go-ethereum/vendor/golang.org/x/text/language/maketables.go
Péter Szilágyi 289b30715d Godeps, vendor: convert dependency management to trash (#3198)
This commit converts the dependency management from Godeps to the vendor
folder, also switching the tool from godep to trash. Since the upstream tool
lacks a few features proposed via a few PRs, until those PRs are merged in
(if), use github.com/karalabe/trash.

You can update dependencies via trash --update.

All dependencies have been updated to their latest version.

Parts of the build system are reworked to drop old notions of Godeps and
invocation of the go vet command so that it doesn't run against the vendor
folder, as that will just blow up during vetting.

The conversion drops OpenCL (and hence GPU mining support) from ethash and our
codebase. The short reasoning is that there's noone to maintain and having
opencl libs in our deps messes up builds as go install ./... tries to build
them, failing with unsatisfied link errors for the C OpenCL deps.

golang.org/x/net/context is not vendored in. We expect it to be fetched by the
user (i.e. using go get). To keep ci.go builds reproducible the package is
"vendored" in build/_vendor.
2016-10-28 19:05:01 +02:00

1649 lines
46 KiB
Go

// Copyright 2013 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.
// +build ignore
// Language tag table generator.
// Data read from the web.
package main
import (
"bufio"
"flag"
"fmt"
"io"
"io/ioutil"
"log"
"math"
"reflect"
"regexp"
"sort"
"strconv"
"strings"
"golang.org/x/text/internal/gen"
"golang.org/x/text/internal/tag"
"golang.org/x/text/unicode/cldr"
)
var (
test = flag.Bool("test",
false,
"test existing tables; can be used to compare web data with package data.")
outputFile = flag.String("output",
"tables.go",
"output file for generated tables")
)
var comment = []string{
`
lang holds an alphabetically sorted list of ISO-639 language identifiers.
All entries are 4 bytes. The index of the identifier (divided by 4) is the language tag.
For 2-byte language identifiers, the two successive bytes have the following meaning:
- if the first letter of the 2- and 3-letter ISO codes are the same:
the second and third letter of the 3-letter ISO code.
- otherwise: a 0 and a by 2 bits right-shifted index into altLangISO3.
For 3-byte language identifiers the 4th byte is 0.`,
`
langNoIndex is a bit vector of all 3-letter language codes that are not used as an index
in lookup tables. The language ids for these language codes are derived directly
from the letters and are not consecutive.`,
`
altLangISO3 holds an alphabetically sorted list of 3-letter language code alternatives
to 2-letter language codes that cannot be derived using the method described above.
Each 3-letter code is followed by its 1-byte langID.`,
`
altLangIndex is used to convert indexes in altLangISO3 to langIDs.`,
`
langAliasMap maps langIDs to their suggested replacements.`,
`
script is an alphabetically sorted list of ISO 15924 codes. The index
of the script in the string, divided by 4, is the internal scriptID.`,
`
isoRegionOffset needs to be added to the index of regionISO to obtain the regionID
for 2-letter ISO codes. (The first isoRegionOffset regionIDs are reserved for
the UN.M49 codes used for groups.)`,
`
regionISO holds a list of alphabetically sorted 2-letter ISO region codes.
Each 2-letter codes is followed by two bytes with the following meaning:
- [A-Z}{2}: the first letter of the 2-letter code plus these two
letters form the 3-letter ISO code.
- 0, n: index into altRegionISO3.`,
`
regionTypes defines the status of a region for various standards.`,
`
m49 maps regionIDs to UN.M49 codes. The first isoRegionOffset entries are
codes indicating collections of regions.`,
`
m49Index gives indexes into fromM49 based on the three most significant bits
of a 10-bit UN.M49 code. To search an UN.M49 code in fromM49, search in
fromM49[m49Index[msb39(code)]:m49Index[msb3(code)+1]]
for an entry where the first 7 bits match the 7 lsb of the UN.M49 code.
The region code is stored in the 9 lsb of the indexed value.`,
`
fromM49 contains entries to map UN.M49 codes to regions. See m49Index for details.`,
`
altRegionISO3 holds a list of 3-letter region codes that cannot be
mapped to 2-letter codes using the default algorithm. This is a short list.`,
`
altRegionIDs holds a list of regionIDs the positions of which match those
of the 3-letter ISO codes in altRegionISO3.`,
`
variantNumSpecialized is the number of specialized variants in variants.`,
`
suppressScript is an index from langID to the dominant script for that language,
if it exists. If a script is given, it should be suppressed from the language tag.`,
`
likelyLang is a lookup table, indexed by langID, for the most likely
scripts and regions given incomplete information. If more entries exist for a
given language, region and script are the index and size respectively
of the list in likelyLangList.`,
`
likelyLangList holds lists info associated with likelyLang.`,
`
likelyRegion is a lookup table, indexed by regionID, for the most likely
languages and scripts given incomplete information. If more entries exist
for a given regionID, lang and script are the index and size respectively
of the list in likelyRegionList.
TODO: exclude containers and user-definable regions from the list.`,
`
likelyRegionList holds lists info associated with likelyRegion.`,
`
likelyScript is a lookup table, indexed by scriptID, for the most likely
languages and regions given a script.`,
`
matchLang holds pairs of langIDs of base languages that are typically
mutually intelligible. Each pair is associated with a confidence and
whether the intelligibility goes one or both ways.`,
`
matchScript holds pairs of scriptIDs where readers of one script
can typically also read the other. Each is associated with a confidence.`,
`
nRegionGroups is the number of region groups.`,
`
regionInclusion maps region identifiers to sets of regions in regionInclusionBits,
where each set holds all groupings that are directly connected in a region
containment graph.`,
`
regionInclusionBits is an array of bit vectors where every vector represents
a set of region groupings. These sets are used to compute the distance
between two regions for the purpose of language matching.`,
`
regionInclusionNext marks, for each entry in regionInclusionBits, the set of
all groups that are reachable from the groups set in the respective entry.`,
}
// TODO: consider changing some of these structures to tries. This can reduce
// memory, but may increase the need for memory allocations. This could be
// mitigated if we can piggyback on language tags for common cases.
func failOnError(e error) {
if e != nil {
log.Panic(e)
}
}
type setType int
const (
Indexed setType = 1 + iota // all elements must be of same size
Linear
)
type stringSet struct {
s []string
sorted, frozen bool
// We often need to update values after the creation of an index is completed.
// We include a convenience map for keeping track of this.
update map[string]string
typ setType // used for checking.
