forgejo/vendor/github.com/dlclark/regexp2/syntax/charclass.go
mrsdizzie af7ffaa279
Server-side syntax highlighting for all code (#12047)
* Server-side syntax hilighting for all code

This PR does a few things:

* Remove all traces of highlight.js
* Use chroma library to provide fast syntax hilighting directly on the server
* Provide syntax hilighting for diffs
* Re-style both unified and split diffs views
* Add custom syntax hilighting styling for both regular and arc-green

Fixes #7729
Fixes #10157
Fixes #11825
Fixes #7728
Fixes #3872
Fixes #3682

And perhaps gets closer to #9553

* fix line marker

* fix repo search

* Fix single line select

* properly load settings

* npm uninstall highlight.js

* review suggestion

* code review

* forgot to call function

* fix test

* Apply suggestions from code review

suggestions from @silverwind thanks

Co-authored-by: silverwind <me@silverwind.io>

* code review

* copy/paste error

* Use const for highlight size limit

* Update web_src/less/_repository.less

Co-authored-by: Lauris BH <lauris@nix.lv>

* update size limit to 1MB and other styling tweaks

* fix highlighting for certain diff sections

* fix test

* add worker back as suggested

Co-authored-by: silverwind <me@silverwind.io>
Co-authored-by: Lauris BH <lauris@nix.lv>
2020-07-01 00:34:03 +03:00

