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source: code/trunk/vendor/github.com/dlclark/regexp2/runner.go@ 67

Last change on this file since 67 was 67, checked in by Izuru Yakumo, 23 months ago

Use vendored modules

Signed-off-by: Izuru Yakumo <yakumo.izuru@…>

File size: 34.7 KB

Rev	Line
[67]	1	package regexp2
	2
	3	import (
	4	"bytes"
	5	"errors"
	6	"fmt"
	7	"math"
	8	"strconv"
	9	"strings"
	10	"time"
	11	"unicode"
	12
	13	"github.com/dlclark/regexp2/syntax"
	14	)
	15
	16	type runner struct {
	17	re *Regexp
	18	code *syntax.Code
	19
	20	runtextstart int // starting point for search
	21
	22	runtext []rune // text to search
	23	runtextpos int // current position in text
	24	runtextend int
	25
	26	// The backtracking stack. Opcodes use this to store data regarding
	27	// what they have matched and where to backtrack to. Each "frame" on
	28	// the stack takes the form of [CodePosition Data1 Data2...], where
	29	// CodePosition is the position of the current opcode and
	30	// the data values are all optional. The CodePosition can be negative, and
	31	// these values (also called "back2") are used by the BranchMark family of opcodes
	32	// to indicate whether they are backtracking after a successful or failed
	33	// match.
	34	// When we backtrack, we pop the CodePosition off the stack, set the current
	35	// instruction pointer to that code position, and mark the opcode
	36	// with a backtracking flag ("Back"). Each opcode then knows how to
	37	// handle its own data.
	38	runtrack []int
	39	runtrackpos int
	40
	41	// This stack is used to track text positions across different opcodes.
	42	// For example, in /(a*b)+/, the parentheses result in a SetMark/CaptureMark
	43	// pair. SetMark records the text position before we match a*b. Then
	44	// CaptureMark uses that position to figure out where the capture starts.
	45	// Opcodes which push onto this stack are always paired with other opcodes
	46	// which will pop the value from it later. A successful match should mean
	47	// that this stack is empty.
	48	runstack []int
	49	runstackpos int
	50
	51	// The crawl stack is used to keep track of captures. Every time a group
	52	// has a capture, we push its group number onto the runcrawl stack. In
	53	// the case of a balanced match, we push BOTH groups onto the stack.
	54	runcrawl []int
	55	runcrawlpos int
	56
	57	runtrackcount int // count of states that may do backtracking
	58
	59	runmatch *Match // result object
	60
	61	ignoreTimeout bool
	62	timeout time.Duration // timeout in milliseconds (needed for actual)
	63	timeoutChecksToSkip int
	64	timeoutAt time.Time
	65
	66	operator syntax.InstOp
	67	codepos int
	68	rightToLeft bool
	69	caseInsensitive bool
	70	}
	71
	72	// run searches for matches and can continue from the previous match
	73	//
	74	// quick is usually false, but can be true to not return matches, just put it in caches
	75	// textstart is -1 to start at the "beginning" (depending on Right-To-Left), otherwise an index in input
	76	// input is the string to search for our regex pattern
	77	func (re Regexp) run(quick bool, textstart int, input []rune) (Match, error) {
	78
	79	// get a cached runner
	80	runner := re.getRunner()
	81	defer re.putRunner(runner)
	82
	83	if textstart < 0 {
	84	if re.RightToLeft() {
	85	textstart = len(input)
	86	} else {
	87	textstart = 0
	88	}
	89	}
	90
	91	return runner.scan(input, textstart, quick, re.MatchTimeout)
	92	}
	93
	94	// Scans the string to find the first match. Uses the Match object
	95	// both to feed text in and as a place to store matches that come out.
	96	//
	97	// All the action is in the Go() method. Our
	98	// responsibility is to load up the class members before
	99	// calling Go.
	100	//
	101	// The optimizer can compute a set of candidate starting characters,
	102	// and we could use a separate method Skip() that will quickly scan past
	103	// any characters that we know can't match.
	104	func (r runner) scan(rt []rune, textstart int, quick bool, timeout time.Duration) (Match, error) {
	105	r.timeout = timeout
	106	r.ignoreTimeout = (time.Duration(math.MaxInt64) == timeout)
	107	r.runtextstart = textstart
	108	r.runtext = rt
	109	r.runtextend = len(rt)
	110
	111	stoppos := r.runtextend
	112	bump := 1
	113
	114	if r.re.RightToLeft() {
	115	bump = -1
	116	stoppos = 0
	117	}
	118
	119	r.runtextpos = textstart
	120	initted := false
	121
	122	r.startTimeoutWatch()
	123	for {
	124	if r.re.Debug() {
	125	//fmt.Printf("\nSearch content: %v\n", string(r.runtext))
	126	fmt.Printf("\nSearch range: from 0 to %v\n", r.runtextend)
	127	fmt.Printf("Firstchar search starting at %v stopping at %v\n", r.runtextpos, stoppos)
	128	}
	129
	130	if r.findFirstChar() {
	131	if err := r.checkTimeout(); err != nil {
	132	return nil, err
	133	}
	134
	135	if !initted {
	136	r.initMatch()
	137	initted = true
	138	}
	139
	140	if r.re.Debug() {
	141	fmt.Printf("Executing engine starting at %v\n\n", r.runtextpos)
	142	}
	143
	144	if err := r.execute(); err != nil {
	145	return nil, err
	146	}
	147
	148	if r.runmatch.matchcount[0] > 0 {
	149	// We'll return a match even if it touches a previous empty match
	150	return r.tidyMatch(quick), nil
	151	}
	152
	153	// reset state for another go
	154	r.runtrackpos = len(r.runtrack)
	155	r.runstackpos = len(r.runstack)
	156	r.runcrawlpos = len(r.runcrawl)
	157	}
	158
	159	// failure!