}
func (ss *stringSet) clone() stringSet {
c := *ss
c.s = append([]string(nil), c.s...)
return c
}
func (ss *stringSet) setType(t setType) {
if ss.typ != t && ss.typ != 0 {
log.Panicf("type %d cannot be assigned as it was already %d", t, ss.typ)
}
}
// parse parses a whitespace-separated string and initializes ss with its
// components.
func (ss *stringSet) parse(s string) {
scan := bufio.NewScanner(strings.NewReader(s))
scan.Split(bufio.ScanWords)
for scan.Scan() {
ss.add(scan.Text())
}
}
func (ss *stringSet) assertChangeable() {
if ss.frozen {
log.Panic("attempt to modify a frozen stringSet")
}
}
func (ss *stringSet) add(s string) {
ss.assertChangeable()
ss.s = append(ss.s, s)
ss.sorted = ss.frozen
}
func (ss *stringSet) freeze() {
ss.compact()
ss.frozen = true
}
func (ss *stringSet) compact() {
if ss.sorted {
return
}
a := ss.s
sort.Strings(a)
k := 0
for i := 1; i < len(a); i++ {
if a[k] != a[i] {
a[k+1] = a[i]
k++
}
}
ss.s = a[:k+1]
ss.sorted = ss.frozen
}
type funcSorter struct {
fn func(a, b string) bool
sort.StringSlice
}
func (s funcSorter) Less(i, j int) bool {
return s.fn(s.StringSlice[i], s.StringSlice[j])
}
func (ss *stringSet) sortFunc(f func(a, b string) bool) {
ss.compact()
sort.Sort(funcSorter{f, sort.StringSlice(ss.s)})
}
func (ss *stringSet) remove(s string) {
ss.assertChangeable()
if i, ok := ss.find(s); ok {
copy(ss.s[i:], ss.s[i+1:])
ss.s = ss.s[:len(ss.s)-1]
}
}
func (ss *stringSet) replace(ol, nu string) {
ss.s[ss.index(ol)] = nu
ss.sorted = ss.frozen
}
func (ss *stringSet) index(s string) int {
ss.setType(Indexed)
i, ok := ss.find(s)
if !ok {
if i < len(ss.s) {
log.Panicf("find: item %q is not in list. Closest match is %q.", s, ss.s[i])
}
log.Panicf("find: item %q is not in list", s)
}
return i
}
func (ss *stringSet) find(s string) (int, bool) {
ss.compact()
i := sort.SearchStrings(ss.s, s)
return i, i != len(ss.s) && ss.s[i] == s
}
func (ss *stringSet) slice() []string {
ss.compact()
return ss.s
}
func (ss *stringSet) updateLater(v, key string) {
if ss.update == nil {
ss.update = map[string]string{}
}
ss.update[v] = key
}
// join joins the string and ensures that all entries are of the same length.
func (ss *stringSet) join() string {
ss.setType(Indexed)
n := len(ss.s[0])
for _, s := range ss.s {
if len(s) != n {
log.Panicf("join: not all entries are of the same length: %q", s)
}
}
ss.s = append(ss.s, strings.Repeat("\xff", n))
return strings.Join(ss.s, "")
}
// ianaEntry holds information for an entry in the IANA Language Subtag Repository.
// All types use the same entry.
// See http://tools.ietf.org/html/bcp47#section-5.1 for a description of the various
// fields.
type ianaEntry struct {
typ string
description []string
scope string
added string
preferred string
deprecated string
suppressScript string
macro string
prefix []string
}
type builder struct {
w *gen.CodeWriter
hw io.Writer // MultiWriter for w and w.Hash
data *cldr.CLDR
supp *cldr.SupplementalData
// indices
locale stringSet // common locales
lang stringSet // canonical language ids (2 or 3 letter ISO codes) with data
langNoIndex stringSet // 3-letter ISO codes with no associated data
script stringSet // 4-letter ISO codes
region stringSet // 2-letter ISO or 3-digit UN M49 codes
variant stringSet // 4-8-alphanumeric variant code.
// Region codes that are groups with their corresponding group IDs.
groups map[int]index
// langInfo
registry map[string]*ianaEntry
}
type index uint
func newBuilder(w *gen.CodeWriter) *builder {
r := gen.OpenCLDRCoreZip()
defer r.Close()
d := &cldr.Decoder{}
data, err := d.DecodeZip(r)
failOnError(err)
b := builder{
w: w,
hw: io.MultiWriter(w, w.Hash),
data: data,
supp: data.Supplemental(),
}
b.parseRegistry()
return &b
}
func (b *builder) parseRegistry() {
r := gen.OpenIANAFile("assignments/language-subtag-registry")
defer r.Close()
b.registry = make(map[string]*ianaEntry)
scan := bufio.NewScanner(r)
scan.Split(bufio.ScanWords)
var record *ianaEntry
for more := scan.Scan(); more; {
key := scan.Text()
more = scan.Scan()
value := scan.Text()
switch key {
case "Type:":
record = &ianaEntry{typ: value}
case "Subtag:", "Tag:":
if s := strings.SplitN(value, "..", 2); len(s) > 1 {
for a := s[0]; a <= s[1]; a = inc(a) {
b.addToRegistry(a, record)
}
} else {
b.addToRegistry(value, record)
}
case "Suppress-Script:":
record.suppressScript = value
case "Added:":
record.added = value
case "Deprecated:":
record.deprecated = value
case "Macrolanguage:":
record.macro = value
case "Preferred-Value:":
record.preferred = value
case "Prefix:":
record.prefix = append(record.prefix, value)
case "Scope:":
record.scope = value
case "Description:":
buf := []byte(value)
for more = scan.Scan(); more; more = scan.Scan() {
b := scan.Bytes()
if b[0] == '%' || b[len(b)-1] == ':' {
break
}
buf = append(buf, ' ')
buf = append(buf, b...)
}
record.description = append(record.description, string(buf))
continue
default:
continue
}
more = scan.Scan()
}
if scan.Err() != nil {
log.Panic(scan.Err())
}
}
func (b *builder) addToRegistry(key string, entry *ianaEntry) {
if info, ok := b.registry[key]; ok {
if info.typ != "language" || entry.typ != "extlang" {
log.Fatalf("parseRegistry: tag %q already exists", key)
}
} else {
b.registry[key] = entry
}
}
var commentIndex = make(map[string]string)
func init() {
for _, s := range comment {
key := strings.TrimSpace(strings.SplitN(s, " ", 2)[0])
commentIndex[key] = s
}
}
func (b *builder) comment(name string) {
if s := commentIndex[name]; len(s) > 0 {
b.w.WriteComment(s)
} else {
fmt.Fprintln(b.w)
}
}
func (b *builder) pf(f string, x ...interface{}) {
fmt.Fprintf(b.hw, f, x...)
fmt.Fprint(b.hw, "\n")
}
func (b *builder) p(x ...interface{}) {
fmt.Fprintln(b.hw, x...)