854 lines
22 KiB
Go
Vendored

package syntax
import (
"bytes"
"encoding/binary"
"fmt"
"sort"
"unicode"
"unicode/utf8"
)
// CharSet combines start-end rune ranges and unicode categories representing a set of characters
type CharSet struct {
ranges []singleRange
categories []category
sub *CharSet //optional subtractor
negate bool
anything bool
}
type category struct {
negate bool
cat string
}
type singleRange struct {
first rune
last rune
}
const (
spaceCategoryText = " "
wordCategoryText = "W"
)
var (
ecmaSpace = []rune{0x0009, 0x000e, 0x0020, 0x0021, 0x00a0, 0x00a1, 0x1680, 0x1681, 0x2000, 0x200b, 0x2028, 0x202a, 0x202f, 0x2030, 0x205f, 0x2060, 0x3000, 0x3001, 0xfeff, 0xff00}
ecmaWord = []rune{0x0030, 0x003a, 0x0041, 0x005b, 0x005f, 0x0060, 0x0061, 0x007b}
ecmaDigit = []rune{0x0030, 0x003a}
)
var (
AnyClass = getCharSetFromOldString([]rune{0}, false)
ECMAAnyClass = getCharSetFromOldString([]rune{0, 0x000a, 0x000b, 0x000d, 0x000e}, false)
NoneClass = getCharSetFromOldString(nil, false)
ECMAWordClass = getCharSetFromOldString(ecmaWord, false)
NotECMAWordClass = getCharSetFromOldString(ecmaWord, true)
ECMASpaceClass = getCharSetFromOldString(ecmaSpace, false)
NotECMASpaceClass = getCharSetFromOldString(ecmaSpace, true)
ECMADigitClass = getCharSetFromOldString(ecmaDigit, false)
NotECMADigitClass = getCharSetFromOldString(ecmaDigit, true)
WordClass = getCharSetFromCategoryString(false, false, wordCategoryText)
NotWordClass = getCharSetFromCategoryString(true, false, wordCategoryText)
SpaceClass = getCharSetFromCategoryString(false, false, spaceCategoryText)
NotSpaceClass = getCharSetFromCategoryString(true, false, spaceCategoryText)
DigitClass = getCharSetFromCategoryString(false, false, "Nd")
NotDigitClass = getCharSetFromCategoryString(false, true, "Nd")
)
var unicodeCategories = func() map[string]*unicode.RangeTable {
retVal := make(map[string]*unicode.RangeTable)
for k, v := range unicode.Scripts {
retVal[k] = v
}
for k, v := range unicode.Categories {
retVal[k] = v
}
for k, v := range unicode.Properties {
retVal[k] = v
}
return retVal
}()
func getCharSetFromCategoryString(negateSet bool, negateCat bool, cats ...string) func() *CharSet {
if negateCat && negateSet {
panic("BUG! You should only negate the set OR the category in a constant setup, but not both")
}
c := CharSet{negate: negateSet}
c.categories = make([]category, len(cats))
for i, cat := range cats {
c.categories[i] = category{cat: cat, negate: negateCat}
}
return func() *CharSet {
//make a copy each time
local := c
//return that address
return &local
}
}
func getCharSetFromOldString(setText []rune, negate bool) func() *CharSet {
c := CharSet{}
if len(setText) > 0 {
fillFirst := false
l := len(setText)
if negate {
if setText[0] == 0 {
setText = setText[1:]
} else {
l++
fillFirst = true
}
}
if l%2 == 0 {
c.ranges = make([]singleRange, l/2)
} else {
c.ranges = make([]singleRange, l/2+1)
}
first := true
if fillFirst {
c.ranges[0] = singleRange{first: 0}
first = false
}
i := 0
for _, r := range setText {
if first {
// lower bound in a new range
c.ranges[i] = singleRange{first: r}
first = false
} else {
c.ranges[i].last = r - 1
i++
first = true
}
}
if !first {
c.ranges[i].last = utf8.MaxRune
}
}
return func() *CharSet {
local := c
return &local
}
}
// Copy makes a deep copy to prevent accidental mutation of a set
func (c CharSet) Copy() CharSet {
ret := CharSet{
anything: c.anything,
negate: c.negate,
}
ret.ranges = append(ret.ranges, c.ranges...)
ret.categories = append(ret.categories, c.categories...)
if c.sub != nil {
sub := c.sub.Copy()
ret.sub = &sub
