src/pkg/exp/norm/maketables.go - go - Git at Google

 // Copyright 2011 The Go Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style
 // license that can be found in the LICENSE file.

 // Normalization table generator.
 // Data read from the web.

 package main

 import (
 	"bufio"
 	"bytes"
 	"flag"
 	"fmt"
 	"http"
 	"io"
 	"log"
 	"os"
 	"regexp"
 	"strconv"
 	"strings"
 )

 func main() {
 	flag.Parse()
 	loadUnicodeData()
 	loadCompositionExclusions()
 	completeCharFields(FCanonical)
 	completeCharFields(FCompatibility)
 	verifyComputed()
 	printChars()
 	makeTables()
 	testDerived()
 }

 var url = flag.String("url",
 	"http://www.unicode.org/Public/6.0.0/ucd/",
 	"URL of Unicode database directory")
 var tablelist = flag.String("tables",
 	"all",
 	"comma-separated list of which tables to generate; "+
 		"can be 'decomp', 'recomp', 'info' and 'all'")
 var test = flag.Bool("test",
 	false,
 	"test existing tables; can be used to compare web data with package data")
 var verbose = flag.Bool("verbose",
 	false,
 	"write data to stdout as it is parsed")
 var localFiles = flag.Bool("local",
 	false,
 	"data files have been copied to the current directory; for debugging only")

 var logger = log.New(os.Stderr, "", log.Lshortfile)

 // UnicodeData.txt has form:
 //	0037;DIGIT SEVEN;Nd;0;EN;;7;7;7;N;;;;;
 //	007A;LATIN SMALL LETTER Z;Ll;0;L;;;;;N;;;005A;;005A
 // See http://unicode.org/reports/tr44/ for full explanation
 // The fields:
 const (
 	FCodePoint = iota
 	FName
 	FGeneralCategory
 	FCanonicalCombiningClass
 	FBidiClass
 	FDecompMapping
 	FDecimalValue
 	FDigitValue
 	FNumericValue
 	FBidiMirrored
 	FUnicode1Name
 	FISOComment
 	FSimpleUppercaseMapping
 	FSimpleLowercaseMapping
 	FSimpleTitlecaseMapping
 	NumField

 	MaxChar = 0x10FFFF // anything above this shouldn't exist
 )

 // Quick Check properties of runes allow us to quickly
 // determine whether a rune may occur in a normal form.
 // For a given normal form, a rune may be guaranteed to occur
 // verbatim (QC=Yes), may or may not combine with another
 // rune (QC=Maybe), or may not occur (QC=No).
 type QCResult int

 const (
 	QCUnknown QCResult = iota
 	QCYes
 	QCNo
 	QCMaybe
 )

 func (r QCResult) String() string {
 	switch r {
 	case QCYes:
 		return "Yes"
 	case QCNo:
 		return "No"
 	case QCMaybe:
 		return "Maybe"
 	}
 	return "***UNKNOWN***"
 }

 const (
 	FCanonical     = iota // NFC or NFD
 	FCompatibility        // NFKC or NFKD
 	FNumberOfFormTypes
 )

 const (
 	MComposed   = iota // NFC or NFKC
 	MDecomposed        // NFD or NFKD
 	MNumberOfModes
 )

 // This contains only the properties we're interested in.
 type Char struct {
 	name          string
 	codePoint     rune  // if zero, this index is not a valid code point.
 	ccc           uint8 // canonical combining class
 	excludeInComp bool  // from CompositionExclusions.txt
 	compatDecomp  bool  // it has a compatibility expansion

 	forms [FNumberOfFormTypes]FormInfo // For FCanonical and FCompatibility

 	state State
 }

 var chars = make([]Char, MaxChar+1)

 func (c Char) String() string {
 	buf := new(bytes.Buffer)

 	fmt.Fprintf(buf, "%U [%s]:\n", c.codePoint, c.name)
 	fmt.Fprintf(buf, "  ccc: %v\n", c.ccc)
 	fmt.Fprintf(buf, "  excludeInComp: %v\n", c.excludeInComp)
 	fmt.Fprintf(buf, "  compatDecomp: %v\n", c.compatDecomp)
 	fmt.Fprintf(buf, "  state: %v\n", c.state)
 	fmt.Fprintf(buf, "  NFC:\n")
 	fmt.Fprint(buf, c.forms[FCanonical])
 	fmt.Fprintf(buf, "  NFKC:\n")
 	fmt.Fprint(buf, c.forms[FCompatibility])

 	return buf.String()
 }

 // In UnicodeData.txt, some ranges are marked like this:
 //	3400;<CJK Ideograph Extension A, First>;Lo;0;L;;;;;N;;;;;
 //	4DB5;<CJK Ideograph Extension A, Last>;Lo;0;L;;;;;N;;;;;
 // parseCharacter keeps a state variable indicating the weirdness.
 type State int

 const (
 	SNormal State = iota // known to be zero for the type
 	SFirst
 	SLast
 	SMissing
 )

 var lastChar = rune('\u0000')

 func (c Char) isValid() bool {
 	return c.codePoint != 0 && c.state != SMissing
 }

 type FormInfo struct {
 	quickCheck [MNumberOfModes]QCResult // index: MComposed or MDecomposed
 	verified   [MNumberOfModes]bool     // index: MComposed or MDecomposed

 	combinesForward  bool // May combine with rune on the right
 	combinesBackward bool // May combine with rune on the left
 	isOneWay         bool // Never appears in result
 	inDecomp         bool // Some decompositions result in this char.
 	decomp           Decomposition
 	expandedDecomp   Decomposition
 }

 func (f FormInfo) String() string {
 	buf := bytes.NewBuffer(make([]byte, 0))

 	fmt.Fprintf(buf, "    quickCheck[C]: %v\n", f.quickCheck[MComposed])
 	fmt.Fprintf(buf, "    quickCheck[D]: %v\n", f.quickCheck[MDecomposed])
 	fmt.Fprintf(buf, "    cmbForward: %v\n", f.combinesForward)
 	fmt.Fprintf(buf, "    cmbBackward: %v\n", f.combinesBackward)
 	fmt.Fprintf(buf, "    isOneWay: %v\n", f.isOneWay)
 	fmt.Fprintf(buf, "    inDecomp: %v\n", f.inDecomp)
 	fmt.Fprintf(buf, "    decomposition: %v\n", f.decomp)
 	fmt.Fprintf(buf, "    expandedDecomp: %v\n", f.expandedDecomp)

