2
0
mirror of https://github.com/junegunn/fzf synced 2024-11-10 13:10:44 +00:00
fzf/src/ansi_test.go
2023-12-25 17:05:54 +09:00

432 lines
11 KiB
Go

package fzf
import (
"math/rand"
"regexp"
"strings"
"testing"
"unicode/utf8"
"github.com/junegunn/fzf/src/tui"
)
// The following regular expression will include not all but most of the
// frequently used ANSI sequences. This regex is used as a reference for
// testing nextAnsiEscapeSequence().
//
// References:
// - https://github.com/gnachman/iTerm2
// - https://web.archive.org/web/20090204053813/http://ascii-table.com/ansi-escape-sequences.php
// (archived from http://ascii-table.com/ansi-escape-sequences.php)
// - https://web.archive.org/web/20090227051140/http://ascii-table.com/ansi-escape-sequences-vt-100.php
// (archived from http://ascii-table.com/ansi-escape-sequences-vt-100.php)
// - http://tldp.org/HOWTO/Bash-Prompt-HOWTO/x405.html
// - https://invisible-island.net/xterm/ctlseqs/ctlseqs.html
var ansiRegexReference = regexp.MustCompile("(?:\x1b[\\[()][0-9;:]*[a-zA-Z@]|\x1b][0-9][;:][[:print:]]+(?:\x1b\\\\|\x07)|\x1b.|[\x0e\x0f]|.\x08)")
func testParserReference(t testing.TB, str string) {
t.Helper()
toSlice := func(start, end int) []int {
if start == -1 {
return nil
}
return []int{start, end}
}
s := str
for i := 0; ; i++ {
got := toSlice(nextAnsiEscapeSequence(s))
exp := ansiRegexReference.FindStringIndex(s)
equal := len(got) == len(exp)
if equal {
for i := 0; i < len(got); i++ {
if got[i] != exp[i] {
equal = false
break
}
}
}
if !equal {
var exps, gots []rune
if len(got) == 2 {
gots = []rune(s[got[0]:got[1]])
}
if len(exp) == 2 {
exps = []rune(s[exp[0]:exp[1]])
}
t.Errorf("%d: %q: got: %v (%q) want: %v (%q)", i, s, got, gots, exp, exps)
return
}
if len(exp) == 0 {
return
}
s = s[exp[1]:]
}
}
func TestNextAnsiEscapeSequence(t *testing.T) {
testStrs := []string{
"\x1b[0mhello world",
"\x1b[1mhello world",
"椙\x1b[1m椙",
"椙\x1b[1椙m椙",
"\x1b[1mhello \x1b[mw\x1b7o\x1b8r\x1b(Bl\x1b[2@d",
"\x1b[1mhello \x1b[Kworld",
"hello \x1b[34;45;1mworld",
"hello \x1b[34;45;1mwor\x1b[34;45;1mld",
"hello \x1b[34;45;1mwor\x1b[0mld",
"hello \x1b[34;48;5;233;1mwo\x1b[38;5;161mr\x1b[0ml\x1b[38;5;161md",
"hello \x1b[38;5;38;48;5;48;1mwor\x1b[38;5;48;48;5;38ml\x1b[0md",
"hello \x1b[32;1mworld",
"hello world",
"hello \x1b[0;38;5;200;48;5;100mworld",
"\x1b椙",
"椙\x08",
"\n\x08",
"X\x08",
"",
"\x1b]4;3;rgb:aa/bb/cc\x07 ",
"\x1b]4;3;rgb:aa/bb/cc\x1b\\ ",
ansiBenchmarkString,
}
for _, s := range testStrs {
testParserReference(t, s)
}
}
func TestNextAnsiEscapeSequence_Fuzz_Modified(t *testing.T) {
t.Parallel()
if testing.Short() {
t.Skip("short test")
}