}
return ret
}
// gets a human-readable description for a set string
func (c CharSet) String() string {
buf := &bytes.Buffer{}
buf.WriteRune('[')
if c.IsNegated() {
buf.WriteRune('^')
}
for _, r := range c.ranges {
buf.WriteString(CharDescription(r.first))
if r.first != r.last {
if r.last-r.first != 1 {
//groups that are 1 char apart skip the dash
buf.WriteRune('-')
}
buf.WriteString(CharDescription(r.last))
}
}
for _, c := range c.categories {
buf.WriteString(c.String())
}
if c.sub != nil {
buf.WriteRune('-')
buf.WriteString(c.sub.String())
}
buf.WriteRune(']')
return buf.String()
}
// mapHashFill converts a charset into a buffer for use in maps
func (c CharSet) mapHashFill(buf *bytes.Buffer) {
if c.negate {
buf.WriteByte(0)
} else {
buf.WriteByte(1)
}
binary.Write(buf, binary.LittleEndian, len(c.ranges))
binary.Write(buf, binary.LittleEndian, len(c.categories))
for _, r := range c.ranges {
buf.WriteRune(r.first)
buf.WriteRune(r.last)
}
for _, ct := range c.categories {
buf.WriteString(ct.cat)
if ct.negate {
buf.WriteByte(1)
} else {
buf.WriteByte(0)
}
}
if c.sub != nil {
c.sub.mapHashFill(buf)
}
}
// CharIn returns true if the rune is in our character set (either ranges or categories).
// It handles negations and subtracted sub-charsets.
func (c CharSet) CharIn(ch rune) bool {
val := false
// in s && !s.subtracted
//check ranges
for _, r := range c.ranges {
if ch < r.first {
continue
}
if ch <= r.last {
val = true
break
}
}
//check categories if we haven't already found a range
if !val && len(c.categories) > 0 {
for _, ct := range c.categories {
// special categories...then unicode
if ct.cat == spaceCategoryText {
if unicode.IsSpace(ch) {
// we found a space so we're done
// negate means this is a "bad" thing
val = !ct.negate
break
} else if ct.negate {
val = true
break
}
} else if ct.cat == wordCategoryText {
if IsWordChar(ch) {
val = !ct.negate
break
} else if ct.negate {
val = true
break
}
} else if unicode.Is(unicodeCategories[ct.cat], ch) {
// if we're in this unicode category then we're done
// if negate=true on this category then we "failed" our test
// otherwise we're good that we found it
val = !ct.negate
break
} else if ct.negate {
val = true
break
}
}
}
// negate the whole char set
if c.negate {
val = !val
}
// get subtracted recurse
if val && c.sub != nil {
val = !c.sub.CharIn(ch)
}
//log.Printf("Char '%v' in %v == %v", string(ch), c.String(), val)
return val
}
func (c category) String() string {
switch c.cat {
case spaceCategoryText:
if c.negate {
return "\\S"
}
return "\\s"
case wordCategoryText:
if c.negate {
return "\\W"
}
return "\\w"
}
if _, ok := unicodeCategories[c.cat]; ok {
if c.negate {
return "\\P{" + c.cat + "}"
}
return "\\p{" + c.cat + "}"
}
return "Unknown category: " + c.cat
}
// CharDescription Produces a human-readable description for a single character.
func CharDescription(ch rune) string {
/*if ch == '\\' {
return "\\\\"
}
if ch > ' ' && ch <= '~' {
return string(ch)
} else if ch == '\n' {
return "\\n"
} else if ch == ' ' {
return "\\ "
}*/
b := &bytes.Buffer{}
escape(b, ch, false) //fmt.Sprintf("%U", ch)
return b.String()
}
// According to UTS#18 Unicode Regular Expressions (http://www.unicode.org/reports/tr18/)
// RL 1.4 Simple Word Boundaries The class of <word_character> includes all Alphabetic
// values from the Unicode character database, from UnicodeData.txt [UData], plus the U+200C
// ZERO WIDTH NON-JOINER and U+200D ZERO WIDTH JOINER.
func IsWordChar(r rune) bool {
//"L", "Mn", "Nd", "Pc"
return unicode.In(r,
unicode.Categories["L"], unicode.Categories["Mn"],
