// 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. package language import ( "bytes" "flag" "fmt" "strings" "testing" "golang.org/x/text/internal/testtext" ) var verbose = flag.Bool("verbose", false, "set to true to print the internal tables of matchers") func TestAddLikelySubtags(t *testing.T) { tests := []struct{ in, out string }{ {"aa", "aa-Latn-ET"}, {"aa-Latn", "aa-Latn-ET"}, {"aa-Arab", "aa-Arab-ET"}, {"aa-Arab-ER", "aa-Arab-ER"}, {"kk", "kk-Cyrl-KZ"}, {"kk-CN", "kk-Arab-CN"}, {"cmn", "cmn"}, {"zh-AU", "zh-Hant-AU"}, {"zh-VN", "zh-Hant-VN"}, {"zh-SG", "zh-Hans-SG"}, {"zh-Hant", "zh-Hant-TW"}, {"zh-Hani", "zh-Hani-CN"}, {"und-Hani", "zh-Hani-CN"}, {"und", "en-Latn-US"}, {"und-GB", "en-Latn-GB"}, {"und-CW", "pap-Latn-CW"}, {"und-YT", "fr-Latn-YT"}, {"und-Arab", "ar-Arab-EG"}, {"und-AM", "hy-Armn-AM"}, {"und-002", "en-Latn-NG"}, {"und-Latn-002", "en-Latn-NG"}, {"en-Latn-002", "en-Latn-NG"}, {"en-002", "en-Latn-NG"}, {"en-001", "en-Latn-US"}, {"und-003", "en-Latn-US"}, {"und-GB", "en-Latn-GB"}, {"Latn-001", "en-Latn-US"}, {"en-001", "en-Latn-US"}, {"es-419", "es-Latn-419"}, {"he-145", "he-Hebr-IL"}, {"ky-145", "ky-Latn-TR"}, {"kk", "kk-Cyrl-KZ"}, // Don't specialize duplicate and ambiguous matches. {"kk-034", "kk-Arab-034"}, // Matches IR and AF. Both are Arab. {"ku-145", "ku-Latn-TR"}, // Matches IQ, TR, and LB, but kk -> TR. {"und-Arab-CC", "ms-Arab-CC"}, {"und-Arab-GB", "ks-Arab-GB"}, {"und-Hans-CC", "zh-Hans-CC"}, {"und-CC", "en-Latn-CC"}, {"sr", "sr-Cyrl-RS"}, {"sr-151", "sr-Latn-151"}, // Matches RO and RU. // We would like addLikelySubtags to generate the same results if the input // only changes by adding tags that would otherwise have been added // by the expansion. // In other words: // und-AA -> xx-Scrp-AA implies und-Scrp-AA -> xx-Scrp-AA // und-AA -> xx-Scrp-AA implies xx-AA -> xx-Scrp-AA // und-Scrp -> xx-Scrp-AA implies und-Scrp-AA -> xx-Scrp-AA // und-Scrp -> xx-Scrp-AA implies xx-Scrp -> xx-Scrp-AA // xx -> xx-Scrp-AA implies xx-Scrp -> xx-Scrp-AA // xx -> xx-Scrp-AA implies xx-AA -> xx-Scrp-AA // // The algorithm specified in // http://unicode.org/reports/tr35/tr35-9.html#Supplemental_Data, // Section C.10, does not handle the first case. For example, // the CLDR data contains an entry und-BJ -> fr-Latn-BJ, but not // there is no rule for und-Latn-BJ. According to spec, und-Latn-BJ // would expand to en-Latn-BJ, violating the aforementioned principle. // We deviate from the spec by letting und-Scrp-AA expand to xx-Scrp-AA // if a rule of the form und-AA -> xx-Scrp-AA is defined. // Note that as of version 23, CLDR has some explicitly specified // entries that do not conform to these rules. The implementation // will not correct these explicit inconsistencies. A later versions of CLDR // is supposed to fix this. {"und-Latn-BJ", "fr-Latn-BJ"}, {"und-Bugi-ID", "bug-Bugi-ID"}, // regions, scripts and languages without definitions {"und-Arab-AA", "ar-Arab-AA"}, {"und-Afak-RE", "fr-Afak-RE"}, {"und-Arab-GB", "ks-Arab-GB"}, {"abp-Arab-GB", "abp-Arab-GB"}, // script has preference over region {"und-Arab-NL", "ar-Arab-NL"}, {"zza", "zza-Latn-TR"}, // preserve variants and extensions {"de-1901", "de-Latn-DE-1901"}, {"de-x-abc", "de-Latn-DE-x-abc"}, {"de-1901-x-abc", "de-Latn-DE-1901-x-abc"}, {"x-abc", "x-abc"}, // TODO: is this the desired behavior? } for i, tt := range tests { in, _ := Parse(tt.in) out, _ := Parse(tt.out) in, _ = in.addLikelySubtags() if in.String() != out.String() { t.Errorf("%d: add(%s) was %s; want %s", i, tt.in, in, tt.out) } } } func TestMinimize(t *testing.T) { tests := []struct{ in, out string }{ {"aa", "aa"}, {"aa-Latn", "aa"}, {"aa-Latn-ET", "aa"}, {"aa-ET", "aa"}, {"aa-Arab", "aa-Arab"}, {"aa-Arab-ER", "aa-Arab-ER"}, {"aa-Arab-ET", "aa-Arab"}, {"und", "und"}, {"und-Latn", "und"}, {"und-Latn-US", "und"}, {"en-Latn-US", "en"}, {"cmn", "cmn"}, {"cmn-Hans", "cmn-Hans"}, {"cmn-Hant", "cmn-Hant"}, {"zh-AU", "zh-AU"}, {"zh-VN", "zh-VN"}, {"zh-SG", "zh-SG"}, {"zh-Hant", "zh-Hant"}, {"zh-Hant-TW", "zh-TW"}, {"zh-Hans", "zh"}, {"zh-Hani", "zh-Hani"}, {"und-Hans", "und-Hans"}, {"und-Hani", "und-Hani"}, {"und-CW", "und-CW"}, {"und-YT", "und-YT"}, {"und-Arab", "und-Arab"}, {"und-AM", "und-AM"}, {"und-Arab-CC", "und-Arab-CC"}, {"und-CC", "und-CC"}, {"und-Latn-BJ", "und-BJ"}, {"und-Bugi-ID", "und-Bugi"}, {"bug-Bugi-ID", "bug-Bugi"}, // regions, scripts and languages without definitions {"und-Arab-AA", "und-Arab-AA"}, // preserve variants and extensions {"de-Latn-1901", "de-1901"}, {"de-Latn-x-abc", "de-x-abc"}, {"de-DE-1901-x-abc", "de-1901-x-abc"}, {"x-abc", "x-abc"}, // TODO: is this the desired behavior? } for i, tt := range tests { in, _ := Parse(tt.in) out, _ := Parse(tt.out) min, _ := in.minimize() if min.String() != out.String() { t.Errorf("%d: min(%s) was %s; want %s", i, tt.in, min, tt.out) } max, _ := min.addLikelySubtags() if x, _ := in.addLikelySubtags(); x.String() != max.String() { t.Errorf("%d: max(min(%s)) = %s; want %s", i, tt.in, max, x) } } } func TestRegionDistance(t *testing.T) { tests := []struct { a, b string d int }{ {"NL", "NL", 0}, {"NL", "EU", 1}, {"EU", "NL", 1}, {"005", "005", 0}, {"NL", "BE", 2}, {"CO", "005", 1}, {"005", "CO", 1}, {"CO", "419", 2}, {"419", "CO", 2}, {"005", "419", 1}, {"419", "005", 1}, {"001", "013", 2}, {"013", "001", 2}, {"CO", "CW", 4}, {"CO", "PW", 6}, {"CO", "BV", 6}, {"ZZ", "QQ", 2}, } for i, tt := range tests { testtext.Run(t, tt.a+"/"+tt.b, func(t *testing.T) { ra, _ := getRegionID([]byte(tt.a)) rb, _ := getRegionID([]byte(tt.b)) if d := regionDistance(ra, rb); d != tt.d { t.Errorf("%d: d(%s, %s) = %v; want %v", i, tt.a, tt.b, d, tt.d) } }) } } func TestParentDistance(t *testing.T) { tests := []struct { parent string tag string d uint8 }{ {"en-001", "en-AU", 1}, {"pt-PT", "pt-AO", 1}, {"pt", "pt-AO", 2}, {"en-AU", "en-GB", 255}, {"en-NL", "en-AU", 255}, // Note that pt-BR and en-US are not automatically minimized. {"pt-BR", "pt-AO", 255}, {"en-US", "en-AU", 255}, } for _, tt := range tests { r := Raw.MustParse(tt.parent).region tag := Raw.MustParse(tt.tag) if d := parentDistance(r, tag); d != tt.d { t.Errorf("d(%s, %s) was %d; want %d", r, tag, d, tt.d) } } } // Implementation of String methods for various types for debugging purposes. func (m *matcher) String() string { w := &bytes.Buffer{} fmt.Fprintln(w, "Default:", m.default_) for