// Copyright 2009 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 bytes_test import ( . "bytes" "fmt" "internal/testenv" "math" "math/rand" "reflect" "strings" "testing" "unicode" "unicode/utf8" "unsafe" ) func eq(a, b []string) bool { if len(a) != len(b) { return false } for i := 0; i < len(a); i++ { if a[i] != b[i] { return false } } return true } func sliceOfString(s [][]byte) []string { result := make([]string, len(s)) for i, v := range s { result[i] = string(v) } return result } // For ease of reading, the test cases use strings that are converted to byte // slices before invoking the functions. var abcd = "abcd" var faces = "☺☻☹" var commas = "1,2,3,4" var dots = "1....2....3....4" type BinOpTest struct { a string b string i int } func TestEqual(t *testing.T) { // Run the tests and check for allocation at the same time. allocs := testing.AllocsPerRun(10, func() { for _, tt := range compareTests { eql := Equal(tt.a, tt.b) if eql != (tt.i == 0) { t.Errorf(`Equal(%q, %q) = %v`, tt.a, tt.b, eql) } } }) if allocs > 0 { t.Errorf("Equal allocated %v times", allocs) } } func TestEqualExhaustive(t *testing.T) { var size = 128 if testing.Short() { size = 32 } a := make([]byte, size) b := make([]byte, size) b_init := make([]byte, size) // randomish but deterministic data for i := 0; i < size; i++ { a[i] = byte(17 * i) b_init[i] = byte(23*i + 100) } for len := 0; len <= size; len++ { for x := 0; x <= size-len; x++ { for y := 0; y <= size-len; y++ { copy(b, b_init) copy(b[y:y+len], a[x:x+len]) if !Equal(a[x:x+len], b[y:y+len]) || !Equal(b[y:y+len], a[x:x+len]) { t.Errorf("Equal(%d, %d, %d) = false", len, x, y) } } } } } // make sure Equal returns false for minimally different strings. The data // is all zeros except for a single one in one location. func TestNotEqual(t *testing.T) { var size = 128 if testing.Short() { size = 32 } a := make([]byte, size) b := make([]byte, size) for len := 0; len <= size; len++ { for x := 0; x <= size-len; x++ { for y := 0; y <= size-len; y++ { for diffpos := x; diffpos < x+len; diffpos++ { a[diffpos] = 1 if Equal(a[x:x+len], b[y:y+len]) || Equal(b[y:y+len], a[x:x+len]) { t.Errorf("NotEqual(%d, %d, %d, %d) = true", len, x, y, diffpos) } a[diffpos] = 0 } } } } } var indexTests = []BinOpTest{ {"", "", 0}, {"", "a", -1}, {"", "foo", -1}, {"fo", "foo", -1}, {"foo", "baz", -1}, {"foo", "foo", 0}, {"oofofoofooo", "f", 2}, {"oofofoofooo", "foo", 4}, {"barfoobarfoo", "foo", 3}, {"foo", "", 0}, {"foo", "o", 1}, {"abcABCabc", "A", 3}, // cases with one byte strings - test IndexByte and special case in Index() {"", "a", -1}, {"x", "a", -1}, {"x", "x", 0}, {"abc", "a", 0}, {"abc", "b", 1}, {"abc", "c", 2}, {"abc", "x", -1}, {"barfoobarfooyyyzzzyyyzzzyyyzzzyyyxxxzzzyyy", "x", 33}, {"fofofofooofoboo", "oo", 7}, {"fofofofofofoboo", "ob", 11}, {"fofofofofofoboo", "boo", 12}, {"fofofofofofoboo", "oboo", 11}, {"fofofofofoooboo", "fooo", 8}, {"fofofofofofoboo", "foboo", 10}, {"fofofofofofoboo", "fofob", 8}, {"fofofofofofofoffofoobarfoo", "foffof", 12}, {"fofofofofoofofoffofoobarfoo", "foffof", 13}, {"fofofofofofofoffofoobarfoo", "foffofo", 12}, {"fofofofofoofofoffofoobarfoo", "foffofo", 13}, {"fofofofofoofofoffofoobarfoo", "foffofoo", 13}, {"fofofofofofofoffofoobarfoo", "foffofoo", 12}, {"fofofofofoofofoffofoobarfoo", "foffofoob", 13}, {"fofofofofofofoffofoobarfoo", "foffofoob", 12}, {"fofofofofoofofoffofoobarfoo", "foffofooba", 13}, {"fofofofofofofoffofoobarfoo", "foffofooba", 12}, {"fofofofofoofofoffofoobarfoo", "foffofoobar", 13}, {"fofofofofofofoffofoobarfoo", "foffofoobar", 12}, {"fofofofofoofofoffofoobarfoo", "foffofoobarf", 13}, {"fofofofofofofoffofoobarfoo", "foffofoobarf", 12}, {"fofofofofoofofoffofoobarfoo", "foffofoobarfo", 13}, {"fofofofofofofoffofoobarfoo", "foffofoobarfo", 12}, {"fofofofofoofofoffofoobarfoo", "foffofoobarfoo", 13}, {"fofofofofofofoffofoobarfoo", "foffofoobarfoo", 12}, {"fofofofofoofofoffofoobarfoo", "ofoffofoobarfoo", 12}, {"fofofofofofofoffofoobarfoo", "ofoffofoobarfoo", 11}, {"fofofofofoofofoffofoobarfoo", "fofoffofoobarfoo", 11}, {"fofofofofofofoffofoobarfoo", "fofoffofoobarfoo", 10}, {"fofofofofoofofoffofoobarfoo", "foobars", -1}, {"foofyfoobarfoobar", "y", 4}, {"oooooooooooooooooooooo", "r", -1}, {"oxoxoxoxoxoxoxoxoxoxoxoy", "oy", 22}, {"oxoxoxoxoxoxoxoxoxoxoxox", "oy", -1}, // test fallback to Rabin-Karp. {"000000000000000000000000000000000000000000000000000000000000000000000001", "0000000000000000000000000000000000000000000000000000000000000000001", 5}, } var lastIndexTests = []BinOpTest{ {"", "", 0}, {"", "a", -1}, {"", "foo", -1}, {"fo", "foo", -1}, {"foo", "foo", 0}, {"foo", "f", 0}, {"oofofoofooo", "f", 7}, {"oofofoofooo", "foo", 7}, {"barfoobarfoo", "foo", 9}, {"foo", "", 3}, {"foo", "o", 2}, {"abcABCabc", "A", 3}, {"abcABCabc", "a", 6}, } var indexAnyTests = []BinOpTest{ {"", "", -1}, {"", "a", -1}, {"", "abc", -1}, {"a", "", -1}, {"a", "a", 0}, {"\x80", "\xffb", 0}, {"aaa", "a", 0}, {"abc", "xyz", -1}, {"abc", "xcz", 2}, {"ab☺c", "x☺yz", 2}, {"a☺b☻c☹d", "cx", len("a☺b☻")}, {"a☺b☻c☹d", "uvw☻xyz", len("a☺b")}, {"aRegExp*", ".(|)*+?^$[]", 7}, {dots + dots + dots, " ", -1}, {"012abcba210", "\xffb", 4}, {"012\x80bcb\x80210", "\xffb", 3}, {"0123456\xcf\x80abc", "\xcfb\x80", 10}, } var lastIndexAnyTests = []BinOpTest{ {"", "", -1}, {"", "a", -1}, {"", "abc", -1}, {"a", "", -1}, {"a", "a", 0}, {"\x80", "\xffb", 0}, {"aaa", "a", 2}, {"abc", "xyz", -1}, {"abc", "ab", 1}, {"ab☺c", "x☺yz", 2}, {"a☺b☻c☹d", "cx", len("a☺b☻")}, {"a☺b☻c☹d", "uvw☻xyz", len("a☺b")}, {"a.RegExp*", ".(|)*+?