
1861:                            }
1862:                        } else {
1863:                            if (op == REOP_ASSERTTEST) {
1864:                                // Do nothing
1865:                            } else {
1866:                                result = true;
1867:                            }
1868:                        }
1869:                    }
1870:                        break;
1871:
1872:                    case REOP_STAR:
1873:                    case REOP_PLUS:
1874:                    case REOP_OPT:
1875:                    case REOP_QUANT:
1876:                    case REOP_MINIMALSTAR:
1877:                    case REOP_MINIMALPLUS:
1878:                    case REOP_MINIMALOPT:
1879:                    case REOP_MINIMALQUANT: {
1880:                        int min, max;
1881:                        boolean greedy = false;
1882:                        switch (op) {
1883:                        case REOP_STAR:
1884:                            greedy = true;
1885:                            // fallthrough
1886:                        case REOP_MINIMALSTAR:
1887:                            min = 0;
1888:                            max = -1;
1889:                            break;
1890:                        case REOP_PLUS:
1891:                            greedy = true;
1892:                            // fallthrough
1893:                        case REOP_MINIMALPLUS:
1894:                            min = 1;
1895:                            max = -1;
1896:                            break;
1897:                        case REOP_OPT:
1898:                            greedy = true;
1899:                            // fallthrough
1900:                        case REOP_MINIMALOPT:
1901:                            min = 0;
1902:                            max = 1;
1903:                            break;
1904:                        case REOP_QUANT:
1905:                            greedy = true;
1906:                            // fallthrough
1907:                        case REOP_MINIMALQUANT:
1908:                            min = getOffset(program, pc);
1909:                            pc += INDEX_LEN;
1910:                            // See comments in emitREBytecode for " - 1" reason
1911:                            max = getOffset(program, pc) - 1;
1912:                            pc += INDEX_LEN;
1913:                            break;
1914:                        default:
1915:                            throw Kit.codeBug();
1916:                        }
1917:                        pushProgState(gData, min, max, null,
1918:                                currentContinuation_pc, currentContinuation_op);
1919:                        if (greedy) {
1920:                            currentContinuation_op = REOP_REPEAT;
1921:                            currentContinuation_pc = pc;
1922:                            pushBackTrackState(gData, REOP_REPEAT, pc);
1923:                            /* Step over <parencount>, <parenindex> & <next> */
1924:                            pc += 3 * INDEX_LEN;
1925:                            op = program[pc++];
1926:                        } else {
1927:                            if (min != 0) {
1928:                                currentContinuation_op = REOP_MINIMALREPEAT;
1929:                                currentContinuation_pc = pc;
1930:                                /* <parencount> <parenindex> & <next> */
1931:                                pc += 3 * INDEX_LEN;
1932:                                op = program[pc++];
1933:                            } else {
1934:                                pushBackTrackState(gData, REOP_MINIMALREPEAT,
1935:                                        pc);
1936:                                popProgState(gData);
1937:                                pc += 2 * INDEX_LEN; // <parencount> & <parenindex>
1938:                                pc = pc + getOffset(program, pc);
1939:                                op = program[pc++];
1940:                            }
1941:                        }
1942:                    }
1943:                        continue;
1944:
1945:                    case REOP_ENDCHILD:
1946:                        // Use the current continuation.
1947:                        pc = currentContinuation_pc;
1948:                        op = currentContinuation_op;
1949:                        continue;
1950:
1951:                    case REOP_REPEAT: {
1952:                        REProgState state = popProgState(gData);
1953:                        if (!result) {
1954:                            //
1955:                            // There's been a failure, see if we have enough
1956:                            // children.