	160
	161	if r.runtextpos == stoppos {
	162	r.tidyMatch(true)
	163	return nil, nil
	164	}
	165
	166	// Recognize leading []* and various anchors, and bump on failure accordingly
	167
	168	// r.bump by one and start again
	169
	170	r.runtextpos += bump
	171	}
	172	// We never get here
	173	}
	174
	175	func (r *runner) execute() error {
	176
	177	r.goTo(0)
	178
	179	for {
	180
	181	if r.re.Debug() {
	182	r.dumpState()
	183	}
	184
	185	if err := r.checkTimeout(); err != nil {
	186	return err
	187	}
	188
	189	switch r.operator {
	190	case syntax.Stop:
	191	return nil
	192
	193	case syntax.Nothing:
	194	break
	195
	196	case syntax.Goto:
	197	r.goTo(r.operand(0))
	198	continue
	199
	200	case syntax.Testref:
	201	if !r.runmatch.isMatched(r.operand(0)) {
	202	break
	203	}
	204	r.advance(1)
	205	continue
	206
	207	case syntax.Lazybranch:
	208	r.trackPush1(r.textPos())
	209	r.advance(1)
	210	continue
	211
	212	case syntax.Lazybranch \| syntax.Back:
	213	r.trackPop()
	214	r.textto(r.trackPeek())
	215	r.goTo(r.operand(0))
	216	continue
	217
	218	case syntax.Setmark:
	219	r.stackPush(r.textPos())
	220	r.trackPush()
	221	r.advance(0)
	222	continue
	223
	224	case syntax.Nullmark:
	225	r.stackPush(-1)
	226	r.trackPush()
	227	r.advance(0)
	228	continue
	229
	230	case syntax.Setmark \| syntax.Back, syntax.Nullmark \| syntax.Back:
	231	r.stackPop()
	232	break
	233
	234	case syntax.Getmark:
	235	r.stackPop()
	236	r.trackPush1(r.stackPeek())
	237	r.textto(r.stackPeek())
	238	r.advance(0)
	239	continue
	240
	241	case syntax.Getmark \| syntax.Back:
	242	r.trackPop()
	243	r.stackPush(r.trackPeek())
	244	break
	245
	246	case syntax.Capturemark:
	247	if r.operand(1) != -1 && !r.runmatch.isMatched(r.operand(1)) {
	248	break
	249	}
	250	r.stackPop()
	251	if r.operand(1) != -1 {
	252	r.transferCapture(r.operand(0), r.operand(1), r.stackPeek(), r.textPos())
	253	} else {
	254	r.capture(r.operand(0), r.stackPeek(), r.textPos())
	255	}
	256	r.trackPush1(r.stackPeek())
	257
	258	r.advance(2)
	259
	260	continue
	261
	262	case syntax.Capturemark \| syntax.Back:
	263	r.trackPop()
	264	r.stackPush(r.trackPeek())
	265	r.uncapture()
	266	if r.operand(0) != -1 && r.operand(1) != -1 {
	267	r.uncapture()
	268	}
	269
	270	break
	271
	272	case syntax.Branchmark:
	273	r.stackPop()
	274
	275	matched := r.textPos() - r.stackPeek()
	276
	277	if matched != 0 { // Nonempty match -> loop now
	278	r.trackPush2(r.stackPeek(), r.textPos()) // Save old mark, textpos
	279	r.stackPush(r.textPos()) // Make new mark
	280	r.goTo(r.operand(0)) // Loop
	281	} else { // Empty match -> straight now
	282	r.trackPushNeg1(r.stackPeek()) // Save old mark
	283	r.advance(1) // Straight
	284	}
	285	continue
	286
	287	case syntax.Branchmark \| syntax.Back:
	288	r.trackPopN(2)
	289	r.stackPop()
	290	r.textto(r.trackPeekN(1)) // Recall position
	291	r.trackPushNeg1(r.trackPeek()) // Save old mark
	292	r.advance(1) // Straight
	293	continue
	294
	295	case syntax.Branchmark \| syntax.Back2:
	296	r.trackPop()
	297	r.stackPush(r.trackPeek()) // Recall old mark
	298	break // Backtrack
	299
	300	case syntax.Lazybranchmark:
	301	{
	302	// We hit this the first time through a lazy loop and after each
	303	// successful match of the inner expression. It simply continues
	304	// on and doesn't loop.
	305	r.stackPop()
	306
	307	oldMarkPos := r.stackPeek()
	308
	309	if r.textPos() != oldMarkPos { // Nonempty match -> try to loop again by going to 'back' state
	310	if oldMarkPos != -1 {
	311	r.trackPush2(oldMarkPos, r.textPos()) // Save old mark, textpos
	312	} else {
	313	r.trackPush2(r.textPos(), r.textPos())
	314	}
	315	} else {
	316	// The inner expression found an empty match, so we'll go directly to 'back2' if we
	317	// backtrack. In this case, we need to push something on the stack, since back2 pops.
	318	// However, in the case of ()+? or similar, this empty match may be legitimate, so push the text
	319	// position associated with that empty match.
	320	r.stackPush(oldMarkPos)
	321
	322	r.trackPushNeg1(r.stackPeek()) // Save old mark
	323	}
	324	r.advance(1)
	325	continue
	326	}
	327
	328	case syntax.Lazybranchmark \| syntax.Back:
	329
	330	// After the first time, Lazybranchmark \| syntax.Back occurs
	331	// with each iteration of the loop, and therefore with every attempted
	332	// match of the inner expression. We'll try to match the inner expression,
	333	// then go back to Lazybranchmark if successful. If the inner expression
	334	// fails, we go to Lazybranchmark \| syntax.Back2
	335
	336	r.trackPopN(2)
	337	pos := r.trackPeekN(1)
	338	r.trackPushNeg1(r.trackPeek()) // Save old mark
	339	r.stackPush(pos) // Make new mark
	340	r.textto(pos) // Recall position
	341	r.goTo(r.operand(0)) // Loop
	342	continue
	343
	344	case syntax.Lazybranchmark \| syntax.Back2:
	345	// The lazy loop has failed. We'll do a true backtrack and
	346	// start over before the lazy loop.
