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// Copyright 2011 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package norm
import (
"bufio"
"bytes"
"fmt"
"regexp"
"runtime"
"strconv"
"strings"
"sync"
"testing"
"time"
"unicode/utf8"
"golang.org/x/text/internal/gen"
"golang.org/x/text/internal/testtext"
)
var once sync.Once
func skipShort(t *testing.T) {
testtext.SkipIfNotLong(t)
once.Do(func() { loadTestData(t) })
}
// This regression test runs the test set in NormalizationTest.txt
// (taken from https://www.unicode.org/Public/<unicode.Version>/ucd/).
//
// NormalizationTest.txt has form:
// @Part0 # Specific cases
// #
// 1E0A;1E0A;0044 0307;1E0A;0044 0307; # (Ḋ; Ḋ; D◌̇; Ḋ; D◌̇; ) LATIN CAPITAL LETTER D WITH DOT ABOVE
// 1E0C;1E0C;0044 0323;1E0C;0044 0323; # (Ḍ; Ḍ; D◌̣; Ḍ; D◌̣; ) LATIN CAPITAL LETTER D WITH DOT BELOW
//
// Each test has 5 columns (c1, c2, c3, c4, c5), where
// (c1, c2, c3, c4, c5) == (c1, NFC(c1), NFD(c1), NFKC(c1), NFKD(c1))
//
// CONFORMANCE:
// 1. The following invariants must be true for all conformant implementations
//
// NFC
// c2 == NFC(c1) == NFC(c2) == NFC(c3)
// c4 == NFC(c4) == NFC(c5)
//
// NFD
// c3 == NFD(c1) == NFD(c2) == NFD(c3)
// c5 == NFD(c4) == NFD(c5)
//
// NFKC
// c4 == NFKC(c1) == NFKC(c2) == NFKC(c3) == NFKC(c4) == NFKC(c5)
//
// NFKD
// c5 == NFKD(c1) == NFKD(c2) == NFKD(c3) == NFKD(c4) == NFKD(c5)
//
// 2. For every code point X assigned in this version of Unicode that is not
// specifically listed in Part 1, the following invariants must be true
// for all conformant implementations:
//
// X == NFC(X) == NFD(X) == NFKC(X) == NFKD(X)
//
// Column types.
const (
cRaw = iota
cNFC
cNFD
cNFKC
cNFKD
cMaxColumns
)
// Holds data from NormalizationTest.txt
var part []Part
type Part struct {
name string
number int
tests []Test
}
type Test struct {
name string
partnr int
number int
r rune // used for character by character test
cols [cMaxColumns]string // Each has 5 entries, see below.
}
func (t Test) Name() string {
if t.number < 0 {
return part[t.partnr].name
}
return fmt.Sprintf("%s:%d", part[t.partnr].name, t.number)
}
var partRe = regexp.MustCompile(`@Part(\d) # (.*)$`)
var testRe = regexp.MustCompile(`^` + strings.Repeat(`([\dA-F ]+);`, 5) + ` # (.*)$`)
var counter int
// Load the data form NormalizationTest.txt
func loadTestData(t *testing.T) {
f := gen.OpenUCDFile("NormalizationTest.txt")
defer f.Close()
scanner := bufio.NewScanner(f)
for scanner.Scan() {
line := scanner.Text()
if len(line) == 0 || line[0] == '#' {
continue
}
m := partRe.FindStringSubmatch(line)
if m != nil {
if len(m) < 3 {
t.Fatal("Failed to parse Part: ", line)
}
i, err := strconv.Atoi(m[1])
if err != nil {
t.Fatal(err)
}
name := m[2]
part = append(part, Part{name: name[:len(name)-1], number: i})
continue
}
m = testRe.FindStringSubmatch(line)
if m == nil || len(m) < 7 {
t.Fatalf(`Failed to parse: "%s" result: %#v`, line, m)
}
test := Test{name: m[6], partnr: len(part) - 1, number: counter}
counter++
for j := 1; j < len(m)-1; j++ {
for _, split := range strings.Split(m[j], " ") {
r, err := strconv.ParseUint(split, 16, 64)
if err != nil {
t.Fatal(err)
}
if test.r == 0 {
// save for CharacterByCharacterTests
test.r = rune(r)
}
var buf [utf8.UTFMax]byte
sz := utf8.EncodeRune(buf[:], rune(r))
test.cols[j-1] += string(buf[:sz])
}
}
part := &part[len(part)-1]
part.tests = append(part.tests, test)
}
if scanner.Err() != nil {
t.Fatal(scanner.Err())
}
}
func cmpResult(t *testing.T, tc *Test, name string, f Form, gold, test, result string) {
if gold != result {
t.Errorf("%s:%s: %s(%+q)=%+q; want %+q: %s",
tc.Name(), name, fstr[f], test, result, gold, tc.name)
}
}
func cmpIsNormal(t *testing.T, tc *Test, name string, f Form, test string, result, want bool) {
if result != want {
t.Errorf("%s:%s: %s(%+q)=%v; want %v", tc.Name(), name, fstr[f], test, result, want)
}
}
func doTest(t *testing.T, tc *Test, f Form, gold, test string) {
testb := []byte(test)
result := f.Bytes(testb)
cmpResult(t, tc, "Bytes", f, gold, test, string(result))
sresult := f.String(test)
cmpResult(t, tc, "String", f, gold, test, sresult)
acc := []byte{}
i := Iter{}
i.InitString(f, test)
for !i.Done() {
acc = append(acc, i.Next()...)
