// 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. //go:generate go run gen.go gen_common.go -output tables.go package language // import "golang.org/x/text/internal/language" // TODO: Remove above NOTE after: // - verifying that tables are dropped correctly (most notably matcher tables). import ( "errors" "fmt" "strings" ) const ( // maxCoreSize is the maximum size of a BCP 47 tag without variants and // extensions. Equals max lang (3) + script (4) + max reg (3) + 2 dashes. maxCoreSize = 12 // max99thPercentileSize is a somewhat arbitrary buffer size that presumably // is large enough to hold at least 99% of the BCP 47 tags. max99thPercentileSize = 32 // maxSimpleUExtensionSize is the maximum size of a -u extension with one // key-type pair. Equals len("-u-") + key (2) + dash + max value (8). maxSimpleUExtensionSize = 14 ) // Tag represents a BCP 47 language tag. It is used to specify an instance of a // specific language or locale. All language tag values are guaranteed to be // well-formed. type Tag struct { // TODO: the following fields have the form TagTypeID. This name is chosen // to allow refactoring the public package without conflicting with its // Base, Script, and Region methods. Once the transition is fully completed // the ID can be stripped from the name. LangID Language RegionID Region // TODO: we will soon run out of positions for ScriptID. Idea: instead of // storing lang, region, and ScriptID codes, store only the compact index and // have a lookup table from this code to its expansion. This greatly speeds // up table lookup, speed up common variant cases. // This will also immediately free up 3 extra bytes. Also, the pVariant // field can now be moved to the lookup table, as the compact index uniquely // determines the offset of a possible variant. ScriptID Script pVariant byte // offset in str, includes preceding '-' pExt uint16 // offset of first extension, includes preceding '-' // str is the string representation of the Tag. It will only be used if the // tag has variants or extensions. str string } // Make is a convenience wrapper for Parse that omits the error. // In case of an error, a sensible default is returned. func Make(s string) Tag { t, _ := Parse(s) return t } // Raw returns the raw base language, script and region, without making an // attempt to infer their values. // TODO: consider removing func (t Tag) Raw() (b Language, s Script, r Region) { return t.LangID, t.ScriptID, t.RegionID } // equalTags compares language, script and region subtags only. func (t Tag) equalTags(a Tag) bool { return t.LangID == a.LangID && t.ScriptID == a.ScriptID && t.RegionID == a.RegionID } // IsRoot returns true if t is equal to language "und". func (t Tag) IsRoot() bool { if int(t.pVariant) < len(t.str) { return false } return t.equalTags(und) } // IsPrivateUse reports whether the Tag consists solely of an IsPrivateUse use // tag. func (t Tag) IsPrivateUse() bool { return t.str != "" && t.pVariant == 0 } // RemakeString is used to update t.str in case lang, script or region changed. // It is assumed that pExt and pVariant still point to the start of the // respective parts. func (t *Tag) RemakeString() { if t.str == "" { return } extra := t.str[t.pVariant:] if t.pVariant > 0 { extra = extra[1:] } if t.equalTags(und) && strings.HasPrefix(extra, "x-") { t.str = extra t.pVariant = 0 t.pExt = 0 return } var buf [max99thPercentileSize]byte // avoid extra memory allocation in most cases. b := buf[:t.genCoreBytes(buf[:])] if extra != "" { diff := len(b) - int(t.pVariant) b = append(b, '-') b = append(b, extra...) t.pVariant = uint8(int(t.pVariant) + diff) t.pExt = uint16(int(t.pExt) + diff) } else { t.pVariant = uint8(len(b)) t.pExt = uint16(len(b)) } t.str = string(b) } // genCoreBytes writes a string for the base languages, script and region tags // to the given buffer and returns the number of bytes written. It will never // write more than maxCoreSize bytes. func (t *Tag) genCoreBytes(buf []byte) int { n := t.LangID.StringToBuf(buf[:]) if