src/testing/fstest/testfs.go - go - Git at Google

 // Copyright 2020 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 fstest implements support for testing implementations and users of file systems.
 package fstest

 import (
 	"errors"
 	"fmt"
 	"io"
 	"io/fs"
 	"path"
 	"reflect"
 	"sort"
 	"strings"
 	"testing/iotest"
 )

 // TestFS tests a file system implementation.
 // It walks the entire tree of files in fsys,
 // opening and checking that each file behaves correctly.
 // It also checks that the file system contains at least the expected files.
 // As a special case, if no expected files are listed, fsys must be empty.
 // Otherwise, fsys must contain at least the listed files; it can also contain others.
 // The contents of fsys must not change concurrently with TestFS.
 //
 // If TestFS finds any misbehaviors, it returns an error reporting all of them.
 // The error text spans multiple lines, one per detected misbehavior.
 //
 // Typical usage inside a test is:
 //
 //	if err := fstest.TestFS(myFS, "file/that/should/be/present"); err != nil {
 //		t.Fatal(err)
 //	}
 //
 func TestFS(fsys fs.FS, expected ...string) error {
 	if err := testFS(fsys, expected...); err != nil {
 		return err
 	}
 	for _, name := range expected {
 		if i := strings.Index(name, "/"); i >= 0 {
 			dir, dirSlash := name[:i], name[:i+1]
 			var subExpected []string
 			for _, name := range expected {
 				if strings.HasPrefix(name, dirSlash) {
 					subExpected = append(subExpected, name[len(dirSlash):])
 				}
 			}
 			sub, err := fs.Sub(fsys, dir)
 			if err != nil {
 				return err
 			}
 			if err := testFS(sub, subExpected...); err != nil {
 				return fmt.Errorf("testing fs.Sub(fsys, %s): %v", dir, err)
 			}
 			break // one sub-test is enough
 		}
 	}
 	return nil
 }

 func testFS(fsys fs.FS, expected ...string) error {
 	t := fsTester{fsys: fsys}
 	t.checkDir(".")
 	t.checkOpen(".")
 	found := make(map[string]bool)
 	for _, dir := range t.dirs {
 		found[dir] = true
 	}
 	for _, file := range t.files {
 		found[file] = true
 	}
 	delete(found, ".")
 	if len(expected) == 0 && len(found) > 0 {
 		var list []string
 		for k := range found {
 			if k != "." {
 				list = append(list, k)
 			}
 		}
 		sort.Strings(list)
 		if len(list) > 15 {
 			list = append(list[:10], "...")
 		}
 		t.errorf("expected empty file system but found files:\n%s", strings.Join(list, "\n"))
 	}
 	for _, name := range expected {
 		if !found[name] {
 			t.errorf("expected but not found: %s", name)
 		}
 	}
 	if len(t.errText) == 0 {
 		return nil
 	}
 	return errors.New("TestFS found errors:\n" + string(t.errText))
 }

 // An fsTester holds state for running the test.
 type fsTester struct {
 	fsys    fs.FS
 	errText []byte
 	dirs    []string
 	files   []string
 }

 // errorf adds an error line to errText.
 func (t *fsTester) errorf(format string, args ...interface{}) {
 	if len(t.errText) > 0 {
 		t.errText = append(t.errText, '\n')
 	}
 	t.errText = append(t.errText, fmt.Sprintf(format, args...)...)
 }

 func (t *fsTester) openDir(dir string) fs.ReadDirFile {
 	f, err := t.fsys.Open(dir)
 	if err != nil {
 		t.errorf("%s: Open: %v", dir, err)
 		return nil
 	}
 	d, ok := f.(fs.ReadDirFile)
 	if !ok {
 		f.Close()
 		t.errorf("%s: Open returned File type %T, not a fs.ReadDirFile", dir, f)
 		return nil
 	}
 	return d
 }

 // checkDir checks the directory dir, which is expected to exist
 // (it is either the root or was found in a directory listing with IsDir true).
 func (t *fsTester) checkDir(dir string) {
 	// Read entire directory.
 	t.dirs = append(t.dirs, dir)
 	d := t.openDir(dir)
 	if d == nil {
 		return
 	}
 	list, err := d.ReadDir(-1)
 	if err != nil {
 		d.Close()
 		t.errorf("%s: ReadDir(-1): %v", dir, err)
 		return
 	}

 	// Check all children.
 	var prefix string
 	if dir == "." {
 		prefix = ""
 	} else {
 		prefix = dir + "/"
 	}
 	for _, info := range list {
 		name := info.Name()
 		switch {
 		case name == ".", name == "..", name == "":
 			t.errorf("%s: ReadDir: child has invalid name: %#q", dir, name)
 			continue
 		case strings.Contains(name, "/"):
 			t.errorf("%s: ReadDir: child name contains slash: %#q", dir, name)
 			continue
 		case strings.Contains(name, `\`):
 			t.errorf("%s: ReadDir: child name contains backslash: %#q", dir, name)
 			continue
 		}
 		path := prefix + name
 		t.checkStat(path, info)
 		t.checkOpen(path)
 		if info.IsDir() {
 			t.checkDir(path)
 		} else {
 			t.checkFile(path)
 		}
 	}