	347	r.stackPop()
	348	r.trackPop()
	349	r.stackPush(r.trackPeek()) // Recall old mark
	350	break
	351
	352	case syntax.Setcount:
	353	r.stackPush2(r.textPos(), r.operand(0))
	354	r.trackPush()
	355	r.advance(1)
	356	continue
	357
	358	case syntax.Nullcount:
	359	r.stackPush2(-1, r.operand(0))
	360	r.trackPush()
	361	r.advance(1)
	362	continue
	363
	364	case syntax.Setcount \| syntax.Back:
	365	r.stackPopN(2)
	366	break
	367
	368	case syntax.Nullcount \| syntax.Back:
	369	r.stackPopN(2)
	370	break
	371
	372	case syntax.Branchcount:
	373	// r.stackPush:
	374	// 0: Mark
	375	// 1: Count
	376
	377	r.stackPopN(2)
	378	mark := r.stackPeek()
	379	count := r.stackPeekN(1)
	380	matched := r.textPos() - mark
	381
	382	if count >= r.operand(1) \|\| (matched == 0 && count >= 0) { // Max loops or empty match -> straight now
	383	r.trackPushNeg2(mark, count) // Save old mark, count
	384	r.advance(2) // Straight
	385	} else { // Nonempty match -> count+loop now
	386	r.trackPush1(mark) // remember mark
	387	r.stackPush2(r.textPos(), count+1) // Make new mark, incr count
	388	r.goTo(r.operand(0)) // Loop
	389	}
	390	continue
	391
	392	case syntax.Branchcount \| syntax.Back:
	393	// r.trackPush:
	394	// 0: Previous mark
	395	// r.stackPush:
	396	// 0: Mark (= current pos, discarded)
	397	// 1: Count
	398	r.trackPop()
	399	r.stackPopN(2)
	400	if r.stackPeekN(1) > 0 { // Positive -> can go straight
	401	r.textto(r.stackPeek()) // Zap to mark
	402	r.trackPushNeg2(r.trackPeek(), r.stackPeekN(1)-1) // Save old mark, old count
	403	r.advance(2) // Straight
	404	continue
	405	}
	406	r.stackPush2(r.trackPeek(), r.stackPeekN(1)-1) // recall old mark, old count
	407	break
	408
	409	case syntax.Branchcount \| syntax.Back2:
	410	// r.trackPush:
	411	// 0: Previous mark
	412	// 1: Previous count
	413	r.trackPopN(2)
	414	r.stackPush2(r.trackPeek(), r.trackPeekN(1)) // Recall old mark, old count
	415	break // Backtrack
	416
	417	case syntax.Lazybranchcount:
	418	// r.stackPush:
	419	// 0: Mark
	420	// 1: Count
	421
	422	r.stackPopN(2)
	423	mark := r.stackPeek()
	424	count := r.stackPeekN(1)
	425
	426	if count < 0 { // Negative count -> loop now
	427	r.trackPushNeg1(mark) // Save old mark
	428	r.stackPush2(r.textPos(), count+1) // Make new mark, incr count
	429	r.goTo(r.operand(0)) // Loop
	430	} else { // Nonneg count -> straight now
	431	r.trackPush3(mark, count, r.textPos()) // Save mark, count, position
	432	r.advance(2) // Straight
	433	}
	434	continue
	435
	436	case syntax.Lazybranchcount \| syntax.Back:
	437	// r.trackPush:
	438	// 0: Mark
	439	// 1: Count
	440	// 2: r.textPos
	441
	442	r.trackPopN(3)
	443	mark := r.trackPeek()
	444	textpos := r.trackPeekN(2)
	445
	446	if r.trackPeekN(1) < r.operand(1) && textpos != mark { // Under limit and not empty match -> loop
	447	r.textto(textpos) // Recall position
	448	r.stackPush2(textpos, r.trackPeekN(1)+1) // Make new mark, incr count
	449	r.trackPushNeg1(mark) // Save old mark
	450	r.goTo(r.operand(0)) // Loop
	451	continue
	452	} else { // Max loops or empty match -> backtrack
	453	r.stackPush2(r.trackPeek(), r.trackPeekN(1)) // Recall old mark, count
	454	break // backtrack
	455	}
	456
	457	case syntax.Lazybranchcount \| syntax.Back2:
	458	// r.trackPush:
	459	// 0: Previous mark
	460	// r.stackPush:
	461	// 0: Mark (== current pos, discarded)
	462	// 1: Count
	463	r.trackPop()
	464	r.stackPopN(2)
	465	r.stackPush2(r.trackPeek(), r.stackPeekN(1)-1) // Recall old mark, count
	466	break // Backtrack
	467
	468	case syntax.Setjump:
	469	r.stackPush2(r.trackpos(), r.crawlpos())
	470	r.trackPush()
	471	r.advance(0)
	472	continue
	473
	474	case syntax.Setjump \| syntax.Back:
	475	r.stackPopN(2)
	476	break
	477
	478	case syntax.Backjump:
	479	// r.stackPush:
	480	// 0: Saved trackpos
	481	// 1: r.crawlpos
	482	r.stackPopN(2)
	483	r.trackto(r.stackPeek())
	484
	485	for r.crawlpos() != r.stackPeekN(1) {
	486	r.uncapture()
	487	}
	488
	489	break
	490
	491	case syntax.Forejump:
	492	// r.stackPush:
	493	// 0: Saved trackpos
	494	// 1: r.crawlpos
	495	r.stackPopN(2)
	496	r.trackto(r.stackPeek())
	497	r.trackPush1(r.stackPeekN(1))
	498	r.advance(0)
	499	continue
	500
	501	case syntax.Forejump \| syntax.Back:
	502	// r.trackPush:
	503	// 0: r.crawlpos
	504	r.trackPop()
	505
	506	for r.crawlpos() != r.trackPeek() {
	507	r.uncapture()
	508	}
	509
	510	break
	511
	512	case syntax.Bol:
	513	if r.leftchars() > 0 && r.charAt(r.textPos()-1) != '\n' {
	514	break
	515	}
	516	r.advance(0)
	517	continue
	518
	519	case syntax.Eol:
	520	if r.rightchars() > 0 && r.charAt(r.textPos()) != '\n' {
	521	break
	522	}
	523	r.advance(0)
	524	continue
	525
	526	case syntax.Boundary:
	527	if !r.isBoundary(r.textPos(), 0, r.runtextend) {
	528	break
	529	}
	530	r.advance(0)
	531	continue
	532
	533	case syntax.Nonboundary:
	534	if r.isBoundary(r.textPos(), 0, r.runtextend) {
	535	break
	536	}
	537	r.advance(0)
	538	continue
	539
	540	case syntax.ECMABoundary:
	541	if !r.isECMABoundary(r.textPos(), 0, r.runtextend) {
	542	break
	543	}
	544	r.advance(0)
	545	continue
	546
	547	case syntax.NonECMABoundary:
	548	if r.isECMABoundary(r.textPos(), 0, r.runtextend) {
	549	break
	550	}
	551	r.advance(0)
	552	continue
	553
	554	case syntax.Beginning:
	555	if r.leftchars() > 0 {
	556	break
	557	}
	558	r.advance(0)
	559	continue
	560
	561	case syntax.Start:
	562	if r.textPos() != r.textstart() {
	563	break
	564	}
	565	r.advance(0)
	566	continue
	567
	568	case syntax.EndZ:
	569	rchars := r.rightchars()
	570	if rchars > 1 {
	571	break
	572	}
	573	// RE2 and EcmaScript define $ as "asserts position at the end of the string"
	574	// PCRE/.NET adds "or before the line terminator right at the end of the string (if any)"
	575	if (r.re.options & (RE2 \| ECMAScript)) != 0 {
	576	// RE2/Ecmascript mode
	577	if rchars > 0 {
	578	break
	579	}
	580	} else if rchars == 1 && r.charAt(r.textPos()) != '\n' {
	581	// "regular" mode
	582	break
	583	}
	584
	585	r.advance(0)
	586	continue
	587
	588	case syntax.End:
	589	if r.rightchars() > 0 {
	590	break
	591	}
	592	r.advance(0)
	593	continue
	594
	595	case syntax.One:
	596	if r.forwardchars() < 1 \|\| r.forwardcharnext() != rune(r.operand(0)) {
	597	break
	598	}
	599
	600	r.advance(1)
	601	continue
	602
	603	case syntax.Notone:
	604	if r.forwardchars() < 1 \|\| r.forwardcharnext() == rune(r.operand(0)) {
	605	break
	606	}
	607
	608	r.advance(1)
	609	continue
	610
	611	case syntax.Set:
	612
	613	if r.forwardchars() < 1 \|\| !r.code.Sets[r.operand(0)].CharIn(r.forwardcharnext()) {
	614	break
	615	}
	616
	617	r.advance(1)
	618	continue
	619
	620	case syntax.Multi:
	621	if !r.runematch(r.code.Strings[r.operand(0)]) {
	622	break
	623	}
	624
	625	r.advance(1)
	626	continue
	627
	628	case syntax.Ref:
	629
	630	capnum := r.operand(0)
	631
	632	if r.runmatch.isMatched(capnum) {
	633	if !r.refmatch(r.runmatch.matchIndex(capnum), r.runmatch.matchLength(capnum)) {
	634	break
	635	}
	636	} else {
	637	if (r.re.options & ECMAScript) == 0 {
	638	break
	639	}
	640	}
	641
	642	r.advance(1)
	643	continue
	644
	645	case syntax.Onerep:
	646
	647	c := r.operand(1)
	648
	649	if r.forwardchars() < c {
	650	break
	651	}
	652
	653	ch := rune(r.operand(0))
	654
	655	for c > 0 {
	656	if r.forwardcharnext() != ch {
	657	goto BreakBackward
	658	}
	659	c--
	660	}
	661
	662	r.advance(2)
	663	continue
	664
	665	case syntax.Notonerep:
	666
	667	c := r.operand(1)
	668
	669	if r.forwardchars() < c {
	670	break
	671	}
	672	ch := rune(r.operand(0))
	673
	674	for c > 0 {
	675	if r.forwardcharnext() == ch {
	676	goto BreakBackward
	677	}
	678	c--
	679	}
	680
	681	r.advance(2)
	682	continue
	683
	684	case syntax.Setrep:
	685
	686	c := r.operand(1)
	687
	688	if r.forwardchars() < c {
	689	break
	690	}
	691
	692	set := r.code.Sets[r.operand(0)]
	693
	694	for c > 0 {
	695	if !set.CharIn(r.forwardcharnext()) {
	696	goto BreakBackward
	697	}
	698	c--
	699	}
	700
	701	r.advance(2)
	702	continue
	703
	704	case syntax.Oneloop:
	705
	706	c := r.operand(1)
	707
	708	if c > r.forwardchars() {
	709	c = r.forwardchars()
	710	}
	711
	712	ch := rune(r.operand(0))
	713	i := c
	714
	715	for ; i > 0; i-- {
	716	if r.forwardcharnext() != ch {
	717	r.backwardnext()
	718	break
	719	}
	720	}
	721
	722	if c > i {
	723	r.trackPush2(c-i-1, r.textPos()-r.bump())
	724	}
	725
	726	r.advance(2)
	727	continue
	728
	729	case syntax.Notoneloop:
	730
	731	c := r.operand(1)
	732
	733	if c > r.forwardchars() {
	734	c = r.forwardchars()
	735	}
	736
	737	ch := rune(r.operand(0))
	738	i := c
	739
	740	for ; i > 0; i-- {
	741	if r.forwardcharnext() == ch {
	742	r.backwardnext()
	743	break
	744	}
	745	}
	746
	747	if c > i {
	748	r.trackPush2(c-i-1, r.textPos()-r.bump())
	749	}
	750
	751	r.advance(2)
	752	continue
	753
	754	case syntax.Setloop:
	755
	756	c := r.operand(1)
	757
	758	if c > r.forwardchars() {
	759	c = r.forwardchars()
	760	}
	761
	762	set := r.code.Sets[r.operand(0)]
	763	i := c
	764
	765	for ; i > 0; i-- {
	766	if !set.CharIn(r.forwardcharnext()) {
	767	r.backwardnext()
	768	break
	769	}
	770	}
	771
	772	if c > i {
	773	r.trackPush2(c-i-1, r.textPos()-r.bump())
	774	}
	775
	776	r.advance(2)
	777	continue
	778
	779	case syntax.Oneloop \| syntax.Back, syntax.Notoneloop \| syntax.Back:
	780
	781	r.trackPopN(2)
	782	i := r.trackPeek()
	783	pos := r.trackPeekN(1)
	784
	785	r.textto(pos)
	786
	787	if i > 0 {
	788	r.trackPush2(i-1, pos-r.bump())
	789	}
	790
	791	r.advance(2)
	792	continue
	793
	794	case syntax.Setloop \| syntax.Back:
	795
	796	r.trackPopN(2)
	797	i := r.trackPeek()
	798	pos := r.trackPeekN(1)
	799
	800	r.textto(pos)
	801
	802	if i > 0 {
	803	r.trackPush2(i-1, pos-r.bump())
	804	}
	805
	806	r.advance(2)
	807	continue
	808
	809	case syntax.Onelazy, syntax.Notonelazy:
	810
	811	c := r.operand(1)
	812
	813	if c > r.forwardchars() {
	814	c = r.forwardchars()
	815	}
	816
	817	if c > 0 {
	818	r.trackPush2(c-1, r.textPos())