 	return buf.String()
 }

 type Decomposition []rune

 func (d Decomposition) String() string {
 	return fmt.Sprintf("%.4X", d)
 }

 func openReader(file string) (input io.ReadCloser) {
 	if *localFiles {
 		f, err := os.Open(file)
 		if err != nil {
 			logger.Fatal(err)
 		}
 		input = f
 	} else {
 		path := *url + file
 		resp, err := http.Get(path)
 		if err != nil {
 			logger.Fatal(err)
 		}
 		if resp.StatusCode != 200 {
 			logger.Fatal("bad GET status for "+file, resp.Status)
 		}
 		input = resp.Body
 	}
 	return
 }

 func parseDecomposition(s string, skipfirst bool) (a []rune, e os.Error) {
 	decomp := strings.Split(s, " ")
 	if len(decomp) > 0 && skipfirst {
 		decomp = decomp[1:]
 	}
 	for _, d := range decomp {
 		point, err := strconv.Btoui64(d, 16)
 		if err != nil {
 			return a, err
 		}
 		a = append(a, rune(point))
 	}
 	return a, nil
 }

 func parseCharacter(line string) {
 	field := strings.Split(line, ";")
 	if len(field) != NumField {
 		logger.Fatalf("%5s: %d fields (expected %d)\n", line, len(field), NumField)
 	}
 	x, err := strconv.Btoui64(field[FCodePoint], 16)
 	point := int(x)
 	if err != nil {
 		logger.Fatalf("%.5s...: %s", line, err)
 	}
 	if point == 0 {
 		return // not interesting and we use 0 as unset
 	}
 	if point > MaxChar {
 		logger.Fatalf("%5s: Rune %X > MaxChar (%X)", line, point, MaxChar)
 		return
 	}
 	state := SNormal
 	switch {
 	case strings.Index(field[FName], ", First>") > 0:
 		state = SFirst
 	case strings.Index(field[FName], ", Last>") > 0:
 		state = SLast
 	}
 	firstChar := lastChar + 1
 	lastChar = rune(point)
 	if state != SLast {
 		firstChar = lastChar
 	}
 	x, err = strconv.Atoui64(field[FCanonicalCombiningClass])
 	if err != nil {
 		logger.Fatalf("%U: bad ccc field: %s", int(x), err)
 	}
 	ccc := uint8(x)
 	decmap := field[FDecompMapping]
 	exp, e := parseDecomposition(decmap, false)
 	isCompat := false
 	if e != nil {
 		if len(decmap) > 0 {
 			exp, e = parseDecomposition(decmap, true)
 			if e != nil {
 				logger.Fatalf(`%U: bad decomp |%v|: "%s"`, int(x), decmap, e)
 			}
 			isCompat = true
 		}
 	}
 	for i := firstChar; i <= lastChar; i++ {
 		char := &chars[i]
 		char.name = field[FName]
 		char.codePoint = i
 		char.forms[FCompatibility].decomp = exp
 		if !isCompat {
 			char.forms[FCanonical].decomp = exp
 		} else {
 			char.compatDecomp = true
 		}
 		if len(decmap) > 0 {
 			char.forms[FCompatibility].decomp = exp
 		}
 		char.ccc = ccc
 		char.state = SMissing
 		if i == lastChar {
 			char.state = state
 		}
 	}
 	return
 }

 func loadUnicodeData() {
 	f := openReader("UnicodeData.txt")
 	defer f.Close()
 	input := bufio.NewReader(f)
 	for {
 		line, err := input.ReadString('\n')
 		if err != nil {
 			if err == os.EOF {
 				break
 			}
 			logger.Fatal(err)
 		}
 		parseCharacter(line[0 : len(line)-1])
 	}
 }

 var singlePointRe = regexp.MustCompile(`^([0-9A-F]+) *$`)

 // CompositionExclusions.txt has form:
 // 0958    # ...
 // See http://unicode.org/reports/tr44/ for full explanation
 func parseExclusion(line string) int {
 	comment := strings.Index(line, "#")
 	if comment >= 0 {
 		line = line[0:comment]
 	}
 	if len(line) == 0 {
 		return 0
 	}
 	matches := singlePointRe.FindStringSubmatch(line)
 	if len(matches) != 2 {
 		logger.Fatalf("%s: %d matches (expected 1)\n", line, len(matches))
 	}
 	point, err := strconv.Btoui64(matches[1], 16)
 	if err != nil {
 		logger.Fatalf("%.5s...: %s", line, err)
 	}
 	return int(point)
 }

 func loadCompositionExclusions() {
 	f := openReader("CompositionExclusions.txt")
 	defer f.Close()
 	input := bufio.NewReader(f)
 	for {
 		line, err := input.ReadString('\n')
 		if err != nil {
 			if err == os.EOF {
 				break
 			}
 			logger.Fatal(err)
 		}
 		point := parseExclusion(line[0 : len(line)-1])
 		if point == 0 {
 			continue
 		}
 		c := &chars[point]
 		if c.excludeInComp {
 			logger.Fatalf("%U: Duplicate entry in exclusions.", c.codePoint)
 		}
 		c.excludeInComp = true
 	}
 }

 // hasCompatDecomp returns true if any of the recursive
 // decompositions contains a compatibility expansion.
 // In this case, the character may not occur in NFK*.
 func hasCompatDecomp(r rune) bool {
 	c := &chars[r]
 	if c.compatDecomp {
 		return true
 	}
 	for _, d := range c.forms[FCompatibility].decomp {
 		if hasCompatDecomp(d) {
 			return true
 		}
 	}
 	return false
 }

 // Hangul related constants.
 const (
 	HangulBase = 0xAC00
 	HangulEnd  = 0xD7A4 // hangulBase + Jamo combinations (19 * 21 * 28)

 	JamoLBase = 0x1100
 	JamoLEnd  = 0x1113
 	JamoVBase = 0x1161
 	JamoVEnd  = 0x1176
 	JamoTBase = 0x11A8
 	JamoTEnd  = 0x11C3
 )

 func isHangul(r rune) bool {
 	return HangulBase <= r && r < HangulEnd
 }

 func ccc(r rune) uint8 {
 	return chars[r].ccc
 }

 // Insert a rune in a buffer, ordered by Canonical Combining Class.
 func insertOrdered(b Decomposition, r rune) Decomposition {
 	n := len(b)
 	b = append(b, 0)
 	cc := ccc(r)
 	if cc > 0 {
 		// Use bubble sort.
 		for ; n > 0; n-- {
 			if ccc(b[n-1]) <= cc {
 				break
 			}
 			b[n] = b[n-1]
 		}
 	}
 	b[n] = r
 	return b
 }

