rclone/fstest/fstest.go
database64128 a7a8372976
🧪 fstest: fix time tests on Windows and add convenience methods to check local and remote fs with precision
Previously only the fs being checked on gets passed to
GetModifyWindow(). However, in most tests, the test files are
generated in the local fs and transferred to the remote fs. So the
local fs time precision has to be taken into account.

This meant that on Windows the time tests failed because the
local fs has a time precision of 100ns. Checking remote items uploaded
from local fs on Windows also requires a modify window of 100ns.
2021-11-09 11:43:36 +00:00

530 lines
16 KiB
Go

// Package fstest provides utilities for testing the Fs
package fstest
// FIXME put name of test FS in Fs structure
import (
"bytes"
"context"
"flag"
"fmt"
"io"
"io/ioutil"
"log"
"math/rand"
"os"
"path"
"path/filepath"
"regexp"
"runtime"
"sort"
"strings"
"testing"
"time"
"github.com/rclone/rclone/fs"
"github.com/rclone/rclone/fs/accounting"
"github.com/rclone/rclone/fs/config"
"github.com/rclone/rclone/fs/config/configfile"
"github.com/rclone/rclone/fs/hash"
"github.com/rclone/rclone/fs/walk"
"github.com/rclone/rclone/lib/random"
"github.com/stretchr/testify/assert"
"github.com/stretchr/testify/require"
"golang.org/x/text/unicode/norm"
)
// Globals
var (
RemoteName = flag.String("remote", "", "Remote to test with, defaults to local filesystem")
Verbose = flag.Bool("verbose", false, "Set to enable logging")
DumpHeaders = flag.Bool("dump-headers", false, "Set to dump headers (needs -verbose)")
DumpBodies = flag.Bool("dump-bodies", false, "Set to dump bodies (needs -verbose)")
Individual = flag.Bool("individual", false, "Make individual bucket/container/directory for each test - much slower")
LowLevelRetries = flag.Int("low-level-retries", 10, "Number of low level retries")
UseListR = flag.Bool("fast-list", false, "Use recursive list if available. Uses more memory but fewer transactions.")
// SizeLimit signals tests to skip maximum test file size and skip inappropriate runs
SizeLimit = flag.Int64("size-limit", 0, "Limit maximum test file size")
// ListRetries is the number of times to retry a listing to overcome eventual consistency
ListRetries = flag.Int("list-retries", 3, "Number or times to retry listing")
// MatchTestRemote matches the remote names used for testing
MatchTestRemote = regexp.MustCompile(`^rclone-test-[abcdefghijklmnopqrstuvwxyz0123456789]{24}$`)
)
// Seed the random number generator
func init() {
rand.Seed(time.Now().UnixNano())
}
// Initialise rclone for testing
func Initialise() {
ctx := context.Background()
ci := fs.GetConfig(ctx)
// Never ask for passwords, fail instead.
// If your local config is encrypted set environment variable
// "RCLONE_CONFIG_PASS=hunter2" (or your password)
ci.AskPassword = false
// Override the config file from the environment - we don't
// parse the flags any more so this doesn't happen
// automatically
if envConfig := os.Getenv("RCLONE_CONFIG"); envConfig != "" {
_ = config.SetConfigPath(envConfig)
}
configfile.Install()
accounting.Start(ctx)
if *Verbose {
ci.LogLevel = fs.LogLevelDebug
}
if *DumpHeaders {
ci.Dump |= fs.DumpHeaders
}
if *DumpBodies {
ci.Dump |= fs.DumpBodies
}
ci.LowLevelRetries = *LowLevelRetries
ci.UseListR = *UseListR
}
// Item represents an item for checking
type Item struct {
Path string
Hashes map[hash.Type]string
ModTime time.Time
Size int64
}
// NewItem creates an item from a string content
func NewItem(Path, Content string, modTime time.Time) Item {
i := Item{
Path: Path,
ModTime: modTime,
Size: int64(len(Content)),
}
hash := hash.NewMultiHasher()
buf := bytes.NewBufferString(Content)
_, err := io.Copy(hash, buf)
if err != nil {
log.Fatalf("Failed to create item: %v", err)
}
i.Hashes = hash.Sums()
return i
}
// CheckTimeEqualWithPrecision checks the times are equal within the
// precision, returns the delta and a flag
func CheckTimeEqualWithPrecision(t0, t1 time.Time, precision time.Duration) (time.Duration, bool) {
dt := t0.Sub(t1)
if dt >= precision || dt <= -precision {
return dt, false
}
return dt, true
}
// AssertTimeEqualWithPrecision checks that want is within precision