t.ScriptID != 0 { n += copy(buf[n:], "-") n += copy(buf[n:], t.ScriptID.String()) } if t.RegionID != 0 { n += copy(buf[n:], "-") n += copy(buf[n:], t.RegionID.String()) } return n } // String returns the canonical string representation of the language tag. func (t Tag) String() string { if t.str != "" { return t.str } if t.ScriptID == 0 && t.RegionID == 0 { return t.LangID.String() } buf := [maxCoreSize]byte{} return string(buf[:t.genCoreBytes(buf[:])]) } // MarshalText implements encoding.TextMarshaler. func (t Tag) MarshalText() (text []byte, err error) { if t.str != "" { text = append(text, t.str...) } else if t.ScriptID == 0 && t.RegionID == 0 { text = append(text, t.LangID.String()...) } else { buf := [maxCoreSize]byte{} text = buf[:t.genCoreBytes(buf[:])] } return text, nil } // UnmarshalText implements encoding.TextUnmarshaler. func (t *Tag) UnmarshalText(text []byte) error { tag, err := Parse(string(text)) *t = tag return err } // Variants returns the part of the tag holding all variants or the empty string // if there are no variants defined. func (t Tag) Variants() string { if t.pVariant == 0 { return "" } return t.str[t.pVariant:t.pExt] } // VariantOrPrivateUseTags returns variants or private use tags. func (t Tag) VariantOrPrivateUseTags() string { if t.pExt > 0 { return t.str[t.pVariant:t.pExt] } return t.str[t.pVariant:] } // HasString reports whether this tag defines more than just the raw // components. func (t Tag) HasString() bool { return t.str != "" } // Parent returns the CLDR parent of t. In CLDR, missing fields in data for a // specific language are substituted with fields from the parent language. // The parent for a language may change for newer versions of CLDR. func (t Tag) Parent() Tag { if t.str != "" { // Strip the variants and extensions. b, s, r := t.Raw() t = Tag{LangID: b, ScriptID: s, RegionID: r} if t.RegionID == 0 && t.ScriptID != 0 && t.LangID != 0 { base, _ := addTags(Tag{LangID: t.LangID}) if base.ScriptID == t.ScriptID { return Tag{LangID: t.LangID} } } return t } if t.LangID != 0 { if t.RegionID != 0 { maxScript := t.ScriptID if maxScript == 0 { max, _ := addTags(t) maxScript = max.ScriptID } for i := range parents { if Language(parents[i].lang) == t.LangID && Script(parents[i].maxScript) == maxScript { for _, r := range parents[i].fromRegion { if Region(r) == t.RegionID { return Tag{ LangID: t.LangID, ScriptID: Script(parents[i].script), RegionID: Region(parents[i].toRegion), } } } } } // Strip the script if it is the default one. base, _ := addTags(Tag{LangID: t.LangID}) if base.ScriptID != maxScript { return Tag{LangID: t.LangID, ScriptID: maxScript} } return Tag{LangID: t.LangID} } else if t.ScriptID != 0 { // The parent for an base-script pair with a non-default script is // "und" instead of the base language. base, _ := addTags(Tag{LangID: t.LangID}) if base.ScriptID != t.ScriptID { return und } return Tag{LangID: t.LangID} } } return und } // ParseExtension parses s as an extension and returns it on success. func ParseExtension(s string) (ext string, err error) { scan := makeScannerString(s) var end int if n := len(scan.token); n != 1 { return "", ErrSyntax } scan.toLower(0, len(scan.b)) end = parseExtension(&scan) if end != len(s) { return "", ErrSyntax } return string(scan.b), nil } // HasVariants reports whether t has variants. func (t Tag) HasVariants() bool { return uint16(t.pVariant) < t.pExt } // HasExtensions reports whether t has extensions. func (t Tag) HasExtensions() bool { return int(t.pExt) < len(t.str) } // Extension returns the extension of type x for tag t. It will return // false for ok if t does not have the requested extension. The returned // extension will be invalid in this case. func (t Tag) Extension(x byte) (ext string, ok bool) { for i := int(t.pExt); i < len(t.str)-1; { var ext string i, ext = getExtension(t.str, i) if ext[0] == x { return ext, true } } return "", false } // Extensions returns all extensions of t. func (t Tag) Extensions() []string { e := []string{} for