}
func (b *builder) addSize(s int) {
b.w.Size += s
b.pf("// Size: %d bytes", s)
}
func (b *builder) writeConst(name string, x interface{}) {
b.comment(name)
b.w.WriteConst(name, x)
}
// writeConsts computes f(v) for all v in values and writes the results
// as constants named _v to a single constant block.
func (b *builder) writeConsts(f func(string) int, values ...string) {
b.pf("const (")
for _, v := range values {
b.pf("\t_%s = %v", v, f(v))
}
b.pf(")")
}
// writeType writes the type of the given value, which must be a struct.
func (b *builder) writeType(value interface{}) {
b.comment(reflect.TypeOf(value).Name())
b.w.WriteType(value)
}
func (b *builder) writeSlice(name string, ss interface{}) {
b.writeSliceAddSize(name, 0, ss)
}
func (b *builder) writeSliceAddSize(name string, extraSize int, ss interface{}) {
b.comment(name)
b.w.Size += extraSize
v := reflect.ValueOf(ss)
t := v.Type().Elem()
b.pf("// Size: %d bytes, %d elements", v.Len()*int(t.Size())+extraSize, v.Len())
fmt.Fprintf(b.w, "var %s = ", name)
b.w.WriteArray(ss)
b.p()
}
type fromTo struct {
from, to uint16
}
func (b *builder) writeSortedMap(name string, ss *stringSet, index func(s string) uint16) {
ss.sortFunc(func(a, b string) bool {
return index(a) < index(b)
})
m := []fromTo{}
for _, s := range ss.s {
m = append(m, fromTo{index(s), index(ss.update[s])})
}
b.writeSlice(name, m)
}
const base = 'z' - 'a' + 1
func strToInt(s string) uint {
v := uint(0)
for i := 0; i < len(s); i++ {
v *= base
v += uint(s[i] - 'a')
}
return v
}
// converts the given integer to the original ASCII string passed to strToInt.
// len(s) must match the number of characters obtained.
func intToStr(v uint, s []byte) {
for i := len(s) - 1; i >= 0; i-- {
s[i] = byte(v%base) + 'a'
v /= base
}
}
func (b *builder) writeBitVector(name string, ss []string) {
vec := make([]uint8, int(math.Ceil(math.Pow(base, float64(len(ss[0])))/8)))
for _, s := range ss {
v := strToInt(s)
vec[v/8] |= 1 << (v % 8)
}
b.writeSlice(name, vec)
}
// TODO: convert this type into a list or two-stage trie.
func (b *builder) writeMapFunc(name string, m map[string]string, f func(string) uint16) {
b.comment(name)
v := reflect.ValueOf(m)
sz := v.Len() * (2 + int(v.Type().Key().Size()))
for _, k := range m {
sz += len(k)
}
b.addSize(sz)
keys := []string{}
b.pf(`var %s = map[string]uint16{`, name)
for k := range m {
keys = append(keys, k)
}
sort.Strings(keys)
for _, k := range keys {
b.pf("\t%q: %v,", k, f(m[k]))
}
b.p("}")
}
func (b *builder) writeMap(name string, m interface{}) {
b.comment(name)
v := reflect.ValueOf(m)
sz := v.Len() * (2 + int(v.Type().Key().Size()) + int(v.Type().Elem().Size()))
b.addSize(sz)
f := strings.FieldsFunc(fmt.Sprintf("%#v", m), func(r rune) bool {
return strings.IndexRune("{}, ", r) != -1
})
sort.Strings(f[1:])
b.pf(`var %s = %s{`, name, f[0])
for _, kv := range f[1:] {
b.pf("\t%s,", kv)
}
b.p("}")
}
func (b *builder) langIndex(s string) uint16 {
if s == "und" {
return 0
}
if i, ok := b.lang.find(s); ok {
return uint16(i)
}
return uint16(strToInt(s)) + uint16(len(b.lang.s))
}
// inc advances the string to its lexicographical successor.
func inc(s string) string {
const maxTagLength = 4
var buf [maxTagLength]byte
intToStr(strToInt(strings.ToLower(s))+1, buf[:len(s)])
for i := 0; i < len(s); i++ {
if s[i] <= 'Z' {
buf[i] -= 'a' - 'A'
}
}
return string(buf[:len(s)])
}
func (b *builder) parseIndices() {
meta := b.supp.Metadata
for k, v := range b.registry {
var ss *stringSet
switch v.typ {
case "language":
if len(k) == 2 || v.suppressScript != "" || v.scope == "special" {
b.lang.add(k)
continue
} else {
ss = &b.langNoIndex
}
case "region":
ss = &b.region
case "script":
ss = &b.script
case "variant":
ss = &b.variant
default:
continue
}
ss.add(k)
}
// Include any language for which there is data.
for _, lang := range b.data.Locales() {
if x := b.data.RawLDML(lang); false ||
x.LocaleDisplayNames != nil ||
x.Characters != nil ||
x.Delimiters != nil ||
x.Measurement != nil ||
x.Dates != nil ||
x.Numbers != nil ||
x.Units != nil ||
x.ListPatterns != nil ||
x.Collations != nil ||
x.Segmentations != nil ||
x.Rbnf != nil ||
x.Annotations != nil ||
x.Metadata != nil {
from := strings.Split(lang, "_")
if lang := from[0]; lang != "root" {
b.lang.add(lang)
}
}
}
// Include locales for plural rules, which uses a different structure.
for _, plurals := range b.data.Supplemental().Plurals {
for _, rules := range plurals.PluralRules {
for _, lang := range strings.Split(rules.Locales, " ") {
if lang = strings.Split(lang, "_")[0]; lang != "root" {
b.lang.add(lang)
}
}
}
}
// Include languages in likely subtags.
for _, m := range b.supp.LikelySubtags.LikelySubtag {
from := strings.Split(m.From, "_")
b.lang.add(from[0])
}
// Include ISO-639 alpha-3 bibliographic entries.
for _, a := range meta.Alias.LanguageAlias {
if a.Reason == "bibliographic" {
b.langNoIndex.add(a.Type)
}
}
// Include regions in territoryAlias (not all are in the IANA registry!)
