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mirror of https://github.com/rclone/rclone synced 2024-12-27 19:43:48 +01:00
rclone/vfs/write.go
Saleh Dindar 23f8dea182 vfs: [bugfix] Implement Name() method in WriteFileHandle and ReadFileHandle
Name() method was originally left out and defaulted to the base
class which always returns empty. This trigerred incorrect behavior
in serve nfs where it relied on the Name() of the interafce to figure
out what file it was modifying.

This method is copied from RWFileHandle struct.

Added extra assert in the tests.
2023-10-06 14:08:20 +01:00

330 lines
9.5 KiB
Go

package vfs
import (
"context"
"io"
"os"
"sync"
"time"
"github.com/rclone/rclone/fs"
"github.com/rclone/rclone/fs/operations"
)
// WriteFileHandle is an open for write handle on a File
type WriteFileHandle struct {
baseHandle
mu sync.Mutex
cond sync.Cond // cond lock for out of sequence writes
remote string
pipeWriter *io.PipeWriter
o fs.Object
result chan error
file *File
offset int64
flags int
closed bool // set if handle has been closed
writeCalled bool // set the first time Write() is called
opened bool
truncated bool
}
// Check interfaces
var (
_ io.Writer = (*WriteFileHandle)(nil)
_ io.WriterAt = (*WriteFileHandle)(nil)
_ io.Closer = (*WriteFileHandle)(nil)
)
func newWriteFileHandle(d *Dir, f *File, remote string, flags int) (*WriteFileHandle, error) {
fh := &WriteFileHandle{
remote: remote,
flags: flags,
result: make(chan error, 1),
file: f,
}
fh.cond = sync.Cond{L: &fh.mu}
fh.file.addWriter(fh)
return fh, nil
}
// returns whether it is OK to truncate the file
func (fh *WriteFileHandle) safeToTruncate() bool {
return fh.truncated || fh.flags&os.O_TRUNC != 0 || !fh.file.exists()
}
// openPending opens the file if there is a pending open
//
// call with the lock held
func (fh *WriteFileHandle) openPending() (err error) {
if fh.opened {
return nil
}
if !fh.safeToTruncate() {
fs.Errorf(fh.remote, "WriteFileHandle: Can't open for write without O_TRUNC on existing file without --vfs-cache-mode >= writes")
return EPERM
}
var pipeReader *io.PipeReader
pipeReader, fh.pipeWriter = io.Pipe()
go func() {
// NB Rcat deals with Stats.Transferring, etc.
o, err := operations.Rcat(context.TODO(), fh.file.Fs(), fh.remote, pipeReader, time.Now(), nil)
if err != nil {
fs.Errorf(fh.remote, "WriteFileHandle.New Rcat failed: %v", err)
}
// Close the pipeReader so the pipeWriter fails with ErrClosedPipe
_ = pipeReader.Close()
fh.o = o
fh.result <- err
}()
fh.file.setSize(0)
fh.truncated = true
fh.file.Dir().addObject(fh.file) // make sure the directory has this object in it now
fh.opened = true
return nil
}
// String converts it to printable
func (fh *WriteFileHandle) String() string {
if fh == nil {
return "<nil *WriteFileHandle>"
}
fh.mu.Lock()
defer fh.mu.Unlock()
if fh.file == nil {
return "<nil *WriteFileHandle.file>"
}
return fh.file.String() + " (w)"
}
// Node returns the Node associated with this - satisfies Noder interface
func (fh *WriteFileHandle) Node() Node {
fh.mu.Lock()
defer fh.mu.Unlock()
return fh.file
}
// WriteAt writes len(p) bytes from p to the underlying data stream at offset
// off. It returns the number of bytes written from p (0 <= n <= len(p)) and
// any error encountered that caused the write to stop early. WriteAt must
// return a non-nil error if it returns n < len(p).
//
// If WriteAt is writing to a destination with a seek offset, WriteAt should
// not affect nor be affected by the underlying seek offset.
//
// Clients of WriteAt can execute parallel WriteAt calls on the same
// destination if the ranges do not overlap.
//
// Implementations must not retain p.
func (fh *WriteFileHandle) WriteAt(p []byte, off int64) (n int, err error) {
fh.mu.Lock()
defer fh.mu.Unlock()
return fh.writeAt(p, off)
}
// Implementation of WriteAt - call with lock held
func (fh *WriteFileHandle) writeAt(p []byte, off int64) (n int, err error) {
// defer log.Trace(fh.remote, "len=%d off=%d", len(p), off)("n=%d, fh.off=%d, err=%v", &n, &fh.offset, &err)
if fh.closed {
fs.Errorf(fh.remote, "WriteFileHandle.Write: error: %v", EBADF)
return 0, ECLOSED
}
if fh.offset != off {
waitSequential("write", fh.remote, &fh.cond, fh.file.VFS().Opt.WriteWait, &fh.offset, off)
}
if fh.offset != off {
fs.Errorf(fh.remote, "WriteFileHandle.Write: can't seek in file without --vfs-cache-mode >= writes")
return 0, ESPIPE
}
if err = fh.openPending(); err != nil {
return 0, err
}
fh.writeCalled = true
n, err = fh.pipeWriter.Write(p)
fh.offset += int64(n)
fh.file.setSize(fh.offset)
if err != nil {
fs.Errorf(fh.remote, "WriteFileHandle.Write error: %v", err)
return 0, err
}
// fs.Debugf(fh.remote, "WriteFileHandle.Write OK (%d bytes written)", n)
fh.cond.Broadcast() // wake everyone up waiting for an in-sequence read
return n, nil
}
// Write writes len(p) bytes from p to the underlying data stream. It returns