}
cmpResult(t, tc, "Iter.Next", f, gold, test, string(acc))
buf := make([]byte, 128)
acc = nil
for p := 0; p < len(testb); {
nDst, nSrc, _ := f.Transform(buf, testb[p:], true)
acc = append(acc, buf[:nDst]...)
p += nSrc
}
cmpResult(t, tc, "Transform", f, gold, test, string(acc))
for i := range test {
out := f.Append(f.Bytes([]byte(test[:i])), []byte(test[i:])...)
cmpResult(t, tc, fmt.Sprintf(":Append:%d", i), f, gold, test, string(out))
}
cmpIsNormal(t, tc, "IsNormal", f, test, f.IsNormal([]byte(test)), test == gold)
cmpIsNormal(t, tc, "IsNormalString", f, test, f.IsNormalString(test), test == gold)
}
func doConformanceTests(t *testing.T, tc *Test, partn int) {
for i := 0; i <= 2; i++ {
doTest(t, tc, NFC, tc.cols[1], tc.cols[i])
doTest(t, tc, NFD, tc.cols[2], tc.cols[i])
doTest(t, tc, NFKC, tc.cols[3], tc.cols[i])
doTest(t, tc, NFKD, tc.cols[4], tc.cols[i])
}
for i := 3; i <= 4; i++ {
doTest(t, tc, NFC, tc.cols[3], tc.cols[i])
doTest(t, tc, NFD, tc.cols[4], tc.cols[i])
doTest(t, tc, NFKC, tc.cols[3], tc.cols[i])
doTest(t, tc, NFKD, tc.cols[4], tc.cols[i])
}
}
func TestCharacterByCharacter(t *testing.T) {
skipShort(t)
tests := part[1].tests
var last rune = 0
for i := 0; i <= len(tests); i++ { // last one is special case
var r rune
if i == len(tests) {
r = 0x2FA1E // Don't have to go to 0x10FFFF
} else {
r = tests[i].r
}
for last++; last < r; last++ {
// Check all characters that were not explicitly listed in the test.
tc := &Test{partnr: 1, number: -1}
char := string(last)
doTest(t, tc, NFC, char, char)
doTest(t, tc, NFD, char, char)
doTest(t, tc, NFKC, char, char)
doTest(t, tc, NFKD, char, char)
}
if i < len(tests) {
doConformanceTests(t, &tests[i], 1)
}
}
}
func TestStandardTests(t *testing.T) {
skipShort(t)
for _, j := range []int{0, 2, 3} {
for _, test := range part[j].tests {
doConformanceTests(t, &test, j)
}
}
}
// TestPerformance verifies that normalization is O(n). If any of the
// code does not properly check for maxCombiningChars, normalization
// may exhibit O(n**2) behavior.
func TestPerformance(t *testing.T) {
skipShort(t)
runtime.GOMAXPROCS(2)
success := make(chan bool, 1)
go func() {
buf := bytes.Repeat([]byte("\u035D"), 1024*1024)
buf = append(buf, "\u035B"...)
NFC.Append(nil, buf...)
success <- true
}()
timeout := time.After(1 * time.Second)
select {
case <-success:
// test completed before the timeout
case <-timeout:
t.Errorf(`unexpectedly long time to complete PerformanceTest`)
}
}