	819	}
	820
	821	r.advance(2)
	822	continue
	823
	824	case syntax.Setlazy:
	825
	826	c := r.operand(1)
	827
	828	if c > r.forwardchars() {
	829	c = r.forwardchars()
	830	}
	831
	832	if c > 0 {
	833	r.trackPush2(c-1, r.textPos())
	834	}
	835
	836	r.advance(2)
	837	continue
	838
	839	case syntax.Onelazy \| syntax.Back:
	840
	841	r.trackPopN(2)
	842	pos := r.trackPeekN(1)
	843	r.textto(pos)
	844
	845	if r.forwardcharnext() != rune(r.operand(0)) {
	846	break
	847	}
	848
	849	i := r.trackPeek()
	850
	851	if i > 0 {
	852	r.trackPush2(i-1, pos+r.bump())
	853	}
	854
	855	r.advance(2)
	856	continue
	857
	858	case syntax.Notonelazy \| syntax.Back:
	859
	860	r.trackPopN(2)
	861	pos := r.trackPeekN(1)
	862	r.textto(pos)
	863
	864	if r.forwardcharnext() == rune(r.operand(0)) {
	865	break
	866	}
	867
	868	i := r.trackPeek()
	869
	870	if i > 0 {
	871	r.trackPush2(i-1, pos+r.bump())
	872	}
	873
	874	r.advance(2)
	875	continue
	876
	877	case syntax.Setlazy \| syntax.Back:
	878
	879	r.trackPopN(2)
	880	pos := r.trackPeekN(1)
	881	r.textto(pos)
	882
	883	if !r.code.Sets[r.operand(0)].CharIn(r.forwardcharnext()) {
	884	break
	885	}
	886
	887	i := r.trackPeek()
	888
	889	if i > 0 {
	890	r.trackPush2(i-1, pos+r.bump())
	891	}
	892
	893	r.advance(2)
	894	continue
	895
	896	default:
	897	return errors.New("unknown state in regex runner")
	898	}
	899
	900	BreakBackward:
	901	;
	902
	903	// "break Backward" comes here:
	904	r.backtrack()
	905	}
	906	}
	907
	908	// increase the size of stack and track storage
	909	func (r *runner) ensureStorage() {
	910	if r.runstackpos < r.runtrackcount*4 {
	911	doubleIntSlice(&r.runstack, &r.runstackpos)
	912	}
	913	if r.runtrackpos < r.runtrackcount*4 {
	914	doubleIntSlice(&r.runtrack, &r.runtrackpos)
	915	}
	916	}
	917
	918	func doubleIntSlice(s []int, pos int) {
	919	oldLen := len(*s)
	920	newS := make([]int, oldLen*2)
	921
	922	copy(newS[oldLen:], *s)
	923	*pos += oldLen
	924	*s = newS
	925	}
	926
	927	// Save a number on the longjump unrolling stack
	928	func (r *runner) crawl(i int) {
	929	if r.runcrawlpos == 0 {
	930	doubleIntSlice(&r.runcrawl, &r.runcrawlpos)
	931	}
	932	r.runcrawlpos--
	933	r.runcrawl[r.runcrawlpos] = i
	934	}
	935
	936	// Remove a number from the longjump unrolling stack
	937	func (r *runner) popcrawl() int {
	938	val := r.runcrawl[r.runcrawlpos]
	939	r.runcrawlpos++
	940	return val
	941	}
	942
	943	// Get the height of the stack
	944	func (r *runner) crawlpos() int {
	945	return len(r.runcrawl) - r.runcrawlpos
	946	}
	947
	948	func (r *runner) advance(i int) {
	949	r.codepos += (i + 1)
	950	r.setOperator(r.code.Codes[r.codepos])
	951	}
	952
	953	func (r *runner) goTo(newpos int) {
	954	// when branching backward or in place, ensure storage
	955	if newpos <= r.codepos {
	956	r.ensureStorage()
	957	}
	958
	959	r.setOperator(r.code.Codes[newpos])
	960	r.codepos = newpos
	961	}
	962
	963	func (r *runner) textto(newpos int) {
	964	r.runtextpos = newpos
	965	}
	966
	967	func (r *runner) trackto(newpos int) {
	968	r.runtrackpos = len(r.runtrack) - newpos
	969	}
	970
	971	func (r *runner) textstart() int {
	972	return r.runtextstart
	973	}
	974
	975	func (r *runner) textPos() int {
	976	return r.runtextpos
	977	}
	978
	979	// push onto the backtracking stack
	980	func (r *runner) trackpos() int {
	981	return len(r.runtrack) - r.runtrackpos
	982	}
	983
	984	func (r *runner) trackPush() {
	985	r.runtrackpos--
	986	r.runtrack[r.runtrackpos] = r.codepos
	987	}
	988
	989	func (r *runner) trackPush1(I1 int) {
	990	r.runtrackpos--
	991	r.runtrack[r.runtrackpos] = I1
	992	r.runtrackpos--
	993	r.runtrack[r.runtrackpos] = r.codepos
	994	}
	995
	996	func (r *runner) trackPush2(I1, I2 int) {
	997	r.runtrackpos--
	998	r.runtrack[r.runtrackpos] = I1
	999	r.runtrackpos--
	1000	r.runtrack[r.runtrackpos] = I2
	1001	r.runtrackpos--
	1002	r.runtrack[r.runtrackpos] = r.codepos
	1003	}
	1004
	1005	func (r *runner) trackPush3(I1, I2, I3 int) {
	1006	r.runtrackpos--
	1007	r.runtrack[r.runtrackpos] = I1
	1008	r.runtrackpos--
	1009	r.runtrack[r.runtrackpos] = I2
	1010	r.runtrackpos--
	1011	r.runtrack[r.runtrackpos] = I3
	1012	r.runtrackpos--
	1013	r.runtrack[r.runtrackpos] = r.codepos
	1014	}
	1015
	1016	func (r *runner) trackPushNeg1(I1 int) {
	1017	r.runtrackpos--
	1018	r.runtrack[r.runtrackpos] = I1
	1019	r.runtrackpos--
	1020	r.runtrack[r.runtrackpos] = -r.codepos
	1021	}
	1022
	1023	func (r *runner) trackPushNeg2(I1, I2 int) {
	1024	r.runtrackpos--
	1025	r.runtrack[r.runtrackpos] = I1
	1026	r.runtrackpos--
	1027	r.runtrack[r.runtrackpos] = I2
	1028	r.runtrackpos--
	1029	r.runtrack[r.runtrackpos] = -r.codepos
	1030	}
	1031
	1032	func (r *runner) backtrack() {
	1033	newpos := r.runtrack[r.runtrackpos]
	1034	r.runtrackpos++
	1035
	1036	if r.re.Debug() {
	1037	if newpos < 0 {
	1038	fmt.Printf(" Backtracking (back2) to code position %v\n", -newpos)
	1039	} else {
	1040	fmt.Printf(" Backtracking to code position %v\n", newpos)
	1041	}