for _, reg := range b.supp.Metadata.Alias.TerritoryAlias {
if len(reg.Type) == 2 {
b.region.add(reg.Type)
}
}
for _, s := range b.lang.s {
if len(s) == 3 {
b.langNoIndex.remove(s)
}
}
b.writeConst("numLanguages", len(b.lang.slice())+len(b.langNoIndex.slice()))
b.writeConst("numScripts", len(b.script.slice()))
b.writeConst("numRegions", len(b.region.slice()))
// Add dummy codes at the start of each list to represent "unspecified".
b.lang.add("---")
b.script.add("----")
b.region.add("---")
// common locales
b.locale.parse(meta.DefaultContent.Locales)
}
// TODO: region inclusion data will probably not be use used in future matchers.
func (b *builder) computeRegionGroups() {
b.groups = make(map[int]index)
// Create group indices.
for i := 1; b.region.s[i][0] < 'A'; i++ { // Base M49 indices on regionID.
b.groups[i] = index(len(b.groups))
}
for _, g := range b.supp.TerritoryContainment.Group {
// Skip UN and EURO zone as they are flattening the containment
// relationship.
if g.Type == "EZ" || g.Type == "UN" {
continue
}
group := b.region.index(g.Type)
if _, ok := b.groups[group]; !ok {
b.groups[group] = index(len(b.groups))
}
}
if len(b.groups) > 32 {
log.Fatalf("only 32 groups supported, found %d", len(b.groups))
}
b.writeConst("nRegionGroups", len(b.groups))
}
var langConsts = []string{
"af", "am", "ar", "az", "bg", "bn", "ca", "cs", "da", "de", "el", "en", "es",
"et", "fa", "fi", "fil", "fr", "gu", "he", "hi", "hr", "hu", "hy", "id", "is",
"it", "ja", "ka", "kk", "km", "kn", "ko", "ky", "lo", "lt", "lv", "mk", "ml",
"mn", "mo", "mr", "ms", "mul", "my", "nb", "ne", "nl", "no", "pa", "pl", "pt",
"ro", "ru", "sh", "si", "sk", "sl", "sq", "sr", "sv", "sw", "ta", "te", "th",
"tl", "tn", "tr", "uk", "ur", "uz", "vi", "zh", "zu",
// constants for grandfathered tags (if not already defined)
"jbo", "ami", "bnn", "hak", "tlh", "lb", "nv", "pwn", "tao", "tay", "tsu",
"nn", "sfb", "vgt", "sgg", "cmn", "nan", "hsn",
}
// writeLanguage generates all tables needed for language canonicalization.
func (b *builder) writeLanguage() {
meta := b.supp.Metadata
b.writeConst("nonCanonicalUnd", b.lang.index("und"))
b.writeConsts(func(s string) int { return int(b.langIndex(s)) }, langConsts...)
b.writeConst("langPrivateStart", b.langIndex("qaa"))
b.writeConst("langPrivateEnd", b.langIndex("qtz"))
// Get language codes that need to be mapped (overlong 3-letter codes,
// deprecated 2-letter codes, legacy and grandfathered tags.)
langAliasMap := stringSet{}
aliasTypeMap := map[string]langAliasType{}
// altLangISO3 get the alternative ISO3 names that need to be mapped.
altLangISO3 := stringSet{}
// Add dummy start to avoid the use of index 0.
altLangISO3.add("---")
altLangISO3.updateLater("---", "aa")
lang := b.lang.clone()
for _, a := range meta.Alias.LanguageAlias {
if a.Replacement == "" {
a.Replacement = "und"
}
// TODO: support mapping to tags
repl := strings.SplitN(a.Replacement, "_", 2)[0]
if a.Reason == "overlong" {
if len(a.Replacement) == 2 && len(a.Type) == 3 {
lang.updateLater(a.Replacement, a.Type)
}
} else if len(a.Type) <= 3 {
switch a.Reason {
case "macrolanguage":
aliasTypeMap[a.Type] = langMacro
case "deprecated":
// handled elsewhere
continue
case "bibliographic", "legacy":
if a.Type == "no" {
continue
}
aliasTypeMap[a.Type] = langLegacy
default:
log.Fatalf("new %s alias: %s", a.Reason, a.Type)
}
langAliasMap.add(a.Type)
langAliasMap.updateLater(a.Type, repl)
}
}
// Manually add the mapping of "nb" (Norwegian) to its macro language.
// This can be removed if CLDR adopts this change.
langAliasMap.add("nb")
langAliasMap.updateLater("nb", "no")
aliasTypeMap["nb"] = langMacro
for k, v := range b.registry {
// Also add deprecated values for 3-letter ISO codes, which CLDR omits.
if v.typ == "language" && v.deprecated != "" && v.preferred != "" {
langAliasMap.add(k)
langAliasMap.updateLater(k, v.preferred)
aliasTypeMap[k] = langDeprecated
}
}
// Fix CLDR mappings.
lang.updateLater("tl", "tgl")
lang.updateLater("sh", "hbs")
lang.updateLater("mo", "mol")
lang.updateLater("no", "nor")
lang.updateLater("tw", "twi")
lang.updateLater("nb", "nob")
lang.updateLater("ak", "aka")
lang.updateLater("bh", "bih")
// Ensure that each 2-letter code is matched with a 3-letter code.
for _, v := range lang.s[1:] {
s, ok := lang.update[v]
if !ok {
if s, ok = lang.update[langAliasMap.update[v]]; !ok {
continue
}
lang.update[v] = s
}
if v[0] != s[0] {
altLangISO3.add(s)
altLangISO3.updateLater(s, v)
}
}
// Complete canonialized language tags.
lang.freeze()
for i, v := range lang.s {
// We can avoid these manual entries by using the IANI registry directly.
// Seems easier to update the list manually, as changes are rare.
// The panic in this loop will trigger if we miss an entry.
add := ""
if s, ok := lang.update[v]; ok {
if s[0] == v[0] {
add = s[1:]
} else {
add = string([]byte{0, byte(altLangISO3.index(s))})
}
} else if len(v) == 3 {
add = "\x00"
} else {
log.Panicf("no data for long form of %q", v)
}
lang.s[i] += add
}
b.writeConst("lang", tag.Index(lang.join()))
b.writeConst("langNoIndexOffset", len(b.lang.s))
// space of all valid 3-letter language identifiers.
b.writeBitVector("langNoIndex", b.langNoIndex.slice())
altLangIndex := []uint16{}
for i, s := range altLangISO3.slice() {
altLangISO3.s[i] += string([]byte{byte(len(altLangIndex))})
if i > 0 {
idx := b.lang.index(altLangISO3.update[s])
altLangIndex = append(altLangIndex, uint16(idx))
}
}
b.writeConst("altLangISO3", tag.Index(altLangISO3.join()))
b.writeSlice("altLangIndex", altLangIndex)
b.writeSortedMap("langAliasMap", &langAliasMap, b.langIndex)
types := make([]langAliasType, len(langAliasMap.s))
for i, s := range langAliasMap.s {
types[i] = aliasTypeMap[s]
}
b.writeSlice("langAliasTypes", types)
}
var scriptConsts = []string{
"Latn", "Hani", "Hans", "Hant", "Qaaa", "Qaai", "Qabx", "Zinh", "Zyyy",
"Zzzz",
}
func (b *builder) writeScript() {
b.writeConsts(b.script.index, scriptConsts...)
b.writeConst("script", tag.Index(b.script.join()))
supp := make([]uint8, len(b.lang.slice()))
for i, v := range b.lang.slice()[1:] {
if sc := b.registry[v].suppressScript; sc != "" {
supp[i+1] = uint8(b.script.index(sc))
}
}
b.writeSlice("suppressScript", supp)
// There is only one deprecated script in CLDR. This value is hard-coded.
