// 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 kernel import ( "fmt" "math" "strings" "sync/atomic" "syscall" "gvisor.dev/gvisor/pkg/abi/linux" "gvisor.dev/gvisor/pkg/context" "gvisor.dev/gvisor/pkg/refs" "gvisor.dev/gvisor/pkg/sentry/fs" "gvisor.dev/gvisor/pkg/sentry/fs/lock" "gvisor.dev/gvisor/pkg/sentry/limits" "gvisor.dev/gvisor/pkg/sentry/vfs" "gvisor.dev/gvisor/pkg/sync" ) // FDFlags define flags for an individual descriptor. // // +stateify savable type FDFlags struct { // CloseOnExec indicates the descriptor should be closed on exec. CloseOnExec bool } // ToLinuxFileFlags converts a kernel.FDFlags object to a Linux file flags // representation. func (f FDFlags) ToLinuxFileFlags() (mask uint) { if f.CloseOnExec { mask |= linux.O_CLOEXEC } return } // ToLinuxFDFlags converts a kernel.FDFlags object to a Linux descriptor flags // representation. func (f FDFlags) ToLinuxFDFlags() (mask uint) { if f.CloseOnExec { mask |= linux.FD_CLOEXEC } return } // descriptor holds the details about a file descriptor, namely a pointer to // the file itself and the descriptor flags. // // Note that this is immutable and can only be changed via operations on the // descriptorTable. // // It contains both VFS1 and VFS2 file types, but only one of them can be set. // // +stateify savable type descriptor struct { // TODO(gvisor.dev/issue/1624): Remove fs.File. file *fs.File fileVFS2 *vfs.FileDescription flags FDFlags } // FDTable is used to manage File references and flags. // // +stateify savable type FDTable struct { refs.AtomicRefCount k *Kernel // mu protects below. mu sync.Mutex `state:"nosave"` // next is start position to find fd. next int32 // used contains the number of non-nil entries. It must be accessed // atomically. It may be read atomically without holding mu (but not // written). used int32 // descriptorTable holds descriptors. descriptorTable `state:".(map[int32]descriptor)"` } func (f *FDTable) saveDescriptorTable() map[int32]descriptor { m := make(map[int32]descriptor) f.forEach(func(fd int32, file *fs.File, fileVFS2 *vfs.FileDescription, flags FDFlags) { m[fd] = descriptor{ file: file, fileVFS2: fileVFS2, flags: flags, } }) return m } func (f *FDTable) loadDescriptorTable(m map[int32]descriptor) { f.init() // Initialize table. for fd, d := range m { f.setAll(fd, d.file, d.fileVFS2, d.flags) // Note that we do _not_ need to acquire a extra table reference here. The // table reference will already be accounted for in the file, so we drop the // reference taken by set above. switch { case d.file != nil: d.file.DecRef() case d.fileVFS2 != nil: d.fileVFS2.DecRef() } } } // drop drops the table reference. func (f *FDTable) drop(file *fs.File) { // Release locks. file.Dirent.Inode.LockCtx.Posix.UnlockRegion(f, lock.LockRange{0, lock.LockEOF}) // Send inotify events. d := file.Dirent var ev uint32 if fs.IsDir(d.Inode.StableAttr) { ev |= linux.IN_ISDIR } if file.Flags().Write { ev |= linux.IN_CLOSE_WRITE } else { ev |= linux.IN_CLOSE_NOWRITE } d.InotifyEvent(ev, 0) // Drop the table reference. file.DecRef() } // dropVFS2 drops the table reference. func (f *FDTable) dropVFS2(file *vfs.FileDescription) { // TODO(gvisor.dev/issue/1480): Release locks. // Generate inotify events. ev := uint32(linux.IN_CLOSE_NOWRITE) if file.IsWritable() { ev = linux.IN_CLOSE_WRITE } file.Dentry().InotifyWithParent(ev, 0, vfs.PathEvent) // Drop the table reference. file.DecRef() } // NewFDTable allocates a new FDTable that may be used by tasks in k. func (k *Kernel) NewFDTable() *FDTable { f := &FDTable{k: k} f.init() return f } // destroy removes all of the file descriptors from the map. func (f *FDTable) destroy() { f.RemoveIf(func(*fs.File, *vfs.FileDescription, FDFlags) bool { return true }) } // DecRef implements RefCounter.DecRef with destructor f.destroy. func (f *FDTable) DecRef() { f.DecRefWithDestructor(f.destroy) } // Size returns the number of file descriptor slots currently allocated. func (f *FDTable) Size() int { size := atomic.LoadInt32(&f.used) return int(size) } // forEach iterates over all non-nil files in sorted order. // // It is the caller's responsibility to acquire an appropriate lock. func (f *FDTable) forEach(fn func(fd int32, file *fs.File, fileVFS2 *vfs.FileDescription, flags FDFlags)) { // retries tracks the number of failed TryIncRef attempts for the same FD. retries := 0 fd := int32(0) for { file, fileVFS2, flags, ok := f.getAll(fd) if !ok { break } switch { case file != nil: if !file.TryIncRef() { retries++ if retries > 1000 { panic(fmt.Sprintf("File in FD table has been destroyed. FD: %d, File: %+v, FileOps: %+v", fd, file, file.FileOperations)) } continue // Race caught. } fn(fd, file, nil, flags) file.DecRef() case fileVFS2 != nil: if !fileVFS2.TryIncRef() { retries++ if retries > 1000 { panic(fmt.Sprintf("File in FD table has been destroyed. FD: %d, File: %+v, Impl: %+v", fd, fileVFS2, fileVFS2.Impl())) } continue // Race caught. } fn(fd, nil, fileVFS2, flags) fileVFS2.DecRef() } retries = 0 fd++ } } // String is a stringer for FDTable. func (f *FDTable) String() string { var buf strings.Builder f.forEach(func(fd int32, file *fs.File, fileVFS2 *vfs.FileDescription, flags FDFlags) { switch { case file != nil: n, _ := file.Dirent.FullName(nil /* root */) fmt.Fprintf(&buf, "\tfd:%d => name %s\n", fd, n) case fileVFS2 != nil: vfsObj := fileVFS2.Mount().Filesystem().VirtualFilesystem() name, err := vfsObj.PathnameWithDeleted(context.Background(), vfs.VirtualDentry{}, fileVFS2.VirtualDentry()) if err != nil { fmt.Fprintf(&buf, "\n", err) return } fmt.Fprintf(&buf, "\tfd:%d => name %s\n", fd, name) } }) return buf.String() } // NewFDs allocates new FDs guaranteed to be the lowest number available // greater than or equal to the fd parameter. All files will share the set // flags. Success is guaranteed to be all or none. func (f *FDTable) NewFDs(ctx context.Context, fd int32, files []*fs.File, flags FDFlags) (fds []int32, err error) { if fd < 0 { // Don't accept negative FDs. return nil, syscall.EINVAL } // Default limit. end := int32(math.MaxInt32) // Ensure we don't get past the provided limit. if limitSet := limits.FromContext(ctx); limitSet != nil { lim := limitSet.Get(limits.NumberOfFiles) if lim.Cur != limits.Infinity { end = int32(lim.Cur) } if fd >= end { return nil, syscall.EMFILE } } f.mu.Lock() defer f.mu.Unlock() // From f.next to find available fd. if fd < f.next { fd = f.next } // Install all entries. for i := fd; i < end && len(fds) < len(files); i++ { if d, _, _ := f.get(i); d == nil { f.set(i, files[len(fds)], flags) // Set the descriptor. fds = append(fds, i) // Record the file descriptor. } } // Failure? Unwind existing FDs. if len(fds) < len(files) { for _, i := range fds { f.set(i, nil, FDFlags{}) // Zap entry. } return nil, syscall.EMFILE } if fd == f.next { // Update next search start position. f.next = fds[len(fds)-1] + 1 } return fds, nil } // NewFDsVFS2 allocates new FDs guaranteed to be the lowest number available // greater than or equal to the fd parameter. All files will share the set // flags. Success is guaranteed to be all or none. func (f *FDTable) NewFDsVFS2(ctx context.Context, fd int32, files []*vfs.FileDescription, flags FDFlags) (fds []int32, err error) { if fd < 0 { // Don't accept negative FDs. return nil, syscall.EINVAL } // Default limit. end := int32(math.MaxInt32) // Ensure we don't get past the provided