 // Recursively decompose.
 func decomposeRecursive(form int, r rune, d Decomposition) Decomposition {
 	if isHangul(r) {
 		return d
 	}
 	dcomp := chars[r].forms[form].decomp
 	if len(dcomp) == 0 {
 		return insertOrdered(d, r)
 	}
 	for _, c := range dcomp {
 		d = decomposeRecursive(form, c, d)
 	}
 	return d
 }

 func completeCharFields(form int) {
 	// Phase 0: pre-expand decomposition.
 	for i := range chars {
 		f := &chars[i].forms[form]
 		if len(f.decomp) == 0 {
 			continue
 		}
 		exp := make(Decomposition, 0)
 		for _, c := range f.decomp {
 			exp = decomposeRecursive(form, c, exp)
 		}
 		f.expandedDecomp = exp
 	}

 	// Phase 1: composition exclusion, mark decomposition.
 	for i := range chars {
 		c := &chars[i]
 		f := &c.forms[form]

 		// Marks script-specific exclusions and version restricted.
 		f.isOneWay = c.excludeInComp

 		// Singletons
 		f.isOneWay = f.isOneWay || len(f.decomp) == 1

 		// Non-starter decompositions
 		if len(f.decomp) > 1 {
 			chk := c.ccc != 0 || chars[f.decomp[0]].ccc != 0
 			f.isOneWay = f.isOneWay || chk
 		}

 		// Runes that decompose into more than two runes.
 		f.isOneWay = f.isOneWay || len(f.decomp) > 2

 		if form == FCompatibility {
 			f.isOneWay = f.isOneWay || hasCompatDecomp(c.codePoint)
 		}

 		for _, r := range f.decomp {
 			chars[r].forms[form].inDecomp = true
 		}
 	}

 	// Phase 2: forward and backward combining.
 	for i := range chars {
 		c := &chars[i]
 		f := &c.forms[form]

 		if !f.isOneWay && len(f.decomp) == 2 {
 			f0 := &chars[f.decomp[0]].forms[form]
 			f1 := &chars[f.decomp[1]].forms[form]
 			if !f0.isOneWay {
 				f0.combinesForward = true
 			}
 			if !f1.isOneWay {
 				f1.combinesBackward = true
 			}
 		}
 	}

 	// Phase 3: quick check values.
 	for i := range chars {
 		c := &chars[i]
 		f := &c.forms[form]

 		switch {
 		case len(f.decomp) > 0:
 			f.quickCheck[MDecomposed] = QCNo
 		case isHangul(rune(i)):
 			f.quickCheck[MDecomposed] = QCNo
 		default:
 			f.quickCheck[MDecomposed] = QCYes
 		}
 		switch {
 		case f.isOneWay:
 			f.quickCheck[MComposed] = QCNo
 		case (i & 0xffff00) == JamoLBase:
 			f.quickCheck[MComposed] = QCYes
 			if JamoLBase <= i && i < JamoLEnd {
 				f.combinesForward = true
 			}
 			if JamoVBase <= i && i < JamoVEnd {
 				f.quickCheck[MComposed] = QCMaybe
 				f.combinesBackward = true
 				f.combinesForward = true
 			}
 			if JamoTBase <= i && i < JamoTEnd {
 				f.quickCheck[MComposed] = QCMaybe
 				f.combinesBackward = true
 			}
 		case !f.combinesBackward:
 			f.quickCheck[MComposed] = QCYes
 		default:
 			f.quickCheck[MComposed] = QCMaybe
 		}
 	}
 }

 func printBytes(b []byte, name string) {
 	fmt.Printf("// %s: %d bytes\n", name, len(b))
 	fmt.Printf("var %s = [...]byte {", name)
 	for i, c := range b {
 		switch {
 		case i%64 == 0:
 			fmt.Printf("\n// Bytes %x - %x\n", i, i+63)
 		case i%8 == 0:
 			fmt.Printf("\n")
 		}
 		fmt.Printf("0x%.2X, ", c)
 	}
 	fmt.Print("\n}\n\n")
 }

 // See forminfo.go for format.
 func makeEntry(f *FormInfo) uint16 {
 	e := uint16(0)
 	if f.combinesForward {
 		e |= 0x8
 	}
 	if f.quickCheck[MDecomposed] == QCNo {
 		e |= 0x1
 	}
 	switch f.quickCheck[MComposed] {
 	case QCYes:
 	case QCNo:
 		e |= 0x2
 	case QCMaybe:
 		e |= 0x6
 	default:
 		log.Fatalf("Illegal quickcheck value %v.", f.quickCheck[MComposed])
 	}
 	return e
 }

 // Bits
 // 0..8:   CCC
 // 9..12:  NF(C|D) qc bits.
 // 13..16: NFK(C|D) qc bits.
 func makeCharInfo(c Char) uint16 {
 	e := makeEntry(&c.forms[FCompatibility])
 	e = e<<4 | makeEntry(&c.forms[FCanonical])
 	e = e<<8 | uint16(c.ccc)
 	return e
 }

 func printCharInfoTables() int {
 	// Quick Check + CCC trie.
 	t := newNode()
 	for i, char := range chars {
 		v := makeCharInfo(char)
 		if v != 0 {
 			t.insert(rune(i), v)
 		}
 	}
 	return t.printTables("charInfo")
 }

 func printDecompositionTables() int {
 	decompositions := bytes.NewBuffer(make([]byte, 0, 10000))
 	size := 0

 	// Map decompositions
 	positionMap := make(map[string]uint16)

 	// Store the uniqued decompositions in a byte buffer,
 	// preceded by their byte length.
 	for _, c := range chars {
 		for f := 0; f < 2; f++ {
 			d := c.forms[f].expandedDecomp
 			s := string([]rune(d))
 			if _, ok := positionMap[s]; !ok {
 				p := decompositions.Len()
 				decompositions.WriteByte(uint8(len(s)))
 				decompositions.WriteString(s)
 				positionMap[s] = uint16(p)
 			}
 		}
 	}
 	b := decompositions.Bytes()
 	printBytes(b, "decomps")
 	size += len(b)

 	nfcT := newNode()
 	nfkcT := newNode()
 	for i, c := range chars {
 		d := c.forms[FCanonical].expandedDecomp
 		if len(d) != 0 {
 			nfcT.insert(rune(i), positionMap[string([]rune(d))])
 			if ccc(c.codePoint) != ccc(d[0]) {
 				// We assume the lead ccc of a decomposition is !=0 in this case.
 				if ccc(d[0]) == 0 {
 					logger.Fatal("Expected differing CCC to be non-zero.")
 				}
 			}
 		}
 		d = c.forms[FCompatibility].expandedDecomp
 		if len(d) != 0 {
 			nfkcT.insert(rune(i), positionMap[string([]rune(d))])
 			if ccc(c.codePoint) != ccc(d[0]) {
 				// We assume the lead ccc of a decomposition is !=0 in this case.
 				if ccc(d[0]) == 0 {
 					logger.Fatal("Expected differing CCC to be non-zero.")
 				}
 			}
 		}
 	}
 	size += nfcT.printTables("nfcDecomp")
 	size += nfkcT.printTables("nfkcDecomp")
 	return size
 }

 func contains(sa []string, s string) bool {
 	for _, a := range sa {
 		if a == s {
 			return true
 		}
 	}
 	return false
 }