1957:                            //
1958:                            if (state.min == 0)
1959:                                result = true;
1960:                            currentContinuation_pc = state.continuation_pc;
1961:                            currentContinuation_op = state.continuation_op;
1962:                            pc += 2 * INDEX_LEN; /* <parencount> & <parenindex> */
1963:                            pc = pc + getOffset(program, pc);
1964:                            break;
1965:                        } else {
1966:                            if (state.min == 0 && gData.cp == state.index) {
1967:                                // matched an empty string, that'll get us nowhere
1968:                                result = false;
1969:                                currentContinuation_pc = state.continuation_pc;
1970:                                currentContinuation_op = state.continuation_op;
1971:                                pc += 2 * INDEX_LEN;
1972:                                pc = pc + getOffset(program, pc);
1973:                                break;
1974:                            }
1975:                            int new_min = state.min, new_max = state.max;
1976:                            if (new_min != 0)
1977:                                new_min--;
1978:                            if (new_max != -1)
1979:                                new_max--;
1980:                            if (new_max == 0) {
1981:                                result = true;
1982:                                currentContinuation_pc = state.continuation_pc;
1983:                                currentContinuation_op = state.continuation_op;
1984:                                pc += 2 * INDEX_LEN;
1985:                                pc = pc + getOffset(program, pc);
1986:                                break;
1987:                            }
1988:                            pushProgState(gData, new_min, new_max, null,
1989:                                    state.continuation_pc,
1990:                                    state.continuation_op);
1991:                            currentContinuation_op = REOP_REPEAT;
1992:                            currentContinuation_pc = pc;
1993:                            pushBackTrackState(gData, REOP_REPEAT, pc);
1994:                            int parenCount = getIndex(program, pc);
1995:                            pc += INDEX_LEN;
1996:                            int parenIndex = getIndex(program, pc);
1997:                            pc += 2 * INDEX_LEN;
1998:                            op = program[pc++];
1999:                            for (int k = 0; k < parenCount; k++) {
2000:                                gData.set_parens(parenIndex + k, -1, 0);
2001:                            }
2002:                        }
2003:                    }
2004:                        continue;
2005:
2006:                    case REOP_MINIMALREPEAT: {
2007:                        REProgState state = popProgState(gData);
2008:                        if (!result) {
2009:                            //
2010:                            // Non-greedy failure - try to consume another child.
2011:                            //
2012:                            if (state.max == -1 || state.max > 0) {
2013:                                pushProgState(gData, state.min, state.max,
2014:                                        null, state.continuation_pc,
2015:                                        state.continuation_op);
2016:                                currentContinuation_op = REOP_MINIMALREPEAT;
2017:                                currentContinuation_pc = pc;
2018:                                int parenCount = getIndex(program, pc);
2019:                                pc += INDEX_LEN;
2020:                                int parenIndex = getIndex(program, pc);
2021:                                pc += 2 * INDEX_LEN;
2022:                                for (int k = 0; k < parenCount; k++) {
2023:                                    gData.set_parens(parenIndex + k, -1, 0);
2024:                                }
2025:                                op = program[pc++];
2026:                                continue;
2027:                            } else {
2028:                                // Don't need to adjust pc since we're going to pop.
2029:                                currentContinuation_pc = state.continuation_pc;
2030:                                currentContinuation_op = state.continuation_op;
2031:                                break;
2032:                            }
2033:                        } else {
2034:                            if (state.min == 0 && gData.cp == state.index) {
2035:                                // Matched an empty string, that'll get us nowhere.
2036:                                result = false;
2037:                                currentContinuation_pc = state.continuation_pc;
2038:                                currentContinuation_op = state.continuation_op;
2039:                                break;
2040:                            }
2041:                            int new_min = state.min, new_max = state.max;
2042:                            if (new_min != 0)
2043:                                new_min--;
2044:                            if (new_max != -1)
2045:                                new_max--;
2046:                            pushProgState(gData, new_min, new_max, null,
2047:                                    state.continuation_pc,
2048:                                    state.continuation_op);
2049:                            if (new_min != 0) {
2050:                                currentContinuation_op = REOP_MINIMALREPEAT;
2051:                                currentContinuation_pc = pc;
2052:                                int parenCount = getIndex(program, pc);
2053:                                pc += INDEX_LEN;
2054:                                int parenIndex = getIndex(program, pc);
2055:                                pc += 2 * INDEX_LEN;
2056:                                for (int k = 0; k < parenCount; k++) {
2057:                                    gData.set_parens(parenIndex + k, -1, 0);
2058:                                }
2059:                                op = program[pc++];
2060:                            } else {
2061:                                currentContinuation_pc = state.continuation_pc;
2062:                                currentContinuation_op = state.continuation_op;
2063:                                pushBackTrackState(gData, REOP_MINIMALREPEAT,
2064:                                        pc);
2065:                                popProgState(gData);
2066:                                pc += 2 * INDEX_LEN;
2067:                                pc = pc + getOffset(program, pc);
2068:                                op = program[pc++];
2069:                            }
2070:                            continue;
2071:                        }
2072:                    }
2073:
2074:                    case REOP_END:
2075:                        return true;
2076:
2077:                    default:
2078:                        throw Kit.codeBug();
2079:
2080:                    }
2081:                    /*
2082:                     *  If the match failed and there's a backtrack option, take it.