testStrs := []string{
"\x1b[0mhello world",
"\x1b[1mhello world",
"椙\x1b[1m椙",
"椙\x1b[1椙m椙",
"\x1b[1mhello \x1b[mw\x1b7o\x1b8r\x1b(Bl\x1b[2@d",
"\x1b[1mhello \x1b[Kworld",
"hello \x1b[34;45;1mworld",
"hello \x1b[34;45;1mwor\x1b[34;45;1mld",
"hello \x1b[34;45;1mwor\x1b[0mld",
"hello \x1b[34;48;5;233;1mwo\x1b[38;5;161mr\x1b[0ml\x1b[38;5;161md",
"hello \x1b[38;5;38;48;5;48;1mwor\x1b[38;5;48;48;5;38ml\x1b[0md",
"hello \x1b[32;1mworld",
"hello world",
"hello \x1b[0;38;5;200;48;5;100mworld",
ansiBenchmarkString,
}
replacementBytes := [...]rune{'\x0e', '\x0f', '\x1b', '\x08'}
modifyString := func(s string, rr *rand.Rand) string {
n := rr.Intn(len(s))
b := []rune(s)
for ; n >= 0 && len(b) != 0; n-- {
i := rr.Intn(len(b))
switch x := rr.Intn(4); x {
case 0:
b = append(b[:i], b[i+1:]...)
case 1:
j := rr.Intn(len(replacementBytes) - 1)
b[i] = replacementBytes[j]
case 2:
x := rune(rr.Intn(utf8.MaxRune))
for !utf8.ValidRune(x) {
x = rune(rr.Intn(utf8.MaxRune))
}
b[i] = x
case 3:
b[i] = rune(rr.Intn(utf8.MaxRune)) // potentially invalid
default:
t.Fatalf("unsupported value: %d", x)
}
}
return string(b)
}
rr := rand.New(rand.NewSource(1))
for _, s := range testStrs {
for i := 1_000; i >= 0; i-- {
testParserReference(t, modifyString(s, rr))
}
}
}
func TestNextAnsiEscapeSequence_Fuzz_Random(t *testing.T) {
t.Parallel()
if testing.Short() {
t.Skip("short test")
}
randomString := func(rr *rand.Rand) string {
numChars := rand.Intn(50)
codePoints := make([]rune, numChars)
for i := 0; i < len(codePoints); i++ {
var r rune
for n := 0; n < 1000; n++ {
r = rune(rr.Intn(utf8.MaxRune))
// Allow 10% of runes to be invalid
if utf8.ValidRune(r) || rr.Float64() < 0.10 {
break
}
}
codePoints[i] = r
}
return string(codePoints)
}
rr := rand.New(rand.NewSource(1))
for i := 0; i < 100_000; i++ {
testParserReference(t, randomString(rr))
}
}
func TestExtractColor(t *testing.T) {
assert := func(offset ansiOffset, b int32, e int32, fg tui.Color, bg tui.Color, bold bool) {
var attr tui.Attr
if bold {
attr = tui.Bold
}
if offset.offset[0] != b || offset.offset[1] != e ||
offset.color.fg != fg || offset.color.bg != bg || offset.color.attr != attr {
t.Error(offset, b, e, fg, bg, attr)
}
}
src := "hello world"
var state *ansiState
clean := "\x1b[0m"
check := func(assertion func(ansiOffsets *[]ansiOffset, state *ansiState)) {
output, ansiOffsets, newState := extractColor(src, state, nil)
state = newState
if output != "hello world" {
t.Errorf("Invalid output: %s %v", output, []rune(output))
}
t.Log(src, ansiOffsets, clean)
assertion(ansiOffsets, state)
}
check(func(offsets *[]ansiOffset, state *ansiState) {
if offsets != nil {
t.Fail()
