// Copyright 2018 The gVisor Authors. // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. package gofer import ( "fmt" "time" "golang.org/x/sys/unix" "gvisor.dev/gvisor/pkg/context" "gvisor.dev/gvisor/pkg/log" "gvisor.dev/gvisor/pkg/metric" "gvisor.dev/gvisor/pkg/p9" "gvisor.dev/gvisor/pkg/sentry/device" "gvisor.dev/gvisor/pkg/sentry/fs" "gvisor.dev/gvisor/pkg/sentry/fs/fsutil" "gvisor.dev/gvisor/pkg/sentry/fsmetric" "gvisor.dev/gvisor/pkg/sentry/memmap" "gvisor.dev/gvisor/pkg/syserror" "gvisor.dev/gvisor/pkg/usermem" "gvisor.dev/gvisor/pkg/waiter" ) // fileOperations implements fs.FileOperations for a remote file system. // // +stateify savable type fileOperations struct { fsutil.FileNoIoctl `state:"nosave"` fsutil.FileNoSplice `state:"nosplice"` waiter.AlwaysReady `state:"nosave"` // inodeOperations is the inodeOperations backing the file. It is protected // by a reference held by File.Dirent.Inode which is stable until // FileOperations.Release is called. inodeOperations *inodeOperations `state:"wait"` // dirCursor is the directory cursor. dirCursor string // handles are the opened remote file system handles, which may // be shared with other files. handles *handles `state:"nosave"` // flags are the flags used to open handles. flags fs.FileFlags `state:"wait"` } // fileOperations implements fs.FileOperations. var _ fs.FileOperations = (*fileOperations)(nil) // NewFile returns a file. NewFile is not appropriate with host pipes and sockets. // // The `name` argument is only used to log a warning if we are returning a // writeable+executable file. (A metric counter is incremented in this case as // well.) Note that we cannot call d.BaseName() directly in this function, // because that would lead to a lock order violation, since this is called in // d.Create which holds d.mu, while d.BaseName() takes d.parent.mu, and the two // locks must be taken in the opposite order. func NewFile(ctx context.Context, dirent *fs.Dirent, name string, flags fs.FileFlags, i *inodeOperations, handles *handles) *fs.File { // Remote file systems enforce readability/writability at an offset, // see fs/9p/vfs_inode.c:v9fs_vfs_atomic_open -> fs/open.c:finish_open. flags.Pread = true flags.Pwrite = true if fs.IsFile(dirent.Inode.StableAttr) { // If cache policy is "remote revalidating", then we must // ensure that we have a host FD. Otherwise, the // sentry-internal page cache will be used, and we can end up // in an inconsistent state if the remote file changes. cp := dirent.Inode.InodeOperations.(*inodeOperations).session().cachePolicy if cp == cacheRemoteRevalidating && handles.Host == nil { panic(fmt.Sprintf("remote-revalidating cache policy requires gofer to donate host FD, but file %q did not have host FD", name)) } } f := &fileOperations{ inodeOperations: i, handles: handles, flags: flags, } if flags.Write { if err := dirent.Inode.CheckPermission(ctx, fs.PermMask{Execute: true}); err == nil { metric.SuspiciousOperationsMetric.Increment("opened_write_execute_file") log.Warningf("Opened a writable executable: %q", name) } } if handles.Host != nil { fsmetric.GoferOpensHost.Increment() } else { fsmetric.GoferOpens9P.Increment() } return fs.NewFile(ctx, dirent, flags, f) } // Release implements fs.FileOpeations.Release. func (f *fileOperations) Release(context.Context) { f.handles.DecRef() } // Readdir implements fs.FileOperations.Readdir. func (f *fileOperations) Readdir(ctx context.Context, file *fs.File, serializer fs.DentrySerializer) (int64, error) { root := fs.RootFromContext(ctx) if root != nil { defer root.DecRef(ctx) } dirCtx := &fs.DirCtx{ Serializer: serializer, DirCursor: &f.dirCursor, } n, err := fs.DirentReaddir(ctx, file.Dirent, f, root, dirCtx, file.Offset()) if