// We check here if the code must be updated.
for _, a := range b.supp.Metadata.Alias.ScriptAlias {
if a.Type != "Qaai" {
log.Panicf("unexpected deprecated stript %q", a.Type)
}
}
}
func parseM49(s string) int16 {
if len(s) == 0 {
return 0
}
v, err := strconv.ParseUint(s, 10, 10)
failOnError(err)
return int16(v)
}
var regionConsts = []string{
"001", "419", "BR", "CA", "ES", "GB", "MD", "PT", "UK", "US",
"ZZ", "XA", "XC", "XK", // Unofficial tag for Kosovo.
}
func (b *builder) writeRegion() {
b.writeConsts(b.region.index, regionConsts...)
isoOffset := b.region.index("AA")
m49map := make([]int16, len(b.region.slice()))
fromM49map := make(map[int16]int)
altRegionISO3 := ""
altRegionIDs := []uint16{}
b.writeConst("isoRegionOffset", isoOffset)
// 2-letter region lookup and mapping to numeric codes.
regionISO := b.region.clone()
regionISO.s = regionISO.s[isoOffset:]
regionISO.sorted = false
regionTypes := make([]byte, len(b.region.s))
// Is the region valid BCP 47?
for s, e := range b.registry {
if len(s) == 2 && s == strings.ToUpper(s) {
i := b.region.index(s)
for _, d := range e.description {
if strings.Contains(d, "Private use") {
regionTypes[i] = iso3166UserAssgined
}
}
regionTypes[i] |= bcp47Region
}
}
// Is the region a valid ccTLD?
r := gen.OpenIANAFile("domains/root/db")
defer r.Close()
buf, err := ioutil.ReadAll(r)
failOnError(err)
re := regexp.MustCompile(`"/domains/root/db/([a-z]{2}).html"`)
for _, m := range re.FindAllSubmatch(buf, -1) {
i := b.region.index(strings.ToUpper(string(m[1])))
regionTypes[i] |= ccTLD
}
b.writeSlice("regionTypes", regionTypes)
iso3Set := make(map[string]int)
update := func(iso2, iso3 string) {
i := regionISO.index(iso2)
if j, ok := iso3Set[iso3]; !ok && iso3[0] == iso2[0] {
regionISO.s[i] += iso3[1:]
iso3Set[iso3] = -1
} else {
if ok && j >= 0 {
regionISO.s[i] += string([]byte{0, byte(j)})
} else {
iso3Set[iso3] = len(altRegionISO3)
regionISO.s[i] += string([]byte{0, byte(len(altRegionISO3))})
altRegionISO3 += iso3
altRegionIDs = append(altRegionIDs, uint16(isoOffset+i))
}
}
}
for _, tc := range b.supp.CodeMappings.TerritoryCodes {
i := regionISO.index(tc.Type) + isoOffset
if d := m49map[i]; d != 0 {
log.Panicf("%s found as a duplicate UN.M49 code of %03d", tc.Numeric, d)
}
m49 := parseM49(tc.Numeric)
m49map[i] = m49
if r := fromM49map[m49]; r == 0 {
fromM49map[m49] = i
} else if r != i {
dep := b.registry[regionISO.s[r-isoOffset]].deprecated
if t := b.registry[tc.Type]; t != nil && dep != "" && (t.deprecated == "" || t.deprecated > dep) {
fromM49map[m49] = i
}
}
}
for _, ta := range b.supp.Metadata.Alias.TerritoryAlias {
if len(ta.Type) == 3 && ta.Type[0] <= '9' && len(ta.Replacement) == 2 {
from := parseM49(ta.Type)
if r := fromM49map[from]; r == 0 {
fromM49map[from] = regionISO.index(ta.Replacement) + isoOffset
}
}
}
for _, tc := range b.supp.CodeMappings.TerritoryCodes {
if len(tc.Alpha3) == 3 {
update(tc.Type, tc.Alpha3)
}
}
// This entries are not included in territoryCodes. Mostly 3-letter variants
// of deleted codes and an entry for QU.
for _, m := range []struct{ iso2, iso3 string }{
{"CT", "CTE"},
{"DY", "DHY"},
{"HV", "HVO"},
{"JT", "JTN"},
{"MI", "MID"},
{"NH", "NHB"},
{"NQ", "ATN"},
{"PC", "PCI"},
{"PU", "PUS"},
{"PZ", "PCZ"},
{"RH", "RHO"},
{"VD", "VDR"},
{"WK", "WAK"},
// These three-letter codes are used for others as well.
{"FQ", "ATF"},
} {
update(m.iso2, m.iso3)
}
for i, s := range regionISO.s {
if len(s) != 4 {
regionISO.s[i] = s + " "
}
}
b.writeConst("regionISO", tag.Index(regionISO.join()))
b.writeConst("altRegionISO3", altRegionISO3)
b.writeSlice("altRegionIDs", altRegionIDs)
// Create list of deprecated regions.