}
})
state = nil
src = "\x1b[0mhello world"
check(func(offsets *[]ansiOffset, state *ansiState) {
if offsets != nil {
t.Fail()
}
})
state = nil
src = "\x1b[1mhello world"
check(func(offsets *[]ansiOffset, state *ansiState) {
if len(*offsets) != 1 {
t.Fail()
}
assert((*offsets)[0], 0, 11, -1, -1, true)
})
state = nil
src = "\x1b[1mhello \x1b[mw\x1b7o\x1b8r\x1b(Bl\x1b[2@d"
check(func(offsets *[]ansiOffset, state *ansiState) {
if len(*offsets) != 1 {
t.Fail()
}
assert((*offsets)[0], 0, 6, -1, -1, true)
})
state = nil
src = "\x1b[1mhello \x1b[Kworld"
check(func(offsets *[]ansiOffset, state *ansiState) {
if len(*offsets) != 1 {
t.Fail()
}
assert((*offsets)[0], 0, 11, -1, -1, true)
})
state = nil
src = "hello \x1b[34;45;1mworld"
check(func(offsets *[]ansiOffset, state *ansiState) {
if len(*offsets) != 1 {
t.Fail()
}
assert((*offsets)[0], 6, 11, 4, 5, true)
})
state = nil
src = "hello \x1b[34;45;1mwor\x1b[34;45;1mld"
check(func(offsets *[]ansiOffset, state *ansiState) {
if len(*offsets) != 1 {
t.Fail()
}
assert((*offsets)[0], 6, 11, 4, 5, true)
})
state = nil
src = "hello \x1b[34;45;1mwor\x1b[0mld"
check(func(offsets *[]ansiOffset, state *ansiState) {
if len(*offsets) != 1 {
t.Fail()
}
assert((*offsets)[0], 6, 9, 4, 5, true)
})
state = nil
src = "hello \x1b[34;48;5;233;1mwo\x1b[38;5;161mr\x1b[0ml\x1b[38;5;161md"
check(func(offsets *[]ansiOffset, state *ansiState) {
if len(*offsets) != 3 {
t.Fail()
}
assert((*offsets)[0], 6, 8, 4, 233, true)
assert((*offsets)[1], 8, 9, 161, 233, true)
assert((*offsets)[2], 10, 11, 161, -1, false)
})
// {38,48};5;{38,48}
state = nil
src = "hello \x1b[38;5;38;48;5;48;1mwor\x1b[38;5;48;48;5;38ml\x1b[0md"
check(func(offsets *[]ansiOffset, state *ansiState) {
if len(*offsets) != 2 {
t.Fail()
}
assert((*offsets)[0], 6, 9, 38, 48, true)
assert((*offsets)[1], 9, 10, 48, 38, true)
})
src = "hello \x1b[32;1mworld"
check(func(offsets *[]ansiOffset, state *ansiState) {
if len(*offsets) != 1 {
t.Fail()
}
if state.fg != 2 || state.bg != -1 || state.attr == 0 {
t.Fail()
}
assert((*offsets)[0], 6, 11, 2, -1, true)
})
src = "hello world"
check(func(offsets *[]ansiOffset, state *ansiState) {
if len(*offsets) != 1 {
t.Fail()
}
if state.fg != 2 || state.bg != -1 || state.attr == 0 {
t.Fail()
}
assert((*offsets)[0], 0, 11, 2, -1, true)
})
src = "hello \x1b[0;38;5;200;48;5;100mworld"
check(func(offsets *[]ansiOffset, state *ansiState) {
if len(*offsets) != 2 {
t.Fail()
}
if state.fg != 200 || state.bg != 100 || state.attr > 0 {
t.Fail()
}
assert((*offsets)[0], 0, 6, 2, -1, true)
assert((*offsets)[1], 6, 11, 200, 100, false)
})
}
func TestAnsiCodeStringConversion(t *testing.T) {