 // Extract the version number from the URL.
 func version() string {
 	// From http://www.unicode.org/standard/versions/#Version_Numbering:
 	// for the later Unicode versions, data files are located in
 	// versioned directories.
 	fields := strings.Split(*url, "/")
 	for _, f := range fields {
 		if match, _ := regexp.MatchString(`[0-9]\.[0-9]\.[0-9]`, f); match {
 			return f
 		}
 	}
 	logger.Fatal("unknown version")
 	return "Unknown"
 }

 const fileHeader = `// Generated by running
 //	maketables --tables=%s --url=%s
 // DO NOT EDIT

 package norm

 `

 func makeTables() {
 	size := 0
 	if *tablelist == "" {
 		return
 	}
 	list := strings.Split(*tablelist, ",")
 	if *tablelist == "all" {
 		list = []string{"decomp", "recomp", "info"}
 	}
 	fmt.Printf(fileHeader, *tablelist, *url)

 	fmt.Println("// Version is the Unicode edition from which the tables are derived.")
 	fmt.Printf("const Version = %q\n\n", version())

 	if contains(list, "decomp") {
 		size += printDecompositionTables()
 	}

 	if contains(list, "recomp") {
 		// Note that we use 32 bit keys, instead of 64 bit.
 		// This clips the bits of three entries, but we know
 		// this won't cause a collision. The compiler will catch
 		// any changes made to UnicodeData.txt that introduces
 		// a collision.
 		// Note that the recomposition map for NFC and NFKC
 		// are identical.

 		// Recomposition map
 		nrentries := 0
 		for _, c := range chars {
 			f := c.forms[FCanonical]
 			if !f.isOneWay && len(f.decomp) > 0 {
 				nrentries++
 			}
 		}
 		sz := nrentries * 8
 		size += sz
 		fmt.Printf("// recompMap: %d bytes (entries only)\n", sz)
 		fmt.Println("var recompMap = map[uint32]uint32{")
 		for i, c := range chars {
 			f := c.forms[FCanonical]
 			d := f.decomp
 			if !f.isOneWay && len(d) > 0 {
 				key := uint32(uint16(d[0]))<<16 + uint32(uint16(d[1]))
 				fmt.Printf("0x%.8X: 0x%.4X,\n", key, i)
 			}
 		}
 		fmt.Printf("}\n\n")
 	}

 	if contains(list, "info") {
 		size += printCharInfoTables()
 	}
 	fmt.Printf("// Total size of tables: %dKB (%d bytes)\n", (size+512)/1024, size)
 }

 func printChars() {
 	if *verbose {
 		for _, c := range chars {
 			if !c.isValid() || c.state == SMissing {
 				continue
 			}
 			fmt.Println(c)
 		}
 	}
 }

 // verifyComputed does various consistency tests.
 func verifyComputed() {
 	for i, c := range chars {
 		for _, f := range c.forms {
 			isNo := (f.quickCheck[MDecomposed] == QCNo)
 			if (len(f.decomp) > 0) != isNo && !isHangul(rune(i)) {
 				log.Fatalf("%U: NF*D must be no if rune decomposes", i)
 			}

 			isMaybe := f.quickCheck[MComposed] == QCMaybe
 			if f.combinesBackward != isMaybe {
 				log.Fatalf("%U: NF*C must be maybe if combinesBackward", i)
 			}
 		}
 	}
 }

 var qcRe = regexp.MustCompile(`^([0-9A-F\.]+) *; (NF.*_QC); ([YNM]) #.*$`)

 // Use values in DerivedNormalizationProps.txt to compare against the
 // values we computed.
 // DerivedNormalizationProps.txt has form:
 // 00C0..00C5    ; NFD_QC; N # ...
 // 0374          ; NFD_QC; N # ...
 // See http://unicode.org/reports/tr44/ for full explanation
 func testDerived() {
 	if !*test {
 		return
 	}
 	f := openReader("DerivedNormalizationProps.txt")
 	defer f.Close()
 	input := bufio.NewReader(f)
 	for {
 		line, err := input.ReadString('\n')
 		if err != nil {
 			if err == os.EOF {
 				break
 			}
 			logger.Fatal(err)
 		}
 		qc := qcRe.FindStringSubmatch(line)
 		if qc == nil {
 			continue
 		}
 		rng := strings.Split(qc[1], "..")
 		i, err := strconv.Btoui64(rng[0], 16)
 		if err != nil {
 			log.Fatal(err)
 		}
 		j := i
 		if len(rng) > 1 {
 			j, err = strconv.Btoui64(rng[1], 16)
 			if err != nil {
 				log.Fatal(err)
 			}
 		}
 		var ftype, mode int
 		qt := strings.TrimSpace(qc[2])
 		switch qt {
 		case "NFC_QC":
 			ftype, mode = FCanonical, MComposed
 		case "NFD_QC":
 			ftype, mode = FCanonical, MDecomposed
 		case "NFKC_QC":
 			ftype, mode = FCompatibility, MComposed
 		case "NFKD_QC":
 			ftype, mode = FCompatibility, MDecomposed
 		default:
 			log.Fatalf(`Unexpected quick check type "%s"`, qt)
 		}
 		var qr QCResult
 		switch qc[3] {
 		case "Y":
 			qr = QCYes
 		case "N":
 			qr = QCNo
 		case "M":
 			qr = QCMaybe
 		default:
 			log.Fatalf(`Unexpected quick check value "%s"`, qc[3])
 		}
 		var lastFailed bool
 		// Verify current
 		for ; i <= j; i++ {
 			c := &chars[int(i)]
 			c.forms[ftype].verified[mode] = true
 			curqr := c.forms[ftype].quickCheck[mode]
 			if curqr != qr {
 				if !lastFailed {
 					logger.Printf("%s: %.4X..%.4X -- %s\n",
 						qt, int(i), int(j), line[0:50])
 				}
 				logger.Printf("%U: FAILED %s (was %v need %v)\n",
 					int(i), qt, curqr, qr)
 				lastFailed = true
 			}
 		}
 	}
 	// Any unspecified value must be QCYes. Verify this.
 	for i, c := range chars {
 		for j, fd := range c.forms {
 			for k, qr := range fd.quickCheck {
 				if !fd.verified[k] && qr != QCYes {
 					m := "%U: FAIL F:%d M:%d (was %v need Yes) %s\n"
 					logger.Printf(m, i, j, k, qr, c.name)
 				}
 			}
 		}
 	}
 }
	// Copyright 2011 The Go Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style
	// license that can be found in the LICENSE file.