unicode.Categories["Nd"], unicode.Categories["Pc"]) || r == '\u200D' || r == '\u200C'
//return 'A' <= r && r <= 'Z' || 'a' <= r && r <= 'z' || '0' <= r && r <= '9' || r == '_'
}
func IsECMAWordChar(r rune) bool {
return unicode.In(r,
unicode.Categories["L"], unicode.Categories["Mn"],
unicode.Categories["Nd"], unicode.Categories["Pc"])
//return 'A' <= r && r <= 'Z' || 'a' <= r && r <= 'z' || '0' <= r && r <= '9' || r == '_'
}
// SingletonChar will return the char from the first range without validation.
// It assumes you have checked for IsSingleton or IsSingletonInverse and will panic given bad input
func (c CharSet) SingletonChar() rune {
return c.ranges[0].first
}
func (c CharSet) IsSingleton() bool {
return !c.negate && //negated is multiple chars
len(c.categories) == 0 && len(c.ranges) == 1 && // multiple ranges and unicode classes represent multiple chars
c.sub == nil && // subtraction means we've got multiple chars
c.ranges[0].first == c.ranges[0].last // first and last equal means we're just 1 char
}
func (c CharSet) IsSingletonInverse() bool {
return c.negate && //same as above, but requires negated
len(c.categories) == 0 && len(c.ranges) == 1 && // multiple ranges and unicode classes represent multiple chars
c.sub == nil && // subtraction means we've got multiple chars
c.ranges[0].first == c.ranges[0].last // first and last equal means we're just 1 char
}
func (c CharSet) IsMergeable() bool {
return !c.IsNegated() && !c.HasSubtraction()
}
func (c CharSet) IsNegated() bool {
return c.negate
}
func (c CharSet) HasSubtraction() bool {
return c.sub != nil
}
func (c CharSet) IsEmpty() bool {
return len(c.ranges) == 0 && len(c.categories) == 0 && c.sub == nil
}
func (c *CharSet) addDigit(ecma, negate bool, pattern string) {
if ecma {
if negate {
c.addRanges(NotECMADigitClass().ranges)
} else {
c.addRanges(ECMADigitClass().ranges)
}
} else {
c.addCategories(category{cat: "Nd", negate: negate})
}
}
func (c *CharSet) addChar(ch rune) {
c.addRange(ch, ch)
}
func (c *CharSet) addSpace(ecma, negate bool) {
if ecma {
if negate {
c.addRanges(NotECMASpaceClass().ranges)
} else {
c.addRanges(ECMASpaceClass().ranges)
}
} else {
c.addCategories(category{cat: spaceCategoryText, negate: negate})
}
}
func (c *CharSet) addWord(ecma, negate bool) {
if ecma {
if negate {
c.addRanges(NotECMAWordClass().ranges)
} else {
c.addRanges(ECMAWordClass().ranges)
}
} else {
c.addCategories(category{cat: wordCategoryText, negate: negate})
}
}
// Add set ranges and categories into ours -- no deduping or anything
func (c *CharSet) addSet(set CharSet) {
if c.anything {
return
}
if set.anything {
c.makeAnything()
return
}
// just append here to prevent double-canon
c.ranges = append(c.ranges, set.ranges...)
c.addCategories(set.categories...)
c.canonicalize()
}
func (c *CharSet) makeAnything() {
c.anything = true
c.categories = []category{}
c.ranges = AnyClass().ranges
}
func (c *CharSet) addCategories(cats ...category) {
// don't add dupes and remove positive+negative
if c.anything {
// if we've had a previous positive+negative group then
// just return, we're as broad as we can get
return
}
for _, ct := range cats {
found := false
for _, ct2 := range c.categories {
if ct.cat == ct2.cat {
if ct.negate != ct2.negate {
// oposite negations...this mean we just
// take us as anything and move on
c.makeAnything()
return
}
found = true
break
}
}
if !found {
c.categories = append(c.categories, ct)
}
}
}
// Merges new ranges to our own
func (c *CharSet) addRanges(ranges []singleRange) {
if c.anything {
return
}
c.ranges = append(c.ranges, ranges...)