 	// Check ReadDir(-1) at EOF.
 	list2, err := d.ReadDir(-1)
 	if len(list2) > 0 || err != nil {
 		d.Close()
 		t.errorf("%s: ReadDir(-1) at EOF = %d entries, %v, wanted 0 entries, nil", dir, len(list2), err)
 		return
 	}

 	// Check ReadDir(1) at EOF (different results).
 	list2, err = d.ReadDir(1)
 	if len(list2) > 0 || err != io.EOF {
 		d.Close()
 		t.errorf("%s: ReadDir(1) at EOF = %d entries, %v, wanted 0 entries, EOF", dir, len(list2), err)
 		return
 	}

 	// Check that close does not report an error.
 	if err := d.Close(); err != nil {
 		t.errorf("%s: Close: %v", dir, err)
 	}

 	// Check that closing twice doesn't crash.
 	// The return value doesn't matter.
 	d.Close()

 	// Reopen directory, read a second time, make sure contents match.
 	if d = t.openDir(dir); d == nil {
 		return
 	}
 	defer d.Close()
 	list2, err = d.ReadDir(-1)
 	if err != nil {
 		t.errorf("%s: second Open+ReadDir(-1): %v", dir, err)
 		return
 	}
 	t.checkDirList(dir, "first Open+ReadDir(-1) vs second Open+ReadDir(-1)", list, list2)

 	// Reopen directory, read a third time in pieces, make sure contents match.
 	if d = t.openDir(dir); d == nil {
 		return
 	}
 	defer d.Close()
 	list2 = nil
 	for {
 		n := 1
 		if len(list2) > 0 {
 			n = 2
 		}
 		frag, err := d.ReadDir(n)
 		if len(frag) > n {
 			t.errorf("%s: third Open: ReadDir(%d) after %d: %d entries (too many)", dir, n, len(list2), len(frag))
 			return
 		}
 		list2 = append(list2, frag...)
 		if err == io.EOF {
 			break
 		}
 		if err != nil {
 			t.errorf("%s: third Open: ReadDir(%d) after %d: %v", dir, n, len(list2), err)
 			return
 		}
 		if n == 0 {
 			t.errorf("%s: third Open: ReadDir(%d) after %d: 0 entries but nil error", dir, n, len(list2))
 			return
 		}
 	}
 	t.checkDirList(dir, "first Open+ReadDir(-1) vs third Open+ReadDir(1,2) loop", list, list2)

 	// If fsys has ReadDir, check that it matches and is sorted.
 	if fsys, ok := t.fsys.(fs.ReadDirFS); ok {
 		list2, err := fsys.ReadDir(dir)
 		if err != nil {
 			t.errorf("%s: fsys.ReadDir: %v", dir, err)
 			return
 		}
 		t.checkDirList(dir, "first Open+ReadDir(-1) vs fsys.ReadDir", list, list2)

 		for i := 0; i+1 < len(list2); i++ {
 			if list2[i].Name() >= list2[i+1].Name() {
 				t.errorf("%s: fsys.ReadDir: list not sorted: %s before %s", dir, list2[i].Name(), list2[i+1].Name())
 			}
 		}
 	}

 	// Check fs.ReadDir as well.
 	list2, err = fs.ReadDir(t.fsys, dir)
 	if err != nil {
 		t.errorf("%s: fs.ReadDir: %v", dir, err)
 		return
 	}
 	t.checkDirList(dir, "first Open+ReadDir(-1) vs fs.ReadDir", list, list2)

 	for i := 0; i+1 < len(list2); i++ {
 		if list2[i].Name() >= list2[i+1].Name() {
 			t.errorf("%s: fs.ReadDir: list not sorted: %s before %s", dir, list2[i].Name(), list2[i+1].Name())
 		}
 	}

 	t.checkGlob(dir, list)
 }

 // formatEntry formats an fs.DirEntry into a string for error messages and comparison.
 func formatEntry(entry fs.DirEntry) string {
 	return fmt.Sprintf("%s IsDir=%v Type=%v", entry.Name(), entry.IsDir(), entry.Type())
 }

 // formatInfoEntry formats an fs.FileInfo into a string like the result of formatEntry, for error messages and comparison.
 func formatInfoEntry(info fs.FileInfo) string {
 	return fmt.Sprintf("%s IsDir=%v Type=%v", info.Name(), info.IsDir(), info.Mode().Type())
 }

 // formatInfo formats an fs.FileInfo into a string for error messages and comparison.
 func formatInfo(info fs.FileInfo) string {
 	return fmt.Sprintf("%s IsDir=%v Mode=%v Size=%d ModTime=%v", info.Name(), info.IsDir(), info.Mode(), info.Size(), info.ModTime())
 }

 // checkGlob checks that various glob patterns work if the file system implements GlobFS.
 func (t *fsTester) checkGlob(dir string, list []fs.DirEntry) {
 	if _, ok := t.fsys.(fs.GlobFS); !ok {
 		return
 	}