f.inodeOperations.session().cachePolicy.cacheUAttrs(file.Dirent.Inode) { f.inodeOperations.cachingInodeOps.TouchAccessTime(ctx, file.Dirent.Inode) } return n, err } // IterateDir implements fs.DirIterator.IterateDir. func (f *fileOperations) IterateDir(ctx context.Context, d *fs.Dirent, dirCtx *fs.DirCtx, offset int) (int, error) { f.inodeOperations.readdirMu.Lock() defer f.inodeOperations.readdirMu.Unlock() // Fetch directory entries if needed. if !f.inodeOperations.session().cachePolicy.cacheReaddir() || f.inodeOperations.readdirCache == nil { entries, err := f.readdirAll(ctx) if err != nil { return offset, err } // Cache the readdir result. f.inodeOperations.readdirCache = fs.NewSortedDentryMap(entries) } // Serialize the entries. n, err := fs.GenericReaddir(dirCtx, f.inodeOperations.readdirCache) return offset + n, err } // readdirAll fetches fs.DentAttrs for f, using the attributes of g. func (f *fileOperations) readdirAll(ctx context.Context) (map[string]fs.DentAttr, error) { entries := make(map[string]fs.DentAttr) var readOffset uint64 for { // We choose some arbitrary high number of directory entries (64k) and call // Readdir until we've exhausted them all. dirents, err := f.handles.File.readdir(ctx, readOffset, 64*1024) if err != nil { return nil, err } if len(dirents) == 0 { // We're done, we reached EOF. break } // The last dirent contains the offset into the next set of dirents. The gofer // returns the offset as an index into directories, not as a byte offset, because // converting a byte offset to an index into directories entries is a huge pain. // But everything is fine if we're consistent. readOffset = dirents[len(dirents)-1].Offset for _, dirent := range dirents { if dirent.Name == "." || dirent.Name == ".." { // These must not be included in Readdir results. continue } // Find a best approximation of the type. var nt fs.InodeType switch dirent.Type { case p9.TypeDir: nt = fs.Directory case p9.TypeSymlink: nt = fs.Symlink default: nt = fs.RegularFile } // Install the DentAttr. entries[dirent.Name] = fs.DentAttr{ Type: nt, // Construct the key to find the virtual inode. // Directory entries reside on the same Device // and SecondaryDevice as their parent. InodeID: goferDevice.Map(device.MultiDeviceKey{ Device: f.inodeOperations.fileState.key.Device, SecondaryDevice: f.inodeOperations.fileState.key.SecondaryDevice, Inode: dirent.QID.Path, }), } } } return entries, nil } // maybeSync will call FSync on the file if the file flags require it. func (f *fileOperations) maybeSync(ctx context.Context, file *fs.File, offset, n int64) error { flags := file.Flags() var syncType fs.SyncType switch { case flags.Direct || flags.Sync: syncType = fs.SyncAll case flags.DSync: syncType = fs.SyncData default: // No need to sync. return nil } return f.Fsync(ctx, file, offset, offset+n, syncType) } // Write implements fs.FileOperations.Write. func (f *fileOperations) Write(ctx context.Context, file *fs.File, src usermem.IOSequence, offset int64) (int64, error) { if fs.IsDir(file.Dirent.Inode.StableAttr) { // Not all remote file systems enforce this so this client does. return 0, syserror.EISDIR } var ( n int64 err error ) // The write is handled in different ways depending on the cache policy // and availability of a host-mappable FD. if f.inodeOperations.session().cachePolicy.useCachingInodeOps(file.Dirent.Inode) { n, err = f.inodeOperations.cachingInodeOps.Write(ctx, src, offset) } else if f.inodeOperations.fileState.hostMappable != nil { n, err = f.inodeOperations.fileState.hostMappable.Write(ctx, src, offset) } else { n, err = src.CopyInTo(ctx, f.handles.readWriterAt(ctx, offset)) } if n == 0 { // Nothing written. We are done. return 0, err } // Write the dirty pages and attributes if cache policy tells us to. if