2083:                     *  Otherwise this is a complete and utter failure.
2084:                     */
2085:                    if (!result) {
2086:                        REBackTrackData backTrackData = gData.backTrackStackTop;
2087:                        if (backTrackData != null) {
2088:                            gData.backTrackStackTop = backTrackData.previous;
2089:
2090:                            gData.lastParen = backTrackData.lastParen;
2091:
2092:                            // XXX: If backTrackData will no longer be used, then
2093:                            // there is no need to clone backTrackData.parens
2094:                            if (backTrackData.parens != null) {
2095:                                gData.parens = (long[]) backTrackData.parens
2096:                                        .clone();
2097:                            }
2098:
2099:                            gData.cp = backTrackData.cp;
2100:
2101:                            gData.stateStackTop = backTrackData.stateStackTop;
2102:
2103:                            currentContinuation_op = gData.stateStackTop.continuation_op;
2104:                            currentContinuation_pc = gData.stateStackTop.continuation_pc;
2105:                            pc = backTrackData.continuation_pc;
2106:                            op = backTrackData.continuation_op;
2107:                            continue;
2108:                        } else
2109:                            return false;
2110:                    }
2111:
2112:                    op = program[pc++];
2113:                }
2114:
2115:            }
2116:
2117:            private static boolean matchRegExp(REGlobalData gData,
2118:                    RECompiled re, char[] chars, int start, int end,
2119:                    boolean multiline) {
2120:                if (re.parenCount != 0) {
2121:                    gData.parens = new long[re.parenCount];
2122:                } else {
2123:                    gData.parens = null;
2124:                }
2125:
2126:                gData.backTrackStackTop = null;
2127:
2128:                gData.stateStackTop = null;
2129:
2130:                gData.multiline = multiline;
2131:                gData.regexp = re;
2132:                gData.lastParen = 0;
2133:
2134:                int anchorCh = gData.regexp.anchorCh;
2135:                //
2136:                // have to include the position beyond the last character
2137:                //  in order to detect end-of-input/line condition
2138:                //
2139:                for (int i = start; i <= end; ++i) {
2140:                    //
2141:                    // If the first node is a literal match, step the index into
2142:                    // the string until that match is made, or fail if it can't be
2143:                    // found at all.
2144:                    //
2145:                    if (anchorCh >= 0) {
2146:                        for (;;) {
2147:                            if (i == end) {
2148:                                return false;
2149:                            }
2150:                            char matchCh = chars[i];
2151:                            if (matchCh == anchorCh
2152:                                    || ((gData.regexp.flags & JSREG_FOLD) != 0 && upcase(matchCh) == upcase((char) anchorCh))) {
2153:                                break;
2154:                            }
2155:                            ++i;
2156:                        }
2157:                    }
2158:                    gData.cp = i;
2159:                    for (int j = 0; j < re.parenCount; j++) {
2160:                        gData.set_parens(j, -1, 0);
2161:                    }
2162:                    boolean result = executeREBytecode(gData, chars, end);
2163:
2164:                    gData.backTrackStackTop = null;
2165:                    gData.stateStackTop = null;
2166:                    if (result) {
2167:                        gData.skipped = i - start;
2168:                        return true;
2169:                    }
2170:                }
2171:                return false;
2172:            }
2173:
2174:            /*
2175:             * indexp is assumed to be an array of length 1
2176:             */
2177:            Object executeRegExp(Context cx, Scriptable scopeObj,
2178:                    RegExpImpl res, String str, int indexp[], int matchType) {
2179:                REGlobalData gData = new REGlobalData();
2180:
2181:                int start = indexp[0];
2182:                char[] charArray = str.toCharArray();
2183:                int end = charArray.length;
2184:                if (start > end)
2185:                    start = end;
2186:                //
2187:                // Call the recursive matcher to do the real work.
