package syntax import ( "os" "unicode" ) // A patchList is a list of instruction pointers that need to be filled in (patched). // Because the pointers haven't been filled in yet, we can reuse their storage // to hold the list. It's kind of sleazy, but works well in practice. // See http://swtch.com/~rsc/regexp/regexp1.html for inspiration. // // These aren't really pointers: they're integers, so we can reinterpret them // this way without using package unsafe. A value l denotes // p.inst[l>>1].Out (l&1==0) or .Arg (l&1==1). // l == 0 denotes the empty list, okay because we start every program // with a fail instruction, so we'll never want to point at its output link. type patchList uint32 func (l patchList) next(p *Prog) patchList { i := &p.Inst[l>>1] if l&1 == 0 { return patchList(i.Out) } return patchList(i.Arg) } func (l patchList) patch(p *Prog, val uint32) { for l != 0 { i := &p.Inst[l>>1] if l&1 == 0 { l = patchList(i.Out) i.Out = val } else { l = patchList(i.Arg) i.Arg = val } } } func (l1 patchList) append(p *Prog, l2 patchList) patchList { if l1 == 0 { return l2 } if l2 == 0 { return l1 } last := l1 for { next := last.next(p) if next == 0 { break } last = next } i := &p.Inst[last>>1] if last&1 == 0 { i.Out = uint32(l2) } else { i.Arg = uint32(l2) } return l1 } // A frag represents a compiled program fragment. type frag struct { i uint32 // index of first instruction out patchList // where to record end instruction } type compiler struct { p *Prog } // Compile compiles the regexp into a program to be executed. // The regexp should have been simplified already (returned from re.Simplify). func Compile(re *Regexp) (*Prog, os.Error) { var c compiler c.init() f := c.compile(re) f.out.patch(c.p, c.inst(InstMatch).i) c.p.Start = int(f.i) return c.p, nil } func (c *compiler) init() { c.p = new(Prog) c.p.NumCap = 2 // implicit ( and ) for whole match $0 c.inst(InstFail) } var anyRuneNotNL = []rune{0, '\n' - 1, '\n' + 1, unicode.MaxRune} var anyRune = []rune{0, unicode.MaxRune} func (c *compiler) compile(re *Regexp) frag { switch re.Op { case OpNoMatch: return c.fail() case OpEmptyMatch: return c.nop() case OpLiteral: if len(re.Rune) == 0 { return c.nop() } var f frag for j := range re.Rune { f1 := c.rune(re.Rune[j:j+1], re.Flags) if j == 0 { f = f1 } else { f = c.cat(f, f1) } } return f case OpCharClass: return c.rune(re.Rune, re.Flags) case OpAnyCharNotNL: return c.rune(anyRuneNotNL, 0) case OpAnyChar: return c.rune(anyRune, 0) case OpBeginLine: return c.empty(EmptyBeginLine) case OpEndLine: return c.empty(EmptyEndLine) case OpBeginText: return c.empty(EmptyBeginText) case OpEndText: return c.empty(EmptyEndText) case OpWordBoundary: return c.empty(EmptyWordBoundary) case OpNoWordBoundary: return c.empty(EmptyNoWordBoundary) case OpCapture: bra := c.cap(uint32(re.Cap << 1)) sub := c.compile(re.Sub[0]) ket := c.cap(uint32(re.Cap<<1 | 1)) return c.cat(c.cat(bra, sub), ket) case OpStar: return c.star(c.compile(re.Sub[0]), re.Flags&NonGreedy != 0) case OpPlus: return c.plus(c.compile(re.Sub[0]), re.Flags&NonGreedy != 0) case OpQuest: return c.quest(c.compile(re.Sub[0]), re.Flags&NonGreedy != 0) case OpConcat: if len(re.Sub) == 0 { return c.nop() } var f frag for i, sub := range re.Sub { if i == 0 { f = c.compile(sub) } else { f = c.cat(f, c.compile(sub)) } } return f case OpAlternate: var f frag for _, sub := range re.Sub { f = c.alt(f, c.compile(sub)) } return f } panic("regexp: unhandled case in compile") } func (c *compiler) inst(op InstOp) frag { // TODO: impose length limit f := frag{i: uint32(len(c.p.Inst))} c.p.Inst = append(c.p.Inst, Inst{Op: op}) return f } func (c *compiler) nop() frag { f := c.inst(InstNop) f.out = patchList(f.i << 1) return f } func (c *compiler) fail() frag { return frag{} } func (c *compiler) cap(arg uint32) frag { f := c.inst(InstCapture) f.out = patchList(f.i << 1) c.p.Inst[f.i].Arg = arg if c.p.NumCap < int(arg)+1 { c.p.NumCap = int(arg) + 1 } return f } func (c *compiler) cat(f1, f2 frag) frag { // concat of failure is failure if f1.i == 0 || f2.i == 0 { return frag{} } // TODO: elide nop f1.out.patch(c.p, f2.i) return frag{f1.i, f2.out} } func (c *compiler) alt(f1, f2 frag) frag { // alt of failure is other if f1.i == 0 { return f2 } if f2.i == 0 { return f1 } f := c.inst(InstAlt) i := &c.p.Inst[f.i] i.Out = f1.i i.Arg = f2.i f.out = f1.out.append(c.p, f2.out) return f } func (c *compiler) quest(f1 frag, nongreedy bool) frag { f := c.inst(InstAlt) i := &c.p.Inst[f.i] if nongreedy { i.Arg = f1.i f.out = patchList(f.i << 1) } else { i.Out = f1.i f.out = patchList(f.i<<1 | 1) } f.out = f.out.append(c.p, f1.out) return f } func (c *compiler) star(f1 frag, nongreedy bool) frag { f := c.inst(InstAlt) i := &c.p.Inst[f.i] if nongreedy { i.Arg = f1.i f.out = patchList(f.i << 1) } else { i.Out = f1.i f.out = patchList(f.i<<1 | 1) } f1.out.patch(c.p, f.i) return f } func (c *compiler) plus(f1 frag, nongreedy bool) frag { return frag{f1.i, c.star(f1, nongreedy).out} } func (c *compiler) empty(op EmptyOp) frag { f := c.inst(InstEmptyWidth) c.p.Inst[f.i].Arg = uint32(op) f.out = patchList(f.i << 1) return f } func (c *compiler) rune(r []rune, flags Flags) frag { f := c.inst(InstRune) i := &c.p.Inst[f.i] i.Rune = r flags &= FoldCase // only relevant flag is FoldCase if len(r) != 1 || unicode.SimpleFold(r[0]) == r[0] { // and sometimes not even that flags &^= FoldCase } i.Arg = uint32(flags) f.out = patchList(f.i << 1) // Special cases for exec machine. switch { case flags&FoldCase == 0 && (len(r) == 1 || len(r) == 2 && r[0] == r[1]): i.Op = InstRune1 case len(r) == 2 && r[0] == 0 && r[1] == unicode.MaxRune: i.Op = InstRuneAny case len(r) == 4 && r[0] == 0 && r[1] == '\n'-1 && r[2] == '\n'+1 && r[3] == unicode.MaxRune: i.Op = InstRuneAnyNotNL } return f }