limit. if limitSet := limits.FromContext(ctx); limitSet != nil { lim := limitSet.Get(limits.NumberOfFiles) if lim.Cur != limits.Infinity { end = int32(lim.Cur) } if fd >= end { return nil, syscall.EMFILE } } f.mu.Lock() defer f.mu.Unlock() // From f.next to find available fd. if fd < f.next { fd = f.next } // Install all entries. for i := fd; i < end && len(fds) < len(files); i++ { if d, _, _ := f.getVFS2(i); d == nil { f.setVFS2(i, files[len(fds)], flags) // Set the descriptor. fds = append(fds, i) // Record the file descriptor. } } // Failure? Unwind existing FDs. if len(fds) < len(files) { for _, i := range fds { f.setVFS2(i, nil, FDFlags{}) // Zap entry. } return nil, syscall.EMFILE } if fd == f.next { // Update next search start position. f.next = fds[len(fds)-1] + 1 } return fds, nil } // NewFDVFS2 allocates a file descriptor greater than or equal to minfd for // the given file description. If it succeeds, it takes a reference on file. func (f *FDTable) NewFDVFS2(ctx context.Context, minfd int32, file *vfs.FileDescription, flags FDFlags) (int32, error) { if minfd < 0 { // Don't accept negative FDs. return -1, syscall.EINVAL } // Default limit. end := int32(math.MaxInt32) // Ensure we don't get past the provided limit. if limitSet := limits.FromContext(ctx); limitSet != nil { lim := limitSet.Get(limits.NumberOfFiles) if lim.Cur != limits.Infinity { end = int32(lim.Cur) } if minfd >= end { return -1, syscall.EMFILE } } f.mu.Lock() defer f.mu.Unlock() // From f.next to find available fd. fd := minfd if fd < f.next { fd = f.next } for fd < end { if d, _, _ := f.getVFS2(fd); d == nil { f.setVFS2(fd, file, flags) if fd == f.next { // Update next search start position. f.next = fd + 1 } return fd, nil } fd++ } return -1, syscall.EMFILE } // NewFDAt sets the file reference for the given FD. If there is an active // reference for that FD, the ref count for that existing reference is // decremented. func (f *FDTable) NewFDAt(ctx context.Context, fd int32, file *fs.File, flags FDFlags) error { return f.newFDAt(ctx, fd, file, nil, flags) } // NewFDAtVFS2 sets the file reference for the given FD. If there is an active // reference for that FD, the ref count for that existing reference is // decremented. func (f *FDTable) NewFDAtVFS2(ctx context.Context, fd int32, file *vfs.FileDescription, flags FDFlags) error { return f.newFDAt(ctx, fd, nil, file, flags) } func (f *FDTable) newFDAt(ctx context.Context, fd int32, file *fs.File, fileVFS2 *vfs.FileDescription, flags FDFlags) error { if fd < 0 { // Don't accept negative FDs. return syscall.EBADF } // Check the limit for the provided file. if limitSet := limits.FromContext(ctx); limitSet != nil { if lim := limitSet.Get(limits.NumberOfFiles); lim.Cur != limits.Infinity && uint64(fd) >= lim.Cur { return syscall.EMFILE } } // Install the entry. f.mu.Lock() defer f.mu.Unlock() f.setAll(fd, file, fileVFS2, flags) return nil } // SetFlags sets the flags for the given file descriptor. // // True is returned iff flags were changed. func (f *FDTable) SetFlags(fd int32, flags FDFlags) error { if fd < 0 { // Don't accept negative FDs. return syscall.EBADF } f.mu.Lock() defer f.mu.Unlock() file, _, _ := f.get(fd) if file == nil { // No file found. return syscall.EBADF } // Update the flags. f.set(fd, file, flags) return nil } // SetFlagsVFS2 sets the flags for the given file descriptor. // // True is returned iff flags were changed. func (f *FDTable) SetFlagsVFS2(fd int32, flags FDFlags) error { if fd < 0 { // Don't accept negative FDs. return syscall.EBADF } f.mu.Lock() defer f.mu.Unlock() file, _, _ := f.getVFS2(fd) if file == nil { // No file found. return syscall.EBADF } // Update the