assert := func(code string, prevState *ansiState, expected string) {
state := interpretCode(code, prevState)
if expected != state.ToString() {
t.Errorf("expected: %s, actual: %s",
strings.Replace(expected, "\x1b[", "\\x1b[", -1),
strings.Replace(state.ToString(), "\x1b[", "\\x1b[", -1))
}
}
assert("\x1b[m", nil, "")
assert("\x1b[m", &ansiState{attr: tui.Blink, lbg: -1}, "")
assert("\x1b[0m", &ansiState{fg: 4, bg: 4, lbg: -1}, "")
assert("\x1b[;m", &ansiState{fg: 4, bg: 4, lbg: -1}, "")
assert("\x1b[;;m", &ansiState{fg: 4, bg: 4, lbg: -1}, "")
assert("\x1b[31m", nil, "\x1b[31;49m")
assert("\x1b[41m", nil, "\x1b[39;41m")
assert("\x1b[92m", nil, "\x1b[92;49m")
assert("\x1b[102m", nil, "\x1b[39;102m")
assert("\x1b[31m", &ansiState{fg: 4, bg: 4, lbg: -1}, "\x1b[31;44m")
assert("\x1b[1;2;31m", &ansiState{fg: 2, bg: -1, attr: tui.Reverse, lbg: -1}, "\x1b[1;2;7;31;49m")
assert("\x1b[38;5;100;48;5;200m", nil, "\x1b[38;5;100;48;5;200m")
assert("\x1b[38:5:100:48:5:200m", nil, "\x1b[38;5;100;48;5;200m")
assert("\x1b[48;5;100;38;5;200m", nil, "\x1b[38;5;200;48;5;100m")
assert("\x1b[48;5;100;38;2;10;20;30;1m", nil, "\x1b[1;38;2;10;20;30;48;5;100m")
assert("\x1b[48;5;100;38;2;10;20;30;7m",
&ansiState{attr: tui.Dim | tui.Italic, fg: 1, bg: 1},
"\x1b[2;3;7;38;2;10;20;30;48;5;100m")
}
func TestParseAnsiCode(t *testing.T) {
tests := []struct {
In, Exp string
N int
}{
{"123", "", 123},
{"1a", "", -1},
{"1a;12", "12", -1},
{"12;a", "a", 12},
{"-2", "", -1},
}
for _, x := range tests {
n, _, s := parseAnsiCode(x.In, 0)
if n != x.N || s != x.Exp {
t.Fatalf("%q: got: (%d %q) want: (%d %q)", x.In, n, s, x.N, x.Exp)
}
}
}
// kernel/bpf/preload/iterators/README
const ansiBenchmarkString = "\x1b[38;5;81m\x1b[01;31m\x1b[Kkernel/\x1b[0m\x1b[38:5:81mbpf/" +
"\x1b[0m\x1b[38:5:81mpreload/\x1b[0m\x1b[38;5;81miterators/" +
"\x1b[0m\x1b[38:5:149mMakefile\x1b[m\x1b[K\x1b[0m"
func BenchmarkNextAnsiEscapeSequence(b *testing.B) {
b.SetBytes(int64(len(ansiBenchmarkString)))
for i := 0; i < b.N; i++ {
s := ansiBenchmarkString
for {
_, o := nextAnsiEscapeSequence(s)
if o == -1 {
break
}
s = s[o:]
}
}
}
// Baseline test to compare the speed of nextAnsiEscapeSequence() to the
// previously used regex based implementation.
func BenchmarkNextAnsiEscapeSequence_Regex(b *testing.B) {
b.SetBytes(int64(len(ansiBenchmarkString)))
for i := 0; i < b.N; i++ {
s := ansiBenchmarkString
for {
a := ansiRegexReference.FindStringIndex(s)
if len(a) == 0 {
break
}
s = s[a[1]:]
}
}
}
func BenchmarkExtractColor(b *testing.B) {
b.SetBytes(int64(len(ansiBenchmarkString)))
for i := 0; i < b.N; i++ {
extractColor(ansiBenchmarkString, nil, nil)
}
}