// of got, asserting that with t and logging remote
func AssertTimeEqualWithPrecision(t *testing.T, remote string, want, got time.Time, precision time.Duration) {
dt, ok := CheckTimeEqualWithPrecision(want, got, precision)
assert.True(t, ok, fmt.Sprintf("%s: Modification time difference too big |%s| > %s (want %s vs got %s) (precision %s)", remote, dt, precision, want, got, precision))
}
// CheckModTime checks the mod time to the given precision
func (i *Item) CheckModTime(t *testing.T, obj fs.Object, modTime time.Time, precision time.Duration) {
AssertTimeEqualWithPrecision(t, obj.Remote(), i.ModTime, modTime, precision)
}
// CheckHashes checks all the hashes the object supports are correct
func (i *Item) CheckHashes(t *testing.T, obj fs.Object) {
require.NotNil(t, obj)
types := obj.Fs().Hashes().Array()
for _, Hash := range types {
// Check attributes
sum, err := obj.Hash(context.Background(), Hash)
require.NoError(t, err)
assert.True(t, hash.Equals(i.Hashes[Hash], sum), fmt.Sprintf("%s/%s: %v hash incorrect - expecting %q got %q", obj.Fs().String(), obj.Remote(), Hash, i.Hashes[Hash], sum))
}
}
// Check checks all the attributes of the object are correct
func (i *Item) Check(t *testing.T, obj fs.Object, precision time.Duration) {
i.CheckHashes(t, obj)
assert.Equal(t, i.Size, obj.Size(), fmt.Sprintf("%s: size incorrect file=%d vs obj=%d", i.Path, i.Size, obj.Size()))
i.CheckModTime(t, obj, obj.ModTime(context.Background()), precision)
}
// Normalize runs a utf8 normalization on the string if running on OS
// X. This is because OS X denormalizes file names it writes to the
// local file system.
func Normalize(name string) string {
if runtime.GOOS == "darwin" {
name = norm.NFC.String(name)
}
return name
}
// Items represents all items for checking
type Items struct {
byName map[string]*Item
byNameAlt map[string]*Item
items []Item
}
// NewItems makes an Items
func NewItems(items []Item) *Items {
is := &Items{
byName: make(map[string]*Item),
byNameAlt: make(map[string]*Item),
items: items,
}
// Fill up byName
for i := range items {
is.byName[Normalize(items[i].Path)] = &items[i]
}
return is
}
// Find checks off an item
func (is *Items) Find(t *testing.T, obj fs.Object, precision time.Duration) {
remote := Normalize(obj.Remote())
i, ok := is.byName[remote]
if !ok {
i, ok = is.byNameAlt[remote]
assert.True(t, ok, fmt.Sprintf("Unexpected file %q", remote))
}
if i != nil {
delete(is.byName, i.Path)
i.Check(t, obj, precision)
}
}
// Done checks all finished
func (is *Items) Done(t *testing.T) {
if len(is.byName) != 0 {
for name := range is.byName {
t.Logf("Not found %q", name)
}
}
assert.Equal(t, 0, len(is.byName), fmt.Sprintf("%d objects not found", len(is.byName)))
}
// makeListingFromItems returns a string representation of the items
//
// it returns two possible strings, one normal and one for windows
func makeListingFromItems(items []Item) string {
nameLengths := make([]string, len(items))
for i, item := range items {
remote := Normalize(item.Path)
nameLengths[i] = fmt.Sprintf("%s (%d)", remote, item.Size)
}
sort.Strings(nameLengths)
return strings.Join(nameLengths, ", ")
}
// makeListingFromObjects returns a string representation of the objects
func makeListingFromObjects(objs []fs.Object) string {
nameLengths := make([]string, len(objs))
for i, obj := range objs {
nameLengths[i] = fmt.Sprintf("%s (%d)", Normalize(obj.Remote()), obj.Size())
}
sort.Strings(nameLengths)
return strings.Join(nameLengths, ", ")
}
// filterEmptyDirs removes any empty (or containing only directories)
// directories from expectedDirs
func filterEmptyDirs(t *testing.T, items []Item, expectedDirs []string) (newExpectedDirs []string) {
dirs := map[string]struct{}{"": {}}
for _, item := range items {
base := item.Path
for {
base = path.Dir(base)
if base == "." || base == "/" {
break
}
dirs[base] = struct{}{}
}
}
for _, expectedDir := range expectedDirs {
if _, found := dirs[expectedDir]; found {
newExpectedDirs = append(newExpectedDirs, expectedDir)
} else {
t.Logf("Filtering empty directory %q", expectedDir)
}
}
return newExpectedDirs
}
// CheckListingWithRoot checks the fs to see if it has the
// expected contents with the given precision.