i := int(t.pExt); i < len(t.str)-1; { var ext string i, ext = getExtension(t.str, i) e = append(e, ext) } return e } // TypeForKey returns the type associated with the given key, where key and type // are of the allowed values defined for the Unicode locale extension ('u') in // http://www.unicode.org/reports/tr35/#Unicode_Language_and_Locale_Identifiers. // TypeForKey will traverse the inheritance chain to get the correct value. func (t Tag) TypeForKey(key string) string { if start, end, _ := t.findTypeForKey(key); end != start { return t.str[start:end] } return "" } var ( errPrivateUse = errors.New("cannot set a key on a private use tag") errInvalidArguments = errors.New("invalid key or type") ) // SetTypeForKey returns a new Tag with the key set to type, where key and type // are of the allowed values defined for the Unicode locale extension ('u') in // http://www.unicode.org/reports/tr35/#Unicode_Language_and_Locale_Identifiers. // An empty value removes an existing pair with the same key. func (t Tag) SetTypeForKey(key, value string) (Tag, error) { if t.IsPrivateUse() { return t, errPrivateUse } if len(key) != 2 { return t, errInvalidArguments } // Remove the setting if value is "". if value == "" { start, end, _ := t.findTypeForKey(key) if start != end { // Remove key tag and leading '-'. start -= 4 // Remove a possible empty extension. if (end == len(t.str) || t.str[end+2] == '-') && t.str[start-2] == '-' { start -= 2 } if start == int(t.pVariant) && end == len(t.str) { t.str = "" t.pVariant, t.pExt = 0, 0 } else { t.str = fmt.Sprintf("%s%s", t.str[:start], t.str[end:]) } } return t, nil } if len(value) < 3 || len(value) > 8 { return t, errInvalidArguments } var ( buf [maxCoreSize + maxSimpleUExtensionSize]byte uStart int // start of the -u extension. ) // Generate the tag string if needed. if t.str == "" { uStart = t.genCoreBytes(buf[:]) buf[uStart] = '-' uStart++ } // Create new key-type pair and parse it to verify. b := buf[uStart:] copy(b, "u-") copy(b[2:], key) b[4] = '-' b = b[:5+copy(b[5:], value)] scan := makeScanner(b) if parseExtensions(&scan); scan.err != nil { return t, scan.err } // Assemble the replacement string. if t.str == "" { t.pVariant, t.pExt = byte(uStart-1), uint16(uStart-1) t.str = string(buf[:uStart+len(b)]) } else { s := t.str start, end, hasExt := t.findTypeForKey(key) if start == end { if hasExt { b = b[2:] } t.str = fmt.Sprintf("%s-%s%s", s[:start], b, s[end:]) } else { t.str = fmt.Sprintf("%s%s%s", s[:start], value, s[end:]) } } return t, nil } // findKeyAndType returns the start and end position for the type corresponding // to key or the point at which to insert the key-value pair if the type // wasn't found. The hasExt return value reports whether an -u extension was present. // Note: the extensions are typically very small and are likely to contain // only one key-type pair. func (t Tag) findTypeForKey(key string) (start, end int, hasExt bool) { p := int(t.pExt) if len(key) != 2 || p == len(t.str) || p == 0 { return p, p, false } s := t.str // Find the correct extension. for p++; s[p] != 'u'; p++ { if s[p] > 'u' { p-- return p, p, false } if p = nextExtension(s, p); p == len(s) { return len(s), len(s), false } } // Proceed to the hyphen following the extension name. p++ // curKey is the key currently being processed. curKey := "" // Iterate over keys until we get the end of a section. for { // p points to the hyphen preceding the current token. if p3 := p + 3; s[p3] == '-' { // Found a key. // Check whether we just processed the key that was requested. if curKey == key { return start, p, true } // Set to the next key and continue scanning type tokens. curKey = s[p+1 : p3] if curKey > key { return p, p, true } // Start of the type token sequence. start = p + 4 // A type is at least 3 characters long. p += 7 // 4 + 3 } else { // Attribute or type, which is at least 3 characters long. p += 4 } // p points past the third character of a type or attribute. max := p + 5 // maximum length of token plus hyphen. if