c.canonicalize()
}
// Merges everything but the new ranges into our own
func (c *CharSet) addNegativeRanges(ranges []singleRange) {
if c.anything {
return
}
var hi rune
// convert incoming ranges into opposites, assume they are in order
for _, r := range ranges {
if hi < r.first {
c.ranges = append(c.ranges, singleRange{hi, r.first - 1})
}
hi = r.last + 1
}
if hi < utf8.MaxRune {
c.ranges = append(c.ranges, singleRange{hi, utf8.MaxRune})
}
c.canonicalize()
}
func isValidUnicodeCat(catName string) bool {
_, ok := unicodeCategories[catName]
return ok
}
func (c *CharSet) addCategory(categoryName string, negate, caseInsensitive bool, pattern string) {
if !isValidUnicodeCat(categoryName) {
// unknown unicode category, script, or property "blah"
panic(fmt.Errorf("Unknown unicode category, script, or property '%v'", categoryName))
}
if caseInsensitive && (categoryName == "Ll" || categoryName == "Lu" || categoryName == "Lt") {
// when RegexOptions.IgnoreCase is specified then {Ll} {Lu} and {Lt} cases should all match
c.addCategories(
category{cat: "Ll", negate: negate},
category{cat: "Lu", negate: negate},
category{cat: "Lt", negate: negate})
}
c.addCategories(category{cat: categoryName, negate: negate})
}
func (c *CharSet) addSubtraction(sub *CharSet) {
c.sub = sub
}
func (c *CharSet) addRange(chMin, chMax rune) {
c.ranges = append(c.ranges, singleRange{first: chMin, last: chMax})
c.canonicalize()
}
func (c *CharSet) addNamedASCII(name string, negate bool) bool {
var rs []singleRange
switch name {
case "alnum":
rs = []singleRange{singleRange{'0', '9'}, singleRange{'A', 'Z'}, singleRange{'a', 'z'}}
case "alpha":
rs = []singleRange{singleRange{'A', 'Z'}, singleRange{'a', 'z'}}
case "ascii":
rs = []singleRange{singleRange{0, 0x7f}}
case "blank":
rs = []singleRange{singleRange{'\t', '\t'}, singleRange{' ', ' '}}
case "cntrl":
rs = []singleRange{singleRange{0, 0x1f}, singleRange{0x7f, 0x7f}}
case "digit":
c.addDigit(false, negate, "")
case "graph":
rs = []singleRange{singleRange{'!', '~'}}
case "lower":
rs = []singleRange{singleRange{'a', 'z'}}
case "print":
rs = []singleRange{singleRange{' ', '~'}}
case "punct": //[!-/:-@[-`{-~]
rs = []singleRange{singleRange{'!', '/'}, singleRange{':', '@'}, singleRange{'[', '`'}, singleRange{'{', '~'}}
case "space":
c.addSpace(true, negate)
case "upper":
rs = []singleRange{singleRange{'A', 'Z'}}
case "word":
c.addWord(true, negate)
case "xdigit":
rs = []singleRange{singleRange{'0', '9'}, singleRange{'A', 'F'}, singleRange{'a', 'f'}}
default:
return false
}
if len(rs) > 0 {
if negate {
c.addNegativeRanges(rs)
} else {
c.addRanges(rs)
}
}
return true
}
type singleRangeSorter []singleRange
func (p singleRangeSorter) Len() int { return len(p) }
func (p singleRangeSorter) Less(i, j int) bool { return p[i].first < p[j].first }
func (p singleRangeSorter) Swap(i, j int) { p[i], p[j] = p[j], p[i] }
// Logic to reduce a character class to a unique, sorted form.
func (c *CharSet) canonicalize() {
var i, j int
var last rune
//
// Find and eliminate overlapping or abutting ranges
//
if len(c.ranges) > 1 {
sort.Sort(singleRangeSorter(c.ranges))
done := false
for i, j = 1, 0; ; i++ {
for last = c.ranges[j].last; ; i++ {
if i == len(c.ranges) || last == utf8.MaxRune {
done = true
break
}
CurrentRange := c.ranges[i]
if CurrentRange.first > last+1 {
break
}
if last < CurrentRange.last {
last = CurrentRange.last
}
}
c.ranges[j] = singleRange{first: c.ranges[j].first, last: last}
j++
if done {
break
}
if j < i {
c.ranges[j] = c.ranges[i]
}
}
c.ranges = append(c.ranges[:j], c.ranges[len(c.ranges):]...)