 	// Make a complex glob pattern prefix that only matches dir.
 	var glob string
 	if dir != "." {
 		elem := strings.Split(dir, "/")
 		for i, e := range elem {
 			var pattern []rune
 			for j, r := range e {
 				if r == '*' || r == '?' || r == '\\' || r == '[' || r == '-' {
 					pattern = append(pattern, '\\', r)
 					continue
 				}
 				switch (i + j) % 5 {
 				case 0:
 					pattern = append(pattern, r)
 				case 1:
 					pattern = append(pattern, '[', r, ']')
 				case 2:
 					pattern = append(pattern, '[', r, '-', r, ']')
 				case 3:
 					pattern = append(pattern, '[', '\\', r, ']')
 				case 4:
 					pattern = append(pattern, '[', '\\', r, '-', '\\', r, ']')
 				}
 			}
 			elem[i] = string(pattern)
 		}
 		glob = strings.Join(elem, "/") + "/"
 	}

 	// Test that malformed patterns are detected.
 	// The error is likely path.ErrBadPattern but need not be.
 	if _, err := t.fsys.(fs.GlobFS).Glob(glob + "nonexist/[]"); err == nil {
 		t.errorf("%s: Glob(%#q): bad pattern not detected", dir, glob+"nonexist/[]")
 	}

 	// Try to find a letter that appears in only some of the final names.
 	c := rune('a')
 	for ; c <= 'z'; c++ {
 		have, haveNot := false, false
 		for _, d := range list {
 			if strings.ContainsRune(d.Name(), c) {
 				have = true
 			} else {
 				haveNot = true
 			}
 		}
 		if have && haveNot {
 			break
 		}
 	}
 	if c > 'z' {
 		c = 'a'
 	}
 	glob += "*" + string(c) + "*"

 	var want []string
 	for _, d := range list {
 		if strings.ContainsRune(d.Name(), c) {
 			want = append(want, path.Join(dir, d.Name()))
 		}
 	}

 	names, err := t.fsys.(fs.GlobFS).Glob(glob)
 	if err != nil {
 		t.errorf("%s: Glob(%#q): %v", dir, glob, err)
 		return
 	}
 	if reflect.DeepEqual(want, names) {
 		return
 	}

 	if !sort.StringsAreSorted(names) {
 		t.errorf("%s: Glob(%#q): unsorted output:\n%s", dir, glob, strings.Join(names, "\n"))
 		sort.Strings(names)
 	}

 	var problems []string
 	for len(want) > 0 || len(names) > 0 {
 		switch {
 		case len(want) > 0 && len(names) > 0 && want[0] == names[0]:
 			want, names = want[1:], names[1:]
 		case len(want) > 0 && (len(names) == 0 || want[0] < names[0]):
 			problems = append(problems, "missing: "+want[0])
 			want = want[1:]
 		default:
 			problems = append(problems, "extra: "+names[0])
 			names = names[1:]
 		}
 	}
 	t.errorf("%s: Glob(%#q): wrong output:\n%s", dir, glob, strings.Join(problems, "\n"))
 }

 // checkStat checks that a direct stat of path matches entry,
 // which was found in the parent's directory listing.
 func (t *fsTester) checkStat(path string, entry fs.DirEntry) {
 	file, err := t.fsys.Open(path)
 	if err != nil {
 		t.errorf("%s: Open: %v", path, err)
 		return
 	}
 	info, err := file.Stat()
 	file.Close()
 	if err != nil {
 		t.errorf("%s: Stat: %v", path, err)
 		return
 	}
 	fentry := formatEntry(entry)
 	fientry := formatInfoEntry(info)
 	// Note: mismatch here is OK for symlink, because Open dereferences symlink.
 	if fentry != fientry && entry.Type()&fs.ModeSymlink == 0 {
 		t.errorf("%s: mismatch:\n\tentry = %s\n\tfile.Stat() = %s", path, fentry, fientry)
 	}

 	einfo, err := entry.Info()
 	if err != nil {
 		t.errorf("%s: entry.Info: %v", path, err)
 		return
 	}
 	finfo := formatInfo(info)
 	if entry.Type()&fs.ModeSymlink != 0 {
 		// For symlink, just check that entry.Info matches entry on common fields.
 		// Open deferences symlink, so info itself may differ.
 		feentry := formatInfoEntry(einfo)
 		if fentry != feentry {
 			t.errorf("%s: mismatch\n\tentry = %s\n\tentry.Info() = %s\n", path, fentry, feentry)
 		}
 	} else {
 		feinfo := formatInfo(einfo)
 		if feinfo != finfo {
 			t.errorf("%s: mismatch:\n\tentry.Info() = %s\n\tfile.Stat() = %s\n", path, feinfo, finfo)
 		}
 	}

 	// Stat should be the same as Open+Stat, even for symlinks.
 	info2, err := fs.Stat(t.fsys, path)
 	if err != nil {
 		t.errorf("%s: fs.Stat: %v", path, err)
 		return
 	}
 	finfo2 := formatInfo(info2)
 	if finfo2 != finfo {
 		t.errorf("%s: fs.Stat(...) = %s\n\twant %s", path, finfo2, finfo)
 	}

 	if fsys, ok := t.fsys.(fs.StatFS); ok {
 		info2, err := fsys.Stat(path)
 		if err != nil {
 			t.errorf("%s: fsys.Stat: %v", path, err)
 			return
 		}
 		finfo2 := formatInfo(info2)
 		if finfo2 != finfo {
 			t.errorf("%s: fsys.Stat(...) = %s\n\twant %s", path, finfo2, finfo)
 		}
 	}
 }

