rclone/vfs/read.go
Nick Craig-Wood ba121eddf0 vfs: make objects of unknown size readable through the VFS
These objects (eg Google Docs) appear with 0 length in the VFS.

Before this change, these only read 0 bytes.

After this change, even though the size appears to be 0, the objects
can be read to the end.  If the objects are read to the end then the
size on the handle will be updated.
2019-09-14 13:09:07 +01:00

443 lines
12 KiB
Go

package vfs
import (
"context"
"io"
"os"
"sync"
"github.com/pkg/errors"
"github.com/rclone/rclone/fs"
"github.com/rclone/rclone/fs/accounting"
"github.com/rclone/rclone/fs/chunkedreader"
"github.com/rclone/rclone/fs/hash"
)
// ReadFileHandle is an open for read file handle on a File
type ReadFileHandle struct {
baseHandle
done func(err error)
mu sync.Mutex
closed bool // set if handle has been closed
r *accounting.Account
readCalled bool // set if read has been called
size int64 // size of the object (0 for unknown length)
offset int64 // offset of read of o
roffset int64 // offset of Read() calls
noSeek bool
sizeUnknown bool // set if size of source is not known
file *File
hash *hash.MultiHasher
opened bool
remote string
}
// Check interfaces
var (
_ io.Reader = (*ReadFileHandle)(nil)
_ io.ReaderAt = (*ReadFileHandle)(nil)
_ io.Seeker = (*ReadFileHandle)(nil)
_ io.Closer = (*ReadFileHandle)(nil)
)
func newReadFileHandle(f *File) (*ReadFileHandle, error) {
var mhash *hash.MultiHasher
var err error
o := f.getObject()
if !f.d.vfs.Opt.NoChecksum {
mhash, err = hash.NewMultiHasherTypes(o.Fs().Hashes())
if err != nil {
fs.Errorf(o.Fs(), "newReadFileHandle hash error: %v", err)
}
}
fh := &ReadFileHandle{
remote: o.Remote(),
noSeek: f.d.vfs.Opt.NoSeek,
file: f,
hash: mhash,
size: nonNegative(o.Size()),
sizeUnknown: o.Size() < 0,
}
return fh, nil
}
// openPending opens the file if there is a pending open
// call with the lock held
func (fh *ReadFileHandle) openPending() (err error) {
if fh.opened {
return nil
}
o := fh.file.getObject()
r, err := chunkedreader.New(context.TODO(), o, int64(fh.file.d.vfs.Opt.ChunkSize), int64(fh.file.d.vfs.Opt.ChunkSizeLimit)).Open()
if err != nil {
return err
}
tr := accounting.GlobalStats().NewTransfer(o)
fh.done = tr.Done
fh.r = tr.Account(r).WithBuffer() // account the transfer
fh.opened = true
return nil
}
// String converts it to printable
func (fh *ReadFileHandle) String() string {
if fh == nil {
return "<nil *ReadFileHandle>"
}
fh.mu.Lock()
defer fh.mu.Unlock()
if fh.file == nil {
return "<nil *ReadFileHandle.file>"
}
return fh.file.String() + " (r)"
}
// Node returns the Node assocuated with this - satisfies Noder interface
func (fh *ReadFileHandle) Node() Node {
fh.mu.Lock()
defer fh.mu.Unlock()
return fh.file
}
// seek to a new offset
//
// if reopen is true, then we won't attempt to use an io.Seeker interface
//
// Must be called with fh.mu held
func (fh *ReadFileHandle) seek(offset int64, reopen bool) (err error) {
if fh.noSeek {
return ESPIPE
}
fh.hash = nil
if !reopen {
ar := fh.r.GetAsyncReader()
// try to fullfill the seek with buffer discard
if ar != nil && ar.SkipBytes(int(offset-fh.offset)) {
fh.offset = offset
return nil
}
}
fh.r.StopBuffering() // stop the background reading first
oldReader := fh.r.GetReader()
r, ok := oldReader.(*chunkedreader.ChunkedReader)
if !ok {
fs.Logf(fh.remote, "ReadFileHandle.Read expected reader to be a ChunkedReader, got %T", oldReader)
reopen = true
}
if !reopen {
fs.Debugf(fh.remote, "ReadFileHandle.seek from %d to %d (fs.RangeSeeker)", fh.offset, offset)
_, err = r.RangeSeek(context.TODO(), offset, io.SeekStart, -1)
if err != nil {
fs.Debugf(fh.remote, "ReadFileHandle.Read fs.RangeSeeker failed: %v", err)
return err
}
} else {
fs.Debugf(fh.remote, "ReadFileHandle.seek from %d to %d", fh.offset, offset)
// close old one
err = oldReader.Close()
if err != nil {
fs.Debugf(fh.remote, "ReadFileHandle.Read seek close old failed: %v", err)
}
// re-open with a seek
o := fh.file.getObject()
r = chunkedreader.New(context.TODO(), o, int64(fh.file.d.vfs.Opt.ChunkSize), int64(fh.file.d.vfs.Opt.ChunkSizeLimit))
_, err := r.Seek(offset, 0)
if err != nil {
fs.Debugf(fh.remote, "ReadFileHandle.Read seek failed: %v", err)
return err
}
r, err = r.Open()
if err != nil {
fs.Debugf(fh.remote, "ReadFileHandle.Read seek failed: %v", err)
return err
}
}
fh.r.UpdateReader(r)
fh.offset = offset
return nil
}
// Seek the file - returns ESPIPE if seeking isn't possible