// TODO: consider inserting SF -> FI. Not included by CLDR, but is the only
// Transitionally-reserved mapping not included.
regionOldMap := stringSet{}
// Include regions in territoryAlias (not all are in the IANA registry!)
for _, reg := range b.supp.Metadata.Alias.TerritoryAlias {
if len(reg.Type) == 2 && reg.Reason == "deprecated" && len(reg.Replacement) == 2 {
regionOldMap.add(reg.Type)
regionOldMap.updateLater(reg.Type, reg.Replacement)
i, _ := regionISO.find(reg.Type)
j, _ := regionISO.find(reg.Replacement)
if k := m49map[i+isoOffset]; k == 0 {
m49map[i+isoOffset] = m49map[j+isoOffset]
}
}
}
b.writeSortedMap("regionOldMap", &regionOldMap, func(s string) uint16 {
return uint16(b.region.index(s))
})
// 3-digit region lookup, groupings.
for i := 1; i < isoOffset; i++ {
m := parseM49(b.region.s[i])
m49map[i] = m
fromM49map[m] = i
}
b.writeSlice("m49", m49map)
const (
searchBits = 7
regionBits = 9
)
if len(m49map) >= 1<<regionBits {
log.Fatalf("Maximum number of regions exceeded: %d > %d", len(m49map), 1<<regionBits)
}
m49Index := [9]int16{}
fromM49 := []uint16{}
m49 := []int{}
for k, _ := range fromM49map {
m49 = append(m49, int(k))
}
sort.Ints(m49)
for _, k := range m49[1:] {
val := (k & (1<<searchBits - 1)) << regionBits
fromM49 = append(fromM49, uint16(val|fromM49map[int16(k)]))
m49Index[1:][k>>searchBits] = int16(len(fromM49))
}
b.writeSlice("m49Index", m49Index)
b.writeSlice("fromM49", fromM49)
}
const (
// TODO: put these lists in regionTypes as user data? Could be used for
// various optimizations and refinements and could be exposed in the API.
iso3166Except = "AC CP DG EA EU FX IC SU TA UK"
iso3166Trans = "AN BU CS NT TP YU ZR" // SF is not in our set of Regions.
// DY and RH are actually not deleted, but indeterminately reserved.
iso3166DelCLDR = "CT DD DY FQ HV JT MI NH NQ PC PU PZ RH VD WK YD"
)
const (
iso3166UserAssgined = 1 << iota
ccTLD
bcp47Region
)
func find(list []string, s string) int {
for i, t := range list {
if t == s {
return i
}
}
return -1
}
// writeVariants generates per-variant information and creates a map from variant
// name to index value. We assign index values such that sorting multiple
// variants by index value will result in the correct order.
// There are two types of variants: specialized and general. Specialized variants
// are only applicable to certain language or language-script pairs. Generalized
// variants apply to any language. Generalized variants always sort after
// specialized variants. We will therefore always assign a higher index value
// to a generalized variant than any other variant. Generalized variants are
// sorted alphabetically among themselves.
// Specialized variants may also sort after other specialized variants. Such
// variants will be ordered after any of the variants they may follow.
// We assume that if a variant x is followed by a variant y, then for any prefix
// p of x, p-x is a prefix of y. This allows us to order tags based on the
// maximum of the length of any of its prefixes.
// TODO: it is possible to define a set of Prefix values on variants such that
// a total order cannot be defined to the point that this algorithm breaks.
// In other words, we cannot guarantee the same order of variants for the
// future using the same algorithm or for non-compliant combinations of
// variants. For this reason, consider using simple alphabetic sorting
// of variants and ignore Prefix restrictions altogether.
func (b *builder) writeVariant() {
generalized := stringSet{}
specialized := stringSet{}
specializedExtend := stringSet{}
// Collate the variants by type and check assumptions.
for _, v := range b.variant.slice() {
e := b.registry[v]
if len(e.prefix) == 0 {
generalized.add(v)
continue
}
c := strings.Split(e.prefix[0], "-")
hasScriptOrRegion := false
if len(c) > 1 {
_, hasScriptOrRegion = b.script.find(c[1])
if !hasScriptOrRegion {
_, hasScriptOrRegion = b.region.find(c[1])
}
}
if len(c) == 1 || len(c) == 2 && hasScriptOrRegion {
// Variant is preceded by a language.
specialized.add(v)
continue
}
// Variant is preceded by another variant.
specializedExtend.add(v)
prefix := c[0] + "-"
if hasScriptOrRegion {
prefix += c[1]
}
for _, p := range e.prefix {
// Verify that the prefix minus the last element is a prefix of the
// predecessor element.
i := strings.LastIndex(p, "-")
pred := b.registry[p[i+1:]]
if find(pred.prefix, p[:i]) < 0 {
log.Fatalf("prefix %q for variant %q not consistent with predecessor spec", p, v)
}
// The sorting used below does not work in the general case. It works
// if we assume that variants that may be followed by others only have
// prefixes of the same length. Verify this.
count := strings.Count(p[:i], "-")
for _, q := range pred.prefix {
if c := strings.Count(q, "-"); c != count {
log.Fatalf("variant %q preceding %q has a prefix %q of size %d; want %d", p[i+1:], v, q, c, count)
}
}
if !strings.HasPrefix(p, prefix) {
log.Fatalf("prefix %q of variant %q should start with %q", p, v, prefix)
}
}
}
// Sort extended variants.
a := specializedExtend.s
less := func(v, w string) bool {
// Sort by the maximum number of elements.
maxCount := func(s string) (max int) {
for _, p := range b.registry[s].prefix {
if c := strings.Count(p, "-"); c > max {
max = c
}
}
return
}
if cv, cw := maxCount(v), maxCount(w); cv != cw {
return cv < cw
}
// Sort by name as tie breaker.
return v < w
}
sort.Sort(funcSorter{less, sort.StringSlice(a)})
specializedExtend.frozen = true
// Create index from variant name to index.
variantIndex := make(map[string]uint8)
add := func(s []string) {
for _, v := range s {
variantIndex[v] = uint8(len(variantIndex))
}
}
add(specialized.slice())
add(specializedExtend.s)
numSpecialized := len(variantIndex)
add(generalized.slice())
if n := len(variantIndex); n > 255 {
log.Fatalf("maximum number of variants exceeded: was %d; want <= 255", n)
}
b.writeMap("variantIndex", variantIndex)
b.writeConst("variantNumSpecialized", numSpecialized)
}
func (b *builder) writeLanguageInfo() {
}
// writeLikelyData writes tables that are used both for finding parent relations and for
// language matching. Each entry contains additional bits to indicate the status of the
// data to know when it cannot be used for parent relations.
func (b *builder) writeLikelyData() {
const (
isList = 1 << iota
scriptInFrom
regionInFrom
)
type ( // generated types
likelyScriptRegion struct {
region uint16
script uint8
flags uint8
}
likelyLangScript struct {
lang uint16
script uint8
flags uint8
}
likelyLangRegion struct {
lang uint16
region uint16
}
// likelyTag is used for getting likely tags for group regions, where
// the likely region might be a region contained in the group.