	// Normalization table generator.
	// Data read from the web.

	package main

	import (
	"bufio"
	"bytes"
	"flag"
	"fmt"
	"http"
	"io"
	"log"
	"os"
	"regexp"
	"strconv"
	"strings"
	)

	func main() {
	flag.Parse()
	loadUnicodeData()
	loadCompositionExclusions()
	completeCharFields(FCanonical)
	completeCharFields(FCompatibility)
	verifyComputed()
	printChars()
	makeTables()
	testDerived()
	}

	var url = flag.String("url",
	"http://www.unicode.org/Public/6.0.0/ucd/",
	"URL of Unicode database directory")
	var tablelist = flag.String("tables",
	"all",
	"comma-separated list of which tables to generate; "+
	"can be 'decomp', 'recomp', 'info' and 'all'")
	var test = flag.Bool("test",
	false,
	"test existing tables; can be used to compare web data with package data")
	var verbose = flag.Bool("verbose",
	false,
	"write data to stdout as it is parsed")
	var localFiles = flag.Bool("local",
	false,
	"data files have been copied to the current directory; for debugging only")

	var logger = log.New(os.Stderr, "", log.Lshortfile)

	// UnicodeData.txt has form:
	// 0037;DIGIT SEVEN;Nd;0;EN;;7;7;7;N;;;;;
	// 007A;LATIN SMALL LETTER Z;Ll;0;L;;;;;N;;;005A;;005A
	// See http://unicode.org/reports/tr44/ for full explanation
	// The fields:
	const (
	FCodePoint = iota
	FName
	FGeneralCategory
	FCanonicalCombiningClass
	FBidiClass
	FDecompMapping
	FDecimalValue
	FDigitValue
	FNumericValue
	FBidiMirrored
	FUnicode1Name
	FISOComment
	FSimpleUppercaseMapping
	FSimpleLowercaseMapping
	FSimpleTitlecaseMapping
	NumField

	MaxChar = 0x10FFFF // anything above this shouldn't exist
	)

	// Quick Check properties of runes allow us to quickly
	// determine whether a rune may occur in a normal form.
	// For a given normal form, a rune may be guaranteed to occur
	// verbatim (QC=Yes), may or may not combine with another
	// rune (QC=Maybe), or may not occur (QC=No).
	type QCResult int

	const (
	QCUnknown QCResult = iota
	QCYes
	QCNo
	QCMaybe
	)

	func (r QCResult) String() string {
	switch r {
	case QCYes:
	return "Yes"
	case QCNo:
	return "No"
	case QCMaybe:
	return "Maybe"
	}
	return "*UNKNOWN*"
	}

	const (
	FCanonical = iota // NFC or NFD
	FCompatibility // NFKC or NFKD
	FNumberOfFormTypes
	)

	const (
	MComposed = iota // NFC or NFKC
	MDecomposed // NFD or NFKD
	MNumberOfModes
	)

	// This contains only the properties we're interested in.
	type Char struct {
	name string
	codePoint rune // if zero, this index is not a valid code point.
	ccc uint8 // canonical combining class
	excludeInComp bool // from CompositionExclusions.txt
	compatDecomp bool // it has a compatibility expansion

	forms [FNumberOfFormTypes]FormInfo // For FCanonical and FCompatibility

	state State
	}

	var chars = make([]Char, MaxChar+1)

	func (c Char) String() string {
	buf := new(bytes.Buffer)

	fmt.Fprintf(buf, "%U [%s]:\n", c.codePoint, c.name)
	fmt.Fprintf(buf, " ccc: %v\n", c.ccc)
	fmt.Fprintf(buf, " excludeInComp: %v\n", c.excludeInComp)
	fmt.Fprintf(buf, " compatDecomp: %v\n", c.compatDecomp)
	fmt.Fprintf(buf, " state: %v\n", c.state)
	fmt.Fprintf(buf, " NFC:\n")
	fmt.Fprint(buf, c.forms[FCanonical])
	fmt.Fprintf(buf, " NFKC:\n")
	fmt.Fprint(buf, c.forms[FCompatibility])

	return buf.String()
	}

	// In UnicodeData.txt, some ranges are marked like this:
	// 3400;<CJK Ideograph Extension A, First>;Lo;0;L;;;;;N;;;;;
	// 4DB5;<CJK Ideograph Extension A, Last>;Lo;0;L;;;;;N;;;;;
	// parseCharacter keeps a state variable indicating the weirdness.
	type State int

	const (
	SNormal State = iota // known to be zero for the type
	SFirst
	SLast
	SMissing
	)

	var lastChar = rune('\u0000')

	func (c Char) isValid() bool {
	return c.codePoint != 0 && c.state != SMissing
	}

	type FormInfo struct {
	quickCheck [MNumberOfModes]QCResult // index: MComposed or MDecomposed
	verified [MNumberOfModes]bool // index: MComposed or MDecomposed

	combinesForward bool // May combine with rune on the right
	combinesBackward bool // May combine with rune on the left
	isOneWay bool // Never appears in result
	inDecomp bool // Some decompositions result in this char.
	decomp Decomposition
	expandedDecomp Decomposition
	}

	func (f FormInfo) String() string {
	buf := bytes.NewBuffer(make([]byte, 0))