2188:                //
2189:                boolean matches = matchRegExp(gData, re, charArray, start, end,
2190:                        res.multiline);
2191:                if (!matches) {
2192:                    if (matchType != PREFIX)
2193:                        return null;
2194:                    return Undefined.instance;
2195:                }
2196:                int index = gData.cp;
2197:                int i = index;
2198:                indexp[0] = i;
2199:                int matchlen = i - (start + gData.skipped);
2200:                int ep = index;
2201:                index -= matchlen;
2202:                Object result;
2203:                Scriptable obj;
2204:
2205:                if (matchType == TEST) {
2206:                    /*
2207:                     * Testing for a match and updating cx.regExpImpl: don't allocate
2208:                     * an array object, do return true.
2209:                     */
2210:                    result = Boolean.TRUE;
2211:                    obj = null;
2212:                } else {
2213:                    /*
2214:                     * The array returned on match has element 0 bound to the matched
2215:                     * string, elements 1 through re.parenCount bound to the paren
2216:                     * matches, an index property telling the length of the left context,
2217:                     * and an input property referring to the input string.
2218:                     */
2219:                    Scriptable scope = getTopLevelScope(scopeObj);
2220:                    result = ScriptRuntime.newObject(cx, scope, "Array", null);
2221:                    obj = (Scriptable) result;
2222:
2223:                    String matchstr = new String(charArray, index, matchlen);
2224:                    obj.put(0, obj, matchstr);
2225:                }
2226:
2227:                if (re.parenCount == 0) {
2228:                    res.parens = null;
2229:                    res.lastParen = SubString.emptySubString;
2230:                } else {
2231:                    SubString parsub = null;
2232:                    int num;
2233:                    res.parens = new SubString[re.parenCount];
2234:                    for (num = 0; num < re.parenCount; num++) {
2235:                        int cap_index = gData.parens_index(num);
2236:                        String parstr;
2237:                        if (cap_index != -1) {
2238:                            int cap_length = gData.parens_length(num);
2239:                            parsub = new SubString(charArray, cap_index,
2240:                                    cap_length);
2241:                            res.parens[num] = parsub;
2242:                            if (matchType == TEST)
2243:                                continue;
2244:                            parstr = parsub.toString();
2245:                            obj.put(num + 1, obj, parstr);
2246:                        } else {
2247:                            if (matchType != TEST)
2248:                                obj.put(num + 1, obj, Undefined.instance);
2249:                        }
2250:                    }
2251:                    res.lastParen = parsub;
2252:                }
2253:
2254:                if (!(matchType == TEST)) {
2255:                    /*
2256:                     * Define the index and input properties last for better for/in loop
2257:                     * order (so they come after the elements).
2258:                     */
2259:                    obj.put("index", obj, new Integer(start + gData.skipped));
2260:                    obj.put("input", obj, str);
2261:                }
2262:
2263:                if (res.lastMatch == null) {
2264:                    res.lastMatch = new SubString();
2265:                    res.leftContext = new SubString();
2266:                    res.rightContext = new SubString();
2267:                }
2268:                res.lastMatch.charArray = charArray;
2269:                res.lastMatch.index = index;
2270:                res.lastMatch.length = matchlen;
2271:
2272:                res.leftContext.charArray = charArray;
2273:                if (cx.getLanguageVersion() == Context.VERSION_1_2) {
2274:                    /*
2275:                     * JS1.2 emulated Perl4.0.1.8 (patch level 36) for global regexps used
2276:                     * in scalar contexts, and unintentionally for the string.match "list"
2277:                     * psuedo-context.  On "hi there bye", the following would result:
2278:                     *
2279:                     * Language     while(/ /g){print("$`");}   s/ /$`/g
2280:                     * perl4.036    "hi", "there"               "hihitherehi therebye"
2281:                     * perl5        "hi", "hi there"            "hihitherehi therebye"
2282:                     * js1.2        "hi", "there"               "hihitheretherebye"
2283:                     *
2284:                     * Insofar as JS1.2 always defined $` as "left context from the last
2285:                     * match" for global regexps, it was more consistent than perl4.