	1042	}
	1043
	1044	if newpos < 0 {
	1045	newpos = -newpos
	1046	r.setOperator(r.code.Codes[newpos] \| syntax.Back2)
	1047	} else {
	1048	r.setOperator(r.code.Codes[newpos] \| syntax.Back)
	1049	}
	1050
	1051	// When branching backward, ensure storage
	1052	if newpos < r.codepos {
	1053	r.ensureStorage()
	1054	}
	1055
	1056	r.codepos = newpos
	1057	}
	1058
	1059	func (r *runner) setOperator(op int) {
	1060	r.caseInsensitive = (0 != (op & syntax.Ci))
	1061	r.rightToLeft = (0 != (op & syntax.Rtl))
	1062	r.operator = syntax.InstOp(op & ^(syntax.Rtl \| syntax.Ci))
	1063	}
	1064
	1065	func (r *runner) trackPop() {
	1066	r.runtrackpos++
	1067	}
	1068
	1069	// pop framesize items from the backtracking stack
	1070	func (r *runner) trackPopN(framesize int) {
	1071	r.runtrackpos += framesize
	1072	}
	1073
	1074	// Technically we are actually peeking at items already popped. So if you want to
	1075	// get and pop the top item from the stack, you do
	1076	// r.trackPop();
	1077	// r.trackPeek();
	1078	func (r *runner) trackPeek() int {
	1079	return r.runtrack[r.runtrackpos-1]
	1080	}
	1081
	1082	// get the ith element down on the backtracking stack
	1083	func (r *runner) trackPeekN(i int) int {
	1084	return r.runtrack[r.runtrackpos-i-1]
	1085	}
	1086
	1087	// Push onto the grouping stack
	1088	func (r *runner) stackPush(I1 int) {
	1089	r.runstackpos--
	1090	r.runstack[r.runstackpos] = I1
	1091	}
	1092
	1093	func (r *runner) stackPush2(I1, I2 int) {
	1094	r.runstackpos--
	1095	r.runstack[r.runstackpos] = I1
	1096	r.runstackpos--
	1097	r.runstack[r.runstackpos] = I2
	1098	}
	1099
	1100	func (r *runner) stackPop() {
	1101	r.runstackpos++
	1102	}
	1103
	1104	// pop framesize items from the grouping stack
	1105	func (r *runner) stackPopN(framesize int) {
	1106	r.runstackpos += framesize
	1107	}
	1108
	1109	// Technically we are actually peeking at items already popped. So if you want to
	1110	// get and pop the top item from the stack, you do
	1111	// r.stackPop();
	1112	// r.stackPeek();
	1113	func (r *runner) stackPeek() int {
	1114	return r.runstack[r.runstackpos-1]
	1115	}
	1116
	1117	// get the ith element down on the grouping stack
	1118	func (r *runner) stackPeekN(i int) int {
	1119	return r.runstack[r.runstackpos-i-1]
	1120	}
	1121
	1122	func (r *runner) operand(i int) int {
	1123	return r.code.Codes[r.codepos+i+1]
	1124	}
	1125
	1126	func (r *runner) leftchars() int {
	1127	return r.runtextpos
	1128	}
	1129
	1130	func (r *runner) rightchars() int {
	1131	return r.runtextend - r.runtextpos
	1132	}
	1133
	1134	func (r *runner) bump() int {
	1135	if r.rightToLeft {
	1136	return -1
	1137	}
	1138	return 1
	1139	}
	1140
	1141	func (r *runner) forwardchars() int {
	1142	if r.rightToLeft {
	1143	return r.runtextpos
	1144	}
	1145	return r.runtextend - r.runtextpos
	1146	}
	1147
	1148	func (r *runner) forwardcharnext() rune {
	1149	var ch rune
	1150	if r.rightToLeft {
	1151	r.runtextpos--
	1152	ch = r.runtext[r.runtextpos]
	1153	} else {
	1154	ch = r.runtext[r.runtextpos]
	1155	r.runtextpos++
	1156	}
	1157
	1158	if r.caseInsensitive {
	1159	return unicode.ToLower(ch)
	1160	}
	1161	return ch
	1162	}
	1163
	1164	func (r *runner) runematch(str []rune) bool {
	1165	var pos int
	1166
	1167	c := len(str)
	1168	if !r.rightToLeft {
	1169	if r.runtextend-r.runtextpos < c {
	1170	return false
	1171	}
	1172
	1173	pos = r.runtextpos + c
	1174	} else {
	1175	if r.runtextpos-0 < c {
	1176	return false
	1177	}
	1178
	1179	pos = r.runtextpos
	1180	}
	1181
	1182	if !r.caseInsensitive {
	1183	for c != 0 {
	1184	c--
	1185	pos--
	1186	if str[c] != r.runtext[pos] {
	1187	return false
	1188	}
	1189	}
	1190	} else {
	1191	for c != 0 {
	1192	c--
	1193	pos--
	1194	if str[c] != unicode.ToLower(r.runtext[pos]) {
	1195	return false
	1196	}
	1197	}
	1198	}
	1199
	1200	if !r.rightToLeft {
	1201	pos += len(str)
	1202	}
	1203
	1204	r.runtextpos = pos
	1205
	1206	return true
	1207	}
	1208
	1209	func (r *runner) refmatch(index, len int) bool {
	1210	var c, pos, cmpos int
	1211
	1212	if !r.rightToLeft {
	1213	if r.runtextend-r.runtextpos < len {
	1214	return false
	1215	}
	1216
	1217	pos = r.runtextpos + len
	1218	} else {
	1219	if r.runtextpos-0 < len {
	1220	return false
	1221	}
	1222
	1223	pos = r.runtextpos
	1224	}
	1225	cmpos = index + len
	1226
	1227	c = len
	1228
	1229	if !r.caseInsensitive {
	1230	for c != 0 {
	1231	c--
	1232	cmpos--
	1233	pos--
	1234	if r.runtext[cmpos] != r.runtext[pos] {
	1235	return false
	1236	}
	1237
	1238	}
	1239	} else {
	1240	for c != 0 {
	1241	c--
	1242	cmpos--
	1243	pos--
	1244
	1245	if unicode.ToLower(r.runtext[cmpos]) != unicode.ToLower(r.runtext[pos]) {
	1246	return false
	1247	}
	1248	}
	1249	}
	1250
	1251	if !r.rightToLeft {
	1252	pos += len
	1253	}
	1254
	1255	r.runtextpos = pos
	1256
	1257	return true
	1258	}
	1259
	1260	func (r *runner) backwardnext() {
	1261	if r.rightToLeft {
	1262	r.runtextpos++
	1263	} else {
	1264	r.runtextpos--
	1265	}