//
// If expectedDirs is non nil then we check those too. Note that no
// directories returned is also OK as some remotes don't return
// directories.
//
// dir is the directory used for the listing.
func CheckListingWithRoot(t *testing.T, f fs.Fs, dir string, items []Item, expectedDirs []string, precision time.Duration) {
if expectedDirs != nil && !f.Features().CanHaveEmptyDirectories {
expectedDirs = filterEmptyDirs(t, items, expectedDirs)
}
is := NewItems(items)
ctx := context.Background()
oldErrors := accounting.Stats(ctx).GetErrors()
var objs []fs.Object
var dirs []fs.Directory
var err error
var retries = *ListRetries
sleep := time.Second / 2
wantListing := makeListingFromItems(items)
gotListing := "<unset>"
listingOK := false
for i := 1; i <= retries; i++ {
objs, dirs, err = walk.GetAll(ctx, f, dir, true, -1)
if err != nil && err != fs.ErrorDirNotFound {
t.Fatalf("Error listing: %v", err)
}
gotListing = makeListingFromObjects(objs)
listingOK = wantListing == gotListing
if listingOK && (expectedDirs == nil || len(dirs) == len(expectedDirs)) {
// Put an extra sleep in if we did any retries just to make sure it really
// is consistent (here is looking at you Amazon Drive!)
if i != 1 {
extraSleep := 5*time.Second + sleep
t.Logf("Sleeping for %v just to make sure", extraSleep)
time.Sleep(extraSleep)
}
break
}
sleep *= 2
t.Logf("Sleeping for %v for list eventual consistency: %d/%d", sleep, i, retries)
time.Sleep(sleep)
if doDirCacheFlush := f.Features().DirCacheFlush; doDirCacheFlush != nil {
t.Logf("Flushing the directory cache")
doDirCacheFlush()
}
}
assert.True(t, listingOK, fmt.Sprintf("listing wrong, want\n %s got\n %s", wantListing, gotListing))
for _, obj := range objs {
require.NotNil(t, obj)
is.Find(t, obj, precision)
}
is.Done(t)
// Don't notice an error when listing an empty directory
if len(items) == 0 && oldErrors == 0 && accounting.Stats(ctx).GetErrors() == 1 {
accounting.Stats(ctx).ResetErrors()
}
// Check the directories
if expectedDirs != nil {
expectedDirsCopy := make([]string, len(expectedDirs))
for i, dir := range expectedDirs {
expectedDirsCopy[i] = Normalize(dir)
}
actualDirs := []string{}
for _, dir := range dirs {
actualDirs = append(actualDirs, Normalize(dir.Remote()))
}
sort.Strings(actualDirs)
sort.Strings(expectedDirsCopy)
assert.Equal(t, expectedDirsCopy, actualDirs, "directories")
}
}
// CheckListingWithPrecision checks the fs to see if it has the
// expected contents with the given precision.
//
// If expectedDirs is non nil then we check those too. Note that no
// directories returned is also OK as some remotes don't return
// directories.
func CheckListingWithPrecision(t *testing.T, f fs.Fs, items []Item, expectedDirs []string, precision time.Duration) {
CheckListingWithRoot(t, f, "", items, expectedDirs, precision)
}
// CheckListing checks the fs to see if it has the expected contents
func CheckListing(t *testing.T, f fs.Fs, items []Item) {
precision := f.Precision()
CheckListingWithPrecision(t, f, items, nil, precision)
}
// CheckItemsWithPrecision checks the fs with the specified precision
// to see if it has the expected items.