^$[]", 8}, {dots + dots + dots, " ", -1}, {"012abcba210", "\xffb", 6}, {"012\x80bcb\x80210", "\xffb", 7}, {"0123456\xcf\x80abc", "\xcfb\x80", 10}, } // Execute f on each test case. funcName should be the name of f; it's used // in failure reports. func runIndexTests(t *testing.T, f func(s, sep []byte) int, funcName string, testCases []BinOpTest) { for _, test := range testCases { a := []byte(test.a) b := []byte(test.b) actual := f(a, b) if actual != test.i { t.Errorf("%s(%q,%q) = %v; want %v", funcName, a, b, actual, test.i) } } var allocTests = []struct { a []byte b []byte i int }{ // case for function Index. {[]byte("000000000000000000000000000000000000000000000000000000000000000000000001"), []byte("0000000000000000000000000000000000000000000000000000000000000000001"), 5}, // case for function LastIndex. {[]byte("000000000000000000000000000000000000000000000000000000000000000010000"), []byte("00000000000000000000000000000000000000000000000000000000000001"), 3}, } allocs := testing.AllocsPerRun(100, func() { if i := Index(allocTests[1].a, allocTests[1].b); i != allocTests[1].i { t.Errorf("Index([]byte(%q), []byte(%q)) = %v; want %v", allocTests[1].a, allocTests[1].b, i, allocTests[1].i) } if i := LastIndex(allocTests[0].a, allocTests[0].b); i != allocTests[0].i { t.Errorf("LastIndex([]byte(%q), []byte(%q)) = %v; want %v", allocTests[0].a, allocTests[0].b, i, allocTests[0].i) } }) if allocs != 0 { t.Errorf("expected no allocations, got %f", allocs) } } func runIndexAnyTests(t *testing.T, f func(s []byte, chars string) int, funcName string, testCases []BinOpTest) { for _, test := range testCases { a := []byte(test.a) actual := f(a, test.b) if actual != test.i { t.Errorf("%s(%q,%q) = %v; want %v", funcName, a, test.b, actual, test.i) } } } func TestIndex(t *testing.T) { runIndexTests(t, Index, "Index", indexTests) } func TestLastIndex(t *testing.T) { runIndexTests(t, LastIndex, "LastIndex", lastIndexTests) } func TestIndexAny(t *testing.T) { runIndexAnyTests(t, IndexAny, "IndexAny", indexAnyTests) } func TestLastIndexAny(t *testing.T) { runIndexAnyTests(t, LastIndexAny, "LastIndexAny", lastIndexAnyTests) } func TestIndexByte(t *testing.T) { for _, tt := range indexTests { if len(tt.b) != 1 { continue } a := []byte(tt.a) b := tt.b[0] pos := IndexByte(a, b) if pos != tt.i { t.Errorf(`IndexByte(%q, '%c') = %v`, tt.a, b, pos) } posp := IndexBytePortable(a, b) if posp != tt.i { t.Errorf(`indexBytePortable(%q, '%c') = %v`, tt.a, b, posp) } } } func TestLastIndexByte(t *testing.T) { testCases := []BinOpTest{ {"", "q", -1}, {"abcdef", "q", -1}, {"abcdefabcdef", "a", len("abcdef")}, // something in the middle {"abcdefabcdef", "f", len("abcdefabcde")}, // last byte {"zabcdefabcdef", "z", 0}, // first byte {"a☺b☻c☹d", "b", len("a☺")}, // non-ascii } for _, test := range testCases { actual := LastIndexByte([]byte(test.a), test.b[0]) if actual != test.i { t.Errorf("LastIndexByte(%q,%c) = %v; want %v", test.a, test.b[0], actual, test.i) } } } // test a larger buffer with different sizes and alignments func TestIndexByteBig(t *testing.T) { var n = 1024 if testing.Short() { n = 128 } b := make([]byte, n) for i := 0; i < n; i++ { // different start alignments b1 := b[i:] for j := 0; j < len(b1); j++ { b1[j] = 'x' pos := IndexByte(b1, 'x') if pos != j { t.Errorf("IndexByte(%q, 'x') = %v", b1, pos) } b1[j] = 0 pos = IndexByte(b1, 'x') if pos != -1 { t.Errorf("IndexByte(%q, 'x') = %v", b1, pos) } } // different end alignments b1 = b[:i] for j := 0; j < len(b1); j++ { b1[j] = 'x' pos := IndexByte(b1, 'x') if pos != j { t.Errorf("IndexByte(%q, 'x') = %v", b1, pos) } b1[j] = 0 pos = IndexByte(b1, 'x') if pos != -1 { t.Errorf("IndexByte(%q, 'x') = %v", b1, pos) } } // different start and end alignments b1 = b[i/2 : n-(i+1)/2] for j := 0; j < len(b1); j++ { b1[j] = 'x' pos := IndexByte(b1, 'x') if pos != j { t.Errorf("IndexByte(%q, 'x') = %v", b1, pos) } b1[j] = 0 pos = IndexByte(b1, 'x') if pos != -1 { t.Errorf("IndexByte(%q, 'x') = %v", b1, pos) } } } } // test a small index across all page offsets func TestIndexByteSmall(t *testing.T) { b := make([]byte, 5015) // bigger than a page // Make sure we find the correct byte even when straddling a page. for i := 0; i <= len(b)-15; i++ { for j := 0; j < 15; j++ { b[i+j] = byte(100 + j) } for j := 0; j < 15; j++ { p := IndexByte(b[i:i+15], byte(100+j)) if p != j { t.Errorf("IndexByte(%q, %d) = %d", b[i:i+15], 100+j, p) } } for j := 0; j < 15; j++ { b[i+j] = 0 } } // Make sure matches outside the slice never trigger. for i := 0; i <= len(b)-15; i++ { for j := 0; j < 15; j++ { b[i+j] = 1 } for j := 0; j < 15; j++ { p := IndexByte(b[i:i+15], byte(0)) if p != -1 { t.Errorf("IndexByte(%q, %d) = %d", b[i:i+15], 0, p) } } for j := 0; j < 15; j++ { b[i+j] = 0 } } } func TestIndexRune(t *testing.T) { tests := []struct { in string rune rune want int }{ {"", 'a', -1}, {"", '☺', -1}, {"foo", '☹', -1}, {"foo", 'o', 1}, {"foo☺bar", '☺', 3}, {"foo☺☻☹bar", '☹', 9}, {"a A x", 'A', 2}, {"some_text=some_value", '=', 9}, {"☺a", 'a', 3}, {"a☻☺b", '☺', 4}, // RuneError should match any invalid UTF-8 byte sequence. {"�", '�', 0}, {"\xff", '�', 0}, {"☻x�", '�', len("☻x")}, {"☻x\xe2\x98", '�', len("☻x")}, {"☻x\xe2\x98�", '�', len("☻x")}, {"☻x\xe2\x98x", '�', len("☻x")}, // Invalid rune values should never match. {"a☺b☻c☹d\xe2\x98�\xff�\xed\xa0\x80", -1, -1}, {"a☺b☻c☹d\xe2\x98�\xff�\xed\xa0\x80", 0xD800, -1}, // Surrogate pair {"a☺b☻c☹d\xe2\x98�\xff�\xed\xa0\x80", utf8.MaxRune + 1, -1}, } for _, tt := range tests { if got := IndexRune([]byte(tt.in), tt.rune); got != tt.want { t.Errorf("IndexRune(%q, %d) = %v; want %v", tt.in, tt.rune, got, tt.want) } } haystack := []byte("test世界") allocs := testing.AllocsPerRun(1000, func() { if i := IndexRune(haystack, 's'); i != 2 { t.Fatalf("'s' at %d; want 2", i) } if i := IndexRune(haystack, '世'); i != 4 { t.Fatalf("'世' at %d; want 4", i) } }) if allocs != 0 { t.Errorf("expected no allocations, got %f", allocs) } } // test count of a single byte across page offsets func TestCountByte(t *testing.T) { b := make([]byte, 5015) // bigger than a page windows := []int{1, 2, 3, 4, 15, 16, 17, 31, 32, 33, 63, 64, 65, 128} testCountWindow := func(i, window int) { for j := 0; j < window; j++ { b[i+j] = byte(100) p := Count(b[i:i+window], []byte{100}) if p != j+1 { t.Errorf("TestCountByte.Count(%q, 100) = %d", b[i:i+window], p) } } } maxWnd := windows[len(windows)-1] for i := 0; i <= 2*maxWnd; i++ { for _, window := range windows { if window > len(b[i:]) { window = len(b[i:]) } testCountWindow(i, window) for j := 0; j < window; j++ { b[i+j] = byte(0) } } } for i := 4096 - (maxWnd + 1); i < len(b); i++ { for _, window := range windows { if window > len(b[i:]) { window = len(b[i:]) } testCountWindow(i, window) for j := 0; j < window; j++ { b[i+j] = byte(0) } } } } // Make sure we don't count bytes outside our window func TestCountByteNoMatch(t *testing.T) { b := make([]byte, 5015) windows := []int{1, 2, 3, 4, 15, 16, 17, 31, 32, 33, 63, 64, 65, 128} for i := 0; i <= len(b); i++ { for _, window := range windows { if window > len(b[i:]) { window = len(b[i:]) } // Fill the window with non-match for j := 0; j < window; j++ { b[i+j] = byte(100) } // Try to find something that doesn't exist p := Count(b[i:i+window], []byte{0}) if p != 0 { t.Errorf("TestCountByteNoMatch(%q, 0) = %d", b[i:i+window], p) } for j := 0; j < window; j++ { b[i+j] = byte(0) } } } } var bmbuf []byte func valName(x int) string { if s := x >> 20; s<<20 == x { return fmt.Sprintf("%dM", s) } if s := x >> 10; s<<10 == x { return fmt.Sprintf("%dK", s) } return fmt.Sprint(x) } func benchBytes(b *testing.B, sizes []int, f func(b *testing.B, n int)) { for _, n := range sizes { if isRaceBuilder && n > 4<<10 { continue } b.Run(valName(n), func(b *testing.B) { if len(bmbuf) < n { bmbuf = make([]byte, n) } b.SetBytes(int64(n)) f(b, n) }) } } var indexSizes = []int{10, 32, 4 << 10, 4 << 20, 64 << 20} var isRaceBuilder = strings.HasSuffix(testenv.Builder(), "-race") func BenchmarkIndexByte(b *testing.B) { benchBytes(b, indexSizes, bmIndexByte(IndexByte)) } func BenchmarkIndexBytePortable(b *testing.B) { benchBytes(b, indexSizes, bmIndexByte(IndexBytePortable)) } func bmIndexByte(index func([]byte, byte) int) func(b *testing.B, n int) { return func(b *testing.B, n int) { buf := bmbuf[0:n] buf[n-1] = 'x' for i := 0; i < b.N; i++ { j := index(buf, 'x') if j != n-1 { b.Fatal("bad index", j) } } buf[n-1] = '\x00' } } func BenchmarkIndexRune(b *testing.B) { benchBytes(b, indexSizes, bmIndexRune(IndexRune)) } func BenchmarkIndexRuneASCII(b *testing.B) { benchBytes(b, indexSizes, bmIndexRuneASCII(IndexRune)) } func bmIndexRuneASCII(index func([]byte, rune) int) func(b *testing.B, n int) { return func(b *testing.B, n int) { buf := bmbuf[0:n] buf[n-1] = 'x' for i := 0; i < b.N; i++ { j := index(buf, 'x') if j != n-1 { b.Fatal("bad index", j) } } buf[n-1] = '\x00' } } func bmIndexRune(index func([]byte, rune) int) func(b *testing.B, n int) { return func(b *testing.B, n int) { buf := bmbuf[0:n] utf8.EncodeRune(buf[n-3:], '世') for i := 0; i < b.N; i++ { j := index(buf, '世') if j != n-3 { b.Fatal("bad index", j) } } buf[n-3] = '\x00' buf[n-2] = '\x00' buf[n-1] = '\x00' } } func BenchmarkEqual(b *testing.B) { b.Run("0", func(b *testing.B) { var buf [4]byte buf1 := buf[0:0] buf2 := buf[1:1] for i := 0; i < b.N; i++ { eq := Equal(buf1, buf2) if !eq { b.Fatal("bad equal") } } }) sizes := []int{1, 6, 9, 15, 16, 20, 32, 4 << 10, 4 << 20, 64 << 20} b.Run("same", func(b *testing.B) { benchBytes(b, sizes, bmEqual(func(a, b []byte) bool { return Equal(a, a) })) }) benchBytes(b, sizes, bmEqual(Equal)) } func bmEqual(equal func([]byte, []byte) bool) func(b *testing.B, n int) { return func(b *testing.B, n int) { if len(bmbuf) < 2*n { bmbuf = make([]byte, 2*n) } buf1 := bmbuf[0:n] buf2 := bmbuf[n : 2*n] buf1[n-1] = 'x' buf2[n-1] = 'x' for i := 0; i < b.N; i++ { eq := equal(buf1, buf2) if !eq { b.Fatal("bad equal") } } buf1[n-1] = '\x00' buf2[n-1] = '\x00' } } func BenchmarkEqualBothUnaligned(b *testing.B) { sizes := []int{64, 4 << 10} if !isRaceBuilder { sizes = append(sizes, []int{4 << 20, 64 << 20}...) } maxSize := 2 * (sizes[len(sizes)-1] + 8) if len(bmbuf) < maxSize { bmbuf = make([]byte, maxSize) } for _, n := range sizes { for _, off := range []int{0, 1, 4, 7} { buf1 := bmbuf[off : off+n] buf2Start := (len(bmbuf) / 2) + off buf2 := bmbuf[buf2Start : buf2Start+n] buf1[n-1] = 'x' buf2[n-1] = 'x' b.Run(fmt.Sprint(n, off), func(b *testing.B) { b.SetBytes(int64(n)) for i := 0; i < b.N; i++ { eq := Equal(buf1, buf2) if !eq { b.Fatal("bad equal") } } }) buf1[n-1] = '\x00' buf2[n-1] = '\x00' } } } func BenchmarkIndex(b *testing.B) { benchBytes(b, indexSizes, func(b *testing.B, n int) { buf := bmbuf[0:n] buf[n-1] = 'x' for i := 0; i < b.N; i++ { j := Index(buf, buf[n-7:]) if j != n-7 { b.Fatal("bad index", j) } } buf[n-1] = '\x00' }) } func BenchmarkIndexEasy(b *testing.B) { benchBytes(b, indexSizes, func(b *testing.B, n int) { buf := bmbuf[0:n] buf[n-1] = 'x' buf[n-7] = 'x' for i := 0; i < b.N; i++ { j := Index(buf, buf[n-7:]) if j != n-7 { b.Fatal("bad index", j) } } buf[n-1] = '\x00' buf[n-7] = '\x00' }) } func BenchmarkCount(b *testing.B) { benchBytes(b, indexSizes, func(b *testing.B, n int) { buf := bmbuf[0:n] buf[n-1] = 'x' for i := 0; i < b.N; i++ { j := Count(buf, buf[n-7:]) if j != 1 { b.Fatal("bad count", j) } } buf[n-1] = '\x00' }) } func BenchmarkCountEasy(b *testing.B) { benchBytes(b, indexSizes, func(b *testing.B, n int) { buf := bmbuf[0:n] buf[n-1] = 'x' buf[n-7] = 'x' for i := 0; i < b.N; i++ { j := Count(buf, buf[n-7:]) if j != 1 { b.Fatal("bad count", j) } } buf[n-1] = '\x00' buf[n-7] = '\x00' }) } func BenchmarkCountSingle(b *testing.B) { benchBytes(b, indexSizes, func(b *testing.B, n int) { buf := bmbuf[0:n] step := 8 for i := 0; i < len(buf); i += step { buf[i] = 1 } expect := (len(buf) + (step - 1)) / step for i := 0; i < b.N; i++ { j := Count(buf, []byte{1}) if j != expect { b.Fatal("bad count", j, expect) } } for i := 0; i < len(buf); i++ { buf[i] = 0 } }) } type SplitTest struct { s string sep string n int a []string } var splittests = []SplitTest{ {"", "", -1, []string{}}, {abcd, "a", 0, nil}, {abcd, "", 2, []string{"a", "bcd"}}, {abcd, "a", -1, []string{"", "bcd"}}, {abcd, "z", -1, []string{"abcd"}}, {abcd, "", -1, []string{"a", "b", "c", "d"}}, {commas, ",", -1, []string{"1", "2", "3", "4"}}, {dots, "...", -1, []string{"1", ".2", ".3", ".4"}}, {faces, "☹", -1, []string{"☺☻", ""}}, {faces, "~", -1, []string{faces}}, {faces, "", -1, []string{"☺", "☻", "☹"}}, {"1 2 3 4", " ", 3, []string{"1", "2", "3 4"}}, {"1 2", " ", 3, []string{"1", "2"}}, {"123", "", 2, []string{"1", "23"}}, {"123", "", 17, []string{"1", "2", "3"}}, {"bT", "T", math.MaxInt / 4, []string{"b", ""}}, {"\xff-\xff", "", -1, []string{"\xff", "-", "\xff"}}, {"\xff-\xff", "-", -1, []string{"\xff", "\xff"}}, } func TestSplit(t *testing.T) { for _, tt := range splittests { a := SplitN([]byte(tt.s), []byte(tt.sep), tt.n) // Appending to the results should not change future results. var x []byte for _, v := range a { x = append(v, 'z') } result := sliceOfString(a) if !eq(result, tt.a) { t.Errorf(`Split(%q, %q, %d) = %v; want %v`, tt.s, tt.sep, tt.n, result, tt.a) continue } if tt.n == 0 || len(a) == 0 { continue } if want := tt.a[len(tt.a)-1] + "z"; string(x) != want { t.Errorf("last appended result was %s; want %s", x, want) } s := Join(a, []byte(tt.sep)) if string(s) != tt.s { t.Errorf(`Join(Split(%q, %q, %d), %q) = %q`, tt.s, tt.sep, tt.n, tt.sep, s) } if tt.n < 0 { b := Split([]byte(tt.s), []byte(tt.sep)) if !reflect.DeepEqual(a, b) { t.Errorf("Split disagrees withSplitN(%q, %q, %d) = %v; want %v", tt.s, tt.sep, tt.n, b, a) } } if len(a) > 0 { in, out := a[0], s if cap(in) == cap(out) && &in[:1][0] == &out[:1][0] { t.Errorf("Join(%#v, %q) didn't copy", a, tt.sep) } } } } var splitaftertests = []SplitTest{ {abcd, "a", -1, []string{"a", "bcd"}}, {abcd, "z", -1, []string{"abcd"}}, {abcd, "", -1, []string{"a", "b", "c", "d"}}, {commas, ",", -1, []string{"1,", "2,", "3,", "4"}}, {dots, "...", -1, []string{"1...", ".2...", ".3...", ".4"}}, {faces, "☹", -1, []string{"☺☻☹", ""}}, {faces, "~", -1, []string{faces}}, {faces, "", -1, []string{"☺", "☻", "☹"}}, {"1 2 3 4", " ", 3, []string{"1 ", "2 ", "3 4"}}, {"1 2 3", " ", 3, []string{"1 ", "2 ", "3"}}, {"1 2", " ", 3, []string{"1 ", "2"}}, {"123", "", 2, []string{"1", "23"}}, {"123", "", 17, []string{"1", "2", "3"}}, } func TestSplitAfter(t *testing.T) { for _, tt := range splitaftertests { a := SplitAfterN([]byte(tt.s), []byte(tt.sep), tt.n) // Appending to the results should not change future results. var x []byte for _, v := range a { x = append(v, 'z') } result := sliceOfString(a) if !eq(result, tt.a) { t.Errorf(`Split(%q, %q, %d) = %v; want %v`, tt.s, tt.sep, tt.n, result, tt.a) continue } if want := tt.a[len(tt.a)-1] + "z"; string(x) != want { t.Errorf("last appended result was %s; want %s", x, want) } s := Join(a, nil) if string(s) != tt.s { t.Errorf(`Join(Split(%q, %q, %d), %q) = %q`, tt.s, tt.sep, tt.n, tt.sep, s) } if tt.n < 0 { b := SplitAfter([]byte(tt.s), []byte(tt.sep)) if !reflect.DeepEqual(a, b) { t.Errorf("SplitAfter disagrees withSplitAfterN(%q, %q, %d) = %v; want %v", tt.s, tt.sep, tt.n, b, a) } } } } type FieldsTest struct { s string a []string } var fieldstests = []FieldsTest{ {"", []string{}}, {" ", []string{}}, {" \t ", []string{}}, {" abc ", []string{"abc"}}, {"1 2 3 4", []string{"1", "2", "3", "4"}}, {"1 2 3 4", []string{"1", "2", "3", "4"}}, {"1\t\t2\t\t3\t4", []string{"1", "2", "3", "4"}}, {"1\u20002\u20013\u20024", []string{"1", "2", "3", "4"}}, {"\u2000\u2001\u2002", []string{}}, {"\n™\t™\n", []string{"™", "™"}}, {faces, []string{faces}}, } func TestFields(t *testing.T) { for _, tt := range fieldstests { b := []byte(tt.s) a := Fields(b) // Appending to the results should not change future results. var x []byte for _, v := range a { x = append(v, 'z') } result := sliceOfString(a) if !eq(result, tt.a) { t.Errorf("Fields(%q) = %v; want %v", tt.s, a, tt.a) continue } if string(b) != tt.s { t.Errorf("slice changed to %s; want %s", string(b), tt.s) } if len(tt.a) > 0 { if want := tt.a[len(tt.a)-1] + "z"; string(x) != want { t.Errorf("last appended result was %s; want %s", x, want) } } } } func TestFieldsFunc(t *testing.T) { for _, tt := range fieldstests { a := FieldsFunc([]byte(tt.s), unicode.IsSpace) result := sliceOfString(a) if !eq(result, tt.a) { t.Errorf("FieldsFunc(%q, unicode.IsSpace) = %v; want %v", tt.s, a, tt.a) continue } } pred := func(c rune) bool { return c == 'X' } var fieldsFuncTests = []FieldsTest{ {"", []string{}}, {"XX", []string{}}, {"XXhiXXX", []string{"hi"}}, {"aXXbXXXcX", []string{"a", "b", "c"}}, } for _, tt := range fieldsFuncTests { b := []byte(tt.s) a := FieldsFunc(b, pred) // Appending to the results should not change future results. var x []byte for _, v := range a { x = append(v, 'z') } result := sliceOfString(a) if !eq(result, tt.a) { t.Errorf("FieldsFunc(%q) = %v, want %v", tt.s, a, tt.a) } if string(b) != tt.s { t.Errorf("slice changed to %s; want %s", b, tt.s) } if len(tt.a) > 0 { if want := tt.a[len(tt.a)-1] + "z"; string(x) != want { t.Errorf("last appended result was %s; want %s", x, want) } } } } // Test case for any function which accepts and returns a byte slice. // For ease of creation, we write the input byte slice as a string. type StringTest struct { in string out []byte } var upperTests = []StringTest{ {"", []byte("")}, {"ONLYUPPER", []byte("ONLYUPPER")}, {"abc", []byte("ABC")}, {"AbC123", []byte("ABC123")}, {"azAZ09_", []byte("AZAZ09_")}, {"longStrinGwitHmixofsmaLLandcAps", []byte("LONGSTRINGWITHMIXOFSMALLANDCAPS")}, {"long\u0250string\u0250with\u0250nonascii\u2C6Fchars", []byte("LONG\u2C6FSTRING\u2C6FWITH\u2C6FNONASCII\u2C6FCHARS")}, {"\u0250\u0250\u0250\u0250\u0250", []byte("\u2C6F\u2C6F\u2C6F\u2C6F\u2C6F")}, // grows one byte per char {"a\u0080\U0010FFFF", []byte("A\u0080\U0010FFFF")}, // test utf8.RuneSelf and utf8.MaxRune } var lowerTests = []StringTest{ {"", []byte("")}, {"abc", []byte("abc")}, {"AbC123", []byte("abc123")}, {"azAZ09_", []byte("azaz09_")}, {"longStrinGwitHmixofsmaLLandcAps", []byte("longstringwithmixofsmallandcaps")}, {"LONG\u2C6FSTRING\u2C6FWITH\u2C6FNONASCII\u2C6FCHARS", []byte("long\u0250string\u0250with\u0250nonascii\u0250chars")}, {"\u2C6D\u2C6D\u2C6D\u2C6D\u2C6D", []byte("\u0251\u0251\u0251\u0251\u0251")}, // shrinks one byte per char {"A\u0080\U0010FFFF", []byte("a\u0080\U0010FFFF")}, // test utf8.RuneSelf and utf8.MaxRune } const space = "\t\v\r\f\n\u0085\u00a0\u2000\u3000" var trimSpaceTests = []StringTest{ {"", nil}, {" a", []byte("a")}, {"b ", []byte("b")}, {"abc", []byte("abc")}, {space + "abc" + space, []byte("abc")}, {" ", nil}, {"\u3000 ", nil}, {" \u3000", nil}, {" \t\r\n \t\t\r\r\n\n ", nil}, {" \t\r\n x\t\t\r\r\n\n ", []byte("x")}, {" \u2000\t\r\n x\t\t\r\r\ny\n \u3000", []byte("x\t\t\r\r\ny")}, {"1 \t\r\n2", []byte("1 \t\r\n2")}, {" x\x80", []byte("x\x80")}, {" x\xc0", []byte("x\xc0")}, {"x \xc0\xc0 ", []byte("x \xc0\xc0")}, {"x \xc0", []byte("x \xc0")}, {"x \xc0 ", []byte("x \xc0")}, {"x \xc0\xc0 ", []byte("x \xc0\xc0")}, {"x ☺\xc0\xc0 ", []byte("x ☺\xc0\xc0")}, {"x ☺ ", []byte("x ☺")}, } // Execute f on each test case. funcName should be the name of f; it's used // in failure reports. func runStringTests(t *testing.T, f func([]byte) []byte, funcName