mirror of
https://github.com/VictoriaMetrics/VictoriaMetrics.git
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297 lines
6.8 KiB
Go
297 lines
6.8 KiB
Go
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// Copyright 2011 The Go Authors. All rights reserved.
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// Use of this source code is governed by a BSD-style
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// license that can be found in the LICENSE file.
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package syntax
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import "unicode"
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// A patchList is a list of instruction pointers that need to be filled in (patched).
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// Because the pointers haven't been filled in yet, we can reuse their storage
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// to hold the list. It's kind of sleazy, but works well in practice.
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// See https://swtch.com/~rsc/regexp/regexp1.html for inspiration.
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//
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// These aren't really pointers: they're integers, so we can reinterpret them
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// this way without using package unsafe. A value l.head denotes
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// p.inst[l.head>>1].Out (l.head&1==0) or .Arg (l.head&1==1).
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// head == 0 denotes the empty list, okay because we start every program
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// with a fail instruction, so we'll never want to point at its output link.
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type patchList struct {
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head, tail uint32
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}
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func makePatchList(n uint32) patchList {
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return patchList{n, n}
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}
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func (l patchList) patch(p *Prog, val uint32) {
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head := l.head
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for head != 0 {
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i := &p.Inst[head>>1]
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if head&1 == 0 {
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head = i.Out
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i.Out = val
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} else {
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head = i.Arg
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i.Arg = val
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}
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}
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}
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func (l1 patchList) append(p *Prog, l2 patchList) patchList {
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if l1.head == 0 {
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return l2
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}
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if l2.head == 0 {
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return l1
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}
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i := &p.Inst[l1.tail>>1]
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if l1.tail&1 == 0 {
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i.Out = l2.head
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} else {
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i.Arg = l2.head
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}
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return patchList{l1.head, l2.tail}
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}
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// A frag represents a compiled program fragment.
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type frag struct {
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i uint32 // index of first instruction
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out patchList // where to record end instruction
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nullable bool // whether fragment can match empty string
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}
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type compiler struct {
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p *Prog
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}
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// Compile compiles the regexp into a program to be executed.
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// The regexp should have been simplified already (returned from re.Simplify).
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func Compile(re *Regexp) (*Prog, error) {
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var c compiler
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c.init()
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f := c.compile(re)
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f.out.patch(c.p, c.inst(InstMatch).i)
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c.p.Start = int(f.i)
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return c.p, nil
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}
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func (c *compiler) init() {
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c.p = new(Prog)
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c.p.NumCap = 2 // implicit ( and ) for whole match $0
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c.inst(InstFail)
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}
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var anyRuneNotNL = []rune{0, '\n' - 1, '\n' + 1, unicode.MaxRune}
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var anyRune = []rune{0, unicode.MaxRune}
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func (c *compiler) compile(re *Regexp) frag {
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switch re.Op {
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case OpNoMatch:
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return c.fail()
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case OpEmptyMatch:
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return c.nop()
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case OpLiteral:
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if len(re.Rune) == 0 {
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return c.nop()
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}
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var f frag
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for j := range re.Rune {
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f1 := c.rune(re.Rune[j:j+1], re.Flags)
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if j == 0 {
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f = f1
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} else {
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f = c.cat(f, f1)
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}
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}
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return f
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case OpCharClass:
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return c.rune(re.Rune, re.Flags)
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case OpAnyCharNotNL:
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return c.rune(anyRuneNotNL, 0)
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case OpAnyChar:
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return c.rune(anyRune, 0)
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case OpBeginLine:
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return c.empty(EmptyBeginLine)
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case OpEndLine:
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return c.empty(EmptyEndLine)
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case OpBeginText:
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return c.empty(EmptyBeginText)
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case OpEndText:
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return c.empty(EmptyEndText)
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case OpWordBoundary:
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return c.empty(EmptyWordBoundary)
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case OpNoWordBoundary:
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return c.empty(EmptyNoWordBoundary)
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case OpCapture:
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bra := c.cap(uint32(re.Cap << 1))
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sub := c.compile(re.Sub[0])
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ket := c.cap(uint32(re.Cap<<1 | 1))
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return c.cat(c.cat(bra, sub), ket)
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case OpStar:
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return c.star(c.compile(re.Sub[0]), re.Flags&NonGreedy != 0)
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case OpPlus:
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return c.plus(c.compile(re.Sub[0]), re.Flags&NonGreedy != 0)
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case OpQuest:
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return c.quest(c.compile(re.Sub[0]), re.Flags&NonGreedy != 0)
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case OpConcat:
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if len(re.Sub) == 0 {
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return c.nop()
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}
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var f frag
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for i, sub := range re.Sub {