f.inodeOperations.session().cachePolicy.writeThrough(file.Dirent.Inode) { if werr := f.inodeOperations.cachingInodeOps.WriteDirtyPagesAndAttrs(ctx, file.Dirent.Inode); werr != nil { // Report no bytes written since the write faild. return 0, werr } } // We may need to sync the written bytes. if syncErr := f.maybeSync(ctx, file, offset, n); syncErr != nil { // Sync failed. Report 0 bytes written, since none of them are // guaranteed to have been synced. return 0, syncErr } return n, err } // incrementReadCounters increments the read counters for the read starting at the given time. We // use this function rather than using a defer in Read() to avoid the performance hit of defer. func (f *fileOperations) incrementReadCounters(start time.Time) { if f.handles.Host != nil { fsmetric.GoferReadsHost.Increment() fsmetric.FinishReadWait(fsmetric.GoferReadWaitHost, start) } else { fsmetric.GoferReads9P.Increment() fsmetric.FinishReadWait(fsmetric.GoferReadWait9P, start) } } // Read implements fs.FileOperations.Read. func (f *fileOperations) Read(ctx context.Context, file *fs.File, dst usermem.IOSequence, offset int64) (int64, error) { start := fsmetric.StartReadWait() if fs.IsDir(file.Dirent.Inode.StableAttr) { // Not all remote file systems enforce this so this client does. f.incrementReadCounters(start) return 0, syserror.EISDIR } if f.inodeOperations.session().cachePolicy.useCachingInodeOps(file.Dirent.Inode) { n, err := f.inodeOperations.cachingInodeOps.Read(ctx, file, dst, offset) f.incrementReadCounters(start) return n, err } n, err := dst.CopyOutFrom(ctx, f.handles.readWriterAt(ctx, offset)) f.incrementReadCounters(start) return n, err } // Fsync implements fs.FileOperations.Fsync. func (f *fileOperations) Fsync(ctx context.Context, file *fs.File, start, end int64, syncType fs.SyncType) error { switch syncType { case fs.SyncAll, fs.SyncData: if err := file.Dirent.Inode.WriteOut(ctx); err != nil { return err } fallthrough case fs.SyncBackingStorage: // Sync remote caches. if f.handles.Host != nil { // Sync the host fd directly. return unix.Fsync(f.handles.Host.FD()) } // Otherwise sync on the p9.File handle. return f.handles.File.fsync(ctx) } panic("invalid sync type") } // Flush implements fs.FileOperations.Flush. func (f *fileOperations) Flush(ctx context.Context, file *fs.File) error { // If this file is not opened writable then there is nothing to flush. // We do this because some p9 server implementations of Flush are // over-zealous. // // FIXME(edahlgren): weaken these implementations and remove this check. if !file.Flags().Write { return nil } // Execute the flush. return f.handles.File.flush(ctx) } // ConfigureMMap implements fs.FileOperations.ConfigureMMap. func (f *fileOperations) ConfigureMMap(ctx context.Context, file *fs.File, opts *memmap.MMapOpts) error { return f.inodeOperations.configureMMap(file, opts) } // UnstableAttr implements fs.FileOperations.UnstableAttr. func (f *fileOperations) UnstableAttr(ctx context.Context, file *fs.File) (fs.UnstableAttr, error) { s := f.inodeOperations.session() if s.cachePolicy.cacheUAttrs(file.Dirent.Inode) { return f.inodeOperations.cachingInodeOps.UnstableAttr(ctx, file.Dirent.Inode) } // Use f.handles.File, which represents 9P fids that have been opened, // instead of inodeFileState.file, which represents 9P fids that have not. // This may be significantly more efficient in some implementations. _, valid, pattr, err := getattr(ctx, f.handles.File) if err != nil { return fs.UnstableAttr{}, err } return unstable(ctx, valid, pattr, s.mounter, s.client), nil } // Seek implements fs.FileOperations.Seek. func (f *fileOperations) Seek(ctx context.Context, file *fs.File, whence fs.SeekWhence, offset int64) (int64, error) { return fsutil.SeekWithDirCursor(ctx, file, whence, offset, &f.dirCursor) }