string, testCases []StringTest) { for _, tc := range testCases { actual := f([]byte(tc.in)) if actual == nil && tc.out != nil { t.Errorf("%s(%q) = nil; want %q", funcName, tc.in, tc.out) } if actual != nil && tc.out == nil { t.Errorf("%s(%q) = %q; want nil", funcName, tc.in, actual) } if !Equal(actual, tc.out) { t.Errorf("%s(%q) = %q; want %q", funcName, tc.in, actual, tc.out) } } } func tenRunes(r rune) string { runes := make([]rune, 10) for i := range runes { runes[i] = r } return string(runes) } // User-defined self-inverse mapping function func rot13(r rune) rune { const step = 13 if r >= 'a' && r <= 'z' { return ((r - 'a' + step) % 26) + 'a' } if r >= 'A' && r <= 'Z' { return ((r - 'A' + step) % 26) + 'A' } return r } func TestMap(t *testing.T) { // Run a couple of awful growth/shrinkage tests a := tenRunes('a') // 1. Grow. This triggers two reallocations in Map. maxRune := func(r rune) rune { return unicode.MaxRune } m := Map(maxRune, []byte(a)) expect := tenRunes(unicode.MaxRune) if string(m) != expect { t.Errorf("growing: expected %q got %q", expect, m) } // 2. Shrink minRune := func(r rune) rune { return 'a' } m = Map(minRune, []byte(tenRunes(unicode.MaxRune))) expect = a if string(m) != expect { t.Errorf("shrinking: expected %q got %q", expect, m) } // 3. Rot13 m = Map(rot13, []byte("a to zed")) expect = "n gb mrq" if string(m) != expect { t.Errorf("rot13: expected %q got %q", expect, m) } // 4. Rot13^2 m = Map(rot13, Map(rot13, []byte("a to zed"))) expect = "a to zed" if string(m) != expect { t.Errorf("rot13: expected %q got %q", expect, m) } // 5. Drop dropNotLatin := func(r rune) rune { if unicode.Is(unicode.Latin, r) { return r } return -1 } m = Map(dropNotLatin, []byte("Hello, 세계")) expect = "Hello" if string(m) != expect { t.Errorf("drop: expected %q got %q", expect, m) } // 6. Invalid rune invalidRune := func(r rune) rune { return utf8.MaxRune + 1 } m = Map(invalidRune, []byte("x")) expect = "\uFFFD" if string(m) != expect { t.Errorf("invalidRune: expected %q got %q", expect, m) } } func TestToUpper(t *testing.T) { runStringTests(t, ToUpper, "ToUpper", upperTests) } func TestToLower(t *testing.T) { runStringTests(t, ToLower, "ToLower", lowerTests) } func BenchmarkToUpper(b *testing.B) { for _, tc := range upperTests { tin := []byte(tc.in) b.Run(tc.in, func(b *testing.B) { for i := 0; i < b.N; i++ { actual := ToUpper(tin) if !Equal(actual, tc.out) { b.Errorf("ToUpper(%q) = %q; want %q", tc.in, actual, tc.out) } } }) } } func BenchmarkToLower(b *testing.B) { for _, tc := range lowerTests { tin := []byte(tc.in) b.Run(tc.in, func(b *testing.B) { for i := 0; i < b.N; i++ { actual := ToLower(tin) if !Equal(actual, tc.out) { b.Errorf("ToLower(%q) = %q; want %q", tc.in, actual, tc.out) } } }) } } var toValidUTF8Tests = []struct { in string repl string out string }{ {"", "\uFFFD", ""}, {"abc", "\uFFFD", "abc"}, {"\uFDDD", "\uFFFD", "\uFDDD"}, {"a\xffb", "\uFFFD", "a\uFFFDb"}, {"a\xffb\uFFFD", "X", "aXb\uFFFD"}, {"a☺\xffb☺\xC0\xAFc☺\xff", "", "a☺b☺c☺"}, {"a☺\xffb☺\xC0\xAFc☺\xff", "日本語", "a☺日本語b☺日本語c☺日本語"}, {"\xC0\xAF", "\uFFFD", "\uFFFD"}, {"\xE0\x80\xAF", "\uFFFD", "\uFFFD"}, {"\xed\xa0\x80", "abc", "abc"}, {"\xed\xbf\xbf", "\uFFFD", "\uFFFD"}, {"\xF0\x80\x80\xaf", "☺", "☺"}, {"\xF8\x80\x80\x80\xAF", "\uFFFD", "\uFFFD"}, {"\xFC\x80\x80\x80\x80\xAF", "\uFFFD", "\uFFFD"}, } func TestToValidUTF8(t *testing.T) { for _, tc := range toValidUTF8Tests { got := ToValidUTF8([]byte(tc.in), []byte(tc.repl)) if !Equal(got, []byte(tc.out)) { t.Errorf("ToValidUTF8(%q, %q) = %q; want %q", tc.in, tc.repl, got, tc.out) } } } func TestTrimSpace(t *testing.T) { runStringTests(t, TrimSpace, "TrimSpace", trimSpaceTests) } type RepeatTest struct { in, out string count int } var longString = "a" + string(make([]byte, 1<<16)) + "z" var RepeatTests = []RepeatTest{ {"", "", 0}, {"", "", 1}, {"", "", 2}, {"-", "", 0}, {"-", "-", 1}, {"-", "----------", 10}, {"abc ", "abc abc abc ", 3}, // Tests for results over the chunkLimit {string(rune(0)), string(make([]byte, 1<<16)), 1 << 16}, {longString, longString + longString, 2}, } func TestRepeat(t *testing.T) { for _, tt := range RepeatTests { tin := []byte(tt.in) tout := []byte(tt.out) a := Repeat(tin, tt.count) if !Equal(a, tout) { t.Errorf("Repeat(%q, %d) = %q; want %q", tin, tt.count, a, tout) continue } } } func repeat(b []byte, count int) (err error) { defer func() { if r := recover(); r != nil { switch v := r.(type) { case error: err = v default: err = fmt.Errorf("%s", v) } } }() Repeat(b, count) return } // See Issue golang.org/issue/16237 func TestRepeatCatchesOverflow(t *testing.T) { tests := [...]struct { s string count int errStr string }{ 0: {"--", -2147483647, "negative"}, 1: {"", int(^uint(0) >> 1), ""}, 2: {"-", 10, ""}, 3: {"gopher", 0, ""}, 4: {"-", -1, "negative"}, 5: {"--", -102, "negative"}, 6: {string(make([]byte, 255)), int((^uint(0))/255 + 1), "overflow"}, } for i, tt := range tests { err := repeat([]byte(tt.s), tt.count) if tt.errStr == "" { if err != nil { t.Errorf("#%d panicked %v", i, err) } continue } if err == nil || !strings.Contains(err.Error(), tt.errStr) { t.Errorf("#%d expected %q got %q", i, tt.errStr, err) } } } func runesEqual(a, b []rune) bool { if len(a) != len(b) { return false } for i, r := range a { if r != b[i] { return false } } return true } type RunesTest struct { in string out []rune lossy bool } var RunesTests = []RunesTest{ {"", []rune{}, false}, {" ", []rune{32}, false}, {"ABC", []rune{65, 66, 67}, false}, {"abc", []rune{97, 98, 99}, false}, {"\u65e5\u672c\u8a9e", []rune{26085, 26412, 35486}, false}, {"ab\x80c", []rune{97, 98, 0xFFFD, 99}, true}, {"ab\xc0c", []rune{97, 98, 0xFFFD, 99}, true}, } func TestRunes(t *testing.T) { for _, tt := range RunesTests { tin := []byte(tt.in) a := Runes(tin) if !runesEqual(a, tt.out) { t.Errorf("Runes(%q) = %v; want %v", tin, a, tt.out) continue } if !tt.lossy { // can only test reassembly if we didn't lose information s := string(a) if s != tt.in { t.Errorf("string(Runes(%q)) = %x; want %x", tin, s, tin) } } } } type TrimTest struct { f string in, arg, out string } var trimTests = []TrimTest{ {"Trim", "abba", "a", "bb"}, {"Trim", "abba", "ab", ""}, {"TrimLeft", "abba", "ab", ""}, {"TrimRight", "abba", "ab", ""}, {"TrimLeft", "abba", "a", "bba"}, {"TrimLeft", "abba", "b", "abba"}, {"TrimRight", "abba", "a", "abb"}, {"TrimRight", "abba", "b", "abba"}, {"Trim", "", "<>", "tag"}, {"Trim", "* listitem", " *", "listitem"}, {"Trim", `"quote"`, `"`, "quote"}, {"Trim", "\u2C6F\u2C6F\u0250\u0250\u2C6F\u2C6F", "\u2C6F", "\u0250\u0250"}, {"Trim", "\x80test\xff", "\xff", "test"}, {"Trim", " Ġ ", " ", "Ġ"}, {"Trim", " Ġİ0", "0 ", "Ġİ"}, //empty string tests {"Trim", "abba", "", "abba"}, {"Trim", "", "123", ""}, {"Trim", "", "", ""}, {"TrimLeft", "abba", "", "abba"}, {"TrimLeft", "", "123", ""}, {"TrimLeft", "", "", ""}, {"TrimRight", "abba", "", "abba"}, {"TrimRight", "", "123", ""}, {"TrimRight", "", "", ""}, {"TrimRight", "☺\xc0", "☺", "☺\xc0"}, {"TrimPrefix", "aabb", "a", "abb"}, {"TrimPrefix", "aabb", "b", "aabb"}, {"TrimSuffix", "aabb", "a", "aabb"}, {"TrimSuffix", "aabb", "b", "aab"}, } type TrimNilTest struct { f string in []byte arg string out []byte } var trimNilTests = []TrimNilTest{ {"Trim", nil, "", nil}, {"Trim", []byte{}, "", nil}, {"Trim", []byte{'a'}, "a", nil}, {"Trim", []byte{'a', 'a'}, "a", nil}, {"Trim", []byte{'a'}, "ab", nil}, {"Trim", []byte{'a', 'b'}, "ab", nil}, {"Trim", []byte("☺"), "☺", nil}, {"TrimLeft", nil, "", nil}, {"TrimLeft", []byte{}, "", nil}, {"TrimLeft", []byte{'a'}, "a", nil}, {"TrimLeft", []byte{'a', 'a'}, "a", nil}, {"TrimLeft", []byte{'a'}, "ab", nil}, {"TrimLeft", []byte{'a', 'b'}, "ab", nil}, {"TrimLeft", []byte("☺"), "☺", nil}, {"TrimRight", nil, "", nil}, {"TrimRight", []byte{}, "", []byte{}}, {"TrimRight", []byte{'a'}, "a", []byte{}}, {"TrimRight", []byte{'a', 'a'}, "a", []byte{}}, {"TrimRight", []byte{'a'}, "ab", []byte{}}, {"TrimRight", []byte{'a', 'b'}, "ab", []byte{}}, {"TrimRight", []byte("☺"), "☺", []byte{}}, {"TrimPrefix", nil, "", nil}, {"TrimPrefix", []byte{}, "", []byte{}}, {"TrimPrefix", []byte{'a'}, "a", []byte{}}, {"TrimPrefix", []byte("☺"), "☺", []byte{}}, {"TrimSuffix", nil, "", nil}, {"TrimSuffix", []byte{}, "", []byte{}}, {"TrimSuffix", []byte{'a'}, "a", []byte{}}, {"TrimSuffix", []byte("☺"), "☺", []byte{}}, } func TestTrim(t *testing.T) { toFn := func(name string) (func([]byte, string) []byte, func([]byte, []byte) []byte) { switch name { case "Trim": return Trim, nil case "TrimLeft": return TrimLeft, nil case "TrimRight": return TrimRight, nil case "TrimPrefix": return nil, TrimPrefix case "TrimSuffix": return nil, TrimSuffix default: t.Errorf("Undefined trim function %s", name) return nil, nil } } for _, tc := range trimTests { name := tc.f f, fb := toFn(name) if f == nil && fb == nil { continue } var actual string if f != nil { actual = string(f([]byte(tc.in), tc.arg)) } else { actual = string(fb([]byte(tc.in), []byte(tc.arg))) } if actual != tc.out { t.Errorf("%s(%q, %q) = %q; want %q", name, tc.in, tc.arg, actual, tc.out) } } for _, tc := range trimNilTests { name := tc.f f, fb := toFn(name) if f == nil && fb == nil { continue } var actual []byte if f != nil { actual = f(tc.in, tc.arg) } else { actual = fb(tc.in, []byte(tc.arg)) } report := func(s []byte) string { if s == nil { return "nil" } else { return fmt.Sprintf("%q", s) } } if len(actual) != 0 { t.Errorf("%s(%s, %q) returned non-empty value", name, report(tc.in), tc.arg) } else { actualNil := actual == nil outNil := tc.out == nil if actualNil != outNil { t.Errorf("%s(%s, %q) got nil %t; want nil %t", name, report(tc.in), tc.arg, actualNil, outNil) } } } } type predicate struct { f func(r rune) bool name string } var isSpace = predicate{unicode.IsSpace, "IsSpace"} var isDigit = predicate{unicode.IsDigit, "IsDigit"} var isUpper = predicate{unicode.IsUpper, "IsUpper"} var isValidRune = predicate{ func(r rune) bool { return r != utf8.RuneError }, "IsValidRune", } type TrimFuncTest struct { f predicate in string trimOut []byte leftOut []byte rightOut []byte } func not(p predicate) predicate { return predicate{ func(r rune) bool { return !p.f(r) }, "not " + p.name, } } var trimFuncTests = []TrimFuncTest{ {isSpace, space + " hello " + space, []byte("hello"), []byte("hello " + space), []byte(space + " hello")}, {isDigit, "\u0e50\u0e5212hello34\u0e50\u0e51", []byte("hello"), []byte("hello34\u0e50\u0e51"), []byte("\u0e50\u0e5212hello")}, {isUpper, "\u2C6F\u2C6F\u2C6F\u2C6FABCDhelloEF\u2C6F\u2C6FGH\u2C6F\u2C6F", []byte("hello"), []byte("helloEF\u2C6F\u2C6FGH\u2C6F\u2C6F"), []byte("\u2C6F\u2C6F\u2C6F\u2C6FABCDhello")}, {not(isSpace), "hello" + space + "hello", []byte(space), []byte(space + "hello"), []byte("hello" + space)}, {not(isDigit), "hello\u0e50\u0e521234\u0e50\u0e51helo", []byte("\u0e50\u0e521234\u0e50\u0e51"), []byte("\u0e50\u0e521234\u0e50\u0e51helo"), []byte("hello\u0e50\u0e521234\u0e50\u0e51")}, {isValidRune, "ab\xc0a\xc0cd", []byte("\xc0a\xc0"), []byte("\xc0a\xc0cd"), []byte("ab\xc0a\xc0")}, {not(isValidRune), "\xc0a\xc0", []byte("a"), []byte("a\xc0"), []byte("\xc0a")}, // The nils returned by TrimLeftFunc are odd behavior, but we need // to preserve backwards compatibility. {isSpace, "", nil, nil, []byte("")}, {isSpace, " ", nil, nil, []byte("")}, } func TestTrimFunc(t *testing.T) { for _, tc := range trimFuncTests { trimmers := []struct { name string trim func(s []byte, f func(r rune) bool) []byte out []byte }{ {"TrimFunc", TrimFunc, tc.trimOut}, {"TrimLeftFunc", TrimLeftFunc, tc.leftOut}, {"TrimRightFunc", TrimRightFunc, tc.rightOut}, } for _, trimmer := range trimmers { actual := trimmer.trim([]byte(tc.in), tc.f.f) if actual == nil && trimmer.out != nil { t.Errorf("%s(%q, %q) = nil; want %q", trimmer.name, tc.in, tc.f.name, trimmer.out) } if actual != nil && trimmer.out == nil { t.Errorf("%s(%q, %q) = %q; want nil", trimmer.name, tc.in, tc.f.name, actual) } if !Equal(actual, trimmer.out) { t.Errorf("%s(%q, %q) = %q; want %q", trimmer.name, tc.in, tc.f.name, actual, trimmer.out) } } } } type IndexFuncTest struct { in string f predicate first, last int } var indexFuncTests = []IndexFuncTest{ {"", isValidRune, -1, -1}, {"abc", isDigit, -1, -1}, {"0123", isDigit, 0, 3}, {"a1b", isDigit, 1, 1}, {space, isSpace, 0, len(space) - 3}, // last rune in space is 3 bytes {"\u0e50\u0e5212hello34\u0e50\u0e51", isDigit, 0, 18}, {"\u2C6F\u2C6F\u2C6F\u2C6FABCDhelloEF\u2C6F\u2C6FGH\u2C6F\u2C6F", isUpper, 0, 