2286:                     */
2287:                    res.leftContext.index = start;
2288:                    res.leftContext.length = gData.skipped;
2289:                } else {
2290:                    /*
2291:                     * For JS1.3 and ECMAv2, emulate Perl5 exactly:
2292:                     *
2293:                     * js1.3        "hi", "hi there"            "hihitherehi therebye"
2294:                     */
2295:                    res.leftContext.index = 0;
2296:                    res.leftContext.length = start + gData.skipped;
2297:                }
2298:
2299:                res.rightContext.charArray = charArray;
2300:                res.rightContext.index = ep;
2301:                res.rightContext.length = end - ep;
2302:
2303:                return result;
2304:            }
2305:
2306:            int getFlags() {
2307:                return re.flags;
2308:            }
2309:
2310:            private static void reportWarning(Context cx, String messageId,
2311:                    String arg) {
2312:                if (cx.hasFeature(Context.FEATURE_STRICT_MODE)) {
2313:                    String msg = ScriptRuntime.getMessage1(messageId, arg);
2314:                    Context.reportWarning(msg
2315:                    // <netbeans>
2316:                            , messageId, arg
2317:                    // </netbeans>
2318:                            );
2319:                }
2320:            }
2321:
2322:            private static void reportError(String messageId, String arg) {
2323:                String msg = ScriptRuntime.getMessage1(messageId, arg);
2324:                throw ScriptRuntime.constructError("SyntaxError", msg);
2325:            }
2326:
2327:            // #string_id_map#
2328:
2329:            private static final int Id_lastIndex = 1, Id_source = 2,
2330:                    Id_global = 3, Id_ignoreCase = 4, Id_multiline = 5,
2331:
2332:                    MAX_INSTANCE_ID = 5;
2333:
2334:            protected int getMaxInstanceId() {
2335:                return MAX_INSTANCE_ID;
2336:            }
2337:
2338:            protected int findInstanceIdInfo(String s) {
2339:                int id;
2340:                // #generated# Last update: 2007-05-09 08:16:24 EDT
2341:                L0: {
2342:                    id = 0;
2343:                    String X = null;
2344:                    int c;
2345:                    int s_length = s.length();
2346:                    if (s_length == 6) {
2347:                        c = s.charAt(0);
2348:                        if (c == 'g') {
2349:                            X = "global";
2350:                            id = Id_global;
2351:                        } else if (c == 's') {
2352:                            X = "source";
2353:                            id = Id_source;
2354:                        }
2355:                    } else if (s_length == 9) {
2356:                        c = s.charAt(0);
2357:                        if (c == 'l') {
2358:                            X = "lastIndex";
2359:                            id = Id_lastIndex;
2360:                        } else if (c == 'm') {
2361:                            X = "multiline";
2362:                            id = Id_multiline;
2363:                        }
2364:                    } else if (s_length == 10) {
2365:                        X = "ignoreCase";
2366:                        id = Id_ignoreCase;
2367:                    }
2368:                    if (X != null && X != s && !X.equals(s))
2369:                        id = 0;
2370:                    break L0;
2371:                }
2372:                // #/generated#
2373:                // #/string_id_map#
2374:
2375:                if (id == 0)
2376:                    return super .findInstanceIdInfo(s);
2377:
2378:                int attr;
2379:                switch (id) {
2380:                case Id_lastIndex:
2381:                    attr = PERMANENT | DONTENUM;
2382:                    break;
2383:                case Id_source:
2384:                case Id_global:
2385:                case Id_ignoreCase:
2386:                case Id_multiline:
2387:                    attr = PERMANENT | READONLY | DONTENUM;
2388:                    break;
2389:                default:
2390:                    throw new IllegalStateException();
2391:                }
2392:                return instanceIdInfo(attr, id);
2393:            }
2394:
2395:            protected String getInstanceIdName(int id) {
2396:                switch (id) {
2397:                case Id_lastIndex:
2398:                    return "lastIndex";