tag, h := range m.index { fmt.Fprintf(w, " %s: %v\n", tag, h) } return w.String() } func (h *matchHeader) String() string { w := &bytes.Buffer{} fmt.Fprintf(w, "exact: ") for _, h := range h.exact { fmt.Fprintf(w, "%v, ", h) } fmt.Fprint(w, "; max: ") for _, h := range h.max { fmt.Fprintf(w, "%v, ", h) } return w.String() } func (t haveTag) String() string { return fmt.Sprintf("%v:%d:%v:%v-%v|%v", t.tag, t.index, t.conf, t.maxRegion, t.maxScript, t.altScript) } func parseSupported(list string) (out []Tag) { for _, s := range strings.Split(list, ",") { out = append(out, mk(strings.TrimSpace(s))) } return out } // The test set for TestBestMatch is defined in data_test.go. func TestBestMatch(t *testing.T) { for i, tt := range matchTests { supported := parseSupported(tt.supported) m := newMatcher(supported) if *verbose { fmt.Printf("%s:\n%v\n", tt.comment, m) } for _, tm := range tt.test { tag, _, conf := m.Match(parseSupported(tm.desired)...) if tag.String() != tm.match { t.Errorf("%d:%s: find %s in %q: have %s; want %s (%v)\n", i, tt.comment, tm.desired, tt.supported, tag, tm.match, conf) } } } } func TestBestMatchAlloc(t *testing.T) { m := NewMatcher(parseSupported("en sr nl")) // Go allocates when creating a list of tags from a single tag! list := []Tag{English} avg := testtext.AllocsPerRun(1, func() { m.Match(list...) }) if avg > 0 { t.Errorf("got %f; want 0", avg) } } var benchHave = []Tag{ mk("en"), mk("en-GB"), mk("za"), mk("zh-Hant"), mk("zh-Hans-CN"), mk("zh"), mk("zh-HK"), mk("ar-MK"), mk("en-CA"), mk("fr-CA"), mk("fr-US"), mk("fr-CH"), mk("fr"), mk("lt"), mk("lv"), mk("iw"), mk("iw-NL"), mk("he"), mk("he-IT"), mk("tlh"), mk("ja"), mk("ja-Jpan"), mk("ja-Jpan-JP"), mk("de"), mk("de-CH"), mk("de-AT"), mk("de-DE"), mk("sr"), mk("sr-Latn"), mk("sr-Cyrl"), mk("sr-ME"), } var benchWant = [][]Tag{ []Tag{ mk("en"), }, []Tag{ mk("en-AU"), mk("de-HK"), mk("nl"), mk("fy"), mk("lv"), }, []Tag{ mk("en-AU"), mk("de-HK"), mk("nl"), mk("fy"), }, []Tag{ mk("ja-Hant"), mk("da-HK"), mk("nl"), mk("zh-TW"), }, []Tag{ mk("ja-Hant"), mk("da-HK"), mk("nl"), mk("hr"), }, } func BenchmarkMatch(b *testing.B) { m := newMatcher(benchHave) for i := 0; i < b.N; i++ { for _, want := range benchWant { m.getBest(want...) } } } func BenchmarkMatchExact(b *testing.B) { want := mk("en") m := newMatcher(benchHave) for i := 0; i < b.N; i++ { m.getBest(want) } } func BenchmarkMatchAltLanguagePresent(b *testing.B) { want := mk("hr") m := newMatcher(benchHave) for i := 0; i < b.N; i++ { m.getBest(want) } } func BenchmarkMatchAltLanguageNotPresent(b *testing.B) { want := mk("nn") m := newMatcher(benchHave) for i := 0; i < b.N; i++ { m.getBest(want) } } func BenchmarkMatchAltScriptPresent(b *testing.B) { want := mk("zh-Hant-CN") m := newMatcher(benchHave) for i := 0; i < b.N; i++ { m.getBest(want) } } func BenchmarkMatchAltScriptNotPresent(b *testing.B) { want := mk("fr-Cyrl") m := newMatcher(benchHave) for i := 0; i < b.N; i++ { m.getBest(want) } } func BenchmarkMatchLimitedExact(b *testing.B) { want := []Tag{mk("he-NL"), mk("iw-NL")} m := newMatcher(benchHave) for i := 0; i < b.N; i++ { m.getBest(want...) } }