 // checkDirList checks that two directory lists contain the same files and file info.
 // The order of the lists need not match.
 func (t *fsTester) checkDirList(dir, desc string, list1, list2 []fs.DirEntry) {
 	old := make(map[string]fs.DirEntry)
 	checkMode := func(entry fs.DirEntry) {
 		if entry.IsDir() != (entry.Type()&fs.ModeDir != 0) {
 			if entry.IsDir() {
 				t.errorf("%s: ReadDir returned %s with IsDir() = true, Type() & ModeDir = 0", dir, entry.Name())
 			} else {
 				t.errorf("%s: ReadDir returned %s with IsDir() = false, Type() & ModeDir = ModeDir", dir, entry.Name())
 			}
 		}
 	}

 	for _, entry1 := range list1 {
 		old[entry1.Name()] = entry1
 		checkMode(entry1)
 	}

 	var diffs []string
 	for _, entry2 := range list2 {
 		entry1 := old[entry2.Name()]
 		if entry1 == nil {
 			checkMode(entry2)
 			diffs = append(diffs, "+ "+formatEntry(entry2))
 			continue
 		}
 		if formatEntry(entry1) != formatEntry(entry2) {
 			diffs = append(diffs, "- "+formatEntry(entry1), "+ "+formatEntry(entry2))
 		}
 		delete(old, entry2.Name())
 	}
 	for _, entry1 := range old {
 		diffs = append(diffs, "- "+formatEntry(entry1))
 	}

 	if len(diffs) == 0 {
 		return
 	}

 	sort.Slice(diffs, func(i, j int) bool {
 		fi := strings.Fields(diffs[i])
 		fj := strings.Fields(diffs[j])
 		// sort by name (i < j) and then +/- (j < i, because + < -)
 		return fi[1]+" "+fj[0] < fj[1]+" "+fi[0]
 	})

 	t.errorf("%s: diff %s:\n\t%s", dir, desc, strings.Join(diffs, "\n\t"))
 }

 // checkFile checks that basic file reading works correctly.
 func (t *fsTester) checkFile(file string) {
 	t.files = append(t.files, file)

 	// Read entire file.
 	f, err := t.fsys.Open(file)
 	if err != nil {
 		t.errorf("%s: Open: %v", file, err)
 		return
 	}

 	data, err := io.ReadAll(f)
 	if err != nil {
 		f.Close()
 		t.errorf("%s: Open+ReadAll: %v", file, err)
 		return
 	}

 	if err := f.Close(); err != nil {
 		t.errorf("%s: Close: %v", file, err)
 	}

 	// Check that closing twice doesn't crash.
 	// The return value doesn't matter.
 	f.Close()

 	// Check that ReadFile works if present.
 	if fsys, ok := t.fsys.(fs.ReadFileFS); ok {
 		data2, err := fsys.ReadFile(file)
 		if err != nil {
 			t.errorf("%s: fsys.ReadFile: %v", file, err)
 			return
 		}
 		t.checkFileRead(file, "ReadAll vs fsys.ReadFile", data, data2)

 		// Modify the data and check it again. Modifying the
 		// returned byte slice should not affect the next call.
 		for i := range data2 {
 			data2[i]++
 		}
 		data2, err = fsys.ReadFile(file)
 		if err != nil {
 			t.errorf("%s: second call to fsys.ReadFile: %v", file, err)
 			return
 		}
 		t.checkFileRead(file, "Readall vs second fsys.ReadFile", data, data2)

 		t.checkBadPath(file, "ReadFile",
 			func(name string) error { _, err := fsys.ReadFile(name); return err })
 	}

 	// Check that fs.ReadFile works with t.fsys.
 	data2, err := fs.ReadFile(t.fsys, file)
 	if err != nil {
 		t.errorf("%s: fs.ReadFile: %v", file, err)
 		return
 	}
 	t.checkFileRead(file, "ReadAll vs fs.ReadFile", data, data2)

 	// Use iotest.TestReader to check small reads, Seek, ReadAt.
 	f, err = t.fsys.Open(file)
 	if err != nil {
 		t.errorf("%s: second Open: %v", file, err)
 		return
 	}
 	defer f.Close()
 	if err := iotest.TestReader(f, data); err != nil {
 		t.errorf("%s: failed TestReader:\n\t%s", file, strings.ReplaceAll(err.Error(), "\n", "\n\t"))
 	}
 }

 func (t *fsTester) checkFileRead(file, desc string, data1, data2 []byte) {
 	if string(data1) != string(data2) {
 		t.errorf("%s: %s: different data returned\n\t%q\n\t%q", file, desc, data1, data2)
 		return
 	}
 }

 // checkBadPath checks that various invalid forms of file's name cannot be opened using t.fsys.Open.
 func (t *fsTester) checkOpen(file string) {
 	t.checkBadPath(file, "Open", func(file string) error {
 		f, err := t.fsys.Open(file)
 		if err == nil {
 			f.Close()
 		}
 		return err
 	})
 }