2399:                case Id_source:
2400:                    return "source";
2401:                case Id_global:
2402:                    return "global";
2403:                case Id_ignoreCase:
2404:                    return "ignoreCase";
2405:                case Id_multiline:
2406:                    return "multiline";
2407:                }
2408:                return super .getInstanceIdName(id);
2409:            }
2410:
2411:            protected Object getInstanceIdValue(int id) {
2412:                switch (id) {
2413:                case Id_lastIndex:
2414:                    return ScriptRuntime.wrapNumber(lastIndex);
2415:                case Id_source:
2416:                    return new String(re.source);
2417:                case Id_global:
2418:                    return ScriptRuntime
2419:                            .wrapBoolean((re.flags & JSREG_GLOB) != 0);
2420:                case Id_ignoreCase:
2421:                    return ScriptRuntime
2422:                            .wrapBoolean((re.flags & JSREG_FOLD) != 0);
2423:                case Id_multiline:
2424:                    return ScriptRuntime
2425:                            .wrapBoolean((re.flags & JSREG_MULTILINE) != 0);
2426:                }
2427:                return super .getInstanceIdValue(id);
2428:            }
2429:
2430:            protected void setInstanceIdValue(int id, Object value) {
2431:                if (id == Id_lastIndex) {
2432:                    lastIndex = ScriptRuntime.toNumber(value);
2433:                    return;
2434:                }
2435:                super .setInstanceIdValue(id, value);
2436:            }
2437:
2438:            protected void initPrototypeId(int id) {
2439:                String s;
2440:                int arity;
2441:                switch (id) {
2442:                case Id_compile:
2443:                    arity = 1;
2444:                    s = "compile";
2445:                    break;
2446:                case Id_toString:
2447:                    arity = 0;
2448:                    s = "toString";
2449:                    break;
2450:                case Id_toSource:
2451:                    arity = 0;
2452:                    s = "toSource";
2453:                    break;
2454:                case Id_exec:
2455:                    arity = 1;
2456:                    s = "exec";
2457:                    break;
2458:                case Id_test:
2459:                    arity = 1;
2460:                    s = "test";
2461:                    break;
2462:                case Id_prefix:
2463:                    arity = 1;
2464:                    s = "prefix";
2465:                    break;
2466:                default:
2467:                    throw new IllegalArgumentException(String.valueOf(id));
2468:                }
2469:                initPrototypeMethod(REGEXP_TAG, id, s, arity);
2470:            }
2471:
2472:            public Object execIdCall(IdFunctionObject f, Context cx,
2473:                    Scriptable scope, Scriptable this Obj, Object[] args) {
2474:                if (!f.hasTag(REGEXP_TAG)) {
2475:                    return super .execIdCall(f, cx, scope, this Obj, args);
2476:                }
2477:                int id = f.methodId();
2478:                switch (id) {
2479:                case Id_compile:
2480:                    return realThis(this Obj, f).compile(cx, scope, args);
2481:
2482:                case Id_toString:
2483:                case Id_toSource:
2484:                    return realThis(this Obj, f).toString();
2485:
2486:                case Id_exec:
2487:                    return realThis(this Obj, f).execSub(cx, scope, args, MATCH);
2488:
2489:                case Id_test: {
2490:                    Object x = realThis(this Obj, f).execSub(cx, scope, args,
2491:                            TEST);
2492:                    return Boolean.TRUE.equals(x) ? Boolean.TRUE
2493:                            : Boolean.FALSE;
2494:                }
2495:
2496:                case Id_prefix:
2497:                    return realThis(this Obj, f)
2498:                            .execSub(cx, scope, args, PREFIX);
2499:                }
2500:                throw new IllegalArgumentException(String.valueOf(id));
2501:            }
2502:
2503:            private static NativeRegExp realThis(Scriptable this Obj,
2504:                    IdFunctionObject f) {
2505:                if (!(this Obj instanceof  NativeRegExp))
2506:                    throw incompatibleCallError(f);
2507:                return (NativeRegExp) this Obj;
2508:            }
2509:
2510:            // #string_id_map#