likelyTag struct {
lang uint16
region uint16
script uint8
}
)
var ( // generated variables
likelyRegionGroup = make([]likelyTag, len(b.groups))
likelyLang = make([]likelyScriptRegion, len(b.lang.s))
likelyRegion = make([]likelyLangScript, len(b.region.s))
likelyScript = make([]likelyLangRegion, len(b.script.s))
likelyLangList = []likelyScriptRegion{}
likelyRegionList = []likelyLangScript{}
)
type fromTo struct {
from, to []string
}
langToOther := map[int][]fromTo{}
regionToOther := map[int][]fromTo{}
for _, m := range b.supp.LikelySubtags.LikelySubtag {
from := strings.Split(m.From, "_")
to := strings.Split(m.To, "_")
if len(to) != 3 {
log.Fatalf("invalid number of subtags in %q: found %d, want 3", m.To, len(to))
}
if len(from) > 3 {
log.Fatalf("invalid number of subtags: found %d, want 1-3", len(from))
}
if from[0] != to[0] && from[0] != "und" {
log.Fatalf("unexpected language change in expansion: %s -> %s", from, to)
}
if len(from) == 3 {
if from[2] != to[2] {
log.Fatalf("unexpected region change in expansion: %s -> %s", from, to)
}
if from[0] != "und" {
log.Fatalf("unexpected fully specified from tag: %s -> %s", from, to)
}
}
if len(from) == 1 || from[0] != "und" {
id := 0
if from[0] != "und" {
id = b.lang.index(from[0])
}
langToOther[id] = append(langToOther[id], fromTo{from, to})
} else if len(from) == 2 && len(from[1]) == 4 {
sid := b.script.index(from[1])
likelyScript[sid].lang = uint16(b.langIndex(to[0]))
likelyScript[sid].region = uint16(b.region.index(to[2]))
} else {
r := b.region.index(from[len(from)-1])
if id, ok := b.groups[r]; ok {
if from[0] != "und" {
log.Fatalf("region changed unexpectedly: %s -> %s", from, to)
}
likelyRegionGroup[id].lang = uint16(b.langIndex(to[0]))
likelyRegionGroup[id].script = uint8(b.script.index(to[1]))
likelyRegionGroup[id].region = uint16(b.region.index(to[2]))
} else {
regionToOther[r] = append(regionToOther[r], fromTo{from, to})
}
}
}
b.writeType(likelyLangRegion{})
b.writeSlice("likelyScript", likelyScript)
for id := range b.lang.s {
list := langToOther[id]
if len(list) == 1 {
likelyLang[id].region = uint16(b.region.index(list[0].to[2]))
likelyLang[id].script = uint8(b.script.index(list[0].to[1]))
} else if len(list) > 1 {
likelyLang[id].flags = isList
likelyLang[id].region = uint16(len(likelyLangList))
likelyLang[id].script = uint8(len(list))
for _, x := range list {
flags := uint8(0)
if len(x.from) > 1 {
if x.from[1] == x.to[2] {
flags = regionInFrom
} else {
flags = scriptInFrom
}
}
likelyLangList = append(likelyLangList, likelyScriptRegion{
region: uint16(b.region.index(x.to[2])),
script: uint8(b.script.index(x.to[1])),
flags: flags,
})
}
}
}
// TODO: merge suppressScript data with this table.
b.writeType(likelyScriptRegion{})
b.writeSlice("likelyLang", likelyLang)
b.writeSlice("likelyLangList", likelyLangList)
for id := range b.region.s {
list := regionToOther[id]
if len(list) == 1 {
likelyRegion[id].lang = uint16(b.langIndex(list[0].to[0]))
likelyRegion[id].script = uint8(b.script.index(list[0].to[1]))
if len(list[0].from) > 2 {
likelyRegion[id].flags = scriptInFrom
}
} else if len(list) > 1 {
likelyRegion[id].flags = isList
likelyRegion[id].lang = uint16(len(likelyRegionList))
likelyRegion[id].script = uint8(len(list))
for i, x := range list {
if len(x.from) == 2 && i != 0 || i > 0 && len(x.from) != 3 {
log.Fatalf("unspecified script must be first in list: %v at %d", x.from, i)
}
x := likelyLangScript{
lang: uint16(b.langIndex(x.to[0])),
script: uint8(b.script.index(x.to[1])),
}
if len(list[0].from) > 2 {
x.flags = scriptInFrom
}
likelyRegionList = append(likelyRegionList, x)
}
}
}
b.writeType(likelyLangScript{})
b.writeSlice("likelyRegion", likelyRegion)
b.writeSlice("likelyRegionList", likelyRegionList)
b.writeType(likelyTag{})
b.writeSlice("likelyRegionGroup", likelyRegionGroup)
}
type mutualIntelligibility struct {
want, have uint16
conf uint8
oneway bool
}
type scriptIntelligibility struct {
lang uint16 // langID or 0 if *
want, have uint8
conf uint8
}
type sortByConf []mutualIntelligibility
func (l sortByConf) Less(a, b int) bool {
return l[a].conf > l[b].conf
}
func (l sortByConf) Swap(a, b int) {
l[a], l[b] = l[b], l[a]
}
func (l sortByConf) Len() int {
return len(l)
}
// toConf converts a percentage value [0, 100] to a confidence class.
func toConf(pct uint8) uint8 {
switch {
case pct == 100:
return 3 // Exact
case pct >= 90:
return 2 // High
case pct > 50:
return 1 // Low
default:
return 0 // No
}
}
// writeMatchData writes tables with languages and scripts for which there is
// mutual intelligibility. The data is based on CLDR's languageMatching data.
// Note that we use a different algorithm than the one defined by CLDR and that
// we slightly modify the data. For example, we convert scores to confidence levels.
// We also drop all region-related data as we use a different algorithm to
// determine region equivalence.
func (b *builder) writeMatchData() {
b.writeType(mutualIntelligibility{})
b.writeType(scriptIntelligibility{})
lm := b.supp.LanguageMatching.LanguageMatches
cldr.MakeSlice(&lm).SelectAnyOf("type", "written")
matchLang := []mutualIntelligibility{}
matchScript := []scriptIntelligibility{}
// Convert the languageMatch entries in lists keyed by desired language.
for _, m := range lm[0].LanguageMatch {
// Different versions of CLDR use different separators.
desired := strings.Replace(m.Desired, "-", "_", -1)
supported := strings.Replace(m.Supported, "-", "_", -1)
d := strings.Split(desired, "_")
s := strings.Split(supported, "_")
if len(d) != len(s) || len(d) > 2 {
// Skip all entries with regions and work around CLDR bug.
continue
}
pct, _ := strconv.ParseInt(m.Percent, 10, 8)
if len(d) == 2 && d[0] == s[0] && len(d[1]) == 4 {
// language-script pair.