len(s) < max { max = len(s) } for ; p < max && s[p] != '-'; p++ { } // Bail if we have exhausted all tokens or if the next token starts // a new extension. if p == len(s) || s[p+2] == '-' { if curKey == key { return start, p, true } return p, p, true } } } // ParseBase parses a 2- or 3-letter ISO 639 code. // It returns a ValueError if s is a well-formed but unknown language identifier // or another error if another error occurred. func ParseBase(s string) (Language, error) { if n := len(s); n < 2 || 3 < n { return 0, ErrSyntax } var buf [3]byte return getLangID(buf[:copy(buf[:], s)]) } // ParseScript parses a 4-letter ISO 15924 code. // It returns a ValueError if s is a well-formed but unknown script identifier // or another error if another error occurred. func ParseScript(s string) (Script, error) { if len(s) != 4 { return 0, ErrSyntax } var buf [4]byte return getScriptID(script, buf[:copy(buf[:], s)]) } // EncodeM49 returns the Region for the given UN M.49 code. // It returns an error if r is not a valid code. func EncodeM49(r int) (Region, error) { return getRegionM49(r) } // ParseRegion parses a 2- or 3-letter ISO 3166-1 or a UN M.49 code. // It returns a ValueError if s is a well-formed but unknown region identifier // or another error if another error occurred. func ParseRegion(s string) (Region, error) { if n := len(s); n < 2 || 3 < n { return 0, ErrSyntax } var buf [3]byte return getRegionID(buf[:copy(buf[:], s)]) } // IsCountry returns whether this region is a country or autonomous area. This // includes non-standard definitions from CLDR. func (r Region) IsCountry() bool { if r == 0 || r.IsGroup() || r.IsPrivateUse() && r != _XK { return false } return true } // IsGroup returns whether this region defines a collection of regions. This // includes non-standard definitions from CLDR. func (r Region) IsGroup() bool { if r == 0 { return false } return int(regionInclusion[r]) < len(regionContainment) } // Contains returns whether Region c is contained by Region r. It returns true // if c == r. func (r Region) Contains(c Region) bool { if r == c { return true } g := regionInclusion[r] if g >= nRegionGroups { return false } m := regionContainment[g] d := regionInclusion[c] b := regionInclusionBits[d] // A contained country may belong to multiple disjoint groups. Matching any // of these indicates containment. If the contained region is a group, it // must strictly be a subset. if d >= nRegionGroups { return b&m != 0 } return b&^m == 0 } var errNoTLD = errors.New("language: region is not a valid ccTLD") // TLD returns the country code top-level domain (ccTLD). UK is returned for GB. // In all other cases it returns either the region itself or an error. // // This method may return an error for a region for which there exists a // canonical form with a ccTLD. To get that ccTLD canonicalize r first. The // region will already be canonicalized it was obtained from a Tag that was // obtained using any of the default methods. func (r Region) TLD() (Region, error) { // See http://en.wikipedia.org/wiki/Country_code_top-level_domain for the // difference between ISO 3166-1 and IANA ccTLD. if r == _GB { r = _UK } if (r.typ() & ccTLD) == 0 { return 0, errNoTLD } return r, nil } // Canonicalize returns the region or a possible replacement if the region is // deprecated. It will not return a replacement for deprecated regions that // are split into multiple regions. func (r Region) Canonicalize() Region { if cr := normRegion(r); cr != 0 { return cr } return r } // Variant represents a registered variant of a language as defined by BCP 47. type Variant struct { ID uint8 str string } // ParseVariant parses and returns a Variant. An error is returned if s is not // a valid variant. func ParseVariant(s string) (Variant, error) { s = strings.ToLower(s) if id, ok := variantIndex[s]; ok { return Variant{id, s}, nil } return Variant{}, NewValueError([]byte(s)) } // String returns the string representation of the variant. func (v Variant) String() string { return v.str }