34}, {"12\u0e50\u0e52hello34\u0e50\u0e51", not(isDigit), 8, 12}, // tests of invalid UTF-8 {"\x801", isDigit, 1, 1}, {"\x80abc", isDigit, -1, -1}, {"\xc0a\xc0", isValidRune, 1, 1}, {"\xc0a\xc0", not(isValidRune), 0, 2}, {"\xc0☺\xc0", not(isValidRune), 0, 4}, {"\xc0☺\xc0\xc0", not(isValidRune), 0, 5}, {"ab\xc0a\xc0cd", not(isValidRune), 2, 4}, {"a\xe0\x80cd", not(isValidRune), 1, 2}, } func TestIndexFunc(t *testing.T) { for _, tc := range indexFuncTests { first := IndexFunc([]byte(tc.in), tc.f.f) if first != tc.first { t.Errorf("IndexFunc(%q, %s) = %d; want %d", tc.in, tc.f.name, first, tc.first) } last := LastIndexFunc([]byte(tc.in), tc.f.f) if last != tc.last { t.Errorf("LastIndexFunc(%q, %s) = %d; want %d", tc.in, tc.f.name, last, tc.last) } } } type ReplaceTest struct { in string old, new string n int out string } var ReplaceTests = []ReplaceTest{ {"hello", "l", "L", 0, "hello"}, {"hello", "l", "L", -1, "heLLo"}, {"hello", "x", "X", -1, "hello"}, {"", "x", "X", -1, ""}, {"radar", "r", "", -1, "ada"}, {"", "", "<>", -1, "<>"}, {"banana", "a", "<>", -1, "b<>n<>n<>"}, {"banana", "a", "<>", 1, "b<>nana"}, {"banana", "a", "<>", 1000, "b<>n<>n<>"}, {"banana", "an", "<>", -1, "b<><>a"}, {"banana", "ana", "<>", -1, "b<>na"}, {"banana", "", "<>", -1, "<>b<>a<>n<>a<>n<>a<>"}, {"banana", "", "<>", 10, "<>b<>a<>n<>a<>n<>a<>"}, {"banana", "", "<>", 6, "<>b<>a<>n<>a<>n<>a"}, {"banana", "", "<>", 5, "<>b<>a<>n<>a<>na"}, {"banana", "", "<>", 1, "<>banana"}, {"banana", "a", "a", -1, "banana"}, {"banana", "a", "a", 1, "banana"}, {"☺☻☹", "", "<>", -1, "<>☺<>☻<>☹<>"}, } func TestReplace(t *testing.T) { for _, tt := range ReplaceTests { in := append([]byte(tt.in), ""...) in = in[:len(tt.in)] out := Replace(in, []byte(tt.old), []byte(tt.new), tt.n) if s := string(out); s != tt.out { t.Errorf("Replace(%q, %q, %q, %d) = %q, want %q", tt.in, tt.old, tt.new, tt.n, s, tt.out) } if cap(in) == cap(out) && &in[:1][0] == &out[:1][0] { t.Errorf("Replace(%q, %q, %q, %d) didn't copy", tt.in, tt.old, tt.new, tt.n) } if tt.n == -1 { out := ReplaceAll(in, []byte(tt.old), []byte(tt.new)) if s := string(out); s != tt.out { t.Errorf("ReplaceAll(%q, %q, %q) = %q, want %q", tt.in, tt.old, tt.new, s, tt.out) } } } } type TitleTest struct { in, out string } var TitleTests = []TitleTest{ {"", ""}, {"a", "A"}, {" aaa aaa aaa ", " Aaa Aaa Aaa "}, {" Aaa Aaa Aaa ", " Aaa Aaa Aaa "}, {"123a456", "123a456"}, {"double-blind", "Double-Blind"}, {"ÿøû", "Ÿøû"}, {"with_underscore", "With_underscore"}, {"unicode \xe2\x80\xa8 line separator", "Unicode \xe2\x80\xa8 Line Separator"}, } func TestTitle(t *testing.T) { for _, tt := range TitleTests { if s := string(Title([]byte(tt.in))); s != tt.out { t.Errorf("Title(%q) = %q, want %q", tt.in, s, tt.out) } } } var ToTitleTests = []TitleTest{ {"", ""}, {"a", "A"}, {" aaa aaa aaa ", " AAA AAA AAA "}, {" Aaa Aaa Aaa ", " AAA AAA AAA "}, {"123a456", "123A456"}, {"double-blind", "DOUBLE-BLIND"}, {"ÿøû", "ŸØÛ"}, } func TestToTitle(t *testing.T) { for _, tt := range ToTitleTests { if s := string(ToTitle([]byte(tt.in))); s != tt.out { t.Errorf("ToTitle(%q) = %q, want %q", tt.in, s, tt.out) } } } var EqualFoldTests = []struct { s, t string out bool }{ {"abc", "abc", true}, {"ABcd", "ABcd", true}, {"123abc", "123ABC", true}, {"αβδ", "ΑΒΔ", true}, {"abc", "xyz", false}, {"abc", "XYZ", false}, {"abcdefghijk", "abcdefghijX", false}, {"abcdefghijk", "abcdefghij\u212A", true}, {"abcdefghijK", "abcdefghij\u212A", true}, {"abcdefghijkz", "abcdefghij\u212Ay", false}, {"abcdefghijKz", "abcdefghij\u212Ay", false}, } func TestEqualFold(t *testing.T) { for _, tt := range EqualFoldTests { if out := EqualFold([]byte(tt.s), []byte(tt.t)); out != tt.out { t.Errorf("EqualFold(%#q, %#q) = %v, want %v", tt.s, tt.t, out, tt.out) } if out := EqualFold([]byte(tt.t), []byte(tt.s)); out != tt.out { t.Errorf("EqualFold(%#q, %#q) = %v, want %v", tt.t, tt.s, out, tt.out) } } } var cutTests = []struct { s, sep string before, after string found bool }{ {"abc", "b", "a", "c", true}, {"abc", "a", "", "bc", true}, {"abc", "c", "ab", "", true}, {"abc", "abc", "", "", true}, {"abc", "", "", "abc", true}, {"abc", "d", "abc", "", false}, {"", "d", "", "", false}, {"", "", "", "", true}, } func TestCut(t *testing.T) { for _, tt := range cutTests { if before, after, found := Cut([]byte(tt.s), []byte(tt.sep)); string(before) != tt.before || string(after) != tt.after || found != tt.found { t.Errorf("Cut(%q, %q) = %q, %q, %v, want %q, %q, %v", tt.s, tt.sep, before, after, found, tt.before, tt.after, tt.found) } } } var cutPrefixTests = []struct { s, sep string after string found bool }{ {"abc", "a", "bc", true}, {"abc", "abc", "", true}, {"abc", "", "abc", true}, {"abc", "d", "abc", false}, {"", "d", "", false}, {"", "", "", true}, } func TestCutPrefix(t *testing.T) { for _, tt := range cutPrefixTests { if after, found := CutPrefix([]byte(tt.s), []byte(tt.sep)); string(after) != tt.after || found != tt.found { t.Errorf("CutPrefix(%q, %q) = %q, %v, want %q, %v", tt.s, tt.sep, after, found, tt.after, tt.found) } } } var cutSuffixTests = []struct { s, sep string before string found bool }{ {"abc", "bc", "a", true}, {"abc", "abc", "", true}, {"abc", "", "abc", true}, {"abc", "d", "abc", false}, {"", "d", "", false}, {"", "", "", true}, } func TestCutSuffix(t *testing.T) { for _, tt := range cutSuffixTests { if before, found := CutSuffix([]byte(tt.s), []byte(tt.sep)); string(before) != tt.before || found != tt.found { t.Errorf("CutSuffix(%q, %q) = %q, %v, want %q, %v", tt.s, tt.sep, before, found, tt.before, tt.found) } } } func TestBufferGrowNegative(t *testing.T) { defer func() { if err := recover(); err == nil { t.Fatal("Grow(-1) should have panicked") } }() var b Buffer b.Grow(-1) } func TestBufferTruncateNegative(t *testing.T) { defer func() { if err := recover(); err == nil { t.Fatal("Truncate(-1) should have panicked") } }() var b Buffer b.Truncate(-1) } func TestBufferTruncateOutOfRange(t *testing.T) { defer func() { if err := recover(); err == nil { t.Fatal("Truncate(20) should have panicked") } }() var b Buffer b.Write(make([]byte, 10)) b.Truncate(20) } var containsTests = []struct { b, subslice []byte want bool }{ {[]byte("hello"), []byte("hel"), true}, {[]byte("日本語"), []byte("日本"), true}, {[]byte("hello"), []byte("Hello, world"), false}, {[]byte("東京"), []byte("京東"), false}, } func TestContains(t *testing.T) { for _, tt := range containsTests { if got := Contains(tt.b, tt.subslice); got != tt.want { t.Errorf("Contains(%q, %q) = %v, want %v", tt.b, tt.subslice, got, tt.want) } } } var ContainsAnyTests = []struct { b []byte substr string expected bool }{ {[]byte(""), "", false}, {[]byte(""), "a", false}, {[]byte(""), "abc", false}, {[]byte("a"), "", false}, {[]byte("a"), "a", true}, {[]byte("aaa"), "a", true}, {[]byte("abc"), "xyz", false}, {[]byte("abc"), "xcz", true}, {[]byte("a☺b☻c☹d"), "uvw☻xyz", true}, {[]byte("aRegExp*"), ".