 // checkBadPath checks that various invalid forms of file's name cannot be opened using open.
 func (t *fsTester) checkBadPath(file string, desc string, open func(string) error) {
 	bad := []string{
 		"/" + file,
 		file + "/.",
 	}
 	if file == "." {
 		bad = append(bad, "/")
 	}
 	if i := strings.Index(file, "/"); i >= 0 {
 		bad = append(bad,
 			file[:i]+"//"+file[i+1:],
 			file[:i]+"/./"+file[i+1:],
 			file[:i]+`\`+file[i+1:],
 			file[:i]+"/../"+file,
 		)
 	}
 	if i := strings.LastIndex(file, "/"); i >= 0 {
 		bad = append(bad,
 			file[:i]+"//"+file[i+1:],
 			file[:i]+"/./"+file[i+1:],
 			file[:i]+`\`+file[i+1:],
 			file+"/../"+file[i+1:],
 		)
 	}

 	for _, b := range bad {
 		if err := open(b); err == nil {
 			t.errorf("%s: %s(%s) succeeded, want error", file, desc, b)
 		}
 	}
 }
	// Copyright 2020 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 fstest implements support for testing implementations and users of file systems.
	package fstest

	import (
	"errors"
	"fmt"
	"io"
	"io/fs"
	"path"
	"reflect"
	"sort"
	"strings"
	"testing/iotest"
	)

	// TestFS tests a file system implementation.
	// It walks the entire tree of files in fsys,
	// opening and checking that each file behaves correctly.
	// It also checks that the file system contains at least the expected files.
	// As a special case, if no expected files are listed, fsys must be empty.
	// Otherwise, fsys must contain at least the listed files; it can also contain others.
	// The contents of fsys must not change concurrently with TestFS.
	//
	// If TestFS finds any misbehaviors, it returns an error reporting all of them.
	// The error text spans multiple lines, one per detected misbehavior.
	//
	// Typical usage inside a test is:
	//
	// if err := fstest.TestFS(myFS, "file/that/should/be/present"); err != nil {
	// t.Fatal(err)
	// }
	//
	func TestFS(fsys fs.FS, expected ...string) error {
	if err := testFS(fsys, expected...); err != nil {
	return err
	}
	for _, name := range expected {
	if i := strings.Index(name, "/"); i >= 0 {
	dir, dirSlash := name[:i], name[:i+1]
	var subExpected []string
	for _, name := range expected {
	if strings.HasPrefix(name, dirSlash) {
	subExpected = append(subExpected, name[len(dirSlash):])
	}
	}
	sub, err := fs.Sub(fsys, dir)
	if err != nil {
	return err
	}
	if err := testFS(sub, subExpected...); err != nil {
	return fmt.Errorf("testing fs.Sub(fsys, %s): %v", dir, err)
	}
	break // one sub-test is enough
	}
	}
	return nil
	}

	func testFS(fsys fs.FS, expected ...string) error {
	t := fsTester{fsys: fsys}
	t.checkDir(".")
	t.checkOpen(".")
	found := make(map[string]bool)
	for _, dir := range t.dirs {
	found[dir] = true
	}
	for _, file := range t.files {
	found[file] = true
	}
	delete(found, ".")
	if len(expected) == 0 && len(found) > 0 {
	var list []string
	for k := range found {
	if k != "." {
	list = append(list, k)
	}
	}
	sort.Strings(list)
	if len(list) > 15 {
	list = append(list[:10], "...")
	}
	t.errorf("expected empty file system but found files:\n%s", strings.Join(list, "\n"))
	}
	for _, name := range expected {
	if !found[name] {
	t.errorf("expected but not found: %s", name)
	}
	}
	if len(t.errText) == 0 {
	return nil
	}
	return errors.New("TestFS found errors:\n" + string(t.errText))
	}

	// An fsTester holds state for running the test.
	type fsTester struct {
	fsys fs.FS
	errText []byte
	dirs []string
	files []string
	}

	// errorf adds an error line to errText.
	func (t *fsTester) errorf(format string, args ...interface{}) {
	if len(t.errText) > 0 {
	t.errText = append(t.errText, '\n')
	}
	t.errText = append(t.errText, fmt.Sprintf(format, args...)...)
	}

	func (t *fsTester) openDir(dir string) fs.ReadDirFile {
	f, err := t.fsys.Open(dir)
	if err != nil {
	t.errorf("%s: Open: %v", dir, err)
	return nil
	}
	d, ok := f.(fs.ReadDirFile)
	if !ok {
	f.Close()
	t.errorf("%s: Open returned File type %T, not a fs.ReadDirFile", dir, f)
	return nil
	}
	return d
	}

	// checkDir checks the directory dir, which is expected to exist
	// (it is either the root or was found in a directory listing with IsDir true).
	func (t *fsTester) checkDir(dir string) {
	// Read entire directory.
	t.dirs = append(t.dirs, dir)
	d := t.openDir(dir)
	if d == nil {
	return
	}
	list, err := d.ReadDir(-1)
	if err != nil {
	d.Close()
	t.errorf("%s: ReadDir(-1): %v", dir, err)
	return
	}

	// Check all children.
	var prefix string
	if dir == "." {
	prefix = ""
	} else {
	prefix = dir + "/"
	}
	for _, info := range list {
	name := info.Name()
	switch {
	case name == ".", name == "..", name == "":
	t.errorf("%s: ReadDir: child has invalid name: %#q", dir, name)
	continue
	case strings.Contains(name, "/"):
	t.errorf("%s: ReadDir: child name contains slash: %#q", dir, name)
	continue
	case strings.Contains(name, `\`):
	t.errorf("%s: ReadDir: child name contains backslash: %#q", dir, name)
	continue
	}
	path := prefix + name
	t.checkStat(path, info)
	t.checkOpen(path)
	if info.IsDir() {
	t.checkDir(path)
	} else {
	t.checkFile(path)
	}
	}