	fmt.Fprintf(buf, " quickCheck[C]: %v\n", f.quickCheck[MComposed])
	fmt.Fprintf(buf, " quickCheck[D]: %v\n", f.quickCheck[MDecomposed])
	fmt.Fprintf(buf, " cmbForward: %v\n", f.combinesForward)
	fmt.Fprintf(buf, " cmbBackward: %v\n", f.combinesBackward)
	fmt.Fprintf(buf, " isOneWay: %v\n", f.isOneWay)
	fmt.Fprintf(buf, " inDecomp: %v\n", f.inDecomp)
	fmt.Fprintf(buf, " decomposition: %v\n", f.decomp)
	fmt.Fprintf(buf, " expandedDecomp: %v\n", f.expandedDecomp)

	return buf.String()
	}

	type Decomposition []rune

	func (d Decomposition) String() string {
	return fmt.Sprintf("%.4X", d)
	}

	func openReader(file string) (input io.ReadCloser) {
	if *localFiles {
	f, err := os.Open(file)
	if err != nil {
	logger.Fatal(err)
	}
	input = f
	} else {
	path := *url + file
	resp, err := http.Get(path)
	if err != nil {
	logger.Fatal(err)
	}
	if resp.StatusCode != 200 {
	logger.Fatal("bad GET status for "+file, resp.Status)
	}
	input = resp.Body
	}
	return
	}

	func parseDecomposition(s string, skipfirst bool) (a []rune, e os.Error) {
	decomp := strings.Split(s, " ")
	if len(decomp) > 0 && skipfirst {
	decomp = decomp[1:]
	}
	for _, d := range decomp {
	point, err := strconv.Btoui64(d, 16)
	if err != nil {
	return a, err
	}
	a = append(a, rune(point))
	}
	return a, nil
	}

	func parseCharacter(line string) {
	field := strings.Split(line, ";")
	if len(field) != NumField {
	logger.Fatalf("%5s: %d fields (expected %d)\n", line, len(field), NumField)
	}
	x, err := strconv.Btoui64(field[FCodePoint], 16)
	point := int(x)
	if err != nil {
	logger.Fatalf("%.5s...: %s", line, err)
	}
	if point == 0 {
	return // not interesting and we use 0 as unset
	}
	if point > MaxChar {
	logger.Fatalf("%5s: Rune %X > MaxChar (%X)", line, point, MaxChar)
	return
	}
	state := SNormal
	switch {
	case strings.Index(field[FName], ", First>") > 0:
	state = SFirst
	case strings.Index(field[FName], ", Last>") > 0:
	state = SLast
	}
	firstChar := lastChar + 1
	lastChar = rune(point)
	if state != SLast {
	firstChar = lastChar
	}
	x, err = strconv.Atoui64(field[FCanonicalCombiningClass])
	if err != nil {
	logger.Fatalf("%U: bad ccc field: %s", int(x), err)
	}
	ccc := uint8(x)
	decmap := field[FDecompMapping]
	exp, e := parseDecomposition(decmap, false)
	isCompat := false
	if e != nil {
	if len(decmap) > 0 {
	exp, e = parseDecomposition(decmap, true)
	if e != nil {
	logger.Fatalf(`%U: bad decomp \|%v\|: "%s"`, int(x), decmap, e)
	}
	isCompat = true
	}
	}
	for i := firstChar; i <= lastChar; i++ {
	char := &chars[i]
	char.name = field[FName]
	char.codePoint = i
	char.forms[FCompatibility].decomp = exp
	if !isCompat {
	char.forms[FCanonical].decomp = exp
	} else {
	char.compatDecomp = true
	}
	if len(decmap) > 0 {
	char.forms[FCompatibility].decomp = exp
	}
	char.ccc = ccc
	char.state = SMissing
	if i == lastChar {
	char.state = state
	}
	}
	return
	}

	func loadUnicodeData() {
	f := openReader("UnicodeData.txt")
	defer f.Close()
	input := bufio.NewReader(f)
	for {
	line, err := input.ReadString('\n')
	if err != nil {
	if err == os.EOF {
	break
	}
	logger.Fatal(err)
	}
	parseCharacter(line[0 : len(line)-1])
	}
	}

	var singlePointRe = regexp.MustCompile(`^([0-9A-F]+) *$`)

	// CompositionExclusions.txt has form:
	// 0958 # ...
	// See http://unicode.org/reports/tr44/ for full explanation
	func parseExclusion(line string) int {
	comment := strings.Index(line, "#")
	if comment >= 0 {
	line = line[0:comment]
	}
	if len(line) == 0 {
	return 0
	}
	matches := singlePointRe.FindStringSubmatch(line)
	if len(matches) != 2 {
	logger.Fatalf("%s: %d matches (expected 1)\n", line, len(matches))
	}
	point, err := strconv.Btoui64(matches[1], 16)
	if err != nil {
	logger.Fatalf("%.5s...: %s", line, err)
	}
	return int(point)
	}

	func loadCompositionExclusions() {
	f := openReader("CompositionExclusions.txt")
	defer f.Close()
	input := bufio.NewReader(f)
	for {
	line, err := input.ReadString('\n')
	if err != nil {
	if err == os.EOF {
	break
	}
	logger.Fatal(err)
	}
	point := parseExclusion(line[0 : len(line)-1])
	if point == 0 {
	continue
	}
	c := &chars[point]
	if c.excludeInComp {
	logger.Fatalf("%U: Duplicate entry in exclusions.", c.codePoint)
	}
	c.excludeInComp = true
	}
	}

	// hasCompatDecomp returns true if any of the recursive
	// decompositions contains a compatibility expansion.
	// In this case, the character may not occur in NFK*.
	func hasCompatDecomp(r rune) bool {
	c := &chars[r]
	if c.compatDecomp {
	return true
	}
	for _, d := range c.forms[FCompatibility].decomp {
	if hasCompatDecomp(d) {
	return true
	}
	}
	return false
	}

	// Hangul related constants.
	const (
	HangulBase = 0xAC00
	HangulEnd = 0xD7A4 // hangulBase + Jamo combinations (19 * 21 * 28)

	JamoLBase = 0x1100
	JamoLEnd = 0x1113
	JamoVBase = 0x1161
	JamoVEnd = 0x1176
	JamoTBase = 0x11A8
	JamoTEnd = 0x11C3
	)

	func isHangul(r rune) bool {
	return HangulBase <= r && r < HangulEnd
	}

	func ccc(r rune) uint8 {
	return chars[r].ccc
	}

	// Insert a rune in a buffer, ordered by Canonical Combining Class.
	func insertOrdered(b Decomposition, r rune) Decomposition {
	n := len(b)
	b = append(b, 0)
	cc := ccc(r)
	if cc > 0 {
	// Use bubble sort.
	for ; n > 0; n-- {
	if ccc(b[n-1]) <= cc {
	break
	}
	b[n] = b[n-1]
	}
	}
	b[n] = r
	return b
	}