2511:            protected int findPrototypeId(String s) {
2512:                int id;
2513:                // #generated# Last update: 2007-05-09 08:16:24 EDT
2514:                L0: {
2515:                    id = 0;
2516:                    String X = null;
2517:                    int c;
2518:                    L: switch (s.length()) {
2519:                    case 4:
2520:                        c = s.charAt(0);
2521:                        if (c == 'e') {
2522:                            X = "exec";
2523:                            id = Id_exec;
2524:                        } else if (c == 't') {
2525:                            X = "test";
2526:                            id = Id_test;
2527:                        }
2528:                        break L;
2529:                    case 6:
2530:                        X = "prefix";
2531:                        id = Id_prefix;
2532:                        break L;
2533:                    case 7:
2534:                        X = "compile";
2535:                        id = Id_compile;
2536:                        break L;
2537:                    case 8:
2538:                        c = s.charAt(3);
2539:                        if (c == 'o') {
2540:                            X = "toSource";
2541:                            id = Id_toSource;
2542:                        } else if (c == 't') {
2543:                            X = "toString";
2544:                            id = Id_toString;
2545:                        }
2546:                        break L;
2547:                    }
2548:                    if (X != null && X != s && !X.equals(s))
2549:                        id = 0;
2550:                    break L0;
2551:                }
2552:                // #/generated#
2553:                return id;
2554:            }
2555:
2556:            private static final int Id_compile = 1, Id_toString = 2,
2557:                    Id_toSource = 3, Id_exec = 4, Id_test = 5, Id_prefix = 6,
2558:
2559:                    MAX_PROTOTYPE_ID = 6;
2560:
2561:            // #/string_id_map#
2562:
2563:            private RECompiled re;
2564:            double lastIndex; /* index after last match, for //g iterator */
2565:
2566:        }; // class NativeRegExp
2567:
2568:        class RECompiled implements  Serializable {
2569:            static final long serialVersionUID = -6144956577595844213L;
2570:
2571:            char[] source; /* locked source string, sans // */
2572:            int parenCount; /* number of parenthesized submatches */
2573:            int flags; /* flags  */
2574:            byte[] program; /* regular expression bytecode */
2575:            int classCount; /* count [...] bitmaps */
2576:            RECharSet[] classList; /* list of [...] bitmaps */
2577:            int anchorCh = -1; /* if >= 0, then re starts with this literal char */
2578:        }
2579:
2580:        class RENode {
2581:
2582:            RENode(byte op) {
2583:                this .op = op;
2584:            }
2585:
2586:            byte op; /* r.e. op bytecode */
2587:            RENode next; /* next in concatenation order */
2588:            RENode kid; /* first operand */
2589:
2590:            RENode kid2; /* second operand */
2591:            int num; /* could be a number */
2592:            int parenIndex; /* or a parenthesis index */
2593:
2594:            /* or a range */
2595:            int min;
2596:            int max;
2597:            int parenCount;
2598:            boolean greedy;
2599:
2600:            /* or a character class */
2601:            int startIndex;
2602:            int kidlen; /* length of string at kid, in chars */
2603:            int bmsize; /* bitmap size, based on max char code */
2604:            int index; /* index into class list */
2605:
2606:            /* or a literal sequence */
2607:            char chr; /* of one character */
2608:            int length; /* or many (via the index) */
2609:            int flatIndex; /* which is -1 if not sourced */
2610:
2611:        }
2612:
2613:        class CompilerState {
2614:
2615:            CompilerState(Context cx, char[] source, int length, int flags) {
2616:                this .cx = cx;
2617:                this .cpbegin = source;
2618:                this .cp = 0;
2619:                this .cpend = length;
2620:                this .flags = flags;
2621:                this .parenCount = 0;
2622:                this .classCount = 0;
2623:                this .progLength = 0;
2624:            }
2625:
2626:            Context cx;
2627:            char cpbegin[];
2628:            int cpend;
2629:            int cp;
2630:            int flags;