	// Check ReadDir(-1) at EOF.
	list2, err := d.ReadDir(-1)
	if len(list2) > 0 \|\| err != nil {
	d.Close()
	t.errorf("%s: ReadDir(-1) at EOF = %d entries, %v, wanted 0 entries, nil", dir, len(list2), err)
	return
	}

	// Check ReadDir(1) at EOF (different results).
	list2, err = d.ReadDir(1)
	if len(list2) > 0 \|\| err != io.EOF {
	d.Close()
	t.errorf("%s: ReadDir(1) at EOF = %d entries, %v, wanted 0 entries, EOF", dir, len(list2), err)
	return
	}

	// Check that close does not report an error.
	if err := d.Close(); err != nil {
	t.errorf("%s: Close: %v", dir, err)
	}

	// Check that closing twice doesn't crash.
	// The return value doesn't matter.
	d.Close()

	// Reopen directory, read a second time, make sure contents match.
	if d = t.openDir(dir); d == nil {
	return
	}
	defer d.Close()
	list2, err = d.ReadDir(-1)
	if err != nil {
	t.errorf("%s: second Open+ReadDir(-1): %v", dir, err)
	return
	}
	t.checkDirList(dir, "first Open+ReadDir(-1) vs second Open+ReadDir(-1)", list, list2)

	// Reopen directory, read a third time in pieces, make sure contents match.
	if d = t.openDir(dir); d == nil {
	return
	}
	defer d.Close()
	list2 = nil
	for {
	n := 1
	if len(list2) > 0 {
	n = 2
	}
	frag, err := d.ReadDir(n)
	if len(frag) > n {
	t.errorf("%s: third Open: ReadDir(%d) after %d: %d entries (too many)", dir, n, len(list2), len(frag))
	return
	}
	list2 = append(list2, frag...)
	if err == io.EOF {
	break
	}
	if err != nil {
	t.errorf("%s: third Open: ReadDir(%d) after %d: %v", dir, n, len(list2), err)
	return
	}
	if n == 0 {
	t.errorf("%s: third Open: ReadDir(%d) after %d: 0 entries but nil error", dir, n, len(list2))
	return
	}
	}
	t.checkDirList(dir, "first Open+ReadDir(-1) vs third Open+ReadDir(1,2) loop", list, list2)

	// If fsys has ReadDir, check that it matches and is sorted.
	if fsys, ok := t.fsys.(fs.ReadDirFS); ok {
	list2, err := fsys.ReadDir(dir)
	if err != nil {
	t.errorf("%s: fsys.ReadDir: %v", dir, err)
	return
	}
	t.checkDirList(dir, "first Open+ReadDir(-1) vs fsys.ReadDir", list, list2)

	for i := 0; i+1 < len(list2); i++ {
	if list2[i].Name() >= list2[i+1].Name() {
	t.errorf("%s: fsys.ReadDir: list not sorted: %s before %s", dir, list2[i].Name(), list2[i+1].Name())
	}
	}
	}

	// Check fs.ReadDir as well.
	list2, err = fs.ReadDir(t.fsys, dir)
	if err != nil {
	t.errorf("%s: fs.ReadDir: %v", dir, err)
	return
	}
	t.checkDirList(dir, "first Open+ReadDir(-1) vs fs.ReadDir", list, list2)

	for i := 0; i+1 < len(list2); i++ {
	if list2[i].Name() >= list2[i+1].Name() {
	t.errorf("%s: fs.ReadDir: list not sorted: %s before %s", dir, list2[i].Name(), list2[i+1].Name())
	}
	}

	t.checkGlob(dir, list)
	}

	// formatEntry formats an fs.DirEntry into a string for error messages and comparison.
	func formatEntry(entry fs.DirEntry) string {
	return fmt.Sprintf("%s IsDir=%v Type=%v", entry.Name(), entry.IsDir(), entry.Type())
	}

	// formatInfoEntry formats an fs.FileInfo into a string like the result of formatEntry, for error messages and comparison.
	func formatInfoEntry(info fs.FileInfo) string {
	return fmt.Sprintf("%s IsDir=%v Type=%v", info.Name(), info.IsDir(), info.Mode().Type())
	}

	// formatInfo formats an fs.FileInfo into a string for error messages and comparison.
	func formatInfo(info fs.FileInfo) string {
	return fmt.Sprintf("%s IsDir=%v Mode=%v Size=%d ModTime=%v", info.Name(), info.IsDir(), info.Mode(), info.Size(), info.ModTime())
	}

	// checkGlob checks that various glob patterns work if the file system implements GlobFS.
	func (t *fsTester) checkGlob(dir string, list []fs.DirEntry) {
	if _, ok := t.fsys.(fs.GlobFS); !ok {
	return
	}