	// Recursively decompose.
	func decomposeRecursive(form int, r rune, d Decomposition) Decomposition {
	if isHangul(r) {
	return d
	}
	dcomp := chars[r].forms[form].decomp
	if len(dcomp) == 0 {
	return insertOrdered(d, r)
	}
	for _, c := range dcomp {
	d = decomposeRecursive(form, c, d)
	}
	return d
	}

	func completeCharFields(form int) {
	// Phase 0: pre-expand decomposition.
	for i := range chars {
	f := &chars[i].forms[form]
	if len(f.decomp) == 0 {
	continue
	}
	exp := make(Decomposition, 0)
	for _, c := range f.decomp {
	exp = decomposeRecursive(form, c, exp)
	}
	f.expandedDecomp = exp
	}

	// Phase 1: composition exclusion, mark decomposition.
	for i := range chars {
	c := &chars[i]
	f := &c.forms[form]

	// Marks script-specific exclusions and version restricted.
	f.isOneWay = c.excludeInComp

	// Singletons
	f.isOneWay = f.isOneWay \|\| len(f.decomp) == 1

	// Non-starter decompositions
	if len(f.decomp) > 1 {
	chk := c.ccc != 0 \|\| chars[f.decomp[0]].ccc != 0
	f.isOneWay = f.isOneWay \|\| chk
	}

	// Runes that decompose into more than two runes.
	f.isOneWay = f.isOneWay \|\| len(f.decomp) > 2

	if form == FCompatibility {
	f.isOneWay = f.isOneWay \|\| hasCompatDecomp(c.codePoint)
	}

	for _, r := range f.decomp {
	chars[r].forms[form].inDecomp = true
	}
	}

	// Phase 2: forward and backward combining.
	for i := range chars {
	c := &chars[i]
	f := &c.forms[form]

	if !f.isOneWay && len(f.decomp) == 2 {
	f0 := &chars[f.decomp[0]].forms[form]
	f1 := &chars[f.decomp[1]].forms[form]
	if !f0.isOneWay {
	f0.combinesForward = true
	}
	if !f1.isOneWay {
	f1.combinesBackward = true
	}
	}
	}

	// Phase 3: quick check values.
	for i := range chars {
	c := &chars[i]
	f := &c.forms[form]

	switch {
	case len(f.decomp) > 0:
	f.quickCheck[MDecomposed] = QCNo
	case isHangul(rune(i)):
	f.quickCheck[MDecomposed] = QCNo
	default:
	f.quickCheck[MDecomposed] = QCYes
	}
	switch {
	case f.isOneWay:
	f.quickCheck[MComposed] = QCNo
	case (i & 0xffff00) == JamoLBase:
	f.quickCheck[MComposed] = QCYes
	if JamoLBase <= i && i < JamoLEnd {
	f.combinesForward = true
	}
	if JamoVBase <= i && i < JamoVEnd {
	f.quickCheck[MComposed] = QCMaybe
	f.combinesBackward = true
	f.combinesForward = true
	}
	if JamoTBase <= i && i < JamoTEnd {
	f.quickCheck[MComposed] = QCMaybe
	f.combinesBackward = true
	}
	case !f.combinesBackward:
	f.quickCheck[MComposed] = QCYes
	default:
	f.quickCheck[MComposed] = QCMaybe
	}
	}
	}

	func printBytes(b []byte, name string) {
	fmt.Printf("// %s: %d bytes\n", name, len(b))
	fmt.Printf("var %s = [...]byte {", name)
	for i, c := range b {
	switch {
	case i%64 == 0:
	fmt.Printf("\n// Bytes %x - %x\n", i, i+63)
	case i%8 == 0:
	fmt.Printf("\n")
	}
	fmt.Printf("0x%.2X, ", c)
	}
	fmt.Print("\n}\n\n")
	}

	// See forminfo.go for format.
	func makeEntry(f *FormInfo) uint16 {
	e := uint16(0)
	if f.combinesForward {
	e \|= 0x8
	}
	if f.quickCheck[MDecomposed] == QCNo {
	e \|= 0x1
	}
	switch f.quickCheck[MComposed] {
	case QCYes:
	case QCNo:
	e \|= 0x2
	case QCMaybe:
	e \|= 0x6
	default:
	log.Fatalf("Illegal quickcheck value %v.", f.quickCheck[MComposed])
	}
	return e
	}

	// Bits
	// 0..8: CCC
	// 9..12: NF(C\|D) qc bits.
	// 13..16: NFK(C\|D) qc bits.
	func makeCharInfo(c Char) uint16 {
	e := makeEntry(&c.forms[FCompatibility])
	e = e<<4 \| makeEntry(&c.forms[FCanonical])
	e = e<<8 \| uint16(c.ccc)
	return e
	}

	func printCharInfoTables() int {
	// Quick Check + CCC trie.
	t := newNode()
	for i, char := range chars {
	v := makeCharInfo(char)
	if v != 0 {
	t.insert(rune(i), v)
	}
	}
	return t.printTables("charInfo")
	}

	func printDecompositionTables() int {
	decompositions := bytes.NewBuffer(make([]byte, 0, 10000))
	size := 0

	// Map decompositions
	positionMap := make(map[string]uint16)

	// Store the uniqued decompositions in a byte buffer,
	// preceded by their byte length.
	for _, c := range chars {
	for f := 0; f < 2; f++ {
	d := c.forms[f].expandedDecomp
	s := string([]rune(d))
	if _, ok := positionMap[s]; !ok {
	p := decompositions.Len()
	decompositions.WriteByte(uint8(len(s)))
	decompositions.WriteString(s)
	positionMap[s] = uint16(p)
	}
	}
	}
	b := decompositions.Bytes()
	printBytes(b, "decomps")
	size += len(b)

	nfcT := newNode()
	nfkcT := newNode()
	for i, c := range chars {
	d := c.forms[FCanonical].expandedDecomp
	if len(d) != 0 {
	nfcT.insert(rune(i), positionMap[string([]rune(d))])
	if ccc(c.codePoint) != ccc(d[0]) {
	// We assume the lead ccc of a decomposition is !=0 in this case.
	if ccc(d[0]) == 0 {
	logger.Fatal("Expected differing CCC to be non-zero.")
	}
	}
	}
	d = c.forms[FCompatibility].expandedDecomp
	if len(d) != 0 {
	nfkcT.insert(rune(i), positionMap[string([]rune(d))])
	if ccc(c.codePoint) != ccc(d[0]) {
	// We assume the lead ccc of a decomposition is !=0 in this case.
	if ccc(d[0]) == 0 {
	logger.Fatal("Expected differing CCC to be non-zero.")
	}
	}
	}
	}
	size += nfcT.printTables("nfcDecomp")
	size += nfkcT.printTables("nfkcDecomp")
	return size
	}

	func contains(sa []string, s string) bool {
	for _, a := range sa {
	if a == s {
	return true
	}
	}
	return false
	}