lang := uint16(0)
if d[0] != "*" {
lang = uint16(b.langIndex(d[0]))
}
matchScript = append(matchScript, scriptIntelligibility{
lang: lang,
want: uint8(b.script.index(d[1])),
have: uint8(b.script.index(s[1])),
conf: toConf(uint8(pct)),
})
if m.Oneway != "true" {
matchScript = append(matchScript, scriptIntelligibility{
lang: lang,
want: uint8(b.script.index(s[1])),
have: uint8(b.script.index(d[1])),
conf: toConf(uint8(pct)),
})
}
} else if len(d) == 1 && d[0] != "*" {
if pct == 100 {
// nb == no is already handled by macro mapping. Check there
// really is only this case.
if d[0] != "no" || s[0] != "nb" {
log.Fatalf("unhandled equivalence %s == %s", s[0], d[0])
}
continue
}
matchLang = append(matchLang, mutualIntelligibility{
want: uint16(b.langIndex(d[0])),
have: uint16(b.langIndex(s[0])),
conf: uint8(pct),
oneway: m.Oneway == "true",
})
} else {
// TODO: Handle other mappings.
a := []string{"*;*", "*_*;*_*", "es_MX;es_419"}
s := strings.Join([]string{desired, supported}, ";")
if i := sort.SearchStrings(a, s); i == len(a) || a[i] != s {
log.Printf("%q not handled", s)
}
}
}
sort.Stable(sortByConf(matchLang))
// collapse percentage into confidence classes
for i, m := range matchLang {
matchLang[i].conf = toConf(m.conf)
}
b.writeSlice("matchLang", matchLang)
b.writeSlice("matchScript", matchScript)
}
func (b *builder) writeRegionInclusionData() {
var (
// mm holds for each group the set of groups with a distance of 1.
mm = make(map[int][]index)
// containment holds for each group the transitive closure of
// containment of other groups.
containment = make(map[index][]index)
)
for _, g := range b.supp.TerritoryContainment.Group {
// Skip UN and EURO zone as they are flattening the containment
// relationship.
if g.Type == "EZ" || g.Type == "UN" {
continue
}
group := b.region.index(g.Type)
groupIdx := b.groups[group]
for _, mem := range strings.Split(g.Contains, " ") {
r := b.region.index(mem)
mm[r] = append(mm[r], groupIdx)
if g, ok := b.groups[r]; ok {
mm[group] = append(mm[group], g)
containment[groupIdx] = append(containment[groupIdx], g)
}
}
}
regionContainment := make([]uint32, len(b.groups))
for _, g := range b.groups {
l := containment[g]
// Compute the transitive closure of containment.
for i := 0; i < len(l); i++ {
l = append(l, containment[l[i]]...)
}
// Compute the bitmask.
regionContainment[g] = 1 << g
for _, v := range l {
regionContainment[g] |= 1 << v
}
// log.Printf("%d: %X", g, regionContainment[g])
}
b.writeSlice("regionContainment", regionContainment)
regionInclusion := make([]uint8, len(b.region.s))
bvs := make(map[uint32]index)
// Make the first bitvector positions correspond with the groups.
for r, i := range b.groups {
bv := uint32(1 << i)
for _, g := range mm[r] {
bv |= 1 << g
}
bvs[bv] = i
regionInclusion[r] = uint8(bvs[bv])
}
for r := 1; r < len(b.region.s); r++ {
if _, ok := b.groups[r]; !ok {
bv := uint32(0)
for _, g := range mm[r] {
bv |= 1 << g
}
if bv == 0 {
// Pick the world for unspecified regions.
bv = 1 << b.groups[b.region.index("001")]
}
if _, ok := bvs[bv]; !ok {
bvs[bv] = index(len(bvs))
}
regionInclusion[r] = uint8(bvs[bv])
}
}
b.writeSlice("regionInclusion", regionInclusion)
regionInclusionBits := make([]uint32, len(bvs))
for k, v := range bvs {
regionInclusionBits[v] = uint32(k)
}
// Add bit vectors for increasingly large distances until a fixed point is reached.
regionInclusionNext := []uint8{}
for i := 0; i < len(regionInclusionBits); i++ {
bits := regionInclusionBits[i]
next := bits
for i := uint(0); i < uint(len(b.groups)); i++ {
if bits&(1<<i) != 0 {
next |= regionInclusionBits[i]
}
}
if _, ok := bvs[next]; !ok {
bvs[next] = index(len(bvs))
regionInclusionBits = append(regionInclusionBits, next)
}
regionInclusionNext = append(regionInclusionNext, uint8(bvs[next]))
}
b.writeSlice("regionInclusionBits", regionInclusionBits)
b.writeSlice("regionInclusionNext", regionInclusionNext)
}
type parentRel struct {
lang uint16
script uint8
maxScript uint8
toRegion uint16
fromRegion []uint16
}
func (b *builder) writeParents() {
b.writeType(parentRel{})
parents := []parentRel{}
// Construct parent overrides.
n := 0
for _, p := range b.data.Supplemental().ParentLocales.ParentLocale {
// Skipping non-standard scripts to root is implemented using addTags.
if p.Parent == "root" {
continue
}
sub := strings.Split(p.Parent, "_")
parent := parentRel{lang: b.langIndex(sub[0])}
if len(sub) == 2 {
// TODO: check that all undefined scripts are indeed Latn in these
// cases.
parent.maxScript = uint8(b.script.index("Latn"))
parent.toRegion = uint16(b.region.index(sub[1]))
} else {
parent.script = uint8(b.script.index(sub[1]))
parent.maxScript = parent.script
parent.toRegion = uint16(b.region.index(sub[2]))
}
for _, c := range strings.Split(p.Locales, " ") {
region := b.region.index(c[strings.LastIndex(c, "_")+1:])
parent.fromRegion = append(parent.fromRegion, uint16(region))
}
parents = append(parents, parent)
n += len(parent.fromRegion)
}
b.writeSliceAddSize("parents", n*2, parents)
}
func main() {
gen.Init()
gen.Repackage("gen_common.go", "common.go", "language")
w := gen.NewCodeWriter()
defer w.WriteGoFile("tables.go", "language")
fmt.Fprintln(w, `import "golang.org/x/text/internal/tag"`)
b := newBuilder(w)
gen.WriteCLDRVersion(w)
b.parseIndices()
b.writeType(fromTo{})
b.writeLanguage()
b.writeScript()
b.writeRegion()
b.writeVariant()
// TODO: b.writeLocale()
b.computeRegionGroups()
b.writeLikelyData()
b.writeMatchData()
b.writeRegionInclusionData()
b.writeParents()
}