	// Make a complex glob pattern prefix that only matches dir.
	var glob string
	if dir != "." {
	elem := strings.Split(dir, "/")
	for i, e := range elem {
	var pattern []rune
	for j, r := range e {
	if r == '*' \|\| r == '?' \|\| r == '\\' \|\| r == '[' \|\| r == '-' {
	pattern = append(pattern, '\\', r)
	continue
	}
	switch (i + j) % 5 {
	case 0:
	pattern = append(pattern, r)
	case 1:
	pattern = append(pattern, '[', r, ']')
	case 2:
	pattern = append(pattern, '[', r, '-', r, ']')
	case 3:
	pattern = append(pattern, '[', '\\', r, ']')
	case 4:
	pattern = append(pattern, '[', '\\', r, '-', '\\', r, ']')
	}
	}
	elem[i] = string(pattern)
	}
	glob = strings.Join(elem, "/") + "/"
	}

	// Test that malformed patterns are detected.
	// The error is likely path.ErrBadPattern but need not be.
	if _, err := t.fsys.(fs.GlobFS).Glob(glob + "nonexist/[]"); err == nil {
	t.errorf("%s: Glob(%#q): bad pattern not detected", dir, glob+"nonexist/[]")
	}

	// Try to find a letter that appears in only some of the final names.
	c := rune('a')
	for ; c <= 'z'; c++ {
	have, haveNot := false, false
	for _, d := range list {
	if strings.ContainsRune(d.Name(), c) {
	have = true
	} else {
	haveNot = true
	}
	}
	if have && haveNot {
	break
	}
	}
	if c > 'z' {
	c = 'a'
	}
	glob += "" + string(c) + ""

	var want []string
	for _, d := range list {
	if strings.ContainsRune(d.Name(), c) {
	want = append(want, path.Join(dir, d.Name()))
	}
	}

	names, err := t.fsys.(fs.GlobFS).Glob(glob)
	if err != nil {
	t.errorf("%s: Glob(%#q): %v", dir, glob, err)
	return
	}
	if reflect.DeepEqual(want, names) {
	return
	}

	if !sort.StringsAreSorted(names) {
	t.errorf("%s: Glob(%#q): unsorted output:\n%s", dir, glob, strings.Join(names, "\n"))
	sort.Strings(names)
	}

	var problems []string
	for len(want) > 0 \|\| len(names) > 0 {
	switch {
	case len(want) > 0 && len(names) > 0 && want[0] == names[0]:
	want, names = want[1:], names[1:]
	case len(want) > 0 && (len(names) == 0 \|\| want[0] < names[0]):
	problems = append(problems, "missing: "+want[0])
	want = want[1:]
	default:
	problems = append(problems, "extra: "+names[0])
	names = names[1:]
	}
	}
	t.errorf("%s: Glob(%#q): wrong output:\n%s", dir, glob, strings.Join(problems, "\n"))
	}

	// checkStat checks that a direct stat of path matches entry,
	// which was found in the parent's directory listing.
	func (t *fsTester) checkStat(path string, entry fs.DirEntry) {
	file, err := t.fsys.Open(path)
	if err != nil {
	t.errorf("%s: Open: %v", path, err)
	return
	}
	info, err := file.Stat()
	file.Close()
	if err != nil {
	t.errorf("%s: Stat: %v", path, err)
	return
	}
	fentry := formatEntry(entry)
	fientry := formatInfoEntry(info)
	// Note: mismatch here is OK for symlink, because Open dereferences symlink.
	if fentry != fientry && entry.Type()&fs.ModeSymlink == 0 {
	t.errorf("%s: mismatch:\n\tentry = %s\n\tfile.Stat() = %s", path, fentry, fientry)
	}

	einfo, err := entry.Info()
	if err != nil {
	t.errorf("%s: entry.Info: %v", path, err)
	return
	}
	finfo := formatInfo(info)
	if entry.Type()&fs.ModeSymlink != 0 {
	// For symlink, just check that entry.Info matches entry on common fields.
	// Open deferences symlink, so info itself may differ.
	feentry := formatInfoEntry(einfo)
	if fentry != feentry {
	t.errorf("%s: mismatch\n\tentry = %s\n\tentry.Info() = %s\n", path, fentry, feentry)
	}
	} else {
	feinfo := formatInfo(einfo)
	if feinfo != finfo {
	t.errorf("%s: mismatch:\n\tentry.Info() = %s\n\tfile.Stat() = %s\n", path, feinfo, finfo)
	}
	}

	// Stat should be the same as Open+Stat, even for symlinks.
	info2, err := fs.Stat(t.fsys, path)
	if err != nil {
	t.errorf("%s: fs.Stat: %v", path, err)
	return
	}
	finfo2 := formatInfo(info2)
	if finfo2 != finfo {
	t.errorf("%s: fs.Stat(...) = %s\n\twant %s", path, finfo2, finfo)
	}

	if fsys, ok := t.fsys.(fs.StatFS); ok {
	info2, err := fsys.Stat(path)
	if err != nil {
	t.errorf("%s: fsys.Stat: %v", path, err)
	return
	}
	finfo2 := formatInfo(info2)
	if finfo2 != finfo {
	t.errorf("%s: fsys.Stat(...) = %s\n\twant %s", path, finfo2, finfo)
	}
	}
	}