	// Extract the version number from the URL.
	func version() string {
	// From http://www.unicode.org/standard/versions/#Version_Numbering:
	// for the later Unicode versions, data files are located in
	// versioned directories.
	fields := strings.Split(*url, "/")
	for _, f := range fields {
	if match, _ := regexp.MatchString(`[0-9]\.[0-9]\.[0-9]`, f); match {
	return f
	}
	}
	logger.Fatal("unknown version")
	return "Unknown"
	}

	const fileHeader = `// Generated by running
	// maketables --tables=%s --url=%s
	// DO NOT EDIT

	package norm

	`

	func makeTables() {
	size := 0
	if *tablelist == "" {
	return
	}
	list := strings.Split(*tablelist, ",")
	if *tablelist == "all" {
	list = []string{"decomp", "recomp", "info"}
	}
	fmt.Printf(fileHeader, tablelist, url)

	fmt.Println("// Version is the Unicode edition from which the tables are derived.")
	fmt.Printf("const Version = %q\n\n", version())

	if contains(list, "decomp") {
	size += printDecompositionTables()
	}

	if contains(list, "recomp") {
	// Note that we use 32 bit keys, instead of 64 bit.
	// This clips the bits of three entries, but we know
	// this won't cause a collision. The compiler will catch
	// any changes made to UnicodeData.txt that introduces
	// a collision.
	// Note that the recomposition map for NFC and NFKC
	// are identical.

	// Recomposition map
	nrentries := 0
	for _, c := range chars {
	f := c.forms[FCanonical]
	if !f.isOneWay && len(f.decomp) > 0 {
	nrentries++
	}
	}
	sz := nrentries * 8
	size += sz
	fmt.Printf("// recompMap: %d bytes (entries only)\n", sz)
	fmt.Println("var recompMap = map[uint32]uint32{")
	for i, c := range chars {
	f := c.forms[FCanonical]
	d := f.decomp
	if !f.isOneWay && len(d) > 0 {
	key := uint32(uint16(d[0]))<<16 + uint32(uint16(d[1]))
	fmt.Printf("0x%.8X: 0x%.4X,\n", key, i)
	}
	}
	fmt.Printf("}\n\n")
	}

	if contains(list, "info") {
	size += printCharInfoTables()
	}
	fmt.Printf("// Total size of tables: %dKB (%d bytes)\n", (size+512)/1024, size)
	}

	func printChars() {
	if *verbose {
	for _, c := range chars {
	if !c.isValid() \|\| c.state == SMissing {
	continue
	}
	fmt.Println(c)
	}
	}
	}

	// verifyComputed does various consistency tests.
	func verifyComputed() {
	for i, c := range chars {
	for _, f := range c.forms {
	isNo := (f.quickCheck[MDecomposed] == QCNo)
	if (len(f.decomp) > 0) != isNo && !isHangul(rune(i)) {
	log.Fatalf("%U: NF*D must be no if rune decomposes", i)
	}

	isMaybe := f.quickCheck[MComposed] == QCMaybe
	if f.combinesBackward != isMaybe {
	log.Fatalf("%U: NF*C must be maybe if combinesBackward", i)
	}
	}
	}
	}

	var qcRe = regexp.MustCompile(`^([0-9A-F\.]+) ; (NF._QC); ([YNM]) #.*$`)

	// Use values in DerivedNormalizationProps.txt to compare against the
	// values we computed.
	// DerivedNormalizationProps.txt has form:
	// 00C0..00C5 ; NFD_QC; N # ...
	// 0374 ; NFD_QC; N # ...
	// See http://unicode.org/reports/tr44/ for full explanation
	func testDerived() {
	if !*test {
	return
	}
	f := openReader("DerivedNormalizationProps.txt")
	defer f.Close()
	input := bufio.NewReader(f)
	for {
	line, err := input.ReadString('\n')
	if err != nil {
	if err == os.EOF {
	break
	}
	logger.Fatal(err)
	}
	qc := qcRe.FindStringSubmatch(line)
	if qc == nil {
	continue
	}
	rng := strings.Split(qc[1], "..")
	i, err := strconv.Btoui64(rng[0], 16)
	if err != nil {
	log.Fatal(err)
	}
	j := i
	if len(rng) > 1 {
	j, err = strconv.Btoui64(rng[1], 16)
	if err != nil {
	log.Fatal(err)
	}
	}
	var ftype, mode int
	qt := strings.TrimSpace(qc[2])
	switch qt {
	case "NFC_QC":
	ftype, mode = FCanonical, MComposed
	case "NFD_QC":
	ftype, mode = FCanonical, MDecomposed
	case "NFKC_QC":
	ftype, mode = FCompatibility, MComposed
	case "NFKD_QC":
	ftype, mode = FCompatibility, MDecomposed
	default:
	log.Fatalf(`Unexpected quick check type "%s"`, qt)
	}
	var qr QCResult
	switch qc[3] {
	case "Y":
	qr = QCYes
	case "N":
	qr = QCNo
	case "M":
	qr = QCMaybe
	default:
	log.Fatalf(`Unexpected quick check value "%s"`, qc[3])
	}
	var lastFailed bool
	// Verify current
	for ; i <= j; i++ {
	c := &chars[int(i)]
	c.forms[ftype].verified[mode] = true
	curqr := c.forms[ftype].quickCheck[mode]
	if curqr != qr {
	if !lastFailed {
	logger.Printf("%s: %.4X..%.4X -- %s\n",
	qt, int(i), int(j), line[0:50])
	}
	logger.Printf("%U: FAILED %s (was %v need %v)\n",
	int(i), qt, curqr, qr)
	lastFailed = true
	}
	}
	}
	// Any unspecified value must be QCYes. Verify this.
	for i, c := range chars {
	for j, fd := range c.forms {
	for k, qr := range fd.quickCheck {
	if !fd.verified[k] && qr != QCYes {
	m := "%U: FAIL F:%d M:%d (was %v need Yes) %s\n"
	logger.Printf(m, i, j, k, qr, c.name)
	}
	}
	}
	}
	}