flags. f.setVFS2(fd, file, flags) return nil } // Get returns a reference to the file and the flags for the FD or nil if no // file is defined for the given fd. // // N.B. Callers are required to use DecRef when they are done. // //go:nosplit func (f *FDTable) Get(fd int32) (*fs.File, FDFlags) { if fd < 0 { return nil, FDFlags{} } for { file, flags, _ := f.get(fd) if file != nil { if !file.TryIncRef() { continue // Race caught. } // Reference acquired. return file, flags } // No file available. return nil, FDFlags{} } } // GetVFS2 returns a reference to the file and the flags for the FD or nil if no // file is defined for the given fd. // // N.B. Callers are required to use DecRef when they are done. // //go:nosplit func (f *FDTable) GetVFS2(fd int32) (*vfs.FileDescription, FDFlags) { if fd < 0 { return nil, FDFlags{} } for { file, flags, _ := f.getVFS2(fd) if file != nil { if !file.TryIncRef() { continue // Race caught. } // Reference acquired. return file, flags } // No file available. return nil, FDFlags{} } } // GetFDs returns a sorted list of valid fds. // // Precondition: The caller must be running on the task goroutine, or Task.mu // must be locked. func (f *FDTable) GetFDs() []int32 { fds := make([]int32, 0, int(atomic.LoadInt32(&f.used))) f.forEach(func(fd int32, _ *fs.File, _ *vfs.FileDescription, _ FDFlags) { fds = append(fds, fd) }) return fds } // GetRefs returns a stable slice of references to all files and bumps the // reference count on each. The caller must use DecRef on each reference when // they're done using the slice. func (f *FDTable) GetRefs() []*fs.File { files := make([]*fs.File, 0, f.Size()) f.forEach(func(_ int32, file *fs.File, _ *vfs.FileDescription, _ FDFlags) { file.IncRef() // Acquire a reference for caller. files = append(files, file) }) return files } // GetRefsVFS2 returns a stable slice of references to all files and bumps the // reference count on each. The caller must use DecRef on each reference when // they're done using the slice. func (f *FDTable) GetRefsVFS2() []*vfs.FileDescription { files := make([]*vfs.FileDescription, 0, f.Size()) f.forEach(func(_ int32, _ *fs.File, file *vfs.FileDescription, _ FDFlags) { file.IncRef() // Acquire a reference for caller. files = append(files, file) }) return files } // Fork returns an independent FDTable. func (f *FDTable) Fork() *FDTable { clone := f.k.NewFDTable() f.forEach(func(fd int32, file *fs.File, fileVFS2 *vfs.FileDescription, flags FDFlags) { // The set function here will acquire an appropriate table // reference for the clone. We don't need anything else. switch { case file != nil: clone.set(fd, file, flags) case fileVFS2 != nil: clone.setVFS2(fd, fileVFS2, flags) } }) return clone } // Remove removes an FD from and returns a non-file iff successful. // // N.B. Callers are required to use DecRef when they are done. func (f *FDTable) Remove(fd int32) (*fs.File, *vfs.FileDescription) { if fd < 0 { return nil, nil } f.mu.Lock() defer f.mu.Unlock() // Update current available position. if fd < f.next { f.next = fd } orig, orig2, _, _ := f.getAll(fd) // Add reference for caller. switch { case orig != nil: orig.IncRef() case orig2 != nil: orig2.IncRef() } if orig != nil || orig2 != nil { f.setAll(fd, nil, nil, FDFlags{}) // Zap entry. } return orig, orig2 } // RemoveIf removes all FDs where cond is true. func (f *FDTable) RemoveIf(cond func(*fs.File, *vfs.FileDescription, FDFlags) bool) { f.mu.Lock() defer f.mu.Unlock() f.forEach(func(fd int32, file *fs.File, fileVFS2 *vfs.FileDescription, flags FDFlags) { if cond(file, fileVFS2, flags) { f.set(fd, nil, FDFlags{}) // Clear from table. // Update current available position. if fd < f.next { f.next = fd } } }) }