}
}
// Adds to the class any lowercase versions of characters already
// in the class. Used for case-insensitivity.
func (c *CharSet) addLowercase() {
if c.anything {
return
}
toAdd := []singleRange{}
for i := 0; i < len(c.ranges); i++ {
r := c.ranges[i]
if r.first == r.last {
lower := unicode.ToLower(r.first)
c.ranges[i] = singleRange{first: lower, last: lower}
} else {
toAdd = append(toAdd, r)
}
}
for _, r := range toAdd {
c.addLowercaseRange(r.first, r.last)
}
c.canonicalize()
}
/**************************************************************************
Let U be the set of Unicode character values and let L be the lowercase
function, mapping from U to U. To perform case insensitive matching of
character sets, we need to be able to map an interval I in U, say
I = [chMin, chMax] = { ch : chMin <= ch <= chMax }
to a set A such that A contains L(I) and A is contained in the union of
I and L(I).
The table below partitions U into intervals on which L is non-decreasing.
Thus, for any interval J = [a, b] contained in one of these intervals,
L(J) is contained in [L(a), L(b)].
It is also true that for any such J, [L(a), L(b)] is contained in the
union of J and L(J). This does not follow from L being non-decreasing on
these intervals. It follows from the nature of the L on each interval.
On each interval, L has one of the following forms:
(1) L(ch) = constant (LowercaseSet)
(2) L(ch) = ch + offset (LowercaseAdd)
(3) L(ch) = ch | 1 (LowercaseBor)
(4) L(ch) = ch + (ch & 1) (LowercaseBad)
It is easy to verify that for any of these forms [L(a), L(b)] is
contained in the union of [a, b] and L([a, b]).
***************************************************************************/
const (
LowercaseSet = 0 // Set to arg.
LowercaseAdd = 1 // Add arg.
LowercaseBor = 2 // Bitwise or with 1.
LowercaseBad = 3 // Bitwise and with 1 and add original.
)
type lcMap struct {
chMin, chMax rune
op, data int32
}
var lcTable = []lcMap{
lcMap{'\u0041', '\u005A', LowercaseAdd, 32},
lcMap{'\u00C0', '\u00DE', LowercaseAdd, 32},
lcMap{'\u0100', '\u012E', LowercaseBor, 0},
lcMap{'\u0130', '\u0130', LowercaseSet, 0x0069},
lcMap{'\u0132', '\u0136', LowercaseBor, 0},
lcMap{'\u0139', '\u0147', LowercaseBad, 0},
lcMap{'\u014A', '\u0176', LowercaseBor, 0},
lcMap{'\u0178', '\u0178', LowercaseSet, 0x00FF},
lcMap{'\u0179', '\u017D', LowercaseBad, 0},
lcMap{'\u0181', '\u0181', LowercaseSet, 0x0253},
lcMap{'\u0182', '\u0184', LowercaseBor, 0},
lcMap{'\u0186', '\u0186', LowercaseSet, 0x0254},
lcMap{'\u0187', '\u0187', LowercaseSet, 0x0188},
lcMap{'\u0189', '\u018A', LowercaseAdd, 205},
lcMap{'\u018B', '\u018B', LowercaseSet, 0x018C},
lcMap{'\u018E', '\u018E', LowercaseSet, 0x01DD},
lcMap{'\u018F', '\u018F', LowercaseSet, 0x0259},
lcMap{'\u0190', '\u0190', LowercaseSet, 0x025B},
lcMap{'\u0191', '\u0191', LowercaseSet, 0x0192},
lcMap{'\u0193', '\u0193', LowercaseSet, 0x0260},
lcMap{'\u0194', '\u0194', LowercaseSet, 0x0263},
lcMap{'\u0196', '\u0196', LowercaseSet, 0x0269},
lcMap{'\u0197', '\u0197', LowercaseSet, 0x0268},
lcMap{'\u0198', '\u0198', LowercaseSet, 0x0199},
lcMap{'\u019C', '\u019C', LowercaseSet, 0x026F},
lcMap{'\u019D', '\u019D', LowercaseSet, 0x0272},
lcMap{'\u019F', '\u019F', LowercaseSet, 0x0275},
lcMap{'\u01A0', '\u01A4', LowercaseBor, 0},
lcMap{'\u01A7', '\u01A7', LowercaseSet, 0x01A8},
lcMap{'\u01A9', '\u01A9', LowercaseSet, 0x0283},
lcMap{'\u01AC', '\u01AC', LowercaseSet, 0x01AD},
lcMap{'\u01AE', '\u01AE', LowercaseSet, 0x0288},
lcMap{'\u01AF', '\u01AF', LowercaseSet, 0x01B0},
lcMap{'\u01B1', '\u01B2', LowercaseAdd, 217},