// the number of bytes written from p (0 <= n <= len(p)) and any error
// encountered that caused the write to stop early. Write must return a non-nil
// error if it returns n < len(p). Write must not modify the slice data, even
// temporarily.
//
// Implementations must not retain p.
func (fh *WriteFileHandle) Write(p []byte) (n int, err error) {
fh.mu.Lock()
defer fh.mu.Unlock()
// Since we can't seek, just call WriteAt with the current offset
return fh.writeAt(p, fh.offset)
}
// WriteString a string to the file
func (fh *WriteFileHandle) WriteString(s string) (n int, err error) {
return fh.Write([]byte(s))
}
// Offset returns the offset of the file pointer
func (fh *WriteFileHandle) Offset() (offset int64) {
fh.mu.Lock()
defer fh.mu.Unlock()
return fh.offset
}
// close the file handle returning EBADF if it has been
// closed already.
//
// Must be called with fh.mu held
func (fh *WriteFileHandle) close() (err error) {
if fh.closed {
return ECLOSED
}
fh.closed = true
// leave writer open until file is transferred
defer func() {
fh.file.delWriter(fh)
}()
// If file not opened and not safe to truncate then leave file intact
if !fh.opened && !fh.safeToTruncate() {
return nil
}
if err = fh.openPending(); err != nil {
return err
}
writeCloseErr := fh.pipeWriter.Close()
err = <-fh.result
if err == nil {
fh.file.setObject(fh.o)
err = writeCloseErr
} else {
// Remove vfs file entry when no object is present
if fh.file.getObject() == nil {
_ = fh.file.Remove()
}
}
return err
}
// Close closes the file
func (fh *WriteFileHandle) Close() error {
fh.mu.Lock()
defer fh.mu.Unlock()
return fh.close()
}
// Flush is called on each close() of a file descriptor. So if a
// filesystem wants to return write errors in close() and the file has
// cached dirty data, this is a good place to write back data and
// return any errors. Since many applications ignore close() errors
// this is not always useful.
//
// NOTE: The flush() method may be called more than once for each
// open(). This happens if more than one file descriptor refers to an
// opened file due to dup(), dup2() or fork() calls. It is not
// possible to determine if a flush is final, so each flush should be
// treated equally. Multiple write-flush sequences are relatively
// rare, so this shouldn't be a problem.
//
// Filesystems shouldn't assume that flush will always be called after
// some writes, or that if will be called at all.
func (fh *WriteFileHandle) Flush() error {
fh.mu.Lock()
defer fh.mu.Unlock()
if fh.closed {
fs.Debugf(fh.remote, "WriteFileHandle.Flush nothing to do")
return nil
}
// fs.Debugf(fh.remote, "WriteFileHandle.Flush")
// If Write hasn't been called then ignore the Flush - Release
// will pick it up
if !fh.writeCalled {
fs.Debugf(fh.remote, "WriteFileHandle.Flush unwritten handle, writing 0 bytes to avoid race conditions")
_, err := fh.writeAt([]byte{}, fh.offset)
return err
}
err := fh.close()
if err != nil {
fs.Errorf(fh.remote, "WriteFileHandle.Flush error: %v", err)
//} else {
// fs.Debugf(fh.remote, "WriteFileHandle.Flush OK")
}
return err
}
// 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 *WriteFileHandle) Release() error {
fh.mu.Lock()
defer fh.mu.Unlock()
if fh.closed {
fs.Debugf(fh.remote, "WriteFileHandle.Release nothing to do")
return nil
}
fs.Debugf(fh.remote, "WriteFileHandle.Release closing")
err := fh.close()
if err != nil {
fs.Errorf(fh.remote, "WriteFileHandle.Release error: %v", err)
//} else {
// fs.Debugf(fh.remote, "WriteFileHandle.Release OK")
}
return err
}
// Stat returns info about the file
func (fh *WriteFileHandle) Stat() (os.FileInfo, error) {
fh.mu.Lock()
defer fh.mu.Unlock()
return fh.file, nil
}
// Truncate file to given size
func (fh *WriteFileHandle) Truncate(size int64) (err error) {
// defer log.Trace(fh.remote, "size=%d", size)("err=%v", &err)
fh.mu.Lock()
defer fh.mu.Unlock()
if size != fh.offset {
fs.Errorf(fh.remote, "WriteFileHandle: Truncate: Can't change size without --vfs-cache-mode >= writes")
return EPERM
}
// File is correct size
if size == 0 {
fh.truncated = true
}
return nil
}
// Read reads up to len(p) bytes into p.
func (fh *WriteFileHandle) Read(p []byte) (n int, err error) {
fs.Errorf(fh.remote, "WriteFileHandle: Read: Can't read and write to file without --vfs-cache-mode >= minimal")
return 0, EPERM
}
// 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.
func (fh *WriteFileHandle) ReadAt(p []byte, off int64) (n int, err error) {
fs.Errorf(fh.remote, "WriteFileHandle: ReadAt: Can't read and write to file without --vfs-cache-mode >= minimal")
return 0, EPERM
}
// Sync commits the current contents of the file to stable storage. Typically,
// this means flushing the file system's in-memory copy of recently written
// data to disk.
func (fh *WriteFileHandle) Sync() error {
return nil
}
// Name returns the name of the file from the underlying Object.
func (fh *WriteFileHandle) Name() string {
return fh.file.String()
}