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if i == 0 {
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f = c.compile(sub)
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} else {
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f = c.cat(f, c.compile(sub))
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}
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}
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return f
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case OpAlternate:
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var f frag
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for _, sub := range re.Sub {
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f = c.alt(f, c.compile(sub))
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}
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return f
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}
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panic("regexp: unhandled case in compile")
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}
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func (c *compiler) inst(op InstOp) frag {
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// TODO: impose length limit
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f := frag{i: uint32(len(c.p.Inst)), nullable: true}
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c.p.Inst = append(c.p.Inst, Inst{Op: op})
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return f
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}
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func (c *compiler) nop() frag {
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f := c.inst(InstNop)
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f.out = makePatchList(f.i << 1)
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return f
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}
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func (c *compiler) fail() frag {
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return frag{}
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}
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func (c *compiler) cap(arg uint32) frag {
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f := c.inst(InstCapture)
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f.out = makePatchList(f.i << 1)
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c.p.Inst[f.i].Arg = arg
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if c.p.NumCap < int(arg)+1 {
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c.p.NumCap = int(arg) + 1
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}
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return f
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}
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func (c *compiler) cat(f1, f2 frag) frag {
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// concat of failure is failure
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if f1.i == 0 || f2.i == 0 {
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return frag{}
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}
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// TODO: elide nop
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f1.out.patch(c.p, f2.i)
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return frag{f1.i, f2.out, f1.nullable && f2.nullable}
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}
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func (c *compiler) alt(f1, f2 frag) frag {
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// alt of failure is other
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if f1.i == 0 {
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return f2
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}
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if f2.i == 0 {
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return f1
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}
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f := c.inst(InstAlt)
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i := &c.p.Inst[f.i]
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i.Out = f1.i
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i.Arg = f2.i
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f.out = f1.out.append(c.p, f2.out)
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f.nullable = f1.nullable || f2.nullable
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return f
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}
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func (c *compiler) quest(f1 frag, nongreedy bool) frag {
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f := c.inst(InstAlt)
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i := &c.p.Inst[f.i]
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if nongreedy {
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i.Arg = f1.i
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f.out = makePatchList(f.i << 1)
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} else {
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i.Out = f1.i
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f.out = makePatchList(f.i<<1 | 1)
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}
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f.out = f.out.append(c.p, f1.out)
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return f
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}
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// loop returns the fragment for the main loop of a plus or star.
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// For plus, it can be used after changing the entry to f1.i.
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// For star, it can be used directly when f1 can't match an empty string.
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// (When f1 can match an empty string, f1* must be implemented as (f1+)?
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// to get the priority match order correct.)
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func (c *compiler) loop(f1 frag, nongreedy bool) frag {
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f := c.inst(InstAlt)
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i := &c.p.Inst[f.i]
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if nongreedy {
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i.Arg = f1.i
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f.out = makePatchList(f.i << 1)
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} else {
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i.Out = f1.i
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f.out = makePatchList(f.i<<1 | 1)
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}
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f1.out.patch(c.p, f.i)
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return f
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}
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func (c *compiler) star(f1 frag, nongreedy bool) frag {
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if f1.nullable {
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// Use (f1+)? to get priority match order correct.
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// See golang.org/issue/46123.
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return c.quest(c.plus(f1, nongreedy), nongreedy)
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}
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return c.loop(f1, nongreedy)
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}
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func (c *compiler) plus(f1 frag, nongreedy bool) frag {
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return frag{f1.i, c.loop(f1, nongreedy).out, f1.nullable}
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}
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func (c *compiler) empty(op EmptyOp) frag {
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f := c.inst(InstEmptyWidth)
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c.p.Inst[f.i].Arg = uint32(op)
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f.out = makePatchList(f.i << 1)
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return f
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}
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func (c *compiler) rune(r []rune, flags Flags) frag {
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f := c.inst(InstRune)
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f.nullable = false
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i := &c.p.Inst[f.i]
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i.Rune = r
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flags &= FoldCase // only relevant flag is FoldCase
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if len(r) != 1 || unicode.SimpleFold(r[0]) == r[0] {
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// and sometimes not even that
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flags &^= FoldCase
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}
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i.Arg = uint32(flags)
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f.out = makePatchList(f.i << 1)
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// Special cases for exec machine.
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switch {
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case flags&FoldCase == 0 && (len(r) == 1 || len(r) == 2 && r[0] == r[1]):
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i.Op = InstRune1
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case len(r) == 2 && r[0] == 0 && r[1] == unicode.MaxRune:
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i.Op = InstRuneAny
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case len(r) == 4 && r[0] == 0 && r[1] == '\n'-1 && r[2] == '\n'+1 && r[3] == unicode.MaxRune:
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i.Op = InstRuneAnyNotNL
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}
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return f
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}
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