lcMap{'\u01B3', '\u01B5', LowercaseBad, 0},
lcMap{'\u01B7', '\u01B7', LowercaseSet, 0x0292},
lcMap{'\u01B8', '\u01B8', LowercaseSet, 0x01B9},
lcMap{'\u01BC', '\u01BC', LowercaseSet, 0x01BD},
lcMap{'\u01C4', '\u01C5', LowercaseSet, 0x01C6},
lcMap{'\u01C7', '\u01C8', LowercaseSet, 0x01C9},
lcMap{'\u01CA', '\u01CB', LowercaseSet, 0x01CC},
lcMap{'\u01CD', '\u01DB', LowercaseBad, 0},
lcMap{'\u01DE', '\u01EE', LowercaseBor, 0},
lcMap{'\u01F1', '\u01F2', LowercaseSet, 0x01F3},
lcMap{'\u01F4', '\u01F4', LowercaseSet, 0x01F5},
lcMap{'\u01FA', '\u0216', LowercaseBor, 0},
lcMap{'\u0386', '\u0386', LowercaseSet, 0x03AC},
lcMap{'\u0388', '\u038A', LowercaseAdd, 37},
lcMap{'\u038C', '\u038C', LowercaseSet, 0x03CC},
lcMap{'\u038E', '\u038F', LowercaseAdd, 63},
lcMap{'\u0391', '\u03AB', LowercaseAdd, 32},
lcMap{'\u03E2', '\u03EE', LowercaseBor, 0},
lcMap{'\u0401', '\u040F', LowercaseAdd, 80},
lcMap{'\u0410', '\u042F', LowercaseAdd, 32},
lcMap{'\u0460', '\u0480', LowercaseBor, 0},
lcMap{'\u0490', '\u04BE', LowercaseBor, 0},
lcMap{'\u04C1', '\u04C3', LowercaseBad, 0},
lcMap{'\u04C7', '\u04C7', LowercaseSet, 0x04C8},
lcMap{'\u04CB', '\u04CB', LowercaseSet, 0x04CC},
lcMap{'\u04D0', '\u04EA', LowercaseBor, 0},
lcMap{'\u04EE', '\u04F4', LowercaseBor, 0},
lcMap{'\u04F8', '\u04F8', LowercaseSet, 0x04F9},
lcMap{'\u0531', '\u0556', LowercaseAdd, 48},
lcMap{'\u10A0', '\u10C5', LowercaseAdd, 48},
lcMap{'\u1E00', '\u1EF8', LowercaseBor, 0},
lcMap{'\u1F08', '\u1F0F', LowercaseAdd, -8},
lcMap{'\u1F18', '\u1F1F', LowercaseAdd, -8},
lcMap{'\u1F28', '\u1F2F', LowercaseAdd, -8},
lcMap{'\u1F38', '\u1F3F', LowercaseAdd, -8},
lcMap{'\u1F48', '\u1F4D', LowercaseAdd, -8},
lcMap{'\u1F59', '\u1F59', LowercaseSet, 0x1F51},
lcMap{'\u1F5B', '\u1F5B', LowercaseSet, 0x1F53},
lcMap{'\u1F5D', '\u1F5D', LowercaseSet, 0x1F55},
lcMap{'\u1F5F', '\u1F5F', LowercaseSet, 0x1F57},
lcMap{'\u1F68', '\u1F6F', LowercaseAdd, -8},
lcMap{'\u1F88', '\u1F8F', LowercaseAdd, -8},
lcMap{'\u1F98', '\u1F9F', LowercaseAdd, -8},
lcMap{'\u1FA8', '\u1FAF', LowercaseAdd, -8},
lcMap{'\u1FB8', '\u1FB9', LowercaseAdd, -8},
lcMap{'\u1FBA', '\u1FBB', LowercaseAdd, -74},
lcMap{'\u1FBC', '\u1FBC', LowercaseSet, 0x1FB3},
lcMap{'\u1FC8', '\u1FCB', LowercaseAdd, -86},
lcMap{'\u1FCC', '\u1FCC', LowercaseSet, 0x1FC3},
lcMap{'\u1FD8', '\u1FD9', LowercaseAdd, -8},
lcMap{'\u1FDA', '\u1FDB', LowercaseAdd, -100},
lcMap{'\u1FE8', '\u1FE9', LowercaseAdd, -8},
lcMap{'\u1FEA', '\u1FEB', LowercaseAdd, -112},
lcMap{'\u1FEC', '\u1FEC', LowercaseSet, 0x1FE5},
lcMap{'\u1FF8', '\u1FF9', LowercaseAdd, -128},
lcMap{'\u1FFA', '\u1FFB', LowercaseAdd, -126},
lcMap{'\u1FFC', '\u1FFC', LowercaseSet, 0x1FF3},
lcMap{'\u2160', '\u216F', LowercaseAdd, 16},
lcMap{'\u24B6', '\u24D0', LowercaseAdd, 26},
lcMap{'\uFF21', '\uFF3A', LowercaseAdd, 32},
}
func (c *CharSet) addLowercaseRange(chMin, chMax rune) {
var i, iMax, iMid int
var chMinT, chMaxT rune
var lc lcMap
for i, iMax = 0, len(lcTable); i < iMax; {
iMid = (i + iMax) / 2
if lcTable[iMid].chMax < chMin {
i = iMid + 1
} else {
iMax = iMid
}
}
for ; i < len(lcTable); i++ {
lc = lcTable[i]
if lc.chMin > chMax {
return
}
chMinT = lc.chMin
if chMinT < chMin {
chMinT = chMin
}
chMaxT = lc.chMax
if chMaxT > chMax {
chMaxT = chMax
}
switch lc.op {
case LowercaseSet:
chMinT = rune(lc.data)
chMaxT = rune(lc.data)
break
case LowercaseAdd:
chMinT += lc.data
chMaxT += lc.data
break
case LowercaseBor:
chMinT |= 1
chMaxT |= 1
break
case LowercaseBad:
chMinT += (chMinT & 1)
chMaxT += (chMaxT & 1)
break
}
if chMinT < chMin || chMaxT > chMax {
c.addRange(chMinT, chMaxT)
}
}
}