	1266	}
	1267
	1268	func (r *runner) charAt(j int) rune {
	1269	return r.runtext[j]
	1270	}
	1271
	1272	func (r *runner) findFirstChar() bool {
	1273
	1274	if 0 != (r.code.Anchors & (syntax.AnchorBeginning \| syntax.AnchorStart \| syntax.AnchorEndZ \| syntax.AnchorEnd)) {
	1275	if !r.code.RightToLeft {
	1276	if (0 != (r.code.Anchors&syntax.AnchorBeginning) && r.runtextpos > 0) \|\|
	1277	(0 != (r.code.Anchors&syntax.AnchorStart) && r.runtextpos > r.runtextstart) {
	1278	r.runtextpos = r.runtextend
	1279	return false
	1280	}
	1281	if 0 != (r.code.Anchors&syntax.AnchorEndZ) && r.runtextpos < r.runtextend-1 {
	1282	r.runtextpos = r.runtextend - 1
	1283	} else if 0 != (r.code.Anchors&syntax.AnchorEnd) && r.runtextpos < r.runtextend {
	1284	r.runtextpos = r.runtextend
	1285	}
	1286	} else {
	1287	if (0 != (r.code.Anchors&syntax.AnchorEnd) && r.runtextpos < r.runtextend) \|\|
	1288	(0 != (r.code.Anchors&syntax.AnchorEndZ) && (r.runtextpos < r.runtextend-1 \|\|
	1289	(r.runtextpos == r.runtextend-1 && r.charAt(r.runtextpos) != '\n'))) \|\|
	1290	(0 != (r.code.Anchors&syntax.AnchorStart) && r.runtextpos < r.runtextstart) {
	1291	r.runtextpos = 0
	1292	return false
	1293	}
	1294	if 0 != (r.code.Anchors&syntax.AnchorBeginning) && r.runtextpos > 0 {
	1295	r.runtextpos = 0
	1296	}
	1297	}
	1298
	1299	if r.code.BmPrefix != nil {
	1300	return r.code.BmPrefix.IsMatch(r.runtext, r.runtextpos, 0, r.runtextend)
	1301	}
	1302
	1303	return true // found a valid start or end anchor
	1304	} else if r.code.BmPrefix != nil {
	1305	r.runtextpos = r.code.BmPrefix.Scan(r.runtext, r.runtextpos, 0, r.runtextend)
	1306
	1307	if r.runtextpos == -1 {
	1308	if r.code.RightToLeft {
	1309	r.runtextpos = 0
	1310	} else {
	1311	r.runtextpos = r.runtextend
	1312	}
	1313	return false
	1314	}
	1315
	1316	return true
	1317	} else if r.code.FcPrefix == nil {
	1318	return true
	1319	}
	1320
	1321	r.rightToLeft = r.code.RightToLeft
	1322	r.caseInsensitive = r.code.FcPrefix.CaseInsensitive
	1323
	1324	set := r.code.FcPrefix.PrefixSet
	1325	if set.IsSingleton() {
	1326	ch := set.SingletonChar()
	1327	for i := r.forwardchars(); i > 0; i-- {
	1328	if ch == r.forwardcharnext() {
	1329	r.backwardnext()
	1330	return true
	1331	}
	1332	}
	1333	} else {
	1334	for i := r.forwardchars(); i > 0; i-- {
	1335	n := r.forwardcharnext()
	1336	//fmt.Printf("%v in %v: %v\n", string(n), set.String(), set.CharIn(n))
	1337	if set.CharIn(n) {
	1338	r.backwardnext()
	1339	return true
	1340	}
	1341	}
	1342	}
	1343
	1344	return false
	1345	}
	1346
	1347	func (r *runner) initMatch() {
	1348	// Use a hashtable'ed Match object if the capture numbers are sparse
	1349
	1350	if r.runmatch == nil {
	1351	if r.re.caps != nil {
	1352	r.runmatch = newMatchSparse(r.re, r.re.caps, r.re.capsize, r.runtext, r.runtextstart)
	1353	} else {
	1354	r.runmatch = newMatch(r.re, r.re.capsize, r.runtext, r.runtextstart)
	1355	}
	1356	} else {
	1357	r.runmatch.reset(r.runtext, r.runtextstart)
	1358	}
	1359
	1360	// note we test runcrawl, because it is the last one to be allocated
	1361	// If there is an alloc failure in the middle of the three allocations,
	1362	// we may still return to reuse this instance, and we want to behave
	1363	// as if the allocations didn't occur. (we used to test _trackcount != 0)
	1364
	1365	if r.runcrawl != nil {
	1366	r.runtrackpos = len(r.runtrack)
	1367	r.runstackpos = len(r.runstack)
	1368	r.runcrawlpos = len(r.runcrawl)
	1369	return
	1370	}
	1371
	1372	r.initTrackCount()
	1373
	1374	tracksize := r.runtrackcount * 8
	1375	stacksize := r.runtrackcount * 8
	1376
	1377	if tracksize < 32 {
	1378	tracksize = 32
	1379	}
	1380	if stacksize < 16 {
	1381	stacksize = 16
	1382	}
	1383
	1384	r.runtrack = make([]int, tracksize)
	1385	r.runtrackpos = tracksize
	1386
	1387	r.runstack = make([]int, stacksize)
	1388	r.runstackpos = stacksize
	1389
	1390	r.runcrawl = make([]int, 32)
	1391	r.runcrawlpos = 32
	1392	}
	1393
	1394	func (r runner) tidyMatch(quick bool) Match {
	1395	if !quick {
	1396	match := r.runmatch
	1397
	1398	r.runmatch = nil
	1399
	1400	match.tidy(r.runtextpos)
	1401	return match
	1402	} else {
	1403	// send back our match -- it's not leaving the package, so it's safe to not clean it up
	1404	// this reduces allocs for frequent calls to the "IsMatch" bool-only functions
	1405	return r.runmatch
	1406	}
	1407	}
	1408
	1409	// capture captures a subexpression. Note that the
	1410	// capnum used here has already been mapped to a non-sparse
	1411	// index (by the code generator RegexWriter).
	1412	func (r *runner) capture(capnum, start, end int) {
	1413	if end < start {
	1414	T := end
	1415	end = start
	1416	start = T
	1417	}
	1418
	1419	r.crawl(capnum)
	1420	r.runmatch.addMatch(capnum, start, end-start)
	1421	}
	1422
	1423	// transferCapture captures a subexpression. Note that the
	1424	// capnum used here has already been mapped to a non-sparse
	1425	// index (by the code generator RegexWriter).