	// checkDirList checks that two directory lists contain the same files and file info.
	// The order of the lists need not match.
	func (t *fsTester) checkDirList(dir, desc string, list1, list2 []fs.DirEntry) {
	old := make(map[string]fs.DirEntry)
	checkMode := func(entry fs.DirEntry) {
	if entry.IsDir() != (entry.Type()&fs.ModeDir != 0) {
	if entry.IsDir() {
	t.errorf("%s: ReadDir returned %s with IsDir() = true, Type() & ModeDir = 0", dir, entry.Name())
	} else {
	t.errorf("%s: ReadDir returned %s with IsDir() = false, Type() & ModeDir = ModeDir", dir, entry.Name())
	}
	}
	}

	for _, entry1 := range list1 {
	old[entry1.Name()] = entry1
	checkMode(entry1)
	}

	var diffs []string
	for _, entry2 := range list2 {
	entry1 := old[entry2.Name()]
	if entry1 == nil {
	checkMode(entry2)
	diffs = append(diffs, "+ "+formatEntry(entry2))
	continue
	}
	if formatEntry(entry1) != formatEntry(entry2) {
	diffs = append(diffs, "- "+formatEntry(entry1), "+ "+formatEntry(entry2))
	}
	delete(old, entry2.Name())
	}
	for _, entry1 := range old {
	diffs = append(diffs, "- "+formatEntry(entry1))
	}

	if len(diffs) == 0 {
	return
	}

	sort.Slice(diffs, func(i, j int) bool {
	fi := strings.Fields(diffs[i])
	fj := strings.Fields(diffs[j])
	// sort by name (i < j) and then +/- (j < i, because + < -)
	return fi[1]+" "+fj[0] < fj[1]+" "+fi[0]
	})

	t.errorf("%s: diff %s:\n\t%s", dir, desc, strings.Join(diffs, "\n\t"))
	}

	// checkFile checks that basic file reading works correctly.
	func (t *fsTester) checkFile(file string) {
	t.files = append(t.files, file)

	// Read entire file.
	f, err := t.fsys.Open(file)
	if err != nil {
	t.errorf("%s: Open: %v", file, err)
	return
	}

	data, err := io.ReadAll(f)
	if err != nil {
	f.Close()
	t.errorf("%s: Open+ReadAll: %v", file, err)
	return
	}

	if err := f.Close(); err != nil {
	t.errorf("%s: Close: %v", file, err)
	}

	// Check that closing twice doesn't crash.
	// The return value doesn't matter.
	f.Close()

	// Check that ReadFile works if present.
	if fsys, ok := t.fsys.(fs.ReadFileFS); ok {
	data2, err := fsys.ReadFile(file)
	if err != nil {
	t.errorf("%s: fsys.ReadFile: %v", file, err)
	return
	}
	t.checkFileRead(file, "ReadAll vs fsys.ReadFile", data, data2)

	// Modify the data and check it again. Modifying the
	// returned byte slice should not affect the next call.
	for i := range data2 {
	data2[i]++
	}
	data2, err = fsys.ReadFile(file)
	if err != nil {
	t.errorf("%s: second call to fsys.ReadFile: %v", file, err)
	return
	}
	t.checkFileRead(file, "Readall vs second fsys.ReadFile", data, data2)

	t.checkBadPath(file, "ReadFile",
	func(name string) error { _, err := fsys.ReadFile(name); return err })
	}

	// Check that fs.ReadFile works with t.fsys.
	data2, err := fs.ReadFile(t.fsys, file)
	if err != nil {
	t.errorf("%s: fs.ReadFile: %v", file, err)
	return
	}
	t.checkFileRead(file, "ReadAll vs fs.ReadFile", data, data2)

	// Use iotest.TestReader to check small reads, Seek, ReadAt.
	f, err = t.fsys.Open(file)
	if err != nil {
	t.errorf("%s: second Open: %v", file, err)
	return
	}
	defer f.Close()
	if err := iotest.TestReader(f, data); err != nil {
	t.errorf("%s: failed TestReader:\n\t%s", file, strings.ReplaceAll(err.Error(), "\n", "\n\t"))
	}
	}

	func (t *fsTester) checkFileRead(file, desc string, data1, data2 []byte) {
	if string(data1) != string(data2) {
	t.errorf("%s: %s: different data returned\n\t%q\n\t%q", file, desc, data1, data2)
	return
	}
	}

	// checkBadPath checks that various invalid forms of file's name cannot be opened using t.fsys.Open.
	func (t *fsTester) checkOpen(file string) {
	t.checkBadPath(file, "Open", func(file string) error {
	f, err := t.fsys.Open(file)
	if err == nil {
	f.Close()
	}
	return err
	})
	}

	// checkBadPath checks that various invalid forms of file's name cannot be opened using open.
	func (t *fsTester) checkBadPath(file string, desc string, open func(string) error) {
	bad := []string{
	"/" + file,
	file + "/.",
	}
	if file == "." {
	bad = append(bad, "/")
	}
	if i := strings.Index(file, "/"); i >= 0 {
	bad = append(bad,
	file[:i]+"//"+file[i+1:],
	file[:i]+"/./"+file[i+1:],
	file[:i]+`\`+file[i+1:],
	file[:i]+"/../"+file,
	)
	}
	if i := strings.LastIndex(file, "/"); i >= 0 {
	bad = append(bad,
	file[:i]+"//"+file[i+1:],
	file[:i]+"/./"+file[i+1:],
	file[:i]+`\`+file[i+1:],
	file+"/../"+file[i+1:],
	)
	}

	for _, b := range bad {
	if err := open(b); err == nil {
	t.errorf("%s: %s(%s) succeeded, want error", file, desc, b)
	}
	}
	}