2631:            int parenCount;
2632:            int parenNesting;
2633:            int classCount; /* number of [] encountered */
2634:            int progLength; /* estimated bytecode length */
2635:            RENode result;
2636:        }
2637:
2638:        class REProgState {
2639:            REProgState(REProgState previous, int min, int max, int index,
2640:                    REBackTrackData backTrack, int continuation_pc,
2641:                    int continuation_op) {
2642:                this .previous = previous;
2643:                this .min = min;
2644:                this .max = max;
2645:                this .index = index;
2646:                this .continuation_op = continuation_op;
2647:                this .continuation_pc = continuation_pc;
2648:                this .backTrack = backTrack;
2649:            }
2650:
2651:            REProgState previous; // previous state in stack
2652:
2653:            int min; /* current quantifier min */
2654:            int max; /* current quantifier max */
2655:            int index; /* progress in text */
2656:            int continuation_op;
2657:            int continuation_pc;
2658:            REBackTrackData backTrack; // used by ASSERT_  to recover state
2659:        }
2660:
2661:        class REBackTrackData {
2662:
2663:            REBackTrackData(REGlobalData gData, int op, int pc) {
2664:                previous = gData.backTrackStackTop;
2665:                continuation_op = op;
2666:                continuation_pc = pc;
2667:                lastParen = gData.lastParen;
2668:                if (gData.parens != null) {
2669:                    parens = (long[]) gData.parens.clone();
2670:                }
2671:                cp = gData.cp;
2672:                stateStackTop = gData.stateStackTop;
2673:            }
2674:
2675:            REBackTrackData previous;
2676:
2677:            int continuation_op; /* where to backtrack to */
2678:            int continuation_pc;
2679:            int lastParen;
2680:            long[] parens; /* parenthesis captures */
2681:            int cp; /* char buffer index */
2682:            REProgState stateStackTop; /* state of op that backtracked */
2683:        }
2684:
2685:        class REGlobalData {
2686:            boolean multiline;
2687:            RECompiled regexp; /* the RE in execution */
2688:            int lastParen; /* highest paren set so far */
2689:            int skipped; /* chars skipped anchoring this r.e. */
2690:
2691:            int cp; /* char buffer index */
2692:            long[] parens; /* parens captures */
2693:
2694:            REProgState stateStackTop; /* stack of state of current ancestors */
2695:
2696:            REBackTrackData backTrackStackTop; /* last matched-so-far position */
2697:
2698:            /**
2699:             * Get start of parenthesis capture contents, -1 for empty.
2700:             */
2701:            int parens_index(int i) {
2702:                return (int) (parens[i]);
2703:            }
2704:
2705:            /**
2706:             * Get length of parenthesis capture contents.
2707:             */
2708:            int parens_length(int i) {
2709:                return (int) (parens[i] >>> 32);
2710:            }
2711:
2712:            void set_parens(int i, int index, int length) {
2713:                parens[i] = (index & 0xffffffffL) | ((long) length << 32);
2714:            }
2715:
2716:        }
2717:
2718:        /*
2719:         * This struct holds a bitmap representation of a class from a regexp.
2720:         * There's a list of these referenced by the classList field in the NativeRegExp
2721:         * struct below. The initial state has startIndex set to the offset in the
2722:         * original regexp source of the beginning of the class contents. The first
2723:         * use of the class converts the source representation into a bitmap.
2724:         *
2725:         */
2726:        final class RECharSet implements  Serializable {
2727:            static final long serialVersionUID = 7931787979395898394L;
2728:
2729:            RECharSet(int length, int startIndex, int strlength) {
2730:                this .length = length;
2731:                this .startIndex = startIndex;
2732:                this .strlength = strlength;
2733:            }
2734:
2735:            int length;
2736:            int startIndex;
2737:            int strlength;
2738:
2739:            volatile transient boolean converted;
2740:            volatile transient boolean sense;
2741:            volatile transient byte[] bits;
2742:        }
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