func (fh *ReadFileHandle) Seek(offset int64, whence int) (n int64, err error) {
fh.mu.Lock()
defer fh.mu.Unlock()
if fh.noSeek {
return 0, ESPIPE
}
size := fh.size
switch whence {
case io.SeekStart:
fh.roffset = 0
case io.SeekEnd:
fh.roffset = size
}
fh.roffset += offset
// we don't check the offset - the next Read will
return fh.roffset, nil
}
// ReadAt reads len(p) bytes into p starting at offset off in the
// underlying input source. It returns the number of bytes read (0 <=
// n <= len(p)) and any error encountered.
//
// When ReadAt returns n < len(p), it returns a non-nil error
// explaining why more bytes were not returned. In this respect,
// ReadAt is stricter than Read.
//
// Even if ReadAt returns n < len(p), it may use all of p as scratch
// space during the call. If some data is available but not len(p)
// bytes, ReadAt blocks until either all the data is available or an
// error occurs. In this respect ReadAt is different from Read.
//
// If the n = len(p) bytes returned by ReadAt are at the end of the
// input source, ReadAt may return either err == EOF or err == nil.
//
// If ReadAt is reading from an input source with a seek offset,
// ReadAt should not affect nor be affected by the underlying seek
// offset.
//
// Clients of ReadAt can execute parallel ReadAt calls on the same
// input source.
//
// Implementations must not retain p.
func (fh *ReadFileHandle) ReadAt(p []byte, off int64) (n int, err error) {
fh.mu.Lock()
defer fh.mu.Unlock()
return fh.readAt(p, off)
}
// Implementation of ReadAt - call with lock held
func (fh *ReadFileHandle) readAt(p []byte, off int64) (n int, err error) {
// defer log.Trace(fh.remote, "p[%d], off=%d", len(p), off)("n=%d, err=%v", &n, &err)
err = fh.openPending() // FIXME pending open could be more efficient in the presense of seek (and retries)
if err != nil {
return 0, err
}
// fs.Debugf(fh.remote, "ReadFileHandle.Read size %d offset %d", reqSize, off)
if fh.closed {
fs.Errorf(fh.remote, "ReadFileHandle.Read error: %v", EBADF)
return 0, ECLOSED
}
doSeek := off != fh.offset
if doSeek && fh.noSeek {
return 0, ESPIPE
}
var newOffset int64
retries := 0
reqSize := len(p)
doReopen := false
for {
if doSeek {
// Are we attempting to seek beyond the end of the
// file - if so just return EOF leaving the underlying
// file in an unchanged state.
if off >= fh.size {
fs.Debugf(fh.remote, "ReadFileHandle.Read attempt to read beyond end of file: %d > %d", off, fh.size)
return 0, io.EOF
}
// Otherwise do the seek
err = fh.seek(off, doReopen)
} else {
err = nil
}
if err == nil {
if reqSize > 0 {
fh.readCalled = true
}
n, err = io.ReadFull(fh.r, p)
newOffset = fh.offset + int64(n)
// if err == nil && rand.Intn(10) == 0 {
// err = errors.New("random error")
// }
if err == nil {
break
} else if (err == io.ErrUnexpectedEOF || err == io.EOF) && (newOffset == fh.size || fh.sizeUnknown) {
if fh.sizeUnknown {
// size is now known since we have read to the end
fh.sizeUnknown = false
fh.size = newOffset
}
// Have read to end of file - reset error
err = nil
break
}
}
if retries >= fs.Config.LowLevelRetries {
break
}
retries++
fs.Errorf(fh.remote, "ReadFileHandle.Read error: low level retry %d/%d: %v", retries, fs.Config.LowLevelRetries, err)
doSeek = true
doReopen = true
}
if err != nil {
fs.Errorf(fh.remote, "ReadFileHandle.Read error: %v", err)
} else {
fh.offset = newOffset
// fs.Debugf(fh.remote, "ReadFileHandle.Read OK")
if fh.hash != nil {
_, err = fh.hash.Write(p[:n])
if err != nil {
fs.Errorf(fh.remote, "ReadFileHandle.Read HashError: %v", err)
return 0, err
}
}
// If we have no error and we didn't fill the buffer, must be EOF
if n != len(p) {
err = io.EOF
}
}
return n, err
}
func (fh *ReadFileHandle) checkHash() error {
if fh.hash == nil || !fh.readCalled || fh.offset < fh.size {
return nil
}
o := fh.file.getObject()
for hashType, dstSum := range fh.hash.Sums() {
srcSum, err := o.Hash(context.TODO(), hashType)
if err != nil {
return err
}
if !hash.Equals(dstSum, srcSum) {
return errors.Errorf("corrupted on transfer: %v hash differ %q vs %q", hashType, dstSum, srcSum)
}
}
return nil
}
// Read reads up to len(p) bytes into p. It returns the number of bytes read (0
// <= n <= len(p)) and any error encountered. Even if Read returns n < len(p),
// it may use all of p as scratch space during the call. If some data is
// available but not len(p) bytes, Read conventionally returns what is
// available instead of waiting for more.