	1426	func (r *runner) transferCapture(capnum, uncapnum, start, end int) {
	1427	var start2, end2 int
	1428
	1429	// these are the two intervals that are cancelling each other
	1430
	1431	if end < start {
	1432	T := end
	1433	end = start
	1434	start = T
	1435	}
	1436
	1437	start2 = r.runmatch.matchIndex(uncapnum)
	1438	end2 = start2 + r.runmatch.matchLength(uncapnum)
	1439
	1440	// The new capture gets the innermost defined interval
	1441
	1442	if start >= end2 {
	1443	end = start
	1444	start = end2
	1445	} else if end <= start2 {
	1446	start = start2
	1447	} else {
	1448	if end > end2 {
	1449	end = end2
	1450	}
	1451	if start2 > start {
	1452	start = start2
	1453	}
	1454	}
	1455
	1456	r.crawl(uncapnum)
	1457	r.runmatch.balanceMatch(uncapnum)
	1458
	1459	if capnum != -1 {
	1460	r.crawl(capnum)
	1461	r.runmatch.addMatch(capnum, start, end-start)
	1462	}
	1463	}
	1464
	1465	// revert the last capture
	1466	func (r *runner) uncapture() {
	1467	capnum := r.popcrawl()
	1468	r.runmatch.removeMatch(capnum)
	1469	}
	1470
	1471	//debug
	1472
	1473	func (r *runner) dumpState() {
	1474	back := ""
	1475	if r.operator&syntax.Back != 0 {
	1476	back = " Back"
	1477	}
	1478	if r.operator&syntax.Back2 != 0 {
	1479	back += " Back2"
	1480	}
	1481	fmt.Printf("Text: %v\nTrack: %v\nStack: %v\n %s%s\n\n",
	1482	r.textposDescription(),
	1483	r.stackDescription(r.runtrack, r.runtrackpos),
	1484	r.stackDescription(r.runstack, r.runstackpos),
	1485	r.code.OpcodeDescription(r.codepos),
	1486	back)
	1487	}
	1488
	1489	func (r *runner) stackDescription(a []int, index int) string {
	1490	buf := &bytes.Buffer{}
	1491
	1492	fmt.Fprintf(buf, "%v/%v", len(a)-index, len(a))
	1493	if buf.Len() < 8 {
	1494	buf.WriteString(strings.Repeat(" ", 8-buf.Len()))
	1495	}
	1496
	1497	buf.WriteRune('(')
	1498	for i := index; i < len(a); i++ {
	1499	if i > index {
	1500	buf.WriteRune(' ')
	1501	}
	1502
	1503	buf.WriteString(strconv.Itoa(a[i]))
	1504	}
	1505
	1506	buf.WriteRune(')')
	1507
	1508	return buf.String()
	1509	}
	1510
	1511	func (r *runner) textposDescription() string {
	1512	buf := &bytes.Buffer{}
	1513
	1514	buf.WriteString(strconv.Itoa(r.runtextpos))
	1515
	1516	if buf.Len() < 8 {
	1517	buf.WriteString(strings.Repeat(" ", 8-buf.Len()))
	1518	}
	1519
	1520	if r.runtextpos > 0 {
	1521	buf.WriteString(syntax.CharDescription(r.runtext[r.runtextpos-1]))
	1522	} else {
	1523	buf.WriteRune('^')
	1524	}
	1525
	1526	buf.WriteRune('>')
	1527
	1528	for i := r.runtextpos; i < r.runtextend; i++ {
	1529	buf.WriteString(syntax.CharDescription(r.runtext[i]))
	1530	}
	1531	if buf.Len() >= 64 {
	1532	buf.Truncate(61)
	1533	buf.WriteString("...")
	1534	} else {
	1535	buf.WriteRune('$')
	1536	}
	1537
	1538	return buf.String()
	1539	}
	1540
	1541	// decide whether the pos
	1542	// at the specified index is a boundary or not. It's just not worth
	1543	// emitting inline code for this logic.
	1544	func (r *runner) isBoundary(index, startpos, endpos int) bool {
	1545	return (index > startpos && syntax.IsWordChar(r.runtext[index-1])) !=
	1546	(index < endpos && syntax.IsWordChar(r.runtext[index]))
	1547	}
	1548
	1549	func (r *runner) isECMABoundary(index, startpos, endpos int) bool {
	1550	return (index > startpos && syntax.IsECMAWordChar(r.runtext[index-1])) !=
	1551	(index < endpos && syntax.IsECMAWordChar(r.runtext[index]))
	1552	}
	1553
	1554	// this seems like a comment to justify randomly picking 1000 :-P
	1555	// We have determined this value in a series of experiments where x86 retail
	1556	// builds (ono-lab-optimized) were run on different pattern/input pairs. Larger values
	1557	// of TimeoutCheckFrequency did not tend to increase performance; smaller values
	1558	// of TimeoutCheckFrequency tended to slow down the execution.
	1559	const timeoutCheckFrequency int = 1000
	1560
	1561	func (r *runner) startTimeoutWatch() {
	1562	if r.ignoreTimeout {
	1563	return
	1564	}
	1565
	1566	r.timeoutChecksToSkip = timeoutCheckFrequency
	1567	r.timeoutAt = time.Now().Add(r.timeout)
	1568	}
	1569
	1570	func (r *runner) checkTimeout() error {
	1571	if r.ignoreTimeout {
	1572	return nil
	1573	}
	1574	r.timeoutChecksToSkip--
	1575	if r.timeoutChecksToSkip != 0 {
	1576	return nil
	1577	}
	1578
	1579	r.timeoutChecksToSkip = timeoutCheckFrequency
	1580	return r.doCheckTimeout()
	1581	}
	1582
	1583	func (r *runner) doCheckTimeout() error {
	1584	current := time.Now()
	1585
	1586	if current.Before(r.timeoutAt) {
	1587	return nil
	1588	}
	1589
	1590	if r.re.Debug() {
	1591	//Debug.WriteLine("")
	1592	//Debug.WriteLine("RegEx match timeout occurred!")
	1593	//Debug.WriteLine("Specified timeout: " + TimeSpan.FromMilliseconds(_timeout).ToString())
	1594	//Debug.WriteLine("Timeout check frequency: " + TimeoutCheckFrequency)
	1595	//Debug.WriteLine("Search pattern: " + _runregex._pattern)
	1596	//Debug.WriteLine("Input: " + r.runtext)
	1597	//Debug.WriteLine("About to throw RegexMatchTimeoutException.")
	1598	}
	1599
	1600	return fmt.Errorf("match timeout after %v on input `%v`", r.timeout, string(r.runtext))
	1601	}
	1602
	1603	func (r *runner) initTrackCount() {
	1604	r.runtrackcount = r.code.TrackCount
	1605	}
	1606
	1607	// getRunner returns a run to use for matching re.
	1608	// It uses the re's runner cache if possible, to avoid
	1609	// unnecessary allocation.
	1610	func (re Regexp) getRunner() runner {
	1611	re.muRun.Lock()
	1612	if n := len(re.runner); n > 0 {
	1613	z := re.runner[n-1]
	1614	re.runner = re.runner[:n-1]
	1615	re.muRun.Unlock()
	1616	return z
	1617	}
	1618	re.muRun.Unlock()
	1619	z := &runner{
	1620	re: re,
	1621	code: re.code,
	1622	}
	1623	return z
	1624	}
	1625
	1626	// putRunner returns a runner to the re's cache.
	1627	// There is no attempt to limit the size of the cache, so it will
	1628	// grow to the maximum number of simultaneous matches
	1629	// run using re. (The cache empties when re gets garbage collected.)
	1630	func (re Regexp) putRunner(r runner) {
	1631	re.muRun.Lock()
	1632	re.runner = append(re.runner, r)
	1633	re.muRun.Unlock()
	1634	}

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