(|)*+?^$[]", true}, {[]byte(dots + dots + dots), " ", false}, } func TestContainsAny(t *testing.T) { for _, ct := range ContainsAnyTests { if ContainsAny(ct.b, ct.substr) != ct.expected { t.Errorf("ContainsAny(%s, %s) = %v, want %v", ct.b, ct.substr, !ct.expected, ct.expected) } } } var ContainsRuneTests = []struct { b []byte r rune expected bool }{ {[]byte(""), 'a', false}, {[]byte("a"), 'a', true}, {[]byte("aaa"), 'a', true}, {[]byte("abc"), 'y', false}, {[]byte("abc"), 'c', true}, {[]byte("a☺b☻c☹d"), 'x', false}, {[]byte("a☺b☻c☹d"), '☻', true}, {[]byte("aRegExp*"), '*', true}, } func TestContainsRune(t *testing.T) { for _, ct := range ContainsRuneTests { if ContainsRune(ct.b, ct.r) != ct.expected { t.Errorf("ContainsRune(%q, %q) = %v, want %v", ct.b, ct.r, !ct.expected, ct.expected) } } } func TestContainsFunc(t *testing.T) { for _, ct := range ContainsRuneTests { if ContainsFunc(ct.b, func(r rune) bool { return ct.r == r }) != ct.expected { t.Errorf("ContainsFunc(%q, func(%q)) = %v, want %v", ct.b, ct.r, !ct.expected, ct.expected) } } } var makeFieldsInput = func() []byte { x := make([]byte, 1<<20) // Input is ~10% space, ~10% 2-byte UTF-8, rest ASCII non-space. for i := range x { switch rand.Intn(10) { case 0: x[i] = ' ' case 1: if i > 0 && x[i-1] == 'x' { copy(x[i-1:], "χ") break } fallthrough default: x[i] = 'x' } } return x } var makeFieldsInputASCII = func() []byte { x := make([]byte, 1<<20) // Input is ~10% space, rest ASCII non-space. for i := range x { if rand.Intn(10) == 0 { x[i] = ' ' } else { x[i] = 'x' } } return x } var bytesdata = []struct { name string data []byte }{ {"ASCII", makeFieldsInputASCII()}, {"Mixed", makeFieldsInput()}, } func BenchmarkFields(b *testing.B) { for _, sd := range bytesdata { b.Run(sd.name, func(b *testing.B) { for j := 1 << 4; j <= 1<<20; j <<= 4 { b.Run(fmt.Sprintf("%d", j), func(b *testing.B) { b.ReportAllocs() b.SetBytes(int64(j)) data := sd.data[:j] for i := 0; i < b.N; i++ { Fields(data) } }) } }) } } func BenchmarkFieldsFunc(b *testing.B) { for _, sd := range bytesdata { b.Run(sd.name, func(b *testing.B) { for j := 1 << 4; j <= 1<<20; j <<= 4 { b.Run(fmt.Sprintf("%d", j), func(b *testing.B) { b.ReportAllocs() b.SetBytes(int64(j)) data := sd.data[:j] for i := 0; i < b.N; i++ { FieldsFunc(data, unicode.IsSpace) } }) } }) } } func BenchmarkTrimSpace(b *testing.B) { tests := []struct { name string input []byte }{ {"NoTrim", []byte("typical")}, {"ASCII", []byte(" foo bar ")}, {"SomeNonASCII", []byte(" \u2000\t\r\n x\t\t\r\r\ny\n \u3000 ")}, {"JustNonASCII", []byte("\u2000\u2000\u2000☺☺☺☺\u3000\u3000\u3000")}, } for _, test := range tests { b.Run(test.name, func(b *testing.B) { for i := 0; i < b.N; i++ { TrimSpace(test.input) } }) } } func BenchmarkToValidUTF8(b *testing.B) { tests := []struct { name string input []byte }{ {"Valid", []byte("typical")}, {"InvalidASCII", []byte("foo\xffbar")}, {"InvalidNonASCII", []byte("日本語\xff日本語")}, } replacement := []byte("\uFFFD") b.ResetTimer() for _, test := range tests { b.Run(test.name, func(b *testing.B) { for i := 0; i < b.N; i++ { ToValidUTF8(test.input, replacement) } }) } } func makeBenchInputHard() []byte { tokens := [...]string{ "", "

", "", "", "", "

", "", "", "hello", "world", } x := make([]byte, 0, 1<<20) for { i := rand.Intn(len(tokens)) if len(x)+len(tokens[i]) >= 1<<20 { break } x = append(x, tokens[i]...) } return x } var benchInputHard = makeBenchInputHard() func benchmarkIndexHard(b *testing.B, sep []byte) { for i := 0; i < b.N; i++ { Index(benchInputHard, sep) } } func benchmarkLastIndexHard(b *testing.B, sep []byte) { for i := 0; i < b.N; i++ { LastIndex(benchInputHard, sep) } } func benchmarkCountHard(b *testing.B, sep []byte) { for i := 0; i < b.N; i++ { Count(benchInputHard, sep) } } func BenchmarkIndexHard1(b *testing.B) { benchmarkIndexHard(b, []byte("<>")) } func BenchmarkIndexHard2(b *testing.B) { benchmarkIndexHard(b, []byte("")) } func BenchmarkIndexHard3(b *testing.B) { benchmarkIndexHard(b, []byte("hello world")) } func BenchmarkIndexHard4(b *testing.B) { benchmarkIndexHard(b, []byte("
helloworld
")) } func BenchmarkLastIndexHard1(b *testing.B) { benchmarkLastIndexHard(b, []byte("<>")) } func BenchmarkLastIndexHard2(b *testing.B) { benchmarkLastIndexHard(b, []byte("")) } func BenchmarkLastIndexHard3(b *testing.B) { benchmarkLastIndexHard(b, []byte("hello world")) } func BenchmarkCountHard1(b *testing.B) { benchmarkCountHard(b, []byte("<>")) } func BenchmarkCountHard2(b *testing.B) { benchmarkCountHard(b, []byte("")) } func BenchmarkCountHard3(b *testing.B) { benchmarkCountHard(b, []byte("hello world")) } func BenchmarkSplitEmptySeparator(b *testing.B) { for i := 0; i < b.N; i++ { Split(benchInputHard, nil) } } func BenchmarkSplitSingleByteSeparator(b *testing.B) { sep := []byte("/") for i := 0; i < b.N; i++ { Split(benchInputHard, sep) } } func BenchmarkSplitMultiByteSeparator(b *testing.B) { sep := []byte("hello") for i := 0; i < b.N; i++ { Split(benchInputHard, sep) } } func BenchmarkSplitNSingleByteSeparator(b *testing.B) { sep := []byte("/") for i := 0; i < b.N; i++ { SplitN(benchInputHard, sep, 10) } } func BenchmarkSplitNMultiByteSeparator(b *testing.B) { sep := []byte("hello") for i := 0; i < b.N; i++ { SplitN(benchInputHard, sep, 10) } } func BenchmarkRepeat(b *testing.B) { for i := 0; i < b.N; i++ { Repeat([]byte("-"), 80) } } func BenchmarkRepeatLarge(b *testing.B) { s := Repeat([]byte("@"), 8*1024) for j := 8; j <= 30; j++ { for _, k := range []int{1, 16, 4097} { s := s[:k] n := (1 << j) / k if n == 0 { continue } b.Run(fmt.Sprintf("%d/%d", 1<