//
// When Read encounters an error or end-of-file condition after successfully
// reading n > 0 bytes, it returns the number of bytes read. It may return the
// (non-nil) error from the same call or return the error (and n == 0) from a
// subsequent call. An instance of this general case is that a Reader returning
// a non-zero number of bytes at the end of the input stream may return either
// err == EOF or err == nil. The next Read should return 0, EOF.
//
// Callers should always process the n > 0 bytes returned before considering
// the error err. Doing so correctly handles I/O errors that happen after
// reading some bytes and also both of the allowed EOF behaviors.
//
// Implementations of Read are discouraged from returning a zero byte count
// with a nil error, except when len(p) == 0. Callers should treat a return of
// 0 and nil as indicating that nothing happened; in particular it does not
// indicate EOF.
//
// Implementations must not retain p.
func (fh *ReadFileHandle) Read(p []byte) (n int, err error) {
fh.mu.Lock()
defer fh.mu.Unlock()
if fh.roffset >= fh.size && !fh.sizeUnknown {
return 0, io.EOF
}
n, err = fh.readAt(p, fh.roffset)
fh.roffset += int64(n)
return n, err
}
// close the file handle returning EBADF if it has been
// closed already.
//
// Must be called with fh.mu held
func (fh *ReadFileHandle) close() error {
if fh.closed {
return ECLOSED
}
fh.closed = true
if fh.opened {
var err error
defer func() {
fh.done(err)
}()
// Close first so that we have hashes
err = fh.r.Close()
if err != nil {
return err
}
// Now check the hash
err = fh.checkHash()
if err != nil {
return err
}
}
return nil
}
// Close closes the file
func (fh *ReadFileHandle) Close() error {
fh.mu.Lock()
defer fh.mu.Unlock()
return fh.close()
}
// Flush is called each time the file or directory is closed.
// Because there can be multiple file descriptors referring to a
// single opened file, Flush can be called multiple times.
func (fh *ReadFileHandle) Flush() error {
fh.mu.Lock()
defer fh.mu.Unlock()
if !fh.opened {
return nil
}
// fs.Debugf(fh.remote, "ReadFileHandle.Flush")
if err := fh.checkHash(); err != nil {
fs.Errorf(fh.remote, "ReadFileHandle.Flush error: %v", err)
return err
}
// fs.Debugf(fh.remote, "ReadFileHandle.Flush OK")
return nil
}
// Release is called when we are finished with the file handle
//
// It isn't called directly from userspace so the error is ignored by
// the kernel
func (fh *ReadFileHandle) Release() error {
fh.mu.Lock()
defer fh.mu.Unlock()
if !fh.opened {
return nil
}
if fh.closed {
fs.Debugf(fh.remote, "ReadFileHandle.Release nothing to do")
return nil
}
fs.Debugf(fh.remote, "ReadFileHandle.Release closing")
err := fh.close()
if err != nil {
fs.Errorf(fh.remote, "ReadFileHandle.Release error: %v", err)
} else {
// fs.Debugf(fh.remote, "ReadFileHandle.Release OK")
}
return err
}
// Size returns the size of the underlying file
func (fh *ReadFileHandle) Size() int64 {
fh.mu.Lock()
defer fh.mu.Unlock()
return fh.size
}
// Stat returns info about the file
func (fh *ReadFileHandle) Stat() (os.FileInfo, error) {
fh.mu.Lock()
defer fh.mu.Unlock()
return fh.file, nil
}