func CheckItemsWithPrecision(t *testing.T, f fs.Fs, precision time.Duration, items ...Item) {
CheckListingWithPrecision(t, f, items, nil, precision)
}
// CheckItems checks the fs to see if it has only the items passed in
// using a precision of fs.Config.ModifyWindow
func CheckItems(t *testing.T, f fs.Fs, items ...Item) {
CheckListingWithPrecision(t, f, items, nil, fs.GetModifyWindow(context.TODO(), f))
}
// CompareItems compares a set of DirEntries to a slice of items and a list of dirs
// The modtimes are compared with the precision supplied
func CompareItems(t *testing.T, entries fs.DirEntries, items []Item, expectedDirs []string, precision time.Duration, what string) {
is := NewItems(items)
var objs []fs.Object
var dirs []fs.Directory
wantListing := makeListingFromItems(items)
for _, entry := range entries {
switch x := entry.(type) {
case fs.Directory:
dirs = append(dirs, x)
case fs.Object:
objs = append(objs, x)
// do nothing
default:
t.Fatalf("unknown object type %T", entry)
}
}
gotListing := makeListingFromObjects(objs)
listingOK := wantListing == gotListing
assert.True(t, listingOK, fmt.Sprintf("%s not equal, want\n %s got\n %s", what, wantListing, gotListing))
for _, obj := range objs {
require.NotNil(t, obj)
is.Find(t, obj, precision)
}
is.Done(t)
// Check the directories
if expectedDirs != nil {
expectedDirsCopy := make([]string, len(expectedDirs))
for i, dir := range expectedDirs {
expectedDirsCopy[i] = Normalize(dir)
}
actualDirs := []string{}
for _, dir := range dirs {
actualDirs = append(actualDirs, Normalize(dir.Remote()))
}
sort.Strings(actualDirs)
sort.Strings(expectedDirsCopy)
assert.Equal(t, expectedDirsCopy, actualDirs, "directories not equal")
}
}
// Time parses a time string or logs a fatal error
func Time(timeString string) time.Time {
t, err := time.Parse(time.RFC3339Nano, timeString)
if err != nil {
log.Fatalf("Failed to parse time %q: %v", timeString, err)
}
return t
}
// LocalRemote creates a temporary directory name for local remotes
func LocalRemote() (path string, err error) {
path, err = ioutil.TempDir("", "rclone")
if err == nil {
// Now remove the directory
err = os.Remove(path)
}
path = filepath.ToSlash(path)
return
}
// RandomRemoteName makes a random bucket or subdirectory name
//
// Returns a random remote name plus the leaf name
func RandomRemoteName(remoteName string) (string, string, error) {
var err error
var leafName string
// Make a directory if remote name is null
if remoteName == "" {
remoteName, err = LocalRemote()
if err != nil {
return "", "", err
}
} else {
if !strings.HasSuffix(remoteName, ":") {
remoteName += "/"
}
leafName = "rclone-test-" + random.String(24)
if !MatchTestRemote.MatchString(leafName) {
log.Fatalf("%q didn't match the test remote name regexp", leafName)
}
remoteName += leafName
}
return remoteName, leafName, nil
}
// RandomRemote makes a random bucket or subdirectory on the remote
// from the -remote parameter
//
// Call the finalise function returned to Purge the fs at the end (and
// the parent if necessary)
//
// Returns the remote, its url, a finaliser and an error
func RandomRemote() (fs.Fs, string, func(), error) {
var err error
var parentRemote fs.Fs
remoteName := *RemoteName
remoteName, _, err = RandomRemoteName(remoteName)
if err != nil {
return nil, "", nil, err
}
remote, err := fs.NewFs(context.Background(), remoteName)
if err != nil {
return nil, "", nil, err
}
finalise := func() {
Purge(remote)
if parentRemote != nil {
Purge(parentRemote)
if err != nil {
log.Printf("Failed to purge %v: %v", parentRemote, err)
}
}
}
return remote, remoteName, finalise, nil
}
// Purge is a simplified re-implementation of operations.Purge for the
// test routine cleanup to avoid circular dependencies.
//
// It logs errors rather than returning them
func Purge(f fs.Fs) {
ctx := context.Background()
var err error
doFallbackPurge := true
if doPurge := f.Features().Purge; doPurge != nil {
doFallbackPurge = false
fs.Debugf(f, "Purge remote")
err = doPurge(ctx, "")
if err == fs.ErrorCantPurge {
doFallbackPurge = true
}
}
if doFallbackPurge {
dirs := []string{""}
err = walk.ListR(ctx, f, "", true, -1, walk.ListAll, func(entries fs.DirEntries) error {
var err error
entries.ForObject(func(obj fs.Object) {
fs.Debugf(f, "Purge object %q", obj.Remote())
err = obj.Remove(ctx)
if err != nil {
log.Printf("purge failed to remove %q: %v", obj.Remote(), err)
}
})
entries.ForDir(func(dir fs.Directory) {
dirs = append(dirs, dir.Remote())
})
return nil
})
sort.Strings(dirs)
for i := len(dirs) - 1; i >= 0; i-- {
dir := dirs[i]
fs.Debugf(f, "Purge dir %q", dir)
err := f.Rmdir(ctx, dir)
if err != nil {
log.Printf("purge failed to rmdir %q: %v", dir, err)
}
}
}
if err != nil {
log.Printf("purge failed: %v", err)
}
}